Energy Conservation Program: Energy Conservation Standards for General Service Fluorescent Lamps and Incandescent Reflector Lamps, 16920-17027 [E9-7634]
Download as PDF
<![CDATA[
16920
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket Number EE–2006–STD–0131]
RIN 1904–AA92
Energy Conservation Program: Energy
Conservation Standards for General
Service Fluorescent Lamps and
Incandescent Reflector Lamps
AGENCY: Office of Energy Efficiency and
Renewable Energy, Department of
Energy.
ACTION: Notice of proposed rulemaking.
SUMMARY: The Energy Policy and
Conservation Act (EPCA) prescribes
energy conservation standards for
various consumer products and
commercial and industrial equipment,
including general service fluorescent
lamps (GSFL) and incandescent
reflector lamps (IRL), and the statute
also requires the Department of Energy
(DOE) to subsequently determine
whether more stringent, amended
standards for GSFL and IRL would be
technologically feasible and
economically justified, and would save
a significant amount of energy. In
addition, EPCA directs DOE to consider
adoption of standards for additional
GSFL not already covered by EPCAprescribed standards. In this notice,
DOE proposes amended energy
conservation standards for certain GSFL
and IRL and new energy conservation
standards for certain additional GSFL
not currently covered by standards.
DATES: DOE held a public meeting on
Tuesday, February 3, 2009 in
Washington, DC. DOE began accepting
comments, data, and information
regarding this notice of proposed
rulemaking (NOPR) at the public
meeting, and will continue to accept
comments until no later than June 12,
2009. See section VIII, ‘‘Public
Participation,’’ of this NOPR for details.
ADDRESSES: The public meeting was
held at the U.S. Department of Energy,
Forrestal Building, Room 1E–245, 1000
Independence Avenue, SW.,
Washington, DC 20585–0121.
Any comments submitted must
identify the NOPR for Energy
Conservation Standards for Lighting
Products, and provide the docket
number EE–2006–STD–0131 and/or
regulatory information number (RIN)
number 1904–AA92. Comments may be
submitted using any of the following
methods:
• Federal eRulemaking Portal: https://
www.regulations.gov. Follow the
instructions for submitting comments.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
• E-mail: fluorescent_and_
incandescent_lamps.rulemaking@
ee.doe.gov. Include the docket number
EE–2006–STD–0131and/or RIN 1904–
AA92 in the subject line of the message.
• Postal Mail: Ms. Brenda Edwards,
U.S. Department of Energy, Building
Technologies Program, Mailstop EE–2J,
1000 Independence Avenue, SW.,
Washington, DC 20585–0121. Please
submit one signed paper original.
• Hand Delivery/Courier: Ms. Brenda
Edwards, U.S. Department of Energy,
Building Technologies Program, 950
L’Enfant Plaza, SW., Suite 600,
Washington, DC 20024. Telephone:
(202) 586–2945. Please submit one
signed paper original.
For detailed instructions on
submitting comments and additional
information on the rulemaking process,
see section VIII of this document (Public
Participation).
Docket: For access to the docket to
read background documents or
comments received, visit the U.S.
Department of Energy, Resource Room
of the Building Technologies Program,
950 L’Enfant Plaza, SW., Suite 600,
Washington, DC, (202) 586–2945,
between 9 a.m. and 4 p.m., Monday
through Friday, except Federal holidays.
Please call Ms. Brenda Edwards at the
above telephone number for additional
information regarding visiting the
Resource Room.
FOR FURTHER INFORMATION CONTACT: Ms.
Linda Graves, U.S. Department of
Energy, Office of Energy Efficiency and
Renewable Energy, Building
Technologies Program, EE–2J, 1000
Independence Avenue, SW.,
Washington, DC 20585–0121.
Telephone: (202) 586–1851. E-mail:
Linda.Graves@ee.doe.gov.
Mr. Eric Stas or Ms. Francine Pinto,
U.S. Department of Energy, Office of the
General Counsel, GC–72, Forrestal
Building, Mail Station GC–72, 1000
Independence Avenue, SW.,
Washington, DC 20585–0121.
Telephone: (202) 586–9507. E-mail:
Eric.Stas@hq.doe.gov or
Francine.Pinto@hq.doe.gov.
For information on how to submit or
review public comments, contact Ms.
Brenda Edwards, U.S. Department of
Energy, Office of Energy Efficiency and
Renewable Energy, Building
Technologies Program, EE–2J, 1000
Independence Avenue, SW.,
Washington, DC 20585–0121.
Telephone: (202) 586–2945. E-mail:
Brenda.Edwards@ee.doe.gov.
SUPPLEMENTARY INFORMATION:
Table of Contents
I. Summary of the Proposed Rule
PO 00000
Frm 00002
Fmt 4701
Sfmt 4702
II. Introduction
A. Consumer Overview
B. Authority
C. Background
1. Current Standards
2. History of Standards Rulemaking for
General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps
III. Issues Affecting the Scope of This
Rulemaking
A. Additional General Service Fluorescent
Lamps for Which DOE is Proposing
Standards
1. Scope of EPCA Requirement that DOE
Consider Standards for Additional
Lamps
2. Identification of the Additional Lamps
for Which DOE Proposes Standards
a. Coverage of T5 Lamps
b. Extension of Lamp Wattage Ranges
3. Summary GSFL Lamps to Which DOE
Proposes to Extend Coverage
B. Exempted Incandescent Reflector Lamps
C. Amended Definitions
1. ‘‘Rated Wattage’’
2. ‘‘Colored Fluorescent Lamp’’
D. Off Mode and Standby Mode Energy
Consumption Standards
E. Color Rendering Index Standards for
General Service Fluorescent Lamps
IV. General Discussion
A. Test Procedures
B. Technological Feasibility
1. General
2. Maximum Technologically Feasible
Levels
C. Energy Savings
1. Determination of Savings
2. Significance of Savings
D. Economic Justification
1. Specific Criteria
a. Economic Impact on Manufacturers and
Consumers
b. Life-Cycle Costs
c. Energy Savings
d. Lessening of Utility or Performance of
Products
e. Impact of Any Lessening of Competition
f. Need of the Nation to Conserve Energy
g. Other Factors
2. Rebuttable Presumption
V. Methodology and Discussion of Comments
A. Product Classes
1. General Service Fluorescent Lamps
a. T12 and T8 Lamps
b. T5 Lamps
c. Correlated Color Temperature
2. Incandescent Reflector Lamps
a. Modified-Spectrum Lamps
b. Long-Life Lamps
c. Lamp Diameter
d. Voltage
B. Screening Analysis
1. General Service Fluorescent Lamps
a. Higher-Efficiency Lamp Fill Gas
Composition
b. Higher-Efficiency Phosphors
c. Glass Coating
d. Lamp Diameter
e. Multi-Photon Phosphors
2. Incandescent Reflector Lamps
C. Engineering Analysis
1. Approach
2. Representative Product Classes
3. Baseline Lamps and Systems
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. Lamp and Lamp-and-Ballast Designs
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Efficiency Levels
a. General Service Fluorescent Lamps
i. Revisions to ANOPR Efficiency Levels
ii. Four-Foot T5 Miniature Bipin Efficiency
Levels
b. Incandescent Reflector Lamps
6. Engineering Analysis Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
7. Scaling to Product Classes Not Analyzed
a. General Service Fluorescent Lamps
i. Correlated Color Temperature
ii. U-Shaped Lamps
b. Incandescent Reflector Lamps
i. Modified-Spectrum IRL
ii. Lamp Diameter
iii. Voltage
D. Life-Cycle Cost and Payback Period
Analyses
1. Consumer Product Price
2. Sales Tax
3. Installation Costs
4. Disposal Costs
5. Annual Operating Hours
a. Sectors Analyzed
b. Regional Variation
c. Building Type
6. Product Energy Consumption Rate
7. Electricity Prices
8. Electricity Price Trends
9. Lifetime
a. Ballast Lifetime
b. Lamp Lifetime
10. Discount Rates
11. Analysis Period
12. Effective Date
13. Payback Period Inputs
14. Lamp Purchase Events
E. National Impact Analysis—National
Energy Savings and Net Present Value
Analysis
1. General
a. Overview of NIA Changes in This Notice
2. Shipments Analysis
a. Lamp Inventory
b. Shipments Growth
i. Floor Space and Building Growth
ii. Lamps per Household
iii. Wider Spacing of More-Efficient
Fixtures
c. Base-Case Scenarios: Emerging
Technologies and Existing Technologies
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
d. Fluorescent Market Sectors Analyzed
e. GSFL Product Migration
i. Ballast Rule Effective Start Date
ii. Four-Foot Medium Bipin T12 Lamp
Replacements
iii. Eight-Foot Single Pin Slimline T12
Lamp Replacements
iv. Four-Foot T5 Lamps
3. Base-Case Market-Share Matrices
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. GSFL Standards-Case Shipment
Scenarios and Forecasts
a. Shift/Roll-Up Scenarios
b. Lighting Expertise Scenarios
c. Voluntary Retrofits
5. IRL-Standards-Case Shipment Scenarios
and Forecasts
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
i. Shift/Roll-Up Scenarios
ii. Product-Substitution Scenarios
6. Other Inputs
a. Analysis Period
b. Total Installed Cost
c. Electricity Price Forecast
d. Energy Site-to-Source Conversion
e. HVAC Interaction Factor
f. Rebound Effect
g. Discount Rates
F. Consumer Subgroup Analysis
G. Manufacturer Impact Analysis
1. Overview
a. Phase 1, Industry Profile
b. Phase 2, Industry Cash-Flow Analysis
c. Phase 3, Subgroup Impact Analysis
2. Discussion of Comments
3. Government Regulatory Impact Model
Analysis
4. Manufacturer Interviews
a. Key Issues
i. GSFL
ii. IRL
b. Government Regulatory Impact Model
Scenarios and Key Inputs
i. GSFL Base-Case Shipment Forecast
ii. IRL Base Case Shipments Forecast
iii. GSFL Standards Case Shipments
Forecast
iv. IRL Standards-Case Shipments Forecast
v. Manufacturing Production Costs
vi. Amended Energy Conservation
Standards Markup Scenarios
vii. Product and Capital Conversion Costs
H. Employment Impact Analysis
I. Utility Impact Analysis
J. Environmental Analysis
VI. Analytical Results
A. Trial Standard Levels
1. General Service Fluorescent Lamps
2. Incandescent Reflector Lamps
B. Economic Justification and Energy
Savings
1. Economic Impacts on Consumers
a. Life-Cycle Cost and Payback Period
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
b. Consumer Subgroup Analysis
i. Low-Income Households
ii. Institutions of Religious Worship
iii. Institutions That Serve Low-Income
Populations
iv. Historical Facilities
v. Consumers of T12 electronic ballasts
2. Economic Impacts on Manufacturers
a. Industry Cash-Flow Analysis Results
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
b. Cumulative Regulatory Burden
c. Impacts on Employment
d. Impacts on Manufacturing Capacity
e. Impacts on Manufacturer Subgroups
3. National Impact Analysis
a. Significance of Energy Savings
b. Net Present Value
c. Impacts on Employment
4. Impact on Utility or Performance of
Products
5. Impact of Any Lessening of Competition
6. Need of the Nation to Conserve Energy
C. Proposed Standard
1. Overview
2. General Service Fluorescent Lamps
Conclusion
a. Trial Standard Level 5
b. Trial Standard Level 4
PO 00000
Frm 00003
Fmt 4701
Sfmt 4702
16921
c. Trial Standard Level 3
3. Incandescent Reflector Lamps
Conclusion
a. Trial Standard Level 5
b. Trial Standard Level 4
VII. Procedural Issues and Regulatory Review
A. Review Under Executive Order 12866
B. Review Under the Regulatory Flexibility
Act
C. Review Under the Paperwork Reduction
Act
D. Review Under the National
Environmental Policy Act
E. Review Under Executive Order 13132
F. Review Under Executive Order 12988
G. Review Under the Unfunded Mandates
Reform Act of 1995
H. Review Under the Treasury and General
Government Appropriations Act, 1999
I. Review Under Executive Order 12630
J. Review Under the Treasury and General
Government Appropriations Act, 2001
K. Review Under Executive Order 13211
L. Review Under the Information Quality
Bulletin for Peer Review
VIII. Public Participation
A. Submission of Comments
B. Issues on Which DOE Seeks Comment
IX. Approval of the Office of the Secretary
Acronyms and Abbreviations
ACEEE American Council for an Energy
Efficiency Economy
AEO Annual Energy Outlook
ANOPR advance notice of proposed
rulemaking
ANSI American National Standards
Institute
ASAP Appliance Standards Awareness
Project
ASE Alliance to Save Energy
BF ballast factor
BLS Bureau of Labor Statistics
BPAR bulged parabolic aluminized reflector
BR bulged reflector (reflector lamp shape)
BT Building Technologies Program
BTU British Thermal Unit
CAIR Clean Air Interstate Act
CAMR Clean Air Mercury Rule
CBECS Commercial Buildings Energy
Consumption Survey
CCT correlated color temperature
CFR Code of Federal Regulations
CFL compact fluorescent lamp
CIE International Commission on
Illumination
CMH ceramic metal halide
CO2 carbon dioxide
CRI color rendering index
CSL candidate standard level
DIY do-it-yourself
DOE U.S. Department of Energy
DOJ U.S. Department of Justice
E26 Edison screw-base (incandescent lamp
base type)
EERE Office of Energy Efficiency and
Renewable Energy
EIA Energy Information Administration
EISA 2007 Energy Independence and
Security Act of 2007
EL efficacy level
EPA Environmental Protection Agency
EPACT 1992 Energy Policy Act of 1992
EPACT 2005 Energy Policy Act of 2005
EPCA Energy Policy and Conservation Act
ER elliptical reflector (reflector lamp shape)
E:\FR\FM\13APP2.SGM
13APP2
16922
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
FEMP Federal Energy Management Program
FR Federal Register
FTC Federal Trade Commission
GE General Electric Lighting and Industrial
GRIM Government Regulatory Impact
Model
GSFL general service fluorescent lamp
GSIL general service incandescent lamp
GW gigawatt
Hg mercury
HID high-intensity discharge
HIR halogen infrared reflector
HO high output
HVAC Heating, Ventilating and AirConditioning
IESNA Illuminating Engineering Society of
North America
ImSET Impact of Sector Energy
Technologies
INPV industry net present value
I–O input-output
IPCC Intergovernmental Panel on Climate
Change
IR Infrared
IRFA initial regulatory flexibility analysis
IRL incandescent reflector lamp
K degrees Kelvin
kt kilotons
LCC life-cycle cost
LED Light-Emitting Diode
LMC U.S. Lighting Market Characterization
Volume I
Lm/W lumens per watt
MBP medium bipin
MECS Manufacturer Energy Consumption
Survey (MECS)
MIA Manufacturer Impact Analysis
MMt million metric tons
Mt metric tons
MW megawatts
NAICS North American Industry
Classification System
NCLC National Consumer Law Center
NEEP Northeast Energy Efficiency
Partnership
NEMA National Electrical Manufacturers
Association
NEMS National Energy Modeling System
NEMS–BT National Energy Modeling
System—Building Technologies
NES national energy savings
NIA National Impact Analysis
NIST National Institute of Standards and
Technology
NOPR notice of proposed rulemaking
NOX nitrogen oxides
NPCC Northwest Power and Conservation
Council
NPV net present value
NRDC Natural Resources Defense Council
NVLAP National Voluntary Laboratory
Accreditation Program
OEM Original Equipment Manufacturer
OIRA Office of Information and Regulatory
Affairs
OMB U.S. Office of Management and
Budget
PAR parabolic aluminized reflector
(reflector lamp shape)
PBP payback period
PG&E Pacific Gas and Electric
quad quadrillion BTU
R reflector (reflector lamp shape)
R–CFL reflector compact fluorescent lamp
R&D research and development
RDC recessed double contact
RECS Residential Energy Consumption
Survey
RIA regulatory impact analysis
RoHS Restriction on Hazardous Substances
directive
SBA Small Business Administration
SCF Survey of Consumer Finances
SEC Securities and Exchange Commission
SEL spectrally-enhanced lighting
SG&A selling, general, and administrative
costs
SO standard output
SO2 sulfur dioxide
SP single pin
S&P Standard & Poor’s
T8, T10, T12 tubular fluorescent lamps,
diameters of 1, 1.25 or 1.5 inches,
respectively
TSD technical support document
TSL trial standard level
TWh terawatt-hour
UMRA Unfunded Mandates Reform Act
U.S.C. United States Code
UV ultraviolet
V volts
VHO very high output
W watts
I. Summary of the Proposed Rule
The Energy Policy and Conservation
Act (EPCA or the Act) (42 U.S.C. 6291
et seq.), as amended, requires DOE to
consider whether to amend the existing
energy conservation standards for GSFL
and IRL, and to also consider whether
to adopt new energy conservation
standards for additional types of GSFL
beyond those already covered by EPCAprescribed standards. (42 U.S.C.
6295(i)(3)–(5)) The Act also specifies
that any new or amended energy
conservation standard DOE prescribes
for certain consumer and/or commercial
products, such as GSFL and IRL, shall
be designed to ‘‘achieve the maximum
improvement in energy efficiency * * *
which the Secretary determines is
technologically feasible and
economically justified.’’ (42 U.S.C.
6295(o)(2)(A); 6316(a)) Furthermore, the
new or amended standard must ‘‘result
in significant conservation of energy.’’
(42 U.S.C. 6295(o)(3)(B); 6316(a)) In
accordance with these and other
statutory provisions discussed in this
notice, DOE proposes new and amended
energy conservation standards for GSFL
and IRL, as shown in Table I.1 and
Table I.2. The proposed standards
would apply to all products listed in
Table I.1 and Table I.2 that are
manufactured in or imported into the
United States on or after June 30, 2012.
TABLE I.1—SUMMARY OF THE PROPOSED ENERGY CONSERVATION STANDARDS FOR GENERAL SERVICE FLUORESCENT
LAMPS
Correlated
color
temperature
Lamp type
4-Foot Medium Bipin ...................................................................................................................
2-Foot U-Shaped .........................................................................................................................
8-Foot Slimline .............................................................................................................................
8-Foot High Output ......................................................................................................................
4-Foot Miniature Bipin Standard Output ......................................................................................
4-Foot Miniature Bipin High Output .............................................................................................
≤
>
≤
>
≤
>
≤
>
≤
>
≤
>
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
Proposed level
lm/W
Percent
increase over
current
standards or
baseline
84
78
78
73
95
91
88
84
103
97
89
85
12%
4%
15%/22%*
7%/14%*
19%
14%
10%
5%
20%
13%
16%
10%
* For these product classes, EPCA has different efficacy standards for lamps with wattages less than 35W and greater than or equal to 35W.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00004
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
16923
TABLE I.2—SUMMARY OF THE PROPOSED ENERGY CONSERVATION STANDARD FOR IRL
Lamp type
Diameter
Standard Spectrum 40W–205W ...................................................................
Voltage
Proposed level
lm/W
Percent
increase over
current standards or
baseline
≥
<
≥
<
≥
<
≥
<
7.1P0.27
6.2P0.27
6.3P0.27
5.5P0.27
5.8P0.27
5.0P0.27
5.1P0.27
4.4P0.27
69%–100%
47%–75%
50%–78%
31%–55%
38%–63%
19%–41%
21%–44%
7%–27%
> 2.5 inches ......
≤ 2.5 inches ......
Modified Spectrum 40W–205W ....................................................................
> 2.5 inches ......
≤ 2.5 inches ......
125
125
125
125
125
125
125
125
Note: P is equal to the rated lamp wattage, in watts.
DOE’s analyses indicate that the
proposed standards would save a
significant amount of energy—an
estimated 3.2 to 7.3 quads (for GSFL)
and 1.3 to 2.3 quads (for IRL) of
cumulative energy over 31 years (2012–
2042). The economic impacts on most
GSFL and all IRL individual and
commercial consumers (i.e., the average
life-cycle cost (LCC) savings) are
positive.
The cumulative national net present
value (NPV) of total consumer costs and
savings of the proposed standards from
2012 to 2042 in 2007$ ranges from $3.2
billion (at a 7-percent discount rate) to
$25.7 billion (at a 3-percent discount
rate) for GSFL. For IRL, the NPV from
2012 to 2042 in 2007$ ranges from $3.7
billion (at a 7-percent discount rate) to
$14.0 billion (at a 3-percent discount
rate). This is the estimated total value of
future operating-cost savings minus the
estimated increased product costs,
discounted to 2007. DOE estimates the
GSFL industry net present value (INPV)
to currently be $575–602 million in
2007$. If DOE were to adopt the
proposed standards, it expects that
manufacturers may lose up to 24
percent of their INPV, which is
approximately $139 million. The NPV
of the proposed standards for GSFL
consumers (at least $3.2 billion at the 7percent discount rate) would exceed
anticipated industry losses by at least 23
times. DOE estimates the IRL industry
net present value to be $207–267
million in 2007$. If DOE were to adopt
the proposed standards, it expects that
manufacturers may lose 29–46 percent
of their INPV, which is approximately
$77–94 million. The NPV of the
proposed standards for IRL consumers
(at least $3.7 billion at the 7-percent
discount rate) would exceed anticipated
industry losses by at least 39 times.
In addition, the proposed standards
would have significant environmental
benefits. All of the energy saved would
be in the form of electricity, and DOE
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
expects the energy savings from the
proposed standards to eliminate the
need for approximately 1100 to 3400
megawatts (MW) of generating capacity
for GSFL and up to 450 MW for IRL by
2042. This would result in cumulative
(undiscounted) greenhouse gas emission
reductions of 184 to 395 million metric
tons (MMT) of carbon dioxide (CO2) for
GSFL and 59 to 114 MMT for IRL from
2012 to 2042. During this same period,
the standard would result in power
plant emission reductions of 12 to 623
kilotons (kt) of nitrogen oxides (NOX)
for GSFL and 4 to 181 kt NOX for IRL.
Mercury (Hg) emission reductions
would be up to 6.9 tons for GFSL and
up to 1.7 tons avoided for IRL.
DOE has tentatively concluded that
the proposed standards represent the
maximum improvement in energy
efficiency that is technologically
feasible and economically justified, and
would result in significant conservation
of energy. DOE further notes that
products achieving these standard levels
are already commercially available.
Based upon the rulemaking analyses
culminating in this proposal, DOE
found that the benefits (energy savings,
consumer LCC savings, national NPV
increase, and emission reductions) to
the Nation of the proposed standards
outweigh the burdens (INPV decrease
and LCC increases for some lamp users).
DOE considered higher efficacy levels
(ELs) as trial standard levels (TSLs), and
is still considering them in this
rulemaking; however, DOE has
tentatively concluded that the burdens
of the higher efficiency levels outweigh
the benefits. Based upon consideration
of public comments and related
information, DOE may adopt either
higher or lower ELs presented in this
proposal or some level in between.
II. Introduction
U.S.C. 6295(i)(1)) DOE proposes to raise
these standards and to set efficacy
standards for certain other GSFL, as
shown in Table I.1 and Table I.2 above.
The proposed standards would apply to
products manufactured in the United
States, or imported to it, three years
after the final rule is published in the
Federal Register.1 Table I.1 and Table
I.2 also show the percentage
improvement in efficacy that each
standard level represents, relative to the
current standard levels or to products
typically on the market today. The
proposed standards represent an overall
improvement of approximately 4 to 22
percent and 7 to 100 percent in the
efficacies of the GSFL and IRL baselines,
respectively, covered by the standards.
DOE’s analyses suggest that
residential and commercial consumers
would see benefits from the proposed
standards. Although DOE expects that
under the proposed standards, the
purchase price of high-efficacy GSFL
would be higher (up to three times
higher) than the average price of these
products today, but that the energy
efficiency gains would result in lower
energy costs that more than offset such
higher costs. When the potential savings
due to efficiency gains are summed over
the lifetime of the high-efficacy
products, consumers would be expected
to save up to $56.60 (depending on the
lamp type), on average, compared to
their expenditures on today’s baseline
GSFL.
The results of DOE’s analyses for IRL
follow a similar pattern. Although DOE
expects the purchase price of the highefficacy IRL would be higher (ranging
from 56 to 63 percent) than the average
price of these products today, the energy
efficiency gains would result in lower
energy costs that more than offset the
higher costs. When these potential
A. Consumer Overview
EPCA currently prescribes efficacy
standards for certain IRL and GSFL. (42
1 The final rule is expected to be published by
June 30, 2009; therefore, the effective date would
be June 30, 2012.
PO 00000
Frm 00005
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
16924
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
savings due to efficiency gains are
summed over the lifetime of the highefficacy IRL, it is estimated that
consumers would save between $1.62
and $8.14, on average, compared to their
expenditures on today’s baseline IRL.
B. Authority
Title III of EPCA sets forth a variety
of provisions designed to improve
energy efficiency. Part A 2 of Title III (42
U.S.C. 6291–6309) established the
‘‘Energy Conservation Program for
Consumer Products Other Than
Automobiles.’’ The program covers
consumer products and certain
commercial products (referred to
hereafter as ‘‘covered products’’),
including GSFL and IRL. (42 U.S.C.
6292(a)(14) and 6295(i)) EPCA
prescribes energy conservation
standards for certain GSFL and IRL. (42
U.S.C. 6295(i)(1)) The statute further
directs DOE to determine whether the
existing standards for fluorescent and
incandescent lamps should be amended
and whether to adopt standards for
additional GSFL. (42 U.S.C. 6295(i)(3)–
(5)) This rulemaking represents the first
round of amendments to the GSFL and
IRL energy conservation standards as
directed by 42 U.S.C. 6295(i)(3).
The scope of coverage for these
requirements for GSFL and IRL is
dictated by EPCA’s definitions of these
and related terms, as explained below.
EPCA defines ‘‘general service
fluorescent lamp’’ as follows: * * *
[F]luorescent lamps which can be used
to satisfy the majority of fluorescent
applications, but does not include any
lamp designed and marketed for the
following nongeneral lighting
applications: (i) Fluorescent lamps
designed to promote plant growth. (ii)
Fluorescent lamps specifically designed
for cold temperature installations. (iii)
Colored fluorescent lamps. (iv) Impactresistant fluorescent lamps. (v)
Reflectorized or aperture lamps. (vi)
Fluorescent lamps designed for use in
reprographic equipment. (vii) Lamps
primarily designed to produce radiation
in the ultra-violet region of the
spectrum. (viii) Lamps with a color
rendering index of 87 or greater. (42
U.S.C. 6291(30)(B))
EPCA defines ‘‘incandescent reflector
lamp’’ as follows: * * * [A] lamp in
which light is produced by a filament
heated to incandescence by an electric
current * * * [and] (commonly referred
to as a reflector lamp) which is not
colored or designed for rough or
vibration service applications, that
2 This part was originally titled Part B; however,
it was redesignated Part A after Part B was repealed
by Pub. L. 109–58.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
contains an inner reflective coating on
the outer bulb to direct the light, an R,
PAR, ER, BR, BPAR, or similar bulb
shapes with E26 medium screw bases, a
rated voltage or voltage range that lies
at least partially within 115 and 130
volts, a diameter which exceeds 2.25
inches, and has a rated wattage that is
40 watts or higher.
(42 U.S.C. 6291(30)(C), (C)(ii) and (F))
EPCA further clarifies this definition
of IRL by defining the lamp types
excluded from the definition: The term
‘‘rough service lamp’’ means a lamp
that—(i) has a minimum of 5 supports
with filament configurations that are C–
7A, C–11, C–17, and C–22 as listed in
Figure 6–12 of the 9th edition of the
IESNA Lighting handbook, or similar
configurations where lead wires are not
counted as supports; and (ii) is
designated and marketed specifically for
‘rough service’ applications, with (I) the
designation appearing on the lamp
packaging; and (II) marketing materials
that identify the lamp as being for rough
service. (42 U.S.C. 6291(30)(X))
The term ‘‘vibration service lamp’’
means a lamp that—(i) has filament
configurations that are C–5, C–7A, or C–
9, as listed in Figure 6–12 of the 9th
Edition of the IESNA Lighting
Handbook or similar configurations; (ii)
has a maximum wattage of 60 watts; (iii)
is sold at retail in packages of 2 lamps
or less; and (iv) is designated and
marketed specifically for vibration
service or vibration-resistant
applications, with—(I) the designation
appearing on the lamp packaging; and
(II) marketing materials that identify the
lamp as being vibration service only. (42
U.S.C. 6291(30)(AA))
The term ‘‘colored incandescent
lamp’’ means an incandescent lamp
designated and marketed as a colored
lamp that has—(i) a color rendering
index of less than 50, as determined
according to the test method given in
C.I.E. publication 13.3–1995; or (ii) a
correlated color temperature of less than
2,500K, or greater than 4,600K, where
correlated temperature is computed
according to the Journal of Optical
Society of America, Vol. 58, pages
1528–1595 (1986). (42 U.S.C.
6291(30)(EE)) 3
The advance notice of proposed
rulemaking (ANOPR) in this proceeding
(73 FR 13620, 13622, 13625, 13628–29
(March 13, 2008)), as well as subsection
3 DOE notes that the publication year of the
referenced article in the definition of ‘‘colored
incandescent lamp,’’ as printed in section
321(a)(1)(B) of EISA, contains two typographical
errors. The citation should read as follows: Journal
of Optical Society of America, Vol. 58, pages 1528–
1535 (1968).
PO 00000
Frm 00006
Fmt 4701
Sfmt 4702
II.C and section III below, provide
additional detail on the nature and
statutory history of EPCA’s
requirements for GSFL and IRL.
Under the Act, DOE’s energy
conservation program for covered
products consists essentially of four
parts: (1) Testing; (2) labeling; (3)
Federal energy conservation standards,
and (4) certification and enforcement
procedures. The Federal Trade
Commission (FTC) is responsible for
labeling, and DOE implements the
remainder of the program. Section 323
of the Act authorizes DOE, subject to
certain criteria and conditions, to
develop test procedures to measure the
energy efficiency, energy use, or
estimated annual operating cost of each
covered product. (42 U.S.C. 6293) The
test procedures for GSFL and IRL appear
at title 10 Code of Federal Regulations
(CFR) part 430, subpart B, appendix R.
EPCA provides criteria for prescribing
new or amended energy conservation
standards for covered products. As
indicated above, any new or amended
standard for a covered product under
Part A must be designed to achieve the
maximum improvement in energy
efficiency that is technologically
feasible and economically justified (42
U.S.C. 6295(o)(2)(A)), although EPCA
precludes DOE from adopting any
standard that would not result in
significant conservation of energy. (42
U.S.C. 6295(o)(3)(B)) Moreover, DOE
may not prescribe a standard: (1) For
certain products, including GSFL and
IRL, if no test procedure has been
established for that type (or class) of
product, or (2) if DOE determines by
rule that the standard would not result
in significant conservation of energy or
is not technologically feasible or
economically justified. (42 U.S.C.
6295(o)(3)) The Act also provides that,
in deciding whether a standard is
economically justified, DOE must
determine whether the benefits of the
standard exceed its burdens. (42 U.S.C.
6295(o)(2)(B)(i)) DOE must do so after
receiving comments on the proposed
standard and by considering, to the
greatest extent practicable, the following
seven factors:
(1) The economic impact of the
standard on manufacturers and
consumers of the products subject to the
standard;
(2) The savings in operating costs
throughout the estimated average life of
the covered products in the type (or
class) compared to any increase in the
price, initial charges, or maintenance
expenses for the covered products that
are likely to result from the imposition
of the standard;
E:\FR\FM\13APP2.SGM
13APP2
16925
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
(3) The total projected amount of
energy savings likely to result directly
from the imposition of the standard;
(4) Any lessening of the utility or the
performance of the covered products
likely to result from the imposition of
the standard;
(5) The impact of any lessening of
competition, as determined in writing
by the Attorney General, that is likely to
result from the imposition of the
standard;
(6) The need for national energy
conservation; and
(7) Other factors the Secretary
considers relevant. (42 U.S.C.
6295(o)(2)(B)(i)(I)–(VII))
Furthermore, EPCA contains what is
commonly known as an ‘‘antibacksliding’’ provision, which mandates
that the Secretary not prescribe any
amended standard that either increases
the maximum allowable energy use or
decreases the minimum required energy
efficiency of a covered product. (42
U.S.C. 6295(o)(1)) Also, the Secretary
may not prescribe an amended or new
standard if interested persons have
established by a preponderance of
evidence that the standard is likely to
result in the unavailability in the United
States of any covered product type (or
class) with performance characteristics
(including reliability), features, sizes,
capacities, and volumes that are
substantially the same as those generally
available in the United States. (42 U.S.C.
6295(o)(4))
Under 42 U.S.C. 6295(o)(2)(b)(iii),
EPCA establishes a rebuttable
presumption that a standard is
economically justified if the Secretary
finds that ‘‘the additional cost to the
consumer of purchasing a product
complying with an energy conservation
standard level will be less than three
times the value of the energy, and as
applicable, water, savings during the
first year that the consumer will receive
as a result of the standard, as calculated
under the applicable test procedure.
* * *’’
Under 42 U.S.C. 6295(q)(1), EPCA sets
forth additional requirements applicable
to promulgating a standard for a type or
class of covered product that has two or
more subcategories. DOE must specify a
different standard level than that which
applies generally to such type or class
of products ‘‘for any group of covered
products which have the same function
or intended use, if * * * products
within such group—(A) consume a
different kind of energy from that
consumed by other covered products
within such type (or class); or (B) have
a capacity or other performance-related
feature which other products within
such type (or class) do not have and
such feature justifies a higher or lower
standard’’ than applies or will apply to
the other products. Id. In determining
whether a performance-related feature
justifies such a different standard for a
group of products, DOE must ‘‘consider
such factors as the utility to the
consumer of such a feature’’ and other
factors DOE deems appropriate. Id. Any
rule prescribing such a standard must
include an explanation of the basis on
which such higher or lower level was
established. (42 U.S.C. 6295(q)(2))
Federal energy efficiency
requirements generally supersede State
laws or regulations concerning energy
conservation testing, labeling, and
standards. (42 U.S.C. 6297(a)–(c)) DOE
can, however, grant waivers of Federal
preemption for particular State laws or
regulations, in accordance with the
procedures and other provisions of
section 327(d) of the Act. (42 U.S.C.
6297(d))
C. Background
1. Current Standards
EPCA prescribes the energy
conservation standards that are
currently applicable to specified types
of GSFL and IRL. More specifically, the
standards set efficacy levels and color
rendering index (CRI) levels for certain
GSFL, and efficacy standards for certain
IRL. (42 U.S.C. 6295(i)(1); 10 CFR
430.32(n)) These statutory standard
levels are set forth in Table II.1 and
Table II.2 below.
TABLE II.1—EPCA STANDARD LEVELS FOR GSFL
Nominal lamp
wattage
Lamp type
4-Foot Medium Bipin ...................................................................................................................
2-Foot U-Shaped .........................................................................................................................
8-Foot Slimline .............................................................................................................................
8-Foot High Output ......................................................................................................................
TABLE II.2—EPCA STANDARD LEVELS
FOR IRL
Wattage
Min. avg.
efficacy
lm/W
40–50 ......................................
51–66 ......................................
67–85 ......................................
86–115 ....................................
116–155 ..................................
156–205 ..................................
VerDate Nov<24>2008
19:12 Apr 10, 2009
10.5
11.0
12.5
14.0
14.5
15.0
Jkt 217001
2. History of Standards Rulemaking for
General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps
As stated above, EPCA established
energy conservation standards for
certain types of GSFL and IRL. (42
U.S.C. 6295(i)(1)) EPCA also requires
that DOE conduct two cycles of
rulemakings to determine whether to
amend these standards, and that DOE
initiate a rulemaking to determine
whether to adopt standards for
additional types of GSFL. (42 U.S.C.
6295(i)(3)–(5)) This rulemaking
addresses both the amendment of
PO 00000
Frm 00007
Fmt 4701
Sfmt 4702
Minimum CRI
> 35W
≤ 35W
> 35W
≤ 35W
> 65W
≤ 65W
> 100W
≤ 100W
69
45
69
45
69
45
69
45
Minimum
average
efficacy
lm/W
75.0
75.0
68.0
64.0
80.0
80.0
80.0
80.0
existing GSFL and IRL standards, and
the adoption of standards for additional
GSFL.
DOE initiated this rulemaking on May
31, 2006, by publishing on its Web site
its ‘‘Rulemaking Framework Document
for General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps.’’ 4
DOE also published a notice in the
Federal Register announcing the
availability of the framework document
4 A PDF copy of the framework document
published in May 2006 is available at: https://www/
eere.energy.gov/buildings/appliance_standards/
residential/pdfs/lamps_framework.pdf.
E:\FR\FM\13APP2.SGM
13APP2
16926
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
and a public meeting on the document,
which requested public comments on
the matters raised in the framework
document. 71 FR 30834 (May 31, 2006).
The framework document described the
procedural and analytical approaches
that DOE anticipated using to evaluate
energy conservation standards for the
products covered by this rulemaking,
and it identified various issues to be
resolved in conducting the rulemaking.
DOE held the public meeting on June
15, 2006, to present the framework
document, describe the analyses it
planned to conduct during the
rulemaking, seek comments from
stakeholders on these subjects, and
inform stakeholders about and facilitate
their involvement in the rulemaking. At
the public meeting and during the
comment period, DOE received many
comments that both addressed issues
raised in the framework document and
identified additional issues relevant to
this rulemaking.
As the title of the framework
document indicates, DOE initially
included general service incandescent
lamps (GSIL) in this rulemaking. This
was done to address the requirement
then present in section 325(i)(5) of
EPCA that DOE consider energy
conservation standards for additional
GSIL. (42 U.S.C. 6295(i)(5)) However,
section 321(a)(3)(A)(iii) of the Energy
Independence and Security Act of
2007,5 (EISA 2007) amended EPCA to
remove this requirement, thereby
eliminating DOE’s authority to regulate
additional GSIL. Instead, section
321(a)(3)(A)(ii) of EISA 2007 amended
EPCA to prescribe energy conservation
standards for GSIL. Therefore, this
rulemaking no longer addresses GSIL.
DOE issued the ANOPR for this
rulemaking on February 21, 2008 and
published it in the Federal Register on
March 13, 2008. 73 FR 13620. On
February 22, 2008, DOE posted the
ANOPR, as well as the complete
ANOPR technical support document
(TSD), on its Web site.6 The TSD
includes the results of the following
DOE preliminary analyses: (1) Market
and technology assessment; (2)
screening analysis; (3) engineering
analysis; (4) energy use characterization;
(5) product price determinations; (6)
life-cycle cost (LCC) and pay back
period (PBP) analyses; (7) shipments
analysis; and (8) national impact
analysis (NIA).
5 Pub.
L. 110–140 (enacted Dec. 19, 2007).
copies of the ANOPR and ANOPR TSD
published in March 2008 are available at: https://
www1.eere.energy.gov/buildings/
appliance_standards/residential/
incandescent_lamps_anopr.html.
6 PDF
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
In the March 2008 ANOPR, DOE
invited comment in particular on the
following issues: (1) Consideration of
additional GSFL; (2) amended
definitions; (3) product classes; (4)
scaling to product classes not analyzed;
(5) screening of design options; (6) lamp
operating hours; (7) energy consumption
of GSFL; (8) LCC calculation; (9)
installation costs; (10) base-case marketshare matrices; (11) shipment forecasts;
(12) base-case and standards-case
forecasted efficiencies; (13) trial
standard levels; and (14) period for
lamp production equipment conversion.
73 FR 13620, 13686–88 (March 13,
2008).
In the ANOPR, DOE described and
sought comment on the analytical
framework, models, and tools (e.g., LCC
and national energy savings (NES)
spreadsheets) DOE was using to analyze
the impacts of energy conservation
standards for GSFL and IRL. DOE held
a public meeting in Washington, DC, on
March 10, 2008, to present the
methodologies and results for the March
2008 ANOPR analyses. At this meeting,
stakeholders recommended that DOE
revise certain analyses in the energy
conservation standard ANOPR and the
scope of covered products. DOE later
received written comments from the
National Electrical Manufacturers
Association (NEMA). In addition, DOE
received a joint comment from several
stakeholders. The Joint Comment was
submitted by the American Council for
an Energy Efficient Economy (ACEEE),
Alliance to Save Energy (ASE),
Appliance Standards Awareness Project
(ASAP), National Consumer Law Center,
National Grid, Natural Resources
Defense Council (NRDC), Northeast
Energy Efficiency Partnerships (NEEP),
Northwest Power and Conservation
Council (NPCC), Pacific Gas and Electric
Company (PG&E), and Vermont Energy
Investment Corporation. The comments
received since publication of the March
2008 ANOPR and during the March 10,
2008 public meeting have contributed to
DOE’s proposed resolution of the issues
in this rulemaking. This NOPR quotes,
summarizes, and responds to the issues
raised in these public comments. (A
parenthetical reference at the end of a
quotation or paraphrase provides the
location of the item in the public
record.)
Subsequent to the public meeting and
at NEMA’s request, DOE and NEMA met
on June 26, 2008 to discuss appropriate
lumens per watt (lm/W) standards for
high correlated color temperature (CCT)
fluorescent lamps. (DOE, No. 27) 7
7 A notation in the form ‘‘DOE, No. 27 ’’ identifies
a written comment that DOE has received and has
PO 00000
Frm 00008
Fmt 4701
Sfmt 4702
NEMA subsequently submitted a
written comment documenting its
presentation at this meeting (hereafter
the ‘‘June 2008 NEMA meeting’’).
(NEMA, No. 26) Topics covered at this
meeting included the expected market
share of high-CCT fluorescent lamps,
appropriate efficacy standard scaling
factors for GSFL with a CCT greater than
4,500K but less than or equal to 7,000K,
and coverage of GSFL with a CCT
greater than 7,000K. See sections III.C.2,
V.A.1.c, and V.C.7.a.i of this notice for
a more detailed discussion of NEMA’s
comments at this meeting, as well as
DOE’s responses.
III. Issues Affecting the Scope of This
Rulemaking
A. Additional General Service
Fluorescent Lamps for Which DOE Is
Proposing Standards
1. Scope of EPCA Requirement That
DOE Consider Standards for Additional
Lamps
As discussed above, EPCA established
energy conservation standards for
certain general service fluorescent
lamps, (42 U.S.C. 6295(i)(1)) and
directed the Secretary to ‘‘initiate a
rulemaking procedure to determine if
the standards in effect for fluorescent
lamps * * * should be amended so that
they would be applicable to additional
general service fluorescent [lamps].
* * *’’ (42 U.S.C. 6295(i)(5)) Thus, DOE
must consider whether to adopt energy
efficacy standards for additional GSFL
beyond those already covered by the
statutorily-prescribed standards.
The March 2008 ANOPR notes that a
wide variety of GSFL are not currently
covered by energy conservation
standards, and they are potential
candidates for coverage under 42 U.S.C.
6295(i)(5). 73 FR 13620, 13628–29
(March 13, 2008). However, the
requirement that DOE consider
additional GSFL appears to conflict
with EPCA’s definitions of key terms,
which it might be argued would
preclude coverage of additional GSFL.
As explained below, DOE has carefully
considered these statutory provisions
and is interpreting them in a manner so
as to give effect to the requirement to
consider additional GSFL.
Specifically, the conflict is centered
on the statutory definition of ‘‘general
service fluorescent lamp.’’ As set forth
above and repeated here for purposes of
this discussion, ‘‘general service
fluorescent lamp’’ is defined in 42
included in the docket of this rulemaking or a
written docket submission. This particular notation
refers to a comment: (1) Submitted by DOE; and (2)
in document number 27 in the docket of this
rulemaking.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
U.S.C. 6291(30)(B) to mean: ‘‘fluorescent
lamps which can be used to satisfy the
majority of fluorescent lamp
applications, but does not include any
lamp designed and marketed for the
following nongeneral lighting
applications: [list of eight exclusions not
relevant to the present issue].’’
As such, the term ‘‘general service
fluorescent lamp’’ appears to be defined
by reference to the term ‘‘fluorescent
lamp,’’ which is also defined under the
statute as follows: ‘‘Except as provided
in subparagraph (E), the term
‘fluorescent lamp’ means a low pressure
mercury electric-discharge source in
which a fluorescing coating transforms
some of the ultraviolet energy generated
by the mercury discharge into light,
including only the following: (i) Any
straight-shaped lamp (commonly
referred to as 4-foot medium bi-pin
lamps) with medium bi-pin bases of
nominal overall length of 48 inches and
rated wattage of 28 or more. (ii) Any Ushaped lamp (commonly referred to as
2-foot U-shaped lamps) with medium
bi-pin bases of nominal overall length
between 22 and 25 inches and rated
wattage of 28 or more. (iii) Any rapid
start lamp (commonly referred to as 8foot high output lamps) with recessed
double contact bases of nominal overall
length of 96 inches and 0.800 nominal
amperes, as defined in ANSI C78.1–
1978 and related supplements. (iv) Any
instant start lamp (commonly referred to
as 8-foot slimline lamps) with single pin
bases of nominal overall length of 96
inches and rated wattage of 52 or more,
as defined in ANSI C78.3–1978 (R1984)
and related supplement ANSI C78.3a–
1985.’’ 42 U.S.C. 6291(30)(A) (Emphasis
added).
The term ‘‘fluorescent lamp’’ is, by its
terms, limited to four enumerated types
of lamps. Further, the four types of
lamps set forth in the definition of
‘‘fluorescent lamp’’ have corresponding
energy conservation standards
prescribed under the statute at 42 U.S.C.
6295(i)(1)(B). Given that the statutory
definition of ‘‘fluorescent lamp’’ is
limited to four specified types of lamps
and that the statute prescribes standards
for those four lamps, it is not possible
to give effect to the congressional
directive to consider establishing
standards for additional GSFL if the
term ‘‘general service fluorescent lamp’’
is limited by the definition of
‘‘fluorescent lamp.’’
Given this identified conflict, DOE
has determined that there is an inherent
ambiguity in the statute in terms of how
these provisions are to be implemented.
In order to move forward with this
standards rulemaking, DOE must
resolve this legal conundrum.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Although there is no legislative
history to clarify this point, there are a
number of reasons to believe that
Congress did not intend to strictly limit
consideration of ‘‘additional’’ GSFL.
First, Congress adopted both the
relevant statutory definitions and the
‘‘additional’’ lamps requirement as part
of Energy Policy Act of 1992 (EPACT
1992; Pub. L. 102–486). DOE does not
believe Congress would intentionally
insert a legislative provision that, when
read in conjunction with a
simultaneously added provision,
amounts to a nullity. Second, reading
the definition to preclude consideration
of additional GSFL would run counter
to the energy-saving purposes of EPCA.
It is reasonable to assume that Congress
would not have intended to limit energy
conservation standards to only those
technologies available in 1992, but
would instead cast a broader net that
would achieve energy efficiency
improvements in lighting products
incorporating newer technologies.
Consequently, DOE interprets these
statutory provisions such that, in
defining ‘‘general service fluorescent
lamp,’’ Congress intended to incorporate
the term ‘‘fluorescent lamp’’ in a
broader, more generic sense. DOE
understands that the industry routinely
refers to ‘‘fluorescent lamps’’ as
including products in addition to the
four enumerated in the statutory
definition of that term. In fact, in the
March 2008 ANOPR, DOE presented its
plan for including additional GSFL for
coverage, and did not receive adverse
comment. Thus, DOE has determined to
read the statutory definition of ‘‘general
service fluorescent lamp’’ in this
broader context.
For these reasons, and for the
additional reasons set forth in the March
2008 ANOPR,8 DOE views ‘‘additional’’
GSFL, as that term is used in 42 U.S.C.
6295(i)(5), as lamps that: (1) Meet the
technical portion of the statutory
definition of ‘‘fluorescent lamp’’ (i.e., a
low-pressure mercury electric-discharge
source in which a fluorescing coating
transforms some of the ultraviolet
energy generated by the mercury
discharge into light) (42 U.S.C.
6291(30)(A)) without restriction to the
four specified lamp types in that
definition; (2) can be used to satisfy the
majority of fluorescent lighting
applications (42 U.S.C. 6291(30)(B)); (3)
are not within the exclusions from the
definition of GSFL specified in 42
U.S.C. 6291(30)(B); and (4) are ones for
which EPCA does not prescribe
standards. Such an interpretation does
not alter the existing statutory provision
8 73
PO 00000
FR 13620, 13629 (March 13, 2008).
Frm 00009
Fmt 4701
Sfmt 4702
16927
or standards for ‘‘fluorescent lamps,’’
but it does permit DOE to give effect to
section 6295(i)(5) of EPCA by expanding
the universe of GSFL open to potential
regulation. The scope of coverage
reflected in this NOPR is in keeping
with the interpretation outlined above.
2. Identification of the Additional
Lamps for Which DOE Proposes
Standards
As set forth more fully in the March
2008 ANOPR, DOE took the following
three steps in terms of identifying
additional GSFL for which standard
setting might be appropriate. DOE first
conducted a comprehensive review of
the fluorescent lighting market in order
to identify particular types of lamps that
meet the four criteria above to
determine the additional GSFL for
which DOE would consider adopting
standards. Second, DOE examined each
lamp type to determine potential energy
savings that energy conservation
standards would bring for that lamp.
Third, DOE further evaluated selected
lamps to determine if such standards
would be technologically feasible and
economically justified. In carrying out
these steps before issuance of the March
2008 ANOPR, DOE considered
comments on these issues that it had
received previously. 73 FR 13620,
13629–30 (March 13, 2008).
In implementing the first of these
three steps, DOE identified the
following categories of GSFL as meeting
the four criteria for consideration as
‘‘additional’’ GSFL under 42 U.S.C.
6295(i)(5):
• 4-foot, medium bipin (MBP),
straight-shaped lamps, rated wattage of
< 28W;
• 2-foot, medium bipin, U-shaped
lamps, rated wattage of < 28W;
• 8-foot, recessed double contact
(RDC), rapid start, high output (HO)
lamps not defined in ANSI Standard
C78.1–1991 9 or with current other than
0.800 nominal amperes;
• 8-foot single pin (SP), instant start,
slimline lamps with a rated wattage ≥
52, not defined in ANSI Standard
C78.3–1991 10;
• Very high output (VHO) straightshaped lamps;
• T5 11 miniature bipin (MiniBP)
straight-shaped lamps;
• Additional straight-shaped and Ushaped lamps other than those listed
9 Titled ‘‘for Fluorescent Lamps—Rapid-Start
Types—Dimensional and Electrical
Characteristics.’’
10 Titled ‘‘for Fluorescent Lamps—Instant-Start
and Cold-Cathode Types—Dimensional and
Electrical Characteristics.’’
11 T5, T8, T10, and T12 are nomenclature used to
refer to tubular fluorescent lamps with diameters of
0.625, 1, 1.25, and 1.5 inches, respectively.
E:\FR\FM\13APP2.SGM
13APP2
16928
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
above (e.g., alternate lengths, diameters,
or bases); and
• Additional fluorescent lamps with
alternate shapes (e.g., circline, pin-based
compact fluorescent lamps (CFL)).
73 FR 13620, 13630 (March 13, 2008).
DOE then assessed the potential
energy savings of standards for these
GSFL (second step) and whether
candidate standards for those GSFL
would be technologically feasible and
economically justified (third step), in
order to determine which GSFL to
analyze in depth regarding whether, and
at what levels, standards would be
warranted under the EPCA criteria in 42
U.S.C. 6295(o). DOE’s analytical process
related to these additional GSFL
categories is discussed generally below.
In a review of 4-foot medium bipin
lamps, DOE found that the current
market lacked any products with a rated
wattage below 25W. Therefore, in the
March 2008 ANOPR, DOE preliminarily
decided not to extend coverage to 4-foot
medium bipin lamps below 25W. In the
following section, DOE discusses its
consideration in the March 2008
ANOPR of possibly regulating lamps
with rated wattages less than 28W and
greater than or equal to 25W.
Similar to the 4-foot medium bipin
lamps, in the March 2008 ANOPR, DOE
investigated the potential for regulating
2-foot U-shaped lamps less than 28W. A
review of available manufacturer
catalogs found no commerciallyavailable products in that category.
Therefore, DOE concluded that lowering
the minimum wattage threshold of 2foot U-shaped lamps would likely not
result in substantial energy savings and
preliminarily decided not to expand
coverage to these lamps.
DOE also considered whether to
expand coverage to include VHO
fluorescent lamps. While VHO lamps
consume large amounts of energy, they
are commonly used in outdoor
applications where high-intensity
discharge (HID) lamps are rapidly
gaining market share. Further research
indicated that shipments of VHO T12
lamps are declining rapidly. Although
individually these products have greater
per-lamp energy savings than high
output or standard output lamps, the
total energy savings resulting from
regulation would be small and would be
expected to decrease over time as these
lamps disappear from the market.
Therefore, DOE preliminarily decided
not to extend coverage to VHO lamps.
In the March 2008 ANOPR, DOE also
preliminarily decided not to expand
coverage to T5 fluorescent lamps. DOE’s
initial analysis showed that T5 lamps
currently have a relatively small share
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
of the GSFL market, and, therefore, have
limited potential to contribute to total
energy savings. Although T5 lamps can
serve as a substitute for T8 or T12
lamps, DOE found that T5 lamps tend
to have higher efficacy. Research
showed that the highest efficacy 32W 4foot medium bipin T8 lamp is 95 lm/W,
compared to 104 lm/W for a standard
output 4-foot miniature bipin T5 lamps.
Thus, DOE stated that excluding T5
lamps from this rulemaking would be
unlikely to undermine any energy
savings that would result from a T12
and T8 standard, even if the standard
caused increased sales of T5 systems
Lastly, DOE preliminarily decided not
to extend coverage to fluorescent lamps
that had alternate lengths, diameters,
bases, or shapes (or a combination
thereof) than the lamps specifically
mentioned. DOE reasoned that the
products it had already selected for
coverage represented the significant
majority of the GSFL market, and, thus,
the bulk of the potential energy savings.
Furthermore, DOE tentatively
concluded there was limited potential
for lamps with miscellaneous lengths
and bases to grow in market share, given
the constraint of fixture lengths and
socket compatibility.
After eliminating the lamps
aforementioned lamps from further
consideration for the reasons cited
above, DOE was left with the following
additional GSFL to consider evaluating
in depth for potential standards:
• 4-foot, medium bipin lamps with
wattages ≥ 25 and < 28;
• 8-foot, recessed double contact
(RDC), rapid start, high output (HO)
lamps not defined in ANSI Standard
C78.1–1991 or with current other than
0.800 nominal amperes;
• 8-foot single pin (SP), instant start,
slimline lamps with a rated wattage ≥
52, not defined in ANSI Standard
C78.3–1991;
73 FR 13620, 13632 (March 13, 2008).
As mentioned in the March 2008
ANOPR, DOE explored extending
coverage to 4-foot medium bipin lamps
with wattages less than 28W. A product
review found that manufacturers
marketed and sold 25W 4-foot medium
bipin T8 fluorescent lamps as
replacements for higher wattage 4-foot
medium bipin T8 fluorescent lamps.
Thus, DOE concluded that lowering the
minimum wattage threshold to include
these lamps would mitigate the risk of
25W lamps becoming a loophole and
would maximize potential energy
savings. In addition, as the technology
and incremental costs associated with
increased efficacy of 25W lamps are
similar to their already regulated 28W
PO 00000
Frm 00010
Fmt 4701
Sfmt 4702
counterparts, DOE tentatively
concluded that standards for these
lamps would be technologically feasible
and economically justified.
In the March 2008 ANOPR, DOE also
preliminarily decided to extend
coverage to 8-foot recessed double
contact, rapid start, HO lamps not
defined in ANSI Standard C78.1–1991.
Due to the ampere specification in the
definition, the statutory standards
covered only T12 8-foot recessed double
contact HO lamps, but none of the T8
8-foot recessed double contact HO
lamps (which usually have 0.400
nominal amperes). Since the T8 8-foot
lamps serve as substitutes for their T12
counterparts, DOE risked losing
potential energy savings unless such
lamps are also covered by energy
conservation standards. Consequently,
DOE preliminarily extended coverage to
T8, 8-foot recessed double contact HO
lamps, thereby adding lamps previously
restricted by the 0.800 nominal ampere
limitation in the definition of ‘‘general
service fluorescent lamp.’’
Furthermore, DOE planned to expand
coverage to 8-foot recessed double
contact, rapid start, high output
fluorescent lamps not listed in ANSI
Standard C78.1–1991. DOE made this
decision because the ANSI standards
referenced in DOE regulations were
outdated.12 As new lamps are
introduced to the market, it is likely
they would not be covered by the 1991
ANSI standard and potentially even the
currently most up-to-date standard. Any
of these lamps could serve as substitutes
for regulated lamps. To maximize
energy savings from these standards,
DOE extended coverage to 8-foot
recessed double contact, rapid start,
high output fluorescent lamps not listed
in ANSI Standard C78.1–1991.
Because the technologies of T8, 8-foot
recessed double contact HO lamps and
the 8-foot recessed double contact HO
lamps not listed in the ANSI Standard
C78.1–1991 were similar to the
technologies of their already-regulated
T12 counterparts, DOE tentatively
concluded that standards for these
lamps would meet the statutory
criterion of technological feasibility.
Preliminary analysis of these lamps in
the LCC and NIA demonstrated
substantial economic savings. Therefore,
DOE tentatively concluded that energy
conservation standards for these lamps
would be expected to be economically
justified.
12 ANSI Standard C78.1–1991 has been updated
and replaced by ANSI Standard C78.81–2005, ‘‘for
Electric Lamps—Double Capped Fluorescent
Lamps—Electrical and Dimensional
Characteristics.’’
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
Similar to 8-foot recessed double
contact HO lamps, in the March 2008
ANOPR, DOE considered extending
coverage to 8-foot, single pin, instant
start, slimline lamps not included in
ANSI Standard C78.3–1991 (which
includes T8 lamps as well). DOE’s
preliminary analysis indicated that
regulation of these lamps has the
potential to achieve substantial energy
savings. Therefore, DOE preliminarily
decided to expand the scope of energy
conservation standard coverage to 8-foot
single pin slimline lamps with a rated
wattage greater than or equal to 52W not
listed in ANSI Standard C78.3–1991.
Since the technologies of T8, 8-foot
single pin slimline lamps and the 8-foot
single pin slimline lamps not listed in
ANSI Standard C78.3–1991 are similar
to the technologies of their alreadyregulated counterparts, DOE tentatively
concluded that standards for these
lamps would be expected to meet the
statutory criterion of technological
feasibility. Analyses in the LCC and NIA
confirmed the potential for substantial
economic savings associated with
regulation of these lamp types. As a
result, in the March 2008 ANOPR, DOE
tentatively concluded that energy
conservation standards for these lamps
would be economically justified.
During and after the public meeting,
DOE received numerous verbal and
written comments regarding the lamps
included in or excluded from coverage
in the March 2008 ANOPR. As a general
matter, commenters supported DOE’s
approach for consideration of additional
GSFL for coverage by energy
conservation standards. However,
commenters urged DOE to consider
changes in its approach in two areas,
specifically coverage of T5 lamps and
extension of lamp wattage ranges.
Sections III.A.2.a and III.A.2.b of this
notice immediately below discuss the
submitted comments and DOE’s
responses.
a. Coverage of T5 Lamps
At the March 2008 ANOPR public
meeting, NEMA announced that it was
considering supporting coverage of T5
lamps to prevent the introduction of
less-efficient T5 lamps into the market,
particularly those containing
halophosphors. (Public Meeting
Transcript, No. 21 at pp. 71–72) 13
13 A notation in the form ‘‘Public Meeting
Transcript, No. 21 at pp. 71–72’’ identifies a written
comment that DOE has received and has included
in the docket of this rulemaking. This particular
notation refers to a comment: (1) Submitted during
the public meeting on March 10–11, 2008; (2) in
document number 21 in the docket of this
rulemaking; and (3) appearing on pages 71 through
72 of the transcript.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
ACEEE likewise suggested that DOE
should analyze opportunities involving
regulation of T5 lamps. (Public Meeting
Transcript, No. 21 at p. 73) In its written
comments, NEMA stated that it would
not oppose covering newer T5
fluorescent lamp technology (e.g., 28W
4-foot T5 lamps), but would not
recommend covering older technology
(i.e., T5 preheat fluorescent lamps).
(NEMA, No. 22 at p. 3) In addition, the
Joint Comment stated that DOE should
extend coverage to T5 lamps. These
organizations argued that if only T8 and
T12 lamps are covered by the standard,
it could possibly spur market
introduction of less-efficient
halophosphor T5 lamps with a lower
first cost. Such a development would
increase the overall market share of T5
lamps and decrease the potential energy
savings associated with this rulemaking.
(Joint Comment, No. 23 at pp. 2–5)
DOE agrees with these comments.
While most T5 lamps are currently more
efficient than the T8 and T12 lamps for
which they can be substituted,
excluding them from energy
conservation standards could provide
an incentive for less-efficient T5 lamps
to enter the market. Such trend would
result in increased market share of lessefficient products, thereby creating the
potential for significant energy savings
losses unless these lamps are regulated.
Because this potential substitution effect
is a primary criterion which DOE uses
to determine coverage for additional
GSFL, DOE is proposing in this NOPR
to extend coverage to T5 miniature
bipin lamps.
DOE researched the market and
product availability of T5 lamps and
found they exist in a variety of lengths
and wattages. Standard T5 lamps
include wattages ranging from 14W to
80W, and lengths ranging from
nominally 2 feet to 6 feet. DOE’s
research indicates that the primary
driver of T5 market share growth is
substitution for currently regulated 4foot MBP lamps. Therefore, DOE
proposes to cover only the nominally 4foot lengths of T5 miniature bipin
lamps. DOE believes that alternate
lengths of T5 lamps are not likely to
gain significant market share as they are
not easily substitutable for 4-foot MBP
systems which represent the majority of
the total fluorescent market. In addition,
interviews with manufacturers and a
review of product literature indicate
that standard-output (approximately
28W) and high-output (approximately
54W) lamps are the highest volume T5
miniature bipin lamps. In addition to
the full-wattage versions of these lamps,
DOE has found that reduced-wattage
versions of the standard- and high-
PO 00000
Frm 00011
Fmt 4701
Sfmt 4702
16929
output T5 lamp (26W and 51W
respectively) are available. Therefore, in
this NOPR, DOE proposes to extend
coverage to 4-foot nominal, straightshaped, T5 miniature bipin standard
output lamps with rated wattages ≥ 26W
and to 4-foot nominal, straight-shaped,
T5 miniature bipin high output lamps
with rated wattages ≥ 51W, as they
present the greatest potential for energy
savings. DOE estimates potential energy
savings from these lamps of up to 2.05
quads over the analysis period (2012 to
2042). Because higher-efficacy versions
of some of these lamps are already
present in the market, DOE tentatively
concludes that standards for these
lamps are technologically feasible.
Based on DOE’s LCC and NIA
analyses, coverage of the T5 lamps
discussed above would be economically
justified. These analyses show that T5
lamp coverage has the potential to
achieve on average $47.03 per standardoutput lamp system and $56.60 per
high-output lamp system in LCC
savings. In addition, DOE’s NIA
indicates that regulating these lamps
could result in an NPV of up to $6.84
billion to the Nation (discounted at 3
percent). See section VI.B.1.a.i and
section VI.B.3 of this document and
chapters 8 and 11 of the TSD for more
details on these results.
b. Extension of Lamp Wattage Ranges
Regarding fluorescent lamp coverage,
the Joint Comment suggested that DOE
should extend wattage ranges to cover
lower-wattage products. (Joint
Comment, No. 23 at p. 4) In relevant
part, section 123 of EPACT 1992
amended EPCA to establish standards
for 4-foot medium bipin lamps of 28W
or more. The Joint Comment notes that
since that law took effect, ‘‘new
products continue to be introduced, and
there is an incentive to circumvent
standards by producing lamps just
outside of the watt range (e.g. the
current 25W residential lamp).’’ Id.
NEMA commented that while current
standards cover 2-foot U-shaped
medium bipin lamps greater than or
equal to 28W, new products have been
introduced at 25W. (Public Meeting
Transcript, No. 21 at p. 73) To prevent
this trend from continuing, the Joint
Comment recommended substantially
lowering watt ranges for GSFL product
classes to protect the energy savings that
would be accomplished by this rule. If
niche products exist in the new range,
the Joint Comment expressed a
preference for using narrowly drawn
exemptions rather than limiting the
covered watt range. (Joint Comment, No.
23 at p. 4)
E:\FR\FM\13APP2.SGM
13APP2
16930
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
DOE agrees with the Joint Comment
regarding the appropriateness of
extending wattage ranges when
commercially-available products exist.
As discussed in the March 2008
ANOPR, DOE proposed to extend
coverage to 4-foot medium bipin
fluorescent lamps with wattages
between 25W and 28W. DOE discovered
these lamps were being marketed as
substitutes for currently regulated lamps
subject to the current and amended
standards (proposed in this NOPR) on 4foot medium bipin lamps. Therefore,
consistent with that approach, in this
NOPR, DOE proposes to extend
coverage to 2-foot U-shaped lamps with
wattages greater than 25W.
The Joint Comment expressed
concern that substitutable products
outside the range of covered wattages
will emerge in other product classes. It
suggested a proactive approach of
lowering the watt ranges even further,
although no products may currently
exist in that range. (Joint Comment, No.
23 at p. 4) While DOE understands the
Joint Comment’s concern, DOE
disagrees with this approach. DOE is
required to consider energy
conservation standards that are
technologically feasible. If a lower
wattage lamp does not yet exist, DOE
cannot confirm that it would be
technologically feasible or economically
justified for such a lamp to meet a set
energy conservation standard. In
addition, lower wattage lamps may
provide different lumen outputs, and
thereby different utility. Therefore, if
DOE were to include these lamps in its
coverage without determining if the set
energy conservation standard is
technologically feasible, DOE could be
reducing the utility of covered product
or precluding its development entirely.
Further, DOE encourages the
introduction of lamps at lower wattages.
Thus, DOE will only propose to extend
wattage ranges for 4-foot medium bipin
lamps and 2-foot medium bipin Ushaped lamps to the extent specified in
this NOPR.
3. Summary GSFL Lamps to Which DOE
Proposes To Extend Coverage
With the exception of the abovediscussed comments, DOE received no
other input related to coverage of GSFL.
In addition, DOE’s revised analyses
indicate that energy conservation
standards for the lamps which DOE
preliminarily decided to extend
coverage in the March 2008 ANOPR are
still expected to be technologically
feasible, economically justified, and
would result in significant energy
savings. Therefore, in summary, DOE is
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
proposing to cover the following
additional GSFL:
• 2-foot, medium bipin U-shaped
lamps with a rated wattage ≥ 25 and less
than < 28;
• 4-foot, medium bipin lamps with a
rated wattage ≥ 25 and less than 28;
• 4-foot T5, miniature bipin, straightshaped, standard output lamps with
rated wattage ≥ 26;
• 4-foot T5, miniature bipin, straightshaped, high output lamps with rated
wattage ≥ 51;
• 8-foot recessed double contact,
rapid start, HO lamps other than those
defined in ANSI Standard C78.1–1991;
• 8-foot recessed double contact,
rapid start, HO lamps (other than 0.800
nominal amperes) defined in ANSI
Standard C78.1–1991; and
• 8-foot single pin instant start
slimline lamps, with a rated wattage ≥
52, not defined in ANSI Standard
C78.3–1991.
B. Exempted Incandescent Reflector
Lamps
Section 322(a)(1) of EISA 2007
amended section 321(30)(C)(ii) of EPCA
to expand the portion of the definition
of ‘‘incandescent lamp’’ applicable to
incandescent reflector lamps to include
lamps with a diameter between 2.25 and
2.75 inches, as well as ER, BR, BPAR,
or similar bulb shapes. (42 U.S.C.
6291(30)(C)(ii)) Furthermore, section
322(b) of EISA 2007 incorporates several
new exemptions to the IRL standards in
the new section 325(i)(1)(C) of EPCA.
(42 U.S.C. 6295(i)(1)(C)) These
exemptions are as follows: (1) Lamps
rated 50 watts or less that are ER30,
BR30, BR40, or ER40; (2) lamps rated 65
watts that are BR30, BR40, or ER40
lamps; and (3) R20 incandescent
reflector lamps rated 45 watts or less.
At the ANOPR stage, DOE concluded
that it does not have the authority to set
standards for these lamps, for the
following reasons. Although Congress
included ER, BR, and small-diameter
(less than 2.75 inches) lamps in the
definition of an ‘‘incandescent lamp,’’ it
specifically exempted certain wattages
and diameters from the prescribed
efficacy standards, thereby indicating
Congress’s intent not to set standards for
those products. Furthermore, DOE’s
reading of 42 U.S.C. 6295(i)(3), which
directs DOE to amend the standards in
paragraph (1), led it to believe that
DOE’s authority to amend the standards
does not include the authority to amend
the exemptions. Specifically, under 42
U.S.C. 6295(i)(1)(C), ‘‘Exemptions,’’ the
statute refers to ‘‘the standards specified
in subparagraph (B),’’ whose title is
‘‘Minimum Standards.’’ Therefore, in
amending the standards in paragraph
PO 00000
Frm 00012
Fmt 4701
Sfmt 4702
(1), under 42 U.S.C. 6295(i)(3), DOE
reasoned that it had the authority to
change the efficacy values but not the
exemptions. Accordingly, DOE
conducted its ANOPR analyses under
the premise that it could not extend
coverage to these statutorily-exempted
products.
The Joint Comment argued that by
covering these products in EISA 2007,
Congress effectively brought them into
the Federal standards program and,
thus, granted DOE the authority to
regulate them. The Joint Comment
recommended extending coverage to 65watt ER and BR lamps. In addition, it
encouraged DOE to evaluate standards
for ER and BR lamps less than 65 watts
and for R20 lamps less than 45 watts.
The Joint Comment further contended
that by failing to extend coverage to
these lamps, DOE is not meeting its
obligation to maximize energy savings.
The Joint Comment argued that the
exempted lamps represent a large,
growing market share and are a
substitute for products that DOE plans
to regulate. The Joint Comment stated
that because 65-watt BR lamps represent
a low-cost, low-efficacy alternative to
the more-efficient products covered by
the standards, continued exemptions
could decrease the potentially
significant energy savings associated
with the present rulemaking. (Joint
Comment, No. 23 at p. 12–14)
Accompanying the Joint Comment
were two legal memoranda from the
National Consumer Law Center (NCLC),
maintaining that not only does DOE
have the authority to regulate ER and BR
lamps, but that DOE is obligated to
regulate them. NCLC pointed out that
with the passage of EISA 2007, Congress
included BR and ER lamps that have a
‘‘rated wattage that is 40 watts or
higher’’ within the definition of
‘‘incandescent lamp’’ [EISA 2007,
section 322(a), amending 42 U.S.C.
6291(30)(C)] and, thus, included these
BR and ER lamps as covered products
under 42 U.S.C. 6291(2) and
6292(a)(14). NCLC further contended
that the only explanation for Congress
adding ER and BR lamps to the
definition was to include them among
the covered products. (Joint Comment,
No. 23 at p. 27) NCLC cited the
rulemaking for microwave and electric
ovens as an example of a rulemaking in
which DOE is considering applying
standards to products for which no
prescriptive efficiency standards exist.
(Joint Comment, No. 23 at p. 28)
Through the initial drafting of this
NOPR, DOE adhered to its earlier
conclusion that it lacked authority to
consider standards for ER, BR, and
small-diameter lamps that had been
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
specifically exempted by Congress.
However, after carefully considering the
testimony of the February 3, 2009 NOPR
public meeting and reexamining the
ANOPR public comments on this issue,
DOE reexamined its authority under
EPCA to amend standards for ER, BR,
and small-diameter lamps and has
concluded that its earlier view may have
been in error. DOE is further
considering if it has authority to
consider energy conservation standards
for ER, BR, and small-diameter lamps
for the reasons that follow.
DOE agrees with the Joint Comment,
that prior to enactment of EISA 2007 on
December 19, 2007, ER, BR, and smalldiameter lamps were by definition
excluded from coverage under EPCA;
however, once EISA 2007 amended the
definition of ‘‘incandescent lamp,’’ ER,
BR, and small-diameter lamps become
products by the new definition. (Joint
Comment, No. 23 at p. 27) Congress
proceeded to expressly exempt certain
types of ER, BR, and small-diameter
lamps from the statutorily-set IRL
standards established by EISA 2007.
However, given that these expressly
exempted lamp types constitute the
overwhelming majority of the ER, BR,
and small-diameter lamps market,
DOE’s original construction of the
relevant statutory provisions (as
expressed in the ANOPR) would have
the effect of once again moving most ER,
BR, and small-diameter lamps beyond
the reach of energy conservation
standards. Accordingly, DOE is
reconsidering whether, under 42 U.S.C
6295(i)(3), the directive to amend the
standards in paragraph (1) encompasses
both the statutory levels and the
exemptions to those standards.
As a practical matter, if DOE does
conclude that it has authority to
establish standards for ER, BR, and
small-diameter lamps, it cannot
consider such lamps as part of the
present rulemaking because it has not
conducted the requisite analyses to
propose appropriate standard levels. At
the same time, DOE does not wish to
delay the present rulemaking (and the
accompanying energy savings to the
Nation) for the sole reason of
considering this subset of ER, BR, and
small-diameter lamps. The analyses to
consider standards for ER, BR, and
small-diameter lamps are severable from
the analyses underlying the present
rulemaking, so separate treatment
would not impact the outcomes for any
of the lamp types under consideration
in this NOPR. Therefore, DOE has
decided to proceed with setting energy
conservation standards for the lamps
that are the subject of the present
rulemaking and to commence a separate
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
rulemaking for ER, BR, and smalldiameter lamps. DOE believes that
much of the analytical work for the
current rulemaking will benefit the ER,
BR, and small diameter lamps
rulemaking, thereby permitting issuance
of a new NOPR and final rule on an
accelerated basis, if it determined that it
has the authority to do so.
For the purposes of the present NOPR,
however, DOE notes that the balance of
this notice (analyses and related
discussions) assumes that the exempted
ER, BR, and small-diameter lamps
remain unregulated by energy
conservation standards. DOE
acknowledges that while such an
assumption has no impact on the
engineering and life-cycle cost analyses,
the regulation of these exempted IRL
may affect the future shipment of IRL
and thereby the national impact and
other downstream analyses. However,
DOE believes that its analysis of
multiple shipment scenarios (as
discussed in section V.E.5) captures the
broad range of possible impacts were
these exempted lamps to be regulated in
the future. Therefore DOE’s assumption
does not impact the standards proposed
in this rulemaking or DOE’s
reconsideration of its authority, nor
does it otherwise constrain DOE’s
ability to conduct further analyses in a
separate rulemaking.
C. Amended Definitions
To clarify the scope of EPCA’s
coverage of GSFL, IRL, and the recently
adopted standards for GSIL, DOE
proposes to revise its existing
definitions of ‘‘rated wattage’’ and
‘‘colored fluorescent lamp.’’ These
definitional changes are discussed
below.
1. ‘‘Rated Wattage’’
One element of EPCA’s definitions for
‘‘fluorescent lamp’’ and ‘‘incandescent
reflector lamp’’ is a lamp’s rated
wattage, which helps delineate the
lamps for which the statute sets
standards. (42 U.S.C. 6291(30)(A), (C)(ii)
and (F), and 6295(i)). In addition,
section 321(a)(3) of EISA 2007 amended
EPCA to prescribe energy conservation
standards for GSIL, requiring lamps of
particular lumen outputs to have certain
maximum rated wattages. (42 U.S.C.
6295(i)) However, EPCA does not define
the term ‘‘rated wattage.’’
DOE has defined ‘‘rated wattage’’ in
its regulations, but only for 4-foot
medium bipin T8, T10, and T12
fluorescent lamps. 10 CFR 430.2. This
definition references ANSI Standard
C78.1–1991, ‘‘for Fluorescent Lamps—
Rapid-Start Types—Dimensional and
Electrical Characteristics.’’ Id. Although
PO 00000
Frm 00013
Fmt 4701
Sfmt 4702
16931
EPCA also uses the term ‘‘rated wattage’’
to delineate 2-foot U-shaped lamps (42
U.S.C. 6291(30)(A)(ii)), 8-foot slimline
lamps, (42 U.S.C. 6291(30)(A)(iv)), and
IRL (42 U.S.C. 6291(30)(C)), DOE has
not defined ‘‘rated wattage’’ for these
lamps. In the March 2008 ANOPR, DOE
considered revising and updating the
definition of ‘‘rated wattage’’ to cite the
current version of ANSI Standard
C78.1–1991, clarify and improve the
definition, and apply the revised
definition to those lamps for which
rated wattage is a key characteristic but
is not currently defined by DOE. In
response to the March 2008 ANOPR,
DOE received one comment regarding
the definition of ‘‘rated wattage.’’ NEMA
commented that it agrees with DOE’s
revised definition. (NEMA, No. 22 at p.
4).
Therefore, DOE proposes the
following definition for ‘‘rated wattage’’:
Rated wattage means:
(1) With respect to fluorescent lamps
and general service fluorescent lamps:
(i) If the lamp is listed in ANSI
C78.81–2005 or ANSI C78.901–2005,
the rated wattage of a lamp determined
by the lamp designation of Clause 11.1
of ANSI C78.81–2005 or ANSI C78.901–
2005;
(ii) If the lamp is a residential straightshaped lamp, and not listed in ANSI
C78.81–2005, the wattage of a lamp
when operated on a reference ballast for
which the lamp is designed; or
(iii) If the lamp is neither listed in one
of the ANSI guides referenced in (1)(i)
nor a residential straight-shaped lamp,
the wattage of a lamp when measured
according to the test procedures
outlined in Appendix R to subpart B of
this part.
(2) With respect to general service
incandescent lamps and incandescent
reflector lamps, the wattage measured
according to the test procedures
outlined in Appendix R to subpart B of
this part.
2. ‘‘Colored Fluorescent Lamp’’
Colored fluorescent lamps are
excluded from EPCA’s definition of
‘‘general service fluorescent lamp.’’ (42
U.S.C. 6291 (30)(B)(iii)) However, EPCA
does not define the term ‘‘colored
fluorescent lamp.’’ In order to fully
define the scope of EPCA’s definition of
GSFL, DOE currently defines ‘‘colored
fluorescent lamp’’ as follows:
‘‘Colored fluorescent lamp’’ means a
fluorescent lamp designated and marketed as
a colored lamp, and with either of the
following characteristics: a CRI less than 40,
as determined according to the method given
in CIE Publication 13.2 (10 CFR 430.3), or a
correlated color temperature less than 2,500K
or greater than 6,600K.
E:\FR\FM\13APP2.SGM
13APP2
16932
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
10 CFR 430.2. Because these lamps are
not GSFL under EPCA, they are not
covered by the standards applicable to
GSFL.
The central element of EPCA’s
definition of ‘‘general service
fluorescent lamp’’ is that they are
fluorescent lamps ‘‘which can be used
to satisfy the majority of lighting
applications.’’ (42 U.S.C. 6291(30)(B))
The exclusions, such as the one for
colored lamps, are for lamps designed
and marketed for ‘‘non-general lighting
applications.’’ Id. As detailed in the
March 2008 ANOPR, DOE became
aware of a lamp on the European market
that meets the above definition of
‘‘colored fluorescent lamp’’ and that is
intended for general illumination
applications. 73 FR 13620, 13634
(March 13, 2008). Although DOE is
unaware of any similar general purpose
fluorescent lamps being introduced into
the U.S. market, the availability of the
European lamp demonstrates the
potential for DOE’s definition of
‘‘colored fluorescent lamp’’ to exclude
new products with general service
applications from the definition of
‘‘general service fluorescent lamp,’’ and
thereby from the coverage of standards
applicable to GSFL. For this reason, in
the March 2008 ANOPR, DOE proposed
to revise its definition of ‘‘colored
fluorescent lamp’’ by adding the
following phrase after the words
‘‘colored lamp’’: ‘‘and not designed or
marketed for general illumination
applications.’’ Id.
In submitted written comments on the
ANOPR, NEMA agreed with the
proposed revised definition of ‘‘colored
fluorescent lamp,’’ while noting that
DOE will need to give additional
consideration to general illumination
fluorescent lamps with higher color
temperatures. NEMA cited an example
of a lamp with a CCT of 8,000K that
could be used for both general
illumination and specialty applications
(NEMA, No. 22 at p. 9). NEMA
requested a meeting to discuss this
matter in greater detail, since it was
performing research related to this
topic. (DOE, No. 27) This meeting is
subsequently discussed in section II.C.2
of this NOPR.
At the June 2008 NEMA meeting and
in its written comments, NEMA
recommended that the range of GSFL
affected by standards should be
increased to 7,000K from the current
coverage, which extends to only 6,600K.
NEMA believes that lamps with a CCT
between 4,500K and 7,000K are growing
in popularity and, therefore, energy
conservation standards within that
range are justifiable (NEMA, No. 26 at
pp. 3–4).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
NEMA also stated that an efficacy
standard would be inappropriate for
GSFL with a CCT greater than 7,000K.
Because very few GSFL with a CCT
greater than 7,000K are commercially
available, NEMA argued that it would
be impossible to determine whether
there would be an appropriate efficacy
standard for these lamps that would be
technologically feasible. (NEMA, No. 26
at pp. 5–6) NEMA also stated that it is
unlikely that exempting these high CCT
lamps would increase their sales after a
standard, as these lamps are often too
‘‘blue’’ for typical consumers. Therefore,
NEMA urged DOE to exempt all lamps
with a CCT greater than 7,000K from
energy conservation standards (NEMA,
No. 26 at pp. 3–4).
DOE considered NEMA’s input and
agrees that because so few of these
products with a CCT greater than
7,000K exist in the market, there is not
enough information to reliably analyze
the performance of currently-available
products or the expected performance of
emerging products. Manufacturing
lamps with CCTs greater than 7,000K
would likely require the use of new
materials not currently utilized in
commonly sold lamps today. In
addition, manufacturers may encounter
different design trade-offs when
developing their products Therefore,
DOE is unable to determine whether a
particular standard level would be
technologically feasible for these lamps.
DOE also agrees that it is appropriate
to raise the 6,600K limit to 7,000K in the
definition of ‘‘colored fluorescent
lamp.’’ DOE believes that this
amendment would further the statutory
objective of maintaining the coverage of
GSFL serving general application
purposes under DOE’s energy
conservation standards. Although lamps
with CCTs greater than 6,600K and less
than 7,000K are not prevalent in the
market, DOE’s research14 indicates that
manufacturers would likely be able to
produce a lamp at 7,000K using the
same materials as a 6,500K lamp (a
commonly sold lamp). In consideration
of the technological similarity between
6,500K and 7,000K lamps, DOE believes
that it would be possible to establish
technologically feasible efficacy levels
for 7,000K lamps.
Therefore, DOE proposes to modify
the definition of ‘‘colored fluorescent
lamp’’ so as to include lamps with CCT
less than or equal to 7,000K exclude all
lamps with a CCT greater than 7,000K
from energy conservation standards.
However, DOE notes that NEMA has
14 Ex parte communication with Edward Yandek
of General Electric Company (Dec. 8, 2008) (DOE,
No. 29).
PO 00000
Frm 00014
Fmt 4701
Sfmt 4702
offered to track the sales of GSFL with
a CCT greater than 7,000K in order to
determine in the future if energy
conservation standards are necessary for
these products. (NEMA, No. 26 at p. 4)
If these lamp sales show significant
growth, and thus the potential for
significant energy savings, DOE may
consider amending the definition of
‘‘colored fluorescent lamp’’ to provide
for coverage of these lamps and setting
an appropriate energy conservation
standard for them in a future
rulemaking.
As discussed in the March 2008
ANOPR, the discovery of a fluorescent
lamp in the European market with a
CCT of 17,000K being marketed for
general illumination applications
prompted DOE to consider actions to
prevent such lamps from becoming a
potential loophole to the GSFL energy
conservation standard. However, the
inherently ‘‘blue’’ color of these lamps
may prevent widespread adoption as
substitutes for standard CCT lamps (e.g.,
4,100K). Therefore, DOE no longer
considers these lamps to be a potential
loophole to standards set forth by this
rulemaking. For this reason and because
DOE is unable to determine a
technologically feasible standard for
these lamps, DOE believes that the
addition of the phrase ‘‘and not
designed or marketed for general
illumination applications’’ with respect
lamps with a CCT greater than 7,000K
is no longer necessary.
