Energy Conservation Program: Energy Conservation Standards for General Service Fluorescent Lamps and Incandescent Reflector Lamps, 13620-13689 [E8-4018]
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Federal Register / Vol. 73, No. 50 / Thursday, March 13, 2008 / Proposed Rules
DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket No. EE–2006–STD–0131]
RIN 1904–AA92
Energy Conservation Program: Energy
Conservation Standards for General
Service Fluorescent Lamps and
Incandescent Reflector Lamps
Office of Energy Efficiency and
Renewable Energy, Department of
Energy.
ACTION: Advance notice of proposed
rulemaking.
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AGENCY:
SUMMARY: The Energy Policy and
Conservation Act authorizes the
Department of Energy (DOE) to establish
energy conservation standards for
various consumer products and
commercial and industrial equipment,
including general service fluorescent
lamps and incandescent reflector lamps,
for which DOE determines that energy
conservation standards would be
technologically feasible and
economically justified, and would result
in significant energy savings. In this
advance notice of proposed rulemaking
(ANOPR), DOE is considering
amendment of existing energy
conservation standards for general
service fluorescent lamps and
incandescent reflector lamps, and it is
also considering whether standards
should apply to additional general
service fluorescent lamps. In addition,
this ANOPR considers various
amendments to lighting-related
definitions DOE previously developed
and incorporated into the CFR.
DATES: DOE held a public meeting in
Washington, DC, that began on March
10, 2008. The agenda for the public
meeting covered first the concurrent test
procedure rulemaking for general
service fluorescent, incandescent
reflector, and general service
incandescent lamps (see proposal in
today’s Federal Register), and then this
energy conservation standards
rulemaking for these lighting products.
DOE began accepting comments, data,
and information regarding the ANOPR
at the public meeting and will continue
to accept comments until, but no later
than April 14, 2008. See section V,
‘‘Public Participation,’’ of this ANOPR
for details.
ADDRESSES: The public meeting was
held at the U.S. Department of Energy,
Forrestal Building, Room 8E–089, 1000
Independence Avenue, SW.,
Washington, DC 20585–0121.
Any comments submitted must
identify the ANOPR for Lighting
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Standards, and provide the docket
number EE–2006–STD–0131 and/or
Regulatory Information Number (RIN)
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–0131 and/or RIN number
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, 6th
Floor, 950 L’Enfant Plaza, SW.,
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 V 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, 6th Floor, 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. Please call Ms.
Brenda Edwards at (202) 586–2945 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.
Ms. Francine Pinto or Mr. Eric Stas,
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. Telephone:
(202) 586–9507. E-mail:
Francine.Pinto@hq.doe.gov or
Eric.Stas@hq.doe.gov.
For information on how to submit or
review public comments and on how to
participate in the public meeting,
contact Ms. Brenda Edwards, U.S.
Department of Energy, Office of Energy
Efficiency and Renewable Energy,
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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. Introduction
A. Purpose of the Advance Notice of
Proposed Rulemaking
B. Authority
C. Summary of Proposed Coverage for
Lamps
D. Overview of the Analyses Performed
1. Engineering Analysis and Product Price
Determination
2. Energy-Use Characterization
3. Life-Cycle Cost and Payback Period
Analyses
4. National Impact Analysis
E. Background
1. History of Standards Rulemaking for
General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps
2. Energy Independence and Security Act
of 2007
a. General Service Fluorescent Lamps
b. General Service Incandescent Lamps
c. Incandescent Reflector Lamps
d. Off Mode and Standby Mode Energy
Consumption
3. Test Procedures
II. Consideration Regarding the Scope of
Energy Conservation Standards Coverage
A. Introduction
B. Additional General Service Fluorescent
Lamps Being Considered Under EPCA
Section 325(i)(5)
1. Scope
2. Rationale for Coverage
3. Analysis of Individual General Service
Fluorescent Lamps
C. Amended Definitions
1. ‘‘Rated Wattage’’
2. ‘‘Colored Fluorescent Lamp’’
III. Energy Conservation Standards Analyses
for Fluorescent and Incandescent
Reflector Lamps
A. Market and Technology Assessment
1. Market Assessment
2. Product Classes
a. General Service Fluorescent Lamps
i. Class Setting Factors
ii. Other Potential Class-setting Factors
Considered, But Not Adopted
iii. Product Class Results
b. Incandescent Reflector Lamps
i. Class Setting Factors
ii. Other Potential Class-setting Factors
Considered, But Not Adopted
iii. Product Class Results
3. Technology Assessment
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
B. Screening Analysis
1. Technology Options Screened Out
a. Multi-photon Phosphors
b. Microcavity Filaments
c. Novel Filament Materials
d. Crystallite Filament Coatings
e. Luminescent Gases
f. Non-Tungsten-Halogen Regenerative
Cycles
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g. Infrared Phosphor Glass Coatings
h. Integrally Ballasted Low Voltage Lamps
i. Trihedral Corner Reflectors
2. Design Options Considered Further in
Analysis
C. Engineering Analysis
1. Approach
2. Representative Product Classes and
Baseline Lamps
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
3. Lamp and Lamp-and-Ballast Designs
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. Candidate Standard Levels
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Engineering Analysis Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
6. Scaling to Product Classes Not Analyzed
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
D. Energy-Use Characterization
1. Operating Hours
2. Results
E. Product Price Determination
1. Introduction and Methodology
a. Overview
b. General Service Fluorescent Lamps
c. Incandescent Reflector Lamps
2. End-User Price Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
3. Sales Taxes
F. Rebuttable Presumption Payback Periods
G. Life-Cycle Cost and Payback Period
Analyses
1. Approach
2. Life-Cycle Cost Inputs
a. Total Installed Cost Inputs
b. Operating Cost, Replacement Cost, and
Residual Value Inputs
i. Electricity Prices
ii. Lamp Lifetime
iii. Discount Rates
iv. Analysis Period
v. Effective Date
3. Payback Period Inputs
4. Lamp Purchasing Events
5. Life-Cycle Cost and Payback Period
Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
H. Shipment Analysis
1. Historical Shipments
2. Shipment Projections to 2011 and
Calculations of Stock of Lamps in 2011
3. Base-Case and Standards-Case Shipment
Forecasts to 2042
4. Market-Share Matrices
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Shipment Forecast Results
I. National Impact Analysis
1. Approach
2. Base-Case and Standards-Case
Forecasted Efficacies
3. National Impact Analysis Inputs
4. National Impact Analysis Results
J. Life-Cycle Cost Subgroup Analysis
K. Manufacturer Impact Analysis
1. Cumulative Regulatory Burden
2. Preliminary Results of the Manufacturer
Impact Analysis
a. Retooling Equipment to Produce
Standards-Compliant Lamps
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b. Availability of Materials to Produce
Standards-Compliant Lamps
c. Maintaining Product Availability and
Features
L. Utility Impact Analysis
M. Employment Impact Analysis
N. Environmental Assessment
O. Regulatory Impact Analysis
IV. Candidate Energy Conservation Standards
Levels
V. Public Participation
A. Submission of Comments
B. Issues on Which DOE Seeks Comment
1. Consideration of Additional General
Service Fluorescent Lamps
2. Amended Definitions
3. Product Classes
4. Scaling to Product Classes Not Analyzed
5. Screening of Design Options
6. Operating Hours
7. General Service Fluorescent Energy
Consumption
8. Life-Cycle Cost Calculation
9. Installation Costs
10. Base-Case Market-Share Matrices in
2012
11. Shipment Forecasts
12. Base-Case and Standards-Case
Forecasted Efficiencies
13. Trial Standard Levels
14. Lamp Production Equipment
Conversion Timeframe
VI. Regulatory Review and Procedural
Requirements
VII. Approval of the Office of the Secretary
Acronyms and Abbreviations
AEO Annual Energy Outlook
ANOPR advance notice of proposed
rulemaking
ANSI American National Standards
Institute
BEF ballast efficacy factor
BF ballast factor
BR bulged reflector (reflector lamp
shape)
CBECS Commercial Buildings Energy
Consumption Survey
CCT correlated color temperature
CEC California Energy Commission
CEE Consortium for Energy Efficiency
CFR Code of Federal Regulations
CFL compact fluorescent lamp
CIE International Commission on
Illumination
CO2 carbon dioxide
CRI color rendering index
CSL candidate standard level
DOE U.S. Department of Energy
E26 Medium screw-base (incandescent
lamp base type)
EIA Energy Information
Administration
EISA 2007 Energy Independence and
Security Act of 2007
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)
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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
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
I–O input-output
IR Infrared
IRL incandescent reflector lamp
K degrees Kelvin
LCC life-cycle cost
Lm lumens
LMC U.S. Lighting Market
Characterization Volume I
Lm/W lumens per watt
MECS Manufacturer Energy
Consumption Survey (MECS)
MIA Manufacturer Impact Analysis
NAICS North American Industry
Classification System
NEEP Northeast Energy Efficiency
Partnership
NEMA National Electrical
Manufacturers Association
NEMS National Energy Modeling
System
NES national energy savings
NIA National Impact Analysis
NOPR notice of proposed rulemaking
NOX nitrogen oxides
NPV net present value
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
R reflector (reflector lamp shape)
RECS Residential Energy Consumption
Survey
SBA Small Business Administration
SO2 sulfur dioxide
T5, T8, T10, T12 tubular fluorescent
lamps, diameters of 0.625, 1, 1.25 or
1.5 inches, respectively
TSD technical support document
TSL trial standard level
U.S.C. United States Code
UV ultraviolet
V volts
W watts
I. Introduction
This advance notice of proposed
rulemaking (ANOPR) serves two
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primary purposes: (1) Providing a
preliminary determination regarding
additional general service fluorescent
lamps (GSFL) that DOE is considering
for coverage and standards; and (2)
initiating rulemaking to consider
amending DOE’s energy conservation
standards related to coverage of GSFL
and incandescent reflector lamps (IRL).
The ANOPR is intended to help DOE
satisfy two statutory directives, namely
to make a preliminary determination
representing the Secretary’s initial
assessment of additional GSFL to
consider for energy conservation
standards under section 325(i)(5) of the
Energy Policy and Conservation Act
(hereinafter ‘‘EPCA’’) (42 U.S.C.
6295(i)(5)), and to conduct an energy
conservation standards rulemaking for
general service fluorescent lamps and
incandescent reflector lamps under
Section 325(i)(3) of EPCA (42 U.S.C.
6295(i)(3)). Because the preliminary
determination for certain additional
lamps is positive, DOE is including such
lamps in the ANOPR analyses for
standard-setting purposes.
DOE welcomes comment on any
relevant issue related to this ANOPR.
However, throughout this Federal
Register notice, DOE identifies specific
areas and issues on which it specifically
invites comment. These critical issues
are summarized in section V.E of this
notice.
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A. Purpose of the Advance Notice of
Proposed Rulemaking
The purpose of the ANOPR is to
provide interested parties with an
opportunity to comment on:
1. The preliminary determination of
additional GSFL being considered for
energy conservation standards;
2. The product classes DOE is
planning to analyze in this rulemaking;
3. The analytical framework,
methodology, inputs, and models (e.g.,
life-cycle cost (LCC) and national
impact analysis (NIA) spreadsheets) that
DOE developed to evaluate energy
conservation standards for GSFL and
IRL (collectively referred to in this
ANOPR as the ‘‘two categories of
lamps’’);
4. The analyses conducted for the
ANOPR, including the preliminary
results for the engineering analysis,
product price determination, LCC and
payback period (PBP) analysis, and NIA.
These analyses are summarized in this
ANOPR and presented in detail in the
ANOPR technical support document
(TSD), Energy Conservation Standards
for General Service Fluorescent Lamps
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and Incandescent Reflector Lamps,1
published in tandem with this ANOPR;
and
5. The candidate standard levels
(CSLs) that DOE developed for the
ANOPR.
B. Authority
Title III of EPCA (42 U.S.C. 6291 et
seq.) sets forth a variety of provisions
designed to improve energy efficiency.
Part B of Title III (42 U.S.C. 6291–6309)
established the ‘‘Energy Conservation
Program for Consumer Products Other
Than Automobiles,’’ which includes
major household appliances.
Subsequent amendments expanded
Title III of EPCA to include additional
consumer products and certain
commercial and industrial equipment,
including certain fluorescent and
incandescent lamps—the products that
are the focus of this document. In
particular, amendments to EPCA in the
Energy Policy Act of 1992 (EPACT
1992), P.L. 102–486, established energy
conservation standards for certain
classes of GSFL and IRL, and authorized
DOE to amend these standards if such
amendments were warranted. (42 U.S.C.
6291(1), 6295(i)(1) and (3)–(4)) The
same EPACT 1992 amendments to
EPCA also authorized DOE to adopt
standards for additional GSFL and
general service incandescent lamps
(GSIL), if such additional standards
were warranted. (42 U.S.C. 6295(i)(5))
Subsequent amendments to EPCA in the
Energy Independence and Security Act
of 2007 (EISA 2007), P.L. 110–140,
amended the existing energy
conservation standards for IRL and
removed DOE’s authority under 42
U.S.C. 6295(i)(5) to adopt standards for
additional GSIL.
Before DOE establishes any new or
amended energy conservation
standards, it must first solicit public
comments on a proposed standard.
EPCA, as amended, specifies that any
new or amended energy conservation
standard that DOE prescribes for
consumer products shall be designed to
‘‘achieve the maximum improvement in
energy efficiency * * * which the
Secretary [of Energy] determines is
technologically feasible and
economically justified.’’ (42 U.S.C.
6295(o)(2)(A)) Moreover, EPCA states
that the Secretary of Energy (the
Secretary) may not establish an
amended standard if such standard
would not result in ‘‘significant
conservation of energy,’’ or ‘‘is not
1 To view the technical support document for this
rulemaking, visit DOE’s website at: https://
www.eere.energy.gov/buildings/
appliance_standards/residential/
incandescent_lamps.html.
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technologically feasible or economically
justified.’’ (42 U.S.C. 6295(o)(3)(B)) To
determine whether a proposed standard
is economically justified, DOE must,
after receiving comments on the
proposed standard, determine whether
the benefits of the standard exceed its
burdens to the greatest extent
practicable, weighing the following
seven statutory factors:
(1) The economic impact of the
standard on manufacturers and
consumers of the product subject to the
standard;
(2) The savings in operating costs
throughout the estimated average life of
the covered product in the type (or
class) compared to any increase in the
price, initial charges, or maintenance
expenses for the covered product that
are likely to result from the imposition
of the standard;
(3) The total projected amount of
energy savings (or, as applicable, water
savings) likely to result directly from the
imposition of the standard;
(4) Any lessening of the utility or the
performance of the covered product
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))
C. Summary of Proposed Coverage for
Lamps
DOE’s regulations currently set energy
efficiency standards for certain classes
of general service fluorescent lamps and
incandescent reflector lamps. 10 CFR
430.32(n). However, section 325(i)(5) of
EPCA directs the Secretary of Energy to
consider whether the standards in effect
for GSFL should be amended so as to
apply to ‘‘additional general service
fluorescent lamps.’’ (42 U.S.C.
6295(i)(5)). Accordingly, in section II of
this notice, DOE presents its
preliminary determination regarding
additional lamps that may be
considered as part of the standards
rulemaking. Section II provides a
summary of DOE’s authority under
EPCA to consider additional lamps for
coverage. In addition, because the
preliminary determination was positive,
section II also presents, by lamp type,
the additional lamps for which DOE
intends to consider setting standards.
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D. Overview of the Analyses Performed
As noted above, EPCA authorizes
DOE to consider establishing or
amending energy conservation
standards for various consumer
products and commercial and industrial
equipment, including the two categories
of lamps that are the subject of this
ANOPR. For each of these products,
DOE conducted key technical analyses
for this ANOPR in the following areas:
(1) Engineering; (2) energy-use
characterization; (3) product price
determination; (4) LCC and PBP
analyses; and (5) NIA. DOE performed a
separate set of the requisite analyses for
each of the two categories of lamps
examined in this rulemaking. This
ANOPR presents the methodology and
results of each of these analyses (first an
overview, followed by a more in-depth
discussion).
For each type of analysis, Table I.1
identifies the sections in this document
that summarize the methodologies, key
inputs, and assumptions for the
analysis. In addition, DOE conducted
several other analyses that either
support the five analyses discussed
above or are preliminary analyses that
will be expanded upon during the
NOPR stage of this rulemaking. These
analyses include the market and
technology assessment, a screening
analysis which contributes to the
engineering analysis, and the shipments
analysis which contributes to the
national impacts analysis. In addition to
these analyses, DOE has begun some
preliminary work on the life-cycle cost
subgroup analysis, manufacturer impact
analysis, utility impact analysis,
employment impact analysis,
environmental assessment analysis, and
the regulatory impact analysis for the
ANOPR. These analyses will be
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expanded upon during the NOPR stage
of this rulemaking.
DOE consulted with interested parties
as part of its process for conducting all
of the analyses for the ANOPR and
invites further input from the public on
these topics. While obtaining such input
is the primary purpose of this stage of
the rulemaking, this notice also contains
a synopsis of the preliminary analytical
results. (The TSD contains a complete
set of results.) The purpose of
publishing these preliminary results in
this notice is to: (1) Facilitate public
comment on DOE’s analytical
methodology; (2) illustrate the level of
detail found in the TSD; and (3) invite
comment on the structure and the
presentation of those results. The
preliminary analytical results presented
in the ANOPR are subject to revision
following review and input from the
public.
TABLE I.—1 KEY TECHNICAL ANALYSES CONDUCTED FOR THE ANOPR
ANOPR section and
TSD chapter
Methodology
Key inputs 2
Key assumptions
Engineering Analysis
Design option analysis to establish lamp and lamp-andballast designs at each CSL.
Published catalog data on performance values such as
operating life, rated power,
efficacy, and light output.
Multiply lamp power, or lampand-ballast system power,
by annual operating hours.
Product Price Determination.
Mark up manufacturer price
schedules to develop low,
medium, and high end-user
retail prices.
Future pricing for more efficacious products will reflect
discounts used with today’s
commodity products.
Section III.E and
TSD Chapter 7.
Life-cycle Cost and
Payback Period
Analyses.
Use Monte Carlo simulation in
combination with inputs that
are characterized with probability distributions to establish a distribution of consumer economic impacts
(i.e., LCC savings and
PBP); capture variability in
annual energy use; correlate
electricity prices with building samples to capture regional and sector-specific
variability; use residual
value to account for any remaining life of a lamp at the
end of the analysis period;
report LCC savings by event
type and CSL.
Annual operating hours by
lamp type; lamp, or lamp
and ballast, energy consumption. Energy Information Administration (EIA)
2001, 2002, and 2003 survey data and 2002 U.S.
Lighting Market Characterization Study Vol. I.
Manufacturer price schedules.
Publicly available discount
schedules from State procurement contracts and
other users.
Lamp and ballast installation
costs; annual energy consumption; electricity prices
and future trends; product
lifetimes; discount rates;
consumer ‘‘lamp purchasing
events’’ that cause purchase
of a new lamp / system;
building samples based on
the EIA’s Commercial Building Energy Consumption
Survey (CBECS), EIA’s Residential Energy Consumption
Survey (RECS), and EIA’s
Manufacturing Energy Consumption Survey (MECS)
and the U.S. Lighting Market
Characterization Vol. I
(LMC).
Analysis can be extended to
product classes and efficiency levels for which DOE
did not conduct analysis;
ballast system power varies
linearly by ballast factor.
Data sources are indicative of
current lighting use.
Section III.C and
TSD Chapter 5.
Energy-Use Characterization.
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Section III.D and
TSD Chapter 6.
AEO 2007 basis for energy
Section III.G and
price forecasts and EIA
TSD Chapter 8.
2005 basis for distribution of
electricity prices; average
discount rate is 5.6% for the
residential sector, 6.2% for
the commercial sector, and
7.5% for the industrial sector.
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TABLE I.—1 KEY TECHNICAL ANALYSES CONDUCTED FOR THE ANOPR—Continued
Analysis area
Methodology
Key inputs 2
Key assumptions
National Impact Analysis and Shipment
Analysis.
Forecasts of national GSFL
and IRL costs and energy
consumption; forecast shipments through the use of a
stock accounting model.
DOE used the lamp purchase events to divide the
market into segments—new
construction, replacements,
and early retrofit (only for
GSFL); use multiple scenarios to forecast the technology mix of lamps (and
ballasts) sold at each CSL.
Historical and forecasted annual shipments; lamp stock;
total installed product costs;
unit annual energy consumptions; AEO2007 energy
price forecasts; site-tosource conversion factors
for electricity; discount rate;
HVAC interaction, and rebound effect.
Annual shipments; forecasted
base-case and standardscase efficacy improvements
based on market-share matrices and historical trends;
AEO2007 basis for site-tosource conversion factors;
discount rates are 3 percent
and 7 percent real; future
costs discounted to present
year (2007).
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1. Engineering Analysis and Product
Price Determination
DOE uses the engineering analysis
and product price determination
together to characterize the relationship
between the end-user (consumer) price
and the efficiency of the product DOE
evaluates for standards. The
relationship between the efficiency of a
product and the price of that product is
essential in determining the relative cost
of a more efficient product over its
lifetime (i.e., the purchase price of the
product plus maintenance and operating
costs) as compared to a less efficient
product. This calculation is necessary to
determine whether individual
consumers and the nation will benefit
under an efficiency standard. DOE’s
approach to these analyses is explained
briefly below.
The engineering analysis identifies
the representative baseline lamps, or
lamp-and-ballast combinations, that
DOE will evaluate in the engineering
analysis. The term ‘‘baseline’’ refers to
a lamp (or lamp-and-ballast system) that
has features and technologies typically
found in equipment currently offered
for sale and is representative of the
characteristics of products in a given
product class; for products which are
already subject to an energy efficiency
standard, the baseline unit is typically
one which just meets the current
regulatory requirement.
DOE based the product price
determination for lamps and ballasts on
marked-up manufacturer price
schedules, developing low, medium,
and high end-user retail prices. Section
III.C and Chapter 5 of the TSD discuss
the engineering analysis, and section
2 The data sources cited in this table were the
most current available at the time DOE prepared
this ANOPR. In the future, should more up-to-date
sources become available, DOE will incorporate
those more up-to-date sources into its analysis.
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ANOPR section and
TSD chapter
Sections III.H and
III.I; TSD Chapters 9 and 10.
III.E and Chapter 7 of the TSD discuss
the product price determination in
further detail.
detail on the calculation of operating
hours is available in section III.D.1 of
this notice, and Chapter 6 of the TSD.
2. Energy-Use Characterization
The energy-use characterization
provides estimates of annual energy use
for the two categories of lamps which
are the subject of the present
rulemaking. DOE uses these estimates in
the LCC and PBP analyses, as well as
the NIA. To develop annual energy use
estimates, DOE multiplied annual usage
(in hours per year) by the system power
estimates (in watts). In order to obtain
the inputs for these calculations, DOE
took the following steps. DOE
developed the system power estimates
in the engineering analysis. To derive
annual energy usage, DOE used data
published in the U.S. Lighting Market
Characterization: Volume I (LMC) 3, the
Residential Energy Consumption Survey
(RECS) 4, the Commercial Building
Energy Consumption Survey (CBECS) 5,
and the Manufacturer Energy
Consumption Survey (MECS) 6. More
3. Life-Cycle Cost and Payback Period
Analyses
3 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:
www.eere.energy.gov/buildings/info/documents/
pdfs/lmc_vol1_final.pdf.
4 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.
5 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.
6 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.
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The LCC and PBP analyses determine
the economic impact of potential
standards on individual consumers. The
LCC is the total consumer expense for
a product over the life of the product
(i.e., purchase price plus maintenance
and operating costs). The LCC analysis
compares the LCC of products and
equipment designed to meet possible
energy conservation standards with the
LCC of the products and equipment
likely to be installed in the absence of
standards.
The PBP represents the number of
years required to recover the increase in
purchase price (including installation
cost) of a more-efficient product through
savings in the operating cost of the
product. The PBP is calculated by
dividing the change in total installed
cost due to increased efficacy by the
change in annual operating cost from
increased efficacy. More detail on the
calculation of LCC and PBP is available
in section III.G of this notice and
Chapter 8 of the TSD.
4. National Impact Analysis
The NIA estimates the national energy
savings (NES) and the net present value
(NPV) of total customer costs and
savings expected to result to the nation
from new standards at specific
efficiency levels. Stated another way, in
the NIA, DOE calculates NES and NPV
for any given potential standard level
for each of the two categories of lamps
as the difference between a base-case
forecast (i.e., without new standards)
and the standards-case forecast (i.e.,
with new standards). To start, DOE
determines national annual energy
consumption by multiplying the
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number of units in use which are
expected to be purchased after the
standard takes effect by their average
unit energy consumption. Using that
input, the NES is calculated as the sum
of the cumulative annual energy savings
over the analysis period (2012–2042).7
The national NPV is then calculated
from the discounted net savings each
year for the products purchased over
that same analysis period. The NPV
sums the discounted net savings each
year, consisting of the difference
between the savings in total operating
costs and increases in total installed
costs. More detail on the NIA is
available in sections III.H and III.I of
this notice and Chapters 9 and 10 of the
TSD.
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E. Background
1. History of Standards Rulemaking for
General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps
As noted above, EPCA established
energy conservation standards for GSFL,
requiring that certain fluorescent lamps
meet prescribed minimum efficacy
levels and minimum color rendering
index (CRI) levels. EPCA also
established efficacy standards for
certain IRL. (42 U.S.C. 6295(i)(1)) For
both categories of lamps, EPCA requires
that DOE conduct two cycles of
rulemakings to determine whether the
standards should be amended. (42
U.S.C. 6295(i)(3)–(4)) In addition, EPCA
provides that within 24 months after
U.S. Federal Trade Commission (FTC)
labeling requirements become effective
for GSFL and GSIL, DOE must initiate
a rulemaking to determine if the
standards in effect for fluorescent and
incandescent lamps should be amended
so that they would be applicable to
additional general service fluorescent
lamps. (42 U.S.C. 6295(i)(5)) Within 18
months of initiating the rulemaking,
EPCA further requires DOE to publish a
final rule containing such amendment,
if any. (42 U.S.C. 6295(i)(5)) The FTC
published a final rule establishing
labeling requirements for covered lamps
on May 13, 1994, with an effective date
of May 15, 1995. 59 FR 25176.
In this rulemaking, DOE is addressing
two statutory directives under 42 U.S.C.
6295(i). First, DOE is reviewing and
deciding whether to amend EPCA’s
prescribed energy conservation
standards for GSFL and IRL. (42 U.S.C.
7 DOE uses 31 years as the time period of analysis
for its NES calculations in many of its rulemakings,
in order to enable stakeholders to understand the
relative magnitude of energy savings potentials of
the various products and standard levels being
considered.
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6295(i)(3)) Second, DOE is reviewing
whether energy conservation standards
should be made applicable to additional
GSFL. (42 U.S.C. 6295(i)(5))
To initiate the current energy
conservation standards rulemaking, on
May 31, 2006, DOE published on its
Web site the Rulemaking Framework
Document for General Service
Fluorescent Lamps, Incandescent
Reflector Lamps, and General Service
Incandescent Lamps 8 (‘‘Framework
Document’’), which describes the
procedural and analytical approaches it
anticipated using to evaluate potential
energy conservation standards for these
products.9 DOE published a notice to
announce the availability of the
Framework Document, to schedule a
public meeting on the planned
analytical framework for this
rulemaking (hereafter, ‘‘Public
Meeting’’), and to invite written
comments concerning this analytical
framework. The title of that Federal
Register notice published on May 31,
2006 is ‘‘Energy Conservation Standards
for General Service Fluorescent Lamps,
Incandescent Reflector Lamps, and
General Service Incandescent Lamps:
Notice of Public Meeting and
Availability of the Framework
Document,’’ 10—71 FR 30834.
A Public Meeting was held on June
15, 2006, whose purpose was to discuss
the analyses and issues identified in
various sections of the Framework
Document. At the Public Meeting, DOE
described the different analyses it
would conduct, such as the LCC and
PBP analyses, the methods it planned to
employ when conducting them, and the
relationship among the various
analyses.11 Manufacturers, trade
associations, environmental advocates,
and other interested parties attended the
Public Meeting. Issues discussed
included: (1) The rulemaking’s scope of
coverage and definition of exclusions;
(2) the development of product classes;
(3) lamp-life variation; (4) selection of
representative lamps for analysis and
baseline models; (5) appropriate
methods and sources for developing
8 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.
9 At the time of publication of the Framework
Document, EPCA gave DOE authority to consider
energy conservation standards for additional GSIL
under 42 U.S.C. 6295(i)(5). However, subsequent
amendments to EPCA in EISA 2007 removed that
authority.
10 This rulemaking notice is available at: https://
www.eere.energy.gov/buildings/appliance_
standards/residential/incandescent_lamps.html.
11 PDF copies of the slides and other material
associated with the public meeting are available at:
https://www.eere.energy.gov/buildings/appliance_
standards/residential/lamps_meeting_061506.html.
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end-user price estimates; (6) test
procedures; (7) the methodology for
developing shipment estimates; (8) the
need for systems analysis for GSFL (i.e.,
analyzing a lamp and a ballast in some
scenarios); (9) the impact of higher
efficacy lamps on building space
conditioning loads; and (10) the use of
average electricity rates. Comments
submitted during the Framework
Document comment period elaborated
upon these major issues raised at the
June 2006 Public Meeting. DOE worked
with its contractors to address these
issues in the ANOPR analyses.
Comments received in response to the
Framework Document helped identify
further issues involved in this
rulemaking, and such input contributed
to the overall analytical process. This
document summarizes the comments
DOE has received to date, each with a
parenthetical reference at the end citing
the location of the item in the docket for
this rulemaking (i.e., the public record).
2. Energy Independence and Security
Act of 2007
On December 19, 2007, during the
ANOPR phase of this rulemaking, the
Energy Independence and Security Act
of 2007 was signed into law. In relevant
parts, EISA 2007 amends various EPCA
provisions regarding GSFL, IRL, and
GSIL, and considerably changes the
scope of this rulemaking and the
structure of DOE’s ANOPR analyses.
Accordingly, DOE has incorporated
these changes in both the preliminary
determination and energy conservation
standards analyses contained in this
ANOPR. DOE notes that the relevant
amendments in EISA 2007 are effective
on the date prescribed by the legislation,
not on the effective date of this
rulemaking.
As stated earlier, in May 2006 DOE
published a Framework Document
outlining the procedural and analytical
approaches it anticipated using for this
rulemaking. In addition, DOE received
both written and oral comments in
response to the Framework Document.
Due to the recent amendments to EPCA
in EISA 2007, the scope of coverage and
analytical approach presented in this
ANOPR by necessity differs from that
which was previously outlined in the
Framework Document. In addition,
given these latest legislative
amendments, numerous comments
submitted no longer hold relevance to
this rulemaking and, therefore, are not
addressed in this ANOPR. The
following section summarizes various
sections of EISA 2007 relevant to this
rulemaking and discusses their effect on
the preliminary determination and
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a. General Service Fluorescent Lamps
Regarding GSFL, section 316(b) of
EISA 2007 amends section
321(30)(B)(viii) of EPCA (42 U.S.C.
6291(30)(B)(viii)) by modifying the
definition of ‘‘general service
fluorescent lamp’’ so as to exclude
lamps with a CRI of 87 or greater (as
compared to the previous exclusion for
lamps with a CRI of 82 or greater). This
amendment effectively changes the
scope of coverage of energy
conservation standards for GSFL to now
include additional fluorescent lamps
with a CRI rating from 82 up to 87. The
ANOPR analyses reflect this change in
scope of coverage by analyzing lamp
designs with CRI ratings up through 86
and also by accounting for the national
impacts due to the regulation of this full
range of GSFL.
In addition, section 322(b) of EISA
2007 amends section 325(i) of EPCA (42
U.S.C. 6295(i)) by moving the table of
efficacy requirements for fluorescent
lamps from section 325(i)(1)(A) to
section 325(i)(1)(B). However, every
aspect of the table is identical to the
previous standard as enacted by EPACT
1992, including the product groupings,
and the minimum efficacy and CRI
requirements.12 Therefore, the
amendment in section 322(b) of EISA
2007 results in no substantive change in
DOE’s approach toward GSFL.
Furthermore, the legislation does not
modify the authority to consider
extending coverage to additional GSFL
under section 325(i)(5) of EPCA (42
U.S.C. 6295(i)(5)).
b. General Service Incandescent Lamps
Regarding GSIL, section 321(a)(1) of
EISA 2007 amends section 321(30) of
EPCA (42 U.S.C. 6291(30)) by deleting
the existing definition and inserting a
new definition for ‘‘general service
incandescent lamp.’’ In the context of
redefining ‘‘general service
incandescent lamp,’’ this section also
introduces new definitions for several
lighting-related terms, some of which
were previously defined by DOE in the
CFR. Definitions contained in section
321(a)(1) of EISA 2007 relevant to this
rulemaking include the following terms:
(1) ‘‘Modified spectrum;’’ (2) ‘‘rough
service lamp;’’ (3) ‘‘vibration service
lamp;’’ and (4) ‘‘colored incandescent
lamp.’’ The effect that the incorporation
12 These CRI requirements reflect minimum CRI
standards for covered fluorescent lamps. These
minimum requirements are not affected by the
exclusion in the definition of ‘‘general service
fluorescent lamp’’ for lamps with a CRI of 87 or
greater, as amended by EISA 2007.
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of these definitions has on this
rulemaking will be discussed in section
I.E.2.c of this notice.
In addition, section 321(a)(3) amends
section 325 of EPCA (42 U.S.C. 6295) by
prescribing separate energy
conservation standards and minimum
rated lifetimes for general service
incandescent lamps and modified
spectrum general service incandescent
lamps, with effective dates ranging from
January 1, 2012 to January 1, 2014. In
addition, this section also directs DOE
to conduct two future standards
rulemakings to review and possibly
amend the standards. Furthermore,
although EPACT 1992 gave DOE
authority under 42 U.S.C. 6295(i)(5) to
consider additional general service
incandescent lamps for energy
conservation standards coverage,
section 321(a)(3) of EISA 2007 amends
section 325(i)(5) of EPCA and removes
this provision. Accordingly, DOE has
terminated its preliminary
determination regarding the expansion
of scope to additional GSIL. In addition,
as EISA 2007 prescribed energy
conservation standards for GSIL, this
ANOPR does present any analyses or
candidate standard levels related to
GSIL.
c. Incandescent Reflector Lamps
Regarding IRL, section 322(a)(1) of
EISA 2007 amends section 321(30)(C)(ii)
of EPCA (42 U.S.C. 6291(30)(C)(ii)) by
modifying the portion of the definition
of ‘‘incandescent lamp’’ which is
applicable to reflector lamps so as to
expand that definition to include lamps
with a diameter between 2.25 and 2.75
inches, as well as BPAR-, ER-, and BRshaped lamps. In addition, section
322(a)(2) of EISA 2007 adds new
statutory definitions for a BPAR
incandescent reflector lamp, a BR
incandescent reflector lamp, and an ER
incandescent reflector lamp. These new
statutory definitions supersede the
existing CFR definitions for ‘‘ER
incandescent reflector lamp’’ and ‘‘BR
incandescent reflector lamp’’ that were
developed by DOE (62 FR 29221 (May
29, 1997)), and thereby remove DOE’s
authority to amend these definitions.
In addition, section 322(b) of EISA
2007 amends section 325(i) of EPCA (42
U.S.C. 6295(i)) by moving the table of
minimum average lamp efficacy
requirements for IRL from section
325(i)(1)(A) to section 325(i)(1)(B).
However, as noted above for GSFL,
every aspect of this table of IRL efficacy
requirements is identical to the previous
standard as enacted by EPACT 1992.
Section 322(b) also amends EPCA to
incorporate several new exemptions to
the IRL standards in a newly-adopted
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section 325(i)(1)(C) of EPCA. These
exemptions are as follows: (1) Lamps
rated at 50 watts or less that are ER30,
BR30, BR40, and ER40; (2) lamps rated
at 65 watts that are BR30, BR40, or ER40
lamps; and (3) R20 incandescent
reflector lamps rated 45 watts or less.
DOE notes that the expanded scope of
IRL, as presented in EISA 2007, is
consistent the proposal contained in a
joint comment submitted by the
American Council for an Energy
Efficient Economy (ACEEE) and the
National Electrical Manufacturers
Association (NEMA) regarding this
rulemaking. (ACEEE and NEMA, No. 14
at pp. 3–8) The effective date of energy
conservation standards for BPAR, ER,
and BR shaped lamps as prescribed by
EISA 2007 is January 1, 2008. The
effective date of standards for smaller
diameter IRL as prescribed by EISA
2007 (i.e., diameter of more than 2.25
inches, but not more than 2.75 inches)
is the later of January 1, 2008 or 180
days after the date of enactment of EISA
2007. Given that EISA 2007 was enacted
on December 19, 2007, the effective date
of these standards for smaller diameter
IRL is June 16, 2008. In both of these
cases, the EISA 2007 standards come
into effect well before an amended IRL
standard (as would be prescribed by this
rulemaking) would come into effect.
DOE’s draft ANOPR analyses were
modified to account for this expanded
scope of IRL coverage by selecting IRL
baselines which DOE expects to be the
least efficacious covered lamp design
that would comply with the amended
standard. In addition, DOE updated its
IRL shipment forecasts in response to
EISA 2007 to account for both the
expansion of scope for Federallyregulated reflector lamps and the
exemptions to the standards.
In addition, it is also important to
note that, as previously discussed, EISA
2007 introduced statutory definitions
for ‘‘rough service lamp,’’ ‘‘vibration
service lamp,’’ and ‘‘colored
incandescent lamp,’’—lamp types
which are explicitly excluded from the
definition of ‘‘incandescent reflector
lamp,’’ as contained in the referenced
definition of ‘‘incandescent lamp.’’ DOE
had previously developed and adopted
into the CFR definitions for these three
terms in the context of IRL; however, as
previously mentioned, these DOE
definitions are now superseded by the
statutory definitions in EISA 2007. As
these terms are used to define that
portion of the definition of
‘‘incandescent lamp’’ that corresponds
to the definition of ‘‘incandescent
reflector lamp,’’ any amendments to
these terms affect the scope of energy
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conservation standards coverage of IRL.
In examining the new definitions for
‘‘rough service lamp’’ and ‘‘vibration
service lamp,’’ DOE recognizes that they
differ from the earlier CFR definitions
DOE had adopted. In response to the
changes to these definitions, DOE
attempted to account for these changes
in the ANOPR analyses. Similarly, the
new EISA 2007 definition for ‘‘colored
incandescent lamp’’ effectively expands
the scope of coverage for IRL. That is,
IRL containing five percent or more of
neodymium content and plant light IRL
are now subject to energy conservation
standards. DOE accounts for this
expanded coverage of IRL by creating a
separate product class for these lamps,
termed ‘‘modified spectrum lamps.’’
This decision to treat modified
spectrum lamps separately is consistent
with the approach taken in EISA 2007
with respect to GSIL.
Finally, although EPACT 1992 gave
DOE authority under U.S.C. 6295(i)(5) to
consider additional general service
incandescent lamps (which included
IRL) for energy conservation standards
coverage, section 321(a)(3) of EISA 2007
has amended section 325(i)(5) of EPCA
to remove this provision. Accordingly,
DOE has terminated its preliminary
determination regarding the expansion
of scope to additional GSIL and IRL.
However, as discussed above, in the
ANOPR analyses, DOE accounts for the
new scope of coverage for IRL for
purposes that remain relevant to this
rulemaking (i.e., considering amended
efficacy standards for all covered IRL).
d. Off Mode and Standby Mode Energy
Consumption
In addition to the specific relevant
actions described above, EISA 2007 also
places various requirements on all
covered products. Of particular note
here, section 310(3) of EISA 2007
amends section 325 of EPCA (42 U.S.C.
6295) by mandating that any final rule
establishing or revising a standard for a
covered product that is adopted after
July 1, 2010 shall incorporate standby
mode and off mode energy use into the
standard, if feasible. DOE notes that
final rule for this energy conservation
standards rulemaking on fluorescent
and incandescent lamps is scheduled
for publication by June 2009. In
addition, after careful review, DOE has
preliminarily determined that for the
GSFL and IRL which are the subjects of
this rulemaking, current technologies
for these products do not employ 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
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mode,’’ and ‘‘standby mode’’ 13
applicable to both GSFL and IRL, the
lamp must be entirely disconnected
from the main power source (i.e., the
lamp is switched off) in order not to
provide any active mode function (i.e.,
emit light), thereby meeting the second
provision in the definition of ‘‘off
mode.’’ However, if the lamp is
disconnected from the main power
source, the lamp clearly does not satisfy
the requirements of operating in off
mode. In addition, DOE believes that all
covered products that meet the
definitions of ‘‘GSFL’’ and ‘‘IRL’’ are
single-function products and do not
offer any secondary user-oriented or
protective functions. Therefore, DOE
has tentatively concluded that it is not
feasible to incorporate off mode or
standby mode energy use into the
energy conservation standards for GSFL
and IRL. DOE welcomes comment on its
understanding of off mode and standby
mode energy consumption for the
products addressed by this rulemaking.
3. Test Procedures
DOE test procedures outline the
method by which manufacturers must
determine the efficiency of their
products and equipment, and thereby
assess and certify compliance with the
energy conservation standards adopted
pursuant to EPCA. DOE established test
procedures for fluorescent and
incandescent lamps in a final rule
published in the Federal Register on
May 29, 1997 (hereafter ‘‘1997 Test
Procedure Final Rule’’). 62 FR 29222
(adopting 10 CFR part 430, Subpart B,
Appendix R 14). In addition, the test
procedures incorporate by reference
American National Standards Institute
(ANSI), Illuminating Engineering
Society of North America (IESNA), and
International Commission on
Illumination (CIE) standards to measure
13 In amending 42 U.S.C. 6295(gg)(1)(a)(i), (ii),
and (iii), EISA 2007 defines ‘‘active mode,’’ ‘‘off
mode,’’ and ‘‘standby mode’’ as follows: ‘‘ The term
‘active mode’ means the condition in which an
energy-using product—(I) is connected to a main
power source; (II) has been activated; and (III)
provides 1 or more main functions.’’ ‘‘The term ‘off
mode’ means the condition in which an energyusing product—(I) is connected to a main power
source; and (II) is not providing any stand-by or
active mode function.’’ ‘‘The term ‘standby mode’
means the condition in which an energy-using
product—(I) is connected to a main power source;
and (II) offers 1 or more of the following useroriented or protective functions: (aa) To facilitate
the activation or deactivation of other functions
(including active mode) by remote switch
(including remote control), internal sensor, or timer.
(bb) Continuous functions including information or
status displays (including clocks) or sensor-based
functions.’’
14 ‘‘Uniform Test Method for Measuring Average
Lamp Efficiency (LE) and Color Rendering Index
(CRI) of Electric Lamps.’’
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lamp efficacy and CRI. In their totality,
the DOE test procedures provide
detailed instructions for measuring the
performance of GSFL and IRL and
certain performance attributes of GSIL.
The National Electrical Manufacturers
Association (NEMA) submitted a
comment identifying what it perceived
to be problems with several of the
industry standards incorporated in
DOE’s test procedures. Specifically,
NEMA stated that many of the standards
referenced in the test procedures are
outdated, have been replaced, or are no
longer available. (NEMA, No. 12 at pp.
2–4) 15
Prompted by the NEMA comment,
DOE reviewed the DOE test procedures
for GSFL, IRL, and GSIL, and DOE has
tentatively concluded that they should
be revised because many of industry
standards cited in the test procedures
are out of date, are not available for
purchase, or are no longer maintained.
Therefore, DOE has initiated a test
procedure rulemaking, in parallel with
this energy conservation standards
rulemaking, to review and revise the test
procedures for these three categories of
lamps—GSFL, IRL and GSIL (even
though GSIL is no longer part of this
ANOPR). To this end, DOE is publishing
a notice of proposed rulemaking (NOPR)
in today’s Federal Register that
proposes to amend the lighting test
procedures. The following briefly
summarizes the major points in the test
procedures NOPR; however, for a
complete discussion on these and other
points, please consult the NOPR.
In the test procedure NOPR, DOE is
proposing primarily to update the
references to outdated industry
standards for fluorescent and
incandescent lamps. DOE believes this
update is necessary in order to ensure
that stakeholders and testing
laboratories are able to follow DOE’s test
procedures, which require obtaining
and using several industry standards
incorporated by reference. DOE believes
that the proposed test procedure
amendments would not impact the
measured efficacy of a lamp.
In the test procedure NOPR, DOE is
also proposing a few definitional and
procedural modifications to
accommodate technological migrations
in the GSFL market and approaches
DOE is considering in this energy
15 A notation in the form ‘‘NEMA, No. 12 at pp.
2–4’’ 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) by the National Electrical
Manufacturers Association (NEMA), (2) in
document number 12 in the docket of this
rulemaking, and (3) appearing on pages 2 through
4.
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conservation standards rulemaking.
Specifically, DOE is proposing to
mandate that GSFL testing continue to
be conducted on low-frequency ballasts
whenever possible. By maintaining
fluorescent lamp testing on lowfrequency ballasts when possible, DOE’s
proposed updates to more current ANSI
standards would not alter the measured
efficacy of fluorescent lamps and
maintain consistent testing across
manufacturers. In addition, DOE is
proposing amendments related to the
calculation of ‘‘lamp efficacy’’ for GSFL.
Presently, manufacturers are directed to
report efficacies to differing degrees of
accuracy for fluorescent and
incandescent lamps. For example,
fluorescent lamp efficacies are rounded
off to the nearest whole number, while
incandescent lamp efficacies are
reported to the tenths decimal place.
DOE is proposing to revise the reporting
requirements for GSFL, such that all
covered lamp efficacies are reported
with an accuracy to the tenths decimal
place. DOE believes that such change
would not only promote consistency
among the various lamp categories, but
also would coincide with the significant
digits presented in the EPCA efficacy
standard. In addition DOE found that in
order to have standard levels for GSFL
that are best able to maximize energy
savings, it must utilize the tenths
decimal place in its energy conservation
standards analysis.
DOE is also proposing in the test
procedure NOPR to adopt a testing and
calculation method for measuring the
correlated color temperature (CCT) of
fluorescent and incandescent lamps, a
provision that is not currently contained
in the test procedure. DOE is
considering using CCT to differentiate
between product classes for GSFL, and
DOE notes that the definitions of
‘‘colored fluorescent lamp’’ and
‘‘colored incandescent lamp’’ both
incorporate CCT ranges, which, in part,
determine whether lamps are subject to
regulation.
The test procedure NOPR also
recognizes that DOE is considering the
possibility of extending coverage to
certain additional GSFL (see section II
of this notice). In addition, the test
procedure NOPR recognizes and
accounts for the fact that EISA 2007 has
extended statutorily-prescribed energy
conservation standards to specified
types of GSIL. Thus, the NOPR informs
the public that DOE intends to amend
the test procedures to accommodate
these additional lamps, and to provide
appropriate test methods, should DOE
adopt standards for them.
Overall, and as stated in the NOPR,
DOE believes that most of the proposed
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revisions to the test procedures would
not significantly change the reported
efficacy of covered lamps or result in a
significant increase in testing burden.
For any that do have an appreciable
impact on the reported efficacy, DOE is
proposing to delay the effectiveness of
such test procedure revision until the
effective date of any new energy
conservation standard for these
products.
DOE held a public meeting to discuss
both the test procedure NOPR and
energy conservation standards ANOPR
for fluorescent and incandescent lamps.
DOE intends to issue a final rule for the
lamps test procedure prior to issuing the
NOPR for the energy conservation
standards rulemaking.
II. Consideration Regarding the Scope
of Energy Conservation Standards
Coverage
A. Introduction
As noted previously, section 325(i)(5)
requires DOE to consider whether to
adopt energy efficiency standards for
additional GSFL beyond those already
covered by the statutorily-prescribed
standard. (42 U.S.C. 6295(i)(5)) More
specifically, EPCA directs that the
Secretary ‘‘shall 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] * * * ’’ Id. Pursuant
to this mandate and as explained in this
section of the notice, DOE has made a
preliminary determination that
expanded coverage would be
appropriate. The public is invited to
review and comment on the initial
findings and analyses, as set forth
below, regarding which additional
fluorescent lamps should be evaluated
for possible coverage by energy
conservation standards.
Furthermore, DOE was urged to make
this preliminary determination by
comments received at the Public
Meeting. For example, the Appliance
Standards Awareness Project (ASAP)
recommended that DOE should permit
the public to comment on consideration
of the scope of additional product
coverage, and that DOE should define
that scope of coverage early in the
rulemaking process in order to prevent
any scheduling delays. (Public Meeting
Transcript, No. 4.5 at pp. 34–36) DOE
agrees with the ASAP comment, and
consequently, this notice provides the
public with the opportunity to submit
comments regarding DOE’s preliminary
determination.
Below, DOE discusses the range of
additional lamps that EPCA authorizes
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DOE to consider. Then, DOE identifies
those additional GSFL that it believes
warrant further consideration for
possible energy conservation standards,
and why. DOE requests comment on
these subjects. After consideration of
these comments, DOE may propose
additional lamps to be covered, along
with proposed standard levels for these
lamps, during the NOPR stage of this
standards rulemaking. After further
public comment, DOE will publish a
final rule which includes its final
decision regarding coverage of
additional lamps (and applicable
standards levels, as appropriate).
In addition, the following sections
also discuss modifications of various
existing lighting-related definitions DOE
developed and incorporated into the
CFR. These modifications reflect market
migrations or changes in industry
standards and often have the effect of
increasing or decreasing DOE’s scope of
energy conservation standards coverage.
B. Additional General Service
Fluorescent Lamps Being Considered
Under EPCA Section 325(i)(5)
1. Scope
Prior to embarking on a discussion of
additional coverage of general service
fluorescent lamps, it is first necessary to
explain the extent of coverage under the
present standard. Section 325(i)(1) of
EPCA established energy conservation
standards for certain 4-foot medium
bipin lamps, 2-foot U-shaped lamps, 8foot recessed double contact high output
lamps, and 8-foot single pin slimline
lamps. (42 U.S.C. 6295(i)(1)) The
relevant standard levels for the products
can be found in DOE’s regulations at 10
CFR 430.32(n).
As the next step in this inquiry, DOE
notes that section 325(i)(5) of EPCA
directs DOE to determine if the
standards in effect should be amended
so as to apply to ‘‘additional general
service fluorescent [lamps] * * *’’ (42
U.S.C. 6295(i)(5)) There are currently a
wide variety of fluorescent lamps being
used in broad, general service lighting
applications 16 that are not covered by
16 A key provision in the statutory definitions of
‘‘general service fluorescent lamp’’ is that the lamp
must satisfy ‘‘the majority of fluorescent
applications.’’ (42 U.S.C. 6291(B)) DOE interprets
these phrases to mean that these lamps have broad
utility in various fluorescent or lighting
applications. In general, these lamps will not
represent products used solely in niche
applications (such as those specifically excluded in
the definition of ‘‘general service fluorescent
lamp’’), but rather will represent products that often
fulfill general illumination purposes (casting light
over a broad area), such as in the following common
locations: Office space, warehouses, call centers,
schools, health care, government buildings,
residential housing, and retail stores.
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existing energy conservation standards.
Accordingly, these lamps are potential
candidates for expanded coverage
pursuant to 42 U.S.C. 6295(i)(5).
In addition, DOE received a joint
comment from several stakeholders
(hereafter referred to as ‘‘Joint
Comment’’) concerning the extent of
DOE’s authority to expand coverage of
its energy conservation standard for
lighting products. The Joint Comment
was submitted by the Alliance to Save
Energy, ACEEE, ASAP, Natural
Resources Defense Council, Northeast
Energy Efficiency Partnerships,
Northwest Power and Conservation
Council, and PG&E (Pacific Gas and
Electric). Given the stakeholders
involved, it should be noted that the
Joint Comment reflects views of both
energy efficiency advocates and
utilities.
The Joint Comment asserted that
section 325(i)(5) of EPCA authorizes
DOE to adopt standards for any
fluorescent lamp not currently covered
by standards so long as standards for
that lamp would be technologically
feasible, economically justified, and
would achieve significant energy
savings. The comment seems to argue
that in implementing section 325(i)(5),
DOE should interpret its mandate
broadly to include any GSFL that meet
these statutory criteria. (Joint Comment,
No. 9 at pp. 1–2; Public Meeting
Transcript, No. 4.5, pp. 38–39, and 45)
Given that EPCA’s statutory
definitions of ‘‘general service
fluorescent lamp’’ contains a number of
express exclusions for certain categories
of fluorescent lamps, DOE finds no basis
in the language of EPCA to support
commenters’ assertions that the agency’s
authority to act under section 325(i)(5)
of EPCA is unlimited. As discussed
below, DOE believes section 325(i)(5)
covers additional GSFL that are not one
of the enumerated specialized products
that EPCA excludes from coverage (see
42 U.S.C. 6291(30)(B)). 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 non-general
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.
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(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)) Both key
elements of this definition—i.e., that the
lamps can satisfy the majority of
lighting applications and the exclusion
of certain specialized fluorescent
lamps—are consistent with the mandate
of section 325(i)(5) that DOE consider
and adopt standards for GSFL that
currently are not covered by standards.
That would allow DOE to cover a broad
range of additional products used and
viewed as general service fluorescent
lamps.
In determining which GSFL would be
suitable for consideration under 42
U.S.C. 6295(i)(5), DOE limited its
inquiry to those fluorescent lamps with
generic physical and operational
features closely matching the IESNA’s
widely accepted definition of
‘‘fluorescent lamp,’’ as contained in
‘‘The IESNA Lighting Handbook:
Reference and Application,’’ Ninth
Edition, 2000, p. G–14.17 Because only
lamps with these features are commonly
understood to be fluorescent or general
service fluorescent lamps, DOE would
apply standards to only such fluorescent
lamps, provided that such lamps are not
expressly excluded under 42 U.S.C.
