Energy Conservation Program for Consumer Products: Test Procedures for Clothes Dryers and Room Air Conditioners, 972-1036 [2010-32118]
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket No. EERE–2008–BT–TP–0010]
RIN 1904–AC02
Energy Conservation Program for
Consumer Products: Test Procedures
for Clothes Dryers and Room Air
Conditioners
Office of Energy Efficiency and
Renewable Energy, Department of
Energy.
ACTION: Final rule.
AGENCY:
The U.S. Department of
Energy (DOE) amends its test
procedures for residential clothes dryers
and room air conditioners under the
Energy Policy and Conservation Act
(EPCA). The amendments provide for
measurement of standby mode and off
mode power use by these products and
also amend the active mode test
procedures for these products. For
standby and off mode energy use, these
amendments incorporate into the DOE
test procedures relevant provisions from
the International Electrotechnical
Commission (IEC) Standard 62301,
‘‘Household electrical appliances—
Measurement of standby power,’’ (first
edition June 2005), including language
to clarify application of these provisions
for measuring standby mode and off
mode power consumption in clothes
dryers and room air conditioners. In
addition, DOE is adopting definitions of
modes based on the relevant provisions
from IEC Standard 62301 Second
Edition Committee Draft for Vote. For
active mode energy use, DOE adopts
testing methods for ventless clothes
dryers, test cloth preconditioning
requirements for clothes dryer energy
tests, test conditions for gas clothes
dryers, test conditions for clothes dryer
drum capacity measurement,
amendments to clarify current clothes
dryer usage patterns and capabilities
and to update the references to industry
standards in the room air conditioner
and clothes dryer test procedures.
DATES: This rule is effective February 7,
2011. The incorporation by reference of
certain publications listed in the rule is
approved by the Director of the Federal
Register on February 7, 2011.
ADDRESSES: You may review copies of
all materials related to this rulemaking
at the U.S. Department of Energy,
Resource Room of the Building
Technologies Program, 950 L’Enfant
Plaza, SW., Suite 600, Washington, DC,
(202) 586–2945, between 9 a.m. and 4
p.m., Monday through Friday, except
Federal holidays. Please call Ms. Brenda
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SUMMARY:
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Edwards at the above telephone number
for additional information regarding
visiting the Resource Room.
FOR FURTHER INFORMATION CONTACT: Mr.
Subid Wagley, 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) 287–1414. E-mail:
Subid.Wagley@ee.doe.gov.
Ms. Elizabeth Kohl, U.S. Department
of Energy, Office of the General Counsel,
GC–71, 1000 Independence Avenue,
SW., Washington, DC 20585–0121.
Telephone: (202) 586–7796. E-mail:
Elizabeth.Kohl@hq.doe.gov.
SUPPLEMENTARY INFORMATION: This final
rule incorporates by reference into part
430 the following industry standards:
(1) AHAM HLD–1–2009 (‘‘AHAM
HLD–1’’), ‘‘Household Tumble Type
Clothes Dryers,’’ (2009).
Copies of AHAM HLD–1 are available
from the Association of Home
Appliance Manufacturers, 1111 19th
Street, NW., Suite 402, Washington, DC
20036, (202) 872–5955, or https://
www.aham.org/.
(2) ANSI/AHAM RAC–1–2008
(‘‘ANSI/AHAM RAC–1’’), ‘‘Room Air
Conditioners,’’ (2008; ANSI approved
July 7, 2008).
Copies of ANSI/AHAM RAC–1 are
available from the American National
Standards Institute, 11 West 42nd
Street, New York, New York 10036,
(212) 642–4936, or https://
webstore.ansi.org/.
(3) ANSI/ASHRAE Standard 16–1983
(‘‘ANSI/ASHRAE 16’’) (RA 2009),
(Reaffirmation of ANSI/ASHRAE
Standard 16–1983 [RA 1999]), ‘‘Method
of Testing for Rating Room Air
Conditioners and Packaged Terminal
Air Conditioners,’’ ASHRAE approved
October 18, 1988, and reaffirmed June
20, 2009; ANSI approved October 20,
1998 and reaffirmed June 25, 2009.
Copies of ANSI/ASHRAE 16 are
available from the American National
Standards Institute, 11 West 42nd
Street, New York, New York 10036,
(212) 642–4936, or https://
webstore.ansi.org/.
(4) International Electrotechnical
Commission (IEC) Standard 62301 (‘‘IEC
62301’’), ‘‘Household electrical
appliances—Measurement of standby
power (first edition June 2005).’’
Copies of IEC 62301 are available
from the American National Standards
Institute, 11 West 42nd Street, New
York, New York 10036, (212) 642–4936,
or https://webstore.iec.ch/.
Table of Contents
I. Background and Authority
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II. Summary of the Proposal
III. Discussion
A. Products Covered by the Test Procedure
Changes
B. Clothes Dryer and Room Air Conditioner
Standby Mode and Off Mode Test
Procedures
1. Incorporating by Reference IEC Standard
62301 for Measuring Standby Mode and
Off Mode Power in Clothes Dryers and
Room Air Conditioners
2. Determination of Modes To Be
Incorporated
3. Adding Specifications for the Test
Methods and Measurements for Clothes
Dryer and Room Air Conditioner
Standby Mode and Off Mode Testing
a. Clothes Dryers
b. Room Air Conditioners
4. Calculation of Energy Use Associated
With Standby Modes and Off Mode
a. Clothes Dryers
b. Room Air Conditioners
5. Measures of Energy Consumption
a. Clothes Dryers
b. Room Air Conditioners
C. Clothes Dryer and Room Air Conditioner
Active Mode Test Procedures
1. Correction of Text Describing Energy
Factor Calculation for Clothes Dryers
2. Automatic Cycle Termination for
Clothes Dryers
3. Test Procedure for Ventless Clothes
Dryers
4. Detergent Specifications for Clothes
Dryer Test Cloth Preconditioning
5. Changes To Reflect Current Usage
Patterns and Capabilities
a. Clothes Dryer Number of Annual Cycles
b. Clothes Dryer Initial Remaining
Moisture Content
c. Clothes Dryer Test Load Weight
d. Room Air Conditioner Annual Operating
Hours
e. Room Air Conditioner Part-Load
Performance
f. Room Air Conditioner Ambient Test
Conditions
6. Room Air Conditioner Referenced Test
Procedures
7. Clothes Dryer Referenced Test Procedure
8. Technical Correction for the Per-Cycle
Gas Dryer Continuously Burning Pilot
Light Gas Energy Consumption
9. Clarification of the Gas Supply Test
Conditions for Gas Clothes Dryers
10. Other Clothes Dryer Test Procedure
Issues
a. Test Cloth Specifications
b. Relative Humidity Measurement
Specifications
c. Calculations of EF and CEF
d. Measurement of Kilowatt Electricity
Demand
e. Clarifications to the Measurement of
Drum Capacity
f. Test Procedure Language
D. Compliance With Other EPCA
Requirements
1. Test Burden
2. Integration of Standby Mode and Off
Mode Energy Consumption Into the
Energy Efficiency Metrics
IV. Effects of Test Procedure Revisions on
Compliance With Standards
A. Standby Mode and Off Mode
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B. Active Mode—Clothes Dryers
C. Active Mode—Room Air Conditioners
V. Procedural Requirements
A. Review Under Executive Order 12866
B. Review Under the Regulatory Flexibility
Act
C. Review Under the Paperwork Reduction
Act of 1995
D. Review Under the National
Environmental Policy Act of 1969
E. Review Under Executive Order 13132
F. Review Under Executive Order 12988
G. Review Under the Unfunded Mandates
Reform Act of 1995
H. Review Under the Treasury and General
Government Appropriations Act, 1999
I. Review Under Executive Order 12630
J. Review Under the Treasury and General
Government Appropriations Act, 2001
K. Review Under Executive Order 13211
L. Review Under Section 32 of the Federal
Energy Administration Act of 1974
M. Congressional Notification
VI. Approval of the Office of the Secretary
I. Background and Authority
Title III of the Energy Policy and
Conservation Act of 1975 (42 U.S.C.
6291, et seq.; ‘‘EPCA’’ or, in context, ‘‘the
Act’’) sets forth a variety of provisions
designed to improve energy efficiency.
Part B of Title III, Public Law 94–163
(42 U.S.C. 6291–6309, as codified)
establishes the ‘‘Energy Conservation
Program for Consumer Products Other
Than Automobiles,’’ a program covering
most major household appliances
including clothes dryers and room air
conditioners (all of which are referred to
below as ‘‘covered products’’).1 (42
U.S.C. 6291(1)–(2) and 6292(a)(2) and
(8))
Under the Act, this program consists
essentially of four parts: (1) Testing; (2)
labeling; (3) the establishment of
Federal energy conservation standards;
and (4) certification and enforcement
procedures. The Federal Trade
Commission (FTC) is responsible for
labeling, and DOE implements the
remainder of the program. The testing
requirements consist of test procedures
that, pursuant to EPCA, manufacturers
of covered products must use as the
basis for certifying to DOE that their
products comply with applicable energy
conservation standards adopted under
EPCA and for representations about the
efficiency of those products. Similarly,
DOE must use these test requirements to
determine whether the products comply
with EPCA standards. Under 42 U.S.C.
6293, EPCA sets forth criteria and
procedures for DOE’s adoption and
amendment of such test procedures.
EPCA provides that any test procedures
1 All references to EPCA refer to the statute as
amended including through the Energy
Independence and Security Act of 2007, Public Law
110–140. For editorial reasons, upon codification in
the U.S. Code, Part B was re-designated Part A.
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prescribed or amended under this
section shall be reasonably designed to
produce test results which measure
energy efficiency, energy use or
estimated annual operating cost of a
covered product during a representative
average use cycle or period of use and
shall not be unduly burdensome to
conduct. (42 U.S.C. 6293(b)(3))
In any rulemaking to amend a test
procedure, DOE must also determine to
what extent, if any, the proposed test
procedure would alter the measured
energy efficiency of any covered
product as determined under the
existing test procedure. (42 U.S.C.
6293(e)(1)) If DOE determines that the
amended test procedure would alter the
measured efficiency of a covered
product, DOE must amend the
applicable energy conservation standard
accordingly. In determining the
amended energy conservation standard,
the Secretary shall measure, pursuant to
the amended test procedure, the energy
efficiency, energy use, or water use of a
representative sample of covered
products that minimally comply with
the existing standard. The average of
such energy efficiency, energy use, or
water use levels determined under the
amended test procedure shall constitute
the amended energy conservation
standard for the applicable covered
products. (42 U.S.C. 6293(e)(2)) EPCA
also states that models of covered
products in use before the date on
which the amended energy conservation
standard becomes effective (or revisions
of such models that come into use after
such date and have the same energy
efficiency, energy use, or water use
characteristics) that comply with the
energy conservation standard applicable
to such covered products on the day
before such date shall be deemed to
comply with the amended energy
conservation standard. (42 U.S.C.
6293(e)(3)) EPCA also states that the
Secretary’s authority to amend energy
conservation standards under 42 U.S.C.
6293(e) shall not affect the Secretary’s
obligation to issue final rules as
described in 42 U.S.C. 6295. (42 U.S.C.
6293(e)(4))
DOE’s test procedures for clothes
dryers are found at 10 CFR part 430,
subpart B, appendix D. DOE established
its test procedure for clothes dryers in
a final rule published in the Federal
Register on September 14, 1977 (the
September 1977 TP Final Rule). 42 FR
46145. On May 19, 1981 DOE published
a final rule (the May 1981 TP Final
Rule) to amend the test procedure by
establishing a field-use factor for clothes
dryers with automatic termination
controls, clarifying the test cloth
specifications and clothes dryer
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preconditioning, and making editorial
and minor technical changes. 46 FR
27324. The existing clothes dryer test
procedure incorporates by reference two
industry test standards: (1) The
Association of Home Appliance
Manufacturers (AHAM) Standard HLD–
1–1974, ‘‘AHAM Performance
Evaluation Procedure for Household
Tumble Type Clothes Dryers’’ (AHAM
Standard HLD–1–1974); and (2) AHAM
Standard HLD–2EC, ‘‘Test Method for
Measuring Energy Consumption of
Household Tumble Type Clothes
Dryers’’ December 1975 (AHAM
Standard HLD–2EC). The test procedure
includes provisions for determining the
energy factor (EF) for clothes dryers,
which is a measure of the total energy
required to dry a standard test load of
laundry to a ‘‘bone dry’’ 2 state.
DOE’s test procedures for room air
conditioners are found at 10 CFR part
430, subpart B, appendix F. DOE
established its room air conditioner test
procedure on June 1, 1977, and
redesignated and amended it on June
29, 1979. 42 FR 27898; 44 FR 37938.
The existing room air conditioner test
procedure incorporates by reference two
industry test standards: (1) American
National Standard (ANS) (since
renamed American National Standards
Institute (ANSI)) Z234.1–1972, ‘‘Room
Air Conditioners;’’ 3 and (2) American
Society of Heating, Refrigerating, and
Air-Conditioning Engineers (ASHRAE)
Standard 16–69, ‘‘Method of Testing for
Rating Room Air Conditioners.’’ 4 The
DOE test procedure includes provisions
for determining the energy efficiency
ratio (EER) of room air conditioners,
which is the ratio of the cooling
capacity in British thermal units (Btu) to
the power input in watts (W).
As currently drafted, the test
procedures for the products at issue in
this rulemaking do not account for
standby mode and off mode energy
consumption, except in one narrow
product class. Specifically, for gas
clothes dryers with constant burning
pilot lights, DOE’s current test
procedure for clothes dryers addresses
the standby energy use of such pilot
lights. EPCA, however, states that gas
clothes dryers shall not be equipped
with a constant burning pilot for
2 ‘‘Bone dry’’ is defined in the DOE clothes dryer
test procedure as ‘‘a condition of a load of test
clothes which has been dried in a dryer at
maximum temperature for a minimum of 10
minutes, removed and weighed before cool down,
and then dried again for 10-minute periods until the
final weight change of the load is 1 percent or less.’’
(10 CFR subpart B, appendix D, section 1.2)
3 ANSI standards are available at https://
www.ansi.org.
4 ASHRAE standards are available at https://
www.ashrae.org.
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products manufactured on or after
January 1, 1988. (42 U.S.C. 6295(g)(3))
As discussed in section III.C.8, DOE
amends the clothes dryer test procedure
in today’s final rule to remove any
provisions for measuring constant
burning pilot lights.
EPCA directs DOE to amend its test
procedures to include measures of
standby mode and off mode energy
consumption. EPCA further directs DOE
to amend the test procedures to
integrate such energy consumption into
a single energy descriptor for that
product. If that is technically infeasible,
DOE must prescribe a separate standby
mode and off mode energy-use test
procedure, if technically feasible. (42
U.S.C. 6295(gg)(2)(A)) Any such
amendment must consider the most
current versions of the International
Electrotechnical Commission (IEC)
Standard 62301 [‘‘Household electrical
appliances—measurement of standby
power,’’ First Edition 2005–06 (IEC
Standard 62301)] 5 6 and IEC Standard
62087 [‘‘Methods of measurement for the
power consumption of audio, video, and
related equipment,’’ Second Edition
2008–09]. Id.
EPCA also provides that amendments
to the test procedures to include
standby mode and off mode energy
consumption will not determine
compliance with previously established
standards. (U.S.C. 6295(gg)(2)(C)) The
test procedure amendments regarding
provisions for standby mode and off
mode in today’s final rule shall become
effective 30 days after the publication of
the rule in the Federal Register. DOE
notes, however, that the procedures and
calculations for standby mode and off
mode energy consumption need not be
performed at this time to determine
compliance with the current energy
conservation standards. Manufacturers
would be required to use the amended
test procedures’ standby mode and off
mode provisions starting on the
compliance date of any final rule
establishing amended energy
conservation standards for clothes
dryers and room air conditioners that
address standby mode and off mode
energy consumption. In addition,
starting 180 days after publication of
today’s test procedure final rule, any
representations as to the standby mode
and off mode energy consumption must
be based upon results generated under
5 IEC standards are available at: https://
www.iec.ch.
6 Multiple editions of this standard are referenced
in this final rule. Unless otherwise indicated, the
terms ‘‘IEC Standard 62301’’ or ‘‘IEC Standard 62301
First Edition’’ refer to ‘‘Household electrical
appliances—measurement of standby power,’’ First
Edition 2005–06.
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the applicable provisions of this test
procedure. (42 U.S.C. 6293(c)(2))
DOE published a notice of proposed
rulemaking (NOPR) on December 9,
2008 (the December 2008 TP NOPR), in
which it proposed a number of revisions
and additions to its test procedures for
clothes dryers and room air
conditioners. These consisted largely of
provisions to address the new statutory
requirement to expand test procedures
to incorporate a measure of standby
mode and off mode energy
consumption. 73 FR 74639. DOE also
proposed amendments to correct text
describing the EF calculation for clothes
dryers and the text referencing room air
conditioner industry test standards. 73
FR 74650. The proposals in the NOPR
were addressed at a public meeting on
December 17, 2008 (the December 2008
Public Meeting). In addition, DOE
invited written comments, data, and
information on the December 2008 TP
NOPR through February 23, 2009.
DOE received oral comments from
interested parties at the December 2008
Public Meeting and subsequently
received four written comments. The
principal test procedure issues on
which interested parties commented
were: (1) Establishing multiple low
power or standby modes for both
clothes dryers and room air
conditioners; (2) the number of annual
hours associated with active, standby,
and off modes for the calculation of
energy use; (3) considering an
additional standby mode (a ‘‘network
mode’’); (4) clarifying the definitions of
standby and off mode; (5) harmonizing
mode definitions and testing procedures
with international standards, in
particular IEC Standard 62301 Second
Edition, Committee Draft 2 (IEC
Standard 62301 CD2); and (6)
integrating of standby and off mode
energy use and active mode energy use
into a single energy-use metric.
DOE determined after the December
2008 TP NOPR was published that it
would consider a revised version of IEC
Standard 62301, i.e., IEC Standard
62301 Second Edition, which at that
time was expected to be published in
July 2009. DOE anticipated, based on
review of drafts of the updated IEC
Standard 62301, that the revisions could
include different mode definitions.
Subsequently, DOE received
information that IEC Standard 62301
Second Edition would not be published
until late 2010. To allow for the
consideration of standby and off mode
power consumption in the concurrent
energy conservation standards
rulemaking, DOE published a SNOPR
on June 29, 2010 (hereafter referred to
as the June 2010 TP SNOPR), proposing
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mode definitions based on the new
mode definitions from the most recent
draft version of IEC Standard 62301
Second Edition which, at that time, was
designated as IEC Standard 62301
Second Edition Committee Draft for
Vote (IEC Standard 62301 CDV). 75 FR
37594. The IEC circulated IEC Standard
62301 CDV on August 28, 2009. IEC
Standard 62301 CDV contained the most
recent proposed amendments to IEC
Standard 62301, including new mode
definitions, at the time the June 2010 TP
SNOPR was issued. IEC Standard 62301
CDV revised the proposed mode
definitions from previous draft versions
of IEC Standard 62301 and addressed
comments received by interested parties
in response to those drafts. As a result,
DOE stated in the June 2010 TP SNOPR
that the mode definitions in IEC
Standard 62301 CDV represent the best
definitions available for the supporting
analysis. Id.
DOE also determined after publication
of the December 2008 TP NOPR to
conduct a rulemaking to amend the
active mode test procedure for clothes
dryers and room air conditioners. As
part of this rulemaking, DOE intended
to address issues on which it requested
comment in the concurrent energy
conservation standards rulemaking,
discussed below. In the June 2010 TP
SNOPR, DOE proposed the following
test procedure amendments for the
measurement of active mode energy
consumption for clothes dryers and
room air conditioners: (1) Procedures for
more accurately measuring the effects of
different automatic termination
technologies in clothes dryers; (2)
provisions for ventless clothes dryers,
which are being considered under an
amended energy conservation standard;
(3) updated detergent specifications for
clothes dryer test cloth preconditioning;
(4) changes to better reflect current
usage patterns and capabilities for the
covered products; (5) updated
references to external test procedures;
and (6) clarifications to the test
conditions for gas clothes dryers. 75 FR
37594 (June 29, 2010).
The proposals in the SNOPR were
addressed at a public meeting on July
14, 2010 (July 2010 Public Meeting). In
addition, DOE invited written
comments, data, and information on the
June 2010 TP SNOPR through August
30, 2010. DOE received oral comments
from interested parties at the July 2010
Public Meeting and subsequently
received 13 written comments. The
principal test procedure issues on
which interested parties commented
were: (1) The consideration of the most
recent draft IEC Standard 62301 Second
Edition, Final Draft International
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Standard (IEC Standard 62301 FDIS); (2)
the settings used for standby and off
mode testing; (3) the allocation of hours
to different standby and off modes; (4)
the clothes dryer cycle settings selected
for automatic cycle termination testing
methods; (5) the inclusion of the cooldown period for clothes dryer automatic
cycle termination tests; (6) revisions to
the water temperature for clothes dryer
test load preparation; (7) test conditions
for ventless clothes dryers; (8) the
consideration of the effects of clothes
dryers on HVAC energy use; (9) the
initial remaining moisture content
(RMC) value for clothes dryers; (10) the
number of room air conditioner annual
operating hours; and (11) the
consideration of fan-only active mode
for room air conditioners.
Test procedure amendments for the
measurement of active mode energy
consumption for clothes dryers and
room air conditioners will become
effective 30 days after the publication of
today’s final rule in the Federal
Register. In addition, DOE also notes
that as of 180 days after the publication
of today’s test procedure final rule, any
representations with respect to the
energy use or efficiency or cost of
energy consumed of the products that
are the subject of this rulemaking must
be based upon results generated under
the applicable provisions of these
amended test procedures. (42 U.S.C.
6293(c)(2))
This test procedure rulemaking
fulfills the 7-year review requirement
prescribed by EPCA. At least once every
7 years, the Secretary shall review test
procedures for all covered products and
amend test procedures with respect to
any covered product or publish notice
in the Federal Register of any
determination not to amend a test
procedure. (42 U.S.C. 6293(b)(1)(A))
DOE is also conducting a concurrent
energy conservation standards
rulemaking for residential clothes dryers
and room air conditioners. For clothes
dryers, EPCA establishes prescriptive
standards for clothes dryers, requiring
that gas dryers manufactured on or after
January 1, 1988 not be equipped with a
constant burning pilot and further
requiring that DOE conduct two cycles
of rulemakings to determine if more
stringent standards are justified. (42
U.S.C. 6295(g)(3) and (4)) On May 14,
1991, DOE published a final rule in the
Federal Register establishing the first
set of performance standards for
residential clothes dryers (56 FR 22250);
the new standards became effective on
May 14, 1994. 10 CFR 430.32(h). DOE
has initiated the second cycle of clothes
dryer standards rulemakings by
publishing a notice of availability of a
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framework document, discussed in
more detail below. 72 FR 57254
(October 9, 2007).
For room air conditioners, EPCA
establishes performance standards that
became effective on January 1, 1990,
and directs DOE to conduct two cycles
of rulemakings to determine if more
stringent standards are justified. (42
U.S.C. 6295(c)(1) and (2)) On March 4,
1994, DOE published a NOPR for
several products, including room air
conditioners. 59 FR 10464. On
September 24, 1997, DOE published a
final rule establishing an updated set of
performance standards, with an
effective date of October 1, 2000. 62 FR
50122; 10 CFR 40.32(b). DOE initiated
the second cycle of room air conditioner
standards rulemakings concurrent with
the clothes dryer rulemaking. 72 FR
57254 (October 9, 2007).
As stated above, DOE initiated the
second cycle of residential clothes dryer
and room air conditioner energy
conservation standards rulemakings by
publishing a notice in the Federal
Register announcing the availability of
a framework document to initiate a
rulemaking to consider amended energy
conservation standards for residential
clothes dryers and room air conditioners
on October 9, 2007 (hereafter the
October 2007 Framework Document). 72
FR 57254. In the October 2007
Framework Document, DOE identified
specific ways in which it could revise
its test procedures for these two
products and requested comment from
interested parties on whether it should
adopt such revisions. Specifically, DOE
sought comment on potential
amendments to the clothes dryer test
procedure to: (1) Reflect lower
remaining moisture content (RMC) 7 in
clothes loads; (2) account for fewer
annual use cycles; and (3) add the
capability to test ventless clothes dryers.
(Framework Document, STD No. 1 at
pp. 4–6) 8 DOE received comments in
response to the October 2007
Framework Document that it should
consider changes to the clothes dryer
test load size. For room air conditioners,
7 RMC is the ratio of the weight of water
contained by the test load to the bone-dry weight
of the test load, expressed as a percent.
8 A notation in this form provides a reference for
information that is in the docket of DOE’s
rulemaking to develop energy conservation
standards for clothes dryers and room air
conditioners (Docket No. EERE–2007–BT–STD–
0010), which is maintained in the Resource Room
of the Building Technologies Program. This
notation indicates that the statement preceding the
reference was made in DOE’s Framework
Document, which is document number 1 in the
docket for the clothes dryer and room air
conditioner energy conservation standards
rulemaking, and appears at pages 4–6 of that
document.
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DOE requested input on potential
amendments to the test procedure to: (1)
Incorporate the most recent ANSI and
ASHRAE test standards; (2) reduce the
annual operating hours; and (3) measure
part-load performance. (Framework
Document, STD No. 1 at pp. 6–7) DOE
received comments in response to the
October 2007 Framework Document that
it should consider changes to the
ambient test conditions for room air
conditioners.
EPCA directs DOE to incorporate
standby and off mode energy use into
any final rule establishing or revising a
standard for a covered product adopted
after July 1, 2010. (42 U.S.C. 6295(gg)(3))
DOE is required by consent decree to
publish a final rule setting forth any
revised efficiency standards for clothes
dryers and room air conditioners by
June 30, 2011. As result, this final rule
must incorporate standby and off mode
energy use.
II. Summary of the Proposal
In today’s final rule, DOE amends its
test procedures for clothes dryers and
room air conditioners to: (1) Use in the
concurrent development of energy
conservation standards that address the
energy use of these products when in
standby mode and off mode, as well as
in the implementation of any amended
standards; (2) address the statutory
requirement to expand test procedures
to incorporate measures of standby
mode and off mode power consumption;
(3) adopt changes to the water
temperature for clothes dryer test load
preparation; (4) expand the clothes
dryer test procedures to accommodate
ventless clothes dryers being considered
for coverage under an amended energy
conservation standard; (5) adopt
technical changes to better reflect
current usage patterns and capabilities
for the covered products; (6) update
detergent specifications for clothes
dryer test cloth preconditioning; (7)
update the references to external test
procedures; (8) clarify the test
conditions for gas clothes dryers; and (9)
clarify the test conditions for clothes
dryer drum capacity measurements. As
discussed in this section, DOE is not
adopting the technical changes and
procedures to more accurately measure
the effects of different automatic cycle
termination technologies in clothes
dryers proposed in the June 2010 TP
SNOPR. The following paragraphs
summarize the amendments.
Standby and Off Mode
In today’s final rule, DOE incorporates
by reference into both the clothes dryer
and room air conditioner test
procedures specific clauses from IEC
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Standard 62301 regarding test
conditions and test procedures for
measuring standby mode and off mode
power consumption. DOE also
incorporates into each test procedure
the definitions of ‘‘active mode,’’
‘‘standby mode,’’ and ‘‘off mode’’ based
on the definitions provided in IEC
Standard 62301 CDV. Further, DOE
adopts additional language in each test
procedure to clarify how clauses from
IEC Standard 62301 and the mode
definitions from IEC Standard 62301
CDV are to be applied when measuring
standby mode and off mode power
consumption.9
For reasons discussed in section
III.B.2 for clothes dryers, DOE adopts a
definition and testing procedures for a
single standby mode, rather than the
multiple standby modes—‘‘inactive’’
mode, ‘‘cycle finished’’ mode, and ‘‘delay
start’’ mode—as proposed in the
December 2008 TP NOPR. 73 FR 74639,
74645 (December 9, 2008). DOE also
adopts new methods to calculate clothes
dryer standby mode and off mode
energy use, as well as a new measure of
energy efficiency—Combined Energy
Factor (CEF)—that includes energy use
in standby mode and off mode. The
standby mode and off mode
amendments do not change the method
to calculate the existing clothes dryer
energy efficiency metric for active
mode, the energy factor (EF).
Similarly, for reasons discussed in
section III.B.2 for room air conditioners,
DOE adopts a definition and testing
procedures for a single standby mode,
rather than the multiple standby
modes—‘‘inactive’’ mode, ‘‘delay start’’
mode, and ‘‘off-cycle’’ mode—as
proposed in the December 2008 TP
NOPR. 73 FR 74639, 74645. DOE also
adopts new methods to calculate room
air conditioner standby mode and off
mode energy use and a new measure of
energy efficiency—Combined Energy
Efficiency Ratio (CEER)—that includes
energy use in the standby mode and the
off mode. The standby mode and off
mode amendments do not change the
method used to calculate the existing
room air conditioner energy efficiency
metric for active mode, the energy
efficiency ratio (EER).
In the December 2008 TP NOPR, DOE
also proposed that standby mode and off
mode testing be conducted with room9 EISA 2007 directs DOE to also consider IEC
Standard 62087 when amending its test procedure
to include standby mode and off mode energy
consumption. See 42 U.S.C. 6295(gg)(2)(A). As
explained subsequently in this notice, because IEC
Standard 62087 addresses the methods of
measuring the power consumption of audio, video,
and related equipment, it is inapplicable to the
products at issue in this rulemaking.
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side air temperature at 74 ± 2 degrees
Fahrenheit (°F), with a temperature
control setting of 79 °F. 73 FR 74639,
74646. Upon further consideration,
however, DOE determined that, because
the proposed test procedure would be
limited to measuring a single standby
mode and an off mode, the proposed
close tolerance on ambient temperature
and the proposed temperature setting of
79 °F, which were relevant only for an
off-cycle standby mode measurement,
would not be required. Therefore, DOE
is not adopting those requirements for
testing conditions in today’s final rule.
In the June 2010 TP SNOPR, DOE
proposed that standby mode and off
mode testing for both clothes dryers and
room air conditioners be conducted at
the settings that produce the highest
power consumption level, consistent
with the particular mode definition
under test. 75 FR 37594, 37604 (June 29,
2010). Upon further consideration,
however, DOE believes that provisions
for testing in the settings that produce
the highest power consumption level
would not be representative of
consumer usage. For the reasons
discussed in section III.B.2, DOE
believes the provisions in section 5.2 of
IEC Standard 62301 that specify the
appliance be installed and set up in
accordance with manufacturers’
instructions, or if no instructions are
given, the appliance be tested at factory
or ‘‘default’’ settings, is more
representative of consumer usage.
Therefore, DOE amends the test
procedure in today’s final rule to
incorporate by reference section 5.2 of
IEC Standard 62301 for standby and off
mode testing for both clothes dryers and
room air conditioners in today’s final
rule.
For the reasons discussed in section
III.B.5, DOE revises the estimated
annual operating cost calculation for
both clothes dryers and room air
conditioners (Estimated Annual
Operating Cost and Annual Energy Cost,
respectively) to integrate the cost of
energy use in the standby mode and off
mode.
Amendments to the Water Temperature
for Clothes Dryer Test Load Preparation
The existing DOE clothes dryer test
procedure requires that the test load be
agitated in water whose temperature is
100 °F ± 5 °F. In the June 2010 TP
SNOPR, DOE stated that it did not have
data indicating whether a different
water temperature for clothes dryer test
load preparation would be more
representative of current consumer
usage, but that if consumer usage data
is made available that indicates a 60 °F
± 5 °F water temperature is more
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representative of consumer use, DOE
may adopt this alternate approach. 75
FR 37594, 37615 (June 29, 2010). As
discussed in section III.C.2, DOE
believes that the cold water rinse cycle
is more representative of typical
consumer use based on the rinse
temperature use factors in the DOE
clothes washer test procedure and the
Energy Information Administration
(EIA) 2005 ‘‘Residential Energy
Consumption Survey’’ (RECS) 10 11 data
reporting the percentage of clothes
washer cycles for which consumers use
cold water for the rinse cycle. Therefore,
DOE amends the clothes dryer test
procedure in today’s final rule to change
the water temperature for clothes dryer
test load preparation to 60 °F ± 5 °F. This
temperature is more representative of
the clothes load temperature after a cold
rinse cycle at the end of the wash cycle.
Provisions for Testing Ventless Clothes
Dryers
In today’s final rule, DOE amends the
current clothes dryer test procedure to
include provisions for testing ventless
clothes dryers. These provisions are
based upon an alternate test procedure
developed by DOE and proposed in the
June 2010 TP SNOPR that provide
separate definitions for a ‘‘conventional
clothes dryer’’ and a ‘‘condensing
clothes dryer.’’ These provisions also
qualify the requirement for an exhaust
simulator so that it would apply only to
conventional clothes dryers. Further,
DOE includes in the test procedure
additional language based on provisions
from European Standard EN 61121,
‘‘Tumble dryers for household use—
Methods for measuring the
performance,’’ Edition 3 2005 (the EN
Standard 61121). These provisions
clarify the alternate test procedure
developed by DOE. EN Standard 61121
is an internationally-accepted test
standard that specifies methods for
testing ventless clothes dryers. The
clarifications require that if a ventless
clothes dryer is equipped with a
condensation box, the clothes dryer
shall be tested with such condensation
box installed as specified by the
manufacturer. A condensation box
stores condensed moisture removed
from the air exiting the drum. The box
is later emptied by the user. In addition,
the clarifications also state that if the
clothes dryer stops the test cycle
because the condensation box is full, the
10 U.S. Department of Energy-Energy Information
Administration. Residential Energy Consumption
Survey 2005 Public Use Data Files, 2005.
Washington, DC. Available online at: https://
www.eia.doe.gov/emeu/recs/.
11 EIA’s 2005 RECS is the latest available version
of this survey.
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test is not valid because the unit would
not be operating as intended by the
manufacturer to condense moisture in
the air exiting the clothes dryer drum.
In such cases, the condensation box
must be emptied and the test re-run
from the beginning. The clarifications
also state that the condenser heat
exchanger cannot be taken out of the
clothes dryer between tests to clarify the
test procedure and ensures that all
manufacturers are testing products
under the same conditions. Finally,
DOE adopts clarifications that address
clothes dryer preconditioning for
ventless clothes dryers, as discussed in
section III.C.3.
Amendments To Reflect Current Usage
Patterns and Capabilities
DOE amends the test procedure for
clothes dryers to reflect current usage
patterns and capabilities. These
amendments are based on DOE’s
analysis of consumer usage patterns
data. As proposed in the June 2010
SNOPR, DOE revises the number of
annual use cycles from the 416 cycles
per year currently specified by the DOE
test procedure to 283 cycles per year for
all types (that is, product classes) of
clothes dryers. This revision is based on
DOE’s analysis of data from the 2005
RECS for the number of laundry loads
(clothes washer cycles) washed per
week and the frequency of clothes dryer
use. In addition, as proposed in the
2010 SNOPR, DOE changes the 7-pound
(lb) clothes dryer test load size specified
by the current test procedure for
standard-size clothes dryers to 8.45 lb.
This revision is based on the historical
trends of clothes washer tub volumes
and the corresponding percentage
increase in clothes washer test load
sizes (as specified by the DOE clothes
washer test procedure). DOE assumes
these historical trends proportionally
impact clothes dryer load sizes. DOE
believes most compact clothes dryers
are used in conjunction with compactsize clothes washers, however, and DOE
does not have any information to
suggest that the tub volume of such
clothes washers has changed
significantly. Therefore, DOE is not
changing the 3-lb test load size currently
specified in its clothes dryer test
procedure for compact clothes dryers in
today’s final rule.
In the June 2010 TP SNOPR, DOE also
proposed to revise the 70-percent initial
RMC required by the test procedure to
47 percent so as to accurately represent
the condition of a laundry load after a
wash cycle. This proposal was based on
analysis of shipment-weighted RMC
data for clothes washers submitted by
AHAM and a distribution analysis of
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RMC data for clothes washer models
listed in the December 22, 2008
California Energy Commission (CEC)
directory. 75 FR 37594, 37599 (June 29,
2010). In response to comments from
interested parties on the June 2010 TP
SNOPR, DOE determined that an initial
clothes dryer RMC of 57.5 percent more
accurately represents the moisture
content of laundry loads after a wash
cycle for the purposes of clothes dryer
testing. As discussed in section III.5.b,
this RMC is derived from the 47-percent
shipment-weighted RMC for clothes
washers, but was derived without
applying an RMC correction factor as
required by the DOE clothes washer test
procedure. For these reasons, DOE
revises the initial clothes dryer RMC
from 70 percent to 57.5 percent in
today’s final rule.
Clothes Dryer Automatic Cycle
Termination
In the June 2010 TP SNOPR, DOE
proposed to revise its clothes dryer test
procedure to include definitions of and
provisions for testing both timer dryers
and automatic termination control
dryers using methodology provided in
Australia/New Zealand (AS/NZS)
Standard 2442.1: 1996, ‘‘Performance of
household electrical appliances—Rotary
clothes dryers, Part 1: Energy
consumption and performance’’ (AS/
NZS Standard 2442.1) and AS/NZS
Standard 2442.2: 2000, ‘‘Performance of
household electrical appliances—Rotary
clothes dryers, Part 2: Energy labeling
requirements’’ (AS/NZS Standard
2442.2). 75 FR 37594, 37598 (June 29,
2010). DOE proposed to incorporate the
testing methods from these international
test standards, along with a number of
clarifications, to measure the energy
consumption for both timer dryers and
automatic termination control dryers.
The measurement would account for the
amount of over-drying energy
consumption, that is, the energy
consumed by the clothes dryer after the
load reaches an RMC of 5 percent. 75 FR
37594, 37599 (June 29, 2010).
DOE conducted testing of
representative clothes dryers using the
automatic cycle termination test
procedure proposed in the June 2010 TP
SNOPR; however, the test results
showed that all of the clothes dryers
tested significantly over-dried the DOE
test load to near bone dry. In addition,
the measured EF values were
significantly lower than EF values
obtained using the existing DOE test
procedure, and the test data indicated
that clothes dryers equipped with
automatic termination controls were
less efficient than timer dryers. DOE
believes the test procedure amendments
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977
for automatic cycle termination
proposed in the June 2010 TP SNOPR
do not adequately measure the energy
consumption of clothes dryers equipped
with such systems using the test load
specified in the DOE test procedure.
DOE believes that clothes dryers with
automatic termination sensing control
systems, which infer the RMC of the
load from the properties of the exhaust
air such as temprature and humidity,
may be designed to stop the cycle when
the consumer load has a higher RMC
than the RMC obtained using the
proposed automatic cycle termination
test procedure in conjunction with the
existing test load.12 Manufacturers have
indicated, however, that test load types
and test cloth materials different than
those specified in the DOE test
procedure do not produce results as
repeatable as those obtained using the
test load as currenty specified. In
addition, DOE presented data in the
May 1981 TP Final Rule from a field use
survey conducted by AHAM as well as
an analysis conducted by the National
Bureau of Standards (now known as the
National Institute of Standards and
Technology (NIST)) of field test data on
automatic termination control dryers.
Analysis of this data showed that
clothes dryers equipped with an
automatic cycle termination feature
consume less energy than timer dryers
by reducing over-drying. 46 FR 27324
(May 19, 1981).
For the reasons discussed above, DOE
believes the test procedure amendments
for automatic cycle termination
proposed in the June 2010 TP SNOPR
do not adequately measure the energy
consumption of clothes dryers equipped
with such systems. As a result, DOE is
not adopting the amendments for
automatic cycle termination proposed in
the June 2010 TP SNOPR. 75 FR 37594,
37598–99 (June 29, 2010). If data is
made available to develop a test
procedure that accurately measures the
energy consumption of clothes dryers
equipped with automatic termination
controls, DOE may consider revised
amendments in a future rulemaking.
12 To investigate this, DOE conducted additional
testing using a test load similar to that specified in
AHAM Standard HLD–1–2009, which consists of
cotton bed sheets, towels, and pillow cases. For
tests using the same automatic cycle termination
settings as were used in the testing described earlier
(i.e., normal cycle setting and highest temperature
setting, the alternate test load was dried to 1.7 to
2.2 percent final RMC, with an average RMC of 2.0
percent. In comparison, the same clothes dryer
under the same cycle settings dried the DOE test
load to 0.3 to 1.2 percent RMC, with an average
RMC of 0.7 percent. Thus, DOE concluded that the
proposed automatic cycle termination control test
procedures may not stop at an appropriate RMC
when used with the current test load.
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DOE received comments in response
to the June 2010 TP SNOPR that it
should revise the definition of
‘‘automatic termination control’’ in the
current clothes dryer test procedure.
Commenters felt the definition should
more clearly account for electronic
controls by specifying that a preferred
automatic termination control setting
can also be indicated by any other
visual indicator (in addition to a mark
or detent). DOE agrees this clarification
should be added and is amending the
definition of ‘‘automatic termination
control’’ in the clothes dryer test
procedure to include it.
DOE also received comments stating
that the field-use factor for clothes
dryers with automatic cycle termination
applied in the per-cycle energy
consumption calculation excludes
sensing technologies that do not meet
the definitions of ‘‘temperature sensing
control’’ or ‘‘moisture sensing control,’’
which are narrowly defined to require
that the control system use either a
temperature sensor that monitors the
exhaust air or a moisture sensor
contained within the drum. DOE
believes the definition of ‘‘automatic
termination control’’ more broadly
applies to any sensing system that
monitors either the dryer load
temperature or its moisture content and
that this definition would not limit the
emergence of any new sensor
technologies that monitor the moisture
content or temperature in other ways
from applying the field use factor for
automatic cycle termination. For these
reasons, DOE amends the test procedure
to specify that the field use factor
applies to clothes dryers that meet the
requirements for the definitions of
‘‘automatic termination control.’’