After incorporating the changes
discussed above, DOE proposes the
following definition of ‘‘colored
fluorescent lamp’’ for this notice:
Colored fluorescent lamp means either: (1)
A fluorescent lamp designated and marketed
as a colored lamp with a CRI less than 40,
as determined according to the method set
forth in CIE Publication 13.2 (10 CFR 430.3);
(2) a fluorescent lamp designed and marketed
as a colored lamp with a correlated color
temperature (CCT) less than 2,500K; or (3) a
fluorescent lamp with a CCT greater than
7,000K.
D. Off Mode and Standby Mode Energy
Consumption Standards
Section 310(3) of EISA 2007 amended
EPCA to require future energy
conservation standards to address
standby mode and off mode energy use.
Specifically, EPCA, as amended, now
requires that, when DOE adopts
standards for a covered product after
July 1, 2010, DOE must, if justified by
the criteria for adoption of standards in
42 U.S.C. 6295(o), incorporate standby
mode and off mode energy use into the
standard, if feasible, or adopt a separate
standard for such energy use for that
product. (42 U.S.C. 6295(gg)(3)) DOE
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
notes that although the final rule in this
standards rulemaking is scheduled for
publication by June 2009 (i.e., before the
statutory deadline above), DOE
nonetheless undertook a preliminary
analysis of the potential for energy
savings associated with the regulation of
standby mode and off mode in covered
lamps. DOE has tentatively determined
that current technologies for the GSFL
and IRL that are the subjects of this
rulemaking do not use a standby mode
or off mode, so a determination of the
energy consumption of such features is
inapplicable.
Given EISA 2007’s definitions of
‘‘active mode,’’ ‘‘off mode,’’ and
‘‘standby mode’’ applicable to both
GSFL and IRL, in order to meet the
definition of ‘‘off-mode’’ or ‘‘standby
mode,’’ the lamp must not be providing
any active mode function (i.e., emit
light). However, to reach such a state,
the lamp must be entirely disconnected
from the main power source (i.e., the
lamp is switched off), thereby not
satisfying the requirements of operating
in off mode. In addition, DOE believes
that all covered products that meet the
definitions of ‘‘general service
fluorescent lamp’’ and ‘‘incandescent
reflector lamp’’ are single-function
products and do not offer any secondary
user-oriented or protective functions.
Thus, GSFL and IRL do not satisfy the
definition for ‘‘standby mode.’’ DOE
received comments from NEMA in
response to the March 2008 ANOPR
supporting this characterization of off
mode and standby mode energy
consumption for these products.
(NEMA, No. 22 at p. 1) Therefore, DOE
maintains that it is not feasible to
incorporate off mode or standby mode
energy use into the energy conservation
standards for GSFL and IRL and is not
proposing amendments to the standard
to address lamp operation in such
modes. The March 2008 ANOPR
provides additional details that support
this conclusion. 73 FR 13620, 13627
(March 13, 2008).
E. Color Rendering Index Standards for
General Service Fluorescent Lamps
Existing EPCA standards specify both
lumens per watt and CRI levels that
products must comply with before
entering the market. (42 U.S.C.
6295(i)(1)) At the public meeting and in
written comments, NEMA and the Joint
Comment suggested that it may be
necessary to amend the minimum CRI
requirements to prevent the possible
emergence of loopholes in the product
classes structure and standards levels
considered in the March 2008 ANOPR.
(Public Meeting Transcript, No. 21 at
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
pp. 82–84, 92, 94; Joint Comment, No.
23 at p. 6; NEMA, No. 22 at p. 4–5)
However, because CRI is not a
measure of energy consumption or
efficacy, but rather a measure of the
color quality of the light, DOE has
concluded that it does not have the
authority to change the CRI standard, for
the reasons that follow. According to 42
U.S.C. 6291(6), ‘‘energy conservation
standard’’ means either: (1) A
performance standard which prescribes
a minimum level of energy efficiency or
a maximum quantity of energy use; or
(2) a design requirement (only for
specifically enumerated products).
Although CRI is a performance
requirement, it is not an energy
performance requirement within the
meaning of the term ‘‘energy
conservation standard.’’ Because, in the
case of GSFL, DOE has the authority to
regulate only energy conservation
standards (i.e., energy performance
requirements), DOE is not proposing to
amend the existing minimum CRI
requirements.
IV. General Discussion
A. Test Procedures
DOE’s test procedures for fluorescent
and incandescent lamps are set forth at
10 CFR part 430, subpart B, appendix
R.15 These test procedures provide
detailed instructions for measuring
GSFL and IRL performance, as well as
performance attributes of GSIL, largely
by incorporating several industry
standards. Prompted by an earlier
NEMA comment (NEMA, No. 12, pp. 2–
4) at the Framework stage of the energy
conservation standards rulemaking,
DOE examined these test procedures
and decided to initiate a rulemaking, in
parallel with this standards rulemaking,
to revise its test procedures for GSFL,
IRL, and GSIL (even though, as
explained above, GSIL are no longer
part of this standards rulemaking).
These revisions consist largely of: (1)
Referencing the most current versions of
several lighting industry standards
incorporated by reference; (2) adopting
certain technical changes and
clarifications; (3) expanding the test
procedures to accommodate new classes
of lamps subject to extended coverage
by either EISA 2007 or this energy
conservation standards rulemaking; and
(4) addressing standby mode and off
mode energy consumption (which were
found not to apply to GSFL and IRL), as
mandated by EISA 2007.
To this end, DOE published a NOPR
that proposed to update the current test
15 ‘‘Uniform Test Method for Measuring Average
Lamp Efficiency (LE) and Color Rendering Index
(CRI) of Electric Lamps.’’
PO 00000
Frm 00015
Fmt 4701
Sfmt 4702
16933
procedure’s references to industry
standards for fluorescent and
incandescent lamps. 73 FR 13465
(March 13, 2008) (the test procedure
NOPR). The test procedure NOPR also
proposed the following: (1) A small
number of definitional and procedural
modifications to the test procedure to
accommodate technological migrations
in the GSFL market and approaches
DOE is considering in this standards
rulemaking (73 FR 13465, 13472–73
(March 13, 2008)); (2) revision of the
reporting requirements for GSFL, such
that all covered lamp efficacies would
be reported with an accuracy to the
tenths decimal place (73 FR 13465,
13473 (March 13, 2008)); and (3)
adoption of a testing and calculation
method for measuring the CCT of
fluorescent and incandescent lamps (73
FR 13465, 13473–74 (March 13, 2008)).
Please see the March 2008 ANOPR (73
FR 13620, 13627–28 (March 13, 2008))
and the March 2008 test procedure
NOPR (73 FR 13465, 13472–74 (March
13, 2008)) for a detailed discussion of
these proposals and related matters.
The public meeting for the March
2008 ANOPR also served as a public
meeting to present and receive
comments on the test procedure NOPR.
DOE later received written remarks from
NEMA responding to the proposals
contained in the test procedure NOPR.
(NEMA, No. 16) 16 DOE is considering
these comments, and will be publishing
a final rule in the near future.
B. Technological Feasibility
1. General
In each standards rulemaking, DOE
conducts a screening analysis, which it
bases on information it has gathered on
all current technology options and
prototype designs that could improve
the efficiency of the product or
equipment that is the subject of the
rulemaking. DOE considers a design
option to be ‘‘technologically
feasible’’ 17 if it is in the marketplace or
if research has progressed to the
development of a working prototype.
In consultation with manufacturers,
design engineers, and other interested
parties, DOE develops a list of design
options for consideration in the
rulemaking. In the context of the present
rulemaking, when determining
16 This written comment was submitted to the
docket of the test procedure rulemaking (Docket No.
EERE–2007–BT–TP–0013; RIN number 1904–
AB72).
17 DOE’s regulations set forth the following
definition of ‘‘technological feasibility’’:
‘‘Technologies incorporated in commercially
available products or in working prototypes will be
considered technologically feasible.’’ 10 CFR 430,
subpart C, appendix A, section 4(a)(4)(i).
E:\FR\FM\13APP2.SGM
13APP2
16934
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
proposed efficacy levels for GSFL, DOE
only considered commercially-available
products that can meet or exceed each
level. For IRL, trial standard levels 2, 3,
4, and 5 are based on commerciallyavailable products. Although TSL1 is
not based on product currently sold in
the marketplace, DOE has used a design
option (i.e., higher-efficiency gas fills) to
model the performance of a higherefficacy lamp that meets TSL1. DOE
received input from manufacturers
during interviews to verify that such a
design option is technologically
feasible. Therefore, DOE has concluded
that the all design options to achieve the
proposed efficacy levels are
technologically feasible.
Once DOE has determined that
particular design options are
technologically feasible, it evaluates
each design option in light of the
following criteria: (1) Practicability to
manufacture, install, or service; (2)
adverse impacts on product utility or
availability; and (3) adverse impacts on
health or safety. Chapter 4 of the TSD
accompanying this notice contains a
description of the screening analysis for
this rulemaking. Also, see section 0 of
this notice for a discussion of the design
options DOE considered.
2. Maximum Technologically Feasible
Levels
When DOE proposes to adopt or to
decline to adopt an amended or new
standard for a type (or class) of covered
product, as part of the rulemaking
process, DOE must ‘‘determine the
maximum improvement in energy
efficiency or maximum reduction in
energy use that is technologically
feasible’’ for the product. (42 U.S.C.
6295(p)(1)) In response to the ANOPR,
stakeholders commented that 42 U.S.C.
6295(o) requires that DOE evaluate the
maximum technologically feasible, or
‘‘max-tech,’’ potential standard
efficiency levels. They assert that
because DOE has gathered only
technical information based on products
available on the market today, it may
not have considered those products that
are technically feasible but not yet
marketed. If such options are available,
stakeholders believe DOE should model
them as the max-tech efficiency levels.
(Joint Comment, No. 23 at p. 19)
DOE researched whether any
technologies could improve the efficacy
of GSFL lamps currently marketed. DOE
found that higher efficacy GSFL could
be achieved but require the use of a
higher efficiency fill gas composition.
More efficient fill gases often include
higher molecular weight gases (e.g.,
krypton) to increase ultraviolet light
output, and, thus, visible light output.
However, the use of these heavier gases
can cause lamp instability, resulting in
striations or flickering. Evidence of this
effect can be seen with reduced-wattage
lamps, which generally incorporate a
mixture of krypton and argon gases,
versus full-wattage lamps which
primarily use only argon. Reducedwattage lamps are often marketed with
several application-limiting
performance notes. For example, NEMA
stated reduced-wattage lamps can have
performance issues in low-temperature
applications or when operated on rapid
start or dimming ballasts. (NEMA, No.
21 at p. 10) Therefore, DOE did not
consider efficacy levels for GSFL that
would require the use of higherefficiency fill gases that would result in
reduced utility. DOE was unable to find
any higher-efficacy prototypes or
commercially-available lamps that
provide the same utility and
performance required of GSFL.
Therefore, DOE has concluded that
TSL5 was the maximum technologically
feasible level for GSFL.
For IRL, DOE determined that the
maximum technologically feasible
efficacy level incorporates the highest
technologically feasible efficiency
reflector, halogen infrared coating, and
filament design. From its research, DOE
believes that the highest efficiency
reflector employs silver, a technology
that DOE understands to be proprietary.
From discussions with developers of IR
coating technology, DOE understands
that by modifying the coating pattern
and materials used, varying degrees of
IR coating efficiencies can be achieved.
Finally, altering filament design to
obtain the highest temperature filament
operation, while maintaining a lifetime
similar to the baseline lamp (3,000
hours), would result in the most
efficacious filament. Combining all
three of these highest efficiency
technologies simultaneously results in
the maximum technologically feasible
level; however, this level is dependent
on the use of a proprietary technology
(the silver reflector). Because DOE is
unaware of any alternate technology
pathways to achieve this efficacy level,
DOE did not consider it in its analysis.
Instead, DOE based the highest efficacy
level analyzed for IRL on a
commercially-available IRL which
employs a silver reflector, an improved
(but not most efficient) IR coating, and
a filament design that results in a
lifetime of 4,200 hours. Although, this
commercially-available lamp uses silver
technology, DOE believes that there are
alternate pathways to achieve this level.
A combination of redesigning the
filament to achieve higher temperature
operation (and thus reducing lifetime to
3,000 hours), employing other nonproprietary high-efficiency reflectors, or
applying higher-efficiency IR coatings
has the potential to result in an IRL that
meets an equivalent efficacy level. For
more information regarding these
technologies, see chapter 3 of the TSD.
Therefore, DOE has concluded that
TSL5 is the maximum technologically
feasible level for IRL that is not
dependent on the use of a proprietary
technology.
Table IV.1 and Table IV.2 list the
max-tech levels (TSL5 for GSFL and
TSL5 for IRL) that DOE determined for
this rulemaking.18
TABLE IV.1—MAX-TECH LEVELS FOR GSFL
Lamp type
4-Foot
8-Foot
8-Foot
4-Foot
4-Foot
CCT
Medium Bipin ...............................................................................................................................................
Single Pin Slimline .......................................................................................................................................
RDC HO .......................................................................................................................................................
T5 SO ...........................................................................................................................................................
T5 HO ...........................................................................................................................................................
18 As discussed in section V.C, due to scheduling
and resource constraints, DOE did not analyze all
GSFL and IRL product classes. Instead, DOE chose
representative product classes to directly analyze
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
and scaled analytical results to the remaining
product classes. Table IV.1 and Table IV.2 present
max-tech levels for only analyzed product classes.
Classes not analyzed include the 2-foot U-shaped
PO 00000
Frm 00016
Fmt 4701
Sfmt 4702
≤
≤
≤
≤
≤
4,500K
4,500K
4,500K
4,500K
4,500K
Max-tech
efficiency
lm/W
94
100
95
108
92
and high-CCT product classes (for GSFL) and the
modified spectrum, ≥ 125 volts, and ≤ 2.5 inches
diameter product classes (for IRL).
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
16935
TABLE IV.2—MAX-TECH LEVEL FOR IRL
Lamp type
Diameter
Standard Spectrum ......................................................................................................................
> 2.5 inches
Voltage
< 125
Max-tech efficiency
lm/W
6.9P0.27 *
* Where P is the rated wattage.
C. Energy Savings
1. Determination of Savings
DOE used its NIA spreadsheets to
estimate energy savings from amended
standards for the lamps currently
covered by standards and from new
standards for the remaining additional
lamps that are the subject of this
rulemaking. (The NIA spreadsheet
models are described in section V.E of
this notice and in chapter 11 of the
TSD.) DOE forecasted energy savings
over the period of analysis (beginning in
2012, the year that amended standards
would go into effect, and ending in
2042) for each TSL. It quantified the
energy savings attributable to amended
and new energy conservation standards
(i.e., to each TSL) as the difference in
energy consumption between the
standards case and the base case. The
base case represents the forecast of
energy consumption in the absence of
amended and new mandatory energy
conservation standards. The base case
considers market demand for moreefficient products. For example, for both
GSFL and IRL, DOE models a shift in
the base case from covered GSFL and
IRL toward emerging technologies such
as light emitting diodes (LED). In
addition, consistent with current GSFL
market trends, DOE models a shift from
T12 lamps to higher-efficacy T8 and T5
lamps. For IRL in the commercial sector,
the base-case shipments forecast also
considers a migration from halogen IRL
to higher-efficacy halogen infrared (HIR)
lamps. See section 0 of this notice and
chapter 10 of the TSD for details.
The NIA spreadsheet models calculate
the energy savings in site energy
expressed in kilowatt-hours (kWh). Site
energy is the energy directly consumed
at building sites by GSFL or IRL. DOE
reports national energy savings in terms
of the source energy savings, which is
the savings in the energy that is used to
generate and transmit the energy
consumed at the site. To convert site
energy to source energy, DOE uses
annual site-to-source conversion factors
based on the version of the National
Energy Modeling System (NEMS) that
corresponds to Annual Energy Outlook
2008 (AEO2008). The conversion factors
vary over time because of projected
changes in the nation’s portfolio of
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
generation sources. DOE estimated that
conversion factors remain constant at
2030 values throughout the remainder
of the forecast. See chapter 11 of the
TSD for details.
2. Significance of Savings
Section 325 of EPCA prohibits DOE
from adopting a standard for a covered
product if that standard would not
result in ‘‘significant’’ energy savings.
(42 U.S.C. 6295(o)(3)(B)) While the term
‘‘significant’’ is not defined in EPCA,
the U.S. Court of Appeals, in Natural
Resources Defense Council v.
Herrington, 768 F.2d 1355, 1373 (DC
Cir. 1985), indicated that Congress
intended ‘‘significant’’ energy savings in
this context to be savings that were not
‘‘genuinely trivial.’’ The energy savings
for all of the TSLs considered in this
rulemaking are nontrivial, and therefore,
DOE considers them ‘‘significant’’
within the meaning of section 325 of
EPCA.
D. Economic Justification
1. Specific Criteria
As noted earlier, EPCA provides
seven factors to be evaluated in
determining whether an energy
conservation standard is economically
justified (42 U.S.C. 6295(o)(2)(B)). The
following sections discuss how DOE has
addressed each of those seven factors in
this rulemaking.
a. Economic Impact on Manufacturers
and Consumers
To determine the quantitative impacts
of a new or amended standard on
manufacturers, the economic impact
analysis is based on an annual-cashflow approach. This includes both a
short-term assessment—based on the
cost and capital requirements during the
period between the announcement of a
regulation and the regulation’s effective
start date—and a long-term assessment.
The impacts analyzed include INPV
(which values the industry on the basis
of expected future cash flows), cash
flows by year, changes in revenue and
income, and other appropriate measures
of impact. Second, DOE analyzes and
reports the impacts on different types of
manufacturers, with particular attention
to impacts on small manufacturers.
Third, DOE considers the impact of
PO 00000
Frm 00017
Fmt 4701
Sfmt 4702
standards on domestic manufacturer
employment, manufacturing capacity,
plant closures, and loss of capital
investment. Finally, DOE takes into
account cumulative impacts of different
DOE and other regulations on
manufacturers.
For consumers, measures of economic
impact include the changes in price,
LCC, and payback period for each trial
standard level. The LCC is one of the
seven factors to be considered in
determining the economic justification
for a new or amended standard. (42
U.S.C. 6295(o)(2)(B)(i)(II))
b. Life-Cycle Costs
The LCC is the sum of the purchase
price of a product (including its
installation) and the operating expense
(including energy and maintenance
expenditures) discounted over the
lifetime of the product. For each GSFL
and IRL product class, DOE calculated
both LCC and LCC savings for various
efficacy levels. The LCC analysis
required a variety of inputs, such as
product prices, installation labor costs,
electricity prices, annual operating
hours, product energy consumption
rates, and discount rates.
To characterize variability in
electricity pricing, DOE established
regional differences in electricity prices.
To account for uncertainty and
variability in other inputs, such as
annual operating hours and discount
rates, DOE used a distribution of values
with probabilities assigned to each
value. Then for each consumer, DOE
sampled the values of these inputs from
the probability distributions. The
analysis produced a range of LCCs. A
distinct advantage of this approach is
that DOE can identify the percentage of
consumers achieving LCC savings due
to an increased energy conservation
standard, in addition to the average LCC
savings. DOE presents only average LCC
savings in this NOPR; however,
additional details showing the
distribution of results can be found in
chapter 8 and appendix 8B of the TSD.
In the LCC analysis, DOE also
considered several events that would
prompt a consumer to purchase a lamp.
For GSFL, DOE calculated LCCs for five
lamp purchasing events: (1) Lamp
failure; (2) standards-induced retrofit;
E:\FR\FM\13APP2.SGM
13APP2
16936
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
(3) ballast failure; (4) ballast retrofit; and
(5) new construction/renovation. For
IRL, DOE calculated LCCs for the lamp
failure and new construction/renovation
events, as these were the only lamp
purchase events deemed applicable to
this product type. Because each event
may present the consumer with
different lamp (or lamp-and-ballast)
options and economics, DOE presents
the LCC results for several events for
each product class in this NOPR. DOE
assumed that the consumer purchases
the product in 2012 (the effective start
date of the standard). For further detail
regarding lamp purchasing events and
related LCC calculations, see section
V.D and chapter 8 of the TSD.
c. Energy Savings
While significant conservation of
energy is a separate statutory
requirement for adopting an energy
conservation standard, EPCA requires
DOE, in determining the economic
justification of a standard, to consider
the total projected energy savings that
are expected to result directly from the
standard. (42 U.S.C. 6295(o)(2)(B)(i)(III))
DOE used the NES spreadsheet results
in its consideration of total projected
savings.
d. Lessening of Utility or Performance of
Products
In establishing classes of products,
and in evaluating design options and
the impact of potential standard levels,
DOE aimed to develop standards for
GSFL and IRL that would not lessen the
utility or performance of these products.
None of the considered trial standard
levels would reduce the utility or
performance of the GSFL and IRL under
consideration in the rulemaking. (42
U.S.C. 6295(o)(2)(B)(i)(IV))
Since all standard levels for GSFL use
full-wattage lamps, rather than requiring
a shift to higher-efficacy reducedwattage lamps (which may have
application restrictions), no GSFL
efficacy levels reduce the utility or
performance of the covered products.
For IRL, for all standard levels, there are
commercially available IRL with the
same utility and performance as the
baseline lamps. Therefore, DOE believes
that none of the considered trial
standard levels would reduce the utility
or performance of the IRL under
consideration in this rulemaking.
e. Impact of Any Lessening of
Competition
EPCA directs DOE to consider any
lessening of competition likely to result
from standards. It directs the Attorney
General to determine the impact, if any,
of any lessening of competition likely to
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
result from a proposed standard and to
transmit such determination to the
Secretary no later than 60 days after the
publication of a proposed rule, together
with an analysis of the nature and
extent of such impact. (42 U.S.C.
6295(o)(2)(B)(i)(V) and (B)(ii)) DOE has
transmitted a copy of today’s proposed
rule to the Attorney General and has
requested that the Department of Justice
(DOJ) provide its determination on this
issue. DOE will address the Attorney
General’s determination in the final
rule.
f. Need of the Nation To Conserve
Energy
The non-monetary benefits of the
proposed standard are likely to be
reflected in improvements to the
security and reliability of the Nation’s
energy system—namely, reductions in
the overall demand for energy will
result in reduced costs for maintaining
the Nation’s electricity system. DOE
conducts a utility impact analysis to
estimate how standards may affect the
Nation’s needed power generation
capacity. This analysis captures the
effects of efficiency improvements on
electricity consumption by the covered
products that are the subject of this
rulemaking.
The proposed standard also is likely
to result in improvements to the
environment. In quantifying these
improvements, DOE has defined a range
of primary energy conversion factors
and associated emission reductions
based on the estimated level of power
generation displaced by energy
conservation standards. DOE reports the
environmental effects from each TSL for
this equipment in the environmental
assessment in the TSD. (42. U.S.C.
6295(o)(2)(B)(i)(VI) and 6316(a))
g. Other Factors
EPCA allows the Secretary of Energy,
in determining whether a standard is
economically justified, to consider any
other factors that the Secretary deems to
be relevant. (42 U.S.C.
6295(o)(2)(B)(i)(VII)) Under this
provision, DOE considered subgroups of
consumers that may be adversely
affected by the standards proposed in
this rule. Specifically, DOE assessed the
impact of standards on low-income
consumers, institutions of religious
worship, historical facilities, and
institutions that serve low-income
populations. In considering these
subgroups, DOE analyzed variations on
electricity prices, operating hours,
discount rates, and baseline lamps. See
section 0 of this notice for further detail.
PO 00000
Frm 00018
Fmt 4701
Sfmt 4702
2. Rebuttable Presumption
As set forth in section 325(o)(2)(B)(iii)
of EPCA, there is a rebuttable
presumption that an energy
conservation standard is economically
justified if the additional cost to the
consumer of a product that meets the
standard level is less than three times
the value of the first-year energy (and,
as applicable, water) savings resulting
from the standard, as calculated under
the applicable DOE test procedure. (42
U.S.C. 6295(o)(2)(B)(iii) and 42 U.S.C.
6316(e)(1)) DOE’s LCC and PBP analyses
generate values that calculate the
payback period for consumers of
potential energy conservation standards,
which includes, but is not limited to,
the three-year payback period
contemplated under the rebuttable
presumption test discussed above.
However, DOE routinely conducts a full
economic analysis that considers the
full range of impacts, including those to
the consumer, manufacturer, Nation,
and environment, as required under 42
U.S.C. 6295(o)(2)(B)(i) and 42 U.S.C.
6316(e)(1)). The results of this analysis
serve as the basis for DOE to definitively
evaluate the economic justification for a
potential standard level (thereby
supporting or rebutting the results of
any preliminary determination of
economic justification). Section 0 of this
notice addresses the rebuttablepresumption payback calculation.
V. Methodology and Discussion of
Comments
A. Product Classes
In general, in evaluating and
establishing energy conservation
standards, DOE divides covered
products into classes by the type of
energy used, capacity, or other
performance-related features that affect
efficiency, and factors such as the utility
of the product to users. (42 U.S.C.
6295(q)) DOE normally establishes
different energy conservation standards
for different product classes based on
these criteria.
1. General Service Fluorescent Lamps
In the March 2008 ANOPR, DOE
proposed to establish product classes for
GSFL based on the following three
attributes that have differential utility
and affect efficacy: (1) Physical
constraints of lamps (i.e., lamp shape
and length); (2) lumen package (i.e.,
standard versus high output); and (3)
correlated color temperature. 73 FR
13620, 13636 (March 13, 2008). The
following sections summarize and
address comments DOE received in
response to the GSFL product classes it
considered for the March 2008 ANOPR.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
DOE received comments related to
product classes on three major topics:
T12 and T8 lamps, T5 lamps, and
correlated color temperature.
a. T12 and T8 Lamps
The physical constraints of the lamp
relate to the shape of the lamp (e.g., Ushaped versus linear) and the fact that
these lamps could not be substitutes for
each other, unless the entire fixture is
changed. The lamp shapes provide
unique utility because the shapes of
these lamps prevent them from being
used as replacements, even with a
ballast replacement, in a given fixture.
However, the shape and geometry of a
lamp also impact its efficacy. In the
March 2008 ANOPR, DOE
acknowledged that a lamp’s diameter
can affect its efficacy. However, because
the utility provided to the end-user is a
function of the light output in lumens
(which is comparable between T12 and
T8 lamps) and not diameter of the bulb,
DOE decided not to establish separate
product classes for T12 and T8 lamps.
At the public meeting and in its
written comments, NEMA stated that
separate product classes might be
necessary for T8 and T12 lamps. Both
NEMA and General Electric (GE) noted
that DOE used the 10-percent efficacy
differential between 8-foot slimline and
8-foot high output lamps as one reason
for establishing their separate product
classes. They reasoned that because T8
lamps are at least 10 percent more
efficient that T12 lamps, DOE should
also split T8 and T12 lamps into
separate classes. (Public Meeting
Transcript, No. 21 at pp. 82–86; NEMA,
No. 22 at p. 5) GE emphasized that
because T8 and T12 lamps require
different ballasts and because a growing
number of new T8 fixtures will not fit
T12 lamps, the two are not always
suitable replacements and should
therefore have separate product classes.
GE also expressed concern that it would
be impossible to set a single efficacy
standard using a lumen-per-watt metric
that would be suitable for both T8 and
T12 lamps. (Public Meeting Transcript,
No. 21 at pp. 88–89)
Conversely, the Joint Comment
strongly supported combining T8 and
T12 lamps under one product class
because the lamps are the same length,
use the same lamp holders, and provide
the same utility (as measured by lumen
package). At the public meeting, ACEEE
emphasized that the two lamps compete
directly in the marketplace because of
their similar performance features.
ACEEE also expressed concern that
setting product classes based on efficacy
could lead to separate standards for any
inefficient product. (ACEEE, No. 22 at p.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
91) The Joint Comment also stated that
the fact that the two lamps use different
ballasts is an economic issue, not a
utility issue. The Joint Comment noted
that large energy savings would be lost
if DOE used separate classes because
consumers would not migrate to the
more efficient T8 lamps—a factor DOE
must consider, given its obligation to set
standards at the ‘‘maximum
improvement in energy efficiency’’ that
is ‘‘technologically feasible and
economically justified.’’ (Joint
Comment, No. 23 at pp. 4–5)
DOE research shows that T8 lamps are
commonly used to replace T12 lamps;
this implies that, in this case, lamp
diameter does not significantly affect
lamp utility. It also illustrates that the
lamps share performance features and
compete directly in the market. While
DOE recognizes that lamp diameter can
affect efficacy, lamp efficacy alone is not
a criterion DOE uses to establish
product classes; to warrant a separate
product class, a unique utility feature
must be present. As DOE has not
identified a unique utility feature of T12
lamps, DOE has decided to combine
both T8 and T12 lamps into one product
class for each lamp type. However, in
response to GE’s comment, DOE
recognizes that T8 and T12 lamps
usually operate on different ballasts.
Thus, DOE has structured its analytical
tools to consider the impact of standards
on consumers of both lamp types. That
is, DOE takes the economics of
purchasing another ballast into account
in its LCC and NIA analyses.
b. T5 Lamps
The Joint Comment stated that T5
lamps (in this rulemaking, referred to as
4-foot miniature bipin lamps) should
probably be in the same product class as
T8 and T12 lamps because they compete
against them in the market. The
advocates noted the existence of
retrofitting kits for installing T5 lamps
into T8 and T12 fixtures, but
acknowledged T5 lamps require
different lamp holders and are ‘‘too
bright to use in direct lighting fixtures.’’
The Joint Comment asked DOE to
research the pros and cons of including
T5 lamps with T8 and T12 lamps. (Joint
Comment, No. 23 at p. 5)
Based on its research and
consideration of the above comments,
DOE has decided to establish a separate
product class for 4-foot miniature bipin
lamps because their physical constraints
prevent them from being used as direct
replacements for T8 and T12 lamps in
many applications. For example,
applications in which consumers cannot
change the lamp fixture (from a 4-foot
MBP to a 4-foot MiniBP) may not be
PO 00000
Frm 00019
Fmt 4701
Sfmt 4702
16937
appropriate for retrofitting to the 4-foot
MiniBP system type. As the Joint
Comment noted, these lamps require
different lamp holders (due to
differences in length and base type), and
thereby qualify for a separate product
class under the previously established
‘‘physical constraints of lamps’’ classsetting criteria.
In addition, a lamp’s lumen package
may result in certain application
constraints. Because 4-foot T5 MiniBP
lamps have similar total lumen output
as 4-foot T8 and T12 MBP lamps over
a significantly smaller surface area, T5
lamps are often marketed as too bright
for use in direct lighting fixtures. If 4foot T5 MiniBP lamps were regulated in
the same product class as 4-foot MBP
lamps, the standard could effectively
mandate the use of T5 lamps. To
prevent eliminating lamps appropriate
for direct lighting applications, DOE
believes that 4-foot miniature bipin
lamps (T5 lamps) warrant a separate
product class from 4-foot medium bipin
lamps (primarily T8 and T12 lamps).
In researching these lamp types, DOE
found that the high output lamp is rated
to emit more than one and a half times
the number of lumens as the standard
output lamp, also potentially affecting
utility. In general, lamps that have high
lumen output may be installed in
certain high-ceiling or outdoor
installations, where large quantities of
light are needed. Lamps that have
standard levels of light output might be
installed in lower-ceiling installations
such as offices or hospitals, where
distance between the light source and
the illuminated surfaces is not as large.
DOE also found that this significant
lumen output differential in standard
output and high output T5 lamps is
accompanied by an efficacy difference.
Considering the differences in utility
(light output and their applicability in
direct lighting fixtures) and efficacy,
and consistent with DOE’s approach in
the March 2008 ANOPR, DOE is
proposing separate product classes for
standard output 4-foot miniature bipin
lamps and high output 4-foot miniature
bipin lamps.
c. Correlated Color Temperature
Correlated color temperature is a
measure of the perceived color of the
white light emitted from a lamp, which
DOE believes affects lamp utility.
Generally, as CCT increases, efficacy of
the bulb decreases. The measured
efficacy of lamps with different CCT is
different because efficacy is measured in
lumens per watt, and light emitted
across the visible spectrum is not given
equal weighting under this metric.
Lumens are determined using the
E:\FR\FM\13APP2.SGM
13APP2
16938
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
human eye’s sensitivity function, and
due to the fact that the human eye is less
responsive to blue light, those
fluorescent lamps that shift their
spectral emission profiles to contain
more blue light will have lower
efficacies. In the March 2008 ANOPR,
DOE established two product classes for
GSFL based on CCT: one for high-colortemperature lamps greater than 4,500K,
and another for lamps less than 4,500K.
At the public meeting and in its
written comments, NEMA agreed with
DOE’s decision to establish two product
classes based on CCT. However, at the
public meeting NEMA noted additional
divisions may be necessary at higher
CCT levels because these lamps—NEMA
specifically noted an 8,000K lamp—are
capturing an increasing market share of
general service applications. (Public
Meeting Transcript, No. 21 at pp. 95–97)
Industrial Ecology stated that lamps
around 6,500K, which were once
reserved for specialty applications, are
increasingly being used in general
service applications. Industrial Ecology
argued that such a trend supports the
idea of another product class above the
4,500K division. (Public Meeting
Transcript, No. 21 at pp. 97–98).
At the June 2008 NEMA meeting and
in a written comment, NEMA
commented that growth in higher CCT
lamps would likely come at the 5,000K
level, although they would remain a
relatively small portion of the general
service market for the foreseeable future.
Lamps with CCTs greater than 7,000K
represent a very small portion of the
general service market because most
consumers consider their light to be too
blue. Given the small market for lamps
above 7,000K, NEMA stated it had very
little practical production data related to
efficacies and costs. Therefore, NEMA
argued, lamps above 7,000K should be
exempt from standards, especially
considering that the current energy
savings potential from their coverage is
very small and unlikely to grow anytime
soon. (NEMA, No. 26 at pp. 3–4)
NEMA also commented that an
equation using a continuous function
(without discontinuities) is
inappropriate when developing an
efficacy standard for GSFL based on
CCT. According to NEMA, practical
lamp designs used to develop higher
CCT lamps—such as phosphor design,
weight and coating formulation, and
coating adherence—do not provide for a
general physical equation that yields an
optimum lumens-per-watt standard.
Instead, NEMA stated that successive
step function factors need to be applied
as CCT continues to increase. (NEMA,
No. 26 at p. 5) The Joint Comment said
that DOE should design CCT product
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
class divisions carefully to prevent
‘‘gaming.’’ The advocates preferred a
continuous function to multiple product
class divisions because the latter would
encourage products to migrate to the
lowest CCT value in each product class.
If a continuous function were not
possible, the Joint Comment strongly
recommended raising the 4,500K
division to 4,900K. Additionally, the
Joint Comment stated, if DOE does set
a product class aimed at regulating the
8,000K lamps, the boundary should be
approximately 7,900K. (Joint Comment,
No. 23 at pp. 5–6)
As noted above, DOE believes CCT
affects consumer utility. For example, a
lighting designer would likely consider
the bluish color of higher color
temperature lamps when specifying a
luminaire for a particular application. In
addition, as NEMA stated, higher CCT
lamps are sometimes used for
spectrally-enhanced lighting (SEL).19
Advocates of spectrally-enhanced
lighting believe that lamps with a higher
CCT can help save energy and may also
have health benefits. (NEMA, No. 26 at
pp. 2–3) However, DOE notes that
although spectrally-enhanced lighting
has benefits, higher CCT lamps do emit
a different color light that may not be
appropriate for all applications. Given
the effect on utility and the fact that
lamp efficacy usually decreases with
higher color temperatures, it is
appropriate to establish different
product classes based on CCT.
DOE agrees that a continuous function
is not possible because increasing the
CCT does not lead to proportional
reductions in lumens per watt. This
occurs because design factors that do
not have a linear relationship with
lumens per watt, such as rare earth
phosphor mix and reformulation, must
be employed to maintain efficacy,
particularly as CCT increases.
DOE disagrees that a 4,900K division
should be used rather than the proposed
4,500K division. If DOE were to use a
4,900K division and manufacturers
introduced a 4,850K lamp to the market,
it would be subject to standards based
on the performance of a 4,100k lamp,
which might be difficult to meet, as
4,100K lamps are generally more
efficacious than their higher CCT
counterparts. Likewise, if DOE used a
19 DOE has conducted several studies on SEL
examining whether a significant amount of energy
can be saved by using lamps that have less light
output, but higher CCT. Lamps with higher CCT
appear brighter than those with lower CCT, so the
actual light output of higher-CCT lamps can be
decreased, while maintaining equivalent perceived
brightness and visual acuity. More information on
spectrally enhanced lighting is available at:
https://www1.eere.energy.gov/buildings/
spectrally_enhanced.html.
PO 00000
Frm 00020
Fmt 4701
Sfmt 4702
4,200K division and manufacturers
developed a 4,300K lamp for
commercial use, it would be subject to
potentially lower standards based on the
performance of a 5,000k lamp. This may
result in a significant loss in potential
energy savings. Instead, DOE proposes
to use a 4,500K division, which
effectively represents the midpoint
between the most common
commercially available ‘‘warmer’’ and
‘‘cooler’’ lamps at 4,100K and 5,000K,
respectively. By establishing the
product class division at the midpoint,
DOE ensures that it is establishing a
structure that will not subject lamps to
inappropriately high standards and also
not result in the loss of potential energy
savings.
DOE also disagrees with the Joint
Comment’s argument for a third product
class division around 7,900K aimed at
8,000K lamps. As discussed in section
III.C.2, DOE is amending its definition
of ‘‘colored fluorescent lamp,’’ such that
these lamps above 7,000K would be
excluded from coverage by energy
conservation standards. In consideration
of this exclusion, DOE feels that is
unnecessary to establish a third product
class for lamps with a CCT greater than
7,900K.
2. Incandescent Reflector Lamps
In the March 2008 ANOPR, DOE
considered product classes for IRL
based on the standard-spectrum and
modified-spectrum of the lamp. DOE
received numerous comments regarding
establishing separate product classes
for: (1) Modified-spectrum lamps; (2)
long-life lamps; (3) lamp diameter; and
(4) voltage. The following sections
summarize and address these
comments.
a. Modified-Spectrum Lamps
Modified-spectrum lamps provide a
unique performance-related feature to
consumers, in that they offer a different
spectrum of light from the typical
incandescent lamp, much like two
fluorescent lamps with different CCT
values. These lamps offer the same
benefits as fluorescent lamps with
‘‘cooler’’ CCTs, in that they may ensure
better color discrimination and often
appear more similar to natural daylight,
possibly resulting in psychological
benefits.20 In addition to providing a
unique performance feature, DOE also
understands that the technologies that
modify the spectral emission from these
lamps also decrease their efficacy
because a portion of the light emission
20 ‘‘Full Spectrum Q&A,’’ National Lighting
Product Information Program, Vol. 7 Issue 5 (March
2005). Available at: https://www.lrc.rpi.edu/
programs/nlpip/lightingAnswers/fullSpectrum.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
is absorbed by the coating. NEMA and
GE supported establishing separate
product classes for modified-spectrum
lamps. (Public Meeting Transcript, No.
21 at p. 105; NEMA, No. 22 at p. 6).
However, the Joint Comment stated
that separate product classes are
unnecessary because modified-spectrum
products which meet all efficacy levels
DOE considered in the ANOPR already
exist in the market place. The Joint
Comment further argued that additive
methods, used for some non-IRL
technologies, boost particular visible
wavelengths of light to achieve a
modified spectrum. These methods
represent a more efficient way to
achieve a modified spectrum than
subtractive methods commonly used for
IRL, which filter particular visible
wavelengths of light. Therefore,
according to the Joint Comment,
establishing a separate product class
could reduce energy savings because
modified-spectrum technology would be
subject to a needlessly lower standard.
The Joint Comment contended that such
a situation would run counter to the
rulemaking’s goals. (Joint Comment, No.
23 at pp. 14–15) At the public meeting,
ACEEE and PG&E questioned whether
consumers receive additional utility
from modified-spectrum lamps, and, if
they do, whether it is sufficient to
warrant a separate product class. ACEEE
and PG&E suggested DOE analyze the
energy savings that could be lost with a
separate product class. PG&E further
noted that consumers could obtain any
additional utility that modifiedspectrum lamps provide from other
available light sources. (Public Meeting
Transcript, No. 21 at pp. 101–103) PG&E
commented that modified-spectrum
lamps occupy significant retail shelf
space, which suggests they have a
significant market share, and therefore,
present a significant energy savings
opportunity. (Public Meeting Transcript,
No. 21 at p. 104)
DOE maintains that modifiedspectrum lamps provide a unique
performance-related feature (a different
spectrum of light from the typical
incandescent lamp) that standard
spectrum lamps do not provide.
However, the coatings used for
modified-spectrum IRL absorb light
output, thus reducing the lamps’
efficacies. Given the reduction in
efficacy, DOE believes that some
modified-spectrum lamps may not be
able to meet standards if subjected to
the same levels as standard-spectrum
lamps. That, in turn, could cause the
unavailability of such products, thereby
eliminating this performance-related
feature from the IRL market. DOE notes
that the statute directs DOE to maintain
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
performance-related features for a
covered product type. (42 U.S.C.
6295(o)(4))
Regarding the Joint Comment’s
argument that higher-efficiency,
additive technologies may be
substituted for subtractive technologies
currently used in modified-spectrum
IRL lamps, DOE is unaware of any
commercially-available IRL or working
IRL prototype that employs these
additive technologies. Although
modified-spectrum LED products may
be available, because DOE has
determined that modified-spectrum
lamps provide a unique performancerelated feature, it is unable to subject
them to standards that would result in
the elimination of such IRL products
from the market. Thus, DOE believes it
is appropriate to establish a separate
product class for modified-spectrum
lamps based on their unique
performance feature and the impact of
this performance feature on product
efficacy.
b. Long-Life Lamps
DOE received several comments
regarding IRL with long lifetimes. At the
public meeting, NEMA commented that
lamp life is a top consideration for the
lighting industry’s customers,
particularly large retailers. NEMA stated
in its written comments that the current
long-life lamps on the market might be
jeopardized by the proposed standard
levels, which could cause
manufacturers to reduce lamp life to
increase efficacy—a scenario not
necessarily in the market’s interest.
(Public Meeting Transcript, No. 21 at
pp. 177–178; NEMA, No. 22 at p. 17)
Although NEMA did not explicitly
request a separate product class, the
Joint Comment argued that DOE should
not establish a separate product class for
long-life lamps, noting that other
existing lamp types, including halogen
infrared reflector lamps and CFLs, could
adequately serve long-life applications.
In support of their position, the
advocates stated further that Congress
did not establish a separate class for
‘‘long life’’ general service incandescent
lamps. (Joint Comment, No. 23 at p. 15)
DOE considers lifetime an economic
issue rather than a utility issue, and
accounts for lifetime in its LCC and NPV
calculations. Lifetime is not considered
a utility issue because it does not
change the light output of the lamp. As
such, DOE did not establish a separate
product class based on lamp lifetime.
For more details, see the engineering
analysis in section V.C.4.b and chapter
5 of the TSD.
PO 00000
Frm 00021
Fmt 4701
Sfmt 4702
16939
c. Lamp Diameter
In its written comments, NEMA noted
that smaller diameter lamps—
specifically, PAR20 lamps—are
inherently less efficient than larger
diameter IRL. Manufacturing PAR20
lamps to be compliant with the same
efficacy standards as larger lamps would
be very difficult. NEMA also
commented that the technology options
available to larger lamps are not
necessarily applicable to PAR20 lamps.
For example, the most efficient doubleended infrared halogen burner is
difficult to use in PAR20 lamps because
of mounting considerations. (NEMA,
No. 22 at p. 17)
In response, DOE believes that the IRL
diameter provides a distinct utility to
the consumer (such as the ability of
reduced diameter lamps to be installed
in smaller fixtures) and recognizes that
efficacy declines with a smaller lamp
diameter. A smaller diameter lamp has
an inherently lower optical efficiency
than a larger diameter lamp given a
similar filament size. Therefore, DOE is
proposing to establish separate product
classes for lamps with a diameter of 2.5
inches or less and lamps with a
diameter greater than 2.5 inches.
d. Voltage
In its written comments, NEMA
mentioned that DOE’s proposed product
classes and standards do not address
how the market actually uses 130 volt
(V) lamps, which represent a sizable
portion of standard halogen product
sales. NEMA stated that customers
almost always operate these 130V lamps
at 120V (normal line voltage), which
doubles their lifetime but reduces their
efficacy below standard levels. (NEMA,
No. 22 at p. 16)
DOE agrees with NEMA and is
concerned that the operation of 130V
lamps at 120V has the potential to
significantly affect energy savings.
When operated under 120V conditions,
lamps rated at 130V in compliance with
existing IRL efficacy standards are
generally less efficacious than lamps
using equivalent technology rated at
120V. Because of this inherent
difference in efficacy, it may be less
costly to manufacture a lamp rated at
130V and tested at 130V that complies
with a standard than a similar 120V
lamp complying with the same
standard. For example, if DOE were to
adopt a minimum efficacy requirement
that would effectively require HIR
technology for 120V lamps, due to
differences in the test procedures for
lamps rated at 130V, a 130V lamp may
only need to employ an improved
halogen technology, which would be
E:\FR\FM\13APP2.SGM
13APP2
16940
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
less costly. If DOE does not establish a
separate standard for lamps rated at
130V, more consumers may purchase
130V lamps because they are less
expensive. When consumers operate
these lamps at 120V, in order to obtain
sufficient light output, they may use
more energy than standards-compliant
120V lamps. This practice would
increase energy consumption and result
in lamps operating with a lower efficacy
than any cost-justified standard level.
Therefore, to preserve the energy
savings intended by these standards,
DOE is proposing to establish two
separate product classes: (1) Lamps with
a rated voltage less than 125V, and (2)
lamps with a rated voltage greater than
or equal to 125V.
DOE recognizes that there are other
possible approaches for addressing this
issue of the operational efficacy of 130V
lamps. One alternative approach would
be that DOE could require all IRL to be
tested at 120V, the most common
application voltage in the market. DOE
requests comment on this issue.
B. Screening Analysis
DOE uses the following four screening
criteria to determine which design
options are unsuitable for further
consideration in the rulemaking:
(1) Technological Feasibility. DOE
will consider technologies incorporated
in commercial products or in working
prototypes to be technologically
feasible.
(2) Practicability to Manufacture,
Install, and Service. If mass production
and reliable installation and servicing of
a technology in commercial products
could be achieved on the scale
necessary to serve the relevant market at
the time the standard comes into effect,
then DOE will consider that technology
practicable to manufacture, install, and
service.
(3) Adverse Impacts on Product Utility
or Product Availability. If DOE
determines a technology would have
significant adverse impact on the utility
of the product to significant subgroups
of consumers, or would result in the
unavailability of any covered product
type with performance characteristics
(including reliability), features, sizes,
capacities, and volumes that are
substantially the same as products
generally available in the United States
at the time, it will not consider this
technology further.
(4) Adverse Impacts on Health or
Safety. If DOE determines that a
technology will have significant adverse
impacts on health or safety, it will not
consider this technology further.
10 CFR part 430, subpart C, appendix A,
(4)(a)(4) and (5)(b).
Considering these criteria, DOE
compiled a list of design options in the
March 2008 ANOPR that could be used
to increase the efficacy of GSFL and IRL
lamps (Table V.1). 73 FR 13620, 13644
(March 13, 2008).
TABLE V.1—GSFL AND IRL DESIGN OPTIONS
GSFL design options
IRL design options
Highly emissive electrode coatings
Higher efficiency lamp fill gas composition
Higher efficiency phosphors
Glass coatings
Higher efficiency lamp diameter
Higher temperature operation.
Thinner filaments.
Efficient filament coiling.
Efficient filament orientation.
Higher efficiency inert fill gas.
Tungsten-halogen lamps.
Higher pressure tungsten-halogen lamps.
Infrared glass coatings.
Higher efficiency reflector coatings.
Efficient filament placement.
DOE received a number of comments
in response to its list of proposed design
options, as discussed below.
1. General Service Fluorescent Lamps
NEMA generally agreed with the list
of design options, but mentioned that
for GSFL, further efficacy improvement
will likely come from improved system
(lamp-ballast-luminaire) combinations,
and urged DOE to aim in future
rulemakings to improve overall systems.
(NEMA, No. 22 at p. 9; Public Meeting
Transcript, No. 21 at pp. 108–109)
DOE understands that the fluorescent
lamp is only one part of a fluorescent
lamp system, which also includes
ballasts and fixtures. However, DOE
does not have the authority to regulate
a fluorescent lamp system. EPCA
prescribes energy conservation
standards for certain GSFL (42 U.S.C.
6295(i)(1)(B)) and fluorescent lamp
ballasts. (42 U.S.C. 6295(g)(7)) EPCA
does not contain any standards for
fluorescent lamp systems. Since EPCA
directs DOE to amend only the existing
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
standards for GSFL and fluorescent
lamp ballasts, DOE has concluded that
it does not have the authority to set
energy conservation standards for
fluorescent lamp systems. DOE believes
other approaches, such as building
codes, are more appropriate for
regulating a fluorescent lamp system.
a. Higher-Efficiency Lamp Fill Gas
Composition
NEMA commented that fill gas mixes
are already in use in both T12 and T8
reduced-wattage energy savings lamps.
NEMA stated that lamps could be
manufactured using even higher
efficiency fill gas compositions;
however, the actual achieved lumen
levels may be unacceptable to the
market. NEMA also commented that
most manufacturers identify several
application-limiting issues for both T8
and T12 reduced-wattage energy saving
lamps. (NEMA, No. 22 at pp. 7, 11–12)
DOE agrees that using fill gas
composition in reduced-wattage lamps
can lead to lamps with limited utility.
PO 00000
Frm 00022
Fmt 4701
Sfmt 4702
For example, when marketed, many
reduced wattage lamps are not
recommended to be used under low
lamp ambient temperatures or in drafty
locations and on dimming ballasts.
These situations could result in lamp
starting or stabilization problems,
striation (alternating light and dark
bands), pulsing or a reduction in light
output. Therefore, although DOE
incorporates reduced-wattage lamps
into the LCC and NIA (as they are viable
and likely choices for most GSFL
applications), DOE does not consider
any efficacy level that would force
consumers to purchase these lamps. See
section V.C.4.a for details.
b. Higher-Efficiency Phosphors
NEMA commented that rare earth
phosphors are already at nearly 100
percent quantum efficiency.21 While
slight improvements in efficacy are
21 ‘‘Quantum efficiency,’’ in this context, is used
to quantify the percentage of ultraviolet photons
absorbed by the phosphor that are then reemitted
as visible photons.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
possible with a thicker phosphor
coating, NEMA argued that using this
option will disproportionately increase
`
lamp costs vis-a-vis the performance
improvement. NEMA stated that the
opportunities for performance
improvement using phosphors ‘‘lie in
tailoring phosphor blends and color
temperatures to optimize appropriate
light sources for specific applications.’’
(NEMA, No. 22 at p. 7)
While DOE agrees that thicker
phosphor coats may increase cost, DOE
does not consider increased costs in the
screening analysis. DOE considers
potential cost increases in its economic
analyses. In addition, many higherefficiency GSFL incorporate varying
thicknesses of rare earth phosphors, or
blends of halophosphors and rare earth
phosphors. These lamps, more
efficacious than their pure
halophosphor counterparts, show that
using higher-efficiency phosphors is a
valid design option that meets all of the
screening criteria. Therefore, DOE
believes there is room for significant
efficacy improvement potential with
this design option and, thus, continued
to carry it forward in its analyses.
c. Glass Coating
NEMA commented that higherefficiency lamps already use glass
coatings. NEMA also stated that while
opportunities exist to improve this
technology, manufacturers need to
balance costs and performance. (NEMA,
No. 22 at p. 7) DOE recognizes that costs
may increase with this technology
option, but as stated earlier, DOE does
not consider the impacts of cost in its
screening analysis. Therefore, DOE has
included glass coatings as a design
option for GSFL, where prototypes or
commercially-available products exist.
d. Lamp Diameter
NEMA commented that lamp
diameter is already used to optimize
luminaire optics and system efficacy,
but not to improve lamp efficacy.
According to NEMA, further
improvements in performance can come
from new luminaire designs based on
different diameter lamps, but will be
limited by lumen packages and the
distance between the light source and
the luminaire surfaces. (NEMA, No. 22
at p. 7)
In response to this comment, DOE
only considered lamp diameter as a
design option in the migration from T12
to T8 lamps. DOE’s research indicates
that T8 lamps are common replacements
for T12 lamps. Although the total lumen
output of T8 lamps is often lower than
that of T12 lamps, these differences in
lumen outputs (on the order of 10
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
percent) do not seem to be significant
enough to affect consumer utility.
Conversely, although the total lumen
output of 4-foot T5 MiniBP lamps can
be similar to 4-foot T8 MBP and 4-foot
T12 MBP lamps, the lumen output is
emitted from a more concentrated light
source. DOE’s research indicates that T5
lamps’ higher light concentrations (and
therefore brightness) may require greater
distances between the light source and
illuminated surfaces. Due to this
limitation in utility, DOE did not
consider migration to a lamp diameter
associated with T5 lamps to be a design
option to improve the efficacy of T8 and
T12 lamps.
e. Multi-Photon Phosphors
NEMA commented that although
commercial multi-photon phosphors are
theoretically possible, they have yet to
be developed, despite 30 to 40 years of
research. (NEMA, No. 22 at p. 7) As
explained in chapter 3 of the TSD,
because multi-photon phosphors emit
more than one visible photon for each
incident ultraviolet photon, a lamp
would be able to emit more light for the
same amount of power, thereby
increasing efficacy. DOE agrees that this
technology is not sufficiently mature as
to warrant further analysis, so DOE has
screened out this technology option in
the March 2008 ANOPR.
2. Incandescent Reflector Lamps
NEMA does not believe that xenon, a
higher-efficiency inert fill gas, should be
considered a design option because
there is a limited supply of this gas and
prices are increasing rapidly. (NEMA,
No. 22 at p. 8; Public Meeting
Transcript, No. 21 at pp. 108–109)
Although price is not considered in
the screening criteria, DOE did conduct
an in-depth market assessment of the
supply of xenon, and the potential
impact of xenon supply limitations on
IRL standard levels. DOE determined
that although xenon is a rare gas, its
supply is sufficiently large to
incorporate into all IRL and that the
xenon supply would not affect IRL
product availability. A more detailed
analysis of xenon and its availability
can be found in appendix 3B of the
TSD.
C. Engineering Analysis
For each product class, the
engineering analysis identifies potential,
increasing efficacy levels above the level
of the baseline model. Those
technologies not eliminated in the
screening analysis (design options) are
inputs to this process. Design options
consist of discrete technologies (e.g.,
infrared reflective coatings, rare-earth
PO 00000
Frm 00023
Fmt 4701
Sfmt 4702
16941
phosphor mixes). As detailed in the
March 2008 ANOPR, to ensure that
efficacy levels analyzed are
technologically feasible, DOE
concentrated its efforts on developing
product efficacy levels associated with
‘‘lamp designs,’’ based upon
commercially-available lamps that
incorporate a range of design options in
the engineering analysis. 73 FR 13620,
13645 (March 13, 2008). However, when
necessary, DOE supplemented
commercially available product
information with an examination of the
improved performance attributable to
discrete technologies so that a substitute
lamp at each efficacy level would be
available for each baseline lamp.
In energy conservation standard
rulemakings for other products, DOE
often develops cost-efficiency
relationships in the engineering
analysis. However, for this lamps
rulemaking, DOE derived efficacy levels
in the engineering analysis and end-user
prices in the product price
determination. By combining the results
of the engineering analysis and the
product price determination, DOE
derived typical inputs for use in the
LCC and NIA. See the chapter 7 of the
TSD for further details on the product
price determination.
1. Approach
For the NOPR, DOE is using the same
methodology for the engineering
analysis that was detailed in the March
2008 ANOPR. 73 FR 13620, 13645–46
(March 13, 2008). The following is a
summary of the steps taken in the
engineering analysis:
• Step 1: Select Representative Product
Classes
• Step 2: Select Baseline Lamps
• Step 3: Identify Lamp or Lamp-andBallast Designs
• Step 4: Develop Efficiency Levels.
A more detailed discussion of the
methodology DOE followed to perform
the engineering analysis can be found in
the engineering analysis chapter of the
TSD (chapter 5).
2. Representative Product Classes
As discussed in section 0 of this
notice, DOE proposes establishing
several product classes for GSFL and
IRL. DOE proposes eight product classes
across the range of covered GSFL based
on utility and performance features,
such as: (1) Physical constraints of
lamps (i.e., lamp shape and length); (2)
lumen package (i.e., standard versus
high output); and (3) correlated color
temperature. For IRL, DOE proposes
eight product classes based on
spectrum, lamp diameter, and rated
E:\FR\FM\13APP2.SGM
13APP2
16942
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
voltage. As detailed in the March 2008
ANOPR, due to scheduling and resource
constraints, DOE was not able to analyze
each and every product class. 73 FR
13620, 13646 (March 13, 2008). Instead,
DOE carefully selected certain product
classes to analyze, and then scaled its
analytical findings for those
representative product classes to other
product classes that were not analyzed.
73 FR 13620, 13652 (March 13, 2008).
While DOE received several stakeholder
comments regarding methods of scaling
to product classes not analyzed
(discussed in section V.C.7), DOE did
not receive objections to the decision to
scale to certain product classes and the
representative product classes chosen in
the March 2008 ANOPR.
For the NOPR, similar to its approach
in the March 2008 ANOPR, DOE
continued to analyze 4-foot medium
bipin, 8-foot single pin slimline, and 8foot recessed double-contact high
output GSFL product classes with CCTs
less than or equal to 4,500K. DOE did
not explicitly analyze U-shaped lamps,
but instead scaled the results of the 4foot medium bipin class analysis. In
addition, DOE has decided to analyze 4foot T5 miniature bipin standard output
lamps and 4-foot T5 miniature bipin
high output lamps with CCTs less than
or equal to 4,500K as representative
product classes.
As discussed in section A.2, DOE
chose to subdivide IRL into eight
product classes with three subdivisions:
(1) High versus low voltage; (2) large
versus small diameter lamps; and (3)
modified spectrum versus standard
spectrum. As detailed in the March
2008 ANOPR, DOE chose to analyze the
standard-spectrum incandescent
reflector product class because
standard-spectrum lamps are more
common than modified-spectrum
lamps. 73 FR 13620, 13648 (March 13,
2008). After analyzing catalog data and
talking to industry experts, DOE found
that lamps with a diameter greater than
2.5 inches are more common than lamps
of smaller diameters. Lamps with
voltage ratings less than 125V also are
more common than lamps with higher
voltage ratings. Therefore, for the NOPR,
DOE proposes to analyze the product
class characterized by standard
spectrum, voltage less than 125V, and
diameter greater than 2.5 inches. For
further information on representative
product classes, see chapter 5 of the
TSD.
3. Baseline Lamps and Systems
Once DOE identified the
representative product classes for
analysis, DOE selected the
representative units for analysis (i.e.,
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
baseline lamps) from within each
product class. These representative
units are generally what DOE believes to
be the most common, least efficacious
lamps in their respective product
classes. DOE chose multiple baseline
lamps because DOE found that the
market for each product class is
segmented into multiple submarkets for
lamps with slightly different consumer
utilities. For example, the 40W T12,
34W T12, and 32W T8 lamps are the
most common lamps in the commercial
four-foot medium bipin product class.
The 34W T12 is a reduced wattage lamp
that is not as versatile as the 40W T12,
however, and consumers switching from
a T12 to a T8 lamp must purchase a new
ballast. Thus, these lamps are not
entirely substitutable, so DOE has
chosen to analyze them as separate
baselines. DOE’s selection of baseline
lamps is discussed in further detail
below.
a. General Service Fluorescent Lamps
As described in the March 2008
ANOPR, DOE took a systems approach
to its GSFL analysis. 73 FR 13620,
13649 (March 13, 2008). In this
approach, DOE selected typical ballasts
(which provide current to the lamps) to
pair with each baseline lamp and
higher-efficacy lamp. Though DOE did
not consider the ballast as directly
affecting lamp efficacy, the ballast
selection does affect the overall system
efficacy (system input power and total
lumen output), thereby having a
significant impact on LCC and NIA
results. For this reason, DOE considered
a variety of ballast types (e.g., electronic
and magnetic) and ballast factors in its
analysis.
In the March 2008 ANOPR, DOE
chose three baseline lamps for 4-foot
medium bipins less than or equal to
4,500K (installed on T8 electronic and
T12 magnetic ballasts), three baseline
lamps for 8-foot single pin slimlines less
than or equal to 4,500K (installed on T8
electronic and T12 magnetic ballasts),
and two baseline lamps for 8-foot
recessed double-contact HOs less than
or equal to 4,500K (installed on T8
magnetic and T12 magnetic ballasts). 73
FR 13620, 13647 (March 13, 2008). DOE
did not receive any comments on
baseline lamps for the commercial and
industrial sectors and thus has retained
all baseline lamps from the March 2008
ANOPR. However, as discussed below,
DOE did receive comments regarding
additional sectors to analyze and the
ballast selected to pair with the 8-foot
RDC HO baseline lamps. In addition,
DOE developed baseline lamp-andballast systems for the 4-foot T5 MiniBP
SO and HO product classes.
PO 00000
Frm 00024
Fmt 4701
Sfmt 4702
Regarding GSFL operating in the
residential sector, several stakeholders
commented that residential T12 ballasts
will continue to be sold past 2009 and
that the residential applications of these
ballasts represent a large portion of the
remaining market for these lamps.
(NEMA, No. 22 at pp. 20, 25; Public
Meeting Transcript, No. 21 at pp. 276–
277) PG&E stated that T12 lamps on
magnetic ballasts continue to exist in
the residential sector in California.
(Public Meeting Transcript, No. 21 at p.
279) The Joint Comment also stated that
residential applications need to be
factored into the analysis, but because
the same lamps can be used in all
sectors, a separate analysis is not
needed for the residential sector. (Joint
Comment, No. 23 at p. 10)
In response, in this NOPR, DOE has
analyzed GSFL in the residential sector.
In interviews with manufacturers and
by reviewing manufacturer product
catalogs, DOE found that a significant
portion of T12 4-foot medium bipin
lamps operate in the residential sector.
DOE is maintaining the same standards
case lamps used in the commercial and
industrial sectors for 4-foot medium
bipins in the residential sector because,
as the Joint Comment stated, the same
lamps can be used in all sectors.
However, DOE is choosing a separate
baseline lamp for the residential 4-foot
medium bipin analysis. Conversations
with industry experts and a published
study prepared for PG&E 22 have
revealed that residential consumers are
more likely to buy 40W T12 lamps
because 32W T8 lamps and 34W T12
lamps are less common. Therefore, in
the residential sector, DOE is only
analyzing the 40W T12 lamp as a
baseline lamp. In addition, reviewing
available catalog information, DOE has
found that the most common 40W T12
lamp sold in the residential sector is
different from the 40W T12 baseline
lamp presented in the March 2008
ANOPR for the commercial and
industrial sectors. 73 FR 13620, 13647
(March 13, 2008). Therefore, in the
NOPR, DOE has chosen a 40W T12
baseline lamp for the residential sector
that has a slightly lower efficacy (76.8
lm/W) and shorter lifetime (15,000
hours) than the typical 40W T12 lamp
sold in the commercial sector.
22 ‘‘Codes and Standards Enhancement (CASE)
Initiative for PY2008: Title 20 Standards
Development,’’ Analysis of Standards Options for
Linear Fluorescent Fixtures (Prepared for PG&E by
ACEEE, Lighting Wizards, and Energy Solutions).
(Last modified May 14, 2008) Available at: https://
www.energy.ca.gov/appliances/2008rulemaking/
documents/2008-05-15_workshop/other/
PGE_CASE_Study_-_Linear_Fluorescent_
Fixtures.pdf.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
After reviewing manufacturer
literature and the study prepared for
PG&E on fixtures in the residential
sector,23 DOE found that the most
common residential sector ballast is a
low-power-factor 2-lamp magnetic T12
system with a ballast factor of 0.68.
Therefore, for the NOPR, DOE paired
the baseline lamp with this ballast for
the residential sector analysis.
Because DOE has decided to cover
and analyze 4-foot T5 miniature bipin
standard output and 4-foot T5 miniature
bipin high output lamps in this
rulemaking (section 0 of this notice),
DOE established baseline lamps for
these two product classes. NEMA and
the Joint Comment both stated that if
DOE does not cover T5 lamps, then less
efficient, halophosphor T5 lamps may
enter the market place. (Public Meeting
Transcript, No. 21 at pp. 71–72; Joint
Comment, No. 23 at p. 3) Because these
less efficient halophosphor T5 lamps are
not on the market today, DOE developed
model T5 halophosphor lamps in its
engineering analysis. To create these
model T5 lamps, DOE used efficacy data
from short halophosphor fluorescent T5
lamps currently available and
developed a relationship between length
and efficacy. DOE validated this
relationship by comparing it to previous
industry research. DOE then used this
relationship to determine the efficacies
of a halophosphor 4-foot T5 miniature
bipin standard output lamp and a
halophosphor 4-foot halophosphor T5
miniature bipin HO lamps. Specifically,
the baseline 4-foot miniature bipin
standard output lamp is 28W with an
efficacy of 86 lm/W and a lifetime of
20,000 hours. The baseline 4-foot
miniature bipin high output lamp is
54W with an efficacy of 77 lm/W and a
lifetime of 20,000 hours. DOE used
these lamps as baseline lamps to
establish the economic impacts of a
standard that would eliminate such
lamps. For more information about
these and other baseline lamps, see
chapter 5 and appendix 5B of the TSD.
In its review of manufacturer
literature, DOE found that a range of
ballast factors are available for the 4-foot
T5 product classes, and the most
common ballast is a 2-lamp electronic
ballast. DOE attempts to compare lampand-ballast systems with similar light
output so that consumers switching to
more efficient systems will be able to
preserve lumen output. In order for the
halophosphor baseline T5 lamps to
produce light output similar to the
standards-case T5 lamps, they must be
paired with the highest ballast factor
ballasts available on the market today.
23 Id.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Therefore, in the NOPR, DOE is pairing
its baseline 4-foot T5 SO miniature
bipin lamp with a 1.15 ballast factor
ballast, and its baseline 4-foot T5
miniature bipin HO lamp with a 1.0
ballast factor ballast. For further detail
on the baseline lamps and ballasts
selected for the 4-foot T5 product
classes, see chapter 5 of the TSD.
DOE proposed in the March 2008
ANOPR that the most common ballast in
use for the 8-foot T12 recessed doublecontact, high-output product class is an
electronic rapid-start ballast. (March
2008 ANOPR TSD chapter 5). Several
stakeholders commented at the public
meeting that the majority of 8-foot T12
high-output ballasts installed today are
magnetic. (Public Meeting Transcript,
No. 21 at pp. 124–125; Public Meeting
Transcript, No. 21 at p. 126) NEMA and
the Joint Comment also commented that
magnetic T12 high-output ballasts are
allowed under current regulations and,
therefore, will continue to be sold past
2009. (Joint Comment, No. 23 at p. 7;
NEMA, No. 22 at p. 25) Because the
majority of the installed base is
magnetic, DOE is revising its baseline
T12 high-output ballast to be magnetic
for the life-cycle cost analysis. However,
DOE recognizes that historical
shipments from the 2000 rulemaking on
GSFL ballasts (hereafter ‘‘2000 Ballast
Rule’’) (62 FR 56740 (Sept. 19, 2000))
indicate that T12 electronic high-output
ballasts are also increasingly being
shipped.24 Therefore, in the national
impacts analysis, DOE modeled the
installed base on magnetic ballasts, and
forecasted shipments of T12 high-output
lamps operating on both electronic and
magnetic ballasts in the national
impacts analysis. For further detail
regarding the revised baseline lamps
and systems for the 8-foot RDC HO
product class, see chapter 5 of the TSD.
DOE reviewed the remaining baseline
lamp-and-ballast systems discussed in
the March 2008 ANOPR and believes
they are still appropriate, as DOE
received no comments concerning these
systems. Therefore, DOE maintained the
same number of lamps per system and
ballasts discussed in the March 2008
ANOPR for the 4-foot medium bipin and
8-foot single pin slimline product
classes analyzed in the commercial and
industrial sectors. 73 FR 13620, 13647
(March 13, 2008).
24 U.S. Department of Energy—Energy Efficiency
and Renewable Energy Office of Building Research
and Standards, Technical Support Document:
Energy Efficiency Standards for Consumer
Products: Fluorescent Lamp Ballast Proposed Rule
(Jan. 2000). Available at: https://
www1.eere.energy.gov/buildings/
appliance_standards/residential/
gs_fluorescent_0100_r.html.
PO 00000
Frm 00025
Fmt 4701
Sfmt 4702
16943
b. Incandescent Reflector Lamps
In the March 2008 ANOPR, DOE
proposed three baseline lamps for the
IRL representative product class. 73 FR
13620, 13648 (March 13, 2008). These
baseline lamps, all parabolic reflector
(PAR) halogen baseline lamps, are
regulated by EPCA and meet the EPCA
standard. (42 U.S.C. 6295(i)(1)) NEMA
commented that because BR lamps
remain on the market due to a Federal
exemption and because they are
commonly used in consumer
applications, the BR lamp should be the
baseline lamp instead of the halogen
PAR. (Public Meeting Transcript, No. 21
at p. 162; NEMA, No. 22 at pp. 10, 16,
and 18) NEMA also contends that
because DOE selected halogen PAR
lamps as the baseline, DOE is losing the
opportunity to show additional energy
savings. (NEMA, No. 22 at p. 16)
In response, although BR lamps are a
common incandescent reflector lamp on
the market today, DOE believes they
should not be selected as baseline lamps
in the engineering analysis of this
rulemaking for the reasons that follow.
The baseline lamp should be typical of
covered lamps within a certain product
class. The most common BR lamp is the
65W BR lamp, which remains on the
market due to Federal exemptions.
Because the 65W BR lamp is not
covered in this rulemaking, it cannot be
a baseline lamp. In addition, consumers
purchasing the 65W BR lamp would not
be affected by the amended standards
proposed in this NOPR. Therefore, DOE
would not be able to demonstrate
additional energy savings for those
consumers purchasing the 65W BR lamp
even if it were able to select that lamp
as a baseline lamp.
Although certain BR lamps are
covered in this rulemaking, DOE
predicts that the most typical lamp sold
on the market in 2012 will continue to
be the halogen PAR lamp. EISA 2007
required that all non-exempted BR
lamps meet EPCA standards by January
1, 2008. Because these lamps are similar
in efficacy and price to the halogen
PAR, the most common reflector lamps
meeting the EPCA standard in 2007,
DOE is continuing to choose halogen
PAR lamps as the baseline lamp for the
NOPR.
NEMA commented that current PAR
baseline lamps have higher efficacy than
the lamps sold in 1992 (when EPACT
1992 prescribed IRL standards), due to
optical improvements. (NEMA, No. 22
at p. 16) However, because DOE prefers
that the baseline lamp be typical of
lamps sold on the market today, DOE is
maintaining the same 90W PAR baseline
lamp and 75W PAR baseline lamp used
E:\FR\FM\13APP2.SGM
13APP2
16944
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
in the March 2008 ANOPR. 73 FR
13620, 13648 (March 13, 2008). DOE
now believes that the 50W PAR30
baseline lamp with a lifetime of 3,000
hours and an efficacy of 11.6 lm/W
presented in the March 2008 ANOPR is
not typical of lamps sold on the market
today. 73 FR 13620, 13648 (March 13,
2008). Therefore, for this notice, DOE is
choosing a 50W PAR30 lamp with an
efficacy of 14.2 lm/W and a lifetime of
3,000 hours. Based on an examination of
manufacturer product catalogs, DOE
believes that this lamp is a highervolume product than the baseline lamp
presented in the March 2008 ANOPR.
The lamp choice is consistent with
advice DOE received from GE to use
lamps from major manufacturers in the
IRL analysis for modified-spectrum
lamps. (Public Meeting Transcript, No.
21 at p. 170) For further detail on IRL
baseline lamps, see chapter 5 of the
TSD.
4. Lamp and Lamp-and-Ballast Designs
As described in the March 2008
ANOPR, in the engineering analysis,
DOE considered only ‘‘design
options’’—technology options used to
improve lamp efficacy that were not
eliminated in the screening analysis. 73
FR 13620, 13644 (March 13, 2008).
DOE’s selection of design options
guided its selection of lamp and lampand-ballast designs and efficacy levels.
For example, for GSFL, DOE noted
groupings around the types of phosphor
used and the wall thickness of those
phosphors. Regarding IRL, DOE
identified natural ‘‘technology-based’’
divisions in the market around the type
of incandescent technology (i.e.,
halogen or HIR) used. DOE also
identified certain technology options
and created model lamps to represent
the efficacy those technology options
could achieve.
As described in the March 2008
ANOPR, DOE also accounted for lumen
output when DOE established lamp
designs for its analyses. 73 FR 13620,
13648 (March 13, 2008). For the LCC
analysis, DOE considered those lamps
(or lamp-and-ballast systems) that: (1)
Emit lumens equal to the lumen output
of the baseline lamp or lamp-and-ballast
system, or below that lamp by no more
than 10 percent; and (2) result in energy
savings. DOE took this approach in
order to accurately characterize the costeffectiveness of a particular efficacy
level if a consumer makes an informed
decision that maintains light output.
However, as DOE recognizes that all
consumers may not make such
decisions, lamp or lamp-and-ballast
designs that under-illuminate, over-
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
illuminate, or do not result in energy
savings are considered in the NIA.
a. General Service Fluorescent Lamps
As described in the March 2008
ANOPR, DOE used a systems approach
for the fluorescent lamp analysis,
because DOE recognizes that both lamps
and ballasts determine a system’s energy
use and the overall system lumen
output. 73 FR 13620, 13649 (March 13,
2008). This approach allows DOE to
select a variety of lamp-and-ballast
designs that meet a given efficacy level.
Generally, DOE chose its potential
design options by selecting
commercially-available fluorescent
lamps at higher efficacies than the
baseline lamps. These higher efficacies
are achieved through the design options
described in the screening analysis.
After selecting these higher-efficacy
lamps, DOE selected lamp-and-ballast
combinations for the LCC that both save
energy and maintain comparable lumen
output. For instances when the
consumer is replacing only the lamp,
DOE selected a reduced-wattage, higherefficacy lamp for use on the existing
ballast. For instances when the
consumer is replacing both the lamp
and the ballast, DOE was able to obtain
energy savings and maintain
comparable lumen output using a
variety of lamp-and-ballast
combinations.
In the March 2008 ANOPR, DOE
stated that it was not able to identify
any application restrictions on using
reduced-wattage fluorescent lamps, so
therefore, DOE included reducedwattage lamps as design options in the
ANOPR. 73 FR 13620, 13650 (March 13,
2008). NEMA responded that most
manufacturers identify several
application issues for these lamps. For
example, NEMA stated that reducedwattage T8 lamps cannot be used with
certain rapid-start circuits, at
temperatures below 60 degrees
Fahrenheit (°F) (or 70 °F for the 25W
lamp), in drafty locations, in airhandling fixtures, on low-power-factor
ballasts, on dimming ballasts, or on an
inverter-operated emergency lighting
system, unless the equipment is
specifically listed for use with the
reduced-wattage lamp in question.
(NEMA, No. 22 at p. 10) NEMA also
stated that reduced-wattage T12 lamps
cannot be used at temperatures below
60 °F, in drafty locations, on low-powerfactor ballasts, on reduced-light-output
ballasts, on dimming ballasts, or on
inverter-operated emergency lighting
systems unless the equipment is
specifically listed for use with the
reduced-wattage lamp in question.
(NEMA, No. 22 at p. 11)
PO 00000
Frm 00026
Fmt 4701
Sfmt 4702
In response, DOE recognizes that
reduced-wattage lamps cannot be used
in certain applications and that
consumers should not be subject to any
decrease in utility and performance due
to an amended energy conservation
standard. However, because consumers
have the opportunity to purchase at
least one full-wattage T12 or T8 lamp at
each efficacy level, consumer utility
will not be reduced by amending the
existing energy conservation standard.
There are many applications where
reduced-wattage lamps are appropriate.
Therefore, DOE is modeling reducedwattage lamps in the engineering
analysis. In the NIA, DOE did not shift
all consumers to reduced-wattage lamps
in response to an energy conservation
standard, because reduced-wattage
lamps cannot be used in certain
applications. Specifically, the majority
of residential consumers have lowpower-factor ballasts not designed to
operate 34W T12 lamps. These
assumptions are displayed in the NIA
market-share matrices described in
chapter 10 of the TSD.
b. Incandescent Reflector Lamps
In the March 2008 ANOPR, DOE
selected lamp designs and candidate
standard levels (CSLs) by observing
natural efficacy divisions in the
marketplace that correspond to the use
of technologies (e.g., halogen capsules,
HIR technology, and improved reflector
coatings) to increase lamp efficacy. 73
FR 13620, 13650 (March 13, 2008).
CSL1, as set forth in the March 2008
ANOPR, could be met with a halogen
lamp using a silverized reflector coating.
CSL2 could be met with a 3,000-hour
halogen infrared (IR) lamp. CSL3 could
be met with an improved 4,000-hour
halogen infrared lamp. CSL3 could also
be achieved by using design options like
a silverized reflector coating with a
halogen infrared burner, or improved
filament placement and higher
efficiency inert fill gases in conjunction
with a halogen infrared burner.
At the public meeting and through
written comments, NEMA proposed
several changes to the lamp designs and
efficacy levels DOE identified for the
IRL engineering analysis. NEMA
suggested that DOE should analyze four
efficacy levels, beginning with one
slightly above EPCA and ending with
the max-tech candidate standard level
analyzed in the March 2008 ANOPR.
(NEMA, No. 22 at p. 17) However, the
efficacies of the baseline lamps chosen
in the engineering analysis are above the
lowest NEMA-proposed efficacy level.
Therefore, because NEMA’s lowest
proposed efficacy level would not raise
the efficacies of the most common
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
reflector lamps on the market today,
DOE did not consider it in this NOPR.
NEMA commented that DOE should
also consider in its NOPR an efficacy
level that can be met with non-standard
halogen or infrared halogen lamps.
(NEMA, No. 22 at p. 18) This standard
level would lie between the first efficacy
level proposed by NEMA and the first
candidate standard level (CSL1)
proposed by DOE in the March 2008
ANOPR. 73 FR 13620, 13651 (March 13,
2008). To model the technologies that
meet this efficacy level, DOE modeled
an improved halogen lamp that uses
xenon, a higher efficiency inert fill gas.
NEMA commented that DOE should
not analyze CSL1 presented in the
March 2008 ANOPR because that level
is based on the silverized reflector
coating, a patented technology.25
(NEMA, No. 22 at pp. 16–17; Public
Meeting Transcript, No. 21 at pp. 157–
158) Other stakeholders commented that
DOE should research when the patent
on the silver technology expires,
because the standard does not go into
effect until 2012. (Joint Comment, No.
23 at p. 15) The Joint Comment stated
that DOE should research viable
alternatives that can be used to reach
the first CSL if the silverized reflector
coating is indeed patented. (Joint
Comment, No. 23 at p. 15)
In response to these stakeholder
comments, DOE researched the
silverized reflector technology and
found that the patent for that technology
expires in December 2019.26 Therefore,
for the purpose of this rulemaking, DOE
considers the silverized reflector coating
a proprietary technology. As discussed
during the Framework stage of this
rulemaking, DOE only considers
proprietary designs in its engineering
analysis if there are other technology
pathways to meet that efficacy level.
DOE researched possible lamp designs
for the March 2008 ANOPR’s first CSL
and found that a halogen lamp with a
silverized reflector coating is the only
improved halogen technology that can
meet the March 2008 ANOPR CSL1.
However, a slightly lower level can be
achieved with an HIR lamp that has a
6,000-hour lifetime. Therefore, DOE is
considering a slightly lower level that
25 DOE
notes that it would clearly be
technologically feasible for manufacturers to adopt
a product design that surpasses the levels specified
in CSL1 (e.g., using technologies that meet CSL2)
and also avoids use of the proprietary technology
in question. However, if DOE were to adopt CSL1,
as presented in the March 2008 ANOPR, such
manufacturers would be at a competitive
disadvantage as compared to manufacturers who
are able to access the patented technology.
26 Zhao, Tianji et al., ‘‘Protected Coating for
Energy Efficient Lamp,’’ U.S. Patent 6,773,141
(August 10, 2004).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
can be met by both long-life HIR lamp
designs and silverized reflector coating
lamp designs in the NOPR. In its
analysis of this level, DOE considers
both lamp designs as viable consumer
options.
NEMA commented that DOE should
lower CSL2, because longer life lamps
would be in jeopardy of being
eliminated from the marketplace.
Because longer life products typically
have lower efficacies, manufacturers
may need to reduce lamp life to meet a
particular efficacy level. (Public Meeting
Transcript, No. 21 at pp. 177–178;
NEMA, No. 22 at p. 16; Joint Comment,
No. 23 at p. 15) Although increased
lifetime reduces a lamp’s efficacy, DOE
believes that lifetime is a consumer
economic issue rather than a utility
issue. In addition, the IRL at each
standard level can be manufactured
with lifetimes equal to or greater than
the lifetimes of the baseline lamp.
Therefore, consumers who are
purchasing the baseline lamp will
continue to be able to purchase a lamp
with a similar lifetime in the standards
case. Finally, DOE has conducted an
analysis to assess the impact of
standards on longer lifetime lamps.
Based on this analysis, documented in
appendix 5D of the TSD, DOE is
reasonably certain that even under the
highest efficacy level analyzed in this
NOPR, 6,000 hour lifetime lamps are
technologically feasible. For all of these
reasons, DOE maintained the lamp
designs and efficacy level for CSL2
described in the March 2008 ANOPR.
Similar to its comments related to
CSL1, NEMA commented that CSL3 is
problematic because it is also based on
the silverized reflector coating, a
patented technology. (NEMA, No. 22 at
p. 17; Public Meeting Transcript, No. 21
at pp. 157–158)
In its conversations with
manufacturers and review of
manufacturer catalogs, DOE found that
CSL3 is achievable using technologies
other than a silverized reflector coating.
For example, other non-patented types
of improved reflectors and higherefficiency IR coatings can be used to
reach this level. In fact, all major
manufacturers produce two or more
lamps that exceed this level, some of
which are not dependent on the
proprietary silverized reflector.
Therefore, because there are alternate
technology pathways to this level, DOE
maintained the March 2008 ANOPR
CSL3 as efficacy level 4 in the NOPR.
This efficacy level is consistent with
CSL4 proposed by NEMA in its
comment. (NEMA, No. 22 at p. 17)
Finally, DOE conducted additional
market research and discovered that IRL
PO 00000
Frm 00027
Fmt 4701
Sfmt 4702
16945
with efficacies significantly higher than
the ANOPR CSL3 (or NOPR EL4) are
being sold by one major manufacturer.
These IRL are marketed as halogen
infrared lamps with a silverized
reflector, improved IR coating, and a
lifetime of 4,200 hours. Therefore, in
order to meet the requirement to analyze
the highest technologically feasible
level, for the NOPR, DOE has added a
fifth efficacy level (EL5) based on these
high-efficacy lamps. Although, to DOE’s
knowledge, there are no commerciallyavailable IRL that do not use the
patented silverized reflector and are
equivalent in efficacy, DOE’s research
indicates that that are alternate, nonproprietary technology pathways to
meet this efficacy level. In particular,
DOE has extensively researched one
particular advanced IR coating
technology. Through interviews with
manufacturers of this technology and
through independent testing, DOE has
preliminarily concluded that by using
this advanced IR coating technology
with a standard aluminum reflector,
manufacturers can produce an IRL with
an efficacy that exceeds EL5. For further
detail on DOE’s research on this
technology, see appendix 5D of the TSD.