6291(30)(B).
In summary, in considering whether
to amend the standards in effect for
fluorescent lamps to apply to
‘‘additional’’ GSFL under section
325(i)(5) of EPCA, DOE has considered
all lamps that meet the general
description of a ‘‘fluorescent lamp’’ in
the introductory language of 42 U.S.C.
6291(30)(A), that can be used to satisfy
the majority of fluorescent lighting
applications, for which EPCA does not
prescribe standards, and that are not
within the exclusions specified in 42
U.S.C. 6291(30)(B).
2. Rationale for Coverage
In considering which additional GSFL
to cover, DOE considered lamps other
than those specifically excluded.
Among the lamps considered, DOE used
potential energy savings of the lamps as
the primary criterion in considering
preliminarily which should be covered
by the standards program. After
selecting the lamps for consideration,
17 The definition of fluorescent lamp in the
IESNA handbook is a ‘‘low-pressure mercury
electric-discharge lamp in which a fluorescing
coating (phosphor) transforms some of the UV
energy generated by the discharge into light.’’
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DOE then conducted a preliminary
assessment of whether a standard on
those lamps would have the potential to
meet the two remaining criteria for
prescribing new or amended
standards—i.e., being technologically
feasible and economically justified. (42
U.S.C. 6295(o)(2)(A)) In the ANOPR (as
described in section III below) and
NOPR, each lamp selected for coverage
would then be the subject of a more
comprehensive analysis to determine if
there is a reasonable likelihood that
standards are justified.
DOE assessed the potential to achieve
significant energy savings by extending
coverage to particular lamps from
market-share estimates and from
potential incremental energy savings
that could result from more-efficacious
lamp designs. DOE has quantitative
shipment or market share information
for certain lamps, such as 8-foot T8
single pin slimline lamps, which it
considered and cites in this notice.
However, DOE has little to no
information on shipments or market
share for other lamp types which DOE
is considering, such as 8-foot very high
output (VHO) fluorescent lamps. In the
absence of data, DOE has relied on
qualitative assessments of market share
(based on discussions with lighting
industry experts) to gauge the potential
for significant energy savings. DOE
invites the public to present further
shipment or market share data relevant
to consideration of coverage for
additional lamps.
In addition, DOE assessed the
potential to achieve significant energy
savings for particular lamps by
considering whether these lamps serve
as potential substitutes to other
regulated lamps. By leaving potential
substitutes unregulated, DOE risks that
regulating one lamp shape may lead to
rapid increased sales of other,
unregulated substitutable shapes. This
shift of installed stock towards
unregulated lamps may result in
decreased energy savings, or even the
possibility of increased energy use, from
energy conservation standards on
regulated lamps. In order to avoid this
consequence, DOE plans to consider
coverage of GSFL lamps that are
potential substitutes for any lamps that
have high energy savings potential and
are likely to be regulated. Though the
shipments of these substitute lamps may
not currently be high-volume, DOE
believes that if the lamps are left
unregulated, the shipments have the
potential to grow in market share. As
long as efficacy improvements are
technologically feasible, coverage of
these additional substitute lamps has
the potential to not only provide energy
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savings in their own right, but to also
prevent potentially significant losses in
energy savings through substitution
effect.
In addition to independently
conducting its preliminary
determination analysis, DOE considered
comments on the additional GSFL it
should cover. The following subsections
provide a discussion of the GSFL being
considered and not considered as
expanded coverage, a summary of
comments relating to the preliminary
determination, and DOE’s response to
these comments. DOE invites comment
on the rationale for coverage presented
in this preliminary determination. DOE
also invites comment on the scope of
coverage defined in this preliminary
determination.
In addition, the following sections
also discuss modifications to various
existing lighting-related definitions DOE
developed and incorporated into the
CFR, which would have the effect of
increasing the scope of coverage under
applicable energy conservation
standards. The new and amended
definitions under consideration are
discussed and presented in section II.C.
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3. Analysis of Individual General
Service Fluorescent Lamps
Current DOE regulations set standards
for the following types of fluorescent
lamps: (1) 4-foot, medium bipin,
straight-shaped lamps, rated wattage ≥
28W; (2) 2-foot, medium bipin, Ushaped lamps, rated wattage of ≥ 28W;
(3) 8-foot, recessed double contact, rapid
start, high output lamps, 0.800 nominal
amperes (as defined in ANSI C78.1–
1991); and (4) 8-foot, single pin, instant
start, slimline lamps, rated wattage of ≥
52 (as defined in ANSI C78.3–1991).
Based on an investigation of available
products in manufacturer catalogs, DOE
identified various, currentlyunregulated general service fluorescent
lamps that could be considered for
additional coverage under section
325(i)(5) of EPCA, while maintaining
the exclusions specified in the
definition of ‘‘general service
fluorescent lamp.’’ These lamps are as
follows:
• 4-foot, medium bipin, straightshaped lamps, rated wattage of < 28W;
• 2-foot, medium bipin, U-shaped
lamps, rated wattage of < 28W;
• Additional 8-foot, recessed double
contact, rapid start, high output lamps;
• Additional 8-foot single pin, instant
start, slimline lamps;
• Very High Output (VHO) straightshaped lamps;
• T5 miniature bipin straight-shaped
lamps;
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• Additional straight-shaped and Ushaped lamps, other than those listed
above (e.g., alternate lengths, diameters,
or bases); and
• Additional fluorescent lamps with
alternate shapes (e.g., circline, pin-based
CFL).
The following section discusses DOE’s
rationale for considering or not
considering expansion of coverage to
the above-listed lamps. In addition, in
section II.C, DOE considers revisions to
the definitions of ‘‘rated wattage’’ and
‘‘colored fluorescent lamp’’ which may
further affect DOE’s scope of energy
conservations standards coverage.
DOE is considering extension of the
standard’s coverage to certain 4-foot,
medium bipin, GSFL to which
standards do not currently apply.
Presently, DOE’s regulations do not
cover or set standards for any 4-foot
medium bipin lamp with a wattage less
than 28W. As part of this preliminary
determination, DOE is considering
extension of coverage to 4-foot, medium
bipin, straight-shaped fluorescent lamps
with wattages between 25W and 28W.
DOE understands that 25W, 4-foot
medium bipin, T12 fluorescent lamps
are manufactured and used primarily in
the residential sector for general
purpose illumination applications,
providing additional opportunity for
energy savings. Although DOE received
no quantitative shipment information
on the market share of these wattages of
4-foot medium bipin lamps, DOE has
found that manufacturers currently
market and sell 25W, 4-foot medium
bipin, T8 fluorescent lamps as
replacements for higher-wattage, 4-foot
medium bipin, T8 fluorescent lamps. As
discussed earlier, by expanding
standards coverage to substitute lamps
of currently regulated lamps, DOE
mitigates the risk of 25W lamps
becoming a potential loophole (that
decreases energy savings) to the current
and pending amended standards on 4foot medium bipin lamps.
For these reasons, DOE believes that
25W 4-foot medium bipin lamps (both
T8 and T12) are suitable candidates to
be considered for coverage under this
rulemaking. In addition, as the
technology and incremental costs
associated with increased efficiency of
25W lamps are similar to their already
regulated 28W counterparts, DOE has
tentatively concluded that standards on
these lamps have the potential to meet
the statutory criteria of being
technologically feasible and
economically justified. Therefore, in
this ANOPR, DOE analyzes these lamps
as part of the 4-foot medium bipin
product class in the life-cycle cost (LCC)
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and national impact analysis (NIA)
(sections III.G and III.I, respectively).
DOE invites comment on this potential
expansion of coverage to 4-foot medium
bipin lamps with wattages greater than
or equal to 25W, including whether T12
lamps (commonly referred to as
‘‘residential straight-shaped lamps’’)
should be covered.
Similar to 4-foot medium bipin lamps,
DOE’s current regulations do not cover
or set standards for any 2-foot U-shaped
lamp with a wattage less than 28W. In
its research of available product in
manufacturer catalogs, DOE found no
commercially-available 2-foot U-shaped
GSFL with wattages less than 28W.
Therefore, DOE believes that the current
standards cover the majority of the Ushaped general service lighting products
available in the market today.
Consequently, DOE’s preliminary
assessment is that lowering the
minimum wattage threshold of Ushaped lamps will most likely not result
in significant additional energy savings.
For this reason, DOE is not considering
expanded coverage of 2-foot, medium
bipin, U-shaped lamps in this
preliminary determination.
In this preliminary determination,
DOE is considering extension of the
standard’s coverage to certain 8-foot,
recessed double contact, rapid start,
high output fluorescent lamps to which
energy conservation standards do not
currently apply. DOE’s definition of
‘‘fluorescent lamp,’’ adopted in
accordance with EPCA, includes only
those 8-foot recessed double contact HO
lamps with 0.800 nominal amperes and
which are listed in ANSI Standard
C78.1–1991. 10 CFR 430.2. Due to the
ampere specification in the definition,
the current standards applicable to
GSFL (10 CFR 430.32(n)(1)), cover 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). ACEEE and Osram Sylvania
(hereafter ‘‘Osram’’) commented that
DOE should cover T8, 8-foot lamps.
(Public Meeting Transcript, No. 4.5 at p.
59) According to Osram, T8, 8-foot
recessed double contact HO lamps are
currently available, and are replacing
the older T12 technology. Osram stated
its belief that this trend will continue.
(Osram, No. 15 at p. 5)
Furthermore, DOE is aware that T8, 8foot lamps are substitutes for T12, 8-foot
lamps. As discussed earlier, by not
regulating substitutes (e.g., T8, 8-foot
recessed double contact HO lamps) of
regulated lamps (e.g., T12, 8-foot
recessed double contact HO lamps),
DOE risks losing the potential energy
savings of the current energy
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conservation standards for T12, 8-foot
lamps, as well as any revised standard
that may be adopted pursuant to this
rulemaking. In addition, because T8, 8foot recessed double contact HO lamps
are predicted to replace the T12 market,
the shipments of T8 lamps may increase
considerably.
For the reasons above, DOE believes
that regulating T8, 8-foot recessed
double contact HO lamps has the
potential to achieve significant energy
savings. DOE analyzes these T8 lamps
as part of the 8-foot recessed double
contact HO product class in the NIA.
From this analysis, DOE estimates that
the energy savings achieved due to
regulation of T8, 8-foot recessed double
contact HO lamps could be as high as
0.30 quads over the analysis period.
(See section III.I of this notice.)
In addition, in this preliminary
determination, DOE tentatively plans to
expand its coverage of 8-foot recessed
double contact, rapid start, high output
fluorescent lamps to those not listed in
ANSI Standard C78.1–1991. As
discussed in the fluorescent and
incandescent lamps test procedure
NOPR published in today’s Federal
Register, many of the ANSI standards
currently referenced in DOE regulations
(e.g., ANSI Standard C78.1–1991) are
outdated. DOE understands that as the
fluorescent lamp market moves forward
and evolves, new 8-foot recessed double
contact, rapid start, high output lamps
(with 0.800 nominal amperes or other
currents) may be introduced into the
market. As these lamps would not be
listed in the 1991 ANSI standard, they
would not be covered under paragraph
(3) of the definition of fluorescent lamp,
and, therefore, would not be subject to
current energy conservation standards.
However, DOE understands that though
these newly introduced lamps might
have different wattages than those listed
in ANSI Standard C78.1–1991, they
serve as replacements and substitutes
for the regulated 8-foot recessed double
contact high output lamps. As discussed
earlier, by leaving these potential
substitute lamps unregulated, DOE risks
not achieving the maximum energy
savings from its established energy
conservation standards.
Given the potential energy savings, in
this preliminary determination, DOE is
considering extension of coverage to T8,
8-foot recessed double contact HO
lamps, thereby adding lamps previously
restricted by the 0.800 nominal ampere
limitation. In addition, DOE is
considering extension of coverage to 8foot recessed double contact HO lamps
not listed in ANSI Standard C78.1–
1991. As the technologies of T8, 8-foot
recessed double contact HO lamps and
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the 8-foot recessed double contact HO
lamps not listed in ANSI Standard
C78.1–1991 are similar to the
technologies of their already-regulated
T12 counterparts, DOE has tentatively
concluded that standards on these
lamps have the potential to meet the
statutory criterion of being
technologically feasible. With regards to
the statutory criterion of being
economically justified, DOE analyzes
T8, 8-foot recessed double contact HO
lamps in the LCC analysis and NIA.
Preliminary results show that regulation
of these lamps would be expected to
achieve LCC savings up to $3.15
(discounted at 6.2 percent) per lamp
system and net present value (NPV) up
to $0.73 billion to the nation
(discounted at 3 percent) over the
analysis period. Also, 8-foot recessed
double contact HO lamps not listed in
ANSI Standard C78.1–1991 should
incur similar economic effects as their
already-covered counterparts. Therefore,
for the purpose of this preliminary
determination, DOE has tentatively
concluded that energy conservation
standards on these lamps have the
potential of being economically
justified.
Similar to 8-foot recessed double
contact HO lamps, in this preliminary
determination, DOE is considering
extension of the standard’s coverage to
certain 8-foot, single pin, instant start,
slimline lamps to which energy
conservation standards do not currently
apply. DOE’s definition of ‘‘fluorescent
lamp,’’ adopted in accordance with
EPCA, includes only those 8-foot, single
pin, instant start, slimline lamps, with
a rated wattage greater than or equal to
52W and listed in ANSI Standard
C78.3–1991. 10 CFR 430.2. Under this
definition, because they are not listed in
ANSI Standard C78.3–1991, no T8, 8foot single pin slimline lamps would be
subject to energy conservation
standards. However, as indicated by
their inclusion in the updated ANSI
Standard C78.81–2005, DOE
understands that since the publication
of ANSI Standard C78.3–1991, T8, 8foot single pin slimline lamps have
penetrated the GSFL market. Shipment
information submitted by NEMA
indicates that T8 lamps comprise
approximately 15 percent of the total 8foot single pin slimline market. (NEMA,
No. 12 at p. 2) In addition, ACEEE and
Osram commented that DOE should
cover T8, 8-foot single pin slimline
lamps. (Public Meeting Transcript, No.
4.5 at p. 59) For similar reasons as
discussed with regard to T8, 8-foot
recessed double contact HO lamps, DOE
believes that the regulation of T8, 8-foot
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single pin slimline lamps has the
potential to achieve significant energy
savings. DOE analyzes these T8 lamps
as part of the 8-foot single pin slimline
product class in the NIA. From this
analysis, the energy savings achieved
due to the regulation of T8, 8-foot single
pin slimline lamps would be expected
to be as high as 0.25 quads over the
analysis period (i.e., from the year 2012
to 2042). (See section III.I of this notice.)
As such, in this preliminary
determination, DOE is considering
expanding the standards’ scope of
coverage of 8-foot single pin slimline
lamps with a rated wattage greater than
or equal to 52W to those not listed in
ANSI Standard C78.3–1991. This would
include T8 lamps and any additional 8foot single pin slimline lamps that
might be introduced into the fluorescent
lamp market in the future. As 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 already-regulated
T12 counterparts, DOE has tentatively
concluded that standards on these
lamps have the potential to meet the
statutory criterion of being
technologically feasible. With regards to
the statutory criterion of being
economically justified, DOE analyzes
T8, 8-foot single pin slimline lamps in
the LCC analysis and NIA. Preliminary
results show that regulation of these
lamps has the potential to achieve LCC
savings up to $8.27 per lamp system
(discounted at 6.2 percent) and NPV of
$1.15 billion to the nation (discounted
at 3 percent) over the analysis period
(i.e., from the year 2012 to 2042). Also,
8-foot single pin slimline lamps not
listed in ANSI Standard C78.1–1991
would be expected to incur similar
economic effects as their already
covered counterparts. Therefore, for the
purpose of this preliminary
determination, DOE has tentatively
concluded that energy conservation
standards for these lamps have the
potential to be economically justified.
DOE also observed that some 8-foot,
single pin, slimline lamps with wattages
below 52W are available on the market
today. These include 51W and 50W
versions. However, DOE notes that
published catalogs offered very few
models at these wattages. Also, DOE
believes that these lower-wattage
slimline lamps are used for niche
applications and would likely not be
used as a substitute for higher-wattage
versions. In particular, these lamps offer
different lumen packages from their
higher-wattage counterparts and are not
currently marketed as substitutes.
Consequently, DOE believes that the
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market share of such lamps is and will
remain relatively small, thereby making
the potential energy savings that would
be achieved from their regulation small
as well. Therefore, DOE has tentatively
decided not to extend coverage of the
energy conservation standards to T8, 8foot single pin slimline lamps with
wattages below 52W. DOE requests
comment on this approach.
In this preliminary determination,
DOE also considered whether or not to
expand coverage to include very high
output (VHO) fluorescent lamps. Philips
Lighting (hereafter ‘‘Philips’’)
commented that DOE should set
standards for VHO, T12 fluorescent
lamps, asserting that these lamps
consume a large amount of energy.
(Philips, No. 5 at p. 1) DOE research
involving review of manufacturer
catalog data corroborated the Philips
comment, as common VHO fluorescent
lamps can have rated wattages ranging
from 115W to 215W, while
corresponding HO lamps have rated
wattages ranging from 60W to 110W.
However, in considering the Philips
comment, DOE learned from
discussions with manufacturers that
many VHO lamps are used in outdoor
applications, such as parking lot or
other area illumination, where highintensity discharge (HID) lamps are
rapidly gaining market share. Research
also indicated that shipments of VHO,
T12 lamps have been and are continuing
to decline rapidly. Overall, DOE
understands that these lamps constitute
a very low-volume share of the relevant
market, and these products will likely
further decrease in terms of market
share. As such, although these lamps
may individually have a per-lamp
energy savings potential larger than that
of a typical GSFL, DOE believes that the
total energy savings from regulating
these lamps would be small and
decreasing as that these lamps are
naturally disappearing from the market
in the absence of regulation. Therefore,
DOE does not plan to extend coverage
of the energy conservation standard to
VHO lamps.
DOE also considered whether to
include T5 fluorescent lamps in its
expansion of energy conservation
standards coverage. At the Public
Meeting on the Framework Document,
ACEEE and PG&E commented that DOE
should cover T5 lamps. (Public Meeting
Transcript, No. 4.5 at pp. 39 and 59)
However, ACEEE and PG&E did not
provide a rationale for consideration of
these lamps, and DOE did not receive
any written comments recommending
that it consider T5 lamps for coverage.
To further investigate this issue, DOE
evaluated the market and typical
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applications for T5 lamps, and has
tentatively decided to not extend
coverage to T5 lamps, for the reasons
that follow.
DOE found that T5 systems are used
in a wide variety of indoor general
illumination applications where T8 and
T12 systems could also be used.
However, DOE understands that T5
systems are always operated with
higher-efficiency, high-frequency
electronic ballasts (versus lowerefficiency, low-frequency ballasts). In
addition, it was found that these lamps
tend to have higher efficacies and that
the systems tend to have lower energy
consumption than the corresponding T8
and T12 lamps and systems. Therefore,
DOE believes that the regulation of T5
lamps may not have the potential for
significant per-unit energy savings. In
addition, DOE understands that the
current GSFL market share of T5 lamps
is relatively small, representing low
total energy savings potential. DOE also
notes that T5 systems tend to be higher
in cost than T8 or T12 systems. Thus,
DOE believes 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.18 To the
contrary, not regulating T5 lamps could
provide market incentives for and result
in energy savings by encouraging greater
end-user use of highly efficacious T5
lamps. For the above stated reasons,
DOE does not plan to extend the
standards’ coverage to T5 lamps. DOE
solicits further comment on whether it
should extend coverage to T5 lamps, as
well as the rationale for doing so.
Furthermore, DOE does not intend to
extend coverage to fluorescent lamps
that have alternate lengths, diameters,
bases, or shapes (or a combination
thereof) than the lamps discussed in the
preceding section. DOE believes that the
lamps currently covered and the
additional lamps described above that
DOE is considering for coverage (i.e.,
ones which have lengths and bases the
same as those currently regulated)
represent the significant majority of the
market for GSFL, and, thus, the bulk of
potential energy savings. Furthermore,
DOE believes that there is limited
potential for lamps with miscellaneous
lengths and bases to grow in market
18 At CSLs four and five, some T8 systems are
more efficacious than their T5 counterparts.
However, DOE notes that the average cost of a T5
system is more expensive than a T8 system. The
fact that T5 lamps are less efficacious and more
expensive at these standard levels indicates that
there is little or no incentive for stakeholders to
migrate to T5 lamps from T8 or T12 lamps in an
effort to avoid the fluorescent lamp standard.
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share, given the constraint of fixture
lengths and socket compatibility. DOE
requests comment on this approach.
In summary, the following list
represents the ‘‘additional general
service fluorescent lamps’’ which DOE
is considering for expanded coverage
under the energy conservation
standards:
• 4-foot, medium bipin lamps with
wattages ≥ 25 and < 28;
• 8-foot recessed double contact,
rapid start, HO lamps not 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.
C. Amended Definitions
As part of the examination of the
scope of coverage of GSFL, DOE is
considering amendments to existing
DOE-adopted definitions in order to
more clearly and accurately define the
scope of GSFL and IRL. The following
section describes these planned
amendments and requests comment.
1. ‘‘Rated Wattage’’
One element of EPCA’s definitions for
‘‘fluorescent lamp’’ and ‘‘incandescent
reflector lamp’’ is a lamp’s ‘‘rated
wattage,’’ which helps to delineate the
lamps for which the statute set
prescriptive standards. (42 U.S.C.
6291(30)(A), (C)(ii) and (F)). For
example, the definition of ‘‘fluorescent
lamp’’ includes certain 4-foot medium
bipin lamps with ‘‘a rated wattage of 28
or more’’ (42 U.S.C. 6291(30)(A)(i)), and
EPCA prescribes standards for these
particular lamps (42 U.S.C.
6295(i)(1)(B)). In addition, EISA 2007
prescribed energy conservation
standards for general service
incandescent lamps that require lamps
of particular lumen outputs to have
certain maximum rated wattages.
(section 321(a)(3) of EISA 2007
amending section 325(i) of EPCA) EPCA
does not, however, define ‘‘rated
wattage.’’ Therefore, DOE adopted a
definition of ‘‘rated wattage’’ for 4-foot
medium bipin T8, T10, and T12
fluorescent lamps when it established
test procedures for fluorescent and
incandescent lamps in 1997. 62 FR
29222 (May 29, 1997). This definition,
located in 10 CFR 430.2, references an
ANSI guide from 1991, specifically
ANSI Standard C78.1–1991, ‘‘for
Fluorescent Lamps—Rapid-Start
Types—Dimensional and Electrical
Characteristics.’’ Although EPCA also
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uses the term ‘‘rated wattage’’ when
referring to ‘‘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
‘‘incandescent lamps’’ (i.e., the portion
of that definition pertaining to IRL) (42
U.S.C. 6291(30)(C)), DOE did not define
‘‘rated wattage’’ for these lamps in 1997.
In this rulemaking, DOE plans to update
its existing definition of ‘‘rated wattage’’
to cite the current version of ANSI
Standard C78.1–1991, and to apply this
definition to those lamps where rated
wattage is a key characteristic but is not
currently defined.
DOE’s current definition of ‘‘rated
wattage’’ for 4-foot medium bipin T8,
T10, or T12 lamps, in effect, contains
three definitions of ‘‘rated wattage’’:
One for those lamps listed in the ANSI
Standard C78.1–1991 standard; another
for residential straight-shaped lamps;
and a third for all other lamps. The
definition of ‘‘rated wattage’’ currently
contained in DOE regulations is as
follows:
Rated wattage, with respect to 4-foot
medium bi-pin T8, T10 or T12 lamps,
means:
(1) If the lamp is listed in ANSI
C78.1–1991, the nominal wattage of a
lamp determined by the lamp
designation in Annex A.2 of ANSI
C78.1–1991; or
(2) If the lamp is a residential straightshaped lamp, the wattage a lamp
consumes when operated on a reference
ballast for which the lamp is designed;
or
(3) If the lamp is neither listed in
ANSI C78.1–1991 nor a residential
straight-shaped lamp, the wattage a
lamp consumes when using reference
ballast characteristics of 236 volts, 0.43
amps and 439 ohms for T10 or T12
lamps or reference ballast characteristics
of 300 volts, 0.265 amps and 910 ohms
for T8 lamps. (10 CFR 430.2)
Annex A.2 of ANSI Standard C78.1–
1991, referenced in the first part of the
definition, discusses how to designate
lamps according to industry procedure.
It indicates that the lamp abbreviation
may include either the rated wattage or
nominal wattage for a particular lamp.
The most current equivalent industry
standard corresponding to ANSI
Standard C78.1–1991 is ANSI Standard
C78.81–2005, which also includes an
equivalent section on lamp
abbreviations. However, this equivalent
section specifies that lamp abbreviations
are to incorporate only the nominal
wattage. DOE believes that a different
section of ANSI Standard C78.81–2005
more appropriately defines ‘‘rated
wattage.’’ Specifically, Clause 11.1 of
ANSI Standard C78.81–2005 deals more
directly with rated wattage when it
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refers to rated values in the lamp data
sheets of Part IV of the standard and
notes the margin that manufacturer’s
average values must maintain from rated
values. In relevant part, Clause 11.1 of
ANSI Standard C78.81–2005 states: The
values of lamp voltage, current and
wattage shown on the individual lamp
data sheets in Part IV are rated values
that apply after the lamps have been
aged for 100 hours. These values were
chosen by consensus to represent the
industry average at the time of
publication. No manufacturer’s average
wattage shall exceed the rated value by
more than 5% plus 0.5 watts * * *
Therefore, DOE tentatively plans to
update the ‘‘rated wattage’’ definition’s
reference to ANSI Standard C78.81–
2005 and to reference Clause 11.1 of that
ANSI standard in place of Annex A.2 of
ANSI Standard C78.1–1991.
The second part of the ‘‘rated
wattage’’ definition addresses
residential straight-shaped lamps. DOE
adopted a definition for ‘‘residential
straight-shaped lamp’’ in 10 CFR 430.2
at the same time it defined ‘‘rated
wattage’’ and established the applicable
test procedures. 62 FR 29222 (May 29,
1997). This definition applies only to 4foot medium bipin lamps. The
provisions on residential straightshaped lamps reflect DOE’s
understanding that lamp wattage differs
when a lamp operates on a low-powerfactor ballast (typically residential
applications) versus a high-power-factor
ballast (typically commercial
applications). (The measured wattage of
a residential straight-shaped lamp could
be different depending on the ballast on
which it is operated.) 19 Thus, these
provisions effectively ensure that lamps
designed for residential applications are
tested on ballasts typically used for
residential applications. Defining ‘‘rated
wattage’’ for these lamps is significant,
as it clarifies whether DOE’s standards
are applicable to them. DOE believes
that the clarification is still relevant.
However, DOE notes that ANSI
Standard C78.81–2005 lists a rated
wattage value for a 25-Watt, 4-foot T12
rapid start medium bipin fluorescent
lamp, operating on a low-power-factor
ballast. Thus, it appears that some
lamps which could be classified as a
residential straight-shaped lamp have
rated wattage values listed in ANSI
Standard C78.81–2005. Therefore, DOE
intends to update the second portion of
the definition to state that if a
residential straight-shaped lamp is not
listed in ANSI, then rated wattage
19 If a lamp is not listed in ANSI C78.1–1991, its
‘‘rated wattage’’ would depend on test
measurements.
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should be based on the wattage a lamp
consumes when operated on a reference
ballast for which the lamp is designed.
The third part of the definition for
‘‘rated wattage’’ (applicable if neither of
the first two parts applies) states that the
rated wattage is that which results when
the lamp is tested under specified
testing conditions. DOE is updating the
test procedures for fluorescent and
incandescent lamps in a concurrent test
procedures rulemaking. The NOPR for
that rulemaking is published in today’s
Federal Register. As part of the test
procedures rulemaking, DOE is also
developing testing methods for lamps
not currently listed in ANSI standards
which will be included as part of the
DOE test procedure. DOE believes that
it is preferable to reference these more
detailed test procedures, rather than the
current approach of specifying testing
conditions in the definitions section of
10 CFR 430.2. Therefore, DOE intends to
replace the third part of the ‘‘rated
wattage’’ definition with a reference to
the test procedures that will be set forth
in 10 CFR Part 430, Subpart B,
Appendix R.
EPCA’s definition of ‘‘fluorescent
lamp’’ uses the term ‘‘rated wattage’’ not
only in describing 4-foot medium bipin
lamps, but also in describing 2-foot Ushaped and 8-foot single pin slimline
lamps. (42 U.S.C. 6291(30)(A)(ii) and
(iv)) To clarify rated wattage for 2-foot
U-shaped, and 8-foot single pin slimline
lamps, DOE has tentatively decided to
utilize the same framework to define
‘‘rated wattage’’ as was used for 4-foot
medium bipin lamps. In particular, DOE
plans to reference ANSI industry
standards where they have defined the
rated wattage for particular lamps, and
to reference DOE’s test procedures (as
amended) where ANSI has not defined
the rated wattage for particular lamps.
Thus, DOE intends to modify the
current definition of ‘‘rated wattage’’
that applies to 4-foot medium bipin
lamps and make it applicable to all
covered fluorescent lamps. Because
ANSI Standard C78.81–2005 does not
include ratings for U-shaped lamps,
DOE plans to incorporate by reference
and to cite to ANSI Standard C78.901–
2005, ‘‘for Electric Lamps—Single-Based
Fluorescent Lamps—Dimensional and
Electrical Characteristics’’, which does.
ANSI Standard C78.901–2005 also
contains Clause 11.1, using text similar
to that noted above.
The statutory definition for
‘‘incandescent lamp’’ also contains the
term ‘‘rated wattage,’’ and the definition
for ‘‘incandescent reflector lamp’’
similarly references a portion of the
definition of ‘‘incandescent lamp’’
which contains that term. In addition,
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EISA 2007 set energy conservation
standards for general service
incandescent lamps which require the
lamps to meet a maximum rated wattage
for a particular lumen output. For
incandescent reflector lamps and
general service incandescent lamps, the
rated wattage is the same as measured
wattage. Therefore, DOE believes that
the test procedures outlined in 10 CFR
Part 430, Subpart B, Appendix R suffice
for determining rated wattage for
incandescent lamps.
The following summarizes the
modified definition of ‘‘rated wattage’’
that DOE intends to consider making
applicable to all covered lamps and
updated to reference current industry
standards:
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.
DOE requests comment on its abovediscussed modification of the definition
of ‘‘rated wattage,’’ applicable to both
covered fluorescent and incandescent
lamps. DOE recognizes that changes to
the definition could affect coverage for
fluorescent lamps. However, DOE
believes that the modifications would
have a relatively minor, if any, impact
on the scope of coverage.
2. ‘‘Colored Fluorescent Lamp’’
With regard to the definition of
‘‘colored fluorescent lamp’’ that was
codified in the CFR as part of the 1997
Test Procedure Final Rule, DOE is
requesting comment on the definition
for this type of fluorescent lamp which
is excluded from energy conservation
standards. The current definition of that
term reads as follows:
Colored fluorescent lamp means a
fluorescent lamp designated and
marketed as a colored lamp, and with
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either of the following characteristics: A
CRI less than 40, as determined
according to the method given in CIE
Publication 13.2 (see 10 CFR 430.22), or
a lamp correlated color temperature less
than 2,500K or greater than 6,600K. 10
CFR 430.2.
In its market research, DOE observed
that one of the major lamp
manufacturers that operates in the
European market recently introduced a
fluorescent lamp with a correlated color
temperature (CCT) of 17,000K. The
product literature associated with this
new lamp indicates that it is intended
for general illumination applications. In
the ‘‘Product Application’’ section of the
literature, it suggests that this lamp be
used for ‘‘Indoor working areas (call
centers, industry, schools, healthcare
etc.), especially where an energizing
environment needs to be created.’’ 20
Even though DOE is unaware of any
general purpose fluorescent lamps like
this one being introduced into the U.S.
market, there is the potential that the
current definition of ‘‘colored
fluorescent lamp’’ would provide an
exclusion for new products being
introduced in general illumination
lighting applications. Therefore, DOE is
considering revising the definition,
possibly by adding a phrase such as
‘‘and not designed or marketed for
general illumination applications.’’ DOE
invites comment on this issue.
III. Energy Conservation Standards
Analyses for Fluorescent and
Incandescent Reflector Lamps
This section addresses the analyses
DOE has performed and intends to
perform for GSFL and IRL under
consideration in this rulemaking and
discusses the underlying assumptions
applied to the analyses. For both GSFL
and IRL, DOE will perform a set of
analyses, including: (1) An engineering
analysis; (2) a product price
determination; (3) an energy-use
determination; (4) an LCC and PBP
analysis; (5) an NIA; and (6) an MIA. A
full description of how these analyses
are performed is contained in the TSD.21
However, this section of the ANOPR
provides an overview of these analyses,
while focusing on how these analyses
are being tailored to this rulemaking and
on their underlying assumptions. It also
discusses comments received from
interested parties since DOE published
20 Philips Lighting Product Specification
Document, MASTER TL5 ActiViva Active 54W SLV
(published June 29, 2007).
21 Available at: https://www.eere.energy.gov/
buildings/appliance_standards/residential/
incandescent_lamps.html.
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the lighting products Framework
Document.
A. Market and Technology Assessment
The market assessment provides an
overall picture of the market for the
products concerned, including the
nature of the products, the industry
structure, and market characteristics for
the products. The technology
assessment identifies available
technologies for these products, which
will be considered in the screening
analysis. The subjects addressed in the
market and technology assessment
include product classes, technology
options, manufacturers, quantities and
types of products sold and offered for
sale, retail market trends, and regulatory
and non-regulatory programs. DOE
considers both quantitative and
qualitative information from publicly
available sources and stakeholders in
this assessment. The information DOE
gathers for the market and technology
assessment serves as resource material
for use throughout the rulemaking.
1. Market Assessment
Issues addressed in the market
assessment include: (1) Information
about lamp manufacturers; (2) existing
regulatory and non-regulatory
initiatives; (3) historical shipments and
(4) product classes. Each of these topics
will be discussed in turn below.
NEMA is the trade association that
represents many GSFL and IRL
manufacturers. NEMA provides an
organization framework for
manufacturers of lighting products to
work together on projects that affect
their industry and business.
The majority of the domestic market
share of GSFL and IRL is held by three
manufacturers: (1) GE Lighting (General
Electric, Inc.); (2) OSRAM Sylvania
(Siemens AG); and (3) Philips Lighting
(Royal Philips Electronics). In addition
to lamps listed under this rulemaking,
the lighting divisions of all three
companies manufacture other products,
such as lamp ballasts, high intensity
discharge lamps, LED lighting, GSIL
(already regulated by EISA 2007) and
compact fluorescent lamps (CFL).
It is noted that DOE is required to
consider whether small businesses are
likely to be particularly affected by the
promulgation of minimum efficacy
standards for lamps. (5 U.S.C. 601 et
seq.) The Small Business
Administration (SBA) defines ‘‘small
business’’ manufacturing enterprises for
manufacturers of GSFL and IRL as ones
having 1,000 or fewer employees.22
22 Small Business Administration, Table of Small
Business Size Standards: Matched to North
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More specifically, SBA lists small
business size standards that are matched
to industries as they are described in the
North American Industry Classification
System (NAICS). A small business size
standard is the largest that a for-profit
entity can be and still qualify as a small
business for Federal Government
programs. These size standards are
generally related to the average annual
receipts or the average employment of a
firm. For lamp products, the size
standard is matched to NAICS code
335110, Electric Lamp Bulb and Part
Manufacturing, which has a size
standard of 1,000 employees. DOE
identifies several small business
manufacturers of GSFL and IRL in
Chapter 3 of the TSD. DOE will study
the potential impacts on small
businesses in detail during the MIA,
which it will conduct as a part of the
analyses for the notice of proposed
rulemaking.
Furthermore, DOE is aware of several
Federal, State, and international
regulatory programs that impact the
GSFL and IRL markets. Amendments to
EPCA in EPACT 1992 established
Federal energy conservation standards
for residential, commercial, and
industrial GSFL and IRL. (42 U.S.C.
6295(i)(1)) In addition to the Federal
regulations, the following States have
established appliance efficiency
regulations for other lamps for which
there are no Federal standards (and thus
are not preempted): Arizona, California,
Connecticut, Maryland, Massachusetts,
Minnesota, New Jersey, New York,
Oregon, Rhode Island, Vermont, and
Washington.
DOE also reviewed several voluntary
programs promoting the use of energyefficient GSFL in the United States,
including the Federal Energy
Management Program’s (FEMP) program
for energy-efficient lighting, the
Consortium for Energy Efficiency
(CEE)’s High Performance Commercial
Lighting Initiative, the Energy Efficient
Commercial Buildings Deduction, and
various regional initiatives that work
with State utilities to offer rebates for
installation of higher efficacy GSFL
systems. See Chapter 3 of the TSD for
more information regarding regulatory
and non-regulatory initiatives.
DOE received historical shipment
data from NEMA for the years 2001 to
2005 for the two categories of lamps.
(NEMA, No. 12 at pp. 5–6) Overall,
NEMA’s historical lamp shipment data
that was incorporated by DOE into the
analytical tools for the ANOPR had
three main purposes. First, the shipment
data and market trend information
contributed to the shipments analysis
and base-case forecast for each of the
two categories of lamps (see Chapter 9
of the TSD). By using recent shipment
data and expert opinion on market
trends, DOE believes that the shipments
model and base-case forecasts are based
on a sound dataset. Second, DOE used
the data to select the representative
product classes and representative units
for analysis. Generally, DOE selected
representative product classes and units
for analysis to reflect the highest
volume, most common lamp types and
wattages used in the U.S. today (see
Chapter 3 of the TSD). And thirdly, DOE
used these data to develop the market-
share matrices for the NIA (see Chapter
10 of the TSD). Based on its
understanding of trends in the market,
DOE estimated how the market would
respond to the various CSLs.
Additional detail on the market
assessment can be found in Chapter 3 of
the TSD.
2. Product Classes
In general, when 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. (See 42 U.S.C.
6295(q)) DOE normally establishes
different energy conservation standards
for different product classes based on
these criteria. However, classification of
lamps into product classes presents a
challenge, because, for example, a
fluorescent lamp is a component of a
system, and the lamp’s performance is
directly related to the ballast on which
it operates. The following section
describes and discusses the product
classes of lamps that DOE is considering
for this rulemaking.
a. General Service Fluorescent Lamps
EPCA established eight product
classes for GSFL based on the four
fluorescent lamp types EPCA describes
in its definition for ‘‘fluorescent lamp’’
and based on nominal lamp wattage. (42
U.S.C. 6295(i)(1)(B)) These product
classes are outlined in Table III.1.
TABLE III.1.—EPCA PRODUCT CLASSES FOR GSFL
Nominal
lamp
wattage
W
Lamp type
4-ft Medium Bipin .....................................................................................................................................
2-ft U-Shaped ..........................................................................................................................................
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8-ft Single Pin ..........................................................................................................................................
Slimline ....................................................................................................................................................
8-ft High Output .......................................................................................................................................
In the Framework Document for this
rulemaking, DOE presented a
preliminary discussion of potential
revisions to the prescriptive standards
established by EPCA. ((42 U.S.C.
6295(i)(1)(B); see 10 CFR 430.32(n)(1)).
Specifically, DOE considered
subdividing the product categories in
EPCA’s table of efficacy requirements
for fluorescent lamps, nearly doubling
the number of product classes by
introducing lamp tube diameter as a
differentiating variable (i.e., ‘‘>T8’’ and
‘‘≤T8’’). In presenting this potential
American Industry Classification System Codes.
(Feb. 2007). Available at: https://www.sba.gov/
>35W
≤35W
>35W
≤35W
>65W
≤65W
>100W
≤100W
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Min. CRI
69
45
69
45
69
45
69
45
Min. avg.
efficacy
lm/W
75.0
75.0
68.0
64.0
80.0
80.0
80.0
80.0
modification, DOE used the same
wattage divisions and minimum color
rendering index (CRI) requirements that
EPCA uses for these lamps, with T8 and
T12 lamps in the same product class.
Several stakeholders provided comment
on the draft product classes discussed in
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the Framework Document, as discussed
below.
For 4-foot medium bipin lamps,
Philips suggested combining all lamps
with diameters greater than T8 into one
category. Philips then suggested creating
a category for T8 and smaller diameters
with wattages less than or equal to 32W.
(Philips, No. 11 at p. 1) GE and Osram
both supported DOE’s suggestion for
lamps with diameters greater than T8,
but they suggested that DOE should
change the wattage division from 35W
to 31W, and include a correlated color
temperature (CCT) division for lamps
with diameters less than or equal to T8.
(GE, No. 13 at pp. 1–2; Osram, No. 15
at pp. 2–3) The Joint Comment
recommended that DOE combine the T8
and T12 product classes, because there
are few T8 lamps above 35W, and,
therefore, the existing wattage bins
could be analyzed by maintaining some
separation of T8 and T12 lamps. (Joint
Comment, No. 9 at p. 8)
For 2-foot U-shaped lamps, Philips
suggested modifying the draft product
classes by combining wattage ranges,
and the commenter also recommended
having just two product classes, based
upon lamp diameter, that apply to any
wattage 2-foot U-shaped lamps. GE and
Osram both supported DOE’s approach
for considering lamps with diameters
greater than T8, and these commenters
suggested that DOE should change the
wattage division from 35W to 31W, and
include a CCT division for lamps with
diameters less than or equal to T8. (GE,
No. 13 at pp. 1–2; Osram, No. 15 at pp.
2–3)
For the 8-foot single pin slimline
lamps, Philips suggested combining all
lamps with diameters greater than T8
into one product class, and then
establishing a separate product class for
lamps with T8 and narrower diameters,
regardless of wattage. (Philips, No. 11 at
pp. 1–2) GE and Osram both suggested
keeping the T12 category of high output
lamps, and creating a separate class for
diameters less than T12. For this new
separate class, GE and Osram both
proposed dividing it further into two
subclasses, one including T12 8-foot
single pin slimline lamps with wattages
greater than 58W and another including
T12 8-foot single pin lamps with
wattages less than or equal to 58W. (GE,
No. 13 at pp. 1–2; Osram, No. 15 at pp.
2–3)
For the 8-foot high output lamps,
Philips suggested combining all lamps
with diameters greater than T8 into one
product class, and then establishing a
separate product class for lamps with T8
and narrower diameters with a nominal
lamp wattage of 86W and below.
(Philips, No. 11 at pp. 1–2) GE and
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Osram both suggested keeping the T12
category of high output lamps, and
creating a separate class for lamps with
diameters less than T12. (GE, No. 13 at
pp. 1–2; Osram, No. 15 at pp. 2–3) GE
argued that this class of lamps with
diameters less than T12 should
encompass all wattages, whereas Osram
recommended that the class should
encompass only lamps greater than
85W. (GE, No. 13 at pp. 1–2; Osram, No.
15 at pp. 2–3)
DOE considered all these comments,
and continued to research appropriate
product classes for the general service
fluorescent lamps being considered for
coverage under this rulemaking. DOE
identified differential utility and
physical attributes of fluorescent lamps
around which the development of
separate product classes would be based
on the statutory criteria. (42 U.S.C.
6295(q)) 23 In this notice, DOE is
considering establishing product classes
based upon the following three lamp
attributes that have differential utility
and impact efficacy: (1) Physical
constraints of lamps (i.e., lamp shape
and lamp length); (2) lumen package
(i.e., regular versus high output); and (3)
CCT. Following that discussion, this
document also analyzes other potential
factors that DOE considered as potential
product class determinants (i.e., ballast
interoperability, lamp wattage, lamp
diameter, and color rendering index),
but which were not adopted for reasons
indicated below.
i. Class Setting Factors
Physical Constraints of Lamps. The
physical constraints of the lamp relate
to the shape of the lamp (e.g., U-shaped
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
23 (q) Special rule for certain types or classes of
products
(1) A rule prescribing an energy conservation
standard for a type (or class) of covered products
shall specify a level of energy use or efficiency
higher or lower than that which applies (or would
apply) for such type (or class) for any group of
covered products which have the same function or
intended use, if the Secretary determines that
covered 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 from that which applies (or will
apply) to other products within such type (or class).
In making a determination under this paragraph
concerning whether a performance-related feature
justifies the establishment of a higher or lower
standard, the Secretary shall consider such factors
as the utility to the consumer of such a feature, and
such other factors as the Secretary deems
appropriate.
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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. For
example, a 2-foot U-shaped lamp, while
having the same overall tube length, is
less efficacious than a 4-foot linear lamp
due in part to the fact that the electrical
arc within the tube has to bend to
conform to the shape of the lamp.
Similarly, a 4-foot lamp has a different
utility than an 8-foot lamp, as these
lamps generally require different
fixtures. And, efficacy tends to increase
with length, such that all else being
equal, 8-foot lamps generally have
higher efficacy values than 4-foot lamps.
Given the impact that geometry has on
both utility and efficacy, DOE proposes
maintaining the division of product
classes by lamp geometry.
Lumen Package. In addition to the
physical constraints of a lamp, DOE also
recognizes that the lumen package a
lamp provides to consumers is another
potential differentiating factor for
product classes, because it provides
utility in the form of a quantity of light
per unit lamp length. In this way, 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 notes, however, that efficacy
decreases as a fluorescent lamp is
driven harder to increase its light
output. For example, the efficacy of high
output 8-foot lamps are approximately 7
to 10 percent lower than that of slimline
8-foot lamps. Because 8-foot lamps are
not already subdivided according to
physical constraints, DOE plans to
further subdivide the 8-foot linear lamps
into slimline and high output.
Considering the fluorescent lamps
currently covered under EPCA and the
additional general service fluorescent
lamps discussed in section II which
DOE is considering for coverage, DOE is
considering establishment of the
following four differentiating categories
of lamps: (a) 4-foot medium bipin; (b) 2foot U-shaped; (c) 8-foot single pin
slimline; and (d) 8-foot recessed double
contact high output. DOE notes that
these are the same four categories of
lamps that were established by EPCA in
section 325(i)(1). (42 U.S.C.
6295(i)(1)(B))
Correlated Color Temperature.
Finally, within each of these four
categories of fluorescent lamps, DOE
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recognizes that the CCT of the
fluorescent lamps provides a distinct
utility (i.e., the light emitted by the
fluorescent lamp has different qualities),
which impacts the efficacy of the lamp.
The CCT describes, in part, how the
white light emitted from a fluorescent
lamp is perceived. Lower color
temperatures correspond to ‘‘warmer’’
light, with more red content in the
spectrum, and higher color temperatures
correspond to ‘‘cooler’’ light, with more
blue content. As the spectral emission of
the light radiated from the fluorescent
lamp is modified to change the CCT, the
light emitted may contain more red light
(and less blue) or more blue light (and
less red). The measured efficacy of these
lamps with different CCT will be
different, because efficacy is measured
in lumens 24 per watt, and light emitted
across the visible spectrum is not given
equal weighting under this metric.
Lumens are determined using the
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 sum, the metric that DOE
will establish as the minimum
performance requirement for fluorescent
lamps—efficacy, measured in lumens
per watt—may need to be adjusted to
account for differences in the CCT of
light emitted from a fluorescent lamp.
Today, lamps with a ‘‘warmer’’ CCT
(4,100K) represent the majority of the
fluorescent lamp market, and therefore
this is the CCT of the lamps analyzed in
this ANOPR. Fluorescent lamps having
a ‘‘cooler’’ CCT (e.g., >5,000K) are
growing in popularity in the market,
perhaps because they have been found
to allow for better color discrimination
and improved visual performance.25
GE and Osram both requested that
DOE establish separate product classes
for T8 lamps with CCT above and below
4,500K. (GE, No. 13 at pp. 1–2; Osram,
No. 15 at p. 1 and p. 3) Osram
commented that higher CCT lamps have
a lower lumen output because lamps
with higher CCT contain more blue
light, which causes the lumen
measurement to be lower. Osram argued
that it is important for DOE to
differentiate certain fluorescent lamps
24 A ‘‘lumen’’ is a measurement of the radiometric
energy emission from a light source weighted by the
response function of a human eye, referred to as the
‘‘photopic spectral luminous efficiency function’’
(V(λ)).
25 ‘‘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/
claims.asp.
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by CCT in the analysis to account for
this difference in performance. (Osram,
No. 15 at p. 1) GE also stated that should
DOE decide to regulate lamps with high
CCT values (e.g., 5,000K), then these
types of lamps would require a different
and lower lumen-per-watt threshold,
because of the slightly lower lumen
rating due to the increased energy in the
blue part of the light emission spectrum.
(GE, No. 13 at p. 1) Philips commented
that if DOE decides to adopt efficacy
levels higher than those proposed by
Philips, then DOE should place higher
CCT lamps in a separate product class
because they tend to have slightly lower
efficacies. (Philips, No. 11 at p. 2)
In response, DOE believes that for
fluorescent lamps, the differences in
CCT of the light emission can be
sufficiently large that they constitute a
performance-related feature that affects
the efficacy of the lamp. Therefore, DOE
is planning to establish separate product
classes for GSFL in part based upon
CCT. Related to this preliminary
decision are two critical, associated
issues—(1) How many groups should be
established? and (2) Where should the
separator(s) between product classes be
set? DOE’s initial thoughts on this
matter are set forth below.
Presently, EPCA does not cover
colored fluorescent lamps (i.e., such
lamps are excluded under 42 U.S.C.
6291(30)(B)(iii)) and these lamps are
defined, in part by their CCT (both
terms defined at 10 CFR 430.2). Lamps
with a CCT less than 2,500K or greater
than 6,600K are considered ‘‘colored
fluorescent lamps’’ and are not subject
to the minimum efficacy standards
(note: See discussion in this section
pertaining to a potential revision to
coverage of colored fluorescent lamps).
DOE is considering dividing GSFL,
(with CCTs ranging from 2,500K to
6,000K) into two product classes. DOE
believes that establishing two groups
does not make the product classification
overly complex, and yet such approach
acknowledges the primary issue raised
about the different utility provided by
the cooler lamps. To this end, DOE is
considering adoption of a CCT divider
at 4,500K, as recommended by industry.
(Osram, No. 15 at p. 1, GE, No. 13 at p.
2) The most common CCTs found on the
market are 3,500K, 4,100K, 5,000K, and
6,500K. Thus, having a divider at
4,500K will establish separate product
classes for those lamps with ‘‘warmer’’
CCTs (3,500K and 4,100K) and ‘‘cooler’’
CCTs (5,000 and 6,500K). Although in
this proceeding, DOE is considering
establishing two separate CCT groups
for GSFL, if the trend toward much
higher CCT lamps continues (discussed
in section II.B.3), then DOE may need to
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establish multiple CCT groups, as the
spectral emission (and thus, efficacy) of
these general service lamps will vary as
the CCT increases.
DOE is requesting comment on all
aspects of this potential CCT division,
but particularly: (1) Whether there
should be a CCT product class divider;
(2) how many groupings of CCT are
appropriate; and (3) what the CCT
divider or dividers should be. In
addition, DOE welcomes technical
perspectives on how DOE might scale
the efficacy level from the
representative unit of analysis of 4,100K
to higher CCT product classes. In
addition, DOE also notes that if
comments indicate that the definition of
a colored fluorescent lamp warrants
some revision such that certain very
high CCT lamps would be covered (e.g.,
over 17,000K), then perhaps it would be
appropriate to consider several CCT
groupings (which would manifest
themselves as minimum efficacy steps).
DOE requests further comment on this
issue, including technical perspectives.
ii. Other Potential Class-Setting Factors
Considered, But Not Adopted
As stated above, DOE did not choose
to establish product classes based upon
any of the following four factors: (1)
Ballast interoperability; (2) lamp
wattage; (3) lamp diameter (i.e., T8 vs.
T12); and (4) color rendering index
(CRI). Each of these factors is discussed
below, along with DOE’s rationale for
not further considering them for classsetting purposes.
Ballast Interoperability. DOE did not
consider interoperability of lamps on
the same ballast system as a
differentiating factor for product classes.
DOE acknowledges that there is a
difference between lamps and lampand-ballast systems, and that certain
lamps may have the same form factor
but may not operate on the same ballast.
However, DOE treats these constraints
as an economic issue in its LCC
analysis, rather than a utility issue. In
other words, in the LCC analysis, DOE
considered a T8 lamp as a moreefficacious replacement for a T12
baseline lamp. In its economic analysis,
DOE accounts for the need to install a
new ballast to operate the T8 lamp by
including the installed cost of a new
lamp and ballast for the T8 replacement.
This consideration of T8 lamps as
substitutes for T12 lamps is consistent
with DOE’s understanding of the
market, and with manufacturers’
marketing literature. Had DOE elected to
differentiate these lamps on ballast
interoperability, or indeed, lamp
diameter, this direct comparison may
not have been made. DOE believes this
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approach is appropriate for this
rulemaking, because there is no unique
functionality or service rendered by, for
example, one T8 lamp and an
equivalent T12 lamp.
Lamp Wattage. With respect to lamp
wattage, DOE observed in the product
literature published by manufacturers
that lower-wattage lamps are marketed
and promoted as energy-saving versions
of the more popular wattages. For
example, lamps with 25W, 28W, and
30W are marketed as energy-efficient
alternatives to the 32W T8. For this
reason, DOE does not believe it is
appropriate to establish divisions based
upon wattage within the product
classes, because wattage does not have
utility in and of itself, but rather is a
measure of energy use. For example, if
a 30W T8 lamp can deliver the same (or
very similar) performance as a 32W T8,
then there is no reason to establish an
arbitrary wattage divide at 31W, forcing
these two lamps into separate product
classes. If two product classes were set,
the 30W T8 lamp could not be
considered as an efficient alternative for
the 32W T8 lamp, which conflicts with
how these lamps are treated by the
market. DOE understands that these
reduced-wattage lamps are marketed
and used by consumers as energyefficient substitutes, and therefore,
should be considered as such when
DOE establishes product classes for
these lamp types. Therefore, DOE plans
to consider eliminating wattage-based
dividers, because this attribute by itself
does not provide utility. Fluorescent
lamps of different wattages are generally
capable of being substituted for each
other, and provide the same or similar
service. DOE also believes that a
product classification system that
eliminates wattage dividers would be
more representative of how these lamps
are currently being installed and used in
the market.