Other Changes
For clothes dryers, DOE also revises
the detergent specifications for test cloth
preconditioning to update the detergent
specified in the test procedure,
eliminates an unnecessary reference to
an obsolete industry clothes dryer test
standard, and amends the test
conditions for gas clothes dryers to
specify the required gas supply
pressure.
DOE also received comments related
to clothes dryers from interested parties
on issues not addressed in the June 2010
TP SNOPR. Commenters suggested that
DOE clarify the provisions for the
measurement of drum capacity to
specify that the clothes dryer’s rear
drum surface be supported on a
platform scale to ‘‘prevent deflection of
the drum surface * * *’’ instead of
‘‘prevent deflection of the dryer.’’ As
discussed in section III.C.10.e, DOE
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agrees with these comments and adopts
that provision in today’s final rule. In
addition, DOE received comments in
response to the June 2010 TP SNOPR
that it should expressly state the
equations for EF and CEF in the test
procedure to provide optimal clarity for
the regulated industry. DOE agrees with
comments that the equations for EF and
CEF should be included in 10 CFR part
430, subpart B, appendix D1 for
completeness. Therefore, DOE amends
the clothes dryer test procedure in
today’s final rule to include those
calculations and to clarify in 10 CFR
part 430.23(d)(2) and (3) that the EF and
CEF must be determined in accordance
with the appropriate sections in 10 CFR
part 430, subpart B, appendix D1.
For room air conditioners, DOE
updates the references in its current
room air conditioner test procedure to
incorporate the most recent ANSI and
ASHRAE test standards—ANSI/AHAM
RAC–1–R2008, ‘‘Room Air
Conditioners,’’ (ANSI/AHAM RAC–1–
R2008) and ANSI/ASHRAE Standard
16–1983 (RA 2009) ‘‘Method of Testing
for Rating Room Air Conditioners and
Packaged Terminal Air Conditioners’’
(ANSI/ASHRAE Standard 16–1983
(RA 2009)). DOE has also determined
that the 750 annual operating hours
specified by the current DOE test
procedure is representative of current
usage patterns, based upon its
interpretation of data from the 2005
RECS. Therefore, DOE is not amending
the annual usage hours specified by the
current DOE test procedure for room air
conditioners.
As noted in section I, EPCA requires
that DOE determine to what extent, if
any, test procedure amendments would
alter the measured energy efficiency of
any covered product as determined
under the existing test procedure.
(42 U.S.C. 6293(e)(1)) If DOE determines
that the amended test procedure would
alter the measured efficiency of a
covered product, DOE must amend the
applicable energy conservation
standard. In determining the amended
energy conservation standard, DOE
must measure, pursuant to the amended
test procedure, the energy efficiency,
energy use, or water use (as applicable)
of a representative sample of covered
products that minimally comply with
the existing standard. (42 U.S.C.
6293(e)(2)) Under 42 U.S.C.
6295(gg)(2)(C), EPCA provides that
amendments to the test procedures that
include standby mode and off mode
energy consumption will not determine
compliance with previously established
standards. (U.S.C. 6295(gg)(2)(C))
These amended clothes dryer and
room air conditioner test procedures are
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effective 30 days after the publication of
today’s final rule in the Federal
Register. Because the amendments to
the test procedures for measuring
standby mode and off mode energy
consumption do not alter the existing
measures of energy consumption or
efficiency for clothes dryers and room
air conditioners, the amendments do not
affect a manufacturer’s ability to comply
with current energy conservation
standards. Manufacturers will not be
required to use the amended test
procedures’ standby mode and off mode
provisions until the mandatory
compliance date of any amended
clothes dryer and room air conditioner
energy conservation standards. All
representations related to standby mode
and off mode energy consumption of
both clothes dryers and room air
conditioners made 180 days after the
publication of today’s final rule must be
based upon the standby and off mode
requirements of the amended test
procedures. (42 U.S.C. 6293(c)(2)) DOE
examines how each of the amendments
to the active mode provisions in its
clothes dryer and room air conditioner
test procedures in today’s final rule will
affect the measured efficiency of
products in section IV.
III. Discussion
A. Products Covered by the Test
Procedure Changes
Today’s amendments to DOE’s clothes
dryer test procedure cover both electric
and gas clothes dryers, DOE defines a
clothes dryer to mean a cabinet-like
appliance designed to dry fabrics in a
tumble-type drum with forced air
circulation, with blower(s) driven by an
electric motor(s) and either gas or
electricity as the heat source.
Porticos Inc. (Porticos) commented in
response to the June 2010 TP SNOPR
that DOE’s definition for an electric
clothes dryer excludes every possible
alternative from consideration. Porticos
stated that any alternate innovative
clothes dryer technology, such as
microwave, radio-frequency, vacuum,
desiccant, and vapor-compression,
would not meet the current electric
clothes dryer definition, and direct
comparisons would not be possible.
Porticos commented that a better
definition would be ‘‘an electrical
appliance for drying clothes’’ and that
any more limiting verbiage serves only
to exclude new entrants from the
marketplace. (Porticos, No. 23 at p. 1)
Porticos also commented that DOE
should reexamine the test procedures to
remove any explicit or implicit
reference to a particular technology or
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approach to clothes drying. (Porticos,
No. 23 at p. 2)
DOE notes that the definition of a
clothes dryer in the CFR does not
prohibit other products (that is, those
that do not fall under the definition of
a clothes dryer) from being introduced
to the market. For example, spin dryers
or drying cabinets that do not use a heat
source, forced air circulation, or a
tumble-type drum are currently
commercially available. Under the
product definition suggested by
Porticos, DOE notes that blow dryers,
fans, or heat lamps could be considered
covered products. DOE is also not aware
of any commercially available
microwave, radio-frequency, vacuum,
desiccant, or vapor-compression clothes
dryers. As a result, no data is available
by which DOE could develop standards
for such dryers. For these reasons, DOE
is not revising the definition of a clothes
dryer in today’s final rule.
DOE’s regulations define a room air
conditioner as a consumer product
which is powered by a single-phase
electric current and which is an encased
assembly designed as a unit for
mounting in a window or through the
wall for the purpose of providing
delivery of conditioned air to an
enclosed space. It includes a prime
source of refrigeration and may include
a means for ventilating and heating. It
does not include packaged terminal air
conditioners.13 This definition and the
amendments discussed below cover
room air conditioners designed for
single- or double-hung windows with or
without louvered sides and with or
without reverse cycle, as well as
casement-slider and casement-only
window-type room air conditioners.
DOE is not changing the definition for
room air conditioners in today’s final
rule.
B. Clothes Dryer and Room Air
Conditioner Standby Mode and Off
Mode Test Procedures
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1. Incorporating by Reference IEC
Standard 62301 for Measuring Standby
Mode and Off Mode Power in Clothes
Dryers and Room Air Conditioners
As noted in the December 2008 TP
NOPR, DOE considered, pursuant to
EPCA, the most current versions of IEC
Standard 62301 and IEC Standard 62087
for measuring power consumption in
standby mode and off mode. (42 U.S.C.
6295(gg)(2)(A)) 73 FR 74639, 74643–44
13 DOE’s regulations define a packaged terminal
air conditioner as a wall sleeve and a separate
encased combination of heating and cooling
assemblies specified by the builder and intended
for mounting through the wall. It includes a prime
source of refrigeration, separable outdoor louvers,
forced ventilation, and heating availability energy.
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(December 9, 2008).14 DOE noted that
IEC Standard 62301 provides for
measuring standby power in electrical
appliances, including clothes dryers and
room air conditioners, and, therefore, is
applicable to the proposed amendments
to the clothes dryer and room air
conditioner test procedures. 73 FR
74643–44 (December 9, 2008).
DOE proposed in the December 2008
TP NOPR to incorporate by reference
into the DOE test procedures for clothes
dryers and room air conditioners
specific clauses from IEC Standard
62301 for measuring standby mode and
off mode power: from section 4
(‘‘General conditions for
measurements’’); paragraph 4.2, ‘‘Test
room’’; paragraph 4.4, ‘‘Supply voltage
waveform’’; and paragraph 4.5, ‘‘Power
measurement accuracy’’; as well as from
section 5 (‘‘Measurements’’); paragraph
5.1, ‘‘General’’; and paragraph 5.3,
‘‘Procedure.’’ DOE also proposed to
reference these same provisions in the
DOE test procedure for room air
conditioners, as well as section 4,
paragraph 4.3, ‘‘Power supply.’’ 73 FR
74639, 74644 (December 9, 2008).
In the December 2008 TP NOPR, DOE
noted that EPCA (42 U.S.C.
6295(gg)(2)(A)) requires that in
developing any amended test
procedures, DOE consider the most
current version of IEC Standard 62301.
The IEC is currently developing an
updated version of this standard, IEC
Standard 62301 Second Edition. 73 FR
74639, 74644 (December 9, 2008). At the
time of publication of the December
2008 TP NOPR, however, IEC Standard
62301 was the ‘‘current version, which
DOE was required by EPCA to consider.
DOE incorporated sections from IEC
Standard 62301 in the proposed
amendments to the test procedure in the
December 2008 TP NOPR. 73 FR 74639,
74644 (December 9, 2008).
DOE did not receive any objections to
the proposed testing methods and
procedures referenced in IEC Standard
62301 in response to the December 2008
TP NOPR. As a result, the June 2010 TP
SNOPR did not affect DOE’s proposal in
the December 2008 TP NOPR to
incorporate by reference the clauses
presented above from IEC Standard
62301. 75 FR 37594, 37602 (June 29,
2010).
14 DOE notes that IEC Standard 62087 specifies
methods of measuring the power consumption of
TV receivers, videocassette recorders (VCRs), set
top boxes, audio equipment, and multi-function
equipment for consumer use. IEC Standard 62087
does not include measurement for the power
consumption of electrical appliances such as
clothes dryers and room air conditioners. Therefore,
IEC Standard 62087 is not applicable to the
amendments to the clothes dryer and room air
conditioner test procedures.
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DOE anticipated, based on review of
draft versions of IEC Standard 62301
Second Edition, that the revisions to IEC
Standard 62301 could include different
mode definitions. DOE received
information, however, that IEC Standard
62301 Second Edition would not be
available until late 2010. To allow for
consideration of standby and off mode
power consumption in the concurrent
energy conservation standards
rulemaking, DOE proposed in the June
2010 TP SNOPR the new mode
definitions from the most recent draft
version of IEC Standard 62301 Second
Edition, IEC Standard 62301 CDV. The
definitions of standby mode, off mode,
and active mode in IEC Standard 62301
CDV expand upon the EPCA mode
definitions and provide additional
guidance as to which functions are
associated with each mode. 75 FR
37594, 37602 (June 29, 2010). The
comments received by IEC on IEC
Standard 62301 CD2, and the resulting
amended mode definitions proposed in
IEC Standard 62301 CDV, demonstrate
significant participation of interested
parties in the development of
definitions that represent a substantial
improvement over those in IEC
Standard 62301. Id. These definitions
are discussed in detail in Section III.B.2.
In response to the June 2010 TP
SNOPR, AHAM, Alliance Laundry
Systems (ALS), and Whirlpool
Corporation (Whirlpool) commented in
support of referencing the most recent
draft version of IEC Standard 62301
Second Edition, designated as IEC
Standard 62301 FDIS, for test methods
and mode definitions rather than IEC
Standard 62301 First Edition and IEC
Standard 62301 CDV. (AHAM, Public
Meeting Transcript, No. 20 at pp. 18,
26–27; AHAM, No. 27 at p. 2; ALS, No.
24 at p. 1; Whirlpool, No. 27 at p. 1)
AHAM and Whirlpool commented
that IEC Standard 62301 FDIS will soon
be formally adopted by IEC, and it
contains a number of clarifications to
the definitions and test procedures not
present in IEC Standard 62301 CDV.
According to AHAM and Whirlpool,
this will allow for optimum
international harmonization, giving
clarity and consistency to the regulated
community and decreasing testing
burden. (AHAM, No. 31 at p. 2;
Whirlpool, No. 27 at p. 1) Additionally,
AHAM commented that no technical
edits can be made to the standard after
the FDIS version, so most countries
allow a legal reference to this version.
(AHAM, Public Meeting Transcript, No.
20 at pp. 14–15)
AHAM commented that IEC Standard
62031 FDIS incorporates comments
from energy efficiency advocates,
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including the addition of an uncertainty
power measurement section that would
limit the possibility for different
measurement results from different test
labs. (AHAM, Public Meeting
Transcript, No. 20 at pp. 16, 18, 26–27)
AHAM also noted that IEC Standard
62301 FDIS includes a new sampling
measurement method and an average
reading measurement method. (AHAM,
Public Meeting Transcript, No. 20 at pp.
13–18) AHAM commented that if DOE
chooses not to adopt the IEC Standard
62301 FDIS, AHAM supports the use of
IEC Standard 62301 CDV as the main
referenced document. (AHAM, No. 31 at
p. 2) Pacific Gas and Electric Company
(PG&E), Southern California Gas
Company (SCGC), Southern California
Edison (SCE), and Natural Resources
Defense Council (NRDC) (hereafter ‘‘the
California Utilities/NRDC’’), stated in a
jointly filed comment that they support
harmonization with international
standards and support the use of the
definitions and test procedures in IEC
Standard 62301 CDV. (California
Utilities/NRDC, No. 33 at p. 2)
According to publicly available
information, the IEC currently
anticipates that the final version of IEC
Standard 62301 Second Edition will
likely be published in early 2011.
Therefore, the second edition is not
available for DOE’s consideration or
incorporation by reference. DOE is
aware that there are significant
differences between IEC Standard 62301
First Edition and IEC Standard 62301
FDIS, which is the latest draft version of
IEC Standard 62301 Second Edition.
DOE notes that these changes in
methodology were first introduced only
at the IEC Standard 62301 FDIS stage.
These changes have not been the subject
of significant comment from interested
parties, nor has DOE had the
opportunity to conduct a thorough
analysis of those provisions.
Consequently, the merits of these latest
changes have not been fully vetted to
demonstrate that they are preferable to
the existing methodological provisions
in the current version of the IEC
standard. For these reasons, DOE has
decided to base the test procedure
amendments (other than the mode
definitions, which are discussed in
Section III.B.2) on the provisions of IEC
Standard 62301 First Edition. DOE
based the mode definitions on the
language from IEC Standard 62301 CDV
to address specific concerns raised by
interested parties, as discussed above in
this section. As discussed in section
III.B.2, DOE notes that the mode
definitions in IEC Standard 62301 CDV
are essentially the same as the
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definitions provided in IEC Standard
62301 FDIS, with only minor editorial
changes.
For the reasons discussed above and
in the December 2008 NOPR and June
2010 SNOPR, DOE amends its test
procedures for clothes dryers and room
air conditioners in today’s final rule to
incorporate by reference the clauses
from IEC Standard 62301 First Edition
and the mode definitions from IEC
Standard 62301 CDV. 73 FR 74639
(December 9, 2008); 75 FR 37594, 37602
(June 29, 2010). DOE may consider
incorporating by reference clauses from
IEC Standard 62301 Second Edition
when that version has been published.
2. Determination of Modes To Be
Incorporated
December 2008 TP NOPR
In the December 2008 TP NOPR, DOE
proposed to incorporate into the clothes
dryer and room air conditioner test
procedure the definitions of ‘‘active
mode,’’ ‘‘standby mode,’’ and ‘‘off mode’’
specified by EPCA. 73 FR 74639, 74644
(December 9, 2008). EPCA defines
‘‘active mode’’ as ‘‘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.’’
(42 U.S.C. 6295(gg)(1)(A)(i))
EPCA defines ‘‘standby mode’’ as ‘‘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.’’
(42 U.S.C. 6295(gg)(1)(A)(iii)) This
definition differs from IEC Standard
62301 First Edition, which defines
standby mode as the ‘‘lowest power
consumption mode which cannot be
switched off (influenced) by the user
and that may persist for an indefinite
time when an appliance is connected to
the main electricity supply and used in
accordance with the manufacturer’s
instructions.’’ The EPCA definition
permits the inclusion of multiple
standby modes.
EPCA defines ‘‘off mode’’ as ‘‘the
condition in which an energy-using
product—
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(I) Is connected to a main power
source; and
(II) is not providing any standby mode
or active mode function.’’ 15
(42 U.S.C. 6295(gg)(1)(A)(ii))
DOE recognized, however, that the
EPCA definitions for ‘‘active mode,’’
‘‘standby mode,’’ and ‘‘off mode’’ were
developed to be broadly applicable for
many energy-using products. For
specific products with multiple
functions, these broad definitions could
lead to certain features being considered
part of standby mode or off mode
instead of active mode depending on the
interpretation of the meaning of ‘‘main
functions.’’ 73 FR 74639, 74644–45
(December 9, 2008). As a result, DOE
further proposed in the December 2008
TP NOPR to amend the clothes dryer
and room air conditioner test
procedures to clarify the range of main
functions that would be classified as
active mode functions and clarify
standby and off mode definitions as
follows:
For clothes dryers—
‘‘Active mode’’ means a mode in
which the clothes dryer is performing
the main function of tumbling the
clothing with or without heated or
unheated forced air circulation to
remove moisture from the clothing and/
or remove or prevent wrinkling of the
clothing;
‘‘Inactive mode’’ means a standby
mode other than delay start mode or
cycle finished mode that facilitates the
activation of active mode by remote
switch (including remote control),
internal sensor, or timer, or provides
continuous status display;
‘‘Cycle finished mode’’ means a
standby mode that provides continuous
status display following operation in
active mode;
‘‘Delay start mode’’ means a standby
mode that facilitates the activation of
active mode by timer; and
15 DOE notes that some features that provide
consumer utility, such as displays and remote
controls, are associated with standby mode and not
off mode. A clothes dryer or room air conditioner
is considered to be in ‘‘off mode’’ if it is plugged
in to a main power source, is not being used for an
active function such as drying clothing or providing
cooling, and is consuming power for features other
than a display, controls (including a remote
control), or sensors required to reactivate it from a
low power state. For example, a clothes dryer with
mechanical controls and no display or
continuously-energized moisture sensor, but that
consumes power for components such as a power
supply when the unit was not activated, would be
considered to be in off mode when not providing
an active function. For room air conditioners, a unit
with mechanical controls and no display or remote
control but with a power supply that consumes
energy could be considered to be in off mode while
not providing an active function.
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‘‘Off mode’’ means a mode in which
the clothes dryer is not performing any
active or standby function. 73 FR 74645.
For room air conditioners—
‘‘Active mode’’ means a mode in
which the room air conditioner is
performing the main function of cooling
or heating the conditioned space, or
circulating air through activation of its
fan or blower, with or without
energizing active air-cleaning
components or devices such as
ultraviolet (UV) radiation, electrostatic
filters, ozone generators, or other aircleaning devices;
‘‘Inactive mode’’ means a standby
mode other than delay start mode or offcycle mode that facilitates the activation
of active mode by remote switch
(including remote control) or internal
sensor or provides continuous status
display;
‘‘Delay start mode’’ means a standby
mode in which activation of an active
mode is facilitated by a timer;
‘‘Off-cycle mode’’ means a standby
mode in which the room air
conditioner: (1) Has cycled off its main
function by thermostat or temperature
sensor; (2) does not have its fan or
blower operating; and (3) will reactivate
the main function according to the
thermostat or temperature sensor signal;
and
‘‘Off mode’’ means a mode in which a
room air conditioner is not performing
any active or standby function. 73 FR
74645.
June 2010 TP SNOPR and Today’s Final
Rule—Active Mode.
As discussed in section III.B.1, DOE
proposed in the June 2010 TP SNOPR to
amend the DOE clothes dryer and room
air conditioner test procedures to define
active mode as a mode that ‘‘includes
product modes where the energy using
product is connected to a mains power
source, has been activated and provides
one or more main functions’’ 75 FR
37594, 37603 (June 29, 2010). The
definition of active mode proposed in
the June 2010 TP SNOPR is the same as
the definition proposed for the
December 2008 TP NOPR, with minor
editorial changes to conform with the
definition in IEC Standard 62301 CDV.
73 FR 74639, 74644 (December 9, 2008).
DOE noted that IEC Standard 62301 CD2
provided additional clarification that
‘‘delay start mode is a one off user
initiated short duration function that is
associated with an active mode.’’ (IEC
Standard 62301 CD2, section 3.8) IEC
Standard 62301 CDV removed this
clarification; however, in response to
comments on IEC Standard 62301 CD2
that led to IEC Standard 62301 CDV, IEC
states that delay start mode is a one off
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function of limited duration.16 DOE
inferred this to mean that delay start
mode would not be considered a
standby mode, although no conclusion
is made as to whether it would be
considered part of active mode. 75 FR
37594, 37603 (June 29, 2010). Delay
start mode is discussed later in this
section.
As discussed above in section III.B.1,
the California Utilities/NRDC
commented that it supports the use of
the mode definitions in IEC Standard
62301 CDV. (California Utilities/NRDC,
No. 33 at p. 2) Also discussed above in
section III.B.1, AHAM and Whirlpool
supported the use of the mode
definitions in IEC Standard 62301 FDIS.
(AHAM, Public Meeting Transcript, No.
20 at p. 18; AHAM, No. 31 at p. 2;
Whirlpool, No. 27 at p. 1) DOE notes
that the definition of active mode in IEC
Standard 62301 FDIS is essentially the
same as the definition provided in IEC
Standard 62301 CDV, with only minor
editorial changes. For the reasons stated
above, DOE is adopting in today’s final
rule the active mode definition
proposed in the June 2010 TP SNOPR.
In the June 2010 TP SNOPR, DOE did
not change the additional clarifications
discussed above for the range of main
functions that would be classified as
active mode functions, which were
proposed in the December 2008 TP
NOPR. 75 FR 37594, 37603 (June 29,
2010). DOE did not receive any
comments objecting to the clarifications
for the range of main functions that
would be classified as active mode
functions for each product. Therefore,
for the reasons stated above, DOE adopts
the amendments to clarify the range of
main functions that would be classified
as active mode functions as proposed in
the December 2008 TP NOPR. Id.
For clothes dryers, DOE also
investigated in the June 2010 TP SNOPR
whether certain operating cycles
providing a steam function should be
covered under active mode, and
whether measurement of energy
consumption for such cycles should be
incorporated into the DOE clothes dryer
test procedure. 75 FR 37594, 37603
(June 29, 2010). The current DOE test
procedure does not contain any
provisions that would account for the
energy and water use of steam cycles.
DOE’s analysis of a preliminary market
survey of products available on the
market conducted for the June 2010 TP
SNOPR suggests that, at this time, steam
cycles represent a very small fraction of
16 ‘‘Compilation of comments on 59/523/CD: IEC
62301 Ed 2.0: Household electrical appliances—
Measurement of standby power.’’ August 7, 2009.
p. 6. IEC Standards are available online at https://
www.iec.ch.
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overall product use nationwide. DOE
also stated that it is unaware of energy
and water consumption or consumer
usage data with respect to steam. For
these reasons, DOE did not propose
amendments to include measurement of
steam cycles for clothes dryers in the
June 2010 TP SNOPR. Id. DOE did not
receive any comments regarding the
determination to not include
measurement of steam cycles for clothes
dryers. For these reasons, DOE is not
amending its clothes dryer test
procedure to include measurement of
steam cycles.
June 2010 TP SNOPR and Today’s Final
Rule—Standby Mode
As discussed in section III.B.1, DOE
proposed in the June 2010 SNOPR to
amend the DOE test procedure for
clothes dryers and room air conditioners
to define standby mode based on the
definitions provided in IEC Standard
62301 CDV. 75 FR 37604. DOE proposed
to define standby mode as a mode that
‘‘includes any product modes where the
energy using product is connected to a
mains power source and offers one or
more of the following user oriented or
protective functions which may persist
for an indefinite time: 17
• To facilitate the activation of other
modes (including activation or
deactivation of active mode) by remote
switch (including remote control),
internal sensor, timer;
• Continuous function: information
or status displays including clocks;
• Continuous function: sensor-based
functions.’’ Id.
DOE also proposed an additional
clarifiction that ‘‘a timer is a continuous
clock function (which may or may not
be associated with a display) that
provides regular scheduled tasks (e.g.,
switching) and that operates on a
continuous basis.’’ Id. This defintion
was developed based on the definitions
provided in IEC Standard 62301 CDV,
and expands upon the EPCA mode
definitions to provide additional
clarifications as to which functions are
associated with each mode.
ALS supported DOE’s proposed
definition of standby mode. (ALS, No.
17 The actual language for the standby mode
definition in IEC Standard 62301 CDV describes
‘‘ * * * user oriented or protective functions which
usually persist’’ rather than ‘‘* * * user oriented or
protective functions which may persist for an
indefinite time.’’ DOE notes, however, that section
5.1 of IEC Standard 62301 CDV states that ‘‘a mode
is considered persistent where the power level is
constant or where there are several power levels
that occur in a regular sequence for an indefinite
period of time.’’ DOE believes that the proposed
language, which was originally included in IEC
Standard 62301 CD2, encompasses the possible
scenarios foreseen by section 5.1 of IEC Standard
62301 CDV without unnecessary specificity.
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24 at p. 1) Whirlpool commented that
DOE should reference IEC 62301 FDIS
for the standby mode definition.
(Whirlpool, No. 27 at p. 1) AHAM
commented that DOE should define a
timer function under the standby mode
definition to exclude limited duration
situations where the appliance is in a
higher power state, for example in delay
start mode. (AHAM, Public Meeting
Transcript, No. 20 at pp. 35–36) DOE
notes that the definition of standby
mode in IEC Standard 62301 FDIS is
essentially the same as the definition
provided in IEC Standard 62301 CDV,
with only minor editorial changes. DOE
also notes the definition of standby
mode specifies that it must be a mode
that may persist for an indefinite time,
which would exclude limited duration
situations. Therefore, DOE does not
believe that any additional clarification
in the definition of standby mode is
necessary. For these reasons, DOE is
adopting in today’s final rule the
standby mode definition proposed in
the June 2010 TP SNOPR. 75 FR 37594,
37604 (June 29, 2010).
DOE stated in the June 2010 TP
SNOPR that given these proposed
definitions, delay start mode and cyclefinished mode for clothes dryers and
delay start mode and off-cycle mode for
room air conditioners are not modes
that persist for an indefinite time, and
would therefore not be considered as
part of a standby mode. 75 FR 37604.
DOE’s analysis of annual energy use in
specific clothes dryer and room air
conditioner modes presented in the
December 2008 TP NOPR showed that
delay start mode and cycle-finished
mode for clothes dryers, and delay start
mode and off-cycle mode for room air
conditioners, each represent a negligible
portion (0.1 percent or less) of the
annual energy use for those products. 73
FR 74639, 74647, 74649 (December 9,
2008). Therefore, an integrated energy
efficiency metric for either clothes
dryers or room air conditioners would
not be measurably affected by the
exclusion of the energy use in any of
these modes. Further, DOE stated in the
June 2010 TP SNOPR that the benefit of
incorporating the energy use of these
modes into the overall energy efficiency
metric is outweighed by the burden that
would be placed on the manufacturers
to measure power consumption in each
of these modes. For these reasons, DOE
did not propose amendments to the test
procedures to define delay start, cycle
finished, and off-cycle modes or to
measure power consumption in delay
start mode for either product, cycle
finished mode for clothes dryers, and
off-cycle mode for room air conditioners
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in the June 2010 TP SNOPR. DOE
included in the proposed clothes dryer
and room air conditioner test
procedures amendments in the June
2010 TP SNOPR provisions for
measuring energy consumption only in
the inactive mode and off mode. 75 FR
37594, 37604 (June 29, 2010).
The California Utilities/NRDC,
AHAM, ALS, and Whirlpool agreed that
delay start and cycle finished modes for
clothes dryers would not be considered
standby modes. (California Utilities/
NRDC, No. 33 at p. 2; AHAM, No. 31 at
p. 3; Whirlpool, No. 27 at p. 1; ALS, No.
24 at p. 1) AHAM and Whirlpool added
that delay start and cycle finished
modes should instead be considered
part of active mode. (AHAM, No. 31 at
p. 3; Whirlpool, No. 27 at p. 1)
Whirlpool also commented that any
function begun by the user when
initiating the operating mode includes
all power consumed until the full
conclusion of that operation.
(Whirlpool, No. 27 at p. 1)
DOE continues to believe that delay
start, cycle finished, and off-cycle
modes for clothes dryers and room air
conditioners are not modes that persist
for an indefinite time and, therefore,
would not be considered standby
modes. For the reasons discussed above,
DOE continues to believe that the
benefit of incorporating the energy use
of these modes into the overall energy
efficiency is outweighed by the burden
that would be placed on the
manufacturers to measure power
consumption in each of these modes. As
discussed in section III.B.4, however,
DOE determined that the power
consumption of clothes dryers and room
air conditioners operating in such
modes approximates the power levels in
inactive/off modes. Therefore, DOE
amends the test procedure in today’s
final rule to specify that all non-active
mode hours be allocated to the inactive
and off modes for both clothes dryers
and room air conditioners. Thus, the
amended test procedure accounts for the
energy use in delay start, cycle finished,
and off-cycle modes. For these reasons,
DOE is not adopting amendments to the
test procedures to define delay start,
cycle finished, and off-cycle modes or to
measure power consumption in delay
start mode for either product, cycle
finished mode for clothes dryers, and
off-cycle mode for room air
conditioners.
In the June 2010 TP SNOPR, DOE
noted that it received comments from
interested parties in response to the
December 2008 TP NOPR that the asshipped factory or ‘‘default’’ settings
should be used for standby and off
mode testing. 75 FR 37594, 37605 (June
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29, 2010). DOE stated in the June 2010
TP SNOPR that provisions for setting up
the appliance for standby mode and off
mode testing should be specified in the
test procedure. However, DOE stated
that setting up the appliance in
accordance with manufacturer’s
instructions or in the as-shipped factory
or ‘‘default’’ settings would allow
manufacturers to ship appliances set in
a low power mode that consumers may
switch out of during typical standby or
off mode use. Therefore, DOE proposed
in the June 2010 TP SNOPR that the
appliance be set up with the settings
that produce the highest power
consumption level, consistent with the
particular mode definition under test,
for standby and off mode testing. Id.
AHAM, Whirlpool, and ALS objected
to the proposal that the clothes dryer be
set up at the highest energy
consumption level consistent with the
particular standby or off mode. They felt
such an approach does not reflect
consumer use, increases test burden to
determine such settings, and lacks
conformity, consistency, and
repeatability across manufacturers.
AHAM, Whirlpool, and ALS
commented that the clothes dryer
should instead be set up in factory or
‘‘default’’ cycle settings, and that this
procedure is consistent with consumer
usage and will result in repeatable,
reproducible results. AHAM and
Whirlpool stated that should there be no
indicators for the default settings, the
appliance should be tested as shipped.
AHAM, Whirlpool, and ALS stated that
such an approach would ensure
uniformity among the different
laboratories that may run the test. They
also stated that DOE’s proposal would
introduce unnecessary variability into
the test and add to the test burden
because manufacturers would need to
run several tests on every model to
determine which cycle is the highestenergy cycle. (AHAM, No. 31 at pp.
4–5; Whirlpool, No. 27 at p. 1; ALS, No.
24 at pp. 1–2) Whirlpool added that
repeatable results are of increasing
importance for verification processes.
(Whirlpool, No. 27 at p. 1)
AHAM commented that incentivizing
manufacturers to ship products with the
lowest power settings is a better way to
save energy than shipping with the
highest power settings, because most
consumers do not change the settings.
(AHAM, Public Meeting Transcript, No.
20 at p. 56) AHAM stated that products
may have provisions for the consumer
to add or delete product functions that
alter the as-shipped standby energy
mode, and that the power consumption
in these user-selected modes may
exceed the power consumption in the
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lowest-power consumption mode.
AHAM stated that the user must be
informed as to how to make these
selections and that the selection(s) will
override the lowest-power consumption
mode. According to AHAM, testing the
appliance in the factory settings or
‘‘default’’ settings provides a clear and
simple way to define standby mode and
allow new functions that may be
developed to be added to the
appropriate mode without requiring the
test procedure be revised. (AHAM, No.
31 at p. 3)
The California Utilities/NRDC
supported DOE’s proposed approach to
use the settings that produce the highest
power consumption for standby and off
mode testing. They felt this approach
would remove a potential opportunity
for ‘‘gaming’’ appliance testing and
would ensure that the standby mode
and off mode testing would measure the
highest energy-consuming combination
of modes. The California Utilities/NRDC
stated that there is no data that indicates
that the factory default settings are
uniform, or that they are typically used
by consumers. In addition, the
California Utilities/NRDC stated that
DOE’s proposed approach would
standardize the standby mode and off
mode testing among manufacturers,
because how a factory default setting is
used during testing may not be
consistent from manufacturer to
manufacturer. (California Utilities/
NRDC, No. 33 at p. 2) Appliance
Standards Awareness Project (ASAP)
also commented that using the default
settings for testing would give
manufacturers an incentive to ship
products in a very low-power mode that
consumers may never use because they
can easily adjust the settings. (ASAP,
Public Meeting Transcript, No. 20 at
p. 55)
DOE agrees with AHAM, Whirlpool,
and ALS that the proposed provisions
for testing standby and off mode using
the settings that produce the highest
power consumption level consistent
with the particular mode definition
under test would not be representative
of consumer use. If manufacturers were
to ship products in a very low-power
mode, DOE does not believe that
consumers would likely modify the
settings so that the product is in the
highest power settings, but would
instead use what would have been the
as-shipped factory or ‘‘default’’ settings
during typical standby or off mode use.
DOE agrees that, because newer
products offer more consumer related
features and thus more display or
settings configurations, requiring
laboratories to determine the settings
that produce the highest power
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consumption levels would make it more
difficult to ensure that test results are
repeatable. DOE notes that section 5.2 of
IEC Standard 62301, ‘‘Selection and
preparation of appliance or equipment,’’
includes provisions for installing and
setting up the appliance as specified by
manufacturers instructions. Section 5.2
of IEC Standard 62301 also specifies
that if no instructions are given, the
appliance shall be tested at factory or
default settings, and where there are no
indications for such settings, the
appliance shall be tested as supplied.
DOE believes that section 5.2 of IEC
Standard 62301 clarifies the installation
requirements for standby mode and off
mode energy consumption testing and
provides additional guidance regarding
specifications for test setup that would
result in a measure of standby and off
mode energy consumption that best
replicates actual consumer usage. For
these reasons, DOE is incorporating by
reference section 5.2 of IEC Standard
62301 for standby and off mode testing
in today’s final rule.
June 2010 TP SNOPR and Today’s Final
Rule—Standby Mode or Active Mode,
Network Mode
For the June 2010 TP SNOPR, DOE
also considered whether it should adopt
amendments for network mode. 75 FR
37594, 37605 (June 29, 2010). Section
3.7 of IEC Standard 62301 CDV defines
network mode as a mode category that
‘‘includes any product modes where the
energy using product is connected to a
main power source and at least one
network function is activated (such as
reactivation via network command or
network integrity communication) but
where the primary function is not
active.’’ Section 3.7 of IEC Standard
62301 CDV also provides a note stating,
‘‘Where a network function is provided
but is not active and/or not connected
to a network, then this mode is not
applicable. A network function could
become active intermittently according
to a fixed schedule or in response to a
network requirement. A ‘network’ in
this context includes communication
between two or more separate
independently powered devices or
pieces of equipment. A network does
not include one or more controls, which
are dedicated to a single piece of
equipment. Network mode may include
one or more standby functions.’’
However, DOE stated in the June 2010
TP SNOPR that it is unaware of any
clothes dryers or room air conditioners
currently available on the market that
incorporate a networking function.
Further, DOE stated that it is unaware
of any data regarding network mode that
would enable it to determine
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983
appropriate testing procedures and
mode definitions for clothes dryers and
room air conditioners. In particular,
DOE stated that it is unaware of data
and methods for the appropriate
configuration of networks; whether
network connection speed or the
number and type of network
connections affects power consumption;
or whether wireless network devices
may consume power differently when
the device is looking for a connection as
opposed to when the network
connection is actually established. DOE
stated that it is also unaware of how the
energy consumption for clothes dryers
and room air conditioners in a network
environment might be affected by their
product design, user interaction, or
network interaction. For example, DOE
is unaware of what affects might result
should the network function become
active intermittently according to a
fixed schedule or in response to a
network requirement. For these reasons,
the proposed amendments in the June
2010 TP SNOPR did not include
network mode. Id.
AHAM commented that there are not
enough products currently available on
the market from which to gather data
regarding network mode. AHAM stated
that, in the event DOE decides to
address network mode, AHAM does not
support including network mode in
standby or off mode. AHAM commented
that network mode and the energy use
associated with ‘‘Smart Appliances’’ 18
should be treated as a distinctive energy
use that enhances electrical grid system
efficiencies that save energy and reduce
carbon emissions, adding that this is
consistent with IEC Standard 62301
FDIS. AHAM also commented that
when sufficient data exists, AHAM
would be willing to work with DOE to
define where and how to address
network mode. (AHAM, No. 31 at p. 4)
AHAM also added that if network mode
is considered part of standby mode, it
would be a major difficulty in the
development of ‘‘Smart Appliances’’ and
the ‘‘Smart Grid.’’ 19 (AHAM, Public
Meeting Transcript, No. 20 at pp. 38–39)
Whirlpool commented that network
mode will become a vital mode in the
future development of appliances
capable of interacting with the Smart
Grid, but that such products do not exist
today outside of development
laboratories. Whirlpool urged DOE to
18 A ‘‘Smart Appliance’’ is a product equipped
with network mode capabilities.
19 A ‘‘Smart Grid’’ is an automated electric power
system that monitors and controls electrical grid
activities and is capable of real-time two-way digital
communications between utilities and consumers.
Information on Smart Grid is available online at
https://www.oe.energy.gov/smartgrid.htm.
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retain network mode as a separate mode
as distinct from any other mode.
Whirlpool urged that no standard or test
procedure be adopted for this mode
until manufacturers have sufficient
quantities of Smart Grid models in
production that comprehensive testing
and measurement can take place.
(Whirlpool, No. 27 at pp. 1–2)
The American Council for an EnergyEfficient Economy (ACEEE), ASAP, and
NRDC stated in a jointly filed comment
(hereafter the ‘‘Joint Efficiency
Advocates Comment’’) that if network
mode is a mode the appliance would be
in at all times, it should be classified as
standby; if it is an intermittent or useractivated condition, it should be
considered active mode. The Joint
Efficiency Advocates Comment
suggested that DOE’s definition of
network mode be aligned with the IEC
definition and recommended creating a
test method for network mode. This test
method would be similar to the standby
test method, but network connectivity
would be enabled. The Joint Efficiency
Advocates Comment stated that units
could be tested without actually
connecting to a network; simply
enabling the network capabilities
should be enough to test energy
consumption while in a simulated
networking state. The Joint Efficiency
Advocates Comment recommended that
DOE consider incorporating network
mode into energy consumption ratings
as the market for network-enabled
devices developed. In the meantime,
network mode should be tested on
available appliances, and that research
and analysis should be conducted on
predicted or actual consumer usage in
advance of a future revision to the test
procedure. (Joint Efficiency Advocates
Comment, No. 28 at p. 3)
DOE notes that, in the absence of data
on the operation and functionality of
network mode, it is unable to define
appropriate testing conditions and
procedures for accurately measuring the
energy use of clothes dryers and room
air conditioners capable of functioning
in network mode. This lack of data also
prevents DOE from evaluating how
these products will develop in the
future. Also, because DOE does not have
sufficient data on the operation and
functionality of network mode, it is not
making a determination as to whether
network mode would be included as
part of standby or active mode. DOE
may consider amendments to the
clothes dryer and room air conditioner
test procedures when products capable
of functioning in network mode are in
production and commercially available.
At that time, comprehensive analysis
can determine appropriate testing
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conditions and procedures for
accurately measuring network mode
energy use.
June 2010 TP SNOPR and Today’s Final
Rule—Off Mode
As discussed in section III.B.1, DOE
proposed in the June 2010 TP SNOPR to
amend the DOE test procedure for
clothes dryers and room air conditioners
to define off mode based upon the
definition in IEC Standard 62301 CDV.
DOE proposed to define off mode as a
mode category which ‘‘includes any
product modes where the energy using
product is connected to a mains power
source and is not providing any standby
mode or active mode function and
where the mode may persist for an
indefinite time.20 An indicator that only
shows the user that the product is in the
off position is included within the
clasification of off mode.’’ This defintion
was developed based on the definitions
provided in IEC Standard 62301 CDV,
and expands upon the EPCA mode
definitions to provide additional
clarifications as to which functions are
associated with each mode. 75 FR
37594, 37605 (June 29, 2010).
AHAM commented that the off mode
definition proposed in the June 2010 TP
SNOPR, which is based on IEC Standard
62301 CDV, is identical to the definition
included in IEC Standard 62301 FDIS.
(AHAM, Public Meeting Transcript, No.
20 at p. 41) For the reasons stated above,
DOE is adopting in today’s final rule the
off mode definition proposed in the
June 2010 TP SNOPR. 75 FR 37594,
37605 (June 29, 2010).
DOE also stated in the June 2010 TP
SNOPR that under the proposed mode
definitions, a clothes dryer or room air
conditioner equipped with a mechanical
on/off switch that can disconnect power
to the display, control components, or
both would be considered as operating
in the off mode when the switch is in
the ‘‘off’’ position, provided that no
other standby or active mode functions
are energized. DOE also stated that an
energized LED or other indication that
only shows the user the product is in
the off position would be considered
part of off mode under the proposed
definition, provided that no other
standby or active mode functions were
energized. If energy is consumed by the
appliance in the presence of a one-way
remote control, however, the unit would
be operating in standby mode pursuant
to EPCA (42 U.S.C. 6295(gg)(1)(A)(iii)).