In summary, EL1 is based on an
improved halogen lamp that uses xenon,
a higher-efficiency inert fill gas. EL2 is
based on a halogen infrared lamp with
a lifetime of 6,000 hours; a halogen
lamp using a silverized reflector coating
could also meet this EL. EL3 is
associated with a 3,000-hour halogen
infrared lamp; this EL is more efficient
than EL2 due to higher temperature
operation of the filament. EL4 is based
on a 4,000-hour improved halogen
infrared lamp; improvements in the
halogen infrared lamp could be made by
using a double-ended halogen infrared
burner, higher-efficiency inert fill gases,
and efficient filament orientation. EL5 is
based on a 4,200-hour halogen infrared
lamps (even further improved); these
further improvements include an
improved reflector, IR coating, or
filament design that produces highertemperature operation (and may reduce
lifetime to 3,000 hours).
5. Efficiency Levels
a. General Service Fluorescent Lamps
i. Revisions to ANOPR Efficiency Levels
For the March 2008 ANOPR, DOE
developed CSLs for GSFL by dividing
initial lumen output by the ANSI rated
wattages of commercially-available
lamps, resulting in rated lamp efficacies.
In response to the potential GSFL
efficacy levels presented in the March
2008 ANOPR, NEMA commented on
several reasons why the association
E:\FR\FM\13APP2.SGM
13APP2
16946
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
believes that the efficacy levels need to
be revised. NEMA’s comments regarding
the efficacy levels considered in the
March 2008 ANOPR can be divided into
five categories: (1) The appropriateness
of using ANSI rated wattages in the
calculation of lumens per watt; (2)
consideration of variability in
production of GSFL; (3) manufacturing
process limitations related to specialty
products; (4) consideration of
adjustments to photometry calibrations;
and (5) the appropriateness of
establishing efficacy levels to the
nearest tenth of a lumen per watt.
(NEMA, No. 22 at p. 13–14) In
consideration of the above issues,
NEMA suggested revised efficacy levels
that could achieve the same results as
the efficacy levels considered in the
March 2008 ANOPR.
First, in support of lowering the
March 2008 ANOPR efficacy levels,
NEMA argued that ANSI rated wattages
of GSFL are not necessarily
representative of long-term reference
watts. NEMA further stated that in many
cases the actual lamp reference watts are
greater than the ANSI designated value.
(NEMA, No. 22 at p. 14) Second, NEMA
commented on production variability
and its impact on the resulting
measured lamp efficacies. NEMA stated
that DOE should not use nominal
catalog initial lumen values when
developing efficacy levels, as they do
not reflect statistical lot-to-lot
production variation. It also argued that
as lamp lumens per watt is not a
controlled process element in
production or a product rating, larger
tolerances may be required. NEMA
further stated that lumens per watt is
actually a calculation based on two
primary process control elements: (1)
Watts and (2) lumens. When practical
production variation in lamp wattage
(above ANSI-designated values) and
lamp lumens (below catalog initial
lumens) combine, the resulting variation
in lumens per watt may be larger than
expected. NEMA stated that DOE’s
proposed efficacy levels should be
lowered to account for these tolerances.
(NEMA, No. 22 at p. 14)
In consultation with the National
Institute of Standards and Technology
(NIST), DOE has investigated this issue
thoroughly, and DOE agrees with NEMA
on several points. By analyzing
manufacturer compliance reports
(submitted to DOE for existing GSFL
energy conservation standards), DOE
found that efficacies of lamps when
reported for the purpose of compliance
often vary from catalog-rated values.
Specifically, DOE agrees that ANSI
designated rated wattages may not be
appropriate in calculating efficacy. In
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
fact, the test procedures for GSFL
incorporate a tolerance factor comparing
measured lamp wattage to ANSI-rated
wattage. DOE acknowledges that this
tolerance factor could in fact
significantly alter the measured efficacy
of the lamps from the rated efficacy. In
addition, DOE agrees that using rated
lamp efficacy does not sufficiently
account for lot-to-lot production
variability. For this reason, to establish
revised GSFL efficacy levels, DOE
proposes to use lamp efficacy values
submitted to DOE over the past 10 years
for the purpose of compliance with
existing energy conservation standards.
Using compliance reports as a basis for
efficacy standards should ensure that
DOE is accurately characterizing the
tested performance of GSFL, accounting
for the measured wattage effects and
wattage and lumen output variability as
discussed above.
Further remarking on the effects of
production variability, NEMA argued
that it is inappropriate to use a small
number of test samples to calculate a
lumen-per-watt efficacy level. NEMA
stated that its suggested levels
incorporate a safety factor to take into
account manufacturer process
variations. (NEMA, No. 22 at p. 14)
While DOE appreciates NEMA’s input,
it disagrees that the sample size is
inappropriate. At NEMA’s suggestion, a
sample size of 21 lamps was originally
established for reporting requirements
in the 1997 test procedure rulemaking.
62 FR 29222, 29229 (May 29, 1997). The
reported efficacy values are obtained by
testing at least three lamps
manufactured each month for at least 7
months out of a 12-month period. Upon
receiving NEMA’s comment, DOE
consulted with NIST and has tentatively
concluded that the minimum of 21
samples is sufficiently large sample size,
assuming a normal distribution. In
addition, by using the compliance
report efficacies, DOE believes that it is
accounting for statistical variations due
to differences in production. The
efficacy reported for compliance is
related to the lower limit of the 95percent confidence interval. This
interval represents variation over the
whole population of production, not
only the sample size. 62 FR 29222,
29230 (May 29, 1997).
Third, NEMA commented that the
proposed efficacy levels should be
lowered to account for realistic
production and manufacturing process
limitations. NEMA argued that it may
not be possible to apply the highest
efficacy levels to some specialty
products because they do not use highspeed production methods. (NEMA, No.
22 at p. 14) DOE is unaware of specialty
PO 00000
Frm 00028
Fmt 4701
Sfmt 4702
products that meet the definition of
GSFL and would be unable to meet the
proposed standards. Therefore, DOE
cannot appropriately quantify the
reduction in efficacy level necessary if
such situation in fact exists. DOE
requests further comment and detail on
this topic.
Fourth, NEMA claims that because
the National Voluntary Laboratory
Accreditation Program (NVLAP) has
made adjustments to photometry
calibrations since 1997, the lumens for
some products have actually been
reduced. These adjustments would
thereby merit a reduction in DOE’s
GSFL efficacy levels. (NEMA, No. 22 at
p. 14) In response, DOE consulted with
NIST, which is unaware of any such
adjustments in photometry calibrations
since 1997. The lumen scale has not
changed more than 0.2 percent as a
result of changes to calibration systems.
Furthermore, the formula used in the
compliance reports contains a 2-percent
de-rate factor to allow for testing
variations. Therefore, DOE disagrees
with NEMA’s assertion that the efficacy
levels should be further lowered to
account for these adjustments.
Finally, NEMA maintained that if
DOE uses lumens per watt as the
efficacy level measurement, then the
numbers should be rounded to the
nearest whole number, rather than
carried out to the tenths decimal place.
In the March 2008 ANOPR, DOE
considered efficacy levels that were
specified to the nearest tenths lumen
per watt. NEMA asserts that lamp
testing and production variation does
not allow for establishing minimum
lumens per watt levels to the tenth
place. (NEMA, No. 22 at p. 12) While
DOE appreciates NEMA’s comment,
after consulting with NIST, DOE
disagrees that lamp production variation
would prohibit the regulation of GSFL
to the nearest tenth decimal place of
lumens per watt. If DOE were able to set
minimum efficacy requirements to the
nearest tenth of a decimal place, the
higher-accuracy measurements and
compliance could result in increased
energy savings. However, in
consideration of DOE’s approach to
establish efficacy levels and conduct
subsequent analyses based on
certification and compliance reports
submitted by manufacturers, DOE now
believes that maintaining the current
rounding procedure (i.e., to the nearest
whole lumen per watt) is more
appropriate. Because manufacturer
compliance reports round numbers to
the nearest lumen per watt, DOE
believes that the data would not support
establishment of an energy conservation
standard for GSFL to the nearest tenth
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
of a lumen per watt. Therefore, in this
NOPR, DOE is proposing to establish
efficacy levels as whole lumen per watt
numbers.
DOE presents revised GSFL efficacy
levels in section VI.A.1 of this NOPR.
ii. Four-Foot T5 Miniature Bipin
Efficiency Levels
Because DOE proposes to cover 4-foot
T5 miniature bipin lamps and 4-foot T5
miniature bipin HO lamps, DOE
developed efficacy levels for these two
product classes. In its review of
manufacturer literature, DOE identified
the most common 4-foot T5 miniature
bipin standard output lamps on the
market (which based on product
catalogs, DOE believes accounts for the
majority of the 4-foot T5 SO market).
The first efficacy level for this product
class is based on these lamps, which use
800-series phosphors and have a rated
catalog efficacy (initial lamp lumens
divided by ANSI rated wattage) of 104
lm/W. In its research, DOE also noted
higher efficacy 4-foot T5 miniature
bipin standard output lamps that use
improved 800-series phosphors.
Specifically, there is a reduced-wattage
(26W) 4-foot T5 miniature bipin lamp
(with a rated efficacy of 112 lm/w) and
a full-wattage (28W) lamp (with a rated
efficacy of 110 lm/w). EL2, the second
efficacy level for this product class, is
based on these higher-efficacy lamps.
Therefore, DOE analyzed two efficacy
levels for this product class. The first
efficacy level prevents the introduction
of less-efficacious halophosphor lamps
on the market, while the second efficacy
level raises the efficacy of the current
highest volume 4-foot T5 miniature
bipin lamps on the market. In order to
account for manufacturer variation, DOE
used the average reductions in efficacy
values due to manufacturer variation
calculated for the highest efficacy 4-foot
T8 medium bipin lamps, and applied
those same reductions to the 4-foot
miniature bipin rated efficacy values.
For the 4-foot T5 miniature bipin HO
product class, DOE found that higherefficacy full-wattage lamps do not exist
on the market today. DOE did identify
a higher-efficacy reduced-wattage lamp
for this product class. However, because
reduced-wattage lamps have a limited
utility, DOE is choosing to base its
efficacy levels on full-wattage lamps. In
this way, consumers are not forced to
purchase a lamp with limited utility
under energy conservation standards.
Therefore, for this product class, DOE is
analyzing one efficacy level, which
prevents the introduction of lessefficacious halophosphor lamps on the
market. For more information on GSFL
efficacy levels, see chapter 5 of the TSD.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
b. Incandescent Reflector Lamps
As wattage increases for incandescent
lamps, efficacy generally increases.
Therefore, so that the efficacy levels
reflected the performance of these
lamps, DOE proposed in the ANOPR
that the efficacy requirement for IRL
vary according to the following
equation: a*P0.27, where ‘‘a’’ is a
constant specifying the technology level
and ‘‘P’’ is the wattage of the lamp. 73
FR 13620, 13645 (March 13, 2008). At
the public meeting, NEMA commented
that the smooth form of the candidate
standard levels for IRL was appropriate.
(Public Meeting Transcript, No. 21 at
pp. 100–101, 156) Several other
stakeholders also commented that they
support the continuous function for IRL.
These stakeholders noted that
continuous functions more closely
follow theoretical equations predicting
the level of efficacy possible for any
given desired level of light output and
thus maximize energy savings. (Joint
Comment, No. 23 at p. 15) DOE agrees
with these comments and is proposing
to maintain the continuous function for
IRL in the same equation form proposed
in the ANOPR.
As described in section V.C.4.b, DOE
is proposing five efficacy levels in this
NOPR. EL1 is based on an improved
halogen lamp that uses xenon, a higherefficiency inert fill gas. EL2 is based on
a halogen infrared lamp with a lifetime
of 6,000 hours. A halogen lamp using a
silverized reflector coating also meets
this EL. EL3 is based on the 3,000-hour
HIR lamp. EL4 is based on a 4,000-hour
improved HIR lamp. EL5 is based on a
4,200-hour improved HIR lamp.
6. Engineering Analysis Results
a. General Service Fluorescent Lamps
In chapter 5 of the March 2008
ANOPR TSD, DOE presented lifetime,
rated wattage, and rated efficacy results
for all lamp-and-ballast designs. NEMA
commented that the lifetime rating for
the reduced-wattage 30W T8 lamp
should be 20,000 hours instead of
18,000 hours. (NEMA, No. 22 at p. 18)
DOE reviewed catalog data and agrees
that 20,000 hours is the appropriate
lifetime for the 30W T8 lamp. DOE also
reviewed catalog data for other reducedwattage lamps. DOE found several 25W
T8 lamps that were introduced on the
market after it completed the ANOPR
GSFL engineering analysis. Therefore,
DOE updated the 25W T8 reducedwattage lamp to have a slightly higher
lumen output and longer lifetime to
reflect the more common 25W T8 lamps
sold on the market today.
Through interviews with lamp
manufacturers, DOE found that several
PO 00000
Frm 00029
Fmt 4701
Sfmt 4702
16947
of the rated wattages DOE used in its
ANOPR for the 4-foot medium bipin
product class were not accurate. For the
NOPR, DOE updated the rated wattage
of the nominally 40W T12 from 40 to 41
watts. DOE also updated the rated
wattage of the 30W T8, 28W T8, and
25W T8 lamp from 30 to 30.4 watts, 28
to 28.4 watts, and 25 to 26.6 watts,
respectively. Due to these updates (and
because the rated wattage affects the
rated lamp efficacy), two 40W T12
lamps and the 25W T8 lamp have lower
efficiencies than as they were analyzed
in the March 2008 ANOPR. For further
detail associated with these revisions,
see chapter 5 of the TSD.
In addition to updating lamp efficacy,
DOE revised the 8-foot T12 high output
engineering analysis to reflect the
purchase of a magnetic ballast in both
the base case and standards case. As
discussed in section V.C.4.a of this
notice, DOE recognizes that a typical 8foot T12 high output system uses a
magnetic ballast. In addition, as the
2000 ballast rule does not require that
these systems be electronic, consumers
will be able to purchase a magnetic 8foot T12 high output system in the
future.
DOE also created a separate
residential engineering analysis. In this
engineering analysis, DOE assumes that
the most typical installed fluorescent
system in a residential household is a
40W T12 magnetic system. However,
DOE recognizes that T8 systems are
gaining in market share in the
residential market. Therefore, DOE
assumes that the majority of fluorescent
systems installed for new construction
and renovation in the residential sector
are T8 systems. DOE discusses this
assumption further in section V.D and
V.E, as it primarily affects the LCC and
NIA.
In the March 2008 ANOPR, DOE
considered using two low ballast factor
(BF) ballasts for 4-foot T8s, a 0.75 BF
and a 0.78 BF. ACEEE stated that
manufacturers are now selling ballasts
for 4-foot T8 lamps with a ballast factor
between 0.68–0.7 and that DOE should
consider this ballast in the engineering
analysis. (Public Meeting Transcript,
No. 21 at p. 262) After reviewing catalog
data for fluorescent lamp ballasts, DOE
decided to add a ballast with a 0.71 BF
in its engineering analysis as a system
option that attains energy savings while
maintaining light output. By including
this low-BF ballast, DOE is able to more
thoroughly characterize all consumer
purchase options in the LCC and NIA.
b. Incandescent Reflector Lamps
In the March 2008 ANOPR, DOE also
presented engineering analysis results
E:\FR\FM\13APP2.SGM
13APP2
16948
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
for IRL. NEMA generally agreed with
the efficacy values in the table. (NEMA,
No. 22 at p. 18) Thus, DOE is
maintaining this approach with one
exception. Specifically, DOE is revising
the efficacy values it used for the 50W
PAR30 baseline lamps and is creating
several additional model lamps for the
efficacy levels not analyzed in the
March 2008 ANOPR. Because the
revised baseline model exhibits a
slightly different lumen package than
the baseline model analyzed in the
March 2008 ANOPR, DOE has created
several additional model lamps in order
to match the lumen package of the
baseline lamp. For more information on
the revised baseline model, see section
V.C.3.b. For more information about
lamp designs used in the IRL
engineering analysis, see chapter 5 of
the TSD.
7. Scaling to Product Classes Not
Analyzed
As discussed above, DOE identified
and selected certain product classes as
‘‘representative’’ product classes where
DOE would concentrate its analytical
effort. DOE chose these representative
product classes primarily because of
their high market volumes. The
following section discusses how DOE
scaled efficacy standards from those
product classes it analyzed to those it
did not.
a. General Service Fluorescent Lamps
In the engineering analysis for GSFL,
DOE decided not to analyze the 2-foot
U-shaped product class and the product
classes with a CCT greater than 4,500K,
due to the small market share of these
classes. Instead, DOE is scaling the
efficacy standards for the product
classes analyzed to these product
classes. The following sections discuss
DOE’s approaches to scaling to product
classes not directly analyzed.
i. Correlated Color Temperature
Regarding the CCT product class
division, DOE found in the March 2008
ANOPR that the reduction in efficacy
between 4,100K and 6,500K lamps was
between 4 percent and 7 percent. To
avoid subjecting certain products to
inappropriately high standards, DOE
considered a single 7-percent reduction
(from the efficacy levels for lamps with
CCT less than or equal to 4,500K (low
CCT)) for product classes greater than
4,500K (high CCT). 73 FR 13620, 13653
(March 13, 2008).
NEMA disagreed with DOE’s use of a
single 7-percent reduction for all GSFL
lamps with a CCT greater than 4,500K.
(NEMA, No. 22 at p. 18) NEMA
submitted a written comment
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
recommending an individualized
reduction for each efficacy level and
each product class for products with a
CCT between 4,500K and 7,000K.
NEMA’s reductions ranged from 2.6
percent to 7.2 percent, depending on the
efficacy level and product class.
(NEMA, No. 26 at pp. 4, 6–7)
The Joint Comment also disagreed
with the 7-percent reduction DOE
employed. Looking at catalog data for
the greater-than-4,500K product classes,
the Joint Comment noted that the
reduction in efficacy when moving from
low-CCT to high-CCT lamps or from 4foot MBP to 2-foot U-shaped lamps
varies by efficacy level. For example, at
CSL1 in the 4-foot medium bipin
product class, the Joint Comment found
that no reduction in the efficacy
standard was necessary because highCCT and 2-foot U-shaped T8 lamps are
able to meet that level. At CSL3, the
Joint Comment found a 5-percent
reduction was appropriate; at CSL4 and
CSL5, the Joint Comment found a 3percent reduction was appropriate.
Based on this data, the Joint Comment
stated that the commenters would
accept a 5-percent reduction for both the
2-foot U-shaped and greater-than-4,500K
product classes. (Joint Comment, No. 23
at pp. 9–10)
Through an examination of the
comments and a further inspection of
manufacturer catalog data, DOE now
recognizes that a single efficacy
reduction of 7 percent for each efficacy
level and each product class is not
always appropriate when trying to
establish efficacy levels for lamps with
greater than 4,500K CCT. Therefore, for
this NOPR, DOE proposes to establish a
separate scaling factor for each EL and
product class. DOE’s intention in
developing scaling factors for this NOPR
was to establish high-CCT efficacy
levels that mimic the same
technological effects as the low-CCT
efficacy levels. For example, if EL3 for
the low-CCT 4-foot MBP product class
eliminates all but the highest-efficacy,
low-CCT T12 lamps, DOE established a
high-CCT EL3 that attempted to
eliminate all but the highest-efficacy,
high-CCT, T12 lamps as well. Because
the NEMA technical committee
analyzed all efficacy levels for all
product classes with a similar intention
and because DOE found that this range
is consistent with the range of
reductions found in manufacturer
literature, DOE proposes to adopt the
percentage reduction for each EL
suggested by NEMA. In order to
establish efficacy levels for high CCT
lamps, DOE then applied these
percentage reductions to the efficacy
levels (discussed in sectionV.C.5.a) for
PO 00000
Frm 00030
Fmt 4701
Sfmt 4702
the representative product classes. For
more information on the efficacy levels
for product classes with a CCT greater
than 4,500K, see chapter 5 of the TSD.
ii. U-Shaped Lamps
Regarding the 2-foot U-shaped
product classes, in March 2008 ANOPR,
DOE found that when comparing catalog
efficacies of 2-foot U-shaped lamps to 4foot MBP lamps, efficacy scaling factors
varied depending on whether one was
comparing T12 lamps or T8 lamps.
Specifically, DOE had initially
determined that a 3-percent reduction
was appropriate for T8 lamps, and a 6percent reduction was appropriate for
T12 lamps. To avoid subjecting certain
products to inappropriately high
standards, DOE stated that it was
considering to apply a single 6-percent
reduction from the five 4-foot medium
bipin efficacy levels to obtain five 2-foot
U-shaped efficacy levels. 73 FR 13620,
13653 (March 13, 2008).
In response to the ANOPR, NEMA
commented that only three ELs for the
2-foot U-shaped product class were
appropriate. These ELs recommended
by NEMA were based on the same
technology options for the 4-foot
medium bipin product class: (1)
NEMA’s EL1 would remove all
halophosphor T12 lamps; (2) NEMA’s
EL2 would remove all 700-series T12 Ulamps; and (3) NEMA’s EL3 would
remove all T12 U-lamps. (NEMA, No. 22
at p. 15) Each EL recommended by
NEMA represented an approximately 9percent to 10-percent reduction from
ELs in the 4-foot medium bipin product
class. As discussed above, the Joint
Comment recommended that DOE use a
single 5-percent reduction when scaling
from the 4-foot medium bipin product
class to the 2-foot U-shaped product
class. However, the Joint Comment also
found that the reduction varied by CSL.
(Joint Comment, No. 23 at pp. 9–10)
Similar to its analysis regarding
scaling to high-CCT product classes,
DOE recognizes that a single reduction
in efficacy may not be appropriate for
all efficacy levels for the U-shaped
product classes. Therefore, similar to
NEMA’s suggestion, DOE is proposing a
separate reduction for each efficacy
level based on similar technology steps
seen for the 4-foot medium bipin
product class. However, after examining
commercially-available product DOE
believes that five, not three, efficacy
levels are appropriate for the 2-foot Ushaped product class. DOE assessed
manufacturer catalogs containing
commercially-available U-shaped lamps
to develop standard levels with a
similar technology impact at each EL as
4-foot linear medium bipin lamps. DOE
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
supplemented this analysis with
compliance report data for U-shaped
lamps to verify that the established
efficacy levels coincide with the
technological goals and actual
performance of products on the market.
For specific scaling factors for the
proposed 2-foot U-shaped efficacy levels
and a more detailed discussion of DOE’s
methodology, see chapter 5 of the TSD.
b. Incandescent Reflector Lamps
i. Modified-Spectrum IRL
At the ANOPR public meeting, DOE
stated that the average reduction in
efficacy of modified-spectrum lamps (as
compared to standard spectrum lamps)
was between 2 percent and 25 percent,
with an average reduction of 15 percent.
DOE acknowledged the range of
spectrum modification and its effects on
utility, and aimed to establish a
standard that would not eliminate
modified-spectrum lamps. Therefore, in
the March 2008 ANOPR, DOE
considered a minimum efficacy
requirement for each modified-spectrum
lamp that would be dependent on the
testing of a equivalent standardspectrum lamp. More specifically, the
efficacy requirement for the modifiedspectrum lamp would be determined on
a per-lamp basis by measuring the
lumen output of both the modifiedspectrum lamp and the equivalent
standard-spectrum reference lamp;
manufacturers would then multiply the
ratio of lumen outputs (i.e., the lumen
output of the modified-spectrum lamp
divided by the lumen output of the
standard-spectrum reference lamp) by
the efficacy requirement for the
standard-spectrum reference lamp to
obtain the efficacy requirement for that
modified-spectrum lamp. 73 FR
13620,13653 (March 13, 2008).
GE commented that this approach
may be reasonable as long as DOE gave
this reduction to true modifiedspectrum lamps, rather than lamps
marketed as having modified spectrums,
but which in fact do not meet the
requirements of that term. (Public
Meeting Transcript, No. 21 at p. 168)
NEMA commented that DOE’s proposal
for establishing an efficacy standard for
modified-spectrum IRL is complicated,
difficult to enforce, and non-verifiable.
(NEMA, No. 22 at p. 19) In addition,
NEMA expressed concern that the
responsibility of establishing the
efficacy for the equivalent standardspectrum lamp would fall on the
manufacturer. (Public Meeting
Transcript, No. 21 at pp. 100–101) Also,
the Joint Comment disagreed with an
approach that would allow modifiedspectrum technologies a variable
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
reduction in efficacy (depending on
their degree of spectrum modification
and the method with which it is
reached). (Joint Comment, No. 23 at p.
16) In response to those comments, DOE
recognizes the drawbacks to the
approach considered in the ANOPR and
instead in the NOPR is proposing a
single efficacy requirement (irrespective
of the degree or method of spectrum
modification) for each modifiedspectrum IRL product class.
GE and NEMA suggested that the 25percent reduction for A-line modifiedspectrum lamps enacted by EISA 2007
standards for general service
incandescent lamps (GSIL) and
modified-spectrum GSIL may be
appropriate for modified-spectrum IRL.
(Public Meeting Transcript, No. 21 at
pp. 169–170; NEMA, No. 22 at p. 19)
The Joint Comment expressed an
opposing viewpoint, arguing that the 25percent reduction specified in EISA
2007 was based on a political
compromise, not technical research. The
Joint Comment also mentions that Ecos
Consulting, on behalf of PG&E, tested a
variety of modified-spectrum general
service incandescent lamps. Their
researchers estimated a total light
output reduction of 11 to 18 percent due
to the modified spectrum. (Joint
Comment, No. 23 at p. 16)
DOE agrees with the Joint Comment
that the reduction in efficacy for general
service incandescent lamps used in
EISA 2007 may not be appropriate for
IRL. Instead, DOE based its reduction
for the modified-spectrum product
classes on independent testing and
research of commercially-available
modified-spectrum and standardspectrum IRL.
Several stakeholders commented that
the range of lumen reduction (2 percent
to 29 percent) found among
commercially-available modifiedspectrum IRL may be attributable to
lamps that do not meet the statutory
definition of ‘‘modified spectrum,’’
which would make the stated average
too high. (NEMA, No. 22 at p. 19; Public
Meeting Transcript, No. 21 at pp. 164–
167) These stakeholders suggested that
DOE should only use lamps that meet
the definition of ‘‘modified spectrum’’
when determining an appropriate
scaling factor. (Public Meeting
Transcript, No. 21 at p. 167–168) GE
suggested that lamps sold by major
manufacturers will meet the statutory
definition of ‘‘modified spectrum’’
because NEMA manufacturers offered
input into the legislative process that
created this definition. (Public Meeting
Transcript, No. 21 at p. 171)
In addition, the Joint Comment noted
that when determining the modified-
PO 00000
Frm 00031
Fmt 4701
Sfmt 4702
16949
spectrum scaling factor, DOE should
base its analysis on HIR IRL sources
rather than conventional incandescent
or conventional halogen IRL. The Joint
Comment further stated that the spectral
distribution of the HIR sources have
reduced output in the red region of the
spectrum compared to conventional
incandescent lamp. The comment
argued because this red region is the
portion of the spectrum modifiedspectrum lamps are often trying to
suppress, a lower and more accurate
scaling factor could be calculated by
considering only HIR lamps. (Joint
Comment, No. 23 at p. 16)
DOE agrees with stakeholders
regarding the need to determine
appropriate scaling factors and tested
several modified-spectrum lamps from
major manufacturers to determine
whether they qualify as modified
spectrum under the statutory definition.
DOE only used the IRL that qualify as
modified spectrum under the statutory
definition to determine an appropriate
scaling factor. In addition, DOE
acknowledges that the spectral power
distributions of incandescent (nonhalogen), halogen, and HIR IRL are
different over the electromagnetic
spectrum. However, DOE does not
believe that the reduced light output in
the red region of the spectrum of HIR
sources significantly affects the
resulting scaling factor. This high
wavelength red region of the spectrum
is not weighted heavily when
calculating the lumens emitted by the
lamp. Therefore, any spectral
differences in the infrared regions
between the halogen IRL compared to
the halogen infrared IRL would produce
only minor differences in the reduction
in efficacy for modified-spectrum
lamps. Therefore, DOE tested both HIR
and conventional halogen lamps in
determining an appropriate scaling
factor for modified spectrum.
However, as non-halogen (or
conventional incandescent) IRL have
significantly different radiation spectra
over wavelengths contributing to the
calculation of lumens (in general their
light outputs are shifted toward lower
wavelengths), it is likely that the
resulting scaling factor based on these
lamps would be significantly different
than for halogen sources. Because nonhalogen IRL (representing the IRL lamp
types exempted from standards) are not
regulated in this rulemaking, DOE
believes that it would be inappropriate
to include such lamps in its scaling
factor analysis. Therefore, DOE
considered only halogen and HIR IRL
for the computation of the modifiedspectrum IRL scaling factor.
E:\FR\FM\13APP2.SGM
13APP2
16950
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
To determine the scaling factor, DOE
tested seven pairs (each pair consisting
of one standard-spectrum lamp and one
lamp marketed as modified-spectrum or
a similar designation) of halogen IRL
and one pair of HIR IRL made by major
manufacturers. Though many of the
lamps did not qualify as modifiedspectrum under the statutory definition,
for those that did qualify, DOE
determined that the difference in light
output and efficacy due to the modifiedspectrum coating was 19 percent for
both the halogen and IR halogen lamps.
Therefore, DOE proposes to use a 19
percent reduction as the scaling factor
for modified-spectrum IRL. For further
details on scaling to modified-spectrum
lamps, see chapter 5 and appendix 5C
of the TSD.
ii. Lamp Diameter
As discussed in section V.A.2.c, in
this NOPR, DOE has established
separate product classes for IRL with a
diameter of 2.5 inches or less based on
their decreased efficacy associated with
the unique utility that they provide (e.g.,
ability of reduced diameter lamps to be
installed in smaller fixtures). NEMA
commented that a percentage reduction
should be applied to the PAR30/PAR38
CSL so as not to eliminate PAR20 lamps
(with diameters of 2.5 inches) at the
highest CSLs set forth in the ANOPR.
(Public Meeting Transcript, No. 21 at
pp. 158–159) NEMA explained that the
PAR20 lamp optical system is
inherently less efficient than the PAR30
and PAR38 optical systems. In addition,
it is difficult to implement the most
efficient double-ended HIR burner in
the PAR20 lamps. Therefore, NEMA
suggests a reduction in the lumen per
watt standards by 12 percent. (NEMA,
No. 22 at pp. 17–18) In the Joint
Comment, stakeholders stated that they
were not opposed to a reduction in the
efficacy standard as long as data
supports manufacturer claims. (Joint
Comment, No. 23 at p. 15–16)
DOE understands that PAR20 lamps
are inherently less efficient than PAR30
and PAR38 lamps. To determine an
appropriate scaling factor, DOE
examined the inherent efficacy
differences between the PAR20 lamp
and its PAR30 or PAR38 counterpart by
comparing catalog efficacy data of each
lamp type from several lamp
manufacturers. In general, DOE’s
analysis is consistent with NEMA’s
suggestion. Therefore, DOE proposes
applying a 12-percent reduction from
the efficacy requirement of the PAR30/
PAR38 product class to determine the
efficacy requirement for the PAR20
product class. For further details
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
regarding the scaling to smaller lamp
diameters, see chapter 5 of the TSD.
iii. Voltage
DOE also conducted an analysis to
determine how to scale from the less
than 125 volt product class to the
greater or equal to 125 volt product
class. NEMA commented that lamps
rated at 130V are almost always used by
customers to achieve ‘‘double life’’ by
operating them at 120V, which results
in performance below EPACT 1992
efficacy levels. (NEMA, No. 22 at p. 16)
In consideration of the different test
procedures for IRL rated at 130V than
those rated at 120V, and by using
equations from the IESNA Lighting
Handbook,27 DOE derived an efficacy
scaling factor which would result in
equivalent performance of both classes
of IRL when operating under the same
voltage conditions (as NEMA suggests
they most often are). DOE determined
that a higher standard for lamps equal
to or greater than 125V would result in
similar technological requirements and
operational efficacies for lamps rated at
all voltages. Using published
manufacturer literature and the IESNA
Lighting Handbook, DOE determined
that there should be a 15-percent
increase in the efficacy standard for
lamps rated at 125V or greater. See
chapter 5 of the TSD for details of the
results and methodology used in the
scaling analysis and other aspects of the
engineering analysis.
D. Life-Cycle Cost and Payback Period
Analyses
This section describes the LCC and
payback period analyses and the
spreadsheet model DOE used for
analyzing the economic impacts of
possible standards on individual
consumers. Details of the spreadsheet
model, and of all the inputs to the LCC
and PBP analyses, are contained in
chapter 8 and appendix 8A of the TSD.
DOE conducted the LCC and PBP
analyses using a spreadsheet model
developed in Microsoft Excel. When
combined with Crystal Ball (a
commercially-available software
program), the LCC and PBP model
generates a Monte Carlo simulation 28 to
perform the analysis by incorporating
uncertainty and variability
considerations.
The LCC analysis estimates the
impact of a standard on consumers by
27 Rea, M. S., ed., The IESNA Lighting Handbook:
Reference and Application, 9th Edition. New York:
Illuminating Engineering Society of North America.
IESNA (2000).
28 Monte Carlo simulations model uncertainty by
utilizing probability distributions instead of single
values for certain inputs and variables.
PO 00000
Frm 00032
Fmt 4701
Sfmt 4702
calculating the net cost of a lamp (or
lamp-and-ballast system) under a basecase scenario (in which no new energy
conservation standard is in effect) and
under a standards-case scenario (in
which the proposed energy conservation
regulation is applied). As detailed in the
March 2008 ANOPR, the life-cycle cost
of a particular lamp design is composed
of the total installed cost (which
includes manufacturer selling price,
sales taxes, distribution chain mark-ups,
and any installation cost), operating
expenses (energy, repair, and
maintenance costs), product lifetime,
and discount rate. 73 FR 13620, 13659
(March 13, 2008). As noted in the March
2008 ANOPR, DOE also incorporated a
residual value calculation to account for
any remaining lifetime of lamps (or
ballasts) at the end of the analysis
period. 73 FR 13620, 13659 (March 13,
2008). The residual value is an estimate
of the product’s value to the consumer
at the end of the life-cycle cost analysis
period. In addition, this residual value
must recognize that a lamp system
continues to function beyond the end of
the analysis period. DOE calculates the
residual value by linearly prorating the
product’s initial cost consistent with the
methodology described in the Life-Cycle
Costing Manual for the Federal Energy
Management Program.29
The payback period is the change in
purchase expense due to an increased
energy conservation standard, divided
by the change in annual operating cost
that results from the standard. Stated
more simply, the payback period is the
time period it takes to recoup the
increased purchase cost (including
installation) of a more-efficient product
through energy savings. DOE expresses
this period in years.
The Joint Comment stated that given
the inherent uncertainty in the LCC
methodology, DOE should recognize
that LCC results within a certain range
can be considered essentially
equivalent. The Joint Comment
emphasized that recognizing this
uncertainty is especially important if
other aspects of the analysis (e.g., energy
savings) show large differences for
standard levels with LCC results that,
given uncertainty in the analysis, are
essentially the same. (Joint Comment,
No. 23 at p. 22) DOE agrees that there
are inherent sources of uncertainty in
29 Fuller, Sieglinde K. and Stephen R. Peterson,
National Institute of Standards and Technology
Handbook 135 (1996 Edition); Life-Cycle Costing
Manual for the Federal Energy Management
Program (Prepared for U. S. Department of Energy,
Federal Energy Management Program, Office of the
Assistant Secretary for Conservation and Renewable
Energy) (Feb. 1996). Available at: https://
fire.nist.gov/fire/firedocs/build96/PDF/b96121.pdf.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
the results of the LCC analysis due to
the need to forecast certain inputs (e.g.,
future electricity prices). In addition,
DOE recognizes that inputs such as sales
tax, operating hours, and discount rates
may introduce variability in LCC
results. However, as explained below,
DOE’s analyses are structured so as to
address such uncertainties. As stated
earlier, to properly characterize the LCC
results, DOE performed probability
analyses via Monte Carlo simulations by
utilizing Microsoft Excel in combination
with Crystal Ball. The Monte Carlo
approach allowed DOE to determine
average LCC savings and payback
periods, as well as the proportion of
lamp installations achieving LCC
savings or attaining certain payback
values. To fully consider the range of
LCC results that may occur due to a
standard, DOE also performed several
sensitivity analyses on inputs such as
operating hours, electricity price
forecasts, and product prices. Based on
these analyses, DOE believes that it can
characterize the LCC and PBP for these
products with a reasonable degree of
16951
certainty. See the TSD appendix 8B for
further details, where probable ranges of
LCC results are presented.
Table V.2 summarizes the approach
and data that DOE used to derive the
inputs to the LCC and PBP calculations
for the March 2008 ANOPR and the
changes made for today’s proposed rule.
The following sections discuss these
inputs and comments DOE received
regarding its presentation of the LCC
and PBP analyses in the March 2008
ANOPR, as well as DOE’s responses
thereto.
TABLE V.2—SUMMARY OF INPUTS AND KEY ASSUMPTIONS USED IN THE ANOPR AND NOPR LCC ANALYSES
Inputs
March 2008 ANOPR
Changes for the Proposed Rule
Consumer Product ...............
Price .....................................
Applied discounts to manufacturer catalog (‘‘bluebook’’) pricing in order to represent low, medium, and
high prices for all lamp categories. Discounts were
also applied to develop a price for ballasts.
Derived weighted-average tax values for each Census
division and large State from data provided by the
Sales Tax Clearinghouse.1
Derived costs using the RS Means Electrical Cost
Data, 2007 3 to obtain average labor times for installation, as well as labor rates for electricians and helpers based on wage rates, benefits, and training costs.
Used same methodology from March 2008 ANOPR to
derive additional prices for new lamps and ballasts
incorporated into the engineering analysis.
Sales Tax .............................
Installation Cost ...................
Disposal Cost .......................
Not included ....................................................................
Annual Operating Hours ......
Determined operating hours by associating buildingtype-specific operating hours data with regional distributions of various building types using the 2002
U.S. Lighting Market Characterization 4 and the Energy Information Administration’s (EIA) 2003 Commercial Building Energy Consumption Survey
(CBECS),5 2001 Residential Energy Consumption
Survey,6 and 2002 Manufacturing Energy Consumption Survey.7
Determined lamp input power (or lamp-and-ballast system input power for GSFL) based on published manufacturer literature. Used a linear fit of GSFL system
power on several different ballasts with varying ballast factors in order to derive GSFL system power for
all of the ballasts used in the analysis.
Price: Based on EIA’s 2005 Form EIA–861 data ...........
Variability: Regional energy prices determined for 13
regions.
Forecasted with EIA’s Annual Energy Outlook (AEO)
2007.9
Ballast lifetime based on average ballast life of 49,054
from 2000 Ballast Rule.11 Lamp lifetime based on
published manufacturer literature where available.
DOE assumed a lamp operating time of 3 hours per
start. Where manufacturer literature was not available, DOE derived lamp lifetimes as part of the engineering analysis.
Product Energy Consumption Rate.
Electricity Prices ...................
Electricity Price Trends ........
Lifetime .................................
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00033
Fmt 4701
Sfmt 4702
Updated the sales tax using the latest information from
the Sales Tax Clearinghouse.2
IRL and GSFL: Updated lamp replacement and lamp
and ballast replacement labor rates from 2006$ to
2007$.
GSFL: Added 2.5 minutes of installation time to the
new construction, major retrofit, and renovation
events in the commercial and industrial sectors to
capture the time needed to install luminaire disconnects.
GSFL: Included a recycling cost of 10 cents per linear
foot in the commercial and industrial sectors.
IRL: No change.
GSFL: Added residential GSFL to LCC analysis and
used methodology developed in the March 2008
ANOPR to derive residential operating hours for
GSFL based on data in the 2002 U.S. Lighting Market Characterization and the EIA’s 2001 Residential
Energy Consumption Survey.
IRL: Removed industrial sector analysis due to the low
prevalence of IRL in that sector.
Updated 4-foot T8 lamp-and-ballast system input power
based on additional published manufacturer literature. Developed new system input powers for 8foot T12 HO systems, 4-foot T12 residential systems,
and 4-foot T5 systems.
Price: Updated using EIA’s 2006 Form EIA 861 data.8
Variability: No change.
Updated with EIA’s AEO2008.10
Ballasts: No change in commercial and industrial sector. Developed separate ballast lifetime estimate for
the residential sector.
Residential GSFL: 4-foot medium bipin lamp lifetime is
dependent on the fixture lifetime (i.e., the fixture
reaches end of life before the lamp reaches end of
life.).
Commercial and industrial GSFL: No change.
IRL: No change.
E:\FR\FM\13APP2.SGM
13APP2
16952
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE V.2—SUMMARY OF INPUTS AND KEY ASSUMPTIONS USED IN THE ANOPR AND NOPR LCC ANALYSES—
Continued
Inputs
March 2008 ANOPR
Changes for the Proposed Rule
Discount Rate ......................
Residential: Approach based on the finance cost of
raising funds to purchase lamps either through the financial cost of any debt incurred to purchase product
or the opportunity cost of any equity used to purchase equipment, based on the Federal Reserve’s
Survey of Consumer Finances data 12 for 1989,
1992, 1995, 1998, 2001, and 2004.
Commercial and industrial: Derived discount rates using
the cost of capital of publicly-traded firms in the sectors that purchase lamps, based on data in the 2003
CBECS,13 Damodaran Online,14 Ibbotson’s Associates,15 the 2007 Value Line Investment survey,16 Office of Management and Budget (OMB) Circular No.
A–94,17 2008 State and local bond interest rates,18
and the U.S. Bureau of Economic Analysis.19
Based on the longest baseline lamp life in a product
class divided by the annual operating hours of that
lamp.
DOE updated the commercial and industrial discount
rates using the latest versions of the sources used in
the March 2008 ANOPR.
Analysis Period ....................
Lamp Purchasing Events .....
DOE assessed five events: Lamp failure, standards-induced retrofit, ballast failure (GSFL only), ballast retrofit (GSFL only), and new construction/renovation.
Commercial and industrial GSFL: No Change.
Residential GSFL: Analysis period is based on the useful lifetime of the baseline lamp.
IRL: No Change.
GSFL: DOE assumed that HO lamps used magnetic
ballasts in the base case. DOE added lamp failure,
ballast failure/fixture failure, and new construction
events for 4-foot medium bipin systems in the residential sector, where DOE also assumed the usage
of magnetic ballasts in the base case.
IRL: No change.
1 The
four large States are New York, California, Texas, and Florida.
Tax Clearinghouse, Aggregate State Tax Rates (2008)(Last accessed May 30, 2008). Available at: https://thestc.com/STrates.stm. The
May 30, 2008 material from this Web site is available in Docket # EE–2006–STD–0131. For more information, contact Brenda Edwards at (202)
586–2945.
3 R. S. Means Company, Inc., 2007 RS Means Electrical Cost Data (2007).
4 U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Energy Conservation Program for Consumer Products: Final
Report: U.S. Lighting Market Characterization, Volume I: National Lighting Inventory and Energy Consumption Estimate (2002). Available at:
https://www.eere.energy.gov/buildings/info/documents/pdfs/lmc_vol1_final.pdf.
5 U.S. Department of Energy, Energy Information Administration, Commercial Building Energy Consumption Survey: Micro-level data, file 2
Building Activities, Special Measures of Size, and Multi-building Facilities (2003). Available at: https://www.eia.doe.gov/emeu/cbecs/public_use.html.
6 U.S. Department of Energy, Energy Information Administration, Residential Energy Consumption Survey: File 1: Housing Unit Characteristic
(2006). Available at: https://www.eia.doe.gov/emeu/recs/recs2001/publicuse2001.html.
7 U.S. Department of Energy, Energy Information Administration, Manufacturing Energy Consumption Survey, Table 1.4: Number of Establishments by First Use of Energy for All Purposes (Fuel and Nonfuel) (2002). Available at: https://www.eia.doe.gov/emeu/mecs/mecs2002/data02/
shelltables.html.
8 U.S. Department of Energy, Energy Information Administration, Form EIA–861 for 2006 (2006). Available at: https://www.eia.doe.gov/cneaf/
electricity/page/eia861.html.
9 U.S. Department of Energy, Energy Information Administration, Annual Energy Outlook 2007 with Projections to 2030 (Feb. 2007). Available
at: https://www.eia.doe.gov/oiaf/aeo/.
10 U.S. Department of Energy, Energy Information Administration, Annual Energy Outlook 2008 with Projections to 2030 (June 2008). Available
at: https://www.eia.doe.gov/oiaf/aeo/excel/aeotab_3.xls.
11 U.S. Department of Energy, Energy Efficiency and Renewable Energy, Office of Building Research and Standards, Technical Support Document: Energy Efficiency Standards for Consumer Products: Fluorescent Lamps Ballast Final Rule (Sept. 2000). Available at: https://
www1.eere.energy.gov/buildings/appliance_standards/residential/gs_fluorescent_0100_r.html.
12 The Federal Reserve Board, Survey of Consumer Finances. Available at: https://www.federalreserve.gov/PUBS/oss/oss2/scfindex.html.
13 U.S. Department of Energy, Energy Information Administration, Commercial Building Energy Consumption Survey (2003). Available at: https://
www.eia.doe.gov/emeu/cbecs/.
14 Damodaran Online, The Data Page: Historical Returns on Stocks, Bonds, and Bills—United States (2006). Available at: https://
pages.stern.nyu.edu/adamodar. (Last accessed Sept. 12, 2007.) The September 12, 2007 material from this Web site is available in Docket #
EE–2006–STD–0131. For more information, contact Brenda Edwards at (202) 586–2945.
15 Ibbotson’s Associates, Stocks, Bonds, Bills, and Inflation, Valuation Edition, 2001 Yearbook (2001).
16 Value Line, Value Line Investment Survey (2007). Available at: https://www.valueline.com.
17 U.S. Office of Management and Budget, Circular No. A–94 Appendix C (2008). Available at: https://www.whitehouse.gov/omb/circulars/a094/
a94_appx-c.html.
18 Federal Reserve Board, Statistics: Releases and Historical Data—Selected Interest Rates—State and Local Bonds (2008). Available at:
https://www.federalreserve.gov/releases/h15/data/Monthly/H15_SL_Y20.txt.
19 U.S. Department of Commerce, Bureau of Economic Analysis, Table 1.1.9 Implicit Price Deflators for Gross Domestic Product (2008). Available at: https://www.bea.gov/national/nipaweb/SelectTable.asp?Selected=N.
2 Sales
1. Consumer Product Price
As in the March 2008 ANOPR, DOE
used a variety of sources to develop
consumer equipment prices, including
lamp and ballast prices in
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
manufacturers’ suggested retail price
lists (‘‘blue books’’), State procurement
contracts, large electrical supply
distributors, hardware and home
improvement stores, Internet retailers,
and other similar sources. DOE then
PO 00000
Frm 00034
Fmt 4701
Sfmt 4702
developed low, medium, and high
prices based on its findings.
For the NOPR, DOE added several
new lamps and ballasts to its analyses.
Accordingly, DOE developed prices for
4-foot medium bipin GSFL systems in
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
the residential sector, the 8-foot HO
magnetic ballast, and commerciallyavailable 4-foot T5 miniature bipin
standard output and high-output lamps
and ballasts using the same
methodology applied in the March 2008
ANOPR. However, not all lamps
assessed for this rulemaking are
commercially available. In particular,
DOE developed model halophosphor T5
standard-output and high-output lamps
as baselines for these product classes.
To establish prices for these baseline
lamps, DOE calculated the price
differential between a halophosphor 4foot MBP lamp and the highest-efficacy
32W 4-foot MBP lamp. DOE then used
this relationship to scale prices from the
commercially-available T5 standardoutput and high-output lamps to
establish the halophosphor lamp prices.
DOE also developed a model IRL for
EL1 based on the incorporation of xenon
gas into the lamps. To determine the
price of these lamps, DOE interviewed
manufacturers and conducted its own
research on the cost of xenon 30 to
develop a manufacturer cost increase
over the baseline lamp in a product
class, and then applied a markup to
represent consumer prices. See the
engineering analysis in section V.C.4.b
for further information on the model IRL
lamp.
DOE also developed a price for the
6,000-hour HIR IRL for the NOPR. After
reviewing data in manufacturer catalogs
and interviewing manufacturers, DOE
determined that the manufacturing costs
for the 6,000-hour HIR lamp are the
same as the manufacturing costs for the
3,000-hour HIR lamps that meet EL3.
Therefore, for the NOPR, the
commoditized retail prices for the longlife HIR lamps are the same as for the
IRL that meet EL3.
Lastly, because DOE did not have
manufacturer suggested retail price list
data for the EL5 (HIR Plus) IRL, DOE
used prices offered by Internet retailers
to establish prices for these lamps.
Specifically, DOE calculated individual
retailers’ discounts on blue book prices
for EL4 (Improved HIR) lamps. DOE
applied these same discounts to
establish average blue book prices for
EL5 lamps across all Internet retailers
found to sell both EL4 and EL5 lamps.
Using these approximate blue-book
prices, DOE then followed the same
methodology applied in the March 2008
ANOPR to establish low, medium and
high lamp prices.
30 DOE
used the information in the following
article to obtain the price of xenon: Betzendahl,
Richard, ‘‘The Rare Gets More Rare: The Rare Gases
Market Update,’’ CryoGas International (June 2008)
26.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
2. Sales Tax
As in the March 2008 ANOPR, DOE
obtained State and local sales tax data
from the Sales Tax Clearinghouse.
(March 2008 ANOPR TSD chapter 7)
The data represented weighted averages
that include county and city rates. DOE
used the data to compute populationweighted average tax values for each
Census division and four large States
(New York, California, Texas, and
Florida). For the NOPR, DOE retained
this methodology and used updated
sales tax data from the Sales Tax
Clearinghouse 31 and updated
population estimates from the U.S.
Census Bureau.32
3. Installation Costs
As detailed in the ANOPR, DOE
considered the total installed cost of a
lamp or lamp-and-ballast system to be
the consumer product price (including
sales taxes) plus the installation cost. 73
FR 13620, 13660 (March 13, 2008). For
the commercial and industrial sectors,
DOE assumed an installation cost that
was the product of the average labor rate
and the time needed to install a lamp or
lamp and ballast. In the residential
sector, DOE assumed that consumers
must pay for the installation of a lamp
and ballast system. Therefore, the
installation cost assumed was the
product of the average labor rate and the
time needed to install the lamp and
ballast system. However, DOE assumed
that consumers would install their own
replacement lamps and, thus, would
incur no installation cost when
replacing their own lamp.
DOE received multiple comments on
the average labor rates DOE used in the
March 2008 ANOPR: $65.35 per hour
for an electrician and $42.40 per hour
for an electrician’s helper. (March 2008
ANOPR TSD chapter 8). DOE assumed
that the lamp-and-ballast hourly labor
rate is 50 percent of an electrician’s rate
and 50 percent of the helper’s rate, for
a total labor rate of $53.88 based on ‘‘RS
Means Electrical Cost Data, 2007’’ (RS
Means).33 NEMA commented that
$53.88 per hour is approximately 10
percent lower than the current labor rate
including benefits, while the Joint
Comment stated that $54 per hour for
31 Sales Tax Clearinghouse, ‘‘Aggregate State Tax
Rates’’ (2007) (Last accessed May 30, 2008).
Available at: https://thestc.com/STrates.stm. The
May 30, 2008, material from this Web site is
available in Docket #EE–2006–STD–0131. For more
information, contact Brenda Edwards at (202) 586–
2945.
32 U.S. Census Bureau, ‘‘Population Change: April
1, 2000 to July 1, 2007’’ (July 2007). Available at:
https://www.census.gov/popest/states/files/NSTEST2007-popchg2000-2007.csv.
33 R. S. Means Company, Inc., 2007 RS Means
Electrical Cost Data (2007).
PO 00000
Frm 00035
Fmt 4701
Sfmt 4702
16953
ballast change-outs is reasonable only
for residential and small commercial
customers, and is too high for large
commercial customers, who will have a
full-time electrician or non-electrician
maintenance person on staff for
installations. (NEMA, No. 22 at p. 22;
Joint Comment, No. 23 at p. 10) ACEEE
also commented that large companies
may have electricians on staff and
encouraged DOE to research labor rates
for these workers. (Public Meeting
Transcript, No. 21 at pp. 216–217)
DOE understands that there may be a
range of labor rates in the market for
installations and also clarifies that the
March 2008 ANOPR labor rate of $53.88
per hour is for the installation of lamps
and ballasts, not only ballasts, as stated
in the Joint Comment. ACEEE and the
Joint Comment requested that DOE
lower the labor rate, while NEMA
commented that DOE should raise the
labor rate; none of the comments
provided DOE with supporting
references. DOE uses ‘‘RS Means
Electrical Cost Data, 2007,’’ because
labor costs in RS Means are based on
labor union agreements and
construction wages, as well as actual
working conditions in 30 major U.S.
cities. Productivity data in RS Means
represents an extended period of
observations. For this reason, DOE
chose to retain for the NOPR the RS
Means methodology used for the March
2008 ANOPR. Based on inflation
estimates derived from consumer price
index data from the U.S. Bureau of
Labor Statistics, DOE estimated that this
rate in 2007 dollars is $55.41 per hour.
DOE also updated the lamp replacement
labor rate to be $15.94 per hour in 2007
dollars.
In the March 2008 ANOPR, DOE used
several installation times for lamps and
ballasts in the commercial and
industrial sector analyses, such as the
lower bound installation time of 30
minutes for 2-lamp 4-foot medium bipin
fixtures, and the upper bound
installation time of 60 minutes for 2lamp 8-foot recessed double contact
high-output fixtures. (March 2008
ANOPR TSD chapter 8) These times
were obtained from the 2000 Ballast
Rule TSD.34
DOE received several comments
addressing these installation times. GE
commented that the 2005 National
Electric Code requirements for
disconnecting luminaires before they
are serviced for lamp or ballast
34 U.S. Department of Energy, ‘‘Appendix A:
Engineering Analysis Support Documentation, 2000
Ballast Rule’’ (2000) (Last accessed June 20, 2008).
Available at: https://www.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/appendix_
a.pdf.
E:\FR\FM\13APP2.SGM
13APP2
16954
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
replacements and installing luminaire
disconnects for new construction or
major retrofits will necessitate
additional labor time. (Public Meeting
Transcript, No. 21 at pp. 218–219;
NEMA, No. 22 at p. 22) NEMA
recommended that DOE use an
installation time of approximately 2 to
3 minutes for luminaire disconnects.
Industrial Ecology commented on
average installation times during the
recent relamping of a school in Atlantic
City, NJ, in which an electrician
changed ballasts and lamps for 4-lamp
and 2-lamp fixtures at the rate of
approximately 3 fixtures per hour.
(Public Meeting Transcript, No. 21 at p.
220)
DOE agrees that extra time will be
needed when a luminaire disconnect
must be installed. Because DOE has not
received detailed data on other
installation times apart from the ones
used in the 2000 Ballast Rule, DOE
revised the ANOPR installation times
specifically to address the time added
by the installation of luminaire
disconnects. For the NOPR analysis,
DOE added 2.5 minutes to the ANOPR
installation times for new construction,
major retrofits, and renovation, events
in which DOE assumed that a luminaire
disconnect must be installed.
Additional details on installation costs
are available in chapter 8 of the NOPR
TSD.
4. Disposal Costs
DOE did not consider disposal costs
in the March 2008 ANOPR. Industrial
Ecology commented that recycling costs
should be considered in the LCC
analysis for GSFL and that such costs
range from 5 cents to 10 cents per foot.
(Public Meeting Transcript, No. 21 at p.
212) In response, DOE researched
recycling costs for GSFL and found an
average cost of 10 cents per linear foot.35
DOE also explored the prevalence of
recycling in the commercial, industrial,
and residential sectors. A report
released by the Association of Lighting
and Mercury Recyclers in 2004 noted
that approximately 30 percent of lamps
used by businesses and 2 percent of
lamps in the residential sector are
recycled nationwide.36 DOE considers
the 30 percent commercial and
industrial recycling rate to be significant
and, thus, incorporates recycling costs
35 Environmental Health and Safety Online’s
fluorescent lights and lighting disposal and
recycling Web page—Recycling Costs. Available at:
https://www.ehso.com/fluoresc.php (Last accessed
Dec. 8, 2008).
36 Association of Lighting and Mercury Recyclers,
‘‘National Mercury-Lamp Recycling Rate and
Availability of Lamp Recycling Services in the
U.S.’’ (Nov. 2004).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
into its main analysis. DOE applied a
cost of 10 cents per linear foot in the
commercial and industrial sectors every
time a lamp is replaced during the LCC
analysis period. Due to discounting, the
inclusion of recycling costs affects the
LCC savings of lamps with different
lifetimes than the baseline lamps that
they are compared to. The recycling cost
also affects the residual value of lamps
that operate beyond the end of the
analysis period. In the Monte Carlo
analysis, DOE assumes that commercial
and industrial consumers pay recycling
costs in approximately 30 percent of
lamp failures. DOE does not expect the
2 percent residential recycling rate to
affect the residential sector LCC
substantially, however, and thus did not
apply the recycling costs to this sector.
5. Annual Operating Hours
DOE developed annual operating
hours for IRL and GSFL in the March
2008 ANOPR by combining building
type-specific operating hours data in the
2002 U.S. Lighting Market
Characterization (LMC) 37 with data in
the 2003 Commercial Building Energy
Consumption Survey (CBECS),38 the
2001 Residential Energy Consumption
Survey (RECS),39 and the 2002
Manufacturing Energy Consumption
Survey (MECS),40 which describe the
probability that a particular building
type exists in a particular region. (March
2008 ANOPR TSD chapter 6) DOE
received comments on three areas
related to the operating hours used for
the LCC analysis: (1) Sectors analyzed;
(2) regional variations; and (3) building
types. These comments are discussed
below. For further details regarding the
annual operating hours used in the
analyses, see chapter 6 of the TSD.
37 U.S. Department of Energy, Office of Energy
Efficiency and Renewable Energy, ‘‘U.S. Lighting
Market Characterization. Volume I: National
Lighting Inventory and Energy Consumption
Estimate (2002).’’ Available at: https://
www.netl.doe.gov/ssl/PDFs/lmc_vol1_final.pdf.
38 U.S. Department of Energy, Energy Information
Agency, ‘‘Commercial Building Energy
Consumption Survey: Micro-Level Data, File 2
Building Activities, Special Measures of Size, and
Multi-building Facilities (2003).’’ Available at:
https://www.eia.doe.gov/emeu/cbecs/
public_use.html.
39 U.S. Department of Energy, Energy Information
Agency, ‘‘Residential Energy Consumption Survey:
File 1: Housing Unit Characteristic (2006).’’
Available at: https://www.eia.doe.gov/emeu/recs/
recs2001/publicuse2001.html.
40 U.S. Department of Energy, Energy Information
Agency, ‘‘Manufacturing Energy Consumption
Survey, Table 1.4: Number of Establishments by
First Use of Energy for All Purposes (Fuel and
Nonfuel) (2002).’’ Available at: https://
www.eia.doe.gov/emeu/mecs/mecs2002/data02/
shelltables.html.
PO 00000
Frm 00036
Fmt 4701
Sfmt 4702
a. Sectors Analyzed
In the March 2008 ANOPR, DOE
analyzed GSFL in the commercial and
industrial sectors; DOE did not analyze
the usage of GSFL in the residential
sector because it believed it was a
relatively small portion of GSFL sales.
The Joint Comment requested that DOE
perform an LCC analysis of GSFL in the
residential sector, because lamps in the
residential sector are replaced
infrequently due to lower operating
hours compared to the commercial and
industrial sectors. (Joint Comment, No.
23 at p. 10) Similarly, NEMA
commented that DOE should assess
GSFL in the residential sector, because
certain ELs may eliminate T12 lamp
types, requiring many residential
consumers to install new lamp fixtures.
(NEMA, No. 22 at p. 32)
In response, DOE assessed the
installed stock of lamps using the LMC,
which stated that approximately 25
percent of linear fluorescent lamps exist
in the residential sector. DOE considers
this proportion to be significant and,
thus, supports the recommendation to
perform a residential LCC analysis of
GSFL. DOE developed residential
operating hours for GSFL by using data
in the 2002 LMC and the 2001 RECS.
However, DOE only performed an LCC
analysis of 4-foot medium bipin lamps
in the residential sector, because
marketing literature indicates that 8-foot
single pin slimline lamps and 8-foot
recessed double contact HO lamps are
not prevalent in residential settings.
In the March 2008 ANOPR, DOE
analyzed IRL in the commercial,
residential, and industrial sectors.
(March 2008 ANOPR TSD chapter 6)
NEMA commented that IRL should be
removed from the industrial sector LCC
analysis because they are rarely used in
industrial settings. The Joint Comment
emphasized the importance of analyzing
IRL in the residential sector due to
lower operating hours and higher
electricity prices for residences
compared to prices in the commercial
sector. (NEMA, No. 22 at p. 20; Joint
Comment, No. 23 at p. 17)
The LMC indicates that less than 1
percent of IRL were found in the
industrial sector. Based on this data,
DOE agrees with both comments and
has removed IRL from the industrial
sector in terms of its analyses.
Consistent with the March 2008 ANORP
LCC analysis, DOE also continued to
perform a residential sector LCC
analysis of IRL for the NOPR.
b. Regional Variation
At the public meeting for the March
2008 ANOPR, the Alliance to Save
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
Energy commented that the LMC, which
DOE used during the LCC analysis, may
underestimate energy usage in the
residential sector because operating
hours may vary regionally (e.g., by
latitude), even for the same building
types. (Public Meeting Transcript, No.
21 at pp. 197–198) In contrast, the
Northwest Power and Conservation
Council responded that there was a
variation of a tenth of an hour per day
in operating hours between a study
completed in Tacoma, Washington, and
a study of California. Therefore, the
Council suggested that differences in
latitude and weather do not
significantly affect operating hours.
(Public Meeting Transcript, No. 21 at p.
199)
DOE found no conclusive evidence
that would suggest that geographic
location has a significant impact on
operating hours for a given building
type. However, DOE found evidence of
regional differences in the proportions
of different building types (e.g., number
of mobile homes versus number of
multi-family dwellings) as the probable
source of regional variation in operating
hours.41 As detailed in the March 2008
ANOPR, DOE captured this regional
variation by using the RECS, CBECS,
and MECS to determine the probability
that a particular building type exists in
a particular region. 73 FR 13620, 13654
(March 13, 2008). For this reason, DOE
has not revised its analysis for the
NOPR to specifically address latitude,
weather, or other regional factors apart
from building type proportions.
c. Building Type
NEMA requested a confirmation that
DOE has included retail facilities in its
consideration of operating hours,
because retail facilities have more
operating hours compared to other
commercial facilities. (NEMA, No. 22 at
p. 20) DOE is aware that different
commercial building types have
different average operating hours and,
thus, considered a variety of commercial
building types, including retail
facilities, in its analysis. Operating
hours were determined using the LMC
study. DOE assessed the operating hours
for retail facilities for the March 2008
ANOPR (ANOPR chapter 6 of the TSD)
and retained the assessment of
commercial retail facility operating
hours for the NOPR analysis.
41 E. Vine, D. Fielding, ‘‘An Evaluation of
Residential CFL Hours-of-Use Methodologies and
Estimates: Recommendations for Evaluators and
Program Managers,’’ Energy and Buildings 38
(2006), 1388–1394.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
6. Product Energy Consumption Rate
As in the March 2008 ANOPR, DOE
determined lamp input power (or lampand-ballast system input power for
GSFL) based on published manufacturer
literature. (March 2008 ANOPR TSD
chapter 5) For GSFL, DOE assessed a
variety of lamp-and-ballast
combinations by establishing a
correlation between ballast factor and
system input power. This allowed DOE
to derive GSFL system power (in watts)
for all of the lamp and ballast
combinations used in the analysis. The
rated system power was then multiplied
by the annual operating hours of the
system to determine the annual energy
consumption. DOE retained this
methodology for this notice.
For this NOPR, DOE updated system
input power ratings for certain lampand-ballast combinations, and
developed new system-input powers for
other lamp-and-ballast combinations not
considered in the March 2008 ANOPR.
Specifically, DOE obtained additional
system power ratings for 4-foot T8
ballasts from recently released
manufacturer literature and updated
these system input power ratings for the
NOPR. DOE also developed new system
input power ratings for magnetic
residential 4-foot T12 systems, magnetic
8-foot HO systems, 4-foot T5 miniature
bipin systems, and 4-foot T5 miniature
bipin HO systems.
7. Electricity Prices
DOE determined energy prices by
deriving regional average prices for 13
geographic areas consisting of the nine
U.S. Census divisions, with four large
states (New York, Florida, Texas, and
California) treated separately. The
derivation of prices was based on data
in EIA’s Form EIA–861. DOE received
three comments on the regional
electricity prices that it used for the
ANOPR LCC. PG&E commented that the
California residential electricity price of
9.9 cents per kWh (ANOPR TSD chapter
8) was lower than what appears to be an
average of 14 cents per kWh in the State.
ACEEE and the Joint Comment
recommended that DOE use EIA’s
publication ‘‘Electric Power Monthly’’—
as a source of recent electricity prices
instead of Form EIA–861. (Public
Meeting Transcript, No. 21 at pp. 223–
224; Joint Comment, No. 23 at p. 18)
In response, DOE notes that it uses
Form EIA–861 for two reasons. First, it
allows for the creation of regional
average electricity prices weighted by
the number of customers each electric
utility serves. DOE prefers to use
customer-weighted average electricity
prices so that prices are not skewed by
PO 00000
Frm 00037
Fmt 4701
Sfmt 4702
16955
utilities serving small numbers of very
large electricity consumers. Electricity
sales are not well correlated with the
number of consumers in the commercial
sector, and the usage of customerweighted averages more heavily weights
the utilities that serve larger numbers of
consumers. Second, ‘‘Electric Power
Monthly’’ does not report customerweighted prices. DOE appreciates the
comments related to electricity prices,
and for the NOPR analysis, DOE
updated its electricity prices by using
the latest version of Form EIA–861
(2006).42 DOE notes that the latest
Form’s updated residential electricity
price for California is 14.7 cents per
kWh which is consistent with PG&E’s
assessment that the average residential
electricity price in California is around
14 cents per kWh.
8. Electricity Price Trends
To project electricity prices to the end
of the LCC analysis period in the March
2008 ANOPR, DOE used the reference,
low-economic-growth, and higheconomic-growth projections in EIA’s
AEO2007.43 73 FR 13620, 13660 (March
13, 2008). DOE received several
comments on the resulting electricity
price trends that it used in the LCC
calculation. PG&E commented that
DOE’s forecasted electricity prices do
not increase in real terms in the next 20
years, which the commenter argued is
unrealistic. ACEEE and the Joint
Comment both stated that DOE should
use the most recent AEO forecasts along
with a collection of other electricity
price forecasts. (Public Meeting
Transcript, No. 21 at pp. 224–225; Joint
Comment, No. 23 at p. 18)
DOE supports the suggestion that it
should use the most recent electricity
price forecasts. DOE uses EIA’s AEO
because it is publicly available and has
been widely reviewed. The latest AEO
contains a table of comparisons to three
other electricity forecasts; the only
forecast that included prices (from
Global Insight, Inc.) showed electricity
prices very similar to the prices in the
AEO2008 reference case. Also, a
conversion of the AEO2008 forecast into
real dollars reveals that AEO’s
forecasted electricity prices do increase
in real terms. For these reasons, DOE
chose to continue using the AEO and
42 Energy Information Administration, Form EIA–
861 Final Data File for 2006 (2006) (Last accessed
June 20, 2008). Available at: https://
www.eia.doe.gov/cneaf/electricity/page/
eia861.html.
43 U.S. Department of Energy, Energy Information
Administration, Annual Energy Outlook 2007 with
Projections to 2030 (Feb. 2007). Available at:
https://www.eia.doe.gov/oiaf/archive/aeo07/
index.html.
E:\FR\FM\13APP2.SGM
13APP2
16956
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
the reference case in AEO2008.44 DOE
also presents LCC and PBP results for
the low-economic-growth and higheconomic-growth scenarios from
AEO2008 in appendix 8B of the TSD.
9. Lifetime
a. Ballast Lifetime
In chapter 8 of the March 2008
ANOPR TSD, DOE stated that it used
49,054 hours as the estimated ballast
lifetime based on findings in the 2000
Ballast Rule. The Joint Comment
suggested three reasons why ballast
lifetimes are actually longer than the
lifetime used in the 2000 Ballast Rule.
The Joint Comment stated that, on
average, ballasts operate below their life
rating temperature. In addition,
manufacturer estimates exceed the DOE
lifetime even at rated conditions. The
commenter also argued that market data
of historical shipments of ballasts sold
to new construction versus retrofit and
replacement suggest that the average
ballast life is longer than suggested. The
Joint Comment contends that, in
addition to considering the above points
generally, DOE should specifically
study these shipments to establish
ballast lifetime. (Joint Comment, No. 23
at pp. 7–9)
Based on the Joint Comment’s
suggestions, DOE investigated several
different ways of measuring a ballast’s
useful lifetime in commercial and
residential buildings. DOE does not
believe that using the rated temperature
of ballasts is an appropriate way to
measure a ballast’s lifetime. For
example, a building renovation or a
lighting retrofit may cause buildings or
homeowners to replace a ballast before
it fails. DOE also believes that
examining historical sales data of
ballasts sold to new construction versus
replacement and retrofit to estimate
ballast lifetime would involve too many
assumptions to provide a useful
measure of lifetime. For example, DOE
would need to estimate an appropriate
distribution of ballast lifetimes in the
field because ballasts are replaced at
various points in their useful life due to
different operating hours, failure rates,
and time periods between initial
building construction and the first
lighting retrofit.
In its investigation of ballast lifetime,
DOE encountered several studies that
establish the ‘‘measure life’’ (i.e., the
true service life of a ballast in the field)
of ballasts in both the commercial and
residential sectors. One study
44 U.S. Department of Energy, Energy Information
Administration, Annual Energy Outlook 2008 with
Projections to 2030 (June 2008). Available at:
https://www.eia.doe.gov/oiaf/aeo/excel/aeotab_3.xls.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
comparing the results of several
‘‘measure life’’ reports found that the
average ballast lifetime after a retrofit in
the commercial sector is 13 years, and
the average ballast lifetime after new
construction is 15 years.45 Using DOE’s
estimate of 49,054 hours and average
operating hours for GSFL in the
commercial sector, the lifetime of an
average ballast is approximately 14.2
years. Because this lifetime is consistent
with several measure life reports, DOE
maintains the same ballast lifetime of
49,054 hours in its NOPR analysis. DOE
also found in a separate measure life
report that the average fixture and
ballast in the residential sector lasts for
15 years. Therefore, in its residential
sector analysis for GSFL, DOE
established 15 years as the average
ballast lifetime in the residential
sector,46 and an average annual
operating lifetime of 789 hours. The
ballast’s average hours of operation over
its service lifetime is therefore 11,835
hours in the residential sector.
b. Lamp Lifetime
When possible, DOE used
manufacturer literature to measure lamp
lifetimes, as in the March 2008 ANOPR.
73 FR 13620, 13662 (March 13, 2008).
When published manufacturer literature
was not available (as for some IRL), DOE
derived lamp lifetimes as part of the
engineering analysis (section V.C.4.b).
DOE based its calculations of GSFL
lifetime for the base and standards cases
on lamp operating times of 3 hours per
start in the March 2008 ANOPR LCC
analysis. 73 FR 13620, 13662 (March 13,
2008). In comments, NEMA supported
the 3 hours per start operating time for
both the base and standards cases, but
also argued that while lamps are started
every 12 hours in commercial and
industrial applications, the increasing
use of occupancy sensors is leading to
shorter start cycles. (NEMA, No. 22 at p.
23) DOE did not receive any other
comments about using a GSFL operating
time of 3 hours per start. Therefore, DOE
retained the assumption of 3 hours per
start in the NOPR LCC analysis for both
the base and standards cases. In
addition, DOE researched the impact of
occupancy sensors on start cycle
lengths. However, DOE was unable to
obtain significant information with
which it could quantify this effect.
45 GDS Associates, Inc., Engineers and
Consultants, Measure Life Report: Residential and
Commercial/Industrial Lighting and HVAC
Measures (The New England State Program
Working Group) (2007).
46 Economic Research Associates, Inc., and
Quantec, LLC., Revised/Updated EULs Based on
Retention and Persistence Studies Results
(Southern California Edison) (2005).
PO 00000
Frm 00038
Fmt 4701
Sfmt 4702
As in the March 2008 ANOPR, DOE
also considered in the NOPR analysis
the impact of group re-lamping practices
on GSFL lifetime in the commercial and
industrial sectors. 73 FR 13620, 13662
(March 13, 2008). DOE assumed that a
lamp subject to group re-lamping
operates for 75 percent of its rated
lifetime, an estimate obtained from the
2000 Ballast Rule.47 By considering
lamp rated lifetimes and the prevalence
of group versus spot re-lamping
practices, DOE derived an average
lifetime for a GSFL. This ranged from 91
percent of rated lifetime for 8-foot single
pin slimline lamps to 94 percent of
rated lifetime for 4-foot medium bipin
lamps. See chapter 8 of the TSD for
further details.
As stated above, DOE is using 15
years as the estimated fixture and ballast
lifetime in the residential sector for
purposes of its analyses. If one
calculates the lifetime of the baseline
GSFL lamp in the residential sector by
dividing the life in hours by the average
operating hours of a GSFL in the
residential sector (789 hours), one finds
that the baseline lamp should live for 19
years. Because the lifetime of the
baseline lamp is longer than the average
lifetime of a fixture and ballast, DOE
assumes that the ballast or fixture
lifetime limits the lifetime of an average
lamp in the residential sector. DOE is
aware that there are certain rooms in
residential buildings where GSFL are
operated for much longer than 789
hours per year; in particular, GSFL are
operated for approximately 1,210 hours
per year in kitchens of single-family
detached households. Therefore, DOE
has conducted the residential sector
analysis under average operating hours
and high operating hours. Under
average operating hours (789 hours per
year), DOE assumes that lamp lifetime
of the baseline-case and standards-case
lamps is limited to 11,835 hours or 15
years, due to a ballast or fixture failure.
Thus, in this situation, the lamp failure
event does not occur; only the ballast
failure event occurs. See section V.D.14
for a description of lamp purchase
events.
DOE recognizes that although some
consumers do not experience a lamp
failure in the residential sector,
consumers whose operating hours yield
a lamp lifetime that is shorter than that
of the fixture or ballast do need to
replace their lamp occasionally. DOE
47 U.S. Department of Energy, Office of Energy
Efficiency and Renewable Energy, ‘‘Energy
Conservation Program for Consumer Products:
Technical Support Document: Energy Efficiency
Standards for Consumer Products: Fluorescent
Lamp Ballast Proposed Rule: Appendix A’’ (Jan.
2000) A–19.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
assumes the shortest lifetime of the
baseline lamp, using the highest
operating hours for GSFL in the LMC of
1,210 hours per year (as in kitchens), is
approximately 12.5 years. When a
baseline lamp is replaced at 12.5 years,
the fixture and ballast have another 2.5
years of life remaining. DOE assumes
that when fixtures or ballasts are
discarded, their associated lamps are
also discarded at the same time.
Therefore, for GSFL in the residential
sector, the longest useful life of the
baseline replacement lamp would be 2.5
years or 1,972 hours. At the end of this
lifetime, the ballast and fixture are
replaced. Therefore, for the lamp
replacement event for a GSFL in the
residential sector in a high operating
hours scenario (1,210 hours per year),
the lifetime of the baseline lamp is
assumed to be 1,972 hours or 2.5 years,
and DOE assumes that the ballast failure
event does not occur. DOE requests
comment on the typical service life of a
GSFL in the residential sector.
10. Discount Rates
In the March 2008 ANOPR, DOE
derived residential discount rates by
identifying all possible debt or asset
classes that might be used to purchase
replacement products, including
household assets that might be affected
indirectly. 73 FR 13620, 13663 (March
13, 2008). DOE estimated the average
shares of the various debt and equity
classes in the average U.S. household
equity and debt portfolios using data
from the SCFs from 1989 to 2004. DOE
used the mean share of each class across
the six sample years as a basis for
estimating the effective financing rate
for replacement equipment. DOE
estimated interest or return rates
associated with each type of equity and
debt using SCF data and other sources.
The mean real effective rate across the
classes of household debt and equity,
weighted by the shares of each class, is
5.6 percent.
For the commercial sector and
industrial sector, DOE derived the
discount rate from the cost of capital of
publicly-traded firms in the sectors that
purchase lamps. To obtain an average
discount rate value for the commercial
sector, DOE used data from CBECS
2003, which provides market-share data
by type of owner. Weighting each
ownership type by its market share,
DOE estimated the average discount rate
for the commercial sector to be 6.2
percent. Similarly, the industrial sector
discount rate was derived to be 7.5
percent. 73 FR 13620, 13663 (March 13,
2008).
The Joint Comment stated that, in the
past, NRDC has argued that a 2 to 3
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
percent real discount rate should be
used in the LCC. (Joint Comment, No. 23
at p. 22) It also stated that ACEEE and
others have supported the weighted
average cost of capital approach. In
general, the Joint Comment stated that if
DOE continues with using the weighted
cost of capital approach, the agency
should make sure its calculations are
updated, as current economic
conditions will influence agency
estimates for discount rates over the
analysis period. (Joint Comment, No. 23
at p. 22) In consideration of the above
comments (and absent any evidence to
the contrary), DOE agrees with ACEEE
and others in the Joint Comment that
the weighted average cost of capital
approach described above is the most
accurate way of establishing an
appropriate consumer discount rate for
the LCC analysis. For this NOPR, DOE
was not able to use the most up-to-date
information to update the residential
discount rate, because the 2007 SCF
survey was not available at the time of
publication. However, because the rates
for various forms of credit carried by
households in these years were
established over a range of time, DOE
believes they are representative of rates
that may be in effect in 2012. DOE is not
aware of any other nationally
representative data source that provides
interest rates from a statistically valid
sample. Therefore, DOE continued to
use the above approach and results for
today’s proposed rule. According to the
Federal Reserve Board Web site, the
2007 SCF survey may be available in the
first quarter of 2009.48 Contingent on
this data’s release in a timely manner,
DOE will attempt to incorporate the
2007 SCF survey in the final rule of this
rulemaking.
Despite the limitations associated
with its residential analysis, DOE was
able to update certain sources used to
compute the commercial and industrial
sector discount rates. Specifically, DOE
applied the 2008 Damodaran Online
Data, the 2008 implicit price deflators
from the U.S. Department of Commerce,
the 2007 Value Line Investment Survey
data, information from the 2008 OMB
Circular No. A–94, and 2008 State and
local bond interest rates. However, DOE
continued to use data from CBECS 2003,
which provides market-share data by
type of owner to obtain an average
discount rate value for the commercial
sector. DOE is not aware of any other
nationally representative data source
that provides market-share data by type
of owner and, therefore, is continuing to
use this source of data in today’s
48 https://www.federalreserve.gov/PUBS/oss/oss2/
2007/scf2007home_modify.html.
PO 00000
Frm 00039
Fmt 4701
Sfmt 4702
16957
proposed rule. DOE computed the new
discount rates to be 7.0 percent in the
commercial sector and 7.6 percent in
the industrial sector. For further details
on discount rates, see chapter 8 and
appendix 8C of the TSD.
11. Analysis Period
The analysis period is the span of
time over which the LCC is calculated.
For the March 2008 ANOPR, DOE used
the longest baseline lamp life in a
product class divided by the annual
operating hours of that lamp as the
analysis period. 73 FR 13620, 13663
(March 13, 2008). During Monte Carlo
simulations for the LCC analysis, DOE
selected the analysis period based on
the longest baseline lamp life divided by
the annual operating hours chosen by
Crystal Ball. For the NOPR analysis,
DOE retained this methodology for IRL
and GSFL in the commercial and
industrial sectors. However, for GSFL in
the residential sector, the analysis
period is based on the useful life of the
baseline lamp for a specific event.
Specifically, for the lamp replacement
event, the analysis period is 2.5 years,
and for the lamp and ballast
replacement and new construction
event, the analysis period is 15 years.
DOE requests comment on the analysis
period used for the residential sector
analysis. See section V.D.9.a of this
notice for more information on the
useful life of the baseline lamp in all
residential sector purchase events.
12. Effective Date
For purposes of DOE’s analyses, the
effective date is the date when a new
standard becomes operative. DOE
intends to publish the final rule for this
rulemaking in June 2009. 73 FR 13620,
13663 (March 13, 2008). In accordance
with sections 325(i)(3) and (i)(5) of
EPCA, the effective date of any new or
amended energy conservation standard
for these lamps shall be 3 years after the
final rule is published, which would be
June 2012 for this rulemaking. (42
U.S.C. 6295(i)(3) and (i)(5)) DOE
performed its LCC analysis based upon
an assumption that each consumer
would purchase a new product in the
year that the standard takes effect.
13. Payback Period Inputs
The payback period (PBP) is the
amount of time a consumer needs to
recover the assumed additional costs of
a more-efficient product through lower
operating costs. As in the March 2008
ANOPR, DOE used a ‘‘simple’’ PBP for
the NOPR, because the PBP does not
take into account other changes in
operating expenses over time or the time
value of money. 73 FR 13620, 13663
E:\FR\FM\13APP2.SGM
13APP2
16958
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
(March 13, 2008). As inputs to the PBP
analysis, DOE used the total installed
cost of the product to the consumer for
each efficacy level, as well as the first
year annual operating costs for each
efficacy level. The calculation requires
the same inputs as the LCC, except for
energy price trends and discount rates;
only energy prices for the year the
standard takes effect (2012 in this case)
are needed. 73 FR 13620, 13663 (March
13, 2008).
14. Lamp Purchase Events
In the March 2008 ANOPR, DOE
described five types of events that
would prompt a consumer to purchase
a lamp. 73 FR 13620, 13664 (March 13,
2008). These events are described below
along with changes for the NOPR
analysis. Of particular note, DOE
conducted a number of new analyses for
the NOPR which assessed lamp failure,
ballast failure, and new construction
events for residential sector GSFL. In
addition, though described primarily in
the context of GSFL, lamp purchase
events can be applied to IRL as well.
However, considering that IRL are
generally not used with a ballast the
only lamp purchase events applicable
are lamp failure (event I) and new
construction and renovation (event V).
• Lamp Failure (Event I): This event
reflects a scenario in which a lamp has
failed (spot relamping) or is about to fail
(group re-lamping). In the base case,
identical lamps are installed as
replacements. In the standards case, the
consumer installs a standards-compliant
lamp that is compatible with the
existing ballast. When a standardscompliant lamp for that ballast is not
available, the consumer purchases a
new lamp and ballast. For the NOPR,
DOE added a residential sector GSFL
lamp failure event.
• Standards-Induced Retrofit (Event
II): This event occurs when a consumer
realizes that its T12 lamp will fail in the
near future and installs a standardscompliant lamp and ballast. In the base
case, the consumer would have installed
only a new lamp. This event applies
only to T12 commercial and industrial
users because there are certain lamp
standard levels that a T12 cannot meet.
This event does not apply to T12
residential users because these users
would not proactively replace their T12
system before the T12 lamp fails.
• Ballast Failure (Event III): In the
March 2008 ANOPR, DOE assumed that
failed ballasts would be replaced with
electronic ballasts because standards set
by the 2000 Ballast Rule and EPACT
2005 ban the sale of magnetic 4-foot
medium bipin and 8-foot single pin
slimline ballasts beginning in 2010. 73
FR 13620, 13664 (March 13, 2008).
NEMA commented that the 2000 Ballast
Rule allows the continued sale of
residential magnetic ballasts as well as
magnetic cold-temperature ballasts,
which operate a large portion of the
installed base of T12 recessed double
contact high-output lamps. (NEMA, No.
22 at p. 20) In response, DOE has
assumed that failed magnetic HO
ballasts would be replaced with
magnetic ballasts in the base case for the
NOPR analysis. DOE also assumed that
magnetic ballasts would be purchased
in the event of a ballast or fixture failure
in the residential sector base case for the
NOPR analysis because residential
systems are commonly T12 magnetic
systems currently. In addition,
standards established in the 2000
Ballast Rule and the Energy Policy Act
of 2005 (EPACT 2005, Pub. L. 109–58)
will allow magnetic ballasts to continue
to be sold in the residential sector after
2010. See the engineering analysis
(section V.C) for further details.
• Ballast Retrofit (Event IV): This
event applies only to T12 users because,
according to industry experts, the
majority of ballast retrofits occur for
consumers with T12 systems.
Consumers retrofitting their ballasts
commonly do so to save energy, and T8
systems are generally more efficacious
than T12 systems.