Lamp Diameter. With respect to lamp
diameter, DOE had expressed in the
Framework Document its intention to
consider lamps with diameters of T8
and smaller in one product class and
lamps with diameters greater than T8 in
a separate product class. On further
consideration, DOE has tentatively
decided that the lamp diameter does not
provide unique utility to end-users. As
an example, a consumer can choose to
use a 4-foot medium bipin lamp and be
able to obtain similar lumen packages
from either a T12 or T8 model. The T8
lamp may need to be operated on a
different ballast with a higher ballast
factor (BF), but the system can be
modified to account for the differences
in lamp diameter, so the resultant
systems are approximately equivalent.
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DOE recognizes that the diameter of the
lamp will impact the efficacy, but the
utility provided to the end-user is
comparable and/or equivalent.
Therefore, DOE has tentatively decided
not to separate product classes by lamp
diameter.
However, recognizing that both T12
and T8 lamps operate on different
ballasts and in order to consider
separately the impact of standards on
consumers of both types of lamps, DOE
structured the analytical tools
(including the LCC and NIA
spreadsheets) so that each consumer
subgroup could be analyzed separately.
Thus, for example, the LCC results are
reported separately for T8 and T12
baseline lamps.
Color Rendering Index. The Color
Rendering Index (CRI) is the ability of
a light source to produce color in
objects. The CRI is expressed on a scale
from 0–100, where 100 is the best in
producing vibrant color in objects.
Relatively speaking, a source with a CRI
of 80 will produce more vibrant color in
the same object than a source with a CRI
of 60. Generally, fluorescent lamps with
higher efficiency phosphors exhibit both
a higher efficacy and higher CRI,
although this is not always the case.
EPCA establishes an upper and lower
bound on the CRI of GSFL. Specifically,
EPCA states that lamps with a CRI equal
to or greater than 87 are excluded from
coverage. (42 U.S.C. 6291(30)(B)(viii))
EPCA also establishes two minimum
CRI requirements for each of the four
groups of fluorescent lamps, one at 69
CRI and one at 45 CRI. Within one
group of fluorescent lamps (e.g., 4-foot
medium bipin), EPCA requires that
lamps nominally rated at greater than
35W have a minimum CRI of 69 and
that lamps nominally rated at 35W or
lower have a minimum CRI of 45. (42
U.S.C. 6295(i)(1)(B); see 10 CFR
430.32(n)(1))
Several manufacturers suggested that
DOE should make changes to the
minimum CRI required for GSFL.
(Philips, No. 11 at p. 1; GE, No. 13 at
p. 2; Osram, No. 15 at p. 3) These
manufacturers recommended that the
T8 lamp diameter product classes
should have minimum CRI values of 75.
Philips also recommended that DOE
should adopt minimum CRI values of 75
or greater for all fluorescent lamp
product classes, given today’s
technology. (Philips, No. 11 at p. 1)
DOE considered these comments, but
believes it lacks the authority to
accommodate this request to adjust
minimum CRI values in this way. While
75 CRI may be a reasonable level for
fluorescent lamps, DOE’s mandate from
Congress is to focus on advancing
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energy efficiency and energy
conservation in the marketplace. DOE
does not set standards by regulating
specific performance attributes of
products, such as the CRI rating of a
lamp. Furthermore, if DOE were to
simply adopt the higher CRI level, it
might be eliminating lamps from the
market without conducting a
rulemaking analysis to determine
whether this action was cost-justified or
not. For all of these reasons, DOE is not
increasing the minimum CRI
requirement to 75, but is inviting further
comment and rationale on possible
approaches to handling the issue of CRI.
DOE recognizes that in removing the
wattage distinctions for GSFL product
classes, the metric that differentiated by
CRI is no longer present. Therefore,
some possible solutions would be to: (1)
Eliminate the CRI minimum
requirement for all regulated fluorescent
lamps; (2) adopt the lower of the two
CRI minimum requirements (i.e., 45
CRI) as applying to all regulated
fluorescent lamps; (3) adopt the higher
of the two CRI requirements (i.e., 69
CRI) as applying to all regulated
fluorescent lamps; (4) adopt the CRI of
the representative lamp that is
determined to be cost-justified as the
minimum CRI for that product class;
and (5) maintain the CRI requirements
in EPCA for the product classes
established by EPACT 1992 while
setting efficacy standards for the
product classes established in this
notice.
DOE recognizes that each of these
approaches for addressing the CRI
minimum requirement has its own
advantages and disadvantages. The first
option, eliminating the CRI requirement,
risks the potential for a back-sliding in
performance. That said, for the products
offered in the market today, the CRI
generally increases with the efficacy
levels considered in this rulemaking.
Thus, the CRI values of future
standards-compliant lamps would
naturally be higher than the two existing
minimum requirements. The second
option suggests that DOE simply apply
the minimum 45 CRI requirement to all
fluorescent lamps. This approach would
not eliminate any lamps now covered
between 45 and 69 CRI, however as with
the first option, carries a certain risk
that there may be some backsliding for
lamps that previously required to meet
would have had to have been 69 CRI,
but which now could be as low as 45
CRI.
The third option, to simply require all
lamps to have a minimum of 69 CRI,
would eliminate certain lamps that are
presently manufactured between 45 and
69 CRI. DOE notes that through this
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energy conservation standards
rulemaking, it may be increasing the
efficacy requirements on those lamps
anyway, which may have the effect of
preventing further use of those
phosphors that supply light with a 45 to
69 CRI performance. However, to simply
change the CRI requirement without
analysis, and thereby eliminate product,
appears to be in conflict with DOE’s
authority under EPCA. The fourth
option identified above concerns DOE
simply adopting the CRI requirement of
the cost-justified lamp considered in the
rulemaking analysis. That is to say, if
DOE determines that a particular lamp
with a certain efficacy is the costjustified level at which it will set the
mandatory standard for that product
class, DOE would also adopt the CRI of
that lamp as the minimum CRI
requirement for all lamps in that
product class. Finally, the fifth option
maintains the current minimum
requirements in EPCA for the product
classes established in EPACT 1992
while setting efficacy requirements for
the additional product classes
established in this notice. Because this
option requires no change in the CRI
requirement for fluorescent lamps, there
is no risk of eliminating product from
the marketplace nor does it allow for
backsliding in performance.
DOE requests comment on these five
alternative approaches or others that
would address the issue of the
minimum CRI requirement for
fluorescent lamps.
iii. Product Class Results
For the reasons discussed above, DOE
has tentatively decided to consider the
following product classes for GSFL (see
Table III.2). These draft product classes
are more aggregated than those
originally presented in the Framework
Document. For each of the eight product
classes, DOE anticipates that it would
develop a point efficacy value (lumens
per watt), which would apply to all the
lamps covered within each class.
TABLE III.2.—DOE ANOPR PRODUCT CLASSES FOR GSFL
For CCT ≤ 4,500K,
minimum lamp efficacy
lm/W
Lamp type
4-foot
2-foot
8-foot
8-foot
medium bipin ..........................................................
U-shaped ................................................................
single pin slimline ...................................................
recessed double contact HO .................................
b. Incandescent Reflector Lamps
EPCA established minimum efficacy
requirements by wattage for IRL, as
presented in Table III.3. (42 U.S.C.
6295(i)(1)(B))
TABLE III.3.—EPCA PRODUCT CLASSES AND EFFICACY REQUIREMENTS
FOR IRL
Wattage
W
Min. average
efficacy
lm/W
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40–50 ....................................
51–66 ....................................
67–85 ....................................
86–115 ..................................
116–155 ................................
156–205 ................................
10.5
11.0
12.5
14.0
14.5
15.0
In its Framework Document, DOE
stated its preliminary intention to keep
the same six product classes. DOE
requested comment on this approach,
including whether any modifications to
the six product classes was warranted.
Several stakeholders commented that
these potential product classes for IRL
seemed reasonable and appropriate for
this rulemaking. (NEMA, No. 4.5 at p.
75; ACEEE, No. 4.5 at p. 75; PG&E, No.
4.5 at p. 75; EEI, No. 4.5 at p. 76; NEMA,
No. 8 at p. 2; Joint Comment, No. 9 at
p. 5) DOE’s additional research,
however, has identified a problem with
the potential product classes presented
in the Framework Document,
particularly as DOE considered standard
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Product
Product
Product
Product
Class
Class
Class
Class
#1
#2
#3
#4
.............................................................
.............................................................
.............................................................
.............................................................
levels with higher efficacy values. The
existing wattage groups are problematic
because the wattage rating of the lamp
is a property about the lamp that the
regulation is working to reduce, and yet
it is also being used as the basis of
classification. This issue is further
complicated by the fact that some
consumers (particularly in the
residential sector) think of and purchase
IRL based on the rated wattage, which
is associated with an expected level of
light output. The following discussion
outlines DOE analyses in determining
preliminary product classes for
incandescent reflector lamps and the
rationale therefore.
i. Class Setting Factors
Modified-Spectrum. As discussed in
section I.E.2, EISA 2007 adopted a new
definition for ‘‘colored incandescent
lamp’’ 26 which supersedes DOE’s
definition previously incorporated at 10
CFR 430.2.27 This new statutory
26 EISA 2007’s definition of ‘‘colored
incandescent lamp’’ reads as follows: ‘‘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 CIE 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).’’
27 The definition of ‘‘colored incandescent lamp’’
adopted by the 1997 Lamps Test Procedure Final
Rule 62 FR 29221, 29228 (May 29, 1997) reads as
follows: ‘‘Colored incandescent lamp means an
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minimum lamp efficacy
lm/W
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Product
Product
Product
Product
Class
Class
Class
Class
#5.
#6.
#7.
#8.
definition effectively increases the
scope of energy conservation standards
coverage of IRL to include any IRL that
has a lens containing five percent or
more neodymium oxide or is a plant
light lamp. As both of these types of IRL
filter out portions of the emitted
spectrum of the lamp, DOE believes that
many of these lamps would fall under
the definition of ‘‘modified spectrum’’
which was also adopted by the new
energy legislation. The EISA 2007
definition of ‘‘modified spectrum’’ reads
as follows:
‘‘The term ‘modified spectrum’
means, with respect to an incandescent
lamp, an incandescent lamp that—
(i) Is not a colored incandescent lamp;
and
(ii) When operated at the rated voltage
and wattage of the incandescent lamp—
I. Has a color point with (x,y)
chromaticity coordinates on the
Commission Internationale de
l’Eclairage (C.I.E.) 1931 chromaticity
diagram that lies below the black-body
locus; and
II. has a color point (x,y) chromaticity
coordinates on the C.I.E. 1931
chromaticity diagram that lies at least 4
incandescent lamp designated and marketed as a
colored lamp that has a CRI less than 50, as
determined according to the method given in CIE
Publication 13.2 (see 10 CFR 430.22); has a
correlated color temperature less than 2,500K or
greater than 4,600K; has a lens containing 5 percent
or more neodymium oxide; or contains a filter to
suppress yellow and green portions of the spectrum
and is specifically designed, designated and
marketed as a plant light.’’
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MacAdam steps (as referenced in IESNA
LM16) distant from the color point of a
clear lamp with the same filament and
bulb shape, operated at the same rated
voltage and wattage.’’ (42 U.S.C.
6291(30)(W))
Modified-spectrum lamps provide
unique utility 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
improved visual performance.28 In
addition to providing a unique utility,
DOE also understands that the
technologies that modify the spectral
emission from these lamps also decrease
their efficacy (i.e., the ability of the
lamp to convert watts of energy into
lumens of visible light). This is because
a portion of the light emission is
absorbed by the coating. Neodymium
coatings or other coatings on modifiedspectrum lamps absorb some of the
visible emission from the incandescent
filament (usually red), creating a
modified, reduced spectral emission.
Since the neodymium or other coatings
absorb some of the lumen output from
the filament, these coatings decrease the
efficacy of the lamp.
DOE is concerned that, given the
newly-adopted definition of ‘‘colored
incandescent lamp,’’ if DOE were to
subject modified-spectrum IRL to the
same standard as standard-spectrum
IRL, then these IRL with modifiedspectrum glass or coatings may not be
able to achieve the mandatory standard,
which could in turn lead to this type of
product being lost from the market.
Therefore, consistent with EISA 2007’s
approach on general service
incandescent lamp standards, DOE is
planning to establish separate product
classes for regular IRL (i.e., those
without modification to the spectral
emission) and modified-spectrum IRL
(i.e., ones which have some portion of
the spectral emission absorbed).
However, to ensure that a suitable
standard level is set for these lamps
(such that they are neither
disadvantaged nor advantaged
compared to standard-spectrum lamps),
DOE plans to establish an appropriately
scaled efficacy requirement for them,
28 ‘‘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/
claims.asp.
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based on DOE’s analysis of standardspectrum IRL and then adjusted to
account for the portions of the spectrum
that are absorbed by the neodymium or
spectrally-enhancing coating. DOE
discusses how this scaling would be
accomplished in the Engineering
Analysis (see section III.C.6).
ii. Other Potential Class-Setting Factors
Considered, but Not Adopted
Wattage. As DOE started to structure
the analytical framework for the IRL
analysis, DOE increasingly found that
the initial approach of six wattage
groups for product classes was not
reasonable. Particularly as moreefficacious IRL with equivalent light
output were considered, the approach
presented in the Framework Document
would have resulted in these
replacement lamps being placed in a
separate product class, and as such,
would no longer be considered a
‘‘replacement.’’ For example, consider a
75W reflector lamp at 14.0 lm/W and an
equivalent, more-efficacious
replacement at 60W at 17.5 lm/W. These
two lamps are essentially equivalent
products, with equal levels of light
output, operating lives, and customer
utility (e.g., both operate in the same
socket). However, under the Framework
Document’s approach for potential IRL
product classes, these lamps would
appear in different product classes. (42
U.S.C. 6295(i)(1)(B); see 10 CFR
430.32(n)(2)) Thus, DOE realized that
wattage is not a suitable product class
divider because it does not provide a
unique utility; instead, it merely
provides a measure of power
consumption.
On further examination and
consideration of the standard
established by EPCA for reflector lamps,
DOE is now interpreting the wattage
groups in the existing standard as
equivalent to a mathematical stepfunction equation that applies to all
regulated IRL. DOE believes EPCA, in
effect, establishes different minimum
average lamp efficacies at each ‘‘step’’ or
range of wattages for a single product
class, which encompasses all IRL. This
function recognizes that IRL
incorporating the same technological
feature, like a halogen capsule, are less
efficacious at lower wattages than
higher wattages. Therefore, lamps at
lower wattages are subject to a lower
standard than lamps at higher wattages
even though lamps at all wattages are in
the same product class.
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As DOE considers more-efficacious
substitute lamps in the analysis for this
rulemaking, it must decrease the
nominal lamp wattage range in order to
keep the light output of the substitute
lamps to within ten percent of the light
output of the baseline lamp. Thus, as
DOE presents the CSLs for the ANOPR,
DOE plans to use a mathematical
function that would establish the
efficacy requirement at any wattage.
Like the step function in EPCA, this
mathematical function accounts for the
fact that lamps at lower wattages are
inherently less efficacious than lamps at
higher wattages. See TSD Chapter 5 for
a detailed discussion on the
development of the CSLs for IRL.
Spot Versus Flood Incandescent
Reflector Lamps. With respect to the
issue of spot versus flood reflector
lamps, several stakeholders commented
that they did not believe DOE should
establish separate product classes on
this basis. (NEMA, No. 4.5 at p. 75;
ACEEE, No. 4.5 at p. 75; PG&E, No. 4.5
at p. 75; EEI, No. 4.5 at p. 76; NEMA,
No. 8 at p. 2) DOE considered these
comments and reviewed technical
reports on the performance of spot
versus flood reflector lamps. Based
upon this information, DOE has
tentatively concluded that while there
might be a differentiating utility
afforded to consumers through the light
distribution patterns of a spot reflector
lamp versus a flood reflector lamp, that
differentiating utility would not be
expected to impact the efficacy of the
lamp. Thus, DOE does not plan on
creating separate product classes for
spot and flood reflector lamps.
iii. Product Class Results
In sum, as discussed previously, DOE
is considering all wattages of reflector
lamps to be part of the same product
class, with the standard level for any
given lamp being a function of lamp
wattage. As DOE considers moreefficacious replacement lamps, the rated
wattages must decrease in order to
maintain consistent levels of light
output (i.e., within ten percent of the
baseline lamp). Additionally, DOE is
planning to consider efficacy standards
for full-spectrum IRL separately from
modified-spectrum IRL. Table III.4
summarizes the two product classes
DOE is considering for the ANOPR. (For
ease of commenting on IRL product
classes, DOE has continued the product
class numbering from where the GSFL
classes left off.)
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TABLE III.4.—DOE ANOPR PRODUCT CLASSES FOR IRL
Modified-spectrum
minimum lamp efficacy
lm/W
Lamp type
Standard-spectrum minimum lamp efficacy
lm/W
Incandescent Reflector Lamps .........................................
Product Class #9 .............................................................
3. Technology Assessment
In the technology assessment, DOE
identifies technology options that
appear to be feasible means of
improving product efficacy. This
assessment provides the technical
background and structure on which
DOE bases its screening and engineering
analyses. The following discussion
provides an overview of the salient
aspects of the technology assessment,
including issues on which DOE seeks
public comment. For a more complete
discussion, Chapter 3 of the TSD
provides detailed descriptions of the
basic construction and operation of
GSFL and IRL, followed by a discussion
of technology options to improve the
efficacy of that lamp type.
Product Class #10.
a. General Service Fluorescent Lamps
Table III.5 lists the technology options
that DOE has identified for improving
the efficacy of GSFL. Table III.5 also
provides TSD citations to each of the
options listed, in order to enable the
public to learn more about what is
encompassed under each of the options.
TABLE III.5.—GENERAL SERVICE FLUORESCENT LAMP TECHNOLOGY OPTIONS
Name of technology option
Description
Highly Emissive Electrode Coatings ...........................
Improved electrode coatings to increase electron
emission.
Fill gas compositions to improve cathode thermionic
emission or increase mobility of ions and electrons in the lamp plasma.
Techniques to increase the conversion of ultraviolet
light into visible light.
Coatings that enable the phosphors to absorb more
UV energy, so that they emit more visible light.
Vary the lamp diameter to improve its efficacy .........
Emitting more than one visible photon for each incident UV photon.
Higher Efficiency Lamp Fill Gas Composition ............
Higher Efficiency Phosphors .......................................
Glass Coatings ............................................................
Higher Efficiency Lamp Diameter ...............................
Multi-Photon Phosphors ..............................................
Philips commented that some lamps
use an extra thick layer of expensive
phosphors to improve efficacy.
However, Philips commented that the
global supply of these high-quality
phosphors is unknown, and there may
be some issues associated with higher
manufacturing cost if a standard level
were set such that it required the use of
this technology. (Philips, No. 11 at p. 2)
DOE will keep this comment in mind
during the manufacturer impact analysis
interviews it will conduct at the NOPR
stage of this rulemaking.
b. Incandescent Reflector Lamps
Table III.6 lists the technology options
DOE has identified to improve the
efficacy of IRL. Some of the technology
options listed in Table III.6 are
TSD reference
Chapter 3, Section 3.3.1.1.
Chapter 3, Section 3.3.1.2.
Chapter 3, Section 3.3.1.3.
Chapter 3, Section 3.3.1.4.
Chapter 3, Section 3.3.1.5.
Chapter 3, Section 3.3.1.6.
incorporated into commerciallyavailable products today. For example,
higher-temperature operation is utilized
(usually in conjunction with halogen
lamps) to improve the efficacy of the
tungsten filament. Additionally, coiling
of the tungsten filament is currently
practiced widely by lamp manufacturers
to increase its surface area, thereby
improving filament efficacy.
TABLE III.6.—INCANDESCENT REFLECTOR LAMP TECHNOLOGY OPTIONS
Name of technology option
Description
Higher-Temperature Operation ...................................
Operating the filament at higher temperatures, the
spectral output shifts to lower wavelengths, increasing its overlap with the eye sensitivity curve.
This measure may shorten the operating life of
the lamp.
Texturing, surface perforations, microcavity holes
with material fillings.
More-efficacious filament alloys ................................
Thinner filaments to increase operating temperature.
This measure may shorten the operating life of
the lamp.
Coiling of the filament to increase surface area .......
Layers of micron or submicron crystallites deposited
on the filament surface.
Positioning the incandescent filament to increase
light emission out of the lamp.
Filling lamps with alternative gases, such as Krypton, to improve efficacy by reducing heat conduction.
Microcavity Filaments ..................................................
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Novel Filament Materials ............................................
Thinner Filaments .......................................................
Efficient Filament Coiling ............................................
Crystallite Filament Coatings ......................................
Efficient Filament Orientation ......................................
Higher Efficiency Inert Fill Gas ...................................
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TSD reference
Chapter 3, Section 3.3.2.1.
Chapter 3, Section 3.3.2.2.
Chapter 3, Section 3.3.2.3.
Chapter 3, Section 3.3.2.4.
Chapter 3, Section 3.3.2.5.
Chapter 3, Section 3.3.2.6.
Chapter 3, Section 3.3.2.7.
Chapter 3, Section 3.3.2.8.
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TABLE III.6.—INCANDESCENT REFLECTOR LAMP TECHNOLOGY OPTIONS—Continued
Name of technology option
Description
Luminescent Gas ........................................................
Gaseous fills that react with certain wavelengths of
the filament emission to generate visible light.
Small diameter fused quartz envelope with a halogen molecule to re-deposit tungsten on the filament. Commonly referred to as a ‘‘halogen’’ lamp.
Increased pressure of the halogen capsule by increasing the density of halogen elements.
Novel filament materials that incorporate a regenerative cycle.
Infrared coatings (both phosphor and thin-film) to reflect some of the radiant energy back onto the
filament. When used in conjunction with a halogen capsule, this technology option is referred to
as a halogen infrared reflector (HIR) lamp.
The ballast converts the operating voltage of the
lamp from line voltage to a lower voltage.
Alternative internal coatings with higher reflectivity ..
Individual corner reflectors in the cover glass that
reflect light directly back in the direction from
which it came.
Positioning the filament to increase light emission
out of the lamp.
Tungsten-Halogen Lamps ...........................................
Higher Pressure Tungsten-Halogen Lamps ...............
Non-Tungsten Regenerative Cycles ...........................
Infrared Glass Coatings ..............................................
Integrally Ballasted Low Voltage Lamps .....................
Higher Efficiency Reflector Coatings ..........................
Trihedral Corner Reflectors .........................................
Efficient Filament Placement ......................................
Additional detail on the technology
assessment can be found in Chapter 3 of
the TSD.
In summary, DOE invites comments
on all of the technology options it
considered for GSFL and IRL, including
any omissions or revisions necessary to
have a more comprehensive technology
assessment. In the context of
commenting on technology options,
DOE also requests information on the
feasibility, performance improvement,
and cost of the technology options, as
well as any recent developments in their
technical maturity.
B. Screening Analysis
The purpose of the screening analysis
is to evaluate the technology options
identified as having the potential to
improve the efficiency of a product, to
determine which options to consider
further and which options to screen out.
DOE consults with industry, technical
experts, and other interested parties in
developing a list of technology options
for consideration. Section III.A.3
discusses the lists of identified
technology options for the products
being considered for coverage under this
TSD reference
rulemaking. DOE then applies the
following set of 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
Chapter 3, Section 3.3.2.9.
Chapter 3, Section 3.3.2.10.
Chapter 3, Section 3.3.2.11.
Chapter 3, Section 3.3.2.12.
Chapter 3, Section 3.3.2.13.
Chapter 3, Section 3.3.2.14.
Chapter 3, Section 3.3.2.15.
Chapter 3, Section 3.3.2.16.
Chapter 3, Section 3.3.2.17.
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).
1. Technology Options Screened Out
Applying the four screening criteria
discussed above to the identified
technology options for GSFL and IRL,
DOE developed the list of technology
options shown in Table III.13 that will
not be considered further in this
rulemaking analysis, because they do
not meet one or more of the
aforementioned screening criteria. In the
text following Table III.13, DOE
discusses each of these technology
options and provides the rationale for
screening them out. Chapter 4 of the
TSD provides further information on the
Screening Analysis.
TABLE III.7.—SUMMARY OF TECHNOLOGY OPTIONS SCREENED OUT OF DOE’S ANALYSIS
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Lamp category
Technology option
Screening criteria failed on
GSFL ...............................................................
Multi-Photon Phosphors .....................
IRL ..................................................................
Microcavity Filaments .........................
IRL ..................................................................
Novel Filament Materials ....................
IRL ..................................................................
IRL ..................................................................
Crystallite Filament Coatings .............
Luminescent Gas ...............................
Technological feasibility; Practicability to manufacture,
install, and service.
Product utility to consumers; Practicability to manufacture, install, and service.
Practicability to manufacture, install, and service; Product utility to consumers.
Practicability to manufacture, install, and service.
Technological feasibility.
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TABLE III.7.—SUMMARY OF TECHNOLOGY OPTIONS SCREENED OUT OF DOE’S ANALYSIS—Continued
Lamp category
Technology option
Screening criteria failed on
IRL ..................................................................
Non-Tungsten-Halogen Regenerative
Cycles.
Infrared Phosphor Glass Coating .......
Integrally Ballasted Low Voltage
Lamps.
Trihedral Corner Reflectors ................
Practicability to manufacture, install, and service; Product utility to consumers.
Practicability to manufacture, install, and service.
Technological feasibility.
IRL ..................................................................
IRL ..................................................................
IRL ..................................................................
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a. Multi-Photon Phosphors
For GSFL, DOE screened out the use
of multi-photon phosphors, even though
they have the potential to significantly
improve lamp efficacy. By emitting
more than one visible photon for each
incident ultraviolet photon, a lamp
employing this technology would be
able to emit more light for the same
amount of power. However,
development of this technology remains
in the research phase, and DOE is
unaware of any prototypes or
commercialized products that
incorporate multi-photon phosphors.
Thus, DOE screened out this technology
option based on the first criterion,
technological feasibility. Additionally,
because this technology is still in the
research phase, DOE believes that it
would not be practicable, or even
possible, to manufacture, install, and
service this technology on the scale
necessary to serve the relevant market at
the time of the effective date of an
amended standard. As discussed below
in section III.C, DOE based the GSFL
engineering analysis on commerciallyavailable lamps, deriving efficacy values
for these lamps from manufacturer
catalogs and specifications. Therefore,
DOE considered the technology options
contained in Table III.5 implicitly as
incorporated into commercially
available lamps at the efficacy levels it
evaluated.
b. Microcavity Filaments
DOE also screened out several
technologies that could potentially
improve the efficacy of IRL. First, DOE
screened out the use of microcavity
filaments. Microcavity filaments
increase an incandescent lamp’s efficacy
by reducing the amount of energy
converted to infrared light emitted by
the filament while increasing the
amount of energy converted to visible
light. The TSD’s market and technology
assessment (TSD Chapter 3) notes that
Sandia National Laboratories
researchers examined microcavity
resonance in a tungsten photonic lattice,
and a literature search revealed multiple
patents referencing this technology.
Since research prototypes of
microcavity filaments do exist, DOE
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Practicability to manufacture, install, and service.
determined that this technology option
is technologically feasible. However,
research indicates that materials
patterned at the submicron level may
experience problems with stability.
Because such instability could
negatively affect lamp function and life,
DOE believes that it is not yet
practicable to implement this
technology in general service lamps. For
this reason, DOE screened out this
technology option based on the third
criterion, impacts on product utility to
consumers. Furthermore, DOE is
unaware of any commercialized lamps
that incorporate microcavity filaments,
so we are concerned that massmanufacturing techniques for this
technology would be problematic. For
this reason, DOE does not believe that
this technology would be practicable to
manufacture, install, and service.
Therefore, DOE is not considering
filaments with microcavities as a design
option for improving the efficacy of IRL.
c. Novel Filament Materials
Second, DOE screened out the use of
novel filament materials, such as
nitrides and carbides, that have the
potential to improve lamp efficacy by
emitting more light in the visible
spectrum at a given temperature than
traditional tungsten filaments. Because
several patents on such filaments exist,
DOE believes that this technology
option is technologically feasible.
However, DOE is unaware of any lamps
available today that use such filaments.
Furthermore, DOE understands that
technological barriers, such as
prohibitive brittleness of the filament,
limit implementation of this technology.
Finding a practical way to incorporate
novel filament materials into
commercially-viable incandescent
lamps would require further research, as
would making such lamps practical for
general service applications. Thus, DOE
believes this option must be screened
out due to its potential negative impacts
on consumer utility. Furthermore, DOE
believes that it would not be practicable
to manufacture this technology on the
scale necessary to serve the relevant
market at the time of the effective date
of an amended standard. Therefore,
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DOE is not considering novel filament
materials as a design option for
improving the efficacy of IRL.
d. Crystallite Filament Coatings
Third, DOE screened out crystallite
filament coatings, which are oxidecovered micron or sub-micron
crystallites comprised of thorium,
tantalum, or niobium. These coatings
can be used to increase the light
emissivity of an incandescent lamp’s
filament. Because several patents on
such filament coatings exist, DOE
believes that this technology option is
technologically feasible. However, DOE
was unable to locate any data on the
incorporation of crystallite filament
coatings into prototypes or
commercially available products. Using
crystallite filament coatings in
incandescent lamps may require
additional manufacturing techniques,
such as chemical vapor deposition. DOE
understands that these techniques are
not in use in the mass-production of
incandescent lamps. In addition, DOE
believes that it would not be practicable
to manufacture this technology on the
scale necessary to serve the relevant
market of incandescent lamps before the
effective date of an amended standard.
Therefore, DOE is not considering
crystallite filament coatings as a design
option for improving the efficacy of IRL.
e. Luminescent Gases
Fourth, DOE screened out
luminescent gases. These gases, placed
inside the envelope of an incandescent
lamp, react with certain wavelengths of
the filament emission and generate
visible light. DOE is unaware of any
existing commercially-available
products or prototypes of incandescent
lamps incorporating luminescent gases.
Accordingly, DOE screened out
luminescent gases based on the first
criterion, technological feasibility.
Therefore, DOE is not considering
luminescent gas fills as a design option
for improving the efficacy of IRL.
f. Non-Tungsten-Halogen Regenerative
Cycles
Fifth, DOE screened out non-tungstenhalogen regenerative cycles.
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Regenerative cycles allow a filament to
burn at a higher temperature (and thus
higher efficacy) than conventional
incandescent lamps, while maintaining
a useful service life. Non-tungstenhalogen regenerative cycles are
regenerative cycles that do not employ
the use of the tungsten filament or
halogen gas fill. DOE understands that
regenerative cycles other than tungstenhalogen may be possible for other
filament materials. However, as noted
above, DOE screened out the use of
novel filament materials on the basis of
the second and third screening criteria.
Due to the fact that use of the nontungsten-halogen regenerative cycles
would depend on the incorporation of a
non-tungsten filament (already screened
out), DOE is screening out such cycles
from consideration based on the same
two criteria. DOE believes that it would
not be practicable, and maybe not even
possible, to manufacture novel filament
materials lamps with associated
regenerative cycles on the scale
necessary to serve the relevant market at
the time of the effective date of an
amended standard. Also, the use of
other filament materials, and therefore
their associated regenerative cycles, may
have an adverse impact on consumer
utility. Therefore, DOE is not
considering non-tungsten-halogen
regenerative cycles as a design option
for improving the efficacy of IRL.
g. Infrared Phosphor Glass Coatings
For IRL, DOE screened out infrared
phosphor glass coatings. When used as
a coating on the bulb surface, infrared
phosphors harvest the emitted infrared
energy and convert it to visible light,
thereby potentially increasing lamp
efficacy. Because patents on such
infrared phosphor coatings exist, DOE
determined that this technology option
is technologically feasible. However,
DOE does not believe infrared phosphor
glass coatings would be practicable to
manufacture because making hundreds
of millions of incandescent lamps
annually with infrared phosphor
coatings would require significant
changes to current manufacturing
processes and DOE has no data to
indicate that such manufacturing
processes are feasible or could be made
ready to serve the relevant market at the
time of the effective date of an amended
standard. Therefore, DOE is not
considering infrared phosphor coatings
as a design option for improving the
efficacy of IRL.
h. Integrally Ballasted Low Voltage
Lamps
Incandescent filaments that are
designed to operate at a lower voltage
are both shorter in length and thicker in
cross-sectional area than incandescent
filaments designed to operate at a line
voltage from 115 to 130V. Increasing the
thickness of the filament can improve
its efficacy by allowing the lamp to be
operated at higher temperatures.
Therefore, using an integral ballast
allows one to increase the efficacy of a
lamp by operating its filament at a lower
voltage (e.g., 12 volts) than standard
U.S. household line voltage (i.e., 120
volts). Although this technology is
commercially available in Europe 29 and
elsewhere in the world where the
standard household line voltage is 220–
240 volts, DOE is unaware of any
commercially-available products or
prototypes of this same technology
option that operate on U.S. household
line voltage of 120 volts. Accordingly,
DOE is screening out integrally ballasted
low voltage lamps based on the first
criterion, technological feasibility.
Therefore, DOE is not considering
integrally ballasted low voltage lamps as
a design option for improving the
efficacy of IRL.
i. Trihedral Corner Reflectors
For IRL, DOE screened out trihedral
corner reflectors, which could be
incorporated into the cover glass of IRL
and have the potential to increase lamp
efficacy by redirecting infrared radiation
back onto the filament. Because patents
on trihedral corner reflectors exist, DOE
determined that this technology option
is technologically feasible. However,
manufacturer data have not provided
any indication as to the incorporation of
this technology into prototypes or
commercially-available products. Using
trihedral corner reflectors, which entail
an additional disc requiring external
fabrication and installation in the lamp,
is likely to necessitate manufacturing
techniques not currently available for
mass production. For this reason, DOE
believes that it would not be practicable
to implement this technology on the
scale necessary to serve the relevant IRL
market at the time of the effective date
of an amended standard. Therefore,
DOE is not considering trihedral corner
reflectors as a design option for
improving the efficacy of IRL.
2. Design Options Considered Further in
Analysis
After screening out technologies in
accordance with the policies set forth in
10 CFR part 430, Subpart C, Appendix
A, (4)(a)(4) and 5(b), DOE is considering
the technologies, or ‘‘design options,’’
listed in the table below as viable means
of improving the efficacy of lamps
covered under this ANOPR. The market
and technology assessment (TSD
Chapter 3) provides a detailed
description of these design options.
TABLE III.8.—GSFL AND IRL DESIGN OPTIONS
GSFL design options
IRL design options
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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 (thin-film).
Higher Efficiency Reflector Coatings.
Efficient Filament Placement.
The above listed ‘‘design options’’
will be considered by DOE in the
engineering analysis. As discussed in
section III.C, to the greatest extent
possible, DOE based its engineering
analysis on commercially-available
products, which incorporate one or
more of the design options listed above.
In this way, DOE is better able to apply
29 Philips Electronics Press Release (2007).
Available at: https://www.lighting.philips.com/gl_en/
news/press/product_innovations/archive_2007/
press_new_masterclassic_lamp.php.
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these features of more-efficacious lamps
in a manner consistent with real world
application. To this end, DOE has used
catalog data, including price and
performance information, where
available.
DOE invited comment on DOE’s
selection of these design options.
Previously, manufacturers have
expressed some concern about certain
technologies impacting the
manufacturing of high-volume IRL. DOE
understands that infrared reflective
coatings require time to deposit on the
capsules/lamps. While lamps with this
technology option are commercially
available today in small production
runs, DOE is requesting comment on
whether these technologies could be
applied in the volumes necessary to
meet the market demand for IRL in the
three-year compliance period mandated
under the law authorizing DOE to
conduct this rulemaking. In particular,
DOE requests comment on whether this
technology (or other technology options
listed above) indeed meet DOE’s
screening criterion related to whether a
technology can be ‘‘mass
manufactured.’’
For more detail on how DOE
developed the technology options and
on the process DOE used to screen these
options, refer to Chapter 3 and Chapter
4 of the TSD.
mstockstill on PROD1PC66 with PROPOSALS2
C. Engineering Analysis
The engineering analysis identifies,
for each product class, potential
increasing efficiency levels above the
level of the baseline model. As key
inputs in this process, the engineering
analysis considers technologies not
eliminated in the screening analysis.
DOE considers these technologies either
explicitly as design options or implicitly
as incorporated into commerciallyavailable lamps at the efficiency levels
evaluated. For more information on the
technologies used in commerciallyavailable lamps, refer to Chapter 5 of the
TSD.
In the engineering analysis for this
rulemaking, DOE concentrated its efforts
on developing product efficacy levels
associated with ‘‘lamps designs,’’ based
upon commercially-available lamps that
incorporate a range of design options.
‘‘Design options’’ consist of discrete
technologies (e.g., infrared reflective
coatings). However, where necessary,
DOE supplemented commerciallyavailable product information with an
examination of the incremental costs
and improved performance of discrete
technologies. In this way, DOE’s
standards development analyses can
appropriately assess the technologies
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identified as candidates for improving
lamp efficacy.
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. Section III.E of this notice
discusses the product price
determination (see TSD Chapter 7 for
further detail).
1. Approach
To the extent possible, DOE based the
analysis on commercially-available
lamps that incorporate the design
options identified by the Technology
Assessment and Screening Analysis. For
GSFL, all lamp-and-ballast designs are
commercially available and have
publicly available performance and
price information. The majority of the
engineering analysis for IRL is also
based on commercially-available lamps.
However, where needed, DOE
supplemented these lamps with
additional model lamps which use
commercially-available technologies so
that a substitute lamp at each CSL was
available for each baseline lamp. For
both GSFL and IRL, instead of using
manufacturer cost data, DOE elected to
follow suggestions to derive price
information using observed market
prices for existing products. For more
information on the rationale for this
approach, refer to section III.E of this
notice.
The engineering analysis follows on
the same general approach for both
categories of lamps analyzed in this
rulemaking. The steps below more fully
describe this approach:
Step 1: Select Representative Product
Classes. DOE reviewed covered lamps
and their associated product classes.
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. Section III.C.2 of this
notice provides detail on the
representative product classes selected
for the analysis. Section III.C.6 of this
notice provides detail on how DOE
extrapolates from the representative
product class to other product classes.
Step 2: Select Baseline Lamps. DOE
selected baseline lamps from the
representative product classes on which
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it conducted the engineering analysis
(and subsequent analyses). These
baseline lamps were selected to
represent the characteristics of typical
lamps in a given product class.
Generally, a baseline lamp is one that
just meets existing mandatory energy
conservation standards or one that
represents the typical lamp sold.
Specific characteristics such as CCT,
operating life, and light output were all
selected to characterize the most
common lamps purchased by
consumers today. For all the
representative product classes, DOE
selected multiple baseline lamps, in
order to ensure consideration of
different high-volume lamps and
associated consumer economics.
Baseline lamps are discussed in section
III.C.2 of this notice.
Step 3: Identify Candidate Lamp or
Lamp-and-Ballast Designs. DOE
selected a series of more-efficacious
lamps for each of the baseline lamps
considered within each representative
product class. DOE considered
technologies not eliminated in the
screening analysis. DOE considered
these technologies either explicitly as
design options or implicitly as design
options incorporated into commerciallyavailable lamps at the efficiency levels
evaluated. In identifying more
efficacious lamp or lamp-and-ballast
designs, DOE recognizes that the lumen
package and performance characteristics
of a system are important design criteria
for consumers. For example, if
consumers do not have the option to
purchase substitution lamps or lampand-ballast systems with similar lumen
packages under an energy conservations
standard, consumers would need to
renovate the lighting design in a
particular building in order to maintain
a similar light output. Therefore, lamp
and lamp-and-ballast designs for the
LCC analysis were established such that
potential substitutions maintained light
output above a maximum 10 percent
decrease from the baseline lamp
system’s light output. In addition,
substitute lamps were chosen to have
performance characteristics (e.g., CCT)
similar to those of the baseline lamp.
In identifying more-efficacious
substitutes for GSFL, DOE utilized a
database of commercially-available
lamps. For the LCC, DOE developed the
engineering analysis based on the two
substitution scenarios where a
consumer can maintain light output
while decreasing energy consumption.
In the first scenario, the consumer
maintains light output while decreasing
energy by replacing the baseline lamp
with a more efficacious lower-wattage
lamp that operates on the existing
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ballast. In the second scenario, the
consumer maintains light output while
decreasing energy consumption by
replacing the lamp-and-ballast system
with a more efficacious lamp and a
different ballast. For example, a lampand-ballast system with a more
efficacious same-wattage lamp and
lower ballast factor ballast will consume
less energy and maintain light output.
For IRL, DOE used some
commercially-available lamps, but also
developed ‘‘model’’ lamps which
incorporate design options that may not
be commercially available for certain
lamp types and wattages but which use
commercially-available technologies.
For example, DOE developed efficacy
estimates for reduced-wattage IRL with
an improved halogen infrared (HIR)
coating. For the LCC, DOE considered
only one substitution scenario. In this
scenario, consumers save energy and
maintain light output by replacing their
lamp with a lower wattage more
efficacious lamp. For a more detailed
discussion of lamp and ballast designs,
see section III.C.3 of this notice.
Step 4: Developed Candidate
Standard Levels. Having identified the
more-efficacious substitutes for each of
the baseline lamps (or lamp-and-ballast
systems), DOE developed CSLs based on
a consideration of several factors
including: (1) The design options
associated with the specific lamps being
studied (e.g., grades of phosphor for
fluorescent lamps, the use of infrared
coatings for IRL); (2) the ability of lamps
across wattages to comply with the
standard level of a given product
class; 30 and (3) the maximum
technologically-feasible level. For a
more detailed discussion of CSL
development for each of the
representative product classes analyzed,
see section III.C.4 of this notice.
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).
mstockstill on PROD1PC66 with PROPOSALS2
2. Representative Product Classes and
Baseline Lamps
As discussed in section III.A.2, DOE
is considering establishing eight product
classes across the range of covered GSFL
and two product classes for covered IRL.
Due to scheduling and resource
constraints, DOE was not able to analyze
each and every product class. Instead
DOE carefully selected certain product
classes that it would analyze, and then
30 Efficacy levels span multiple lamps of different
wattages. In selecting CSLs, DOE considered
whether these multiple lamps can meet the efficacy
levels.
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scale its analytical findings on those
representative product classes to other
product classes that were not analyzed.
The representative product classes are
generally selected to encompass the
highest volume, most commonly sold
lamp types.
Once DOE identifies the
representative product classes for
analysis, DOE selects the representative
units for analysis (i.e., baseline lamps)
from within each product class. In the
Framework Document, DOE identified
some preliminary ideas for
representative product classes and units
for analysis. This section summarizes
the comments received on this topic and
the related decisions DOE made in
conducting this portion of the ANOPR
analysis.
ACEEE provided a cross-cutting
comment about representative product
classes and units for analysis. ACEEE
expressed concern that DOE may oversimplify the analysis by analyzing
lamps of a few wattages and then
generalizing to lamps of other wattages,
in which case the results may not scale
well. (ACEEE, No. 4.5 at pp. 67 and 79–
80) The Joint Comment expressed this
same concern, stating that analyzing too
few products risks oversimplifying the
analysis and obtaining results that
cannot be extended to other products.
Because such an approach could result
in the sacrifice of potential energy
savings, the Joint Commenters urged
DOE to analyze multiple lamp wattages.
(Joint Comment, No. 9 at p. 2)
In response, DOE plans to establish
eight product classes for GSFL. For IRL,
although DOE is considering only two
product classes, DOE defines CSLs with
lamp efficacy requirements that vary by
wattage to prevent oversimplification of
the analysis. In addition, for each
potential GSFL and IRL product class
that is being analyzed, DOE is analyzing
more than one baseline lamp to reflect
the range of manufacturers’ current
lamp offerings. For example, for IRL,
DOE recognizes that an incandescent
lamp with the same basic technology
exhibits higher efficacies at higher
wattages. By analyzing multiple
products at several different wattages,
DOE was able to define a CSL that sets
the same technology requirement for
IRL, regardless of wattage.
a. General Service Fluorescent Lamps
As discussed in section III.A.2, DOE
has tentatively decided to revise the
table of product classes to reflect the
utility of these products and how they
are used in the market. From this new
set of product classes, DOE generally
selected as representative product
classes those that encompassed the
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majority of shipments and from which
efficacy values could be scaled.
DOE observed that 4-foot medium
bipin lamps constitute the vast majority
of GSFL sales. These are followed in
order of unit sales by 8-foot single pin
slimline lamps and 8-foot recessed
double contact HO lamps, which
together constitute less than a quarter of
GSFL sales. Because 4-foot medium
bipin, 8-foot single pin slimline, and 8foot recessed double contact HO lamps
are the most common GSFL, DOE has
selected them as representative lamps
for its analysis. Shipments of 2-foot Ushaped lamps account for less than 5
percent of GSFL unit sales
historically.31 Given the relatively small
market share of U-shaped lamps, DOE
did not explicitly analyze these lamps.
With regard to product class divisions
by CCT, DOE recognizes that lamps
whose CCT is greater than 4,500K
represent a small market share of GSFL.
Therefore, DOE has chosen to analyze
lamps with CCT less than or equal to
4,500K.
Although DOE is not analyzing the 2foot U-shaped lamps or lamps that have
a CCT greater than 4,500K, DOE
nevertheless plans to consider standards
for these product classes. DOE will
extend its decision for the 4-foot
medium bipin product class to the 2foot U-shaped product class. This is
possible because 2-foot U-shaped lamps
generally are operated in the same way
and generally span the same wattages as
4-foot medium bipin lamps. For lamps
whose CCT is greater than 4,500K, DOE
will extrapolate its findings from the
representative lamps it analyzed that are
less than or equal to 4,500K. For details
on how DOE intends to consider
development of standards for product
classes not analyzed, see section III.C.6
of this notice.
Within the representative product
classes for GSFL, DOE selected as
representative units for analysis those
lamps with the highest volumes.
Although DOE reorganized the product
classes from what it presented in the
Framework Document, the
representative units selected for analysis
are generally consistent with the
comments received regarding the
appropriate units for analysis. For
example, several stakeholders
commented that DOE should select the
cool white phosphor energy-saver T12
as a baseline lamp. (NEMA, No. 8 at pp.
2–3; GE, No. 4.5 at pp. 63–65 at pp. 70–
71; Philips, No. 11 at p. 1; GE, No. 13
at pp. 2–4; Osram, No. 15 at p. 3; GE,
No. 4.5 at pp. 63–65). Osram
commented that DOE should also
31 Source:
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consider a 700 series T8 as a baseline
lamp. (Osram, No. 15 at p. 3). In
contrast, EEI and PG&E commented that
the baseline lamps should be selected in
terms of when the standard will go into
effect (six years from now), and the cool
white lamp may not be a good
representative baseline lamp at that
time. (EEI, No. 4.5 at pp. 68–69, PG&E,
No. 4.5 at p. 73). In addition, ACEEE
commented that it may be better for
DOE to analyze both the energy-saver
and non-energy-saver lamps as
baselines, and then later in the process
DOE could decide whether one should
be removed from the analysis. (ACEEE,
No. 4.5 at pp. 66–67).
After consideration of the public
comments, DOE selected T8 and T12
baseline lamps for analysis. For T12
lamps, DOE selected both non-energysaver lamps (i.e., 40W T12 4-foot
medium bipin GSFL) and energy-saver
versions (i.e., 34W T12 4-foot medium
bipin GSFL), where they were available,
as baseline lamps. For non-energy-saver
versions of T12 GSFL, DOE selected 700
series, non-cool-white T12 lamps. For
energy-saver versions of the T12 GSFL,
DOE selected cool white models as
baseline lamps. For T8 lamps, DOE only
selected the non-energy-saver lamp (i.e.,
32W T8 4-foot medium bipin GSFL) as
a baseline lamp because energy-saver
versions are not prevalent in the
marketplace. For the baseline 32W T8
lamp, DOE used a rare-earth phosphor
700 series non-energy-saving lamp as
the baseline. In all cases, the phosphor
technology employed by each of these
lamps is a direct reflection of the most
commonly sold lamp today. DOE also
selected fluorescent lamps with a CCT
of 4,100K for all the analysis (i.e.,
baseline lamps and standard-compliant
replacement lamps). DOE selected this
CCT value because it is both the most
popular CCT and because it falls
approximately in the middle of the
range of typical GSFL, which span from
3,000K to 6,500K.
Table III.9 presents the representative
product classes and baseline lamps that
DOE has tentatively developed for
GSFL.
TABLE III.9.—GSFL REPRESENTATIVE PRODUCT CLASSES AND BASELINE LAMPS
Baseline lamps
Lamp type
Representative
product class
4-foot medium bipin
CCT ≤4,500K ........
8-foot single pin
slimline.
Descriptor
Nominal
wattage
W
Rated
efficacy*
lm/W
CCT
K
Initial light
output
lm
Mean light
output
lm
Lifetime
hr
40
34
32
75
4,100
4,100
4,100
4,100
80.0
77.9
86.2
85.6
3,200
2,650
2,800
6,420
2,880
2,300
2,520
5,906
20,000
20,000
20,000
12,000
CCT ≤4,500K ........
F96T12 ....
F96T8 ......
F96T12 ....
60
59
110
4,100
4,100
4,100
87.6
94.8
80.1
5,300
5,700
9,050
4,664
5,130
8,145
12,000
15,000
12,000
F96T12 ....
8-foot recessed
double contact
HO.
CCT ≤4,500K ........
F40T12 ....
F34T12 ....
F32T8 ......
F96T12 ....
95
4,100
82.5
8,000
6,950
12,000
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*Rated efficacy is based on the rated wattage of the lamps and the initial lumen output. The rated wattage in order of baseline is 40W, 34W,
32.5W, 75W, 60.5W, 60.1W, 113W, and 97W.
As discussed in section III.C.3.a, DOE
is taking a systems approach to its
analysis for GSFL. In accordance with
this approach, DOE selected typical
ballasts to pair with the baseline lamps.
DOE generally paired a ‘‘normal’’ BF
ballast (i.e., with a BF typically between
0.84 and 1.0) with baseline lamp
systems. These pairings are intended to
characterize the typical system used in
the market. For example, for installed
T8, 4-foot medium bipin fluorescent
systems, DOE selected an instant start
electronic ballast with a BF of 0.88. In
addition to ballast types, DOE also
selected the number of lamps per ballast
that represent a typical system. DOE is
aware that 4-foot medium bipin ballasts
are available in a variety of lamp-perballast designs. According to the 2000
rule on GSFL ballasts (hereafter ‘‘2000
Ballast Rule’’), there are on average 2.8
lamps per 4-foot medium bipin system.
62 FR 56740 (Sept. 19, 2000).32 To
32 U.S. Department of Energy. Office of Energy
Efficiency and Renewable Energy, Energy
Conservation Program for Consumer Products:
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accurately represent the market and to
simplify the analysis, DOE has decided
to use a 3-lamp system for 4-foot
medium bipin lamps. For 8-foot lamps,
DOE selected 2-lamp ballasts,
representative of typical 8-foot systems
in the market. For further detail on the
lamps and lamp-and-ballast systems
DOE uses in its analyses, see Chapters
5 and Appendix 5A of the TSD.
b. Incandescent Reflector Lamps
As discussed above, for the ANOPR,
DOE decided to revise the table of
product classes to reflect the utility of
these products and how they are used
in the market, including the creation of
a product class for modified-spectrum
lamps. Because modified-spectrum
lamps currently make up only a small
Technical Support Document: Energy Efficiency
Standards for Consumer Products: Fluorescent
Lamp Ballast Proposed Rule. Appendix B. Marginal
Energy Prices and National Energy Savings. Table
B.6. (Jan. 2000). Available at: https://
www.eere.energy.gov/buildings/
appliance_standards/residential/pdfs/appendix_b
.pdf.
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percentage of the market, DOE has
selected the standard-spectrum IRL
product class for analysis and intends to
extrapolate its findings to the modifiedspectrum product class. Section III.C.6
provides detail on this extrapolation.
ACEEE commented that DOE should
analyze each of the six IRL wattage
group product classes, rather than only
two, as DOE presented in its Framework
Document. Otherwise, ACEEE argued
that DOE would potentially risk
oversimplifying the analysis. (ACEEE,
No. 4.5 at pp. 79–80) The Joint
Comment also asserted that DOE should
examine each product class for IRL
since the appropriate substitute lamps
in each of those classes can vary. (Joint
Comment, No. 9 at p. 2)
Given the revisions to the product
class structure for IRL (i.e., that product
classes are no longer defined by
wattage), DOE now recognizes that the
discrete utility of IRL is based on the
lumen package, not the wattage rating.
For this reason, the discrete IRL
representative wattage groups that were
discussed in the Framework Document,
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and upon which DOE received
comment, are being merged into one
product class. However, to prevent
oversimplification of the analysis, DOE
has chosen to analyze three different
lamps of multiple wattages (and lumen
packages) in the standard-spectrum
product class. DOE has tentatively
decided to concentrate its resources on
conducting analysis of the most popular
reflector lamps—in terms of lamp size,
wattage, and lumen package.
Accordingly, DOE examined existing
products on the market at multiple
wattages to select baseline lamps which
it used to derive efficacy equations that
span wattage. Therefore, DOE was able
to apply the analysis performed on the
most popular lamps to the other, less
common lamps. Further detail on the
CSLs DOE has developed for IRL
follows in section III.C.6.