20 As with the definition for standby mode, IEC
Standard 62301 CDV qualifies off mode as one that
‘‘* * * usually persists’’ rather than one that ‘‘* * *
may persist for an indefinite time.’’ For the same
reasons as discussed for standby mode, DOE is
proposing the latter definition.
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DOE clarified that the unit would be
operating in standby mode if energy is
consumed in the presence of a remote
control that facilitates the activation or
deactivation of other functions
(including active mode). 75 FR 37594,
37605–06 (June 29, 2010).
AHAM and Whirlpool commented
that they do not support including oneway remote control energy in the
definition of standby mode. AHAM and
Whirlpool stated that although EPCA
defines standby mode to include
activation by remote control, one-way
remotes do not meet the intent of the
statute. AHAM and Whirlpool further
commented that when a standard
remote powers a product ‘‘off,’’ the
remote actually powers the product
down, not off, such that it can be turned
on again via remote control, and that
this would be classified as a standby
mode under the EPCA standby mode
definition. According to AHAM and
Whirlpool, a one-way remote turns the
product completely off such that it
cannot be turned on again by the
remote. Therefore, a one-way remote
does not put the product into a standby
mode and should not be incorporated
into standby mode. (AHAM, No. 31 at
p. 3; AHAM, Public Meeting Transcript,
No. 20 at pp. 32–33; Whirlpool, No. 27
at p. 1) AHAM added that there are
currently few, if any, one-way remotes
in the United States. AHAM stated that
including one-way remotes in the off
mode instead of in the standby mode
will encourage manufacturers to design
products with one-way remotes, which
could result in decreased energy use.
(AHAM, No. 31 at p. 3) AHAM also
noted that a number of other
governments and organizations consider
one-way remotes as exempt from
standby mode because such remotes
save power. AHAM stated that DOE
should take the same approach. (AHAM,
Public Meeting Transcript, No. 20 at pp.
33–34)
DOE notes the definition of standby
mode proposed in the June 2010 TP
SNOPR states that standby mode
includes user-oriented or protective
functions to facilitate the activation of
other modes (including activation or
deactivation of active mode) by remote
switch (including remote control),
internal sensor, or timer. DOE believes
that if the product is consuming energy
to power an infrared sensor used to
receive signals from a remote control
(while not operating in the active
mode), such a function would be
considered part of standby mode,
regardless of whether the remote is
classified as ‘‘one-way’’ or ‘‘two-way.’’
This is because the function to facilitate
the deactivation of another mode by
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remote switch (including remote
control), internal sensor, or timer is still
active. However, if a ‘‘one-way’’ remote
control powers the product down,
including turning off any infrared
sensors to receive signals from a remote
control, the product would be operating
in the off mode once it is powered
down, given that no other standby mode
functions within the product are
energized. Depending on whether the
product is capable of operating in both
a standby mode and off mode or just the
off mode, the annual hours associated
would be allocated as appropriate, as
discussed in section III.B.4.
DOE also notes that section 3.9 of IEC
Standard 62301 CDV provides a
definition of ‘‘disconnected mode,’’
which is ‘‘the status in which all
connections to mains power sources of
the energy using product are removed or
interrupted.’’ IEC Standard 62301 CDV
also adds a note that common terms
such as ‘‘unplugged’’ or ‘‘cut off from
mains’’ also describe this mode and that
this mode is not part of the low power
mode category. DOE believes there
would be no energy use in a
‘‘disconnected mode’’ and therefore is
not adopting a definition or testing
methods for such a mode in the DOE
test procedure for clothes dryers or
room air conditioners in today’s final
rule.
3. Adding Specifications for the Test
Methods and Measurements for Clothes
Dryer and Room Air Conditioner
Standby Mode and Off Mode Testing
DOE proposed in the December 2008
TP NOPR to establish test procedures
for measuring all standby and off modes
associated with clothes dryers and room
air conditioners. 73 FR 74639, 74645
(December 9, 2008). As discussed in
section III.B.2, DOE believes that the
mode identified as inactive mode in the
December 2008 TP NOPR is the only
significant standby mode for clothes
dryers and room air conditioners. This
section discusses product-specific
clarifications of the procedures of IEC
Standard 62301 when used to measure
standby and off mode energy use for
clothes dryers and room air
conditioners.
a. Clothes Dryers
DOE understands that displays on
clothes dryers may reduce power
985
consumption by automatically dimming
or powering down after a certain period
of user inactivity. For those clothes
dryers for which the power input in
inactive mode varies in this fashion
during testing, DOE proposed in the
December 2008 TP NOPR that that the
test be conducted after the power level
has dropped to its lower-power state. 73
FR 74639, 74645 (December 9, 2008).
As part of the residential clothes dryer
energy conservation standards
rulemaking preliminary analyses, DOE
conducted standby mode and off mode
testing on 11 representative residential
clothes dryers. All of the units with
electronic controls automatically
dimmed or powered down after a period
of user inactivity. Table III.1 shows the
measured duration of the higher-power
state for clothes dryers in DOE’s test
sample. DOE observed during this
testing that the higher-power state in
inactive mode may persist for
approximately 5–7 minutes of user
inactivity after the user interface display
has been energized for all products
tested.
TABLE III.1—CLOTHES DRYER STANDBY MODE TESTING: DURATION OF HIGHER-POWER STATE
Product class
Test unit
Vented Electric, Standard ................................
1
2
3
4
5
6
7
8
9
10
11
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Vented Gas ......................................................
Paragraph 5.3.1 of section 5.3 of IEC
Standard 62301 specifies, for products
in which the power varies by not more
than 5 percent from a maximum level
during a period of 5 minutes, that the
user wait at least 5 minutes for the
product to stabilize and then measure
the power at the end of an additional
time period of not less than 5 minutes.
Paragraph 5.3.2 of IEC Standard 62301
contains provisions for measuring
average power in cases where the power
is not stable. In such cases, it requires
a measurement period of no less than 5
minutes, or one or more complete
operating cycles of several minutes or
hours. Based on its testing results
shown in Table III.1, however, DOE
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Electromechanical ............................................
Electromechanical ............................................
Electronic ..........................................................
Electromechanical ............................................
Electromechanical ............................................
Electromechanical ............................................
Electromechanical ............................................
Electronic ..........................................................
Electronic ..........................................................
Electronic ..........................................................
Electronic ..........................................................
noted that some clothes dryers may
remain in the higher-power state for the
duration of a 5-minute stabilization
period and 5-minute measurement
period, and then drop to the lowerpower state that is more representative
of inactive mode. In contrast to IEC
Standard 62301, IEC Standard 62301
CDV specifies for each testing method
that the product be allowed to stabilize
for at least 30 minutes prior to a
measurement period of not less than 10
minutes. DOE stated in the June 2010
TP SNOPR that this clarification would
allow sufficient time for displays that
automatically dim or power down after
a period of user inactivity to reach the
lower-power state prior to measurement.
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Control type
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N
N
Y
N
N
N
N
Y
Y
Y
Y
Duration of
higher-power
state
(min)
......................
......................
5
......................
......................
......................
......................
5
5
7
7
DOE stated that based on its observation
of the automatic power-down time
periods during its testing, the 30-minute
stabilization and 10-minute
measurement periods provide a clearer
and more consistent testing procedure
than the corresponding times specified
in IEC Standard 62301. A testing
procedure using these stabilization and
measurement periods would result in
representative measurements among
products that may have varying times
before the power drops to a low level.
75 FR 37594, 37607 (June 29, 2010).
DOE also noted in the June 2010 TP
SNOPR that allowing a test period of
‘‘not less than’’ or ‘‘at least’’ a specified
amount of time, as provided in both IEC
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Standard 62301 and IEC Standard 62301
CDV, may result in different test
technicians testing the same product for
different periods of time. To ensure the
testing procedures for standby and off
mode are clear and consistent such that
different test technicians test the
product using the same procedures,
DOE proposed the stabilization period
be 30 to 40 minutes, and the test period
be 10 minutes. Id.
ALS and AHAM supported DOE’s
proposal to require a stabilization
period of 30 minutes and a test period
of 10 minutes for clothes dryers. (ALS,
No. 24 at p. 1; AHAM, No. 31 at p. 4)
AHAM commented that the purpose of
the stabilization period is to reach a
steady-state condition with a power
state that may last for an indefinite
period of time. AHAM stated that IEC
Standard 62301 includes provisions to
wait to reach the lowest power state
without specifying a time to allow an
accurate measurement for all products,
so that all products are tested in the
same manner. AHAM noted that this
will result in some power consumption
in the higher energy state not being
measured, but this amount is likely to
be small due to the small amount of
time products spend in this mode.
(AHAM, Public Meeting Transcript, No.
20 at pp. 45–48) AHAM also
commented that a note in section 3.4 of
IEC Standard 62301 FDIS states that a
transition between modes would not be
considered a mode, and that none of the
123 countries involved with the IEC
process commented on this note.
(AHAM, Public Meeting Transcript, No.
20 at pp. 48–49)
DOE agrees with AHAM’s comments
that any transition between modes
would not be considered a mode.
Therefore, DOE does not intend to
include the measurement of energy
consumption for any stabilization or
transition phases when the product is
powering down to a lower-power state.
For the reasons stated above, DOE
adopts in today’s final rule the
requirement that the stabilization period
be 30 to 40 minutes and the test period
be 10 minutes, as proposed in the June
2010 TP SNOPR. 75 FR 37594, 37607
(June 29, 2010).
DOE proposed in the December 2008
TP NOPR to adopt the test room
ambient temperature of 73.4 ± 9 °F
specified by IEC Standard 62301 for
standby mode and off mode testing. 73
FR 74639, 74645–46 (December 9,
2008). This test room ambient
temperature is slightly different from
the ambient temperature currently
specified for DOE’s drying performance
tests of clothes dryers (75 ± 3 °F).
However, the proposed test room
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ambient temperature conditions would
permit manufacturers who opt to test
active, standby, and off modes in the
same test room to use the current
ambient temperature requirements for
drying tests, because the latter
temperatures are within the limits
specified by IEC Standard 62301.
Alternatively, the proposed temperature
specifications would allow a
manufacturer who opts to conduct
standby mode and off mode testing
separately from drying tests more
flexibility in ambient temperature.
In comments submitted on the June
2010 TP SNOPR, AHAM, ALS, and
Whirlpool supported the proposed test
room ambient temperature for clothes
dryer standby and off mode testing.
(AHAM, No. 31 at p. 4; ALS, No. 24 at
p. 1; Whirlpool, No. 27 at p. 2) For the
reasons stated above, and in the absence
of any comments on this proposal, DOE
adopts the test room ambient
temperature of 73.4 ± 9 °F specified by
IEC Standard 62301 for standby mode
and off mode testing.
b. Room Air Conditioners
A room air conditioner with a
temperature display may use varying
amounts of standby power depending
on the digit(s) being displayed. DOE
proposed in the December 2008 TP
NOPR to require that test room
temperature be maintained at 74 ± 2 °F,
and that the temperature control setting
be 79 °F. 73 FR 74639, 74646 (December
9, 2008). These conditions differ from
the cooling performance testing
conditions in the current DOE room air
conditioner test procedure. The cooling
performance test conditions are
specified as 80 °F on the indoor side of
the test chamber and 95 °F on the
outdoor side. In addition, the cooling
performance test conditions do not
specify a temperature control setting.
DOE proposed the different test room
conditions in the December 2008 TP
NOPR because such conditions would
assure a consistent display
configuration, and thus a representative
power consumption, for all room air
conditioners under test, particularly
during the off-cycle operation defined in
the December 2008 TP NOPR as a
standby mode. 73 FR 74646.
As part of the room air conditioner
energy conservation standards
rulemaking preliminary analyses, DOE
conducted standby mode and off mode
testing on representative room air
conditioners. During its preliminary
tests, DOE determined that room air
conditioner displays among the units it
tested do not provide any user
information in inactive mode. In
addition, DOE determined that the
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displays among the units it tested
provide indication of time delay or time
until start rather than temperature when
the air conditioners are in delay start
mode. As a result, DOE stated in the
June 2010 TP SNOPR that the proposed
test chamber ambient conditions would
be relevant only for off-cycle mode. DOE
also stated that if the test procedure
were limited to measurement of inactive
mode as the single standby mode and an
off mode as discussed in section III.B.2,
the proposed close tolerance on ambient
temperature would not be required. 75
FR 37594, 37608 (June 29, 2010). DOE
therefore proposed in the June 2010 TP
SNOPR to provide flexibility in the
room air conditioner test procedure
amendments by allowing standby mode
and off mode testing either in a test
chamber used for measurement of
cooling performance or in a separate test
room that meets the specified standby
mode and off mode test conditions. The
proposed amendments to the room air
conditioner test procedure in the June
2010 TP SNOPR specify maintaining the
indoor test conditions at the
temperature required by section 4.2 of
IEC Standard 62301 if tested in a
cooling performance test chamber. The
proposed amendments also specify
maintaining the room ambient test
conditions at the temperature required
by section 4.2 of IEC Standard 62301 if
tested in a separate test room. Further,
if the unit is tested in the cooling
performance test chamber, the proposed
amendments in the June 2010 TP
SNOPR allow the manufacturer to
maintain the outdoor test conditions
either as specified for the DOE cooling
test procedure or according to section
4.2 of IEC Standard 62301 for standby
and off mode testing. DOE also noted
that the indoor temperature conditions
required by the DOE cooling
performance test procedure fall within
the temperature range specified by
section 4.2 of IEC Standard 62301. Id.
AHAM supported DOE’s proposed
test room ambient temperature for room
air conditioner standby and off mode
testing. (AHAM, No. 31 at p. 4) ASAP
questioned whether DOE has conducted
any testing to determine if there are any
differences in the power measurements
between the two temperature
conditions. (ASAP, Public Meeting
Transcript, No. 20 at p. 60) DOE is not
aware of any data indicating that the
ambient temperature would affect the
measured standby or off mode power.
For the reasons stated above, DOE is
adopting in today’s final rule the test
room ambient temperature proposed in
the June 2010 TP SNOPR for room air
conditioner standby and off mode
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testing. 75 FR 37594, 37608 (June 29,
2010).
Similar to clothes dryers, DOE
proposed in the December 2008 TP
NOPR (73 FR 74639, 74646 (December
9, 2008)) that standby and off modes for
room air conditioners, other than delay
start mode, be tested with a stabilization
period of no less than 5 minutes and a
measurement period of no less than 5
minutes for units with stable power,
consistent with paragraph 5.3.1 of
section 5.3 of IEC Standard 62301. In
cases where the power was unstable, the
provisions of paragraph 5.3.2 would
apply, in which the measurement
period would be no less than 5 minutes
or one or more complete operating
cycles. DOE stated in the June 2010 TP
SNOPR that it does not have any
information or data that would suggest
that a 30-minute stabilization period
followed by a 10-minute measurement
period would produce more
representative or consistent standby and
off mode power measurements than the
times proposed in the December 2008
TP NOPR. 75 FR 37594, 37608 (June 29,
2010).
DOE also noted, however, that
allowing a test period of ‘‘not less than’’
or ‘‘at least’’ a specified amount of time,
as provided in IEC Standard 62301, may
result in different test technicians
testing the same product for different
periods of time. To ensure that the
testing procedures for standby and off
mode are clear and consistent, such that
different test technicians are testing the
product using the same procedures,
DOE proposed in the June 2010 TP
SNOPR to require that the stabilization
period be 5 to 10 minutes, and the test
period be 5 minutes. 75 FR 37594,
37608 (June 29, 2010).
AHAM supported DOE’s proposed
stabilization period for room air
conditioners. (AHAM, No. 31 at p. 4)
For the reasons stated above, DOE
adopts the requirement that the
stabilization period be 5 to 10 minutes
and the test period be 5 minutes, as
proposed in the June 2010 TP SNOPR.
75 FR 37594, 37608 (June 29, 2010).
4. Calculation of Energy Use Associated
With Standby Modes and Off Mode
Measurements of power consumption
associated with each standby and off
mode for clothes dryers and room air
conditioners are expressed in W. The
annual energy consumption in each of
these modes for a clothes dryer or room
air conditioner is the product of the
power consumption in W and the time
spent in that particular mode.
a. Clothes Dryers
Energy use for clothes dryers is
expressed in terms of total energy use
per drying cycle. As discussed in
section III.D.3, DOE has determined that
it is technically feasible to incorporate
measures of standby and off mode
energy use into the overall energy-use
metric. (42 U.S.C. 6295(gg)(2)(A))
Therefore, DOE has examined standby
and off mode energy consumption in
terms of annual energy use apportioned
on a per-cycle basis. Energy used during
a drying cycle (active mode) is directly
measured in the DOE test procedure,
although adjustments are made to the
directly measured energy to account for
differences between test and field
conditions.
DOE proposed in the December 2008
TP NOPR to adopt a similar approach
for measuring energy consumption
during standby and off modes for
clothes dryers. Specifically, to measure
energy consumption during standby and
off modes for clothes dryers, DOE
proposed in the December 2008 TP
NOPR to adopt the current 140 hours
associated with drying (that is, the
active mode) and to associate the
remaining 8,620 hours of the year with
the standby and off modes. Table III.2
presents the comparison of the
approximate wattages and annual
energy use associated with all modes
that DOE proposed in the December
2008 TP NOPR. 73 FR 74639, 74647–48
(December 9, 2008).
TABLE III.2—DOE ESTIMATE OF ANNUAL ENERGY USE OF CLOTHES DRYER MODES
Mode
Hours
Active ................................................................................................................................................
Delay Start ........................................................................................................................................
Cycle Finished ..................................................................................................................................
Off and Inactive ................................................................................................................................
140
* 34
** 429
† 8,157
Typical
power
W
6,907 ...........
3 ..................
3 ..................
0.5 to 3 ........
Annual energy use
kilowatthours (kWh)
967.
0.1.
1.
4 to 24.
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* 5 minutes per cycle × 416 cycles per year.
** 5 percent of remaining time (0.05 × (8,760 ¥ 140 ¥ 34) = 429).
† 95 percent of remaining time (0.95 × (8,760 ¥140 ¥ 34) = 8,157).
DOE reviewed comments from
interested parties on the December 2008
TP NOPR and stated in the June 2010
TP SNOPR that under the proposed
definitions of standby and off modes,
the allocation of annual hours to
inactive and off modes is appropriate.
DOE also stated that the June 2010 TP
SNOPR did not affect DOE’s proposal in
the December 2008 TP NOPR for this
allocation of hours. 75 FR 37594, 37609
(June 29, 2010).
In the December 2008 TP NOPR, DOE
also proposed an alternative simplified
methodology for allocating annual
hours. 73 FR 74639, 74648 (December 9,
2008). The comparison of annual energy
use of different clothes dryer modes
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shows that delay start and cycle
finished modes represent a negligible
percentage of total annual energy
consumption. In addition, for clothes
dryers currently on the market, power
levels in these modes are similar to
those for off/inactive modes. Therefore,
DOE proposed that all of the non-active
hours (which total 8,620) would be
allocated to the inactive and off modes.
73 FR 74648. As discussed in section
III.B.2, DOE determined in the June
2010 TP SNOPR that delay start and
cycle finished modes are not standby
modes according to the proposed
definitions. Because the power
consumption of clothes dryers operating
in such modes approximates the power
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levels in off/inactive modes, DOE stated
in the June 2010 TP SNOPR that it
would be more appropriate under a
simplified approach to allocate the
hours associated with delay start and
cycle finished modes to off/inactive
modes. Therefore, and because DOE did
not propose amendments to the clothes
dryer test procedure to measure delay
start and cycle finished power
consumption given the negligible power
consumption in these modes, DOE
proposed in the June 2010 TP SNOPR to
maintain the estimate of 8,620 hours as
the non-active hours that would be
allocated to inactive and off modes for
clothes dryers. 75 FR 37594, 37601
(June 29, 2010).
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ALS objected to retaining the
allocation of clothes dryer hours
proposed in the June 2010 TP SNOPR.
ALS stated that the estimates were
based on 416 cycles per year and
supported a revision to the hours so that
they are consistent with DOE’s proposed
283 cycles per year and other proposed
cycle definition changes. (ALS, No. 24
at p. 2) DOE notes that the estimate of
delay start mode hours developed in the
December 2008 TP NOPR was based on
the number of cycles per year in the
existing test procedure (that is, 416
cycles per year). DOE estimated in the
December 2008 TP NOPR that 5 minutes
per cycle are spent in delay start mode.
73 FR 74639, 74647 (December 9, 2008).
Under the amended test procedure in
today’s final rule, the number of cycles
per year is revised from 416 to 283
cycles per year. Thus, DOE now
estimates that clothes dryers would be
in delay start mode approximately 24
hours per year. DOE also notes that the
estimate for active mode hours
presented in the December 2008 TP
NOPR was fixed based on the number
of such hours specified in the existing
test procedure (140 hours). 73 FR
74646–7. DOE acknowledges that its
estimate of the number of cycles per
year has decreased. As discussed later
in this section, DOE notes that other
proposed amendments in today’s final
rule, including the changes to the initial
RMC, test load size, and specified water
temperature for test load preparation,
may also affect cycle time and the
number of active mode hours per year.
DOE is not aware, however, of any data
indicating that the number of active
mode hours has changed and, if so,
what a more accurate number might be.
Therefore, DOE is not proposing
amendments to the number of active
mode hours. In the December 2008 TP
NOPR DOE estimated 5 percent of the
remaining hours (that is, not including
active mode hours and delay start mode
hours) would be associated with cycle
finished mode and 95 percent
associated with inactive/off modes (73
FR 74647). This would result in revised
values of 430 hours for cycle finished
mode and 8,166 hours for inactive/off
modes. DOE acknowledges that the
estimates for hours in each standby and
off mode would change based on the
number of annual clothes dryer cycles.
Because DOE is not proposing to
measure delay start and cycle finished
modes for clothes dryers, however, and
is instead allocating those hours to
inactive/off modes (as discussed in
section III.B.2), the aforementioned
revisions to the standby and off mode
hours would not change the total hours
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allocated to inactive/off mode because
the number of active mode hours is
fixed.
ALS commented that DOE must also
take into account the active mode cycle
length change if DOE accepts
commenters’ support for testing the
complete cycle including cool-down in
the automatic termination test cycle.
DOE’s studies indicated that the cooldown in the automatic termination test
cycle would be required to be tested on
100 percent of clothes dryers on the
market. ALS commented that the
Whirlpool-supplied estimate presented
in the June 2010 TP SNOPR indicates an
active drying cycle length of 20 minutes,
which ALS stated is far too short if cooldown period is included. (ALS, No. 24
at p. 2) AHAM also questioned whether
including the cool-down period would
change the number of hours allocated to
each mode in the calculations. (AHAM,
Public Meeting Transcript, No. 20 at pp.
99–100) AHAM further commented that
it could be difficult to assign a typical
time to cool-down mode because there
are significant differences between
clothes dryers in the amount of time
spent in this mode. (AHAM, Public
Meeting Transcript, No. 20 at pp. 100–
101) AHAM also commented, however,
that cycle times are very dependent on
the initial RMC used and that reducing
the initial RMC value and accounting
for cool-down may end up equaling out
to the current 140 hours. (AHAM,
Public Meeting Transcript, No. 20 at pp.
103–104)
As discussed in section III.C.2, DOE is
not adopting the amendments to the
clothes dryer test procedure to better
account for automatic cycle termination
that were proposed in the June 2010 TP
SNOPR. Therefore, DOE is not
amending the test procedure to include
the cool-down period as part of any
automatic cycle termination tests. For
this reason, DOE does not believe the
estimates for the annual hours spent in
each mode should be revised on the
basis of the inclusion of a cool-down
period. With regard to AHAM’s
comments concerning the reduction in
initial RMC and the effect on cycle
times, DOE addresses how that
amendment, along with the other
amendments in today’s final rule, affect
the clothes dryer cycle time later in this
section.
ALS objected to DOE’s proposal of
429 hours of ‘‘cycle finished’’ mode. ALS
commented that while clothes dryers
may include an option alerting the user
that the cycle has finished via an alert
signal emitting periodically for up to an
hour, ALS does not believe a user would
avoid responding to the alert for an hour
each and every cycle. According to ALS,
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most users will attend their dried
garments within only a few minutes
after the end of the drying cycle,
because users want to complete their
laundry chores as quickly as they can.
Additionally, ALS commented that
users would utilize this feature for only
one third of clothes dryer cycles if cycle
finished mode is an option. Therefore,
ALS stated that ‘‘cycle finished mode’’
hours should be no more than one third
of the ‘‘active mode’’ hours. ALS further
suggested that DOE conduct consumer
studies on user habits for ‘‘cycle
finished’’ mode. (ALS, No. 24 at p. 2)
DOE analysis suggests that a cycle
finished mode feature (that is, a status
display following operation in active
mode indicating to the user that the
cycle is complete) is activated by default
at the end of the drying cycle for most
clothes dryers. For this reason, DOE
believes consumers use the cycle
finished mode feature for more than one
third of clothes dryer cycles. In
addition, DOE does not have any
consumer usage data suggesting that
most consumers attend to their laundry
within only a few minutes after the end
of the drying cycle. In the absence of
such data, DOE maintains for today’s
final rule its estimate from the
December 2008 TP NOPR that cycle
finished mode represents 5 percent of
the remaining time outside of active
mode and delay start mode. This
estimate was based on a household
survey conducted in 2000 in Australia.
73 FR 74639, 74647 (December 9, 2008).
DOE is not aware of any other consumer
usage data regarding cycle finished
mode hours. DOE also notes it is not
proposing to measure delay start and
cycle finished modes for clothes dryers
and is instead allocating those hours to
inactive/off modes, as discussed in
section III.B.2. Therefore, any revisions
to the number of cycle finished mode
hours would not change the total hours
allocated to inactive/off mode.
In the December 2008 TP NOPR, DOE
proposed to allocate the number of
hours for the combined off and inactive
modes entirely to either off mode or
standby mode, as appropriate, if only
one of these modes is possible for the
clothes dryer. DOE noted in the October
2008 TP NOPR that information to guide
allocation of the hours for clothes dryers
that have both inactive and off modes is
currently unavailable. DOE is aware of
two operational scenarios: (1) A clothes
dryer reverts to an off mode after a
specified time in inactive mode; or
(2) a clothes dryer stays in inactive
mode unless the user switches the
appliance back to off mode. DOE does
not have information regarding the
percentage of clothes dryers being sold
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that fall into these categories. Because of
this limitation, DOE proposed in the
October 2008 TP NOPR to allocate half
of the hours determined for off/inactive
modes to each of the two modes. 73 FR
74648. Because DOE did not receive any
comments or additional data regarding
allocation of hours in response to the
December 2008 TP NOPR, the SNOPR
did not affect DOE’s proposal in the
December 2008 TP NOPR for the
allocation of hours between inactive
mode and off mode.
The Joint Efficiency Advocates
Comment suggested that DOE conduct
research to determine how inactive and
off mode hours are commonly divided
up in practice for clothes dryers. The
Comment stated that off mode usage
may differ depending on the mode’s
‘‘user-friendliness,’’ but that this is not
accounted for in the current test
procedure. According to the Joint
Efficiency Advocates Comment, very
few consumers would take advantage of
a ‘‘hidden’’ feature such as a small
switch on the back of the unit.
Therefore, crediting 50 percent of nonactive mode hours to off mode would
allow manufacturers to take advantage
of the energy rating benefit simply by
providing the off-mode option,
regardless of how apparent or userfriendly the option was to the consumer.
(Joint Efficiency Advocates Comment,
No. 28 at p. 3)
DOE is unaware of any available data
for the allocation of those hours. DOE
requested data on the annual hours for
various modes, including the split
between standby and off modes in the
NOPR (73 FR 74639, 74654) and the
June 2010 TP SNOPR (75 FR 37594,
37643), but it did not receive any
information. Therefore, in the absence
of data indicating otherwise, DOE is
amending the test procedure in today’s
final rule to allocate half of the hours
determined for off/inactive modes to
each of the two modes, for those
products capable of functioning in both
modes. If data is made available that
indicates a different allocation of hours
between inactive and off mode, DOE
may consider revising this allocation.
DOE recognizes that the analysis of
the number of annual hours allocated to
each clothes dryer mode is based, in
part, on the number of annual use
cycles. As discussed in section III.C.5.a,
DOE believes that the average number of
annual cycles is currently 283 rather
than the 416 cycles specified in the
current DOE clothes dryer test
procedure. DOE stated in the June 2010
TP SNOPR, however, that it does not
have any information on whether active
mode cycle times may have changed
accordingly. 75 FR 37594, 37610 (June
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29, 2010). It is possible that the smaller
number of use cycles may correspond to
the same amount of clothing being dried
in larger load sizes and thus,
potentially, longer drying times. In the
absence of any data supporting this
assumption, however, DOE proposed in
the June 2010 TP SNOPR the same
allocation of hours for inactive mode
and off mode that were proposed in the
December 2008 TP NOPR, even though
DOE proposed fewer annual use cycles
in the June 2010 TP SNOPR. Id.
The California Utilities/NRDC
generally supported DOE’s calculation
method for standby and off mode for
clothes dryers and method of allocation
of yearly clothes dryer hours to standby
and off modes proposed in the June
2010 TP SNOPR. However, the
California Utilities/NRDC urged DOE to
reconsider its allocation of 140 hours to
active mode for clothes dryers,
particularly in light of DOE’s proposed
adoption of 283 annual use cycles. The
California Utilities/NRDC stated that if
DOE assumes 140 active mode hours per
year and 283 cycles per year, this
translates to an average cycle time of
about 30 minutes, but that DOE has not
provided any data to support such an
assumption. (California Utilities/NRDC,
No. 33 at p. 2)
The California Utilities/NRDC also
stated that if DOE relies on Whirlpool’s
value of 20 minutes per cycle, then
under the new test procedure, the
number of active mode hours would be
94 hours per year (283 cycles/year × 20
minutes/cycle). The California Utilities/
NRDC stated that there is also evidence
to indicate the average length of a
clothes dryer cycle may be higher than
20 minutes, and that therefore the
assumption of 140 hours should be
adjusted upwards. The California
Utilities/NRDC added that the report by
Ecos Consulting (ECOS) (prepared for
NRDC) summarizes results for four
clothes dryers tested under a variety of
cycles, which showed an average
recorded cycle length of 46.5 minutes,
corresponding to 219 annual hours
(assuming 283 cycles per year). The
California Utilities/NRDC noted that
these cycles do not all represent the
typical DOE load, but they represent a
wide variety of potential consumer
loads and modes of operation which
may be indicative of in-field conditions.
(California Utilities/NRDC, No. 33 at pp.
2–3) The Joint Efficiency Advocates
Comment similarly stated that according
to the ECOS report for NRDC, the
average cycle length is 49.5 minutes for
clothes dryers with automatic
termination controls, which
corresponds to 233 hours spent in active
mode per year. The Joint Efficiency
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989
Advocates Comment recommended
basing the number of hours spent in
active mode annually on the cycle
length multiplied by the average
number of cycles per year. (Joint
Efficiency Advocates Comment, No. 28
at p. 4)
The Joint Efficiency Advocates
Comment and the California Utilities/
NRDC both commented that DOE
should try to obtain data from AHAM or
manufacturers on average clothes dryer
cycle length and average yearly hours.
(Joint Efficiency Advocates Comment,
No. 28 at p. 4; California Utilities/
NRDC, No. 33 at p. 3) The Joint
Efficiency Advocates Comment also
added that DOE should test a
representative sample of clothes dryers
to develop an accurate estimate of
average cycle length, which could then
be multiplied by the revised number of
cycles per year to calculate the annual
active mode hours. (Joint Efficiency
Advocates Comment, No. 28 at p. 4)
Whirlpool commented that 140 active
mode hours is reasonably consistent
with consumer use and practices, and
was not opposed to the continuing with
this known and well-understood
estimate. (Whirlpool, No. 27 at p. 2)
DOE first notes that it is not relying
on the 20 minutes per cycle estimate
provided by Whirlpool, for which the
testing procedure is not specified, to
estimate the annual active mode hours.
DOE notes that the estimate of 46.5
minutes per cycle, as suggested by the
California Utilities/NRDC and based on
data from the ECOS report, uses
automatic termination cycles with
clothes loads composed of cotton towels
with initial RMCs ranging from 70 to
100 percent. As discussed below in
section III.C.5.b, DOE amends the test
procedure to change the initial RMC to
57.5 percent, which will result in a
cycle time shorter than that estimated
by the California Utilities/NRDC
because less moisture must be removed
during the drying cycle. DOE also notes
that the Joint Efficiency Advocates
Comment’s estimate of 49.5 minutes per
cycle was also based on data from the
ECOS report. The estimate differs from
the California Utilities/NRDC’s estimate
because it included data from an air dry
cycle with a length of 120 minutes,
which would not be appropriate for
developing an estimate of clothes dryer
cycle time. This is because an air dry
cycle would not be representative of
consumer use. Based on the amendment
to the number of annual use cycles, DOE
notes that the cycle length would be
approximately 30 minutes (140 annual
active mode hours/283 active mode
cycles per year). DOE is unaware,
however, of consumer usage data
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indicating that the annual active mode
hours have changed. For these reasons,
DOE is not amending the test procedure
in today’s final rule to revise the
number of active mode hours per year.
In summary, DOE is amending the
clothes dryer test procedure in today’s
final rule to calculate clothes dryer
energy use per cycle associated with
inactive and off modes by: (1)
Calculating the product of wattage and
allocated hours for inactive and off
modes, depending on which of these
modes are possible; (2) summing the
results; (3) dividing the sum by 1,000 to
convert from watt-hours (Wh) to
kilowatt-hours (kWh); and (4) dividing
by 283 cycles per year. The 8,620 hours
for off/inactive modes shall be allocated
entirely to either off mode or inactive
mode, as appropriate, if only one of
these modes is possible for the clothes
dryer. If both modes are possible, the
hours shall be allocated to each mode
equally as discussed in this section, and
each shall be allocated 4,310 hours.
b. Room Air Conditioners
In the December 2008 TP NOPR, DOE
stated it was not aware of reliable data
for hours spent in different standby and
off modes in room air conditioners.
Therefore, DOE estimated the annual
hours for standby and off modes and the
relative magnitude of annual energy use
in standby and off modes in an example
for a representative 8,000 Btu/hour (Btu/
h), 9 EER unit that has delay start, offcycle, and inactive modes. 73 FR 74639,
74648–49 (December 9, 2008). DOE’s
estimates of annual energy use in each
mode are shown in Table III.3.
TABLE III.3—DOE ESTIMATE OF ANNUAL ENERGY USE OF ROOM AIR CONDITIONER MODES FOR A REPRESENTATIVE UNIT
WITH 8,000 BTU/H CAPACITY AND 9 EER
Mode
Hours
Active Cooling ...................................................................................................................................
Delay Start ........................................................................................................................................
Off-Cycle ...........................................................................................................................................
Off and Standby ...............................................................................................................................
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In the December 2008 TP NOPR, DOE
also proposed an alternative simplified
methodology. Similar to the analysis for
clothes dryers, comparing annual energy
use of different room air conditioner
modes shows that delay start and offcycle modes represent a small
percentage of annual energy use in the
active mode, and that the power
consumption in those standby modes is
distinct from but comparable to those
for off/inactive modes. Thus, DOE
proposed adopting an alternative
approach allocating the non-active
hours as if the room air conditioner has
only the inactive standby mode. A total
of 5,115 hours would be allocated to the
standby and off modes (8,760 × 0.75 ¥
750 ¥ 705 = 5,115).21 73 FR 74639,
74649 (December 9, 2008). For these
reasons, and because DOE did not
propose amendments to the room air
conditioner test procedure to measure
delay start and off-cycle power
consumption given the negligible power
consumption in these modes, DOE
proposed in the June 2010 TP SNOPR
allocating 5,115 non-active hours to
inactive and off modes for room air
conditioners. In addition, for the same
reasons as discussed for delay start and
cycle finished modes for clothes dryers,
DOE stated in the June 2010 TP SNOPR
that the delay start and off-cycle hours
21 Multiplying by 0.75 eliminates hours
associated with unplugged hours, assumed for half
of the hours of the year for half of room air
conditioners as described in the December 2008 TP
NOPR (73 FR 74639, 74648 (Dec. 9, 2008)); 750 =
Cooling (active mode) hours; 705 = Fan-only (active
mode) hours.
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for room air conditioners should be
allocated to inactive and off modes even
though it has determined that delay start
and off-cycle modes are not standby
modes. 75 FR 37594, 37610–11 (June 29,
2010).
The California Utilities/NRDC
supported DOE’s proposed calculation
method for standby mode and off mode
annual hours for room air conditioners.
They added that lacking new data on
typical room air conditioner operation
in standby and off modes, DOE’s
proposed method of allocating hours to
standby and off modes is appropriate.
(California Utilities/NRDC, No. 33 at p.
3)
The Joint Efficiency Advocates
Comment and ACEEE both commented
that the 705 fan-only mode hours
presented in the June 2010 TP SNOPR
should be accounted for in the energy
consumption calculations. (Joint
Efficiency Advocates Comment, No. 28
at pp. 2–3; ACEEE, Public Meeting
Transcript, No. 20 at pp. 73–74) The
Joint Efficiency Advocates Comment
stated that fan-only active mode could
be tested by duplicating the existing
cooling-mode test method with the
exception of running the compressor.
The Joint Efficiency Advocates
Comment further stated that there is no
data to support the assumption that
consumers generally run their room air
conditioners in fan-only mode for 705
hours a year. Although the Joint
Efficiency Advocates cannot find any
data on the number of hours typically
used in fan-only mode, they commented
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750
90
440
4,850
Typical
power
(W)
889 ..............
2 ..................
2 ..................
0.5 to 2 ........
Annual energy use
(kWh)
667.
0.2.
0.9.
2.5 to 10.
that the lack of data indicates that this
mode is not used as commonly as
assumed in the June 2010 TP SNOPR.
The Joint Efficiency Advocates
Comment stated that because of DOE’s
allocation, their second
recommendation is that the 705 hours
be reallocated in such a way as to
represent the current consumer usage of
fan-only mode. The Joint Efficiency
Advocates Comment also noted that due
to the lack of data on the use of this
mode, DOE should perform additional
research and data collection. If no data
collection is able to be performed, DOE
should reallocate these hours to active
cooling and/or inactive modes, which
would reflect the lack of data supporting
the average consumer use of any fanonly mode. (Joint Efficiency Advocates
Comment, No. 28 at pp. 2–3)
The California Utilities/NRDC stated
that fan-only operation should be
included in active mode, but that it is
not clear whether fan-only mode is
accounted for in the proposed active
mode test procedure. The California
Utilities/NRDC stated that if fan-only
mode is considered a portion of active
mode, and if energy use in fan-only
mode is measured in the current test
procedure, then the number of hours in
active mode should be revised to
include fan-only mode. The California
Utilities/NRDC stated that if fan-only
mode is considered separate from active
mode, and DOE allocates a portion of
yearly hours to fan-only mode, then
DOE must account for the energy use in
this mode and incorporate it into its
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calculation of CEER. The California
Utilities/NRDC requested that DOE
clarify its approach towards fan-only
mode, provide a test procedure to
measure or otherwise account for fanonly energy use, and incorporate the
energy use of this mode in the CEER.
(California Utilities/NRDC, No. 33, at
pp. 3–4)
Earth Justice (EJ) commented that not
measuring energy consumption when
operating in fan-only mode would
violate EPCA’s minimum standards for
test procedures (42 U.S.C. § 6293(b)(3))
EJ commented that by proposing to
ignore energy consumption in fan-only
mode, DOE has proposed to ignore
nearly half the active mode operating
hours of room air conditioner units. EJ
added that because fan-only mode
accounts for such a large percentage of
total active mode operating hours, a test
procedure that ignores fan-only
operation would not depict ‘‘a
representative average use cycle or
period of use’’ for room air conditioners.
(EJ, No. FDMS D0039 at p. 2)
DOE understands that a fan-only
active mode could include two different
kinds of modes: (1) A mode in which
the room air conditioner does not turn
off the fan when the thermostat
automatically cycles the compressor off
during cooling mode; and (2) a userselected ‘‘ventilation’’ mode that does
not include the cooling. DOE recognizes
that the energy use associated with fanonly mode is not insignificant. As noted
in the December 2008 TP NOPR,
however, DOE is not aware of any
reliable consumer usage data for hours
spent in different room air conditioner
modes, including fan-only mode. 73 FR
74639, 74648 (December 9, 2008). DOE
requested data in the December 2008 TP
NOPR on the estimate of hours for
different room air conditioner modes,
but did not receive any such data. DOE
notes that developing a test procedure to
accurately measure the contribution of
fan-only active mode would require
additional testing and analysis to
determine appropriate testing
conditions and measurement methods
for both types of fan-only modes
described above. In addition, field use
surveys of consumer usage patterns over
multiple cooling seasons and a climatebased load analysis to develop an
estimate of fan-only mode hours that is
representative of consumer use would
need to be conducted. DOE may
consider amendments to address fanonly active mode in a future rulemaking
as data becomes available. DOE
welcomes information on appropriate
testing procedures for accurately
measuring fan-only active mode and
data on consumer usage habits.
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Typically, room air conditioners with
remote control can be controlled
whenever they are plugged in; hence,
these units do not have provision for an
off mode in addition to inactive mode.
However, if a room air conditioner
allows the user to switch off remote
control operation, such a product would
be capable of both off and inactive
modes. DOE notes that information to
guide allocation of the hours for room
air conditioners that have both inactive
and off modes is currently unavailable.