• New Construction and Renovation
(Event V): This event encompasses all
fixture installations where the lighting
design will be completely new or can be
completely changed. The scenario
applies only to baseline lamps that are
usually used in new construction and
renovation (4-foot T8 lamps, 4-foot T12
lamps in the residential sector, 8-foot
single pin slimline T8 lamps, and 8-foot
recessed double contact HO T12 lamps).
For the NOPR analysis, DOE assumed
that 4-foot T8 lamps with electronic
ballasts would be chosen during the
new construction and renovation event
for the 4-foot T12 residential baseline.
E. National Impact Analysis—National
Energy Savings and Net Present Value
Analysis
1. General
DOE’s NIA assesses the national
energy savings (NES) and the national
net present value (NPV) of total
customer costs and savings that would
be expected to result from new
standards at specific efficacy levels.
DOE uses the NIA spreadsheets to
calculate energy savings and NPV based
on the annual energy consumption and
total installed cost data employed in the
LCC analysis. DOE forecasts the energy
savings, energy cost savings, equipment
costs, and NPV for each product class
from 2012 through 2042. The forecasts
provide annual and cumulative values
for all four output parameters. DOE also
examines impact sensitivities by
analyzing various lamp shipment
scenarios (such as Roll-up and Shift).
DOE develops a base-case forecast for
each analyzed lamp type which
characterizes energy use and consumer
costs (lamp purchase and operation) in
the absence of new or revised energy
conservation standards. To evaluate the
impacts of such standards on these
lamps, DOE compares the estimated
base-case projection with projections
characterizing the market if DOE did
promulgate new or amended standards
(i.e., the standards case). In
characterizing the base and standards
cases, DOE considers historical
shipments, the mix of efficacies sold in
the absence of any new standards, and
how that mix might change over time.
Inputs and issues associated with the
NIA are discussed immediately below.
a. Overview of NIA Changes in This
Notice
Based on the comments it received on
the March 2008 ANOPR, DOE made a
number of changes to the NIA. Table V.3
summarizes the approach and data DOE
used to derive the inputs to the NES and
NPV analyses for the March 2008
ANOPR, as well as the changes it made
for this notice. Following the table, DOE
details those inputs and the changes,
and summarizes and responds to each of
the NIA-related comments it received.
See TSD chapters 10 and 11 for further
details.
TABLE V.3—APPROACH AND DATA USED TO DERIVE THE INPUTS TO THE NATIONAL ENERGY SAVINGS AND NET PRESENT
VALUE ANALYSES
Inputs
2008 ANOPR description
Shipments ............................
Annual shipments from shipments model .......................
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00040
Fmt 4701
Changes for the proposed rule
Sfmt 4702
See Table V.4 and Table V.5.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
16959
TABLE V.3—APPROACH AND DATA USED TO DERIVE THE INPUTS TO THE NATIONAL ENERGY SAVINGS AND NET PRESENT
VALUE ANALYSES—Continued
Inputs
2008 ANOPR description
Changes for the proposed rule
Stock of lamps .....................
Established based on the projected 2011 lamp stock,
the service life of lamps and/or ballasts, and the annual shipments. The 2011 stock is based on historical shipments and projected shipments from 2006 to
2011. (See ANOPR TSD chapter 10, shipments analysis.).
2012 ................................................................................
2012 to 2042 ...................................................................
Established in the energy-use characterization, ANOPR
TSD chapter 6, by lamp or lamp-and-ballast design
and sector.
Established in the product price determination, ANOPR
TSD chapter 7 and the LCC analysis, ANOPR chapter 8, by lamp-and-ballast designs.
AEO2007 forecasts (to 2030) and extrapolation for beyond 2030. (See ANOPR TSD chapter 8.).
Conversion varies yearly and is generated by AEO2007
forecasts (to 2030) of electricity generation and electricity-related losses. Conversion factors for beyond
2030 are extrapolated.
Established based on 2005 lamp stock, rather than
2011. Considered market penetration of emerging
technologies. See Table V.4 and Table V.5 for additional detail.
Effective date of standard ....
Analysis period .....................
Unit energy consumption
(kWh/yr).
Total installed cost ...............
Electricity price forecast .......
Energy site-to-source conversion.
HVAC interaction savings ....
Rebound effect .....................
Discount rate ........................
Present year .........................
6.25 percent of total energy savings in the commercial
sector.
1 percent of total energy savings in the commercial and
industrial sectors.
8.5 percent of total energy savings in the residential
sector.
3 and 7 percent real ........................................................
Future costs and savings are discounted to 2007 .........
2. Shipments Analysis
Lamp shipments are an important
input to the NIA. In the March 2008
ANOPR, DOE followed a four-step
approach to forecast shipments for
GSFL and IRL. 73 FR 13620, 13668
(March 13, 2008). First, DOE used
NEMA’s historical shipment data from
2001 to 2005 to estimate total historical
(NEMA members and non-NEMA
members) shipments of each analyzed
lamp type in the commercial, industrial,
and residential sectors. Second, using
No change.
No change.
No change.
Added costs of retrofit kit and labor for replacing a 8foot SP slimline system with two 4-foot MBP systems.
Updated for AEO2008.
Conversion varies yearly and is now generated by
DOE/EIA’s NEMS program (a time-series conversion
factor; includes electric generation, transmission, and
distribution losses).
Conversion factors for beyond 2030 are held constant.
No change.
No change.
No change.
No change.
these historical shipments, DOE linearly
extrapolated shipments to 2011. Then,
based on average service lifetimes, DOE
estimated a stock of lamps in 2011 for
each lamp type. Next, DOE forecasted
lamp (and ballast for GSFL) shipments
from 2012 to 2042 (the NIA analysis
period) based on four market events: (1)
New construction; (2) ballast failure
(GSFL only); (3) lamp replacement; and
(4) standards-induced retrofit (for the
standards case). Lastly, because these
shipments depend on lamp and lampsystem properties (e.g., lifetime and
lumen output), DOE developed basecase and standards-case market-share
matrices. These matrices determine the
forecasted technology mixes in the lamp
stock and shipments.
Table V.4 and Table V.5 summarize
the approach and data DOE used for
GSFL and IRL, respectively, to derive
the inputs to the shipments analysis for
the March 2008 ANOPR, as well as the
changes DOE made for the NOPR. A
discussion of the inputs and the changes
follows.
TABLE V.4—APPROACH AND DATA USED TO DERIVE THE INPUTS TO GSFL SHIPMENTS ANALYSIS
Inputs
2008 ANOPR description
Changes for the proposed rule
Historical shipments .............
2001–2005 shipment data provided publicly by NEMA.
Assumed NEMA data represented 90 percent of
GSFL shipments.
Calculated lamp inventory in 2011 by linearly projecting
NEMA’s 2001–2005 historical shipment data. Then
used growth and shipment assumptions to establish
lamp inventory from 2012 to 2042.
Shipment growth driven by lumen demand. Lumen demand projected from historical CBECS commercial
floor space growth.
Calibrated 2006–2007 forecasted shipments based on
confidential historical shipment data NEMA provided
for those years.
Did not use linear projections; calculated stock in 2005.
Then used growth, emerging technologies, and shipment assumptions to establish lamp inventory from
2006 to 2042.
Based commercial and residential growth on AEO2008
estimates for future floor space growth. For the residential sector, modeled variations in number of lamps
per new home. For the industrial sector, projected
floor space growth using MECS.
Shipments modeled by assuming T5 lamps used in
new construction and in conversions from 4-foot medium bipin, 8-foot SP slimline, and 8-foot RDC HO.
Lamp inventory ....................
Growth ..................................
T5 lamps ..............................
VerDate Nov<24>2008
19:12 Apr 10, 2009
Not included ....................................................................
Jkt 217001
PO 00000
Frm 00041
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
16960
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE V.4—APPROACH AND DATA USED TO DERIVE THE INPUTS TO GSFL SHIPMENTS ANALYSIS—Continued
Inputs
2008 ANOPR description
Changes for the proposed rule
T12 ballasts ..........................
Assumed no T12 magnetic ballasts shipped after 2009
for 8-foot SP slimline and 4-foot MBP lamps. Did not
consider T12 electronic ballasts for 8-foot SP slimline
and 4-foot MBP lamps.
Sectors analyzed .................
Base-case emerging technologies.
Commercial and industrial ..............................................
None included .................................................................
Market share matrices .........
Developed product distributions based on interviews
and catalog data.
Shift and Roll-up scenarios analyzed. Assumed all consumers will attempt to maintain lumen output by either moving to lower ballast factors or reduced-wattage lamps in the standards case.
Assumed no T12 magnetic ballasts shipped after 2010
for commercial 4-foot MBP and 8-foot SP slimline.
Also assumed 4-foot MBP and 8-foot SP slimline
electronic T12 ballasts shipped through 2042. For 8foot T12 RDC HO and residential 4-foot T12 MBP,
assumed magnetic ballasts are shipped through
2042.
Included residential sector in analysis.
Developed two base-case scenarios, one of which
modeled the market penetration of LEDs based on
projected payback period.
Revised product distributions based on comments, subsequent interviews, and further catalog research.
Revised the Shift and Roll-up scenarios. Developed a
standards-case scenario (Market Segment-Based
Lighting Expertise scenario) to characterize consumers who, based on lighting expertise, will not migrate to lower ballast factors or reduced-wattage
lamps to maintain lumen output.
Standards case scenarios ...
TABLE V.5—APPROACH AND DATA USED TO DERIVE THE INPUTS TO IRL SHIPMENTS ANALYSIS
Inputs
2008 ANOPR description
Changes for the proposed rule
Historical shipments .............
2001–2005 shipment data provided publicly by NEMA.
Assumed NEMA data represented 85 percent of IRL
shipments.
Calculated stock in 2011 by linearly projecting NEMA’s
2001–2005 historical shipment data. Then used
growth assumptions to establish lamp inventory from
2012 to 2042.
Shipment growth driven by socket growth. Socket
growth projected from historical CBECS commercial
floor space and RECS residential building growth.
Calibrated 2006–2007 projected shipments based on
confidential historical shipment data NEMA provided
for those years.
Did not use linear projections; calculated stock in 2005.
Then used growth and emerging technologies assumptions to establish lamp inventory from 2006 to
2042.
Based growth on AEO2008 estimates for future commercial floor space and residential buildings.
Also accounted for trend of increasing sockets per
home.
No change.
Developed two base-case scenarios modeling the market penetration of LED, CMH, and R–CFL based on
projected payback period.
Lamp inventory ....................
Growth ..................................
Sectors analyzed .................
Base case reflector compact
fluorescent lamps (R–
CFL) and emerging technologies.
Market share matrices .........
Standards-case scenarios ...
Commercial and residential ............................................
Assumed 0 percent stock penetration in 2012 and 50
percent stock penetration in 2042.
Considered mix of technologies consumers select in
the base case and standards case, as well as each
of the scenarios analyzed.
Modeled the Roll-up scenario. ........................................
Analyzed two standards-case sensitivity scenarios: One
modeling consumer movement to exempted BR
lamps and another modeling a 10 percent increase in
lumen output. Did not consider additional migration to
R–CFL in the standards case.
a. Lamp Inventory
In the March 2008 ANOPR, DOE
linearly extrapolated NEMA’s historical
lamp shipments from 2005 to 2011 to
establish a 2011 installed stock of GSFL
and IRL using each lamp’s average
service lifetime. In its written
comments, NEMA argued that DOE’s
linear extrapolation approach does not
account for market dynamics and is
vulnerable to certain temporal biases
inherent in NEMA’s historical data. For
example, if a new product was
introduced and rapidly gained market
share during this historical shipment
period, a linear extrapolation based on
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Revised market-share matrices to reflect its changes in
the scenarios analyzed and engineering analyses.
Modeled both Roll-up and Shift scenarios.
Revised BR lamp sensitivity scenario, creating two new
standards-case scenarios also accounting for additional migration to R–CFL: ‘‘Product Substitution’’ and
‘‘No Product Substitution.’’
this data could exaggerate the growth
rate of this product in future years.
Likewise, any new products introduced
would be excluded from the future
results. For example, Philips noted at
the public meeting that because DOE
extrapolated shipment data from 2001 to
2005 to establish its lamp stocks, it may
have discounted migration to T5 lamps,
which have only started to grow in the
last couple of years. Thus, the
commenter argued that DOE may have
overstated the 2011 stock of some types
of lamps (e.g., T8 lamps), while
understating others (e.g., T5 lamps).
(NEMA, No. 22 at pp. 23–25, 31; Public
Meeting Transcript, No. 21 at p. 246)
PO 00000
Frm 00042
Fmt 4701
Sfmt 4702
On the other hand, NEMA suggested
that a linear extrapolation is sometimes
appropriate for lamps with small and
stable market shares, such as 8-foot T8
recessed double contact HO lamps.
However, for large and variable product
classes, NEMA urged DOE to model
lamp types against specific economic
factors and technical relationships.
(NEMA, No. 22 at p. 24)
DOE agrees that a linear extrapolation
may generally be too limited in its
application, and that lamp shipment
forecasts from 2006 to 2011 should
incorporate both market dynamics and
macroeconomic factors. Therefore, DOE
is no longer using a linear extrapolation
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
from historical data. Instead, for this
NOPR, DOE calculated an installed
stock of lamps in 2005 and applied
growth, replacement rate, and emerging
technologies assumptions to develop
shipments estimates from 2006 to 2042.
In addition, DOE received confidential
shipment information from NEMA for
2006 and 2007, and, when possible,
calibrated the shipments model to
match that information. The
assumptions used to develop shipment
forecasts are discussed in the following
sections.
b. Shipments Growth
To develop the shipments models for
both GSFL and IRL, DOE applied
several growth rate assumptions. In the
March 2008 ANOPR, DOE modeled
GSFL shipments from 2012 to 2042 by
projecting lumen growth based on
lumen demand serviced by each lamp
type in the commercial and industrial
sectors. For IRL, DOE projected
shipments through 2042 based on
growth in the number of sockets using
IRL in the commercial and residential
sectors. DOE based forecasted lumen
and socket growth for GSFL and IRL on
historical residential building growth
from RECS and historical commercial
and industrial floor space growth from
CBECS and MECS.
DOE received a number of comments
in response to its growth rate
methodology. The majority of these
comments fell into three categories: (1)
The limits of basing lamp stock growth
on historical floor space growth; (2) the
increasing number of lamps per
household; and (3) the wider spacing of
more-efficient light fixtures. Below is a
discussion of those comments. For
further details regarding GSFL and IRL
growth rate assumptions, see TSD
chapter 10.
i. Floor Space and Building Growth
NEMA stated that the commercial and
residential growth rates DOE used in the
March 2008 ANOPR (based on total
floor space from CBECS in RECS) have
likely led to an overstatement of lamp
shipments and stock, given the
deteriorating economy. (NEMA, No. 22
at pp. 23–24) DOE understands NEMA’s
concerns and no longer establishes its
commercial and residential growth from
historical floor space growth. Instead,
for this NOPR, DOE modeled
commercial floor space and residential
buildings growth based on AEO2008,
which estimates year-to-year
commercial floor space and residential
building growth. Because AEO2008
takes into account future trends in
economic growth, DOE was able to
incorporate forecasts of macroeconomic
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
conditions in its growth forecast.
However, because AEO does not
provide industrial floor space forecasts,
DOE used historical MECS floor space
values to establish a growth rate for the
industrial sector.
ii. Lamps per Household
The Joint Comment stated that DOE’s
growth forecasts omitted an important
factor driving IRL sales: a trend toward
an increasing number of recessed
fixtures per home in new construction
and existing home renovation. Because
this trend is excluded from DOE’s
analysis, which assumed growth based
on floor space growth, the Joint
Comment argued that IRL shipments are
likely understated. NEMA also stated
that it has seen a trend toward
increasing light points per home. To
address this development, the Joint
Comment recommended DOE obtain
additional data on sales trends of these
lamps and not assume recessed socket
growth was directly proportional to
floor space growth. The Joint Comment,
PG&E, and ACEEE cited several studies
supporting this claim. (Joint Comment,
No. 23 at p. 17; Public Meeting
Transcript, No. 21 at pp. 287–288;
NEMA, No. 22 at p. 31)
DOE agrees with the Joint Comment
that the increasing popularity of
recessed fixtures in new homes will
drive IRL sales growth faster in the
residential sector. New homes are likely
to install more IRL than those installed
in older homes, and older homes may be
renovated to include more recessed cans
and, thus, more reflector lamps.
Therefore, DOE conducted an analysis
that estimated the average number of
recessed cans in homes between 2005
and 2042. Using California data 49 on
recessed cans per home broken out by
home age, DOE assumed new homes
constructed after 2005 would install the
same number of recessed cans as homes
constructed between 2001 and 2005.
DOE also assumed that half of the
homes constructed before 2001 would
be renovated by 2042 to have an equal
number of recessed cans as newly
constructed homes. DOE estimated the
distribution of homes by age using U.S.
Census data 50 on new building starts in
the residential sector. DOE estimated
new construction and the number of
future homes constructed in each year
49 RLW Analytics, Inc., ‘‘California Statewide
Residential Lighting and Appliance Efficiency
Saturation Survey’’ (August 2005) (Last accessed on
Sept. 29, 2008). Available at: https://
www.calresest.com/docs/2005CLASSREPORT.pdf.
50 U.S. Census Bureau, Manufacturing and
Construction Division, ‘‘New Privately Owned
Housing Unit Starts’’ (2008) (Last accessed on Sept.
29, 2008). Available at: https://www.census.gov/
const/startsan.pdf.
PO 00000
Frm 00043
Fmt 4701
Sfmt 4702
16961
from AEO2008. Using this data, DOE
estimated that the average number of
recessed cans per home in 2005 was
4.82, and the average number of
recessed cans per home in 2042 will be
8.52. As noted above, DOE also agrees
with NEMA that growth rates should
include forecasts of economic
conditions. Therefore, to estimate the
growth rate in each year, DOE
multiplied the number of recessed cans
in homes by the projected stock of
homes according to AEO2008.
Combining these two sources, DOE
predicts an average growth rate of
sockets of 2.6 percent between 2006 and
2042, compared to the 1.6 percent DOE
estimated in the March 2008 ANOPR.
DOE estimated the GSFL growth rate
in the residential sector using a
methodology similar to that which it
employed for IRL in the residential
sector. Instead of using the number of
recessed cans per home by home age,
DOE used the number of T8 and T12
lamps by home age. Again, DOE
assumed that the same number of T8
and T12 lamps per home would be
installed in new homes as those
installed between 2001 and 2005, and
that half of homes built before 2001
would be renovated by 2042 to have the
same number of T8 and T12 lamps as
newly constructed homes. DOE
estimated that the average number of T8
and T12 lamps per home in 2005 was
4.5, and the average number in 2042
will be 4.7. Combining this growth
estimate with AEO2008’s projected
growth in the residential home stock
yields an average growth rate of 1
percent between 2006 and 2042 for
GSFL in the residential sector.
Compared to IRL, the lower GSFL
growth rate reflects the lower growth
rate of T8 and T12 lamps per home
versus recessed cans. (In the March
2008 ANOPR, DOE did not consider the
residential sector for GSFL.)
iii. Wider Spacing of More-Efficient
Fixtures
In its written comments, NEMA
suggested that DOE should assume a
slower growth rate in the commercial
building IRL socket base to account for
wider spacing of lighting fixtures and/
or greater use of high-output systems.
(NEMA, No. 22 at p. 31) While DOE
appreciates NEMA’s comment, it was
unable to find (and the commenter did
not provide) any information related to
wider spacing between fixtures, and,
therefore, DOE did not change growth
estimates to account for this potential
effect.
E:\FR\FM\13APP2.SGM
13APP2
16962
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
c. Base-Case Scenarios: Emerging
Technologies and Existing Technologies
In the March 2008 ANOPR, DOE
estimated that by 2042 R–CFL and
emerging technologies, (e.g., such as
LED lamps, and ceramic metal halide
(CMH) lamps) would compose 50
percent of IRL sockets in the installed
base. 73 FR 13620, 13670 (March 13,
2008). For IRL, DOE accounted for the
impact of emerging technologies by
deducting their market share in each
year over the analysis period from the
installed base of lamps, effectively
reducing the size of the market affected
by the standards proposed in this
rulemaking. In the March 2008 ANOPR,
DOE did not account for any penetration
of emerging technologies into the GSFL
market, and requested comment on if
and how it should incorporate their
effects into its analyses.
DOE received several comments on its
consideration of emerging technologies.
NEMA argued that the performance
improvements of CMH will drive the
technology’s market penetration into the
GSFL market. NEMA also asserted that
LED lamps could displace GSFL
shipments to some extent by 2042.
(NEMA, No. 22 at pp. 24–26) As for
emerging technologies in the IRL
market, NEMA commented that LED
lamps could also displace shipments of
IRL to some extent by 2042, particularly
in the residential sector. NEMA stated
that the shift from halogen IRL to CMH
is already occurring in the retail market.
Industrial Ecology stated that an
integrated PAR CMH lamp would be
expected to replace other IRL PAR
lamps in the commercial retail market.
(NEMA, No. 22 at pp. 24–26; Public
Meeting Transcript, No. 21 at pp. 307–
309) NEMA argued that these emerging
technologies will significantly affect
future lamp shipments and reduce the
NPV results of standards for both GSFL
and IRL. To more accurately forecast the
impact of emerging technologies, NEMA
suggested that DOE should examine
historical price and performance points
of R–CFL, as well as product cycles for
other advanced technology equipment.
(NEMA, No. 22 at pp. 24–26) Industrial
Ecology suggested that DOE should use
semiconductor industry data to assess
the manufacturing capacity for solid
state lamps. (Public Meeting Transcript,
No. 21 at p. 311–312)
DOE agrees that emerging
technologies could penetrate GSFL and
IRL markets and significantly affect
shipment forecasts and NIA results.
Therefore, for the NOPR, DOE has
revised its analysis of emerging
technologies within the IRL market and
now accounts for emerging technologies
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
within the GSFL market as well. These
emerging technologies already are, or
eventually will likely be, significantly
more efficacious and longer lasting than
the lamps they replace. However, to
calculate the energy savings and NPV
benefits due to the penetration of an
emerging technology, DOE must
accurately forecast the anticipated price
and performance points of the
individual technologies—a difficult and
highly speculative task. Forecasts
related to emerging technologies are
inherently uncertain because they
depend upon assumptions about future
price, efficacy, and utility, none of
which can be verified. Therefore, for the
NOPR, DOE has chosen to analyze two
base-case scenarios for both GSFL and
IRL: (1) Existing Technologies, and (2)
Emerging Technologies. DOE believes
evaluating two base-case scenarios more
completely characterizes the inherent
uncertainty of the market penetration of
the technologies and the consequent
impact on NPV and NES. Incorporating
emerging technologies in the base case
does not affect the relative benefits of
each TSL and prevents uncertain
projections of market share, price, or
performance from obscuring the benefits
derived from more-efficient GSFL and
IRL alone.
For these base-case scenarios, DOE
estimated the market penetration of
three specific technologies into the
projected installed stock: (1) LED lamps;
(2) CMH lamps; and (3) reflector CFL. In
general, the Existing Technologies
scenario only considers the market
penetration of technologies that are
currently readily available and have
reached maturation in terms of price
and efficacy. Specifically, DOE
considers R–CFL in the Existing
Technologies scenario within the IRL
market. For GSFL, no technologies other
than those covered by this rulemaking
were analyzed in the Existing
Technologies scenario. (DOE considers
the migration to T5 lamps, a covered
product, separately, as discussed in
section V.E.2.d.)
In the Emerging Technologies
scenario, DOE attempts to forecast the
market penetration of mature
technologies and those technologies that
are still undergoing significant changes
in price and efficacy. Specifically, DOE
considered the market penetration of R–
CFL, LED lamps, and CMH lamps in the
Emerging Technologies scenario.
DOE generally followed a 5-step
process for each scenario to estimate the
market penetration of the analyzed
technologies and account for their
impact on NES and NPV. (Sector- and
technology-specific aspects of DOE’s
PO 00000
Frm 00044
Fmt 4701
Sfmt 4702
methodology are described below and in
TSD chapter 10.)
First, DOE developed price,
performance, and efficacy forecasts for
each of the analyzed technologies.
DOE’s methodology in generating these
forecasts for each analyzed technology
is described below. Second, using those
estimates, DOE calculated the payback
period (PBP) of each technology in the
relevant sector using the difference
between its purchase price, annual
electricity cost, and annual lamp
replacement cost relative to the lamp it
replaces. (See TSD chapter 10 for further
details.) Third, DOE used a relationship
between PBP and market penetration to
predict the market penetration of each
technology in the relevant sector in
every year from 2006 to 2042. Generally,
lower PBP of a given lamp technology
results in a greater predicted market
penetration of that technology. DOE
used a 5-year average of the market
penetrations predicted by the
relationship as its final market
penetration. The 5-year average
represents the time DOE assumed it
takes products with lower PBPs to
penetrate the market. Fourth, when
necessary, DOE applied a scaling factor
to the predicted market penetration to
account for observed market trends.
Fifth, DOE reduced the projected
installed stock of covered products in
each year by the value that
corresponded to the highest level of
market penetration achieved in each
year by one of the analyzed
technologies. Thus, the inclusion of R–
CFL and other lamps using emerging
technologies in the base case have the
effect of lowering the energy savings of
a potential new standard. For those
covered lamps remaining, the costeffectiveness of LCC savings and, thus,
the relative cost effectiveness of each
TSL is not affected.
Because the lamps employing
emerging technologies are beyond the
scope of the rulemaking, they are not
considered design options to improving
IRL or GSFL efficacy, but rather they
may substitutes for the lamps covered in
this rulemaking. In the Emerging
Technologies base case, DOE uses its
prices projections effectively as inputs
into its shipments forecasts of its
covered products, rather than forecasts
of shipments of lamps employing the
emerging technologies themselves. In
this way, the price projections of the
analyzed lamps using emerging
technologies indirectly affect the NPV of
the present rulemaking, despite not
being a direct input into equipment
prices. As stated previously, to
acknowledge the uncertainty of price
forecasts for lamps using emerging
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
technologies, DOE models two base-case
scenarios.
i. General Service Fluorescent Lamps
For the Existing Technologies
scenario, DOE believes that no mature
technologies in the current market show
the potential to significantly penetrate
the GSFL market. (T5 lamps, previously
considered an emerging technology, are
now a covered product class.) Therefore,
for the Existing Technologies scenario,
DOE considered only the fluorescent
technologies already covered by this
rulemaking. Thus, except for the
addition of T5 lamps, the Existing
Technologies base case in this NOPR is
the same as the base case in the March
2008 ANOPR.
In the GSFL Emerging Technology
scenario, however, DOE separately
considered the potential market
penetration of two technologies: (1)
LEDs (into the commercial, residential,
and industrial sectors); and (2) CMH
(into the commercial and industrial
sectors).
For its analysis of LED market
penetration, DOE found a commerciallyavailable retrofit kit that included a LED
replacement for a 4-foot medium bipin
system. DOE used the retrofit kit as a
current baseline from which to project
future cost, efficacy, and price points.
DOE interviewed an integrated circuit
manufacturer to develop cost estimates
for LED driver circuits. For cost
estimates of other components, DOE
used prices of existing LED products
already on the market, which it
modified in accordance with cost data
and efficacy projections from DOE’s
Solid State Lighting Multi-Year Program
Plan.51 Lastly, using markup based on
currently-available LED lamps, DOE was
able to develop price and efficacy
projections for the LED luminaire in the
retrofit kit.52 Following the 5-step
process described above, DOE
calculated a 41 percent market
penetration rate of LED lamps into the
4-foot GSFL commercial sector by 2042.
DOE assumed LED lamps penetrated
only the new construction, renovation,
and fixture replacement markets
because these lamps would require their
own specific fixtures. In the residential
sector, the LED option did not have a
51 Multi-Year
Program Plan FY’09 to FY’14: SolidState Lighting Research and Development (March
2008). Available at: https://www.netl.doe.gov/ssl/
PDFs/SSLMYPP2008_web.pdf.
52 Because they are based on an existing LED
retrofit kit, DOE’s projections did not consider
innovations in form factor on OLED tyechnology
which could improve the possible payback period
for solid-state lighting technologies.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
low enough payback period to result in
any market penetration.
DOE also analyzed the potential
penetration of CMH into the GSFL
market. DOE first estimated current
CMH prices using a methodology
similar to the methodology it used to
estimate GSFL and IRL prices, as
described in the product price
determination. (See TSD chapter 7.)
Industry experts informed DOE that
CMH efficacies and lifetimes would
increase over the next several years
while prices would remain constant.
Applying these lifetime and efficacy
projections DOE compared CMH
replacements to GSFL systems. As a
result, DOE assumed no market
penetration of CMH because it found
that T5 lamp systems (standard output
and high output) would always be less
costly and more efficacious than
projected CMH replacements. Given this
information, DOE believes that it is
likely that migration to CMH (from the
GSFL market) will be dominated by the
migration to standard-output and highoutput T5 lamps.
ii. Incandescent Reflector Lamps
As with GSFL, DOE considered two
base case scenarios for IRL: Existing
Technologies and Emerging
Technologies. Because DOE believes
that R–CFL is a mature technology with
relatively stable price points and
efficacies, DOE considered R–CFL
penetration into the residential market
in the Existing Technologies scenario. In
contrast, for the Emerging Technologies
scenario, DOE considered the market
penetration of R–CFL, LED, and CMH
lamps in both the residential and
commercial sectors. DOE separately
calculated the penetration of each
technology into the IRL stock by using
the 5-step process described above.
For R–CFL, DOE developed price
forecasts based on historical pricing
trends of CFL and R–CFL, using a
methodology similar to the methodology
DOE used to estimate GSFL and IRL
prices, as described in the product price
determination. (See TSD chapter 7.)
DOE assumed no future change in
efficacy. Using this data, DOE found the
market penetration predicted by the PBP
relationship. However, PG&E argued
that R–CFL are not always suitable
substitutes for IRL because they lack
dimming capabilities and their beam
width is too broad. (Public Meeting
Transcript, No. 21 at pp. 289, 321)
Industrial Ecology commented that
dimmable R–CFL do in fact exist, while
PG&E noted that these lamps have little
market share. (Public Meeting
Transcript, No. 21 at pp. 291, 321) DOE
agrees that R–CFL may not always be
PO 00000
Frm 00045
Fmt 4701
Sfmt 4702
16963
appropriate substitutes for IRL, due to
differences in form factor, beam spread,
color quality, size and dimming
capability. DOE observed that the actual
market penetration of CFL replacements
for A-line incandescent lamps thus far
has been approximately 40 percent of
the penetration predicted by the PBPpenetration relationship. Therefore,
DOE applied these same scaling-factor
reductions of 40 percent and 36 percent
in calculating the market penetration of
R–CFL into the IRL market for the
residential and commercial sectors,
respectively.
For LED and CMH lamps in the IRL
market, DOE developed price and
efficacy forecasts using a methodology
similar to the one described above for
GSFL. DOE did not apply the scaling
factor reduction to the predicted LED
and CMH market penetration rates that
it used for the R–CFL analysis. DOE
believes the substitutability problems
that arise when R–CFL replace IRL do
not apply when LED and CMH replace
IRL.
By the methodology described, DOE
arrived at market penetration values
(and market size reductions) for each
base-case scenario. For the Existing
Technology scenario, 2042 R–CFL
penetration reached 38 percent in the
residential sector and 20 percent in the
commercial sector. (This was the
highest market penetration because it
was the only technology analyzed for
the scenario.) For the Emerging
Technology scenario, LED reached the
highest market penetration of any
analyzed technology in both the
residential sector and the commercial
sector. DOE’s analysis found LED lamps
could penetrate 40 percent and 82
percent of the IRL installed stock by
2042 in the residential and commercial
sector, respectively. DOE’s results
support a comment by Industrial
Ecology stating that emerging
technologies will enter the commercial
market first. (Public Meeting Transcript,
No. 21 at p. 308) This effect occurs
because there are higher installation and
operating costs in the commercial sector
relative to the residential sector,
resulting in lower PBPs and faster
migration to emerging technologies.
Again, DOE used these results to
effectively reduce the size of the IRL
market for its analysis.
d. Fluorescent Market Sectors Analyzed
In the March 2008 ANOPR, DOE
modeled both the commercial and
industrial market sectors to generate
GSFL shipments forecasts. DOE
received several comments on its
decision not to model the residential
sector.
E:\FR\FM\13APP2.SGM
13APP2
16964
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
GE commented that DOE should
model the residential sector because it
makes substantial use of less-efficacious
T12 lamps, which could be effectively
eliminated by new standards. GE
estimated that by 2012, roughly 20
percent of GSFL shipments will be T12
lamps, and more than half of those will
go to residential consumers. PG&E
stated that California codes only
recently required higher-efficacy lamps
in new construction; therefore, 4-foot
T12 lamps with magnetic ballasts
remain a large part of the residential
installed stock. (Public Meeting
Transcript, No. 21 at pp. 276–279)
The Joint Comment asserted that a
separate analysis for the residential
sector is unnecessary; however, the Joint
Comment recommended that residential
applications should be accounted for in
DOE’s LCC analysis based on the
proportion of lamp sales, operating
hours, and electric rates. The Joint
Comment stated DOE should use
caution in apportioning all sales
through do-it-yourself (DIY) stores, such
as Home Depot and Lowe’s, to the
residential sector. (Joint Comment, No.
23 at p. 10) PG&E and NEMA
commented that approximately 20
percent of DIY business is commercial.
(NEMA, No. 22 at p. 30; Public Meeting
Transcript, No. 21 at p. 290)
DOE agrees that it should model the
residential sector to more accurately
capture overall consumer behavior and
the market impact of standards. DOE
calculated the initial residential stock of
4-foot medium bipin T12 lamps using
the lamps sold through the DIY
distribution chain, which accounted for
approximately 25 percent of NEMA’s
historical shipments. Next, DOE
assumed 20 percent of those DIY sales
went to small commercial consumers,
with the remaining 80 percent
apportioned to the residential sector. As
a result, DOE assumed 20 percent of all
4-foot medium bipin shipments went to
the residential sector and all of those
were T12 lamps.
From those shipments, DOE
calculated the residential installed stock
and then modeled new construction,
renovation, and fixture/ballast
replacement in the same manner
described in section 0. DOE assumed
that in the base case, a portion of
consumers will continue to purchase 4foot T12 magnetic systems, while the
remaining consumers will choose to
purchase higher-efficacy 4-foot T8 and
4-foot T12 electronic systems. Overall,
the number of 4-foot T12 systems
installed in the residential sectors is
relatively constant over the analysis
period. For more details regarding
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
DOE’s assumptions in the residential
sector, please see chapter 10 of the TSD.
e. GSFL Product Migration
DOE received many comments on its
assumptions characterizing how
consumers will migrate among different
GSFL products. These comments were
primarily focused on the movement
away from T12 systems and the
migration toward T5 systems, topics
discussed in detail below.
i. Ballast Rule Effective Start Date
NEMA commented that the 2000
Ballast Rule does not ban T12 magnetic
ballasts in the commercial sector until
June 2010. This means these ballasts
will be available through the end of
2010, and not 2009 as DOE’s model had
assumed, because some T12s will
remain in the distribution chain for a
period of months after the rule takes
effect. Therefore, NEMA argued, DOE
should expect T12 lamps to continue to
be shipped beyond 2022, the year DOE
projected the lamps will phase out.
(NEMA, No. 22 at p. 25, 28) DOE agrees
with NEMA that commercial sector
magnetic ballasts will continue to be
available through 2010 and has revised
its model accordingly to better reflect
the timing of the 2000 Ballast Rule’s
effective start date of amended
standards. According to the revised
model, DOE estimates that the majority
of banned magnetic T12 ballasts will be
eliminated from the installed stock by
2025. However, as discussed below, the
inclusion of T12 electronic ballasts
results in T12 lamps being shipped
throughout the analysis period.
ii. Four-Foot Medium Bipin T12 Lamp
Replacements
In the March 2008 ANOPR, DOE
assumed that 100 percent of 4-foot T12
systems would be replaced by 4-foot T8
systems upon ballast failure. This
assumption was made in consideration
of the 2000 Ballast Rule, which
effectively banned most 4-foot T12
medium bipin magnetic ballasts. 10 CFR
part 430.32(m)(5) DOE received several
comments related to this assumption
and the implications for DOE’s GSFL
shipments analysis.
Stakeholders generally agreed that
DOE’s base-case assumption was too
optimistic in terms of the migration
from 4-foot T12 to 4-foot T8 systems.
The comments provided two reasons
why consumers would be expected to
maintain T12 electronic ballasts and not
migrate to T8 lamps. First, because the
installed stock is dominated by T12
lamps, it is unlikely all consumers
would switch to T8 lamps upon
repurchase, especially when spot re-
PO 00000
Frm 00046
Fmt 4701
Sfmt 4702
ballasting. Some commercial sector
consumers would be expected to use
another T12 lamp and ballast to
maintain visual consistency with other
lamps in a room. Second, the Joint
Comment noted that residential lowpower-factor ballasts are not subject to
the 2000 Ballast Rule, meaning legal
ballasts compatible with T12 lamps will
continue to exist. 10 CFR part
430.32(m)(7)(iii). Similarly, Osram
Sylvania made the same point and
commented that 4-foot T12 medium
bipin magnetic ballast systems are
common in the residential sector. Osram
Sylvania added that some fixtures
include electronic ballasts and are
marketed as being capable of operating
T12 lamps, which could perpetuate T12
usage. NEMA added that cold
temperature ballasts for 8-foot T12 RDC
high output lamps are still allowed
under the rule as well. (Public Meeting
Transcript, No. 21 at pp. 248–251, 276,
281; NEMA, No. at pp. 25, 28; Joint
Comment, No. 23 at p. 7)
The stakeholders did differ slightly on
the appropriate replacement rates that
DOE should assume. The Joint
Comment recommended DOE assume 5
to 10 percent of the commercial market
and a higher proportion of the
residential market will purchase T12
lamp and ballast systems upon ballast
failure, with the remainder migrating to
T8 systems. (Joint Comment, No. 23 at
p. 7) GE estimated that about 20 percent
of the currently installed base of T12
lamps will be replaced by T12 lamps,
while the other 80 percent will migrate
to T8 lamps. (Public Meeting Transcript,
No. 21 at pp. 250–252) NEMA suggested
that DOE should assume that in 2022,
T12 lamps will compose at least 10
percent of the 4-foot lamp market, 40
percent of the 8-foot single pin slimline
market, and over 90 percent of the RDC
HO market. (NEMA, No. 22 at p. 28)
After careful consideration of these
comments, DOE has decided to modify
its assumption regarding the rate of
migration from T12 to T8 lamps.
Accordingly, DOE is using NEMA’s
estimates to recalibrate its shipment
forecasts. DOE now agrees that not all 4foot T12 lamps would be replaced by T8
systems upon ballast failure. Thus, for
this NOPR, DOE assumed 90 percent
(down from 100 percent) of 4-foot T12
systems will be replaced with T8
systems and 10 percent with T12
systems. According to DOE’s estimates
in 2022, T12 lamps will comprise nearly
20 percent of the 4-foot medium bipin
market, 25 percent of the 8-foot single
pin slimline market, and 93 percent of
the 8-foot recessed double contact HO
market. (See TSD chapter 10.) DOE
notes that these estimates do not exactly
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
align with NEMA’s suggestions, because
they incorporate several other
phenomena in addition to the migration
to T12 electronic systems (e.g., growth
rate, emerging technologies, T5
penetration, 8-foot SP slimline to 4-foot
MBP conversions).
iii. Eight-Foot Single Pin Slimline T12
Lamp Replacements
For its shipments forecasts in the
March 2008 ANOPR, DOE assumed that
90 percent of the 8-foot T12 single pin
systems would be replaced with two 4foot T8 systems, and 10 percent would
be replaced by 8-foot single pin T8
systems. In its written comments,
NEMA generally agreed with DOE’s
assumption but provided slightly
different replacement rate: NEMA
suggested that DOE should assume 80
percent of the 8-foot T12 single pin
lamps would be replaced by two 4-foot
T8 lamps and 20 percent by 8-foot T8
lamps. (NEMA, No. 22 at p. 28) ACEEE
and the Joint Comment argued that
DOE’s assumption that 90 percent of the
8-foot market would switch to 4-foot
lamps is much too high, particularly
because the current stock is dominated
by T12. The Joint Comment also stated
that DOE should include some
electronic T12 system ballast purchases,
as in the case of 4-foot T12 lamps.
(Public Meeting Transcript, No. 21 at
pp. 254–255; Joint Comment, No. 23 at
p. 7)
Based on its consideration of the
above comments, DOE revised its
estimated conversion rates for 8-foot
single pin slimline systems in this
NOPR. In line with the Joint Comment
and NEMA’s recommendations, DOE
lowered its conversion rates to 4-foot
MBP systems. In addition, consistent
with NEMA’s suggestion, DOE has
included a conversion to electronic 8foot T12 SP slimline systems. DOE now
assumes 80 percent of the 8-foot T12
single pin lamps would be replaced by
two 4-foot MBP T8 systems, with the
remaining 20 percent split evenly
between 8-foot T8 and electronic 8-foot
T12 SP slimline systems.
iv. Four-Foot T5 Lamps
In the March 2008 ANOPR, DOE did
not analyze 4-foot miniature bipin T5
standard output (SO) and high output
(HO) lamps as covered product classes.
As discussed in section A.1.b above, for
this NOPR, DOE is proposing to cover
both T5 SO and T5 HO lamps as
additional, distinct product classes. The
following describes the methodology
DOE used to generate shipments of
these lamps.
To establish the 2005 installed stock
of T5 lamps, DOE first estimated 2001-
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
to-2005 shipments based on
assumptions derived from its market
research and supported by manufacturer
interviews. Market literature indicated
that T5 lamps represented 2 percent of
the 2004 GSFL market, a figure DOE
assumed for its analysis. DOE’s research
also indicated that the combined market
share of T5 SO and HO lamps was
growing as a percentage of the overall
GSFL market. Additionally, in
interviews, manufacturers provided
insight on the proportions of T5 lamp
sales that are standard output and high
output. Using these assumptions, DOE
generated historical shipment estimates
for 2001 to 2005, which it used to
calculate the initial stock of SO and HO
lamps in the same manner it does for all
other GSFL product classes. Finally,
DOE received confidential aggregated
(both SO and HO) T5 lamp shipment
data from NEMA for 2001 to 2007. DOE
used this data to validate its installed
stock estimates.
In general, after establishing the 2005
T5 SO and HO installed stocks, DOE
modeled shipment growth based on a
migration from other product classes.
For T5 SO lamps specifically, DOE’s
research indicated that shipment growth
of these lamps is primarily driven by a
migration from the 4-foot MBP market.
In addition, because 4-foot T5 MiniBP
SO systems require a different fixture
than 4-foot MBP systems, T5 systems
would be unlikely to penetrate the
ballast-only replacement market.
Therefore, to establish T5 standard
output shipments, DOE allotted a
portion of the 4-foot MBP fixture
replacement, renovation, and new
construction markets to 4-foot T5
MiniBP systems. To do this, DOE first
calculated the size of this potential
market for new T5 SO systems in each
year. DOE then determined the portion
of this market that would actually be
serviced by T5 SO lamps by calculating
the share that resulted in T5 shipments
consistent with 2006 and 2007 historical
data. DOE held the resulting percentage
(approximately 12.5 percent) constant
throughout the analysis period. As a
result of the inclusion of 4-foot T5
MiniBP lamps eroding part of the 4-foot
MBP market, estimates of total 4-foot
MBP lamp shipments are lower in the
NOPR than in the ANOPR. Using this
methodology, in the base case Emerging
Technologies scenario, DOE forecasts T5
SO shipments of 15.0 million in 2008,
24.2 million in 2012, and 47.4 million
in 2025 (56.2 million in 2025 in the
base-case Existing Technologies
scenario).53
53 As discussed earlier, DOE models two basecase shipment scenarios: Existing Technologies and
PO 00000
Frm 00047
Fmt 4701
Sfmt 4702
16965
For T5 HO lamps, after establishing
the installed stock in 2005 in the same
manner as with T5 SO lamps, DOE
developed 4-foot T5 MiniBP HO lamp
shipments by modeling a migration
from two different lighting markets.
Marketing literature indicated, similar
to 8-foot RDC HO systems, a large
portion of 4-foot MiniBP T5 HO systems
serve high-bay (ceilings higher than 20feet high) applications due to their
highly-concentrated light output.
Historical shipment data for 8-foot RDC
HO lamps showed substantial declines
in 2006 and 2007, indicating T5 HO
lamps may be rapidly displacing them.
In addition, DOE’s research indicated
that a significant portion of 4-foot T5
HO growth can be attributed to a
penetration into the high intensity
discharge (HID) lamp high-bay and lowbay markets. Therefore, to calculate the
growth in 4-foot MiniBP T5 HO lamp
shipments, DOE assumed that these
systems were penetrating both the 8-foot
RDC HO and HID markets. Similar to its
analysis for T5 SO systems, DOE
established that the fixture replacement,
renovation, and new construction
market segments represent the available
market for T5 HO systems. DOE
obtained HID shipment data from the
2004 HID determination,54 from which
DOE calculated the total lumens
servicing low-bay and high-bay
applications. Then, consistent with
historical T5 and 8-foot RDC HO
shipments, DOE assumed T5 HO would
fully penetrate the 8-foot RDC HO new
construction, renovation, and fixture
replacement markets, as well as the HID
new construction and renovation
market. Using this methodology, DOE
forecasts T5 HO shipments of 14.0
million in 2008, 23.6 million in 2012,
and 46.1 million in 2025.
For further details on shipment
forecasts of 4-foot T5 lamps, see chapter
10 of the TSD. DOE seeks public
comment on its analysis of the 4-foot T5
SO and HO markets, as well as its
shipment results.
Emerging Technologies. Because the Emerging
Technologies scenario models the potential
substitution of GSFL systems with lamps that
incorporate emerging technologies (such as LED),
the Emerging Technologies scenario generally
results in fewer shipments of GSFL. However, based
on price and technology advancement projections,
DOE estimated that these emerging technologies
will not likely significantly penetrate the GSFL
market until after 2012.
54 U.S. Department of Energy, Office of Energy
Efficiency and Renewable Energy, ‘‘Energy
Conservation Program for Commercial and
Industrial Equipment: High-Intensity Discharge
Lamps Analysis of Potential Energy Savings’’ (Dec.
2004). Available at: https://www1.eere.energy.gov/
buildings/appliance_standards/commercial/pdfs/
hid_energy_savings_report.pdf.
E:\FR\FM\13APP2.SGM
13APP2
16966
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
3. Base-Case Market-Share Matrices
DOE’s market-share matrices are
another important input into the
shipments analysis and NIA. Within
each product class, DOE considers the
mix of technologies from which
consumers can choose. These choices
are represented in market-share
matrices, which apportion market share
for lamp stocks (in 2012) or lamp
shipments (after 2012). Because
shipments depend on lamp lifetime and
system lumen output assumptions,
among other inputs, DOE allocated
market shares to each of the lamp
technologies for the base case and
standards case. The matrices enable the
shipment model to capture a migration
to different lamps, or, for GSFL, lampand-ballast designs, over time in both
the base and standards cases. Issues
related to these market-share matrices
are discussed below.
a. General Service Fluorescent Lamps
A ballast factor measures the actual
lumen output of a lamp-and-ballast
system relative to a reference system. A
lower ballast factor will, all else equal,
lead to lower lumen output, and
proportionally less energy consumption
than the reference system. ACEEE
commented that the ballast factor of
0.75 that DOE used in the market
matrices is fairly uncommon and that
manufacturers are now marketing lower
ballast factors, including 0.7, 0.69, and
0.68. Therefore, ACEEE expects a bigger
jump from normal to low ballast factor
than the 0.78–0.75 jump that DOE
assumes in its market-share matrices
presented in the ANOPR. The Joint
Comment noted that 0.71 represents the
mid-point of very low ballast factors on
the market. (Public Meeting Transcript,
No. 21 at pp. 262–263; Joint Comment,
No. 21 at p. 10) Consistent with changes
incorporated in the engineering
analysis, DOE incorporated a 0.71
ballast factor ballast option in the NIA.
In sum, DOE attempts to match as
closely as possible the lumen output of
the retiring system and the replacement
system. To the extent that a lower
ballast factor can achieve the
appropriate lumen output, it is
incorporated into the technology
choices facing consumers.
Regarding the base-case 4-foot T8
medium bipin market-share matrix,
Industrial Ecology commented that DOE
was incorrect to assume 0 percent
market share for the 25W lamp in 2012.
Because thousands of these lamps are
being sold in 2008, that estimate should
be much greater than zero. (Public
Meeting Transcript, No. 21 at p. 261)
The Joint Comment stated that 30W
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
lamps are being displaced by 25W and
28W options. Therefore, DOE’s 30W
market share assumptions—4 percent in
2012 and 15 percent in 2042—are too
large. The Joint Comment suggested that
DOE should substantially reduce the
market share of 30W lamps and split
those sales between 25W and 28W
lamps. (Joint Comment, No. 23 at p. 10)
NEMA commented on the same
market-share matrix, stating that the
market share for T8 lamps in the 2042
base case should be less than 30 percent
for 32W lamps and greater than 30
percent for 25W lamps, with the rest of
the market composed of 28W and 30W
lamps. (NEMA, No. 22 at p. 28)
DOE considered the submitted
comments and modified its base-case 4foot T8 medium bipin market-share
matrix accordingly. Based on a
confidential NEMA survey of market
shares of 4-foot medium bipin lamps, in
2012, DOE allocated 4 percent, 4
percent, and 2 percent of the 4-foot T8
market share to 25W, 28W, and 30W
lamps, respectively, for the revised
NOPR base-case market-share matrices.
In 2042, DOE allocated 32 percent, 27
percent, and 14 percent market to 25W,
28W, and 30W lamps, respectively. See
chapter 10 of the NOPR TSD for the full
market-share matrices in 2012 and 2042.
b. Incandescent Reflector Lamps
In the March 2008 ANOPR, DOE
presented market-share matrices for
both residential and commercial IRL.
For the commercial sector, the base-case
IRL market-share matrix apportioned
market share of the stock to only
halogen and the standard HIR (currently
EL2) lamps. Although DOE received no
comments from stakeholders, DOE
modified these matrices for the NOPR to
reflect changes made in the engineering
analysis. For the NOPR, the base case
market-share matrix for commercial IRL
now allocates market share to all
currently commercially-available lamp
technologies, including improved
halogen, long-life HIR, and the
silverized reflector technology. DOE
believes this revised distribution better
reflects product availability and
consumer purchasing trends because
they include all covered lamp
technologies currently being sold.
4. GSFL Standards-Case Shipment
Scenarios and Forecasts
In the March 2008 ANOPR, DOE
modified its base-case market-share
matrices to account for two standardscase scenarios and to generate shipment
forecasts. DOE considered a Roll-up
scenario and a Shift scenario, described
below. DOE also introduced voluntary
standards-induced retrofits in the
PO 00000
Frm 00048
Fmt 4701
Sfmt 4702
standards case. DOE received several
comments on the scenarios it analyzed
and its rate of voluntary retrofits. In
response to those and related comments,
DOE is modifying its Shift and Roll-up
scenarios and introducing new
standards-case scenarios. These
scenarios are discussed in detail below
and in TSD chapter 10.
a. Shift/Roll-Up Scenarios
In the March 2008 ANOPR, DOE
modeled lower-bound and upper-bound
energy conservation scenarios for the
GSFL standards-case NIA to
characterize the range of energy savings
that may result from standards. 73 FR
13620, 13671 (March 13, 2008). In the
standards-case NIA for GSFL and
commercial IRL, DOE first modeled a
lower-bound energy conservation
scenario called the Roll-up scenario. 73
FR 13620, 13671 (March 13, 2008). This
scenario assumes that consumers
owning lamps or systems that do not
meet the new standards will ‘‘roll up’’
to the lowest first-cost option available
(preserving lumen output if possible)
when purchasing standards-compliant
lamps. (March 2008 ANOPR TSD
chapter 9) The Roll-up scenario also
assumes that consumers already owning
standards-compliant lamps or systems
will continue to purchase those lamps
or systems.
DOE also modeled a Shift scenario in
the March 2008 ANOPR for the GSFL
NIA, in which DOE assumed that
consumers are driven by both lamps
cost and energy savings. In this case,
consumers may purchase a variety of
lamps or systems that are more
efficacious than their base case systems.
(73 FR 13620, 13671 (March 13, 2008);
March 2008 ANOPR TSD chapter 9)
Specifically, consumers who purchase
products in the base case at aboveminimum standard levels will ‘‘shift
up’’ to even higher efficacy standard
levels in the Shift scenario. DOE used
this scenario to illustrate upper-bound
energy savings.
The Joint Comment argued that both
the Roll-up and Shift scenarios
understate standards-case energy
savings, but the Roll-up scenario is more
unrealistic because standards change
the relative economics of more-efficient
products. (Joint Comment, No. 23 at p.
11) In other words, standards would
eliminate the least-efficacious lamps
(which usually have the lowest first
costs), thereby reducing the cost
premium of high-efficacy lamps relative
to the lowest first-cost available lamp.
According to the commenter, that would
encourage some consumers to purchase
lamps above the standards. The Joint
Comment also argued that new
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
standards would encourage
manufacturers to promote more
efficacious products, a market dynamic
not sufficiently captured by either
scenario. (Joint Comment, No. 23 at p.
11)
The Joint Comment further stated that
the Shift scenario reflects a more
realistic consumer response to standards
than the Roll-up scenario. Historically,
for example, some consumers have
purchased systems that are more
efficacious than minimum standards.
Still, the Joint Comment argued, the
Shift scenario does not fully capture the
spread of efficiencies in a standardscompliant market and fails to
characterize manufacturer efforts to
hasten development of more-efficient
lamps and systems. The Joint Comment
argued that DOE’s scenarios should
anticipate voluntary programs and
manufacturer interest in establishing
more-efficient product lines in the
standards case. (Joint Comment, No. 23
at pp. 11, 22)
Regarding the comment about the
relative economics of lamp purchases,
DOE agrees that the relative first-costs
change in the standards case (i.e., the
up-front cost differential between the
least-cost, standards-compliant lamp
and a more-efficient lamp) is less than
in the base case. This effect is one of the
reasons DOE models a Shift scenario.
Still, DOE does not believe that this
effect implies that the Shift scenario is
necessarily more viable than the Roll-up
scenario. Although the relative up-front
economics change between cost and
efficacy, they may not change between
cost and income, meaning some
consumers—particularly those not
concerned about energy savings—may
focus on the absolute costs at the time
of purchase. A consumer’s lighting
budget, for example, will not necessarily
increase simply because there is a
smaller cost premium for a moreefficacious lamp. In sum, DOE cannot be
certain which scenario is more likely,
and, thus, continues to model both
scenarios.
However, DOE agrees that revisions to
the Shift scenario may better capture the
spread of efficiencies in the market.
Therefore, DOE revised its Shift
scenario for the NOPR to more closely
retain the existing (baseline) efficacy
distribution in the standards case. (See
TSD chapter 11 for the revised Shift
scenario efficacy distribution results.)
However, as the standard becomes more
stringent, DOE has maintained its
approach of incrementally accumulating
market share of the lamp stock at TSL5
and not projecting some to move beyond
what now characterizes the maximum
technologically feasible standard level
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
(‘‘max-tech’’). It is not possible for DOE
to model a spread of efficiencies above
max-tech levels. DOE has interviewed
manufacturers and concluded it cannot
reasonably predict future price and
performance points of technologies yet
to be developed for the market. DOE
seeks comment and supporting data on
whether the Roll-up or Shift scenario is
more appropriate.
b. Lighting Expertise Scenarios
In its written comments, NEMA stated
that it considers the Shift scenario
implausible because the scenario
assumes consumers will ‘‘aggressively’’
migrate to lower-ballast-factor ballasts.
NEMA strongly disagreed with DOE’s
assumption that more-stringent efficacy
standards are significantly correlated
with lower GSFL ballast factors
(particularly at CSLs 3, 4, and 5), and
NEMA argued that it had seen no direct
and demonstrated causal relationship
between them in its experience. Further,
NEMA argued that there is no proven
correlation between new potential GSFL
standards and the future mix of ballast
factor values that will occur; therefore,
NEMA reasoned that DOE should not
apply such a correlation in its
standards-case market-share matrices.
NEMA also commented that new
standards-compliant GSFL and their
ballasts would have to be interoperable
across manufacturers and with a wide
range of existing ballasts and
luminaires. Therefore, more-stringent
efficacy standards would mostly yield
greater lumen output, rather than
decreasing lamp wattage. As such,
NEMA argued, DOE has overreached in
building a case for standards set at
higher efficacy levels by inappropriately
and arbitrarily assuming a strong
correlation between increasing efficacy
and decreasing ballast factor views.
(NEMA, No. 22 at p. 26, 27)
NEMA also commented that the most
direct way to use the efficacy
improvements imposed by the standards
is to use fewer luminaires to attain the
same delivered light level on the work
surface while reducing the total wattage.
However, NEMA maintains that this is
not a practical possibility because, even
for new construction or major
renovation projects, the spacing of
luminaires is dictated by a building and
ceiling system grid. Thus, there is no
opportunity to take advantage of
additional lumens that might result
from standards by re-spacing existing
luminaires, which must continue to
operate on high-volume ballast designs.
(NEMA, No. 22 at p. 26) Based on these
arguments, NEMA strongly asserted that
moving beyond CSL1 and CSL2 for a
PO 00000
Frm 00049
Fmt 4701
Sfmt 4702
16967
lamp-only rulemaking is ill-advised.
(NEMA, No. 22 at p. 26, 27)
DOE has carefully considered
NEMA’s comments on DOE’s
assumption of a general trend toward
lower-BF ballasts over the analysis
period. In response, DOE undertook an
extensive literature review and
analysis—discussed below—to better
characterize the likelihood of consumers
migrating to lower-BF ballast systems if
higher efficacy standards are required.
DOE assessed the lighting expertise of
groups of consumers, described below,
who make lighting purchase decisions.
DOE assumes that consumers with
‘‘high’’ lighting expertise will be
sufficiently educated about ballast
factors and lamp efficacy to migrate to
lower-ballast-factor ballasts when lower
wattage lamps are not available in the
standards case. That is, these consumers
will seek to maintain light output in the
replacement purchase.
To analyze this issue, DOE first
characterized the lighting market supply
chain in the commercial and residential
sectors and identified the decision
makers within each one (e.g.,
contractors, homeowners). DOE broke
down each sector by the principal
events that prompt lamp purchases: (1)
Ballast failure; (2) retrofit; (3) fixture
replacement; (4) renovation; and (5) new
construction. DOE assigned
probabilities reflecting each decision
maker’s likelihood of making the
lighting purchase decision given the
purchase event. For example, in
purchase events driven by new
construction, DOE assumed lighting
designers, architects, and electrical
engineers make 70 percent of the
decisions, owners make 20 percent, and
electrical contractors make the
remaining 10 percent. DOE then
analyzed the likelihood of each decision
maker choosing to run a lamp on a
lower BF ballast if forced by standards
to purchase a more-efficacious lamp.
DOE described that likelihood with a
probability that was based on the
technical expertise and motivation of
the decision maker. Within each
purchase event, DOE multiplied the
likelihood of each market actor making
the decision by the likelihood of that
actor choosing a lower-BF ballast. In
this way, DOE derived an estimate for
the likelihood of a lower-BF ballast
being selected for each event in each
sector in the standards case.
DOE assumed the commercial and
industrial sectors behave similarly with
respect to ballast factor choices, and no
distinction was made between them in
this analysis. Additionally, decision
makers in the large-commercial sector
can be different agents making different
E:\FR\FM\13APP2.SGM
13APP2
16968
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
decisions than those in the smallcommercial sector. In the market
segments (purchase events) where DOE
found consumer behavior to be
substantially different between these
subsectors, DOE weighted the relative
impact of each subsector when
characterizing the overall commercial
market. Table V.6 presents the results of
DOE’s analysis for the commercial and
residential sectors. The values depict
the probability that lamps purchased in
each event will be matched with lowerballast-factor ballasts, if necessary, to
maintain lumen output. For example, 78
percent of lamps purchased in new
construction in the commercial sector
will be paired with lower-ballast-factor
ballasts, if no reduced-wattage lamps are
available in the standards case,
TABLE V.6—MARKET SEGMENT-BASED LIKELIHOOD OF HIGH LIGHTING EXPERTISE
Probability
Lamp purchase event
Commercial
(in percent)
Renovation ...............................................................................................................................................................
New Construction ....................................................................................................................................................
Retrofit .....................................................................................................................................................................
Ballast Replacement ................................................................................................................................................
Fixture Replacement ................................................................................................................................................
In light of NEMA’s comments and
DOE’s analysis, DOE used these results
to add a second set of standards-case
scenarios to characterize ballast factor
migration in the GSFL NIA. DOE now
also analyzes a High Lighting Expertise
scenario and a Market Segment-Based
Lighting Expertise scenario. These
scenarios characterize consumers’
decisions (or lack thereof) when
purchasing a more-efficient lamp to
either maintain previous lumen output
or accept higher lighting levels. For its
part, the High Lighting Expertise
scenario uses the same methodology as
DOE used in the ANOPR. The High
Lighting Expertise scenario generally
characterizes more sophisticated
lighting decisions in which consistent
lighting levels and/or energy savings
play a determining role in consumer
behavior. In this scenario, consumers
are more likely to choose a lowerballast-factor ballast to pair with higherefficacy lamps. Conversely, in the
Market Segment-Based scenario, DOE
assumed consumers often accept higher
lighting levels as a consequence of
higher-efficacy lamps. As a
consequence, these consumers do not
achieve the same energy savings as
would be possible by migrating to
lower-ballast-factor ballasts. DOE used
this analysis, and the results shown in
Table V.6, to characterize the Market
Segment-Based expertise scenario. On
the other hand, in the High Lighting
Expertise scenario, DOE assumes all
consumers (100 percent) migrate to
lower-ballast-factor ballasts when
appropriate. Please see TSD appendix
10B for more details.
c. Voluntary Retrofits
In the March 2008 ANOPR, DOE
assumed that more-stringent efficacy
standards would lead to higher T12
lamp prices, and, in turn, higher rates of
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
voluntary retrofits from T12 to moreefficacious T8 lamps. For example, DOE
assumed that CSL1 would drive an
additional 10 percent of the T12 market
to voluntarily migrate to T8 lamps, that
CSL2 would drive an additional 20
percent, that CSL3 would drive an
additional 30 percent, and so on. These
commercial standards-induced retrofits
involve consumers voluntarily
discarding their functioning T12
ballasts, and purchasing new T8 ballasts
in the standards case. In contrast, in the
base case, these consumers would have
utilized the entirety of their T12 ballast
lifetime.
At the public meeting, ACEEE agreed
with DOE’s assumption that standards
will accelerate voluntary retrofits, but
argued that DOE’s retrofit rate was too
aggressive. ACEEE specifically stated
that the 50-percent retrofit rate per year
at CSL5 was too high and suggested a
rate of roughly half that level. (Public
Meeting Transcript, No. 21 at p. 282) GE
agreed that DOE’s retrofit rates were too
high, suggesting that 10 percent at CSL1
is an appropriate starting point, but 25
percent should probably be the
maximum assumed retrofit rate at CSL5.
Using those rates as the minimum and
maximum, GE said DOE could scale the
rate for the other CSLs. (Public Meeting
Transcript, No. 21 at pp. 282–283) In its
written comments, NEMA similarly
stated that DOE’s conversion rate for
consumers voluntarily retrofitting from
T12 to T8 systems is likely overstated.
NEMA suggested that DOE should use a
voluntary retrofit rate of 20 to 25
percent for CSL5 and recommended that
other rates be adjusted based on that
percentage. (NEMA, No. 22 at p. 28)
At the public meeting, Philips also
commented that it would expect
utilities to be more aggressive with their
rebate programs in the standards case
than they would be in the base case.
PO 00000
Frm 00050
Fmt 4701
Sfmt 4702
69
78
92
8
34
Residential
(in percent)
48
61
0
0
0
PG&E stated that voluntary retrofits are
driven by many factors, including
attention to global climate change,
increased product availability, and other
factors, not necessarily utility rebate
programs. (Public Meeting Transcript,
No. 21 at pp. 273–275)
DOE considered these comments and
maintains that these standards-induced
retrofits are a likely phenomenon and
important to model in the NIA. DOE
agrees that its initial retrofit
assumptions were likely too high,
particularly for the higher efficacy
levels. For the NOPR, consistent with
comments received, in the commercial
sector DOE continued to assume that
EL1 would drive an additional 10
percent of the T12 market per year to
voluntary retrofit to T8 lamps. DOE also
assumed a 25-percent retrofit rate at EL4
and EL5, levels at which all T12 lamps
are effectively eliminated from the
market. For TSL1, TSL2, and TSL3, DOE
changed the standards-induced retrofit
rates to 10 percent, 15 percent, and 20
percent, respectively.
Similar to DOE’s approach in the
commercial sector, DOE also included
increased migration of residential
consumers from 4-foot medium bipin
T12 systems to T8 systems. As
discussed in chapter 10 of TSD, DOE
assumed in the base case that residential
consumers replacing their T12 fixture
(either due to fixture failure or ballast
failure) would purchase another T12
system. In contrast, in the commercial
sector, DOE assumes 90 percent of 4foot MBP consumer replace their T12
ballasts with T8 ballast upon fixture or
ballast failure in the base case. In
addition, while in the commercial sector
DOE assumed, under amended energy
conservation standards, some
consumers would retrofit their working
T12 ballast systems before end of ballast
life, DOE assumed residential
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
consumers never do so. Instead, in the
residential sector, DOE incorporated an
additional migration to T8 lamps only
when the consumer is confronted with
a ballast or fixture failure. In such
situations DOE assumed that a certain
percentage residential consumers, who
in the base case would purchase a new
T12 system, would instead, in the
standards case, elect to purchase a T8
system—despite the availability of T12
options. Specifically, based on
manufacturer interviews, DOE shifts 25
percent, 35 percent, and 65 percent of
these consumers to T8 systems at TSL1,
TSL2, and TSL3, respectively (thereby
reflecting increased cost of T12 lamps).
At TSL4 and TSL5, all residential
consumers migrate to T8 systems
because T12 lamps would be effectively
eliminated from the market.
5. IRL—Standards-Case Shipment
Scenarios and Forecasts
In the March 2008 ANOPR, DOE
modified its market-share matrices to
account for standards-case scenarios
and generate shipment forecasts for IRL.
DOE created one main shipment
scenario and two sensitivity scenarios to
characterize how IRL consumers would
be expected to react to standards in the
commercial and residential sectors. The
sensitivity scenarios were called the
‘‘65W BR Lamp Substitution’’ scenario
and the ‘‘10-Percent Lumen Increase’’
scenario. For all three standards-case
scenarios in these sectors, DOE assumed
that consumers whose base-case lamp
purchase has an efficacy lower than that
of the standard would roll up to the
least efficacious lamp design available.
Any IRL consumer whose base-case
lamp purchase meets the efficacy
standard would remain unaffected.
In the main shipment scenario, DOE
made two assumptions: (1) Consumers
who purchase covered IRL technology
in the base case continue to purchase
covered IRL technology in the standards
case (i.e., the total number of installed
covered IRL in the base case is the same
as that in the standards case throughout
the analysis period); and (2) in the
standards case, consumers purchase
higher-efficacy lamp designs with
equivalent lumen output as their basecase lamps.
The remaining sensitivity scenarios
modeled two situations—one in which
consumers may migrate from regulated
IRL toward the exempt 65W BR lamps
in the standards case (termed ‘‘65 Watt
BR lamp substitution’’), and another in
which a portion of residential
consumers of IRL buy a more-efficacious
lamp at the same wattage as in the base
case (termed ‘‘10-percent lumen
increase’’). This sensitivity scenario
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
assumed consumers would, on average,
purchase 10 percent more lumens in the
standards case. As explained below,
DOE received several comments on the
March 2008 ANOPR standards-case IRL
shipments. In response to those and
related comments, DOE is modifying
and introducing new standards-case
scenarios, discussed in detail below and
in TSD chapter 10.
i. Shift/Roll-Up Scenarios
For commercial sector IRL, DOE chose
to model a Roll-up scenario in the
March 2008 ANOPR. The Joint
Comment encouraged DOE to also
model a Shift scenario for commercial
IRL because of the variety of existing
and emerging efficiency options
available. The Joint Comment argued a
Shift scenario would better capture both
the improved cost competitiveness of
higher-efficacy options and greater
manufacturer investment in developing
higher-efficacy products. (Joint
Comment, No. 23 at p. 18)
DOE agrees that some commercial
consumers may continue to purchase
products above the minimum standard
level. Therefore, similar to the Shift
scenario in GSFL, DOE created a Shift
scenario for IRL that captures the same
spread of efficiencies in the standards
case as in the base case. To model this,
DOE compiled a distribution of IRL in
the commercial sector with different
efficacies using the revised efficacy
standard levels for this notice. Based on
this distribution, DOE then created a
Shift scenario for the NOPR IRL national
impact analysis.
In the March 2008 ANOPR, DOE’s
residential standards-case market-share
matrix assumed that the entire
residential market purchases the leastcost standards-compliant lamp at each
efficacy level. Because all residential
consumers purchase baseline lamps, the
Shift and Roll-up scenarios lead to
equivalent results. For example, at
CSL1, DOE assumed the entire
residential market would choose
improved halogen lamps; at CSL3, the
market would choose improved HIR.
NEMA commented that residential
consumers do not necessarily purchase
lamps that meet only one efficacy level.
(NEMA, No. 22 at p. 31) NEMA
contended that consumers could opt to
buy lamps that meet a higher CSL than
the one imposed by DOE.
Based on NEMA’s comment, DOE
reconsidered its assumption that
consumers in the residential market
purchase lamps at only the lowest
efficacy level. However, DOE believes
that its assumption that consumers buy
lamps at the lowest first-cost standardscompliant efficacy level correctly
PO 00000
Frm 00051
Fmt 4701
Sfmt 4702
16969
characterizes residential consumer
behavior in general. For example,
although lamps using HIR technology
are available today, consumers generally
do not buy them because of their high
initial cost. DOE does not believe
current market behavior will radically
change under new or amended
standards. Without data suggesting
otherwise, DOE believes the most
appropriate forecasting assumption
should generally reflect the
predominant, current consumer
behavior. Therefore, DOE maintains its
assumption for the NOPR that
residential consumers would continue
to purchase the lowest-first-cost,
standards-compliant lamps. For further
detail regarding the Shift and Roll-up
scenarios, see chapter 10 of the TSD.
ii. Product-Substitution Scenarios
At the public meeting, ACEEE
commented that the deployment of nonIRL emerging technologies will be
affected by the efficacy level that DOE
selects for this rule. (Public Meeting
Transcript, No. 21 at p. 291) While DOE
considered the comment, it ultimately
did not model additional movement to
LED or CMH lamps in response to
standards because the efficacy and price
projections for such lamps have a
significant degree of uncertainty. DOE
does not wish to incorporate that level
of conjecture into the NPV calculation
for this rule.
However, because DOE assumed R–
CFL technology was mature, DOE did
assess additional movement from IRL to
R–CFL in response to standards. For the
residential sector, DOE calculated
simple payback periods comparing R–
CFL to the baseline halogen and R–CFL
to the higher-efficacy lamp designs.
Using incremental market penetrations
based on the payback period
calculations, DOE incorporated
additional movement to R–CFL in the
residential sector standards case. In the
commercial sector, DOE assumed that
all institutions wishing to convert to R–
CFL, despite its shortcomings (such as
lower color quality), do so before 2012.
Therefore, there is no additional
movement to R–CFL in response to
standards.
DOE excluded certain IRL
(particularly some BR and ER lamps,
such as 65W BR30 and ER40 lamps)
from the base-case NIA in the March
2008 ANOPR because these IRL were
exempted from standards by EISA 2007.
(EISA 2007 section 322(b); 42 U.S.C.
6295(i)(1)(C)) In the standards-case
sensitivity scenario, DOE modeled the
movements to exempted IRL as a
reduction in the market size of covered
IRL as consumers move from covered to
E:\FR\FM\13APP2.SGM
13APP2
16970
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
non-covered lamps. DOE received a
number of comments on its choice to
exclude exempted IRL from the base
case and standards case in the NIA.
Several comments recommended that
DOE should model movements to
exempt IRL in the main base-case and
standards-case NIA scenarios instead of
only modeling such movements in a
sensitivity scenario. ACEEE commented
that DOE needs to account for BR lamps
in its analysis; by excluding BR lamps
from the base case, ACEEE argued DOE
was essentially ignoring their presence
in the market. The Joint Comment
argues that 65W BR lamps should be
included in the base case because they
represent a potential loophole to
standards. (Public Meeting Transcript,
No. 21 at pp. 293–294, 313–314; Joint
Comment, No. 23 at p. 17)
As stated above, DOE only includes
products being regulated in this
rulemaking in the base-case shipment
forecasts. Since this rulemaking does
not cover 65W BR lamps, DOE cannot
include them in the base-case NIA.
Accordingly, DOE removed exempted
IRL from the shipment data used as
inputs to the base-case NIA in the
ANOPR. (March 2008 ANOPR TSD
chapter 9) For the standards-case NIA,
DOE created a ‘‘65 Watt BR lamp
substitution’’ sensitivity scenario to
model movements to exempted 65W BR
lamps due to the various CSLs. (March
2008 ANOPR TSD appendix 9A) DOE
included 65W BR lamps in the
standards case because covered
products shift to this lamp.
DOE received a number of comments
on how it modeled the shift to BR lamps
in the standards case. NEMA stressed its
significance and agreed that consumers
will shift from covered to exempted BR
lamps, with the shift increasing as morestringent standards raise product costs.
(NEMA, No. 22 at p. 27) The Joint
Comment maintained that 65W BR
lamps should be included in the
standards case. (Joint Comment, No. 23
at p. 17) However, some attendees of the
public meeting suggested that the shift
to the 65W BR might be inappropriate
because they believed that consumers
already purchase exempted BR lamps in
most applications where consumers
have the option of installing either the
exempted BR lamps or higher-efficacy
PAR lamps. For example, PG&E
commented that the vast majority of IRL
in recessed cans are already exempted
BR lamps, so it is unlikely that
consumers will switch from existing
PAR lamps (which are included in
coverage) to new BR lamps in those
applications. In addition, Industrial
Ecology stated that some household
recessed can fixtures are not strong
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
enough to hold PAR lamps, which are
heavier than BR lamps. Thus, BR lamps
would likely maintain their indoor
recessed can market share relative to
PAR lamps. Regarding outdoor
applications in which PAR lamps are
often used, Industrial Ecology also
commented that BR lamps are generally
incompatible with these application,
meaning consumers would likely not
migrate from PAR lamps to exempted
BR lamps for outdoor applications in
response to standards. (Public Meeting
Transcript, No. 21 at pp. 319, 321)
DOE considered these comments, and
agrees that PAR lamps may be more
suitable for outdoor applications than
the exempted BR lamps. However,
based on residential estimates that 40
percent of all residential IRL are PAR
lamps,55 DOE believes that a
considerable portion of residential PAR
lamps are used in non-outdoor
applications which are compatible with
both PAR and the exempted BR lamps.
Thus, DOE maintains that some
residential consumers would likely
move to exempted IRL under standards.
For the NOPR, DOE revised its estimates
of the number of consumers that will
shift to exempted IRL by calculating
incremental market penetrations for
each standard level.
To better account for migration to
exempted lamps, DOE has decided to
analyze a second set of standards-case
scenarios for IRL in this NOPR. DOE
now analyzes scenarios called the
Product Substitution and No Product
Substitution scenarios. The Product
Substitution scenario models a shift to
both exempted BR lamps and to R–CFL
in the standards case. The No Product
Substitution scenario does not model
any additional shift in the standards
case to non-regulated reflector
technologies. For more information
about the product substitution standards
case scenario, see chapter 10 of the TSD.
DOE maintains the 10-percent lumen
increase sensitivity scenario from the
ANOPR, a scenario in which a portion
of consumers purchase the same wattage
higher efficacy lamp in the standards
case and do not save energy. See
appendix 11A for more detail on this
sensitivity scenario.
6. Other Inputs
a. Analysis Period
In its written comments, NEMA stated
that any market forecast, even over a
55 New York State Energy Research and
Development Authority, Incandescent Reflector
Lamps Study of Proposed Energy Efficiency
Standards for New York State (2006). Available at:
https://www.nyserda.org/publications/Report%200607-Complete%20report-web.pdf (Last accessed Oct.
7, 2006).
PO 00000
Frm 00052
Fmt 4701
Sfmt 4702
short period of time, will contain errors.
NEMA argued that forecasting market
relationships over 30 years will
compound any inherent errors to the
point where the estimate may no longer
be useful. For example, NEMA argued
that overstating growth of lamps
covered by this standard would
overstate the discounted value of
potential benefits associated with
amended standards. (NEMA, No. 22 at
p. 24) DOE recognizes that forecasting
over long periods of time can lead to
inaccuracies. However, due to the long
lifetime of ballasts and lamps in some
sectors, the stock of these products can
take decades to turn over. Thus, DOE
believes the standards impact on energy
consumption and energy savings is best
quantified and evaluated over a long
period of time. Therefore, DOE has
decided to maintain an analysis period
from 2012 to 2042, consistent with the
shipment and national impact analyses
of other rulemakings. However, to
account for the uncertainties involved
in forecasting energy savings and NPV
in general, and over long periods of
time, DOE has created several base-case
and standards-case scenarios. Based on
these scenarios, previously discussed in
sections V.E.2.c, V.E.4, and V.E.5, DOE
believes that it can characterize the NIA
results for these products with a
sufficient degree of certainty.
b. Total Installed Cost
The total annual installed cost
increase is equal to the annual change
in the per-unit total installed cost (i.e.,
the difference between base case and
standards case) multiplied by the
shipments forecasted in the standards
case.
On this topic, GE commented that the
cost of migrating from an 8-foot lamp to
a 4-foot lamp includes not only the
lamp and ballast costs, but also the cost
of the retrofit kit and labor, which was
not included in DOE’s ANOPR NIA.
NEMA commented that the retrofits kits
would cost $45–$50, not including
labor, which would take 20–25 minutes.
(NEMA, No. 22 at p. 28; Public Meeting
Transcript, No. 21 at pp. 255–256) DOE
agrees that the retrofit kit costs should
be included in the NIA. Therefore, DOE
is including in the NIA the retrofit kit
cost of $50 per 8-foot single pin lamp
that is replaced by two 4-foot lamps.
DOE is also including a total installation
time of 25 minutes. See TSD chapter 11
for further detail on retrofit kit costs.
c. Electricity Price Forecast
In the March 2008 ANOPR, DOE
projected electricity prices using EIA’s
AEO2007 estimates and extrapolated
prices beyond 2030. In this notice, DOE
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
updated those projections based upon
AEO2008. DOE received a comment on
using electricity price forecasts other
than those of AEO as sensitivities. See
section 0 above for more detail on this
comment and DOE’s response.
d. Energy Site-to-Source Conversion
The site-to-source conversion factor is
the multiplicative factor DOE uses for
converting site energy consumption into
primary or source energy consumption.
In the March 2008 ANOPR, DOE used
EIA’s AEO2007 forecasts (to 2030) of
electricity generation and electricityrelated losses. DOE extrapolated
conversion factors beyond 2030. In this
notice, however, DOE uses annual siteto-source conversion factors based on
the version of the National Energy
Modeling System (NEMS) that
corresponds to AEO2008. The
conversion factors vary over time
because of projected changes in the
Nation’s portfolio of generation sources.
DOE estimated that conversion factors
remain constant at 2030 values
throughout the remainder of the
forecast.
e. HVAC Interaction Factor
In the March 2008 ANOPR, DOE
assumed a 6.25 percent HVAC
interaction factor. The HVAC
interaction factor measures the reduced
cooling loads and increased heating
loads that result from their interaction
with more-efficacious lighting systems.
For example, a 6.25 percent HVAC
interaction factor means that one quad
of energy savings due to lamps
standards results in 1.0625 quads of
total energy savings after the interaction
with heating, ventilation, and air
conditioning systems is taken into
account. At the public meeting, PG&E
stated that DOE’s assumed level for this
factor was too low. PG&E argued that if
the heat from these products goes
directly into the building and it takes
one unit of electric energy to remove
three units of heat, 6.25 percent was a
very conservative number. (Public
Meeting Transcript, No. 21 at pp. 333–
334) Industrial Ecology agreed that 6.25
percent was on the low end of most
estimates and cited the following rule of
thumb used in the service industry: One
saves a quarter of a watt in HVAC
operation for every watt one saves
ceiling lighting systems. Industrial
Ecology suggested that DOE should look
into other studies for more information
on the HVAC interaction factor. (Public
Meeting Transcript, No. 21 at pp. 333–
334)
DOE is unaware of any other nationallevel studies that may be useful in
estimating the HVAC factor specific to
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
lighting over the entire calendar year.
Therefore, DOE continues to use the
study 56 that originated from the 2000
Ballast Rule. DOE notes that it has
updated the study since its original
publication and that it is a nationallevel analysis covering many building
types across several climate zones.
f. Rebound Effect
In its analyses, DOE accounted for an
anticipated ‘‘rebound effect’’ 57 that may
occur after the installation of energy
efficient lighting equipment. After
consulting the literature 58 reporting on
this effect, DOE used in the March 2008
ANOPR an 8.5-percent rebound effect
for the residential sector and a 1-percent
effect in the commercial sector, with
every 100 percent increase in energy
efficiency. NEMA agreed with DOE’s
inclusion of the rebound effect, but
commented that more research needs to
be done to characterize its magnitude.
(NEMA, No. 22 at p. 30) DOE is unaware
of other data that would affect its
current rebound effect assumptions.
DOE invites additional comments on
this issue and will consider
incorporating any relevant data
provided.
g. Discount Rates
In its analyses, DOE multiplies
monetary values in future years by a
discount factor in order to determine
their present value. DOE estimated
national impacts using both a 3-percent
and a 7-percent real discount rate as the
average real rate of return on private
investment in the U.S. economy. The
Joint Comment argued that DOE should
use a 2-percent to 3-percent real
discount rate, noting other rulemakings
and extensive academic research
supporting a real societal discount rate
in that range. (Joint Comment, No. 23 at
p. 22) While DOE acknowledges the
comment, the Department notes that it
is required to follow guidelines on
discount factors set forth by the Office
56 U.S. Department of Energy—Energy Efficiency
and Renewable Energy Office of Building Research
and Standards. Technical Support Document:
Energy Efficiency Standards for Consumer
Products: Fluorescent Lamp Ballast Proposed Rule:
Appendix B. Marginal Energy Prices and National
Energy Savings. January 2000. Washington, DC.
https://www.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/
appendix_b.pdf.
57 Under economic theory, ‘‘rebound effect’’ refers
to the tendency of a consumer to respond to the cost
savings associated with more-efficient equipment in
a manner that actually leads to marginally greater
product usage, thereby diminishing some portion of
anticipated energy savings related to improved
efficiency.
58 Greening, L.A., D.L. Greene, and C. Difiglio,
‘‘Energy efficiency and consumption—the rebound
effect—a survey,’’ 28 Energy Policy (2000), pp. 389–
401.
PO 00000
Frm 00053
Fmt 4701
Sfmt 4702
16971
of Management and Budget (OMB).
Specifically, DOE uses these discount
rates in accordance with guidance that
OMB provides to Federal agencies on
the development of regulatory analysis
(OMB Circular A–4 (Sept.17, 2003),
particularly section E, ‘‘Identifying and
Measuring Benefits and Costs’’).
Accordingly, DOE is continuing to use
3-percent and 7-percent real discount
rates for the relevant calculations in this
NOPR.
F. Consumer Subgroup Analysis
In analyzing the potential impacts of
new or amended standards, DOE
evaluates the impacts on identifiable
subgroups of consumers (e.g., lowincome households or small businesses)
that may be disproportionately affected
by a national standard. In the March
2008 ANOPR, DOE requested comments
on subgroups that should be considered
for the NOPR analysis. 73 FR 13620,
13682 (March 13, 2008). NEMA
commented that DOE should assess the
impacts of standards on low-income
consumers, as well as houses of
worship, historical facilities, and
institutions that serve low-income
populations. (NEMA, No. 22 at p. 32)
DOE researched the suggested
subgroups using the 2001 RECS and
2003 CBECS databases and the 2002
U.S. Lighting Market Characterization.