With regard to baseline lamps, NEMA
commented that DOE should conduct
more analysis on the 75W and the 150W
parabolic aluminized reflector (PAR)
lamp, and clarify whether these are
‘‘blown PAR’’ lamps. (NEMA, No. 8 at
pp. 2–3) EEI commented that given the
market penetration of halogen PAR
lamps, DOE might consider them as
some of the baseline lamps for the
analyses. (EEI, No. 4.5 at p. 77) GE
commented that blown PAR38 lamps
are very common in the market (both
75W and 150W), and that they may
represent a good baseline because they
are the least efficient type of PAR
technology currently sold. (GE, No. 4.5
at p. 79)
In response, DOE selected three
baseline lamps of varying wattage and
shapes to provide a comprehensive
understanding of consumer economics.
Specifically, DOE included PAR
halogen baseline lamps of three
different wattages: 50, 75, and 90 Watts.
Average wattage information of PAR
lamps acquired from NEMA and a
review of manufacturer product catalogs
indicate that these are the highest
volume wattages. These baseline lamps
are currently regulated by EPCA and,
therefore, meet the EPCA standard.
DOE identified three lumen packages
that are popular in the commercial and
residential sectors, and then identified
lamps that provided that service. These
three packages are in the range of
approximately 600 to 1,300 lumens.
DOE analyzed PAR baseline lamps in
each of the lumen packages as DOE
believes that these lamps represent a
good cross-section of the most common
reflector lamps that will be sold and
used at the effective date of the standard
(the year 2012). Since these lamps
capture a range of wattages and lumen
packages, they cover a range of
applications.
Table III.10 presents the
representative product class and
baseline lamps that DOE has selected for
the ANOPR IRL analyses.
TABLE III.10.—IRL REPRESENTATIVE PRODUCT CLASS AND BASELINE LAMPS
Representative product class baseline lamps
Lamp category
Representative product class
Descriptor
IRL .................................................
IRL Standard-Spectrum .................
DOE requests comment on its
preliminary selection of representative
product classes and baseline lamps for
GSFL and IRL.
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3. Lamp and Lamp-and-Ballast Designs
In the market and technology
assessment (see TSD Chapter 3), DOE
identifies a range of technology options
that improve the efficacy of the two
categories of lamps considered in this
rulemaking. In the screening analysis
(see TSD Chapter 4), DOE screened out
certain technology options because they
fail to satisfy the requirements of all
four screening criteria. Those
technology options not screened out by
the four criteria are called ‘‘design
options,’’ and DOE considered them in
the engineering analysis.
The Joint Comment suggested that,
when deciding how many potential
standard levels to examine, DOE should
look at natural divisions in the market,
by product class, rather than selecting
an arbitrary number of standard levels.
(Joint Comment, No. 9 at p. 4)
For the lamps considered in this
rulemaking, DOE’s selection of design
options guided its selection of CSLs.
Because products spanned a large range
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Wattage
W
PAR30 .....
PAR38 .....
PAR38 .....
of efficacies for GSFL and IRL, DOE
looked at natural divisions in the market
when selecting lamp designs. For
example, for GSFL, DOE noted
groupings around the types of phosphor
used and the wall thickness of those
phosphors. With regard to IRL, DOE
identified natural ‘‘technology-based’’
divisions in the market around the type
of incandescent technology used (i.e.,
halogen, or HIR).
DOE also took into account lumen
output when it established lamp designs
for its analyses. In the Framework
Document, DOE stated its intention to
hold the lamp lumen output constant at
the level of the baseline model. Thus, as
the lamps become more efficacious, they
will consume less energy rather than
produce more light. Holding lumen
output constant across the efficacy
levels is necessary to ensure that
products supply equivalent service
under the base-case and standards-case
scenarios.
The Joint Comment agreed with
DOE’s intention in this regard and
suggested that DOE avoid structuring
the standard so that compliant lamps
would noticeably reduce light output.
The Joint Comment also expressed
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50
75
90
Efficacy
lm/W
11.6
14.0
14.6
Initial light
output
lm
580
1,050
1,310
Lifetime
hr
3,000
2,500
2,500
concern about a standard that might
result in the use of efficiency gains to
over-illuminate certain installations or
to install longer-life lamps instead of
capturing energy savings. (Joint
Comment, No. 9 at p. 6) EEI stated that
there are some energy-saving
incandescent lamps that use a slightly
lower wattage and produce fewer
lumens, but do so at a higher efficacy.
Therefore, to allow for energy savings,
and as a sensitivity to the analysis, EEI
recommended that DOE should evaluate
a 10-percent lumen band of equivalency
for incandescent lamps. (EEI, No. 4.5 at
pp. 117–118)
In response, it is noted that for the
LCC, DOE considered those lamps (or
lamp-and-ballast systems) which: (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. Lamp or lamp-and-ballast
designs that under-illuminate and overilluminate are considered in the NIA.
For the LCC, DOE also chose to consider
only energy-saving options. For GSFL,
energy savings can either be achieved
through lamp replacements or lampand-ballast replacements. For GSFL,
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energy savings can only be achieved
through lamp replacements. For the
NIA, DOE analyzed a range of energy
saving and non-energy-saving options.
The non-energy-savings lamps, as well
as more-efficient lamps that increase or
decrease light output by more than 10
percent of the base case, can be found
in Appendix 5A of the TSD.
a. General Service Fluorescent Lamps
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EEI recommended that DOE should
take a systems approach when analyzing
GSFL in the NES and LCC, because the
ballast is the piece of the system that
determines the energy usage overall.
(EEI, No. 7 at p. 1) DOE agrees with this
comment and did apply 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. By using a
systems approach, DOE was able to
demonstrate the actual energy
consumption and light output of an
operating lamp in a given end-user
installation. DOE is cognizant of the
fact, however, that it is not regulating
fluorescent lamp ballasts in this
rulemaking, and, therefore, while it
selected ballasts with different ballast
factors (BF) 33 in order to obtain the
appropriate level of system lumen
output, DOE did not necessarily select
the most energy-efficient versions of
those ballasts with different BF. (Note:
DOE is initiating a separate rulemaking
on fluorescent lamp ballasts, in which it
will evaluate whether new and
amended efficiency standards should be
applied to fluorescent lamp ballasts.34)
So although DOE is not setting
minimum performance standards for
fluorescent systems in this rulemaking,
DOE’s analysis does consider the
operation of fluorescent lamps in a
lamp-and-ballast system while
33 The ‘‘ballast factor’’ of a ballast is the ratio of
the light output of a fluorescent lamp or lamps
operated on a ballast to the light output of the
lamp(s) operated on a standard (reference) ballast.
Ballast factor depends on both the ballast and the
lamp type; a single ballast can have several ballast
factors depending on lamp type. The light output
of a single fluorescent lamp is measured on a ballast
with a ballast factor of 1.0. One can reduce the light
output of a lamp-and-ballast system by operating a
lamp on a ballast with a lower ballast factor.
34 Energy efficient ballasts are characterized as
having higher ballast efficacy factors (BEF). The
BEF is directly related to the quotient of the BF and
the power consumed by the ballast, such that a
ballast maintaining BF while reducing power
consumption will have a higher BEF, and be a more
energy-efficient ballast. In its ANOPR analysis, DOE
varied the ballast BF, not the BEF, in its assessment
of standards for fluorescent lamps. DOE will be
considering new and amended BEF standards in the
separate fluorescent lamp ballast rulemaking.
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evaluating efficacy standards for these
lamps.
This systems approach allows DOE to
select a variety of energy-saving lampand-ballast designs that meet a given
CSL. In general, 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 a variety of
technologies. As discussed in the
screening analysis (section III.B.2), DOE
considered commercially-available
GSFL that use highly emissive electrode
coatings, higher efficiency lamp fill gas
composition, higher efficiency
phosphors, glass coatings, or higher
efficiency lamp diameter to achieve a
higher efficacy. After selecting these
higher efficacy lamps, DOE selected
lamp-ballast combinations for the LCC
that both save energy and maintain
comparable lumen output. For instances
in which the consumer is replacing only
the lamp, DOE selected a reducedwattage, higher-efficacy lamp for use on
the existing ballast. For instances in
which 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.
GE argued that DOE can only control
a lamp for lamp replacement in this
rulemaking, and that the ballast type is
not regulated as part of this rulemaking.
(GE, No. 4.5 at pp. 110–111) GE also
commented that an increase in lumens
would suffice for the lamp replacement
events. (GE, No. 4.5 at p. 122)
ACEEE and GE commented that DOE
should consider replacement lamps that
have the same wattage but higher
efficacy coupled with a lower ballast
factor (BF) ballast as energy-efficient
substitutes for the baseline lamp.
Similarly, ACEEE recommended that
DOE should consider technology
options that use a lower BF ballast with
a higher-efficiency lamp to achieve
energy savings. (ACEEE, No. 4.5 at p.
113) GE stated that the energy use for
fluorescent lamps is driven primarily by
the BF, and that this should be a part
of the energy savings analysis. (GE, No.
4.5 at pp. 116–117) DOE agrees with
these comments, and followed the
recommendations of these stakeholders
in its analysis. As the efficacies of the
fluorescent lamps being considered
increased, DOE selected and used
ballasts with lower ballast factors, such
that the system lumen output was
within ten percent of the baseline
system lumen output.
In this rulemaking, DOE considers
reduced-wattage lamp options (i.e., ones
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which emit lumens equal to the lumen
output of the baseline lamp, or below
that lamp by no more than 10 percent,
and result in energy savings). In the
NIA, DOE also considers substitute
lamps which produce more light but do
not save energy. This reflects the fact
that DOE cannot require consumers to
change their ballast along with their
lamps. However, in situations where a
consumer has the opportunity to replace
a ballast, DOE allows consumers to
change both their ballast and lamp. For
example, consumers can select a lamp
with a higher efficacy and a ballast with
a lower BF to obtain a system that
would result in approximately the same
system light output as the baseline
system. This new lamp-and-ballast
combination would have a lowerwattage consumption due to the lower
BF.
In the Framework Document, DOE
identified several technology options
that it intended to consider analyzing in
this rulemaking. In response to that list
of technology options, stakeholders
provided feedback on certain options.
Upon reviewing some of the fluorescent
lamp-and-ballast pairings, GE
commented that DOE should not
assume that as lamp efficacy increases,
one could always reduce wattage to
achieve a constant light output with
fluorescent lamps. GE points out that
going below the 34W energy savings
lamp, for example, is not possible,
because lower-wattage lamps would not
work on available ballasts. (GE, No. 4.5
at pp. 106–107)
In response, DOE has sought to create
lamp and lamp-and-ballast designs that
are practical and realistic in this
engineering analysis. For example, for
the 34W 4-foot medium bipin T12
GSFL, DOE did not consider reducedwattage substitutes. Rather, DOE paired
higher efficacy 34W 4-foot medium
bipin T12 GSFL with lower BFs to
capture energy savings while
maintaining lumen output.
GE also stated that it is not always
possible to use a 28W fluorescent lamp
as a replacement for a 32W lamp on all
the available ballasts. GE recommends
that DOE decide what an acceptable
range of reduced-wattage lamps might
be, given that restrictions on use
increase as the wattage decreases. (GE,
No. 4.5 at pp. 126–127).
DOE understands that one of the ways
manufacturers build lower-wattage
fluorescent lamps is through the
addition of krypton gas into the mix to
change the resistance of the lamp. In the
manufacturer interviews DOE held to
prepare for the ANOPR, DOE was told
that as the proportion of krypton gas
increases, the fluorescent lamp has more
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difficulty starting, being dimmed, and
operating in cold-temperature
environments. However, in other
manufacturer interviews, DOE was
informed that technological
improvements were such that 28W
fluorescent lamps should no longer have
problems starting nor issues with
features such as dimming or frequent
on-off (often caused by motion sensors).
DOE also reviewed publicly-available
manufacturer literature and found at
least one major lamp manufacturer
stating that its 28W fluorescent lamp
does not have restrictions on use.35 For
these reasons, DOE did consider the
28W lamp as an energy-saving
replacement for a 32W T8 baseline
lamp. However, DOE is aware that
consumers should not be subject to any
decrease in utility and performance and
that not all consumers would choose a
lower-wattage lamp if DOE established
standards for T8 lamps. The NIA
analysis contains technology option
market-share matrices which contain
assumptions about the relative
proportion of consumers who would
elect a particular lamp (or lamp and
ballast) option in response to a standard.
These matrices are described in section
III.H of this notice, and Chapter 9 of the
TSD. DOE invites further comment on
the use of 28W, as well as 25W,
replacement fluorescent lamps in the
analysis and the expected market share
these lamps would capture at the
various CSLs. DOE intends to continue
the dialogue with the public on this
issue to better understand the capability
of these reduced-wattage fluorescent
lamps.
b. Incandescent Reflector Lamps
For IRL, DOE has observed natural
efficacy divisions in the marketplace
which correspond to the use of halogen
capsules, HIR technology, and improved
reflector coatings to increase lamp
efficacy. DOE considers these efficacy
divisions in selecting CSLs by using the
efficacy levels of commercially-available
lamps as a guide. Commerciallyavailable products do not exist at all of
the CSLs for all of the baseline lamps,
however. For example, the 75W PAR38
baseline lamp with 1,050 lumens has
commercially-available products at all
three CSLs, but the 50W PAR30 baseline
lamp with 580 lumens only has
commercially-available products at one
of the three CSLs. Because DOE believes
it is technically feasible to incorporate
35 This catalog states the following about 25W,
28W, and 30W T8 lamps: ‘‘Operates on: Any Instant
Start Ballast; Programmed Start Ballast that supplies
equal to or greater than 550 starting voltage.’’
Source: Philips Lamp Specification and Application
Guide (2006), p. 72.
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the commercially-available technologies
in lamp types that correspond to all of
the baseline lamps, and in order to have
a continuous range of efficacies to
analyze, DOE is developing some model
IRL which it bases on lamp lumen
packages which are commercially
available. In particular, using efficacy
information for the commerciallyavailable lamp designs (that are
substitutes for certain baseline lamps),
DOE is able to develop a relationship of
efficacy to wattage. This then allows
DOE to develop lamp designs that are
not commercially available for certain
wattages, but that would be substitutes
for other baseline lamps. DOE assumes
that lamps of similar diameters may
substitute for one another (e.g., PAR38
IRL will be substituted with another
PAR38 IRL). Generally, the lamp design
substitutes for baseline lamps are based
around the lumen output of the baseline
lamp, plus or minus 10 percent.
In reviewing published catalog data,
DOE observed that higher efficacy,
reduced-wattage IRL (which maintain
light output within 10 percent) are
available as substitutes for a number of
baseline lamps. Furthermore, these
reduced-wattage designs span a range of
design options available for
consideration in this rule. These design
options, discussed in the screening
analysis portion of this notice (section
III.B), include the tungsten-halogen
regenerative cycle (hereafter ‘‘Halogen’’)
and halogen infrared technologies
(hereafter ‘‘HIR’’), a technology that uses
both Halogen and glass coatings that
reflect infrared light. DOE observed that
the commercially-available halogen IRL
fall within two tiers of efficacy. To
distinguish the efficacies of these
halogen IRL, DOE is designating them as
Halogen and Improved Halogen. DOE
also observes two tiers of efficacy for
HIR IRL. To distinguish the efficacies of
these IRL, DOE is designating them as
HIR and Improved HIR. DOE believes
Improved HIR and Improved Halogen
can be achieved by using the additional
design options discussed in the
screening analysis. These design options
include higher-efficiency filaments,
efficient filament coiling, filament
configuration, capsule design, high
pressure capsules, or higher efficiency
reflector coating. DOE observed lifetime
changes across these ‘‘naturallyoccurring’’ reduced-wattage IRL. (That
is, a halogen reduced-wattage IRL
typically has a lifetime of around 2,000
to 3,000 hours, whereas an HIR IRL
typically lives for 3,000 to 4,000 hours.)
DOE has maintained the lifetime
attributes of the commercially-available
product for its analysis.
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In summary, DOE seeks comment on
its selection of lamp and lamp-andballast designs for GSFL and IRL.
4. Candidate Standard Levels
a. General Service Fluorescent Lamps
Table III.20 and Table III.22 present a
summary of the candidate standard
levels (CSLs) for each of the
representative product classes for the
lamps covered under this rulemaking. In
general, the CSLs for GSFL (presented in
Table III.20) follow a general trend of
increasing efficacy through the use of
higher-quality phosphors. The CSLs also
represent a move from higher-wattage
T12 technologies to lower-wattage,
higher-efficacy T8 technologies. CSL5
represents the most efficacious
fluorescent lamp (i.e., ‘‘max tech’’). In
all product classes, fluorescent lamps
that meet CSL5 are T8 lamps which use
800 series phosphors.
The following paragraph presents a
detailed discussion of the design
options used to meet each CSL for the
4-foot medium bipin product class. For
more information on design options
used to meet each CSL for the 8-foot
single pin slimline product class and
the 8-foot recessed double contact HO
product class, refer to Chapter 5 of the
TSD.
A standard at CSL1 impacts the two
4-foot medium bipin T12 baseline
lamps. Because the baseline T8 lamp is
above this efficacy level, consumers
using the T8 lamp are not impacted.
This CSL can be met with a 34W T12
lamp using 700 series rare earth
phosphors or a 40W T12 lamp using
improved 700 series or 800 series rare
earth phosphors. A standard at CSL2
also only impacts T12 lamps. This CSL
can be met by both the 34WT12 and
40W T12 lamp using an 800 series rare
earth phosphor. A standard at CSL3
impacts all three baseline lamps. To
meet this level, the 32W T8 lamp must
use an 800 series rare earth phosphor.
The T12 lamps must use an 800 series
rare earth phosphor and possibly other
design options such as a different gas
fill or increased thickness of the bulbwall phosphor to increase the lamp’s
efficacy. A standard at CSL4 also
impacts all three baseline lamps.
However, there are no T12 lamps
commercially available that can meet
this efficacy requirement. Therefore,
users of T12 lamps would be forced to
replace their ballasts and operate T8
lamps instead. For the T8 lamps, this
level requires the use of higher-efficacy
800 series rare earth phosphor. A 30W
T8 lamp that produces an equivalent
amount of light as the baseline unit on
a similar ballast meets this CSL. CSL5,
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which also impacts all three baseline
lamps, represents the most efficacious 4foot medium bipin lamps. Again, there
are no T12 lamps commercially
available that can meet this efficacy
requirement. Therefore, users of T12
lamps would be forced to replace their
ballasts and operate T8 lamps instead.
32W T8 lamps which meet this efficacy
level must use 800 series rare earth
phosphor and may incorporate other
efficacy improvements to the lamp, such
as a different gas fill or increased
thickness of the bulb-wall phosphor. A
28W and a 25W T8 lamp that produces
an equivalent amount of light on the
same ballast as the baseline unit meets
this CSL.
Philips commented that there is more
than one kind of reference ballast that
can be used to test GSFL, and that the
same lamp operated on two different
ballasts can have a different efficacy.
Because a given lamp can exhibit
different efficacies based on the testing
method use, Philips commented that
DOE should use a standard test
procedure based on ANSI requirements
to develop lamp efficacy values.
(Philips, No. 11 at p. 3)
In response, DOE’s current test
procedure for fluorescent lamps is based
on ANSI standards and evaluates the
performance of lamps on a single, lowfrequency reference ballast. As noted
previously, DOE is currently conducting
a rulemaking on the test procedures for
fluorescent and incandescent lamps in
tandem to this energy standards
rulemaking. In that rulemaking, DOE is
proposing to continue to use lowfrequency ballast testing for all GSFL
except those which can only be tested
on a high-frequency ballast. Further
detail on the ANSI standards
incorporated by reference that are used
to evaluate lamps is available in 10 CFR
Part 430, Subpart B, Appendix R and in
the Test Procedures NOPR. DOE does
note, however, that while it uses the test
procedure values to set efficacy levels,
it considers the operation of lamps on
several different ballast types in the LCC
and NIA analyses. This way, the
economic evaluation of the CSLs more
accurately reflects how users actually
operate these lamps.36 DOE calculated
system power data using published
catalog information. Further detail on
this calculation is available in Chapter
5 of the TSD.
A more detailed discussion on how
DOE selected these CSLs for each
product class, which technologies they
represent, and which design option
lamps DOE used at these CSLs for each
of the representative units, can be found
in Chapter 5 of the TSD.
TABLE III.11.—SUMMARY OF THE CANDIDATE STANDARD LEVELS FOR FLUORESCENT LAMPS WITH CCT ≤ 4,500K
4-Foot
medium
bipin
CSL1
CSL2
CSL3
CSL4
CSL5
........................................................................................................................................................
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b. Incandescent Reflector Lamps
Table III.22 presents the CSLs for IRL.
For IRL, the increasing CSLs represent
shifts in technology, including shifts
from halogen to HIR technology. As the
baseline lamps are generally already
utilizing halogen technology, CSL1 for
IRL is met through improved halogen
technologies which are achieved with
an improved reflective coating or higher
pressure halogen capsules. CSL2 for IRL
can be met with HIR technology (i.e., a
technology that uses a halogen capsule
with an infrared reflective coating.)
CSL3 for IRL can be met with improved
HIR technologies; this level can be
achieved with an HIR lamp that has an
improved reflective coating, better HIR
coatings or higher pressure halogen
capsules.
The CSLs for IRL use an efficacy
equation which calculates minimum
average efficacy (in lumens per watt)
based on the rated wattage of the lamp
(denoted by the variable P in the
equation). As an example, consider a
baseline 50W PAR30 lamp with an
36 This approach is similar to other rulemakings
where DOE bases product efficacy levels on the test
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efficacy of 11.6 lm/W. The minimum
required efficacies of a 50W lamp under
the CSLs would be 14.4 lm/W at CSL1,
15.8 lm/W at CSL2, and 17.8 lm/W at
CSL3. Plots of these CSLs are presented
in Chapter 5 of the TSD.
8-Foot
recessed
double contact HO
lm/W
Candidate standard level
8-Foot
single pin
slimline
lm/W
lm/W
82.4
85.0
90.0
92.3
95.4
87.3
92.0
94.8
98.2
101.5
83.2
86.1
87.6
91.9
95.3
DOE invites comment on the CSLs for
GSFL and IRL.
5. Engineering Analysis Results
The following section presents partial
results from the engineering analysis for
GSFL and IRL. The results include
TABLE III.12.—SUMMARY OF THE CAN- detail on the characteristics of lamp and
DIDATE STANDARD LEVELS FOR lamp-and-ballast designs DOE used in
its analyses and the CSL which they
STANDARD-SPECTRUM IRL
meet. The full set of results for the
lamps and lamp-and-ballast systems
Standardspectrum inDOE analyzed, including additional
candescent re- product classes and baselines, are
Candidate standard level
flector lamps
available in Chapter 5 and Appendix 5A
of the TSD. DOE is presenting the
lm/W
partial results here to facilitate comment
CSL1 .....................................
5.0P0.27 on the methodology of DOE’s analyses,
CSL2 .....................................
5.5P0.27 and on the presentation of its results.
CSL3 .....................................
6.2P0.27
a. General Service Fluorescent Lamps
A more detailed discussion on how
these CSLs were derived, which
technologies they represent, and which
design option lamps are used at these
CSLs for each of the representative units
can be found in Chapter 5 of the TSD.
Engineering analysis results for GSFL
include descriptions of the lamp-andballast systems DOE selected for the
analyses. Because the CSLs are based on
lamps, and at some CSLs DOE has
analyzed multiple lamps, in some
procedure measurements, while design options
analyzed in the NIA are adjusted with operating
hour data to reflect energy use in the marketplace.
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rated efficacy, the initial and mean light
outputs, and the average operating life
of the lamp. The table is sorted by
efficacy, such that each lamp represents
a higher efficacy, and thus constitutes a
more-efficient lamp design in the
engineering analysis. The table also
presents the type of ballast DOE pairs
with each lamp, including the BF for
that ballast, the resultant system power
rating of the lamp operating on that
ballast, and the system initial and the
system mean light outputs. The BF was
selected so that the new system does not
reduce light output by more than 10
percent of the baseline lamp system.
The system performance of the more-
instances DOE presents multiple
systems per CSL.
Table III.13 presents the engineering
analysis results for a 34W T12 baseline
lamp system. Building from the baseline
system, the table presents each of the
engineering analysis lamp-and-ballast
designs DOE used for each of the five
CSLs. At each CSL, DOE generally
considered both a replacement lamp
that had the same wattage as the
baseline lamp and operates on a new
(lower BF) ballast, and a replacement
lamp that had a reduced wattage. This
difference between the design lamps
considered is evident in the ‘‘rated
wattage’’ column. Then, for each of
those design lamps, DOE provides the
efficacious lamps is utilized in the LCC,
where an economic analysis is
conducted to determine whether a
more-efficacious lamp or lamp-andballast system is cost-justified. For
details on the LCC, see section III.G and
Chapter 8 of the TSD.
4-Foot T8 lamp and ballast
replacements are considered as
substitutes for the baseline lamp. The
highest energy-saving system uses a 0.88
BF electronic ballast with a reducedwattage T8 lamp and maintains lumen
output within 10 percent. Additional
engineering analysis results for GSFL
are available in Chapter 5 and Appendix
5A of the TSD.
TABLE III.13.—LAMP-AND-BALLAST REPLACEMENT ENGINEERING ANALYSIS 4-FOOT MEDIUM BIPIN GSFL WITH A CCT ≤
4,500K
Baseline ..........................
Baseline ..........................
CSL1 ...............................
CSL1 ...............................
CSL2 ...............................
CSL2 ...............................
CSL3 ...............................
CSL3 ...............................
CSL4 ...............................
CSL4 ...............................
CSL5 ...............................
CSL5 ...............................
CSL5 ...............................
Lamp
diameter
Nominal
wattage
Rated
wattage
Rated
efficacy
W
Candidate standard level
Initial
light
output
W
lm/W
lm
lm
2,650
2,650
2,800
2,800
2,900
2,800
2,950
3,100
3,000
2,850
3,100
2,725
2,400
2,300
2,300
2,460
2,460
2,610
2,520
2,710
2,790
2,850
2,680
2,915
2,560
2,280
T12
T12
T12
T12
T12
T8
T8
T12
T8
T8
T8
T8
T8
34
34
34
34
34
32
32
34
32
30
32
28
25
34
34
34
34
34
32.5
32.5
34
32.5
30
32.5
28
25
77.9
77.9
82.4
82.4
85.3
86.2
90.8
91.2
92.3
95
95.4
97.3
96
Mean
light
output
hr
Ballast
factor
Ballast type
20,000
20,000
20,000
20,000
20,000
20,000
20,000
24,000
24,000
18,000
24,000
18,000
24,000
Magnetic .........
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
Electronic .......
0.88
0.88
0.88
0.86
0.86
0.88
0.78
0.86
0.75
0.78
0.75
0.78
0.88
System
initial
light
output
System
mean
light
output
W
Life
System
power
rating
lm
lm
108.0
91.7
91.7
90.3
90.3
87.5
78.5
90.3
75.9
72.4
75.9
63.3
66.8
6,996
6,996
7,392
7,224
7,482
7,392
6,903
7,998
6,750
6,669
6,975
6,377
6,336
6,072
6,072
6,494
6,347
6,734
6,653
6,341
7,198
6,413
6,271
6,559
5,990
6,019
*This table includes the systems DOE analyzed for 3-lamp 34W T12, 4,100K systems. These lamp-and-ballast designs apply to situations where consumers purchase both a lamp and a ballast. Additional results for other baselines and purchasing events are available in Chapter 5 of the TSD.
b. Incandescent Reflector Lamps
Engineering analysis results for IRL
describe the baseline lamps DOE
selected for the analyses. Table III.14
presents the engineering analysis results
for the 75W PAR38 IRL. This baseline
lamp and its lamp design substitutes are
based around a 1,050 lumen-output
lamp. The max-tech option (CSL3) offers
a 36 percent improvement in efficacy,
with longer life. Additional engineering
analysis results are available in Chapter
5 and Appendix 5A of the TSD.
Discussion on the CSL efficacy values
(derived from observed and extrapolated
lamp efficacy values) are also available
in Chapter 5 and Appendix 5A of the
TSD.
TABLE III.14.—ENGINEERING ANALYSIS FOR STANDARD-SPECTRUM IRL*
Lamp
descriptor
Design option
Baseline ................................................
CSL1 .....................................................
CSL2 .....................................................
CSL3 .....................................................
Wattage
Halogen ...........................
Improved Halogen ...........
HIR ..................................
Improved HIR ..................
PAR38
PAR38
PAR38
PAR38
Initial light
output
Efficacy
Lamp
lifetime
W
Candidate standard level
lm
lm/W
Hr
.............
.............
.............
.............
75
66
60
55
1050
1050
1050
1050
14.0
15.9
17.5
19.1
2,500
3,000
3,000
4,000
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*The results in this table are for 75W PAR38 IRL. Additional results are available in Chapter 5 of the TSD.
6. 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
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product classes primarily because of
their high market volumes. The
following section discusses how DOE
intends to scale CSLs from those
product classes that it analyzed to those
product classes that it did not analyze.
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a. General Service Fluorescent Lamps
As discussed in section III.C.2, above,
DOE did not analyze GSFL with a
correlated color temperature (CCT)
above 4,500K and 2-foot U-shaped
lamps. As discussed in section III.A, the
efficacy of lamps with cooler CCTs (i.e.,
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higher CCT values) is lower due to the
quality of blue light emitted by lamps
with cooler CCT. DOE compared
commercially-available T8 lamps at
4,100K and 6,500K, and found that the
efficacy of the 6,500K lamps was
between 4 and 7 percent lower than that
of the 4,100K lamps. In order not to
overly penalize current product offered
in the market, DOE is considering
adopting the larger of the two scaling
factors, namely 7 percent, when
determining the minimum efficacy
requirement for lamps greater than
4,500K. This would mean, for example,
that if 82.4 lm/W (i.e., CSL1) were
selected for the 4-foot medium bipin
product class of 4,500K CCT and below,
the scaled minimum efficacy
requirement for the product class greater
than 4,500K CCT would be 76.6 lm/W.
DOE invites comment on this
preliminary decision, including other
approaches the public suggests, and any
mathematical or other technical scaling
factors that could be applied.
Similarly, DOE observed that 2-foot
U-shaped lamps generally are less
efficacious than 4-foot medium bipin
lamps due to the bend of a 2-foot Ushaped lamp. This drop in efficacy
appears to be dependent on the wattage
and diameter of the lamp in question.
DOE has observed that 40W T12 2-foot
U-shaped lamps are on average 6
percent less efficacious than a 40W T12
medium bipin lamp of the same
phosphor series and manufacturer,
while 34W T12 or 32W T8 2-foot Ushaped lamps are generally 3 percent
less efficacious than the 34W T12 or
32W T8 medium bipin lamp of the same
phosphor series and manufacturer. In
order not to overly penalize T12 lamps,
DOE is considering applying a 6 percent
decrease to the CSLs for 4-foot medium
bipin lamps for 2-foot U-shaped lamps.
DOE invites comment on this
preliminary decision, including other
approaches, and any mathematical or
other technical scaling factors that could
be applied.
b. Incandescent Reflector Lamps
DOE has analyzed standard-spectrum
lamps in its analysis, but DOE intends
to set separate minimum efficacy
requirements for standard-spectrum and
modified-spectrum IRL, utilizing the
approach discussed below. Modifiedspectrum IRL filter out portions of the
light spectrum emitted by the filament
in order to obtain a particular spectral
emission. Modified-spectrum lamps
achieve their particular spectral
emission through either a coating
applied to the outer glass of the lamp or
through the incorporation of
neodymium (or other additives) into the
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outer glass bulb. Because this filtering of
light reduces the lumen output of the
lamp, DOE plans to establish a separate
minimum efficacy requirement,
appropriately scaled, for modifiedspectrum lamps. As there is
considerable variability in the
modification of the spectrum (i.e., with
some lamp coatings or glass additives
adsorbing more light, others less), DOE
plans to scale standard levels based on
the degree of spectral modification.
In order to scale appropriately,
manufacturers would be required to
measure the lumen output of both their
modified-spectrum lamp, as well as the
lumen output of an equivalent,
standard-spectrum reference lamp (i.e.,
a lamp with equivalent: (1) Rated
wattage; (2) rated voltage; (3) gas fill
pressure and composition; (4) bulb
shape and size; (5) filament type and
orientation; (6) finish; and (7) other
design features of the modifiedspectrum lamp except for the coating or
neodymium (or other additives) which
produces the modified-spectrum. In
order to determine the appropriate
minimum efficacy requirement for the
modified-spectrum lamp, manufacturers
would measure the lumen output of
both the modified-spectrum lamp and
the equivalent standard-spectrum
reference lamp, and 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 minimum efficacy requirement for
the standard-spectrum reference lamp.
This lumen-output-adjusted minimum
efficacy requirement would be scaled
appropriately for exactly the coating or
neodymium (or other additives) content
producing the modified spectrum. In
this way, the consumer would be
assured that any minimum efficacy
standard the Secretary may establish for
standard-spectrum lamps would also be
incorporated into the covered modifiedspectrum lamps. DOE invites comment
on this method of establishing a lumenoutput-adjusted efficacy requirement,
including other approaches, and any
mathematical or other scaling factors for
modified-spectrum lamps.
Additional detail on the engineering
analyses can be found in the
Engineering Chapter (Chapter 5) of the
TSD.
D. Energy-Use Characterization
The purpose of the energy-use
characterization is to estimate the
energy consumption of the baseline and
higher efficacy lamps and lamp systems
considered in this analysis. DOE
determines the energy consumption of
the lamps and lamp systems through the
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rated power (i.e., rated in watts) and the
way consumers use the lamp (i.e.,
operating hours per year). This analysis,
which is meant to represent typical
energy consumption in the field, is an
input to both the LCC and PBP analyses
and the NIA. The energy-use
characterization enables DOE to
determine the LCC and the PBP of moreefficacious lamps relative to the baseline
lamp.
DOE derives the annual energy
consumption of lighting systems by
multiplying the power rating by the
number of hours of operation per year.
The following sections discuss the
inputs and calculations DOE used to
develop annual operating hours and the
energy consumptions for the various
lamps and lamp systems considered in
this analysis. For more information on
the representative classes analyzed for
these lamp and lamps systems refer to
section III.C.2 of this notice. Comments
provided on issues related to the energyuse characterization are also
summarized in these sections.
1. Operating Hours
In the Framework Document, DOE
sought data on the typical applications
and end-use profiles of GSFL and IRL.
EEI recommended that DOE take into
account the distribution of operating
hours (i.e., the number of hours a lamp
is in use) by both lamp category and
sector. (Public Meeting Transcript, No.
4.5 at pp. 158–159)
DOE structured the analysis in a
manner consistent with this comment,
developing operating hours by both
lamp category and sector. In addition,
for the LCC analysis, DOE accounted for
variability of operating hours by
developing a distribution of operating
hours for the LCC spreadsheet. The
operating hour distributions capture
variation across census divisions,
building types, and lamp categories for
all sectors. Within the commercial and
industrial sectors, the distributions
capture variation across ‘‘applications,’’
and within the residential sector, the
distribution captures variation across
‘‘room types.’’ A list of these
applications and room types is available
in Chapter 6 of the TSD.
EEI and the Northwest Power and
Conservation Council (NWPCC)
suggested several sources (such as
Electric Power Research Institute, New
York State Energy Research and
Development Authority, California
Energy Commission, CalMac, Florida
Solar Energy Center) that DOE could use
to obtain operating hour distribution
data. (Public Meeting Transcript, No. 4.5
at pp. 158–164) NEMA recommended
that DOE should use data from the 2002
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study, U.S. Lighting Market
Characterization Volume I (LMC).
(Public Meeting Transcript, No. 4.5 at
p. 160; NEMA, No. 8 at p. 3)
After reviewing other data sources,
DOE selected the LMC for this analysis
because it is the most complete source
of operating hour data and because it is
generally consistent with other sources.
The LMC, which is based on thousands
of building audits and surveys, provides
national-level data on operating hours
by building type and lamp category for
all sectors. These operating hours are
broken down by application for the
commercial and industrial sectors, and
room type for the residential sector.
EEI suggested that DOE should update
the operating hour distributions to
account for lighting controls in the
commercial sector (Public Meeting
Transcript, No. 4.5 at p. 158). EEI was
not specific whether the lighting
controls should encompass occupancy
sensors, daylight dimming, or demandresponsive dimming systems that are
activated during peak demand periods.
While DOE recognizes that there
probably are more lighting controls
being used today, DOE does not believe
the level of penetration is likely to be
significantly different from LMC, which
was published in 2002. Furthermore,
DOE believes the overall national level
of penetration of lighting controls at the
individual level (i.e., those that would
respond to one individual’s office) is
still relatively low. Finally, DOE is
unsure how it would account for
lighting controls, as there is uncertainty
about which control systems are being
recommended and nationallyrepresentative data sources on the
impact of lighting controls were not
identified. Therefore, DOE has not
modified the operating hour data from
LMC for the ANOPR. However, DOE
invites comment on this issue. In
particular, DOE invites comment on the
type, prevalence, and operating hour
reductions due to lighting controls used
separately in the commercial, industrial,
and residential sectors.
In conjunction with data from the
LMC, DOE used data from the Energy
Information Administration’s (EIA)
CBECS (2003), RECS (2001), and the
MECS (2002). These EIA studies provide
information on the distribution of
buildings within the U.S., by building
type and census division. DOE
associated the LMC’s operating hour
data by building type with the EIA’s
data by building type and census
division to derive operating hours by
census division. This allowed DOE to
correlate the electricity price
distribution (see TSD Chapter 8) and
sales tax distribution (see TSD Chapter
7) with the operating hour distribution
by census division in the LCC
spreadsheet. The following describes
data sources used to develop operating
hours, by sector.
For the residential sector, DOE used
RECS building data and LMC residential
sector operating hour data. The 2001
RECS data indicate the probability that
a certain building type is within a
census division. The LMC indicates the
occurrence of certain room types within
a given building type and the operating
hour characteristics of typical lamps in
these rooms. By using probabilities
derived from RECS, the LCC model
selects a building of a certain type and
census division. The model then selects
a room within that building type using
LMC data and presents operating hour
data for a typical lamp in that room.
DOE used a similar approach to the
one described for the residential sector
to develop a distribution of operating
hours in the commercial sector.
However, in lieu of room type, the
model selects operating hours based on
application. The 2003 CBECS data
indicate the probability a certain
building type is located in a certain
census division. Once the LCC model
selects a building, DOE used the LMC to
indicate the probability a lamp is
installed in a certain application in that
building. The LMC then estimates the
operating hour characteristics of a
typical lamp for that application. A
sample of the diversity of operating
hour characteristics can be found in
Chapter 6 of the TSD.
To develop a distribution of operating
hours in the industrial sector, DOE used
an approach similar to that used for the
commercial sector. The 2002 MECS data
indicate the probability a certain
building type exists. Once the model
selects a building, DOE uses LMC to
ascertain the probability a GSFL or IRL
is installed in a certain application in
that building. LMC then gives the
operating hour characteristics of a
typical lamp for that application.
Because MECS does not provide the
location of industrial sector buildings,
DOE used population information from
the 2007 census to establish the
probability that a certain industrial
building exists in a certain census
division. Table III.15 summarizes the
weighted-average operating hours per
lamp category per sector.
DOE has not developed the weightedaverage operating hours for GSFL in the
residential sector because shipment
information and manufacturer
interviews indicate that the vast
majority of the GSFL market resides in
the commercial and industrial sectors.
However, if analysis of GSFL in the
residential sector were deemed
necessary, DOE could use the
distribution of operating hours of IRL, as
this may approximate the operating
hour profile of GSFL in the residential
sector. Alternatively, DOE could
develop a distribution of operating
hours from an alternative data source.
DOE invites comment on the average
operating hours for the use of GSFL and
IRL in the commercial, residential, and
industrial sectors. DOE also invites
comment on how DOE should develop
an operating hour distribution for GSFL
in the residential sector.
TABLE III.15.—AVERAGE OPERATING HOURS BY SECTOR AND LAMP CATEGORY
Lamp
category
Sector
Residential ..............................................................................................................................................................
Commercial ............................................................................................................................................................
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Industrial .................................................................................................................................................................
2. Results
For GSFL, energy consumption by
sector is based on the system power
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rating derived by DOE and the average
annual operating hours of that lamp. As
an illustration of how DOE determined
energy consumption, Table III.16 and
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IRL
GSFL
IRL
GSFL
IRL
Average annual
operating hours
hrs/year
884.2
3435.0
3450.0
4795.1
4664.0
Table III.17 list the system power ratings
and annual energy consumption of the
4-foot medium bipin product class.
Additional detail on the energy-use
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characterization of other GSFL can be
found in Chapter 6 of the TSD.
TABLE III.16.—FOUR-FOOT MEDIUM BIPIN T8 GSFL 3-LAMP SYSTEM POWER CONSUMPTION RATING AND ANNUAL
ENERGY CONSUMPTION
System
power
rating
Commercial
Industrial
W
Lamp & ballast designs
kWh
kWh
1.18BF32 Elec 37 ..........................................................................................................................
1.18BF25 Elec .............................................................................................................................
1.0BF32 Elec ...............................................................................................................................
1.0BF30 Elec ...............................................................................................................................
1.0BF28 Elec ...............................................................................................................................
0.88BF32 Elec .............................................................................................................................
0.88BF30 Elec .............................................................................................................................
0.88BF28 Elec .............................................................................................................................
0.88BF25 Elec .............................................................................................................................
0.78BF32 Elec .............................................................................................................................
0.78BF30 Elec .............................................................................................................................
0.78BF28 Elec .............................................................................................................................
0.75BF32 Elec .............................................................................................................................
114.5
93.0
98.3
90.2
80.5
87.5
80.5
71.1
66.8
78.5
72.4
63.3
75.9
Annual energy consumption
393.2
319.5
337.7
309.8
276.5
300.6
276.5
244.2
229.6
269.8
248.8
217.3
260.5
548.9
446.1
471.4
432.5
386.0
419.7
386.0
340.9
320.5
376.6
347.3
303.3
363.7
TABLE III.17.—FOUR-FOOT MEDIUM BIPIN T12 GSFL 3-LAMP SYSTEM POWER RATING AND ANNUAL ENERGY
CONSUMPTION
System
power
rating
0.95BF40
0.88BF34
0.88BF40
0.88BF34
0.87BF40
0.86BF40
Mag
Mag
Elec
Elec
Elec
Elec
Commercial
Industrial
W
Lamp-and-ballast designs
kWh
kWh
.............................................................................................................................
.............................................................................................................................
.............................................................................................................................
.............................................................................................................................
.............................................................................................................................
.............................................................................................................................
Because the lamp system for IRL
consists only of the lamp, the system’s
rate of energy use is simply the rated
power of the lamp. Table III.18 details
the lamp power rating and annual
energy consumption for the 75W PAR38
reference lamp and its lamp designs.
Additional detail on the energy-use
129.0
108.0
107.7
91.7
107.0
90.3
Annual energy consumption
443.1
371.0
369.8
314.8
367.5
310.2
618.6
517.9
516.2
439.5
512.9
433.0
characterization of IRL can be found in
Chapter 6 of the TSD.
TABLE III.18.—IRL POWER RATING AND ANNUAL ENERGY CONSUMPTION, 75PAR38
Lamp
efficacy
Baseline ...............................................................................
CSL1 ....................................................................................
CSL2 ....................................................................................
CSL3 ....................................................................................
mstockstill on PROD1PC66 with PROPOSALS2
E. Product Price Determination
This section explains how DOE
developed end-user prices for baseline
products as well as higher-efficacy
products, and how DOE developed the
sales tax figures it used in the analyses.
To derive the total, installed end-user
37 A notation of the form ‘‘1.18BF32Elec’’
indicates a lamp-ballast system consisting of a 32W
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Commercial
Industrial
Residential
lm/W
Technology option
Lamp
power
rating
W
kWh
kWh
kWh
14.0
15.9
17.5
19.1
Annual energy consumption
75.0
66.0
60.0
55.0
258.8
227.7
207.0
189.8
349.8
307.8
279.8
256.5
cost of products, DOE added sales tax
and installation costs, where
appropriate, to end-user prices. Please
see section III.G for a discussion of
installation costs.
1. Introduction and Methodology
lamp paired with an electronic ballast of a 1.18
ballast factor. ‘‘0.95VF40 Mag’’ refers to a lamp-
ballast system of a 40W lamp paired with a
magnetic ballast of a 0.95 ballast factor.
66.3
58.4
53.1
48.6
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a. Overview
In the Framework Document, DOE
suggested the approach of deriving enduser prices by applying distributor and
contractor mark-ups to manufacturerselling-price estimates. DOE had
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planned to derive manufacturer selling
prices by applying manufacturer markups to the manufacturer costs of
production. At the Public Meeting, GE
and NEMA commented that
manufacturer cost data is proprietary
information and is therefore unlikely to
be shared by manufacturers. (Public
Meeting Transcript, No. 4.5 at pp. 133–
135).
As an alternative to deriving
manufacturer selling price from
manufacturer cost, GE suggested that
DOE obtain manufacturer selling prices
from distributors, State procurement
contracts and other publicly-available
information sources. GE further
recommended that if DOE seeks to
derive manufacturer costs, DOE could
work backwards through the
distribution chain from the publiclyavailable product list prices. (Public
Meeting Transcript, No. 4.5 at p. 133)
ACEEE and several stakeholders
supported the same methodology
recommended by GE. (NEMA, No. 8 at
p. 3, Public Meeting Transcript, No. 4.5,
p. 129 and p. 136; Joint Comment, No.
9 at p. 3).
As suggested by stakeholders, DOE
obtained manufacturer’s published enduser price schedules for lamps (hereafter
called the manufacturer’s ‘‘blue book’’
or ‘‘lamp price schedules’’) as well as
information on discounts applied to
those price schedules from distributors,
State contracts, and other publiclyavailable information sources. In
addition, DOE also obtained information
on distributor pricing (i.e., what a
distributor would pay) for commercial,
industrial, and institutional consumers
of lamps. Thus, in response to
comments on the Framework Document,
and due to the availability of pricing
information, DOE revised its approach
for developing lamp prices from what
was presented in the Framework
Document.
Starting from a consistent set of prices
in the blue books, DOE looked at
publicly-available prices in State
procurement contracts, at large
electrical supply distributors, homeimprovement/hardware stores, and
other sources of publicly-available enduser prices, such as Internet retailers. In
its review of publicly-available market
prices, DOE observed a range of enduser prices paid for a given lamp,
depending on the distribution channel
through which it is purchased and the
volume at which it is purchased. DOE
observed that State procurement
contracts typically negotiated a discount
of around 70 to 90 percent off the blue
book. In the vast majority of instances,
these discounts apply uniformly to all
products on a price schedule
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irrespective of the volume of a
particular lamp.
Internet retailers, electrical supply
distributors, and home-improvement/
hardware stores generally reflected
prices paid by consumers in the
medium-to-high range of prices.
Furthermore, these channels usually
apply different discounts to lamps
depending on their sales volume. Since
many high-efficacy lamps are ‘‘niche’’
products, DOE observed that they were
generally less discounted than
commodity lamps.
ACEEE commented that State
procurement contracts represent prices
with low mark-ups. (Public Meeting
Transcript, No. 4.5 at pp. 129–130) GE
and the Joint Comment stated that markups vary by volume, with GE stating
that higher volume lamps have lower
mark-ups and lower volume lamps have
higher mark-ups. (Public Meeting
Transcript, No. 4.5 at p. 133; Joint
Comment, No. 9 at p. 3).
In response to comments and in line
with its observations of public pricing,
DOE developed three sets of discounts
from the blue books, representing the
range of low, medium, and high lamp
prices for GSFL and IRL. For IRL,
commercially-available products did not
span the full range of efficacies
considered. For those lamps where
commercial pricing was not available,
DOE extrapolated pricing from available
lamps. The development of the low,
medium, and high prices specific to
each lamp category is described below
in subsection III.E.1.b.
Several stakeholders commented that
the manufacturer costs DOE derives
should reflect the production of
commodity-type products. (Joint
Comment, No. 9 at pp. 2–3). To reflect
future commoditization of higherefficacy lamps when they become the
minimum complying products, the
discounts DOE applied to blue books to
derive the low, medium, and high prices
are a constant markdown across all
lamps. (Baseline incandescent lamps
received a slightly larger discount, as
reflected in State procurement
contracts.) DOE also accounted for the
future commoditization of high-efficacy
residential IRL by using the incremental
pricing of PAR 38 IRL. In particular,
DOE notes that the market for highefficacy PAR 38 IRL is well developed
in comparison to the high-efficacy PAR
30 IRL market. Furthermore, DOE notes
that the products themselves use the
same fundamental technologies.
Although DOE did not estimate
manufacturer costs directly, DOE notes
that the use of a single markdown across
efficacies and types of PAR 38 IRL and
the use of PAR38 IRL incremental
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pricing for PAR30 IRL accounts for
commoditization of high-efficacy
products.
Once DOE calculated end-user prices,
DOE added sales tax and, if appropriate,
installation costs to derive the total,
installed end-user cost. Please see
section III.G for a discussion of
installation costs. For the reference case
in the LCC, DOE used the medium lamp
prices, but it also conducted analysis at
the low and high lamp prices, to
ascertain the impact of these other price
points (see TSD Chapter 8). In the NIA,
DOE used only the medium prices in
that analysis because this price best
represents the average purchase price
for a variety of consumers nationwide
(see TSD Chapter 10). DOE also
developed a single average end-user
price for the new and replacement
ballasts used, to which it added sales
tax and installation costs. DOE requests
comment on the approach to developing
end-user prices for GSFL and IRL
considered in this rulemaking.
b. General Service Fluorescent Lamps
To develop low-range prices for
GSFL, DOE calculated a discount off the
blue book consistent with prices found
in State procurement contracts. DOE
mirrored the procurement discount
schedule by using a constant discount
across lamp efficacies. As noted above,
DOE believes that using this discount
schedule is appropriate for the
rulemaking analyses, as it reflects
currently-available pricing and because
it takes into account commoditization of
standard-compliant lamps. Consistent
with State procurement contracts, DOE
assumed that these low-range prices
include a distributor mark-up but no
contractor mark-up. As such, this is
truly a lower bound of pricing which
assumes the most favorable conditions.
For medium-range prices, DOE took a
discount off the blue book that is
consistent with the distributor pricing it
received and that represents a typical
discount for commercial institutions on
high-volume (commodity) lamps. Again,
DOE used a single discount across
efficacies. DOE added a contractor
mark-up of 13 percent so that the
resulting price would encompass both a
contractor and distributor mark-up. DOE
obtained this contractor mark-up
estimate from the 2000 Ballast Rule.38
38 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 (Jan. 2000). Available
at: https://www.eere.energy.gov/buildings/
appliance_standards/residential/
gs_fluorescent_0100_r.html.
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For the high-range prices, DOE
deduced discounts on commodity lamps
from blue book prices for small quantity
purchasers by observing high-range
pricing and obtaining distributor quotes.
These prices also encompass both a
contractor and a distributor mark-up.
DOE was able to obtain data on actual
prices for all GSFL it considered in the
analyses.
For the replacement ballasts
considered in the analysis, DOE
gathered prices from publicly-available
manufacturer price schedules and
applied a uniform discount that is
customary for pricing to large
customers. All ballast prices represent
contractor net price plus contractor
mark-up for ballasts purchased from a
distributor. DOE computed a simple
average end-user price by applying a 50percent mark-up above the lowest price
paid in large multi-year State
procurement contracts. Based on
conversations with industry experts,
DOE believes these prices are
representative of average end-user sales
prices. DOE was able to obtain data on
actual prices for ballasts it considered in
the analyses.
c. Incandescent Reflector Lamps
For IRL, DOE modeled PAR30 and
PAR38 IRL. DOE calculated the lowrange price for PAR38 IRL as it did for
GSFL given their large range of higherefficacy products commercially
available. Specifically, DOE compared
State procurement contracts to blue
books to develop an average discount.
Again, DOE mirrored State contract
pricing by following the discount
schedule used in State contracts. For the
medium-range price, DOE took a
discount off the blue book to represent
shipment weighted-average prices paid
by consumers for commonly available
lamps. For the high-range prices, DOE
took a discount off the blue book that
represents prices that are higher-thanaverage but in line with observed highrange pricing. This medium-range price
is equidistant from the low-range and
high-range prices.
For PAR30 IRL, DOE used a slight
variation to the methodology followed
for GSFL and PAR38 IRL. In particular,
to develop the PAR30 baseline lamp
price, DOE used the price differential
between an incandescent (non-halogen)
BR40 lamp and halogen PAR38 lamp.
DOE added this price differential to a
incandescent (non-halogen) BR30 lamp
price to obtain the baseline halogen
PAR30 lamp price. By developing prices
for the baseline lamps from the
incandescent replacement lamps (BR30
and BR40 lamps), DOE is recognizing
that the high-volume product currently
being shipped may be a lower-efficacy
(non-halogen) incandescent lamp.39
Therefore, basing prices off of this lamp
will most accurately represent the
commoditization of the halogen PAR30
by 2012 (the effective date of the
amended standard). Similarly for
higher-efficacy lamp designs, DOE
developed a list price to discount from
based on the incremental blue book
prices of PAR38 IRL. As such, DOE
added the incremental end-user blue
book price of PAR38 lamps to the
baseline PAR30 lamp price to derive
higher-efficacy PAR30 lamp list prices.
DOE chose this methodology for PAR30
IRL because for PAR30 lamps, two of
the standards-compliant lamps were not
commercially available. In addition,
PAR30 lamps use the same fundamental
technologies as PAR38 lamps, which
serve a more developed market.
2. End-User Price Results
The following section presents partial
results from the product price
determination. The tables summarize
the end-user prices DOE developed
through the product price
determination. (The figures in the tables
do not include tax or installation costs).