For these units, DOE proposed in the
December 2008 TP NOPR that the off/
inactive hours be allocated equally to
the off and inactive modes for such a
product. Otherwise, for units that are
capable of operation in only off or
inactive mode, DOE proposed that all of
the hours be allocated to the appropriate
mode. 73 FR 74649. In the absence of
comments on or additional data
regarding allocation of hours, the June
2010 TP SNOPR did not affect DOE’s
proposal in the December 2008 TP
NOPR for the allocation of hours
between inactive mode and off mode. 75
FR 37594, 37611 (June 29, 2010).
Similar to the comment noted above
for clothes dryers, the Joint Efficiency
Advocates Comment suggested that DOE
conduct research to determine how
consumers allocate inactive and off
mode hours for room air conditioners.
The Joint Efficiency Advocates
Comment stated they are concerned that
off-mode usage may be affected by the
mode’s ‘‘user-friendliness,’’ but that this
is not accounted for in the current test
procedure. (Joint Efficiency Advocates
Comment, No. 28 at p. 3)
DOE requested consumer usage data
on the split of hours between inactive
mode and off mode if both modes are
possible for a product but did not
receive any data. In the absence of data
indicating that an equal split of hours is
not representative of consumer usage
habits, DOE adopts in today’s final rule
the allocation of inactive/off mode
hours proposed in the June 2010 TP
SNOPR. The number of hours will be
allocated equally to the inactive and off
modes for a product capable of both
modes. If data are made available
indicating a different number of hours
spent in inactive and off modes, DOE
may consider amending the test
procedure.
In summary, DOE amends the room
air conditioner test procedure in today’s
final rule to calculate room air
conditioner annual energy use
associated with inactive and off modes
by: (1) Calculating the products of
wattage and allocated hours for inactive
and off modes, depending on which of
these modes is possible; (2) summing
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the results; and (3) dividing the sum by
1,000 to convert from Wh to kWh. The
5,115 hours for off/inactive modes shall
be allocated entirely to either off mode
or inactive mode, as appropriate, if only
one of these modes is possible for the
room air conditioner. If both modes are
possible, the hours shall be allocated to
each mode equally as discussed in this
section, and each shall be allocated
2,557.5 hours.
5. Measures of Energy Consumption
The DOE test procedures for clothes
dryers and room air conditioners
currently provide for the calculation of
several measures of energy
consumption. For clothes dryers, the
test procedure incorporates various
measures of per-cycle energy
consumption, including: (1) Total percycle electric dryer energy
consumption; (2) per-cycle gas dryer
electrical energy consumption; (3) percycle gas dryer gas energy consumption;
and (4) total per-cycle gas dryer energy
consumption expressed, which includes
both the electrical and gas energy
consumption for gas clothes dryers. 10
CFR part 430, subpart B, appendix D,
sections 4.1–4.6 The test procedure also
provides an EF, which is equal to the
clothes load in pounds divided either by
the total per-cycle electric dryer energy
consumption or by the total per-cycle
gas dryer energy consumption expressed
in kWh. 10 CFR 430.23(d) For room air
conditioners, the test procedure
calculates annual energy consumption
in kWh and an EER. 10 CFR 430.23(f)
Under 42 U.S.C. 6295(gg)(2)(A), EPCA
directs that the test procedures for all
covered products be amended pursuant
to section 323 to include standby mode
and off mode energy consumption, with
such energy consumption integrated
into the overall energy efficiency,
energy consumption, or other energy
descriptor for each covered product,
unless DOE determines that—(i) the
current test procedures for a covered
product already fully account for and
incorporate the standby mode and off
mode energy consumption of the
covered product; or (ii) such an
integrated test procedure is technically
infeasible for a particular covered
product, in which case DOE must
prescribe a separate standby mode and
off mode energy-use test procedure for
the covered product, if technically
feasible.
In the December 2008 TP NOPR, DOE
explored whether the existing measures
of energy consumption for clothes
dryers and room air conditioners can be
combined with standby mode and off
mode energy use to form a single metric.
DOE tentatively determined in the
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December 2008 TP NOPR that it is
technically feasible to integrate standby
mode and off mode energy consumption
into the overall energy consumption
metrics for clothes dryers and room air
conditioners. 73 FR 74639, 74650
(December 9, 2008). For the reasons
presented in the December 2008 TP
NOPR, DOE proposed integrated metrics
addressing active, standby, and off
modes for clothes dryers and room air
conditioners, as discussed below.
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a. Clothes Dryers
In the December 2008 TP NOPR, DOE
proposed to establish the following
measures of energy consumption for
clothes dryers that integrate energy use
of standby and off modes with active
mode energy use of the products. ‘‘Percycle integrated total energy
consumption expressed in kWh’’ would
be defined as the sum of per-cycle
standby and off mode energy
consumption and either total per-cycle
electric dryer energy consumption or
total per-cycle gas dryer energy
consumption expressed in kWh,
depending on which type of clothes
dryer is involved. ‘‘Integrated energy
factor’’ (IEF) would be defined as the
(clothes dryer test load weight in lb)/
(per-cycle integrated total energy in
kWh). 73 FR 74639, 74650 (December 9,
2008).
b. Room Air Conditioners
In the December 2008 TP NOPR, DOE
proposed to establish the following
measures of energy consumption for
room air conditioners that integrate
energy use of standby and off modes
with active mode energy use of the
products. ‘‘Integrated annual energy
consumption’’ would be defined as the
sum of annual energy consumption and
standby and off mode energy
consumption. ‘‘Integrated energy
efficiency ratio’’ (IEER) would be
defined as (cooling capacity in Btu/hr ×
750 hours average time in cooling
mode)/(integrated annual energy
consumption × 1,000 Wh per kWh). Id.
DOE noted in the June 2010 TP
SNOPR that the Air-Conditioning,
Heating and Refrigeration Institute
(AHRI) Standard 340/360–2007,
‘‘Performance Rating of Commercial and
Industrial Unitary Air-Conditioning and
Heat Pump Equipment,’’ (AHRI
Standard 340/360) and the ASHRAE
Standard 90.1–2007, ‘‘Energy Standard
for Buildings Except Low-Rise
Residential Buildings,’’ (ASHRAE 90.1)
both published in 2007, included an
IEER metric. This metric, also named
‘‘Integrated Energy Efficiency Ratio,’’ is
meant to rate the part-load performance
of the air-conditioning equipment under
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test. 75 FR 37594, 37612 (June 29, 2010).
Manufacturers of the equipment covered
by these standards currently list IEER
ratings in their product literature and in
the AHRI certified product directory.
This IEER metric does not integrate
standby mode and off mode energy use,
unlike the IEER metric that was
proposed in the December 2008 TP
NOPR. The IEER metric used in AHRI
Standard 340/360 and ASHRAE 90.1
was established prior to the IEER
proposed in this rulemaking. Therefore,
DOE proposed for the June 2010 TP
SNOPR to revise the name of the
integrated metrics incorporating standby
mode and off mode energy use to
‘‘combined’’ metrics for both clothes
dryers and room air conditioners. Id.
DOE has received no comments
objecting to this proposal. Therefore, for
the reasons stated above, DOE
incorporates into the DOE test
procedures the ‘‘per-cycle combined
total energy consumption expressed in
kWh’’ and ‘‘combined energy factor’’
(CEF) for clothes dryers and ‘‘combined
annual energy consumption’’ and
‘‘combined energy efficiency ratio’’
(CEER) for room air conditioners in
today’s final rule as proposed in the
June 2010 TP SNOPR. Id.
In the June 2010 TP SNOPR, DOE did
not propose to amend the annual energy
cost calculations in 10 CFR 430.23 for
clothes dryers and room air conditioners
to include the cost of energy consumed
in standby and off modes. The Joint
Efficiency Advocates Comment stated
that DOE should include standby and
off mode energy costs in the annual
energy cost calculation in order to better
represent actual energy costs. The Joint
Efficiency Advocates Comment noted
that minimum and maximum energy
costs prescribed for the EnergyGuide
label will need to be revised when new
energy conservation standards go into
effect. They suggested that the energy
consumed in standby and off modes
should be able to be incorporated into
the revised minimum and maximum
energy costs. (Joint Efficiency Advocates
Comment, No. 28 at p. 4)
EPCA states that any amended test
procedures shall be reasonably designed
to produce test results that measure
energy efficiency, energy use, water use,
or estimated annual operating cost of a
covered product. (42 U.S.C. 6293(b)(3))
EPCA also directs DOE to amend its test
procedures to include measures of
standby mode and off mode energy
consumption and to integrate such
energy consumption into a single energy
descriptor for that product. If that is
technically infeasible, DOE must
prescribe a separate standby mode and
off mode energy-use test procedure, if
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technically feasible. (42 U.S.C.
6295(gg)(2)(A)) As discussed in section
I, EPCA requires that all representations
related to standby mode and off mode
energy use or efficiency or cost of
energy consumed of both clothes dryers
and room air conditioners made 180
days after today’s final rule be based
upon the standby and off mode
requirements of the amended test
procedures. (42 U.S.C. 6293(c)(2))
Additionally, EPCA requires that any
revisions to the labels for room air
conditioners include disclosure of the
estimated annual operating cost
(determined in accordance with DOE’s
test procedures prescribed under section
6293 of EPCA), unless the Secretary
determines that disclosure of estimated
annual operating cost is not
technologically feasible, or the FTC
determines that such disclosure is not
likely to assist consumers in making
purchasing decisions or is not
economically feasible. (42 U.S.C.
6294(c)(1)) DOE understands that the
FTC would develop any revised labeling
requirements for referencing a revised
annual energy cost calculation that
integrates the cost of energy consumed
in standby and off modes.
For these reasons, DOE agrees with
interested parties that the annual energy
cost calculations in 10 CFR 430.23 for
clothes dryers and room air conditioners
should be amended to include the cost
of energy consumed in standby and off
modes. Therefore, DOE amends the
clothes dryer test procedure to revise
the estimated annual operating cost
calculation to integrate standby and off
mode energy use, and to require that the
estimated annual operating cost be
obtained by multiplying the average
number of annual use cycles by the sum
of the per-cycle active mode energy
consumption and the per-cycle standby
and off mode energy consumption and
by the representative average unit cost
of electrical energy, natural gas, or
propane, as appropriate, in dollars per
kWh or Btu, as provided by DOE.
Similarly, DOE amends the room air
conditioner test procedure to revise the
annual energy cost calculation to
integrate standby and off mode energy
use, and to require that the annual
energy cost be obtained by multiplying
the combined annual energy
consumption by the representative
average unit cost of electrical energy in
dollars per kWh, as provided by DOE.
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C. Clothes Dryer and Room Air
Conditioner Active Mode Test
Procedures
1. Correction of Text Describing Energy
Factor Calculation for Clothes Dryers
DOE proposed in the December 2008
TP NOPR to correct errors in specific
references used in the current DOE test
procedure. 73 FR 74639, 74650
(December 9, 2008). In particular, the
reference to sections 2.6.1 and 2.6.2 of
10 CFR part 430, subpart B, appendix D
in the calculation of EF for clothes
dryers found at section 430.23(d)(2)
should refer instead to sections 2.7.1
and 2.7.2. Section 2.6 provides
instructions for the test clothes to be
used in energy testing of clothes dryers,
whereas section 2.7 provides
instructions on test loads. The EF of
clothes dryers is measured in lb of
clothes per kWh. Because the EF
calculation requires the weight of the
test load, DOE proposed in the
December 2008 TP NOPR to correct
these references in 10 CFR 430.23(d)(2).
DOE did not receive any comments
opposing this correction. Therefore, for
the reasons stated above, DOE adopts
the correction as proposed in the
December 2008 TP NOPR.
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2. Automatic Cycle Termination for
Clothes Dryers
DOE considered amendments to the
clothes dryer test procedure to
accurately measure the benefits of
automatic cycle termination. DOE
considered industry and international
clothes dryer test procedures and
conducted testing and analysis to
develop proposed amendments to the
definitions of product types, test load
preparation, the test measurement cycle
and settings, and the calculation of
results.
October 2007 Framework Document
In the October 2007 Framework
Document, DOE stated that it believes
that the clothes dryer test procedure
may not adequately measure the
benefits of automatic cycle termination,
in which a sensor monitors either the
exhaust air temperature or moisture in
the drum to determine the length of the
drying cycle. (Framework Document,
STD No. 1 at p. 5) The calculation of EF
in the current clothes dryer test includes
a field use scaling factor applied to the
per-cycle drying energy consumption to
account for the over-drying energy
consumption associated with different
termination technologies. Gas or electric
clothes dryers with time termination
control (in other words, those clothes
dryers equipped with only a timer to
determine the end of a drying cycle) are
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assigned an field use of 1.18. Clothes
dryers with automatic termination are
assigned an field use of 1.04. DOE
established the 1.18 field use factor for
clothes dryers with time termination
control in the September 1977 TP Final
Rule based on analysis of data from a
field use survey conducted by
Oklahoma Gas and Electric Company
involving 64 homes as well as data
provided by AHAM on the measured
energy consumption per-cycle under the
DOE test procedure to account for the
differences between the energy
consumption measurements derived
from laboratory test procedures and
those obtained from actual consumer
use. 42 FR 46145, 46146 (September 14,
1977). DOE established the field use
factor of 1.04 for clothes dryers with
automatic termination in the May 1981
TP Final Rule based on analysis of data
from a field use survey conducted by
AHAM involving 72 homes as well as
an analysis conducted by NIST of field
test data on automatic termination
control dryers. Analysis of this data
showed that clothes dryers equipped
with an automatic cycle termination
feature consume less energy than timer
dryers by reducing over-drying. 46 FR
27324 (May 19, 1981). Based on these
field use factors, clothes dryers with
automatic cycle termination control are
determined to reduce energy
consumption by 12 percent compared to
a similar clothes dryer with time
termination control, which consume
more energy due to over- or underdrying. (Under-drying can result in
consumers running an additional drying
cycle.) Currently, the test procedure
specifies a single field use factor for
clothes dryers equipped with automatic
termination. However, it does not
distinguish between the type of sensing
control system (for example,
temperature-sensing or moisture-sensing
controls) and the sophistication and
accuracy of the control system.
Consideration of Industry and
International Clothes Dryer Test
Procedures
DOE proposed in the June 2010 TP
SNOPR that the benefit of automatic
cycle termination should be accurately
measured to account for any over- or
under-drying. Therefore, DOE
considered potential amendments to the
DOE test procedure to account for
automatic cycle termination. For the
June 2010 TP SNOPR, DOE investigated
industry and international clothes dryer
test procedures for measuring the
effectiveness of automatic cycle
termination and conducted limited
testing to analyze over-drying energy
consumption and the applicability of
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993
such procedures to the DOE clothes
dryer test procedure. 75 FR 37594,
37613 (June 29, 2010). DOE reviewed
AHAM’s most recently update to its
industry test standard, AHAM HLD–1–
2009, ‘‘Household Tumble Type Clothes
Dryers’’ (AHAM Standard HLD–1–2009).
The update contains provisions for
measuring the over-drying energy
consumption for clothes dryers that use
automatic cycle termination and
provides separate testing procedures
timer dryers. DOE also reviewed the
international test standards EN Standard
61121 22 and AS/NZS Standard 2442.1,
both of which address methods for
testing clothes dryers with automatic
termination sensor technologies. 75 FR
37594, 37613 (June 29, 2010).
DOE stated in the June 2010 TP
SNOPR that it believes that AHAM
Standard HLD–1–2009 does not provide
an appropriate method for comparing
the amount of over-drying for a timer
dryer to that of an automatic
termination-sensing dryer. This is
because the timer dryer test allows only
for drying the test load to as low as
4-percent RMC, whereas the automatic
cycle termination test allows for drying
the test load to any value below
6-percent RMC, including lower than
4-percent RMC. 75 FR 37613–14. If the
automatic termination control dryer
were to dry the test load to a value
lower than 4-percent, the measured
energy consumption may be greater than
the energy consumption measured for
the same clothes dryer using the timer
dryer test cycle which only measures
the energy required to dry the load to
4-percent RMC. However, as discussed
above in this section, DOE believes that
automatic termination control dryers
reduce energy consumption compared
to timer dryers based on analysis of data
from the AHAM field use survey and
analysis of field test data conducted by
NIST. 46 FR 27324 (May 19, 1981).
DOE also stated in the June 2010
NOPR that although EN Standard 61121
provides test methods to use for both
timer dryers and automatic termination
control dryers, it does not provide any
methodology to measure the energy
consumed over- or under-drying the test
load beyond a certain RMC for each type
of clothes dryer. The provisions in EN
Standard 61121 require the test load be
dried to the same allowable range for
both timer dryers and automatic
termination dryers. According to the test
procedures in EN Standard 61121, if the
22 EN Standard 61121 is used by European Union
(EU) member countries. DOE believes this test
standard is functionally equivalent to IEC Standard
61121, which is used by China, among other
countries. Both test procedures contain identical
testing methods and procedures.
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test load for either a timer dryer or an
automatic termination control dryer is
dried to the same RMC, the clothes
dryers consume the same amount of
energy and would be rated as using the
same amount of energy in real-world
use. 75 FR 37594, 37614 (June 29, 2010).
However, for the same reasons
discussed above in this section, DOE
believes that automatic termination
control dryers reduce energy
consumption compared to timer dryers.
DOE stated in the June 2010 TP
SNOPR that AS/NZS Standard 2442
provides testing methods and
procedures that account for the amount
of over-drying beyond a specified RMC
associated with automatic termination
control dryers by measuring any
additional energy consumed drying the
test load beyond the specified RMC.
DOE also stated that AS/NZS Standard
2442 effectively takes into consideration
the accuracy of different automatic
termination sensor technologies by not
providing a fixed field use factor in the
energy consumption calculation for
automatic cycle termination. Because
the test procedure measures the energy
consumed drying the test load beyond
the specified RMC, a clothes dryer with
an accurate automatic termination
sensor technology that dries the clothes
load to close to the specified RMC
would consume less energy than a
clothes dryer with a sensor technology
that dries the load well beyond the
specified RMC (that is, close to bone
dry). DOE also stated that it believes
that the testing methods provide an
accurate and representative method for
comparing the energy consumption
between timer dryers and automatic
termination control dryers by providing
methods for measuring energy use that
account for over-drying for both types of
clothes dryers. For these reasons, DOE
proposed to amend the DOE test
procedure for clothes dryers to
incorporate the individual test
procedures for timer dryers and
automatic termination control dryers in
AS/NZS Standard 2442, with
modifications as appropriate for the
DOE test procedure. 75 FR 37594, 37615
(June 29, 2010).
After the June 2010 TP SNOPR was
published, AHAM, ACEEE, NRDC,
Alliance to Save Energy (ASE), Alliance
for Water Efficiency (AWE), ASAP,
Northwest Power and Conservation
Council (NPCC), Northeast Energy
Efficiency Partnerships (NEEP),
Consumer Federation of America (CFA),
and National Consumer Law Center
(NCLC) (hereafter the ‘‘Joint Petitioners’’)
jointly submitted the ‘‘Agreement on
Minimum Federal Efficiency Standards,
Smart Appliances, Federal Incentives
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and Related Matters for Specified
Appliances,’’ (Joint Petitioners, No. 25,
hereinafter the ‘‘Joint Petition’’) and the
‘‘Joint Stakeholders Comments On The
Supplementary Notice Of Proposed
Rulemaking On Test Procedures For
Clothes Dryers And Room Air
Conditioners’’ (Joint Petitioners, No. 30).
The Joint Petitioners, AHAM, the Joint
Efficiency Advocates Comment, and the
California Utilities/NRDC supported
DOE’s proposal to account for the
effectiveness of automatic termination
controls. (Joint Petitioners, No. 25 at p.
14; Joint Petitioners, No. 30 at p. 5;
AHAM, No. 31 at p. 5; Joint Efficiency
Advocates Comment, No. 28 at p. 1;
California Utilities/NRDC, No. 33 at p.
4) The Consumers Union (CU)
concurred with this comment. (CU, No.
29 at pp. 1–2, 3) The Joint Efficiency
Advocates Comment added that data
presented by DOE show that over-drying
energy consumption can be significant
(as much as 0.6 kWh per cycle). (Joint
Efficiency Advocates Comment, No. 28
at p. 1; California Utilities/NRDC, No.
33 at p. 4) The Joint Petitioners and
AHAM commented that if DOE decides
to adopt the AS/NZS Standard 2442 as
proposed, they request that DOE
identify the specific sections it is
adopting. (Joint Petitioners, No. 30 at p.
6; AHAM, No. 31 at p. 6)
Product Definitions
Based on the definitions in EN
Standard 61121 and AS/NZS Standard
2442, DOE proposed in the June 2010
TP SNOPR to define ‘‘timer dryer’’ as ‘‘a
dryer which can be preset to carry out
at least one sequence of operations to be
terminated by a timer, but may also be
manually controlled.’’ It also proposed
to define ‘‘automatic termination control
dryer’’ as ‘‘a dryer which can be preset
to carry out at least one sequence of
operations to be terminated by means of
a system assessing, directly or
indirectly, the moisture content of the
load. An automatic termination control
dryer with supplementary timer shall be
tested as an automatic termination
control dryer.’’ 75 FR 37594, 37615 (June
29, 2010).
AHAM suggested that the definition
of a timer dryer may need to specify that
it is a clothes dryer that ‘‘does not
include any automatic termination
function.’’ AHAM commented that
almost any automatic termination dryer
is also going to have a timer function
because of consumer demands, and this
extra explanation would make it clear
that it refers to only a timer dryer.
(AHAM, Public Meeting Transcript, No.
20 at pp. 84, 85–86) AHAM also
commented that the last sentence of the
automatic termination dryer definition
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should be modified and used to clarify
the timer dryer definition. (AHAM,
Public Meeting Transcript, No. 20 at p.
86) ALS also commented that it offers a
product with both an automatic
termination function and a timer
function that uses only
electromechanical controls. (ALS,
Public Meeting Transcript, No. 20 at p.
81)
As discussed later in this section,
DOE is not adopting in today’s final rule
the amendments for automatic cycle
termination proposed in the June 2010
TP SNOPR. Therefore it is not adopting
the definitions for timer dryer and
automatic termination dryer presented
above. DOE agrees, however, that the
reference to timer dryers in the test
procedure (in the application of field
use factors in section 4, ‘‘Calculation of
Derived Results From Test
Measurements’’) should clarify that
clothes dryers with time termination
control systems do not include any
automatic termination control functions.
DOE also believes the reference to
clothes dryers with automatic control
systems in the application of the field
use factors should clarify that clothes
dryers with automatic control systems
that also have a supplementary timer
control receive the 1.04 field use factor.
For these reasons, DOE amends section
4 of the clothes dryer test procedure to
specify that the field use factor equals
1.18 for clothes dryers with time
termination control systems only,
without any automatic termination
control functions and 1.04 for clothes
dryers with automatic control systems
that meet the requirements of the
definition for automatic control systems
in 1.4, 1.14 and 1.18, including those
that also have a supplementary timer
control.
The Joint Petitioners and AHAM also
commented that DOE should revise
section 1.11 of 10 CFR 430 subpart B,
appendix D. The amendment would
more clearly account for electronic
controls by specifying that a preferred
automatic termination control setting
(that is, a setting recommended by
manufacturers) can also be indicated by
a visual indicator (in addition to the
mark or detent), and would read ‘‘* * *
mark, visual indicator or detent which
indicates a preferred * * *’’ (Joint
Petitioners, No. 25 at p. 14; Joint
Petitioners, No. 30 at p. 8; AHAM, No.
31 at p. 11) DOE agrees a clarification
should be added to the definition of
‘‘automatic termination control’’ that a
mark, detent, or other visual indicator
which indicates a preferred automatic
termination control setting must be
present if the dryer is to be classified as
having an automatic termination
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control. Therefore, DOE amends this
definition in today’s final rule to make
this revision.
NRDC commented that most new
clothes dryers have both automatic and
timer termination functions, so the test
procedure should test both of these
drying modes rather than only the
automatic termination mode. (NRDC,
Public Meeting Transcript, No. 20 at pp.
86–87) The Joint Petitioners and AHAM
commented that for clothes dryers that
have both an automatic termination
control cycle and a timer cycle, only the
auto-termination cycle should be tested.
(Joint Petitioners, No. 30 at p. 6; AHAM,
No. 31 at p. 5) Whirlpool commented
that testing the automatic termination
control cycle is most appropriate, as it
represents the vast majority of actual
consumer use. Although the majority of
consumers also want a timed dry cycle,
they use it only about 10 percent of the
time. (Whirlpool, No. 27 at p. 3) DOE is
not aware of any consumer usage data
indicating that timed dry cycles on a
clothes dryer with automatic
termination controls are used by
consumers for a significant portion of
their annual use cycles. In addition, as
discussed below, DOE is not adopting in
today’s final rule the amendments to
better account for automatic cycle
termination proposed in the June 2010
TP SNOPR. For these reasons, DOE is
not amending the test procedure to
measure both automatic termination
control and timed dry cycles for
products capable of both methods.
Test Load Preparation
In the June 2010 TP SNOPR, DOE
proposed to amend sections 2.7.1,
‘‘Compact size dryer load,’’ and 2.7.2,
‘‘Standard size dryer load’’ of the DOE
test procedure for clothes dryers, which
contain provisions for test load
preparation. The amendment would add
at the end of both sections the following
requirement: ‘‘Make a final mass
adjustment, such that the moisture
content is 47 percent ± 0.33 percent by
adding water uniformly to the load in a
very fine spray.’’ 75 FR 37594, 37615
(June 29, 2010). The ± 0.33 percent
allowable RMC range is equivalent to
the allowable range specified in AS/
NZS Standard 2442.1 (190 percent
± 0.02 kg of the bone dry weight) for a
7-lb test load. DOE believes the
specified range produces repeatable EF
measurements. Allowing a larger
allowable range in RMC would increase
the range in the moisture required to be
dried during the test cycle and result in
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increased variability in the measured
EF. DOE also proposed that the
procedure for dampening and extracting
water from the test load specified in the
current test procedure be changed. The
test procedure would be changed to
require that the moisture content of the
test load be between 42 and 47 percent
of the bone-dry weight of the test load,
and would serve as an initial
preparation step prior to the final mass
adjustments to obtain a test load with an
RMC of 47 percent proposed above in
this paragraph. DOE noted that it
proposed to use a nominal initial RMC
of 47 percent based on the proposed
amendment to change the initial RMC
from 70 percent to 47 percent, as
discussed in section III.C.5.b. DOE
noted in the June 2010 TP SNOPR that
if it does not adopt this proposed
amendment to change the nominal
initial RMC, it would instead propose
an amendment stating to first prepare
the test load to 65- to 70-percent RMC
and make adjustments to the moisture
content to get 70-percent ± 0.33-percent
initial RMC. 75 FR 37594, 37615 (June
29, 2010). DOE did not receive any
comments on this alternate proposal.
In the June 2010 TP SNOPR, DOE
noted that section 2.7 of the existing
clothes dryer test procedure regarding
test load preparation requires that the
test load be agitated in water whose
temperature is 100 ° F ± 5 ° F. DOE
recognizes that some residential clothes
washers may use a default cold rinse
cycle at the end of the wash cycle,
which sections 2.6.1.2.1 and 2.6.3.1 of
the current DOE clothes washer test
procedure specify to be 60 ° F ± 5 ° F.
DOE stated in the June 2010 TP SNOPR
that it does not have any data indicating
whether a different water temperature
for clothes dryer test load preparation
would be more representative of current
consumer usage habits, but that if
consumer usage data is made available
that indicates a 60 ° F ± 5° F water
temperature is more representative of
consumer usage, DOE may adopt an
alternate approach specifying a 60 ° F
± 5 ° F water temperature for test load
preparation in section 2.7 of the DOE
clothes dryer test procedure. In
addition, DOE stated that it is unaware
of how changes to the water temperature
for clothes dryer test load preparation
would affect the measured efficiency as
compared to the existing test procedure.
Id.
ALS, the California Utilities/NRDC,
and the Joint Efficiency Advocates
Comment all stated that the water
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995
temperature for clothes dryer test load
preparation should be changed to be
representative of existing national
consumer usage. (ALS, No. 24 at p. 4;
California Utilities/NRDC, No. 33 at p.
5; Joint Efficiency Advocates Comment,
No. 28 at pp. 1–2)
ALS commented that the water
temperature for clothes dryer test load
preparation has been lowered in
response to clothes washer energy
conservation standard changes.
Manufacturers have eliminated most
warm rinses and offer the user the
option of using all cold rinses. ALS
stated that it is reasonable to assume
that today, most clothes loads placed in
a clothes dryer are from clothes washers
that use cold rinse. Therefore, ALS
supported revising the clothes dryer test
procedure to utilize the 60 ° F ± 5 ° F
water temperature specified in the DOE
clothes washer test procedure for the
cold water supply for the preparation of
the clothes dryer test load. (ALS, No. 24
at p. 4; ALS, Public Meeting Transcript,
No. 20 at p. 91)
The California Utilities/NRDC also
stated that lower rinse temperatures
may be more representative of consumer
habits based on both anecdotal evidence
and consumer data. The California
Utilities/NRDC stated that 2003
California Residential Appliance
Saturation Survey (RASS) 23 provides
data on general consumer preferences
on cold, warm, and hot wash cycles (no
data was available for rinse cycles). The
data show there is a general trend
among consumers to prefer warm and
cold wash cycles over hot cycles. Data
cited by the California Utilities/NRDC
from the 2003 California RASS on this
topic are presented in Table III.4.
According to the California Utilities/
NRDC, although the data do not specify
cycle temperatures or final rinse
temperatures, the data may indicate a
consumer preference for cooler wash
and rinse cycles. The California
Utilities/NRDC also stated that a 60 ° F
± 5 ° F preparation temperature would
be better aligned and harmonize with
the cool rinse temperature specified by
the clothes washer test procedure.
(California Utilities/NRDC, No. 33 at pp.
5–6)
23 KEMA, Inc. 2009 California Residential
Appliance Saturation Study. 2010. California
Energy Commission; Sacramento, CA. Publication
number: CEC–200–2010–004–ES. For more
information visit: https://www.energy.ca.gov/
appliances/rass/.
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TABLE III.4—2003 CALIFORNIA RASS SURVEY DATA ON CLOTHES WASHER CYCLE SELECTIONS (PROVIDED IN
COMMENTS BY THE CALIFORNIA UTILITIES/NRDC)
Cold wash
cycles
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Cycles per Week (weighted average) ...................................................................................
Cycles per Year (weighted average) .....................................................................................
Percent of Cycles Chosen .....................................................................................................
The Joint Efficiency Advocates
Comment stated that the 2005 RECS
gathered information about the rinse
water temperature that consumers
usually use. The Joint Efficiency
Advocates Comment noted that, of
respondents that used a clothes washer
in their home, 78.5 percent said they
used cold water for the rinse cycle. The
Joint Efficiency Advocates Comment
also noted that in the current clothes
washer test procedure, temperature use
factors indicate that warm rinse is
assumed to be used only 27 percent of
the time. The Joint Efficiency Advocates
Comment stated that anecdotal evidence
shows that that some clothes washers
are now being manufactured without a
warm rinse option. In addition,
detergent manufacturers support
consumers’ increasing use of cold wash
and cold rinse temperatures, as
evidenced by the recent introduction of
detergents specifically optimized for
these conditions. The Joint Efficiency
Advocates Comment encouraged DOE to
change the water temperature for test
load preparation to reflect these
consumer usage indicators. The Joint
Efficiency Advocates Comment also
stated that, at the very least, the test
procedure should align with the
temperatures used in the clothes washer
test procedure. According to the Joint
Efficiency Advocates Comment, the
washer test procedure assumes that a
cold rinse is used the majority of the
time. Therefore, alignment could be
achieved by requiring a cold rinse (60 °F
± 5 °F) be used for the clothes dryer test
load preparation. (Joint Efficiency
Advocates Comment, No. 28 at pp. 1–2)
Whirlpool commented that the
current load temperature is well
documented and well understood by
manufacturers and independent test
laboratories. Whirlpool stated that any
migration to a different temperature
would require time consuming ‘‘roundrobin’’ testing to determine the impact
that such a new temperature would
have on the EF calculation. Whirlpool
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Warm wash
cycles
1.80
93.7
36
commented that such testing is not
compatible with DOE’s timeframe for
this rulemaking nor would it add value
proportional to the burden required to
reformulate EF. (Whirlpool, No. 27 at
pp. 2–3)
ALS commented that it does not have
any data quantifying what impact a
different test load temperature would
have on the clothes dryer efficiency test
results. ALS stated it is reasonable to
expect that a colder temperature test
load being placed in a dryer will require
additional energy to achieve
evaporation for the moisture from the
clothes. ALS suggested that DOE test
existing clothes dryers to assess the
impact of the load preparation water
temperature change from 100 °F to 60
°F. (ALS, No. 24 at p. 4; ALS; Public
Meeting Transcript, No. 20 at p. 91) The
Joint Efficiency Advocates Comment
stated that the water temperature
adjustment would likely have an effect
on measured dryer energy use. This is
because warmer rinse water, and hence
higher initial load temperature, may
result in faster drying times and lower
energy use, especially if the dryer is
equipped with moisture sensor
technology. (Joint Efficiency Advocates
Comment, No. 28 at p. 2)
DOE analyzed 2005 RECS data on the
rinse water temperatures selected by
consumers for clothes washer cycles.
The usage data for consumers that use
a clothes washer in the home, presented
below in Table III.5, shows that 80
percent of wash cycles per year use a
cold rinse.
2.32
120.8
46
Hot wash
cycles
0.94
49.0
19
Because the DOE clothes washer test
procedure assumes a warm rinse
temperature use factor of 27 percent,
and the 2005 RECS data shows that 80
percent of clothes washer cycles use
cold water for the rinse cycle, DOE
believes that the cold water rinse cycle
is more representative of typical
consumer use. (DOE also notes that it
sought comment on the warm rinse
temperature use factor in the recent
proposal to amend the test procedure for
residential clothes washers because it
received consumer usage survey data
from a manufacturer which indicate
that, for one clothes washer model with
no cold rinse option on the cycle
recommended for cotton clothes and a
default cold rinse on all other cycles,
users participating in the survey
reported using warm rinse for 1.6
percent of all cycles. 75 FR 57556,
57571 (Sept. 21, 2010)) For this reason,
DOE amends the clothes dryer test
procedure to change the water
temperature for clothes dryer test load
preparation to 60 °F ± 5 °F.
DOE tested 13 representative clothes
dryers to evaluate the repeatability and
reproducibility of this amendment to
the water temperature for clothes dryer
test load preparation. DOE tested these
units according to the current DOE
clothes dryer test procedure, except that
the water temperature for clothes dryer
test load preparation was changed to 60°
± 5 °F. For the ventless clothes dryer test
units, DOE used the proposed testing
method for ventless dryers presented in
TABLE III.5—2005 RECS CONSUMER section III.C.3. As shown below in Table
USAGE DATA ON CLOTHES WASHER III.6, the test-to-test variation in
RINSE CYCLES TEMPERATURE SE- measured EF with 60 °F ± 5 °F test load
LECTIONS
water temperature ranged from 0
percent to 4.1 percent, with an average
Average
of 1.5 percent. Therefore, DOE believes
Average
cycles per
usage factor that the amendments to the water
year
temperature for clothes dryer test load
Hot Rinse ..........
5.176
0.018 preparation produce repeatable test
Warm Rinse ......
53.638
0.182 results.
Cold Rinse ........
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0.800
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TABLE III.6—DOE REPEATABILITY TESTING FOR 60° ± 5 °F WATER TEMPERATURE FOR TEST LOAD PREPARATION
EF lb/kWh
Test unit
Test 1
Vented Electric Standard:
Unit 1 ..................................................................................................................
Unit 2 ..................................................................................................................
Unit 3 ..................................................................................................................
Unit 5 ..................................................................................................................
Unit 6 ..................................................................................................................
Vented Gas:
Unit 7 ..................................................................................................................
Unit 9 ..................................................................................................................
Unit 10 ................................................................................................................
Unit 11 ................................................................................................................
Vented Electric Compact (240V):
Unit 12 ................................................................................................................
Unit 13 ................................................................................................................
Ventless Electric Compact (240V):
Unit 15 ................................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ................................................................................................................
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Test Cycle
In the June 2010 TP SNOPR, DOE also
proposed to amend section 3.3, ‘‘Test
cycle,’’ in the DOE test procedure for
clothes dryers to include testing
procedures specific to timed dryers and
dryers with automatic termination
controls.
For timer dryers, the clothes dryer
would be operated at the maximum
temperature setting and, if equipped
with a timer, at the maximum time
setting. The load would be dried to
5–6 percent RMC without the dryer
advancing into cool-down. The timer
would be reset if necessary. If the load
is not dried to within the specified
range, the test would not be considered
valid. The procedure would then be
repeated, but instead the test load
would be dried to 4–5 percent RMC. As
discussed later in this section, DOE
proposed to use the results from the two
proposed tests cycles (corresponding to
5–6 and 4–5 percent final RMCs) to
interpolate the value of the per-cycle
energy consumption required to dry the
test load to exactly 5-percent RMC. 75
FR 37594, 37615 (June 29, 2010). DOE
requested comment in the June 2010 TP
SNOPR on whether using the maximum
temperature setting is representative of
current consumer usage habits. DOE
also requested comment on whether
multiple temperature settings should be
evaluated and averaged, and if so, how
testing multiple temperature settings
would affect the measured efficiency as
compared to the existing DOE clothes
dryer test procedure. That procedure
measures the clothes dryer only at the
maximum temperature setting. Id.
AHAM stated that DOE should not
adopt amendments to the temperature
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Test 3
Test-to-test
variation %
3.00
3.01
3.10
3.18
3.04
3.00
3.07
3.10
3.17
2.92
3.00
3.06
3.09
....................
....................
0.0
2.0
0.3
0.3
4.1
2.74
2.68
2.81
2.77
2.70
2.61
2.73
2.78
....................
....................
....................
2.82
1.5
2.7
2.9
1.8
2.95
2.86
2.94
2.84
....................
2.82
0.3
1.4
2.22
2.23
....................
0.5
1.94
1.98
1.96
2.1
setting provisions in the current test
procedure because there is no
justification or evidence to support such
a change. (AHAM, No. 31 at p. 6)
Whirlpool commented that testing and
averaging multiple cycles and settings,
while perhaps more reflective of
consumer behavior, would dramatically
increase the test burden on
manufacturers, and that the substantial
increase in cost would not be justified
by a better result. Whirlpool added that
testing and averaging of multiple cycles
and settings would introduce
opportunities for error and
circumvention while reducing
repeatability and consistency.
(Whirlpool, No. 27 at p. 3) ALS also
supported setting the temperature at the
‘‘maximum’’ temperature setting option
available on the dryer. (ALS, No. 24 at
p. 5) DOE agrees that the benefit of
testing multiple temperature settings
would be outweighed by the burden on
manufacturers to test multiple settings.
In addition, DOE agrees that including
requirements to test multiple settings
could potentially create problems with
developing a consistent test procedure
that covers all products. This is because
various manufacturers offer different
settings on their clothes dryers, and test
technicians would be required to
determine the appropriate settings for
testing. For these reasons, DOE is not
amending the test procedure in today’s
final rule to require the testing of
multiple temperature settings and
averaging results.
ALS stated that, for clothes dryers
with only a timed dry cycle, the time
should be set at the maximum setting.
ALS commented that it has no data
regarding what time setting consumers
PO 00000
Test 2
utilize most often. ALS believes,
however, that consumers using a timed
dry cycle tend to select a maximum
amount of time to be assured that their
load is dry at end of the cycle. (ALS, No.
24 at p. 4) ALS also commented that the
‘‘full time cycle including cool-down
period’’ should be included for timer
dryers as well as for automatic cycle
termination dryers. According to ALS,
the benefits for timer dryers are as
follows: (1) Test accuracy is improved
because it avoids the variability of
technician judgment on when to stop
the test; (2) burden is reduced on
manufacturers and test labs, because no
interpolation or test ‘‘re-run’’ is required;
and (3) all the energy consumed in a
dryer cycle is accounted for, and is
representative of the manner in which
consumers utilize the dryer in their
homes. (ALS, No. 24 at p. 5)
DOE does not have any data
indicating that the maximum time
setting would be most representative of
consumer usage habits. In addition,
some manufacturers offer a wide range
of timed dry settings for different types
of loads, and these may require varying
periods to dry. Therefore, using the
maximum time setting could result in
energy consumption that may not be
representative of consumer use. DOE
also does not believe it would be
appropriate to include the cool-down
period as part of the time dry test cycle
because the current clothes dryer test
procedure requires a timed dry cycle
using the maximum time setting and
maximum temperature setting and
drying the load to a specified RMC, at
which point the test cycle is stopped.
DOE believes that to specify a timed dry
cycle that includes the cool-down
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period to achieve a target final RMC
would add significant testing burden on
test technicians to determine the
appropriate time setting. It would also
be very difficult to ensure that testing
results are repeatable and reproducible
because different timed dry cycle
lengths, and thus different lengths of
cool-down period, may be selected to
dry a test load to the same final RMC.
For these reasons, DOE is not amending
the timed dry test cycle to include the
cool-down period in today’s final rule.
For dryers with automatic termination
controls, as discussed in the June 2010
TP SNOPR, DOE tested a representative
gas clothes dryer to evaluate test
methods for automatic termination
control dryers as part of the energy
conservation standards rulemaking
preliminary analyses. DOE conducted
this additional testing to determine the
effects of proposed amendments that
would require the selection of program
settings that provide the maximum
drying temperature and maximum
dryness level (that is, lowest final RMC).