The Residential Furnaces and Boilers
NOPR,59 Central Air Conditioners
Supplemental Notice of Proposed
Rulemaking,60 and Clothes Washers
Final Rule 61 defined ‘‘low-income
consumers’’ as residential consumers
with incomes at or below the poverty
line, as defined by the U.S. Census
Bureau. DOE has defined ‘‘low-income
consumers’’ in the same way for this
59 U.S. Department of Energy—Office of Energy
Efficiency and Renewable Energy, Technical
Support Document: Energy Conservation Program
for Consumer Products: Energy Conservation
Standards for Residential Furnaces and Boilers
Proposed Rule: Chapter 11 (2006). Available at:
https://www1.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/
furnaces_boilers/fb_tsd_chapt11_0906.pdf (Last
accessed Dec. 8, 2008).
60 U.S. Department of Energy—Office of Energy
Efficiency and Renewable Energy, Technical
Support Document: Energy Conservation Program
for Consumer Products: Central Air Conditioners
and Heat Pumps Energy Conservation Standards
Proposed Rule: Chapter 10 (2001). Available at:
https://www1.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/chap10_subgrp.pdf (Last accessed Dec. 8, 2008).
61 U.S. Department of Energy—Office of Energy
Efficiency and Renewable Energy, Technical
Support Document: Energy Conservation Program
for Consumer Products: Clothes Washer Energy
Conservation Standards Final Rule: Chapter 18
(2001). Available at: https://www1.eere.energy.gov/
buildings/appliance_standards/residential/pdfs/
chapter_8_consumer_analysis.pdf. (Last accessed
Dec. 8, 2008).
E:\FR\FM\13APP2.SGM
13APP2
16972
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
rule. DOE discovered that in 2001,
residential low-income consumers faced
electricity prices that were 0.1 cents per
kWh lower than the prices faced by
consumers above the poverty line. Using
this information, DOE performed a
subgroup analysis of low-income
consumers for the NOPR, the key
findings of which are presented below
and addressed in section VI.B.1.b.
DOE found that houses of worship
used their lamps for fewer hours per
year than any other building type in the
non-mall commercial building sector,
according to the 2003 CBECS and LMC.
DOE analyzed houses of worship using
1,705 operating hours per year for GSFL
(rather than 3,435 hours per year for an
average commercial facility) and 1,609
operating hours per year for IRL (rather
than 3,450 hours per year for an average
commercial facility).
DOE also found that a wide range of
sites (from single buildings to entire
districts) are classified as ‘‘historical
facilities.’’ Because historical facilities
serve a range of functions, DOE assumed
that such facilities also feature the same
variety of operating hours, electricity
prices, and discount rates as a typical
consumer. However, DOE did find that
these buildings, on average, have more
T12 lamps than the typical commercial
or residential building. Therefore, in its
subgroup analysis for historical
facilities, DOE concentrated on the LCC
analysis and results for those consumers
with T12 fluorescent lamps.
DOE also found a wide array of
nonprofit and for-profit organizations
that serve low-income populations.
Because of the large diversity of
organizations in this sector, DOE does
not expect to see operating hours, lamp
types, or event response behaviors that
vary significantly from the commercial
sector as a whole. However, DOE
believes that the majority of
organizations serving low-income
populations are small nonprofits. For
this reason, DOE chose a subgroup
scenario with a discount rate that is 3.8
percent higher than the average
discount rate for the commercial sector
(for a discount rate of 10.8 percent),
based on the sources used to develop
the discount rate for small business
subgroups in the Ovens and Commercial
Clothes Washers NOPR analysis.62
62 U.S. Department of Energy—Office of Energy
Efficiency and Renewable Energy, Technical
Support Document: Energy Conservation Standards
for Certain Consumer Products (Dishwashers,
Dehumidifiers, Electric and Gas Kitchen Ranges
and Ovens, and Microwave Ovens) and for Certain
Commercial and Industrial Equipment (Commercial
Clothes Washers): Chapter 12 (2008). Available at:
https://www1.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Although NEMA did not request that
DOE analyze consumers of T12
electronic systems, DOE decided to
analyze this subgroup as well, because
consumers that already have a T12
electronic system could potentially
benefit less from standards than those
consumers with magnetic systems.
Specifically, consumers that own a T12
electronic system in the base case would
need to purchase a T8 electronic system
in the case of an energy conservation
standard at EL4 or EL5. Because the T12
electronic system is more efficient than
T12 magnetic systems, consumers with
electronic systems would experience
lower operating cost savings than those
consumers with magnetic systems. In
order to analyze the affect on consumers
of T12 electronic systems, DOE
established a new baseline electronic
T12 system and modified standards-case
systems so that both light output is
maintained in the case of a standard and
energy is saved. For this subgroup, DOE
only analyzed the event where a
consumer purchases a T12 lamp in the
baseline and a T8 lamp and ballast
system in the case of a standard at EL4
and EL5, as T12 lamps are no longer
available. All other factors of the LCC
subgroup analysis remained the same as
in the primary analysis. See the NOPR
TSD chapter 12 for further information
on the LCC analyses for all subgroups.
G. Manufacturer Impact Analysis
1. Overview
DOE performed an MIA to estimate
the financial impact of higher energy
conservation standards on GSFL and
IRL manufacturers, and to calculate the
impact of such standards on domestic
manufacturing employment and
capacity. The MIA has both quantitative
and qualitative aspects. The quantitative
part of the MIA primarily relies on two
separate Government Regulatory Impact
Models (GRIMs)—industry-cash-flow
models customized for this rulemaking.
The GRIM inputs are data characterizing
the industry cost structure, shipments,
and revenues. The key output is the
industry net present value. Different sets
of assumptions (scenarios) will produce
different results. The qualitative part of
the MIA addresses factors such as
product characteristics, characteristics
of particular firms, and market and
product trends, and it also includes an
assessment of the impacts of standards
on subgroups of manufacturers. The
complete MIA is outlined in chapter 13
of the TSD.
home_appliances_tsd/chapter_12.pdf. (Last
accessed Dec. 8, 2008).
PO 00000
Frm 00054
Fmt 4701
Sfmt 4702
DOE conducted the MIA in three
phases. Phase 1, ‘‘Industry Profile,’’
consisted of the preparation of an
industry characterization. Phase 2,
‘‘Industry Cash Flow,’’ focused on the
industry as a whole. In this phase, DOE
used two separate GRIMs (one for the
GSFL industry and one for IRL industry)
to prepare an industry cash-flow
analysis. DOE used publicly-available
information developed in Phase 1 to
adapt each GRIM structure to facilitate
the analysis of amended GSFL and IRL
standards. In Phase 3, ‘‘Subgroup
Impact Analysis,’’ DOE conducted
interviews with manufacturers
representing the majority of domestic
GSFL and IRL sales. During these
interviews, DOE discussed engineering,
manufacturing, procurement, and
financial topics specific to each
company, and also obtained each
manufacturer’s view of the industry as
a whole. The interviews provided
valuable information DOE used to
evaluate the impacts of amended energy
conservation standards on manufacturer
cash flows, manufacturing capacities,
and employment levels.
a. Phase 1, Industry Profile
In Phase 1 of the MIA, DOE prepared
a profile of the GSFL and IRL industries
based on the market and technology
assessment prepared for this
rulemaking. Before initiating the
detailed impact studies, DOE collected
information on the present and past
structure and market characteristics of
the GSFL and IRL industries. The
information DOE collected included
market share, product shipments,
markups, and cost structure for various
manufacturers. The industry profile
includes further detail on the overall
market, product characteristics,
estimated manufacturer market shares,
the financial situation of manufacturers,
and trends in the number of firms in the
lamp industry.
The industry profiles included a topdown cost analysis of GSFL and IRL
manufacturers that DOE used to derive
product costs and preliminary financial
inputs for the GRIM (e.g., revenues;
material, labor, overhead, and
depreciation expenses; selling, general,
and administrative expenses (SG&A);
and research and development (R&D)
expenses). DOE also used public
information to further calibrate its
initial characterization of the industry,
including Securities and Exchange
Commission (SEC) 10–K and 20–F
reports, Standard & Poor’s (S&P) stock
reports, and corporate annual reports.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
b. Phase 2, Industry Cash-Flow Analysis
Phase 2 of the MIA focused on the
financial impacts of potential amended
energy conservation standards on the
industries as a whole. DOE used the
GRIMs to calculate the financial impacts
of standards on manufacturers. DOE
used two separate GRIMs, one for each
industry analyzed (GSFL and IRL). In
Phase 2, DOE used each GRIM to
perform a preliminary industry cashflow analysis. In performing this
analysis, DOE used the financial values
determined during Phase 1 and the
shipment scenarios used in the NIA
analysis.
c. Phase 3, Subgroup Impact Analysis
Using average cost assumptions to
develop an industry-cash-flow estimate
does not adequately assess differential
impacts among manufacturer subgroups.
For example, small manufacturers,
niche players, or manufacturers
exhibiting a cost structure that largely
differs from the industry average could
be more negatively affected. DOE used
the results of the industry
characterization analysis (in Phase 1) to
group manufacturers that exhibit similar
characteristics.
During the ANOPR public meeting,
Industrial Ecology commented that
small lamp manufacturers may be
disproportionately affected by IRL and
GSFL standards. (Public Transcript, No.
21 at pp. 354–356) DOE established two
subgroups for the MIA corresponding to
large and small business manufacturers
of GSFL and IRL products. For the GSFL
and IRL manufacturing industries, small
businesses, as defined by the Small
Business Administration (SBA), are
manufacturing enterprises with 1,000 or
fewer employees. Based on
identification of these two subgroups,
DOE prepared one interview guide with
questions related to both GSFL and IRL
manufacturing for large and small
manufacturers. DOE used the interview
guide to tailor the GRIMs to address
unique financial characteristics of
manufacturers of each industry. DOE
interviewed companies from each
subgroup, including subsidiaries and
independent firms and public and
private corporations. The purpose of the
meetings was to develop an
understanding of how manufacturer
impacts vary by TSL. During the course
of the MIA, DOE interviewed
manufacturers representing the vast
majority of domestic GSFL and IRL
sales. Many of these same companies
also participated in interviews for the
engineering analysis. However, the MIA
interviews broadened the discussion
from primarily technology-related issues
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
to include business-related topics. One
objective was to obtain feedback from
industry on the assumptions used in the
GRIM and to isolate key issues and
concerns. See chapter 13 of the TSD for
details.
2. Discussion of Comments
In response to DOE’s March 2008
ANOPR presentation of the steps DOE
would take during the MIA for the
NOPR, DOE received several comments
related to the high price and limited
availability of xenon. NEMA
commented that xenon gas was the only
viable option for higher-efficiency fill
gas and cited manufacturer concerns
about its limited supply and quickly
escalating prices. (NEMA, No. 22 at p.
8) NEMA also stated that assumptions
DOE uses in its analysis can become
invalid quickly, citing the price of
xenon as an example of an assumption
that could seriously affect their
business. (NEMA, No. 21 at p. 108–109)
During the manufacturer interviews,
manufacturers contended that the global
supply of xenon was fixed and that
competition with other applications
(i.e., anesthesia) has caused the price of
xenon to increase ten-fold over the last
year. After receiving these comments,
DOE conducted its own research to
determine if market conditions for
xenon could affect its use as a higherefficiency fill gas.
According to DOE’s research, xenon is
one of three rare gases (along with neon
and krypton) produced by cryogenic air
separation. Given the low concentration
of the rare gases in the air (neon 0.002
percent, krypton 0.0001 percent, and
xenon 0.00001 percent),63 the only costeffective recovery options are large airseparation units. Most worldwide
supply is met by the three largest
industrial gas companies (Air Liquide,
Praxair, and Linde); another major
supplier is Iceblick, a former Statecontrolled enterprise of the Soviet
Union.
Major applications for xenon include
lighting, television flat panel displays,
the space industry (for ion engines and
satellite repositioning), medical imaging
and anesthesia, and electronic chip
manufacturing. All applications are
growing rapidly. Demand from the
semiconductor industry alone increased
from less than 1 million liters per year
in June 2007 to almost 3 million liters
per year in June 2008. Demand for
xenon has also grown significantly in
the last 18 months, greatly outpacing the
12 million liters of worldwide xenon
63 See
https://www.airliquide.com/file/
otherelement/pj/airliquide2007gb_bd_ok12439.pdf,
p. 110.
PO 00000
Frm 00055
Fmt 4701
Sfmt 4702
16973
production.64 While there remain
essentially inexhaustible supplies of
xenon in the atmosphere, considerable
investment would be required to expand
global production substantially. Since it
is impossible to immediately increase
supply to meet demand, spot prices
have increased from $3–$4 per liter to
$28–$35 per liter for large cylinders.65
These higher prices are likely to be
sustained in the near-term until supply
can meet the growing demand.
DOE estimates that the increased
demand for xenon as a result of this
rulemaking would range from 3.2
percent to 12.8 percent of current
worldwide production in the first year
the rulemaking takes effect. Over the 30year analysis period, the increased
demand for xenon could range from 0.5
percent to 18 percent of current
worldwide production, depending on
the scenario analyzed. This increased
demand is expected to have little longterm effect on the price or availability of
xenon, considering the other
contributing factors. Rapid growth or
decline of existing markets or the
discovery of a new application could
significantly affect the total demand for
xenon, perhaps even more than this
rulemaking. Furthermore, the above
numbers are based on the current
worldwide production (12 million
liters) and assume no increase in
production over the analysis period.
This is highly unlikely, given that
current demand substantially exceeds
supply. Any future increase in xenon
production would decrease the
percentages mentioned above. Thus,
DOE has tentatively concluded that the
amount of xenon required by lamp
manufacturers to produce lamps that
meet the proposed standards would not
significantly affect the price or
availability of xenon. DOE also
conducted an LCC sensitivity analysis to
determine the impact of higher xenon
prices on the consumer. For more
information on the xenon market
analysis and the consumer impacts of
higher xenon prices, see appendix 3B of
the TSD.
In the GSFL industry, manufacturers
stated that the ‘‘rare earth phosphors’’
are a key component of GSFL
performance. During the comment
period, some manufacturers expressed
concern that higher CSLs would
necessitate increasing mixes of the
costly rare earth phosphors in the lamp
coating. These manufacturers stated that
more stringent standards would drive
64 Betzendahl, Richard, ‘‘The Rare Gets More
Rare: The Rare Gases Market Update’’ (CryoGas
International) (June 2008) 26.
65 Id.
E:\FR\FM\13APP2.SGM
13APP2
16974
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
up demand for (and the price of) rare
earth phosphors, which already face
significant supply constraints. These
manufacturers added that continued
growth in the CFL market will also
capture an increasing share of available
phosphor supply in the future,
potentially increasing prices and
jeopardizing the cost-effectiveness of the
standards. Depending on the lamp type,
rare earth phosphors can be the highest
input cost of a GSFL.
Manufacturers also noted that higher
standards could drive manufacturing
processes to China, where the vast
majority of rare earth phosphors are
mined. Coupled with cheaper labor and
high export tariffs, the incentive to
move production of lamps to China
might prove too great to resist. To
address these concerns, DOE analyzed
the rare earth phosphor market to
understand the potential impact of the
standards on supply and demand,
pricing, growth, and innovation. DOE
also analyzed the impact on
employment for domestic
manufacturers.
Because the UV radiation emitted
within the lamp by the reaction of the
electrons and mercury vapor is
invisible, manufacturers must coat the
inside of the lamp’s glass with powered
phosphors. The phosphors fluoresce
when struck by the UV radiation and
convert it into visible light. Lessefficient, low-cost lamps only use
‘‘halophosphors’’ to coat the lamp.
Halophosphors are more abundant and
much less costly than rare earth
phosphors, but are also less efficient
and produce a lower quality light.
Coating a lamp with a layer of rare earth
phosphors in addition to, or in place of,
halophosphors can increase efficacy,
while dramatically improving color
quality and lumen maintenance. The
coating’s blend of phosphors
determines, in part, the CCT and CRI of
the lamp. The lamp coating of highperformance GSFL, often called a
‘‘triband’’ or ‘‘triphosphor’’ blend,
commonly includes three key
elements—terbium, europium, and
yttrium. Terbium and europium are the
rarest and reflect the greatest portion of
the coating’s cost.
DOE evaluated the impact of
standards on the phosphor markets and
concluded that mandating TSL5 would
increase the global demand and prices
of these phosphors. DOE expects 2012
terbium demand to be 31 percent greater
at TSL5 in the Shift-High Consumer
Expertise scenario than it would be in
the Existing Technologies base case.
DOE estimates europium demand would
increase by 10 percent, while Yttrium
demand would increase marginally.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
These estimates reflect the upper bound
of demand increases.
Given the historically volatile prices
of these phosphors and the
unpredictable future determinants of
supply and demand (such as Chinese
policy, additional mining operations,
and future technological changes), DOE
has not developed supply and demand
curves in order to estimate future
phosphor prices. However, DOE
recognizes significant price increases
are possible given the expected surge in
demand, particularly for terbium and
europium. Therefore, to analyze the
impact of higher phosphor prices, DOE
also conducted a sensitivity analysis to
address the potential increases in lamp
prices attributable to greater phosphor
costs on the consumer. That is, DOE
compares LCC savings with current
phosphor costs to LCC savings under a
scenario with higher phosphor prices.
Appendix 3C shows the results of this
sensitivity analysis and the rare earth
phosphor market analysis.
Additionally, DOE found several rare
earth mining projects in development
around the world that have the capacity
to increase rare earth supply. If prices
continue to climb, DOE expects the
economics of mining rare earths to
encourage more projects, and make lessconcentrated rare earth deposits
economically viable, which will
increase supply. For these reasons, DOE
does not believe standards, and their
potential impact on phosphor prices,
will affect product availability.
3. Government Regulatory Impact Model
Analysis
The GRIM analysis uses a standard,
annual cash-flow analysis that
incorporates manufacturer prices,
manufacturing costs, shipments, and
industry financial information as inputs
and models changes in costs,
distribution of shipments, investments,
and associated margins that would
result from new or amended regulatory
conditions (in this case, standard
levels). The GRIM spreadsheet uses a
number of inputs to arrive at a series of
annual cash flows, beginning with the
base year of the analysis (2007) and
continuing to 2042. DOE calculated
INPVs by summing the stream of annual
discounted cash flows during this
period.
DOE used the GRIM to calculate cash
flows using standard accounting
principles and to compare changes in
INPV between a base case and various
TSLs (the standards cases). Essentially,
the difference in INPV between the base
case and a standards case represents the
financial impact of the amended energy
conservation standards on
PO 00000
Frm 00056
Fmt 4701
Sfmt 4702
manufacturers. DOE collected this
information from a number of sources,
including publicly-available data and
interviews with manufacturers. See
chapter 13 of the TSD for details.
4. Manufacturer Interviews
As part of the MIA, DOE discussed
potential impacts of amended energy
conservation standards with
manufacturers responsible for the vast
majority of domestic GSFL and IRL
sales. The manufacturers interviewed
produce approximately 90 percent of
GSFL for sale and 85 percent of IRL for
sale. These interviews were in addition
to those DOE conducted as part of the
engineering analysis. The interviews
provided valuable information that DOE
used to evaluate the impacts of
amended energy conservation standards
on manufacturer cash flows,
manufacturing capacities, and
employment levels.
a. Key Issues
i. GSFL
Rare earth phosphor availability and
price—All of the GSFL manufacturers
DOE interviewed are concerned about
the availability and price of rare earth
phosphors. Due to the importation of
rare earth phosphors, any increases in
duties paid to producing countries, such
as China, could have significant impacts
on lamp manufacturing costs. Any
increase in lamp material costs directly
affects manufacturer profitability.
According to manufacturers, meeting
higher energy conservation standards
for GSFL would require an increase in
rare earth phosphor content in lamp
coatings. These manufacturers stated
that higher energy conservation
standards would drive up demand for
and prices of rare earth phosphors,
which are already in short supply. In
addition, manufacturers stated that the
continued growth in the CFL market
will erode future supply, jeopardizing
the cost-effectiveness of the standards.
Depending on the lamp type, rare earth
phosphors can be the highest input cost
of a GSFL. Some manufacturers also
noted that higher standards could drive
manufacturing processes to China,
where the vast majority of rare earth
phosphors are mined. Issues with rare
earth phosphors are specifically
addressed in appendix 3C of the TSD.
Reduction in product portfolio—Some
manufacturers are concerned that
energy conservation standards will force
manufacturers to eliminate some
product lines, shrinking their overall
marketability. According to
manufacturers, the ability to survive in
the industry is related to the companies’
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
diverse product portfolios. Companies
benefit from a wide range of products
and efficiencies. Depending on the
characteristics of the product,
manufacturers can up-sell to products
that reap higher profits. Manufacturers
are concerned that reducing the product
portfolio will reduce options for
customers and, ultimately, profitability.
Profit margin impact—All
manufacturers stated that energy
conservation standards have the
potential to greatly harm their
profitability. Manufacturers enjoy a
higher profit margin on higher-efficacy
or premium products than lower-end or
baseline products. Since higher-efficacy
or premium products tend to
incorporate design options that increase
energy efficiency, a high-efficiency
standard would commoditize such
products and subsequently lower the
overall manufacturer markup on
shipments. Several manufacturers stated
it is very difficult to pass along cost
increases to customers because of the
competitive nature of the industry.
Therefore, they believe any cost increase
due to standards set by DOE would
automatically lower profit margins.
ii. IRL
Product performance issues—All
manufacturers stated that
implementation of design options to
meet the proposed energy conservation
standards could cause a reduction in
product lifetime. Manufacturers stated
that all standard levels could be met by
lamps that combine improved
technology with shorter life. In addition
to this broad possibility, manufacturers
indicated that the product lifetime of
infrared lamps that meet efficacy levels
prescribed by TSL3, TSL4, and TSL5
could be lowered due to the ‘‘hot shock’’
application problem. If infrared lamps
are installed in a live fixture, sections of
the lamp’s filament can fuse together,
possibly decreasing the lifetime by 25 to
30 percent. Manufacturers are
concerned that both the performance
issues of hot shock and shorter life
could impact consumers’ acceptance of
covered IRL products. Any
dissatisfaction resulting lower lifetimes
of standards-compliant lamps could
hasten the shift to competing
technologies, which have much longer
lifetimes.
Xenon gas availability and price—
According to several manufacturers,
most higher-efficacy model lamps at
each TSL use xenon to increase efficacy.
While using a different fill gas does not
require significant capital investments,
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
manufacturers stated that xenon prices
have increased as much as ten-fold in
the past few years. In the short term,
global supplies of xenon are limited by
existing production capacity, so the IRL
industry has to compete with other
industries, such as medical
applications, that are better able to
support higher prices. For more
information on DOE’s analysis of this
issue, see appendix 3B of the TSD and
section V.G.2 of today’s notice.
Elimination of product types in the
manufacturers’ product portfolio—
Manufacturers are concerned that at
higher efficacy levels, all lamps will
need to switch to all infrared
technology, which would significantly
reduce product offerings.
Elimination of small-diameter
lamps—Manufacturers are concerned
that energy conservation standards
could eliminate smaller-diameter lamps.
Because of the small size, all
manufacturers use a single-ended quartz
burner in lamps smaller than PAR30,
limiting potential efficacy
improvements. Although DOE scales its
standard to smaller-diameter lamps and
there are existing PAR20 lamps at all
TSLs, manufacturers are concerned that
the improvements for small-diameter
lamps at high TSLs could be impossible
or cost prohibitive. DOE addresses the
issues of small-diameter lamps in
section V.C.7.b.ii of today’s notice.
Competition—Manufacturers stated
that some TSLs could affect competition
within the industry. For example, one
manufacturer has a patent on silverized
reflectors. While DOE did not set TSLs
around this technology, this
manufacturer could meet TSL2 with
cheaper lamps than its competitors. One
manufacturer has a cross license on the
technology, but has not made silverized
lamps recently and would incur
substantial capital and conversion costs
to produce them. There are competitive
concerns at TSL4 and TSL5 as well.
Two manufacturers have a full line of
products that currently meet TSL4. The
third manufacturer has some products at
this level, but is concerned that it would
have to incur significantly larger capital
costs at TSL4 to redesign and
manufacture different burners, which
could put it at a competitive
disadvantage. Only one manufacturer
currently has a full line of products at
TSL5. At TSL4 and TSL5, standardscompliant lamps could combine HIR
technology with an improved reflector,
potentially putting the company that
does not have access to silverized
reflectors at a disadvantage.
PO 00000
Frm 00057
Fmt 4701
Sfmt 4702
16975
Market erosion—Manufacturers stated
that emerging technology is already
starting to penetrate the IRL market. A
standard on IRL would be unique
because it would force investments in a
market that would shrink over the entire
lifetime of the investment. Depending
on market penetration of emerging
technology, these investments might
never be recouped. Also, manufacturers
are concerned that a standard on IRL
could hasten the switch to emerging
technology by lowering the difference in
their first cost price. If the standard did
increase the natural migration toward
new technology, it would be less likely
that manufacturers would make the
substantial investments to modify IRL
production equipment. Finally,
manufacturers are concerned that the
BR exemptions in EISA 2007 could also
erode the market: The higher the IRL
standard, the lower the relative cost of
the exempted incandescent lamps. If a
lower relative cost causes a large shift to
exempted incandescent lamps, it is less
likely that investments in improved
halogen lamps could be justified. To
address emerging technologies and BR
exemptions issues discussed by
manufacturers, DOE included several
shipment scenarios in both the NIA and
the GRIM. See chapter 10 and chapter
13 of the TSD for a discussion of the
shipment scenarios used in the
respective analysis.
b. Government Regulatory Impact Model
Scenarios and Key Inputs
i. GSFL Base-Case Shipment Forecast
In the GSFL GRIM, DOE estimated
manufacturer revenues, based on unit
shipment forecasts and distribution by
product class and efficacy. Changes in
the product mix at each standard level
are a key driver of manufacturer
finances. For this analysis, the GSFL
GRIM incorporated the two base-case
shipment scenarios from the NIA. In the
Existing Technologies base case
shipment scenario, DOE assumed that in
the base case customers would not
migrate to emerging technologies. DOE
also modeled an Emerging Technologies
base-case shipment scenario. In this
scenario, GSFL shipments are eroded in
the base case as more customers
purchase emerging technology rather
than covered GSFL. Table V.7 and Table
V.8 show total shipments forecasted by
the NIA for the 2012 and 2042 GSFL
base cases. For further information on
the GSFL base-case shipment forecast,
see chapter 10 of the TSD.
E:\FR\FM\13APP2.SGM
13APP2
16976
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE V.7—GSFL EMERGING TECHNOLOGIES BASE CASE TOTAL NIA-FORECASTED SHIPMENTS IN 2012 AND 2042
Total industry
shipments for
2012*
Product class
4-Foot
8-Foot
8-Foot
4-Foot
4-Foot
MBP ..............................................................................................................................................................
SP Slimline ...................................................................................................................................................
RDC HO .......................................................................................................................................................
T5 .................................................................................................................................................................
T5 HO ...........................................................................................................................................................
Total industry
shipments for
2042*
479,177,000
22,448,000
17,654,000
24,225,000
23,610,000
490,528,000
6,873,000
2,320,000
79,906,000
67,857,000
* Figures rounded to the nearest thousand.
TABLE V.8—GSFL EXISTING TECHNOLOGIES BASE CASE TOTAL NIA-FORECASTED SHIPMENTS IN 2012 AND 2042
Total industry
shipments for
2012*
Product class
4-Foot
8-Foot
8-Foot
4-Foot
4-Foot
MBP ..............................................................................................................................................................
SP Slimline ...................................................................................................................................................
RDC HO .......................................................................................................................................................
T5 .................................................................................................................................................................
T5 HO ...........................................................................................................................................................
Total industry
shipments for
2042*
479,177,000
22,448,000
17,654,000
24,225,000
23,610,000
645,323,000
6,873,000
2,320,000
105,863,000
67,857,000
* Figures rounded to the nearest thousand.
ii. IRL Base Case Shipments Forecast
As with the GSFL GRIM, the IRL
GRIM incorporated the two base-case
shipment scenarios from the NIA for the
period of 2007 to 2042 (Existing and
Emerging Technologies base cases).
Table V.9 and Table V.10 show total
shipments forecasted by the NIA for the
2012 and 2042 IRL for both base cases.
The tables include the base-case
shipments in 2020 because the impacts
under the Emerging Technologies base
case are most apparent in the years after
the standard becomes effective and the
differences between the base cases are
easily demonstrated in 2020. For further
information on IRL base case shipment
forecast, see chapter 10 of the TSD.
TABLE V.9—IRL EXISTING TECHNOLOGIES BASE CASE TOTAL NIA-FORECASTED SHIPMENTS IN 2012 AND 2042
Total industry
shipments in
2012*
Product class
PAR38 90W .................................................................................................................................
PAR38 75W .................................................................................................................................
PAR30 50W .................................................................................................................................
Total industry
shipments in
2020*
Total industry
shipments in
2042*
56,459,000
44,065,000
30,738,000
62,990,000
49,163,000
35,759,000
88,566,000
69,124,000
51,180,000
* Figures rounded to the nearest thousand.
TABLE V.10—IRL EMERGING TECHNOLOGIES BASE CASE TOTAL NIA-FORECASTED SHIPMENTS IN 2012 AND 2042
Total industry
shipments in
2012*
Product class
PAR38 90W .................................................................................................................................
PAR38 75W .................................................................................................................................
PAR30 50W .................................................................................................................................
Total industry
shipments in
2020*
Total industry
shipments in
2042*
52,393,000
40,892,000
28,417,000
31,654,642
24,706,062
17,318,155
52,978,000
41,349,000
30,058,000
* Figures rounded to the nearest thousand.
iii. GSFL Standards Case Shipments
Forecast
iv. IRL Standards-Case Shipments
Forecast
All shipment forecasts in the GSFL
GRIM are obtained from the GSFL NIA.
Consequently, the GSFL GRIM included
two efficacy distribution scenarios (shift
and roll-up), and two lighting expertise
scenarios (high- and market segmentbased lighting expertise). For additional
details on the various shipment
scenarios, see TSD chapter 10.
To characterize consumer behavior in
the IRL standards-case GRIM, DOE
considered the four shipment scenarios
found in the NIA. The IRL GRIM
considered two efficacy distributions
scenarios (shift and roll-up) and two
product substitution scenarios (product
substitution and no product
substitution). See chapter 10 of the TSD
for additional details on the IRL
standards-case shipment scenarios.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00058
Fmt 4701
Sfmt 4702
v. Manufacturing Production Costs
DOE derived manufacturing
production costs by using end-user
prices found in the NIA and discounting
them using typical markups along the
retail distribution chain. To calculate
manufacturer selling prices from these
end-user prices, DOE divided the
medium end-user prices in the NIA by
a typical markup for retail locations that
sell the covered products. DOE
calculated the markup for retail
locations using the revenues and cost of
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
goods sold from the annual reports of
publicly-traded companies. To
determine manufacturer production
costs from manufacturing selling price,
DOE divided manufacturing selling
prices by the manufacturer markup. The
manufacturer markup was calculated
with the same publicly-available
information used to calculate other
GRIM financial inputs (e.g., industrywide tax rate and working capital).
Further discussion of how DOE
calculated other GRIM financial inputs
from publicly-available information is
found in chapter 13 of the TSD.
vi. Amended Energy Conservation
Standards Markup Scenarios
In both the IRL and GSFL GRIM, DOE
modeled a flat markup scenario. This
scenario assumed that the cost of goods
sold for each lamp is marked up by a
flat percentage to cover standard SG&A
expenses, R&D expenses, and profit. To
derive this percentage, DOE evaluated
publicly-available financial information
for manufacturers of lighting equipment.
For GSFL only, DOE also modeled a
four-tier markup scenario. In this
scenario, DOE assumed that the markup
on lamps varies by efficacy in both the
base case and the standards case. DOE
learned from manufacturers that pricing
for GSFL is typically determined on the
basis of four product tiers,
corresponding to different phosphor
series. During the MIA interviews,
manufacturers provided information on
the range of typical efficacy levels in
these four tiers and the change in
profitability for each level. DOE used
this information, retail prices derived in
its product price determination, and
industry average gross margins to
estimate markups for GSFL under a
four-tier pricing strategy in the base
case. In the standards case, DOE
modeled the situation in which
portfolio reduction squeezes the margin
of higher-efficacy products as they are
‘‘demoted’’ to lower-relative-efficacytier products. This scenario is in line
with information submitted during
manufacturing interviews, which
responds to manufacturers’ concern that
DOE standards could severely disrupt
profitability.
The four-tier markup scenario was not
modeled for IRL because markups do
not increase as a function of efficacy as
is the case for GSFL. Thus, this scenario
is not representative of the IRL industry.
vii. Product and Capital Conversion
Costs
Energy conservation standards
typically cause manufacturers to incur
one-time conversion costs to bring their
production facilities and product
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
designs into compliance with the
amended standards. For the purpose of
the MIA, DOE classified these
conversion costs into two major groups:
(1) Product conversion costs; and (2)
capital conversion costs. Product
conversion expenses are one-time
investments in research, development,
testing, and marketing, focused on
making product designs comply with
the new energy conservation standard.
Capital conversion expenditures are
one-time investments in property, plant,
and equipment to adapt or change
existing production facilities so that
new product designs can be fabricated
and assembled.
DOE assessed the R&D expenditures
manufacturers would be required to
make at each TSL. DOE obtained
financial information through
manufacturer interviews and aggregated
the results to mask any proprietary or
confidential information from any one
manufacturer. DOE considered a
number of manufacturer responses for
GSFL and IRL at each TSL. DOE
estimated the total product conversion
expenses by gathering manufacturer
responses, then weighted these data by
market share.
DOE also evaluated the level of
capital conversion expenditures
manufacturers would incur to comply
with amended energy conservation
standards. DOE used the manufacturer
interviews to gather data on the level of
capital investment required at each TSL.
Manufacturers explained how different
TSLs affected their ability to use
existing plants, tooling, and equipment.
From the interviews, DOE was able to
estimate what portion of existing
manufacturing assets would need to be
replaced and/or reconfigured, and what
additional manufacturing assets would
be required to manufacture the higherefficacy products. In most cases, DOE
projected that the proportion of existing
assets that manufacturers would have to
replace would increase as standard
levels for GSFL and IRL increase. For
GSFL, DOE included capital costs for
the natural market shift from T12 to T8
lamps in the base case. For IRL, the
capital conversion expenses
manufacturers provided during
interviews were based on converting
their manufacturing equipment to meet
the current volume of shipments. Since
the shipments projected in the NIA
decrease in the base cases, DOE scaled
the conversion capital investments to
account for the decline in shipments
from 2008 to the year the standard
becomes effective. DOE also consulted
an independent supplier of IRL coaters
to identify additional costs above TSL4
PO 00000
Frm 00059
Fmt 4701
Sfmt 4702
16977
that would be needed for manufacturers
to meet TSL5.
The investment figures used in the
GRIM can be found in section VI.B.2.a
of today’s notice. For additional
information on the estimated product
conversion and capital conversion costs,
see chapter 13 of the TSD.
H. Employment Impact Analysis
DOE considers employment impacts
in the domestic economy as one factor
in selecting a proposed standard.
Employment impacts include direct and
indirect impacts. Direct employment
impacts are any changes in the number
of employees for manufacturers of the
appliance products that are the subject
of this rulemaking, their suppliers, and
related service firms. Indirect
employment impacts are employment
changes in the larger economy that
occur due to the shift in expenditures
and capital investment caused by the
purchase and operation of moreefficient appliances. The MIA addresses
the portion of direct employment
impacts that concern manufacturers of
GSFL and IRL (see section V.G); this
section addresses indirect impacts.
Indirect employment impacts from
standards consist of the net jobs created
or eliminated in the national economy,
other than in the manufacturing sector
being regulated, due to: (1) Reduced
spending by end users on energy (i.e.,
electricity); (2) reduced spending on
new energy supply by the utility
industry; (3) increased spending on the
purchase price of new products; and (4)
the effects of those three factors
throughout the economy. DOE expects
the net monetary savings from standards
to be redirected to other forms of
economic activity. DOE also expects
these shifts in spending and economic
activity to affect the demand for labor in
the short term, as explained below.
One method for assessing the possible
effects on the demand for labor of such
shifts in economic activity is to compare
sectoral employment statistics
developed by the Labor Department’s
Bureau of Labor Statistics (BLS).66 BLS
regularly publishes its estimates of the
number of jobs per million dollars of
economic activity in different sectors of
the economy, as well as the jobs created
elsewhere in the economy by this same
economic activity. Data from BLS
indicate that expenditures in the utility
66 Data on industry employment, hours, labor
compensation, value of production, and the implicit
price deflator for output for these industries are
available upon request by calling the Division of
Industry Productivity Studies (202–691–5618) or by
sending a request by e-mail to dipsweb@bls.gov.
Available at: https://www.bls.gov/news.release/
prin1.nr0.htm.
E:\FR\FM\13APP2.SGM
13APP2
16978
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
sector generally create fewer jobs (both
directly and indirectly) than
expenditures in other sectors of the
economy. There are many reasons for
these differences, including differences
in wages and the fact that the utility
sector is more capital intensive and less
labor intensive than other sectors. See
Bureau of Economic Analysis, ‘‘A User
Handbook for the Regional Input-Output
Modeling System (RIMS II), ’’ Third
Edition, Washington, DC, U.S.
Department of Commerce, March
1997.67
Efficiency standards have the effect of
reducing consumer utility bills. Because
reduced consumer expenditures for
energy likely lead to increased
expenditures in other sectors of the
economy, the general effect of efficacy
standards is to shift economic activity
from a less labor-intensive sector (i.e.,
the utility sector) to more laborintensive sectors (e.g., the retail and
manufacturing sectors). Thus, based on
the BLS data alone, DOE believes net
national employment will increase due
to shifts in economic activity resulting
from standards for GSFL and IRL.
In developing this proposed rule, DOE
estimated indirect national employment
impacts using an input/output model of
the U.S. economy called ‘‘Impact of
Sector Energy Technologies’’ (ImSET);
ImSET is a spreadsheet model of the
U.S. economy that focuses on 188
sectors most relevant to industrial,
commercial, and residential building
energy use.68 ImSET is a specialpurpose version of the ‘‘U.S. Benchmark
National Input-Output (I–O) Model,’’
which has been designed to estimate the
national employment and income
effects of energy-saving technologies
deployed by DOE’s Office of Energy
Efficiency and Renewable Energy.
Compared with previous versions of the
model used in earlier rulemakings, this
version allows for more complete and
automated analysis of the essential
features of energy efficiency
investments in buildings, industry,
transportation, and the electric power
sectors. The ImSET software includes a
computer-based I–O model with
structural coefficients to characterize
economic flows among the 188 sectors.
ImSET’s national economic I–O
structure is based on the 1997 U.S.
benchmark table (Lawson, et al.,
2002),69 specially aggregated to 188
67 Available at: https://www.bea.gov/scb/pdf/
regional/perinc/meth/rims2.pdf.
68 Roop, J. M., M. J. Scott, and R. W. Schultz.
ImSET: Impact of Sector Energy Technologies,
PNNL–15273 (Pacific Northwest National
Laboratory) (2005).
69 Lawson, Ann M., Kurt S. Bersani, Mahnaz
Fahim-Nader, and Jiemin Guo, ‘‘Benchmark Input-
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
sectors. DOE estimated changes in
expenditures using the NIA spreadsheet.
Using ImSET, DOE then estimated the
net national indirect-employment
impacts on employment in the
manufacturing and energy industries of
the new efficacy standards on
employment by sector.
While both ImSET and the direct use
of BLS employment data suggest the
proposed standards could increase the
net demand for labor in the economy,
the gains would most likely be very
small relative to total national
employment. Therefore, DOE concludes
only that the proposed standards are
likely to produce employment benefits
that are sufficient to fully offset, any
adverse impacts on employment in the
manufacturing or energy industries
related to GSFL and IRL. See the TSD
chapter 15.
NEMA agreed that ImSET would be
the most appropriate tool to analyze
employment impacts on a national
scale. NEMA also suggested that DOE
should be mindful of changes in
production technologies and the
associated flows of labor and capital
across industries that could be needed
under more-stringent efficacy standards,
which would not necessarily be
reflected in the ImSET I–O analysis.
(NEMA, No. 22, p. 34)
In response, DOE believes that the
fixed I–O matrix is generally adequate
in predicting the range of magnitude of
lighting savings. Changes in production
technologies and the associated
economic flows with direct employment
implications are addressed in the MIA
chapter (chapter 13) of the TSD. DOE
uses the ImSET model to address
indirect employment effects of the
standards. For more details on the
employment impact analysis, see TSD
chapter 15.
I. Utility Impact Analysis
The utility impact analysis estimates
the change in the forecasted power
generation capacity of the Nation which
would be expected to result from the
adoption of new efficacy standards. This
section discusses the methodology used,
the results of which can be found in
section 0. DOE used a version of EIA’s
National Energy Modeling System
(NEMS) for this utility impact analysis.
NEMS, which is available in the public
domain, is a large, multisectoral, partialequilibrium model of the U.S. energy
sector. EIA uses NEMS to produce its
AEO, a widely-recognized baseline
energy forecast for the United States.
The version of NEMS used for appliance
Output Accounts of the U.S. Economy, 1997,’’
Survey of Current Business (Dec. 2002) 19–117.
PO 00000
Frm 00060
Fmt 4701
Sfmt 4702
standards analysis is called NEMS–BT
and is primarily based on the AEO 2008
with minor modifications.70 The
NEMS–BT offers a sophisticated picture
of the effect of standards, since it
accounts for the interactions between
the various energy supply and demand
sectors and the economy as a whole.
Specifically, NEMS–BT models
certain policy scenarios, such as the
effect of reduced electricity
consumption, for each trial standard
level. The analysis output provides a
forecast for the needed generation
capacities at each TSL. The estimated
net benefit of the standard is the
difference between the forecasted
generation capacities by NEMS–BT and
the AEO2008 Reference Case.
DOE obtained the energy savings
inputs for the utility impact analysis
from the NIA’s electricity consumption
savings. These inputs reflect the effects
on electricity of efficiency
improvements due to the deployment of
GSFL and IRL. Chapter 14 of the TSD
accompanying this notice presents
results of the utility impact analysis.
DOE received comments requesting
that DOE report gas and electricity price
impacts, and the economic benefits of
reduced need for new electric power
plants and infrastructure. The
expectation is that lower electricity
demand will lead to lower prices for
both electricity and natural gas that
would benefit consumers. The Joint
Comment also stated that the benefits of
reduced power plant and infrastructure
costs may not be fully reflected in prices
because consumers generally pay retail
rates for electricity that are based on the
average embedded cost of all the
facilities used to serve them, rather than
on marginal costs. (Joint Comment, No.
23 at pp. 20–22)
DOE considered reporting gas and
electricity price impacts but found that
the uncertainty of price projections,
together with the fairly small impact of
the standards relative to total electricity
demand, makes these price changes
highly uncertain. As a result, DOE
believes that they should not be
weighed heavily in the decision
concerning the standard level. Given the
current complexity of utility regulation
70 The EIA approves the use of the name ‘‘NEMS’’
to describe only an AEO version of the model
without any modification to code or data. Because
the present analysis entails some minor code
modifications and runs the model under various
policy scenarios that deviate from AEO
assumptions, the name ‘‘NEMS–BT’’ refers to the
model as used here. (‘‘BT’’ stands for DOE’s
Building Technologies Program.) For more
information on NEMS, refer to The National Energy
Modeling System: An Overview, DOE/EIA–0581 (98)
(Feb. 1998) (available at: https://tonto.eia.doe.gov/
FTPROOT/forecasting/058198.pdf).
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
in the United States (with significant
variances among States), it does not
seem appropriate to attempt to measure
impacts on infrastructure costs and
prices where there is likely to be
significant overlap.
J. Environmental Analysis
DOE has prepared a draft
environmental assessment (EA)
pursuant to the National Environmental
Policy Act and the requirements of 42
U.S.C. 6295(o)(2)(B)(i)(VI) and 6316(a),
to determine the environmental impacts
of the proposed amended standards.
Specifically, DOE estimated the
reduction in power sector emissions of
carbon dioxide (CO2) using the NEMS–
BT computer model. DOE calculated a
range of estimates for reduction in
oxides of nitrogen (NOX) emissions and
mercury (Hg) emissions using current
power sector emission rates. However,
the Environmental Assessment (see the
Environmental Assessment report of the
TSD accompanying this notice) does not
include the estimated reduction in
power sector impacts of sulfur dioxide
(SO2), because DOE has determined that
due to the presence of nationals caps on
SO2 emissions as addressed below, any
such reduction resulting from an energy
conservation standard would not affect
the overall level of SO2 emissions in the
United States.
The NEMS–BT is run similarly to the
AEO2008 NEMS, except the energy use
is reduced by the amount of energy
saved due to the TSLs. DOE obtained
the inputs of national energy savings
from the NIA spreadsheet model. For
the Environmental Assessment, the
output is the forecasted physical
emissions. The net benefit of the
standard is the difference between
emissions estimated by NEMS–BT and
the AEO2008 Reference Case. The
NEMS–BT tracks CO2 emissions using a
detailed module that provides results
with a broad coverage of all sectors and
inclusion of interactive effects.
The Clean Air Act Amendments of
1990 set an emissions cap on SO2 for all
power generation. The attainment of
this target, however, is flexible among
generators and is enforced through the
use of emissions allowances and
tradable permits. Because SO2 emissions
allowances have value, they will almost
certainly be used by generators,
although not necessarily immediately or
in the same year with and without a
standard in place. In other words, with
or without a standard, total cumulative
SO2 emissions will always be at or near
the ceiling, while there may be some
timing differences between year-by-year
forecast. Thus, it is unlikely that there
will be an SO2 environmental benefit
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
from electricity savings as long as there
is enforcement of the emissions ceilings.
Although there may not be an actual
reduction in SO2 emissions from
electricity savings, there still may be an
economic benefit from reduced demand
for SO2 emission allowances. Electricity
savings decrease the generation of SO2
emissions from power production,
which can decrease the need to
purchase or generate SO2 emissions
allowance credits, and decrease the
costs of complying with regulatory caps
on emissions.
Like SO2, future emissions of NOX
and Hg would have been subject to
emissions caps under the Clean Air
Interstate Act (CAIR) and Clean Air
Mercury Rule (CAMR). As discussed
later in section VI.B.6, these rules have
been vacated by a Federal court. But the
NEMS–BT model used for today’s final
rule assumed that both NOX and Hg
emissions would be subject to CAIR and
CAMR emissions caps. In the case of
NOX emissions, CAIR would have
permanently capped emissions in 28
eastern States and the District of
Columbia. Because the NEMS–BT
modeling assumed NOX emissions
would be subject to CAIR, DOE
established a range of NOX reductions
based on the use of a NOX low and high
emissions rates (in metric kilotons (kt)
of NOX emitted per terawatt-hours
(TWh) of electricity generated) derived
from the AEO2008. To estimate the
reduction in NOX emissions, DOE
multiplied these emission rates by the
reduction in electricity generation due
to the standards considered. For
mercury, because the emissions caps
specified by CAMR would have applied
to the entire country, DOE was unable
to use NEMS–BT model to estimate the
physical quantity changes in mercury
emissions due to energy conservation
standards. To estimate mercury
emission reductions due to standards,
DOE used an Hg emission rate (in metric
tons of Hg per energy produced) based
on AEO2008. Because virtually all
mercury emitted from electricity
generation is from coal-fired power
plants, DOE based the emission rate on
the metric tons of mercury emitted per
TWh of coal-generated electricity. To
estimate the reduction in mercury
emissions, DOE multiplied the emission
rate by the reduction in coal-generated
electricity associated with standards
considered.
DOE received comments from
stakeholders on the valuation of CO2
emissions savings that result from
standards. The Joint Comment stated
that by not placing an economic value
on the benefits from reduced CO2
emissions, DOE makes it difficult to
PO 00000
Frm 00061
Fmt 4701
Sfmt 4702
16979
weigh these benefits in comparison to
other benefits and costs resulting from
a given standard level. Implicitly, the
Joint Comment argued that DOE is
arbitrarily valuing pollution reductions
at $0. The best way to avoid this mistake
would be to estimate an economic value
for pollutant reductions. According to
the Joint Comment, voluminous work,
both from academia and the business
world, exists on the range of potential
carbon prices under various regulatory
scenarios. (Joint Comment, No. 23 at pp.
19–20). NEMA also suggested a CBO
report as a potential starting point.
(NEMA, No. 22 at p. 34) DOE has made
several additions to its monetization of
environmental emissions reductions in
today’s proposed rule, which are
discussed in section 0, but has chosen
to continue to report these benefits
separately from the net benefits of
energy savings. Nothing in EPCA, nor in
the National Environmental Policy Act,
requires that the economic value of
emissions reduction be incorporated in
the net present value analysis of the
value of energy savings. Unlike energy
savings, the economic value of
emissions reduction is not priced in the
marketplace.
VI. Analytical Results
A. Trial Standard Levels
DOE analyzed the costs and benefits
of many TSLs for the GSFL and IRL
covered in today’s proposed rule. Table
VI.2 and Table VI.4 present the TSLs
and the corresponding product class
efficiencies for GSFL and IRL. See the
engineering analysis in section V.C of
this NOPR for a more detailed
discussion of the efficacy levels.
In this section, DOE is only presenting
the analytical results for the TSLs of the
product classes that DOE analyzed
directly (the ‘‘representative product
classes’’). DOE scaled the standards for
these representative product classes to
create standards for other product
classes that were not directly analyzed
(such as modified-spectrum lamps), as
set forth in chapter 5 of the TSD.
The Joint Comment stated that DOE
should use separate TSLs for GSFL and
IRL. The Joint Comment also stated that
the sets of CSLs in the ANOPR should
be made into a single set of TSLs,
without further regrouping. (Joint
Comment, No. 23 at p. 18) In the NOPR,
DOE has generally followed the
methodology suggested by the Joint
Comment. In this notice, DOE did not
group GSFL with IRL. For example,
each GSFL TSL reflects a set of efficacy
levels across all products classes only
within GSFL. DOE believes that this
approach is appropriate because GSFL
E:\FR\FM\13APP2.SGM
13APP2
16980
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
and IRL, though often produced by the
same manufacturers, frequently serve
different lighting applications, so energy
conservation standards for one lamp
type are not likely to affect the market
or energy consumption of the other
lamp type. The following sections
describe the TSLs and corresponding
efficacy levels.
1. General Service Fluorescent Lamps
DOE developed product classes for
GSFL based on the utility of the covered
lamps and how they are used in the
market. DOE observed that 4-foot
medium bipin lamps constitute the vast
majority of GSFL sales. These lamps are
followed in order of unit sales by 8-foot
single pin slimline lamps and 8-foot
recessed double contact high output
lamps. Because 4-foot medium bipin, 8foot single pin slimline, and 8-foot
recessed double contact HO lamps are
the most common GSFL, DOE selected
them as representative lamps for its
analysis. Lamps with a CCT greater than
4,500K comprise a small share of the
GSFL market. Therefore, DOE chose to
analyze lamps with a CCT less than or
equal to 4,500K. For the NOPR, DOE
also chose to analyze 4-foot miniature
bipin T5 standard output (SO) and HO
lamps with a CCT less than or equal to
4,500K. (DOE did not analyze T5 lamps
in the March 2008 ANOPR.)
The following lamps with a CCT less
than 4,500K compose the five
representative product classes: (1) 4-foot
medium bipin; (2) 8-foot single pin
slimline; (3) 8-foot recessed double
contact HO lamps; (4) 4-foot miniature
bipin T5 SO; and (5) 4-foot miniature
bipin T5 HO lamps. Standards for other
product classes were established by
scaling the standards developed for
these representative product classes. All
12 GSFL classes are shown in Table
VI.1.
wattage, lower-diameter lamps with
higher efficacies. Table VI.2 shows the
TSLs for GSFL. Each TSL is generally
composed of the efficacy level of the
same number across all product classes.
That is, TSL1 is composed of EL1 for all
classes, TSL2 is composed of EL2, etc.
For T5 standard output lamps, however,
DOE selected EL1 for all TSLs except
TSL5, to which DOE assigned EL2 (the
maximum technologically feasible
efficacy level for T5 SO lamps). For T5
high output lamps, DOE selected EL1
for all TSLs because it is the maximum
efficacy for this lamp type. With the
methodology, TSL5 represents all
maximum technologically feasible GSFL
efficacy levels for this NOPR.
The efficacy levels for the five
representative product classes are
shown in Table VI.2; Efficiency levels
for all product classes in the TSLs can
be found in the NOPR TSD chapter 5.
DOE analyzes systems that meet each
efficacy level in the TSLs by pairing
standard and reduced-wattage lamps
featuring a variety of design options
with appropriate magnetic or electronic
ballasts. As discussed in the screening
analysis (NOPR TSD chapter 4), DOE
uses design options with highly
emissive electrode coatings, higher
efficiency lamp fill gas composition,
higher efficiency phosphors, glass
coatings, or lamp diameter to achieve
higher efficacy levels.
TABLE VI.1—GSFL PRODUCT
CLASSES
GSFL lamp type
4-Foot Medium
Bipin.
2-Foot UShaped.
8-Foot Single
Pin Slimline.
8-Foot RDC HO
4-Foot T5 SO ...
4-Foot T5 HO ..
CCT
≤ 4,500K (representative).
> 4,500K.
≤ 4,500K.
> 4,500K.
≤ 4,500K (representative).
> 4,500K.
≤ 4,500K (representative).
> 4,500K.
≤ 4,500K (representative).
> 4,500K.
≤ 4,500K (representative).
> 4,500K.
DOE developed TSLs that generally
follow a trend of increasing efficacy by
using higher-quality phosphors. The
TSLs also represent a general move from
higher-wattage technologies to lower-
TABLE VI.2—TRIAL STANDARD LEVELS FOR GSFL—EFFICIENCY LEVELS FOR THE FIVE REPRESENTATIVE GSFL PRODUCT
CLASSES
Trial standard level (lm/w)
Representative product class
4-Foot
8-Foot
8-Foot
4-Foot
4-Foot
EPCA
standard *
Medium Bipin, CCT ≤ 4,500K ..............................
Single Pin Slimline, CCT ≤ 4,500K ......................
RDC HO, CCT ≤ 4,500K ......................................
Miniature Bipin T5 SO, CCT ≤ 4,500K ................
Miniature Bipin T5 HO, CCT ≤ 4,500K ................
TSL1
75.0
80.0
80.0
[None]
[None]
TSL2
78
89
83
103
89
TSL3
81
93
87
103
89
84
95
88
103
89
TSL4
89
97
92
103
89
TSL5
94
100
95
108
89
* 42 U.S.C. 6295(i)(1)(B). Applies to GSFL as defined by EPCA.
TSL1, which would set energy
conservation standards for GSFL to EL1
for all product classes, would eliminate
the 4-foot medium bipin T12 baselines,
the 95W T12 8-foot recessed double
contact HO baseline, and the 75W T12
8-foot single pin slimline baseline from
the market. In the 4-foot medium bipin
product class, this TSL could be met
either with a 40W T12 lamp using
improved 700-series or 800-series
phosphors, or with a 34W T12 lamp
using a 700-series phosphor. At this
TSL, 4-foot medium bipin lamps using
only halophosphors would not be able
to meet this TSL. The 75W 8-foot single
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
pin slimline T12 and 110W recessed
double contact HO lamps would need to
use an 800-series rare earth phosphor to
meet TSL1. TSL1 also represents a level
which would likely prevent the
commercialization of T5 lamps with
halophosphor coatings while allowing
for 800-series 4-foot T5 miniature bipin
and 4-foot T5 miniature bipin HO lamps
that are currently commercially
available to remain on the market.
TSL2 would set energy conservation
standards for GSFL at EL2 for 4-foot
MBP, 8-foot SP slimline, and 8-foot RDC
HO lamps. The 34W T12 4-foot medium
bipin lamps would likely be required to
PO 00000
Frm 00062
Fmt 4701
Sfmt 4702
use 800-series rare earth phosphors to
meet TSL2. For 40W T12 lamps, TSL2
is expected to require a premium 800series rare earth phosphor and is the
maximum TSL that a 40W T12 would be
able meet. In the 8-foot single pin
slimline product class, TSL2 is expected
to require a premium 800-series rare
earth phosphor for the 75W T12 and is
the maximum TSL that 75W T12 would
likely be able to meet. This standard
level would eliminate the 60W T12
baseline and require a 700-series
phosphor for this lamp. In the 8-foot
recessed double contact HO product
class, TSL2 would eliminate 110W T12
E:\FR\FM\13APP2.SGM
13APP2
16981
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
lamps and the 95W T12 baseline and
would require rare earth 700-series
phosphors for 95W T12 lamps. For T5s,
TSL2 still represents the first efficacy
level, which would allow for 800-series
4-foot T5 miniature bipin and 4-foot T5
miniature bipin HO lamps to remain on
the market.
TSL3 would set energy conservation
standards for GSFL at EL3 for 4-foot
MBP, 8-foot SP slimline, and 8-foot RDC
HO lamps. In this product class, the
32W T8 baseline would be eliminated
from the market, and to produce a TSL3compliant 32W T8 lamp, manufacturers
would need to use an 800-series rare
earth phosphor. The 34W T12 lamps
would likely require an improved 800series rare earth phosphor mixture and
possibly other design options, such as a
different gas fill or increased thickness
of the bulb-wall phosphor. Only
reduced-wattage (34W) 4-foot medium
bipin T12 lamps are expected to meet
this TSL. In the 8-foot single pin
slimline product class, TSL3 would
require the use of an 800-series 60W
T12 lamp. This standard level is
expected to eliminate all 75W T12
lamps and to require an improved 700series phosphor for the 60W T12. In the
8-foot recessed double contact HO class,
TSL3 requires 95W T12 lamps to shift
to 800-series rare earth phosphors. TSL3
also represents the first efficacy level for
4-foot T5 miniature bipin and 4-foot T5
miniature bipin HO lamps, retaining
800-series versions of those lamps on
the market.
TSL4, which would set energy
conservation standards for GSFL at EL4
for 4-foot MBP, 8-foot SP slimline, and
8-foot RDC HO, would be expected to
eliminate 4,100K T12 lamps from the
marketplace. TSL4 would also be
expected to raise the efficacy of all fullwattage T8 lamps above the baselines
for the aforementioned product classes.
In the 4-foot medium bipin product
class, TSL4 could be met by improved
800-series full-wattage T8 lamps, or by
800-series 30W and 25W T8 lamps. For
the 8-foot SP slimline product class,
59W T8 lamps would likely need to use
an 800-series rare earth phosphor to
meet TSL4. TSL4, while expected to
eliminate 8-foot T12 RDC HO lamps
from the market, would require an
improved 700-series mixture to be used
in T8 lamps for this product class. TSL4
also represents the first efficacy level for
4-foot T5 miniature bipin and 4-foot T5
miniature bipin HO lamps, retaining
800-series T5 lamps on the market.
TSL5 represents the max-tech EL for
all GSFL product classes. T12 lamps
and 700-series T8 lamps are expected to
not be able to meet this level. In the 4foot medium bipin and 8-foot single pin
slimline product class, T8 lamps would
need to have a premium 800-series rare
earth phosphor coating to meet TSL5.
TSL5 could also be met by the 28W
reduced-wattage 4-foot medium bipin
T8 lamp and the 57W and 55W reducedwattage 8-foot single pin slimline T8
lamps. TSL5 would require movement
800-series T8 lamps in the 8-foot
recessed double contact HO product
class. For the 4-foot T5 MiniBP SO
product class, a standard-wattage (28W)
and reduced-wattage (26W) T5 with an
improved 800-series phosphor would
need to be used in order to meet TSL5.
Because DOE created only one efficacy
level for the 4-foot T5 miniature bipin
HO lamps, TSL5 would set energy
conservation standards for 4-foot T5
MiniBP HO lamps at EL1 and allow 800series T5 HO lamps to remain on the
market. For more information on the
TSLs for GSFL, see chapter 9 of the
TSD.
2. Incandescent Reflector Lamps
As discussed in section V.C, for IRL,
DOE has established five efficacy levels
based on an equation relating efficacy
(in lumens per watt) to lamp wattage.
Also discussed in section V.C, DOE has
analyzed only one representative
product class and intends to scale
minimum efficacy requirements to other
product classes. All IRL classes are
listed in Table VI.3. As seen in the table,
DOE only directly analyzed the
standard-spectrum IRL with a diameter
greater than 2.5 inches and voltage less
than 125 volts.
TABLE VI.3—IRL PRODUCT CLASSES
Lamp type
Diameter
Voltage
Standard Spectrum ..........................................................
> 2.5 inches .....................................................................
≤ 2.5 inches .....................................................................
Modified Spectrum ...........................................................
> 2.5 inches .....................................................................
≤ 2.5 inches .....................................................................
In establishing TSLs for IRL, in this
NOPR, DOE analyzes five TSLs, each
one corresponding to one efficacy level.
For example, TSL1 corresponds to EL1
and TSL5 corresponds to EL5. TSL1
could be achieved with an improved
halogen lamp that uses xenon, a higherefficiency inert fill gas. TSL2 could be
achieved with a standard halogen
infrared lamp with a lifetime of 6,000
hours or a halogen lamp with an
improved reflector, such as silver. TSL3
could be met with a 3,000-hour-lifetime
standard halogen infrared lamp. TSL4
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
could be met with a 4,000-hour-lifetime
improved halogen infrared lamp.
Improvements in the halogen infrared
lamp may include the use of a doubleended halogen infrared burner, higherefficiency inert fill gas, or more-efficient
filament orientation. Finally, TSL5
could be achieved with a 4,200-hourlifetime halogen infrared lamp (even
further improved). These further
improvements include an improved
reflector, improved IR coating, or
filament design that produces higher
PO 00000
Frm 00063
Fmt 4701
Sfmt 4702
≥ 125
> 125 (representative).
≥ 125.
< 125.
≥ 125.
< 125.
≥ 125.
< 125.
temperature operation (and may reduce
lifetime to 3,000 hours).
The efficacy levels for the
representative analyzed product class
are shown in Table VI.4 for the TSLs to
which they correspond. The efficacy
levels for this representative product
class were then scaled to create the
efficacy levels for the seven other IRL
product classes as described in section
V.C.7.b of this notice. For more
information on efficacy standard levels
for the other seven product classes, see
chapter 5 of the TSD.
E:\FR\FM\13APP2.SGM
13APP2
16982
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.4—TRIAL STANDARD LEVELS FOR IRL—EFFICIENCY LEVELS FOR THE STANDARD SPECTRUM, DIAMETER > 2.5
INCHES, VOLTAGE < 125 IRL PRODUCT CLASS
Trial standard level (lm/W)*
EPCA standard**
10.5
11.0
12.5
14.0
14.5
15.0
TSL1
TSL3
TSL4
TSL5
4.6P0.27
(40–50 Watts)
(51–66 Watts)
(67–85 Watts)
(86–115 Watts)
(116–155 Watts)
(156–205 Watts)
TSL2
4.8P0.27
5.5P0.27
6.2P0.27
6.9P0.27
* P is the rated wattage of the lamp.
** 42 U.S.C. 6295(i)(1)(B). Applies to IRL as defined by EPCA.
B. Economic Justification and Energy
Savings
The following section discusses the
results of the analyses discussed in
section 0. Section VI.C contains further
discussion regarding DOE’s
consideration of these results in the
selection of proposed standards levels.
1. Economic Impacts on Consumers
a. Life-Cycle Cost and Payback Period
DOE calculated the average LCC
savings relative to the baseline for each
product class, as in the March 2008
ANOPR. 73 FR 13620, 13665 (March 13,
2008). A new standard would affect
different lamp consumers differently,
depending on the market segment to
which they belong. DOE designs the
LCC analysis around lamp purchasing
events, in order to characterize the
circumstances under which consumers
need to replace a lamp. The LCC
spreadsheet calculates the LCC impacts
for each lamp replacement event
separately. Examining the impacts on
each event separately allows DOE to
view the results of many subgroup
populations in the LCC analyses.
For the NOPR, as in the March 2008
ANOPR, DOE decided not to aggregate
the results of the various event scenarios
together into a single LCC at each
efficacy level. 73 FR 13620, 13655
(March 13, 2008). To do so would have
required too many assumptions, such as
the relative occurrence of each event
over time, and the market share of each
lamp in the base case and each
standards case. DOE believes it is more
appropriate to incorporate assumptions
about consumer decisions and long-term
market trends in the NIA, and leave the
LCC as a direct head-to-head
comparison between lamp and lampand-ballast designs under different
events. Further, the LCC savings results
help DOE estimate consumer behavior
decisions for the NIA.
DOE recognizes that the large number
of LCC and PBP results can make it
difficult to draw conclusions about the
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
cost-effectiveness of efficacy standards.
The following discussion presents
salient results from the LCC analysis.
The LCC results are presented according
to the lamp purchasing events that
culminate in purchase of lamp-andballast designs. These results reflect a
subset of all of the possible events,
although they represent the most
prevalent purchasing events.71 The
analysis provides a range of LCC savings
for each efficacy level. The range
reflects the results of multiple systems
(i.e., multiple lamp-ballast pairings) that
consumers could purchase to meet an
efficacy level.
In addition, DOE has chosen not to
present detailed PBP results by efficacy
level in this NOPR because DOE
believes that LCC results are a better
measure of cost-effectiveness. However,
a full set of both LCC and PBP results
for the systems DOE analyzed are
available in chapter 8 and appendix 8B
of the TSD. All the LCC results shown
here were generated using AEO2008
reference case electricity prices and
medium-range lamp and ballast prices.
i. General Service Fluorescent Lamps
Table VI.5 through Table VI.11
present the results for the baseline
lamps in each of the four product
classes DOE analyzed (i.e., 4-foot
medium bipin, 4-foot miniature bipin
SO, 4-foot miniature bipin HO, 8-foot
single pin slimline, and 8-foot recessed
double contact HO). When a standard
results in ‘‘positive LCC savings,’’ the
life cycle cost of the standardscompliant lamp is less than the life
cycle cost of the baseline lamp, and the
consumer benefits. When a standard
results in ‘‘negative LCC savings,’’ the
life cycle cost of the standardscompliant lamp is higher than the life
cycle cost of the baseline lamp, and the
consumer is adversely affected. The
71 In many cases, DOE omitted events I(b) and IV
in this notice, because DOE believes these lamp
purchase events to be relatively less frequent.
However, DOE did present all analyzed events in
chapter 8 of the TSD.
PO 00000
Frm 00064
Fmt 4701
Sfmt 4702
range of values represents the multiple
ways a consumer can meet a certain
efficacy standard under each lamp
purchasing event. For example, at EL3,
a consumer retrofitting a 4-foot 34W T12
medium bipin baseline system can
either purchase a high-efficacy T12
lamp on an electronic ballast or a highefficacy T8 lamp on an electronic
ballast. While consumers have both
choices, selecting a T8 system offers
positive LCC savings.
Not all baselines have suitable
replacement options for every lamp
purchasing event at every efficacy level.
For instance, because DOE assumed that
consumers wish to purchase systems or
lamp replacements with a lumen output
within 10 percent of their baseline
system output, in some cases, the only
available replacement options produce
less light than this. Thus, the
replacement options are considered
unsuitable substitutions. These cases are
marked with ‘‘LL’’ (less light) in the LCC
results tables below. In some cases,
when consumers who currently own a
T12 system need to replace their lamps,
no T12 energy saving lamp
replacements are available. In these
cases, in order to save energy, the
consumers must switch to other options,
such as a T8 lamp and appropriate
ballast. These cases are marked with
‘‘NER’’ (no energy-saving replacement)
in tables.
Because some baseline lamps already
meet higher efficacy levels (e.g., the
baseline 32W 4-foot T8 MBP lamp
achieves EL2), LCC savings at the levels
below the baseline are zero. In these
cases, ‘‘BAE’’ (baseline above efficacy
level) is listed in the tables to indicate
that the consumer makes the same
purchase decision in the standards-case
as they do in the base-case. Also, not all
lamp purchase events apply for all
baseline lamps or efficacy levels. For
example, DOE assumed that the
standards-induced retrofit event does
not apply to the 32W T8 system,
because it is already the most
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
efficacious 4-foot medium bipin GSFL
system. For these events, an ‘‘EN/A’’
(event not applicable) exists in the table.
Finally, because LCC savings are not
relevant when no energy conservation
standard is established, ‘‘N/A’’ (not
applicable) exists in the LCC savings
column for the baseline system.
DOE is also presenting the installed
prices of the lamp-and-ballast systems
in order to compare the up-front costs
that consumers must bear when
purchasing baseline or standards-case
systems. The installed price results for
a lamp replacement in response to a
lamp failure event (Event IA) only
include the lamp purchase price and
lamps installation costs. For 4-foot MBP,
8-foot SP slimline, and 8-foot RDC HO,
at EL1 through EL3, consumers with
T12 systems would have the option of
purchasing a T12 lamp in the face of a
lamp failure. At EL4 and EL5, because
no T12 lamps are standard-compliant,
consumers would not be able to proceed
with a lamp replacement; therefore, no
installed price increases are shown.
Instead, at EL4 and EL5, consumers
with T12 lamps that either fail at the
beginning of the analysis period (Event
IB: Lamp Failure, Lamp and Ballast
Replacement) or fail in the middle of the
analysis period (Event II: StandardsInduced Retrofit) would need to
purchase a new lamp-and-ballast T8
system. In these situations, the installed
price in the baseline includes the cost
of purchasing replacement lamps,
whereas the installed price at EL4 and
EL5 is much greater, because the
consumer would need to purchase and
install a T8 lamp-and-ballast system.
The ballast failure event (Event III)
and the new construction/renovation
event (Event IV) include the purchase
and installation costs for lamps and a
ballast for the baseline and standardscase systems. This is because the
occurrences of these events require the
purchase of new lamps and ballasts in
all cases. Although in most cases
standards-case lamp-and-ballast systems
are generally more expensive than
baseline lamp-and-ballast systems, in
some cases (primarily for owners of the
T12 baseline systems purchasing a T8
system instead), the standards-case
lamp-and-ballast systems are less
expensive than the baseline systems.
Table VI.5 presents the findings of an
LCC analysis on various 3-lamp 4-foot
medium bipin GSFL systems operating
in the commercial sector. The analysis
period (based on the longest-lived
baseline lamp’s lifetime) for this
product class in the commercial sector
is 5.5 years. As seen in the table, DOE
analyzes three baseline lamps: (1) 40W
T12; (2) 34W T12; and (3) 32W T8.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
For the 40W T12 baseline, when
commercial consumers are confronted
with a lamp failure in the base case,
they purchase the 40W T12 baseline
lamp as a lamp replacement on their
magnetic T12 ballast. In general, the
only energy-saving lamp replacement
option for this system is a 34W T12
lamp. However, as seen in Table VI.5,
the EL1 and EL2 34W T12 lamps do not
produce sufficient light compared to the
baseline lumen output. Therefore, for
the purposes of the LCC analysis, DOE
assumes that at these ELs, 40W T12
consumers would purchase the EL3
34W T12 lamp (which has sufficient
lumen output) in response to a lamp
failure, and achieve positive LCC
savings. Because no T12 lamps would
be standards-compliant at EL4 and EL5,
consumers with T12 ballasts who are
confronted with a lamp failure beyond
EL3 would be forced to retrofit their
ballasts and instead purchase a T8
system. The LCC savings and
incremental costs related to this action
can be seen in Table VI.5 under the
standards induced retrofit event. At EL4
and EL5, consumers who are forced to
retrofit their ballast would achieve
positive LCC savings; however, they
would also incur an incremental
installed price (baseline installed price
minus standards-case installed price)
greater than $49.30 per system. In
particular, 40W T12 consumers who
retrofit would obtain the greatest LCC
savings at EL4 and EL5 by retrofitting to
an electronically-ballasted 32W T8
system.
For the 40W T12 baseline, when
commercial consumers are confronted
with a ballast failure in the base case,
they purchase the 40W T12 baseline
lamps and a 0.88 ballast factor
electronic ballast. In order to save
energy with similar lumen output at EL1
and EL2, consumers would purchase a
higher-efficacy 40W T12 with a lowerBF ballast. As seen in Table VI.5, these
choices result in negative LCC savings.
However, under such a standard, 40W
T12 consumers would be able to achieve
positive LCC savings under a ballast
failure scenario by purchasing systems
at EL4 and EL5. Similar to the
standards-induced retrofit, at EL4 and
EL5 consumers are forced to purchase
T8 systems. Those who purchase a 32W
T8 lamp generally achieve the highest
LCC savings.
For the 34W T12 baseline, when
commercial consumers are confronted
with a lamp failure in the base case,
they purchase the 34W T12 baseline
lamp as a lamp replacement on their
magnetic T12 ballast. As this is the
lowest-wattage commercially-available
T12 lamp, there are no energy-saving
PO 00000
Frm 00065
Fmt 4701
Sfmt 4702
16983
lamp replacement options for this
system. However, as seen in Table VI.5
in the Event IA installed price column,
consumers do have the option to
purchase a higher-efficacy 34W T12
lamps, resulting in no energy-savings
and an installed price increase ranging
from $3.69 to $13.91. For the purposes
of the LCC analysis, at EL1, EL2, and
EL3, DOE analyzes the economics of
standards-retrofit, an energy-saving
response available to the 34W T12
consumer under a lamp failure scenario.
As seen in the table, some LCC savings
results at EL1, EL2, and EL3 are
negative, representing consumers
retrofitting to a 34W T12 lamp on an
electronic T12 ballast or the baseline
32W T8 lamp on an electronic T8
ballast. However, under such a
standard, consumers would also be able
to achieve positive savings by
purchasing EL3, EL4, and EL5 T8
systems with either a higher-efficacy
32W T8 lamp or other reduced-wattage
lamps. Because no T12 lamps would be
standards-compliant at EL4 and EL5,
consumers with T12 ballasts who are
confronted with a lamp failure at these
levels would be forced to retrofit their
ballasts and instead purchase a T8
system. The incremental installed prices
associated with this forced retrofit are
greater than $51.62 per system.
For the 34W T12 baseline, when
commercial consumers are confronted
with a ballast failure in the base case,
they purchase the 34W T12 baseline
lamps and a 0.88 ballast factor
electronic ballast. In order to save
energy with similar lumen output at EL1
and EL2, consumers would purchase a
higher-efficacy 34W T12 with a lowerBF ballast. In addition, at EL3,
consumers may purchase a 34W T12
lamp with a lower-BF ballast as well. As
seen in Table VI.5, these choices result
in negative LCC savings. However,
under such a standard, 34W T12
consumers can achieve positive LCC
savings under a ballast failure scenario
by purchasing systems at EL4 and EL5.
Similar to the standards-induced
retrofit, at EL4 and EL5, consumers
would be forced to purchase T8
systems. Those who purchase the
reduced-wattage 25W and 28W T8
lamps achieve the highest LCC savings.
For the 32W T8 baseline, commercial
consumers purchase either the 32W T8
baseline lamp (under lamp failure) or
the 32W T8 baseline lamp and an
electronic 0.88 BF ballast (under ballast
failure). As the efficacy of this baseline
lamp exceeds EL2, no LCC results or
installed prices are presented for EL1
and EL2. In order to save energy by only
replacing the lamp, the consumer must
purchase reduced wattage lamps (these
E:\FR\FM\13APP2.SGM
13APP2
16984
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
reduced-wattage lamp replacement
option (the 28W T8) achieves positive
LCC savings.
When confronted with a ballast
failure, consumers who would have
purchased the 32W T8 baseline system,
would achieve positive LCC savings at
EL3 by purchasing higher-efficacy 32W
T8 lamps on a lower-BF ballast. At EL4,
these consumers could obtain the
greater LCC savings by purchasing an
electronically-ballasted 25W T8 system
on a 0.88 BF ballast. At EL5, they
achieve highest savings by purchasing
the 32W T8 lamp on a lower-BF ballast.
BILLING CODE 6450–01–P
BILLING CODE 6450–01–C
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00066
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.000</GPH>
only lie at EL4 and EL5). Therefore,
although there are no EL3 energy-saving
lamp replacements, consumers may
purchase EL4 and EL5 lamps at this
standard level. At EL4, consumers who
purchase 30W T8 lamps achieve lower
LCC savings than those who purchase
25W T8 lamps. At EL5, the only
16985
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
As discussed in section V.D, DOE
performed research on the usage of
GSFL in the residential sector and found
a number of variations from the
commercial sector. In particular, DOE
uses separate electricity prices (higher
than commercial), operating hours
(lower than commercial), discount rates
(higher than commercial), and lamp
lifetimes (higher than commercial). DOE
also assumes that residential consumers
of GSFL generally install their own
lamps; thus, labor costs were modeled
only for ballast replacements. DOE also
uses a 40W T12 baseline lamp that has
a lower efficacy, lower price, and
shorter lifetime (in hours). DOE found
that the most common ballast in the
residential sector is a low-power-factor,
2-lamp magnetic rapid-start T12 ballast
with a ballast factor of 0.68. Therefore,
DOE uses the combination of the
magnetic T12 ballast and two 40W T12
lamps as the residential sector GSFL
baseline lamp-and-ballast system.
Based on DOE’s analysis, the average
operating hours for GSFL in the
residential sector are 789 hours per year,
which is lower than the commercial
sector average of 3,435 annual operating
hours. This would suggest a 19-year
service life for the baseline lamp, which
has a lifetime of 15,000 hours. Based on
measured-life reports, DOE uses a 15year average ballast and fixture lifetime
in the residential sector. Under these
assumptions, lamps used under average
residential operating hours would not
fail before the fixture reached the end of
its life; thus, there would be no lamponly replacements, but there would be
lamp-and-ballast replacements in the
residential sector. However, with higher
operating hours, lamp service life does
decrease below 15 years, resulting in a
lamp failure event prior to ballast or
fixture replacement. Because DOE
believes that the lamp failure event is an
important event to analyze, DOE has
presented the residential sector LCC
analysis under both average operating
hours (789 hours per year) and high
operating hours (1,210 hours per year).
The high operating hours are typical of
kitchens, living rooms, dining rooms,
and outdoor spaces.
Table VI.7 presents the LCC results for
a 4-foot medium bipin system operating
in the residential sector under average
operating hours. As discussed earlier,
under average operating hours, only the
ballast failure event (Event III) applies
because the ballast and fixture reach the
end of their 15 year life before the
baseline lamp (which would otherwise
have a lifetime of 19 years when
operated for 789 hours per year) fails.
DOE uses a 15-year analysis period,
based on the effective service life of the
lamp (limited by the fixture or ballast
life). Because DOE assumes that the
residential consumer discards the lamp
when replacing a ballast or fixture, DOE
does not assign any residual value to the
remaining life of the lamp at the end of
the analysis period. In this event,
residential consumers purchase the 40W
T12 baseline lamp with a magnetic T12
system in the base case, and an
electronic or magnetic T12 system or
electronic T8 system in the standards
case.
At EL1 and EL2, although consumers
may purchase an EL1 or EL2 T12 lamp
with a magnetic ballast, none of these
systems are both energy saving and
produce similar lumen output at the
baseline system. Therefore at EL1 and
EL2, the only T12 systems analyzed are
those purchased with electronic T12
ballasts. At EL1, as seen in Table VI.6,
higher LCC savings occur for consumers
purchasing 34W T12 lamps than those
purchasing 40W T12 lamps. When
purchasing at EL2, consumers have the
option of either purchasing an
electronically-ballasted T12 system or a
T8 system with the lowest efficacy 32W
T8 lamp. LCC savings are the least when
a consumer purchases a higher-efficacy
40W T12 lamp with an electronic T12
ballast. Consumers purchasing 32W T8
lamps on an electronic ballast would
obtain the greatest savings at EL2. At
EL3, in addition to the T8 and
electronically-ballasted T12 purchase
options, consumers also can obtain
energy savings and similar lumen
output by purchasing 34W T12 lamps
on magnetic T12 ballasts. However, as
seen in the Table VI.6, this option
results in the least savings of all ELs.
Consumers achieve higher LCC savings
by purchasing EL3 32W T8 lamps with
electronic ballasts. As discussed in
relation to the commercial sector, EL4
and EL5 eliminate T12 lamps from the
market and require the purchasing of a
T8 system. Those consumers who select
a 32W T8 lamp on an electronic ballast
obtain the least LCC savings at EL4,
while LCC savings are greatest of all ELs
when a consumer purchases an
electronically-ballasted 25W T8 system.
At EL5, consumers choosing a 32W T8
system obtain lower LCC savings than
those purchasing a 28W T8 system.
TABLE VI.6—LCC RESULTS FOR A 2-LAMP FOUR-FOOT MEDIUM BIPIN GSFL SYSTEM OPERATING IN THE RESIDENTIAL
SECTOR WITH AVERAGE OPERATING HOURS
LCC savings
2007$
Event III: Ballast
failure*
Baseline
Installed price
2007$
Event III: Ballast
failure
Efficiency level
Baseline .................................................................
EL1 .........................................................................
EL2 .........................................................................
EL3 .........................................................................
EL4 .........................................................................
EL5 .........................................................................
40 Watt T12
N/A .......................
5.87 to 9.24 ..........
5.67 to 16.88 ........
0.27 to 16.63 ........
16.34 to 21.24 ......
17.72 to 19.66 ......
49.47.
47.22 to
48.64 to
50.71 to
50.99 to
51.16 to
54.10.
54.29.
57.95.
54.07.
52.03.
* Analysis period is 15 years.
N/A: Not Applicable.
In addition to conducting the LCC
analysis under average operating hours,
DOE also computed residential LCC
results under high operating hours
(1,210 hours per year) in order to
analyze the economic impacts of the
lamp failure event (Event I). Table VI.7
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
presents these LCC and installed-price
results for a 2-lamp four-foot medium
bipin GSFL system under the lamp
failure event and high operating hours.
As seen in Table VI.7, DOE divides
the residential GSFL lamp failure event
into Events IA (Lamp Failure: Lamp
PO 00000
Frm 00067
Fmt 4701
Sfmt 4702
Replacement) and IB (Lamp Failure:
Lamp and Ballast Replacement). Event
IA, presented also in the commercial
sector analysis, models solely a lamp
purchase (in response to lamp failure) in
both the base case and standards case.
E:\FR\FM\13APP2.SGM
13APP2
16986
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
With high operating hours, DOE
calculates that the baseline lamp
initially purchased with a ballast fails
after 12.5 years. Therefore, a
replacement lamp will operate for only
2.5 additional years before the entire
lamp-and-ballast system is discarded
(due to either ballast failure or fixture
replacement). Therefore, for this high
operating hour scenario’s lamp failure
event calculation, DOE uses a 2.5 year
analysis period. Similar to the average
operating hour analysis, when a lampand-ballast system is discarded, DOE
does not attribute any residual value to
the remaining life of the lamp.
Similar to the commercial analysis,
the only viable energy-saving lamp
replacement option for the 40W T12
residential system is the 34W T12 lamp
at EL3. Thus, under a standard at either
EL1 and EL2, DOE assumes, for the
purpose of the LCC analysis, that
consumers would purchase the 34W
T12 lamp at EL3. DOE recognizes that
not all consumers can use a 34W T12
lamp on a residential magnetic lowpower-factor ballast because not all
ballasts are designated to operate this
lamp. However, in its review of
manufacturer literature, DOE identified
several low-power-factor residential
magnetic ballasts designated to operate
the 34W T12 lamp. Therefore, DOE
considers this to be a viable option for
some residential consumers.
However, as seen in Table VI.7, these
consumers who purchase the EL3 34W
T12 lamp would encounter negative
LCC savings. Although more efficacious
than the baseline, the reduced-wattage
34W T12 lamp that meets this EL does
not save sufficient energy to offset its
increased purchase price within the 2.5year analysis period. The replacement
lamp would need to be in service for
exactly 8 years or greater in order for the
energy cost savings to offset the
increased purchase price of the higherefficacy 34W lamp.