They follow in order of lamp category.
Additional results for the product price
determination are available in Chapter 7
of the TSD.
a. General Service Fluorescent Lamps
Table III.19 lists the low, medium,
and high end-user prices DOE used for
the 4-foot medium bipin T12 GSFL
considered in the analyses. Results for
4-foot medium bipin T8 GSFL and 8foot GSFL are available in Chapter 7 of
the TSD. In reviewing market prices,
DOE observed that prices generally
increased with increasing efficacy.
However, other lamp characteristics
such as lifetime, wattage, and CRI likely
also affected price, but these variables
cannot be completely isolated. To the
extent feasible, DOE considered nonefficacy characteristics that affect
installed or operating costs in the LCC.
TABLE III.19.—END-USER PRICES FOR 4-FOOT MEDIUM BIPIN GSFL*
Lamp
efficacy
lm/W
CSL
T12 40W Baseline ...........................................
T12 34W Baseline ...........................................
1 .......................................................................
1 .......................................................................
2 .......................................................................
2 .......................................................................
3 .......................................................................
3 .......................................................................
80.0
77.9
82.5
82.4
85.0
85.3
90.0
91.2
Lamp
power
W
40
34
40
34
40
34
40
34
Lamp
lifetime
hr
Mean
lamp light
output
lm
CRI
20,000
20,000
20,000
20,000
24,000
20,000
24,000
24,000
70
62
80
70
80
80
85
85
Low price
$
2,880
2,300
3,000
2,460
3,060
2,610
3,250
2,790
1.41
0.89
2.64
1.58
3.51
2.90
3.57
3.50
Medium
price
$
2.35
1.49
4.41
2.64
5.86
4.83
5.95
5.83
High
price
$
3.28
2.09
6.17
3.70
8.20
6.76
8.33
8.16
mstockstill on PROD1PC66 with PROPOSALS2
* This table presents results for T12 4-foot medium bipin GSFL. Results for additional product classes, and T8 4-foot medium bipin GSFL are
available in Chapter 7 of the TSD.
As noted above, DOE derived one
end-user price for the GSFL ballasts it
considered in the analysis. DOE did not
develop end-user prices for magnetic
ballasts operating with 4-foot medium
bipin lamps (rapid start magnetic
ballasts), 8-foot single pin slimline
lamps (instant start magnetic ballasts),
and 8-foot recessed double contact high
output lamps (rapid start magnetic
ballasts). This is because the LCC and
NIA analyses do not model any
purchases of these ballasts after 2012.
The energy conservation standards set
by the 2000 Ballast Rule and the EPACT
2005, Pub. L. 109–58, are effective for
all covered ballasts in 2010. These
standards ban the sale of magnetic 4-
39 Although currently the BR40 non-halogen IRL
may be the higher-volume product, DOE expects
that, with the prescription of energy conservation
standards for certain ER and BR lamps by EISA
2007, by 2012 (the effective date of this
rulemaking’s amended standards) the PAR30
halogen baseline lamp price will reflect the effects
of further commoditization.
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foot medium bipin and 8-foot single pin
slimline ballasts. In addition, DOE
believes that sales of magnetic ballasts
that operate 8-foot recessed double
contact high output lamps will be
minimal after 2012. Again, for all of
these reasons, DOE did not consider
magnetic ballasts in either the LCC or
NIA analyses.
In its review of market prices for
ballasts, DOE observed that prices
tended to be constant within two
groupings of BFs: (1) Low and normal
BFs (a BF typically under 1.0); and (2)
high BFs (a BF typically over 1.0). Table
III.20 presents end-user prices for
ballasts used in the LCC and NIA
analysis.
TABLE III.20.—END-USER PRICES FOR INSTANT START ELECTRONIC FLUORESCENT LAMP BALLASTS
Lamp type
4-foot
4-foot
4-foot
8-foot
8-foot
8-foot
8-foot
8-foot
Ballast
price
Ballast factor range
T8 Medium Bipin ....................................................
T8 Medium Bipin ....................................................
T12 Medium Bipin ..................................................
T8 Single Pin Slimline ............................................
T8 Single Pin Slimline ............................................
T12 Single Pin Slimline ..........................................
T8 Recessed Double Contact HO .........................
T12 Recessed Double Contact HO .......................
b. Incandescent Reflector Lamps
Normal and Low BF .........................................................
High BF ............................................................................
Normal BF ........................................................................
Normal and Low BF .........................................................
High BF ............................................................................
Normal BF ........................................................................
Normal BF ........................................................................
Normal BF ........................................................................
wattage. As a result, DOE did not vary
price by wattage in its analysis.
However, DOE did observe price
differentials between larger- and
smaller-diameter IRL and, therefore,
For IRL, within the range of lamp
wattages analyzed, DOE observed that
lamp price did not vary significantly by
0.75–0.88
1.0–1.18
0.86–0.88
0.78–0.88
1.18
0.85–0.88
0.81–0.88
0.88–0.90
$18.31
25.49
24.36
25.86
47.51
24.73
48.17
30.40
analyzed the two lamp shapes (PAR38
and PAR30) separately. Table III.21
presents the end-user price results for
PAR38 IRL. Results for the PAR30 IRL
are available in Chapter 7 of the TSD.
TABLE III.21.—END-USER PRICES FOR PAR38 IRL
Lamp type
Lamp shape
Halogen ..........................................
Improved Halogen ..........................
HIR .................................................
Improved HIR .................................
PAR38
PAR38
PAR38
PAR38
................................
................................
................................
................................
DOE requests feedback on its
approach to developing lamp or lampand-ballast prices for GSFL and IRL.
Furthermore, DOE requests comment on
its end-user prices results for
fluorescent lamp ballasts.
mstockstill on PROD1PC66 with PROPOSALS2
3. Sales Taxes
The sales tax figure represents State
and local sales taxes that are applied to
the consumer product price. It is a
multiplicative factor that increases the
consumer product price. DOE derived
State and local taxes from data provided
by the Sales Tax Clearinghouse.40 These
data represent weighted averages that
include county and city rates. DOE then
derived population-weighted average
tax values for each Census division and
large State. The distribution of sales tax
rates ranges from a minimum of 0
percent to a maximum of 9.4 percent,
with a weighted-average value of 6.9
percent.
40 Sales Tax Clearinghouse, Aggregate State Tax
Rates (2007). Available at: https://thestc.com/
STrates.stm. Specifically, DOE utilized the relevant
material from this website as posted on May 25,
2007; that material is available in Docket #EE–
2006–STD–0131.
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Lamp lifetime
hr
CSL
Baseline ..............................
1 .........................................
2 .........................................
3 .........................................
Additional detail on the derivation of
the product prices used in this analysis
can be found in Chapter 7 of the TSD,
product price determination.
F. Rebuttable Presumption Payback
Periods
A more energy-efficient device will
usually cost more to purchase than a
device of standard energy efficiency.
However, the more-efficient device will
usually cost less to operate due to
reductions in operating costs (i.e., lower
energy bills). The payback period (PBP)
is the time (usually expressed in years)
it takes to recover the additional
installed cost of the more-efficient
device through energy cost savings.
Section 325(o)(2)(B)(iii) of EPCA
establishes a rebuttable presumption
that a standard for GSFL or IRL 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 * * *
savings during the first year that the
consumer will receive as a result of the
standard, as calculated under the
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Low price
$
2,500
3,000
3,000
4,000
3.20
4.07
4.18
5.00
Medium
price
$
4.80
6.10
6.26
7.50
High
price
$
6.40
8.13
8.35
10.00
applicable test procedure * * *.’’ (42
U.S.C. 6295(o)(2)(B)(iii)) This rebuttable
presumption test is an alternative path
to establishing economic justification, as
compared to consideration of the seven
factors set forth in 42 U.S.C.
6295(o)(2)(B)(i)(I)–(VII).
DOE’s lamp test procedures measure
the rate of light output per unit power
consumption of a lamp (i.e., lumens per
watt) rather than a measurement of
energy consumption (i.e., a
measurement over a duration or
operating time period). Therefore, in
order to calculate energy savings for the
rebuttable presumption payback period,
one would need to multiply the rate of
power consumption of a lamp times the
usage profile of that lamp. For IRL,
energy savings calculations in the LCC
and PBP analyses use both the relevant
test procedures as well as the relevant
usage profile. Because DOE calculates
payback periods using a methodology
consistent with the rebuttable
presumption test for IRL in the LCC and
payback period analysis, DOE is not
performing a stand-alone rebuttable
presumption analysis for IRL, as it is
already embodied in the LCC and PBP
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regulation if the service life of the
covered product is substantially longer
than the PBP.
The following discussion provides an
overview of the approach and inputs for
the LCC and PBP analyses performed by
DOE, as well as a summary of the
preliminary results generated for the
lamps under consideration in this
rulemaking. However, for a more
detailed discussion on the LCC and PBP
analyses please refer to Chapter 8 of the
ANOPR TSD.
G. Life-Cycle Cost and Payback Period
Analyses
The life-cycle cost (LCC) and payback
period (PBP) analyses determine the
economic impact of potential standards
on consumers. The effects of standards
on individual or commercial consumers
include changes in operating expenses
(usually lower) and changes in total
installed cost (usually higher). DOE
analyzed the net effect of these changes
GSFL and IRL first by calculating the
changes in consumers’ LCCs likely to
result from CSLs as compared to a base
case (no new standards). The LCC
calculation considers 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. DOE performed the
LCC analysis from the perspective of the
consumer of a lamp.
DOE also analyzed the effect of
changes in operating expenses and
installed costs by calculating the PBP of
potential standards relative to a base
case. The PBP estimates the amount of
time it would take the individual or
commercial consumer to recover the
assumed higher purchase expense of
more energy efficient product through
lower operating costs. The PBP is based
on the total installed cost and the
operating expenses, the same approach
used in calculating the LCC. However,
unlike in the LCC analysis, DOE
considers only the first-year operating
expenses in the calculation of the PBP.
Because the PBP does not account for
changes in operating expense over time
or the time value of money, it is also
referred to as a simple PBP. Usually the
consumer benefits of a regulation
exceed the consumer costs of that
The LCC analysis estimates the
impact on consumers of potential
energy conservation standards by
calculating the net cost of a lamp (or
lamp-ballast system) under two
scenarios: (1) A ‘‘base case’’ of no new
standard; and (2) a ‘‘standards case’’
under which lamps must comply with
a new energy efficiency standard. The
first step in calculating the LCC is
specifying the installed costs associated
with each design, which includes the
lamp (or lamp-and-ballast system) price,
sales taxes, and any installation cost.
(The development of total installed
costs is explained more fully in sections
III.E of this notice and Chapters 7 and
8 of the TSD.) After developing the
installed costs, DOE used operating
hour data and electricity price data to
develop operating costs of the base-case
and standards-case lamps over the
analysis period. (The development of
operating costs is explained in section
III.D.1. of this notice and Chapters 6 and
8 of the TSD.)
DOE calculated the LCC value for
each design and each customer using a
discount rate that represents the average
cost of capital for that customer. After
repeating the calculation for many
customers and many designs,42 DOE
calculated the distribution of net LCC
impacts of each design. A distinct
advantage of this approach is that DOE
can identify the proportion of lamp
installations achieving LCC savings or
attaining certain payback values due to
a new energy conservation standard, in
addition to the average LCC savings or
average payback for that standard. Refer
to Chapter 8 of the ANOPR TSD for
detailed discussion of the LCC analysis
method.
During the Public Meeting on the
Framework Document, DOE stated its
intention to use Monte Carlo analysis in
the LCC to consider end-user variability
and conduct sensitivity analyses.
41 For example, T8 lamps which are often
operated on high-frequency electronic ballasts
would be tested and measured on a line-frequency
(60 Hz) reference ballast using DOE’s test
procedure, resulting in different performance
characteristics than this lamp would exhibit in the
field, operated on an electronic ballast.
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1. Approach
42 For each design, DOE calculated the LCC
results for 1,000 consumers using Monte Carlo
simulations. These results are presented in
Appendix 8B of the TSD.
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Reinforcing this decision, stakeholders
commented that conducting such
analyses using a Monte Carlo approach
would provide useful information on
the number of purchasers who benefit
from or are disadvantaged by the
standard, and by how much. (Joint
Comment, No. 9 at p. 4) Accordingly,
DOE has incorporated in its LCC and
PBP spreadsheet model both Monte
Carlo simulation and probability
distributions by using Microsoft Excel
spreadsheets with Crystal Ball (a
commercially-available add-in
program). DOE’s Monte Carlo
simulation considers variability in
electricity prices, sales taxes, operating
hours, and discount rates. See section
III.G.2 for a discussion of LCC inputs.
For a detailed discussion on the average
annual energy use of lamps and the
methodology used to calculate the
distribution of annual energy use, please
refer to section III.D of this ANOPR and
Chapter 6 of the TSD.
In order to accurately compare the life
cycle cost of two different products, one
must evaluate the life cycle cost of each
product over the same fixed period of
time (i.e., the analysis period). For the
life-cycle cost analysis, the analysis
period is the lifetime of the covered
product. For most covered products that
DOE analyzes, the lifetimes of the more
efficient products are the same as the
lifetimes of baseline products being
analyzed. For this rulemaking, given the
unequal lifetimes of the baseline and
higher efficacy lamp designs, DOE has
chosen to establish its analysis period
on the lifetime of the baseline lamp. In
situations where a lamp lifetime is
shorter than the analysis period, DOE
assumes that the lamp is replaced
during the analysis period. To account
for any remaining lifetime at the end of
the analysis period, DOE calculates a
‘‘residual value’’ for that lamp.43
SL − PAnalysis − ( n ⋅ SL )
RV = IC ⋅
SL
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
43 The ‘‘residual value’’ represents the remaining
value of a lamp or a ballast from the end of the
period of analysis to the end of the service life of
the lamp or ballast. The equation for residual value
is as follows: (see equation above)
Where IC = total installed cost of the product,
n = the number of replacements within the analysis
period, SL = the service life of the product, and
PAnalysis = the analysis period.
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mstockstill on PROD1PC66 with PROPOSALS2
analyses. For GSFL, DOE believes that
the rate of energy consumption of the
lamp-and-ballast system is a more
accurate measure of real world power
consumption than the rate of power
consumption of the lamp as measured
on a reference ballast, as specified in the
test procedure.41 Because calculations
of energy savings in the LCC are based
on real-world conditions, DOE will also
rely on payback periods calculated in
the LCC for GSFL. See section III.G of
this notice or Chapter 8 of the TSD for
further detail on the LCC and payback
period calculation.
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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.44 More
information discussing the residual
value is given in Chapter 8 of the TSD.
ACEEE commented that a residual
value calculation or a 50-year analysis
period would yield similar results.
(Public Meeting Transcript, No. 4.5 at p.
188) DOE agrees that using a long
analysis period, such as 50 years, and
discounting cash flows would normalize
for differences in lifetimes of different
lamps. However, the statute explicitly
directs DOE to consider the increased
first costs and operating cost savings
over ‘‘the estimated average life of the
covered product.’’ (42 U.S.C.
6295(o)(2)(B)(i)(II)) The life-cycle costs
over a 50 year analysis period would be
significantly larger than those over a
typical lamp lifetime. For this reason,
DOE believes that the residual value
approach is more consistent with the
statute and with the concept of lifecycle costing, and elected to use the
lifetime of the baseline lamp as the
period of analysis. DOE invites
comment on its usage of residual values
in the life-cycle cost analysis as well as
any other possible approaches to
calculating life-cycle costs for products
with different lifetimes.
2. Life-Cycle Cost Inputs
For each efficacy level analyzed, the
LCC analysis requires input data for the
total installed cost of the product, the
operating cost, and the discount rate.
Table III.22 summarizes the inputs and
key assumptions DOE used to calculate
the consumer economic impacts of
various energy efficacy levels for each
product. A more detailed discussion of
the inputs follows.
TABLE III.22.—SUMMARY OF INPUTS AND KEY ASSUMPTIONS USED IN THE LCC ANALYSES
Input
Description
Consumer Equipment Price .................
As discussed in section III.E, DOE started with manufacturer catalog (‘‘blue-book’’) pricing, and used
different discounts to represent low, medium, and high prices for all lamp categories.
Sales tax is then applied to convert the consumer equipment price to a final consumer price including
sales tax. The sales tax mark-up is described in detail in section III.E.
This input represents the cost to the commercial or industrial customers of installing the lamps or lamp
systems. The installation price represents all costs required to install the lamp or lamp system but
does not include the customer equipment price. The installation price includes labor and overhead.
Thus, the total installed cost equals the consumer equipment price including sales tax plus the installation price.
The annual operating hours are the estimated hours that a lamp is in use during the time span of one
year. Section III.D, Energy-Use Characterization, details how DOE determined the lamp operating
hours as a function of end-user sector, geographic region, and application.
The product energy consumption is the site-energy usage rate associated with operating the lamp system. Section III.D, Energy-Use Characterization, details how DOE determined the product energy
consumption rate.
Electricity prices used in the analysis are the average price per kilowatt-hour (i.e., $/kWh) paid by customers. DOE determined electricity prices using national average residential, commercial, and industrial electricity prices for the sample calculation, while for the Monte Carlo distribution, DOE used average residential, commercial, and industrial values for 13 regions and large States. All electricity
price data are obtained from the EIA, 2005.
DOE used the EIA’s AEO2007 45 to forecast electricity prices. For the results presented in this notice,
DOE used the AEO2007 reference case to forecast future electricity prices.
The total hours in operation after which the consumer retires the lamp or components of a lamp system
from service.
The discount rate is the rate at which DOE discounts future expenditures to establish their present
value.
Analysis period is the time span over which DOE calculated the LCC.
Sales tax ...............................................
Installation cost .....................................
Annual operating hours ........................
Product energy consumption rate ........
Electricity prices ...................................
Electricity price trends ..........................
Lifetime .................................................
Discount rate ........................................
Analysis Period .....................................
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a. Total Installed Cost Inputs
The following sections describe the
total installed cost inputs. As described
previously, to account for variability in
pricing, DOE estimated three product
prices per lamp design, which
correspond to variation in purchasing
power. DOE applied sales tax to each
product price to create a set of end-user
prices for these system components.
The installation cost represents all
costs associated with installing the lamp
or lamp-and-ballast system, other than
the end-user lamp price. Thus, the total
installed cost equals the consumer lamp
price (which includes mark-ups and
taxes) plus the installation cost. In its
44 National Institute of Standards and Technology
Handbook 135, 1996 Edition, 210 pages (Feb. 1996),
p. 4–6.
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Framework Document, DOE noted that
installation costs are negligible for the
residential sector but important in the
commercial and industrial sectors.
NEMA commented that there are
generally no repair or maintenance costs
for incandescent lamps, but only
installation costs. (Public Meeting
Transcript, No. 4.5 at p. 174; NEMA, No.
8 at p. 3)
DOE is aware that installation costs
for incandescent lamps are applicable
by sector and not by lamp type. For
example, consumers in the residential
sector typically do not incur installation
costs, as these consumers typically
change their own lamps. Therefore, for
IRL analyzed in the residential sector,
DOE assumed no installation costs.
Rather, the cost the user pays is simply
that of the product. Purchasers in the
commercial and industrial sectors, on
the other hand, do incur installation
costs because they usually employ a
maintenance worker to install their
incandescent lamps. Therefore, DOE
applied installation costs for IRL
analyzed in the commercial and
industrial sectors.
DOE stated in the Framework
Document that it would consider
installation costs but not maintenance
costs in its analysis. According to
NEMA, installation costs are important
45 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/.
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for fluorescent lamps, but there are also
some maintenance costs. (Public
Meeting Transcript, No. 4.5 at p. 174)
DOE presumes that the maintenance
costs to which NEMA referred are the
costs of re-lamping a lighting system
(i.e., replacing the lamp in a lighting
system at end of lamp life). For GSFL,
DOE assumed installation costs for
lamp-and-ballast systems, and relamping costs for lamps.
DOE requested comment in the
Framework Document on whether it
should consider group and spot relamping practices in its analysis of
installation costs. NEMA commented
that, for GSFL, a small percentage of
fluorescent lamps are group re-lamped
rather than spot re-lamped. (Public
Meeting Transcript, No. 4.5 at pp. 174–
176; NEMA, No. 8 at p. 3) GE
commented that group re-lamping
should not be considered for
incandescent or incandescent reflector
lamps, but could be considered for
fluorescent lamps; however, GE did not
provide further explanation for its
opinion. (Public Meeting Transcript, No.
4.5 at pp. 176–177)
The approach DOE is following for
the ANOPR is consistent with these
comments. For GSFL, DOE obtained
estimates of the prevalence of group
versus spot re-lamping from the 2000
Ballast Rule. DOE then weighted the
spot and group re-lamping times by the
percent occurrence of spot versus group
re-lamping to derive weighted-averaged
re-lamping times. To account for
installation costs for IRL in the
commercial sector, DOE used relamping time estimates from the RS
Means Electrical Cost Data, 2007 46
(hereafter ‘‘RS Means’’).
For ballasts, DOE derived labor rates
for electricians and helpers from RS
Means. Labor rates are the sum of the
wage rate, employer-paid fringe benefits
(i.e., vacation pay, employer-paid
health, and welfare costs), and any
appropriate training and industry
advancement funds costs. DOE assumed
that the labor rate for installing a ballast
is a composite that equals 50 percent of
the electrician labor rate plus 50 percent
of the electrician-helper labor rate. For
re-lamping (only lamp replacement),
DOE assumed that the task was
performed by a general maintenance
worker at a labor rate DOE obtained
from the U.S. Bureau of Labor Statistics
for a General Maintenance worker.47
46 R.S. Means Company, Inc., 2007 RS Means
Electrical Cost Data (2007).
47 U.S. Department of Labor Bureau of Labor
Statistics. Occupational Employment and Wage
Estimates. National Cross-Industry Estimates (May
2005). Available at: https://www.bls.gov/oes/
oes_dl.htm.
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Using these labor rates and labor times,
DOE derived the average cost to install
a lamp and the average cost to install a
lamp and ballast.
DOE recognizes that labor times for
replacing a ballast may change because
of changes in the 2005 National Electric
Code.48 Specifically, the addition of Part
XIII, Section 410.73(G) to the 2005
National Electric Code requires a means
for disconnecting luminaires installed
in an indoor location so that electrical
contractors will not work on energized
equipment while replacing or servicing
ballasts. This change applies to both
commercial and industrial
installations.49 This requirement goes
into effect January 1, 2008, and it is
expected to significantly increase the
labor time required for ballast
installations. Therefore, DOE is
requesting comment on how labor times
and related installation costs for ballasts
will be affected by this change in the
National Electric Code.
Additional details on the
development of installation costs can be
found in Chapter 8 of the ANOPR TSD.
b. Operating Cost, Replacement Cost,
and Residual Value Inputs
The following sections describe
additional inputs used in calculating the
LCC. These include inputs used to
develop operating costs, replacement
costs, and residual values. The
operating cost of a lamp system is a
function of the annual energy
consumption, energy cost, repair and
maintenance costs, analysis period, and
the discount rate. Annual energy
consumption is the site-energy use (i.e.,
electricity use) associated with
operating a lamp or lamp-and-ballast
system. The inputs for estimating
annual energy consumption are
discussed in section III.D of this
ANOPR. Electricity prices are the prices
paid by consumers for electricity. DOE
used electricity price trends to forecast
electricity prices into the future.
Multiplying the annual energy
consumption by the electricity prices
yields the annual energy cost. Because
DOE assumed no repair or maintenance
costs, costs associated with repairing or
replacing components that have failed,
the only operating costs associated with
lamps are energy costs. The analysis
period is the time span over which the
LCC is calculated. For the purpose of
this rulemaking, DOE based the analysis
period on the baseline lamp’s service
48 National Fire Protection Association, National
Electric Code 2005. CENGAGE Delmar Learning:
2004.
49 Ode, Mark C., ‘‘Unplugging Fluorescents,’’
Electrical Contractor (July 2005). Available at:
www.ul.com/regulators/ode/0705.pdf.
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lifetime (i.e., the lamp’s operating
lifetime in hours divided by annual
operating hours). The discount rate is
the rate at which DOE discounted future
expenditures to establish their present
value. The replacement cost (i.e., the
costs associated with a lamp
replacement) is dependent on the
installed cost, discount rate, analysis
period, and service life. The product
service life is the age at which the
product is retired from service. The
residual value (also dependent on the
four inputs used to develop replacement
costs) is the discounted total installed
cost of a lamp (or lamp and ballast)
multiplied by the percentage of
remaining life for that lamp (or lamp
and ballast) past the analysis period.
i. Electricity Prices
With regard to electricity prices, DOE
derived 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. For Census divisions
containing one of these large States,
DOE calculated the regional average
values leaving out data for the large
State—for example, the Pacific region
average does not include California, and
the West South Central region does not
include Texas.
DOE estimated residential, industrial,
and commercial electricity prices for
each of the 13 geographic areas based on
data garnered from EIA Form 861,
Annual Electric Power Industry Report.
DOE’s calculation methodology uses the
most recently available EIA data (2005).
For further details of the methodology
that DOE used for deriving energy
prices, see Chapter 8 of the ANOPR
TSD.
DOE stated in the Framework
Document that it would use price
forecasts by the EIA to estimate the
trends in electricity prices. In response,
ACEEE and the Joint Comment argued
that current EIA energy price forecasts
are too low and will likely be revised
upwards over the next few years. (Joint
Comment, No. 9 at p. 3; Public Meeting
Transcript, No. 4.5 at p. 216) Therefore,
the Joint Comment requested that DOE
use the latest available price forecasts
from EIA to conduct the analyses. (Joint
Comment, No. 9 at p. 3) Taking into
account these comments, DOE used
EIA’s AEO2007, containing the latest
available price forecasts from EIA to
estimate future energy prices. For the
analyses to be conducted for the NOPR
and Final Rule, DOE intends to update
its energy price forecasts to be based on
the latest available version of AEO.
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DOE did not explicitly discuss
demand charges 50 in the Framework
Document, but stakeholders identified
this as an issue and submitted
comments. For example, ACEEE
commented that DOE should consider
demand charges in its electricity pricing
rather than averaging prices because
lighting tends to be ‘‘peakier’’ than the
average use. (Public Meeting Transcript,
No. 4.5 at pp. 169–171) PG&E
commented that DOE should account
for the marginal consumer cost of
electricity in its analysis and that the
marginal cost of electricity is
significantly different than the average
cost of electricity in certain regions
(Public Meeting Transcript, No. 4.5 at
pp. 215) PG&E also commented that in
addition to using a single average price,
DOE should look at a range of electricity
prices. EEI commented that separating
out demand charges could lead to
similar results, except, possibly, for the
residential sector. (Public Meeting
Transcript, No. 4.5 at pp. 172 and 215)
The Joint Comment stated that utility
rate structures have been changing over
time, and it recommended that DOE
conduct a sensitivity analysis to
evaluate whether changes in pricing
structure would significantly impact the
rulemaking analyses. The Joint
Comment also suggested that DOE
should consider basic electricity tariff
evolutions in the structure of the LCC
and NIA, if the sensitivity analysis
shows that expected changes to
electricity price structures are
influential. (Joint Comment, No. 9 at p.
4)
DOE notes that in the analysis
performed for the fluorescent ballast
rulemaking, DOE found that the
reduction in ballast energy consumption
results in a correspondingly lower
reduction in peak power. In other
words, the lighting load improves a
building’s load profile. Thus, the
marginal rate of electricity for lighting
was found to be slightly lower than the
average utility rate. In relative terms,
DOE assumed in the ballast rulemaking
that the demand reduction was 80
percent of the energy savings. For the
case study analyzed in the ballast rule,
a 5-percent energy savings resulted in a
4-percent demand reduction of the peak
kW, and at the consumption weighted
mean of the differences, the electricity
marginal prices were found to be 5.2
percent lower than average prices.51
Consistent with a number of other
current DOE rulemakings, DOE has
tentatively decided to use average
regional electricity prices for its
analyses. DOE believes that using
average regional EIA prices would not
underestimate operating cost savings. In
addition, the approach will include the
regional variations in energy prices,
while reducing analytical complexity.
In addition to accounting for regional
variability, DOE also addressed future
variability by incorporating three
separate projections from AEO2007 into
the spreadsheet models for calculating
LCC and PBP: (1) Reference; (2) low
economic growth; and (3) high
economic growth. These three cases
reflect the uncertainty of economic
growth in the forecast period (from 2005
to 2030). The high- and low-growth
cases show the projected effects of
alternative growth assumptions on
energy markets. The development and
use of regional average electricity prices
are described below and in more detail
in Chapter 8 of the TSD.
50 Typically consumers pay a premium for
electricity consumed during times in the day when
the demand for electricity is at its peak. These
additional charges are called ‘‘demand charges.’’
51 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 B, Marginal
Energy Prices and National Energy Savings p. B–10
(Jan. 2000). Available at: https://www.eere.energy.
gov/buildings/appliance_standards/residential/
pdfs/appendix_b.pdf.
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ii. Lamp Lifetime
With regard to lamp lifetime, DOE
stated in the Framework Document that
it would consider published catalog
data, as well as literature sources and
inputs from manufacturers and other
stakeholders in its analysis. GE and
NEMA commented that DOE should use
published catalog data for lamp
lifetimes. (Public Meeting Transcript,
No. 4.5 at p. 176; NEMA, No. 8 at p. 3)
In response, DOE did use published
manufacturer literature for lamp
lifetimes, where available. However, for
some IRL, published manufacturer
literature on lamp lifetimes is not
available. Therefore, where applicable,
DOE derived lamp lifetimes as part of
the engineering analysis, in the manner
discussed in section III.C.
For GSFL, the manufacturer literature
provides lamp lifetimes for both lamps
operated three hours per start and those
operated 12 hours per start. Therefore,
in the Framework Document, DOE
invited comment as to which lifetime
value is more appropriate for use in the
LCC analysis. GE and EEI commented
that by referencing studies on lighting
controls, DOE could develop a weighted
lamp lifetime by estimating the
proportion of the installed base that is
operated at 12 hours per start and the
proportion that is operated at three
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hours per start. (Public Meeting
Transcript, No. 4.5 at p. 179, Public
Meeting Transcript, No. 4.5 at pp. 179–
180) In its comments, EEI opined that
using 3 hours per start in the base case
and standards case would be sufficient
for this analysis (Public Meeting
Transcript, No. 4.5 at p. 180). After
considering public comments, DOE has
tentatively decided on the following
approach in this area. Because
published manufacturer literature on
lamp lifetimes for 12 hours per start is
not available for all lamps in the base
case and the standards case, and
because the lifetimes are shorter in
three-hours-per-start data, DOE decided
to base its calculation of lamp lifetimes
for both base- and standards-case lamps
on three hours per start data. Thus,
under this approach, DOE would not
risk overstating energy savings. DOE
welcomes comment on this approach.
Lamp lifetime is not only affected by
the number of hours per start but also
by the type of relamping practiced. For
example, lamps replaced through group
relamping, in contrast to spot
relamping, will be replaced before the
end of their rated life. In the Framework
Document, DOE invited comment on
whether the effect on lamp lifetime of
group and/or spot re-lamping practices
should be taken into account. GE
commented that group re-lamping
practices should be taken into account
for GSFL and that this practice usually
occurs at 70 percent of the rated
lifetime. (Public Meeting Transcript, No.
4.5 at pp. 176–177) Like the calculation
of re-lamping costs, DOE averaged the
group versus spot re-lamping impact on
lifetime by their percent occurrence for
GSFL. DOE assumed a lamp subject to
group re-lamping practices operates for
75 percent of its rated life, an estimate
obtained from the 2000 Ballast Rule.52
DOE then applied this life impact factor
to the rated lifetimes from the
manufacturing literature for the GSFL it
analyzed. For 4-foot medium bipin
lamps, the average lifetime used in the
analysis was 94 percent of the rated
lifetime. For 8-foot single pin slimline
lamps, the average lifetime was 91
percent of the rated lifetime, and for 8foot recessed double contact HO lamps,
the average lifetime was 92 percent of
the rated lifetime. For the reasons
discussed in section III.G.2.a, DOE
52 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, p. A–19
(Jan. 2000). Available at: https://www.eere.
energy.gov/buildings/appliance_standards/
residential/pdfs/appendix_a.pdf.
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agrees with GE that group re-lamping
should not be considered for IRL.
(Public Meeting Transcript, No. 4.5 at
pp. 176–177). Therefore, DOE did not
assume an impact on lamp lifetime due
to group re-lamping for IRL.
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iii. Discount Rates
As noted in the Framework
Document, DOE planned to develop an
analysis on discount rates similar to
prior rulemaking analyses that
evaluated the impact of standards on
products or equipment installed in the
residential, commercial, and industrial
sectors. NWPCC commented that DOE
should use discount rates from prior
rulemakings, because these rates do not
vary appreciably over the long term.
(Public Meeting Transcript, No. 4.5 at
pp. 183–184) In response, DOE
reviewed the discount rate analyses
from several recent rulemakings, and
decided to use the same residential
discount rates as it did for the 2007
ANOPR for the Residential Electric and
Gas Ranges and Microwave Ovens,
Dishwashers, Dehumidifiers, and
Commercial Clothes Washers (hereafter
‘‘Home Appliance ANOPR’’). 72 FR
64432 (November 15, 2007). For the
commercial sector, DOE used the same
discount rates for the categories of lamp
users as it used for those same
categories in the 2006 NOPR for
Electrical Distribution Transformers
(hereafter ‘‘Transformer NOPR’’). 71 FR
44356 (August 4, 2006). However, DOE
adjusted the aggregate commercial
sector discount rate to account for
differences in the proportions of types
of owners of each lamp type.
For residential replacement lamps,
DOE identified all possible debt or asset
classes that would be sources of funds
used to purchase replacement lamps,
including household assets that might
be affected indirectly. The mean real
effective rate across all types of
household debt and equity, weighted by
the shares of each class, is 5.6 percent.
For the commercial and industrial
sectors, DOE derived the discount rate
from the cost of capital of publiclytraded 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. For further
details on DOE’s method for estimating
discount rates, see Chapter 8 of the
ANOPR TSD.
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iv. Analysis Period
The analysis period is the time span
over which the LCC is calculated. DOE
bases the analysis period on the longest
baseline lamp life in a certain product
class divided by the annual operating
hours of that lamp. If the user chooses
to run the LCC using weighted average
values, then the analysis period is based
on the longest baseline lamp life
divided by the average annual operating
hours for that lamp in a chosen sector,
or a multiple thereof. For example, the
longest lived baseline IRL lamp is 3,000
hrs. If the user chooses to analyze this
lamp in the commercial sector, then the
analysis period is the lamp lifetime of
3,000 hours divided by the average
annual operating hours for IRL in the
commercial sector of 3,450 hrs/yr,
which yields an analysis period of 0.9
years. In order to allow users to compare
the cost of IRL lamps over multiple
lamp lifetimes, one can select a multiple
of this analysis period (i.e., 1.8, 2.7, or
3.6 years). If the user chooses to run the
LCC using Crystal Ball software (a tool
used to do the Monte Carlo analysis),
the analysis period is based on the
longest baseline lamp life divided by the
annual operating hours chosen by
Crystal Ball. For example, the user may
choose to run IRL in the commercial
sector using Monte Carlo analysis. If
Crystal Ball selects a building that is
used for religious worship, the analysis
period for IRL for that selection will be
based on a lamp lifetime of 3,000 hours
divided by the annual operating hours
for IRL in a building used for religious
worship of 1,609 hrs/yr, which yields an
analysis period of 1.9 years. However,
users cannot select a multiple of this
analysis period when using Crystal
Ball due to the nature of the LCC
spreadsheet. For detail on additional
results, please see Chapter 8 and
Appendix 8B of the TSD.
v. Effective Date
For purposes of this discussion, the
‘‘effective date’’ is the future date when
a new standard becomes operative (i.e.,
the date by and after which lamp
manufacturers must manufacture
products that comply with the
standard). DOE publication of a final
rule in this standards rulemaking is
scheduled for completion in June 2009.
Pursuant to sections 325(i)(3) and (5) of
EPCA, the effective date of any new or
amended energy conservation standards
for these lamps must be three years after
the final rule is published, which would
be June 2012. (42 U.S.C. 6295(i)(3) and
(i)(5)) DOE calculated the LCCs for all
consumers, based upon an assumption
that each would purchase the new
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product in the year the standard takes
effect.
3. Payback Period Inputs
As explained above, the PBP is the
amount of time it takes the consumer to
recover the estimated additional
installed cost of more-efficient products
through energy cost savings only.
Payback analysis is a technique used to
obtain a rough indication of whether an
investment is worthwhile. This type of
calculation is known as a ‘‘simple’’
payback period because it does not take
into account other changes in operating
expenses over time or the time value of
money.
The inputs to the calculation of the
PBP are the total installed cost of the
product to the customer for each
efficacy level and the annual
(represented by first-year) operating
expenditures for each efficacy level. The
PBP calculation uses the same inputs as
the LCC analysis, except that energy
price trends and discount rates are not
needed. The calculation needs energy
prices only for the year in which a new
standard is expected to take effect, in
this case 2012.
4. Lamp Purchasing Events
GE, ACEEE, and PG&E all
recommended that DOE should divide
the lamp market into three market
segments: (1) New construction; (2)
major retrofit; and (3) replacement
lamps; such an approach would allow
DOE to differentiate between the
options facing consumers for those three
scenarios. (GE, No. 4.5 at p. 112; ACEEE,
No. 4.5 at p. 113; PG&E, No. 4.5 at p.
113) GE, for example, commented that
lumens can be kept constant with the
baseline system for new construction,
whereas for the replacement lamp
market segment, lumens may be higher
than the baseline system. (GE, No. 4.5 at
p. 122) In response, DOE agrees with
stakeholders on this point and has
broken the LCC and NIA into several
market segments or ‘‘lamp purchasing
events’’ to represent the lamp-andballast designs facing consumers under
each scenario. These ‘‘lamp purchasing
events’’ are described below. Although
DOE considers in the LCC only those
energy-saving design options which
reduce lumen output by 10 percent or
less, all other design options facing
consumers are considered in the NIA.
To further explain, DOE designed the
LCC analysis for this rulemaking around
scenarios where consumers have a need
to replace a lamp; these are collectively
referred to as ‘‘lamp purchasing events.’’
Each of these events may present the
consumer with a different set of
technology options and, therefore, a
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different set of LCC savings for a certain
CSL. For GSFL, DOE identified five
possible scenarios under which
consumers would purchase a lamp and
potentially be affected by a minimum
energy conservation standard. These
scenarios are: (1) Lamp failure; (2)
standards-induced retrofit; (3) ballast
failure; (4) ballast retrofit; and (5) new
construction/renovation. These five
lamp purchasing events are described in
more detail below. (It is noted that for
IRL, due to the fact that there is no
ballast involved, the scenario for the
incandescent lamp product classes is
simply a lamp failure.) In addition to
the descriptions below, Table III.23 and
Table III.24 summarize the lamp
purchasing events considered in this
analysis.
• Lamp Failure (Event I): This event
reflects a scenario in which a lamp
either fails (spot-relamping) or is about
to fail (group relamping) and must be
replaced. In the absence of the energy
conservation standard, the analysis
assumes an identical lamp would have
been installed as a replacement.
However, under a lamp energy
conservation standards scenario, a
standards-compliant lamp is required
which operates on the existing ballast.
Thus, the first consumer response to a
lamp failure is expected to be a simple
lamp replacement with the same type of
lamp. A second response occurs for
owners of T12 systems. Unlike T8
lamps, there are certain lamp standard
levels which a T12 lamp cannot meet.
These users would be required to
purchase both new lamps and ballasts
in order to meet the lamp energy
conservation standard.
• Standards-Induced Retrofit (Event
II): This event reflects a scenario in
which an increase in the energy
conservation standard for lamps
prompts end-users to retrofit both lamps
and ballasts, whereas, in the base case,
they would otherwise have installed
only a lamp due to a lamp failure. This
lamp purchasing event only applies to
users with T12 lamps because, unlike
T8 lamps, there are certain lamp
standard levels which a T12 lamp
cannot meet. This event contemplates a
scenario where users, under a lamp
energy conservation standard, can no
longer purchase a T12 replacement
lamp for their T12 ballast. For this
scenario, DOE assumes a uniform age
distribution of T12 lamps throughout
the nation. Therefore, based on this age
distribution, the average T12 lamp is
halfway through its lifetime. Consumers
in the base case purchase only a lamp
after the average T12 lamp has died (i.e.,
after it has lived through the second half
of its lifetime). Consumers in the
standards case choose to change both
the lamp and the ballast early, instead
of waiting for their T12 lamps to fail.
Therefore, in the standards case, a lampand-ballast purchase would occur at the
beginning of the analysis, before the
average lamp being replaced has failed.
• Ballast Failure (Event III): This
event reflects a scenario in which the
installed ballast has failed. DOE
recognizes that energy conservation
standards for ballasts set by the 2000
Ballast Rule and EPACT 2005 are
effective in 2010. These standards ban
the sale of magnetic 4-foot medium
bipin and 8-foot single pin slimline
ballasts. In addition, DOE believes that
sales of magnetic ballasts that operate 8foot recessed double contact high output
lamps will be minimal after 2012.
Therefore, in the baseline, users who
had a magnetic T12 ballast would be
expected to replace it with an electronic
T12 ballast. Users who had a T8 ballast
installed would be expected to replace
it with a T8 ballast. However, in the
standards case, end-users would select a
standards-compliant lamp-ballast
combination such that the system light
output never drops below 10 percent of
the baseline system.
• Ballast Retrofit (Event IV): This
event applies only to T12 users because,
according to industry experts, the
majority of ballasts that are retrofitted
are T12 lamp-and-ballast systems. As
opposed to the standards-induced
retrofit event where end-users replace
only their lamps in the base case, endusers under this event replace both their
lamps and ballasts in the base case in
order to save energy. With standards,
end-users will also retrofit their old
lamps and ballasts, but with standardscompliant lamps. DOE assumes that
end-users continue to use the existing
fixture and replace only the ballast.
Because the spatial layout in the
building space is constrained by the
number of fixtures, light output of the
replacement lamp-and-ballast system is
maintained.
• New Construction and Renovation
(Event V): This lamp purchasing event
encompasses all the new fixture
installations where the lighting design
will be completely new or can be
completely changed. This scenario is
only applicable to those baseline lamps
that are usually used in new
construction and renovation (4-foot T8s,
8-foot single pin slimline T8s, and 8foot recessed double contact HO T12s).
In this scenario, the spatial layout of
fixtures in the building space is not
constrained to any previous
configuration. Because new fixtures can
be installed, consumers could install a
lamp-and-ballast system that would not
maintain the light output of the baseline
system. For instance, if light output of
the standards case system is lower than
the base case system, consumers can
increase the number of standards case
lamp-and-ballast systems installed in
the building by a certain percentage to
maintain the light output of base case
lamp-and-ballast systems.
Table III.23 and Table III.24 outline
the events and actions taken by
consumers in response to those events
both in the base case and the standards
case.
TABLE III.23.—FRAMEWORK OF EVENT-TYPE SCENARIOS FOR T12 LAMPS
Event
Base-case action
Standards-case action
Event I. Lamp Failure ...............
(a) Installs a T12 lamp .....................................
Installs a lower-wattage, higher efficacy lamp, where the system light output never drops below 10 percent of the baseline system.
Installs a T12 or T8 electronic ballast and lamp, where the
system light output never drops below 10 percent of the
baseline system.
Installs a new T12 or T8 electronic ballast and lamp, where
the system light output never drops below 10 percent of the
baseline system.
Installs a new T12 or T8 ballast and lamps, where the system
light output never drops below 10 percent of the baseline
system.
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(b) Installs a T12 lamp .....................................
Event II. Standards-Induced
Retrofit.
Replace T12 lamp halfway through analysis
period.53
Event III. Ballast Failure ............
Installs a T12 electronic ballast and lamps in
the existing fixture.
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TABLE III.23.—FRAMEWORK OF EVENT-TYPE SCENARIOS FOR T12 LAMPS—Continued
Event
Base-case action
Standards-case action
Event IV. Ballast Retrofit ...........
Installs a T8 electronic ballast and lamps in
the existing fixture.
Event V. New Construction and
Renovation.
Installs a new T12 system ...............................
Installs a new T12 or T8 ballast and lamps, where the system
light output never drops below 10 percent of the baseline
system.
Installs a new T12 or T8 system that is where the system
light output never drops below 10 percent of the baseline
system. Light output can be maintained through spacing.
TABLE III.24.—FRAMEWORK OF EVENT-TYPE SCENARIOS FOR T8 LAMPS
Base-case action
Standards-case action
Event I. Lamp Failure ...............
Installs a T8 lamp .............................................
Event III. Ballast Failure ............
Installs a T8 electronic ballast and lamps in
the existing fixture.
Event V. New Construction and
Renovation.
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Event
Installs a new T8 system .................................
Installs a lower-wattage, higher efficacy lamp, where the system light output never drops below 10 percent of the baseline system.
Installs a new T8 ballast and lamps, where the system light
output never drops below 10 percent of the baseline system.
Installs a new T8 system, where the system light output
never drops below 10 percent of the baseline system. Light
output can be maintained through spacing.
5. Life-Cycle Cost and Payback Period
Results
DOE calculated the average LCC
savings relative to the base-case forecast
for each product class. As mentioned
above, the base case consists of the
projected pattern of product purchases
that would occur in the absence of new
energy conservation standards.
DOE did not explicitly discuss
aggregating results of the LCC and PBP
analyses in the Framework Document,
but stakeholders identified this as a
critical issue and submitted comment
thereon. For example, ACEEE
commented that DOE should weigh its
results for the three market segments it
considered—new construction, retrofit,
and lamp replacement—by their
percentage of sales. (Public Meeting
Transcript, No. 4.5 at pp. 118–119) The
Joint Comment also recommended that
DOE should weigh its results by market
segment. (Joint Comment, No. 9 at p. 5)
In addition, ACEEE commented that
some of the higher efficacy lamp
substitutes could have higher wattages
than their replacement. (Public Meeting
Transcript, No. 4.5 at pp. 118–119)
DOE recognizes that different lamp
consumers will be impacted differently
by a new standard depending on the
market segment to which they belong.
To model these different situations, the
LCC analysis is designed around
scenarios—the ‘‘lamp purchasing
events’’—where consumers have a need
to replace a lamp. The LCC spreadsheet
53 Event Type II represents a standards-induced
retrofit where lamps are substituted before the end
of their lifetime. DOE assumed that lamps lived to
half of their average lifetime when substituted
under this scenario.
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calculates the LCC impacts for each of
these scenarios separately. Looking at
the impacts on each scenario separately
allows one to view the results of many
subgroup populations in the LCC
analyses.
For the ANOPR, DOE decided not to
aggregate the results of the various event
scenarios together into a single LCC at
each CSL. To do so would have required
too many assumptions, such as: (1) The
relative occurrence of each event over
time, or (2) the market share of each
lamp in the base case and each
standards case. Another argument
against aggregating the LCC results
stems from the fact that the LCC
analysis only considers energy-saving
lamp or lamp-and-ballast designs. As
ACEEE commented, consumers may
elect options that save no energy or
perhaps consume more energy. (Public
Meeting Transcript, No. 4.5 at pp. 118–
119) Finally, aggregating the results of
the LCC analysis events blurs the lines
with the NIA analysis. 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-tohead comparison between lamp and
lamp-and-ballast designs under different
scenarios or ‘‘events.’’ Note further that
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
cost-effectiveness of CSLs. The
following presents partial results from
the LCC analysis. The LCC results are
presented according to the lamp
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purchasing events that culminate in
purchase of lamp-and-ballast designs.
These results are for a subset of all of
the possible events, although they
represent the most prevalent purchasing
events (events I(b) and IV have been
omitted in this notice but are presented
in the TSD). A range of the LCC savings
and PBP are given for each CSL. The
range reflects the results of multiple
systems (i.e., multiple lamp-ballast
pairings) which consumers could
purchase to meet a CSL. In addition,
DOE has chosen not to present detailed
PBP results by CSL in this ANOPR
because DOE believes that, given the
drawbacks to PBP discussed earlier, the
short lifetime of IRL and the systems
nature of GSFL, 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 of the TSD. DOE
is presenting the partial results here to
facilitate comment on DOE’s
methodology of its analyses, and on the
presentation of its results.
a. General Service Fluorescent Lamps
Table III.25 through Table III.27 lists
the result for one baseline lamp in each
of the three product classes DOE
analyzed (i.e., 4-foot medium bipin, 8foot single pin slimline and 8-foot
recessed double contact HO).
Throughout this section, the terms
‘‘positive LCC savings’’ and ‘‘negative
LCC savings’’ are used. 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
therefore, the consumer benefits. A
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consumer is adversely affected when a
standard results in ‘‘negative LCC
savings’’ (i.e., when the life cycle cost of
the standards-compliant lamp is higher
than the life cycle cost of the baseline
lamp). The range of values given
represents the multiple ways a
consumer can meet a certain CSL under
each lamp purchasing event. For
example, at CSL3, a consumer in need
of a lamp and ballast can either
purchase a high-efficacy T12 lamp on an
electronic ballast or a high-efficacy T8
lamp on an electronic ballast. While
both these choices are available to the
consumer, the selection of a T8 system
offers positive LCC savings.
Table III.25 presents the findings of an
LCC analysis on the 34W T12 4-foot
medium bipin GSFL baseline operating
in the commercial sector. Key inputs
consist of using AEO2007 reference case
electricity prices, an analysis period of
5.5 years, and medium-range lamp and
ballast prices. Note that any standard
level beyond CSL3 for this baseline
lamp would require a lamp and ballast
replacement, since no T12 lamp
currently meets the efficacy
requirements of CSL4. In addition,
because DOE is only presenting energysaving options in the LCC and because
there are no energy-saving (or reduced
wattage) lamp replacement options for
the 34W T12 lamp, Event I(a) which
would require only a lamp replacement
at all CSL levels. Negative LCC savings
would occur if consumers replace a
functioning 34W T12 lamp on an
electronic ballast with a high efficacy
T12 lamp. The LCC savings of Event III
are greater than those of Event II
because in the base case of Event III
consumers were faced with a ballast
replacement cost.
PBP results for Event II and III range
from zero to 37.7 years. The systems
nature of the lamp LCC makes the
payback period results difficult to
interpret. For example, LCC savings are
positive for many CSLs where the
payback period exceeds the lifetime of
the baseline lamp which is
approximately five years. When these
paybacks are compared to the lifetime of
a lamp-ballast system of 15 years
(spanning the life of one ballast and
three lamp replacements), the payback
periods appear much more acceptable.
Payback periods longer than the lifetime
of the system are associated with
negative LCC savings. The zero-year
payback (or instantaneous payback) also
results from the systems nature of these
LCC results. For example, zero payback
periods that appear for Event III are due
to the replacement of a more expensive
electronic T12 ballast with a less
expensive T8 electronic ballast. For
more information on PBP results refer to
Chapter 8 of the TSD.
is not shown. In general, one finds that
consumers who do switch from T12 to
T8 lamps experience positive LCC
savings at all CSLs.
The positive LCC results for Event II
are due to consumers that replace a
functioning 34W T12 lamp on a
magnetic ballast with a high efficacy T8
lamp on an electronic ballast. This
situation occurs at CSLs three through
five. Negative LCC savings (i.e.,
increases in life-cycle costs) are
generally due to replacement of a
functioning 34W T12 lamp on a
magnetic ballast with a higher-efficacy
T12 lamp on a T12 electronic ballast.
This situation occurs at CSLs one
through three. (Both the T12 and T8
electronic substitutions result in
negative LCC savings at CSL2) These
LCC results explain why consumers are
electing to replace their T12 magnetic
systems with T8 electronic systems
instead of choosing T12 electronic
ballast systems.
Event III represents consumers who
are already faced with replacing both a
lamp and a ballast. The baseline ballast
for this event is assumed to be an
electronic T12, since the ballast
standards from the 2000 Ballast Rule
and EPACT 2005 would be effective in
2010. Consumers prompted by this
event would experience positive LCC
savings if they purchase a high efficacy
4-foot T8 lamp on an electronic ballast
TABLE III.25.—LCC RESULTS FOR A 3-LAMP 4-FOOT MEDIUM BIPIN SYSTEM OPERATING IN THE COMMERCIAL SECTOR*
LCC savings
2006$
Rated lamp
efficacy
lm/W
Candidate standard level
CSL1
CSL2
CSL3
CSL4
CSL5
...............................................................................................................................
...............................................................................................................................
...............................................................................................................................
...............................................................................................................................
...............................................................................................................................
82.4
85.3
90.8
92.3
95.4
to
to
to
to
86.2
91.2
95.0
97.3
Event II: standardsinduced retrofit
(lamp & ballast replacement)
Event III: ballast
failure
(lamp & ballast
replacement)
¥18.00
¥23.36 to ¥6.31
¥23.66 to 1.60
5.01 to 6.26
4.88 to 16.96
¥2.02
¥9.05 to 8.01
¥9.34 to 15.92
19.33 to 20.58
19.19 to 31.28
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* The results displayed are for the 34W T12 baseline lamp with a 5.5 yr analysis period. Additional results are available in Chapter 8 of the
TSD.
Table III.26 presents the findings of an
LCC analysis on the 60W T12 8-foot
single pin slimline GSFL baseline lamp
operating in the commercial sector. Key
inputs consist of using AEO2007
reference case electricity prices, an
analysis period of 4.0 years and
medium-range lamp and ballast prices.
Note that any standard level beyond
CSL3 for this baseline lamp would
require a lamp-and-ballast replacement,
since no T12 lamp currently meets the
efficacy requirements of CSL3. In
general, consumers who do switch from
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a 60W T12 to a T8 lamp experience
positive LCC savings only if their ballast
has already failed.