Table III.7 below shows the results from
this testing compared to the results of
testing the same gas clothes dryer
according to the current DOE test
procedure. 75 FR 37594, 37615–16 (June
29, 2010).
TABLE III.7—DOE AUTOMATIC CYCLE TERMINATION TEST RESULTS
Initial RMC
(%)
Test
70 ................................................
Automatic Cycle Termination .........................................................
Current DOE ...................................................................................
Automatic Cycle Termination .........................................................
Current DOE ...................................................................................
Automatic Cycle Termination .........................................................
Current DOE ...................................................................................
56 ................................................
47 ................................................
Per-cycle energy
consumption
kWh
Final RMC
%
0.6
* 3.3
0.6
* 3.7
0.5
* 3.4
3.018
* 2.462
2.559
* 2.001
2.252
* 1.754
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* Current DOE test procedure normalizes the per-cycle energy consumption equation to represent the energy consumption required to dry the
test load to 4-percent RMC. In addition, the current DOE test procedure multiplies the per-cycle energy consumption by a fixed field-use factor of
1.04 to account for energy consumption due to over-drying.
DOE noted that for all of the test runs,
using the maximum temperature and
dryness level settings resulted in the test
load being dried to near bone dry (0.4percent to 0.7-percent RMC). Using the
data of the estimated RMC of the test
load measured continuously during the
test cycle, DOE also observed that for all
of the test runs, the estimated RMC of
the test load was below 1 percent by the
time the heater began cycling on/off.24
The increased amount of over-drying
resulted in per-cycle energy
consumption that was higher than the
value obtained using the current DOE
test procedure, which uses a fixed field
use factor to account for over-drying
energy consumption. DOE stated that
different manufacturers may target
different final RMCs for their highest
dryness level setting. Based on analysis
of the test results for this gas clothes
dryer unit, DOE stated that the highest
dryness level setting may be intended to
dry the clothes load to near bone dry,
beyond the target RMC of the DOE test
procedure, and would not be
appropriate for the proposed test cycle.
For this reason, DOE did not propose
that the highest dryness level be
specified for the test cycle. DOE stated
in the June 2010 TP SNOPR that a
‘‘normal’’ drying program would be more
representative of consumer usage habits
and would more likely dry the clothes
load to the target range specified in the
24 Towards the end of an automatic termination
cycle, a clothes dryer heater generally turns on and
off multiple times to limit the amount of heat
applied to the air entering the drum.
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DOE clothes dryer test procedure. 75 FR
37616.
Based on the results of this additional
testing, DOE proposed in the June 2010
TP SNOPR an approach in which, for
automatic termination control dryers, a
‘‘normal’’ program would be selected for
the test cycle to be most representative
of consumer usage. Where the drying
temperature can be chosen
independently of the program, it would
be set to the maximum to provide a
clear and consistent method. DOE notes
that ‘‘medium’’ or ‘‘low’’ temperature
settings may not be consistent among
different manufacturers. When the
heater switches off for the final time at
the end of the drying cycle (that is,
immediately before the cool-down
period begins) the dryer would be
stopped. If the final RMC is greater than
5 percent, the tests would be invalid
and a new run shall be conducted using
the highest dryness level setting. Any
test cycle in which the final RMC is 5
percent or less would be considered
valid. DOE also proposed that for
automatic termination control dryers,
the cycle setting selected for the test be
recorded. This would include settings
such as the drying mode, dryness level,
and temperature level. DOE also
requested comment on whether
multiple cycles and settings should be
tested and how the results from those
multiple tests should be evaluated. Id.
Bosch and Siemens Home Appliance
Group (BSH) expressed concern over
using the phrase ‘‘normal program’’
because no manufacturer offers a
program called ‘‘normal,’’ and the term
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‘‘normal’’ is ambiguous. BSH added that
it would be very difficult to achieve
reproducibility from test lab to test lab.
(BSH, Public Meeting Transcript, No. 20
at pp. 93–94) AHAM agreed with BSH
regarding the use of ‘‘normal’’ program,
noting that clothes washers have
transitioned from a normal cycle to
specifying settings based on fabric type.
(AHAM, Public Meeting Transcript, No.
20 at pp. 94–95) AHAM also
recommended that DOE contact
manufacturers of dryer usage materials,
such as fabric softeners, who may have
some survey data regarding usage
factors or the most commonly selected
program to avoid the terminology of
‘‘normal program.’’ (AHAM, Public
Meeting Transcript, No. 20 at p. 95) ALS
supported revising the ‘‘test cycle’’
definition to account for the fact that
most dryers no longer utilize the term
‘‘normal cycle’’ on their controls. ALS
supported using the same test cycle
definition the DOE clothes washer test
procedure utilizes—‘‘the cycle
recommended by the manufacturer for
washing cotton or linen clothes’’—but
modified to specify ‘‘for drying’’ instead
of ‘‘for washing.’’ (ALS, No. 24 at p. 4)
ALS commented that it supports
testing only one cycle (the cycle
recommended by the manufacturer for
drying cotton and linen clothes) for the
following reasons: (1) Manufacturers
provide other cycles for consumers, but
many of these other cycles are used
infrequently because consumers tend to
utilize a favorite cycle such as an
automatic termination cycle, or a default
cycle that they can easily initiate and
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that doesn’t require further
manipulation; (2) it would be difficult if
not impossible to develop any data or a
consensus for the weighting factors to
apply to the other cycles if multiple
cycles were tested; (3) the burden on
manufacturers and test labs to test
multiple cycles out-weighs any benefit;
and (4) the test cycle for cotton and
linen clothes, at maximum temperature
setting, will assess one of the most
energy-intensive cycles on clothes
dryers, so there is no need to further
complicate the test procedure to assess
if other cycles are more energy
intensive. (ALS, No. 24 at p. 5) ALS also
commented that dryers with automatic
cycle termination should have the
temperature for the test set at the
‘‘maximum’’ temperature setting option
available on the dryer. This is because
the test cycle should be ‘‘the cycle
recommended by the manufacturer for
drying cotton and linen clothes’’ and as
such would normally be a hightemperature heat setting. (ALS, No. 24 at
p. 5) Whirlpool stated that consumers
dry a variety of fabrics using a variety
of clothes dryer cycles. While no one
cycle reflects this diverse consumer
behavior, performing the energy test at
the maximum temperature on the
normal cycle is a straightforward means
of representing the highest-cost
consumer use of the product. Whirlpool
commented that, because of the wellestablished history with this approach,
a change in the test procedure to test
multiple cycles would not be warranted.
Whirlpool further stated that any change
would require extensive round-robin
testing to determine the impact of the
new test temperatures on the EF
calculation. (Whirlpool, No. 27 at p. 3)
The California Utilities/NRDC stated
that DOE’s proposal to test a ‘‘normal’’
drying program is reasonably
appropriate. The California Utilities/
NRDC stated that they lack additional
consumer information on typical cycles
and settings, and being aware of a
potentially large testing burden of many
different types of dryer tests, they
support DOE’s proposal to test at
‘‘normal’’ or ‘‘default’’ operation.
(California Utilities/NRDC, No. 33 at p.
4) The California Utilities/NRDC noted
that manufacturers expressed concern
regarding the use of the term ‘‘normal’’
cycle, so it is important that this term
be clarified or defined to prevent a
possible loophole in the test procedure.
The California Utilities/NRDC suggested
that DOE collect data from
manufacturers concerning the
conditions of operation for a ‘‘normal’’
dryer cycle to confirm that such cycles
are reasonably consistent among
manufacturers. Alternatively, DOE
could use that data to define a range of
operating conditions for a normal cycle,
or request that manufacturers suggest
such a definition. (California Utilities/
NRDC, No. 33 at p. 4)
Evaluation of Proposed Amendments for
Automatic Cycle Termination
As discussed above, DOE conducted
testing to evaluate the proposed
amendments to the clothes dryer test
999
procedure. As part of this testing, DOE
tested nine clothes dryers as specified
by the amendments to the test
procedure for automatic cycle
termination proposed in the June 2010
TP SNOPR. The testing consisted of
running the dryer on a ‘‘normal’’
automatic termination setting and
stopping the dryer when the heater
switches off for the final time
(immediately before the cool-down
period begins). Three identical tests
were conducted for each clothes dryer
unit, and the results were averaged. The
results of this testing, presented below
in Table III.8, showed that the tested
clothes dryers had a measured EF
between 12.4 percent and 38.8 percent
lower than the EF measured according
to the current DOE clothes dryer test
procedure. DOE also noted that all of
tested units dried the test load to final
RMCs well below the target RMC of 5
percent, ranging from 0.4 percent to 1.4
percent RMC, with an average of 0.8
percent. DOE also noted that even if the
field use factor of 1.18 for a timer dryer
is applied to the measured EF for a
clothes dryer equipped with automatic
cycle termination using the current DOE
clothes dryer test procedure, this EF
would still be more than the EF
measured under the automatic cycle
termination test procedure amendments
proposed in the June 2010 TP SNOPR.
(Applying the field use factor in this
way adds the fixed estimate of overdrying energy consumption associated
with time termination control dryers.)
TABLE III.8—DOE CLOTHES DRYER AUTOMATIC CYCLE TERMINATION TESTS
Current DOE test
procedure EF
lb/kWh *
Test unit
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Vented Electric Standard:
Unit 3 ................................................
Unit 4 ................................................
Vented Gas:
Unit 8 ................................................
Unit 9 ................................................
Unit 11 ..............................................
Vented Electric Compact 240V:
Unit 12 ..............................................
Unit 13 ..............................................
Vented Electric Compact 120V:
Unit 14 ..............................................
Ventless Electric Compact 240V:
Unit 15 ..............................................
Current DOE
test procedure
w/modified field
use factor **EF
lb/kWh
Proposed automatic cycle termination test procedure
EF
lb/kWh
Percent change
Final RMC
(%)
3.20
3.28
2.82
2.89
2.59
2.59
¥ 19.1
¥ 21.2
1.0
0.6
2.83
2.85
2.98
2.50
2.51
2.63
2.42
2.38
2.40
¥ 14.5
¥ 16.3
¥ 19.5
0.4
0.9
0.9
3.19
2.93
2.81
2.59
2.64
2.27
¥ 17.3
¥ 22.7
0.5
1.4
3.23
2.85
1.98
¥ 38.8
0.7
2.37
2.09
2.07
¥ 12.4
1.1
* Tests use the appropriate field use factor of 1.04 for clothes dryers with automatic termination.
** Field use factor changed from the nominal 1.04 for clothes dryers with automatic termination to 1.18, which is nominally for timer dryers.
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These results showed significantly
higher measured energy use for clothes
dryers tested under the DOE test
procedure with the proposed automatic
cycle termination amendments. DOE
evaluated possible reasons for this
difference, and concluded that given the
test load specified in the current DOE
test procedure,25 the proposed
automatic cycle termination control
procedures may not adequately measure
clothes dryer performance. As discussed
above in this section, DOE believes that,
although automatic termination control
dryers may be measured as having a
lower efficiency than a comparable
dryer with only time termination
control if tested according to the
proposed test procedure, automatic
termination control dryers may in fact
be drying the clothing to approximately
5-percent RMC in real world use. DOE
believes that automatic termination
control dryers reduce energy
consumption (by reducing over-drying)
compared to timer dryers based on
analysis of the AHAM field use survey
and analysis of field test data conducted
by NIST. 46 FR 27324 (May 19, 1981).
For these reasons, DOE believes the
test procedure amendments for
automatic cycle termination proposed in
the June 2010 TP SNOPR do not
adequately measure the energy
consumption of clothes dryers equipped
with such systems. Therefore, DOE is
not adopting in today’s final rule the
amendments for automatic cycle
termination proposed in the June 2010
TP SNOPR. 75 FR 37594, 37616 (June
29, 2010). If data is made available to
develop a test procedure that accurately
measures the energy consumption of
clothes dryers equipped with automatic
termination controls, DOE may consider
revised amendments in a future
rulemaking.
ALS commented that an automatic
cycle termination-equipped dryer that
produces a final RMC of greater than 5
percent should be required to have
additional test cycle runs. The
insufficiently dried load would be
placed back into the dryer for an extra
cycle, and the extra-cycle energy added
to the first test cycle results, until the
final RMC is 5 percent or less. ALS
commented that this extra cycle energy
would be a significant penalty and
incentive to keep manufacturers from
creating automatic cycle termination
systems that essentially tried to achieve
a low energy consumption value while
not achieving consumer-acceptable final
RMC levels. ALS also believes that this
25 The DOE clothes dryer test load is comprised
of 22 in x 34 in pieces of 50/50 cotton/polyesterblend cloth.
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method represents what consumers tend
do when a load is not sufficiently dried
at the end of the cycle—put the load
back into the dryer and run another dry
cycle on the same setting. (ALS, No. 24
at p. 3) The California Utilities/NRDC
supported DOE’s proposal to require a
re-test at the ‘‘highest energy consuming
setting’’ in the case of a dryer failing to
reach 5-percent RMC or less under a
normal drying program. (California
Utilities/NRDC, No. 33 at p. 4)
For the reasons discussed above, DOE
is not adopting in today’s final rule the
amendments proposed in the June 2010
TP SNOPR to better account for
automatic cycle termination. Therefore,
additional specifications for such an
approach are not relevant.
Dry Clothes Load Testing
CU commented that an additional test
using a dry clothes load should be
included as part of the test procedure to
assess how well a sensor detects that a
clothes load has been dried to terminate
the cycle. CU commented that it tested
products using a 12-lb dry clothes load
(less than 5 percent initial RMC) of
mixed cottons with the dryer at normal/
cotton, highest heat, and maximum
dryness level settings. CU observed
notable differences in the performance
of different types of dryers (that is, those
with thermostatic control and those
with moisture sensors). CU noted that
units with moisture sensors stopped
within a reasonable time, but units with
just a thermostat continued running,
sometimes 20 times longer than a dryer
with a moisture sensor. CU noted that
one dryer with the moisture sensor ran
an average of 3 minutes before shutting
off, and in 3 tests, it averaged 162 Wh
per test. Another dryer with a
thermostat ran for an average of about
60 minutes, and in 3 tests, it averaged
2,335 Wh per test. In addition, CU
observed significant variation among
dryers with moisture sensors and those
with thermostats, and stated it should
not be assumed that these results
represent performance for all dryers of
either type. (CU, No. 29 at pp. 2–3)
DOE does not believe running a dry
clothes load would be representative of
consumer usage. It also does not believe
that the amount of time a clothes dryer
operates with such a clothes load would
necessarily be representative of the
effectiveness of a sensor system in
detecting final RMC for an initially
damp clothes load. Further, DOE is not
aware of how an energy efficiency
metric would be established that
considers the energy consumption of a
dry clothes load test cycle. Therefore,
DOE is not adopting any provisions for
measuring the energy consumption of a
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dry clothes load test cycle in today’s
final rule.
Evaluation of Automatic Termination
Technologies
DOE noted in the June 2010 TP
SNOPR that it conducted preliminary
automatic cycle termination tests to
analyze the various automatic
termination technologies found in
DOE’s sample of selected dryers. DOE
selected the AHAM 8-lb test load 26
instead of the 7-lb load specified in the
DOE test procedure for standard-size
clothes dryers. It did so to lengthen the
test cycle times and better evaluate the
function of the dryer controls as the test
load approached low RMCs. DOE also
noted that the independent test lab
conducting the clothes dryer tests used
a data acquisition system to monitor
estimated RMC of the test load
continuously during the test cycle. The
automatic termination tests conducted
by DOE consisted of running the test
cycle in a user-programmable automatic
termination mode and allowing the
dryer to self-terminate the drying cycle
using the various automatic termination
sensor technologies. DOE monitored the
energy consumption and estimated RMC
of the test load during the test cycle
from the starting time at 70-percent
initial RMC to the time when the heater
last cycled off (that is, immediately
before the cool-down period). The
specific focus was on analyzing the
amount of over-drying energy consumed
drying the test load to less than
5-percent RMC.27 75 FR 37594, 37617
(June 29, 2010).
Figure III.1 shows the over-drying
energy consumption versus the final
RMC for a number of different units
tested, and, in some cases, different
cycle settings.28 The data show that
over-drying the test load to lower final
RMCs requires higher energy
consumption, with a slightly
exponential trend likely because it
becomes more difficult to remove the
final small amounts of moisture
remaining in the test load. DOE noted in
the June 2010 TP SNOPR that it did not
observe any relationship between the
type of automatic cycle termination
26 The AHAM 8-lb test load is made up of the
following mixed cotton items, which are intended
to represent clothes items regularly laundered: 2
sheets, 1 table cloth, 2 shirts, 3 bath towels, 2 ‘‘T’’
shirts, 2 pillow cases, 3 shorts, 1 wash cloth, 2
handkerchiefs.
27 As noted in the June 2010 TP SNOPR, DOE
applied a correction factor to the test data to
account for the fact that the automatic cycle
termination tests used the AHAM 8-lb test load
instead of the DOE 7-lb test load.
28 DOE noted that some of the tested units
stopped the test cycle at or higher than 5-percent
RMC, thereby not producing over-drying.
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
1001
methods than the methods proposed in
the June 2010 TP SNOPR (that is,
various automatic cycle termination
settings). Therefore, DOE was unable to
determine whether one type of sensor
technology is more accurate, and thus
more effective at preventing overdrying. 75 FR 37618.
Porticos commented that DOE
considered only two possible methods
for automatic cycle termination
(moisture and temperature sensing).
Porticos commented that these may be
the only practical alternatives in a
vented, forced-convection tumble dryer,
but that alternate drying technologies
may enable alternate methods of
determining when the drying cycle
should be terminated. Ignoring this
possibility penalizes any appliance that
attempts to deploy a different
technology. (Porticos, No. 23 at p. 1)
DOE agrees that the test procedure
should not exclude alternate sensing
technologies used for automatic cycle
termination controls. DOE notes section
3.5 of the test procedure, ‘‘Test for
automatic termination field use factor
credits,’’ specifies that the field use
factor for automatic cycle termination
would apply only to clothes dryers that
meet the requirements for the
definitions of ‘‘temperature sensing
control’’ or ‘‘moisture sensing control.’’
The test procedure defines ‘‘temperature
sensing control’’ a system that monitors
the exhaust air temperature to
automatically terminate the dryer cycle.
The test procedure also defines
‘‘moisture sensing control’’ as a system
that uses a moisture sensing element
within the drum that monitors the
amount of moisture in the clothes to
automatically terminate the dryer cycle.
DOE also notes the test procedure
defines ‘‘automatic termination control’’
as a control system with a sensor that
monitors either the dryer load
temperature or its moisture content and
with a controller that automatically
terminates the drying process. DOE
believes that this definition would not
limit the emergence of any new sensor
technologies that monitor the moisture
content or temperature in other ways
from applying the field use factor for
automatic cycle termination. For these
reasons, DOE amends section 3.5 of the
test procedure to specify that the field
use factor applies to clothes dryers that
meet the requirements for the
definitions of ‘‘automatic termination
control.’’
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Target Final RMC
DOE also noted in the June 2010 TP
SNOPR that AS/NZS Standard 2442
specifies the maximum allowable final
RMC for automatic termination control
dryers as 6 percent. DOE, however,
stated that it is unaware of any data
indicating that a final RMC of 6 percent
would be representative of current
consumer usage habits. DOE also noted
that using 5-percent RMC, as proposed
in today’s June 2010 TP SNOPR, would
remain within the range specified by the
current DOE test procedure, which
specifies 2.5- to 5-percent final RMC. Id.
The Joint Petitioners and AHAM
commented that a final RMC of 5
percent is appropriate. (Joint Petitioners,
No. 30 at p. 6; AHAM, No. 31 at p. 6))
ALS stated that the test load final RMC
should be no greater than 5 percent.
ALS stated that if the test cycle
continued to measure all of the energy
including cool-down, manufacturers
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sensor technology used and the amount
of over-drying. DOE also noted,
however, that these tests were
conducted using different testing
1002
Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
would adopt their own methods to
ensure that they do not over-dry the test
load. (ALS, No. 24 at p. 3) As discussed
above, DOE is not adopting the
amendments to better account for
automatic cycle termination proposed in
the June 2010 TP SNOPR. For these
reasons, DOE is not amending the test
procedure to revise the final RMC.
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Cool-Down Period
DOE also noted in the June 2010 TP
SNOPR that there are at least two ways
to terminate the drying cycle during the
test: (1) Termination before cool-down,
or (2) termination at the end of the
selected test cycle, including cooldown. 75 FR 37594, 37616 (June 29,
2010). Section 4.2 of AS/NZS Standard
2442.1 requires that, for automatic
termination control dryers, the
programmed test cycle be run until
immediately before the cool-down
period begins. Similarly, section 4.5.1 of
AHAM–HLD–1–2009 requires that the
automatic termination control dryer test
cycle not be permitted to advance into
the cool-down period. Alternatively,
section 9.2.1 of EN Standard 61121
requires that the selected test cycle
program be allowed to run until
completion, including the cool-down
period. In the June 2010 TP SNOPR,
DOE proposed amendments for
automatic cycle termination based on
the provisions in AS/NZS Standard
2442 because it provides a more
representative comparison of the energy
consumption between automatic
termination control dryers and timer
dryers than EN Standard 61121. In
addition, the proposed amendments to
stop the test cycle immediately before
the cool-down period would harmonize
DOE test methods with AS/NZS
Standard 2442 and AHAM–HLD–1–
2009. Id. DOE stated, however, that it
was considering the alternative method
of section 9.2.1 of EN Standard 61121.
DOE recognizes that manufacturers may
design products to use the residual heat
during the cool-down period (that is,
immediately after the heater has
switched off for the final time) to
continue to dry the clothes load while
slowly spinning the drum to achieve a
desired RMC.29 DOE recognizes that
including the cool-down period may
make it possible for some manufacturers
to design dryers that attain the desired
RMC with lower total energy
consumption. DOE noted that this
potential for energy efficiency
improvement would not be captured by
29 The clothes dryer would also consume energy
to spin the drum during the cool-down period that
is currently not accounted for by the DOE test
procedure.
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the test methods proposed in the June
2010 TP SNOPR. To capture this realworld energy savings potential
associated with the additional drying
using residual heat during the cooldown period, DOE stated in the June
2010 TP SNOPR that it could adopt an
alternate approach to include the
measurement of the cool-down period
as part of the proposed automatic cycle
termination test methodology. Under
this alternate approach, section 3.3.2 of
the test procedure for automatic
termination control dryers, instead of
specifying that ‘‘when the heater
switches off for the final time,
immediately before the cool-down
period begins, stop the dryer,’’ would
specify to ‘‘run the clothes dryer until
the programmed cycle has terminated.’’
DOE also noted that inclusion of the
cool-down period under the proposed
test method would not affect the ability
to compare energy consumption test
results between automatic termination
control dryers and timer dryers in DOE’s
clothes dryer test procedure. DOE
further stated in the June 2010 TP
SNOPR that it is unaware of data
showing the effects of including the
cool-down period on the measured
efficiency as compared to the existing
test procedure. 75 FR 37616–17.
The Joint Petitioners, AHAM,
Whirlpool and ALS commented that,
although they generally promote
harmonization with international
standards, they do not agree that AS/
NSZ Standard 2442 provides the best
methods and procedures to account for
the amount of over-drying associated
with automatic termination control
dryers beyond a specified RMC. The
Joint Petitioners, AHAM, Whirlpool,
ALS, the California Utilities/NRDC, and
EJ commented that the test procedure
should measure the full cycle, including
cool-down period, which is more
representative of consumer usage
because it includes all of the energy use
in a cycle. The Joint Petitioners, AHAM,
Whirlpool and ALS stated that such an
approach is reproducible and repeatable
because it does not require any
‘‘guesswork’’ as to when the cool-down
will begin. The approach is also less
burdensome because it does not require
the manufacturers to determine the
point immediately before cool-down for
each model. (Joint Petitioners, No. 30 at
p. 5; AHAM, No. 31 at p. 5; Whirlpool,
No. 27 at pp. 2, 3; ALS, No. 24 at p. 3;
ALS, Public Meeting Transcript, No. 20
at pp. 97–98; California Utilities/NRDC,
No. 33 at pp. 4–5; EJ, No. FDMS D0039
at pp. 1–2)
ALS also commented that the
‘‘default’’ cool-down should be set if the
dryer has selectable cool-down time
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period options. (ALS, No. 24 at p. 6)
AHAM commented that the ‘‘asshipped’’ (that is, ‘‘default’’) cool-down
settings should be included in active
mode because this approach is more
representative of actual consumer usage.
(AHAM, No. 31 at p. 6)
The Joint Efficiency Advocates
Comment stated that excluding the cooldown period results in a portion of the
energy consumed by a drying cycle not
being measured by the test procedure. In
addition, the Joint Efficiency Advocates
Comment stated that including the cooldown period could provide
manufacturers with an additional option
for reducing energy consumption. (Joint
Efficiency Advocates, No. 28 at p. 3)
ALS and BSH supported including the
cool-down period in the test procedure.
They feel manufacturers may optimize
the point where the heating is stopped
and the residual heat in the load is used
during cool-down to complete the
drying process to achieve consumeraccepted final moisture retention levels,
while avoiding ‘‘over drying’’ loads and
potentially wasting energy. (ALS, No. 24
at p. 3; BSH, Public Meeting Transcript,
No. 20 at p. 98) EJ commented that a test
procedure that ignores the additional
drying functionality provided by
cool-down mode reduces
manufacturers’ incentive to provide this
energy-saving feature. (EJ, No. FDMS
D0039 at pp. 1–2)
Whirlpool requested that DOE
complete further analysis to adjust EF
within the test procedure to account for
the inclusion of the cool-down portion
of the cycle. Whirlpool stated that
failure to adjust the EF requirements
will inadvertently result in
requirements becoming too stringent.
Whirlpool commented that it can infer
that the cool-down portion of the cycle
consumes little energy when compared
to the drying portion as it is relatively
short and uses only motor energy, not
heating element energy. (Whirlpool, No.
27 at pp. 2, 3) Whirlpool also
commented that the additional energy
consumed during cool-down period
does not follow linear relationship with
the RMC of the test load. Whirlpool
stated that it does not have sufficient
data to fully address how this would be
reflected in total energy consumption.
Whirlpool commented that if DOE were
to make a specific request to AHAM for
such data, Whirlpool would be willing
to gather and supply information to
AHAM for aggregation and submittal to
DOE. (Whirlpool, No. 27 at p. 5) ALS
commented that it has no data to submit
to DOE at this time on how the
proposed added cool-down period
energy consumption would impact the
measured energy efficiency of existing
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clothes dryers, and suggested that DOE
conduct tests to determine the impact.
(ALS, No. 24 at p. 6) The California
Utilities/NRDC similarly commented
that they do not have specific data on
the impacts this cool-down period has
on dryer per-cycle energy use and
calculated EF. However, they stated that
although the impacts may be small, DOE
should, for the purposes of
completeness and reproducibility,
consider including the energy use of the
cool-down portion of the cycle into the
active mode test procedure. The
California Utilities/NRDC stated that
DOE should revise the energy
conservation standards to reflect this
test procedure change. (California
Utilities/NRDC, No. 33 at pp. 4–5)
As discussed above, DOE is not
adopting the amendments to better
account for automatic cycle termination
proposed in the June 2010 TP SNOPR.
For this reason, DOE is not amending
the test procedure to include the cooldown period for automatic termination
test cycles. If DOE considers potential
amendments for automatic cycle
termination in a future rulemaking, it
may consider provisions that account
for the cool-down period.
Calculation of Revised Results From
Automatic Cycle Termination Test
Measurements
In the June 2010 TP SNOPR, DOE also
proposed to revise section 4,
‘‘Calculation of Derived Results from
Test Measurements,’’ of the DOE test
procedure. DOE proposed to revise the
field use factors in the current DOE test
procedure to more appropriately
account for automatic termination
control dryers’ over-drying energy
consumption. DOE proposed that a field
use factor of 1.0 (instead of the 1.04
currently provided) would be specified
for automatic termination control
clothes dryers, so that any over-drying
energy consumption would be added
directly to the drying energy
consumption to decrement EF. If the
proposed test methods were used, an
automatic termination control dryer that
is able minimize over-drying by drying
the test load to close to 5-percent RMC
would achieve a higher measured
efficiency than if it over-dried the test
load to an RMC of less than 5 percent.
The lower amount of energy consumed
over-drying the test load would be
included in the per-cycle energy
consumption, and would result in a
reduction in the measured EF. For timer
dryers, DOE proposed to use the percycle energy consumption
measurements from the two proposed
tests cycles discussed above in this
section (corresponding to 5–6 and 4–5
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percent final RMCs) to interpolate the
value of the per-cycle energy
consumption required to dry the test
load to exactly 5-percent RMC. The 1.18
field use factor in the current DOE test
procedure would then be applied to
account for the over-drying energy
consumption of timer dryers. 75 FR
37594, 37617 (June 29, 2010).
As discussed above in this section,
DOE noted in the September 1977 TP
Final Rule that the 1.18 field use factor
in the calculation of EF for timer dryers
was based on analysis of data from a
field use survey conducted by
Oklahoma Gas and Electric Company
involving 64 homes as well as data
provided by AHAM on the measured
energy consumption per-cycle under the
DOE test procedure to account for the
differences between the values derived
from the laboratory test procedures and
those obtained from actual consumer
use. 42 FR 46145, 46146 (September 14,
1977). DOE stated in the June 2010 TP
SNOPR that it was unaware of any data
or studies indicating the 1.18 field use
factor for timer dryers used to account
for over- or under-drying test loads in
real-world use is inaccurate and not
currently representative of consumer
usage. For this reason, DOE did not
propose to revise the 1.18 field use
factor for timer dryers in the June 2010
TP SNOPR but requested data and
comment on whether this value is
appropriate. Id.
AHAM, the Joint Petitioners, the
California Utilities/NRDC, and ALS
supported DOE’s proposal to change the
field use factor from 1.04 to 1.0 for
automatic termination control dryers
and not revise the 1.18 field use factor
for timer dryers. (AHAM, No. 31 at p.
6; Joint Petitioners, No. 30 at p. 6;
California Utilities/NRDC, No. 33 at p.
5; ALS, No. 24 at p. 3)
As discussed above, DOE is not
adopting in today’s final rule the
amendments to better account for
automatic cycle termination proposed in
the June 2010 TP SNOPR. For the
reasons stated above, DOE is not
amending the test procedure in today’s
final rule to include the revisions to the
energy use calculations or the field use
factors proposed in the June 2010 TP
SNOPR. If DOE considers potential
amendments for automatic cycler
termination in a future rulemaking, it
may consider such revisions to the
energy use calculations and field use
factors.
3. Test Procedure for Ventless Clothes
Dryers
DOE noted in the October 2007
Framework Document that a potential
limitation of the clothes dryer test
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1003
procedure had been identified for
ventless dryers, which include
condensing clothes dryers and
combination washer/dryers.
(Framework Document, STD No. 1 at p.
5) Ventless clothes dryers do not vent
exhaust air to the outside as a
conventional clothes dryer does.
Instead, they typically use ambient air
in a heat exchanger to cool the hot,
humid air inside the appliance, thereby
condensing out the moisture.
Alternatively, cold water can be used in
the heat exchanger to condense the
moisture from the air in the drum.30 In
either case, the dry air exiting the drum
is reheated and recirculated in a closed
loop. Thus, rather than moisture-laden
exhaust air that vents outside, ventless
clothes dryers produce a wastewater
stream that can be either collected in an
included water container or discharged
down the household drain. The process
of condensing out the moisture in the
recirculated air results in higher energy
consumption than a conventional
clothes dryer, however, and it can
significantly increase the ambient room
temperature.
Manufacturers of condensing clothes
dryers have, in the past, applied for
waivers from the DOE test procedure for
these products on the basis that the test
procedure did not contain provisions for
ventless clothes dryers. See, e.g., 74 FR
66334 (December 15, 2009); 75 FR
13122 (Mar. 18, 2010). The current test
procedure requires using an exhaust
restrictor to simulate the backpressure
effects of a vent tube in an installed
condition. Condenser dryers do not
have exhaust vents because they
recirculate rather than exhaust the
process air.
In the October 2007 Framework
Document, DOE stated that it intended
to analyze ventless clothes dryers as a
separate product class, recognizing the
unique utility that ventless clothes
dryers offers to consumers. That utility
is the ability to be installed in
conditions in which vented clothes
dryers would be precluded due to
venting restrictions. DOE considered
two product classes for ventless clothes
dryers: (1) Ventless electric compact
(240V) clothes dryers; and (2) electric
combination washer/dryers.
In this final test procedure rule, DOE
adopts amendments to measure the
energy use of ventless clothes dryers, as
discussed in more detail below.
30 This is a typical approach for combination
washer/dryers, which wash and dry a load in the
same drum.
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Effects of Clothes Dryers on HVAC
Energy Use
In response to the October 2007
Framework Document, DOE received
comments from AHAM that the energy
calculations for ventless clothes dryers
should take a more ‘‘holistic’’ approach
than those for vented clothes dryers.
That is because ventless clothes dryers
can have an effect on energy use oustide
of their system (that is, impacts on
HVAC loads). 75 FR 37594, 37620–21
(June 29, 2010). EPCA requires that any
test procedures prescribed or amended
under this section be reasonably
designed to produce test results that
measure energy efficiency, energy use,
water use, or estimated annual operating
cost of a covered product during a
representative average use cycle or
period of use. (42 U.S.C. 6293(b)(3))
DOE stated in the June 2010 TP SNOPR
that accounting for the impacts of
ventless clothes dryers on HVAC loads
and thus on the energy use of a
household would be inconsistent with
the EPCA requirement that a test
procedure measure the energy use of a
covered product. DOE also noted that,
while the test procedure for heat pump
water heaters does not account for
impacts to HVAC loads, DOE
considered the effects of heat pump
water heaters on house heating loads as
part of the energy-use characterization
in the rulemaking to establish energy
conservation standards rulemaking for
water heaters. For these reasons, DOE
did not propose to amend its clothes
dryer test procedure to account for the
ambient space conditioning impacts in
the June 2010 TP SNOPR, but stated that
it would consider such impacts as part
of the concurrent energy conservation
standards rulemaking. 75 FR 37594,
37621 (June 29, 2010).
In response to the June 2010 TP
SNOPR, the California Utilities/NRDC
commented that DOE should consider
HVAC impacts as part of the concurrent
energy conservation standards
rulemaking. They added that the ECOS
report showed that space conditioning
impacts due to clothes dryer intake air
may be significant. (California Utilities/
NRDC, No. 33 at pp. 8–9) The California
Utilities/NRDC and the Super Efficient
Dryer Initiative (SEDI) noted that the
actual impacts will depend on many
factors, such as climate, season, and
location of the clothes dryer within the
home. They stated DOE should
thoroughly assess this aspect of clothes
dryer operation and research
opportunities for energy reduction.
(California Utilities/NRDC, No. 33 at p.
9; SEDI, No. 34 at p. 2)
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Porticos commented that the HVAC
load from a vented clothes dryer is
much higher than that of other
household appliances. According to
Porticos, a vented clothes dryer induces
air infiltration equal to the exhaust
airflow (up to 160 cubic feet per minute
(cfm)), enough to completely empty a
1200 cubic foot (ft3) home of all its
conditioned air in 1 hour. (Porticos, No.
23 at p. 2) Porticos and SEDI both
commented that there would be
significant HVAC savings associated
with switching from vented to ventless
clothes dryers. (Porticos, No. 23 at p. 2;
SEDI, No. 34 at p. 2) SEDI added that
vented clothes dryers operate by
drawing supply air from the volume of
conditioned space within a house. The
supply air is heated and used to dry the
clothes. The air is then exhausted from
the home. SEDI stated this process
wastes both the heating energy put into
that air by the dryer itself, but also the
heating or cooling energy put into that
air earlier by the home’s HVAC system.
(SEDI, No. 34 at p. 2) Porticos also
added that ventless dryers tend to
directly heat the living space rather than
inducing air infiltration. (Porticos, No.
23 at p. 2) The California Utilities/NRDC
commented that HVAC impacts may be
mitigated through increased use of
ventless dryers, or other technologies for
vented dryers, such as an outside air
intake port, which could provide a
location to fit an intake air vent. The
California Utilities/NRDC stated that it
is important that DOE gather data on the
HVAC impacts of clothes dryers to
accurately assess the costs and savings
impacts of such technologies.
(California Utilities/NRDC, No. 33 at p.
9)
The California Utilities/NRDC
commented that the test procedure
would be a simple and convenient
means for manufacturers to submit
useful data to DOE on clothes dryer
operation that impacts HVAC loads
(namely intake air). Data on intake air
could be gathered by requiring the
measurement of intake air via a small
sensor in the airstream during the test.
The California Utilities/NRDC added
that this information would be a
valuable indication of the amount of
airflow caused by clothes dryers, and
could form the basis for subsequent
DOE analysis. (California Utilities/
NRDC, No. 33 at p. 9) Porticos
recommended the following
modifications to the test procedure to
evaluate the effects of the clothes dryer
on building energy consumption:
1. Directly measure the exhaust
airflow (defined as zero for ventless
appliances);
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2. Directly measure the ambient heatload represented by the appliance
during operation (DOE might define this
as zero for vented appliances);
3. Calculate the overall HVAC burden
due to heat-burden and induced
infiltration; and
4. Optionally, modify this figure to
account for variations due to regional
usage (a vented dryer might work quite
well in a moderate climate, but less-so
in colder climates). (Porticos, No. 23 at
p. 2)
Porticos added that there is a
precedent for addressing impacts
external to the clothes dryer because
existing DOE test procedures penalize
clothes washers which do a poor job of
spin-drying clothes, thus placing an
excessive burden on the clothes dryer.
Id.
SEDI commented that both the current
and proposed clothes dryer test
procedures ignore the HVAC impact of
vented dryers, and will not provide
DOE, or SEDI and other energy
efficiency program providers, with the
information necessary to estimate HVAC
savings. SEDI commented that ideally,
testing for all clothes dryers would
include measurement of the energy
content of the air expelled from the
home during the drying cycle, which
would be added to the energy directly
consumed by the dryer itself. (SEDI, No.
34 at p. 2) SEDI supported the
recommended modifications for
measuring HVAC impacts submitted by
Porticos. SEDI also recognized,
however, that it may be extremely
difficult to develop HVAC energy
consumption algorithms for residential
clothes dryers that are applicable across
the United States. SEDI also recognized
that pursuing this comprehensive
approach could move DOE away from
harmonization with international
standards. SEDI commented that, at a
minimum, DOE should adopt at least
modifications 1 and 2 suggested by
Porticos, presented above, but with the
following change: ‘‘1. Directly measure
the exhaust air volume (defined as zero
for ventless appliances) during the
entire drying cycle.’’ SEDI commented
that this change would enable the
energy use of clothes dryers that have
different rates of venting at different
points during the drying cycle. In
addition, if the volume of air vented by
a clothes dryer from a home is
measured, the HVAC impacts of that
clothes dryer on the home could be
estimated. (SEDI, No. 34 at p. 2)
DOE reiterates that accounting for the
effects of clothes dryers on HVAC
energy use is inconsistent with the
EPCA requirement that a test procedure
measure the energy efficiency, energy
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
use, or estimated annual operating cost
of a covered product. (42 U.S.C.
6293(b)(3)) DOE acknowledges its
clothes washer test procedure measures
the RMC at the end of the wash cycle,
but notes that in this case, the test
procedure accounts directly for the
additional energy use of a clothes
washer to remove moisture from a
clothes load. For these reasons, DOE is
not revising the test procedure to
account for HVAC energy use in today’s
final rule.31
The Joint Petitioners commented that
DOE should create a ventless clothes
dryer test procedure to define a baseline
energy consumption level for this new
product category. Such a procedure
would include combination washer/
dryers. (Joint Petitioners, No. 25 at p. 14;
Joint Petitioners, No. 30 at p. 6) ALS
also supported the addition of test
procedures for ventless clothes dryers.
(ALS, No. 24 at p. 6) SEDI also noted the
importance of expanding the test
procedure to accommodate ventless
clothes dryers, such as the energy
efficient heat pump clothes dryers now
gaining market share in Europe. SEDI
stated that DOE should develop a
ventless clothes dryer test procedure as
soon as possible, while taking care not
to inadvertently discourage efforts to
increase the energy efficiency of clothes
dryers in North America. (SEDI, No. 34
at p. 2)
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Ventless Clothes Dryer Test Procedure
Amendments
In the June 2010 TP SNOPR, DOE
examined an alternate test procedure for
ventless clothes dryers that provided
definitions for ‘‘conventional clothes
dryers’’ and ‘‘condensing clothes dryers’’
and would require the exhaust
simulator to be used only for vented
clothes dryers. DOE conducted limited
tests of ventless clothes dryers at an
independent testing laboratory
according to those amendments. DOE
conducted three tests per unit on one
ventless electric compact (240V) clothes
dryer and one ventless combination
washer/dryer. Table III.9 shows the test
results. DOE observed no variation in EF
from test to test of the proposed test
31 DOE further notes that to accurately evaluate
the HVAC impacts of clothes dryers it would need
to determine the amount of heating and cooling
being performed by the HVAC system, which would
vary by region and time of year. In addition, to
determine the amount of induced infiltration and
heat-load caused by a clothes dryer, DOE would
need to develop provisions for accurate and
repeatable measurements, including: test equipment
tolerances, position of measurement devices in
either the exhaust or other locations, and
determination of representative household air
leakage rates. Such additional testing provisions for
measuring the HVAC impacts would also increase
the testing burden on manufacturers.
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procedure for the ventless electric
compact (240V) dryer, and less than 2percent variation in EF test-to-test for
the ventless combination washer/dryer.