Because no T12 lamps would be
standards-compliant at EL4 and EL5,
consumers with T12 ballasts who are
confronted with a lamp failure at these
levels are forced to retrofit their ballasts
and instead purchase a T8 system. The
LCC savings and incremental costs
related to this action can be seen in
Table VI.7 under the lamp and ballast
replacement event (Event IB). In the
commercial sector, DOE presented the
standards-induced retrofit event (Event
II), where consumers proactively (before
their lamp fails) retrofit their lamp and
ballast in anticipation of the inability to
purchase a standards-compliant, equallumen T12 replacement lamp due to
standards. In contrast, for the residential
sector, DOE believes that consumers
would replace their systems only when
forced by a lamp failure. Thus, instead
of presenting the standards-induced
retrofit event (Event II), for the
residential sector, DOE models Event IB,
where a consumer replaces a lamp-andballast system in direct response to a
lamp failure. At EL4 and EL5, the
available T8 system options do not save
sufficient energy savings to offset the
increased purchase price of the lamp
and ballast in 2.5 years, leading to
negative LCC savings. In addition
consumers who would be forced to
retrofit their ballast would incur an
installed price increase greater than
$47.01 per system. DOE requests
comment on all inputs used in the LCC
analysis for GSFL operating in the
residential sector.
TABLE VI.7—LCC RESULTS FOR A 2–LAMP FOUR-FOOT MEDIUM BIPIN GSFL SYSTEM OPERATING IN THE RESIDENTIAL
SECTOR WITH HIGH OPERATING HOURS
LCC savings
2007$
Baseline
Efficiency level
Installed price
2007$
Event IA: Lamp
replacement*
40 Watt T12
Baseline ....................
EL1 ............................
EL2 ............................
EL3 ............................
EL4 ............................
EL5 ............................
Event IB: Lamp and
ballast
replacement*
Event IA: Lamp
replacement
N/A ............................
LL ..............................
LL ..............................
¥5.42 .......................
NR .............................
NR .............................
N/A ............................
EN/A ..........................
EN/A ..........................
EN/A ..........................
¥4.67 to ¥2.78 .......
¥4.13 to ¥3.50 .......
3.98 ...........................
LL ..............................
LL ..............................
12.46 .........................
NR .............................
NR .............................
Event IB: Lamp and
ballast replacement
3.98.
EN/A.
EN/A.
EN/A.
50.99 to 54.07.
51.16 to 52.03.
*Analysis period is 2.5 years.
N/A: Not Applicable; LL: Available Options Produce Less Light; EN/A: Event Not Applicable; NR: No Replacement
Table VI.8 presents the results for an
electronically-ballasted 4-foot T5
miniature bipin standard-output,
baseline system operating in the
commercial sector. Table VI.9 presents
the results for an electronicallyballasted 4-foot T5 miniature bipin
high-output baseline system operating
in the industrial sector. For the
standard-output baseline, the analysis
period is 5.5 years. For the high-output
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
baseline, the analysis period is 3.9
years. In general, positive LCC savings
exist at all of the efficacy levels
analyzed. However, negative LCC
savings exist for Event I (Lamp
Replacement) in the 4-foot T5 miniature
bipin HO product class. Yet for the 4foot T5 miniature bipin standard-output
product class, consumers selecting a
reduced-wattage T5 achieve positive
LCC savings. Event II (Standards
PO 00000
Frm 00068
Fmt 4701
Sfmt 4702
Induced Retrofit) is not shown because
the 4-foot miniature bipin product class
is composed entirely of T5 lamps. For
Event V, consumers can change the
physical layout of their system to match
the mean lumen output of the baseline
system. Because the T5 baseline
halophosphors have such poor lumen
maintenance compared to the 800-series
T5 lamps, LCC savings for the new
construction event are high.
E:\FR\FM\13APP2.SGM
13APP2
16987
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.8—LCC RESULTS FOR A 2-LAMP FOUR-FOOT MINIATURE BIPIN STANDARD OUTPUT GSFL SYSTEM OPERATING
IN THE COMMERCIAL SECTOR
LCC savings
2007$
Baseline
Installed price
2007$
Efficiency level
Event IA: Lamp
replacement*
Baseline ....................
EL1 ............................
EL2 ............................
28 Watt T5
Event V: New construction/renovation*
Event IA: Lamp
replacement
N/A ............................
NER ..........................
1.22 ...........................
N/A ............................
42.84 .........................
45.27 to 47.03 ...........
9.39 ...........................
13.15 .........................
14.86 .........................
Event V: New construction/renovation
69.20.
72.96.
74.67 to 75.16.
*Analysis period is 5.5 years.
N/A: Not Applicable; NER: No Energy-Saving Replacement.
TABLE VI.9—LCC RESULTS FOR A 2-LAMP FOUR-FOOT MINIATURE BIPIN HIGH OUTPUT GSFL SYSTEM OPERATING IN
THE INDUSTRIAL SECTOR
LCC savings
2007$
Baseline
Installed price
2007$
Efficiency level
Event IA: Lamp
replacement*
54 Watt T5
Baseline ....................
EL1 ............................
Event V: New construction/renovation*
Event IA: Lamp
replacement
N/A ............................
¥3.42 .......................
N/A ............................
55.60 to 56.60 ...........
10.44 .........................
19.85 .........................
Event V: New construction/renovation
71.33.
76.36 to 80.74.
*Analysis period is 3.9 years.
N/A: Not Applicable; NER: No Energy-Saving Replacement.
Table VI.10 presents the results for an
8-foot single-pin slimline GSFL system
operating in the commercial sector. The
analysis period is 4 years. For this
product class, DOE analyzes three
baseline lamps: (1) 75W T12; (2) 60W
T12; and (3) 59W T8.
For the 75W T12 baseline, consumers
confronted with a lamp failure purchase
the baseline 75W T12 for their magnetic
T12 ballast in the base case. In the face
of standards, consumers could save
energy by purchasing reduced-wattage
(60W) T12 lamps as replacements. The
only 60W T12 lamp that produces
sufficient light on the baseline ballast,
however, exists at EL3. For the purposes
of the LCC analysis, DOE assumes that
at standard levels EL1 and EL2, 75W
T12 consumers confronted with a lamp
failure would purchase the EL3
replacement lamp. These consumers
would achieve positive LCC savings.
Note that any standard level beyond EL3
would likely require consumers to
replace their T12 lamps and ballasts
with T8 systems, since no T12 lamp
currently meets the efficacy
requirements of EL4 and EL5. The LCC
savings and installed costs associated
with this action are shown in the
standards induced retrofit event in
Table VI.10. The EL4 lamp available in
this event does not produce sufficient
light output, so DOE assumes that at
standard level EL4, 75W T12 consumers
would retrofit to the EL5 59W T8 and
0.88 ballast factor ballast. At EL4 and
EL5, 75W T12 consumers who retrofit to
the EL5 T8 system achieve positive LCC
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
savings while incurring an incremental
installed price of $78.96 per system.
In response to a ballast failure, 75W
T12 consumers can purchase moreefficacious 75W T12 lamps and lowerballast-factor ballasts at EL1 and EL2.
These systems do not save enough
energy over their lifetimes to offset their
increased installed prices, however,
resulting in negative LCC savings for
consumers. The systems at EL3 and EL4
do not produce sufficient lumen output
in comparison to the baseline system, so
DOE assumes that 75W T12 consumers
encountering ballast failures would
purchase the EL5 59W T8 and 0.88
ballast factor ballast at standard levels
EL3 and EL4. At standard levels EL4
and EL5, only T8 systems are available.
It is possible, however, for 75W T12
consumers to achieve positive LCC
savings by purchasing the EL5 T8
system.
In response to a lamp failure,
consumers of 60W T12 lamps do not
have access to any energy-saving T12
replacement lamps. At EL1, consumers
could still purchase the 60W T12
baseline lamp for their magnetic ballast.
T12 lamps that do not save energy are
also available at standard levels EL2 and
EL3, with installed price increases
ranging from $4.88 to $8.30. To save
energy at EL2 and EL3, consumers of
60W T12 lamps can instead choose to
retrofit to T12 or T8 systems with
electronic ballasts. 60W T12 consumers
would not be able to achieve positive
LCC savings with any of the systems
available for a standards-induced
PO 00000
Frm 00069
Fmt 4701
Sfmt 4702
retrofit at any EL, although they would
save energy. Standard levels EL4 and
EL5 also force T12 lamps from the
market, requiring consumers to retrofit
to T8 systems and incur installed price
increases of at least $82.08.
In response to a ballast failure, DOE
assumes that 60W T12 consumers
would purchase 60W T12 lamps and
0.88 ballast factor electronic ballasts in
the base case. Consumers can also
purchase this system at standard level
EL1. At standard levels EL2 and EL3,
consumers could purchase moreefficacious 60W T12 lamps and lowerballast-factor electronic ballasts when
faced with a ballast failure. Consumers
cannot save enough energy with these
systems to achieve positive LCC savings,
however. Instead, they can purchase the
T8 systems on electronic ballasts
available at EL4 and EL5 and achieve
positive LCC savings. In the face of
standard levels EL4 and EL5, T12
systems would be eliminated from the
market. Consumers can achieve the
greatest positive LCC savings with a
57W T8 on a 0.78 ballast factor
electronic ballast at EL5, while
consumers purchasing the 59W T8 on a
0.78 ballast factor electronic ballast at
EL4 achieve the least positive LCC
savings.
Consumers of 59W T8 lamps can
purchase the baseline 59W T8 to install
on an electronic ballast at standard
levels EL1 through EL3 when faced with
a lamp failure. At EL4, there are no
energy-saving lamp replacement
options, so DOE assumes that
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
consumers of 59W T8 lamps would
instead purchase the 57W or 55W T8
lamps that comply with EL5. Consumers
purchasing these lamps achieve positive
LCC savings and incur installed price
increases ranging from $3.94 to $4.76.
Those purchasing the 55W T8 achieve
the greatest positive LCC savings.
In response to a ballast failure,
consumers of 59W T8 lamps can
purchase the baseline 59W T8 system at
EL1 through EL3. The available system
at EL4 is a 59W T8 lamp on a 0.85
ballast factor electronic ballast, and
consumers purchasing this system
would achieve negative LCC savings. At
EL5, 59W T8 consumers could purchase
Table VI.11 shows LCC results for an
8-foot recessed double-contact GSFL
system operating in the industrial
sector. The analysis period for this
product class is 2.3 years. DOE analyzes
110W T12 and 95W T12 baseline lamps
on magnetic ballasts.
Consumers who own 110W T12
lamps and are faced with a lamp failure
would be expected to purchase 110W
T12 baseline lamps for their magnetic
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00070
Fmt 4701
Sfmt 4702
59W, 57W, or 55W T8 systems on
electronic ballasts and achieve positive
LCC savings. Those purchasing the 55W
T8 system would achieve the greatest
positive LCC savings, while those
purchasing the 57W T8 system would
achieve the least positive LCC savings.
BILLING CODE 6450–01–P
ballast in the base case. The available
replacement lamps at EL1 and EL2 do
not produce sufficient light output in
comparison to the baseline system, so
DOE assumes that 110W T12 consumers
would purchase the reduced-wattage
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.001</GPH>
16988
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
(95W) T12 lamp options at EL3 when
faced with standard levels EL1 and EL2.
Consumers could achieve positive LCC
savings with these lamps while
incurring installed price increases of
$12.64 or $13.27. Standard levels EL4
and EL5 eliminate T12 lamps from the
market, requiring consumers to retrofit
their systems to T8 systems in the face
of a lamp failure. The available T8
system at EL4 does not produce
sufficient light in comparison with the
baseline system, so DOE assumes that at
EL4, consumers would instead purchase
the 86W T8 system and 0.88 ballast
factor electronic ballast at EL5. 110W
T12 consumers purchasing this system
could achieve positive LCC savings
while incurring an installed price
increase of $106.75.
In the face of a ballast failure, 110W
T12 consumers would be expected to
purchase the 110W T12 baseline lamp
and a 0.95 ballast factor magnetic ballast
in the base case. Consumers who own
110W T12 systems can purchase
replacement systems that comply with
EL1, EL3, or EL5 and achieve positive
LCC savings. The available systems at
EL2 and EL4 do not produce sufficient
light, so DOE assumes that in the face
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
of standard levels EL2 or EL4,
consumers would purchase systems
meeting higher standard levels. At EL1,
110W T12 consumers could purchase a
110W T12 lamp on an electronic ballast
but would achieve the least positive
LCC savings. At EL3, consumers could
purchase reduced-wattage (95W) T12
lamps on a magnetic ballast or on an
electronic ballast. Consumers could
achieve the most positive LCC savings
of any EL by purchasing the 86W T8
system available at EL5. Standard levels
EL4 and EL5 would eliminate T12
systems from the market, making the
86W T8 system the only available
option.
When faced with a lamp failure,
consumers of the 95W T12 baseline
lamp would be expected to purchase the
95W T12 baseline for their magnetic
ballast in the base case. This lamp also
complies with EL1. None of the lamps
available at EL1 through EL3, when in
combination with the magnetic ballast
save energy as compared to the baseline
system. However, consumers can
purchase these lamps and incur
installed price increases ranging from
$6.14 to $19.09. Consumers of the 95W
T12 baseline lamp could instead retrofit
PO 00000
Frm 00071
Fmt 4701
Sfmt 4702
16989
their systems to save energy. The EL1
system available for retrofit does not
produce sufficient light output, and
consumers could not achieve positive
LCC savings with any of the system
options available for retrofit at EL2
through EL5. Furthermore, standard
levels EL4 and EL5 would eliminate T12
lamps from the market, thereby forcing
consumers of the 95W T12 baseline
lamp to retrofit to T8 systems when
faced with a lamp failure and incur
installed price increases ranging from
$109.35 to $112.57.
When faced with a ballast failure,
consumers of 95W T12 lamps could
purchase a 95W T12 baseline lamp on
a magnetic ballast in the base case.
Consumers purchasing a higher efficacy
95WT12 at EL2 on an electronic ballast
achieve positive LCC savings. However,
consumers purchasing these systems at
EL3, would not achieve positive LCC
savings. EL4 and EL5 would likely
eliminate T12 systems from the market,
making the EL4 and EL5 86W T8 system
the only available option for consumers
faced with a ballast failure. Those who
purchase the 86W T8 system at EL4 or
EL5 can achieve positive LCC savings.
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
ii. Incandescent Reflector Lamps
Table VI.12 shows the commercial
and residential sector LCC results for
IRL. The results are based on the
reference case AEO2008 electricity price
forecast and medium-range lamp prices.
The analysis period is 3.4 years for the
residential sector and 0.9 years for the
commercial sector. DOE assessed three
efficacy levels for the March 2008
ANOPR. 73 FR 13620, 13666–13667
(March 13, 2008). For the NOPR, DOE
added two additional efficacy levels—
one below the lowest EL considered in
the March 2008 ANOPR, and one above
the highest EL considered in the March
2008 ANOPR See the engineering
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
analysis in chapter 5 of the TSD or
section V.C.4.b of this notice for details.
The majority of efficacy levels result
in positive LCC savings in spite of the
higher installed prices of the standardscase lamps in comparison with the
baseline lamps. In general, the higher
lumen package lamps (i.e., those
replacing the 90W baseline lamp)
achieve higher LCC savings that the
lower lumen package lamps (i.e., those
replacing the 75W and 50W baselines).
This is due to the larger energy savings,
and, thus, operating cost savings
associated with higher-wattage lamps.
At EL1, in all but the residential 90W
PAR38 baseline, consumers would
achieve negative LCC savings when
PO 00000
Frm 00072
Fmt 4701
Sfmt 4702
purchasing the improved halogen lamp.
The improved halogen lamp at this
efficacy level would not save enough
energy to recover its increased initial
cost from the baseline lamp. Maximum
LCC savings would be achieved at EL5
for the 90W and 75W baselines when a
consumer purchases an improved HIR
lamp. For the 50W baseline, both the
EL4 and EL5 replacement lamps are
40W, as this is the lowest-wattage IRL
covered by standards. Therefore, EL4,
consuming the same amount of energy
and with a lower lamp price, would
have higher LCC savings than EL5. In
general, the lamps with the highest LCC
savings are more efficacious and have
longer lifetimes than the baseline lamps.
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.002</GPH>
16990
16991
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.12—LCC RESULTS FOR INCANDESCENT REFLECTOR LAMPS
Event I: Lamp replacement/Event V: New construction and renovation
Baseline
LCC savings
2007$
Efficiency level
Installed price
2007$
Commercial *
Residential * *
Commercial
Residential
90 Watt PAR38
Baseline ....................
EL1 ............................
EL2 ............................
EL3 ............................
EL4 ............................
EL5 ............................
N/A ............................
¥0.03 .......................
3.81 to 6.04 ...............
6.19 ...........................
8.14 ...........................
9.41 ...........................
N/A ............................
0.12 ...........................
3.06 to 4.68 ...............
5.55 ...........................
7.09 ...........................
8.76 ...........................
6.20
7.14
7.58
7.76
9.08
9.65
...........................
...........................
to 7.76 ...............
...........................
...........................
...........................
5.13.
6.07.
6.52 to 6.70.
6.70.
8.02.
8.59.
75 Watt PAR38
Baseline ....................
EL1 ............................
EL2 ............................
EL3 ............................
EL4 ............................
EL5 ............................
N/A ............................
¥0.31 .......................
3.24 to 5.67 ...............
4.77 ...........................
7.00 ...........................
7.50 ...........................
N/A ............................
¥0.18 .......................
2.46 to 4.30 ...............
4.07 ...........................
5.90 ...........................
6.77 ...........................
6.20
7.14
7.58
7.76
9.08
9.65
...........................
...........................
to 7.76 ...............
...........................
...........................
...........................
5.13.
6.07.
6.52 to 6.70.
6.70.
8.02.
8.59.
50 Watt PAR30
Baseline ....................
EL1 ............................
EL2 ............................
EL3 ............................
EL4 ............................
EL5 ............................
N/A ............................
¥0.31 .......................
0.04 to 2.72 ...............
0.77 ...........................
1.95 ...........................
1.51 ...........................
N/A ............................
¥0.28 .......................
0.10 to 2.21 ...............
0.87 ...........................
1.62 ...........................
1.49 ...........................
5.59
6.53
6.98
7.15
8.47
9.04
...........................
...........................
to 7.15 ...............
...........................
...........................
...........................
4.53.
5.46.
5.92 to 6.09.
6.09.
7.41.
7.98.
*Analysis period is 0.9 years.
**Analysis period is 3.4 years.
b. Consumer Subgroup Analysis
i. Low-Income Households
Certain consumer subgroups may be
disproportionately affected by
standards. In the March 2008 ANOPR,
DOE requested comment on which
consumer subgroups should be
considered as well as methods of
analyzing those subgroups. 73 FR
13620, 13682 (March 13, 2008). In
response to comments it received, DOE
performed LCC subgroup analyses in
this NOPR for low-income consumers,
institutions of religious worship, and
institutions that serve low-income
populations. See section 0 of this NOPR
for a review of the inputs to the LCC
analysis. The following discussion
presents the most significant results
from the LCC subgroup analysis.
All of the LCC results shown here
were generated using AEO2008
reference case electricity prices. In
addition, DOE presents subgroup results
using medium-range lamp and ballast
prices, as DOE believes that these prices
represent average prices for the
consumer subgroups as well. As in the
primary LCC analysis, not all baselines
and lamp purchase events have suitable
replacement options at every efficacy
level. See the primary LCC analysis
results in section VI.B.1.a of this NOPR
for more details on this analysis, as well
as the TSD chapter 12 for a full set of
LCC and PBP results for the subgroup
analysis.
DOE conducted the low-income
consumer subgroup analysis based on
the 4-foot MBP 40W baseline operating
in the residential sector and IRL
operating in the residential sector. The
low-income consumer subgroup
analysis is identical to the residential
average consumer LCC analysis, except
that it includes slightly lower electricity
prices, which DOE determined using
data in the 2001 RECS. In comparing
this subgroup’s LCC results to the
primary results presented in Table VI.5,
Table VI.6, and Table VI.12, positive
primary LCC savings results remained
positive and negative primary LCC
savings results remained negative. In
general, LCC savings for GSFL and IRL
are approximately 1 to 2 percent lower
for low-income residential consumers
than they are for the average consumer
in the residential sector.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
ii. Institutions of Religious Worship
DOE found that institutions of
religious worship have the lowest
operating hours of any non-mall
commercial building. Specifically,
operating hours were 1,705 hours per
year for GSFL (vs. the commercial sector
average of 3,435 hours per year) and
1,609 hours per year for IRL (vs. the
commercial sector average of 3,450
hours per year). The LCC analysis for
this subgroup is identical to the main
commercial sector LCC analysis except
for the lower operating hours, resulting
PO 00000
Frm 00073
Fmt 4701
Sfmt 4702
in an analysis period of 11 years for 4foot GSFL, 8 years for 8-foot GSFL, and
1.9 years for IRL. Results are shown in
Table VI.13 through Table VI.16 of this
notice.
Institutions of religious worship
experience lower LCC savings than the
rest of the commercial sector,
particularly for standards-induced
retrofit events. This is because the
longer analysis period (due to lower
operating hours) causes operating cost
savings and residual values to be
discounted more heavily than in the
primary commercial LCC analysis. In
general, LCC savings that were positive
for the 4-foot medium bipin product
class in the primary commercial sector
analysis remain positive for institutions
of religious worship. For example, in
Event II, LCC savings for institutions of
religious worship are approximately $17
lower than savings for the rest of the
commercial sector for the 40W T12
baseline. However, LCC savings for the
standards-induced retrofit event for the
34W T12 baseline lamp and 40W T12
baseline lamp are negative for certain T8
systems at EL4 and EL5.
In the 4-foot T5 miniature bipin
product class, LCC savings for
institutions of religious worship are
several dollars lower than savings for
the rest of the commercial sector. This
is also true for the 8-foot single-pin
slimline product class except for the
standards-induced retrofit event, where
LCC savings for such institutions are
approximately $20 lower than savings
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
for the rest of the commercial sector.
DOE notes that the standards-induced
retrofit of a 75W T12 system at EL5 is
not cost-effective for religious
institutions.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
For IRL, LCC savings for institutions
of religious worship are generally lower
by several cents compared to the rest of
the commercial sector due to the longer
analysis period. LCC savings are slightly
PO 00000
Frm 00074
Fmt 4701
Sfmt 4725
higher, however, at EL1 for the 90W and
75W PAR38 baselines.
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.003</GPH>
16992
16993
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.14—LCC SUBGROUP RESULTS FOR A 2-LAMP FOUR-FOOT T5 MINIATURE BIPIN GSFL SYSTEM OPERATING IN
INSTITUTIONS OF RELIGIOUS WORSHIP
LCC savings
2007$
Baseline
Efficiency level
Installed price
2007$
Event IA: Lamp
replacement*
28 Watt T5
Baseline ....................
EL1 ............................
EL2 ............................
Event V: New
construction/
renovation*
Event IA: Lamp
replacement
N/A ............................
NER ..........................
¥0.08 .......................
N/A ............................
38.73 .........................
39.74 to 42.31 ...........
9.39 ...........................
13.15 .........................
14.86 .........................
Event V: New
construction/
renovation
69.20.
72.96.
74.67 to 75.16.
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00075
Fmt 4701
Sfmt 4725
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.004</GPH>
* Analysis period is 11 years.
N/A: Not Applicable; NER: No Energy-Saving Replacement.
16994
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.16—LCC SUBGROUP RESULTS FOR INCANDESCENT REFLECTOR LAMPS OPERATING IN INSTITUTIONS OF
RELIGIOUS WORSHIP
Event I: Lamp replacement/Event V: New construction and renovation *
Baseline
Efficiency level
LCC savings
2007$
90 Watt PAR38
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
0.00 ..................................................
2.97 to 5.14 ......................................
5.21 ..................................................
6.87 ..................................................
8.28 ..................................................
6.20.
7.14.
7.58 to 7.76.
7.76.
9.08.
9.65.
75 Watt PAR38
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
¥0.26 ...............................................
2.43 to 4.79 ......................................
3.87 ..................................................
5.80 ..................................................
6.48 ..................................................
6.20.
7.14.
7.58 to 7.76.
7.76.
9.08.
9.65.
50 Watt PAR30
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
¥0.35 ...............................................
¥0.04 to 2.55 ..................................
0.64 ..................................................
1.58 ..................................................
1.37 ..................................................
5.59.
6.53.
6.98 to 7.15.
7.15.
8.47.
9.04.
Installed price
2007$
* Analysis period is 1.9 years.
iii. Institutions That Serve Low-Income
Populations
Table VI.17 through Table VI.20 show
the LCC subgroup results for institutions
that serve low-income populations. DOE
assumed that the majority of these
institutions are small nonprofits; thus,
DOE used a higher discount rate of 10.8
percent (versus the 7.0-percent discount
rate for the primary commercial sector
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
analysis). All other factors of the LCC
subgroup analysis remained the same as
in the primary commercial sector
analysis. As a result of the higher
discount rate, LCC savings are lower for
institutions that serve low-income
populations than for the rest of the
commercial sector. For Events I and III
for all analyzed GSFL product classes,
savings are several dollars lower than
for the rest of the commercial sector. For
PO 00000
Frm 00076
Fmt 4701
Sfmt 4702
Event II for GSFL, LCC savings are
approximately $10 lower than for the
rest of the commercial sector. For IRL,
LCC savings are several cents lower than
for the rest of the commercial sector.
Although LCC savings are lower,
positive primary LCC results remained
positive for this subgroup, while
negative primary LCC results remained
negative.
E:\FR\FM\13APP2.SGM
13APP2
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00077
Fmt 4701
Sfmt 4725
E:\FR\FM\13APP2.SGM
13APP2
16995
EP13AP09.005</GPH>
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
16996
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.18—LCC SUBGROUP RESULTS FOR A 2-LAMP FOUR-FOOT MINIATURE BIPIN GSFL SYSTEM OPERATING IN
INSTITUTIONS THAT SERVE LOW-INCOME POPULATIONS
LCC savings
2007$
Baseline
Efficiency level
Installed price
2007$
Event IA: Lamp
replacement*
28 Watt T5
Baseline ....................
EL1 ............................
EL2 ............................
Events V: New
construction/
renovation*
Event IA: Lamp replacement
N/A ............................
NER ..........................
0.37 ...........................
N/A ............................
40.41 .........................
41.91 to 44.24 ...........
9.39 ...........................
13.15 .........................
14.86 .........................
Events V: New
construction/
renovation
69.20.
72.96.
74.67 to 75.16.
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00078
Fmt 4701
Sfmt 4725
E:\FR\FM\13APP2.SGM
13APP2
EP13AP09.006</GPH>
* Analysis period is 5.5 years.
N/A: Not Applicable; NER: No Energy-Saving Replacement.
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
16997
TABLE VI.20—LCC SUBGROUP RESULTS FOR INCANDESCENT REFLECTOR LAMPS OPERATING IN INSTITUTIONS THAT
SERVE LOW-INCOME POPULATIONS
Event I: Lamp replacement/Event V: New construction and renovation *
Baseline
Efficiency level
LCC savings
2007$
90 Watt PAR38
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
¥0.09 ...............................................
3.84 to 6.00 ......................................
6.14 ..................................................
7.97 ..................................................
9.18 ..................................................
6.20.
7.14.
7.58 to 7.76.
7.76.
9.08.
9.65.
75 Watt PAR38
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
¥0.37 ...............................................
3.29 to 5.64 ......................................
4.76 ..................................................
6.87 ..................................................
7.34 ..................................................
6.20.
7.14.
7.58 to 7.76.
7.76.
9.08
9.65.
50 Watt PAR30
Baseline .....................................
EL1 ............................................
EL2 ............................................
EL3 ............................................
EL4 ............................................
EL5 ............................................
N/A ...................................................
¥0.33 ...............................................
¥0.01 to 2.57 ..................................
0.69 ..................................................
1.78 ..................................................
1.34 ..................................................
5.59.
6.53.
6.98 to 7.15.
7.15.
8.47.
9.04.
Installed price
2007$
*Analysis period is 0.9 years.
iv. Historical Facilities
DOE found that historical facilities
have similar operating hours, discount
rates, and electricity prices as the
typical consumer, although they do own
more T12 systems. Accordingly, for this
subgroup, no separate findings are
warranted. See section VI.B.1.a.i of this
notice to view the impacts on those
consumers with T12 lamps.
v. Consumers of T12 Electronic Ballasts
Table VI.21 through Table VI.24 show
the LCC subgroup results for consumers
of T12 electronic ballasts. Specifically,
DOE analyzed the LCC savings of a
consumer that owns a T12 electronic
system in the base case. In the case of
an energy conservation standard at EL4
or EL5, this consumer would need to
purchase a T8 electronic system, as T12
lamps would no longer available. DOE
established a new baseline electronic
T12 system and modified standards case
systems so that both of the following
conditions are met: (1) Light output is
maintained in the case of a standard;
and (2) energy is saved. All other factors
of the LCC subgroup analysis remained
the same as in the primary analysis.
Because electronic T12 systems are
much more efficient than magnetic T12
systems, the LCC savings for this
subgroup are lower than the LCC
savings for systems in the primary
analysis. For 4-foot medium bipin lamps
operating in the commercial sector, LCC
savings are reduced by approximately
$20 to $30, going from positive LCC
savings in the primary analysis to
negative LCC savings for this subgroup.
The source of this reduction is primarily
due to the increased efficacy of the
baseline system.
TABLE VI.21—LCC SUBGROUP RESULTS FOR A 3-LAMP FOUR-FOOT ELECTRONIC MEDIUM BIPIN GSFL SYSTEM
OPERATING IN THE COMMERCIAL SECTOR
Event II: Standards-induced retrofit (lamp & ballast replacement)
Baseline
Efficiency level
LCC savings *
2007$
40 Watt T12
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
¥16.72 to ¥4.37 .........................
¥9.98 to ¥5.76 ...........................
13.96.
EN/A.
EN/A.
EN/A.
63.26 to 75.56.
64.83 to 71.19.
34 Watt T12
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
¥12.38 to ¥1.43 .........................
¥8.63 to ¥5.53 ...........................
11.22.
EN/A.
EN/A.
EN/A.
63.26 to 67.88.
63.51 to 64.83.
Installed price
2007$
* Analysis period is 5.5 years.
EN/A: Event Not Applicable; N/A: Not Applicable.
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00079
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
16998
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
For 4-foot medium bipin lamps
operating in the residential sector, LCC
savings, already negative in the primary
analysis, become slightly more negative
for this subgroup. The change in the
savings is not as large in the residential
sector as in the commercial sector
because consumers for this event have
a shortened analysis period.
TABLE VI.22—LCC SUBGROUP RESULTS FOR A 2-LAMP FOUR-FOOT ELECTRONIC MEDIUM BIPIN GSFL SYSTEM
OPERATING IN THE RESIDENTIAL SECTOR USING HIGH OPERATING HOURS
Event IB: Lamp & ballast replacement
Baseline
LCC savings
2007$
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
40 Watt T12
Efficiency level
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
¥8.35 to ¥6.45 ...........................
¥7.80 to ¥7.18 ...........................
Installed price
2007$
3.98.
EN/A.
EN/A.
EN/A.
50.99 to 54.07.
51.16 to 52.03.
* Analysis period is 2.5 years.
EN/A: Event Not Applicable; N/A: Not Applicable.
For 8-foot single pin slimline lamps,
LCC savings are reduced by
approximately $18 to $25. For the 75W
T12 baseline, consumers experience
negative LCC savings for this subgroup
as opposed to the positive LCC savings
experienced by consumers in the
primary analysis. For the 60W T12
baseline, LCC savings, already negative
in the primary analysis, become more
negative for this subgroup. The source
of this reduction is primarily due to the
increased efficacy of the baseline
system.
TABLE VI.23—LCC SUBGROUP RESULTS FOR A 2-LAMP EIGHT-FOOT ELECTRONIC SINGLE-PIN SLIMLINE GSFL SYSTEM
OPERATING IN THE COMMERCIAL SECTOR
Event II: Standards-induced retrofit (lamp & ballast replacement)
Baseline
Efficiency level
LCC savings*
2007$
75 Watt T12
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
LL ..................................................
¥14.18 .........................................
16.16.
EN/A.
EN/A.
EN/A.
93.41.
95.12.
60 Watt T12
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
¥32.74 .........................................
¥31.86 to ¥30.09 .......................
11.33.
EN/A.
EN/A.
EN/A.
93.41.
93.79 to 95.12.
Installed price
2007$
* Analysis period is 4.0 years.
EN/A: Event Not Applicable; N/A: Not Applicable.
For 8-foot recessed double contact
high output lamps, LCC savings are
reduced by approximately $10 to $15.
For the 110W T12 baseline, consumers
experience negative LCC savings for this
subgroup as opposed to the positive
LCC savings experienced by consumers
in the primary analysis. For the 95W
T12 baseline, LCC savings, already
negative in the primary analysis,
become more negative. The source of
this reduction is again primarily due to
the increased efficacy of the baseline
system.
TABLE VI.24—LCC SUBGROUP RESULTS FOR A 2-LAMP EIGHT-FOOT ELECTRONIC RECESSED DOUBLE-CONTACT HIGH
OUTPUT GSFL SYSTEM OPERATING IN THE INDUSTRIAL SECTOR
Event II: Standards-induced retrofit (lamp & ballast replacement)
Baseline
VerDate Nov<24>2008
20:44 Apr 10, 2009
LCC savings
2007$
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
110 Watt T12
Efficiency level
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
LL ..................................................
¥10.09 .........................................
Jkt 217001
PO 00000
Frm 00080
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
Installed price
2007$
19.74.
EN/A.
EN/A.
EN/A.
123.27 to 123.60.
126.49.
13APP2
16999
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.24—LCC SUBGROUP RESULTS FOR A 2-LAMP EIGHT-FOOT ELECTRONIC RECESSED DOUBLE-CONTACT HIGH
OUTPUT GSFL SYSTEM OPERATING IN THE INDUSTRIAL SECTOR—Continued
Event II: Standards-induced retrofit (lamp & ballast replacement)
Baseline
LCC savings
2007$
Baseline ........................................
EL1 ...............................................
EL2 ...............................................
EL3 ...............................................
EL4 ...............................................
EL5 ...............................................
95 Watt T12
Efficiency level
N/A ................................................
EN/A .............................................
EN/A .............................................
EN/A .............................................
¥26.41 to ¥23.25 .......................
¥23.07 .........................................
Installed price
2007$
13.92.
EN/A.
EN/A.
EN/A.
123.27 to 123.60.
126.49.
* Analysis period is 2.3 years.
EN/A: Event Not Applicable; N/A: Not Applicable.
2. Economic Impacts on Manufacturers
DOE used the INPV in the MIA to
compare the financial impacts of
different TSLs on GSFL and IRL
manufacturers. The INPV is the sum of
all net cash flows discounted by the
industry’s cost of capital (discount rate).
DOE used the GRIMs to compare the
INPV of the base case (no amended
energy conservation standards) to that of
each TSL for the GSFL and IRL
industries. To evaluate the range of
cash-flow impacts on the industries,
DOE constructed different scenarios for
each industry using different
assumptions for markups and shipments
that correspond to the range of
anticipated market responses. Each
scenario results in a unique set of cash
flows and corresponding industry value
at each TSL. These steps allowed DOE
to compare the potential impacts on
industries as a function of TSLs in the
GRIMs. The difference in INPV between
the base case and the standards case is
an estimate of the economic impacts
that implementing that standard level
would have on the entire industry.
a. Industry Cash-Flow Analysis Results
i. General Service Fluorescent Lamps
To assess the lower end of the range
of potential impacts for the GSFL
industry, DOE considered the flat
markup scenario under the Existing
Technologies base case, shipments with
high lighting expertise, and a shift in
efficacy distributions. Besides the
impact of shipments on the INPV, this
case assumed that manufacturers would
be able to maintain gross margins as a
percentage of revenues as production
cost increases with efficacy. To assess
the higher end of the range of potential
impacts for the GSFL industry, DOE
considered the scenario reflecting the
four-tier markup scenario under the
Emerging Technologies base case,
shipments with market-based lighting
expertise, and a rollup in efficacy
distributions. Besides the impact of
shipments on the INPV, this case
assumed standards would reduce
manufacturers’ portfolio, thereby
squeezing the margin of higher-efficacy
products as they are ‘‘demoted’’ to
lower-relative-efficacy tier products.
Table VI.25 and Table VI.26 show the
low end and high end of the range of
MIA results, respectively, for each TSL
using the cases described above.
TABLE VI.25—MANUFACTURER IMPACT ANALYSIS FOR GSFL WITH THE FLAT MARKUP SCENARIO UNDER THE EXISTING
TECHNOLOGIES BASE CASE—HIGH LIGHTING EXPERTISE—SHIFT IN EFFICIENCY DISTRIBUTIONS
INPV ................................................................
Change in INPV ..............................................
Amended Energy Conservation Standards
Product Conversion Expenses.
Amended Energy Conservation Standards
Capital Conversion Expenses.
Total Investment Required ..............................
Trial standard level
Base
case
Units
1
2
3
4
5
(2007$ millions) ..........
(2007$ millions) ..........
(%) ..............................
(2007$ millions) ..........
602
................
................
................
652
49
8.18%
3.3
653
50
8.31%
8.8
673
71
11.78%
8.8
594
¥9
¥1.48%
11.6
616
13
2.21%
29.6
(2007$ millions) ..........
................
38.5
60.5
104.5
181.5
181.5
(2007$ millions) ..........
................
41.8
69.3
113.3
193.1
211.1
TABLE VI.26—MANUFACTURER IMPACT ANALYSIS FOR GSFL WITH THE FOUR-TIER MARKUP SCENARIO UNDER THE
EMERGING TECHNOLOGIES BASE CASE—MARKET SEGMENT LIGHTING EXPERTISE—ROLLUP IN EFFICIENCY DISTRIBUTIONS
Trial standard level
Units
Base case
1
INPV ........................................................
Change in INPV ......................................
Amended Energy Conservation Standards Product Conversion Expenses.
Amended Energy Conservation Standards Capital Conversion Expenses.
Total Investment Required ......................
VerDate Nov<24>2008
20:44 Apr 10, 2009
Jkt 217001
2
3
4
5
(2007$ millions) ......
(2007$ millions) ......
(%) ..........................
(2007$ millions) ......
575
..................
..................
..................
668
93
16.09%
3.3
638
63
11.02%
8.8
436
¥139
¥24.15%
8.8
380
¥195
¥33.96%
11.6
312
¥263
¥45.80%
29.6
(2007$ millions) ......
..................
38.5
60.5
104.5
181.5
181.5
(2007$ millions) ......
..................
41.8
69.3
113.3
193.1
211.1
PO 00000
Frm 00081
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
17000
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
For the GSFL MIA, margin impacts
are the most significant driver of INPV.
The potential margin impacts on
manufacturers are based on their ability
to maintain higher margins as standards
remove efficacy as a differentiator of
premium products. The potential for
standards to disrupt the premium
margins for efficacy is captured in the
higher-bound and lower-bound
scenarios DOE presents. The lowerbound scenario represents the situation
where manufacturers maintain their
current ‘‘good, better, best’’ marketing
strategy by basing higher margins on
features other than efficacy or coming
up with more-efficient products. The
large impacts on industry value in the
upper-bound scenario are caused by
higher standards disrupting
manufacturers’ current marketing
strategy. In this scenario, manufacturers
cannot maintain higher margins when
efficacy is lost as a differentiator and
higher standards lower profitability.
Other drivers of INPV are less
significant because: (1) The capital costs
required at each TSL are relatively small
compared to the industry revenue; and
(2) shipments do not substantially
change regardless of the scenario.
DOE estimated the impacts on INPV
at TSL1 to range from $49 million to $93
million, equal to a 8.2 percent to 16.1
percent increase. At this level, the
highest impact on cash flow in the year
leading up to the standards occurs
under the Emerging Technologies base
case. Under this scenario, industry cash
flow decreases by approximately 37
percent, to $32 million, compared to the
base-case value of $50 million in the
year leading up to the standards.
Product conversion costs are low at
TSL1 because manufacturers have
existing products that meet the efficacy
levels. Capital conversion costs are also
low at this TSL because a minimal
amount of T12 machinery needs to be
converted to meet the growing volume
of T8 production induced by standards.
The necessary conversion costs to meet
TSL1 are low relative to the conversion
costs for the natural market migration
from T12 to T8 lamps in the base case,
which helps to mitigate the impact of
the standards-induced conversion costs.
The positive INPV predicted in the flat
markup scenario is indicative that
product conversion and capital
conversion outlays are also low relative
to the increase in variable production
costs. Whereas GSFL production is
capital intensive, the capital
requirements are a function primarily of
the tube diameter. Efficiency standards
which do not require a change in
diameter will typically require a change
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
in phosphors which is not capital
intensive. Under the tiered markup
scenario, manufacturers are left with a
range of products after standards, so
they still earn higher markups on a wide
variety of premium products. In fact, the
products eliminated at TSL1 are
commodity products which have a
lower-than-average profit margin. Thus,
industry revenues and cash flows are
not negatively affected, and
manufacturers actually benefit from the
higher prices of remaining products.
At TSL2, DOE estimated the impacts
in INPV at TSL2 to range from $50
million to $63 million, equal to a 8.3
percent to 11.0 percent increase. At this
level, the highest impact on cash flow
in the year leading up to the standards
occurs under the Emerging
Technologies base case. Under this
scenario, industry cash flow decreases
by approximately 60 percent, to $20
million, compared to the base-case
value of $50 million in the year leading
up to the standards. Product conversion
costs are still relatively low at TSL2,
because few manufacturers will have to
modify exiting products to meet this
standard level. Capital conversion costs
are also low at this TSL, but the
investments required to meet TSL2 are
larger than TSL1, because more T12
machinery needs to be converted to
meet the growing volume of T8
production induced by standards. INPV
is less positive at TSL2 than at TSL1,
because the higher conversion costs
necessary to meet TSL2 lower the
mitigating impact of the conversion
costs for the natural market migration
from T12 to T8 lamps included in the
base case. At TSL2, more of the mostefficient, higher-priced T12 lamps are
shifting to less-expensive T8 lamps.
INPV in the four-tier markup scenario is
also not as positive, because
manufacturers have fewer premium
products and the profit margins on some
more-efficient T12 products begin to
shrink. While TSL2 eliminates some of
the premium T12 lamps, the T8 lamps
to which consumers must migrate still
earn a higher markup.
At TSL3, the impact on INPV and
cash flow depends heavily on the ability
of manufacturers to differentiate
products and maintain higher margins
as standards move consumers to
previously premium products. DOE
estimated that the impacts on INPV at
TSL3 range from approximately $71
million to ¥$139 million, equal to a
11.8 percent to ¥24.2 percent change.
At this level, the highest impact on cash
flow in the year leading up to the
standards occurs under the Emerging
Technologies base case. Under this
scenario, industry cash flow decreases
PO 00000
Frm 00082
Fmt 4701
Sfmt 4702
by approximately 100 percent, to $0
million, compared to the base-case
value of $50 million in the year leading
up to the standards. At TSL3, most
manufacturers expressed concerns about
the ability to maintain production
volumes of T12 and T8 lamps, because
all but the most efficient T12 lamps are
eliminated. Because a large portion of
existing T12 shipments migrate to T8,
manufacturers have to convert or
replace a significant portion of their T12
production lines to T8, making capital
conversion costs higher at TSL3 than at
TSL1 or TSL2. Conversion costs are also
higher at TSL3, because manufacturers
have to make more R&D expenditures to
offer a full line of T12 and T8 products
that meet the standard. Because TSL3
greatly accelerates the migration of T12
to T8 products, the conversion costs in
the base case have a minimal effect on
offsetting INPV impacts from high
standards-induced conversion costs at
TSL3 and all higher TSLs. If
manufacturers can pass along the
increased production costs of moreefficient products by differentiating the
products with features such as low
mercury content and longer life, they
can recoup margins, thereby mitigating
some of the impacts. If manufacturers
can fully differentiate their products
and earn the same profit margins as in
the base case (the lower range of
impacts), they will benefit from higher
prices and INPV will be positive at this
TSL. However, if manufacturers cannot
differentiate their products and the
margins on previously premium
products begin to erode with
commoditization, DOE expects
manufacturer margins to be negative
and the higher end of the range of
negative INPV will be reached.
At TSL4, DOE estimated the impacts
on INPV range from approximately ¥$9
million to ¥$195 million, equal to a
¥1.5 percent to ¥34.0 percent change.
At this level, the highest impact on cash
flow in the year leading up to the
standards occurs under the Emerging
Technologies base case. Under this
scenario, industry cash flow decreases
by approximately 171 percent, to ¥$36
million, compared to the base-case
value of $50 million in the year leading
up to the standards. At TSL4, there are
significant conversion capital
expenditures because all T12
production lines need to be converted to
T8 lines; the capital requirement for this
conversion is nearly double the amount
needed at TSL3. The large capital costs
make INPV negative even if
manufacturers maintain the margin on
all lamps, as in the base case. Also,
manufacturers expressed concern that
E:\FR\FM\13APP2.SGM
13APP2
17001
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
the highest-grade phosphor mixtures
would be necessary on most lamps to
meet efficiencies prescribed by TSL4.
The more-efficient phosphor blends
substantially increase lamp costs,
decreasing profitability if the cost
increases cannot be passed on to
consumers. That is, at TSL4, more T8
lamps that previously earned a premium
are commoditized because the standard
eliminates all T12 lamps from the
market, thereby squeezing margins on
all lamps and causing more negative
impacts in the four-tier markup
scenario.
At TSL5, DOE estimated that the
impacts on INPV range from
approximately $13 million to ¥$263
million, equal to a 2.2 percent to ¥45.8
percent change. At this level, the
highest impact on cash flow in the year
leading up to the standards occurs
under the Emerging Technologies base
case. Under this scenario, industry cash
flow decreases by approximately 183
percent, to ¥$42 million, compared to
the base-case value of $50 million in the
year leading up to the standards. At
TSL5, the necessary conversion capital
is identical to TSL4 because this TSL
also requires manufacturers to convert
all existing T12 production to T8
production. These large costs make
INPV negative even if manufacturers
pass along all production cost increases
to the consumer. At TSL5, all products
are commoditized because all lamps
must use the most efficient phosphor
coatings. There are few options
available for manufacturers to
differentiate lamps at TSL5, thereby
making it more likely that
manufacturers will be negatively
affected.
Based on interviews with
manufacturers, DOE understands that
manufacturers are constantly forced to
revise their marketing strategies as new
products are introduced and older
products become commoditized. DOE
also understands that higher efficacy is
not the only feature available to
differentiate premium products.
Lifetime, lower mercury content, and
removing lead are all features that also
differentiate products. Therefore, DOE
believes that after significant early
disruptions in pricing, over time the
industry will recover the profitability
levels that existed prior to standards as
manufacturers rebalance their product
mix. The net effect on INPV is uncertain
but should tend toward the midpoint of
the two GRIM scenarios. DOE seeks
comment on the ability of
manufacturers to maintain these
margins through the differentiation of
products by other means. DOE also
seeks comment on how the ability to
differentiate products might vary over
time.
ii. Incandescent Reflector Lamps
During the manufacturer interviews
DOE learned that for IRL lamps,
markups do not increase as a function
of efficacy (in contrast to GSFL).
Instead, manufacturers indicated that
the range of potential impacts would
depend on the magnitude of the capital
investments required and the expected
reduction in product sales. Thus, DOE
modeled manufacturing impacts using
all IRL shipments scenarios described in
sections V.G.4.b.ii and V.G.4.b.iv. To
assess the lower end of the range of
potential impacts for the IRL industry,
DOE considered the Existing
Technologies base case reflecting the no
product substitution scenario with a
shift in efficacy distributions. In this
scenario: (1) Manufacturers benefit from
higher prices from consumers switching
to more-efficient products on their own
(the shift scenario); (2) IRL base-case
shipments are not eroded due to
emerging technologies; and (3)
standards-case shipments do not
decrease due to substitutions of R–CFL
and exempted BR lamps for IRL. To
assess the higher end of the range of
potential impacts for the IRL industry,
DOE considered the Emerging
Technologies base case reflecting the
product substitution scenario with a
rollup in efficacy distributions. In this
scenario: (1) IRL base-case shipments
are eroded due to emerging
technologies; and (2) standards-case
shipments decrease due to substitutions
of R–CFL and exempted BR lamps for
IRL. Table VI.27 and Table VI.28 show
the MIA results for each TSL for IRL
under the shipment scenarios which
result in the highest and lowest INPV
impacts.
TABLE VI.27—MANUFACTURER IMPACT ANALYSIS FOR IRL UNDER THE EXISTING TECHNOLOGIES BASE CASE—NO
PRODUCT SUBSTITUTION SCENARIO—SHIFT IN EFFICIENCY DISTRIBUTION
Trial standard level
Units
Base case
1
INPV ........................................................
Change in INPV ......................................
Amended Energy Conservation Standards Product Conversion Expenses.
Amended Energy Conservation Standards Capital Conversion Expenses.
Total Investment Required ......................
2
3
4
5
(2007$ millions) ......
(2007$ millions) ......
(%) ..........................
(2007$ millions) ......
267
..................
..................
..................
263
(4)
¥1.55%
$3
215
(52)
¥19.36%
$3
205
(62)
¥23.06%
$2
190
(77)
¥28.85%
$3
185
(82)
¥30.85%
$7
(2007$ millions) ......
..................
$31
$83
$134
$166
$185
(2007$ millions) ......
..................
$35
$87
$136
$170
$192
TABLE VI.28—MANUFACTURER IMPACT ANALYSIS FOR IRL UNDER THE EMERGING TECHNOLOGIES BASE CASE—PRODUCT
SUBSTITUTION—ROLL-UP IN EFFICIENCY DISTRIBUTIONS
Trial standard level
Units
Base case
1
INPV ........................................................
Change in INPV ......................................
Amended Energy Conservation Standards Product Conversion Expenses.
Amended Energy Conservation Standards Capital Conversion Expenses.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
2
3
4
5
(2007$ millions) ......
(2007$ millions) ......
(%) ..........................
(2007$ millions) ......
207
..................
..................
..................
191
(16)
¥7.69%
$3
149
(58)
¥27.87%
$3
131
(76)
¥36.85%
$2
112
(94)
¥45.60%
$3
104
(103)
¥49.60%
$7
(2007$ millions) ......
..................
$31
$83
$134
$166
$185
PO 00000
Frm 00083
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
17002
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.28—MANUFACTURER IMPACT ANALYSIS FOR IRL UNDER THE EMERGING TECHNOLOGIES BASE CASE—PRODUCT
SUBSTITUTION—ROLL-UP IN EFFICIENCY DISTRIBUTIONS—Continued
Trial standard level
Units
Base case
1
Total Investment Required ......................
(2007$ millions) ......
To meet TSL1, manufacturers must
replace less-efficient fill gases in the
capsule with xenon. At TSL1, DOE
estimated the impacts on INPV to be
between ¥$4 million and ¥$16
million, or a change in INPV of between
¥1.6 percent and ¥7.7 percent. At this
level, the highest impact on cash flow
in the year leading up to the standards
occurs under the Emerging
Technologies base case. Under this
scenario, the industry cash flow
decreases by approximately 68 percent,
to $7.1 million, compared to the base
case value of $22.5 million in the year
leading up to the standards. All
manufacturers have a full range of
products that meet this TSL. Conversion
expenses are relatively low at this level
because using xenon does not require
substantial changes to the
manufacturing process. Because the
lifetimes of standards-compliant lamps
do not change at TSL1, shipments in the
standards cases are not further impacted
by lower shipments due to higher lamp
lifetimes. In fact, at this TSL,
manufacturers benefit from the
increased prices of standards-compliant
lamps. However, this positive impact on
revenues is not enough to overcome the
product and capital conversion
expenses, making overall INPV negative.
The greater impact on shipments in the
Emerging Technologies base case with
product substitution drives INPV more
negative.
TSL2 is based on a 6,000 hour HIR
lamp, but this level may also be
achieved using an improved reflector.
At TSL2, the impact on INPV and cash
flow depends on a manufacturer’s
ability to recoup the conversion capital
and product conversion expenses and
the extent to which shipments are
reduced in the base case due to
emerging technologies and in the
standards case due to changes in the
product mix (including lamp lifetime).
DOE estimated the impacts in INPV at
TSL2 to be between ¥$52 million and
¥$58 million or a change in INPV of
¥19.4 percent and ¥27.9 percent. At
this level, the highest impact on cash
flow in the year leading up to the
standards occurs under the Emerging
Technologies base case. Under this
scenario, the industry cash flow
decreases by approximately 172 percent,
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
..................
2
$35
to ¥$16.2 million, compared to the
base-case value of $22.5 million in the
year leading up to the standards. At
TSL2, there are negative impacts on
manufacturers due to decreased
shipments and significant product
conversion expenses. At this TSL,
conversion expenses vary greatly among
manufacturers but are significant in the
aggregate due to the need to increase
production of HIR lamps or invest in
improved reflector technology. Two
manufacturers have a complete line of
standards-compliant lamps but must
spend a considerable amount of
resources to expand production of a
low-volume, premium product for mass
production. Another manufacturer must
spend a significant amount of capital to
purchase the machinery to meet
demand with exclusively higher
technology (infrared) lamps in addition
to replacing krypton with xenon as fill
gas in the capsule. The shipment
scenarios chosen account for the range
in INPV. Shipments have a significant
impact on INPV at this TSL in all cases
because the products that meet this
standard have the longest lifetimes in
the standards cases, further decreasing
shipments relative to the base cases.
Some manufacturers have expressed
concerns about competitive impacts at
this TSL. One manufacturer has a patent
on silverized reflectors. Another
manufacturer is believed to have a cross
license on the technology. Despite the
large capital expense to expand this
reflector technology for all baseline
lamps to meet this TSL, both these
manufacturers could capture market
share by selling less-expensive lamps
based on improved reflector coating
instead of HIR technology. The other
manufacturer without access to the
enhanced reflectors would have to make
large expenditures on capital and
product conversion to produce lamps
with a comparable efficacy, but at
higher costs.
TSL3 is based on 3,000-hour HIR
technology. DOE estimated the impacts
on INPV at TSL3 to be between ¥$62
million and ¥$76 million, or a change
in INPV of between ¥23.1 percent and
¥36.9 percent. At this level, the highest
impact on cash flow in the year leading
up to the standards occurs under the
Emerging Technologies base case. Under
PO 00000
Frm 00084
Fmt 4701
Sfmt 4702
3
$87
4
$136
5
$170
$192
this scenario, the industry cash flow
decreases by approximately 272 percent,
to¥$38.6 million, compared to the basecase value of $22.5 million in the year
leading up to the standards. There are
significant capital conversion costs at
this TSL that make INPV negative.
Manufacturers must purchase additional
infrared coaters to increase the
production of these low-volume lamps.
Since current HIR production is very
small relative to standard halogen IRL,
all manufacturers voiced their concerns
about meeting demand at this level.
Also, since all existing HIR capsules use
xenon as the fill gas, manufactures are
concerned about the high material costs
for this gas and the potential for the
price to increase over time. The high
costs to convert all lamps to HIR
technology drive INPV negative and
strand existing equipment for standard
halogen capsules. The range of INPV
arises from the shipment scenarios that
account for different market erosion due
to emerging technology and standards
inducing a switch to exempted BR
lamps and R–CFL. If manufacturer
concerns about consumers switching to
exempted BR and R–CFL are realized in
addition to emerging technology eroding
the IRL market, then the higher end of
the range of negative INPV will be
reached.
TSL4 requires the production of an
improved HIR lamp. At TSL4, DOE
estimated the impacts in INPV to be
between ¥$77 million and ¥$94
million, or a change in INPV of ¥28.9
percent and ¥45.6 percent. At this
level, the highest impact on cash flow
in the year leading up to the standards
occurs under the Emerging
Technologies base case. Under this
scenario, the industry cash flow
decreases by approximately 338 percent,
to ¥$53.6 million, compared to the
base-case value of $22.5 million in the
year leading up to the standards. The
significant capital and product
conversion expenses at this TSL make
INPV negative. At this TSL, all
manufacturers must expand production
of the more-efficient HIR technology to
meet demand of the entire market. Since
current HIR production is relatively
low, these substantial costs make INPV
negative. The capital conversion
expenses are large because, in addition
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
to HIR technology, manufacturers must
also use enhanced reflectors or the most
efficient burners and add xenon. Also,
since all existing HIR capsules use
xenon as the fill gas, manufactures are
concerned about the high material costs
for this gas and the potential for the
price to increase over time. The
lifetimes of products that meet this TSL
are longer than the baseline, creating a
negative impact on INPV from
shipments regardless of the shipment
scenario selected. Manufacturers also
voiced concerns about competition at
TSL4. Because lamps can use an
enhanced reflector with HIR to meet
TSL4, manufacturers have the same
competitive concerns as at TSL2.
Finally, two manufacturers currently
have a full line of lamps that meet TSL4.
A third manufacturer has some
products, but would have to undertake
a costly redesign of its burners in order
to sell a full line of those lamps.
TSL5 requires the production of
lamps with an improved HIR coating
and an additional improvement. At
TSL5, DOE estimated the impacts in
INPV to be between ¥$82 million and
¥$103 million, or a change in INPV of
between ¥30.9 percent and ¥49.6
percent. At this level, the highest impact
on cash flow in the year leading up to
the standards occurs under the
Emerging Technologies base case. Under
this scenario, the industry cash flow
decreases by approximately 381 percent,
to ¥$63.1 million, compared to the
base-case value of $22.5 million in the
year leading up to the standards. The
impacts at TSL5 are the most severe for
manufacturers, because the capital and
product conversion expenses are
greatest at this TSL. At this TSL, all
manufacturers must expand production
of a lamp with multiple improvements
over standard HIR lamps. Manufacturers
must use HIR technology with an
improved coating and with either
enhanced reflectors or more-efficient
burners. Since even standard HIR
production is currently low compared to
standard halogen, expanding the
production of the most-efficient HIR
technology to meet demand of the entire
market is very costly. Due to the large
conversion costs, INPV is greatly
negative even if the market is not eroded
by emerging technology and customers
do not substitute R–CFL and exempted
BR lamps for IRL. If manufacturers
concerns about emerging technology
and substitutions for IRL are realized,
DOE expects the higher range of
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
negative impacts to be reached (a 49.6
percent decrease in INPV).
b. Cumulative Regulatory Burden
While any one regulation may not
impose a significant burden on
manufacturers, DOE understands the
combined effects of several existing and
impending regulations may have serious
consequences for some manufacturers,
groups of manufacturers, or an entire
industry. Assessing the impact of a
single regulation may overlook this
cumulative regulatory burden. For this
reason, DOE conducts an analysis of
cumulative regulatory burden as part of
its rulemakings pertaining to appliance
efficiency.
In its written comment, NEMA
submitted a list of regulatory
requirements that included numerous
reporting requirements, the Restriction
on Hazardous Substances directive
(RoHS), and legislatively-prescribed
minimum performance requirements
that contribute to the industries’
cumulative regulatory burden (NEMA,
No. 22 at p 34). DOE discusses the
suggested regulatory provisions
submitted by NEMA in chapter 13 of the
TSD.
In addition to the energy conservation
standards on GSFL and IRL products,
other regulations can significantly affect
manufacturers’ financial operations.
Multiple regulations affecting the same
manufacturer can quickly strain profits
and possibly cause an exit from the
market. Besides the list of suggested
regulatory provisions that NEMA
submitted, DOE also identified other
regulations these manufacturers are
facing for other products and equipment
they manufacture within three years
prior to and three years after the
effective date of the amended energy
conservation standards for GSFL and
IRL.
DOE believes that the EISA 2007
requirements for GSIL could have the
greatest cumulative burden on
manufacturers of GSFL and IRL. DOE
understands that manufacturers of GSFL
and IRL will also incur large capital and
product conversion investments to
comply with the GSIL minimum
efficacy standards. The GSIL
investments will compete with IRL and
GSFL for company resources. For
example, GSFL, IRL, and GSIL all share
many of the same limited engineering
resources. In addition, the capital costs
to comply with EISA 2007 could
potentially limit the funding available
for GSFL and IRL conversions because
PO 00000
Frm 00085
Fmt 4701
Sfmt 4702
17003
these investments will compete for the
same sources of capital. DOE
understands that these are important but
surmountable challenges for GSFL and
IRL manufacturers.
c. Impacts on Employment
To assess the impacts of energy
conservation standards on GSFL and
IRL direct manufacturing employment,
DOE used the GRIM to estimate
domestic labor expenditures and
employment levels. DOE used statistical
data from the U.S. Census Bureau’s 2006
Annual Survey of Manufacturers (2006
ASM), results from other analyses, and
interviews with manufacturers to
estimate the inputs necessary to
calculate industry-wide labor
expenditures and employment levels. In
the GRIM, total labor expenditures are a
function of the labor content, the sales
volume, and the wage rate which
remains fixed in real terms over time.
The total employment figures presented
for the GSFL and IRL industries include
both production and non-production
workers.
DOE does not believe that standards
will alter the domestic employment
levels of the GSFL industry. During
interviews with manufacturers, DOE
learned that GSFL are produced on
high-speed, fully-automated lines.
Production workers are not involved in
the physical assembly of the final
product (e.g., in inserting components,
transferring partly assembled lamps,
soldering lamp bases). The production
workers counted in DOE’s figure
include plant workers involved in
clearing glass, overseeing a portion of
the assembly line, monitoring quality
control, mixing phosphors, and moving
finished products to loading. The
employment levels required for these
tasks are a function of the total volume
of the facility, not the labor content of
the product mix produced by the plant.
Since higher TSLs involve using moreefficient phosphors, employment will
not be impacted because standards will
not change the overall scale of the
facility. DOE estimates that there are
approximately 1,806 U.S. production
and non-production workers in the
GSFL industry.
Table VI.29 and Table VI.30 show the
domestic employment impacts
calculated in the GRIM for the two cash
flow scenarios used to bound the range
of INPV impacts. The total employment
figures include both production and
non-production workers.
E:\FR\FM\13APP2.SGM
13APP2
17004
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.29—CHANGE IN AVERAGE NUMBER OF DOMESTIC EMPLOYEES IN THE IRL INDUSTRY UNDER THE EXISTING
TECHNOLOGIES BASE CASE—NO PRODUCT SUBSTITUTION SCENARIO—SHIFT IN EFFICIENCY DISTRIBUTION
Baseline
Average Number of Domestic IRL Employees from 2012–2042 ............
Change in the Average Number of Domestic IRL Employees from
2012–2042 ............................................................................................
TSL1
TSL2
TSL3
TSL4
TSL5
1,319
1,518
1,303
1,492
1,396
1,426
................
199
¥16
173
77
107
TABLE VI.30—CHANGE IN AVERAGE NUMBER OF DOMESTIC EMPLOYEES IN THE IRL INDUSTRY UNDER THE EMERGING
TECHNOLOGIES BASE CASE—PRODUCT SUBSTITUTION SCENARIO—ROLL-UP IN EFFICIENCY DISTRIBUTION
Baseline
Average Number of Domestic IRL Employees from 2012–2042 ............
Change in the Average Number of Domestic IRL Employees from
2012–2042 ............................................................................................
DOE believes that amended energy
conservation standards will not
significantly impact IRL direct
employment. The impact that new
standards will have on employment is
far less significant than the potential
impact from emerging technologies.
Both scenarios show that the absolute
magnitudes of employment impacts due
to standards are small. Whether
standards have a positive or negative
impact on employment is largely
determined by the extent to which
consumers elect to substitute IRL with
other lamp technologies (such as R–CFL
or exempted IRL) in the standards case.
The employment impacts calculated
by DOE are independent of the
employment impacts from the broader
U.S. economy, which are documented
in chapter 15 of the TSD accompanying
this notice. The employment
conclusions also do not account for the
possible relocation of domestic jobs to
lower-labor-cost countries because the
potential relocation of U.S. jobs is
uncertain and highly speculative.
During interviews, manufacturers did
not emphasize the risk of shifting
production facilities abroad.
d. Impacts on Manufacturing Capacity
DOE anticipates that amended energy
conservation standards would not
significantly affect the production
capacity of GSFL manufacturers. For
GSFL manufacturers, any necessary
redesign of GSFL would not change the
fundamental assembly of the equipment
because higher TSLs require the use of
more-efficient phosphor coatings, which
are largely a materials issue. Therefore,
in the long-term there should be no
capacity constraints. However, higher
standards would also be expected to
expedite a natural conversion of T12
shipments to T8 shipments. Because
most production lines are specific to
lamp diameter, shifting production from
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
TSL1
Frm 00086
Fmt 4701
TSL3
TSL4
TSL5
699
783
623
724
617
621
................
84
¥77
24
¥82
¥78
T12 to T8 lamps requires shutting down
the line and retooling. Based on the
duration of line changes described by
manufactures, DOE believes that the
conversion of machinery to T8 lamp
production could occur between the
announcement date and the effective
date of the standards. In addition,
manufacturers indicated it is possible to
ramp up production before shutting
down a line to maintain a constant
supply of shipments during retooling.
Manufacturers are concerned that IRL
standards could cause capacity
constraints if amended standards were
to alter the assembly of standard
halogen burners. In particular, IRL
manufacturers are concerned about the
ability to convert their equipment in
time to meet an exclusively HIR
standard (TSL3, TSL4, and TSL5).
Although all manufacturers DOE
interviewed produce lamps with
infrared burners, the current volume of
these lamps is many times lower than
the volume of standard halogen lamps.
In addition, the production of infrared
capsules is much more time consuming,
requiring additional time for the coating
process and quality control due to the
precision necessary for the technology
to increase efficacy. In general, the large
lamp manufacturers are concerned
about their ability to increase the
production volume of HIR capsules in
time to meet the standard. However,
interviews with suppliers of HIR
capsules and coating decks suggest that
the capacity could be met under an HIR
standard. Based on discussions with
suppliers of infrared coaters, DOE also
believes that lamp manufacturers will
have enough time in between the
announcement date and the effective
date of the standards to purchase and
install the necessary coaters to meet
TSL3 and higher and produce all
burners in their own facilities.
Independent of manufacturers’ ability to
PO 00000
TSL2
Sfmt 4702
install coaters to produce all infrared
burners in-house, independent
suppliers of infrared capsules suggested
that they have the ability to supply a
significant portion of the market.
Because manufacturers could install
additional coaters, purchase infrared
burners from a supplier, and use
existing excess capacity, DOE believes
IRL manufacturers will be able to
maintain production capacity levels and
continue to meet market demand for all
IRL standard levels.
e. Impacts on Manufacturer Subgroups
As discussed above, using average
cost assumptions to develop an industry
cash-flow estimate is inadequate for
assessing differential impacts among
manufacturer subgroups. Small
manufacturers, niche players, and
manufacturers exhibiting a cost
structure that differs largely from the
industry average could be affected
differently. DOE used the results of the
industry characterization to group
manufacturers exhibiting similar
characteristics.
During its interviews, DOE did not
identify any small manufacturers of
covered IRL, but DOE did identify one
small manufacturer that produces
covered GSFL.72 This manufacturer
suggested that it could be less impacted
by amended energy conservation
standards on GSFL than the large
manufacturers. Unlike its larger
competitors, the small manufacturer
focuses on specialty products not
covered by this rulemaking and has had
72 DOE identified and contacted 12 businesses
that could potentially be classified as small
business manufacturers of the products that are the
subject of this rulemaking. Four of those businesses
agreed to be interviewed. Of these, DOE verified
that only one of those businesses met all the criteria
to be classified as a small manufacturer of covered
GSFL or IRL. For further detail on DOE’s inquiry
regarding small manufacturers, please see section
VII.B on the review under the Regulatory Flexibility
Act.
E:\FR\FM\13APP2.SGM
13APP2
17005
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
a better ability to pass along product
cost increases. For a discussion of the
impacts on the small manufacturer, see
chapter 13 of the TSD and section 0 of
today’s notice.
3. National Impact Analysis
a. Significance of Energy Savings
To estimate the energy savings
through 2042 due to amended energy
conservation standards, DOE compared
the energy consumption of the lamps
under the base case to the energy
consumption of these products under
the trial standard levels. Table VI.31 and
Table VI.32 show the forecasted
national energy savings (including
rebound effect and HVAC interactions
where applicable) in quads (quadrillion
BTU) at each TSL for GSFL and IRL. As
discussed in section V.E, DOE models
two base-case shipment scenarios and
several standards-case shipment
scenarios. For each lamp type, these
scenarios combined produce eight
possible sets of NES results. The tables
below present the results of the two
scenarios that represent the maximum
and minimum energy savings resulting
from all the scenarios analyzed.
For GSFL, DOE presents ‘‘Existing
Technologies, High Lighting Expertise,
Shift’’ and ‘‘Emerging Technologies,
Market Segment-Based Lighting
Expertise, Roll-Up’’ in Table VI.31 as
the scenarios that produce the
maximum and minimum energy
savings, respectively. Due to a larger
reduction in the installed stock of lamps
affected by standards, the Emerging
Technologies base-case forecast results
in lower energy savings than the
Existing Technologies base-case
forecast. In addition, due to a portion of
consumers purchasing non-energysaving, higher-lumen-output systems,
the Market Segment-Based Lighting
Expertise scenario results in lower
energy savings than the High Lighting
Expertise scenario. Finally, because in
the Shift scenario more consumers move
to higher-efficacy lamps than in the
Roll-Up scenario, the Shift scenario
results in higher energy savings than the
Roll-Up scenario.
Table VI.31 presents total national
energy savings for each TSL (labeled as
‘‘Total’’ savings). The table also reports
national energy savings due to
individually regulating each type of
GSFL (presented next to the lamp type
names), assuming no amended standard
on all other lamp types. However, it is
important to note that individual lamp
type energy savings (due to separate
regulation) do not sum to equal total
energy savings achieved at the trial
standard levels due to standardsinduced substitution effects between
lamp types. Instead, these savings are
provided merely to illustrate the
approximate relative energy savings of
each lamp type under a TSL. As
discussed in the March 2008 ANOPR,
due to their relatively small shipmentsbased market share, DOE did not
directly model the national impacts of
2-foot U-shaped lamps. In the ANOPR,
DOE stated that in order to develop NES
and NPV for this lamps type, it intended
to scale the NIA results from other
analyzed product classes. Given the
similarities in historical shipment
trends (showing a decrease in T12
lamps and an increase in T8 lamps) and
in system input power, in this NOPR,
DOE has decided to scale results from
the 4-foot medium bipin product classes
to approximate NES and NPV of 2-foot
U-Shaped product classes. As historical
shipments 4-foot medium bipin lamps
were 22 times that of 2-foot U-shaped
lamp shipments, DOE used this scaling
factor to approximate the energy savings
of 2-foot U-shaped lamps.
As seen in the tables below, the
highest energy savings result from TSL
5 and from EL5 for all lamp types. In
addition, DOE notes that at EL 1 and EL
2 for 4-foot medium bipin and at EL 1,
EL 2, and EL 3 for 8-foot single pin
slimline and 8-foot RDC HO lamps, all
energy savings originate from shifts to
higher-efficacy T12 lamps and voluntary
early retrofits to the more-efficacious T8
systems (not applicable to 8-foot RDC
HO). At these ELs, all T8 lamps are
compliant and, therefore, unaffected by
standards. At TSL 3, a large increase in
total energy savings of GSFL can be
observed, stemming from the conversion
of all 40W, 4-foot MBP T12 lamps to
34W T12 lamps and also from 4-foot T8
lamps (the majority of the GSFL stock)
being affected by the regulations. It is
also important to note that at TSL 4 and
TSL 5, all 4-foot MBP, 8-foot SP
slimline, and 8-foot RDC HO T12 lamp
systems would be automatically
retrofitted to T8 lamp systems, because
no T12 standards-compliant lamps
would be available.
TABLE VI.31—SUMMARY OF CUMULATIVE NATIONAL ENERGY SAVINGS FOR GSFL
National energy savings
(quad)
TSL/EL
1 .............
Lamp type
Emerging
technologies, market segment-based
lighting expertise,
roll-up
VerDate Nov<24>2008
1.52
0.10
0.18
0.76
1.14
0.07
0.43
0.08
0.02
0.12
0.65
0.02
3.77
1.32
MBP ..........................................................................................................................
SP Slimline ...............................................................................................................
RDC HO ...................................................................................................................
MiniBP SO ................................................................................................................
MiniBP HO ................................................................................................................
U-Shaped ..................................................................................................................
1.57
0.13
0.24
0.76
1.14
0.07
0.60
0.11
0.20
0.12
0.65
0.03
Total .................................................................................................................................
3 .............
MBP ..........................................................................................................................
SP Slimline ...............................................................................................................
RDC HO ...................................................................................................................
MiniBP SO ................................................................................................................
MiniBP HO ................................................................................................................
U-Shaped ..................................................................................................................
Total .................................................................................................................................
2 .............
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
Existing
technologies, high
lighting expertise,
shift
3.90
1.70
4-foot MBP ..........................................................................................................................
4.76
1.99
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00087
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
17006
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.31—SUMMARY OF CUMULATIVE NATIONAL ENERGY SAVINGS FOR GSFL—Continued
National energy savings
(quad)
TSL/EL
Lamp type
8-foot
8-foot
4-foot
4-foot
2-foot
Existing
technologies, high
lighting expertise,
shift
Emerging
technologies, market segment-based
lighting expertise,
roll-up
0.17
0.20
0.12
0.65
0.09
7.33
3.24
MBP ..........................................................................................................................
SP Slimline ...............................................................................................................
RDC HO ...................................................................................................................
MiniBP SO ................................................................................................................
MiniBP HO ................................................................................................................
U-Shaped ..................................................................................................................
8.23
0.38
0.66
0.76
1.14
0.37
2.70
0.23
0.66
0.12
0.65
0.12
Total .................................................................................................................................
11.64
4.49
MBP ..........................................................................................................................
SP Slimline ...............................................................................................................
RDC HO ...................................................................................................................
MiniBP SO ................................................................................................................
MiniBP HO ................................................................................................................
U-Shaped ..................................................................................................................
9.53
0.38
0.72
0.91
1.14
0.43
3.72
0.25
0.67
0.29
0.65
0.17
Total .................................................................................................................................
5 .............
0.18
0.25
0.76
1.14
0.22
Total .................................................................................................................................
4 .............
SP Slimline ...............................................................................................................
RDC HO ...................................................................................................................
MiniBP SO ................................................................................................................
MiniBP HO ................................................................................................................
U-Shaped ..................................................................................................................
13.17
5.75
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
For IRL, DOE presents ‘‘Existing
Technologies, Product Substitution,
Shift’’ and ‘‘Emerging Technologies, No
Product Substitution, Roll-Up’’ in Table
VI.32 as the scenarios that produce the
maximum and minimum energy
savings, respectively. Similar to GSFL,
the Existing Technologies base-case
forecast results in higher energy savings
than the Emerging Technologies basecase forecast due to the greater installed
stock of IRL affected by standards. Also,
although a relatively small difference,
the Product Substitution scenario
(including migration to both higherefficacy R–CFL and lower-efficacy,
exempted BR lamps) results in
marginally higher energy savings than
the No Product Substitution scenario. In
addition, while the effect is greater for
GSFL than for IRL, the Shift scenario
(only affecting commercial consumers)
also represents higher energy savings
than the Roll-Up scenario for IRL. As
seen in the table below, TSL 5 achieves
maximum energy savings for both
scenarios.
TABLE VI.32—SUMMARY OF CUMULATIVE NATIONAL ENERGY SAVINGS FOR INCANDESCENT REFLECTOR LAMPS
National energy savings (quads)
Existing technologies, product
substitution, shift
TSL
1
2
3
4
5
Emerging
technologies, no
product substitution, roll-up
0.37
1.06
1.89
2.32
2.60
0.22
0.52
1.00
1.25
1.48
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
b. Net Present Value
The NPV analysis is a measure of the
cumulative benefit or cost of standards
to the Nation. In accordance with the
OMB’s guidelines on regulatory
analysis,73 DOE calculated NPV using
both a 7-percent and a 3-percent real
73 OMB
Circular A–4, section E (Sept. 17, 2003).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
discount rate. The 7-percent rate is an
estimate of the average before-tax rate of
return to private capital in the U.S.
economy, and reflects the returns to real
estate and small business capital, as
well as corporate capital. DOE used this
discount rate to approximate the
opportunity cost of capital in the private
sector, because recent OMB analysis has
PO 00000
Frm 00088
Fmt 4701
Sfmt 4702
found the average rate of return to
capital to be near this rate. DOE also
used the 3-percent rate to capture the
potential effects of standards on private
consumption (e.g., through higher prices
for equipment and the purchase of
reduced amounts of energy). This rate
represents the rate at which society
discounts future consumption flows to
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
their present value. This rate can be
approximated by the real rate of return
on long-term government debt (i.e.,
yield on Treasury notes minus annual
rate of change in the Consumer Price
Index), which has averaged about 3
percent on a pre-tax basis for the last 30
years.
The table below shows the forecasted
net present value at each trial standard
level for GSFL and IRL. Similar to the
results presented for NES, Table VI.33
DOE presents the ‘‘Existing
Technologies, High Lighting Expertise,
Shift’’ scenario and the ‘‘Emerging
Technologies, Market Segment-Based
Lighting Expertise, Roll Up’’ scenario as
the maximum and minimum NPVs for
GSFL, respectively. In general, the NPV
results at each trial standard level are a
reflection of the life-cycle cost savings at
the corresponding efficacy levels. As
seen in section VI.B.1.a.i for most lamp
purchasing events and most baseline
17007
the LCC results. For the Market
Segment-Based Lighting Expertise
scenario, due to a large lack of lighting
expertise in the residential sector (DOE
assumes 0 percent consumers
conducting T12 fixture replacements
have high lighting expertise), the NPV
from 4-foot medium bipin lamps is
negative at EL1 and EL2. At efficacy
levels above EL2, 4-foot medium bipin
lamps achieve positive NPV due to the
integration of more-efficacious T8 lamps
into both commercial stocks (where
lighting sophistication is higher) and
residential stocks. In addition, the
Emerging Technologies, Market
Segment-Based Lighting Expertise, RollUp scenario shows decreased NPV from
TSL4 to TSL5. This is primarily due to
the portion of consumers (without
lighting expertise) that are forced to
purchase much higher cost lamps, but
do not take advantage of the energy
savings they provide.
lamps, increasing efficacy levels
generally result in increased LCC
savings. Due to this general costeffectiveness of higher-efficacy GSFL,
the Existing Technologies base-case
forecast (which increases the affected
stock and shipments) and the Shift
scenario (which results in the shipment
of more high-efficacy lamps) represent
the high-range scenario for NPV. The
Market Segment-Based Lighting
Expertise scenario models consumers
who purchase higher-first-cost lamps,
but may not achieve energy savings. As
these consumers generally have overall
lower NPV (and often negative NPV)
than their energy-saving counterparts,
the Market Segment-Based Lighting
Expertise scenario results in lower NPV
than the High Lighting Expertise
scenario.
As seen in Table VI.33, NPV generally
increases with increasing trial standard
levels, consistent with the same trend in
TABLE VI.33—SUMMARY OF CUMULATIVE NET PRESENT VALUE FOR GSFL
NPV (billion 2007$)
TSL/EL
Existing technologies, high lighting
expertise, shift
Product class
7% Discount
Emerging technologies, market segmentbased lighting expertise, roll-up
3% Discount
7% Discount
3% Discount
5 .............
¥0.01
0.03
¥0.17
0.05
0.81
0.00
0.73
0.21
¥0.24
0.19
1.91
0.03
7.12
16.46
0.71
2.82
MBP ..................................................
SP Slimline ........................................
RDC HO ............................................
MiniBP SO ........................................
MiniBP HO ........................................
U-Shaped ..........................................
3.14
0.15
0.43
1.11
1.46
0.14
7.78
0.45
0.73
2.70
3.38
0.35
¥0.35
0.09
0.53
0.05
0.81
¥0.02
0.52
0.35
0.87
0.19
1.91
0.02
6.43
15.39
1.11
3.85
MBP ..................................................
SP Slimline ........................................
RDC HO ............................................
MiniBP SO ........................................
MiniBP HO ........................................
U-Shaped ..........................................
7.56
0.37
0.12
1.11
1.46
0.34
17.53
0.81
0.26
2.70
3.38
0.80
1.79
0.37
0.06
0.05
0.81
0.08
5.58
0.80
0.14
0.19
1.91
0.25
11.09
25.67
3.23
8.98
MBP ..................................................
SP Slimline ........................................
RDC HO ............................................
MiniBP SO ........................................
MiniBP HO ........................................
U-Shaped ..........................................
17.47
0.87
1.33
1.11
1.46
0.79
35.93
1.89
2.53
2.70
3.38
1.63
5.97
0.38
1.33
0.05
0.81
0.27
13.34
0.97
2.53
0.19
1.91
0.61
Total .........................................................
4 .............
9.04
0.34
0.60
2.70
3.38
0.41
Total .........................................................
3 .............
3.93
0.10
0.35
1.11
1.46
0.18
Total .........................................................
2 .............
MBP ..................................................
SP Slimline ........................................
RDC HO ............................................
MiniBP SO ........................................
MiniBP HO ........................................
U-Shaped ..........................................
Total .........................................................
1 .............
23.37
48.61
8.85
19.59
18.37
0.87
1.38
1.45
38.56
1.89
2.62
3.46
5.53
0.45
1.28
0.23
12.80
1.11
2.46
0.69
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
4-foot
8-foot
8-foot
4-foot
4-foot
2-foot
4-foot
8-foot
8-foot
4-foot
VerDate Nov<24>2008
MBP ..................................................
SP Slimline ........................................
RDC HO ............................................
MiniBP SO ........................................
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00089
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
17008
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.33—SUMMARY OF CUMULATIVE NET PRESENT VALUE FOR GSFL—Continued
NPV (billion 2007$)
TSL/EL
Existing technologies, high lighting
expertise, shift
Product class
7% Discount
Emerging technologies, market segmentbased lighting expertise, roll-up
3% Discount
7% Discount
3% Discount
4-foot MiniBP HO ........................................
2-foot U-Shaped ..........................................
1.46
0.83
3.38
1.75
0.81
0.25
1.91
0.58
Total .........................................................
24.49
51.90
8.54
19.53
For IRL, DOE presents the ‘‘Existing
Technologies, Product Substitution,
Shift’’ and ‘‘Emerging Technologies, No
Product Substitution, Roll-Up’’
scenarios as the maximum and
minimum NPVs, respectively. As seen
in Table VI.34, NPV increases with TSL,
consistent with LCC savings generally
increasing with efficacy level. In
particular, for the No Product
Substitution scenario, the negative NPV
at TSL1 results because the life-cycle
cost savings at EL1 (the associated EL)
are primarily negative. However, as seen
in the Product Substitution scenario,
TSL1 achieves positive NPV due to
primarily the increased movement to
highly cost-effective R–CFLs. NPV
results are the most positive at TSL5,
because the most cost-effective IRL lamp
is purchased at this TSL.
TABLE VI.34—SUMMARY OF CUMULATIVE NET PRESENT VALUE FOR INCANDESCENT REFLECTOR LAMPS
NPV (billion 2007$)
Existing technologies, product
substitution, shift
TSL
7% Discount
rate
1
2
3
4
5
...............................................................................................................
...............................................................................................................
...............................................................................................................
...............................................................................................................
...............................................................................................................
c. Impacts on Employment
In addition to considering the direct
employment impacts for the
manufacturers of products covered in
this rulemaking (discussed above), DOE
also develops estimates of the indirect
employment impacts of proposed
standards on the economy in general. As
noted previously, DOE expects energy
conservation standards for the GSFL
and IRL covered by these standards to
reduce energy bills for consumers, with
Emerging technologies, no
product substitution, roll-up
3% Discount
rate
0.19
3.47
4.75
6.75
7.52
the resulting net savings being
redirected to other forms of economic
activity. DOE also realizes that these
shifts in spending and economic activity
could affect the demand for labor. To
estimate these effects, DOE used an
input/output model of the U.S. economy
using BLS data (see section V.H). See
chapter 15 of the TSD accompanying
this notice for details.
This input/output model suggests the
proposed standards are likely to slightly
7% Discount
rate
3% Discount
rate
¥0.06
1.82
2.58
3.72
4.34
0.55
7.11
9.85
13.97
15.55
0.00
3.71
5.30
7.68
8.99
increase the net demand for labor in the
economy. Neither the BLS data nor the
input/output model DOE uses includes
the quality or wage level of the jobs. As
Table VI.35 and Table VI.36 show, the
net increase in jobs due to standards for
GSFL and IRL, respectively, is so small
that it would likely be imperceptible in
national labor statistics and might be
offset by other, unanticipated effects on
employment.