Event I is not shown because there are
no energy-saving lamp replacement
options for a 60W T12 lamp. Event II
represents consumers who respond to
higher lamp standards by replacing a
functioning 60W T12 system with a new
lamp and ballast. For this event,
consumers experience increased LCC at
all CSLs. Event III represents consumers
who are already faced with replacing
both a lamp and a ballast. The baseline
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ballast for this event is assumed to be
an electronic T12, since the ballast
standards from the 2000 Ballast Rule
and EPACT 2005 would be effective in
2010. Consumers prompted by this
event would experience positive LCC
savings if they purchase a high-efficacy
8-foot single pin slimline T8 lamp on an
electronic ballast. Negative LCC savings
would occur because some consumers
who replace a functioning 60W T12
lamp on an electronic ballast with a
high-efficacy T12 lamp on an electronic
ballast.
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PBP results for Event II and III range
from 2.7 to 20.7 years. For more
information on PBP results refer to
Chapter 8 of the TSD.
TABLE III.26.—LCC RESULTS FOR A 2-LAMP 8-FOOT SINGLE PIN SLIMLINE SYSTEM OPERATING IN THE COMMERCIAL
SECTOR*
LCC savings 2006$
Rated lamp
efficacy
lm/W
Candidate standard level
CSL154 ...........................................................................................................................
CSL2 ...............................................................................................................................
CSL3 ...............................................................................................................................
CSL4 ...............................................................................................................................
CSL5 ...............................................................................................................................
Event II: standardsinduced retrofit
(lamp & ballast
replacement)
Event III: ballast
failure (lamp &
ballast
replacement)
87.6
92.6
94.8 to 97.5
98.2
101.5 to 101.8
N/A
¥24.78
¥24.31 to ¥23.55
¥16.42
¥15.68 to ¥13.73
N/A
¥3.04
¥2.56
5.33
6.06 to 8.02
*The results displayed are for the 60W T12 baseline lamp with a 6.0 yr analysis period. Additional results are available in Chapter 8 of the
TSD.
Table III.27 presents the findings of an
LCC analysis for a 95W T12 8-foot
recessed double contact GSFL baseline
lamp operating in the industrial sector.
Key inputs consist of using AEO2007
reference case electricity prices, an
analysis period of 2.3 years, and
medium-range lamp and ballast prices.
Note that any standard level beyond
CSL2 for this baseline lamp would
require a lamp and ballast replacement,
since no T12 lamp currently meets the
efficacy requirements of CSL3. In
general, DOE’s research indicates that
consumers who do switch from a 95W
T12 to a T8 lamp would experience
positive LCC savings only if their ballast
has already failed or if they are
renovating or constructing a new
building.
Event I is not shown because there are
no energy-saving lamp replacement
options for a 95W T12 lamp. The
positive LCC results for Event II occur
because some consumers replace a
functioning 95W T12 lamp on an
electronic ballast with a high-efficacy
T8 lamp on an electronic ballast.
Negative LCC results are due to
consumer replacement of a functioning
95W T12 lamp on a magnetic ballast
with a high-efficacy T12 lamp on an
electronic ballast. Events III and V
represent consumers who are already
faced with replacing both a lamp and a
ballast. Consumers, prompted by these
events, would experience positive LCC
savings if they purchase a high-efficacy
T8 lamp on an electronic ballast.
Consumers would experience higher
LCCs if they replace a functioning 95W
T12 lamp on an electronic ballast with
a high-efficacy T12 lamp on an
electronic ballast. Under this scenario,
the lowest LCC occurs at CSL4.
PBP results for Event II, III, and V
range from 3.2 to 64.8 years. For more
information on PBP results refer to
Chapter 8 of the TSD.
TABLE III.27.—LCC RESULTS FOR A 2-LAMP 8-FOOT RECESSED DOUBLE CONTACT HO SYSTEM OPERATING IN THE
INDUSTRIAL SECTOR*
LCC savings 2006$
Rated lamp
efficacy
lm/W
Candidate standard level
Event II: standardsinduced retrofit
(lamp & ballast
replacement)
CSL1 ...............................................................................................................................
CSL2 ...............................................................................................................................
CSL3 ...............................................................................................................................
N/A 55
85.5 to 86.1
87.6 to 88.9
N/A
¥36.86
¥47.10 to ¥46.48
CSL4 ...............................................................................................................................
CSL5 ...............................................................................................................................
91.9 to 93.0
95.3
¥24.12 to ¥21.19
¥20.53
Event III: ballast
failure and event
V: new
construction and
renovation (lamp
&
ballast
replacement)
N/A
¥3.43
¥13.67 to
¥13.05
9.32 to 12.25
12.9
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*The results displayed are for the 95W T12 baseline lamp with a 2.3-yr analysis period. Additional results are available in Chapter 8 of the
TSD.
Results for all GSFL events and
baselines are presented in Table 8.5.1 to
Table 8.5.16 of Chapter 8 in the TSD.
b. Incandescent Reflector Lamps
54 Because the 60W T12 baseline exceeds CSL1,
there are no energy saving design options at this
level. There are, however, energy saving design
options at CSL1 for the 75W T12 baseline.
55 Because the 95W T12 baseline is only slightly
below CSL1, there are no energy saving design
options at this level. There are, however, energy
Table III.28 provides the LCC results
for a 75W PAR38 IRL operating in the
commercial sector. These results are
based on the AEO2007 reference case
electricity prices, an analysis period of
0.9 years,56 and use of medium-range
saving design options at CSL1 for the 110W T12
baseline.
56 The service life of commercial IRL is shorter
than GSFL because the longest lived baseline IRL
Continued
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lamp prices. Note that the lowest LCC
(and highest LCC savings) occurs at
CSL3. PBP results for IRL range from 0.4
to 0.6 years. LCC and PBP results for all
IRL baseline lamps are available in
Chapter 8 in the TSD. More information
about the lamps that meet each CSL are
provided in Chapter 5 of the TSD.
TABLE III.28.—LCC RESULTS FOR A 75W PAR38 OPERATING IN THE COMMERCIAL SECTOR*
Rated lamp
efficacy
lm/W
Candidate standard level
CSL1 ........................................................................................................................................................................
CSL2 ........................................................................................................................................................................
CSL3 ........................................................................................................................................................................
15.9
17.5
19.1
LCC savings
2006$
2.71
3.92
5.89
*These results are for the 75W PAR38 baseline lamp. Additional results are available in Chapter 8 of the TSD.
mstockstill on PROD1PC66 with PROPOSALS2
In summary, DOE presents these
findings to facilitate public review of
the LCC and PBP analyses for this
rulemaking. DOE seeks information and
comments relevant to the assumptions,
methodology, and results for all of these
analyses. See Chapter 8 of the TSD for
additional detail on the LCC and PBP
analyses and results. For results of the
Monte-Carlo model and other
sensitivities refer to Appendix 8B of the
TSD.
H. Shipment Analysis
This section presents the shipment
analysis, which is an input into the
national impact analysis (NIA) (section
III.I) and manufacturer impact analysis
(section III.K). DOE will undertake
revisions to the NIA, conduct the final
manufacturer impact analysis (MIA),
and then report the findings from both
in the NOPR.
As indicated above and in the NIA
section below, DOE developed a basecase shipment forecast for each
analyzed lamp type to depict what
would happen to energy use, and to
consumer costs for purchase and
operation of lamps, in the absence of
new or revised energy conservation
standards. To evaluate the impacts of
such standards for these lamps, DOE
compares the estimated base-case
projection against forecasted estimates
of what would happen if DOE were to
promulgate standards for GSFL and IRL.
One common element in the base-case
and standards-case forecasts is product
shipments. In determining the base case,
DOE considered historical shipments,
the mix of efficacies sold in the absence
of any new standards, and how that mix
might change over time.
DOE developed separate shipment
models for GSFL and IRL. The GSFL
shipment model projects lumen growth
by forecasting lumen demand serviced
by GSFL lamp type in the commercial
and industrial sectors. In accordance
lamp is 3,000 hrs while the baseline lamps for GSFL
vary between 12,000 and 20,000 hours. In addition,
operating hours for commercial IRL are comparable
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with historical shipment data, annual
shipments are forecasted for 8-foot
recessed double contact HO lamps in
the industrial sector, and 4-foot medium
bipin and 8-foot single pin slimline
lamps in the commercial sector. Due to
their relatively small shipment-based
market share (approximately four
percent) of the total GSFL market, DOE
decided—for the ANOPR only—not to
forecast shipments of or analyze the
national impacts of standards on 2-foot
U-shaped lamps. However, for the
NOPR, DOE does intend to scale the
NIA results from other product classes
that were analyzed to the 2-foot Ushaped lamp product classes, to develop
estimates of the NES and NPV for this
lamp type. DOE may base the
extrapolation of NIA results on relative
market shares, average incremental
prices for each lamp design, or average
changes in energy consumption between
lamp-and-ballast designs. DOE invites
comment on which of these or other
scaling relationships it should use for
the NOPR.
The shipment model for IRL is based
on the growth in the number of sockets
using these light sources in the
commercial and residential sectors.
Based on manufacturer interviews, DOE
forecasted shipments of IRL in both the
commercial and residential sectors. DOE
invites comment on the various sectors
used to establish shipment forecast
estimates for GSFL and IRL.
DOE followed a consistent four-step
process to forecast shipments for GSFL
and IRL. First, DOE used NEMA’s
historical shipment data from 2001 to
2005 to estimate total historical (NEMA
member and non-NEMA members)
shipments of each analyzed lamp type
in the sectors described above. Second,
using these historical shipments, DOE
projected shipments to 2011. Then,
based on average service lifetimes, DOE
estimated a stock of lamps in 2011 for
each lamp type. Third, DOE forecasted
lamp (and ballast for GSFL) shipments
from 2012 to 2042 (the analysis period
for the NIA) by modeling various events,
such as lamp replacement or new
construction. Because these shipments
are dependent on lamp and lampsystem properties (e.g., lifetime and
lumen output), as a fourth step, DOE
developed base-case and standards-case
market-share matrices. These marketshare matrices determine the forecasted
technology mixes in the lamp stock and
shipments. Each of these analytical
steps in the shipment analysis is
discussed in further detail below.
to the operating hours for commercial and
industrial GSFL (3,450 for commercial IRL and
3,435 for commercial GSFL or 4,795 for industrial
GSFL).
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1. Historical Shipments
GE and NEMA both commented that
historical shipment data should be used
as an input to the fluorescent and
incandescent lamp shipment models.
(Public Meeting Transcript, No. 4.5 at p.
198; NEMA, No. 12 at p. 2) NEMA
provided shipment data on GSFL and
IRL spanning 2001 to 2005. Recognizing
that these shipment figures cover only
NEMA members, based on manufacturer
interviews DOE increased these
estimates slightly to account for the
volume of fluorescent and incandescent
lamps that are imported and/or
manufactured by non-NEMA lamp
companies. A list of lighting-related
NEMA member companies and several
lists including various lighting-related
non-NEMA member companies can be
found in Chapter 3 of the TSD.
Because certain ER and BR shaped
IRL (BR 30 and BR40 65 Watt) are
statutorily exempted from energy
conservation standards, DOE used
manufacturer product catalogs to
estimate the market share of those
exempted products. As research
indicated that these exempted products
constitute approximately 60 percent of
all incandescent (non-halogen) IRL
shipments, DOE accounted for this
when using the NEMA historical
shipments data. In addition, to model
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IRL operated in the commercial sector
separately from those operated in the
residential sector, DOE used a reflector
lamp study conducted by the New York
State Energy Research and Development
Authority 57 with additional shipment
data submitted by NEMA (NEMA, No.
17 at p. 2) 58 to estimate the percentage
of incandescent and halogen IRL
shipments by sector.
In addition, because GSFL of different
correlated color temperatures (CCTs)
were not segregated in the NEMA
historical shipment data, DOE decided
to analyze and forecast shipments of
each lamp type, aggregating across the
lamps of low (less than or equal to
4,500K) and high (greater than 4,500K)
CCT. Similarly, DOE forecasts IRL
shipments by aggregating across the
standard-spectrum and modifiedspectrum lamps. In both of these cases
of aggregation, DOE used a
representative product class to evaluate
lamp designs and believes that the
national impacts will be similar for
those product classes not directly
analyzed. Specifically, for GSFL, DOE
used lamp designs with CCT less than
or equal to 4,500K to represent both
low-CCT and high-CCT lamps. For IRL,
DOE used standard-spectrum lamp
designs to represent the markets of both
standard-spectrum and modifiedspectrum reflector lamps. In addition,
by aggregating the previously-discussed
product classes, DOE assumes that there
will be no significant migration of
shipments or stock between lamps of
different CCTs or spectrums. DOE
invites comment on this aggregation of
product classes in the shipment analysis
and NIA. Details regarding scaling and
usage of NEMA’s historical shipments
can be found in Chapter 9 of the TSD.
mstockstill on PROD1PC66 with PROPOSALS2
2. Shipment Projections to 2011 and
Calculations of Stock of Lamps in 2011
DOE estimated shipments to 2011 for
GSFL and IRL by linearly extrapolating
historical shipment data (from 2001 to
2005) of each lamp type. In addition,
DOE also accounts for efficacy standards
(effective in 2008) for small diameter
and ER and BR shaped lamps prescribed
by EISA 2007. DOE expects that the
57 New York State Energy Research and
Development Authority, Incandescent Reflector
Lamps Study of Proposed Energy Efficiency
Standards for New York State (2006). (Last accessed
October 7, 2006 at: https://www.nyserda.org/
publications/Report%2006-07-Complete%20reportweb.pdf.) The October 7, 2006 material from this
Web site is available in Docket #EE–2006–STD–
0131.
58 This written comment, document number 17,
was submitted in response to the Energy
Conservation Program for Commercial and
Industrial Equipment: High-Intensity Discharge
(HID) Lamps and is available in Docket #EE–DET–
03–001.
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result of these standards is that by 2008,
all IRL shipments covered in this
rulemaking will be of products using
halogen technology. Because halogen
lamps generally have longer lifetimes
than their incandescent counterparts,
and are therefore replaced (and shipped)
less often, DOE has applied a reduction
to its projection of IRL shipments after
2007. DOE invites comment on the
shipment projections to 2011 for GSFL
and IRL.
The stock of lamps in 2011 was
estimated by summing annual
shipments backward from 2011. For
each lamp type, DOE summed
shipments for the number of years that
corresponds to the average lifetime of
that lamp type. For GSFL, this initial
lamp stock is converted into an initial
lamp-and-ballast system stock. DOE
extrapolated the ballast age profile of
each lamp system type by considering
historical shipments from census data
for electronic and magnetic ballasts and
historical growth in lumen demand.
Since DOE determined that the 2011
lamp stock of 8-foot T8 recessed double
contact HO are a small minority of the
total GSFL stock, DOE disregarded this
initial lamp stock in its shipment
forecast. However, as discussed later,
DOE did capture future shipments of
these lamps as they replace 8-foot T12
recessed double contact HO systems.
DOE invites comment on the
methodology and data sources used to
estimate initial lamp stocks in the year
2011, in particular its treatment on 8foot T8 recessed double contact HO
lamps.
3. Base-Case and Standards-Case
Shipment Forecasts to 2042
The shipment models DOE developed
for the ANOPR each consider specific
market segments in developing their
estimate of annual shipments. For all
lamp types, DOE accounts for two lamp
purchase events (corresponding to those
discussed in Section III.G): (1) Lamp
replacement following a lamp failure
(Event I); and (2) new construction
(Event V). In addition, for the GSFL
shipment models, DOE models two
additional lamp purchase events—lampand-ballast systems installed following a
ballast failure (Event III), and lamp-andballast systems installed due to lamp
system retrofit (an aggregation of Events
II and IV).
ACEEE and the Joint Comment
recommended that DOE should weigh
the analytical results for GSFL by
market segment. (Public Meeting
Transcript, No. 4.5 at pp. 118–119; Joint
Comment, No. 9 at p. 5) In response,
DOE implicitly weighs the occurrence of
new construction, retrofit, and
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replacement lamp sales based on stock
turnover in the shipment model. DOE’s
determination of shipments due to new
construction assumes a 1.6 percent per
year lumen growth rate. DOE estimated
a 1.6 percent per year lumen growth rate
based on the latest CBECS data on
growth of building floor space.
Shipments due to ballast replacement
are based on a ballast inventory model
with a 14-year ballast lifetime in the
commercial sector and a 10-year ballast
lifetime in the industrial sector. To
account for consumer reactions in
response to higher total installed costs
of certain systems, DOE assumes that
the retrofit rates (or rates of early ballast
retirement) of these systems increase as
the CSLs increase. Finally, DOE
calculated the market share of lamp
replacements in the GSFL shipment
model as a function of the average lamp
lifetime of the lamp designs chosen. For
more information, see Chapter 9 of the
TSD.
GE and NEMA both recommended
that DOE should develop its lamp
shipment forecast based on lamp
shipments, rather than a ballast
inventory model. (Public Meeting
Transcript, No. 4.5 at pp. 193–194;
NEMA, No. 8 at p. 3) In response, DOE
did use the lamp shipment data
provided by NEMA and has calibrated
its shipment models using historical
shipment data. However, for the
fluorescent lamp shipment analysis (and
NIA), based on this historical lamp
shipment data and 2002 and 2005 U.S.
Census Bureau data, DOE developed a
ballast inventory model for several
reasons. For example, DOE needs to
capture and track the anticipated
decline in BF that would occur in the
ballast inventory (or stock) in standards
cases as discussed earlier. This decline
in BF is critical to tracking the NIA
calculations and results. Also, by
modeling the ballast stock and its
turnover, DOE was able to model the
occurrence of lamp-and-ballast purchase
events, as described earlier.
In their comments on the Framework
Document, GE and the Joint Commenter
emphasized the importance of
accounting for wider fixture spacing of
higher-lumen-output systems in the new
construction/remodeling market. (Joint
Comment, No. 9 at p. 5; Public Meeting
Transcript, No. 4.5 at pp. 119–120) In
response, DOE notes that the fluorescent
shipment model’s base-case and
standards-case forecasts account for this
effect by allowing installed systems to
have a range of light outputs. DOE then
normalizes the total lumen output due
to new construction by decreasing or
increasing the number of shipments
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based on the average lumen output per
system.
For IRL, the shipment forecasts are
based on a stock turnover (i.e., lamp
replacements upon lamp failure) and
growth in the number of sockets in use
(through new construction). DOE
assumed a 1.6 percent growth rate in
lamp sockets per year for the
commercial sector and 1.3 percent
growth rate per year for the residential
sector. DOE based these estimates on the
latest CBECS and RECS forecasts of
square footage growth in these
respective sectors. The rate of stock
turnover from one lamp technology to
another and the total number of
shipments depend upon operating hours
and the lifetimes of shipped lamps.
DOE also received comments from
ACEEE and NEMA remarking that DOE
should be aware of any clear trends in
historical shipment data and that these
trends should be reflected in the basecase shipment model. (Public Meeting
Transcript, No. 4.5 at p. 194; NEMA, No.
12 at p. 2) DOE took these comments
into account when developing its
analytical approach, using the data on
market trends provided by NEMA as
well as manufacturer and expert
interviews to establish base-case trends.
For example, for GSFL, DOE mimicked
historical trends and modeled a shift
from magnetic to electronic ballasts in
both the 4-foot medium bipin and 8-foot
single pin slimline markets. For the 8foot T12 recessed double contact HO
lamp, DOE modeled it as having no new
construction, because historical
shipments have indicated that its
market is relatively flat. In addition,
DOE incorporated historical market
trends in the GSFL model by controlling
the types of systems shipped to account
for new construction and retrofits. DOE
invites further comments on other
trends that should be modeled in its
shipment forecasts, particularly for
GSFL.
For IRL, a significant source of
uncertainty in the base-case lamp
forecasts involves the potential for
rapidly-emerging new lighting
technologies to enter the market. For
example, the residential market is
already being transformed by the rapid
increase in reflector CFL sales. CFL can
be three to four times more efficient and
last several times longer than the
incandescent lamps they are replacing.
Assumptions made in the base-case
lamp forecast about any change in
market share for CFL greatly impact the
energy savings and NPV benefits that
could result from standards. Yet in
comparison to solid-state lighting (SSL)
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sources,59 CFL are a ‘‘mature’’
technology, with relatively predictable
price, efficacy, and lifetime attributes.
Technology forecasts about the potential
attributes of SSL sources suggest that
they may achieve efficacies twice that of
CFL and may last up to ten times longer.
Clearly, if SSL technology achieved
such promise, it would radically impact
the benefits calculations from potential
standards. However, in order to
calculate the energy savings and NPV
benefits, DOE would need to accurately
forecast the anticipated price and
performance points of an emerging
technology such as SSL, which would
be extremely difficult and speculative.
Therefore, in this rulemaking, DOE
plans to account for the market impact
of these emerging technologies in the
NIA by deducting the anticipated
emerging technology market share from
the installed base. DOE would estimate
the market shares of these technologies
in the future (absent standards) by
deducting that market share from the
base case of impacted customers. This
methodology would effectively reduce
the size of the market impacted by
energy conservation standards, without
requiring DOE to prepare estimates of
the price and efficacy of those emerging
technologies for the NIA model. Thus,
DOE could incorporate the impact of
emerging technologies in the base-case
and standards-case, without having to
prepare uncertain forecasts for those
emerging technologies. DOE believes
that reducing the number of affected
consumers is the most appropriate
approach for this rulemaking because:
(1) the efficacies of the emerging
technologies are projected to be much
higher than those that can be achieved
by incandescent-based lamps; and (2)
the emerging technology lamps are not
yet subject to any DOE regulation, and,
therefore, consumers would be
migrating to non-covered, substitute
lamps.
For the ANOPR, DOE is estimating
that the market penetration of these
emerging technologies (e.g., SSL,
Ceramic Metal Halide, CFL) will be 50%
of the IRL sockets in the installed base
by the year 2042. DOE requests
comment on this methodology used in
the ANOPR for incorporating emerging
technologies in the base-case forecasts.
In addition, DOE seeks input on
reasonable market-share estimates for
GSFL and IRL in order to properly
bound the range of potential energy
savings and NPV that would result from
standards.
59 ‘‘SSL source’’ refer to a lighting technology
using light-emitting diodes (LEDs).
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4. Market-Share Matrices
As discussed in the engineering
analysis (Section III.C) and the LCC
analysis (section III.G), consumers have
available to them a variety of choices in
terms of lamps and lamp systems. When
choosing lighting systems, consumers
often make their choice after
considering lamp attributes such as
lifetime, efficacy, price, lumen output,
rated wattage, and total system power.
As discussed earlier, the shipments for
GSFL and IRL depend on input
assumptions, including lamp lifetime
and system lumen output. In addition,
other lamp or lamp-system properties
such as price and energy consumption
are key inputs to the NES and NPV
calculations. Therefore, within each
product class, DOE believes it necessary
to directly account for the mix of
technologies which consumers select in
the base case and standards case. In
order to account for the range of
possible consumer choices, DOE
developed and populated technology
market-share matrices. These marketshare matrices allocate percentage
market shares to each of the lamp
technologies for the base case and
standards case, either by proportioning
lamp shipments or lamp stocks. As
discussed in the NIA (Section III.I), the
base-case and standards-case efficacy
forecasts are also dependent on the
market-share matrices.
a. General Service Fluorescent Lamps
The GSFL shipment model
incorporates several separate marketshare matrices to characterize shipments
of lamps and lamp-and-ballast systems
at different times during the analysis
period. For each analyzed system type
(e.g., 4-foot T8 medium bipin), DOE
defines market-share matrices for the
ballasts installed before 2012 versus
new ballasts installed in 2012 and later.
This enables the GSFL shipment model
to capture a migration to different lampand-ballast designs over time in both the
base and standards cases.
At the Public Meeting, PG&E
commented that, by the effective date of
the standard, it is expected that
commercial fluorescent lighting fixtures
will be considerably improved. (Public
Meeting Transcript, No. 4.5 at p. 113) In
addition, NWPCC generally commented
that typical BFs may change between
the current stock and the stock in 2012.
(Public Meeting Transcript, No. 4.5 at p.
175) In response, DOE recognizes that
fluorescent lighting systems will likely
improve and that the ballast factors
(BFs) may change over time. DOE
populated the 2012 base-case marketshare matrix (including BFs) based on
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discussions with industry experts,
manufacturer interviews, and a review
of available products. DOE can alter the
inputs into the base-case market-share
matrix (the technology mix in 2012) to
reflect any level of improvement in
lighting fixtures by 2012. In addition,
the base-case GSFL shipment forecast
has the ability to model improvement in
lighting systems and shifts in BFs after
2012. Furthermore, if the public were to
present alternative forecast scenarios to
those considered for the ANOPR, the
matrices are designed such that these
alternative scenarios could be modeled
for the NOPR.
In addition, for the standards-case
market-share matrices, DOE
implemented two shipment scenarios
for fluorescent lamps: (1) ‘‘roll-up,’’ and
(2) ‘‘shift.’’ The ‘‘roll-up’’ scenario
represents the standards case assuming
all product efficacies in the base case
which do not meet the standard would
‘‘roll-up’’ to meet the new standard
level. Those that were above the
standard level are considered unaffected
and continue to purchase the same basecase lamp or lamp system. The ‘‘rollup’’ scenario characterizes consumers
primarily driven by the first-cost of the
lamp, and they are restricted to
replacing their base-case lamp with an
equal wattage lamp when possible. The
‘‘roll-up’’ scenario, therefore, represents
a lower bound of energy-savings
scenario.
The ‘‘shift’’ scenario models the
standards case assuming all product
efficacies are affected by the standard
(whether or not their base-case efficacy
meets the standard). This scenario, in
which consumers are driven by both
lamp cost and energy savings, results in
an upper bound energy-savings
scenario. A detailed description of the
two fluorescent standards-case scenarios
can be found in Chapter 9 of the TSD.
DOE invites comment on the populated
GSFL market-share matrices in the basecase and both standards-case scenarios.
To illustrate the above approach,
Table III.29 presents an example of a
market-share matrix for the GSFL
shipment model. This matrix
characterizes the technology mix of new
4-foot T8 medium bipin lamp-andballast systems shipped in 2012 and
2042 in the base case and at CSL 3
under the shift scenario. Shipments of
new systems in the intermediate years
can be characterized by a linear
progression from the 2012 technology
mix to the 2042 technology mix. A
separate market-share matrix exists for
4-foot T8 medium bipin lamp purchases
on pre-existing ballasts. For this new
system market-share matrix, the lampand-ballast designs were generated by
pairing each lamp with the three
ballasts with the most common BFs
(0.88, 0.78, and 0.75) in the 4-foot T8
medium bipin market. This produces
both energy-saving and non-energysaving options. In the standards-case
scenario shown, consumers then shift to
reduced-wattage lamps and/or lower
BFs.
TABLE III.29.—FOUR-FOOT T8 MEDIUM BIPIN MARKET-SHARE MATRIX UNDER THE SHIFT SCENARIO
Mix of New Lamp-and-Ballast Systems Purchased
Base case
CSL
Lamp-and-ballast design
2012
(percent)
CSL3
2042
(percent)
2012
(percent)
2042
(percent)
Electronic Ballast Factor
0.88
2
3
4
4
5
5
5
................
................
................
................
................
................
................
32.5 W, 86.2 lm/W ....................................................................................
32.5 W, 90.8 lm/W ....................................................................................
32.5 W, 92.3 lm/W ....................................................................................
30 W, 92.3 lm/W .......................................................................................
32.5 W, 95.4 lm/W ....................................................................................
28 W, 97.3 lm/W .......................................................................................
25 W, 96 lm/W ..........................................................................................
43
29
11
0
7
0
0
8
10
14
3
12
3
4
..................
0
0
11
7
0
0
..................
0
0
14
12
3
0
2
3
4
4
5
5
5
................
................
................
................
................
................
................
32.5 W, 86.2 lm/W ....................................................................................
32.5 W, 90.8 lm/W ....................................................................................
32.5 W, 92.3 lm/W ....................................................................................
30 W, 92.3 lm/W .......................................................................................
32.5 W, 95.4 lm/W ....................................................................................
28 W, 97.3 lm/W .......................................................................................
25 W, 96 lm/W ..........................................................................................
0
0
0
2
0
3
0
4
0
6
6
6
7
4
..................
43
29
0
0
0
3
..................
8
10
0
0
4
7
2
3
4
4
5
5
5
................
................
................
................
................
................
................
32.5 W, 86.2 lm/W ....................................................................................
32.5 W, 90.8 lm/W ....................................................................................
32.5 W, 92.3 lm/W ....................................................................................
30 W, 92.3 lm/W .......................................................................................
32.5 W, 95.4 lm/W ....................................................................................
28 W, 97.3 lm/W .......................................................................................
25 W, 96 lm/W ..........................................................................................
0
0
0
2
0
3
0
0
0
0
6
0
7
0
..................
0
0
0
0
7
0
..................
10
9
0
0
19
4
Total ...
...................................................................................................................
100
100
100
100
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0.75
b. Incandescent Reflector Lamps
Similar to the GSFL model, the IRL
shipment model use market-share
matrices to project shipments. The IRL
commercial and residential shipment
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models separately designate stock
technology mixes in the years 2012 and
2042. These market-share matrices also
present the available lamp designs in
the standards case for which the stock
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technology mix is also characterized in
one intermediate year. DOE developed
percentage inputs for the IRL marketshare matrices based on an examination
of manufacturer product catalogs,
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historical shipment information, and
interviews with manufacturers.
Table III.30 presents an example of a
market-share matrix for the commercial
IRL shipment model. This matrix
characterizes the stock technology mix
of IRL in the years 2011 and 2042 in the
base case, and in the years 2013 and
2042 at CSL 2. DOE chooses to
characterize the stock in 2013 because
DOE projects that by then the majority
of the base-case commercial IRL stock
would have turned over to be standards
compliant. In the base case, DOE
predicts a decline in halogen technology
lamps and a rise in more-efficient HIR
lamps. At CSL 2, all IRL must meet an
HIR standard.
TABLE III.30.—MARKET-SHARE MATRIX FOR COMMERCIAL IRL SOCKETS
Percentage
stock in 2011
(Base case
input only)
Percentage of
stock in 2013
(Standards
case input
only)
Percentage of
stock in 2042
Candidate standard level
Lamp design
Base Case ..............................
90 W, 14.6 lm/W, 2500 hrs, Halogen ....................................
75 W, 14.0 lm/W, 2500 hrs, Halogen ....................................
50 W, 11.6 lm/W, 3000 hrs, Halogen ....................................
70 W, 18.0 lm/W, 3000 hrs, HIR ............................................
60 W, 17.5 lm/W, 3000 hrs, HIR ............................................
41.3 W, 15.0 m/W, 3000 hrs, HIR .........................................
33
26
22
8
6
5
........................
........................
........................
........................
........................
........................
21
16
14
21
16
14
Total ................................................................................
100
........................
100
70 W, 18.0 lm/W, 3000 hrs, HIR ............................................
60 W, 17.5 lm/W, 3000 hrs, HIR ............................................
41.3 W, 15.0 m/W, 3000 hrs, HIR .........................................
........................
........................
........................
41
32
27
41
32
27
Total ................................................................................
........................
100
100
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CSL2 .......................................
In addition to modeling one main
scenario for IRL shipments, in order to
capture the range of NES and NPV
results possible, DOE created two
sensitivity scenarios in the IRL
shipments analysis. In one sensitivity
scenario (termed ‘‘65 Watt BR lamp
substitution’’) in the standards case,
DOE models a migration away from
covered IRL toward exempted 65 Watt
BR 30 and 65 Watt BR 40 lamps. As
discussed earlier, EISA 2007 extended
energy conservation standards coverage
to certain ER and BR while exempting
others. DOE believes that as the efficacy
standards for IRL increase, some
consumers who would normally
purchase a covered IRL may instead
choose to purchase a higher-wattage,
lower-first-cost, exempted 65 Watt BR
lamp. Although these exempted lamps
do not fall under the scope of this
rulemaking, DOE has included a
sensitivity scenario incorporating this
potential outcome, because it affects
NES and NPV results. Further
discussion of this 65 Watt BR lamp
substitution sensitivity scenario can be
found in Chapter 9 and Appendix 9A of
the TSD.
Regarding the second standards-case
sensitivity scenario modeled, EEI
commented that consumers may choose
to purchase a higher-wattage lamp
rather than a reduced-wattage lamp.
(EEI, No. 7 at p. 1) If this were to
happen, consumers would operate
lamps in the standards case that gave
them more lumens than they are
modeled to be using in the base case. To
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represent this scenario, DOE created a
‘‘10-percent lumen increase’’ sensitivity
scenario, which assumes that the
residential IRL market, on average,
would produce ten percent more
lumens under standards scenarios. To
achieve this increase in lumens, DOE
models a portion of IRL purchases at
reduced wattages and others at constant
or higher wattages. Appendix 9A of the
TSD presents both the market-share
matrix and results associated with this
scenario.
Chapter 9 and Appendix 9A of the
TSD presents all of the market-share
matrices used in the shipment models
for GSFL and IRL. DOE requests specific
comment on the detailed matrices
which represent the underlying input
assumptions for each of the shipment
scenarios and lamp types.
5. Shipment Forecast Results
Table III.31 and Table III.32 present
the results of the base-case shipment
forecasts for GSFL and IRL, respectively.
In those tables, values provided for the
years 2001 to 2005 present historical
shipment data, whereas the 2006 to
2011 shipments are linear
extrapolations from the historical
shipments. The shipments estimated for
2012 to 2042 are the projected unit
shipments generated by the shipment
models. This section includes a general
discussion of the market dynamics
impacting shipments in the standards
cases. Chapter 9 of the TSD provides the
detailed numerical output of the
standards-case shipment forecasts.
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For GSFL, in accordance with
historical shipment data, shipments of
4-foot T12 medium bipin and 8-foot T12
single pin slimline lamps in the base
case are expected to decline as the
magnetic ballasts on which those lamps
are installed are no longer sold. These
retired 4-foot T12 medium bipin and 8foot T12 single pin slimline systems are
expected to be replaced with 4-foot T8
medium bipin lamp-and-ballast
systems, respectively. In addition, DOE
forecasts that 90 percent of 8-foot T12
single pin slimline systems will be
replaced with 4-foot T8 medium bipin
lamp systems, and 10 percent will be
replaced with 8-foot T8 single pin
slimline systems. This effect, along with
the 4-foot T8 systems purchased for new
construction, account for the expected
increase in 4-foot T8 and 8-foot T8
shipments. The base-case shipment
forecasts of 8-foot T12 recessed double
contact HO are depicted as constant,
similar to the historical shipments.
The standards-case forecasts
experience similar trends, though at
modified rates. At CSL1, CSL2, and
CSL3, the early retrofit rates of 4-foot
T12 medium bipin and 8-foot T12 single
pin slimline systems are expected to
increase, thereby accelerating the
reduction in those shipments while
increasing shipments of 4-foot T8
medium bipin and 8-foot T8 single pin
slimline shipments. Because voluntary
retrofits are not incorporated in the 8foot T12 recessed double contact HO
model, the standards-case shipment
forecasts of these lamps at CSL1, CSL2,
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and CSL3 are similar to the base-case
forecast. In addition, because at CSL 4
and CSL 5, 4-foot T12 medium bipin, 8-
foot T12 single pin slimline, and 8-foot
T12 recessed double contact HO lamps
are no longer standards-compliant, these
systems are automatically retrofitted
upon lamp failure.
TABLE III.31.—GSFL SHIPMENTS IN THE BASE CASE
[Millions]
Year
4-foot T12
medium
bipin
2001 .........................................................................................................
2003 .........................................................................................................
2005 .........................................................................................................
2007 .........................................................................................................
2009 .........................................................................................................
2012 .........................................................................................................
2015 .........................................................................................................
2020 .........................................................................................................
2025 .........................................................................................................
2030 .........................................................................................................
2035 .........................................................................................................
2040 .........................................................................................................
2042 .........................................................................................................
Cumulative (2012–2042) ..........................................................................
236
202
181
151
122
111
71
22
....................
....................
....................
....................
....................
556
The forecasted shipments beyond the
year 2011 of covered IRL (exempted BR
and ER lamps are not included) are
shown in Table III.32. As demonstrated
below, the shipments shown decrease
over the analysis period. There are two
reasons why DOE projects shipments to
decrease: (1) Increased penetration of
CFL and other long-lived emerging
technologies; and (2) historical growth
in IRL stock (approximately 8 to 10
percent annually) which is significantly
higher than the historical growth rate in
4-foot T8
medium
bipin
182
191
240
262
292
425
479
584
657
705
775
874
889
20,812
building floor space (i.e., 1.6 percent
annually in the commercial sector and
1.3 percent annually in the residential
sector). Given this inconsistency in
growth rates, DOE believes this high
historical growth rate in IRL stock is
unsustainable in the long term, so DOE
has tentatively decided to instead base
IRL socket growth after 2011 on the
historical growth in building floor
space. This decrease in stock growth
contributes to the expected decline in
IRL shipments.
8-foot T12
single pin
slimline
8-foot T8
single pin
slimline
48
41
37
32
26
17
10
3
....................
....................
....................
....................
....................
78
5
6
6
7
7
9
9
10
10
10
10
10
10
305
8-foot T12
recessed
double contact HO
27
27
28
27
27
31
31
31
31
31
31
31
31
971
In the standards case, shipments of
IRL in both the commercial and
residential sectors are generally
expected to decrease relative to the base
case, as longer-lived HIR and improved
HIR lamps are incorporated into the
installed stock. In addition, for the 65
Watt BR lamp substitution scenario,
shipments of covered IRL decrease
relative to the base case due to the
migration to exempted 65 Watt BR
lamps.
TABLE III.32.—IRL SHIPMENTS IN THE BASE CASE
[Millions]
Year
Commercial
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2001 .........................................................................................................................................................................
2003 .........................................................................................................................................................................
2005 .........................................................................................................................................................................
2007 .........................................................................................................................................................................
2009 .........................................................................................................................................................................
2012 .........................................................................................................................................................................
2015 .........................................................................................................................................................................
2020 .........................................................................................................................................................................
2025 .........................................................................................................................................................................
2030 .........................................................................................................................................................................
2035 .........................................................................................................................................................................
2040 .........................................................................................................................................................................
2042 .........................................................................................................................................................................
Cumulative (2012–2042) .........................................................................................................................................
Additional detail on the shipments
analyses can be found in Chapter 9 of
the TSD.
I. National Impact Analysis
The national impact analysis (NIA)
assesses cumulative national energy
savings (NES) and the cumulative
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national economic impacts of candidate
standards levels. The analysis measures
economic impacts using the net present
value (NPV) metric, which represents
the net present value (i.e., future
amounts discounted to the present) of
total customer costs and savings
expected to result from new standards at
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67
71
83
89
92
98
98
96
94
90
86
80
77
2,814
Residential
66
70
85
93
85
99
98
96
93
88
83
76
74
2,770
specific efficacy levels. For a given CSL,
DOE calculated the NPV, as well as the
NES, as the difference between a base
case and the standards-case forecasts.
Detailed information on the national
impacts analysis can be found in
Chapter 10 of the TSD.
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DOE determined national annual
energy consumption as the product of
the annual energy consumption per unit
lamp system and the number of total
units in the installed stock. The per-unit
annual energy consumption is a
function of lamp efficacy and lamp
wattage (and BF in the case of the
GSFL). TSD Chapter 6, Energy-Use
Characterization, describes how the perunit energy consumption varies as a
function of efficacy for each of the
considered lamps. Cumulative energy
savings are the sum of the annual NES
determined over a specified time period.
DOE calculated net economic savings
each year as the difference between total
operating cost savings and increases in
total installed costs. Cumulative
economic savings are the sum of the
annual NPVs determined over a
specified time period.
1. Approach
In the standards case, moreefficacious products gradually replace
less-efficacious products over time. This
affects calculations of both the NES and
NPV, which are both a function of the
total number of units in use and their
efficacies, and thus depend on annual
shipments and the lifetime of a product.
Both calculations start by first
estimating the installed lamp stock. As
discussed in section III.H (Shipments
Analysis), new lamps (or, for GSFL, new
lamp-and-ballast systems) shipped over
time are specified by market-share
matrices. These shipments are tracked
through the analysis period to establish
the installed stock of lamps.
In the standards case, given that most
consumers are likely to install lamp
systems with energy consumption less
than or equal to their base-case systems,
the energy consumption per unit of
capacity used by the products in service
gradually decreases in the standards
case relative to the base case. To
estimate the resulting national energy
savings at each CSL, DOE followed a
four-step process. First, DOE calculated
the national site-energy 60 consumption
for GSFL and IRL for each year,
beginning with the expected effective
date of the standards (2012) for the basecase forecast and each standards-case
forecast. Second, DOE determined the
annual site-energy savings, consisting of
the difference in site-energy
consumption between the base case and
the standards case. DOE also estimated
and reported additional heating,
ventilating, and air conditioning
(HVAC) interaction savings associated
with increased lamp efficacy in the
commercial sector. Third, DOE
converted the annual site-energy savings
into the annual amount of energy saved
at the source of electricity generation
(i.e., primary energy), using a site-tosource conversion factor that varies by
year (calculated from AEO 2007
projections). Finally, DOE summed the
annual source-energy savings from 2012
to 2042 to calculate the total NES for
that period.
To estimate NPV, DOE calculated the
net impact each year as the difference
between total operating cost savings (or
the electricity cost savings) and
increases in total installed costs (which
consist of manufacturer selling price,
sales taxes, and installation cost). DOE
calculated the national NPV at each CSL
using a three-step process. First, DOE
determined the total product costs
under the standards case and the base
case from the total installed cost
(including product prices, installation,
and replacement costs as discussed in
section III.G.2.a) and shipments of
lamps (or lamp-and-ballast systems).
Second, DOE determined the total
operating costs in the base case and
standards case from electricity prices
and the stock of lamps and lamp
systems. Third, DOE determined the
difference between the net operating
cost savings and the net product cost
increase to get the net savings (or
expense) for each year. DOE then
discounted the annual net savings (or
expenses) to 2007 for lamps bought
during the analysis period (2012 to
2042) and summed the discounted
values to provide the NPV of a CSL. An
NPV greater than zero shows net savings
(i.e., the CSL would reduce customer
expenditures relative to the base case in
present-value terms). An NPV that is
less than zero indicates that the CSL
would result in a net increase in
customer expenditures in present-value
terms.
2. Base-Case and Standards-Case
Forecasted Efficacies
A key aspect of the estimates of NES
and NPV is the proportion of future
lamp shipments meeting different
efficacies for the base case (without new
standards) and each of the standards
cases (with new standards). Because key
inputs to the calculation of the NES and
NPV are dependent on the estimate of
the efficacies shipped, it is important to
know the projected efficacy-distribution
of lamp shipments. However, with
regard to the calculation of the NES, it
is also important to note that the total
energy savings per unit is not solely
dependent on the lamp efficacy, but also
on the lamp wattage (and BF for
fluorescent lamps). Because most
consumers select lamp wattage when
purchasing lamps, per-unit energy
consumption for a particular standardscase purchase is not necessarily less
than per-unit energy consumption for
the corresponding base-case purchase.
For example, a higher-efficacy lamp can
be purchased at the same wattage under
the standards case, thereby increasing
lumen output without reducing energy
consumption. On the other hand, by
installing an equally-efficacious
fluorescent lamp on a ballast with a
lower BF, the outcome can be a positive
energy savings for that system. As
discussed in section III.H, the lamp
systems available in the shipments
forecast, and ultimately in the NIA,
incorporate consumer choices that
encompass both energy-saving and nonenergy-saving options.
Also discussed in the shipments
analysis (section III.H), the base-case
and standards-case forecasted efficacies
are primarily determined by inputs into
the market-share matrices in both the
fluorescent and incandescent NIA
models. As exemplified in Table III.33,
the base-case efficacy forecast of 4-foot
medium bipin and 8-foot single pin
slimline lamps show a gradual increase
in average efficacy due to both the
phasing out of T12 ballasts and the
penetration of higher-efficacy T8 lamps.
As T12 lamps are generally less
efficacious than their T8 counterparts,
the market shift toward T8 lamp-andballast systems causes an overall
increase in efficacies of shipped
fluorescent lamps. In addition, as T12
magnetic ballasts generally have higher
system powers than their electronic T8
counterparts, average system power
decreases overall. Due to the banning of
magnetic ballasts by the 2000
Fluorescent Ballast rulemaking, by the
year 2025, all magnetic T12 ballasts are
expected to have retired from the
installed stock, and the increase in
average lamp efficacy and decrease in
average system power slows. Because
the installed stock of the 8-foot recessed
double contact HO lamp market is
already predominantly operating on
electronic ballasts, the increase in
average lamp efficacy and decrease in
average system power is solely due to
the penetration of more-efficacious or
reduced-wattage lamps being installed
on lower ballast factor ballasts.
60 ‘‘Site energy’’ is the energy consumed by the
lamp systems directly as they are operated at the
end-use site.
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TABLE III.33.—BASE-CASE AVERAGE LAMP EFFICACY AND SYSTEM POWER OF THE GSFL STOCK
4-foot medium bipin
Year
2012
2015
2020
2025
2030
2035
2042
Average
efficacy
lm/W
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
8-foot single pin slimline
Average
system
power *
W
87.9
88.9
90.0
90.7
91.3
91.9
92.8
Average efficacy
lm/W
93
89
85
84
82
81
79
Average
system
power **
W
91.3
92.6
95.7
97.5
98.0
98.4
99.1
135
129
116
110
109
108
107
8-foot recessed double
contact HO
Average efficacy
lm/W
Average
system
power †
W
83.0
83.0
83.3
83.7
84.1
84.5
85.0
198
197
197
196
194
193
192
* 4-foot medium bipin systems are lamp systems composed of either one or two ballasts and three lamps.
** 8-foot single pin slimline systems are lamp systems composed of one ballast and two lamps.
† 8-foot recessed double contact systems are lamp systems composed of one ballast and two lamps.
Improvement in stock efficacy for IRL
is driven by shifts to more-efficacious
HIR technologies. For IRL, as discussed
in the Shipments Analysis (see section
III.H.3), DOE reports only the
improvement in efficacy of the lamp
sockets not migrating to non-IRL
emerging technologies such as solidstate lighting or ceramic metal halide.
As demonstrated in Table III.34 the
average efficacy of the installed stock of
IRL is expected to increase during the
analysis period.
TABLE III.34.—BASE-CASE AVERAGE
LAMP EFFICACY OF THE IRL STOCK
Average
efficacy
lm/W
Year
2012
2015
2020
2025
2030
2035
2042
......................................
......................................
......................................
......................................
......................................
......................................
......................................
13.7
13.8
13.8
13.8
13.9
13.9
13.9
DOE invites comment on the basecase efficacy forecasts of GSFL and IRL.
3. National Impact Analysis Inputs
Table III.35 summarizes the major
inputs to the NES and NPV spreadsheet
models. For each input, the table
provides a brief description of the data
source. For details on the entire national
impact analysis, see Chapter 10 of the
ANOPR TSD.
TABLE III.35.—NATIONAL ENERGY SAVING AND NET PRESENT VALUE INPUTS
Input data
Data description
Shipments ....................................................................
Annual shipments from the GSFL and IRL shipment models (see TSD Chapter 9, Shipments Analysis).
Established based on the 2011 lamp stock, the service life of lamps and/or ballasts, and
the annual shipments. The initial stock is based on historical shipments and projected
shipments from 2006 to 2011. (See TSD Chapter 9, Shipments Analysis).
2012.
2012 to 2042.
Established in the Energy-Use Characterization, TSD Chapter 6, by lamp or lamp-andballast design and sector.
Established in the Product Price Determination, TSD Chapter 7 and the LCC Analysis,
TSD Chapter 8, by lamp-and-ballast designs.
2007 EIA Annual Energy Outlook forecasts (to 2030) and extrapolation for beyond 2030
(see TSD Chapter 8).
Conversion varies yearly and is generated by 2007 EIA Annual Energy Outlook forecasts
(to 2030) of electricity generation and electricity-related losses. Conversion factors for
beyond 2030 are extrapolated.
6.25% of total energy savings in the commercial sector.
1% of total energy savings in the commercial sector.
8.5% of total energy savings in the residential sector.
3 and 7 percent real.
Future costs and savings are discounted to the year 2007.
Stock of Lamps ............................................................
Effective Date of Standard ..........................................
Analysis Period ............................................................
Unit Energy Consumption (kWh/yr) .............................
Total Installed Cost ......................................................
Electricity Price Forecast .............................................
Electricity Site-to-Source Conversion ..........................
HVAC Interaction Savings ...........................................
Rebound Effect ............................................................
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Discount Rate ..............................................................
Present Year ................................................................
Inputs for the calculation of NES
identified in Table III.35 include the
analysis period, per-unit annual energy
consumption, shipments, lamp stock,
site-to-source conversion factors,
rebound effect, and heating/ventilating/
air conditioning (HVAC) interaction
savings. The following discussion
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provides further context and
information on these inputs.
One of the critical inputs to the NES
and NPV calculations is the analysis
period. DOE received several comments
at the Framework Meeting regarding the
appropriateness of 30 years as the
duration of the analysis period for a
fluorescent and incandescent lamp NES.
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Both GE and PG&E commented that
because the life-cycle of fluorescent
lighting systems is approximately 15 or
20 years, a 30-year analysis period is too
long in the commercial sector. In
addition, GE commented that although
incandescent lamps are often upgraded
much sooner than 20 years, a 20-year
analysis period could be used for
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consistency with the GSFL analysis.
(Public Meeting Transcript, No. 4.5 at
pp.204–205) ACEEE commented that
DOE should use a 30-year analysis
period for consistency with other
rulemaking analyses. (Public Meeting
Transcript, No. 4.5 at pp. 205–206) In
response, DOE recognizes that the lifecycle of GSFL systems and IRL are all
estimated to be less than 30 years;
however, DOE has tentatively decided
to use an analysis period from 2012 to
2042 for consistency with the shipment
and national impact analyses of other
rulemakings.
Annual energy consumption per lamp
system is used to calculate the annual
national energy consumption. For IRL,
the lamp system is solely composed of
the incandescent lamp. For GSFL, DOE
received a comment from EEI urging
DOE to consider system energy
consumption in the fluorescent lamp
national impact analysis. EEI
emphasized that the ballast determines
the energy savings in many situations.
(EEI, No. 7 at p. 1) DOE recognizes the
significance of EEI’s comment and has
incorporated this approach into its
analysis. Accordingly, for the ANOPR,
DOE considered GSFL lamp-and-ballast
pairs, or systems, in constructing its
national impact analysis. Section III.D,
Energy-Use Characterization, provides
the energy consumption of each lampand-ballast pairing used in the national
impact analysis.
The lamp stock in a given year is the
number of lamps shipped from earlier
years to the present and which survive
in the given year. The NIA spreadsheet
model keeps track of the number of
units shipped each year. As discussed
in Section III.H, Shipments Analysis,
DOE develops its forecasted shipments
for the base case from the initial stock
of fluorescent and incandescent lamps
in the year before the effective date of
the standard (i.e., 2011).
For both GSFL and IRL, DOE
developed market-share matrices
illustrating the technology migration of
the stock. The growth in stocks (either
by lumen demand or by number of
sockets in the field) and the average
lumen output per lamp result in a
forecasted lumen output for the
commercial GSFL, industrial GSFL,
commercial IRL, and residential IRL
markets over the analysis period. If DOE
receives comment that over-lighting or
under-lighting in any of the markets will
result in a decrease in total shipments
and total stock, DOE may make such a
stock adjustment for the NOPR. DOE
invites comment on this issue.
The site-to-source conversion factor is
the multiplicative factor DOE uses for
converting site-energy consumption (the
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energy used at the end-use site) into
primary or source energy consumption
(the energy used at the source before
transmission or conversion losses). For
electricity, the conversion factors vary
over time due to projected changes in
generation sources (i.e., the power plant
types projected to provide electricity to
the country). For the ANOPR, DOE
calculated annual average site-to-source
conversion factors using EIA’s
AEO2007. The conversion factors were
derived by dividing the total energy
used to produce electricity in each
forecast year in the United States, as
indicated in AEO2007, by the total
electricity delivered for each forecasted
year. For example, the site-to-source
conversion factor in 2012 is calculated
to be 10,680 BTU/kWh.
DOE received multiple comments
regarding the HVAC system interaction
with fluorescent lighting fixtures in the
commercial sector. EEI commented that
DOE should account for this interaction
(both the reduction of AC loads and
increase in heating loads) as an effect of
the standard in its national impacts
analysis. (EEI, No. 7 at p. 1; Public
Meeting Transcript, No. 4.5 at p. 242) In
addition, EEI noted that a trend toward
higher-efficacy HVAC systems may
lower this HVAC interaction with
lighting. (Public Meeting Transcript, No.
4.5 at pp. 159–160) Based on this
comment, DOE has decided to include
HVAC interaction in its calculation of
the NES (but not in the NPV
calculation). To account for HVAC
energy savings, DOE used the analysis
completed by the 2000 Fluorescent
Ballast rulemaking, which calculates an
HVAC interaction energy savings of 6.25
percent of total energy savings.61 As EEI
suggested, this analysis incorporates
changes in both heating and cooling
loads as a result of the standard. The
analysis also involved calculating the
lighting HVAC interaction energy
savings on buildings built before 1989 (5
percent of total energy savings) and ones
built from 1990 to 1995 (10 percent of
total energy savings). The ballast
analysis assumed that over the analysis
period, the building stock would move
from the 5 percent interaction factor
towards the 10 percent interaction
factor. Using simple scaling methods,
6.25 percent was used as an average
interaction over the entire analysis
61 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 B, pp. B–
23–B–30 (Jan. 2000). Available at: https://www.eere.
energy.gov/buildings/appliance_standards/
residential/pdfs/appendix_b.pdf
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period. Using this same methodology for
lamps, an analysis period ranging from
2012 to 2042 would have a slightly
higher HVAC energy savings. However,
DOE acknowledges EEI’s comment that
the overall HVAC savings with lighting
may also decrease due to more-efficient
heating and cooling systems.