Based on this testing, DOE stated in the
June 2010 TP SNOPR that the alternate
testing procedures appear to produce
repeatable results. 75 FR 37594, 37621
(June 29, 2010).
TABLE III.9—DATA FROM DOE TESTING OF VENTLESS CLOTHES DRYERS
FOR THE JUNE 2010 TP SNOPR
EF (lb/kWh)
Test run
Ventless
electric
compact
(240 V)
1 ................
2 ................
3 ................
Ventless
combination
washer/dryer
2.37
2.37
2.37
1.95
1.96
1.93
DOE also investigated testing
conditions and methods for ventless or
condensing clothes dryers specified in
international test standards, including
those used in Europe, China, Australia,
and New Zealand. Id.
DOE evaluated EN Standard 61121,
and identified as relevant the test
procedures for condensing (ventless)
clothes dryers, as well as certain test
conditions that affect all clothes dryers.
In particular, DOE noted that section 3
of EN Standard 61121, ‘‘Definitions and
symbols,’’ provides definitions for ‘‘air
vented tumble dryer’’ and ‘‘condenser
tumble dryer.’’ DOE noted that section 6
of EN Standard 61121, ‘‘General,’’
provides general conditions for
measurements for both types of dryers,
in particular for installation without an
exhaust duct, as well as ambient
temperature conditions. DOE noted that
section 9 of EN Standard 61121,
‘‘Performance tests,’’ provides the test
procedures for performance tests for
both types of dryers. DOE noted in the
June 2010 TP SNOPR these test
procedures provide greater specificity
than the alternate test procedure
discussed above. 75 FR 37621–22.
DOE also evaluated AS/NZS Standard
2442.1, which specifically includes
condenser clothes dryers and the dryer
function of combination washer/dryers.
DOE noted that AS/NZS Standard
2442.1 provides definitions for vented
and condenser clothes dryers that are
essentially the same as those provided
in EN Standard 61121. DOE also noted
that AS/NZS Standard 2442.1 provides
exhaust conditions for installation that
are very similar to those provided in EN
Standard 61121. 75 FR 37622.
In the June 2010 TP SNOPR, DOE also
considered comments that Whirlpool
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1005
submitted as part of the residential
clothes dryer and room air conditioner
energy conservation standards
rulemaking, providing amendments to
the DOE test procedure for clothes
dryers to include methods for the testing
of condensing dryers.32 These suggested
amendments were largely based on EN
Standard 61121. DOE noted that
Whirlpool suggested definitions for
‘‘exhausted’’ clothes dryers, ‘‘nonexhausted’’ clothes dryers, and
‘‘condensing’’ clothes dryers. Whirlpool
also suggested provisions for the
installation conditions for ventless
clothes dryers, in particular for
installation without an exhaust
simulator. Whirlpool also suggested
provisions for ventless clothes dryers for
pre-conditioning, conditions for a
condensation box and the condenser
unit, as well as test measurement
methods for ventless clothes dryers. 75
FR 37622–23.
DOE reviewed the definitions in EN
Standard 61121 (section 3), AS/NZS
Standard 2442.1 (section 1.4), and
Whirlpool’s proposed amendments to
the DOE test procedure. DOE concluded
that the proposed definitions of
‘‘conventional clothes dryer’’ and
‘‘condensing clothes dryer’’ are
essentially the same as the international
test standards definitions. DOE
proposed to define ‘‘conventional
clothes dryer’’ as ‘‘a clothes dryer that
exhausts the evaporated moisture from
the cabinet.’’ It proposed to define
‘‘ventless clothes dryer’’ as ‘‘a clothes
dryer that uses a closed-loop system
with an internal condenser to remove
the evaporated moisture from the heated
air. The moist air is not discharged from
the cabinet.’’ DOE proposed to use the
term ‘‘ventless’’ to reflect the actual
consumer utility (that is, no external
vent required) instead of ‘‘condensing’’
because of the possibility that vented
dryers that also condense are also
available on the market. 75 FR 37623.
AHAM and ALS commented in support
of the proposed definitions. (AHAM,
No. 31 at p. 6; ALS, No. 24 at p. 6)
Whirlpool commented that it supports
substituting ‘‘ventless’’ for ‘‘condensing’’.
(Whirlpool, No. 27 at p. 3) For the
reasons stated above, DOE adopts the
definitions of ‘‘conventional clothes
dryer’’ and ‘‘ventless clothes dryer’’
proposed in the June 2010 TP SNOPR.
DOE evaluated the installation
conditions detailed in EN Standard
61121 (section 6.1), AS/NZS Standard
2442.1 (section 3.4), and Whirlpool’s
32 Whirlpool, 2007. ‘‘U.S Department of Energy
Test Procedure Change for Condensing Clothes
Dryers.’’ September 4, 2007. Docket No. EE–2007–
BT–STD–0010, Comment Number 13.
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
proposed amendments to the DOE test
procedure. DOE stated in the June 2010
TP SNOPR that the proposed
amendments for the exhaust duct
installation requirements, with
clarifications added, are appropriate for
testing ventless clothes dryers. 75 FR
37594, 37623 (June 29, 2010). DOE
noted the proposed exhaust duct
installation conditions remove the
requirement for installing an exhaust
simulator for a clothes dryer without an
exhaust duct (that is, a ventless clothes
dryer). The international test standards
noted above also require that a clothes
dryer without an exhaust duct be tested
as such. Those standards, however, also
provide additional conditions for a
clothes dryer with an optional exhaust
duct, stating that such a clothes dryer
should be tested without the duct
installed. DOE believes these
installation conditions provide
additional clarity and cover all possible
clothes dryer configurations, as well as
harmonizes with international test
standards. Therefore, DOE proposed in
the June 2010 TP SNOPR to amend
section 2.1 of the DOE test procedure for
clothes dryers, which covers installation
conditions. The amendments qualify the
requirement for an exhaust simulator so
that it would apply only to conventional
clothes dryers. The amendments added
the clarification that ventless clothes
dryers be tested without the exhaust
simulator installed and, if a dryer is
designed to operate with an optional
exhaust duct, the dryer shall be tested
without the duct installed. Id. AHAM,
Whirlpool, and ALS supported the
proposed exhaust duct installation
conditions. (AHAM, No. 31 at p. 7;
Whirlpool, No. 27 at p. 3; ALS, No. 24
at p. 6) In the absence of comments
objecting to this proposal, DOE adopts
the exhaust duct installation conditions
proposed in the June 2010 TP SNOPR.
DOE also believes the provisions in
EN Standard 61121 regarding a
condensation box provides additional
clarity that the test procedures are
intended to cover all possible ventless
clothes dryer configurations. For this
reason, DOE proposed in the June 2010
TP SNOPR to revise section 2.1,
‘‘Installation,’’ of the DOE test procedure
for clothes dryers. The revision would
add this requirement to the installation
conditions: ‘‘if a manufacturer gives the
option to use a ventless clothes dryer
with or without a condensation box, the
clothes dryer shall be tested with the
condensation box installed.’’ In
addition, DOE proposed to amend the
testing cycle measurement in section 3.3
to add that if the dryer automatically
stops during a cycle because the
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condensation box is full of water, the
test is stopped, and the test run is
invalid. This requirement would ensure
efficiency is measured consistently. 75
FR 37594, 37623 (June 29, 2010).
AHAM and Whirlpool both supported
the proposed change to section 2.1 of
the DOE test procedure. (AHAM, No. 31
at p. 7; Whirlpool, No. 27 at p. 3) For
the reasons stated above, and in the
absence of comments objecting to this
proposal, DOE adopts in today’s final
rule the revisions to section 2.1,
Installation of the DOE clothes dryer test
procedure regarding a condensation box
as proposed in the June 2010 TP
SNOPR. 75 FR 37594, 37623 (June 29,
2010).
AHAM also commented that DOE
should clarify that if the condensation
box is full and the test is invalid, the retesting should be conducted under the
same installation conditions as the
original test. Those conditions should
be those provided in the manufacturer’s
use and care guide so that the test is
representative of actual consumer use.
(AHAM, No. 31 at p. 8) Whirlpool
similarly recommended adding, for
clarity, that if the condensation box is
full and the test is invalid, that the box
is to be emptied and the test re-run from
the beginning. (Whirlpool, No. 27 at p.
4) DOE agrees that additional provisions
should be included to clarify the
procedure for retesting when the
condensation box is full of water and
the test is considered valid. DOE
believes that Whirlpool’s suggested
revision provided explicit instructions
as to the procedure for re-running the
test cycle. For these reasons, DOE
amends section 3.3 of the DOE clothes
dryer test procedure to add that ‘‘if the
dryer automatically stops during a cycle
and because the condensation box is full
of water, the test is stopped and the test
run is invalid, in which case the
condensation box shall be emptied and
the test re-run from the beginning.’’
Also regarding installation conditions,
DOE believes that Whirlpool’s proposal
to add a requirement that the condenser
unit of the clothes dryer must remain in
place and not be taken out of the clothes
dryer for any reason between tests
would clarify the test procedure and
ensures that all manufacturers are
testing products under the same
conditions. For this reason, DOE
proposed in the June 2010 TP SNOPR to
add in section 2.1 of the DOE clothes
dryer test procedure the provision that
the condenser unit of the dryer must
remain in place and not be taken out of
the dryer between tests. 75 FR 37594,
37623 (June 29, 2010).
In the June 2010 TP SNOPR,
Whirlpool supported the proposed
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amendment to require that the
condenser unit remain in place and not
be removed between tests, adding that
this is for purposes of repeatability.
Whirlpool commented that, if needed,
the condenser unit should be cleaned
prior to the first test run so it does not
need to be cleaned during the test
procedure. (Whirlpool, No. 27 at p. 4)
ALS also commented in support of
DOE’s proposed amendments regarding
the condenser unit. (ALS, No. 24 at p.
6) AHAM stated that there is no
rationale for the proposed amendment
requiring the condenser unit to remain
in place and not be taken out of the
clothes dryer for any reason between
tests. AHAM commented that DOE
should not include that provision.
However, if it is included, it needs to be
clarified. For example, the test
procedure should state how many test
runs are required. (AHAM, No. 31 at p.
7)
DOE agrees that the condenser unit
may be cleaned prior to the first test
run. DOE also believes that requiring the
condenser unit to remain in place
between tests ensures repeatability. As
discussed later in this section, DOE is
not amending the test procedure to
require multiple test cycles. Because
multiple test cycles may be necessary
under certain conditions, however, such
as a requirement that if the
condensation box is full and must be
emptied, the test would be re-run from
the beginning. For these reasons, DOE
amends section 2.1 of the clothes dryer
test procedure regarding installation to
add the provision the condenser unit of
the dryer must remain in place and not
be taken out of the dryer between tests,
as proposed in the June 2010 TP
SNOPR. 75 FR 37594, 37623 (June 29,
2010).
DOE stated in the June 2010 TP
SNOPR that the methodology in the
current DOE test procedure for
conventional (vented) clothes dryers can
be applied to ventless clothes dryers,
with a number of clarifications added.
Based on starting test conditions
detailed in EN Standard 61121 (section
9.1) and Whirlpool’s proposed
amendments, DOE proposed to revise
section 2.8 to provide a consistent and
repeatable approach for ventless clothes
dryers. 75 FR 37594, 37623 (June 29,
2010). DOE noted that this section,
which addresses clothes dryer
preconditioning, currently requires that
before any test cycle is initiated the
clothes dryer must be operated without
a test load in the non-heat mode for 15
minutes or until the discharge air
temperature varies less than 1 °F during
a period of 10 minutes, whichever is
longer. Because a ventless clothes dryer
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does not have discharge air for which
the temperature can be measured, DOE
proposed in the June 2010 TP SNOPR to
revise this section. The revision would
require that, for ventless clothes dryers,
the steady-state temperature must be
equal to the ambient room temperature
specified by section 2.2 of the existing
DOE clothes dryer test procedure before
the start of all test runs. This could be
done by leaving the machine at ambient
room conditions for at least 12 hours but
not more than 36 hours between tests.
DOE also proposed to revise section 2.8,
‘‘Test loads,’’ of the DOE clothes dryer
test procedure to add a qualification to
the procedure for pre-conditioning that
it applies only to vented clothes dryers.
Id.
AHAM commented at the public
meeting that DOE should remove the
clause specifying a maximum time
between tests because it did not have
supporting information to define a
maximum time between tests. (AHAM,
Public Meeting Transcript, No. 20 at p.
120) AHAM later provided written
comments revising these initial
statements. It stated it supported the
revisions to section 2.8 of the DOE test
procedure proposed in the June 2010 TP
SNOPR, including the specification that
steady-state temperature for ventless
clothes dryers may be achieved by
leaving the machine at ambient room
temperature between tests for at least 12
hours, but not more than 36 hours.
(AHAM, No. 31 at pp. 7–8) Whirlpool
and ALS also supported the revisions to
section 2.8 of the DOE test procedure
proposed in the June 2010 TP SNOPR.
(Whirlpool, No. 27 at p. 4, ALS, No. 24
at p. 6) BSH questioned what method or
procedure might be used to get the
clothes dryer back to a testable state
after a 36-hour break in testing. BSH
also commented that, occasionally,
there are breaks in testing that are longer
than a day and a half; some breaks may
last weeks. (BSH, Public Meeting
Transcript, No. 20 at p. 119) DOE is not
aware of any data providing a rationale
for this 36-hour maximum time limit for
leaving the machine at ambient room
temperature between tests to achieve
steady-state temperature. As a result,
DOE amends section 2.8 of the clothes
dryer test procedure regarding clothes
dryer preconditioning to include the
revisions proposed in the June 2010 TP
SNOPR, as presented above, but without
the 36-hour maximum time limit for
leaving the machine at room ambient
conditions for ventless clothes dryer
preconditioning.
AHAM also commented that DOE
should to insert the word ‘‘machine’’
before temperature when describing the
machine steady-state requirements for
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ventless clothes dryers. (AHAM, Public
Meeting Transcript, No. 20 at pp. 117–
118) AHAM stated that for a
manufacturer running back-to-back
tests, waiting 12 hours between tests is
a significant test burden. AHAM
suggested replacing the word ‘‘can’’ with
‘‘may’’ regarding the 12-hour
requirement to allow manufacturers to
reach the ambient room temperature by
some other means of cooling the
machine, such as a fan or portable air
conditioner. (AHAM, Public Meeting
Transcript, No. 20 at p. 118) BSH
commented that because ventless
clothes dryers do not discharge air there
needs to be a method for determining
steady state other than monitoring the
discharge air temperature. (BSH, Public
Meeting Transcript, No. 20 at pp. 129–
130)
DOE agrees with AHAM’s comments
and accepts the clarifications that the
steady-state ‘‘machine’’ temperature
must be equal to ambient room
temperature. It also agrees that an
additional note should clarify that this
‘‘may’’ be done by leaving the machine
at ambient room conditions for at least
12 hours between tests. Thus, using
other means to achieve a steady-state
machine temperature would be
acceptable under the test procedure
provisions. In response to the comments
by BSH, DOE believes that the steadystate ‘‘machine’’ temperature clarifies
that the temperature of the actual
machine itself should be monitored. For
these reasons, DOE adopts the
amendments to section 2.8 of the DOE
clothes dryer test procedure for clothes
dryer preconditioning proposed in the
June 2010 TP SNOPR, with the
additional clarifications discussed
above.
Relatedly, DOE stated in the June
2010 TP SNOPR that it agrees with the
provisions in section 9.2.2 of EN
Standard 61121 and Whirlpool’s
proposed amendments. These specify
that the first cycle after a period of nonoperation longer than 36 hours shall not
be used for evaluation, and that,
between test cycles, the door of the
clothes dryer shall be closed except for
loading (and unloading). DOE noted that
the first requirement makes the first test
run on an unused (dry) ventless clothes
dryer invalid, and the results from it
could not be used for the energy
efficiency calculations. DOE proposed
in the June 2010 TP SNOPR to
incorporate these provisions into
section 3.3 of the DOE clothes dryer test
procedure. 75 FR 37594, 37623–24 (June
29, 2010).
AHAM, Whirlpool, and ALS
commented in support of the proposed
requirements that after 36 hours of non-
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1007
operation, the first test run is not valid
and that the door remain closed
between tests except for loading and
unloading. They felt these requirements
would enhance repeatability. (AHAM,
No. 31 at p. 8; Whirlpool, No. 27 at
p. 4; ALS, No. 24 at p. 6) DOE is not
aware of any data providing a rationale
for why the first test run after a period
of non-operation of 36 hours would not
be valid. As a result, DOE is not
adopting amendments that specify the
first cycle after a period of nonoperation longer than 36 hours shall not
be used for evaluation. In the absence of
comments objecting to the latter
proposal, DOE adopts the amendment to
the clothes dryer test procedure that,
between test cycles, the door of the
tumble dryer shall be closed except for
loading (and unloading), as proposed in
the June 2010 TP SNOPR. 75 FR 37594,
37623–24 (June 29, 2010).
DOE noted in the June 2010 TP
SNOPR that section 9.2.1 of EN
Standard 61121 requires that at least
five valid test cycles be performed and
the results averaged. DOE’s clothes
dryer test procedure does not specify
multiple test cycles to obtain the
representative EF, and DOE is not aware
of data suggesting that test-to-test
variation is sufficient to warrant a
requirement for more than one test
cycle. Therefore, DOE did not propose
amendments addressing the number of
valid test cycles in the June 2010 TP
SNOPR. 75 FR 37624.
ALS supported DOE’s
recommendation to require only one test
cycle for a valid clothes dryer test
because there is no evidence that
additional tests are warranted, and
additional tests would add burden to
manufacturers and test labs, without
any corresponding benefit. (ALS, No. 24
at p. 6) ALS further commented that if
condensing clothes dryers have a
genuine need to run additional test
cycles, ALS could support such a
requirement limited to condensing
clothes dryers only. (ALS, No. 24 at p.
6) AHAM supported a requirement for
more than one clothes dryer test cycle,
but stated that the number of test cycles
should not be so high as to create a test
burden. AHAM stated that it would
offer to assist DOE in determining the
appropriate number of cycles. AHAM
commented that increasing the number
of test cycles would increase the
repeatability and reproducibility of the
test. AHAM stated that the age of the
test cloth during any given test was a
source of inherent variability that could
be accounted for by introducing a
standard deviation into the related
energy use calculations. AHAM
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
commented that accounting for
variability is especially critical as
regulatory bodies move toward
requiring third-party verification, as the
various test labs must be capable of
reproducing results. (AHAM, No. 31 at
p. 8) Whirlpool recommended that each
unit or model be tested three times and
the results averaged to account for testto-test variation. (Whirlpool, No. 27 at
p. 4) The California Utilities/NRDC also
commented that it would be more
accurate, and good practice, to require
multiple clothes dryer tests, but that
they cannot provide any data at this
time to indicate that doing so would
greatly reduce test-to-test variation.
(California Utilities/NRDC, No. 33 at
p. 4)
As discussed above, DOE is not aware
of any data indicating that the test-totest variation is sufficient to warrant a
requirement for more than one test cycle
and the averaging of results. DOE is also
unaware of any data suggesting that
variability in the age of the test cloth
increases the test-to-test variation of
measured results for the clothes dryer
test procedure. In addition, DOE
conducted limited testing to evaluate
the repeatability and reproducibility of
the amended test procedure in today’s
final rule. As shown below in Table
III.10, the test-to-test variation ranged
from 0 percent to 2.7 percent, with an
average of 0.9 percent. For these
reasons, DOE is not amending the test
procedure in today’s final rule to require
multiple test cycles. DOE would be
open to considering such amendments
in a future rulemaking if such data is
made available showing that test-to-test
variation is large enough to warrant
multiple test cycles.
TABLE III.10—DOE REPEATABILITY TESTING FOR AMENDED CLOTHES DRYER TEST PROCEDURE
Average EF lb/kWh
Test-to-test
variation
%
Test unit
Test 1
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Vented Electric Standard:
Unit 1 ........................................................................................................
Unit 2 ........................................................................................................
Unit 3 ........................................................................................................
Unit 4 ........................................................................................................
Unit 5 ........................................................................................................
Unit 6 ........................................................................................................
Vented Gas:
Unit 7 ........................................................................................................
Unit 8 ........................................................................................................
Unit 9 ........................................................................................................
Unit 11 ......................................................................................................
Vented Electric Compact (240V):
Unit 13 ......................................................................................................
Vented Electric Compact (120V):
Unit 14 ......................................................................................................
Ventless Electric Compact (240V):
Unit 15 ......................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ......................................................................................................
Unit 17 ......................................................................................................
BSH commented that if DOE is
proposing single tests rather than
multiple tests with results averaged,
many of the multiple test requirements,
such as those for not removing a
condenser or specifying a time period
between tests, are irrelevant. BSH
commented that if DOE decides to
require multiple tests, it must define a
set of test runs, and the condenser must
be allowed to be removed and cleaned.
Otherwise, the total number of test runs
on a particular clothes dryer would be
limited. (BSH, Public Meeting
Transcript, No. 20 at p. 122) ACEEE
commented that it is possible that if
only one test cycle is required and the
unit fails that test, more tests would
need to be run on that unit. Therefore,
provisions concerning multiple cycles
would be needed. (ACEEE, Public
Meeting Transcript, No. 20 at pp. 122–
123) AHAM commented that the DOE
test procedure does not have particular
requirements for multiple test cycles,
but in the general CFR there are
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Test 2
3.67
3.77
3.84
3.92
4.01
3.74
3.70
3.77
3.81
3.92
3.95
3.71
3.71
........................
........................
........................
3.93
3.71
1.1
0.0
0.8
0.0
2.0
0.8
3.36
3.38
3.47
3.52
3.36
3.42
3.38
3.49
........................
........................
........................
........................
0.0
1.2
2.7
0.9
3.36
3.35
3.35
0.3
3.74
3.74
........................
0.0
2.71
2.66
2.70
1.9
2.26
2.76
2.27
2.74
........................
2.78
0.4
1.5
requirements for the manufacturer to
obtain repeatable and verifiable results.
AHAM commented that DOE does not
want to specify a minimum number of
tests required, but a manufacturer may
need to modify the condenser if they
want or need to run multiple tests.
(AHAM, Public Meeting Transcript, No.
20 at pp. 123–124) BSH further
commented that if a manufacturer
decides it is only comfortable running 5
or 10 tests, it would be reasonable to
leave the condenser in place for that
number of tests. (BSH, Public Meeting
Transcript, No. 20 at p. 124)
As discussed above, multiple test runs
may be necessary in cases when a test
run is considered invalid, such as when
the drying cycle stops because the
condensation box is full of water and
the test must be re-run. Because there
are cases in which multiple test cycles
may be required, DOE adopts the
amendments discussed above related to
multiple test requirements (that is, that
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Test 3
the condenser not be removed and that
the door be kept closed between tests).
DOE did not propose to measure the
water consumption of ventless clothes
dryers in the June 2010 TP SNOPR. 75
FR 37594, 37624 (June 29, 2010). ALS
objected to DOE’s proposal to not
measure the water consumption of
ventless ‘‘condensing’’ clothes dryers.
ALS believes that if all clothes washers
are required to meet strict standards
regarding the amount of water
consumed in a product that requires
water to provide consumers with
adequate utility, then a condensing
clothes dryer must account for its water
consumption as well. ALS commented
that DOE needs to at least require that
water consumption be measured and
reported so that data is available for any
future consideration of minimum
standards for the water consumption of
a condensing clothes dryer. (ALS, No.
24 at p. 6) General Electric (GE)
commented that it does not have data on
how much water is consumed by
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ventless clothes dryers that utilize an
external water source to condense
moisture from the dryer steam air. GE
believes, however, that water
consumption could be easily measured
by placing a calibrated flow meter on
the water source. GE believes it would
not be burdensome to perform the
measurement and that such
measurements would provide a more
meaningful, robust measure of water
use. (GE, No. 32 at p. 1) Whirlpool
commented that it is not aware of any
ventless clothes dryers in the United
States that utilize water in the
condensing process, and that should
such products exist, their market share
would be so small as to be
immeasurable. Whirlpool commented
that it does not believe that measuring
water consumption is relevant or
necessary. (Whirlpool, No. 27 at p. 4)
DOE notes that EPCA allows the
establishment of water use metrics, but
only for certain products. EPCA defines
‘‘energy conservation standard’’ in
relevant part as:
(A) A performance standard which
prescribes a minimum level of energy
efficiency or a maximum quantity of
energy use, or, in the case of
showerheads, faucets, water closets, and
urinals, water use, for a covered
product, determined in accordance with
test procedures prescribed under section
6293 of this title; (42 U.S.C. 6291(6)(A))
In addition, DOE regulates the water use
of clothes washers based on the water
conservation standards set by Congress
in 42 U.S.C. 6295(g)(9).
Clothes dryers do not belong to the
group of products specified by EPCA for
which DOE can set a water use
standard. As a result, DOE is not
amending the clothes dryer test
procedure in today’s final rule to
establish a water use metric or to
include a requirement to measure the
water consumption for ventless
condensing clothes dryers.
DOE also stated that the results from
DOE’s tests at an independent
laboratory are representative of the
repeatability of results that would be
observed using the testing procedures
proposed in the June 2010 TP SNOPR.
75 FR 37594, 37624 (June 29, 2010).
Although DOE’s tests were conducted
using the alternate test procedure that
provided separate definitions for a
‘‘conventional clothes dryer’’ and a
‘‘condensing clothes dryer’’ and that
simply required use of the exhaust
simulator only for vented clothes dryers,
DOE stated that the additional
clarifications proposed in the June 2010
TP SNOPR would not significantly
affect these testing results because they
do not affect the the test cycle
measurement method. Therefore, DOE
stated that the amendments to the test
procedure for ventless clothes dryers
proposed in the June 2010 TP SNOPR
1009
would produce accurate and repeatable
measurements of EF. Id.
To further support its assertion, after
issuance of the June 2010 TP SNOPR,
DOE conducted three identical tests on
one ventless electric compact (240V)
clothes dryer and two identical tests on
one ventless electric combination
washer/dryer to evaluate the
repeatability of the proposed test
procedure for ventless clothes dryers.
Testing results, presented in Table
III.11, showed 0.8-percent and 3.5percent variation in EF from test to test
for the ventless electric compact (240V)
and ventless electric combination
washer-dryer, respectively. The test-totest variation shown below is
comparable to the test-to-test variation
shown in Table III.10 (conducted
according to the alternate test procedure
that provided separate definitions for a
‘‘conventional clothes dryer’’ and a
‘‘condensing clothes dryer’’ and that
simply required use of the exhaust
simulator only for vented clothes
dryers). The slightly greater test-to-test
variation observed in Table III.11 may
be attributed to other test procedure
tolerances, such as the allowable ranges
in ambient temperature and relative
humidity. DOE continues to believe that
the amendments adopting in today’s
final rule for ventless clothes dryers
produce accurate and repeatable
measurements of EF.
TABLE III.11—DOE REPEATABILITY TESTING FOR VENTLESS CLOTHES DRYER AMENDMENTS
EF lb/kWh
Test unit
Test 1
Ventless Electric Compact (240V) (Unit 15) ....................................................
Ventless Electric Combo Washer-Dryer (Unit 16) ...........................................
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4. Detergent Specifications for Clothes
Dryer Test Cloth Preconditioning
Section 2.6.3 of the current DOE
clothes dryer test procedure specifies
that the test cloth be preconditioned by
performing a 10-minute wash cycle in a
standard clothes washer using AHAM
Standard Test Detergent IIA. 10 CFR
part 430, subpart B, appendix D, section
2.6.3. This detergent is obsolete and no
longer available from AHAM or other
suppliers. The current AHAM standard
detergent is identified as AHAM
standard test detergent Formula 3.
Because AHAM Standard detergent IIA
is no longer available to manufacturers,
DOE proposed in the June 2010 TP
SNOPR to amend section 2.6.3 of the
clothes dryer test procedure to specify
the use of AHAM standard test
detergent Formula 3 in test cloth
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Test 2
2.36
2.05
preconditioning. 75 FR 37594, 37624
(June 29, 2010).
Clothes washer tests that DOE
conducted with AHAM standard test
detergent Formula 3 suggest the dosage
specified in section 2.6.3(2) of the DOE
clothes dryer test procedure for AHAM
Standard detergent IIA (6.0 grams (g) per
gallon of water) may no longer be
appropriate. This is because at the end
of clothes washer test cloth
preconditioning, which specifies the
same dosage, undissolved clumps of
detergent were observed in the cloth
load. Further, DOE conducted extractor
tests that indicate that detergent dosage
impacts RMC measurements by as much
as several percent.
AHAM’s clothes dryer test procedure,
AHAM HLD–1–2009, specifies a
standard test detergent Formula 3
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Test 3
2.38
1.98
2.37
........................
Test-to-test
variation
%
0.8
3.5
dosage of 27 g + 4.0 g/lb of base test load
for test cloth pre-treatment. For DOE’s
clothes dryer test cloth preconditioning,
the current test procedure specifies that
clothes washer water fill level be set to
the maximum level, regardless of test
load size. In the June 2010 TP SNOPR,
DOE proposed to amend the test load
size for standard-size clothes dryers to
8.45 lb ± .085 lb (see section III.C.5.c.),
which would result in a detergent
dosage of AHAM standard test detergent
Formula 3 of 60.8 g. DOE stated that the
detergent concentration should be set by
the pounds of test cloth in this standardsize test load because this load is more
closely matched to the maximum water
fill level than is the compact-size test
load (3.0 lb ± .03 lb). For
preconditioning a compact-size test
load, DOE proposed that the same
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
detergent dosage be specified because
the water fill level would remain the
same as for the larger load, resulting in
the same concentration of the water/
detergent mixture. 75 FR 37594, 37624
(June 29, 2010).
To address the problems associated
with the current dosage specification in
the DOE clothes dryer test procedure,
DOE proposed in the June 2010 TP
SNOPR to amend section 2.6.3 of the
clothes dryer test procedure. The
amendment would require 60.8 g of
AHAM standard test detergent Formula
3 be used to precondition test cloth. Id.
AHAM, Whirlpool, and ALS
supported DOE’s proposed detergent
specifications. (AHAM, No. 31 at p. 8;
Whirlpool, No. 27 at p. 4; ALS, No. 24
at p. 6) Whirlpool also strongly
recommended that the test cloth be
preconditioned in the same way when
used in tests for both clothes washers
and clothes dryers. This would enable
test cloth with common characteristics
to be interchanged between the two
products, which would result in
increased repeatability. (Whirlpool, No.
27 at p. 4) For the reasons stated above
and in the absence of comments
objecting to this proposal, DOE amends
its clothes dryer test procedure in
today’s final rule to revise the detergent
specifications for test cloth
preconditioning as proposed in the June
2010 TP SNOPR. 75 FR 37594, 37624
(June 29, 2010). DOE will address
detergent specifications for test cloth
preconditioning for the clothes washer
test procedure in the test procedure
rulemaking for that product.
5. Changes To Reflect Current Usage
Patterns and Capabilities
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a. Clothes Dryer Number of Annual
Cycles
As noted above, DOE most recently
amended its test procedure for
residential clothes dryers in a final rule
published in the Federal Register on
May 19, 1981. 46 FR 27324. Although
DOE has updated its test procedure for
residential clothes washers since that
time,33 it has not updated its residential
clothes dryer test procedure. In the
revised residential clothes washer test
procedure, the average number of
annual use cycles was revised to reflect
current (at the time) consumer use
patterns. DOE noted in the October 2007
Framework Document that the average
number of clothes dryer use cycles
assumed in the revised clothes washer
test procedure is different from the
number of use cycles in the clothes
33 See
62 FR 45484, 45498 (Aug. 27, 1997).
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dryer test procedure. (Framework
Document, STD No. 1 at p. 4)
In the June 2010 TP SNOPR, DOE
reviewed available data to determine the
number of annual clothes dryer use
cycles so that it could amend its test
procedure to accurately reflect current
consumer usage habits. DOE reviewed
the 2004 California Statewide RASS,
which surveyed appliance product
usage patterns, including clothes
dryers.34 The study surveyed 7,686
households between 2002 and 2003,
asking the question ‘‘how many loads of
clothes do you dry in your clothes dryer
during a typical week?’’ For the 6,790 of
these households that said they owned
a clothes dryer, average usage was 4.69
loads per week, or approximately 244
loads per year. Because this study
provides only a limited dataset,
however, DOE stated in the June 2010
TP SNOPR that it did not intend to rely
only on this data to determine an
appropriate number of annual use
cycles for the clothes dryer test
procedure. 75 FR 37594, 37625 (June 29,
2010).
In the June 2010 TP SNOPR, DOE also
reviewed data from the 2005 RECS to
determine the annual usage of clothes
dryers. RECS is a national sample
survey of housing units that collects
statistical information on the
consumption of and expenditures for
energy in housing units along with data
on energy-related characteristics of the
housing units and occupants. RECS
provides enough information to
establish the type (that is, product class)
of clothes dryer used in each household,
the age of the product, and an estimate
of the household’s annual energy
consumption attributable to clothes
dryers. DOE estimated the number of
clothes dryer cycles per year for each
sample home using data given by RECS
on the number of laundry loads (clothes
washer cycles) washed per week and the
frequency of clothes dryer use. Based on
its analysis of RECS data, DOE
estimated the clothes dryer usage factor
(the percentage of washer loads dried in
a clothes dryer) to be 91 percent and the
calculated average usage to be 283
cycles per year for all product classes of
clothes dryers. DOE also noted that the
RECS data shows that the number of
clothes washer and clothes dryer cycles
has been decreasing steadily for a
number of years to the extent that a
historical trend has been established.
Because this dataset is more extensive
than that of the RASS, DOE believes
these numbers are more representative
34 KEMA, Inc. op. cit. p. 118. For more
information visit: https://www.energy.ca.gov/
appliances/rass/.
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of annual usage patterns. Therefore,
DOE proposed in the June 2010 TP
SNOPR to amend the number of annual
use cycles in its test procedure to 283
cycles for all product classes of clothes
dryers. 75 FR 37594, 37625 (June 29,
2010).
AHAM supported DOE’s proposal to
amend the number of annual use cycles
to 283 cycles for all product classes of
clothes dryers. AHAM stated, however,
that it continues to oppose using 2005
RECS data to support this change
without verification of the RECS
estimates. AHAM commented that the
results from a recent survey by Procter
& Gamble (P&G) indicated that 5.2 to
5.35 loads per household with a clothes
dryer are dried per week, or 279 clothes
dryer loads per year. AHAM noted this
number is similar to that derived from
the 2005 RECS data and therefore, it
supported the change in the number of
clothes dryer annual use cycles to 283.
(AHAM, No. 31 at p. 8; AHAM, Public
Meeting Transcript, No. 20 at p. 137)
The California Utilities/NRDC, the
Joint Petitioners, Whirlpool, and ALS
also commented in support of DOE’s
proposal of 283 annual use cycles.
(California Utilities/NRDC, No. 33 at p.
5; Joint Petitioners, No. 30 at p. 7;
Whirlpool, No. 27 at p. 4; ALS, No. 24
at p. 7) The California Utilities/NRDC
noted that the California 2005 RASS,
which indicates a weighted-average for
California of 235 annual use cycles is
fairly consistent with DOE’s number
and with the overall trend of decreasing
yearly use cycles. (California Utilities/
NRDC, No. 33 at
p. 5) Whirlpool also noted that in its
April 26, 2010 comments that it
recommended 288 cycles per year,
which is essentially consistent with
DOE’s recommendation of 283 cycles
per year. (Whirlpool, No. 27 at p. 4)
DOE notes there is close agreement
between the estimates provided by
interested parties and DOE’s estimate
based on the data reviewed by DOE, and
there were no comments objecting to its
proposal. Therefore, DOE amends the
clothes dryer test procedure to change
the number of annual use cycles to 283
cycles for all product classes of clothes
dryers.
b. Clothes Dryer Initial Remaining
Moisture Content
In the revised residential clothes
washer test procedure, a new parameter,
the RMC of the test cloth, was
introduced. 68 FR 62198, 62199
(October 31, 2003). The clothes washer
RMC is the ratio of the weight of water
contained within the test load at the
completion of the clothes washer energy
test cycle to the bone-dry weight of the
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test load, expressed as a percent.
Correspondingly, the initial RMC of a
clothes load being dried is a function of
RMC at the end of a clothes washer
cycle. The current DOE clothes dryer
test procedure specifies an initial RMC
of 70 ± 3.5 percent. Similar to the
discussion above of the average number
of use cycles per year, the RMC of
typical clothes loads in the residential
clothes washer test procedure should be
consistent with values defined in the
clothes dryer test procedure. For the
reasons explained below, however, DOE
believes that the initial RMC in the
clothes dryer test procedure may not
reflect typical RMCs of actual clothes
dryer loads.
DOE notes that the revision to the
clothes washer test procedure changed
the clothes washer energy conservation
standards metric to a modified energy
factor (MEF). This established a method
for measuring the RMC for clothes
washers. This RMC is then used to
estimate the energy required by a
clothes dryer to dry the clothes load.
This estimate is then factored in to the
calculation of MEF to account for
clothes washers that reduce the
estimated energy required to dry the
clothes load in a clothes dryer. (10 CFR
part 430, subpart B, appendix J1, section
4.3) Since the clothes dryer test
procedure was last amended in 1981
(46 FR 27324 (May 19, 1981)), average
clothes washer RMC has decreased due
to the introduction of higher efficiency
models with higher final spin speeds.
Therefore, while clothes dryer energy
use has decreased with the lower RMC,
clothes washer energy use has increased
somewhat to achieve the higher spin
speeds. This energy use is accounted for
in the residential clothes washer energy
conservation standards rulemaking. In
the clothes washer test procedure final
rule published in the Federal Register
on January 12, 2001, DOE estimated
RMCs at specific efficiency levels. 66 FR
3314. For the residential clothes washer
standard which became effective
January 1, 2007 (1.26 MEF), DOE
estimated a weighted-average RMC of 56
percent.
As discussed in section I, the EF for
clothes dryers is determined by
measuring the total energy required to
dry a standard test load of laundry to a
‘‘bone dry’’ state. If today’s clothes dryer
loads have initial RMCs lower than the
nominal 70 percent specified in the
existing DOE clothes dryer test
procedure, revisions to the test
procedure to reflect more realistic (that
is, lower) RMCs would result in the
current EF rating increasing for a given
clothes dryer. This is because the
clothes dryer would have less water to
remove.
As part of the preliminary analyses for
the residential clothes dryer energy
conservation standards rulemaking,
DOE used a distribution of values for
1011
models listed in the December 12, 2008
CEC product database to estimate the
RMC of clothes washers. For products
for which the RMC was listed, DOE
noted in the June 2010 TP SNOPR that
the RMC values ranged from 30 percent
to 61 percent, with an average of 46
percent. 75 FR 37594, 37626 (June 29,
2010).
As part of the October 2007
Framework Document, DOE requested
data from AHAM showing the
shipments of residential clothes washers
for which RMC was reported, along with
shipment-weighted RMC (See Table
III.12). These data sets, each including
disaggregated data for front-loading and
top-loading clothes washers, as well as
reported overall values for all units,
provide insight into what initial clothes
dryer RMC would be most
representative of current residential
clothes washers. As noted above,
however, AHAM indicated that the data
contain only shipments for which the
RMC was reported, and thus the total
will not be equal to actual shipments
reported for 2000–2008. The data
indicate that RMC has been decreasing
consistently, from about 54 percent in
2000 to 47 percent in 2008. The data
also suggest that the initial RMC of
nominally 70 percent in the DOE
clothes dryer test procedure is greater
than the current shipment-weighted
residential clothes washer average RMC.
TABLE III.12—AHAM SHIPMENT-WEIGHTED CLOTHES WASHER RMC DATA SUBMITTAL 35
Clothes washer shipments for which RMC
was reported
Shipment-weighted RMC
(%)
Year
Frontloading
kgrant on DSKGBLS3C1PROD with BILLS
2000
2001
2002
2003
2004
2005
2006
2007
2008
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
.................................................................................
Based on its analysis of the shipmentweighted RMC data submitted by
AHAM, as well as its own review of the
CEC residential clothes washer
database, DOE stated in the June 2010
TP SNOPR that an initial RMC of 47
percent is representative of current
35 AHAM, 2009. AHAM Weighted RMC for Front
Load and Top Load Units, 2000–2008—DOE
Clothes Dryer Rulemaking, Secondary Data
Request. July 7, 2009. Docket No. EE–2007–BT–
STD–0010, Comment Number 18.
VerDate Mar<15>2010
15:19 Jan 05, 2011
Jkt 223001
232,714
235,989
280,667
351,411
1,179,813
1,563,108
1,851,218
1,973,825
2,043,024
Top-loading
686,440
473,629
529,265
1,676,877
5,270,285
5,394,511
5,628,279
5,371,142
4,492,059
919,154
709,618
809,932
2,028,288
6,450,098
6,957,619
7,479,497
7,344,967
6,535,083
residential clothes dryer initial test load
characteristics. Therefore, DOE
proposed to amend section 2.7, ‘‘Test
loads,’’ of the clothes dryer test
procedure to require the initial RMC be
changed from 70 ± 3.5 percent to 47
percent. DOE further proposed to
eliminate the ± 3.5 percent allowable
range in RMC. This is because the
proposed amendments to the DOE
clothes dryer test procedure for
automatic cycle termination, detailed in
section III.C.2, would require that the
PO 00000
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Fmt 4701
Sfmt 4700
Frontloading
Total
43.6
41.3
41.5
43.1
42.2
40.8
39.3
38.3
38.1
Top-loading
57.4
57.7
58.1
54.5
52.8
52.7
51.4
51.4
51.0
Total
53.9
52.2
52.3
52.5
50.9
50.1
48.4
47.8
47.0
test load be initially prepared to
between 42- and 47-percent RMC. The
proposed amendments would also
require final adjustments be made to the
RMC to achieve 47-percent ± 0.33percent RMC to account for over-drying
energy consumption. 75 FR 37594,
37627 (June 29, 2010).