TABLE VI.35—NET NATIONAL CHANGE IN INDIRECT EMPLOYMENT FOR GSFL, JOBS IN 2042
Net national change in jobs
(thousands)
Existing
technologies,
shift, high
lighting expertise
Trial standard level
1
2
3
4
5
Emerging technologies, roll up,
market segment
based lighting
expertise
15.4
15.2
21.6
27.6
32.4
5.2
5.7
10.1
13.3
15.2
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
Frm 00090
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
17009
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.36—NET NATIONAL CHANGE IN INDIRECT EMPLOYMENT FOR IRL, JOBS IN 2042
Net national change in jobs
(thousands)
Trial standard level
1
2
3
4
5
Existing technologies, product
substitution, shift
Emerging
technologies, no
product substitution, roll up
1.4
3.5
5.8
7.5
8.2
0.9
2.9
5.2
6.9
7.8
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
.......................................................................................................................................................................
4. Impact on Utility or Performance of
Products
As discussed in section IV.D.1.d of
this notice, DOE concluded that none of
the efficacy levels considered in this
notice would reduce the utility or
performance of the GSFL and IRL under
consideration in this rulemaking. (42
U.S.C. 6295(o)(2)(B)(i)(IV)).
Furthermore, manufacturers of these
products currently offer GSFL and IRL
that meet or exceed the proposed
standards.
5. Impact of Any Lessening of
Competition
DOE considers any lessening of
competition likely to result from
standards. The Attorney General
determines the impact, if any, of any
lessening of competition likely to result
from a proposed standard, and transmits
such determination to the Secretary,
together with an analysis of the nature
and extent of such impact. (42 U.S.C.
6295(o)(2)(B)(i)(V) and (B)(ii)).
To assist the Attorney General in
making such a determination, DOE has
provided DOJ with copies of this notice
and the TSD for review. DOE will
consider DOJ’s comments on the
proposed rule in preparing the final
rule. In the final rule, DOE will publish
the Attorney General’s written
determination and respond accordingly.
6. Need of the Nation To Conserve
Energy
An improvement in the energy
efficiency of GSFL and IRL is likely to
improve the security of the Nation’s
energy system by reducing overall
demand for energy, thereby reducing the
Nation’s reliance on foreign sources of
energy. Reduced demand could improve
the reliability of the electricity system,
particularly in the short run during
peak-load periods. As a measure of this
reduced demand, DOE expects the
energy savings from the proposed
standards to eliminate the need for
approximately 1100 to 3400 megawatts
(MW) of generating capacity for GFSL
and up to 450 MW for IRL by 2042.
Enhanced energy efficiency also
produces environmental benefits. The
expected energy savings from higher
standards would reduce the emissions
of air pollutants and greenhouse gases
associated with electric energy
production and may reduce the cost of
maintaining nationwide emissions
standards and constraints. Table VI.37
and Table VI.38 show cumulative CO2,
NOX, and Hg emissions reductions for
GSFL and IRL by TSL over the
rulemaking period.
TABLE VI.37—SUMMARY OF EMISSIONS REDUCTIONS FOR GSFL
[Cumulative reductions for products sold from 2012 to 2042]
TSL1
TSL2
TSL3
TSL4
TSL5
Existing Technologies, Shift, High Lighting Expertise
CO2 (MMt) ......................................................................
NOX (kt) .........................................................................
NOX (kt) .........................................................................
Hg (t) ..............................................................................
Hg (t) ..............................................................................
................................
low .........................
high ........................
low .........................
high ........................
236.4
14
347
0.0
4.2
233.7
15
361
0.0
3.8
395.2
25
623
0.0
6.9
597.7
39
951
0.0
7.9
679.7
43
1,072
0.0
9.1
239.7
17
407
0.0
3.2
312.8
20
503
0.0
4.4
Emerging Technologies, Roll Up, Market Segment Based Lighting Expertise
CO2 (MMt) ......................................................................
NOX (kt) .........................................................................
NOX (kt) .........................................................................
Hg (t) ..............................................................................
Hg (t) ..............................................................................
................................
low .........................
high ........................
low .........................
high ........................
85.7
5
127
0.0
1.5
103.5
7
167
0.0
1.5
184.3
12
289
0.0
2.9
TABLE VI.38—SUMMARY OF EMISSIONS REDUCTIONS FOR IRL
[Cumulative reductions for products sold from 2012 to 2042]
TSL1
TSL2
TSL3
TSL4
TSL5
Existing Technologies, Product Substitution, Shift
CO2 (MMt) ......................................................................
NOX (kt) .........................................................................
NOX (kt) .........................................................................
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
PO 00000
................................
low .........................
high ........................
Frm 00091
Fmt 4701
Sfmt 4702
17.7
1
29
44.8
3
78
E:\FR\FM\13APP2.SGM
88.1
6
141
13APP2
114.4
7
181
118.8
8
193
17010
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.38—SUMMARY OF EMISSIONS REDUCTIONS FOR IRL—Continued
[Cumulative reductions for products sold from 2012 to 2042]
TSL1
Hg (t) ..............................................................................
Hg (t) ..............................................................................
low .........................
high ........................
0.0
0.2
TSL2
TSL3
0.0
0.6
TSL4
TSL5
0.0
1.3
0.0
1.7
0.0
1.7
46.2
3
75
0.0
0.6
58.6
4
94
0.0
0.8
79.3
1
17
0.0
1.3
Emerging Technologies, No Product Substitution, Roll Up
CO2 (MMt) ......................................................................
NOX (kt) .........................................................................
NOX (kt) .........................................................................
Hg (t) ..............................................................................
Hg (t) ..............................................................................
................................
low .........................
high ........................
low .........................
high ........................
10.3
1
17
0.0
0.1
25.1
2
39
0.0
0.3
MMt = million metric tons.
kt = thousand metric tons.
t = metric tons.
NOTE: The derivation for the emission ranges are described below.
The estimated cumulative CO2, NOX,
and Hg emissions reductions for the
proposed amended energy conservation
standards range up to a maximum of
680 MMt for CO2, 1072 kt for NOX, and
9.1 metric tons for Hg for GSFL and 119
MMt for CO2, 193 kt for NOX and 1.7
tons for Hg for IRL over the period from
2012 to 2042. In the Environmental
Assessment (see the Environmental
Assessment report of the TSD), DOE
reports estimated annual changes in
CO2, NOX, and Hg emissions
attributable to each TSL. As discussion
in section V.J of this NOPR, DOE does
not report SO2 emissions reduction from
power plants because reductions from
an energy conservation standard would
not affect the overall level of SO2
emissions in the United States due to
the emissions caps for SO2.
The NEMS–BT modeling assumed
that NOX would be subject to the Clean
Air Interstate Rule (CAIR) issued by the
U.S. Environmental Protection Agency
on March 10, 2005.74 70 FR 25162 (May
12, 2005). On July 11, 2008, the U.S.
Court of Appeals for the District of
Columbia Circuit (DC Circuit) issued its
decision in North Carolina v.
Environmental Protection Agency,75 in
which the court vacated the CAIR. If left
in place, the CAIR would have
permanently capped emissions of NOX
in 28 eastern States and the District of
Columbia. As with the SO2 emissions
cap, a cap on NOX emissions would
have meant that energy conservation
standards are not likely to have a
physical effect on NOX emissions in
74 On December 23, 2008, the D.C. Circuit decided
to allow CAIR to remain in effect until it is replaced
by a rule consistent with the court’s earlier opinion.
North Carolina v. EPA, No. 05–1244, 2008 WL
5335481 (DC Cir. Dec. 23, 2008). Neither the July
11, 2008 nor the December 23, 2008 decisions of the
D.C. Circuit change the standard-setting proposals
reached in this rule. See https://www.epa.gov/
cleanairinterstaterule.
75 531 F.3d 896 (D.C. Cir. 2008).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
States covered by the CAIR caps. While
the caps would have meant that
physical emissions reductions in those
States would not have resulted from the
energy conservation standards that DOE
is proposing today, the standards might
have produced an environmentalrelated economic impact in the form of
lower prices for emissions allowance
credits, if large enough. DOE notes that
the estimated total reduction in NOX
emissions, including projected
emissions or corresponding allowance
credits in States covered by the CAIR
cap was insignificant and too small to
affect allowance prices for NOX under
the CAIR.
Even though the DC Circuit vacated
the CAIR, DOE notes that the DC Circuit
left intact EPA’s 1998 NOX SIP Call rule,
which capped seasonal (summer) NOX
emissions from electric generating units
and other sources in 23 jurisdictions
and gave those jurisdictions the option
to participate in a cap and trade
program for those emissions. 63 FR
57356, 57359 (Oct. 27, 1998).76 DOE
76 In the NO SIP Call rule, EPA found that
X
sources in the District of Columbia and 22
‘‘upwind’’ States (States) were emitting NOX (an
ozone precursor) at levels that significantly
contributed to ‘‘downwind’’ States not attaining the
ozone NAAQS or at levels that interfered with
States in attainment maintaining the ozone NAAQS.
In an effort to ensure that ‘‘downwind’’ States attain
or continue to attain the ozone NAAQS, EPA
established a region-wide cap for NOX emissions
from certain large combustion sources and set a
NOX emissions budget for each State. Unlike the
cap that CAIR would have established, the NOX SIP
Call Rule’s cap only constrains seasonal (summer
time) emissions. In order to comply with the NOX
SIP Call Rule, States could elect to participate in the
NOX Budget Trading Program. Under the NOX
Budget Trading Program, each emission source is
required to have one allowance for each ton of NOX
emitted during the ozone season. States have
flexibility in how they allocate allowances through
their State Implementation Plans but States must
remain within the EPA-established budget.
Emission sources are allowed to buy, sell, and bank
NOX allowances as appropriate. It should be noted
that, on April 16, 2008, EPA determined that
PO 00000
Frm 00092
Fmt 4701
Sfmt 4702
notes that the SIP Call rule may provide
a similar, although smaller in extent,
regional cap and may limit actual
reduction in NOX emissions from
revised standards occurring in States
participating in the SIP Call rule.
However, the possibility that the SIP
Call rule may have the same effect as
CAIR is highly uncertain. Therefore,
DOE established a range of NOX
reductions due to the standards being
considered in today’s proposed rule.
DOE’s low estimate was based on the
emission rate of the cleanest new
natural gas combined-cycle power plant
available for electricity generated based
on the assumption that efficiency
standards would result in only the
cleanest available fossil-fueled
generation being displaced. DOE used
the emission rate, specified in 0.0310
kilotons (0.0341 thousand short tons) of
NOX emitted per TWh of electricity
generated, associated with an advanced
natural gas combined-cycle power plant,
as specified by NEMS–BT. To estimate
the reduction in NOX emissions, DOE
multiplied this emission rate by the
reduction in electricity generation due
to the amended energy conservation
standards considered. DOE’s high
estimate of 0.764 kilotons (0.843
thousand short tons) of NOX per TWh
was based on the use of a nationwide
NOX emission rate for all electrical
generation. Use of such an emission rate
assumes that future efficiency standards
would result in displaced electrical
generation mix that is equivalent to
today’s mix of power plants (i.e., future
power plants displaced are no cleaner
than what are being used currently to
generate electricity). In addition, under
the high estimate assumption, energy
conservation standards would have
little to no effect on the generation mix.
Georgia is no longer subject to the NOX SIP Call
rule. 73 FR 21528 (April 22, 2008).
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
Based on AEO2008 for a recent year
(2006) in which no regulatory or nonregulatory measures were in effect to
limit NOX emissions, DOE multiplied
this emission rate by the reduction in
electricity generation due to the
standards considered. DOE is
considering whether changes are needed
to its plan for addressing the issue of
NOX reduction. DOE invites public
comment on how the agency should
address this issue, including how it
might value NOX emissions for States
now that the CAIR has been vacated.77
The range in NOX emission changes
calculated under using the low- and
high-estimate scenarios are shown in
Table VI.37 and Table VI.38 by TSL.
The range of total cumulative NOX
emission reductions is from 5 to 1071 kt
for GSFL and 1 to 193 kt for IRL for the
range of TSLs considered. These
changes in NOX emissions are extremely
small, at less than 0.1 percent of the
national base-case emissions forecast by
NEMS–BT, depending on the TSL.
As noted above in section V.J, with
regard to Hg emissions, DOE is able to
report an estimate of the physical
quantity changes in these emissions
associated with an energy conservation
standard. As opposed to using the
NEMS–BT model, DOE established a
range of Hg rates to estimate the Hg
emissions that could be reduced from
standards. DOE’s low estimate was
based on the assumption that future
standards could displace electrical
generation from natural gas-fired power
plants as the cleanest possible fossilfueled generation displacement
consistent with the low end of range
established for NOX emissions, thereby
resulting in an effective emission rate of
zero. The low-end emission rate is zero
because virtually all Hg emitted from
electricity generation is from coal-fired
power plants. Based on an emission rate
of zero, no emissions would be reduced
from energy conservation standards.
DOE’s high estimate was based on the
use of a nationwide mercury emission
rate from AEO2008. Because power
plant emission rates are a function of
local regulation, scrubbers, and the
mercury content of coal, it is extremely
difficult to come up with a precise highend emission rate. Therefore, DOE
believes that the most reasonable
estimate is based on the assumption that
all displaced coal generation would
have been emitting at the average
emission rate for coal generation as
77 In anticipation of CAIR replacing the NO SIP
X
Call Rule, many States adopted sunset provisions
for their plans implementing the NOX SIP Call Rule.
The impact of the NOX SIP Call Rule on NOX
emissions will depend, in part, on whether these
implementation plans are reinstated.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
specified by AEO2008. As noted
previously, because virtually all
mercury emitted from electricity
generation is from coal-fired power
plants, DOE based the emission rate on
the tons of mercury emitted per TWh of
coal-generated electricity. Based on the
emission rate for a recent year (2006),
DOE derived a high-end emission rate of
0.023 metric tons (0.0255 short tons) per
TWh. To estimate the reduction in
mercury emissions, DOE multiplied the
emission rate by the reduction in coalgenerated electricity due to the
standards considered as determined in
the utility impact analysis. The
estimated changes in Hg emissions are
shown in Table VI.37 for both GSFL and
IRL from 2012 to 2042. The range of
total Hg emission reductions is from 0
to 9.1 tons for GSFL and 0 to 1.7 tons
for IRL for the range of TSLs considered.
These changes in Hg emissions are
extremely small, generally being less
than 0.1 percent of the national basecase emissions forecast by NEMS–BT,
depending on the TSL.
The NEMS–BT model used for today’s
rulemaking could not be used to
estimate Hg emission reductions due to
standards, as it assumed that Hg
emissions would be subject to EPA’s
Clean Air Mercury Rule 78 (CAMR),
which would have permanently capped
emissions of mercury for new and
existing coal-fired plants in all States by
2010. Similar to SO2 and NOX, DOE
assumed that under such a system,
energy conservation standards would
have resulted in no physical effect on
these emissions, but might have resulted
in an environmental-related economic
benefit in the form of a lower price for
emissions allowance credits, if large
enough. DOE estimated that the change
in the Hg emissions from energy
conservation standards would not be
large enough to influence allowance
prices under CAMR.
On February 8, 2008, the DC Circuit
issued its decision in New Jersey v.
Environmental Protection Agency,79 in
which the DC Circuit, among other
actions, vacated the CAMR referenced
above. Accordingly, DOE is considering
whether changes are needed to its plan
for addressing the issue of mercury
emissions in light of the DC Circuit’s
decision. DOE invites public comment
on addressing mercury emissions in this
rulemaking.
In today’s proposed rule, DOE is
taking into account a monetary benefit
of CO2 emission reductions associated
with this rulemaking. To put the
potential monetary benefits from
78 70
FR 28606 (May 18, 2005).
F.3d 574 (D.C. Cir. 2008).
79 517
PO 00000
Frm 00093
Fmt 4701
Sfmt 4702
17011
reduced CO2 emissions into a form that
is likely to be most useful to decisionmakers and stakeholders, DOE used the
same methods used to calculate the net
present value of consumer cost savings:
the estimated year-by-year reductions in
CO2 emissions were converted into
monetary values and these resulting
annual values were then discounted
over the life of the affected appliances
to the present using both 3 percent and
7 percent discount rates.
These estimates discussed below are
based on a previous analysis that used
a range of no benefit to an average
benefit value reported by the IPCC.80 It
is important to note that the IPCC
estimate used as the upper bound value
was derived from an estimate of the
mean value of worldwide impacts from
potential climate impacts caused by CO2
emissions, and not just the effects likely
to occur within the United States. This
previous analysis assumed that the
appropriate value should be restricted to
a representation of those costs/benefits
likely to be experienced in the United
States. DOE expects that such domestic
values would be lower than comparable
global values; however, there currently
are no consensus estimates for the U.S.
benefits likely to result from CO2
emission reductions. Because U.S.specific estimates were not available,
and DOE did not receive any additional
information that would help serve to
narrow the proposed range as a
representative range for domestic U.S.
benefits, DOE believes it is appropriate
to propose the global mean value as an
appropriate upper bound U.S. value for
purposes of the sensitivity analysis.
As already discussed in section V.J,
DOE received a comment on the March
2008 ANOPR in the present rulemaking
for estimating the value of CO2
emissions reductions. The Joint
80 During the preparation of its most recent
review of the state of climate science, the
Intergovernmental Panel on Climate Change (IPCC)
identified various estimates of the present value of
reducing carbon-dioxide emissions by one ton over
the life that these emissions would remain in the
atmosphere. The estimates reviewed by the IPCC
spanned a range of values. In the absence of a
consensus on any single estimate of the monetary
value of CO2 emissions, DOE used the estimates
identified by the study cited in Summary for
Policymakers prepared by Working Group II of the
IPCC’s Fourth Assessment Report to estimate the
potential monetary value of CO2 reductions likely
to result from standards finalized in this
rulemaking. According to IPCC, the mean social
cost of carbon (SCC) reported in studies published
in peer-reviewed journals was $43 per ton of
carbon. This translates into about $12 per ton of
carbon dioxide. The literature review (Tol 2005)
from which this mean was derived did not report
the year in which these dollars were denominated.
However, we understand this estimate was
denominated in 1995 dollars. Updating that
estimate to 2007 dollars yields a SCC of $15 per ton
of carbon dioxide.
E:\FR\FM\13APP2.SGM
13APP2
17012
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
Comment argued for assigning an
economic value to CO2 emissions.
DOE’s approach for assigning a range to
the dollars per ton of CO2 emissions
recognizes and addresses the concerns
of the Joint Comment.
The Department of Energy, together
with other Federal agencies, is currently
reviewing various methodologies for
estimating the monetary value of
reductions in CO2 and other greenhouse
gas emissions. This review will consider
the comments on this subject that are
part of the public record for this and
other rulemakings, as well as other
methodological assumptions and issues,
such as whether the appropriate values
should represent domestic U.S. or global
benefits (and costs). Given the
complexity of the many issues involved,
this review is ongoing. However,
consistent with DOE’s legal obligations,
and taking into account the uncertainty
involved with this particular issue, DOE
has included in this rulemaking the
values and analyses previously
conducted.
Given the uncertainty surrounding
estimates of the societal cost of carbon
(SCC), DOE previously concluded that
relying on any single study may be
inadvisable since its estimate of the SCC
will depend on many assumptions made
by its authors. The Working Group II’s
contribution to the Fourth Assessment
Report of the IPCC notes that:
The large ranges of SCC are due in the large
part to differences in assumptions regarding
climate sensitivity, response lags, the
treatment of risk and equity, economic and
non-economic impacts, the inclusion of
potentially catastrophic losses, and discount
rates.81
Because of this uncertainty, DOE
previously relied on Tol (2005), which
was presented in the IPCC’s Fourth
Assessment Report, and was a
comprehensive meta-analysis of
estimates for the value of SCC. As a
result, DOE previously decided to rely
on the Tol study reported by the IPCC
as the basis for its analysis.
DOE continues to believe that the
most appropriate monetary values for
consideration in the development of
efficiency standards are those drawn
from studies that attempt to estimate the
present value of the marginal economic
benefits likely to result from reducing
greenhouse gas emissions, rather than
estimates that are based on the market
value of emission allowances under
existing cap and trade programs or
estimates that are based on the cost of
reducing emissions—both of which are
largely determined by policy decisions
that set the timing and extent of
emission reductions and do not
necessarily reflect the benefit of
reductions. DOE also believes that the
studies it relies upon generally should
be studies that were the subject of a peer
review process and were published in
reputable journals.
In today’s NOPR, DOE is essentially
proposing to continue to use the range
of values based on the values presented
in Tol (2005). Additionally, DOE has
applied an annual growth rate of 2.4%
to the value of SCC, as suggested by the
IPCC Working Group II (2007, p. 822),
based on estimated increases in
damages from future emissions reported
in published studies. Because the values
in Tol (2005) were presented in 1995
dollars, DOE is assigning a range for the
SCC of $0 to $20 ($2007) per ton of CO2
emissions.
DOE is proposing to use the median
estimated social cost of CO2 as an upper
bound of the range. This value is based
on Tol (2005), which reviewed 103
estimates of the SCC from 28 published
studies, and concluded that when only
peer-reviewed studies published in
recognized journals are considered,
‘‘that climate change impacts may be
very uncertain but [it] is unlikely that
the marginal damage costs of carbon
dioxide emissions exceed $50 per ton
carbon [comparable to a 2007 value of
$20 per ton carbon dioxide when
expressed in 2007 U.S. dollars with a
2.4% growth rate].’’
In proposing a lower bound of $0 for
the estimated range, DOE’s previous
analysis agreed with the IPCC Working
Group II (2007) report that ‘‘significant
warming across the globe and the
locations of significant observed
changes in many systems consistent
with warming is very unlikely to be due
solely to natural variability of
temperatures or natural variability of the
systems’’ (pp. 9), and, thus, tentatively
concluded that a global value of zero for
reducing emissions cannot be justified.
However, DOE previously tentatively
concluded that it is reasonable to allow
for the possibility that the U.S. portion
of the global cost of carbon dioxide
emissions may be quite low. In fact,
some of the studies looked at in Tol
(2005) reported negative values for the
SCC. DOE assumed that it would be
most appropriate to use U.S. benefit
values, and not world benefit values, in
its analysis, and, further, that U.S.
domestic values will be lower than the
global values. As indicated above, DOE,
together with other Federal agencies, is
now reviewing whether this previous
analysis should be modified.
The resulting estimates of the
potential range of net present value
benefits associated with the reduction of
CO2 emissions are reflected in Table
VI.39 and Table VI.40.
TABLE VI.39—PRELIMINARY ESTIMATES OF SAVINGS FROM CO2 EMISSIONS REDUCTIONS FOR GSFL
Estimated cumulative CO2 (MMt)
emission reductions
TSL
1
2
3
4
5
.....................................................
.....................................................
.....................................................
.....................................................
.....................................................
Value of estimated CO2 emission
reductions (billion 2007$) at
7% discount rate
Value of estimated CO2 emission
reductions (billion 2007$) at
3% discount rate
85.7 to 236.4 ................................
103.5 to 233.7 ..............................
184.3 to 395.2 ..............................
239.7 to 597.7 ..............................
312.8 to 679.7 ..............................
$0
$0
$0
$0
$0
$0
$0
$0
$0
$0
to
to
to
to
to
$1.2
$1.2
$2.1
$3.5
$4.0
.....................................
.....................................
.....................................
.....................................
.....................................
to
to
to
to
to
$2.5
$2.5.
$4.3.
$6.8.
$7.7.
TABLE VI.40—PRELIMINARY ESTIMATES OF SAVINGS FROM CO2 EMISSIONS REDUCTIONS FOR IRL
TSL
Estimated cumulative CO2 (MMt)
emission reductions
Value of estimated CO2 emission
reductions (billion 2007$) at
7% discount rate
Value of estimated CO2 emission
reductions (billion 2007$) at
3% discount rate
1 .....................................................
2 .....................................................
10.3 to 17.7 ..................................
25.1 to 44.8 ..................................
$0 to $0.1 .....................................
$0 to $0.3 .....................................
$0 to $0.2.
$0 to $0.5.
81 Climate Change 2007—Impacts, Adaptation
and Vulnerability. Contribution of Working Group
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
II to the Fourth Assessment Report of the IPCC, 17.
PO 00000
Frm 00094
Fmt 4701
Sfmt 4702
Available at https://www.ipcc-wg2.org (last accessed
Aug. 7, 2008).
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
17013
TABLE VI.40—PRELIMINARY ESTIMATES OF SAVINGS FROM CO2 EMISSIONS REDUCTIONS FOR IRL—Continued
TSL
Estimated cumulative CO2 (MMt)
emission reductions
Value of estimated CO2 emission
reductions (billion 2007$) at
7% discount rate
Value of estimated CO2 emission
reductions (billion 2007$) at
3% discount rate
3 .....................................................
4 .....................................................
5 .....................................................
46.2 to 88.1 ..................................
58.6 to 114.4 ................................
79.3 to 118.8 ................................
$0 to $0.5 .....................................
$0 to $0.6 .....................................
$0 to $0.7 .....................................
$0 to $1.0.
$0 to $1.3.
$0 to $1.3.
DOE also investigated the potential
monetary impact resulting from the
impact of today’s energy conservation
standards on SO2, NOX, and Hg
emissions. As previously stated, DOE’s
initial analysis assumed the presence of
nationwide emission caps on SO2 and
Hg, and caps on NOX emissions in the
28 States covered by the CAIR caps. In
the presence of these emissions caps,
DOE concluded that no physical
reductions in power sector emissions
would likely occur; however, the lower
generation requirements associated with
energy conservation standards could
potentially put downward pressure on
the prices of emissions allowances in
cap-and-trade markets. Estimating this
effect is very difficult because of factors
such as credit banking, which can
change the trajectory of prices. DOE has
further concluded that the effect from
energy conservation standards on SO2
allowance prices is likely to be
negligible, based upon runs of the
NEMS–BT model. See Environmental
Assessment report of the TSD for further
details regarding SO2 allowance price
impacts.
As discussed earlier, with respect to
NOX, the CAIR rule had been vacated by
the courts, so projected annual NOX
allowances from NEMS–BT were no
longer relevant. In DOE’s subsequent
analysis, NOX emissions were not
controlled by a nationwide regulatory
system. For the range of NOX reduction
estimates (and Hg reduction estimates),
DOE estimated the national monetized
benefits of emissions reductions from
today’s proposed rule based on
environmental damage estimates from
the literature. Available estimates
suggest a very wide range of monetary
values for NOX emissions, ranging from
$370 per ton to $3,800 per ton of NOX
from stationary sources, measured in
2001 dollars 82 or a range of $432 per ton
to $4,441 per ton in 2007 dollars. As
discussed above, DOE is considering
how it should address the issue of NOX
reduction and corresponding monetary
valuation. DOE invites public comment
on how the agency should address this
issue.
DOE has already conducted research
for today’s NOPR and determined that
the basic science linking mercury
emissions from power plants to impacts
on humans is considered highly
uncertain. However, DOE identified two
estimates of the environmental damages
of mercury based on two estimates of
the adverse impact of childhood
exposure to methyl mercury on IQ for
American children, and subsequent loss
of lifetime economic productivity
resulting from these IQ losses. The highend estimate is based on an estimate of
the current aggregate cost of the loss of
IQ in American children that results
from exposure to mercury of U.S. power
plant origin ($1.3 billion per year in
year 2000$), which works out to $32.6
million per ton emitted per year
(2007$).83 The low-end estimate was
$664,000 per ton emitted in 2004$ or
$729,000 per ton in 2007$, which DOE
derived from a published evaluation of
mercury control using different methods
and assumptions from the first study,
but also based on the present value of
the lifetime earnings of children
exposed.84 DOE invites public comment
on how the agency should address this
issue, including how to value mercury
emissions in the absence of the CAMR.
The resulting estimates of the potential
range of the present value benefits
associated with the national reduction
of NOX and national reductions in Hg
emissions are reflected in Table VI.41
through Table VI.44.
TABLE VI.41—PRELIMINARY ESTIMATES OF SAVINGS FROM NOX EMISSIONS REDUCTIONS FOR GSFL
Estimated cumulative NOX (kt)
emission reductions
TSL
1
2
3
4
5
.....................................................
.....................................................
.....................................................
.....................................................
.....................................................
5.1 to 347.4 ..................................
6.8 to 361.1 ..................................
11.7 to 623.0 ................................
16.5 to 950.7 ................................
20.3 to 1071.6 ..............................
82 Office of Management and Budget Office of
Information and Regulatory Affairs, ‘‘2006 Report to
Congress on the Costs and Benefits of Federal
Regulations and Unfunded Mandates on State,
Local, and Tribal Entities’’ (2006).
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Value of estimated NOX emission
reductions (billion 2007$) at
7% discount rate
Value of estimated NOX emission
reductions (billion 2007$) at
3% discount rate
$0.0
$0.0
$0.0
$0.0
$0.0
$0.0 to $0.9.
$0.0 to $0.9.
$0.0 to $1.6.
$0.0 to $2.6.
$0. to $2.8.
to
to
to
to
to
$0.5
$0.5
$0.8
$1.3
$1.4
..................................
..................................
..................................
..................................
..................................
83 Trasande, L., et al., ‘‘Applying Cost Analyses to
Drive Policy that Protects Children,’’ 1076 ANN.
N.Y. ACAD. SCI. 911 (2006).
84 Ted Gayer and Robert Hahn, Designing
Environmental Policy: Lessons from the Regulation
of Mercury Emissions, Regulatory Analysis 05–01
PO 00000
Frm 00095
Fmt 4701
Sfmt 4702
(AEI-Brookings Joint Center for Regulatory Studies)
p. 31 (2004). A version of this paper was published
in the Journal of Regulatory Economics in 2006. The
estimate was derived by back-calculating the annual
benefits per ton from the net present value of
benefits reported in the study.
E:\FR\FM\13APP2.SGM
13APP2
17014
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VI.42—PRELIMINARY ESTIMATES OF SAVINGS FROM NOX EMISSIONS REDUCTIONS FOR IRL
Estimated cumulative NOX (kt)
emission reductions
TSL
1
2
3
4
5
.....................................................
.....................................................
.....................................................
.....................................................
.....................................................
0.7
1.6
3.0
3.8
4.5
to
to
to
to
to
29.0 ....................................
77.6 ....................................
140.6 ..................................
180.7 ..................................
193.1 ..................................
Value of estimated NOX emission
reductions (billion 2007$) at
7% discount rate
Value of estimated NOX emission
reductions (billion 2007$) at
3% discount rate
$0
$0
$0
$0
$0
$0
$0
$0
$0
$0
to
to
to
to
to
$0.0
$0.1
$0.2
$0.2
$0.2
.....................................
.....................................
.....................................
.....................................
.....................................
to
to
to
to
to
$0.1.
$0.2.
$0.4.
$0.5.
$0.5.
TABLE VI.43—PRELIMINARY ESTIMATES OF SAVINGS FROM HG EMISSIONS REDUCTIONS FOR GSFL
Estimated cumulative Hg (Tons)
emission reductions
TSL
1
2
3
4
5
.....................................................
.....................................................
.....................................................
.....................................................
.....................................................
0
0
0
0
0
to
to
to
to
to
4.2
3.8
6.9
7.9
9.1
.........................................
.........................................
.........................................
.........................................
.........................................
Value of estimated Hg emission
reductions (million 2007$) at
7% discount rate
$0
$0
$0
$0
$0
to
to
to
to
to
$38. .....................................
$35. .....................................
$65. .....................................
$88. .....................................
$102. ...................................
Value of estimated Hg emission
reductions (million 2007$) at
3% discount rate
$0
$0
$0
$0
$0
to
to
to
to
to
$80.
$73.
$134.
$166.
$192.
TABLE VI.44—PRELIMINARY ESTIMATES OF SAVINGS FROM HG EMISSIONS REDUCTIONS FOR IRL
Estimated cumulative Hg (tons)
emission reductions
TSL
1
2
3
4
5
.....................................................
.....................................................
.....................................................
.....................................................
.....................................................
0
0
0
0
0
to
to
to
to
to
0.2
0.6
1.3
1.7
1.7
.........................................
.........................................
.........................................
.........................................
.........................................
C. Proposed Standard
1. Overview
Under 42 U.S.C. 6295(o)(2)(A), EPCA
requires that any new or amended
energy conservation standard for any
type (or class) of covered product shall
be designed to achieve the maximum
improvement in energy efficiency that
the Secretary determines is
technologically feasible and
economically justified. In determining
whether a standard is economically
justified, the Secretary must determine
whether the benefits of the standard
exceed its burdens to the greatest extent
practicable, in light of the following
seven factors:
(1) The economic impact of the
standard on manufacturers and
consumers of the products or equipment
subject to the standard;
(2) The savings in operating costs
throughout the estimated average life of
the covered products or equipment in
the type (or class) compared to any
increase in the price, initial charges, or
maintenance expenses for the covered
products that are likely to result from
the imposition of the standard;
(3) The total projected amount of
energy (or, as applicable, water) savings
VerDate Nov<24>2008
20:42 Apr 10, 2009
Jkt 217001
Value of estimated Hg emission
reductions (million 2007$) at
7% discount rate
$0
$0
$0
$0
$0
to
to
to
to
to
$2 ........................................
$7 ........................................
$13 ......................................
$16 ......................................
$16 ......................................
likely to result directly from the
imposition of the standard;
(4) Any lessening of the utility or the
performance of the covered products or
equipment likely to result from the
imposition of the standard;
(5) The impact of any lessening of
competition, as determined in writing
by the Attorney General, that is likely to
result from the imposition of the
standard;
(6) The need for national energy and
water conservation; and
(7) Other factors the Secretary
considers relevant. (42 U.S.C.
6295(o)(2)(B)(i))
The new or amended standard also
must ‘‘result in significant conservation
of energy.’’ (42 U.S.C. 6295(o)(3)(B))
As discussed in section 0, DOE
established a separate set of TSLs for
GSFL and IRL. Therefore, DOE analyzed
each lamp type (GSFL or IRL) separately
while establishing the proposed
standards.
During the screening phase of this
rulemaking, DOE eliminated the
maximum technologically feasible
levels for GSFL that would incorporate
the use of a higher-efficiency gas fill
composition than what is currently
available on the market today. DOE’s
research had indicated that further
PO 00000
Frm 00096
Fmt 4701
Sfmt 4702
Value of estimated Hg emission
reductions (million 2007$) at
3% discount rate
$0
$0
$0
$0
$0
to
to
to
to
to
$5.
$13.
$26.
$33.
$33.
usage of heavier gas fills to increase
lamp efficacy beyond GSFL TSL5 would
likely result in decreased utility of the
product. Thus, DOE screened out the
maximum technologically feasible
levels that would be based on these
reduced-utility GSFLs. TSL5 represents
the most efficient level analyzed for
GSFL.
For IRL, in the engineering analysis,
DOE eliminated the maximum
technologically feasible level that would
require the use of a silver reflector,
which DOE understands to be a
proprietary technology. DOE does not
believe there are any alternate
technology pathways to this efficacy
level. Therefore, TSL5 represents the
most efficient level analyzed for IRL
which does not require installation of
the proprietary silver reflector. See
sections IV.B.2 and VI.A.2 of this notice
for more information on maximum
technologically feasible levels and other
efficacy levels DOE analyzed.
DOE then considered the impacts of
standards at each trial standard level,
beginning with the most efficient level,
to determine whether the given level
was economically justified. DOE then
considered less efficient levels until it
reached the highest level that is
technologically feasible and
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
economically justified and saves a
significant amount of energy.
DOE discusses the benefits and/or
burdens of each trial standard level in
the following sections. DOE bases its
discussion on quantitative analytical
results for each trial standard level
(presented in section VI) such as
national energy savings, net present
value (discounted at 7 percent and 3
percent), emissions reductions, industry
net present value, life-cycle cost, and
consumers installed price increases. In
addition to providing a summary of
results, DOE discusses below the lifecycle cost and consumer installed price
increase results for each product class
and baseline where appropriate. Beyond
the quantitative results, DOE also
considers other burdens and benefits
that affect economic justification,
including how impacts on competition,
supply constraints, and lamp input
prices may affect the economic results
presented.
2. General Service Fluorescent Lamps
Conclusion
a. Trial Standard Level 5
For GSFL, DOE first considered the
most efficient level, TSL5, which would
save an estimated total of 5.8 to 13.2
quads of energy through 2042—a
significant amount of energy. For the
Nation as a whole, TSL5 would have a
net savings of $8.5 billion to $24.5
billion at a 7-percent discount rate. The
emissions reductions at TSL5 are
estimated at 313 to 680 MMt of CO2, 20
to 1072 kt of NOX,, up to 9 metric tons
of Hg. Total generating capacity in 2042
is estimated to decrease compared to the
reference case by 1.8 to 5.4 GW under
TSL5.
The impacts on manufacturers would
be very significant, because TSL5 would
commoditize high-efficacy lamps and
require a complete conversion of all T12
4-foot MBP, 8-foot SP slimline, and 8foot RDC HO lines to T8 lines, requiring
a capital investment of $181.5 million.
The projected change in industry value
ranges from a decrease of $263 million
to an increase of $13 million. The extent
of the industry impacts is driven
primarily by the ability to maintain
current gross margins as efficient
products become commoditized.
Currently, manufacturers obtain higher
margins for more-efficient products so
to avoid the higher end of the
anticipated impacts, they must find new
ways to differentiate GSFL to maintain
full product lines. At TSL5, DOE
recognizes the risk of very large negative
impacts if the high end of the range of
impacts is reached, resulting in a net
loss of 46 percent in INPV.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
At TSL5, DOE projects that most
GSFL consumers would experience lifecycle cost savings. The following
discussion outlines specific impacts on
the separate product classes and
baseline lamps.
Table VI.5 presents the findings of an
LCC analysis on various three-lamp, 4foot medium bipin GSFL systems
operating in the commercial sector.
Regardless of the baseline lamp
currently employed, consumers have
available lamp designs which result in
positive LCC savings at TSL5. At this
standard level, users of 40W or 34W 4foot MBP T12 baseline lamps installed
on a magnetic ballast who need to
replace their lamp would incur the cost
of a lamp and ballast replacement
($63.51 to $71.19) because no T12 lamp
currently meets the efficacy
requirements of TSL5. Comparing this
cost of lamp-and-ballast replacements to
the cost of only baseline lamp
replacements ($11.22 to $13.96) results
in installed price increases of $50.87 to
$57.23. These ranges in prices depend
on the specific baseline lamps
previously owned by consumers and the
specific combinations of lamps and
ballasts they select in the standards
case. However, over the life of the lamp,
these consumers would save $15.13 to
$25.26.
Table VI.6 presents LCC results for a
two-lamp 4-foot MBP system operating
in the residential sector under average
operating hours. The results are
presented for a system operating 40W
T12 lamps with a magnetic ballast, as
this configuration is typical of the
installed base of residential GSFL
systems. As discussed in section V.D,
DOE believes that the vast majority of
lamps sold in the residential market are
sold with new ballasts or luminaires. At
TSL5, residential consumers are
expected to purchase T8 lamps with
electronic ballasts in lieu of the T12
lamps with magnetic ballasts that they
would purchase absent standards. These
consumers would see LCC savings of
$17.72 to $19.66. DOE recognizes that
not all residential GSFL lamps would be
sold in conjunction with a new ballast
or luminaire in the base case. In
particular, consumers with higher
operating hours may need to replace
their lamp on an existing system.
However, at TSL5, there are no
standards-compliant T12 replacement
lamps available. As seen in Table VI.7,
the consumer economics of retrofitting a
typical high-use residential 4-foot MBP
system are negative, with life-cycle cost
savings of ¥$3.50 to ¥$4.13.
With regard to 4-foot MBP consumer
subgroups, all consumer subgroups
analyzed achieve similar LCC savings to
PO 00000
Frm 00097
Fmt 4701
Sfmt 4702
17015
the average consumer with the
exception of commercial consumers
who own 40W or 34W 4-foot MBP T12
lamps installed on electronic ballasts.
These consumers, upon lamp failure,
are forced to retrofit their existing
ballasts, resulting in negative LCC
savings of ¥$11.53 to ¥$5.53 (seen in
Table VI.21). Overall, based on the NIA
model, DOE estimates that at TSL5 in
2012, approximately 2 percent of 4-foot
MBP shipments result in negative LCC
savings, and 9 percent of shipments are
associated with the high installed price
increases due to forced retrofits.
Table VI.10 presents the findings of
an LCC analysis on various two-lamp, 8foot SP slimline GSFL systems operating
in the commercial sector. Except for
consumers who purchase reducedwattage 60W T12 lamps absent
standards (and experience a lamp
failure), all other consumers have
available lamp designs that result in
positive LCC savings at TSL5. At this
standard level, users of 75W or 60W 8foot SP slimline T12 baseline lamps
installed on a magnetic ballast who
need to replace their lamp would incur
the cost of a lamp and ballast
replacement ($93.79 to $95.12) because
no T12 lamp currently meets the
efficacy requirements of TSL5.
Comparing the cost of a lamp-andballast replacement to the cost of only
baseline lamp replacement ($11.33 to
$16.16) results in an installed price
increase of $78.96 to $83.99. In
addition, users of 60W T12 lamps who
need to replace their lamp experience
negative LCC savings of ¥$14.02 to
¥$12.26. On the other hand, over the
life of the lamp, users of 75W T12 lamps
who require a lamp replacement would
save $11.45.
With regard to 8-foot SP slimline
consumer subgroups, all consumer
subgroups analyzed achieve similar LCC
savings to the average consumer with
the exception of consumers of T12
lamps operating in religious institutions
or users of T12 lamps installed on
electronic ballasts. These consumers,
upon lamp failure, are forced to retrofit
their existing ballasts, resulting in
negative LCC savings. In particular, as
seen in Table VI.15, these consumers in
institutions of religious worship (with
low operating hours) experience
increases in life-cycle costs of $6.68 to
$28.95. As seen in Table VI.23,
consumers with T12 lamps installed on
electronic ballasts experience increases
in life-cycle costs of $14.18 to $31.86.
Overall, based on the NIA model, DOE
estimates that at TSL5 in 2012,
approximately 24 percent of 8-foot SP
slimline shipments would result in
negative LCC savings, and 65 percent of
E:\FR\FM\13APP2.SGM
13APP2
17016
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
shipments would be associated with the
high installed price increases due to
forced retrofits.
Table VI.11 presents the findings of
an LCC analysis on various two-lamp, 8foot RDC HO GSFL systems operating in
the industrial sector. With the exception
to consumers who purchase reducedwattage 95W T12 lamps absent
standards (and purchase a lamp in
response to a lamp failure), all other
consumers have available lamp designs
that result in positive LCC savings at
TSL5. At this standard level, users of
110W or 95W 8-foot RDC HO T12
baseline lamps installed on a magnetic
ballast who need to replace their lamp
would incur the cost of a lamp and
ballast replacement ($126.49), because
no T12 lamp currently meets the
efficacy requirements of TSL5.
Comparing the cost of a lamp-andballast replacement to the cost of only
baseline lamp replacement ($13.92 to
$19.74) results in an installed price
increase of $106.75 to $112.57. In
addition, users of 95W T12 lamps who
need to replace their lamp experience
negative LCC savings of ¥$12.70. On
the other hand, over the life of the lamp,
users of 110W T12 lamps who require
a lamp replacement would save $5.13.
With regard to 8-foot RDC HO
consumer subgroups, all consumer
subgroups analyzed achieve similar LCC
savings to the average consumer except
consumers who own T12 lamps
installed on electronic ballasts. These
consumers, upon lamp failure, are
forced to retrofit their existing ballasts,
resulting in negative LCC savings of
¥$10.09 to ¥$23.07 (seen in Table
VI.24). Overall, based on the NIA model,
DOE estimates that at TSL5 in 2012,
approximately 33 percent of 8-foot RDC
HO shipments would result in negative
LCC savings, and 86 percent of
shipments would be associated with the
high installed price increases due to
forced retrofits.
Table VI.8 and Table VI.9 present the
LCC analyses on two-lamp 4-foot
MiniBP T5 standard-output and highoutput systems, respectively. The
standard-output system is modeled as
operating in the commercial sector, and
the high-output system is modeled as
operating in the industrial sector. The
baseline lamps for these systems are the
model 28W and 54W halophosphor
lamps, as discussed in section V.C.3.a.
At TSL5 (EL2 for standard output T5
lamps), all consumers of standard
output lamps have available lamp
designs which result in positive LCC
savings of $1.22 (for lamp replacement)
and $45.27 to $47.03 (for new
construction or renovation). At TSL5
(EL1 for high output T5 lamps),
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
consumers of high-output lamps who
need only a lamp replacement would
experience negative LCC savings of
¥$3.42. However, purchasing a T5
high-output system for new
construction or renovation would result
in positive LCC savings of $55.60 to
$56.60.
After carefully considering the
analysis and weighing the benefits and
burdens of TSL5, the Secretary has
reached the following initial conclusion:
At TSL 5, the benefits of energy savings,
emissions reductions (both in physical
reductions and the monetized value of
those reductions), and the positive net
economic savings to the Nation (over 30
years) would be outweighed by the
economic burden on some consumers
(as indicated by the large increase in
total installed cost) and the potentially
large reduction in INPV for
manufacturers resulting from large
conversion costs and reduced gross
margins. Specifically, consumers who
operate a 4-foot MBP, 8-foot SP slimline,
or 8-foot RDC HO T12 ballast prior to
2012 would be forced to retrofit their
system upon lamp failure, incurring an
initial cost six to thirteen times that of
a simple lamp replacement.
Additionally, consumers who installed
T12 electronic ballasts before 2012
would bear the large increases in first
cost without benefiting from LCC
savings. Consequently, the Secretary has
tentatively concluded that trial standard
level 5 is not economically justified.
b. Trial Standard Level 4
Next, DOE considered TSL 4, which
would save an estimated total of 4.5 to
11.6 quads of energy through 2042, a
significant amount of energy. For the
Nation as a whole, TSL4 would have a
net savings of $8.9 billion to $23.4
billion at a 7-percent discount rate. The
emissions reductions at TSL4 are
estimated at 240 to 598 MMt of CO2, 17
to 951 kt of NOX, and up to 8 metric
tons of Hg. Total generating capacity in
2042 is estimated to decrease compared
to the reference case by 1.3 to 4.3 GW
under TSL4.
Similar to TSL5, the impacts on
manufacturers would be very significant
because TSL4 also would commoditize
most high-efficacy lamps and require a
complete conversion of all T12 4-foot
MBP, 8-foot SP slimline, and 8-foot RDC
HO lines to T8 lines, a capital
investment of $181.5 million. The
projected change in industry value
ranges from a decrease of $195 million
to a decrease of $9 million. At TSL4,
DOE recognizes the risk of very large
negative impacts if the high end of the
range of impacts is reached, resulting in
a net loss of 34 percent in INPV.
PO 00000
Frm 00098
Fmt 4701
Sfmt 4702
As seen in Table VI.5 through Table
VI.11, at TSL4, DOE projects that 4-foot
MBP, 8-foot SP slimline, and 8-foot RDC
HO consumers would experience
similar life-cycle cost savings and
increases as they would experience at
TSL5. Like TSL5, consumers who own
T12 ballasts prior to 2012 at TSL4
would likely experience negative
economic impacts, either through lifecycle cost increases or by large increases
in total installed cost. For 4-foot MiniBP
T5 standard-output lamps, TSL4 would
require these lamps to meet EL1,
resulting in positive LCC savings of
$1.22 for lamp replacement and $42.84
for new construction or renovation (seen
in Table VI.8). For 4-foot MiniBP T5
high-output lamps, TSL4 would require
the same efficacy level (EL1) as TSL5,
resulting in identical life-cycle cost
impacts.
After carefully considering the
analysis and weighing the benefits and
burdens of TSL4, the Secretary has
reached the following initial conclusion:
At TSL4, the benefits of energy savings,
emissions reductions (both in physical
reductions and the monetized value of
those reductions), and the positive net
economic savings to the Nation (over 30
years) would be outweighed by the
economic burden on some consumers
(as indicated by the large increase in
total installed cost) and the potentially
large reduction in INPV for
manufacturers. Specifically, consumers
who operate a 4-foot MBP, 8-foot SP
slimline, or 8-foot RDC HO T12 ballast
prior to 2012 would be forced to retrofit
their system upon lamp failure,
incurring an initial cost six to thirteen
times that of a simple lamp
replacement. Additionally, consumers
who installed T12 electronic ballasts
before 2012 would bear the large
increases in first cost without benefiting
from LCC savings. Consequently, the
Secretary has tentatively concluded that
trial standard level 4 is not
economically justified.
c. Trial Standard Level 3
Next, DOE considered TSL3, which
would save an estimated total of 3.2 to
7.3 quads of energy through 2042, a
significant amount of energy. For the
Nation as a whole, TSL3 would have a
net savings of $3.2 billion to $11.1
billion at a 7-percent discount rate. The
emissions reductions at TSL3 are
estimated at 184 to 395 MMt of CO2, 12
to 623 kt of NOX, and up to 7 metric
tons of Hg. Total generating capacity in
2042 would be estimated to decrease
compared to the reference case by 1100
to 3400 megawatts under TSL3.
As opposed to TSL4 and TSL5, TSL3
does not eliminate all T12 lamps from
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
the market. The impacts on
manufacturers are less significant
because TSL3 does not require a
complete conversion of all T12 4-foot
MBP, 8-foot SP slimline, and 8-foot RDC
HO lines to T8 lines. Instead, the
required capital investments of $104.5
million are to account for the likely
accelerated consumer migration toward
T8 lamps. The projected change in
industry value ranges from a decrease of
$139 million to an increase of $71
million. The upper range of these
impacts results from the reduced
efficacy range of the product line and
the corresponding reduction in gross
margins. Compared with TSL 4 and TSL
5, TSL 3 maintains a broader product
line and, thus, provides manufacturers
with a greater opportunity to
differentiate lamp offerings.
At TSL3, DOE projects that most
GSFL consumers would experience lifecycle cost savings. Because the
minimum efficacy levels for the T5
product classes are the same for TSL3 as
they are for TSL4, the life-cycle cost
impacts on these consumers are
identical as well. However, for the other
GSFL product classes, the consumer
economic impacts do differ at TSL3
from TSL4 and TSL5. Because T12
lamps are still available at this level, all
consumers have viable lamp
replacement options without needing to
retrofit their ballasts. As a result, initial
costs for 4-foot MBP, 8-foot SP slimline,
or 8-foot RDC HO T12 lamp
replacements are significantly lower
than initial costs required at TSL4 and
TSL5 when consumers must purchase a
new lamp and new ballast with
standards. For example, for 4-foot MBP
lamps, installed costs at TSL3 may
increase by $13.91 over a baseline lamp
cost of $11.22 in the commercial sector
or by $8.48 over the baseline lamp cost
of $3.98 in the residential sector.
Although incremental total installed
costs are considerably reduced in
comparison to TSL4 and TSL5, some
consumers would still experience
negative life-cycle cost savings at TSL3.
These are many of the same consumers
that would have negative savings at
TSL4 and TSL5. Residential consumers
who own T12 ballasts prior to 2012
would experience negative LCC savings
when replacing only their lamps
(approximately 2 percent of 4-foot MBP
shipments in 2012). Consumers who,
absent standards, replace reducedwattage T12 lamps on 8-foot SP slimline
systems (24 percent of 8-foot SP
slimline shipments in 2012) experience
net life-cycle cost increases.
Approximately 33 percent of 8-foot RDC
HO shipments in 2012 (those consumers
who replace reduced-wattage T12
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
lamps) result in negative LCC savings.
As seen in section VI.B.1.a.i, for GSFL,
often higher efficacy level lamps result
in higher (or less negative) life-cycle
cost savings. At TSL3, consumers have
the option of purchasing these higherefficacy lamps, and, therefore, can
achieve similar life-cycle cost savings as
at TSL4 and TSL5.
After considering the analysis and the
benefits and burdens of trial standard
level 3, the Secretary has reached the
following tentative conclusion: Trial
standard level 3 offers the maximum
improvement in energy efficiency that is
technologically feasible and
economically justified, and will result
in significant conservation of energy.
The Secretary has reached the initial
conclusion that the benefits of energy
savings, emissions reductions (both in
physical reductions and the monetized
value of those reductions), and the
positive net economic savings to the
Nation would outweigh the economic
burden on some consumers (as
indicated by negative life-cycle cost
savings) and the potentially large
reduction in INPV for manufacturers.
TSL 3 offers almost all consumers the
choice to select lamp and ballast
systems that will reduce their life-cycle
costs but does not force them to incur
the increased first costs of a new ballast
if they elect not to do so. Therefore,
DOE today proposes to adopt the energy
conservation standards for GSFL at trial
standard level 3.
DOE will seriously consider adopting
a more stringent standard level in the
final rule that would eliminate T12
lamps, as described in discussions
regarding TSL4 and TSL5. An example
may be for DOE to adopt a more
stringent standard level in the final rule
that, similar to TSL4 and TSL5, would
eliminate T12 lamps, but allow an
extended lead time before compliance
would be required. A second example
may be for DOE to adopt a more
stringent standard level, while
continuing to allow the sale of specially
packaged or labeled T12 lamps in the
residential sector only. DOE seeks
comment on these or other possible
alternative scenarios.
3. Incandescent Reflector Lamps
Conclusion
a. Trial Standard Level 5
For IRL, DOE first considered the
most efficient level, TSL5, which would
save an estimated total of 1.5 to 2.6
quads of energy through 2042—a
significant amount of energy. For the
Nation as a whole, TSL5 would have a
net savings of $4.3 billion to $7.5 billion
at a 7-percent discount rate. The
PO 00000
Frm 00099
Fmt 4701
Sfmt 4702
17017
emissions reductions at TSL5 are
estimated at 79 to 119 MMt of CO2, 5 to
193 kt of NOX, and up to 2 metric tons
of Hg. Total generating capacity in 2042
is estimated to decrease compared to the
reference case by 40 to 500 MW under
TSL5. As seen in Table VI.12, regardless
of the baseline lamp purchased absent
standards, consumers have available
lamp designs which result in positive
LCC savings, ranging from $1.49 to
$9.41, at TSL5. The higher savings
result from consumers who purchase
lamps with larger lumen packages,
while the lower savings result from
consumers who purchase lamps with
smaller lumen packages.
The projected change in industry
value would range from a decrease of
$82 million to $103 million, or a net
loss of 31 to 50 percent in INPV. The
range in impacts is attributed in part to
uncertainty concerning the future share
of emerging technologies in the IRL
market, as well as the expected
migration to R–CFL and exempted IRL
technologies under standards.
DOE based TSL5 on commerciallyavailable IRL which employ a silver
reflector, an improved IR coating, and a
filament design that results in a lifetime
of 4,200 hours. To DOE’s knowledge,
only one manufacturer currently sells
products that meet TSL5. In addition, it
is DOE’s understanding that the silver
reflector is a proprietary technology that
all manufacturers may not be able to
employ. However, DOE considered
TSL5 in its analysis because it believes
that there are alternate pathways to
achieve this level. A combination of
redesigning the filament to achieve
higher-temperature operation (and thus
reducing lifetime to 3,000 hours),
employing other non-proprietary highefficiency reflectors, or applying higherefficiency IR coatings has the potential
to result in an IRL that meets an
equivalent efficacy level. However, to
DOE’s knowledge, no prototype IRL
exists that meets this efficacy level and
does not use proprietary technology.
Therefore, DOE is uncertain as to
whether there are barriers to
implementing these alternate pathways.
In addition, DOE is uncertain of the
manufacturer costs associated with
producing such an IRL. As documented
in appendix 5D of the TSD, DOE
received manufacturer cost estimates
from an IR coating manufacturer. Based
on these cost estimates, DOE estimated
that a medium-range end-user price for
PAR 38 IRL that meet TSL5 and do not
employ the proprietary silverized
reflector would be $7.91. This price,
when compared to the end-user price of
the commercially-available PAR38 IRL
that meet TSL5 and use the silverized
E:\FR\FM\13APP2.SGM
13APP2
17018
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
reflector ($8.03), would appear to be
cost-competitive. However, DOE
requires verification of these cost
estimates before proposing a standard
that would require this higher-efficiency
IR coating technology. If it is
significantly more costly for some
manufacturers to meet this level than
others, it is likely to cause a lessening
of competition and distortions in the
marketplace.
After carefully considering the
analysis and weighing the benefits and
burdens of TSL5, the Secretary has
reached the following initial conclusion:
At TSL5, the benefits of energy savings,
emissions reductions (both in physical
reductions and the monetized value of
those reductions), the positive net
economic savings to the Nation (over 30
years) would be outweighed by the large
capital conversion costs that could
result in a reduction in INPV for
manufacturers and possible lessening of
competition. Consequently, the
Secretary has tentatively concluded that
trial standard level 5 is not
economically justified.
As discussed above, DOE is not
proposing TSL5 because DOE finds that
the benefits to the Nation of TSL5 do
not outweigh the costs, and, therefore,
DOE proposes that TSL5 is not
economically justified. This proposal
reflects DOE’s tentative conclusion that
there remains too much uncertainty
regarding the ability for manufacturers
to produce lamps that meet this level.
While information is available that
suggests that there are other economical
pathways (without the use of
proprietary technology) to meet this
efficacy level, DOE believes that it must
have a higher degree of confidence that
these pathways exist and a clearer
understanding of the economic burdens
(to consumers and manufacturers) to
warrant higher standards before it
imposes such requirements. DOE is
soliciting public comments on these and
other issues, and will reconsider this
tentative conclusion during the
development of its final rule.
Specifically, DOE requests comment on
other technology pathways that may be
utilized to meet TSL5, and whether
these pathways may have any adverse
effects on consumer utility or the ability
for the product to be mass produced. In
addition, DOE requests comment on the
manufacturer costs associated with
these pathways and resulting consumer
product prices for lamps that meet this
efficacy level. Based upon the
information it receives, DOE may
consider adoption of TSL5 at the final
rule stage.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
b. Trial Standard Level 4
DOE next considered TSL4, which
would save an estimated total of 1.3 to
2.3 quads of energy through 2042—a
significant amount of energy. For the
Nation as a whole, TSL4 would have a
net savings of $3.7 billion to $6.8 billion
at a 7-percent discount rate. The
emissions reductions at TSL4 are
estimated at 59 to 114 MMt of CO2, 4
to181 kt of NOX, and up to 2 metric tons
of Hg. Total generating capacity in 2042
is estimated to decrease compared to the
reference case by 0 to 500 MW under
TSL4. As seen in Table VI.12, regardless
of the baseline lamp currently
employed, consumers have available
lamp designs which would result in
positive LCC savings, ranging from
$1.62 to $8.14, at TSL4.
To DOE’s knowledge, two of the three
major manufacturers of IRL currently
sell a full product line (across common
wattages) that meet this standard level.
In addition, it is DOE’s understanding
that the third manufacturer employs a
technology platform that, due to the
positioning of the filament in the HIR
capsule, is inherently less efficient.
Therefore, it is likely that in order to
meet TSL4, this manufacturer would
have to make considerably higher
investments than the other
manufacturers, placing it at a
competitive disadvantage. DOE projects
that change in industry value at TSL4
ranges from a decrease of $77 million to
$94 million, or net loss of 29 to 46
percent in INPV. However, compared to
each of the baselines, TSL4 showed
significant positive life-cycle cost
savings on a national average basis and
for all consumer subgroups. In addition,
TSL4 is projected to result in significant
net economic savings to the Nation.
After considering the analysis,
comments on the ANOPR, and the
benefits and burdens of trial standard
level 4, the Secretary has reached the
following tentative conclusion: Trial
standard level 4 offers the maximum
improvement in efficacy that is
technologically feasible and
economically justified, and will result
in significant conservation of energy.
The Secretary has reached the initial
conclusion that the benefits of energy
savings, emissions reductions (both in
physical reductions and the monetized
value of those reductions), the positive
net economic savings to the Nation, and
positive life-cycle cost savings would
outweigh the potentially large reduction
in INPV for manufacturers. Therefore,
DOE today proposes to adopt the energy
conservation standards for IRL at trial
standard level 4.
VII. Procedural Issues and Regulatory
Review
A. Review Under Executive Order 12866
Today’s regulatory action has been
determined to be an economically
significant regulatory action under
Executive Order 12866, ‘‘Regulatory
Planning and Review.’’ 58 FR 51735
(Oct. 4, 1993). Accordingly, this action
was subject to review under the
Executive Order by the Office of
Information and Regulatory Affairs
(OIRA) at OMB.
The Executive Order requires that
each agency identify in writing the
specific market failure or other specific
problem that it intends to address that
warrant new agency action, as well as
assess the significance of that problem,
to enable assessment of whether any
new regulation is warranted. Executive
Order 12866, § 1(b)(1).
DOE’s analysis for GSFL and IRL
explicitly accounts for the percentage of
consumers that already purchase moreefficient products and takes these
consumers into account when
determining the national energy savings
associated with various trial standard
levels. The analysis suggests that
accounting for the market value of
energy savings alone (i.e., excluding any
possible ‘‘externality’’ benefits such as
those noted below) would produce
enough benefits to yield net benefits
across a wide array of products and
circumstances. In its ANOPR, DOE
requested additional data on and
suggestions for testing the existence and
extent of potential market failures to
assess the significance of these failures
and, thus, the net benefits of regulation.
73 FR 13620, 13688 (March 13, 2008) In
particular, DOE sought to verify the
estimates of the percentage of
consumers purchasing efficient lighting
equipment and the extent to which
consumers will continue to purchase
more-efficient equipment in future
years. DOE received no such data in
response to the ANOPR but continues to
request such data in today’s proposed
rule.
DOE believes that there is a lack of
consumer information and/or
information processing capability about
energy efficiency opportunities in the
lighting market. If this is the case, DOE
would expect the efficiency for lighting
products to be randomly distributed
across key variables such as electricity
prices and usage levels. Although DOE
has identified the percentage of
consumers that already purchase moreefficient lighting products, DOE does
not correlate the consumers’ usage
pattern and electricity price with the
efficiency of the purchased product. In
PO 00000
Frm 00100
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
its ANOPR, DOE sought data on the
correlation between the efficacy of
existing lamps, usage patterns (e.g., how
many hours the product is used), and its
associated electricity price (geographic
region of the country). 73 FR 13620,
13688 (March 13, 2008) DOE received
no such data from interested parties in
response to the ANOPR but continues to
request this data in today’s proposed
rule. DOE plans to use these data to test
the extent to which purchasers of this
equipment behave as if they are
unaware of the costs associated with
their energy consumption.
DOE believes several factors
contribute to the lack of consumer
information for lighting products. In the
residential sector, consumers that base
purchases on wattage rather than lumen
output may reject higher efficacy or
energy-saving lamp designs. For
example, consumers may not recognize
that a higher efficacy, reduced-wattage
lamp fulfills the same utility as a higherwattage lamp, although both lamps may
have similar lumen outputs. For this
reason, higher-efficiency products may
be unduly rejected in the marketplace.
In the commercial and industrial
sectors, the complexity of GSFL systems
may introduce high information costs.
GSFL systems are composed of lamps
and ballasts with a multitude of varying
properties, such as lamp wattage, lumen
output, lifetime, and ballast factor.
These variables impose high
information costs which may prevent
purchasers from selecting the most costeffective GSFL system. In its ANOPR,
DOE sought comment on the potential
for the Federal ENERGY STAR program
to increase consumer knowledge of the
availability and benefits of energyefficient lamps. DOE received no data in
response to the ANOPR but continues to
request this data in today’s proposed
rule.
A related issue is the problem of
asymmetric information (one party to a
transaction has more and better
information than the other) and/or high
transactions costs (costs of gathering
information and effecting exchanges of
goods and services). In many instances,
the party responsible for the lamp
purchase may not pay to operate it. For
example, in the commercial and
industrial sectors, building owners and
developers may make purchasing
decisions about lighting fixtures that
include ballasts and lamps, but tenants
pay the utility bills. Although renters
often have the opportunity to purchase
replacement lamps, renters are severely
limited in their choices by prior fixture
and ballast selections. The separation of
fixture purchases and payment for the
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
operating costs imposes transaction
costs on the renter. If there were no
transactions costs, building developers
and owners would install the lighting
fixtures renters would choose on their
own. For example, a tenant who
knowingly faces higher utility bills from
low-efficacy lighting would be willing
to pay less in rent, and the building
owner would indirectly bear the higher
utility cost. However, this information is
not costless, and it may not be in the
interest of the renter to take the time to
develop the knowledge of the higher
operating cost of low-efficacy lighting.
Similarly, it may not be in the interest
of the building owner who installs
lighting systems to convey operating
cost information to the renter.
DOE did not receive any data that
would enable it to conduct tests of
market failure in response to the March
2008 ANOPR. DOE would not expect a
correlation between higher rents for
office space with high-efficacy lighting
systems if there were a market failure
due to asymmetric information and/or
high transactions costs. If there were
symmetric information with low
transaction costs, renters would be fully
knowledgeable about the lower
operating costs of high-efficacy lighting
systems and would compensate owners
for their reduced costs.
This proposed rulemaking is likely to
yield certain external benefits resulting
from improved energy efficiency of
GSFL and IRL that are not captured by
the users of such products. These
benefits include externalities related to
environmental protection and energy
security which are not reflected in
energy prices, such as reduced
emissions of greenhouse gases. The
emissions reductions in today’s
proposed rule are projected to be 184 to
395 MMt and 59 to 114 MMt of CO2 for
GSFL and IRL, respectively, and 12 to
623 kt, 4 to 181 kt of NOX, for GSFL and
IRL, respectively. In addition, today’s
proposed rule is projected to result in
Hg emissions reduction of up to 7
metric tons and 2 metric tons for GSFL
and IRL, respectively. DOE invites
comments on the weight that DOE
should place on these factors in
determining the maximum energy
efficacy level at which the total benefits
are likely to exceed the total burdens
resulting from an amended standard.
As previously stated, DOE generally
seeks data that might enable it to
conduct tests of market failure for
products under consideration for
standard-setting. For example, given
adequate data, there are ways to test for
the extent of market failure for
commercial GSFL. One would expect
PO 00000
Frm 00101
Fmt 4701
Sfmt 4702
17019
the owners of fluorescent lamps who
also pay for their electricity
consumption to purchase more-efficient
lamps compared to owners who do not
pay for their electricity usage. To test for
this form of market failure, DOE needs
data on energy efficiency of such units
and whether the owner of the
equipment also pays the operating costs.
DOE is also interested in other potential
tests of market failure and data that
would enable such tests.
DOE conducted a regulatory impact
analysis (RIA) and, under the Executive
Order, was subject to review by OIRA.
DOE presented to OIRA for review the
draft proposed rule and other
documents prepared for this
rulemaking, including the RIA, and has
included these documents in the
rulemaking record. They are available
for public review in the Resource Room
of the Building Technologies Program,
950 L’Enfant Plaza, SW., 6th Floor,
Washington, DC 20024, (202) 586–9127,
between 9 a.m. and 4 p.m., Monday
through Friday, except Federal holidays.
The RIA is contained in the TSD as a
separate report. The RIA consists of: (1)
A statement of the problem addressed
by this regulation, and the mandate for
government action; (2) a description and
analysis of the feasible policy
alternatives to this regulation; (3) a
quantitative comparison of the impacts
of the alternatives; and (4) the national
economic impacts of the proposed
standard.
The RIA calculates the effects of
feasible policy alternatives to energy
conservation standards for GSFL and
IRL and provides a quantitative
comparison of the impacts of the
alternatives. DOE identified the
following major policy alternatives for
achieving increased energy efficiency in
GSFL and IRL:
• No new regulatory action.
• Consumer rebates.
• Consumer tax credits.
• Manufacturer tax credits.
• Voluntary energy-efficiency targets.
• Bulk government purchases.
• Early replacement.
• The proposed energy conservation
standards.
DOE evaluated each alternative’s
ability to achieve significant energy
savings at reasonable costs (Table VII.1
and Table VII.2) and compared it to the
effectiveness of the proposed rule. DOE
analyzed these alternatives using a
series of regulatory scenarios as inputs
to the NIA spreadsheets for the two
products, which it modified to allow
inputs for voluntary measures.
E:\FR\FM\13APP2.SGM
13APP2
17020
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
TABLE VII.1—GSFL NATIONAL ENERGY SAVINGS AND NET PRESENT VALUE OF NON-REGULATORY ALTERNATIVES
COMPARED TO THE PROPOSED STANDARDS
National energy
savings
(quads)
Policy alternatives 1
No New Regulatory Action ..................................................................................
Consumer Rebates ..............................................................................................
Consumer Tax Credits .........................................................................................
Manufacturer Tax Credits ....................................................................................
Voluntary Energy Efficiency Targets ...................................................................
Bulk Government Purchases ...............................................................................
Proposed Standards 2 ..........................................................................................
0
1.33–1.74
0.63–0.83
0.35–0.44
1.09–1.44
1.21–1.61
3.15–7.12
Net present value
(billion $2007)
7% Discount rate
0
1.93–2.67
1.13–1.33
0.68–0.73
1.54–2.10
1.69–2.36
3.15–10.75
3% Discount rate
0
4.72–6.58
2.47–3.17
1.49–1.64
3.83–5.19
4.23–5.82
8.73–24.87
Notes:
1 NPV discounted to 2007; Non-regulatory alternatives encourage purchases of GSFL at TSL 3.
TABLE VII.2—IRL NATIONAL ENERGY SAVINGS AND NET PRESENT VALUE OF NON-REGULATORY ALTERNATIVES
COMPARED TO THE PROPOSED STANDARDS
National energy
savings (quads)
Policy alternatives 1
No New Regulatory Action ..................................................................................
Consumer Rebates ..............................................................................................
Consumer Tax Credits .........................................................................................
Manufacturer Tax Credits ....................................................................................
Voluntary Energy Efficiency Targets ...................................................................
Bulk Government Purchases ...............................................................................
Proposed Standards ............................................................................................
Net present value (billion $2007)
7% Discount rate
0
0.52–0.69
0.32–0.42
0.16–0.21
0.26–0.45
0.04–0.24
1.25–2.21
0
1.52–1.89
0.96–1.17
0.53–0.64
0.83–1.28
0.23–0.72
3.72–6.00
3% Discount rate
0
3.19–3.97
1.97–2.44
1.05–1.28
1.65–2.59
0.32–1.33
7.68–12.45
Notes:
1 NPV discounted to 2007, Non-regulatory alternatives encourage purchases of IRL at TSL 4.
The results for each scenario are
reported at the TSLs proposed by DOE
in this rulemaking; they are TSL 3 for
GSFL and TSL 4 for IRL. For GSFL, the
range presented results from the effects
of applying the lighting expertise
scenario discussed in section V.E.4.b.
The lower end of the range represents
the Emerging Technologies, marketsegment based lighting expertise
scenario. In contrast, the upper end of
the range for GSFL represents the
Existing Technologies, high-lighting
expertise scenario. For IRL, the range of
impacts results from the two base-case
shipment scenarios analyzed in the NIA.
The lower end of the range for IRL
represents the Emerging Technologies
scenario, whereas the upper end of the
range represents the Existing
Technologies scenario.
DOE did not analyze one of the policy
alternatives (early replacement),
because, as discussed below, DOE
believes that the lifetimes of the lamps
analyzed are too short for early
replacement to result in significant
savings. In overview, of the other
alternatives that DOE examined, none
would save as much energy nor have an
NPV as high as the proposed standards.
Also, some of the alternatives would
require new enabling legislation (e.g.,
consumer or manufacturer tax credits),
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
as authority to carry out those
alternatives does not presently exist.
The following paragraphs summarize
each policy alternative. Additional
details can be found in the regulatory
impact analysis report of the TSD.
No New Regulatory Action. The case
in which DOE takes no regulatory action
regarding GSFL and IRL is the base case
(or no action) scenario. Because this is
the base case, energy savings and NPV
for GSFL and IRL are zero by definition.
In this case, between 2012 and 2042, as
determined in the NIA, energy
consumption for GSFL is expected to
range from 82.16 to 94.73 quads of
primary energy and energy consumption
for IRL is expected to range from 5.64
to 10.52 quads of primary energy.
Consumer Rebates. Consumer rebates
cover a portion of the difference in
incremental product price between
products meeting baseline efficacy
levels and those meeting higher efficacy
levels, resulting in a higher percentage
of consumers purchasing more efficient
models. For GSFL, DOE estimated the
impact of improving the simple payback
through a rebate that paid 70 percent of
the incremental product price. DOE
based the 70-percent rebate on existing
utility rebate programs for replacing a
T12 lamp with a T8 lamp or upgrading
an existing T8 lamp to a more-
PO 00000
Frm 00102
Fmt 4701
Sfmt 4702
efficacious T8 GSFL.85 DOE studied
each program and found that the
average rebate amounted to about 70
percent of the incremental product price
for GSFL. DOE assumed that the
consumer rebate policy would reduce
the incremental product price for IRL
during the analysis period by the same
percentage. DOE calculated the simple
payback period of each higher efficacy
lamp, both with and without the rebate.
Then by using the market penetration
curves discussed in section V.E.2.c,
DOE estimated percent market adoption
of a technology as a function of
technology simple payback. The
difference between the market
penetration with and without the rebate
was assumed to represent the market
share that would participate in a
consumer rebate program. For both
GSFL and IRL, DOE assumed that the
impact of this policy would be to
permanently transform the market so
that the increased market penetration
seen in the first year of the program
would be maintained throughout the
forecast period.
85 DOE averaged the rebates from utility programs
across the United States, including NSTAR, Pacific
Gas & Electric, Xcel, Idaho Power and Light, Duke
Energy, and Alliant. (See the RIA to the TSD for
additional detail.)
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
At the estimated participation rates
for GSFL, DOE calculated that consumer
rebates would provide between 1.33 and
1.74 quads of national energy savings
and an NPV between $1.93 and $2.67
billion (at a 7-percent discount rate). For
IRL, DOE calculated that consumer
rebates at the estimated participation
rates would provide between 0.52 and
0.69 quads of national energy savings
and an NPV between $1.52 and $1.89
billion (at a 7-percent discount rate).
Although DOE estimated that
consumer rebates would provide
national benefits for GSFL and IRL
products, these benefits would be
smaller than the benefits resulting from
the proposed energy conservation
standards. Thus, DOE rejected consumer
rebates as a policy alternative to energy
conservation standards.
Consumer Tax Credits. Consumer tax
credits cover a percentage of the
difference in incremental product price
between products meeting baseline
efficacy levels and those with higher
efficiencies. Consumer tax credits are
considered a viable non-regulatory
market transformation program, as the
inclusion of Federal consumer tax
credits in EPACT 2005 for various
residential appliances shows. (section
1333 of EPACT 2005; codified at 26
U.S.C. 25C) DOE assumed a consumer
tax credit equivalent to the amount
covered by rebates (i.e., 70 percent of
the difference in incremental product
price between the base case and higherefficacy products).
DOE estimated that for both lamp
types, the consumer participation rate
for tax credits would be lower than the
rate of participation in consumer
rebates. Research on tax credits has
shown that the time delay to the
consumer in receiving a reimbursement
through a tax credit, plus the added
transaction costs in tax-return
preparation, make the tax credit
incentive less effective than a rebate
received at the time of purchase. Based
on previous analyses, DOE assumed that
only 60 percent as many consumers
would take advantage of the tax credit
as would take advantage of a rebate.
DOE assumed the impact of the policy
would be to permanently transform the
market at this market penetration level.
For GSFL, at the estimated
participation rate, consumer tax credits
would provide national energy savings
between 0.63 and 0.83 quads and an
NPV between $1.13 and $1.33 billion (at
a 7-percent discount rate). At the
estimated participation rates for IRL,
consumer tax credits would provide
between 0.32 and 0.42 quads of national
energy savings and an NPV between
$0.96 and $1.17 billion (at a 7-percent
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
discount rate). DOE estimated that while
consumer tax credits would yield
national benefits for GSFL and IRL,
these benefits would be much smaller
than the benefits from the proposed
energy conservation standards. Thus,
DOE rejected consumer tax credits as a
policy alternative to energy
conservation standards.
Manufacturer Tax Credits.
Manufacturer tax credits are considered
a viable non-regulatory market
transformation program, as the
inclusion of Federal tax credits in
EPACT 2005 for manufacturers of
residential appliances shows. (section
1334 of EPACT 2005; codified at 26
U.S.C. 45M) Similar to consumer tax
credits, manufacturer tax credits would
effectively result in lower product
prices for consumers by an amount that
covered part of the incremental product
price difference between products
meeting baseline efficacy levels and
those meeting higher efficacy levels.
Because these tax credits would go to
manufacturers instead of consumers,
fewer consumers would be affected by
a manufacturer tax credit program than
by consumer tax credits.86 87 Although
consumers would benefit from price
reductions passed through to them by
manufacturers, approximately half the
consumers who would benefit from a
consumer tax credit program would be
aware of the economic benefits of moreefficient technologies included in an
appliance manufacturer tax credit
program. Therefore, DOE estimated that
the effect of a manufacturer tax credit
program would be only half of the
maximum impact of a consumer tax
credit program. For both GSFL and IRL,
DOE assumed that this policy would
permanently transform the market so
that the increased market penetration
seen in the first year of the program
would be maintained throughout the
forecast period.
At the estimated participation rates
for GSFL, DOE calculated that
manufacturer tax credits would provide
between 0.35 and 0.44 quads of national
energy savings and an NPV between
$0.68 and $0.73 billion (at a 7-percent
discount rate). For IRL, DOE estimated
national energy savings between 0.16
and 0.21 quads and an NPV between
86 Kenneth Train, Customer Decision Study:
Analysis of Residential Customer Equipment
Purchase Decisions (Prepared for Southern
California Edison by Cambridge Systematics, Pacific
Consulting Services, The Technology Applications
Group, and California Survey Research Services)
(1994).
87 Lawrence Berkeley National Laboratory, EndUse Forecasting Group, Analysis of Tax Credits for
Efficient Equipment (1997). Available at: https://
enduse.lbl.gov/Projects/TaxCredits.html (Last
accessed April 24, 2008).
PO 00000
Frm 00103
Fmt 4701
Sfmt 4702
17021
$0.53 and $0.64 billion (at a 7-percent
discount rate). DOE estimated that while
manufacturer tax credits would yield
national benefits for GSFL and IRL,
these benefits would be much smaller
than the benefits from the proposed
energy conservation standards. Thus,
DOE rejected manufacturer tax credits
as a policy alternative to energy
conservation standards.
Voluntary Energy Efficiency Targets.
DOE estimated the impact of a voluntary
energy efficiency program by reviewing
the historical and projected market
transformation performance of past and
current ENERGY STAR programs. The
Environmental Protection Agency (EPA)
introduced the Green Lights program in
January of 1991. Green Lights was a
voluntary (non-regulatory) program
tasked with a goal of reducing air
pollution by promoting energy-efficient
lighting. Companies that elected to
participate installed energy-efficient
lighting where it proved to be costeffective (as long as lighting quality was
not diminished). In return, the EPA
provided technical assistance and
public recognition. In a similar effort,
the EPA launched the ENERGY STAR
program in 1992 as a voluntary labeling
program to help consumers identify the
most energy-efficient products on the
market. In 1995, Green Lights became a
part of the ENERGY STAR program.88
In order to determine how a lighting
market would respond to a voluntary
energy program, DOE analyzed the
success of the Green Lights program in
the 1990s. One of the significant results
of the Green Lights program was
demonstrated in its initiative to
encourage consumers to purchase
higher-efficiency electronic ballasts over
less-efficient magnetic ballasts. As a
result of this initiative, electronic
ballasts began to enter the market in
increasing numbers. A study that
analyzed the impact of public programs
on fluorescent ballast shipments
concluded that of all the electronic
ballasts shipped between 1986 and
2000, 61 percent were due to this public
program.89 DOE used data from the US
Census to calculate the percent of the
market that opted to use more efficient
ballasts as a result of a voluntary
program. Based on this analysis, DOE
concluded that 20 percent of the market
would shift to more-efficient products
as a result of a voluntary energy
efficiency program. DOE assumed this
participation rate would be the same for
88 Available at: https://www.energystar.gov/
index.cfm?c=about.ab_milestones.
89 Horowitz, Marvin J., ‘‘Economic Indicators of
Market Transformation: Energy Efficient Lighting
and EPA’s Green Lights,’’ Energy Journal, Vol. 22,
No. 4, (2001) pp. 95–122.
E:\FR\FM\13APP2.SGM
13APP2
17022
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
both GSFL and IRL. DOE also assumed
that the impact of this policy would be
to permanently transform the market so
that the increased market penetration
seen in the first year of the program
would be maintained throughout the
forecast period.
For GSFL, DOE estimated that
voluntary energy efficiency targets
would provide between 1.09 and 1.44
quads of national energy savings and an
NPV between $1.54 and $2.10 billion (at
a 7-percent discount rate). For IRL, DOE
estimated national energy savings
between 0.26 and 0.45 quads and an
NPV between $0.83 and $1.28 billion (at
a 7-percent discount rate). DOE
estimated that while voluntary energyefficiency targets would yield national
benefits for GSFL and IRL, these
benefits would be much smaller than
the benefits from the proposed energy
conservation standards. Thus, DOE
rejected voluntary energy efficiency
targets as a policy alternative to energy
conservation standards.
Early Replacement. The early
replacement policy alternative envisions
a program to replace old, inefficient
units with models meeting efficacy
levels higher than baseline equipment.
DOE did not model this alternative
because the lifetimes of GSFL and IRL
are very short (on the order of 1 to 5
years), so the savings would not be very
great. Early replacement policies are
generally beneficial for products with
long lifetimes (e.g., washers and dryers,
furnaces) and that represent a
significant upfront investment, neither
of which apply to GSFL and IRL.
Bulk Government Purchases. Under
this policy alternative, the government
sector would be encouraged to shift its
purchases to products that meet the
target efficacy levels. DOE assumed that
Federal, State, and local government
agencies would administer such a
program. DOE modeled this program by
assuming an increase in the installation
of equipment meeting higher efficacy
levels for those locations where
government agencies purchase or
influence the purchase of appliances.
Similar to previous analysis, DOE
used floor space data from CBECS 2003
to derive the proportion of governmentowned floor space to total commercial
floor space, which is 21.4 percent. DOE
assumed that the portion of governmentowned floor space is proportional to the
portion of government lamp purchases.
DOE then added a 1.4 percent marketpull impact to arrive at a conservative
22.8 percent market penetration rate.90
B. Review Under the Regulatory
Flexibility Act
The Regulatory Flexibility Act (5
U.S.C. 601 et seq.) requires preparation
of an initial regulatory flexibility
analysis (IRFA) for any rule that by law
must be proposed for public comment,
unless the agency certifies that the rule,
if promulgated, will not have a
significant economic impact on a
substantial number of small entities. As
required by Executive Order 13272,
Proper Consideration of Small Entities
in Agency Rulemaking, 67 FR 53461
(August 16, 2002), DOE published
procedures and policies on February 19,
2003, to ensure that the potential
impacts of its rules on small entities are
properly considered during the
rulemaking process. 68 FR 7990. DOE
has made its procedures and policies
available on the Office of the General
Counsel’s Web site at https://
www.gc.doe.gov.
DOE reviewed today’s proposed rule
under the provisions of the Regulatory
Flexibility Act and the procedures and
90 U.S. Department of Energy, Regulatory Impact
Analysis: Energy Conservation Standards for
Consumer Products, Covering: Fluorescent Lamp
Ballasts (Oct. 1999). Available at: https://
www1.eere.energy.gov/buildings/appliance_
standards/residential/pdfs/regulatory_impact.pdf.
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
Bulk government purchases will not
affect the residential market as DOE
believes that most government-owned
buildings are in the commercial sector.
DOE assumed that the impact of this
policy would be to permanently
transform the market so that the
increased market penetration seen in the
first year of the program would be
maintained throughout the forecast
period.
At the above estimated participation
rates, the bulk government purchases
scenario would provide between 1.21
and 1.61 quads of national energy
savings and an NPV between $1.69 and
$2.36 billion (at a 7-percent discount
rate) for GSFL, and between 0.04 and
0.24 quads of national energy savings
and an NPV between $0.23 and $0.72
billion (at a 7-percent discount rate) for
IRL. DOE estimated that while bulk
government purchases would yield
national benefits for GSFL and IRL,
these benefits would be much smaller
than the benefits from the proposed
energy conservation standards. Thus,
DOE rejected voluntary energy
efficiency targets as a policy alternative
to energy conservation standards.