Considering these competing factors,
DOE believes it is reasonable to use 6.25
percent of total energy savings as the
HVAC energy savings in commercial
sector for both GSFL and IRL.
NWPCC commented that due to the
increasing prevalence of air
conditioning systems, it would be
worthwhile to analyze the heating load
of incandescent lamps on the HVAC
systems in the residential sector. (Public
Meeting Transcript, No. 4.5 at pp. 162–
163) GE then responded that
incandescent lamps have a minor effect
on HVAC energy usage, so such an
analysis is not warranted. (Public
Meeting Transcript, No. 4.5 at p. 163)
While DOE appreciates NWPCC’s
comment, DOE believes that IRL will
have a minor effect on HVAC energy
usage in the residential sector.
Therefore, DOE has not included that
interaction in the NES analysis. DOE
invites further comment on the issue of
HVAC interaction in both the
commercial and residential sectors.
In its analysis, DOE considered the
rebound effect 62 that occurs after
installation of energy-efficient lighting
equipment. DOE examined a summary
of the literature regarding the rebound
effect in relation to lighting
equipment.63 Based on four studies, the
summary estimated that, for a 100
percent increase in energy efficiency,
values of ’’take-back’’ or rebound for
residential lighting are between five and
twelve percent of the energy
consumption savings. In addition, with
regards to a firm’s response to higherefficiency lighting, the summary
estimated zero to two percent for values
of rebound for lighting. Therefore, in the
calculation of national energy savings
due to energy conservation standards on
lighting, DOE used a rebound rate of 8.5
percent in the residential sector and one
percent in the commercial and
industrial sectors. However, DOE notes
that the summary of the literature
reports that the results of rebound due
62 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.
63 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.
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to lighting are inconclusive. Thus, DOE
invites comments on both the inclusion
and magnitude of the rebound effect for
purposes of analyzing the expected
effects of this regulation.
The take-back in energy consumption
associated with the rebound effect
provides consumers with increased
value (e.g., increased lighted hours,
since the increased efficiency enables
consumers to use their lighting
equipment for longer periods of time).
The impact on consumers is, thus, the
sum of the change in the cost of owning
the lighting equipment (i.e., life-cycle
cost) and the increased value for the
longer lit hours. However, DOE is
unable to monetize this increase in
consumer value in the LCC analysis.
DOE believes that, if it were able to
monetize the increased value to
consumers added by the rebound effect,
this value would be at least as great as
the value of the foregone energy savings.
For this analysis, DOE estimates that
this value is equivalent to the monetary
value of the energy savings that would
have occurred without the rebound
effect. Therefore, the economic impacts
on consumers with or without the
rebound effect, as measured in the LCC
and NPV analyses, are the same.
The inputs to the NPV calculation are
total installed cost per unit, annual
operating cost savings per unit, total
annual installed cost increases, total
annual operating cost savings, discount
factor, present value of increased
installed costs, and present value of
operating cost savings.
As discussed in section III.E, DOE has
collected prices for GSFL and IRL with
varying wattages, efficacies, and
lifetimes. In addition, for GSFL, ballast
prices are included in the analysis. The
total installed cost per unit, as described
in section III.G, consists of these
manufacturer selling prices, labor costs,
and sales tax.
The annual operating cost savings per
unit incorporates changes in electricity
costs due to a standard efficacy level
and lower energy consumption per unit.
As described previously, DOE
forecasted the per-unit annual
electricity consumption. DOE forecasted
electricity prices based on EIA’s
AEO2007. By using both of these values,
DOE is able to establish the annual
operating cost savings per unit.
The total annual installed cost
increase is equal to the annual change
between the base case and standards
case in the product of per-unit total
installed cost multiplied by the
shipments forecasted of each lamp or
lamp-and-ballast design. The total
annual operating cost savings are equal
to the change in the product of annual
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operating costs per unit and the total
lamp stock by lamp or lamp-and-ballast
design.
DOE multiplies monetary values in
future years by the discount factor to
determine the present value. DOE
estimated national impacts using both a
three-percent and a seven-percent real
discount rate as the average real rate of
return on private investment in the U.S.
economy. DOE uses these discount rates
in accordance with Office of
Management and Budget (OMB)
guidance to Federal agencies on the
development of regulatory analysis
(OMB Circular A–4, September 17,
2003), and section E, ‘‘Identifying and
Measuring Benefits and Costs,’’ therein.
DOE defines the present year as 2007.
The present value of increased
installed costs is the annual installed
cost increase in each year (i.e., the
difference between the standards case
and base case), discounted to the
present, and summed for the time
period over which DOE is considering
the installation of product (i.e., from the
effective date of standards, 2012, to the
year 2042). The increase in total
installed cost refers to both product cost
and installation cost associated with the
higher energy efficacy of product
purchased in the standards case
compared to the base case.
The present value of operating cost
savings is the annual operating cost
savings (i.e., the difference between the
base case and standards case)
discounted to the present, and summed
over the period from the effective date,
2012, to the time when the last unit
installed in 2042 is retired from service.
Savings are decreases in operating costs
associated with the higher energy
efficacy of products purchased in the
standards case compared to the base
case. Total annual operating cost
savings is the savings per unit
multiplied by the number of units
surviving in a particular year.
4. National Impact Analysis Results
Tables III.36 through Table III.38
present the NES results (including
rebound effect and HVAC interactions
where applicable) for each CSL
considered for GSFL and IRL. As
mentioned in Section III.H, due to the
relatively small shipments-based market
share of 2-foot U-shaped lamps, national
impact results for 2-foot U-shaped
lamps are not presented in the ANOPR.
However, DOE does intend to estimate
NES and NPV results for these product
classes in the NOPR. In addition, the
following NES and NPV values provide
results for lamps of all covered CCT for
GSFL. For IRL, the results are
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representative for both the standardspectrum and modified-spectrum lamps.
As mentioned earlier in sections
III.H.3 and III.H.4, in the GSFL
shipment model, when 8-foot T12 single
pin slimline lamp-and-ballast systems
are retired, consumers have the option
to replace those systems with 4-foot T8
medium bipin lamp-and-ballast
systems. For this reason, it is necessary
that DOE considers pairs of CSLs when
reporting the results for the ANOPR. For
the ANOPR, when DOE reports the 4foot medium bipin NES and NPV
results, these values represent only the
savings accrued from new construction
and the replacements of the initial 2011
4-foot medium bipin stock. It does not
include savings that may be
accumulated due to the added
shipments and installed stock of 4-foot
medium bipin systems replacing 8-foot
single pin slimline systems. In addition,
DOE reports the 8-foot single pin
slimline NES and NPV as the savings
accrued from the replacements of the
initial 2011 8-foot single pin slimline
stock. This assumes that 4-foot medium
bipin lamps that replace the 8-foot
single pin slimline lamps are still at the
base-case efficacies. However, when
reporting the total NES and NPV for the
entire linear GSFL market, DOE assumes
that all product classes (4-foot medium
bipin, 8-foot single pin slimline, and 8foot recessed double contact HO) are at
the same CSL and all savings are
accounted for.
DOE invites comment on appropriate
CSL pairings that should be reported as
trial standard levels in the NOPR,
including additional pairings not
presented in this ANOPR. The NIA
spreadsheet has the flexibility to
compute results for all combinations of
CSLs at the product class level and even
at the level of baseline lamps for GSFL.
For example, in the GSFL NIA model,
it is possible to specify different efficacy
requirements for 4-foot T12 medium
bipin and 4-foot T8 medium bipin
lamps. More detailed discussion
regarding these CSL pairs can be found
in Chapter 9 of the TSD.
Table III.36 and Table III.37 present
the national energy savings for GSFL
under both the ‘‘shift’’ (upper bound)
and ‘‘roll-up’’ (lower bound) scenarios.
The highest energy savings result from
CSL 5 for both scenarios and all lamp
types. In addition, note that at CSL 1
and CSL 2 (and CSL 3 for only 8-foot
recessed double contact HO lamps), all
energy savings originate from shifts to
higher-efficacy T12 lamps and, in the 4foot medium bipin and 8-foot single pin
slimline models, early retrofits to the
more-efficacious T8 systems. At these
CSLs, all T8 lamps are standards-
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compliant and, therefore, unaffected in
both scenarios. At CSL 3, a large
increase in total energy savings of GSFL
can be observed, stemming from the
saving associated with 4-foot T8 lamps
(the majority of the stock) being affected
by the regulations. It is also important
to note that at CSL 4 and CSL 5 for all
GSFL product classes, all T12 lamp
systems are automatically retrofitted to
T8 lamp systems because no T12
standards-compliant lamps are available
as lamp designs.
TABLE III.36.—CUMULATIVE NATIONAL ENERGY SAVINGS FOR GSFL UNDER THE SHIFT SCENARIO
[2012–2042] [quads] 64
NES
quads
Candidate standard level
Product class
Undiscounted
0.20
0.04
0.27
0.80
0.31
0.51
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
0.45
0.09
0.65
0.24
0.05
0.20
0.34
0.06
0.37
1.19
0.49
0.78
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
6.79
0.13
0.67
1.98
0.07
0.20
3.81
0.10
0.38
7.94
2.35
4.49
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
8.17
0.41
2.16
2.54
0.15
0.63
4.72
0.25
1.21
11.09
3.43
6.39
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
12.69
0.41
2.19
3.62
0.16
0.64
7.05
0.26
1.23
Total ................................................................................
5 ..............................................
0.14
0.03
0.15
Total ................................................................................
4 ..............................................
0.27
0.05
0.48
Total ................................................................................
3 ..............................................
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
Total ................................................................................
2 ..............................................
Discounted at
3%
Total ................................................................................
1 ..............................................
Discounted at
7%
15.86
4.59
8.86
TABLE III.37.—CUMULATIVE NATIONAL ENERGY SAVINGS FOR GSFL UNDER THE ROLL-UP SCENARIO
[2012–2042] [quads] 64
NES
quads
Candidate standard level
Product class
Undiscounted
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4 ..............................................
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0.27
0.05
0.35
0.14
0.03
0.12
0.20
0.04
0.21
0.67
0.28
0.45
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
0.45
0.09
0.61
0.24
0.05
0.19
0.34
0.06
0.35
1.15
0.48
0.76
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
2.88
0.13
0.63
0.92
0.07
0.19
1.68
0.10
0.36
Total ................................................................................
3 ..............................................
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
Total ................................................................................
2 ..............................................
Discounted at
3%
Total ................................................................................
1 ..............................................
Discounted at
7%
3.79
1.23
2.23
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
3.71
0.17
1.89
1.16
0.09
0.55
2.14
0.13
1.06
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TABLE III.37.—CUMULATIVE NATIONAL ENERGY SAVINGS FOR GSFL UNDER THE ROLL-UP SCENARIO—Continued
[2012–2042] [quads] 64
NES
quads
Candidate standard level
Product class
Undiscounted
Discounted at
3%
Total ................................................................................
5.92
1.85
3.42
4-foot medium bipin ................................................................
8-foot single pin slimline .........................................................
8-foot recessed double contact HO .......................................
6.62
0.23
2.05
1.90
0.11
0.60
3.68
0.16
1.15
Total ................................................................................
5 ..............................................
Discounted at
7%
9.26
2.72
5.20
Table III.38 presents the national
energy savings for IRL in the
commercial and residential sectors. As
shown in the table, energy savings for
both commercial and residential IRL are
greatest at CSL3. Appendix 10B of the
TSD presents NES results for both the
‘‘65 Watt BR lamp substitution’’ and the
‘‘10 percent lumen increase’’ sensitivity
scenarios. Because both of these
scenarios involve the purchasing of
either higher-wattage or same-wattage
lamps, the two sensitivity scenarios
generally present lower NES results
than that of the main scenario presented
in this notice.
TABLE III.38.—CUMULATIVE NATIONAL ENERGY SAVINGS IRL
[2012–2042] [quads]
NES
quads
Candidate standard level
Sector
Undiscounted
mstockstill on PROD1PC66 with PROPOSALS2
0.48
0.60
0.15
0.18
0.28
0.34
1.08
0.33
0.62
Commercial ....................................................
Residential ......................................................
0.83
1.03
0.27
0.30
0.49
0.58
1.86
0.57
1.07
Commercial ....................................................
Residential ......................................................
1.13
1.27
0.36
0.37
0.66
0.71
Total ........................................................
3 ......................................................................
Commercial ....................................................
Residential ......................................................
Total ........................................................
2 ......................................................................
Discounted at
3%
Total ........................................................
1 ......................................................................
Discounted at
7%
2.40
0.73
1.37
Below are the NPV results for the
CSLs considered for GSFL and IRL.
Results are cumulative and are shown as
the discounted value of these savings in
dollar terms. The present value of
increased total installed costs is the total
installed cost increase (i.e., the
difference between the standards case
and base case), discounted to the
present, and summed over the time
period in which DOE evaluates the
impact of standards (i.e., from the
effective date of standards, 2012, to
2042).
Savings are decreases in operating
costs associated with the higher energy
efficacy of each product purchased in
the standards case compared to the base
case. Total operating cost savings are the
savings per unit multiplied by the
number of units surviving in a
particular year. Each product consumes
energy and must be maintained over its
entire lifetime. For a unit that survives
after 2042, DOE calculates a residual
value in both the base case and
standards case to account for its
remaining life. The cost savings
associated with this residual value are
incorporated into the total NPV result.
A detailed description of this
calculation can be found in Chapter 10
of the TSD.
The NPV results for the CSLs
analyzed for each of the lamp types are
based on discount rates of 7 and 3
percent.
Table III.39 and Table III.40 provide
the NPV for GSFL under both the shift
and roll-up scenarios. As seen below,
CSL 4, for 8-foot recessed double
contact HO lamps and 8-foot single pin
slimline lamps, and CSL 5 for 4-foot
medium bipin, achieve the highest NPV
for the shift scenario. For the roll-up
scenario, CSL 5 achieves the highest
NPV for all types of fluorescent lamps
analyzed. Also, for both scenarios and at
all CSLs, the 4-foot medium bipin lamp
results in positive NPV, because
increasingly efficacious lamp-andballast designs generally have higher
LCC savings relative to each other and
64 Results of 4-foot medium bipin energy savings
and NPV are calculated assuming there is no 8-foot
single pin slimline standard while the 8-foot single
pin slimline results assume no 4-foot medium bipin
standard. Total results assume 4-foot medium bipin
lamps and 8-foot single pin slimline lamps are
subject to the same CSL.
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the base-case lamp-and-ballast designs.
For all GSFL, at CSL 4 and CSL 5, large
and positive NPV generally result due to
the integration of more-efficacious T8
design options into both commercial
and industrial lamp stocks. As 4-foot T8
medium bipin lamps are the majority of
stock of all GSFL, an increase in lamp
efficacy and a decrease in energy
consumption result in large operating
cost savings and, therefore, high NPV.
TABLE III.39.—CUMULATIVE NPV RESULTS FOR GSFL UNDER THE SHIFT SCENARIO
[Billion 2006$]
NPV
billion 2006$
Candidate standard level
Product class
Discounted at
7%
2.40
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
0.24
0.01
1.42
0.74
0.11
2.73
1.67
3.58
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
9.33
0.13
0.05
19.92
0.31
0.20
10.15
21.66
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
13.75
0.69
3.64
27.03
1.52
8.08
18.78
37.92
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
20.37
0.68
3.63
42.62
1.51
8.06
Total ...................................................................................................
5 .......................................................
1.11
Total ...................................................................................................
4 .......................................................
0.52
0.02
1.86
Total ...................................................................................................
3 .......................................................
0.20
¥0.03
0.94
Total ...................................................................................................
2 .......................................................
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
Total ...................................................................................................
1 .......................................................
Discounted at
3%
25.74
54.26
TABLE III.40.—CUMULATIVE NPV RESULTS FOR GSFL UNDER THE ROLL-UP SCENARIO
[Billion 2006$]
NPV
billion 2006$
Candidate standard level
Product class
Discounted at
7%
mstockstill on PROD1PC66 with PROPOSALS2
4 .......................................................
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0.52
0.02
1.01
0.73
1.55
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
0.24
0.01
1.15
0.74
0.11
2.13
1.40
2.98
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
2.60
0.13
0.00
6.15
0.31
0.07
Total ...................................................................................................
3 .......................................................
0.20
¥0.03
0.56
Total ...................................................................................................
2 .......................................................
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
Total ...................................................................................................
1 .......................................................
Discounted at
3%
2.98
7.00
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
5.37
0.07
3.27
10.63
0.26
7.33
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TABLE III.40.—CUMULATIVE NPV RESULTS FOR GSFL UNDER THE ROLL-UP SCENARIO—Continued
[Billion 2006$]
NPV
billion 2006$
Candidate standard level
Product class
Discounted at
7%
Total ...................................................................................................
9.00
18.74
4-foot medium bipin ...................................................................................
8-foot single pin slimline ............................................................................
8-foot recessed double contact HO ..........................................................
8.19
0.24
3.40
17.29
0.66
7.61
Total ...................................................................................................
5 .......................................................
Discounted at
3%
12.47
26.72
Table III.41 presents the NPV for IRL
in the commercial and residential
sectors. As shown in Table III.41, the
NPV for IRL is greatest at CSL3,
consistent with trends in LCC savings.
Appendix 10B of the TSD presents NPV
results for both the ‘‘65 Watt BR lamp
substitution’’ and the ‘‘10 percent lumen
increase’’ sensitivity scenarios.
TABLE III.41.—CUMULATIVE NPV RESULTS FOR IRL
[Billion 2006$]
NPV
billion 2006$
Candidate standard level
Sector
Discounted at
7%
1.53
2.47
2.02
4.00
Commercial ...............................................................................................
Residential .................................................................................................
1.54
2.31
2.86
4.64
3.85
7.50
Commercial ...............................................................................................
Residential .................................................................................................
2.88
3.34
5.40
6.76
Total ...................................................................................................
3 .......................................................
0.82
1.20
Total ...................................................................................................
2 .......................................................
Commercial ...............................................................................................
Residential .................................................................................................
Total ...................................................................................................
1 .......................................................
Discounted at
3%
6.22
12.16
mstockstill on PROD1PC66 with PROPOSALS2
J. Life-Cycle Cost Subgroup Analysis
The LCC subgroup analysis evaluates
impacts of standards on identifiable
groups of customers, such as different
population groups of consumers (e.g.,
consumers part of low income
households) or different business types
(e.g., educational facilities), which may
be disproportionately affected by any
national energy conservation standard
level. In the NOPR phase of this
rulemaking, DOE will analyze the LCCs
and PBPs for consumers that fall into
such groups. The analysis will
determine whether any particular group
of consumers would be adversely
affected by any of the trial standard
levels.
DOE plans to examine variations in
energy prices and energy use that might
affect the NPV of a standard for
customer subpopulations. To this end,
DOE intends to perform additional
analyses to consider how differences in
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energy use will affect subgroups of
customers. DOE will determine the
effect on customer subgroups using the
LCC spreadsheet model. As described in
Section III.G, the ANOPR LCC analysis
includes various customer types that
use the lamps being considered under
this rulemaking. This analysis includes
consumers purchasing lamps in
different sectors, purchasing lamps for
different building types, replacing
different baseline lamps or lamp/ballast
systems, and undergoing different
purchasing events.
For IRL, DOE can estimate LCC
savings and payback periods for
consumers in the residential,
commercial, and industrial sectors. For
GSFL, DOE can perform an LCC analysis
for consumers in the commercial and
industrial sectors. A subgroup analysis
for consumers of GSFL in the residential
sector could also be performed if DOE
assumes GSFL residential lamps have
the same operating hour profile as IRL
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residential lamps. DOE requests
comment on this assumption.
DOE can also analyze the LCC
impacts on consumers living in different
buildings in the commercial and
residential sectors. For example, DOE
can analyze the impact of standards for
people running educational facilities
and for those who live in a mobile
home. DOE also has the ability to
analyze the impacts on consumers
living in different regions of the
country.
For both GSFL and IRL, DOE has the
ability to evaluate the LCC impacts on
consumers who purchase different
baseline lamps or lamp-and-ballast
systems. For example, the economic
impacts of a standard will be different
for a consumer who owns a typical 4foot T8 lamp-and-ballast system than for
a consumer who owns a typical 4-foot
T12 lamp-and-ballast system. For GSFL,
DOE also has the ability to analyze the
LCC impact of a standard on consumers
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mstockstill on PROD1PC66 with PROPOSALS2
faced with a variety of different lamppurchasing events. The LCC impacts on
a consumer who must replace a lamp for
their existing system are very different
from those impacts on a consumer who
must purchase a lamp because they are
constructing a new building.
DOE received one comment in
response to the Framework Document
pertaining to the LCC subgroup analysis.
PG&E argued that consumers will
experience differential LCCs impacts,
particularly for low-income households.
(PG&E, No. 4.5 at p.218) DOE will
consider analyzing the impacts of
candidate standards on low-income
subgroups for the NOPR. DOE invites
comment on these and other consumer
subgroups that it should consider for the
NOPR. DOE also invites comments on
how LCC inputs might change for each
consumer subgroup.
K. Manufacturer Impact Analysis
The purpose of the MIA is to identify
the likely impacts of energy
conservation standards on
manufacturers. DOE has begun and will
continue to conduct this analysis with
input from manufacturers and other
interested parties. During the MIA, DOE
considers financial impacts and a wide
range of other quantitative and
qualitative industry impacts that might
occur following the adoption of a
standard. For example, if DOE adopts a
particular standard level, it could
require changes to manufacturing
practices. DOE will identify and
understand these impacts through
interviews with manufacturers and
other stakeholders during the NOPR
stage of its analysis.
More specifically, DOE will conduct
each MIA in this rulemaking in three
phases, and will further tailor the
analytical framework for each MIA
based on comments. In Phase I, DOE
creates an industry profile to
characterize the industry and identify
important issues that require
consideration. In Phase II, DOE prepares
an industry cash flow model and an
interview questionnaire to guide
subsequent discussions. In Phase III,
DOE interviews manufacturers, and
assesses the impacts of standards, both
quantitatively and qualitatively. It
assesses industry and sub-group cash
flow and NPV through use of the
Government Regulatory Impact Model
(GRIM). DOE then assesses impacts on
competition, manufacturing capacity,
employment, and regulatory burden
based on manufacturer interview
feedback and discussions.
Until recently, DOE reported MIA
results in its standards rulemakings only
after the ANOPR phase of the
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rulemaking. However, DOE is now
evaluating and reporting preliminary
MIA information in its ANOPRs. For a
detailed discussion on the MIA, refer to
Chapter 12 of the ANOPR TSD.
From a comment received at the
Framework Document public meeting,
DOE is aware that manufacturer cost
data may be difficult to obtain from
industry. (Public Meeting Transcript,
No. 4.5 at pp. 133–135) Therefore, as
recommended, DOE may approximate
manufacturer costs by working
backwards through the distribution
chain from publicly-available prices by
using estimated manufacturer and
supply chain mark-ups. (Public Meeting
Transcript, No. 4.5 at pp. 129 and 133–
136; NEMA, No. 8 at p. 3; Joint
Comment, No. 9 at p. 3). For more
information on the industry cash flow
analysis, refer to Chapter 12 of the
ANOPR TSD.
1. Cumulative Regulatory Burden
DOE recognizes and seeks to mitigate
the overlapping effects on
manufacturers of new or revised DOE
standards and other regulatory actions
affecting the same product. In response
to the Framework Document, several
stakeholders submitted comments
concerning the cumulative impact of
regulation on lamp manufacturers.
Specifically, NEMA commented that a
number of companies face regulations in
other countries, and that some of these
products are manufactured globally for
sale around the world. Therefore,
NEMA commented that there are some
regulatory burdens and issues that may
play a factor here. (NEMA, No. 4.5 at p.
229) EEI commented that DOE should
take into account State regulations in
assessing the impacts of different
requirements for manufacturers. (EEI,
No. 4.5 at p. 233) PG&E commented that
DOE should take into account trade
impacts in the industry. However, PG&E
does not expect this would have a large
impact for manufacturers of lighting
products. (PG&E, No. 4.5 at pp. 239–
240) In response, DOE recognizes that
both States and foreign countries are
already regulating certain lamp
categories or contemplating doing so. As
discussed in section III.A.1, many States
are currently regulating IRL primarily
used in the commercial sector, and a
few are beginning to regulate lamp types
used more often in the residential
sector. Regulations are also pending in
both Mexico and Canada.
DOE will analyze and consider the
impact on manufacturers of multiple,
product-specific regulatory actions in
the NOPR. DOE invites comment on
regulations applicable to lamp
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manufacturers that contribute to their
cumulative regulatory burden.
2. Preliminary Results of the
Manufacturer Impact Analysis
DOE conducted a series of
preliminary interviews with
manufacturers to assess their concerns
about potential impact of changes to the
requirements or coverage of the
regulatory standard for fluorescent and
incandescent lamps. In general,
manufacturers identified the following
major issues of concern: (a) Sufficient
time to retool in response to the
standards; (b) availability of materials to
produce standards-compliant lamps;
and (c) maintaining product availability
and features that consumers use. Each of
these concerns is discussed in further
detail below.
a. Retooling Equipment To Produce
Standards-Compliant Lamps
All of the manufacturers interviewed
expressed concern regarding the
adequacy of the time periods specified
under EPCA for developing standardscompliant lamps. For GSFL, some
manufacturers expressed concern about
the time period necessary to retool to
produce standards-compliant lamps
(e.g., converting from a T12 product line
to a T8 product line at certain standard
levels). For IRL, manufacturers
commented that, depending on the
timeframe for transition, they could face
production capacity problems if DOE
were to raise standards such that the use
of halogen capsules or infrared
reflective (IR) coatings on halogen
capsules were required. Manufacturers
believe there could be a production
capacity problem due to the process
time involved in layering dozens of
thin, IR-reflective film coatings on the
capsule. The high volumes associated
with both GSFL and IRL were cited
frequently as the underlying cause for
concern.
b. Availability of Materials To Produce
Standards-Compliant Lamps
Manufacturers interviewed expressed
concern about the availability of
materials to manufacture standardscompliant lamps. More specifically,
concern was expressed about potential
shortages of certain materials (e.g., the
phosphor that produces blue light),
which could in turn drive up the
production cost.
c. Maintaining Product Availability and
Features
Manufacturers expressed concern to
DOE about the potential impact the
regulation may have on their ability to
continue to supply a wide diversity of
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products with attributes and features
that their customers require. Depending
on the mandatory standard level,
manufacturers expressed concern that
certain lamp shapes and sizes may be
eliminated from the market, or that
significant market shifts could occur
(e.g., from incandescent technology to
compact fluorescent lamps).
As discussed above, DOE will be
conducting the manufacturer impact
analysis for the NOPR stage of this
rulemaking. As part of this inquiry, DOE
will be investigating this preliminary
list of issues in more depth, as well as
discussing other impacts that
manufacturers may experience. DOE
invites comment on these and other
issues, relating to the regulatory impacts
on manufacturers.
Furthermore, DOE considered the
possible effect of energy conservation
standards for GSFL and IRL on small
businesses. At this time, DOE is not
aware of any small manufacturers of the
lamps being considered in this
rulemaking. Should any small business
manufacturers be identified, DOE will
study the potential impacts in greater
detail during the MIA, which DOE will
conduct as a part of the NOPR analysis.
L. Utility Impact Analysis
For the NOPR, the utility impact
analysis will estimate the effects on the
utility industry of reduced energy
consumption due to any new or
amended energy conservation standards
for fluorescent and incandescent lamps.
For GSFL and IRL, the utility impact
analysis will compare the differences
between each lamp type’s forecasted
base and standards cases for electricity
generation, installed capacity, sales, and
prices.
To estimate the effects of potential
standards on the electric utility
industry, DOE intends to use a variant
of the EIA’s National Energy Modeling
System (NEMS).65 NEMS, which is
available in the public domain, is a
large, multi-sectoral, partial equilibrium
model of the U.S. energy sector. DOE/
EIA uses NEMS to produce a widely
recognized baseline energy forecast for
the U.S. DOE uses a variant of NEMS
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65 For
more information on NEMS, please refer to
the U.S. Department of Energy, Energy Information
EIA documentation; a useful summary is National
Energy Modeling System: An Overview 2003, Report
number: DOE/EIA–0581(2003), March 2003
(available at: https://tonto.eia.doe.gov/FTPROOT/
forecasting/05812003.pdf). DOE/EIA approves use
of the name ‘‘NEMS’’ to describe only an official
version of the model without any modification to
code or data. Because the present analysis entails
some minor code modifications and the model is
run under various policy scenarios that are
variations on DOE/EIA assumptions, in this
analysis, DOE refers to it by the name ‘‘NEMS–BT.’’
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known as NEMS-Building Technologies
(NEMS–BT) to supply key inputs to its
utility impact analysis.
For electrical end uses, NEMS–BT
utilizes predicted growth in demand for
each end use to build up a projection of
the total electric system load growth for
each of fifteen electricity market module
supply regions, which it uses in turn to
predict necessary additions to capacity.
For electrical end uses, NEMS–BT
accounts for the implementation of
energy conservation standards by
decrementing the appropriate reference
case load shape. DOE will determine the
size of the decrement using the per-unit
energy savings data developed in the
LCC and PBP analyses (see Chapter 8 of
the ANOPR TSD) and the forecast of
shipments developed for the NIA (see
Chapter 9 of the ANOPR TSD). For more
information on the utility impact
analysis, refer to Chapter 13 of the
ANOPR TSD.
The use of NEMS for the utility
impact analysis offers several
advantages. As the official DOE energy
forecasting model, NEMS relies on a set
of assumptions that are transparent and
have received wide exposure and
commentary. NEMS allows an estimate
of the interactions between the various
energy supply and demand sectors and
the economy as a whole. The utility
impact analysis will determine the
changes for electric utilities in installed
capacity and in generation by fuel type
produced by each CSL, as well as
changes in electricity sales.
DOE plans to conduct the utility
impact analysis as a variant of
AEO2007, applying the same basic set of
assumptions. For example, the utility
impact analysis uses the operating
characteristics (e.g., energy conversion
efficacy, emissions rates) of future
electricity generating plants.
DOE will also explore deviations from
some of the reference case assumptions
to represent alternative future outcomes.
Two alternative scenarios use the highand low-economic-growth cases of
AEO2007. (The reference case
corresponds to medium growth.) The
high-economic-growth case assumes
higher projected growth rates for
population, labor force, and labor
productivity, resulting in lower
predicted inflation and interest rates
relative to the reference case. The
opposite is true for the low-growth case.
While DOE varies supply-side growth
determinants in all three of these
different economic-growth cases,
AEO2007 assumes the same reference
case energy prices for all three economic
growth cases so that the impact of
differences in the three scenarios are
comparable, referenced against a
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consistent set of energy prices. The
three different economic growth cases
all affect the rate of growth of electricity
demand.
Since the AEO2007 version of NEMS
forecasts only to the year 2030, DOE
must extrapolate results to 2042. It is
not feasible to extend the forecast period
of NEMS–BT for the purposes of this
analysis, nor does EIA have an approved
method for extrapolation of many
outputs beyond 2030. While it might
seem reasonable in general to use
simple linear extrapolations of results,
in practice this is not advisable, because
outputs could be contradictory. For
example, changes in the fuel mix
implied by extrapolations of those
outputs could be inconsistent with the
extrapolation of marginal emissions
factors. An analysis of the various
trends to a sufficiently detailed degree
to guarantee consistency among the
extrapolations is not conducted as part
of this analysis. Further, even it were,
the extrapolations would still involve a
great deal of uncertainty. Therefore, for
all extrapolations beyond 2030, DOE
intends to simply repeat the results from
the year 2030 results, until it reaches the
end of the analysis period, 2042. While
this simplified extrapolation technique
and the resulting values may seem
unreasonable in some instances, results
are nevertheless guaranteed to be
consistent. As with the AEO reference
case in general, the implicit premise is
that the regulatory environment does
not deviate from the current known
situation during the extrapolation
period. Only changes that have been
announced with date-certain
introduction are included in NEMS–BT.
In comments on the Framework
Document, EEI requested that DOE
provide an explanation of the
calculations conducted using the
NEMS–BT model. EEI believes such
explanation would enable the public to
more easily comment on the plausibility
of the output. (EEI, No. 4.5 at pp. 236–
237) In response, when DOE conducts
the utility impact analysis for the NOPR,
it will endeavor to improve the clarity
and presentation of the calculations
conducted using the NEMS–BT model.
M. Employment Impact Analysis
At the NOPR stage, DOE estimates the
impacts of standards on employment for
equipment manufacturers, relevant
service industries, energy suppliers, and
the economy in general. The following
discussion explains the methodology
DOE plans to use in conducting the
employment impact analysis for this
rulemaking. Both indirect and direct
employment impacts are analyzed.
Direct employment impacts would
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result if standards led to a change in the
number of employees at manufacturing
plants and related supply and service
firms. Direct impact estimates are
covered in the MIA.
Indirect employment impacts are
impacts on the national economy other
than in the manufacturing sector being
regulated. Indirect impacts may result
both from expenditures shifting among
goods (substitution effect) and changes
in income which lead to a change in
overall expenditure levels (income
effect). DOE defines indirect
employment impacts from standards as
net jobs eliminated or created in the
general economy as a result of increased
spending driven by the increased
equipment prices and reduced spending
on energy.
DOE expects new standards to
increase the total installed cost of
equipment (includes manufacturer’s
selling price, distribution channel markups, sales taxes, and installation cost).
DOE also expects the new standards to
decrease energy consumption, and,
thus, expenditures on energy. Over
time, increased total installed cost is
paid back through energy savings. The
savings in energy expenditures may be
spent on new commercial investment
and other items.
Using an input/output model of the
U.S. economy, this analysis seeks to
estimate the effects on different sectors
and the net impact on jobs. DOE will
estimate national employment impacts
for major sectors of the U.S. economy in
the NOPR, using public and
commercially available data sources and
software. DOE will make all methods
and documentation pertaining to the
employment impact analysis available
for review in the Technical Support
Document published in conjunction
with the NOPR.
DOE developed Impact of Sector
Energy Technologies (ImSET), a
spreadsheet model of the U.S. economy
that focuses on 188 sectors most
relevant to industrial, commercial, and
residential building energy use.66
ImSET is a special-purpose version of
the U.S. Benchmark National InputOutput (I–O) model, which has been
designed to estimate the national
employment and income effects of
energy-saving technologies that are
considered by the DOE Office of Energy
Efficiency and Renewable Energy. In
comparison with previous versions of
the model used in earlier rulemakings,
the current 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
personal 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
Benchmark U.S. table (Lawson, et al.
2002),67 specially aggregated to 188
sectors. The time scale of the model is
50 years.
The model is a static I–O model,
which means that the model is able to
accommodate a great deal of flexibility
concerning the types of effects the
energy conservation standards can have
on the national employment and income
effects. For example, certain economic
effects of energy-efficiency
improvements require an assessment of
inter-industry purchases, which is
handled in the model. Some energyefficiency investments will not only
reduce the costs of energy in the
economy but the costs of labor and other
goods and services as well, which is
accommodated through a recalculation
of the I–O structure in the model.
Output from the ImSET model can be
used to estimate changes in
employment, industry output, and wage
income in the overall U.S. economy
resulting from changes in expenditures
in the various sectors of the economy.
Although DOE intends to use ImSET
for its analysis of employment impacts,
it welcomes input on other tools and
factors it might consider. For more
information on the employment impacts
analysis, refer to Chapter 14 of the TSD.
66 Roop, J. M., M. J. Scott, and R. W. Schultz,
‘‘ImSET: Impact of Sector Energy Technologies,’’
PNNL–15273. (Pacific Northwest National
Laboratory, Richland, WA)(2005).
67 Lawson, Ann M., Kurt S. Bersani, Mahnaz
Fahim-Nader, and Jiemin Guo, ‘‘Benchmark InputOutput Accounts of the U. S. Economy, 1997,’’
Survey of Current Business (Dec. 2002), pp. 19–117.
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N. Environmental Assessment
For the NOPR, DOE will assess the
environmental effects of energy
conservation standards for GSFL and
IRL. DOE anticipates that the primary
environmental effects will be reduced
power plant emissions resulting from
reduced electricity consumption. DOE
will assess these environmental effects
by using NEMS–BT to provide key
inputs to the analysis. The
environmental assessment produces
results in a manner similar to those
provided in the AEO.
The intent of the environmental
assessment is to provide emissions
results estimates, and to fulfill
legislative requirements that DOE
quantify and consider the
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environmental effects of all new Federal
rules. The environmental assessment
that will be produced by NEMS–BT
considers potential environmental
impacts from three pollutants (sulfur
dioxide (SO2), nitrous oxide (NOX),
mercury (Hg)) and from carbon dioxide
(CO2) emissions. For each of the trial
standard levels, DOE will calculate total
undiscounted and discounted power
plant emissions using NEMS–BT.
DOE will conduct each portion of the
environmental assessment performed
for this rulemaking as an incremental
policy impact (i.e., an energy
conservation standard imposed on the
product being evaluated, in this case
general service fluorescent lamps and
incandescent reflector lamps) of the
AEO2007 forecast, applying the same
basic set of assumptions used in
AEO2007. For example, the emissions
characteristics of an electricity
generating plant will be exactly those
used in AEO2007. Also, forecasts
conducted with NEMS–BT consider the
supply-side and demand-side effects on
the electric utility industry. Thus, the
analysis will account for any factors
affecting the type of electricity
generation and, in turn, the type and
amount of airborne emissions generated
by the utility industry.
The NEMS–BT model tracks carbon
emissions with a specialized carbon
emissions estimation subroutine,
producing reasonably accurate results
due to the broad coverage of all sectors
and the inclusion of interactive effects.
Past experience with carbon results
from NEMS suggests that emissions
estimates are somewhat lower than
emissions based on simple average
factors. One of the reasons for this
divergence is that NEMS tends to
predict that energy conservation
measures will slow generating capacity
growth in future years, and new
generating capacity is expected to be
more efficient than existing capacity. On
the whole, NEMS–BT provides carbon
emissions results of reasonable
accuracy, at a level consistent with
other Federal published results. In
addition to providing estimates of the
quantitative impacts of GSFL and IRL
standards on carbon emissions, DOE
may consider the use of monetary
values to represent the potential value
of such emissions reductions. DOE
invites comment on how to estimate
such monetary values or on any widely
accepted values that might be used in
DOE’s analyses.
NEMS–BT also reports on SO2 and
NOX, which DOE has reported in past
analyses. The Clean Air Act
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13685
Amendments of 1990 68 set an SO2
emissions cap on all power generation.
The attainment of this target, however,
is made flexible among generators
through the use of emissions allowances
and tradable permits. Although NEMS
includes a module for SO2 allowance
trading and delivers a forecast of SO2
allowance prices, accurate simulation of
SO2 trading implies that physical
emissions effects will be zero because
emissions will always be at or near the
ceiling. However, there may be an SO2
economic benefit from energy
conservation in the form of a lower SO2
allowance price. Since the impact of any
one standard on the allowance price is
likely small and highly uncertain, DOE
does not plan to monetize the SO2
benefit.
NEMS–BT also has an algorithm for
estimating NOX emissions from power
generation. The impact of these
emissions, however, will be affected by
the Clean Air Interstate Rule (CAIR),
which the EPA issued on March 10,
2005. 70 FR 25162 (May 12, 2005). CAIR
will permanently cap emissions of NOX
in 28 eastern States and the District of
Columbia. As with SO2 emissions, a cap
on NOX emissions means that product
energy conservation standards may have
no physical effect on these emissions.
When NOX emissions are subject to
emissions caps, DOE’s emissions
reduction estimate corresponds to
incremental changes in the prices of
emissions allowances in cap-and-trade
emissions markets rather than physical
emissions reductions. Therefore, while
the emissions cap may mean that
physical emissions reductions will not
result from standards, standards could
produce an environmental-related
economic benefit in the form of lower
prices for emissions allowance credits.
However, as with SO2 allowance prices,
DOE does not plan to monetize this
benefit because the impact on the NOX
allowance price from any single energy
conservation standard is likely small
and highly uncertain.
With regard to mercury emissions,
NEMS–BT has an algorithm for
estimating these emissions from power
generation, and, as it has done in the
past, DOE is able to report an estimate
of the physical quantity of mercury
emissions reductions associated with an
energy conservation standard. DOE
assumed that these emissions would be
subject to EPA’s Clean Air Mercury
Rule 69 (CAMR), which would
permanently cap 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
system, energy conservation standards
would result in no physical effect on
these emissions, but would be expected
to result in an environmental-related
economic benefit in the form of a lower
price for emissions allowance credits.
DOE’s plan for addressing analysis does
not include monetizing the benefits of
reduced mercury emissions, because
DOE considered that valuation of such
impact from any single energy
conservation standard would likely be
small and highly uncertain.
On February 8, 2008, the U.S. Court
of Appeals for the District of Columbia
Circuit (D.C. Circuit) issued its decision
in State of New Jersey, et al. v.
Environmental Protection Agency,70 in
which the Court, 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 D.C. Circuit’s
decision. DOE invites public comment
on addressing mercury emissions in this
rulemaking.
With regard to particulates, these
emissions are a special case because
they arise not only from direct
emissions, but also from complex
atmospheric chemical reactions that
result from NOX and SO2 emissions.
DOE does not intend to analyze or
report on the particulate emissions from
power stations because of the highly
complex and uncertain relationship
between particulate emissions and
particulate concentrations that impact
air quality. In sum, the results for the
environmental assessment are similar to
a complete NEMS run as published in
the AEO2007. These results include
power-sector emissions for SO2, NOX,
mercury, and carbon in five-year
forecasted increments extrapolated to
2042. The outcome of the analysis for
each CSL is reported as a deviation from
the AEO2007 reference (base) case.
The Joint Comment stated that DOE
should evaluate mercury and particulate
emissions as part of the environmental
assessment due to their potential
impacts on public health. (Joint
Comment, No. 9 at p. 4) As discussed
above, DOE will analyze and report on
mercury emission reductions; however
it does not intend to report on
particulate emissions.
For more detail on the environmental
assessment, refer to the environmental
assessment in the ANOPR TSD.
68 The Clean Air Act Amendments of 1990 were
signed into law as Pub. L. 101–549 on November
15, 1990. The amendment can be viewed at:
https://www.epa.gov/air/caa/.
69 70 FR 28606 (May 18, 2005).
70 No. 05–1097, 2008 WL 341338, at *1 (D.C. Cir.
Feb. 8, 2008).
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O. Regulatory Impact Analysis
DOE will prepare a draft regulatory
impact analysis in compliance with
Executive Order 12866, ‘‘Regulatory
Planning and Review,’’ which will be
subject to review by the Office of
Management and Budget’s Office of
Information and Regulatory Affairs
(OIRA). 58 FR 51735 (Oct. 4, 1993).
As part of the regulatory impact
analysis, and as discussed in Section
III.K, ‘‘Manufacturer Impact Analysis,’’
DOE will identify and seek to mitigate
the overlapping effects on
manufacturers of new or revised DOE
standards and other regulatory actions
affecting the same products. Through
manufacturer interviews and literature
searches, DOE will compile information
on burdens from existing and
impending regulations affecting the
lamps covered under this rulemaking.
DOE also seeks input from the public
about regulations whose impacts it
should consider.
The regulatory impact analysis also
will address the potential for nonregulatory approaches to supplant or
augment energy conservation standards
to improve the efficacy of GSFL and
IRL. The NOPR will include a complete
quantitative analysis of alternatives to
the proposed conservation standards.
DOE will use the NES spreadsheet
model (as discussed in section III.I,
‘‘National Impact Analysis’’) to calculate
the NES and NPV for the alternatives to
the proposed conservation standards.
For more information on the regulatory
impact analysis, refer to the regulatory
impact analysis report in the ANOPR
TSD.
IV. Candidate Energy Conservation
Standards Levels
In terms of process, DOE specifies
candidate standards levels in the
ANOPR, but does not propose a
particular standard at this stage of the
rulemaking. Table IV.1 and Table IV.2
present the CSLs that are discussed in
today’s ANOPR for the fluorescent and
incandescent reflector lamps product
classes directly analyzed. As mentioned
earlier, in this ANOPR, DOE analyzes
four of the ten product classes of lamps.
Section III.C.6 discusses DOE’s
considered approach for extrapolation
of CSLs to other product classes not
analyzed.
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TABLE IV.1.—SUMMARY OF THE CANDIDATE STANDARD LEVELS FOR GSFL
4-Foot medium bipin
lamps with
CCT ≤ 4,500K
CSL1
CSL2
CSL3
CSL4
CSL5
lm/W
lm/W
............................................................................................................................................
............................................................................................................................................
............................................................................................................................................
............................................................................................................................................
............................................................................................................................................
TABLE IV.2.—SUMMARY OF THE CANDIDATE STANDARD LEVELS FOR IRL
Candidate standard level
Standardspectrum incandescent reflector lamps
lm/W
CSL1 .....................................
CSL2 .....................................
CSL3 .....................................
5.0P 0.27
5.5P 0.27
6.2P 0.27
where P = rated wattage of the incandescent lamp
DOE will review the public input it
receives in response to this ANOPR and
update the analyses appropriately for
each product class before issuing the
NOPR. DOE also will consider any
comments it receives on the CSLs set
forth above for GSFL and IRL, and on
whether alternative levels would satisfy
the EPCA criteria.
For the NOPR, DOE will develop trial
standard levels (TSL) for GSFL and IRL
from the above CSLs or other higher or
lower levels after consideration of
public comments. In previous
rulemakings, DOE has considered
several criteria in developing the TSLs,
such as requiring that a CSL have a
minimum LCC, maximum NPV, and
maximum technologically-feasible
efficacy. DOE invites comment on
whether any of these criteria are
appropriate for this rulemaking, or
whether other TSLs are appropriate,
perhaps based on technologies or
applications that are specific to the
lamps being regulated. DOE seeks
feedback on the criteria it should use as
the basis for the selection of TSLs. This
is identified as Issue 10 under ‘‘Issues
on Which DOE Seeks Comment’’ in
Section 0 of this ANOPR.
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8-Foot recessed Double
contact HO
lamps with
CCT ≤ 4,500K
lm/W
Candidate standard level
8-Foot single
pin slimline
amps with
CCT ≤ 4,500K
V. 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,
Sixth Floor, 950 L’Enfant Plaza, SW.,
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Washington, DC, (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 other relevant information
regarding all aspects of this ANOPR at
the public meeting and will continue to
accept comments until no later than
April 14, 2008. Please submit
comments, data, and information
electronically to the following e-mail
address: fluorescent_and_incandescent_
lamps.rulemaking@ee.doe.gov. Please
submit electronic comments in
WordPerfect, Microsoft Word, PDF, or
text (ASCII) file format and avoid the
use of special characters or any form of
encryption. Comments in electronic
format should be identified by the
Docket Number EE–2006–STD–0131
and/or RIN number 1904–AA92, and
whenever possible carry the electronic
signature of the author. Absent an
electronic signature, comments
submitted electronically must be
followed and authenticated by
submitting the signed original paper
document. No telefacsimiles (faxes) will
be accepted.
Under 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 shall include all the
information believed to be confidential,
and the other copy of the document
shall have 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 that DOE considers 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
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85.0
90.0
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95.4
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92.0
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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 interested in receiving
comments on all aspects of this ANOPR.
DOE especially invites comments or
data to improve the analyses, including
data or information that will respond to
the following questions or concerns that
were addressed in this ANOPR:
1. Consideration of Additional General
Service Fluorescent Lamps
EPCA directs DOE to consider
additional GSFL for coverage under 42
U.S.C. 6295(i)(5). In this notice, DOE
outlines its preliminary consideration of
the expansion of coverage for GSFL
under 42 U.S.C. 6295(i)(5), keeping in
mind the express exclusions contained
in the definitions of ‘‘general service
fluorescent lamp’’ (42 U.S.C.
6291(30)(B)). DOE requests comment on
its planned expansion of coverage. See
section II for details on this issue.
2. Amended Definitions
EPCA directs DOE to consider
additional GSFL for coverage under 42
U.S.C. 6295(i)(5). In the definition of
‘‘general service fluorescent lamp,’’ (42
U.S.C. 6291(30)(B)) EPCA identifies
‘‘colored fluorescent lamps’’ as
expressly excluded from coverage.
Although DOE defined ‘‘colored
fluorescent lamp’’ in the 1997 test
Procedure Final Rule, DOE believes this
definition requires updating and,
therefore, presents a draft amended
definition for comment. DOE also
invites comment on whether other
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exclusions are ambiguous or require
modification.
One element of EPCA’s definitions for
‘‘fluorescent lamp’’ and ‘‘incandescent
reflector lamp’’ is a lamp’s ‘‘rated
wattage,’’ which helps to determine
which lamps are subject to standards.
(42 U.S.C. 6291(30)((A), (C)(ii) and (F),
and 6295(i)(1)) In addition, energy
conservation standards for general
service incandescent lamps prescribed
by EISA 2007 require lamps of
particular lumen outputs to have certain
maximum rated wattages. (42 U.S.C.
6295(i)(1)(B) In this rulemaking, DOE
plans to update its definition of rated
wattage to current industry references,
and to apply this definition to those
lamps where rated wattage is not
defined (e.g., 8-foot single pin slimline
lamps and incandescent lamps). DOE
seeks comment on its planned
modification to the definition of ‘‘rated
wattage,’’ a term which applies to both
covered fluorescent and incandescent
lamps. See section II for details on all
of these issues.
3. Product Classes
DOE requests comment on its planned
revisions to the product classes for
GSFL and IRL, including the use of CCT
in the GSFL product classes and the
separate treatment of modified-spectrum
lamps for IRL. Details about DOE’s
planned product classes are presented
in section III.A.2.
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4. Scaling to Product Classes Not
Analyzed
DOE is inviting comment on the
selected representative product classes
where it concentrates its analytical
effort (see section III.C.2), and on the
extrapolation of findings from the
representative product classes to others
that were not analyzed (see section
III.C.6). DOE invites comment on
appropriate scaling methods it should
follow, particularly for the draft scaling
factors discussed in section III.C.6 for 2foot U-shaped GSFL, GSFL with a
higher CCT, and modified-spectrum
IRL.
5. Screening of Design Options
In determining which design options
to consider for the engineering analysis,
DOE applies four statutory screening
criteria to a set of potential technologies
that may improve efficacy (i.e.,
technology options). One of those
screening criteria is ‘‘practicability to
manufacture, install, and service.’’ DOE
invites comment on whether certain
technology options discussed in section
III.B fail to meet this criterion. Some
manufacturers have expressed some
concern about integrating certain
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technology options into high-volume
production lines within a limited timeframe (i.e., the statutory three-year
compliance period). DOE invites
comment on this issue and, if
appropriate, to provide possible
solutions to help resolve the issue. See
section III.B and section III.K for details.
6. Operating Hours
DOE used the U.S. Lighting Market
Characterization Volume I and the EIA’s
RECS, CBECS, and MECS to develop a
national distribution of average
operating hours for lamp types and enduse sectors. DOE requests comment on
whether the average operating hours
derived are a reasonable representation
of these end-uses. See section III.D.1 for
details.
7. General Service Fluorescent Energy
Consumption
In today’s Federal Register, DOE is
also publishing a test procedure NOPR
for fluorescent and incandescent lamps.
In that NOPR, DOE proposes to continue
to use low-frequency ballast testing for
all GSFL except for those lamp types
that can only be tested on highfrequency ballasts. While DOE uses the
test procedure to confirm that
manufacturers have met the minimum
requirements, in this ANOPR, DOE
considers the operation of fluorescent
lamps on several different ballast types
for the LCC and NIA analyses (i.e., DOE
uses average system power ratings of
GSFL operating on electronic and
magnetic ballasts). This approach
enables the economic evaluation of the
CSLs to more accurately reflect how
fluorescent lamps are operated in the
field. DOE invites comment on this
approach, as well as the calculated
system power ratings it derived for the
lamp-and-ballast combinations using
published data. Detail on the system
power ratings can be found in Chapter
5 of the TSD.
8. Life-Cycle Cost Calculation
In order to determine the life-cycle
cost savings of lamp designs with
unequal lifetimes, DOE used an analysis
period corresponding to the lifetime of
the baseline lamp. To account for the
remaining life of the equipment at the
end of the analysis period, DOE
calculated a residual value by linearly
prorating the initial cost of the
equipment. DOE invites comment on its
usage of residual values in the life-cycle
cost analysis and on other possible
approaches to calculating life-cycle
costs for product with different
lifetimes.
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9. Installation Costs
In order to determine the complete
installed cost for the LCC analysis, DOE
developed estimates of commercial
sector installation costs for IRL and
GSFL. DOE seeks comment on the
average labor rates and times for each
lamp type. See Chapter 8 of the TSD for
details.
10. Base-Case Market-Share Matrices in
2012
DOE has developed a base-case to
represent the distribution of lamp
systems and their efficacies currently in
the marketplace, and thereby determine
the proportion of consumers affected by
a particular energy conservation
standard level. DOE developed basecase efficacy distributions for GSFL and
IRL based on a combination of
interviews with lighting experts,
historical shipments information, and
available product data. DOE requests
comment on the resultant base-case
product distributions. See section III.H
for details.
11. Shipment Forecasts
A key input into the shipment
forecasts of GSFL and IRL is the
assumed market growth. For
commercial GSFL and IRL, DOE uses a
growth rate of 1.6 percent based on
CBECS floor space growth projections.
For residential IRL, DOE uses a 1.3
percent growth rate from the RECS
residential building growth projection.
DOE invites comment on the data
sources, estimates, and implementation
of these growth rates. In addition, the
shipment forecasts impact the total
national lumen output of each lamp
type. DOE invites comment on the
national lumen output projection in
both the base case and standards case.