In the June 2010 TP SNOPR, DOE
proposed that if it does not adopt the
proposed amendments for testing
automatic cycle termination, but adopts
only these aforementioned proposed
E:\FR\FM\06JAR2.SGM
06JAR2
1012
Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
amendments to change the initial RMC,
it could specify an initial RMC of 47 ±
3.5 percent. In that case, the tolerance
of ± 3.5 percent on the nominal initial
RMC, as currently specified in DOE’s
test procedure, would allow the same
flexibility in test cloth preparation as is
currently allowed. 75 FR 37594, 37627
(June 29, 2010).
DOE also noted in the June 2010 TP
SNOPR that the current test procedure
contains a provision in the calculation
of per-cycle energy consumption
intended to normalize EF by the
reduction in RMC over the course of the
drying cycle. A scaling factor of 66 is
applied, representative of the percentage
change from the nominal initial RMC of
70 percent to the nominal ending RMC
of 4 percent. DOE noted, however, that
the proposed changes to account for
automatic cycle termination, as
presented above in section III.C.2,
would require amending the
calculations for the per-cycle energy
consumption to remove the need for this
scaling factor. Therefore, DOE did not
propose to amend the scaling factor in
the June 2010 TP SNOPR. 75 FR 37594,
37627 (June 29, 2010). DOE proposed
that if it does not adopt the proposed
amendments for testing automatic cycle
termination, but adopts only these
aforementioned proposed amendments
to change the initial RMC, it could
change the scaling factor to 43 to reflect
a starting RMC of 47 percent. Id.
AHAM, the California Utilities/NRDC,
and the Joint Petitioners all supported
an initial RMC of 47 percent. (AHAM,
No. 31 at p. 9; California Utilities/
NRDC, No. 33 at p. 5; Joint Petitioners,
No. 30, at p. 7) AHAM provided data to
support this approach in their April 26,
2010 comments. (AHAM, No. 31 at p. 9)
Whirlpool also commented that DOE’s
proposal of 47 ± 1 percent RMC is
consistent with its recommendation
from its April 26, 2010 comments.
(Whirlpool, No. 27 at p. 4)
ALS objected to DOE’s proposal to
utilize 47-percent initial RMC. ALS
commented that the current clothes
dryer test procedure uses ‘‘raw’’ noncorrection factored RMC values, unlike
the values DOE used to arrive at the
national average of 47-percent RMC.
The data DOE used was based on
shipment-weighted average clothes
washer data supplied by AHAM that
had a correction factor applied to
account for extraction. (ALS, No. 24 at
p. 7; ALS, Public Meeting Transcript,
No. 20 at p. 141) ALS commented that
DOE should be using raw RMC values
from the clothes washer, because the
current clothes dryer test uses raw
values and there is a significant
difference between ‘‘raw’’ RMC values
and ‘‘correction-factored’’ RMC values.
ALS stated that it conducted tests on
front-load washers (both its own and
those of its competition) that resulted in
raw RMC values of around 50 percent,
compared to the 41-percent RMC
derived when the correction factor is
applied. This is a difference of 9 RMC
percentage points, which is a 18-percent
relative difference. ALS added that it is
apparent that if ‘‘raw’’ values of washer
RMC were analyzed by DOE, the
national average would be closer to 53–
55 percent. ALS acknowledged that no
database exists of ‘‘raw’’ shipmentweighted average RMC values for
clothes washers. ALS suggested DOE
perform limited clothes washer tests to
confirm the ALS results regarding the
‘‘raw’’ versus ‘‘correction-factored’’ RMC
values, and adjust the proposed 47percent value to align more closely to
the ALS-suggested value of 53 percent.
(ALS, No. 24 at p. 7) ALS also
commented that manufacturers prefer to
utilize their own production frontloading clothes washers to prepare test
loads per the DOE clothes dryer test
procedure. However, they would find it
more difficult to achieve DOE’s
proposed 47-percent RMC when the
front-loader in their labs can only
achieve raw values at 50-percent RMC
in default DOE test program cycles.
(ALS, No. 24 at p. 7) ALS did not
recommend adding in correction factors
to the clothes dryer test procedure to
raise the initial RMC higher to reflect
the uncorrected value. (ALS, Public
Meeting Transcript, No. 20 at p. 143)
DOE first notes that it proposed an
initial RMC of 47 percent ± 3.5 percent,
not ±1 percent as commented by
Whirlpool. DOE agrees with ALS that
the clothes dryer test procedure should
be using a ‘‘raw’’ uncorrected RMC value
and not the corrected RMC values in the
data submitted by AHAM. DOE
understands that in the clothes washer
test procedure, an RMC correction factor
curve is applied to account for the
different extraction rates of different test
cloth lots in order to calculate a
corrected RMC value. The correction
factor curve uses the following equation:
RMCcorrected = A × RMCmeasured + B, where
RMCmeasured is the measured RMC after
the clothes washer spin cycle and A and
B are coefficients based on extraction
testing using a linear least-squares fit to
relate the standard RMC to the
measured extraction RMC value. (The
standard RMC is provided in table
2.6.6.1 of the clothes washer test
procedure.) DOE notes that in 2008, the
latest year for which shipment-weighted
average corrected RMC values were
provided in the AHAM data, the most
recent test cloth lot was lot 16. DOE
acknowledges, however, that
manufacturers and testing labs were
likely using previous test cloth lots for
the RMC values reported in the AHAM
data. For this reason, DOE estimated the
2008 uncorrected RMC value by using
the RMC correction factor curves from
lots 12 through 16 and averaging the
results. As shown in Table III.13, the
results showed an average uncorrected
RMC value of 57.5 percent.
TABLE III.13—DOE CLOTHES WASHER TEST PROCEDURE TEST CLOTH LOT RMC CORRECTION FACTOR DATA
Lot #
kgrant on DSKGBLS3C1PROD with BILLS
2008 ShipmentWeighted
Average
Corrected RMC
= 47.0%
Coefficient A
Coefficient B
2008 Shipment-weighted
average uncorrected RMC
(percent)
12
13
14
15
16
Average
0.7165
0.8828
0.8970
0.89904
0.73478
.............................................
0.0505
0.0015
0.0014
-0.04284
0.03174
.............................................
65.5
53.2
52.4
52.3
63.9
57.5
To validate this estimate, DOE
examined the uncorrected RMC data
from tests of 17 residential clothes
washer (9 front-loading and 8 top-
VerDate Mar<15>2010
15:19 Jan 05, 2011
Jkt 223001
loading units) it conducted for the
residential clothes washer energy
conservation standards rulemaking
preliminary analyses. The results from
PO 00000
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Fmt 4701
Sfmt 4700
DOE’s testing are shown below in Table
III.14. Taking the average RMC for each
product class (that is, front-loading and
top-loading) and weighting the average
E:\FR\FM\06JAR2.SGM
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RMCs by the shipments for each
product class resulted in a shipmentweighted average uncorrected RMC of
58.1 percent, which is in close
agreement with the 57.5-percent
uncorrected RMC estimated by DOE
using the RMC correction factor curves.
TABLE III.14—DOE CLOTHES WASHER change the initial RMC to 57.5 percent
TESTING UNCORRECTED RMC RE- ± 3.5 percent. In addition, DOE changes
the scaling factor in the calculation of
SULTS—Continued
Unit 11 ...............................
Unit 12 ...............................
Unit 13 ...............................
Unit 14 ...............................
Unit 15 ...............................
Unit 16 ...............................
Unit 17 ...............................
Shipment-Weighted Average .................................
SULTS
Uncorrected
RMC %
Front-Loading Clothes Washers (2008 Shipments =
3,022,077):
Unit 1 .................................
Unit 2 .................................
Unit 3 .................................
Unit 4 .................................
Unit 5 .................................
Unit 6 .................................
Unit 7 .................................
Unit 8 .................................
Unit 9 .................................
Top-Loading Clothes Washers (2008 Shipments =
5,269,625):
Unit 10 ...............................
Uncorrected
RMC %
Test unit
TABLE III.14—DOE CLOTHES WASHER
TESTING UNCORRECTED RMC RE-
Test unit
1013
94.3
48.4
60.5
65.2
67.1
54.2
50.3
58.1
DOE estimated the uncorrected RMC
value using shipment-weighted average
corrected RMC data submitted by
AHAM and the RMC correction factor
curves for test cloth lots 12 through 16.
Based on that estimate, DOE believes an
initial RMC of 57.5 percent more
accurately represents the moisture
content of a load entering the clothes
dryer after the wash cycle for the
purposes of clothes dryer testing. As a
result, DOE amends the clothes dryer
67.7 test procedure in today’s final rule to
43.7
58.9
55.9
49.3
49.5
38.5
50.7
45.3
45.4
the per-cycle energy consumption that
is intended to normalize EF by the
reduction in RMC over the course of the
drying cycle from a value of 66 to 53.5
(That value is the difference of 57.5percent initial RMC minus 4-percent
nominal final RMC).
DOE tested 13 representative clothes
dryers to evaluate the affect of this
amendment to the initial RMC for
clothes dryer test load preparation on
test repeatability. DOE tested these units
according to the current DOE clothes
dryer test procedure, except that the
initial RMC was changed to 57.5 percent
± 3.5 percent. For the ventless clothes
dryer test units, DOE additionally used
the proposed testing method for ventless
dryers presented in section III.C.3. As
shown below in Table III.15, the test-totest variation ranged from 0.3 percent to
1.8 percent, with an average of 0.9
percent. For this reason, DOE believes
that the amendments to the initial RMC
for clothes dryer test load preparation
produce repeatable test results.
TABLE III.15—DOE REPEATABILITY TESTING FOR 57.5 PERCENT INITIAL RMC
Average EF lb/kWh
Test unit
Test 1
Vented Electric Standard:
Unit 1 ....................................................................................................................................
Unit 3 ....................................................................................................................................
Unit 4 ....................................................................................................................................
Unit 5 ....................................................................................................................................
Unit 6 ....................................................................................................................................
Vented Gas:
Unit 7 ....................................................................................................................................
Unit 8 ....................................................................................................................................
Unit 9 ....................................................................................................................................
Unit 10 ..................................................................................................................................
Unit 11 ..................................................................................................................................
Vented Electric Compact (240V):
Unit 12 ..................................................................................................................................
Unit 13 ..................................................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ..................................................................................................................................
kgrant on DSKGBLS3C1PROD with BILLS
c. Clothes Dryer Test Load Weight
The current DOE clothes dryer test
procedure requires a 7.00 lb ± .07 lb test
load for standard-size clothes dryers and
a 3.00 lb ± .03 lb test load for compactsize clothes dryers. In response to
comments it received on the October
2007 Framework Document, DOE
investigated in the June 2010 TP SNOPR
whether the average test load weight for
standard-size clothes dryers is valid for
use in light of the capacities of the
current generation of clothes washer. 75
FR 37594, 37631 (June 29, 2010).
VerDate Mar<15>2010
15:19 Jan 05, 2011
Jkt 223001
DOE contacted detergent
manufacturers to obtain data on average
residential clothes washer load sizes.
P&G conducted an internal study in
2003 on household laundry habits on a
representative set of the population
across the United States, from which
P&G provided relevant summary data to
DOE for this rulemaking. The clothes
washer load weight data, based on a
sample size of 3367 loads of laundry
from a total of 510 respondents, showed
that the average load size for top-loading
and front-loading clothes washers was
7.2 lb and 8.4 lb, respectively. (P&G, No.
PO 00000
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Fmt 4701
Sfmt 4700
Test 2
Test 3
Test-to-test
variation %
3.68
3.84
3.79
3.93
3.70
3.67
3.81
3.80
3.88
3.71
................
3.82
3.78
3.92
................
0.3
0.8
0.5
1.3
0.3
3.32
3.41
3.23
3.27
3.38
3.32
3.44
3.21
3.31
3.41
3.31
................
3.25
3.28
3.43
0.3
0.9
1.2
1.2
1.5
3.61
3.46
3.62
3.48
3.61
3.42
0.3
1.8
2.35
2.31
2.34
1.7
15 at p. 1) Based on the average
shipment-weighted market share for
top-loading and front-loading clothes
washers between 2000 and 2008 from
data submitted by AHAM (shown in
Table III.12), the shipment-weighted
average clothes washer load size would
be approximately 7.5 lb. DOE stated in
the June 2010 TP SNOPR, however, that
clothes washer capacities were likely to
have increased since the survey was
conducted in 2003. Therefore, DOE
factored into its analysis these capacity
changes to estimate a more current
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average load size. 75 FR 37594, 37631
(June 29, 2010).
Table III.16 shows the trends of the
shipment-weighted average tub volume
for residential clothes washers from
1981 to 2008, based on data from the
AHAM Trends in Energy Efficiency
2008. The shipment-weighted average
tub volume has increased from 2.52 ft3
in 1981 to 3.22 ft3 in 2008.
TABLE III.16—RESIDENTIAL CLOTHES
WASHER SHIPMENT-WEIGHTED AVERAGE TUB VOLUME TRENDS 36
Shipmentweighted
average tub
volume (ft3)
Year
1981
1990
1991
1992
..................
..................
..................
..................
% Change
since 1990
2.52
2.63
2.72
2.71
....................
....................
3.4
3.0
TABLE III.16—RESIDENTIAL CLOTHES
WASHER SHIPMENT-WEIGHTED AVERAGE TUB VOLUME TRENDS 36—
Continued
Shipmentweighted
average tub
volume (ft3)
Year
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
% Change
since 1990
2.71
2.69
2.72
2.80
2.83
2.85
2.89
2.92
2.96
2.96
3.01
3.05
3.08
3.13
3.16
3.0
2.3
3.4
6.5
7.6
8.4
9.9
11.0
12.5
12.5
14.4
16.0
17.2
19.2
20.3
TABLE III.16—RESIDENTIAL CLOTHES
WASHER SHIPMENT-WEIGHTED AVERAGE TUB VOLUME TRENDS 36—
Continued
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
Shipmentweighted
average tub
volume (ft3)
Year
% Change
since 1990
3.22
22.4
2008 ..................
Section 2.7, ‘‘Test Load Sizes,’’ in the
DOE clothes washer test procedure
provides the minimum, maximum, and
average test load size requirements for
the clothes washer test, which are based
on the clothes container capacity. Table
III.17 shows the minimum, maximum,
and average test load sizes for 2.52 ft3
and 3.22 ft3 container capacities
according to Table 5.1 in the DOE
clothes washer test procedure.
TABLE III.17—DOE CLOTHES WASHER TEST LOAD SIZE REQUIREMENTS (FROM TABLE 5.1 OF 10 CFR 430 SUBPART B,
APPENDIX J1)
Minimum
load lb.
Container volume ft3
Maximum
load lb.
3.00
3.00
10.50
13.30
kgrant on DSKGBLS3C1PROD with BILLS
≥ 2.50 to < 2.60 ...................................................................................................................................................
≥ 3.20 to < 3.30 ...................................................................................................................................................
DOE notes that the average load size
in the clothes washer test procedure
increases by about 21 percent when the
container volume increases in capacity,
which DOE believes is the degree to
which container volume impacts clothes
dryer load sizes. Applying this ratio of
average clothes washer test load sizes to
the clothes dryer test load size would
result in an increase from 7.00 lb to 8.45
lb for standard-size clothes dryers
currently available. For these reasons,
DOE proposed to amend the clothes
dryer test load size to 8.45 lb for
standard-size clothes dryers in the June
2010 TP SNOPR. 75 FR 37594, 37632
(June 29, 2010). DOE proposed to amend
the test load size based on the change
in average load size for clothes washers
rather than the maximum load size
because data from the 2005 RECS
indicates that not all clothes that are
washed are machine dried. Therefore,
DOE believes that average clothes
washer load size would be more
representative of clothes dryer load size.
DOE also proposed to maintain the 1percent tolerance in load sizes specified
by the current DOE test procedure for
standard-size clothes dryers (8.45 lb ±
.085 lb). Id.
ALS commented that the clothes
dryer test procedure amendments are
related to the clothes washer test
procedure. It stated that if there are any
changes to the clothes washer test
procedure in an upcoming rulemaking,
especially to the average load size or the
load size chart, the effect of those
changes on the clothes dryer test
procedure must be considered. (ALS,
Public Meeting Transcript, No. 20 at p.
171) DOE recently published a NOPR
proposing amendments to the test
procedure for clothes washers and
welcomes comments on that proposal as
stated in the NOPR. 75 FR 57556
(September 21, 2010). Because DOE has
not published a final rule amending the
clothes washer test procedure, however,
the issue of how any such amendments
might influence conditions for the final
amended clothes dryer test procedure is
not relevant at this time. DOE may
consider this issue in a future
rulemaking.
AHAM, Whirlpool, ALS, the
California Utilities/NRDC, and the Joint
Petitioners commented in support of the
proposed amendment to change the
clothes dryer load size to 8.45 ± 0.085
lb for standard-size clothes dryers.
15:19 Jan 05, 2011
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Sfmt 4700
6.75
8.15
(AHAM, No. 31 at p. 9; Whirlpool, No.
27 at p. 5, ALS, No. 24 at p. 7, California
Utilities/NRDC, No. 33 at p. 5, Joint
Petitioners, No. 30 at p. 7) For the
reasons stated above and in the absence
of comment objecting to this proposal,
DOE amends the clothes dryer test
procedure in today’s final rule to change
the clothes dryer load size to 8.45 ±
0.085 lb for standard-size clothes dryers.
DOE stated in the June 2010 TP
SNOPR that most compact clothes
dryers are used with compact-size
clothes washers, and that DOE does not
have any information to suggest that the
tub volume of such clothes washers has
changed significantly. Therefore, DOE
did not propose to change the 3-lb test
load size currently specified in the test
procedure for compact clothes dryers in
the June 2010 TP SNOPR. DOE sought
data on the historical trends of compactsize clothes washer average tub volumes
or any other data that would suggest a
change in the clothes dryer test load size
for compact clothes dryers.
AHAM and the Joint Petitioners
commented in support of maintaining
the 3-lb load size for compact clothes
dryers until there is sufficient data upon
which to base a change. (AHAM, No. 31
36 Association of Home Appliance Manufacturers,
Trends in Energy Efficiency 2008. p. 3. Washington,
DC. Available at: https://www.aham.org/ht/d/Store.
VerDate Mar<15>2010
Average
load lb.
E:\FR\FM\06JAR2.SGM
06JAR2
Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
at p. 9; Joint Petitioners, No. 30 at p. 7)
For these reasons, DOE is not amending
the test procedure to change the load
size for compact clothes dryers.
DOE tested 8 representative clothes
dryers to evaluate the affect of this
amendment to the test load weight for
standard-size clothes dryers on test
repeatability. DOE tested these units
according to the current DOE clothes
dryer test procedure, except that the test
load size was changed to 8.45 lb ± .085
lbs for standard-size clothes dryers. As
shown below in Table III.18, the test-to-
1015
test variation ranged from 0.0 percent to
2.9 percent, with an average of 1.6
percent. For this reason, DOE believes
that the amendments to the test load
weight in the clothes dryer test
procedure produce repeatable test
results.
TABLE III.18—DOE REPEATABILITY TESTING FOR 8.45 LB ± .085 LB TEST LOAD FOR STANDARD-SIZE CLOTHES DRYERS
Average EF lb/kWh
Test unit
Test 1
Vented Electric Standard:
Unit 1 ........................................................................................................................................................
Unit 4 ........................................................................................................................................................
Unit 6 ........................................................................................................................................................
Unit 7 ........................................................................................................................................................
Unit 8 ........................................................................................................................................................
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Unit 10 ......................................................................................................................................................
Unit 11 ......................................................................................................................................................
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d. Room Air Conditioner Annual
Operating Hours
The DOE test procedure currently
assumes room air conditioners have an
average annual use of 750 hours. DOE’s
technical support document from
September 1997, issued in support of
the most recent room air conditioner
energy conservation standards
rulemaking, shows that the average
annual operational hours are closer to
500 hours.37 That average would yield
approximately 33-percent lower annual
energy consumption than the annual
energy consumption determined using
the 750 operational hours assumed in
the current test procedure.
DOE acknowledged the uncertainty
regarding room air conditioner usage
patterns and investigated the annual
hours of usage from a range of
information sources to develop an
updated estimate of annual operating
hours for the June 2010 TP SNOPR. 75
FR 37594, 37633 (June 29, 2010). DOE’s
investigation revealed a lack of metered
and survey data for the operating hours
of individual room air conditioners.
DOE found that estimates of the annual
operating hours of use were often based
on regional climatic data rather than
actual room air conditioner use. DOE
did find two sources of survey data on
room air conditioner use in the EIA’s
2005 RECS (and previous versions) and
the CEC California Statewide RASS. The
CEC survey contained only aggregated
37 U.S. Department of Energy—Office of Energy
Efficiency and Renewable Energy, Technical
Support Document for Energy Conservation
Standards for Room Air Conditioners. September
1997. Chapter 1, section 1.5. Washington, DC.
https://www.eere.energy.gov/buildings/appliance_
standards/residential/room_ac.html.
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residential data, which limited any
analysis pertaining to the annual
operating hours. EIA’s 2005 RECS
provides extensive data on individual
residences, while providing a more
expansive and representative sample of
households. Thus, DOE continued its
analysis using EIA’s 2005 RECS. Id.
The 2005 RECS provides enough
information to establish the type (that is,
product class) of room air conditioner
used in each household, the age of the
product, and an estimate of the
household’s annual energy consumption
attributable to the room air conditioner.
Using this data, DOE developed an
estimate of the annual hours of use of
a room air conditioner in a household.
This estimate was used to calculate a
weighted national average of room air
conditioner usage hours. The data in the
2005 RECS indicates that the estimated
room air conditioner average annual
usage is 810 hours. DOE noted in the
June 2010 TP SNOPR that this number
of hours is higher than the current 750
hours specified in the test procedure. It
is also significantly higher than the
approximately 500 hours suggested by
the previous energy conservation
standard rulemaking analysis. Id.
An investigation of the 2005 cooling
season covered by RECS indicates that
there were roughly 12-percent more
cooling degree days (CDD) in 2005 than
the 30-year 1971 to 2000 average.38 The
38 CDD is a sum of the difference between
ambient temperature in °F and 65 °F for every hour
of the year that the ambient temperature is higher
than 65 °F for a given location, divided by 24 to
convert from hours to days; DOE used data on CDD
from the National Solar Radiation Database
(NSRDB). National Renewable Energy Laboratory,
National Solar Radiation Database 1991–2005
Update: User’s Manual, 2007. Golden, CO.
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Test 2
Test-to-test
variation %
3.13
3.20
3.53
3.33
3.18
3.13
3.27
3.47
3.34
3.09
0.0
2.2
1.7
0.3
2.9
2.85
2.96
2.81
2.86
2.89
2.73
0.4
2.4
2.9
Annual Energy Outlook projections of
CDD for the future suggest that the
higher level of CDD will continue.39
Hence, the predictions of annual hours
based on the 2005 RECS can be
considered representative of future
usage. Further, DOE stated in the June
2010 TP SNOPR, however, it does not
consider the increase of 60 hours from
750 hours to 810 hours to be significant.
This is because that increase does not
exceed the uncertainty level associated
with the RECS-based approach for
estimation of this value. Hence, DOE
did not propose a change in the annual
operating hours used in the test
procedure in the June 2010 TP SNOPR.
75 FR 37594, 37633 (June 29, 2010).
AHAM commented that it strongly
opposes relying on the RECS data.
(AHAM, No. 31 at pp. 9–10) AHAM
stated that it is becoming more difficult
to get survey data on room air
conditioners as more people rely on
central air conditioning and because
room air conditioners are being used
more for space cooling or assistance
cooling rather than primary cooling.
AHAM also commented that consumers
tend to buy room air conditioners that
are oversized for the cooling space,
resulting in fewer use-hours than if they
had purchased a unit that was sized
appropriately. (AHAM, Public Meeting
Transcript, No. 20 at pp. 151–152)
AHAM believes data are available, and
that DOE should use such data for its
Available online at: https://www.nrel.gov/docs/
fy07osti/41364.pdf.
39 Energy Information Administration, 2006 State
Energy Consumption, Price, and Expenditure
Estimates (SEDS),
2006. Washington, DC. Available online at: https://
www.eia.doe.gov/emeu/states/_seds.html.
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analysis. (AHAM, Public Meeting
Transcript, No. 20 at pp. 152–154)
AHAM also supported maintaining the
current 750 annual operating hours used
in the test procedure for room air
conditioners until or unless additional
reliable surveys or testing are completed
that determine a more representative
number of use hours for room air
conditioners exists. (AHAM, No. 31 at
pp. 9–10; AHAM, Public Meeting
Transcript, No. 20 at p. 150) The
California Utilities/NRDC also
supported DOE’s allocation of 750 hours
per year to active cooling, adding that
this allocation seems reasonable given
available data. However, the California
Utilities/NRDC stated that DOE may
need to revise this allocation in light of
its proposed treatment of fan-only
energy. (California Utilities/NRDC, No.
33 at p. 4)
DOE understands the uncertainties
associated with RECS data, but believes
that the estimates using such data
generally support maintaining the
current 750 annual operating hours. As
discussed in section III.B.4, DOE is not
amending the test procedure in today’s
final rule to account for fan-only active
mode energy use, but may consider
amendments to address fan-only active
mode in a future rulemaking as data
become available. For these reasons,
DOE maintains the current 750 annual
operating hours used in the test
procedure for room air conditioners.
DOE may consider revising this number
of annual operating hours if data are
made available indicating that a change
in this value is warranted.
e. Room Air Conditioner Part-Load
Performance
DOE noted in the October 2007
Framework Document that the current
DOE room air conditioner test
procedure measures full-load
performance and does not assess energy
savings associated with technologies
that improve part-load performance.
DOE concluded in the June 2010 TP
SNOPR that widespread use of part-load
technology in room air conditioners is
not likely to be stimulated by the
development of a part-load metric at
this time, and therefore, the significant
effort required to develop an accurate
part-load metric is not likely to be
warranted by the expected minimal
energy savings. 75 FR 37594, 37633–34
(June 29, 2010). A part-load metric
would measure efficiency of a product
when operating at conditions other than
maximum capacity, with outdoor or
indoor conditions cooler than currently
used in the DOE active mode energy
test, or both. In field use of room air
conditioners using currently available
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technologies, when enough cooling is
provided to the space, any number of
events can occur to prevent overcooling. For example, the user may turn
off the unit or adjust fan speed; or the
controls might turn off the compressor,
turn off both the compressor and the
fan, or reduce fan speed. Delivery of
cooling might be done more efficiently
with part-load technologies, such as a
compressor that can adjust its capacity
rather than cycling on and off, but
sufficient information is not available at
this time regarding use of room air
conditioner features to assess whether
those alternative technologies would be
cost effective. DOE notes that the key
design changes that improve full-load
efficiency also improve part-load
efficiency, so the existing EER metric is
already a strong indication of product
efficiency over a wide range of
conditions. DOE concludes that
development of an additional test for
part load, or a change of the room air
conditioner metric to a part-load metric
is not supported by the information
available to DOE at this time. Therefore,
DOE did not consider amendments to its
room air conditioner test procedure to
measure part-load performance in the
June 2010 TP SNOPR. 75 FR 37594,
37634 (June 29, 2010). For these reasons
and in the absence of comments
objecting to this determination, DOE is
not amending its room air conditioner
test procedure to measure part-load
performance at this time. DOE may
amend the test procedure to account for
part-load performance in a future
rulemaking if information becomes
available on part-load technologies that
are likely to result in significant energy
savings during actual use by consumers.
f. Room Air Conditioner Ambient Test
Conditions
DOE also considered whether the
ambient test conditions in its test
procedure for room air conditioners are
representative of typical installations.
DOE noted in the June 2010 TP SNOPR
that it received a comment in response
to the October 2007 Framework
Document that recommended increasing
the ambient temperature of the DOE
energy test procedure from 95 °F to
115 °F. The commenters stated that
room air conditioners are generally
operated when the outdoor
temperatures are the highest, and that
they are often located on the south or
west side of residences where the sun
can shine on them during operation. 75
FR 37594, 37634 (June 29, 2010). DOE
stated that it did not receive further
information to support the specification
of the higher temperature, and,
therefore, did not consider an
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amendment to the ambient test
conditions specified in the room air
conditioner test procedure in the June
2010 TP SNOPR. Id.
AHAM supported maintaining the
current specifications regarding ambient
test conditions for room air
conditioners. (AHAM, No. 31 at p. 10;
AHAM, Public Meeting Transcript, No.
20 at p. 155) In the absence of data to
support a change to the ambient test
conditions, DOE is not amending the
ambient test conditions specified in the
room air conditioner test procedure.
6. Room Air Conditioner Referenced
Test Procedures
The room air conditioner test
procedure cites two test standards: (1)
ANS Z234.1–1972 and (2) ASHRAE
Standard 16–69. Both the ANS (since
renamed ANSI) and ASHRAE standards
have been updated since DOE last
revised its room air conditioner test
procedure. The current standards are
ANSI/AHAM RAC–1–R2008 and ANSI/
ASHRAE Standard 16–1983 (RA 2009),
respectively. Because it is likely that
any manufacturer rating it products is
using the most recent test standards,
DOE suggested in the October 2007
Framework Document that it consider
updating its test procedure to
incorporate by reference the most recent
test standards.
In the June 2010 TP SNOPR, DOE
reviewed the differences between the
test standards currently referenced by
the DOE test procedure and the latest
versions of these standards to determine
if amendments to reference the latest
ANSI and ASHRAE test standards are
appropriate. DOE noted the sections that
would be referenced in ANSI/AHAM
RAC–1–R2008 by the DOE test
procedure do not introduce any new
changes in the measurement of cooling
capacity or power input. DOE also noted
the sections that would be referenced in
ANSI/ASHRAE Standard 16–1983 (RA
2009) by the DOE test procedure would
introduce changes to the determination
of capacity, four new temperature
measurements, and changes to the test
tolerances. In particular, DOE noted in
the June 2010 TP SNOPR that section
6.1.3 of ANSI/ASHRAE Standard 16–
1983 (RA 2009) introduces a correction
factor based on the test room condition’s
deviation from the standard barometric
pressure of 29.92 inches (in.) of mercury
(Hg) (101 kilopascal (kPa)). Section 6.1.3
of ANSI/ASHRAE Standard 16–1983
(RA 2009) states that the cooling
capacity may be increased 0.8 percent
for each in. Hg below 29.92 in. Hg (0.24
percent for each kPa below 101 kPa).
DOE noted the capacity correction factor
provides manufacturers with more
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flexibility in the test room conditions
while normalizing results to standard
conditions. On November 26, 2010, 75
FR 72739, DOE published notice of a
petition submitted by AHAM
concerning use of the proposed
correction factor for room air
conditioner testing. While DOE seeks
comment on the petition until December
27, 2010, DOE believes that the
correction factor resolves the issues
presented in the AHAM petition. DOE
also noted the referenced section
numbers from the old and current test
standards are identical. 75 FR 37594,
37634–35 (June 29, 2010).
DOE determined that incorporation by
reference of these updated versions
provides more accurate and repeatable
measurements of capacity while
providing greater flexibility to
manufacturers in selecting equipment
and facilities, and does not add any
significant testing burden because the
time required for testing would not
change. Furthermore, these revisions
would not impact the measurement of
EER for this equipment because the
methodology used for this measurement
is the same. DOE also stated that it
believes that manufacturers may already
be using these updated standards in
their testing. Therefore, DOE proposed
amending the DOE test procedure to
reference the relevant sections of ANSI/
AHAM RAC–1–R2008 and ANSI/
ASHRAE Standard 16–1983 (RA 2009).
75 FR 37634–35.
AHAM agreed that DOE should
reference the latest standards for room
air conditioners. (AHAM, No. 31 at p.
10) For the reasons stated above and in
the absence of comments objecting to
amending the DOE test procedure to
reference the relevant sections of ANSI/
AHAM RAC–1–R2008 and ANSI/
ASHRAE Standard 16–1983 (RA 2009),
DOE adopts these amendments.
7. Clothes Dryer Referenced Test
Procedure
The DOE clothes dryer test procedure
currently references the industry test
standard AHAM Standard HLD–1–1974.
Specifically, the DOE clothes dryer test
procedure requires that the clothes
dryer under test add the AHAM exhaust
simulator described in section 3.3.5 of
AHAM Standard HLD–1–1974. The
AHAM test standard has been updated
since DOE established its clothes dryer
test procedure. The current standard is
designated as AHAM Standard HLD–1–
2009. Because it is likely that any
manufacturer rating it products is using
the most recent test standard, DOE
considered potential amendments to its
clothes dryer test procedure to reference
AHAM Standard HLD–1–2009 in the
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June 2010 TP SNOPR. DOE noted that
section 3.3.5.1 of AHAM Standard
HLD–1–2009 regarding exhausting
conditions provides the same
requirements for the exhaust simulator
as required by AHAM Standard HLD–1–
1974. For this reason, DOE proposed to
amend the DOE test procedure to
reference AHAM Standard HLD–1–
2009. DOE stated that because the
requirements for the exhaust simulator
would be the same, the proposed
amendments would not affect the EF
rating of residential clothes dryers and
would not require that the existing
energy conservation standards for these
products be revised. 75 FR 37594, 37636
(June 29, 2010).
AHAM, Whirlpool, and ALS
commented in support of updating the
test procedure to reference AHAM
standard HLD–1–2009. (AHAM, No. 31
at p. 10, AHAM, Public Meeting
Transcript, No. 20 at p. 158, Whirlpool,
No. 27 at p. 5, ALS, No. 24 at p. 8) For
these reasons and in the absence of
comments objecting to amending the
DOE test procedure to reference AHAM
Standard HLD–1–2009, DOE adopts
these amendments in today’s final rule.
DOE also acknowledges that AHAM
Standard HLD–1–2009 allows for the
optional use of a modified exhaust
simulator, which is included as a more
convenient option than the exhaust
simulator originally specified for testing
vented clothes dryers. The requirements
for the modified exhaust simulator are
presented in section 3.3.5.2 of AHAM
Standard HLD–1–2009. The test
standard notes that only limited testing
has been done to compare results using
the two exhaust simulators, and that
users are invited to submit results and
comments for both options. Because this
modified exhaust simulator is recent,
and limited data exist to compare the
effects of using different exhaust
simulators, DOE stated in the June 2010
TP SNOPR that it will continue to
require the standard exhaust simulator
currently referenced by the DOE clothes
dryer test procedure. 75 FR 37594,
37636 (June 29, 2010). However, DOE
requested data from manufacturers
comparing the effects of the two exhaust
simulators on the drying efficiency
using the DOE test procedure. DOE also
invited comment on whether the test
procedure should be amended to allow
for the optional modified exhaust
simulator.
AHAM commented that there may be
more data available concerning the
modified exhaust simulator, which
gained ANSI approval in 2009. (AHAM,
Public Meeting Transcript, No. 20 at pp.
159–160) AHAM stated that DOE should
allow for the optional use of a modified
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1017
exhaust simulator. AHAM added that
the AHAM Standard HLD–1–2009 was
developed after an extensive standardsmaking process, which fully vetted
issues related to optional use of a
modified exhaust simulator, and as such
there is no reason for DOE to deviate
from that standard. (AHAM, No. 31 at p.
10).
DOE is not aware of any data
comparing the effects of the two exhaust
simulators on the drying efficiency
using the DOE test procedure. DOE
notes that it requested such data in the
June 2010 TP SNOPR, but did not
receive any data. In the absence of such
data, DOE will continue to require the
standard exhaust simulator currently
referenced by the DOE clothes dryer test
procedure. If data are made available
showing that the test results using the
modified exhaust simulator produce
repeatable results, as well as comparing
the effects of the different exhaust
simulators on the measured EF, DOE
may consider such revisions to its
clothes dryer test procedure in a future
rulemaking.
Section 1.8 in the ‘‘Definitions’’
section of the DOE clothes dryer test
procedure also references an obsolete
AHAM clothes dryer test standard,
AHAM Standard HLD–2EC. No
provisions of this test standard are
currently used in DOE’s test procedure,
and DOE therefore proposed to remove
this reference in the June 2010 TP
SNOPR. 75 FR 37594, 37636 (June 29,
2010). AHAM and Whirlpool both
commented in support of removing the
reference to AHAM Standard HLD–2EC.
(AHAM, No. 31 at p. 10, Whirlpool, No.
27 at p. 5) For this reason and in the
absence of comments objecting to this
proposal, DOE amends the test
procedure to remove this reference.
8. Technical Correction for the PerCycle Gas Dryer Continuously Burning
Pilot Light Gas Energy Consumption
The equation provided under section
4.4 Per-cycle gas dryer continuously
burning pilot light gas energy
consumption of the current DOE clothes
dryer test procedure contains a
technical error in the equation for
calculation of the per-cycle gas dryer
continuously burning pilot light gas
energy consumption (Eup), in Btus per
cycle. Eup is the product of the following
three factors: (A) The cubic feet of gas
consumed by the gas pilot in hour; (B)
the total number of hours per year the
pilot is consuming gas while the clothes
dryer is not operating in active mode
(8,760 total hours per year minus 140
hours per year the clothes dryer
operates in active mode) divided by the
representative average number of
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clothes dryer cycles in a year (416); and
(C) the corrected gas heat value. Part (B)
of this equation is currently incorrect,
reading (8760 ¥ 140/416) and missing
the appropriate parentheses. The
equation should correctly subtract the
total number of hours per year the pilot
is consuming gas while the clothes
dryer is not operating in active mode
from the number of hours per year the
clothes dryer operates in active mode,
before dividing by the average number
of clothes dryer cycles in a year. The
equation should read ((8760 ¥ 140)/
416) to correctly calculate the per-cycle
gas dryer continuously burning pilot
light gas energy consumption.
Therefore, DOE proposed in the June
2010 TP SNOPR to amend the equation
to correctly calculate the per-cycle gas
dryer continuously burning pilot light
gas energy consumption. 75 FR 37594,
37636 (June 29, 2010).
AHAM and Whirlpool supported the
technical correction to the per-cycle gas
dryer continuously burning pilot light
gas energy consumption calculation.
(AHAM, No. 31 at p. 10; Whirlpool, No.
27 at p. 5) ALS commented that it
supported DOE’s proposed technical
correction. However, ALS believes this
an unnecessary addition to the test
procedure. ALS believes the proper way
to address the issue is to revise the
minimum energy conservation standard
during its current standards rulemaking
to add back into the minimum standard
the design prescription banning
constant burning pilot lights. ALS noted
that the original 1987 standard included
the design prescription, but it was
removed in the first review of the
standard effective May 14, 1994 because
it was perceived that the revised
minimum standard of 1994 would
continue to effectively eliminate
continuously burning pilot lights. ALS
noted that no clothes dryer with
continuously burning gas pilot lights
exists on the market at this time.
Therefore, it is a wasted effort to add
text to the test procedure for something
that does not exist and can be more
effectively dealt with by a simple
revision to the clothes dryer minimum
standard. (ALS, No. 24 at p. 8) AHAM
also commented that it is not aware of
any clothes dryer on the market that
uses a constant burning pilot light, and
doubts any such dryers will be
introduced soon. (AHAM, Public
Meeting Transcript, No. 20 at p. 162)
As discussed in section I, EPCA
establishes prescriptive standards for
clothes dryers, requiring that gas dryers
manufactured on or after January 1,
1988 not be equipped with a constant
burning pilot (42 U.S.C. 6295(g)(3)).
Because constant burning pilot lights
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are precluded by EPCA, DOE agrees
with ALS that any provisions for
measuring constant burning pilot light
energy use in gas clothes dryers are no
longer necessary. As a result, DOE
amends the clothes dryer test procedure
to remove all provisions for measuring
the constant burning pilot light energy
use.
10. Other Clothes Dryer Active Mode
Issues
9. Clarification of Gas Supply Test
Conditions for Gas Clothes Dryers
ALS commented in response to the
June 2010 TP SNOPR that DOE should
consider if the number of test runs
allowed on test cloth after preconditioning should be equal to the
number of allowable runs for clothes
washer test cloth. ALS commented that,
currently, the clothes dryer test cloth
can be used for only 25 test runs, while
the clothes washer test cloth is allowed
to be used for 60 test runs. (ALS, No. 24
at p. 6) Whirlpool commented that both
the clothes washer and clothes dryer
test procedures should be modified to
allow for 50 cycles of test cloth use,
because this would be easier to manage
and reduce the cost of cloth used in
clothes dryers. Whirlpool commented
that beyond 50 wash cycles, the load-toload variability increases significantly,
adversely impacting repeatability.
(Whirlpool, No. 27 at p. 6) DOE is not
aware of any data showing the
repeatability of clothes dryer test results
for test cloth after 25 runs. DOE is also
not aware of any data indicating that the
wear on test cloth from a drying cycle
is equivalent to that of a washing cycle.
Thus, there is no evidence that warrants
changing the test procedures to specify
the same number of allowable test runs
on clothes washer and clothes dryer test
cloths. For these reasons, DOE is not
amending the clothes dryer test
procedure in today’s final rule to change
the number of test runs allowed on
clothes dryer test cloth.
Whirlpool commented that the lot-tolot test cloth correction factors used in
the clothes washer test procedure are
not used in the clothes dryer test
procedure. Whirlpool stated that it is
increasingly the case that clothes dryer
test results are not repeatable across test
cloth lots. Whirlpool stated its research
suggests that adding the washer
correction factors to the clothes dryer
test procedure would substantially
address this problem. (Whirlpool, No.