Energy Conservation Standards. As
indicated in the paragraphs above, none
of the alternatives DOE examined would
save as much energy as the proposed
energy conservation standards.
Therefore, DOE proposes to adopt the
efficacy levels listed in section VI.C
PO 00000
Frm 00104
Fmt 4701
Sfmt 4702
policies published on February 19,
2003. 68 FR 7990. A regulatory
flexibility analysis examines the impact
of the rule on small entities and
considers alternative ways of reducing
negative impacts. DOE identified
producers of all products covered by
this rulemaking which have
manufacturing facilities located within
the United States. DOE then looked at
publicly-available data and contacted
manufacturers, as necessary, to
determine if they meet the Small
Business Administration (SBA)
definition of a small manufacturing
facility.
In the context of this rulemaking,
‘‘small businesses,’’ as defined by the
SBA, for the GSFL and IRL
manufacturing industries, are
manufacturing enterprises with 1,000
employees or fewer. DOE used the small
business size standards published on
March 11, 2008, as amended, by the
SBA to determine whether any small
entities would be required to comply
with the rule. 61 FR 3286 (codified at 13
CFR part 121). The size standards are
listed by North American Industry
Classification System (NAICS) code and
industry description. GSFL and IRL
manufacturing is classified under
NAICS 335110, ‘‘Electric Lamp Bulb
and Part Manufacturing,’’ which sets a
threshold of 1,000 employees or less for
an entity in this category to be
considered a small business.
In overview, the GSFL and IRL
industries include both domestic and
international manufacturers. The
majority of covered GSFL and IRL are
manufactured by three large companies,
with a small percentage of the market
being manufactured by either large or
small companies that are primarily
specialized in lamps not covered by this
rulemaking. Prior to issuing this notice
of proposed rulemaking, DOE
interviewed one small business affected
by the rulemaking. DOE also obtained
information about small business
impacts while interviewing
manufacturers that exceeded the small
business size threshold of 1,000
employees.
To better assess the potential impacts
of this rulemaking on small entities,
DOE proceeded to conduct a more
focused inquiry, as explained below.
During its market survey, DOE created
a list of every company that
manufactures covered and non-covered
GSFL and IRL for sale in the United
States. DOE also asked stakeholders and
industry representatives if they were
aware of any other small manufacturers.
DOE then reviewed publicly-available
data and contacted companies on its
list, as necessary, to determine whether
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
they met the SBA’s definition of a small
business manufacturer in the GSFL or
IRL industries. In total, DOE contacted
57 companies that could potentially be
small businesses. During initial review
of the 57 companies in its list, DOE
either contacted or researched each
company to determine if it sold covered
GSFL and IRL. Based on its research,
DOE screened out companies that did
not offer lamps covered by this
rulemaking. Consequently, DOE
estimated that only 12 out of 57
companies listed were potentially small
business manufacturers of covered
products. DOE contacted these potential
small business manufacturers to request
an interview about the possible impacts
on small business manufacturers. Of the
12 potential small business
manufacturers, four agreed to be
interviewed. Based on its initial
screening and subsequent interviews,
DOE identified only one company as a
small business manufacturer based on
SBA’s definition of a small business
manufacturer for this industry. The
small business manufacturer that DOE
identified only produces covered GSFL
products.
DOE found that the small
manufacturer of covered GSFL shared
some of the same concerns about energy
conservation standards as large
manufacturers. DOE summarized the
key issues in section V.G.4.a of today’s
notice. However, the small
manufacturer was less concerned about
the potential of standards to severely
harm its business. Because the small
manufacturer is more focused on
specialty products not covered by this
rulemaking, covered GSFL represents a
smaller portion of its revenue and
product portfolio. In addition, this
manufacturer stated that it is possible to
pass along cost increases to consumers,
thereby limiting margin impacts due to
energy conservation standards.
DOE could not use the GSFL GRIM to
model the impacts of energy
conservation standards on the small
business manufacturer of covered GSFL.
The GSFL GRIM models the impacts on
GSFL manufacturers if concerns about
margin pressure and significant capital
investments necessitated by standards
are realized. The small manufacturer
did not share these concerns, and,
therefore, the GRIM model would not be
representative of the identified small
business manufacturer. Like large
manufacturers, the small business
manufacturer stated that more-efficient
products earn a premium; however,
unlike larger manufacturers, the small
manufacturer stated that it could pass
costs along to its customers. Since the
GSFL GRIM models the financial impact
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
of the standards commoditizing
premium products, it is not
representative of the small business
manufacturer because the small
business manufacturer did not share
these concerns. Because of its focus on
specialized products, the small
manufacturer was more concerned
about being able to offer the products to
their customers than the impact on its
bottom line. For further information
about the scenarios modeled in the
GRIM, see section VI.B.2.a of today’s
notice and chapter 13 of the TSD.
DOE seeks further comment on how
small businesses could be impacted by
standards on GSFL and IRL.
DOE reviewed the standard levels
considered in today’s notice of proposed
rulemaking under the provisions of the
Regulatory Flexibility Act and the
procedures and policies published on
February 19, 2003. On the basis of the
foregoing, DOE certifies that this
proposed rule, if promulgated, would
not have a significant economic impact
on a substantial number of small
entities. Accordingly, DOE has not
prepared a regulatory flexibility analysis
for this rulemaking. DOE’s certification
and supporting statement of factual
basis will be provided to the Chief
Counsel for Advocacy of the Small
Business Administration pursuant to 5
U.S.C. 605(b).
C. Review Under the Paperwork
Reduction Act
Under the Paperwork Reduction Act
of 1995 (PRA) (44 U.S.C. 3501 et seq.),
a person is not required to respond to
a collection of information by a Federal
agency, including a requirement to
maintain records, unless the collection
displays a valid OMB control number.
(44 U.S.C. 3506(c)(1)(B)(iii)(V)) This
rulemaking would impose no new
information or record keeping
requirements. Accordingly, OMB
clearance is not required under the PRA.
D. Review Under the National
Environmental Policy Act
DOE has prepared a draft
environmental assessment (EA) of the
impacts of the proposed rule pursuant
to the National Environmental Policy
Act of 1969 (42 U.S.C. 4321 et seq.), the
regulations of the Council on
Environmental Quality (40 CFR Parts
1500–1508), and DOE’s regulations for
compliance with the National
Environmental Policy Act (10 CFR Part
1021). This assessment includes an
examination of the potential effects of
emission reductions likely to result from
the rule in the context of global climate
change, as well as other types of
environmental impacts. The draft EA
PO 00000
Frm 00105
Fmt 4701
Sfmt 4702
17023
has been incorporated into the TSD.
Before issuing a final rule for GSFL and
IRL, DOE will consider public
comments and, as appropriate,
determine whether to issue a finding of
no significant impact as part of a final
EA or to prepare an environmental
impact statement (EIS) for this
rulemaking.
E. Review Under Executive Order 13132
Executive Order 13132, ‘‘Federalism,’’
64 FR 43255 (August 4, 1999) imposes
certain requirements on agencies
formulating and implementing policies
or regulations that preempt State law or
that have Federalism implications.
Agencies are required to examine the
constitutional and statutory authority
supporting any action that would limit
the policymaking discretion of the
States and carefully assess the necessity
for such actions. The Executive Order
also requires agencies to have an
accountable process to ensure
meaningful and timely input by State
and local officials in the development of
regulatory policies that have Federalism
implications. On March 14, 2000, DOE
published a statement of policy
describing the intergovernmental
consultation process it will follow in the
development of such regulations. 65 FR
13735. DOE has examined today’s
proposed rule and has determined that
it would not have a substantial direct
effect on the States, on the relationship
between the national government and
the States, or on the distribution of
power and responsibilities among the
various levels of government. EPCA
governs and prescribes Federal
preemption of State regulations on
energy conservation for the products
that are the subject of today’s proposed
rule. States can petition DOE for
exemption from such preemption to the
extent, and based on criteria, set forth in
EPCA. (42 U.S.C. 6297(d) and
6316(b)(2)(D)) No further action is
required by Executive Order 13132.
F. Review Under Executive Order 12988
With respect to the review of existing
regulations and the promulgation of
new regulations, section 3(a) of
Executive Order 12988, ‘‘Civil Justice
Reform’’ (61 FR 4729 (Feb. 7, 1996))
imposes on Executive agencies the
general duty to adhere to the following
requirements: (1) Eliminate drafting
errors and ambiguity; (2) write
regulations to minimize litigation; and
(3) provide a clear legal standard for
affected conduct rather than a general
standard and promote simplification
and burden reduction. Section 3(b) of
Executive Order 12988 specifically
requires that Executive agencies make
E:\FR\FM\13APP2.SGM
13APP2
17024
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
every reasonable effort to ensure that the
regulation: (1) Clearly specifies the
preemptive effect, if any; (2) clearly
specifies any effect on existing Federal
law or regulation; (3) provides a clear
legal standard for affected conduct
while promoting simplification and
burden reduction; (4) specifies the
retroactive effect, if any; (5) adequately
defines key terms; and (6) addresses
other important issues affecting clarity
and general draftsmanship under any
guidelines issued by the Attorney
General. Section 3(c) of Executive Order
12988 requires Executive agencies to
review regulations in light of applicable
standards in section 3(a) and section
3(b) to determine whether they are met
or it is unreasonable to meet one or
more of them. DOE has completed the
required review and determined that, to
the extent permitted by law, this
proposed rule meets the relevant
standards of Executive Order 12988.
G. Review Under the Unfunded
Mandates Reform Act of 1995
DOE reviewed this regulatory action
under Title II of the Unfunded Mandates
Reform Act of 1995 (Pub. L. 104–4)
(UMRA), which requires each Federal
agency to assess the effects of Federal
regulatory actions on State, local and
Tribal governments and the private
sector. For a proposed regulatory action
likely to result in a rule that may cause
the expenditure by State, local, and
Tribal governments, in the aggregate, or
by the private sector of $100 million or
more in any one year (adjusted for
inflation), section 202 of UMRA requires
an agency to publish a written statement
assessing the costs, benefits, and other
effects of the rule on the national
economy. (2 U.S.C. 1532(a), (b)) The
UMRA also requires a Federal agency to
develop an effective process to permit
timely input by elected officers of State,
local, and Tribal governments on a
proposed ‘‘significant intergovernmental
mandate,’’ and requires an agency plan
for giving notice and opportunity for
timely input to potentially affected
small governments before establishing
any requirements that might
significantly or uniquely affect small
governments. On March 18, 1997, DOE
published a statement of policy on its
process for intergovernmental
consultation under UMRA (62 FR
12820) (also available at https://
www.gc.doe.gov). Although today’s
proposed rule does not contain a
Federal intergovernmental mandate, it
may impose expenditures of $100
million or more on the private sector.
Section 202 of UMRA authorizes an
agency to respond to the content
requirements of UMRA in any other
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
statement or analysis that accompanies
the proposed rule. 2 U.S.C. 1532(c). The
content requirements of section 202(b)
of UMRA relevant to a private sector
mandate substantially overlap the
economic analysis requirements that
apply under section 325(o) of EPCA and
Executive Order 12866. The
SUPPLEMENTARY INFORMATION section of
the notice of proposed rulemaking and
the ‘‘Regulatory Impact Analysis’’
section of the TSD for this proposed rule
respond to those requirements.
Under section 205 of UMRA, the
Department is obligated to identify and
consider a reasonable number of
regulatory alternatives before
promulgating a rule for which a written
statement under section 202 is required.
DOE is required to select from those
alternatives the most cost-effective and
least burdensome alternative that
achieves the objectives of the rule
unless DOE publishes an explanation
for doing otherwise or the selection of
such an alternative is inconsistent with
law. As required by 42 U.S.C. 6295(i)
and (o), today’s proposed rule would
establish energy conservation standards
for GSFL and IRL that are designed to
achieve the maximum improvement in
energy efficiency that DOE has
determined to be both technologically
feasible and economically justified. A
full discussion of the alternatives
considered by DOE is presented in the
‘‘Regulatory Impact Analysis’’ section of
the TSD for today’s proposed rule.
H. Review Under the Treasury and
General Government Appropriations
Act, 1999
Section 654 of the Treasury and
General Government Appropriations
Act, 1999 (Pub. L. 105–277) requires
Federal agencies to issue a Family
Policymaking Assessment for any rule
that may affect family well-being. This
proposed rule would not have any
impact on the autonomy or integrity of
the family as an institution.
Accordingly, DOE has concluded that it
is not necessary to prepare a Family
Policymaking Assessment.
J. Review Under the Treasury and
General Government Appropriations
Act, 2001
Section 515 of the Treasury and
General Government Appropriations
Act, 2001 (44 U.S.C. 3516 note) provides
for agencies to review most
disseminations of information to the
public under guidelines established by
each agency pursuant to general
guidelines issued by OMB. OMB’s
guidelines were published at 67 FR
8452 (Feb. 22, 2002), and DOE’s
guidelines were published at 67 FR
62446 (Oct. 7, 2002). DOE has reviewed
today’s proposed rule under the OMB
and DOE guidelines and has concluded
that it is consistent with applicable
policies in those guidelines.
K. Review Under Executive Order 13211
Executive Order 13211, ‘‘Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use,’’ 66 FR 28355 (May
22, 2001), requires Federal agencies to
prepare and submit to OIRA at OMB, a
Statement of Energy Effects for any
proposed significant energy action. A
‘‘significant energy action’’ is defined as
any action by an agency that
promulgates or is expected to lead to
promulgation of a final rule, and that:
(1) Is a significant regulatory action
under Executive Order 12866, or any
successor order; and (2) is likely to have
a significant adverse effect on the
supply, distribution, or use of energy; or
(3) is designated by the Administrator of
OIRA as a significant energy action. For
any proposed significant energy action,
the agency must give a detailed
statement of any adverse effects on
energy supply, distribution, or use
should the proposal be implemented,
and of reasonable alternatives to the
action and their expected benefits on
energy supply, distribution, and use.
Today’s regulatory action is not a
‘‘significant energy action’’ because it
would not have a significant adverse
effect on the supply, distribution, or use
of energy, nor has it been designated as
such by the Administrator of OIRA.
Accordingly, DOE has not prepared a
Statement of Energy Effects.
I. Review Under Executive Order 12630
L. Review Under the Information
Quality Bulletin for Peer Review
DOE has determined under Executive
Order 12630, ‘‘Governmental Actions
and Interference with Constitutionally
Protected Property Rights,’’ 53 FR 8859
(March 18, 1988), that this regulation
would not result in any taking that
would require compensation under the
Fifth Amendment to the U.S.
Constitution.
On December 16, 2004, OMB, in
consultation with the Office of Science
and Technology Policy (OSTP), issued
its ‘‘Final Information Quality Bulletin
for Peer Review’’ (the Bulletin). 70 FR
2664 (Jan. 14, 2005). The Bulletin
establishes that certain scientific
information shall be peer reviewed by
qualified specialists before it is
PO 00000
Frm 00106
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
disseminated by the Federal
government, including influential
scientific information related to agency
regulatory actions. The purpose of the
Bulletin is to enhance the quality and
credibility of the Government’s
scientific information. Under the
Bulletin, the energy conservation
standards rulemaking analyses are
‘‘influential scientific information,’’
which the Bulletin defines as ‘‘scientific
information the agency reasonably can
determine will have, or does have, a
clear and substantial impact on
important public policies or private
sector decisions.’’ 70 FR 2664, 2667
(Jan. 14, 2005).
In response to OMB’s Bulletin, DOE
conducted formal peer reviews of the
energy conservation standards
development process and analyses, and
has prepared a Peer Review Report
pertaining to the energy conservation
standards rulemaking analyses.
Generation of this report involved a
rigorous, formal, and documented
evaluation process using objective
criteria and qualified and independent
reviewers to make a judgment as to the
technical/scientific/business merit, the
actual or anticipated results, and the
productivity and management
effectiveness of programs and/or
projects. The ‘‘Energy Conservation
Standards Rulemaking Peer Review
Report,’’ dated February 2007, has been
disseminated and is available at:
https://www.eere.energy.gov/buildings/
appliance_standards/peer_review.html.
VIII. Public Participation
DOE will make the entire record of
this proposed rulemaking, including the
transcript from the public meeting,
available for inspection at the U.S.
Department of Energy, Resource Room
of the Building Technologies Program,
950 L’Enfant Plaza, SW., Washington,
DC 20024, (202) 586–2945, between
9 a.m. and 4 p.m., Monday through
Friday, except Federal holidays. Any
person may buy a copy of the transcript
from the transcribing reporter.
A. Submission of Comments
DOE began accepting comments, data,
and information regarding the proposed
rule at the public meeting, and will
continue to accept comments until no
later than the date provided at the
beginning of this notice of proposed
rulemaking. Information submitted
should be identified by docket number
EE–2006–STD–0131 and/or RIN 1904–
AA92. Comments, data, and information
submitted to DOE’s e-mail address for
this rulemaking should be provided in
WordPerfect, Microsoft Word, PDF, or
text (ASCII) file format. Stakeholders
VerDate Nov<24>2008
19:12 Apr 10, 2009
Jkt 217001
should avoid the use of special
characters or any form of encryption
and, wherever possible, comments
should carry the electronic signature of
the author. Comments, data, and
information submitted to DOE via mail
or hand delivery/courier should include
one signed paper original. No
telefacsimiles (faxes) will be accepted.
Pursuant to 10 CFR 1004.11, any
person submitting information that he
or she believes to be confidential and
exempt by law from public disclosure
should submit two copies: one copy of
the document including all the
information believed to be confidential,
and one copy of the document with the
information believed to be confidential
deleted. DOE will make its own
determination about the confidential
status of the information and treat it
according to its determination.
Factors of interest to DOE when
evaluating requests to treat submitted
information as confidential include: (1)
A description of the items; (2) whether
and why such items are customarily
treated as confidential within the
industry; (3) whether the information is
generally known by or available from
other sources; (4) whether the
information has previously been made
available to others without obligation
concerning its confidentiality; (5) an
explanation of the competitive injury to
the submitting person which would
result from public disclosure; (6) when
such information might lose its
confidential character due to the
passage of time; and (7) why disclosure
of the information would be contrary to
the public interest.
B. Issues on Which DOE Seeks Comment
DOE is particularly interested in
receiving comments and views of
interested parties concerning:
(1) The scope of covered products
DOE considered in this rulemaking—
specifically, DOE’s decision to cover 4foot T5 miniature bipin SO and 4-foot
T5 miniature bipin HO lamps;
(2) DOE’s decision to amend the
definition of ‘‘colored fluorescent lamp’’
to exclude lamps with a CCT greater
than 7,000K;
(3) The appropriateness of
establishing separate product classes for
IRL by lamp diameter and rated lamp
voltage;
(4) The appropriateness of
establishing separate product classes for
4-foot T5 miniature bipin SO and 4-foot
T5 miniature bipin HO lamps;
(5) The added 4-foot MBP residential
sector engineering analysis, particularly
the choice of the baseline system (lamp
and ballast);
PO 00000
Frm 00107
Fmt 4701
Sfmt 4702
17025
(6) The performance characteristics
(e.g., lumen output, lifetime, wattage)
established for both GSFL and IRL
model lamps DOE used in the
engineering analysis—specifically, the
properties of the T5 halophosphor GSFL
baseline lamps and the improved
halogen IRL that uses xenon as a fill gas
(the lamp established for TSL1);
(7) The efficacy levels DOE
considered for IRL, in particular the
added EL1 and EL5;
(8) The efficacy levels DOE used for
each GSFL product class—particularly,
DOE’s decision to use compliance report
data to establish GSFL efficacy levels;
(9) The methodology DOE used to
scale efficacy levels from representative
product classes to product classes DOE
did not analyze (i.e., 2-foot U-shaped
lamps and high CCT lamps for GSFL,
modified spectrum lamps, lamps with
diameters less than or equal to 2.5
inches, lamps with rated voltage greater
than 125V);
(10) The choice of ballast lifetimes
DOE used in the commercial,
residential, and industrial sectors and
operating hours for GSFL in the
residential sector;
(11) The growth rates DOE used in the
residential sector IRL and GSFL
shipments analysis, the market
penetration of emerging technologies in
the IRL and GSFL shipments analysis,
and the T5 lamp shipment forecasts;
(12) Base-case market-share matrices
and standards-case market-share
matrices for IRL and GSFL—particularly
the percentage of GSFL consumers with
sufficient lighting expertise (i.e., those
consumers who will choose a lower-BF
ballast or reduced-wattage lamp to
maintain lumen output under
standards) by market segment;
(13) The methodology and inputs
DOE used for the manufacturer impact
analysis—specifically, DOE’s
assumptions regarding markups, capital
costs, conversion costs, and stranded
assets;
(14) The determination of the
environmental impacts of the proposed
rule—specifically, methods for valuing
the CO2, NOX, SOX, and Hg emissions
savings due to the proposed standards;
(15) The appropriateness of trial
standard levels DOE considered for
GSFL and IRL, in particular the
combinations of efficacy levels of each
GSFL product class;
(16) The proposed standard levels for
GSFL and IRL;
(17) Alternative scenarios for GSFL
standards that could achieve greater
energy savings. One example may be for
DOE to adopt a more stringent standard
level in the final rule that would
eliminate T12 lamps, as described in
E:\FR\FM\13APP2.SGM
13APP2
17026
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
relation to TSL4 and TSL5. Another
example may be for DOE to adopt a
more stringent standard level in the
final rule that, similar to TSL4 and
TSL5, would eliminate T12 lamps, but
allow an extended lead time before
compliance would be required. A third
example may be for DOE to adopt a
more stringent standard level, while
continuing to allow the sale of specially
packaged or labeled T12 lamps in the
residential sector only.
(18) Other technology pathways that
may be utilized to meet IRL TSL5,
whether these pathways may have any
adverse effects on consumer utility or
the ability for the product to be massproduced, manufacturer costs associated
with these pathways, and resulting
consumer product prices for lamps that
meet this standard level.
IX. Approval of the Office of the
Secretary
The Secretary of Energy has approved
publication of this proposed rule.
List of Subjects in 10 CFR Part 430
Administrative practice and
procedure, Confidential business
information, Energy conservation,
Household appliances, Imports,
Intergovernmental relations, Small
businesses.
Issued in Washington, DC on March 23,
2009.
Steven G. Chalk,
Principal Deputy Assistant Secretary, Energy
Efficiency and Renewable Energy.
For the reasons stated in the
preamble, DOE proposes to amend
chapter II, subchapter D, of title 10 of
the Code of Federal Regulations as set
forth below:
PART 430—ENERGY CONSERVATION
PROGRAM FOR CONSUMER
PRODUCTS
1. The authority citation for Part 430
continues to read as follows:
Authority: 42 U.S.C. 6291–6309; 28 U.S.C.
2461 note.
2. Section 430.2 is amended by
revising the definition of ‘‘colored
fluorescent lamp,’’ ‘‘fluorescent lamp,’’
and ‘‘rated wattage’’ to read as follows:
§ 430.2
Definitions.
*
*
*
*
*
Colored fluorescent lamp means:
(1) A fluorescent lamp designated and
marketed as a colored lamp with a CRI
less than 40, as determined according to
the method given in CIE Publication
13.2 (incorporated by reference, see
§ 430.3);
(2) A fluorescent lamp designed and
marketed as a colored lamp with a
correlated color temperature (CCT) less
than 2,500K; or
(3) A fluorescent lamp with a CCT
greater than 7,000K.
*
*
*
*
*
Fluorescent lamp means a low
pressure mercury electric-discharge
source in which a fluorescing coating
transforms some of the ultraviolet
energy generated by the mercury
discharge into light, including only the
following:
(1) Any straight-shaped lamp
(commonly referred to as 4-foot medium
bipin lamps) with medium bipin bases
of nominal overall length of 48 inches
and rated wattage of 25 or more;
(2) Any U-shaped lamp (commonly
referred to as 2-foot U-shaped lamps)
with medium bipin bases of nominal
overall length between 22 and 25 inches
and rated wattage of 25 or more;
(3) Any rapid start lamp (commonly
referred to as 8-foot high output lamps)
with recessed double contact bases of
nominal overall length of 96 inches;
(4) Any instant start lamp (commonly
referred to as 8-foot slimline lamps)
with single pin bases of nominal overall
length of 96 inches and rated wattage of
52 or more;
(5) Any straight-shaped lamp
(commonly referred to as 4-foot
miniature bipin standard output lamps)
with miniature bipin bases of nominal
*
*
*
*
(n) General service fluorescent lamps
and incandescent reflector lamps. (1)
Except as provided in paragraphs (n)(2)
and (n)(3) of this section, each of the
following general service fluorescent
lamps manufactured after the effective
dates specified in the table shall meet or
exceed the following lamp efficacy and
CRI standards:
Minimum
average lamp
efficacy
(lm/W)
> 35W
≤ 35W
> 35W
≤ 35W
> 65W
≤ 65W
> 100W
≤ 100W
69
45
69
45
69
45
69
45
75.0
75.0
68.0
64.0
80.0
80.0
80.0
80.0
2-foot U-shaped ............................................................................................
8-foot slimline ................................................................................................
8-foot high output ..........................................................................................
Jkt 217001
*
Minimum CRI
4-foot medium bipin ......................................................................................
19:12 Apr 10, 2009
§ 430.32 Energy and water conservation
standards and their effective dates.
Nominal lamp
wattage
Lamp type
VerDate Nov<24>2008
length between 45 and 48 inches and
rated wattage of 26 or more; and
(6) Any straight-shaped lamp
(commonly referred to 4-foot miniature
bipin high output lamps) with miniature
bipin bases of nominal length between
45 and 48 inches and rated wattage of
51 or more.
*
*
*
*
*
Rated wattage, with respect to general
service fluorescent lamps, means:
(1) If the lamp is listed in ANSI
C78.81–2005 or ANSI C78.901–2005,
the rated wattage of a lamp determined
by the lamp designation of Clause 11.1
of ANSI C78.81–2005 or ANSI C78.901–
2005;
(2) If the lamp is a residential straightshaped lamp, and not listed in ANSI
C78.81–2005, the wattage of a lamp
when operated on a reference ballast for
which the lamp is designed;
(3) If the lamp is neither listed in one
of the ANSI guides referenced in (1) nor
a residential straight-shaped lamp, the
wattage of a lamp when measured
according to the test procedures
outlined in Appendix R to subpart B of
this part; or
(4) With respect to general service
incandescent lamps and incandescent
reflector lamps, the wattage measured
according to the test procedures
outlined in Appendix R to subpart B of
this part.
*
*
*
*
*
3. Section 430.32 is amended by
revising paragraph (n) to read as
follows:
PO 00000
Frm 00108
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
Effective date
Nov. 1, 1995
Nov. 1, 1995.
Nov. 1, 1995.
Nov. 1, 1995.
May 1, 1994.
May 1, 1994.
May 1, 1994.
May 1, 1994.
17027
Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 / Proposed Rules
(2) The standards described in
paragraph (n)(1) of this section do not
apply to:
(i) Any 4-foot medium bipin lamp or
2-foot U-shaped lamp with a rated
wattage less than 28 watts;
(ii) Any 8-foot high output lamp not
defined in ANSI C78.1–1978 or related
supplements, or not 0.800 nominal
amperes; or
(iii) Any 8-foot slimline lamp not
defined in ANSI C78.3–1978 (R1984) or
related supplement ANSI C78.3a–1985.
(3) Each of the following general
service fluorescent lamps manufactured
after June 30, 2012, shall meet or exceed
the following lamp efficacy standards
shown in the table:
4-foot medium bipin .................................................................................................................................................
2-foot U-shaped .......................................................................................................................................................
8-foot slimline ...........................................................................................................................................................
8-foot high output .....................................................................................................................................................
4-foot miniature bipin standard output .....................................................................................................................
4-foot miniature bipin high output ............................................................................................................................
(4) Except as provided in paragraph
(n)(5) of this section, each of the
following incandescent reflector lamps
manufactured after November 1, 1995,
shall meet or exceed the lamp efficacy
standards shown in the table:
Minimum
average lamp
efficacy
(lm/W)
Correlated
color
temperature
Lamp type
Minimum average
lamp efficacy
(lm/W)
Nominal lamp wattage
40–50 ..............................
51–66 ..............................
67–85 ..............................
86–115 ............................
116–155 ..........................
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
4,500K
84
78
78
73
95
91
88
84
103
97
89
85
Minimum average
lamp efficacy
(lm/W)
Nominal lamp wattage
10.5
11.0
12.5
14.0
14.5
Lamp spectrum
≤
>
≤
>
≤
>
≤
>
≤
>
≤
>
156–205 ..........................
15.0
(5) Each of the following incandescent
reflector lamps manufactured after June
30, 2012, shall meet or exceed the lamp
efficacy standards shown in the table:
Lamp diameter
Standard Spectrum ......................................................................................................................
Rated voltage
> 2.5″
≤ 2.5″
Modified Spectrum .......................................................................................................................
> 2.5″
≤ 2.5″
≥
<
≥
<
≥
<
≥
<
125V
125V
125V
125V
125V
125V
125V
125V
Minimum
average lamp
efficacy
(lm/W)
7.1P0.27
6.2P0.27
6.3P0.27
5.5P0.27
5.8P0.27
5.0P0.27
5.1P0.27
4.4P0.27
NOTE: P is equal to the rated lamp wattage, in watts.
(6)(i)(A) Subject to the exclusions in
paragraph (6)(ii) of this section, the
standards specified in this section shall
apply to ER incandescent reflector
lamps, BR incandescent reflector lamps,
BPAR incandescent reflector lamps, and
similar bulb shapes on and after January
1, 2008.
(B) Subject to the exclusions in
paragraph (6)(ii) of this section, the
VerDate Nov<24>2008
20:47 Apr 10, 2009
Jkt 217001
standards specified in this section shall
apply to incandescent reflector lamps
with a diameter of more than 2.25
inches, but not more than 2.75 inches,
on and after June 15, 2008.
(ii) The standards specified in this
section shall not apply to the following
types of incandescent reflector lamps:
PO 00000
(A) Lamps rated at 50 watts or less
that are ER30, BR30, BR40, or ER40
lamps;
(B) Lamps rated at 65 watts that are
BR30, BR40, or ER40 lamps; or
(C) R20 incandescent reflector lamps
rated 45 watts or less.
[FR Doc. E9–7634 Filed 4–10–09; 8:45 am]
BILLING CODE 6450–01–P
Frm 00109
Fmt 4701
Sfmt 4702
E:\FR\FM\13APP2.SGM
13APP2
]]>Agencies
[Federal Register Volume 74, Number 69 (Monday, April 13, 2009)]
[Proposed Rules]
[Pages 16920-17027]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: E9-7634]
[[Page 16919]]
-----------------------------------------------------------------------
Part II
Department of Energy
-----------------------------------------------------------------------
10 CFR Part 430
Energy Conservation Program: Energy Conservation Standards for General
Service Fluorescent Lamps and Incandescent Reflector Lamps; Proposed
Rule
��Federal Register / Vol. 74, No. 69 / Monday, April 13, 2009 /
Proposed Rules��
[[Page 16920]]
-----------------------------------------------------------------------
DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket Number EE-2006-STD-0131]
RIN 1904-AA92
Energy Conservation Program: Energy Conservation Standards for
General Service Fluorescent Lamps and Incandescent Reflector Lamps
AGENCY: Office of Energy Efficiency and Renewable Energy, Department of
Energy.
ACTION: Notice of proposed rulemaking.
-----------------------------------------------------------------------
SUMMARY: The Energy Policy and Conservation Act (EPCA) prescribes
energy conservation standards for various consumer products and
commercial and industrial equipment, including general service
fluorescent lamps (GSFL) and incandescent reflector lamps (IRL), and
the statute also requires the Department of Energy (DOE) to
subsequently determine whether more stringent, amended standards for
GSFL and IRL would be technologically feasible and economically
justified, and would save a significant amount of energy. In addition,
EPCA directs DOE to consider adoption of standards for additional GSFL
not already covered by EPCA-prescribed standards. In this notice, DOE
proposes amended energy conservation standards for certain GSFL and IRL
and new energy conservation standards for certain additional GSFL not
currently covered by standards.
DATES: DOE held a public meeting on Tuesday, February 3, 2009 in
Washington, DC. DOE began accepting comments, data, and information
regarding this notice of proposed rulemaking (NOPR) at the public
meeting, and will continue to accept comments until no later than June
12, 2009. See section VIII, ``Public Participation,'' of this NOPR for
details.
ADDRESSES: The public meeting was held at the U.S. Department of
Energy, Forrestal Building, Room 1E-245, 1000 Independence Avenue, SW.,
Washington, DC 20585-0121.
Any comments submitted must identify the NOPR for Energy
Conservation Standards for Lighting Products, and provide the docket
number EE-2006-STD-0131 and/or regulatory information number (RIN)
number 1904-AA92. Comments may be submitted using any of the following
methods:
Federal eRulemaking Portal: https://www.regulations.gov.
Follow the instructions for submitting comments.
E-mail: fluorescent_and_incandescent_lamps.rulemaking@ee.doe.gov. Include the docket number EE-2006-STD-
0131and/or RIN 1904-AA92 in the subject line of the message.
Postal Mail: Ms. Brenda Edwards, U.S. Department of
Energy, Building Technologies Program, Mailstop EE-2J, 1000
Independence Avenue, SW., Washington, DC 20585-0121. Please submit one
signed paper original.
Hand Delivery/Courier: Ms. Brenda Edwards, U.S. Department
of Energy, Building Technologies Program, 950 L'Enfant Plaza, SW.,
Suite 600, Washington, DC 20024. Telephone: (202) 586-2945. Please
submit one signed paper original.
For detailed instructions on submitting comments and additional
information on the rulemaking process, see section VIII of this
document (Public Participation).
Docket: For access to the docket to read background documents or
comments received, visit the U.S. Department of Energy, Resource Room
of the Building Technologies Program, 950 L'Enfant Plaza, SW., Suite
600, Washington, DC, (202) 586-2945, between 9 a.m. and 4 p.m., Monday
through Friday, except Federal holidays. Please call Ms. Brenda Edwards
at the above telephone number for additional information regarding
visiting the Resource Room.
FOR FURTHER INFORMATION CONTACT: Ms. Linda Graves, U.S. Department of
Energy, Office of Energy Efficiency and Renewable Energy, Building
Technologies Program, EE-2J, 1000 Independence Avenue, SW., Washington,
DC 20585-0121. Telephone: (202) 586-1851. E-mail:
Linda.Graves@ee.doe.gov.
Mr. Eric Stas or Ms. Francine Pinto, U.S. Department of Energy,
Office of the General Counsel, GC-72, Forrestal Building, Mail Station
GC-72, 1000 Independence Avenue, SW., Washington, DC 20585-0121.
Telephone: (202) 586-9507. E-mail: Eric.Stas@hq.doe.gov or
Francine.Pinto@hq.doe.gov.
For information on how to submit or review public comments, contact
Ms. Brenda Edwards, U.S. Department of Energy, Office of Energy
Efficiency and Renewable Energy, Building Technologies Program, EE-2J,
1000 Independence Avenue, SW., Washington, DC 20585-0121. Telephone:
(202) 586-2945. E-mail: Brenda.Edwards@ee.doe.gov.
SUPPLEMENTARY INFORMATION:
Table of Contents
I. Summary of the Proposed Rule
II. Introduction
A. Consumer Overview
B. Authority
C. Background
1. Current Standards
2. History of Standards Rulemaking for General Service
Fluorescent Lamps, Incandescent Reflector Lamps, and General Service
Incandescent Lamps
III. Issues Affecting the Scope of This Rulemaking
A. Additional General Service Fluorescent Lamps for Which DOE is
Proposing Standards
1. Scope of EPCA Requirement that DOE Consider Standards for
Additional Lamps
2. Identification of the Additional Lamps for Which DOE Proposes
Standards
a. Coverage of T5 Lamps
b. Extension of Lamp Wattage Ranges
3. Summary GSFL Lamps to Which DOE Proposes to Extend Coverage
B. Exempted Incandescent Reflector Lamps
C. Amended Definitions
1. ``Rated Wattage''
2. ``Colored Fluorescent Lamp''
D. Off Mode and Standby Mode Energy Consumption Standards
E. Color Rendering Index Standards for General Service
Fluorescent Lamps
IV. General Discussion
A. Test Procedures
B. Technological Feasibility
1. General
2. Maximum Technologically Feasible Levels
C. Energy Savings
1. Determination of Savings
2. Significance of Savings
D. Economic Justification
1. Specific Criteria
a. Economic Impact on Manufacturers and Consumers
b. Life-Cycle Costs
c. Energy Savings
d. Lessening of Utility or Performance of Products
e. Impact of Any Lessening of Competition
f. Need of the Nation to Conserve Energy
g. Other Factors
2. Rebuttable Presumption
V. Methodology and Discussion of Comments
A. Product Classes
1. General Service Fluorescent Lamps
a. T12 and T8 Lamps
b. T5 Lamps
c. Correlated Color Temperature
2. Incandescent Reflector Lamps
a. Modified-Spectrum Lamps
b. Long-Life Lamps
c. Lamp Diameter
d. Voltage
B. Screening Analysis
1. General Service Fluorescent Lamps
a. Higher-Efficiency Lamp Fill Gas Composition
b. Higher-Efficiency Phosphors
c. Glass Coating
d. Lamp Diameter
e. Multi-Photon Phosphors
2. Incandescent Reflector Lamps
C. Engineering Analysis
1. Approach
2. Representative Product Classes
3. Baseline Lamps and Systems
[[Page 16921]]
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. Lamp and Lamp-and-Ballast Designs
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Efficiency Levels
a. General Service Fluorescent Lamps
i. Revisions to ANOPR Efficiency Levels
ii. Four-Foot T5 Miniature Bipin Efficiency Levels
b. Incandescent Reflector Lamps
6. Engineering Analysis Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
7. Scaling to Product Classes Not Analyzed
a. General Service Fluorescent Lamps
i. Correlated Color Temperature
ii. U-Shaped Lamps
b. Incandescent Reflector Lamps
i. Modified-Spectrum IRL
ii. Lamp Diameter
iii. Voltage
D. Life-Cycle Cost and Payback Period Analyses
1. Consumer Product Price
2. Sales Tax
3. Installation Costs
4. Disposal Costs
5. Annual Operating Hours
a. Sectors Analyzed
b. Regional Variation
c. Building Type
6. Product Energy Consumption Rate
7. Electricity Prices
8. Electricity Price Trends
9. Lifetime
a. Ballast Lifetime
b. Lamp Lifetime
10. Discount Rates
11. Analysis Period
12. Effective Date
13. Payback Period Inputs
14. Lamp Purchase Events
E. National Impact Analysis--National Energy Savings and Net
Present Value Analysis
1. General
a. Overview of NIA Changes in This Notice
2. Shipments Analysis
a. Lamp Inventory
b. Shipments Growth
i. Floor Space and Building Growth
ii. Lamps per Household
iii. Wider Spacing of More-Efficient Fixtures
c. Base-Case Scenarios: Emerging Technologies and Existing
Technologies
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
d. Fluorescent Market Sectors Analyzed
e. GSFL Product Migration
i. Ballast Rule Effective Start Date
ii. Four-Foot Medium Bipin T12 Lamp Replacements
iii. Eight-Foot Single Pin Slimline T12 Lamp Replacements
iv. Four-Foot T5 Lamps
3. Base-Case Market-Share Matrices
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. GSFL Standards-Case Shipment Scenarios and Forecasts
a. Shift/Roll-Up Scenarios
b. Lighting Expertise Scenarios
c. Voluntary Retrofits
5. IRL-Standards-Case Shipment Scenarios and Forecasts
i. Shift/Roll-Up Scenarios
ii. Product-Substitution Scenarios
6. Other Inputs
a. Analysis Period
b. Total Installed Cost
c. Electricity Price Forecast
d. Energy Site-to-Source Conversion
e. HVAC Interaction Factor
f. Rebound Effect
g. Discount Rates
F. Consumer Subgroup Analysis
G. Manufacturer Impact Analysis
1. Overview
a. Phase 1, Industry Profile
b. Phase 2, Industry Cash-Flow Analysis
c. Phase 3, Subgroup Impact Analysis
2. Discussion of Comments
3. Government Regulatory Impact Model Analysis
4. Manufacturer Interviews
a. Key Issues
i. GSFL
ii. IRL
b. Government Regulatory Impact Model Scenarios and Key Inputs
i. GSFL Base-Case Shipment Forecast
ii. IRL Base Case Shipments Forecast
iii. GSFL Standards Case Shipments Forecast
iv. IRL Standards-Case Shipments Forecast
v. Manufacturing Production Costs
vi. Amended Energy Conservation Standards Markup Scenarios
vii. Product and Capital Conversion Costs
H. Employment Impact Analysis
I. Utility Impact Analysis
J. Environmental Analysis
VI. Analytical Results
A. Trial Standard Levels
1. General Service Fluorescent Lamps
2. Incandescent Reflector Lamps
B. Economic Justification and Energy Savings
1. Economic Impacts on Consumers
a. Life-Cycle Cost and Payback Period
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
b. Consumer Subgroup Analysis
i. Low-Income Households
ii. Institutions of Religious Worship
iii. Institutions That Serve Low-Income Populations
iv. Historical Facilities
v. Consumers of T12 electronic ballasts
2. Economic Impacts on Manufacturers
a. Industry Cash-Flow Analysis Results
i. General Service Fluorescent Lamps
ii. Incandescent Reflector Lamps
b. Cumulative Regulatory Burden
c. Impacts on Employment
d. Impacts on Manufacturing Capacity
e. Impacts on Manufacturer Subgroups
3. National Impact Analysis
a. Significance of Energy Savings
b. Net Present Value
c. Impacts on Employment
4. Impact on Utility or Performance of Products
5. Impact of Any Lessening of Competition
6. Need of the Nation to Conserve Energy
C. Proposed Standard
1. Overview
2. General Service Fluorescent Lamps Conclusion
a. Trial Standard Level 5
b. Trial Standard Level 4
c. Trial Standard Level 3
3. Incandescent Reflector Lamps Conclusion
a. Trial Standard Level 5
b. Trial Standard Level 4
VII. Procedural Issues and Regulatory Review
A. Review Under Executive Order 12866
B. Review Under the Regulatory Flexibility Act
C. Review Under the Paperwork Reduction Act
D. Review Under the National Environmental Policy Act
E. Review Under Executive Order 13132
F. Review Under Executive Order 12988
G. Review Under the Unfunded Mandates Reform Act of 1995
H. Review Under the Treasury and General Government
Appropriations Act, 1999
I. Review Under Executive Order 12630
J. Review Under the Treasury and General Government
Appropriations Act, 2001
K. Review Under Executive Order 13211
L. Review Under the Information Quality Bulletin for Peer Review
VIII. Public Participation
A. Submission of Comments
B. Issues on Which DOE Seeks Comment
IX. Approval of the Office of the Secretary
Acronyms and Abbreviations
ACEEE American Council for an Energy Efficiency Economy
AEO Annual Energy Outlook
ANOPR advance notice of proposed rulemaking
ANSI American National Standards Institute
ASAP Appliance Standards Awareness Project
ASE Alliance to Save Energy
BF ballast factor
BLS Bureau of Labor Statistics
BPAR bulged parabolic aluminized reflector
BR bulged reflector (reflector lamp shape)
BT Building Technologies Program
BTU British Thermal Unit
CAIR Clean Air Interstate Act
CAMR Clean Air Mercury Rule
CBECS Commercial Buildings Energy Consumption Survey
CCT correlated color temperature
CFR Code of Federal Regulations
CFL compact fluorescent lamp
CIE International Commission on Illumination
CMH ceramic metal halide
CO2 carbon dioxide
CRI color rendering index
CSL candidate standard level
DIY do-it-yourself
DOE U.S. Department of Energy
DOJ U.S. Department of Justice
E26 Edison screw-base (incandescent lamp base type)
EERE Office of Energy Efficiency and Renewable Energy
EIA Energy Information Administration
EISA 2007 Energy Independence and Security Act of 2007
EL efficacy level
EPA Environmental Protection Agency
EPACT 1992 Energy Policy Act of 1992
EPACT 2005 Energy Policy Act of 2005
EPCA Energy Policy and Conservation Act
ER elliptical reflector (reflector lamp shape)
[[Page 16922]]
FEMP Federal Energy Management Program
FR Federal Register
FTC Federal Trade Commission
GE General Electric Lighting and Industrial
GRIM Government Regulatory Impact Model
GSFL general service fluorescent lamp
GSIL general service incandescent lamp
GW gigawatt
Hg mercury
HID high-intensity discharge
HIR halogen infrared reflector
HO high output
HVAC Heating, Ventilating and Air-Conditioning
IESNA Illuminating Engineering Society of North America
ImSET Impact of Sector Energy Technologies
INPV industry net present value
I-O input-output
IPCC Intergovernmental Panel on Climate Change
IR Infrared
IRFA initial regulatory flexibility analysis
IRL incandescent reflector lamp
K degrees Kelvin
kt kilotons
LCC life-cycle cost
LED Light-Emitting Diode
LMC U.S. Lighting Market Characterization Volume I
Lm/W lumens per watt
MBP medium bipin
MECS Manufacturer Energy Consumption Survey (MECS)
MIA Manufacturer Impact Analysis
MMt million metric tons
Mt metric tons
MW megawatts
NAICS North American Industry Classification System
NCLC National Consumer Law Center
NEEP Northeast Energy Efficiency Partnership
NEMA National Electrical Manufacturers Association
NEMS National Energy Modeling System
NEMS-BT National Energy Modeling System--Building Technologies
NES national energy savings
NIA National Impact Analysis
NIST National Institute of Standards and Technology
NOPR notice of proposed rulemaking
NOX nitrogen oxides
NPCC Northwest Power and Conservation Council
NPV net present value
NRDC Natural Resources Defense Council
NVLAP National Voluntary Laboratory Accreditation Program
OEM Original Equipment Manufacturer
OIRA Office of Information and Regulatory Affairs
OMB U.S. Office of Management and Budget
PAR parabolic aluminized reflector (reflector lamp shape)
PBP payback period
PG&E Pacific Gas and Electric
quad quadrillion BTU
R reflector (reflector lamp shape)
R-CFL reflector compact fluorescent lamp
R&D research and development
RDC recessed double contact
RECS Residential Energy Consumption Survey
RIA regulatory impact analysis
RoHS Restriction on Hazardous Substances directive
SBA Small Business Administration
SCF Survey of Consumer Finances
SEC Securities and Exchange Commission
SEL spectrally-enhanced lighting
SG&A selling, general, and administrative costs
SO standard output
SO2 sulfur dioxide
SP single pin
S&P Standard & Poor's
T8, T10, T12 tubular fluorescent lamps, diameters of 1, 1.25 or 1.5
inches, respectively
TSD technical support document
TSL trial standard level
TWh terawatt-hour
UMRA Unfunded Mandates Reform Act
U.S.C. United States Code
UV ultraviolet
V volts
VHO very high output
W watts
I. Summary of the Proposed Rule
The Energy Policy and Conservation Act (EPCA or the Act) (42 U.S.C.
6291 et seq.), as amended, requires DOE to consider whether to amend
the existing energy conservation standards for GSFL and IRL, and to
also consider whether to adopt new energy conservation standards for
additional types of GSFL beyond those already covered by EPCA-
prescribed standards. (42 U.S.C. 6295(i)(3)-(5)) The Act also specifies
that any new or amended energy conservation standard DOE prescribes for
certain consumer and/or commercial products, such as GSFL and IRL,
shall be designed to ``achieve the maximum improvement in energy
efficiency * * * which the Secretary determines is technologically
feasible and economically justified.'' (42 U.S.C. 6295(o)(2)(A);
6316(a)) Furthermore, the new or amended standard must ``result in
significant conservation of energy.'' (42 U.S.C. 6295(o)(3)(B);
6316(a)) In accordance with these and other statutory provisions
discussed in this notice, DOE proposes new and amended energy
conservation standards for GSFL and IRL, as shown in Table I.1 and
Table I.2. The proposed standards would apply to all products listed in
Table I.1 and Table I.2 that are manufactured in or imported into the
United States on or after June 30, 2012.
Table I.1--Summary of the Proposed Energy Conservation Standards for General Service Fluorescent Lamps
----------------------------------------------------------------------------------------------------------------
Percent
Correlated increase over
Lamp type color Proposed level current
temperature lm/W standards or
baseline
----------------------------------------------------------------------------------------------------------------
4-Foot Medium Bipin............................................. <= 4,500K 84 12%
> 4,500K 78 4%
2-Foot U-Shaped................................................. <= 4,500K 78 15%/22%*
> 4,500K 73 7%/14%*
8-Foot Slimline................................................. <= 4,500K 95 19%
> 4,500K 91 14%
8-Foot High Output.............................................. <= 4,500K 88 10%
> 4,500K 84 5%
4-Foot Miniature Bipin Standard Output.......................... <= 4,500K 103 20%
> 4,500K 97 13%
4-Foot Miniature Bipin High Output.............................. <= 4,500K 89 16%
> 4,500K 85 10%
----------------------------------------------------------------------------------------------------------------
* For these product classes, EPCA has different efficacy standards for lamps with wattages less than 35W and
greater than or equal to 35W.
[[Page 16923]]
Table I.2--Summary of the Proposed Energy Conservation Standard for IRL
----------------------------------------------------------------------------------------------------------------
Percent
increase over
Lamp type Diameter Voltage Proposed level current
lm/W standards or
baseline
----------------------------------------------------------------------------------------------------------------
Standard Spectrum 40W-205W......... > 2.5 inches............... >= 125 7.1P\0.27\ 69%-100%
< 125 6.2P\0.27\ 47%-75%
<= 2.5 inches.............. >= 125 6.3P\0.27\ 50%-78%
< 125 5.5P\0.27\ 31%-55%
Modified Spectrum 40W-205W......... > 2.5 inches............... >= 125 5.8P\0.27\ 38%-63%
< 125 5.0P\0.27\ 19%-41%
<= 2.5 inches.............. >= 125 5.1P\0.27\ 21%-44%
< 125 4.4P\0.27\ 7%-27%
----------------------------------------------------------------------------------------------------------------
Note: P is equal to the rated lamp wattage, in watts.
DOE's analyses indicate that the proposed standards would save a
significant amount of energy--an estimated 3.2 to 7.3 quads (for GSFL)
and 1.3 to 2.3 quads (for IRL) of cumulative energy over 31 years
(2012-2042). The economic impacts on most GSFL and all IRL individual
and commercial consumers (i.e., the average life-cycle cost (LCC)
savings) are positive.
The cumulative national net present value (NPV) of total consumer
costs and savings of the proposed standards from 2012 to 2042 in 2007$
ranges from $3.2 billion (at a 7-percent discount rate) to $25.7
billion (at a 3-percent discount rate) for GSFL. For IRL, the NPV from
2012 to 2042 in 2007$ ranges from $3.7 billion (at a 7-percent discount
rate) to $14.0 billion (at a 3-percent discount rate). This is the
estimated total value of future operating-cost savings minus the
estimated increased product costs, discounted to 2007. DOE estimates
the GSFL industry net present value (INPV) to currently be $575-602
million in 2007$. If DOE were to adopt the proposed standards, it
expects that manufacturers may lose up to 24 percent of their INPV,
which is approximately $139 million. The NPV of the proposed standards
for GSFL consumers (at least $3.2 billion at the 7-percent discount
rate) would exceed anticipated industry losses by at least 23 times.
DOE estimates the IRL industry net present value to be $207-267 million
in 2007$. If DOE were to adopt the proposed standards, it expects that
manufacturers may lose 29-46 percent of their INPV, which is
approximately $77-94 million. The NPV of the proposed standards for IRL
consumers (at least $3.7 billion at the 7-percent discount rate) would
exceed anticipated industry losses by at least 39 times.
In addition, the proposed standards would have significant
environmental benefits. All of the energy saved would be in the form of
electricity, and DOE expects the energy savings from the proposed
standards to eliminate the need for approximately 1100 to 3400
megawatts (MW) of generating capacity for GSFL and up to 450 MW for IRL
by 2042. This would result in cumulative (undiscounted) greenhouse gas
emission reductions of 184 to 395 million metric tons (MMT) of carbon
dioxide (CO2) for GSFL and 59 to 114 MMT for IRL from 2012
to 2042. During this same period, the standard would result in power
plant emission reductions of 12 to 623 kilotons (kt) of nitrogen oxides
(NOX) for GSFL and 4 to 181 kt NOX for IRL.
Mercury (Hg) emission reductions would be up to 6.9 tons for GFSL and
up to 1.7 tons avoided for IRL.
DOE has tentatively concluded that the proposed standards represent
the maximum improvement in energy efficiency that is technologically
feasible and economically justified, and would result in significant
conservation of energy. DOE further notes that products achieving these
standard levels are already commercially available. Based upon the
rulemaking analyses culminating in this proposal, DOE found that the
benefits (energy savings, consumer LCC savings, national NPV increase,
and emission reductions) to the Nation of the proposed standards
outweigh the burdens (INPV decrease and LCC increases for some lamp
users). DOE considered higher efficacy levels (ELs) as trial standard
levels (TSLs), and is still considering them in this rulemaking;
however, DOE has tentatively concluded that the burdens of the higher
efficiency levels outweigh the benefits. Based upon consideration of
public comments and related information, DOE may adopt either higher or
lower ELs presented in this proposal or some level in between.
II. Introduction
A. Consumer Overview
EPCA currently prescribes efficacy standards for certain IRL and
GSFL. (42 U.S.C. 6295(i)(1)) DOE proposes to raise these standards and
to set efficacy standards for certain other GSFL, as shown in Table I.1
and Table I.2 above. The proposed standards would apply to products
manufactured in the United States, or imported to it, three years after
the final rule is published in the Federal Register.\1\ Table I.1 and
Table I.2 also show the percentage improvement in efficacy that each
standard level represents, relative to the current standard levels or
to products typically on the market today. The proposed standards
represent an overall improvement of approximately 4 to 22 percent and 7
to 100 percent in the efficacies of the GSFL and IRL baselines,
respectively, covered by the standards.
---------------------------------------------------------------------------
\1\ The final rule is expected to be published by June 30, 2009;
therefore, the effective date would be June 30, 2012.
---------------------------------------------------------------------------
DOE's analyses suggest that residential and commercial consumers
would see benefits from the proposed standards. Although DOE expects
that under the proposed standards, the purchase price of high-efficacy
GSFL would be higher (up to three times higher) than the average price
of these products today, but that the energy efficiency gains would
result in lower energy costs that more than offset such higher costs.
When the potential savings due to efficiency gains are summed over the
lifetime of the high-efficacy products, consumers would be expected to
save up to $56.60 (depending on the lamp type), on average, compared to
their expenditures on today's baseline GSFL.
The results of DOE's analyses for IRL follow a similar pattern.
Although DOE expects the purchase price of the high-efficacy IRL would
be higher (ranging from 56 to 63 percent) than the average price of
these products today, the energy efficiency gains would result in lower
energy costs that more than offset the higher costs. When these
potential
[[Page 16924]]
savings due to efficiency gains are summed over the lifetime of the
high-efficacy IRL, it is estimated that consumers would save between
$1.62 and $8.14, on average, compared to their expenditures on today's
baseline IRL.
B. Authority
Title III of EPCA sets forth a variety of provisions designed to
improve energy efficiency. Part A \2\ of Title III (42 U.S.C. 6291-
6309) established the ``Energy Conservation Program for Consumer
Products Other Than Automobiles.'' The program covers consumer products
and certain commercial products (referred to hereafter as ``covered
products''), including GSFL and IRL. (42 U.S.C. 6292(a)(14) and
6295(i)) EPCA prescribes energy conservation standards for certain GSFL
and IRL. (42 U.S.C. 6295(i)(1)) The statute further directs DOE to
determine whether the existing standards for fluorescent and
incandescent lamps should be amended and whether to adopt standards for
additional GSFL. (42 U.S.C. 6295(i)(3)-(5)) This rulemaking represents
the first round of amendments to the GSFL and IRL energy conservation
standards as directed by 42 U.S.C. 6295(i)(3).
---------------------------------------------------------------------------
\2\ This part was originally titled Part B; however, it was
redesignated Part A after Part B was repealed by Pub. L. 109-58.
---------------------------------------------------------------------------
The scope of coverage for these requirements for GSFL and IRL is
dictated by EPCA's definitions of these and related terms, as explained
below. EPCA defines ``general service fluorescent lamp'' as follows: *
* * [F]luorescent lamps which can be used to satisfy the majority of
fluorescent applications, but does not include any lamp designed and
marketed for the following nongeneral lighting applications: (i)
Fluorescent lamps designed to promote plant growth. (ii) Fluorescent
lamps specifically designed for cold temperature installations. (iii)
Colored fluorescent lamps. (iv) Impact-resistant fluorescent lamps. (v)
Reflectorized or aperture lamps. (vi) Fluorescent lamps designed for
use in reprographic equipment. (vii) Lamps primarily designed to
produce radiation in the ultra-violet region of the spectrum. (viii)
Lamps with a color rendering index of 87 or greater. (42 U.S.C.
6291(30)(B))
EPCA defines ``incandescent reflector lamp'' as follows: * * * [A]
lamp in which light is produced by a filament heated to incandescence
by an electric current * * * [and] (commonly referred to as a reflector
lamp) which is not colored or designed for rough or vibration service
applications, that contains an inner reflective coating on the outer
bulb to direct the light, an R, PAR, ER, BR, BPAR, or similar bulb
shapes with E26 medium screw bases, a rated voltage or voltage range
that lies at least partially within 115 and 130 volts, a diameter which
exceeds 2.25 inches, and has a rated wattage that is 40 watts or
higher.
(42 U.S.C. 6291(30)(C), (C)(ii) and (F))
EPCA further clarifies this definition of IRL by defining the lamp
types excluded from the definition: The term ``rough service lamp''
means a lamp that--(i) has a minimum of 5 supports with filament
configurations that are C-7A, C-11, C-17, and C-22 as listed in Figure
6-12 of the 9th edition of the IESNA Lighting handbook, or similar
configurations where lead wires are not counted as supports; and (ii)
is designated and marketed specifically for `rough service'
applications, with (I) the designation appearing on the lamp packaging;
and (II) marketing materials that identify the lamp as being for rough
service. (42 U.S.C. 6291(30)(X))
The term ``vibration service lamp'' means a lamp that--(i) has
filament configurations that are C-5, C-7A, or C-9, as listed in Figure
6-12 of the 9th Edition of the IESNA Lighting Handbook or similar
configurations; (ii) has a maximum wattage of 60 watts; (iii) is sold
at retail in packages of 2 lamps or less; and (iv) is designated and
marketed specifically for vibration service or vibration-resistant
applications, with--(I) the designation appearing on the lamp
packaging; and (II) marketing materials that identify the lamp as being
vibration service only. (42 U.S.C. 6291(30)(AA))
The term ``colored incandescent lamp'' means an incandescent lamp
designated and marketed as a colored lamp that has--(i) a color
rendering index of less than 50, as determined according to the test
method given in C.I.E. publication 13.3-1995; or (ii) a correlated
color temperature of less than 2,500K, or greater than 4,600K, where
correlated temperature is computed according to the Journal of Optical
Society of America, Vol. 58, pages 1528-1595 (1986). (42 U.S.C.
6291(30)(EE)) \3\
---------------------------------------------------------------------------
\3\ DOE notes that the publication year of the referenced
article in the definition of ``colored incandescent lamp,'' as
printed in section 321(a)(1)(B) of EISA, contains two typographical
errors. The citation should read as follows: Journal of Optical
Society of America, Vol. 58, pages 1528-1535 (1968).
---------------------------------------------------------------------------
The advance notice of proposed rulemaking (ANOPR) in this
proceeding (73 FR 13620, 13622, 13625, 13628-29 (March 13, 2008)), as
well as subsection II.C and section III below, provide additional
detail on the nature and statutory history of EPCA's requirements for
GSFL and IRL.
Under the Act, DOE's energy conservation program for covered
products consists essentially of four parts: (1) Testing; (2) labeling;
(3) Federal energy conservation standards, and (4) certification and
enforcement procedures. The Federal Trade Commission (FTC) is
responsible for labeling, and DOE implements the remainder of the
program. Section 323 of the Act authorizes DOE, subject to certain
criteria and conditions, to develop test procedures to measure the
energy efficiency, energy use, or estimated annual operating cost of
each covered product. (42 U.S.C. 6293) The test procedures for GSFL and
IRL appear at title 10 Code of Federal Regulations (CFR) part 430,
subpart B, appendix R.
EPCA provides criteria for prescribing new or amended energy
conservation standards for covered products. As indicated above, any
new or amended standard for a covered product under Part A must be
designed to achieve the maximum improvement in energy efficiency that
is technologically feasible and economically justified (42 U.S.C.
6295(o)(2)(A)), although EPCA precludes DOE from adopting any standard
that would not result in significant conservation of energy. (42 U.S.C.
6295(o)(3)(B)) Moreover, DOE may not prescribe a standard: (1) For
certain products, including GSFL and IRL, if no test procedure has been
established for that type (or class) of product, or (2) if DOE
determines by rule that the standard would not result in significant
conservation of energy or is not technologically feasible or
economically justified. (42 U.S.C. 6295(o)(3)) The Act also provides
that, in deciding whether a standard is economically justified, DOE
must determine whether the benefits of the standard exceed its burdens.
(42 U.S.C. 6295(o)(2)(B)(i)) DOE must do so after receiving comments on
the proposed standard and by considering, to the greatest extent
practicable, the following seven factors:
(1) The economic impact of the standard on manufacturers and
consumers of the products subject to the standard;
(2) The savings in operating costs throughout the estimated average
life of the covered products in the type (or class) compared to any
increase in the price, initial charges, or maintenance expenses for the
covered products that are likely to result from the imposition of the
standard;
[[Page 16925]]
(3) The total projected amount of energy savings likely to result
directly from the imposition of the standard;
(4) Any lessening of the utility or the performance of the covered
products likely to result from the imposition of the standard;
(5) The impact of any lessening of competition, as determined in
writing by the Attorney General, that is likely to result from the
imposition of the standard;
(6) The need for national energy conservation; and
(7) Other factors the Secretary considers relevant. (42 U.S.C.
6295(o)(2)(B)(i)(I)-(VII))
Furthermore, EPCA contains what is commonly known as an ``anti-
backsliding'' provision, which mandates that the Secretary not
prescribe any amended standard that either increases the maximum
allowable energy use or decreases the minimum required energy
efficiency of a covered product. (42 U.S.C. 6295(o)(1)) Also, the
Secretary may not prescribe an amended or new standard if interested
persons have established by a preponderance of evidence that the
standard is likely to result in the unavailability in the United States
of any covered product type (or class) with performance characteristics
(including reliability), features, sizes, capacities, and volumes that
are substantially the same as those generally available in the United
States. (42 U.S.C. 6295(o)(4))
Under 42 U.S.C. 6295(o)(2)(b)(iii), EPCA establishes a rebuttable
presumption that a standard is economically justified if the Secretary
finds that ``the additional cost to the consumer of purchasing a
product complying with an energy conservation standard level will be
less than three times the value of the energy, and as applicable,
water, savings during the first year that the consumer will receive as
a result of the standard, as calculated under the applicable test
procedure. * * *''
Under 42 U.S.C. 6295(q)(1), EPCA sets forth additional requirements
applicable to promulgating a standard for a type or class of covered
product that has two or more subcategories. DOE must specify a
different standard level than that which applies generally to such type
or class of products ``for any group of covered products which have the
same function or intended use, if * * * products within such group--(A)
consume a different kind of energy from that consumed by other covered
products within such type (or class); or (B) have a capacity or other
performance-related feature which other products within such type (or
class) do not have and such feature justifies a higher or lower
standard'' than applies or will apply to the other products. Id. In
determining whether a performance-related feature justifies such a
different standard for a group of products, DOE must ``consider such
factors as the utility to the consumer of such a feature'' and other
factors DOE deems appropriate. Id. Any rule prescribing such a standard
must include an explanation of the basis on which such higher or lower
level was established. (42 U.S.C. 6295(q)(2))
Federal energy efficiency requirements generally supersede State
laws or regulations concerning energy conservation testing, labeling,
and standards. (42 U.S.C. 6297(a)-(c)) DOE can, however, grant waivers
of Federal preemption for particular State laws or regulations, in
accordance with the procedures and other provisions of section 327(d)
of the Act. (42 U.S.C. 6297(d))
C. Background
1. Current Standards
EPCA prescribes the energy conservation standards that are
currently applicable to specified types of GSFL and IRL. More
specifically, the standards set efficacy levels and color rendering
index (CRI) levels for certain GSFL, and efficacy standards for certain
IRL. (42 U.S.C. 6295(i)(1); 10 CFR 430.32(n)) These statutory standard
levels are set forth in Table II.1 and Table II.2 below.
Table II.1--EPCA Standard Levels for GSFL
----------------------------------------------------------------------------------------------------------------
Minimum
Lamp type Nominal lamp Minimum CRI average
wattage efficacy lm/W
----------------------------------------------------------------------------------------------------------------
4-Foot Medium Bipin............................................. > 35W 69 75.0
<= 35W 45 75.0
2-Foot U-Shaped................................................. > 35W 69 68.0
<= 35W 45 64.0
8-Foot Slimline................................................. > 65W 69 80.0
<= 65W 45 80.0
8-Foot High Output.............................................. > 100W 69 80.0
<= 100W 45 80.0
----------------------------------------------------------------------------------------------------------------
Table II.2--EPCA Standard Levels for IRL
------------------------------------------------------------------------
Min. avg.
Wattage efficacy lm/
W
------------------------------------------------------------------------
40-50..................................................... 10.5
51-66..................................................... 11.0
67-85..................................................... 12.5
86-115.................................................... 14.0
116-155................................................... 14.5
156-205................................................... 15.0
------------------------------------------------------------------------
2. History of Standards Rulemaking for General Service Fluorescent
Lamps, Incandescent Reflector Lamps, and General Service Incandescent
Lamps
As stated above, EPCA established energy conservation standards for
certain types of GSFL and IRL. (42 U.S.C. 6295(i)(1)) EPCA also
requires that DOE conduct two cycles of rulemakings to determine
whether to amend these standards, and that DOE initiate a rulemaking to
determine whether to adopt standards for additional types of GSFL. (42
U.S.C. 6295(i)(3)-(5)) This rulemaking addresses both the amendment of
existing GSFL and IRL standards, and the adoption of standards for
additional GSFL.
DOE initiated this rulemaking on May 31, 2006, by publishing on its
Web site its ``Rulemaking Framework Document for General Service
Fluorescent Lamps, Incandescent Reflector Lamps, and General Service
Incandescent Lamps.'' \4\ DOE also published a notice in the Federal
Register announcing the availability of the framework document
[[Page 16926]]
and a public meeting on the document, which requested public comments
on the matters raised in the framework document. 71 FR 30834 (May 31,
2006). The framework document described the procedural and analytical
approaches that DOE anticipated using to evaluate energy conservation
standards for the products covered by this rulemaking, and it
identified various issues to be resolved in conducting the rulemaking.
---------------------------------------------------------------------------
\4\ A PDF copy of the framework document published in May 2006
is available at: https://www/eere.energy.gov/buildings/appliance_standards/residential/pdfs/lamps_framework.pdf.
---------------------------------------------------------------------------
DOE held the public meeting on June 15, 2006, to present the
framework document, describe the analyses it planned to conduct during
the rulemaking, seek comments from stakeholders on these subjects, and
inform stakeholders about and facilitate their involvement in the
rulemaking. At the public meeting and during the comment period, DOE
received many comments that both addressed issues raised in the
framework document and identified additional issues relevant to this
rulemaking.
As the title of the framework document indicates, DOE initially
included general service incandescent lamps (GSIL) in this rulemaking.
This was done to address the requirement then present in section
325(i)(5) of EPCA that DOE consider energy conservation standards for
additional GSIL. (42 U.S.C. 6295(i)(5)) However, section
321(a)(3)(A)(iii) of the Energy Independence and Security Act of
2007,\5\ (EISA 2007) amended EPCA to remove this requirement, thereby
eliminating DOE's authority to regulate additional GSIL. Instead,
section 321(a)(3)(A)(ii) of EISA 2007 amended EPCA to prescribe energy
conservation standards for GSIL. Therefore, this rulemaking no longer
addresses GSIL.
---------------------------------------------------------------------------
\5\ Pub. L. 110-140 (enacted Dec. 19, 2007).
---------------------------------------------------------------------------
DOE issued the ANOPR for this rulemaking on February 21, 2008 and
published it in the Federal Register on March 13, 2008. 73 FR 13620. On
February 22, 2008, DOE posted the ANOPR, as well as the complete ANOPR
technical support document (TSD), on its Web site.\6\ The TSD includes
the results of the following DOE preliminary analyses: (1) Market and
technology assessment; (2) screening analysis; (3) engineering
analysis; (4) energy use characterization; (5) product price
determinations; (6) life-cycle cost (LCC) and pay back period (PBP)
analyses; (7) shipments analysis; and (8) national impact analysis
(NIA).
---------------------------------------------------------------------------
\6\ PDF copies of the ANOPR and ANOPR TSD published in March
2008 are available at: https://www1.eere.energy.gov/buildings/appliance_standards/residential/incandescent_lamps_anopr.html.
---------------------------------------------------------------------------
In the March 2008 ANOPR, DOE invited comment in particular on the
following issues: (1) Consideration of additional GSFL; (2) amended
definitions; (3) product classes; (4) scaling to product classes not
analyzed; (5) screening of design options; (6) lamp operating hours;
(7) energy consumption of GSFL; (8) LCC calculation; (9) installation
costs; (10) base-case market-share matrices; (11) shipment forecasts;
(12) base-case and standards-case forecasted efficiencies; (13) trial
standard levels; and (14) period for lamp production equipment
conversion. 73 FR 13620, 13686-88 (March 13, 2008).
In the ANOPR, DOE described and sought comment on the analytical
framework, models, and tools (e.g., LCC and national energy savings
(NES) spreadsheets) DOE was using to analyze the impacts of energy
conservation standards for GSFL and IRL. DOE held a public meeting in
Washington, DC, on March 10, 2008, to present the methodologies and
results for the March 2008 ANOPR analyses. At this meeting,
stakeholders recommended that DOE revise certain analyses in the energy
conservation standard ANOPR and the scope of covered products. DOE
later received written comments from the National Electrical
Manufacturers Association (NEMA). In addition, DOE received a joint
comment from several stakeholders. The Joint Comment was submitted by
the American Council for an Energy Efficient Economy (ACEEE), Alliance
to Save Energy (ASE), Appliance Standards Awareness Project (ASAP),
National Consumer Law Center, National Grid, Natural Resources Defense
Council (NRDC), Northeast Energy Efficiency Partnerships (NEEP),
Northwest Power and Conservation Council (NPCC), Pacific Gas and
Electric Company (PG&E), and Vermont Energy Investment Corporation. The
comments received since publication of the March 2008 ANOPR and during
the March 10, 2008 public meeting have contributed to DOE's proposed
resolution of the issues in this rulemaking. This NOPR quotes,
summarizes, and responds to the issues raised in these public comments.
(A parenthetical reference at the end of a quotation or paraphrase
provides the location of the item in the public record.)
Subsequent to the public meeting and at NEMA's request, DOE and
NEMA met on June 26, 2008 to discuss appropriate lumens per watt (lm/W)
standards for high correlated color temperature (CCT) fluorescent
lamps. (DOE, No. 27) \7\ NEMA subsequently submitted a written comment
documenting its presentation at this meeting (hereafter the ``June 2008
NEMA meeting''). (NEMA, No. 26) Topics covered at this meeting included
the expected market share of high-CCT fluorescent lamps, appropriate
efficacy standard scaling factors for GSFL with a CCT greater than
4,500K but less than or equal to 7,000K, and coverage of GSFL with a
CCT greater than 7,000K. See sections III.C.2, V.A.1.c, and V.C.7.a.i
of this notice for a more detailed discussion of NEMA's comments at
this meeting, as well as DOE's responses.
---------------------------------------------------------------------------
\7\ A notation in the form ``DOE, No. 27 '' identifies a written
comment that DOE has received and has included in the docket of this
rulemaking or a written docket submission. This particular notation
refers to a comment: (1) Submitted by DOE; and (2) in document
number 27 in the docket of this rulemaking.
---------------------------------------------------------------------------
III. Issues Affecting the Scope of This Rulemaking
A. Additional General Service Fluorescent Lamps for Which DOE Is
Proposing Standards
1. Scope of EPCA Requirement That DOE Consider Standards for Additional
Lamps
As discussed above, EPCA established energy conservation standards
for certain general service fluorescent lamps, (42 U.S.C. 6295(i)(1))
and directed the Secretary to ``initiate a rulemaking procedure to
determine if the standards in effect for fluorescent lamps * * * should
be amended so that they would be applicable to additional general
service fluorescent [lamps]. * * *'' (42 U.S.C. 6295(i)(5)) Thus, DOE
must consider whether to adopt energy efficacy standards for additional
GSFL beyond those already covered by the statutorily-prescribed
standards.
The March 2008 ANOPR notes that a wide variety of GSFL are not
currently covered by energy conservation standards, and they are
potential candidates for coverage under 42 U.S.C. 6295(i)(5). 73 FR
13620, 13628-29 (March 13, 2008). However, the requirement that DOE
consider additional GSFL appears to conflict with EPCA's definitions of
key terms, which it might be argued would preclude coverage of
additional GSFL. As explained below, DOE has carefully considered these
statutory provisions and is interpreting them in a manner so as to give
effect to the requirement to consider additional GSFL.
Specifically, the conflict is centered on the statutory definition
of ``general service fluorescent lamp.'' As set forth above and
repeated here for purposes of this discussion, ``general service
fluorescent lamp'' is defined in 42
[[Page 16927]]
U.S.C. 6291(30)(B) to mean: ``fluorescent lamps which can be used to
satisfy the majority of fluorescent lamp applications, but does not
include any lamp designed and marketed for the following nongeneral
lighting applications: [list of eight exclusions not relevant to the
present issue].''
As such, the term ``general service fluorescent lamp'' appears to
be defined by reference to the term ``fluorescent lamp,'' which is also
defined under the statute as follows: ``Except as provided in
subparagraph (E), the term `fluorescent lamp' means a low pressure
mercury electric-discharge source in which a fluorescing coating
transforms some of the ultraviolet energy generated by the mercury
discharge into light, including only the following: (i) Any straight-
shaped lamp (commonly referred to as 4-foot medium bi-pin lamps) with
medium bi-pin bases of nominal overall length of 48 inches and rated
wattage of 28 or more. (ii) Any U-shaped lamp (commonly referred to as
2-foot U-shaped lamps) with medium bi-pin bases of nominal overall
length between 22 and 25 inches and rated wattage of 28 or more. (iii)
Any rapid start lamp (commonly referred to as 8-foot high output lamps)
with recessed double contact bases of nominal overall length of 96
inches and 0.800 nominal amperes, as defined in ANSI C78.1-1978 and
related supplements. (iv) Any instant start lamp (commonly referred to
as 8-foot slimline lamps) with single pin bases of nominal overall
length of 96 inches and rated wattage of 52 or more, as defined in ANSI
C78.3-1978 (R1984) and related supplement ANSI C78.3a-1985.'' 42 U.S.C.
6291(30)(A) (Emphasis added).
The term ``fluorescent lamp'' is, by its terms, limited to four
enumerated types of lamps. Further, the four types of lamps set forth
in the definition of ``fluorescent lamp'' have corresponding energy
conservation standards prescribed under the statute at 42 U.S.C.
6295(i)(1)(B). Given that the statutory definition of ``fluorescent
lamp'' is limited to four specified types of lamps and that the statute
prescribes standards for those four lamps, it is not possible to give
effect to the congressional directive to consider establishing
standards for additional GSFL if the term ``general service fluorescent
lamp'' is limited by the definition of ``fluorescent lamp.''
Given this identified conflict, DOE has determined that there is an
inherent ambiguity in the statute in terms of how these provisions are
to be implemented. In order to move forward with this standards
rulemaking, DOE must resolve this legal conundrum.
Although there is no legislative history to clarify this point,
there are a number of reasons to believe that Congress did not intend
to strictly limit consideration of ``additional'' GSFL. First, Congress
adopted both the relevant statutory definitions and the ``additional''
lamps requirement as part of Energy Policy Act of 1992 (EPACT 1992;
Pub. L. 102-486). DOE does not believe Congress would intentionally
insert a legislative provision that, when read in conjunction with a
simultaneously added provision, amounts to a nullity. Second, reading
the definition to preclude consideration of additional GSFL would run
counter to the energy-saving purposes of EPCA. It is reasonable to
assume that Congress would not have intended to limit energy
conservation standards to only those technologies available in 1992,
but would instead cast a broader net that would achieve energy
efficiency improvements in lighting products incorporating newer
technologies.
Consequently, DOE interprets these statutory provisions such that,
in defining ``general service fluorescent lamp,'' Congress intended to
incorporate the term ``fluorescent lamp'' in a broader, more generic
sense. DOE understands that the industry routinely refers to
``fluorescent lamps'' as including products in addition to the four
enumerated in the statutory definition of that term. In fact, in the
March 2008 ANOPR, DOE presented its plan for including additional GSFL
for coverage, and did not receive adverse comment. Thus, DOE has
determined to read the statutory definition of ``general service
fluorescent lamp'' in this broader context.
For these reasons, and for the additional reasons set forth in the
March 2008 ANOPR,\8\ DOE views ``additional'' GSFL, as that term is
used in 42 U.S.C. 6295(i)(5), as lamps that: (1) Meet the technical
portion of the statutory definition of ``fluorescent lamp'' (i.e., a
low-pressure mercury electric-discharge source in which a fluorescing
coating transforms some of the ultraviolet energy generated by the
mercury discharge into light) (42 U.S.C. 6291(30)(A)) without
restriction to the four specified lamp types in that definition; (2)
can be used to satisfy the majority of fluorescent lighting
applications (42 U.S.C. 6291(30)(B)); (3) are not within the exclusions
from the definition of GSFL specified in 42 U.S.C. 6291(30)(B); and (4)
are ones for which EPCA does not prescribe standards. Such an
interpretation does not alter the existing statutory provision or
standards for ``fluorescent lamps,'' but it does permit DOE to give
effect to section 6295(i)(5) of EPCA by expanding the universe of GSFL
open to potential regulation. The scope of coverage reflected in this
NOPR is in keeping with the interpretation outlined above.
---------------------------------------------------------------------------
\8\ 73 FR 13620, 13629 (March 13, 2008).
---------------------------------------------------------------------------
2. Identification of the Additional Lamps for Which DOE Proposes
Standards
As set forth more fully in the March 2008 ANOPR, DOE took the
following three steps in terms of identifying additional GSFL for which
standard setting might be appropriate. DOE first conducted a
comprehensive review of the fluorescent lighting market in order to
identify particular types of lamps that meet the four criteria above to
determine the additional GSFL for which DOE would consider adopting
standards. Second, DOE examined each lamp type to determine potential
energy savings that energy conservation standards would bring for that
lamp. Third, DOE further evaluated selected lamps to determine if such
standards would be technologically feasible and economically justified.
In carrying out these steps before issuance of the March 2008 ANOPR,
DOE considered comments on these issues that it had received
previously. 73 FR 13620, 13629-30 (March 13, 2008).
In implementing the first of these three steps, DOE identified the
following categories of GSFL as meeting the four criteria for
consideration as ``additional'' GSFL under 42 U.S.C. 6295(i)(5):
4-foot, medium bipin (MBP), straight-shaped lamps, rated
wattage of < 28W;
2-foot, medium bipin, U-shaped lamps, rated wattage of <
28W;
8-foot, recessed double contact (RDC), rapid start, high
output (HO) lamps not defined in ANSI Standard C78.1-1991 \9\ or with
current other than 0.800 nominal amperes;
---------------------------------------------------------------------------
\9\ Titled ``for Fluorescent Lamps--Rapid-Start Types--
Dimensional and Electrical Characteristics.''
---------------------------------------------------------------------------
8-foot single pin (SP), instant start, slimline lamps with
a rated wattage >= 52, not defined in ANSI Standard C78.3-1991 \10\;
---------------------------------------------------------------------------
\10\ Titled ``for Fluorescent Lamps--Instant-Start and Cold-
Cathode Types--Dimensional and Electrical Characteristics.''
---------------------------------------------------------------------------
Very high output (VHO) straight-shaped lamps;
T5 \11\ miniature bipin (MiniBP) straight-shaped lamps;
---------------------------------------------------------------------------
\11\ T5, T8, T10, and T12 are nomenclature used to refer to
tubular fluorescent lamps with diameters of 0.625, 1, 1.25, and 1.5
inches, respectively.
---------------------------------------------------------------------------
Additional straight-shaped and U-shaped lamps other than
those listed
[[Page 16928]]
above (e.g., alternate lengths, diameters, or bases); and
Additional fluorescent lamps with alternate shapes (e.g.,
circline, pin-based compact fluorescent lamps (CFL)).
73 FR 13620, 13630 (March 13, 2008).
DOE then assessed the potential energy savings of standards for
these GSFL (second step) and whether candidate standards for those GSFL
would be technologically feasible and economically justified (third
step), in order to determine which GSFL to analyze in depth regarding
whether, and at what levels, standards would be warranted under the
EPCA criteria in 42 U.S.C. 6295(o). DOE's analytical process related to
these additional GSFL categories is discussed generally below.
In a review of 4-foot medium bipin lamps, DOE found that the
current market lacked any products with a rated wattage below 25W.
Therefore, in the March 2008 ANOPR, DOE preliminarily decided not to
extend coverage to 4-foot medium bipin lamps below 25W. In the
following section, DOE discusses its consideration in the March 2008
ANOPR of possibly regulating lamps with rated wattages less than 28W
and greater than or equal to 25W.
Similar to the 4-foot medium bipin lamps, in the March 2008 ANOPR,
DOE investigated the potential for regulating 2-foot U-shaped lamps
less than 28W. A review of available manufacturer catalogs found no
commercially-available products in that category. Therefore, DOE
concluded that lowering the minimum wattage threshold of 2-foot U-
shaped lamps would likely not result in substantial energy savings and
preliminarily decided not to expand coverage to these lamps.
DOE also considered whether to expand coverage to include VHO
fluorescent lamps. While VHO lamps consume large amounts of energy,
they are commonly used in outdoor applications where high-intensity
discharge (HID) lamps are rapidly gaining market share. Further
research indicated that shipments of VHO T12 lamps are declining
rapidly. Although individually these products have greater per-lamp
energy savings than high output or standard output lamps, the total
energy savings resulting from regulation would be small and would be
expected to decrease over time as these lamps disappear from the
market. Therefore, DOE preliminarily decided not to extend coverage to
VHO lamps.
In the March 2008 ANOPR, DOE also preliminarily decided not to
expand coverage to T5 fluorescent lamps. DOE's initial analysis showed
that T5 lamps currently have a relatively small share of the GSFL
market, and, therefore, have limited potential to contribute to total
energy savings. Although T5 lamps can serve as a substitute for T8 or
T12 lamps, DOE found that T5 lamps tend to have higher efficacy.
Research showed that the highest efficacy 32W 4-foot medium bipin T8
lamp is 95 lm/W, compared to 104 lm/W for a standard output 4-foot
miniature bipin T5 lamps. Thus, DOE stated that excluding T5 lamps from
this rulemaking would be unlikely to undermine any energy savings that
would result from a T12 and T8 standard, even if the standard caused
increased sales of T5 systems
Lastly, DOE preliminarily decided not to extend coverage to
fluorescent lamps that had alternate lengths, diameters, bases, or
shapes (or a combination thereof) than the lamps specifically
mentioned. DOE reasoned that the products it had already selected for
coverage represented the significant majority of the GSFL market, and,
thus, the bulk of the potential energy savings. Furthermore, DOE
tentatively concluded there was limited potential for lamps with
miscellaneous lengths and bases to grow in market share, given the
constraint of fixture lengths and socket compatibility.
After eliminating the lamps aforementioned lamps from further
consideration for the reasons cited above, DOE was left with the
following additional GSFL to consider evaluating in depth for potential
standards:
4-foot, medium bipin lamps with wattages >= 25 and < 28;
8-foot, recessed double contact (RDC), rapid start, high
output (HO) lamps not defined in ANSI Standard C78.1-1991