Specifically, DOE invites comment on
whether any adjustments are necessary
to respond to consumer actions
resulting in over-lighting or underlighting. See Chapter 9 of the TSD and
section III.H for details.
12. Base-Case and Standards-Case
Forecasted Efficiencies
Forecasts of average market efficacy
and energy consumption, in both the
base case and standards case, are
fundamental inputs to the NES and NPV
calculations. Estimates of the market’s
selection of lamp and lamp-and-ballast
designs, in turn, drive the forecasts for
average efficacy and energy
consumption. As a sensitivity to the
NES and NPV calculations, DOE
developed standards-case scenarios to
test the upper and lower bounds of the
NES and NPV results. DOE invites
comment on these standards-case
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scenarios it developed estimating
market behavior in response to a
standard, such as roll-up and shift in the
GSFL market or the 65W BR lamp
substitution scenario. See section III.H
for details.
13. Trial Standard Levels
For the NOPR, DOE will develop trial
standard levels (TSLs) based on the
candidate standard levels for GSFL and
IRL. DOE is considering several criteria
in developing the TSLs, including, but
not limited to, minimum LCC,
maximum NPV, and maximum
technologically-feasible efficacy. These
TSLs may include combinations of CSLs
and the interaction between product
classes such as 4-foot medium bipin and
8-foot single pin slimline fluorescent
lamps or standard-spectrum and
modified-spectrum IRL. From the list of
TSLs developed, DOE will select one as
its proposed standard for the NOPR.
DOE invites comment on the criteria it
should use as the basis for the selection
of TSLs. See section III.H for details.
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14. Lamp Production Equipment
Conversion Timeframe
Manufacturers of high-volume lamps
expressed concern as to their ability to
retool, invest in, or replace equipment
within the statutorily-required threeyear compliance period, such that they
may continue to offer the volume lamps
for sale at a new standard level. DOE
invites comment on this issue, and
welcomes recommendations on how
best to mitigate any equipment
conversion issues.
VI. Regulatory Review and Procedural
Requirements
DOE submitted this ANOPR for
review to OMB under Executive Order
12866, ‘‘Regulatory Planning and
Review.’’ 58 FR 51735 (October 4, 1993).
If DOE later proposes new or revised
energy conservation standards for GSFL
or IRL, and if the proposed rule
constitutes a significant regulatory
action, DOE would prepare and submit
to OMB for review the assessment of
costs and benefits required by section
6(a)(3) of the Executive Order. The
Executive Order requires agencies to
identify the specific market failure or
other specific problem that it intends to
address that warrants 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 presumes that a perfectly
functioning market would result in
efficiency levels that maximize benefits
to all affected persons. Consequently,
without a market failure or other
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specific problem, a regulation would not
be expected to result in net benefits to
consumers and the nation. However,
DOE also notes that whether it
establishes standards for these products
is determined by the statutory criteria
expressed in EPCA. Even in the absence
of a market failure or other specific
problem, DOE nonetheless may be
required to establish standards under
existing law.
DOE’s preliminary analysis for GSFL
and IRL explicitly accounts for the
percentage of consumers that already
purchase more efficient equipment and
takes these consumers into account
when determining the national energy
savings associated with various
candidate standard levels. The
preliminary 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. DOE requests additional
data on, and suggestions for testing the
existence and extent of potential market
failure to complete an assessment of the
significance of these failures and, thus,
the net benefits of regulation. In
particular DOE seeks to verify the
estimates of the percentage of
consumers of all product types
purchasing efficient equipment and the
extent to which consumers will
continue to purchase more-efficient
equipment in future years.
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 in fact 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 already identified
the percentage of consumers that
already purchase more efficient lighting
products, DOE does not correlate the
consumer’s usage pattern and electricity
price with the efficiency of the
purchased product. Therefore, DOE
seeks data on the efficiency levels of
existing lamps in use by how often it is
utilized (e.g., how many hours the
product is used) and its associated
electricity price (and/or geographic
region of the country). 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.
Specifically, with respect to lighting
products, DOE believes several factors
contribute to the lack of consumer
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information. In the residential sector,
consumer purchases are often based on
wattage rather than lumen output which
may result in consumers not
purchasing, or rejecting higher-efficacy
or energy-saving lamp designs. For
example, consumers may not recognize
a higher-efficacy, reduced-wattage lamp
as fulfilling the same utility as their
higher-wattage lamp though both lamps
may have similar lumen outputs. For
this reason, these higher-efficiency
products may be unduly rejected in the
marketplace. In addition, in the
commercial and industrial sectors, the
complexity of GSFL systems may
introduce high information costs. GSFL
systems are composed of both lamps
and ballasts that may have a multitude
of varying properties such as lamp
wattage, lumen output, lifetime, and
ballast factor. These many numerous
variables impose high information costs
which may prevent purchasers from
selecting the most cost-effective GSFL
system. DOE seeks comment on
additional knowledge of the Federal
Energy Star program, and the program’s
potential as a resource for increasing
knowledge of the availability and
benefits of energy-efficient lamps in the
lighting consumer market.
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 the case of
lamps, in many instances the party
responsible for the lamp purchase may
not be the one who pays the cost to
operate it. For example, in the
commercial and industrial sectors,
building owners and developers may
make purchase decisions about lighting
fixtures which include ballasts and
lamps, but it may be the tenants who
pay the utility bills. Although renters
often have the opportunity to purchase
the replacement lamps, they are
severely limited in their choices by
prior fixture and ballast selections. If
there were no transactions costs, it
would be in the building developers’
and owners’ interests to install lighting
fixtures that renters would choose on
their own. For example, a tenant who
knowingly faces higher utility bills from
low-efficiency 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 it, or, in the case of the building
owner who installs the lamp system, to
convey that information to the renter.
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To the extent that asymmetric
information and/or high transactions
costs are problems, one would expect to
find certain outcomes with respect to
commercial and industrial lighting
energy efficiency. For example, other
things equal, one would not expect to
see higher rents for office space with
high-efficiency lighting systems.
Conversely, if there were symmetric
information, one would expect higher
energy efficiency lighting in commercial
space where the rent includes utilities,
as compared to those where the tenant
pays the utility bills separately.
Of course, there are likely to be
certain ‘‘external’’ benefits resulting
from the improved efficiency of units
that are not captured by the users of
such equipment. These include both
environmental and energy securityrelated externalities that are not already
reflected in energy prices, such as
reduced emissions of greenhouse gases
and reduced use of natural gas and oil
for electricity generation. DOE invites
comments on the weight that should be
given to these factors in DOE’s
determination of the maximum
efficiency level at which the total
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benefits are likely to exceed the total
costs resulting from a DOE 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
the owners of fluorescent lamps who
also pay for their electricity
consumption to purchase lamps that
exhibit higher energy efficiency
compared to lamps whose owners do
not pay for the electricity usage, other
things equal. To test for this form of
market failure, DOE needs data on
energy efficiency of such units and
whether the owner of the equipment is
also the one who pays the operating
costs. DOE is also interested in other
potential tests of market failure and data
that would enable such tests.
In addition, various other analyses
and procedures may apply to such
future rulemaking action, including
those required by the National
Environmental Policy Act (Pub. L. 91–
190, 42 U.S.C. 4321 et seq.); the
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Unfunded Mandates Act of 1995 (Pub.
L. 104–4); the Paperwork Reduction Act
(44 U.S.C. 3501 et seq.); the Regulatory
Flexibility Act (5 U.S.C. 601 et seq.);
and certain Executive Orders.
The draft of today’s action and any
other documents submitted to OMB for
review are part of the rulemaking record
and are available for public review at
the U.S. Department of Energy, Resource
Room of the Building Technologies
Program, Sixth Floor, 950 L’Enfant
Plaza, SW., Washington, DC (202) 586–
2945, between 9 a.m. and 4 p.m.,
Monday through Friday, except Federal
holidays.
VII. Approval of the Office of the
Secretary
The Secretary of Energy has approved
publication of today’s advance notice of
proposed rulemaking.
Issued in Washington, DC, on February 21,
2008.
Alexander A. Karsner,
Assistant Secretary, Energy Efficiency and
Renewable Energy.
[FR Doc. E8–4018 Filed 3–12–08; 8:45 am]
BILLING CODE 6450–01–P
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]]>Agencies
[Federal Register Volume 73, Number 50 (Thursday, March 13, 2008)]
[Proposed Rules]
[Pages 13620-13689]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: E8-4018]
[[Page 13619]]
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Part II
Department of Energy
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10 CFR Part 430
Energy Conservation Program: Energy Conservation Standards for General
Service Fluorescent Lamps and Incandescent Reflector Lamps; Proposed
Rule
��Federal Register / Vol. 73, No. 50 / Thursday, March 13, 2008 /
Proposed Rules��
[[Page 13620]]
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DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket No. 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: Advance notice of proposed rulemaking.
-----------------------------------------------------------------------
SUMMARY: The Energy Policy and Conservation Act authorizes the
Department of Energy (DOE) to establish energy conservation standards
for various consumer products and commercial and industrial equipment,
including general service fluorescent lamps and incandescent reflector
lamps, for which DOE determines that energy conservation standards
would be technologically feasible and economically justified, and would
result in significant energy savings. In this advance notice of
proposed rulemaking (ANOPR), DOE is considering amendment of existing
energy conservation standards for general service fluorescent lamps and
incandescent reflector lamps, and it is also considering whether
standards should apply to additional general service fluorescent lamps.
In addition, this ANOPR considers various amendments to lighting-
related definitions DOE previously developed and incorporated into the
CFR.
DATES: DOE held a public meeting in Washington, DC, that began on March
10, 2008. The agenda for the public meeting covered first the
concurrent test procedure rulemaking for general service fluorescent,
incandescent reflector, and general service incandescent lamps (see
proposal in today's Federal Register), and then this energy
conservation standards rulemaking for these lighting products.
DOE began accepting comments, data, and information regarding the
ANOPR at the public meeting and will continue to accept comments until,
but no later than April 14, 2008. See section V, ``Public
Participation,'' of this ANOPR for details.
ADDRESSES: The public meeting was held at the U.S. Department of
Energy, Forrestal Building, Room 8E-089, 1000 Independence Avenue, SW.,
Washington, DC 20585-0121.
Any comments submitted must identify the ANOPR for Lighting
Standards, and provide the docket number EE-2006-STD-0131 and/or
Regulatory Information Number (RIN) 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-0131
and/or RIN number 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, 6th Floor, 950 L'Enfant
Plaza, SW., 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 V 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, 6th Floor, 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. Please
call Ms. Brenda Edwards at (202) 586-2945 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.
Ms. Francine Pinto or Mr. Eric Stas, 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. Telephone:
(202) 586-9507. E-mail: Francine.Pinto@hq.doe.gov or
Eric.Stas@hq.doe.gov.
For information on how to submit or review public comments and on
how to participate in the public meeting, 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. Introduction
A. Purpose of the Advance Notice of Proposed Rulemaking
B. Authority
C. Summary of Proposed Coverage for Lamps
D. Overview of the Analyses Performed
1. Engineering Analysis and Product Price Determination
2. Energy-Use Characterization
3. Life-Cycle Cost and Payback Period Analyses
4. National Impact Analysis
E. Background
1. History of Standards Rulemaking for General Service
Fluorescent Lamps, Incandescent Reflector Lamps, and General Service
Incandescent Lamps
2. Energy Independence and Security Act of 2007
a. General Service Fluorescent Lamps
b. General Service Incandescent Lamps
c. Incandescent Reflector Lamps
d. Off Mode and Standby Mode Energy Consumption
3. Test Procedures
II. Consideration Regarding the Scope of Energy Conservation
Standards Coverage
A. Introduction
B. Additional General Service Fluorescent Lamps Being Considered
Under EPCA Section 325(i)(5)
1. Scope
2. Rationale for Coverage
3. Analysis of Individual General Service Fluorescent Lamps
C. Amended Definitions
1. ``Rated Wattage''
2. ``Colored Fluorescent Lamp''
III. Energy Conservation Standards Analyses for Fluorescent and
Incandescent Reflector Lamps
A. Market and Technology Assessment
1. Market Assessment
2. Product Classes
a. General Service Fluorescent Lamps
i. Class Setting Factors
ii. Other Potential Class-setting Factors Considered, But Not
Adopted
iii. Product Class Results
b. Incandescent Reflector Lamps
i. Class Setting Factors
ii. Other Potential Class-setting Factors Considered, But Not
Adopted
iii. Product Class Results
3. Technology Assessment
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
B. Screening Analysis
1. Technology Options Screened Out
a. Multi-photon Phosphors
b. Microcavity Filaments
c. Novel Filament Materials
d. Crystallite Filament Coatings
e. Luminescent Gases
f. Non-Tungsten-Halogen Regenerative Cycles
[[Page 13621]]
g. Infrared Phosphor Glass Coatings
h. Integrally Ballasted Low Voltage Lamps
i. Trihedral Corner Reflectors
2. Design Options Considered Further in Analysis
C. Engineering Analysis
1. Approach
2. Representative Product Classes and Baseline Lamps
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
3. Lamp and Lamp-and-Ballast Designs
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
4. Candidate Standard Levels
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Engineering Analysis Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
6. Scaling to Product Classes Not Analyzed
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
D. Energy-Use Characterization
1. Operating Hours
2. Results
E. Product Price Determination
1. Introduction and Methodology
a. Overview
b. General Service Fluorescent Lamps
c. Incandescent Reflector Lamps
2. End-User Price Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
3. Sales Taxes
F. Rebuttable Presumption Payback Periods
G. Life-Cycle Cost and Payback Period Analyses
1. Approach
2. Life-Cycle Cost Inputs
a. Total Installed Cost Inputs
b. Operating Cost, Replacement Cost, and Residual Value Inputs
i. Electricity Prices
ii. Lamp Lifetime
iii. Discount Rates
iv. Analysis Period
v. Effective Date
3. Payback Period Inputs
4. Lamp Purchasing Events
5. Life-Cycle Cost and Payback Period Results
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
H. Shipment Analysis
1. Historical Shipments
2. Shipment Projections to 2011 and Calculations of Stock of
Lamps in 2011
3. Base-Case and Standards-Case Shipment Forecasts to 2042
4. Market-Share Matrices
a. General Service Fluorescent Lamps
b. Incandescent Reflector Lamps
5. Shipment Forecast Results
I. National Impact Analysis
1. Approach
2. Base-Case and Standards-Case Forecasted Efficacies
3. National Impact Analysis Inputs
4. National Impact Analysis Results
J. Life-Cycle Cost Subgroup Analysis
K. Manufacturer Impact Analysis
1. Cumulative Regulatory Burden
2. Preliminary Results of the Manufacturer Impact Analysis
a. Retooling Equipment to Produce Standards-Compliant Lamps
b. Availability of Materials to Produce Standards-Compliant
Lamps
c. Maintaining Product Availability and Features
L. Utility Impact Analysis
M. Employment Impact Analysis
N. Environmental Assessment
O. Regulatory Impact Analysis
IV. Candidate Energy Conservation Standards Levels
V. Public Participation
A. Submission of Comments
B. Issues on Which DOE Seeks Comment
1. Consideration of Additional General Service Fluorescent Lamps
2. Amended Definitions
3. Product Classes
4. Scaling to Product Classes Not Analyzed
5. Screening of Design Options
6. Operating Hours
7. General Service Fluorescent Energy Consumption
8. Life-Cycle Cost Calculation
9. Installation Costs
10. Base-Case Market-Share Matrices in 2012
11. Shipment Forecasts
12. Base-Case and Standards-Case Forecasted Efficiencies
13. Trial Standard Levels
14. Lamp Production Equipment Conversion Timeframe
VI. Regulatory Review and Procedural Requirements
VII. Approval of the Office of the Secretary
Acronyms and Abbreviations
AEO Annual Energy Outlook
ANOPR advance notice of proposed rulemaking
ANSI American National Standards Institute
BEF ballast efficacy factor
BF ballast factor
BR bulged reflector (reflector lamp shape)
CBECS Commercial Buildings Energy Consumption Survey
CCT correlated color temperature
CEC California Energy Commission
CEE Consortium for Energy Efficiency
CFR Code of Federal Regulations
CFL compact fluorescent lamp
CIE International Commission on Illumination
CO2 carbon dioxide
CRI color rendering index
CSL candidate standard level
DOE U.S. Department of Energy
E26 Medium screw-base (incandescent lamp base type)
EIA Energy Information Administration
EISA 2007 Energy Independence and Security Act of 2007
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)
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
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
I-O input-output
IR Infrared
IRL incandescent reflector lamp
K degrees Kelvin
LCC life-cycle cost
Lm lumens
LMC U.S. Lighting Market Characterization Volume I
Lm/W lumens per watt
MECS Manufacturer Energy Consumption Survey (MECS)
MIA Manufacturer Impact Analysis
NAICS North American Industry Classification System
NEEP Northeast Energy Efficiency Partnership
NEMA National Electrical Manufacturers Association
NEMS National Energy Modeling System
NES national energy savings
NIA National Impact Analysis
NOPR notice of proposed rulemaking
NOX nitrogen oxides
NPV net present value
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
R reflector (reflector lamp shape)
RECS Residential Energy Consumption Survey
SBA Small Business Administration
SO2 sulfur dioxide
T5, T8, T10, T12 tubular fluorescent lamps, diameters of 0.625, 1, 1.25
or 1.5 inches, respectively
TSD technical support document
TSL trial standard level
U.S.C. United States Code
UV ultraviolet
V volts
W watts
I. Introduction
This advance notice of proposed rulemaking (ANOPR) serves two
[[Page 13622]]
primary purposes: (1) Providing a preliminary determination regarding
additional general service fluorescent lamps (GSFL) that DOE is
considering for coverage and standards; and (2) initiating rulemaking
to consider amending DOE's energy conservation standards related to
coverage of GSFL and incandescent reflector lamps (IRL). The ANOPR is
intended to help DOE satisfy two statutory directives, namely to make a
preliminary determination representing the Secretary's initial
assessment of additional GSFL to consider for energy conservation
standards under section 325(i)(5) of the Energy Policy and Conservation
Act (hereinafter ``EPCA'') (42 U.S.C. 6295(i)(5)), and to conduct an
energy conservation standards rulemaking for general service
fluorescent lamps and incandescent reflector lamps under Section
325(i)(3) of EPCA (42 U.S.C. 6295(i)(3)). Because the preliminary
determination for certain additional lamps is positive, DOE is
including such lamps in the ANOPR analyses for standard-setting
purposes.
DOE welcomes comment on any relevant issue related to this ANOPR.
However, throughout this Federal Register notice, DOE identifies
specific areas and issues on which it specifically invites comment.
These critical issues are summarized in section V.E of this notice.
A. Purpose of the Advance Notice of Proposed Rulemaking
The purpose of the ANOPR is to provide interested parties with an
opportunity to comment on:
1. The preliminary determination of additional GSFL being
considered for energy conservation standards;
2. The product classes DOE is planning to analyze in this
rulemaking;
3. The analytical framework, methodology, inputs, and models (e.g.,
life-cycle cost (LCC) and national impact analysis (NIA) spreadsheets)
that DOE developed to evaluate energy conservation standards for GSFL
and IRL (collectively referred to in this ANOPR as the ``two categories
of lamps'');
4. The analyses conducted for the ANOPR, including the preliminary
results for the engineering analysis, product price determination, LCC
and payback period (PBP) analysis, and NIA. These analyses are
summarized in this ANOPR and presented in detail in the ANOPR technical
support document (TSD), Energy Conservation Standards for General
Service Fluorescent Lamps and Incandescent Reflector Lamps,\1\
published in tandem with this ANOPR; and
---------------------------------------------------------------------------
\1\ To view the technical support document for this rulemaking,
visit DOE's website at: https://www.eere.energy.gov/buildings/
appliance_standards/residential/incandescent_lamps.html.
---------------------------------------------------------------------------
5. The candidate standard levels (CSLs) that DOE developed for the
ANOPR.
B. Authority
Title III of EPCA (42 U.S.C. 6291 et seq.) sets forth a variety of
provisions designed to improve energy efficiency. Part B of Title III
(42 U.S.C. 6291-6309) established the ``Energy Conservation Program for
Consumer Products Other Than Automobiles,'' which includes major
household appliances. Subsequent amendments expanded Title III of EPCA
to include additional consumer products and certain commercial and
industrial equipment, including certain fluorescent and incandescent
lamps--the products that are the focus of this document. In particular,
amendments to EPCA in the Energy Policy Act of 1992 (EPACT 1992), P.L.
102-486, established energy conservation standards for certain classes
of GSFL and IRL, and authorized DOE to amend these standards if such
amendments were warranted. (42 U.S.C. 6291(1), 6295(i)(1) and (3)-(4))
The same EPACT 1992 amendments to EPCA also authorized DOE to adopt
standards for additional GSFL and general service incandescent lamps
(GSIL), if such additional standards were warranted. (42 U.S.C.
6295(i)(5)) Subsequent amendments to EPCA in the Energy Independence
and Security Act of 2007 (EISA 2007), P.L. 110-140, amended the
existing energy conservation standards for IRL and removed DOE's
authority under 42 U.S.C. 6295(i)(5) to adopt standards for additional
GSIL.
Before DOE establishes any new or amended energy conservation
standards, it must first solicit public comments on a proposed
standard. EPCA, as amended, specifies that any new or amended energy
conservation standard that DOE prescribes for consumer products shall
be designed to ``achieve the maximum improvement in energy efficiency *
* * which the Secretary [of Energy] determines is technologically
feasible and economically justified.'' (42 U.S.C. 6295(o)(2)(A))
Moreover, EPCA states that the Secretary of Energy (the Secretary) may
not establish an amended standard if such standard would not result in
``significant conservation of energy,'' or ``is not technologically
feasible or economically justified.'' (42 U.S.C. 6295(o)(3)(B)) To
determine whether a proposed standard is economically justified, DOE
must, after receiving comments on the proposed standard, determine
whether the benefits of the standard exceed its burdens to the greatest
extent practicable, weighing the following seven statutory factors:
(1) The economic impact of the standard on manufacturers and
consumers of the product subject to the standard;
(2) The savings in operating costs throughout the estimated average
life of the covered product in the type (or class) compared to any
increase in the price, initial charges, or maintenance expenses for the
covered product that are likely to result from the imposition of the
standard;
(3) The total projected amount of energy savings (or, as
applicable, water savings) likely to result directly from the
imposition of the standard;
(4) Any lessening of the utility or the performance of the covered
product 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))
C. Summary of Proposed Coverage for Lamps
DOE's regulations currently set energy efficiency standards for
certain classes of general service fluorescent lamps and incandescent
reflector lamps. 10 CFR 430.32(n). However, section 325(i)(5) of EPCA
directs the Secretary of Energy to consider whether the standards in
effect for GSFL should be amended so as to apply to ``additional
general service fluorescent lamps.'' (42 U.S.C. 6295(i)(5)).
Accordingly, in section II of this notice, DOE presents its preliminary
determination regarding additional lamps that may be considered as part
of the standards rulemaking. Section II provides a summary of DOE's
authority under EPCA to consider additional lamps for coverage. In
addition, because the preliminary determination was positive, section
II also presents, by lamp type, the additional lamps for which DOE
intends to consider setting standards.
[[Page 13623]]
D. Overview of the Analyses Performed
As noted above, EPCA authorizes DOE to consider establishing or
amending energy conservation standards for various consumer products
and commercial and industrial equipment, including the two categories
of lamps that are the subject of this ANOPR. For each of these
products, DOE conducted key technical analyses for this ANOPR in the
following areas: (1) Engineering; (2) energy-use characterization; (3)
product price determination; (4) LCC and PBP analyses; and (5) NIA. DOE
performed a separate set of the requisite analyses for each of the two
categories of lamps examined in this rulemaking. This ANOPR presents
the methodology and results of each of these analyses (first an
overview, followed by a more in-depth discussion).
For each type of analysis, Table I.1 identifies the sections in
this document that summarize the methodologies, key inputs, and
assumptions for the analysis. In addition, DOE conducted several other
analyses that either support the five analyses discussed above or are
preliminary analyses that will be expanded upon during the NOPR stage
of this rulemaking. These analyses include the market and technology
assessment, a screening analysis which contributes to the engineering
analysis, and the shipments analysis which contributes to the national
impacts analysis. In addition to these analyses, DOE has begun some
preliminary work on the life-cycle cost subgroup analysis, manufacturer
impact analysis, utility impact analysis, employment impact analysis,
environmental assessment analysis, and the regulatory impact analysis
for the ANOPR. These analyses will be expanded upon during the NOPR
stage of this rulemaking.
DOE consulted with interested parties as part of its process for
conducting all of the analyses for the ANOPR and invites further input
from the public on these topics. While obtaining such input is the
primary purpose of this stage of the rulemaking, this notice also
contains a synopsis of the preliminary analytical results. (The TSD
contains a complete set of results.) The purpose of publishing these
preliminary results in this notice is to: (1) Facilitate public comment
on DOE's analytical methodology; (2) illustrate the level of detail
found in the TSD; and (3) invite comment on the structure and the
presentation of those results. The preliminary analytical results
presented in the ANOPR are subject to revision following review and
input from the public.
Table I.--1 Key Technical Analyses Conducted for the ANOPR
----------------------------------------------------------------------------------------------------------------
ANOPR section and
Analysis area Methodology Key inputs \2\ Key assumptions TSD chapter
----------------------------------------------------------------------------------------------------------------
Engineering Analysis............ Design option Published catalog Analysis can be Section III.C and
analysis to data on extended to TSD Chapter 5.
establish lamp performance product classes
and lamp-and- values such as and efficiency
ballast designs operating life, levels for which
at each CSL. rated power, DOE did not
efficacy, and conduct analysis;
light output. ballast system
power varies
linearly by
ballast factor.
Energy-Use Characterization..... Multiply lamp Annual operating Data sources are Section III.D and
power, or lamp- hours by lamp indicative of TSD Chapter 6.
and-ballast type; lamp, or current lighting
system power, by lamp and ballast, use.
annual operating energy
hours. consumption.
Energy
Information
Administration
(EIA) 2001, 2002,
and 2003 survey
data and 2002
U.S. Lighting
Market
Characterization
Study Vol. I.
Product Price Determination..... Mark up Manufacturer price Future pricing for Section III.E and
manufacturer schedules. more efficacious TSD Chapter 7.
price schedules Publicly products will
to develop low, available reflect discounts
medium, and high discount used with today's
end-user retail schedules from commodity
prices. State procurement products.
contracts and
other users.
Life-cycle Cost and Payback Use Monte Carlo Lamp and ballast AEO 2007 basis for Section III.G and
Period Analyses. simulation in installation energy price TSD Chapter 8.
combination with costs; annual forecasts and EIA
inputs that are energy 2005 basis for
characterized consumption; distribution of
with probability electricity electricity
distributions to prices and future prices; average
establish a trends; product discount rate is
distribution of lifetimes; 5.6% for the
consumer economic discount rates; residential
impacts (i.e., consumer ``lamp sector, 6.2% for
LCC savings and purchasing the commercial
PBP); capture events'' that sector, and 7.5%
variability in cause purchase of for the
annual energy a new lamp / industrial sector.
use; correlate system; building
electricity samples based on
prices with the EIA's
building samples Commercial
to capture Building Energy
regional and Consumption
sector-specific Survey (CBECS),
variability; use EIA's Residential
residual value to Energy
account for any Consumption
remaining life of Survey (RECS),
a lamp at the end and EIA's
of the analysis Manufacturing
period; report Energy
LCC savings by Consumption
event type and Survey (MECS) and
CSL. the U.S. Lighting
Market
Characterization
Vol. I (LMC).
[[Page 13624]]
National Impact Analysis and Forecasts of Historical and Annual shipments; Sections III.H and
Shipment Analysis. national GSFL and forecasted annual forecasted base- III.I; TSD
IRL costs and shipments; lamp case and Chapters 9 and
energy stock; total standards-case 10.
consumption; installed product efficacy
forecast costs; unit improvements
shipments through annual energy based on market-
the use of a consumptions; share matrices
stock accounting AEO2007 energy and historical
model. DOE used price forecasts; trends; AEO2007
the lamp purchase site-to-source basis for site-to-
events to divide conversion source conversion
the market into factors for factors; discount
segments--new electricity; rates are 3
construction, discount rate; percent and 7
replacements, and HVAC interaction, percent real;
early retrofit and rebound future costs
(only for GSFL); effect. discounted to
use multiple present year
scenarios to (2007).
forecast the
technology mix of
lamps (and
ballasts) sold at
each CSL.
----------------------------------------------------------------------------------------------------------------
1. Engineering Analysis and Product Price Determination
DOE uses the engineering analysis and product price determination
together to characterize the relationship between the end-user
(consumer) price and the efficiency of the product DOE evaluates for
standards. The relationship between the efficiency of a product and the
price of that product is essential in determining the relative cost of
a more efficient product over its lifetime (i.e., the purchase price of
the product plus maintenance and operating costs) as compared to a less
efficient product. This calculation is necessary to determine whether
individual consumers and the nation will benefit under an efficiency
standard. DOE's approach to these analyses is explained briefly below.
---------------------------------------------------------------------------
\2\ The data sources cited in this table were the most current
available at the time DOE prepared this ANOPR. In the future, should
more up-to-date sources become available, DOE will incorporate those
more up-to-date sources into its analysis.
---------------------------------------------------------------------------
The engineering analysis identifies the representative baseline
lamps, or lamp-and-ballast combinations, that DOE will evaluate in the
engineering analysis. The term ``baseline'' refers to a lamp (or lamp-
and-ballast system) that has features and technologies typically found
in equipment currently offered for sale and is representative of the
characteristics of products in a given product class; for products
which are already subject to an energy efficiency standard, the
baseline unit is typically one which just meets the current regulatory
requirement.
DOE based the product price determination for lamps and ballasts on
marked-up manufacturer price schedules, developing low, medium, and
high end-user retail prices. Section III.C and Chapter 5 of the TSD
discuss the engineering analysis, and section III.E and Chapter 7 of
the TSD discuss the product price determination in further detail.
2. Energy-Use Characterization
The energy-use characterization provides estimates of annual energy
use for the two categories of lamps which are the subject of the
present rulemaking. DOE uses these estimates in the LCC and PBP
analyses, as well as the NIA. To develop annual energy use estimates,
DOE multiplied annual usage (in hours per year) by the system power
estimates (in watts). In order to obtain the inputs for these
calculations, DOE took the following steps. DOE developed the system
power estimates in the engineering analysis. To derive annual energy
usage, DOE used data published in the U.S. Lighting Market
Characterization: Volume I (LMC) \3\, the Residential Energy
Consumption Survey (RECS) \4\, the Commercial Building Energy
Consumption Survey (CBECS) \5\, and the Manufacturer Energy Consumption
Survey (MECS) \6\. More detail on the calculation of operating hours is
available in section III.D.1 of this notice, and Chapter 6 of the TSD.
---------------------------------------------------------------------------
\3\ 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: www.eere.energy.gov/buildings/info/documents/pdfs/
lmc_vol1_final.pdf.
\4\ 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.
\5\ 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.
\6\ 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.
---------------------------------------------------------------------------
3. Life-Cycle Cost and Payback Period Analyses
The LCC and PBP analyses determine the economic impact of potential
standards on individual consumers. The LCC is the total consumer
expense for a product over the life of the product (i.e., purchase
price plus maintenance and operating costs). The LCC analysis compares
the LCC of products and equipment designed to meet possible energy
conservation standards with the LCC of the products and equipment
likely to be installed in the absence of standards.
The PBP represents the number of years required to recover the
increase in purchase price (including installation cost) of a more-
efficient product through savings in the operating cost of the product.
The PBP is calculated by dividing the change in total installed cost
due to increased efficacy by the change in annual operating cost from
increased efficacy. More detail on the calculation of LCC and PBP is
available in section III.G of this notice and Chapter 8 of the TSD.
4. National Impact Analysis
The NIA estimates the national energy savings (NES) and the net
present value (NPV) of total customer costs and savings expected to
result to the nation from new standards at specific efficiency levels.
Stated another way, in the NIA, DOE calculates NES and NPV for any
given potential standard level for each of the two categories of lamps
as the difference between a base-case forecast (i.e., without new
standards) and the standards-case forecast (i.e., with new standards).
To start, DOE determines national annual energy consumption by
multiplying the
[[Page 13625]]
number of units in use which are expected to be purchased after the
standard takes effect by their average unit energy consumption. Using
that input, the NES is calculated as the sum of the cumulative annual
energy savings over the analysis period (2012-2042).\7\ The national
NPV is then calculated from the discounted net savings each year for
the products purchased over that same analysis period. The NPV sums the
discounted net savings each year, consisting of the difference between
the savings in total operating costs and increases in total installed
costs. More detail on the NIA is available in sections III.H and III.I
of this notice and Chapters 9 and 10 of the TSD.
---------------------------------------------------------------------------
\7\ DOE uses 31 years as the time period of analysis for its NES
calculations in many of its rulemakings, in order to enable
stakeholders to understand the relative magnitude of energy savings
potentials of the various products and standard levels being
considered.
---------------------------------------------------------------------------
E. Background
1. History of Standards Rulemaking for General Service Fluorescent
Lamps, Incandescent Reflector Lamps, and General Service Incandescent
Lamps
As noted above, EPCA established energy conservation standards for
GSFL, requiring that certain fluorescent lamps meet prescribed minimum
efficacy levels and minimum color rendering index (CRI) levels. EPCA
also established efficacy standards for certain IRL. (42 U.S.C.
6295(i)(1)) For both categories of lamps, EPCA requires that DOE
conduct two cycles of rulemakings to determine whether the standards
should be amended. (42 U.S.C. 6295(i)(3)-(4)) In addition, EPCA
provides that within 24 months after U.S. Federal Trade Commission
(FTC) labeling requirements become effective for GSFL and GSIL, DOE
must initiate a rulemaking to determine if the standards in effect for
fluorescent and incandescent lamps should be amended so that they would
be applicable to additional general service fluorescent lamps. (42
U.S.C. 6295(i)(5)) Within 18 months of initiating the rulemaking, EPCA
further requires DOE to publish a final rule containing such amendment,
if any. (42 U.S.C. 6295(i)(5)) The FTC published a final rule
establishing labeling requirements for covered lamps on May 13, 1994,
with an effective date of May 15, 1995. 59 FR 25176.
In this rulemaking, DOE is addressing two statutory directives
under 42 U.S.C. 6295(i). First, DOE is reviewing and deciding whether
to amend EPCA's prescribed energy conservation standards for GSFL and
IRL. (42 U.S.C. 6295(i)(3)) Second, DOE is reviewing whether energy
conservation standards should be made applicable to additional GSFL.
(42 U.S.C. 6295(i)(5))
To initiate the current energy conservation standards rulemaking,
on May 31, 2006, DOE published on its Web site the Rulemaking Framework
Document for General Service Fluorescent Lamps, Incandescent Reflector
Lamps, and General Service Incandescent Lamps \8\ (``Framework
Document''), which describes the procedural and analytical approaches
it anticipated using to evaluate potential energy conservation
standards for these products.\9\ DOE published a notice to announce the
availability of the Framework Document, to schedule a public meeting on
the planned analytical framework for this rulemaking (hereafter,
``Public Meeting''), and to invite written comments concerning this
analytical framework. The title of that Federal Register notice
published on May 31, 2006 is ``Energy Conservation Standards for
General Service Fluorescent Lamps, Incandescent Reflector Lamps, and
General Service Incandescent Lamps: Notice of Public Meeting and
Availability of the Framework Document,'' \10\--71 FR 30834.
---------------------------------------------------------------------------
\8\ 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.
\9\ At the time of publication of the Framework Document, EPCA
gave DOE authority to consider energy conservation standards for
additional GSIL under 42 U.S.C. 6295(i)(5). However, subsequent
amendments to EPCA in EISA 2007 removed that authority.
\10\ This rulemaking notice is available at: https://
www.eere.energy.gov/buildings/appliance_standards/residential/
incandescent_lamps.html.
---------------------------------------------------------------------------
A Public Meeting was held on June 15, 2006, whose purpose was to
discuss the analyses and issues identified in various sections of the
Framework Document. At the Public Meeting, DOE described the different
analyses it would conduct, such as the LCC and PBP analyses, the
methods it planned to employ when conducting them, and the relationship
among the various analyses.\11\ Manufacturers, trade associations,
environmental advocates, and other interested parties attended the
Public Meeting. Issues discussed included: (1) The rulemaking's scope
of coverage and definition of exclusions; (2) the development of
product classes; (3) lamp-life variation; (4) selection of
representative lamps for analysis and baseline models; (5) appropriate
methods and sources for developing end-user price estimates; (6) test
procedures; (7) the methodology for developing shipment estimates; (8)
the need for systems analysis for GSFL (i.e., analyzing a lamp and a
ballast in some scenarios); (9) the impact of higher efficacy lamps on
building space conditioning loads; and (10) the use of average
electricity rates. Comments submitted during the Framework Document
comment period elaborated upon these major issues raised at the June
2006 Public Meeting. DOE worked with its contractors to address these
issues in the ANOPR analyses.
---------------------------------------------------------------------------
\11\ PDF copies of the slides and other material associated with
the public meeting are available at: https://www.eere.energy.gov/
buildings/appliance_standards/residential/lamps_meeting_
061506.html.
---------------------------------------------------------------------------
Comments received in response to the Framework Document helped
identify further issues involved in this rulemaking, and such input
contributed to the overall analytical process. This document summarizes
the comments DOE has received to date, each with a parenthetical
reference at the end citing the location of the item in the docket for
this rulemaking (i.e., the public record).
2. Energy Independence and Security Act of 2007
On December 19, 2007, during the ANOPR phase of this rulemaking,
the Energy Independence and Security Act of 2007 was signed into law.
In relevant parts, EISA 2007 amends various EPCA provisions regarding
GSFL, IRL, and GSIL, and considerably changes the scope of this
rulemaking and the structure of DOE's ANOPR analyses. Accordingly, DOE
has incorporated these changes in both the preliminary determination
and energy conservation standards analyses contained in this ANOPR. DOE
notes that the relevant amendments in EISA 2007 are effective on the
date prescribed by the legislation, not on the effective date of this
rulemaking.
As stated earlier, in May 2006 DOE published a Framework Document
outlining the procedural and analytical approaches it anticipated using
for this rulemaking. In addition, DOE received both written and oral
comments in response to the Framework Document. Due to the recent
amendments to EPCA in EISA 2007, the scope of coverage and analytical
approach presented in this ANOPR by necessity differs from that which
was previously outlined in the Framework Document. In addition, given
these latest legislative amendments, numerous comments submitted no
longer hold relevance to this rulemaking and, therefore, are not
addressed in this ANOPR. The following section summarizes various
sections of EISA 2007 relevant to this rulemaking and discusses their
effect on the preliminary determination and
[[Page 13626]]
ANOPR analyses contained in this notice.
a. General Service Fluorescent Lamps
Regarding GSFL, section 316(b) of EISA 2007 amends section
321(30)(B)(viii) of EPCA (42 U.S.C. 6291(30)(B)(viii)) by modifying the
definition of ``general service fluorescent lamp'' so as to exclude
lamps with a CRI of 87 or greater (as compared to the previous
exclusion for lamps with a CRI of 82 or greater). This amendment
effectively changes the scope of coverage of energy conservation
standards for GSFL to now include additional fluorescent lamps with a
CRI rating from 82 up to 87. The ANOPR analyses reflect this change in
scope of coverage by analyzing lamp designs with CRI ratings up through
86 and also by accounting for the national impacts due to the
regulation of this full range of GSFL.
In addition, section 322(b) of EISA 2007 amends section 325(i) of
EPCA (42 U.S.C. 6295(i)) by moving the table of efficacy requirements
for fluorescent lamps from section 325(i)(1)(A) to section
325(i)(1)(B). However, every aspect of the table is identical to the
previous standard as enacted by EPACT 1992, including the product
groupings, and the minimum efficacy and CRI requirements.\12\
Therefore, the amendment in section 322(b) of EISA 2007 results in no
substantive change in DOE's approach toward GSFL. Furthermore, the
legislation does not modify the authority to consider extending
coverage to additional GSFL under section 325(i)(5) of EPCA (42 U.S.C.
6295(i)(5)).
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\12\ These CRI requirements reflect minimum CRI standards for
covered fluorescent lamps. These minimum requirements are not
affected by the exclusion in the definition of ``general service
fluorescent lamp'' for lamps with a CRI of 87 or greater, as amended
by EISA 2007.
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b. General Service Incandescent Lamps
Regarding GSIL, section 321(a)(1) of EISA 2007 amends section
321(30) of EPCA (42 U.S.C. 6291(30)) by deleting the existing
definition and inserting a new definition for ``general service
incandescent lamp.'' In the context of redefining ``general service
incandescent lamp,'' this section also introduces new definitions for
several lighting-related terms, some of which were previously defined
by DOE in the CFR. Definitions contained in section 321(a)(1) of EISA
2007 relevant to this rulemaking include the following terms: (1)
``Modified spectrum;'' (2) ``rough service lamp;'' (3) ``vibration
service lamp;'' and (4) ``colored incandescent lamp.'' The effect that
the incorporation of these definitions has on this rulemaking will be
discussed in section I.E.2.c of this notice.
In addition, section 321(a)(3) amends section 325 of EPCA (42
U.S.C. 6295) by prescribing separate energy conservation standards and
minimum rated lifetimes for general service incandescent lamps and
modified spectrum general service incandescent lamps, with effective
dates ranging from January 1, 2012 to January 1, 2014. In addition,
this section also directs DOE to conduct two future standards
rulemakings to review and possibly amend the standards. Furthermore,
although EPACT 1992 gave DOE authority under 42 U.S.C. 6295(i)(5) to
consider additional general service incandescent lamps for energy
conservation standards coverage, section 321(a)(3) of EISA 2007 amends
section 325(i)(5) of EPCA and removes this provision. Accordingly, DOE
has terminated its preliminary determination regarding the expansion of
scope to additional GSIL. In addition, as EISA 2007 prescribed energy
conservation standards for GSIL, this ANOPR does present any analyses
or candidate standard levels related to GSIL.
c. Incandescent Reflector Lamps
Regarding IRL, section 322(a)(1) of EISA 2007 amends section
321(30)(C)(ii) of EPCA (42 U.S.C. 6291(30)(C)(ii)) by modifying the
portion of the definition of ``incandescent lamp'' which is applicable
to reflector lamps so as to expand that definition to include lamps
with a diameter between 2.25 and 2.75 inches, as well as BPAR-, ER-,
and BR-shaped lamps. In addition, section 322(a)(2) of EISA 2007 adds
new statutory definitions for a BPAR incandescent reflector lamp, a BR
incandescent reflector lamp, and an ER incandescent reflector lamp.
These new statutory definitions supersede the existing CFR definitions
for ``ER incandescent reflector lamp'' and ``BR incandescent reflector
lamp'' that were developed by DOE (62 FR 29221 (May 29, 1997)), and
thereby remove DOE's authority to amend these definitions.
In addition, section 322(b) of EISA 2007 amends section 325(i) of
EPCA (42 U.S.C. 6295(i)) by moving the table of minimum average lamp
efficacy requirements for IRL from section 325(i)(1)(A) to section
325(i)(1)(B). However, as noted above for GSFL, every aspect of this
table of IRL efficacy requirements is identical to the previous
standard as enacted by EPACT 1992. Section 322(b) also amends EPCA to
incorporate several new exemptions to the IRL standards in a newly-
adopted section 325(i)(1)(C) of EPCA. These exemptions are as follows:
(1) Lamps rated at 50 watts or less that are ER30, BR30, BR40, and
ER40; (2) lamps rated at 65 watts that are BR30, BR40, or ER40 lamps;
and (3) R20 incandescent reflector lamps rated 45 watts or less. DOE
notes that the expanded scope of IRL, as presented in EISA 2007, is
consistent the proposal contained in a joint comment submitted by the
American Council for an Energy Efficient Economy (ACEEE) and the
National Electrical Manufacturers Association (NEMA) regarding this
rulemaking. (ACEEE and NEMA, No. 14 at pp. 3-8) The effective date of
energy conservation standards for BPAR, ER, and BR shaped lamps as
prescribed by EISA 2007 is January 1, 2008. The effective date of
standards for smaller diameter IRL as prescribed by EISA 2007 (i.e.,
diameter of more than 2.25 inches, but not more than 2.75 inches) is
the later of January 1, 2008 or 180 days after the date of enactment of
EISA 2007. Given that EISA 2007 was enacted on December 19, 2007, the
effective date of these standards for smaller diameter IRL is June 16,
2008. In both of these cases, the EISA 2007 standards come into effect
well before an amended IRL standard (as would be prescribed by this
rulemaking) would come into effect. DOE's draft ANOPR analyses were
modified to account for this expanded scope of IRL coverage by
selecting IRL baselines which DOE expects to be the least efficacious
covered lamp design that would comply with the amended standard. In
addition, DOE updated its IRL shipment forecasts in response to EISA
2007 to account for both the expansion of scope for Federally-regulated
reflector lamps and the exemptions to the standards.
In addition, it is also important to note that, as previously
discussed, EISA 2007 introduced statutory definitions for ``rough
service lamp,'' ``vibration service lamp,'' and ``colored incandescent
lamp,''--lamp types which are explicitly excluded from the definition
of ``incandescent reflector lamp,'' as contained in the referenced
definition of ``incandescent lamp.'' DOE had previously developed and
adopted into the CFR definitions for these three terms in the context
of IRL; however, as previously mentioned, these DOE definitions are now
superseded by the statutory definitions in EISA 2007. As these terms
are used to define that portion of the definition of ``incandescent
lamp'' that corresponds to the definition of ``incandescent reflector
lamp,'' any amendments to these terms affect the scope of energy
[[Page 13627]]
conservation standards coverage of IRL. In examining the new
definitions for ``rough service lamp'' and ``vibration service lamp,''
DOE recognizes that they differ from the earlier CFR definitions DOE
had adopted. In response to the changes to these definitions, DOE
attempted to account for these changes in the ANOPR analyses.
Similarly, the new EISA 2007 definition for ``colored incandescent
lamp'' effectively expands the scope of coverage for IRL. That is, IRL
containing five percent or more of neodymium content and plant light
IRL are now subject to energy conservation standards. DOE accounts for
this expanded coverage of IRL by creating a separate product class for
these lamps, termed ``modified spectrum lamps.'' This decision to treat
modified spectrum lamps separately is consistent with the approach
taken in EISA 2007 with respect to GSIL.
Finally, although EPACT 1992 gave DOE authority under U.S.C.
6295(i)(5) to consider additional general service incandescent lamps
(which included IRL) for energy conservation standards coverage,
section 321(a)(3) of EISA 2007 has amended section 325(i)(5) of EPCA to
remove this provision. Accordingly, DOE has terminated its preliminary
determination regarding the expansion of scope to additional GSIL and
IRL. However, as discussed above, in the ANOPR analyses, DOE accounts
for the new scope of coverage for IRL for purposes that remain relevant
to this rulemaking (i.e., considering amended efficacy standards for
all covered IRL).
d. Off Mode and Standby Mode Energy Consumption
In addition to the specific relevant actions described above, EISA
2007 also places various requirements on all covered products. Of
particular note here, section 310(3) of EISA 2007 amends section 325 of
EPCA (42 U.S.C. 6295) by mandating that any final rule establishing or
revising a standard for a covered product that is adopted after July 1,
2010 shall incorporate standby mode and off mode energy use into the
standard, if feasible. DOE notes that final rule for this energy
conservation standards rulemaking on fluorescent and incandescent lamps
is scheduled for publication by June 2009. In addition, after careful
review, DOE has preliminarily determined that for the GSFL and IRL
which are the subjects of this rulemaking, current technologies for
these products do not employ 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'' \13\ applicable to both GSFL and IRL, the
lamp must be entirely disconnected from the main power source (i.e.,
the lamp is switched off) in order not to provide any active mode
function (i.e., emit light), thereby meeting the second provision in
the definition of ``off mode.'' However, if the lamp is disconnected
from the main power source, the lamp clearly does not satisfy the
requirements of operating in off mode. In addition, DOE believes that
all covered products that meet the definitions of ``GSFL'' and ``IRL''
are single-function products and do not offer any secondary user-
oriented or protective functions. Therefore, DOE has tentatively
concluded that it is not feasible to incorporate off mode or standby
mode energy use into the energy conservation standards for GSFL and
IRL. DOE welcomes comment on its understanding of off mode and standby
mode energy consumption for the products addressed by this rulemaking.
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\13\ In amending 42 U.S.C. 6295(gg)(1)(a)(i), (ii), and (iii),
EISA 2007 defines ``active mode,'' ``off mode,'' and ``standby
mode'' as follows: `` The term `active mode' means the condition in
which an energy-using product--(I) is connected to a main power
source; (II) has been activated; and (III) provides 1 or more main
functions.'' ``The term `off mode' means the condition in which an
energy-using product--(I) is connected to a main power source; and
(II) is not providing any stand-by or active mode function.'' ``The
term `standby mode' means the condition in which an energy-using
product--(I) is connected to a main power source; and (II) offers 1
or more of the following user-oriented or protective functions: (aa)
To facilitate the activation or deactivation of other functions
(including active mode) by remote switch (including remote control),
internal sensor, or timer. (bb) Continuous functions including
information or status displays (including clocks) or sensor-based
functions.''
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3. Test Procedures
DOE test procedures outline the method by which manufacturers must
determine the efficiency of their products and equipment, and thereby
assess and certify compliance with the energy conservation standards
adopted pursuant to EPCA. DOE established test procedures for
fluorescent and incandescent lamps in a final rule published in the
Federal Register on May 29, 1997 (hereafter ``1997 Test Procedure Final
Rule''). 62 FR 29222 (adopting 10 CFR part 430, Subpart B, Appendix R
\14\). In addition, the test procedures incorporate by reference
American National Standards Institute (ANSI), Illuminating Engineering
Society of North America (IESNA), and International Commission on
Illumination (CIE) standards to measure lamp efficacy and CRI. In their
totality, the DOE test procedures provide detailed instructions for
measuring the performance of GSFL and IRL and certain performance
attributes of GSIL.
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\14\ ``Uniform Test Method for Measuring Average Lamp Efficiency
(LE) and Color Rendering Index (CRI) of Electric Lamps.''
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The National Electrical Manufacturers Association (NEMA) submitted
a comment identifying what it perceived to be problems with several of
the industry standards incorporated in DOE's test procedures.
Specifically, NEMA stated that many of the standards referenced in the
test procedures are outdated, have been replaced, or are no longer
available. (NEMA, No. 12 at pp. 2-4) \15\
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\15\ A notation in the form ``NEMA, No. 12 at pp. 2-4''
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) by the National Electrical Manufacturers Association
(NEMA), (2) in document number 12 in the docket of this rulemaking,
and (3) appearing on pages 2 through 4.
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Prompted by the NEMA comment, DOE reviewed the DOE test procedures
for GSFL, IRL, and GSIL, and DOE has tentatively concluded that they
should be revised because many of industry standards cited in the test
procedures are out of date, are not available for purchase, or are no
longer maintained. Therefore, DOE has initiated a test procedure
rulemaking, in parallel with this energy conservation standards
rulemaking, to review and revise the test procedures for these three
categories of lamps--GSFL, IRL and GSIL (even though GSIL is no longer
part of this ANOPR). To this end, DOE is publishing a notice of
proposed rulemaking (NOPR) in today's Federal Register that proposes to
amend the lighting test procedures. The following briefly summarizes
the major points in the test procedures NOPR; however, for a complete
discussion on these and other points, please consult the NOPR.
In the test procedure NOPR, DOE is proposing primarily to update
the references to outdated industry standards for fluorescent and
incandescent lamps. DOE believes this update is necessary in order to
ensure that stakeholders and testing laboratories are able to follow
DOE's test procedures, which require obtaining and using several
industry standards incorporated by reference. DOE believes that the
proposed test procedure amendments would not impact the measured
efficacy of a lamp.
In the test procedure NOPR, DOE is also proposing a few
definitional and procedural modifications to accommodate technological
migrations in the GSFL market and approaches DOE is considering in this
energy
[[Page 13628]]
conservation standards rulemaking. Specifically, DOE is proposing to
mandate that GSFL testing continue to be conducted on low-frequency
ballasts whenever possible. By maintaining fluorescent lamp testing on
low-frequency ballasts when possible, DOE's proposed updates to more
current ANSI standards would not alter the measured efficacy of
fluorescent lamps and maintain consistent testing across manufacturers.
In addition, DOE is proposing amendments related to the calculation of
``lamp efficacy'' for GSFL. Presently, manufacturers are directed to
report efficacies to differing degrees of accuracy for fluorescent and
incandescent lamps. For example, fluorescent lamp efficacies are
rounded off to the nearest whole number, while incandescent lamp
efficacies are reported to the tenths decimal place. DOE is proposing
to revise the reporting requirements for GSFL, such that all covered
lamp efficacies are reported with an accuracy to the tenths decimal
place. DOE believes that such change would not only promote consistency
among the various lamp categories, but also would coincide with the
significant digits presented in the EPCA efficacy standard. In addition
DOE found that in order to have standard levels for GSFL that are best
able to maximize energy savings, it must utilize the tenths decimal
place in its energy conservation standards analysis.
DOE is also proposing in the test procedure NOPR to adopt a testing
and calculation method for measuring the correlated color temperature
(CCT) of fluorescent and incandescent lamps, a provision that is not
currently contained in the test procedure. DOE is considering using CCT
to differentiate between product classes for GSFL, and DOE notes that
the definitions of ``colored fluorescent lamp'' and ``colored
incandescent lamp'' both incorporate CCT ranges, which, in part,
determine whether lamps are subject to regulation.
The test procedure NOPR also recognizes that DOE is considering the
possibility of extending coverage to certain additional GSFL (see
section II of this notice). In addition, the test procedure NOPR
recogn