27 at p. 6) DOE is not aware of any data
indicating variations in test results
across different test cloth lots is
significant enough to warrant amending
the clothes dryer test procedure to
include correction factors. In addition,
DOE notes that the clothes washer RMC
correction factor is based on extractor
testing (spinning water out of the
clothes load). Extractor testing can have
Section 2.3.2.1 and 2.3.2.2 of the DOE
clothes dryer test procedure specifies
maintaining ‘‘the gas supply to the
clothes dryer at a normal inlet test
pressure immediately ahead of all
controls at’’ 7 to 10 inches of water
column for natural gas or 11 to 13
inches of water column for propane gas.
DOE believes that the references to
‘‘normal inlet test pressure’’ in sections
2.3.2.1 and 2.3.2.2 of its clothes dryer
test procedure may be confusing
because the term ‘‘normal’’ is not
defined. DOE believes that such
language is not necessary because the
gas supply pressure immediately ahead
of all controls is explicitly stated.
Therefore, DOE proposed in the June
2010 TP SNOPR to revise the test
pressure conditions in sections 2.3.2.1
and 2.3.2.2 of the DOE clothes dryer test
procedure to specify maintaining ‘‘the
gas supply to the clothes dryer
immediately ahead of all controls at a
pressure of’’ 7 to 10 inches of water
column for natural gas and 11 to 13
inches of water column for propane gas.
75 FR 37594, 37636 (June 29, 2010).
AHAM, Whirlpool, and ALS supported
DOE’s proposed clarification. (AHAM,
No. 31 at pp. 10–11; Whirlpool, No. 27
at p. 5; ALS, No. 24 at p. 8) For these
reasons and in the absence of comments
objecting to this proposal, DOE amends
its clothes dryer test procedure to revise
the test pressure conditions as discussed
above.
DOE also believes the specifications
for a gas pressure regulator in sections
2.3.2.1 and 2.3.2.2 of its clothes dryer
test procedure should clarify that the
outlet pressure for a clothes dryer
equipped with a pressure regulator for
which the manufacturer specifies an
outlet pressure should be approximately
that recommended by the manufacturer.
DOE proposed in the June 2010 TP
SNOPR to make these minor revisions
these sections. 75 FR 37594, 37636 (June
29, 2010). In the absence of comments
objecting to this proposal, DOE is
amending its clothes dryer test
procedure to revise the test pressure
conditions for clothes dryers equipped
with a gas pressure regulator as
discussed above.
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DOE received a number of comments
on issues related to the active mode for
clothes dryers not identified in the June
2010 TP SNOPR. The following sections
discuss each of these issues.
a. Test Cloth Specifications
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very different moisture removal
characteristics than the applied heated
air and slower tumbling to evaporate
moisture during a clothes dryer cycle.
DOE is not aware of any data indicating
that the same correction factor from the
clothes washer test procedure can be
applied to the clothes dryer test
procedure. For these reasons, DOE is not
amending the clothes dryer test
procedure to include a lot-to-lot test
cloth correction factor in today’s final
rule. If data is made available
documenting such lot-to-lot variation as
well as validating that the RMC
correction factor in the clothes washer
test procedure can be applied to the
clothes dryer test procedure, DOE may
consider such amendments.
b. Relative Humidity Measurement
Specifications
ALS commented that section 2.4.4
Dry & Wet Bulb Psychrometer of the
DOE clothes dryer test procedure should
be updated. ALS stated that DOE may
want to remove any reference to a dry
and wet bulb psychrometer, because
electronic digital sensors exist that
directly report the relative humidity and
test labs should be allowed to utilize
them. ALS commented that DOE needs
to research humidity measurement
electronic digital sensors and propose
new limits for their accuracy and
reporting. (ALS, No. 24 at p. 9)
DOE notes section 2.2.4 specifies that
the dry and wet bulb psychrometer shall
have an error no greater than ± 1 °F.
DOE acknowledges that the dry and wet
bulb psychrometer specifications for
determining the relative humidity were
developed in 1981 when the clothes
dryer test procedure was last amended.
Since that time, more advanced digital
equipment has been developed for
measuring relative humidity. DOE also
acknowledges that the DOE test
procedure for central air conditioners
and heat pumps specifies the allowable
error in the measurement of wet bulb
temperature for determining the
psychrometric state of air (the wet bulb
temperature sensor must be accurate
within ± 0.2 °F). That test procedure
also specifies the allowable error for an
alternative option of directly measuring
the relative humidity (such a meter
must be accurate to within ± 0.7
nominal percent relative humidity). 10
CFR part 430, subpart B, appendix M,
§ 2.5.6 DOE is not aware of data or
information on how the allowable dry
and wet bulb psychrometer
measurement error of no greater than ±
1 °F would translate to measurement
error specifications for relative humidity
measurement equipment that could be
used to determine an appropriate
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allowable error for the DOE clothes
dryer test procedure. For these reasons,
DOE is not adopting amendments to the
dry bulb and wet bulb psychrometer
specifications for determining the
relative humidity. If data are made
available indicating an appropriate
range for the allowable error for relative
humidity measurement equipment,
however, DOE may consider
amendments to the clothes dryer test
procedure.
c. Calculations of EF and CEF
ALS commented that DOE needs to
add the calculation for the EF, the
newly proposed IEF,40 or both to the
clothes dryer test procedure. According
to ALS, the clothes washer test
procedure displays the calculation for
the minimum energy efficiency
descriptor (the modified energy factor).
ALS stated the clothes dryer test
procedure should likewise show how to
calculate the value of clothes dryer
minimum energy efficiency descriptor
EF and/or IEF. (ALS, No. 24 at p. 9)
AHAM also requested that DOE
expressly state the equation for EF in
the test procedure to provide optimal
clarity for the regulated industry.
(AHAM, No. 31 at p. 11)
DOE notes that the calculation for EF
(and the proposed CEF) for clothes
dryers can be found at 10 CFR
430.23(d). However, DOE acknowledges
that other test procedures in the
appendices of 10 CFR part 430, subpart
B also include the calculations of the
energy efficiency metric. For example,
the clothes washer test procedure (10
CFR part 430, subpart B, appendix J1)
includes the calculation, as noted by
ALS. Including such calculations would
help test technicians find the proper
calculation for EF and CEF. For these
reasons, DOE believes that the
calculation for EF and CEF should be
included in 10 CFR part 430, subpart B,
appendix D1. Therefore, DOE amends
the clothes dryer test procedure in
today’s final rule to include those
calculations. DOE also amends 10 CFR
part 430.23(d)(2) and (3) in today’s final
rule to clarify that the EF and CEF are
to be determined in accordance with the
appropriate sections in 10 CFR part 430,
subpart B, appendix D1.
40 DOE proposed to use the term Integrated
Energy Factor (IEF) in the December 2008 TP
NOPR. 73 FR 74639, 74650 (December 9, 2008).
However, in the June 2010 TP SNOPR, DOE
proposed to revise the name of the metric to
Combined Energy Factor (CEF). 75 FR 37594, 37612
(June 29, 2010).
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1019
d. Measurement of Kilowatt Electricity
Demand
SEDI recommended that kW
electricity demand, in addition to kWh
energy consumption, also be measured
during the test procedure. SEDI added
that different clothes dryer technologies
can have very different electricity
demand profiles. Typical electric
clothes dryers available in North
America today have powerful heating
elements and may significantly
contribute to system peak demand. SEDI
commented that a more efficient clothes
dryer with a lower contribution to peak
demand may be even more cost-effective
from perspective of electric utilities.
(SEDI, No. 34 at p. 3) As discussed
previously, EPCA provides that any test
procedures prescribed or amended
under this section shall be reasonably
designed to produce test results which
measure energy efficiency, energy use,
water use, or estimated annual operating
cost of a covered product during a
representative average use cycle or
period of use. (42 U.S.C. 6293(b)(3))
DOE believes that measuring the
electricity demand profile of a clothes
dryer to account for designs options that
may reduce utility peak load demand
would be inconsistent with the EPCA
requirement for a test procedure to
measure the energy use of a product. For
this reason, DOE is not amending the
clothes dryer test procedure to measure
the electricity demand profile of a
clothes dryer to account for the peak
load demand of a clothes dryer.
e. Clarifications to the Measurement of
Drum Capacity
The Joint Petitioners and AHAM
commented that DOE should clarify
section 3.1 of the clothes dryer test
procedure regarding the measurement of
drum capacity. The clarification would
specify that the clothes dryer’s rear
drum surface be supported on a
platform scale to ‘‘prevent deflection of
the drum surface * * *’’ instead of
‘‘prevent deflection of the dryer.’’ (Joint
Petitioners, No. 25 at p. 14; Joint
Petitioners, No. 30 at p. 8; AHAM, No.
31 at p. 11) DOE agrees with the
comments that the reference to
deflection of the ‘‘dryer’’ is unclear and
should be clarified to specify that the
clothes dryer’s rear drum surface should
be supported on a platform scale to
prevent deflection of the drum surface.
For this reason, DOE amends the clothes
dryer test procedure to reflect this
change.
f. Test Procedure Language
AHAM commented that
manufacturers are having a difficult
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time using the proposed test procedure
because it is not written in a way that
can be easily followed when running a
test. AHAM commented that the
extraneous portions derived from the
IEC and Australia/New Zealand
procedures create a confusing amalgam
of testing situations that makes the
procedure extremely difficult to
conduct. AHAM stated that the test
procedure itself needs to be evaluated,
and they would like to see a more
sequenced and applicable test
procedure. (AHAM, Public Meeting
Transcript, No. 20 at pp. 88–89, 126–
127) AHAM commented that the AHAM
HLD–1 committee will likely consider
whether the test procedure amendments
should be added as modifications to
AHAM HLD–1, which is written in the
test procedure format. AHAM stated
that it would be helpful for DOE to
identify explicitly how the proposed
changes to the DOE test procedure could
be reflected in AHAM HLD–1. AHAM
added that manufacturers could test on
a version of AHAM HLD–1 that
incorporated the changes DOE
identified and report what changes to
test results have taken place. AHAM
commented that it would also assist the
AHAM HLD–1 committee in processing
the changes because it is unlikely that
the AHAM HLD–1 committee will want
to run tests that are different from the
DOE test procedure. (AHAM, Public
Meeting Transcript, No. 20 at pp. 127–
129)
DOE notes that its proposed clothes
dryer test procedure is similar in
structure to many other DOE test
procedures, and DOE is not aware of the
particular sections of the test procedure
language that may be confusing or
difficult to interpret. DOE also notes
that it is not adopting the amendments
to more accurately account for
automatic cycle termination based on
the provisions in AS/NZS Standard
2442, as discussed in section III.C.2. For
these reasons, DOE does not believe that
the test procedure needs to be
restructured or re-written and is not
including any additional revisions to
the test procedure language.
D. Compliance With Other EPCA
Requirements
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1. Test Burden
Standby Mode and Off Mode
Section 323(b)(3) of EPCA requires
that any test procedures prescribed or
amended under this section shall be
reasonably designed to produce test
results which measure energy
efficiency, energy use or estimated
annual operating cost of a covered
product during a representative average
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use cycle or period of use and shall not
be unduly burdensome to conduct. (42
U.S.C. 6293(b)(3))
For the proposed amendments to
measure standby and off mode energy
use, DOE tentatively concluded in the
December 2008 TP NOPR that amending
the relevant test procedures to
incorporate clauses regarding test
conditions and methods found in IEC
Standard 62301 for measuring standby
mode and off mode power consumption,
along with the proposed clarifications
and text corrections, would satisfy this
requirement because the test methods
and equipment that the amendments
would require are not substantially
different from the test methods and
equipment in the current DOE test
procedures for measuring the products
energy consumption. Therefore, DOE
stated the proposed test procedures
would not require manufacturers to
make major investments in test facilities
and new equipment. 73 FR 74639,
74650 (December 9, 2008).
In the June 2010 TP SNOPR, DOE did
not propose amendments to measure
delay start and cycle finished modes in
the clothes dryer test procedure. DOE
instead proposed a simplified
methodology in which the energy use
associated with delay start and cycle
finished modes, although determined to
not be energy use in a standby mode,
would be approximately represented by
the measured energy in inactive and off
modes. Therefore, because the proposal
in the June 2010 TP SNOPR was less
burdensome than the December 2008 TP
NOPR proposal, DOE tentatively
concluded that the proposed
amendments to the clothes dryer test
procedures for measuring standby and
off modes adopted in June 2010 TP
SNOPR are not unduly burdensome. 75
FR 37594, 37637 (June 29, 2010).
DOE proposed in the June 2010 TP
SNOPR to provide manufacturers
flexibility in setting the ambient
conditions for standby mode and off
mode testing for the room air
conditioner test procedure. The
proposed amendments to the room air
conditioner test procedure specify
maintaining the indoor test conditions
at the temperature required by section
4.2 of IEC Standard 62301. Further, if
the unit is tested in the cooling
performance test chamber, the proposed
amendments allow the manufacturer to
maintain the outdoor test conditions
either as specified for the DOE cooling
test procedure or according to section
4.2 of IEC Standard 62301.
Implementing those two specifications
would mean that manufacturers would
not have to build another facility to run
the standby and off mode tests. In
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addition, DOE did not propose
amendments that would specify
measurement of energy use in delay
start or off-cycle modes to the room air
conditioner test procedure. DOE instead
proposed a simplified methodology in
which the energy use associated with
delay start and off-cycle modes,
although determined to not be energy
use in a standby mode, would be
approximately represented by the
measured energy in inactive and off
modes. For these reasons, DOE
tentatively concluded that the test
conditions proposed in the June 2010
TP SNOPR are not unduly burdensome
and would result in representative
standby mode and off mode energy
consumption measurements. 75 FR
37594, 37637 (June 29, 2010).
As discussed in section III.B.2,
AHAM, Whirlpool, and ALS
commented that the requirement
proposed in the June 2010 TP SNOPR to
conduct standby and off mode testing
for clothes dryers and room air
conditioners in the settings that produce
the highest power consumption level
would result in extra test burden. This
is because manufacturers will need to
run several tests on every model in
order to determine which cycle is the
highest energy cycle (AHAM, No. 31 at
pp. 4–5; Whirlpool, No. 27 at p. 1; ALS,
No. 24 at pp. 1–2) DOE is not adopting
the provisions for conducing standby
and off mode testing in the settings that
produce the highest power consumption
level in today’s final rule. DOE is
instead incorporating by reference
section 5.2 of IEC Standard 62301,
which requires that the appliance be
installed and set up in accordance with
manufacturers instructions; if no
instructions are given, then the
appliance shall be tested at factory or
‘‘default’’ settings; and where there are
no indications for such settings, the
appliance shall be tested as supplied.
DOE believes that such provisions
would not require manufacturers to run
several tests on every model to
determine the appropriate mode, and
therefore would not represent a testing
burden.
For the reasons stated above and in
the absence of additional comments,
DOE concludes that the standby and off
mode testing conditions for clothes
dryers and room air conditioners
adopted in today’s final rule are not
unduly burdensome, yet still produce
representative standby mode and off
mode energy consumption
measurements.
Active Mode
In the June 2010 TP SNOPR, DOE
noted that the proposed amendments to
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its test procedure for clothes dryers to
test automatic termination control
dryers are based upon an international
testing standard used to determine
compliance with energy conservation
standards for clothes dryers in
Australia. A number of manufacturers
that sell clothes dryers in the United
States also sell clothes dryers in
Australia, and therefore likely already
test clothes dryers according to this test
standard. DOE stated the proposed
amendments would not require testing
methods and equipment that are
substantially different from the test
methods and equipment in the current
DOE test procedures. Therefore,
manufacturers would not be required to
make a major investment in test
facilities and new equipment. 75 FR
37594, 37637 (June 29, 2010). As
discussed in section III.C.2, DOE is not
adopting in today’s final rule the
amendments for automatic cycle
termination proposed in the June 2010
TP SNOPR.
In the June 2010 TP SNOPR, DOE also
noted that the proposed amendments to
its test procedure for residential clothes
dryers to test ventless clothes dryers are
based on an international test standard
used throughout the EU to determine
compliance with energy conservation
standards. A number of manufacturers
that sell clothes dryers in the United
States also sell clothes dryers in the EU,
and therefore likely already test clothes
dryers according to this test standard.
DOE stated the proposed amendments
would not require testing methods and
equipment that are substantially
different from the test methods and
equipment in the current DOE clothes
dryer test procedure. 75 FR 37594,
37637 (June 29, 2010).
DOE noted that its proposed
amendments to the clothes dryer test
procedure to reflect current usage
patterns and capabilities in the June
2010 TP SNOPR do not substantially
change the testing procedures and
methods. DOE noted that its proposed
amendments to change the number of
annual use cycles affects only the
calculation of the estimated annual
operating cost. The number of annual
use cycles does not impact the testing
procedures because the value is only
used in the calculation of results. DOE
also noted that the proposed
amendments to change the initial RMC
from 70 percent to 47 percent are
intended to reflect current clothes loads
after a wash cycle. DOE believes that
such a change would likely require only
a moderately longer spin time during
test load preparation to achieve the
proper lower moisture content. Finally,
DOE noted that the proposed
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amendment to change the test load size
for standard-size clothes dryers from
7.00 lb ± .07 lb to 8.45 lb ± .085 lb
would not significantly impact the
testing procedures because it only
affects the amount of test cloth required
to be used for the test cycle. The
amendment also would not require
manufacturers to make any significant
new investment in test facilities and
equipment. DOE stated in the June 2010
TP SNOPR that these proposed
amendments to the DOE clothes dryer
test procedure would produce test
results that measure energy use of
clothes dryers during a representative
average use cycle. 75 FR 37594, 37637
(June 29, 2010).
DOE noted in the June 2010 TP
SNOPR that the proposed amendments
to update the references to external
standards in the DOE room air
conditioner test procedure are based on
the availability of revised standards
representing current industry practices
and methods. The proposed
amendments to reference ANSI/AHAM
RAC–1–R2008 do not introduce any
new changes in the measurement of
cooling capacity or power input. The
proposed amendments to reference
ANSI/ASHRAE Standard 16–69 would
introduce four new temperature
measurements, provide increased test
tolerances, and allow additional
flexibility in the methodology for
measuring capacity. DOE notes the four
new temperature measurements would
be measured simultaneously with the
other measurements already required by
the test procedure, and therefore would
not require additional time to conduct
the test. DOE stated in the June 2010 TP
SNOPR that these proposed
amendments would not require
manufacturers to make any significant
new investment in test facilities and
equipment, nor require significant
changes in the testing methodology. 75
FR 37594, 37637 (June 29, 2010).
For the reasons noted above, DOE
tentatively concluded that the
amendments to the active mode test
procedures would produce
representative test results for both
residential clothes dryers and room air
conditioners, and that testing under the
test procedures would not be unduly
burdensome to conduct. 75 FR 37594,
37638 (June 29, 2010).
ALS commented that there could be a
test burden associated with the revised
initial RMC requirements. ALS stated
that it might not be able to achieve the
47 percent RMC proposed in the June
2010 TP SNOPR in one of their
residential clothes washers due to the
disconnect between the actual RMC and
the corrected RMC values. (ALS, Public
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1021
Meeting Transcript, No. 20 at pp. 166–
167) AHAM commented that extracting
moisture to the 47 percent RMC level
would cause test cloth to deteriorate
more quickly. Also, extracting moisture
to the 47 percent RMC level would
cause other problems. For example, to
achieve the level it would be necessary
to use an extractor, which would require
spending significant sums of money.
(AHAM, Public Meeting Transcript, No.
20 at pp. 167–168)
DOE notes that the tests conducted for
the June 2010 TP SNOPR at an
independent test lab prepared the
clothes dryer test cloth with an RMC of
47 percent using a commercially
available clothes washer. For the
reasons discussed in section III.C.5.b,
however, DOE adopts an initial RMC of
57.5 percent ± 3.5 percent for the
clothes dryer test procedure in today’s
final rule. As a result, DOE believes that
there would be no significant test
burden associated with reaching this
higher initial RMC value.
For the reasons stated above and in
the absence of additional comments,
DOE concludes that the amendments to
the active mode test procedures in
today’s final rule would produce
representative test results for both
residential clothes dryers and room air
conditioners, and that testing under the
test procedures would not be unduly
burdensome to conduct.
2. Integration of Standby Mode and Off
Mode Energy Consumption Into the
Efficiency Metrics
Section 325(gg)(2)(A) requires that
standby mode and off mode energy
consumption be ‘‘integrated into the
overall energy efficiency, energy
consumption, or other energy descriptor
for each covered product’’ unless the
current test procedures already fully
account for the standby mode and off
mode energy consumption or if such an
integrated test procedure is technically
infeasible. (42 U.S.C. 6295(gg)(2)(A)) For
clothes dryers, today’s final rule does
not affect DOE’s proposal in the
December 2008 TP NOPR to incorporate
the standby and off mode energy
consumption into a ‘‘per-cycle combined
total energy consumption expressed in
kilowatt-hours’’ and into an CEF, as
discussed in section III.B.5 of this
notice. For room air conditioners,
today’s final rule does not affect DOE’s
proposal in the December 2008 TP
NOPR to incorporate the standby and off
mode energy consumption into a metric
for ‘‘combined annual energy
consumption’’ and into an CEER, as
discussed in section III.B.5. In addition,
DOE is amending the clothes dryer and
room air conditioner test procedures in
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today’s final rule to incorporate standby
and off mode energy consumption into
the annual energy cost calculations, as
discussed in section III.B.5.
IV. Effects of Test Procedure Revisions
on Compliance With Standards
As noted in section I, DOE must
determine to what extent, if any, the
proposed test procedures would alter
the measured energy efficiency of
covered products as determined under
the existing test procedures. If DOE
determines that an amended test
procedure would alter the measured
efficiency of a covered product, DOE
must amend the applicable energy
conservation standard during the
rulemaking carried out with respect to
such test procedure. (42 U.S.C. 6293(e))
A. Standby Mode and Off Mode
As noted in section II, EPCA provides
that amendments to the test procedures
to include standby mode and off mode
energy consumption will not determine
compliance with previously established
standards. (U.S.C. 6295(gg)(2)(C))
Because the proposed amended test
procedures for standby mode and off
mode energy consumption would not
alter existing measures of energy
consumption or efficiency for active
mode, these amendments would not
affect a manufacturer’s ability to
demonstrate compliance with
previously established standards.
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B. Active Mode—Clothes Dryers
DOE reviewed the amendments to the
DOE clothes dryer active mode test
procedure to evaluate the effects on the
measured EF. The following sections
discuss DOE’s evaluation of each active
mode amendment individually, as well
as DOE’s evaluation of the fully
amended test procedure.
Automatic Cycle Termination
In the June 2010 TP SNOPR, DOE
analyzed how the proposed changes to
the DOE clothes dryer test procedure for
automatic cycle termination controls
discussed above in section III.C.2 would
affect the measured EF of residential
clothes dryers, as required by EPCA. 75
FR 37594, 37618 (June 29, 2010). As
part of DOE’s preliminary analyses for
the energy conservation standards
rulemaking for clothes dryers, DOE
concluded that virtually all clothes
dryers currently available on the U.S.
market that are covered under the
current energy conservation standards
are equipped with some form of
automatic cycle termination sensing.
Therefore, DOE analyzed in the June
2010 TP SNOPR how the proposed
changes to the clothes dryer test
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procedure for automatic termination
control dryers would affect the
measured EF of residential clothes
dryers with such a feature. 75 FR 37594,
37618 (June 29, 2010).
DOE noted in the June 2010 TP
SNOPR that the proposed amendment to
change the field use factor from 1.04 to
1.0 for automatic termination control
dryers would result in a 4-percent
increase in EF for a dryer that has an
automatic cycle termination setting
capable of drying the test load to 5percent RMC. In addition, DOE noted
the proposed target final RMC of 5
percent or lower would result in an
increase in EF of about 2.4 percent
(assuming a starting RMC of 47 percent).
This is as compared to the current DOE
test procedure, which uses a correction
factor in order to determine the energy
consumption required to dry the test
load to a final RMC of 4 percent. DOE
also stated in the June 2010 TP SNOPR
that a clothes dryer that is only
minimally compliant with current
energy conservation standards would
likely use a less accurate automatic
termination control system. DOE stated
that such a dryer would possibly overdry the test load below 5-percent RMC
such that the energy consumption and
measured EF would be equivalent to
that measured by the existing DOE
clothes dryer test procedure. As a result,
DOE stated that it does not believe that
any changes to the current energy
conservation standards as a result of the
proposed amendments to the test
procedure to account for automatic
cycle termination would be warranted.
75 FR 37619–20. Because DOE did not
have data regarding how the proposed
changes to the clothes dryer test
procedure for automatic termination
control dryers would affect the
measured EF of residential clothes
dryers with such a feature, however,
DOE requested comment on this
tentative conclusion in the June 2010 TP
SNOPR. Id.
The Joint Petitioners and AHAM
commented that if the full cycle test
(including cool-down) is adopted, DOE
must also revise the relevant energy
conservation standards to reflect the
new test procedure, ensuring no change
in the stringency of the standards for
clothes dryers with effective automatic
termination controls, as per section 323
of EPCA. The Joint Petitioners and
AHAM stated that, specifically, the
procedures in section 323(e)(2) should
be used, with the clarification that for
the purposes of establishing a
representative sample of products, DOE
should choose a sample of minimally
compliant clothes dryers that
automatically terminate the drying cycle
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at no less than 4-percent RMC. The Joint
Petitioners and AHAM also stated that
there will be additional energy savings
by improving the effectiveness of
automatic termination controls. (Joint
Petitioners, No. 30 at p. 6; AHAM, No.
31 at pp. 30–31)
The California Utilities/NRDC
commented that they are very
concerned with DOE’s proposal to not
revise the current energy conservation
standard levels as a result of its analysis
of the test procedure amendments to
account for automatic cycle termination.
They are also concerned about DOE’s
interpretation of the definition of a
‘‘minimally compliant’’ clothes dryer in
the June 2010 TP SNOPR. The
California Utilities/NRDC noted that
clothes dryers with less accurate
automatic termination controls may
actually over-dry beyond the specified
RMC in the field. They also stated that
clothes dryers with less accurate
automatic termination controls will not
exhibit equivalent energy consumption
and measured EF under the new test
procedure; should not be used as a basis
for DOE’s analysis; and should not be
considered automatically compliant
under the new test procedure.
(California Utilities/NRDC, No. 33 at pp.
6–7)
The California Utilities/NRDC further
stated that clothes dryers with
operational automatic cycle termination
controls will dry the clothes to an
appropriate range of RMC without overdrying (between 2.5- and 5-percent
RMC). They also stated that such clothes
dryers should have about the same
measured per-cycle energy use under
both the current and proposed test
procedures. The California Utilities/
NRDC stated, however, that by changing
the calculation for per-cycle energy use,
and changing the field use factor to 1.0,
the calculated final per-cycle energy use
for automatic termination control dryers
will decrease. The California Utilities/
NRDC stated that the new test procedure
would make these clothes dryers with
operational controls appear to be more
efficient and have a higher EF than
under the current test procedure. The
EF for these clothes dryers would
increase by 4-percent through the
change in the field use factor alone. The
California Utilities/NRDC stated that,
based on their calculations, all clothes
dryers that dry to between 2.5- and
5-percent RMC would have a higher
measured EF. They stated that the
energy conservation standards should
be revised to reflect this measured
higher EF. The California Utilities/
NRDC commented that for dryers with
less accurate automatic termination
controls, EF would decrease because of
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
the over-drying energy consumption
mesaured using the the new test
procedure. The California Utilities/
NRDC stated that adjustments to EF
would be required to account for the
new test procedure, per-cycle energy
use calculation, and change in the field
use factor. (California Utilities/NRDC,
No. 33 at pp. 7–8)
The California Utilities/NRDC stated
they are concerned that by not changing
the clothes dryer standards accordingly
DOE’s current approach may qualify as
backsliding prohibited by EPCA’s ‘‘antibacksliding’’ provision. The California
Utilities/NRDC stated that under DOE’s
proposed approach, many compliant
clothes dryers could test with lower percycle energy use and higher EF, than
currently. By not adjusting the
maximum allowable energy use (and
minimum allowable EF) for such dryers,
DOE risks effectively weakening the
standard. (California Utilities/NRDC,
No. 33 at p. 8) The California Utilities/
NRDC proposed that DOE adjust its
proposed candidate standard levels to a
level consistent with the performance of
a selection of dryers that are ‘‘minimally
compliant’’ under both the current and
proposed test procedure. The California
Utilities/NRDC also recommended that
when DOE selects a representative
sample of minimally compliant clothes
dryers, it choose models that
automatically terminate at between 2.5and 5-percent RMC. They explained that
this approach would remove clothes
dryers with less accurate automatic
termination controls that comply under
the current testing procedure and ensure
that new standards are appropriately
adjusted, so that the standard is not
overly weak. Id.
As discussed in section III.C.2, DOE is
not adopting the amendments to better
account for automatic cycle termination
proposed in the June 2010 TP SNOPR.
For this reason, DOE is not revising the
energy conservation standards based on
the amendments for automatic cycle
termination proposed in the June 2010
TP SNOPR. If DOE considers potential
amendments for automatic cycle
termination in a future rulemaking, it
will consider any necessary revisions to
the energy conservation standards.
Water Temperature for Clothes Dryer
Test Load Preparation
DOE tested the 17 clothes dryers to
evaluate the effects on measured EF to
change the water temperature for
clothes dryer test load preparation from
100 °F ± 5 °F to 60 °F ± 5 °F, as
discussed in section III.C.2. DOE tested
these units according to the current DOE
clothes dryer test procedure, first with
a water temperature for clothes dryer
test load preparation of 100 °F ± 5 °F,
and then with a water temperature of 60
°F ± 5 °F. For the ventless clothes dryer
test units, DOE additionally used the
proposed testing method for ventless
dryers presented in section III.C.3. For
each water temperature, DOE conducted
up to three tests for each test unit and
the results were averaged. Table IV.1
below shows the results from this
testing, which indicate that, on average,
measured EF decreases by about 2.9
percent when the water temperature for
clothes dryer test load preparation is
reduced from 100 °F ± 5 °F to 60 °F ±
5 °F. DOE also notes the variation in the
percentage change in EF from model to
model due to the change in water
temperature may also be due to other
test condition tolerances in the test
procedure, such as the specified ranges
for ambient temperature and relative
humidity.
TABLE IV.1 DOE TEST RESULTS TO EVALUATE THE EFFECTS OF CHANGES TO THE WATER TEMPERATURE FOR CLOTHES
DRYER TEST LOAD PREPARATION
Average EF lb/kWh
Test unit
100° ± 5 °F
Water temp
kgrant on DSKGBLS3C1PROD with BILLS
Vented Electric Standard:
Unit 1 ............................................................................................................................................
Unit 2 ............................................................................................................................................
Unit 3 ............................................................................................................................................
Unit 4 ............................................................................................................................................
Unit 5 ............................................................................................................................................
Unit 6 ............................................................................................................................................
Vented Gas:
Unit 7 ............................................................................................................................................
Unit 8 ............................................................................................................................................
Unit 9 ............................................................................................................................................
Unit 10 ..........................................................................................................................................
Unit 11 ..........................................................................................................................................
Vented Electric Compact (240V):.
Unit 12 ..........................................................................................................................................
Unit 13 ..........................................................................................................................................
Vented Electric Compact (120V):
Unit 14 ..........................................................................................................................................
Ventless Electric Compact (240V):
Unit 15 ..........................................................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ..........................................................................................................................................
Unit 17 ..........................................................................................................................................
Test Procedure for Ventless Clothes
Dryers
The amendments for ventless clothes
dryers are applicable to products not
covered under the current DOE test
procedure. For this reason, the
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amendments in today’s final rule for
ventless clothes dryers discussed in
section III.C.3 would not affect the
existing EF ratings of residential clothes
dryers. Therefore, no change to the
current clothes dryer energy
PO 00000
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60° ± 5 °F
Water temp
%
Change
3.07
3.14
3.20
3.28
3.24
3.12
3.00
3.05
3.10
3.22
3.17
2.98
¥2.2
¥3.1
¥3.2
-1.9
¥2.0
¥4.6
2.78
2.83
2.85
2.80
2.98
2.72
2.92
2.64
2.69
2.79
¥2.4
3.1
¥7.2
¥3.7
¥6.4
3.19
2.93
2.95
2.84
¥7.7
¥3.2
3.23
3.11
¥4.0
2.37
2.22
¥6.1
2.01
2.50
1.96
2.60
¥4.0
3.8
conservation standards would be
required. (42 U.S.C. 6293(e))
E:\FR\FM\06JAR2.SGM
06JAR2
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
Detergent Specifications for Clothes
Dryer Test Cloth Preconditioning
DOE stated in the June 2010 TP
SNOPR that it is unaware of any data
indicating that changes to the detergent
specifications for test cloth
preconditioning discussed in section
III.C.4 would affect efficiency
measurements. DOE stated that the
proposed amendments in the June 2010
TP SNOPR changing the detergent
specifications for test cloth
preconditioning would not affect the EF
rating of residential clothes dryers and
would not require the existing energy
conservation standards for these
products to be revised because DOE is
not aware of any data indicating the
changes to the detergent formula affects
the ability of the clothes dryer to remove
moisture from the clothes load during
the drying cycle. For the reasons stated
above and in the absence of comments
objecting to this determination, DOE
continues to believe that the change to
the detergent specifications would not
affect the EF rating of clothes dryers.
Clothes Dryer Number of Annual Cycles
The amendments for the number of
annual use cycles, discussed in section
III.C.5.a, affect only the estimated
annual operating cost for all clothes
dryers. The EF rating for clothes dryers
is expressed in terms of the total energy
use per drying cycle. Because the EF
rating is measured on a per-cycle basis,
the number of annual use cycles is not
used in the calculation. For this reason,
DOE stated in the June 2010 TP SNOPR
that the proposed amendments to
change the number of clothes dryer
annual use cycles would not affect the
EF rating of residential clothes dryers.
Therefore, the proposed amendments
would not require the existing energy
conservation standards for these
products to be revised.
Whirlpool commented that the change
in the number of annual use cycles has
a linear effect ((416–283)/416 = 32
percent), and therefore the clothes dryer
would be rated as consuming 32 percent
less energy under the proposed under
the proposed test procedure.
(Whirlpool, No. 27 at p. 5) The
California Utilities/NRDC supported
DOE’s proposed revisions to the energy
conservation standards to account for
changes to the cycles per year.
(California Utilities/NRDC, No. 33 at p.
6) DOE first notes it did not propose any
revisions to the energy conservation
standards to account for changes to the
number of clothes dryer cycles per year.
DOE notes that the current energy
conservation standards for clothes
dryers are based on EF and that changes
to the number of annual use cycles does
not affect EF for clothes dryers. As a
result, DOE continues to believe that the
amendments to change the number of
clothes dryer annual use cycles would
not affect the EF rating of residential
clothes dryers. Therefore, the
amendments would not require the
existing energy conservation standards
for these products to be revised.
Clothes Dryer Initial Remaining
Moisture Content
In the June 2010 TP SNOPR, DOE
evaluated how the amendments to the
clothes dryer initial RMC discussed in
section III.C.5.b affect the measured EF.
DOE estimated, based on results of
testing conducted at an independent
testing laboratory, that the measured EF
increases by 41 percent when the initial
RMC is reduced to 47 percent. DOE
stated that if the proposed amendments
to change the initial RMC from 70
percent ± 3.5 percent to 47 percent ± 3.5
percent were implemented, current
energy conservation standards in terms
of EF for vented clothes dryer product
classes would need to increase by 41
percent. 75 FR 37594, 37631 (June 29,
2010).
The California Utilities/NRDC
supported DOE’s proposed revisions to
the energy conservation standards to
account for changes in the initial RMC.
(California Utilities/NRDC, No. 33 at p.
6) Whirlpool commented that the
change in RMC is not linear, but that it
does not have sufficient data to fully
address how this would be reflected in
total energy consumption. Whirlpool
recommended that further study
regarding the impact of changing the
RMC on the energy factor be
undertaken. Whirlpool added that if
DOE were to make a specific request to
AHAM for such data, Whirlpool would
be willing to gather and supply
information to AHAM for aggregation
and submittal to DOE. (Whirlpool, No.
27 at pp 4, 5) The Joint Petitioners and
AHAM both supported increasing EF for
vented clothes dryer product classes to
account for the change in initial RMC.
The Joint Petitioners and AHAM also
stated that they do not currently have
data to quantify the increase, but upon
DOE request would gather data to
determine an appropriate increase.
(Joint Petitioners, No. 30 at p. 7; AHAM,
No. 31 at p. 9) The California Utilities/
NRDC supported DOE’s proposed
revisions to the energy conservation
standards to account for changes in test
load weight, initial RMC, and cycles per
year. (California Utilities/NRDC, No. 33
at p. 6) ALS supported the manner in
which DOE has analyzed the impact of
its proposed revisions to the test
procedure on the minimum standard.
ALS requested the analysis be
conducted using a methodology
consistent with the ALS proposal of an
initial RMC of 53 percent. (ALS, No. 24
at p. 8)
After issuance of the June 2010 TP
SNOPR, DOE conducted additional
clothes dryer testing on 17
representative clothes dryers to evaluate
the effects of the proposed amendment
to change the initial RMC from 70
percent ± 3.5 percent to 57.5 percent ±
3.5 percent for the measured efficiency.
DOE tested these units according to the
current DOE clothes dryer test
procedure with an initial RMC of 70
percent ± 3.5 percent and with an initial
RMC of 57.5 percent ± 3.5 percent. For
the ventless clothes dryer test units,
DOE additionally used the proposed
testing method for ventless dryers
presented in section III.C.3. For each
initial RMC, DOE conducted up to three
tests for each test unit and the results
were averaged Table IV.2 below shows
the results from the tests. The results
indicate that, on average, EF increases
by about 17.1 percent when the initial
RMC is changed from 70 percent ± 3.5
percent to 57.5 percent ± 3.5 percent.
TABLE IV.2—DOE TEST RESULTS TO EVALUATE THE EFFECTS OF CHANGES TO THE INITIAL RMC
Average EF lb/kWh
kgrant on DSKGBLS3C1PROD with BILLS
Test unit
70% ± 3.5%
RMC
Vented Electric Standard:
Unit 1 ............................................................................................................................................
Unit 2 ............................................................................................................................................
Unit 3 ............................................................................................................................................
Unit 4 ............................................................................................................................................
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E:\FR\FM\06JAR2.SGM
3.07
3.14
3.20
3.28
06JAR2
57.5% ± 3.5%
RMC
3.67
3.62
3.83
3.79
%
Change
19.8
15.1
19.6
15.5
1025
Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
TABLE IV.2—DOE TEST RESULTS TO EVALUATE THE EFFECTS OF CHANGES TO THE INITIAL RMC—Continued
Average EF lb/kWh
Test unit
70% ± 3.5%
RMC
Unit 5 ............................................................................................................................................
Unit 6 ............................................................................................................................................
Vented Gas:
Unit 7 ............................................................................................................................................
Unit 8 ............................................................................................................................................
Unit 9 ............................................................................................................................................
Unit 10 ..........................................................................................................................................
Unit 11 ..........................................................................................................................................
Vented Electric Compact (240V):
Unit 12 ..........................................................................................................................................
Unit 13 ..........................................................................................................................................
Vented Electric Compact (120V):
Unit 14 ..........................................................................................................................................
Ventless Electric Compact (240V):
Unit 15 ..........................................................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ..........................................................................................................................................
Unit 17 ..........................................................................................................................................
Clothes Dryer Test Load Weight
As noted previously, EF for clothes
dryers is the bone-dry test load weight
divided by the clothes dryer energy
consumption per cycle. DOE notes that
the proposed amendments to the test
load size, discussed in section III.C.5.c,
would increase both the bone-dry test
load weight and the energy
consumption per cycle. For example, for
a test in which the nominal RMC of the
test load is reduced from an initial 70
percent to a final 4 percent, an 8.45-lb
test load would require about 5.6 lb of
water to be removed during the drying
57.5% ± 3.5%
RMC
%
Change
3.24
3.12
3.91
3.70
20.9
18.7
2.78
2.83
2.85
2.80
2.98
3.32
3.43
3.23
3.29
3.40
19.1
20.9
13.3
17.5
14.2
3.19
2.93
3.61
3.45
13.2
17.7
3.23
4.08
26.1
2.37
2.74
15.9
2.01
2.50
2.33
2.70
15.8
8.0
EF. 75 FR 37594, 37632 (June 29, 2010).
NIST conducted testing to investigate
the effects of changing the clothes dryer
load size on the measured efficiency of
a vented electric standard clothes dryer
with a capacity of 6.3 ft3.41 NIST tested
the clothes dryer according to the DOE
clothes dryer test procedure, except the
test load size varied from 2–15 lb. Table
IV.3 presents the results of the NIST
testing, which shows an increase in EF
when the load size was increased in 7–
9 lb. range, which for the purpose of
analysis corresponds to the 7–8.45 lb.
range.
cycle. However, a 7-lb. test load would
require only 4.6 lb. of water to be
removed. DOE also notes that as lower
nominal RMCs are reached at the end of
the test cycle, the rate and efficiency of
water removal from the load would be
higher for the larger test load. This is
because there would simply be more
water in the load, hence making it easier
to remove.
In the June 2010 TP SNOPR, DOE
reviewed research on the effects of
changing the load size on the measured
efficiency to determine a quantifiable
estimate of the change in the measured
TABLE IV.3—NIST VENTED ELECTRIC STANDARD CLOTHES DRYER VARIABLE TEST LOAD DATA
1
2
3
Room Temperature, °F ....................................................
Room Humidity, % ...........................................................
Nominal Bone-Dry Weight, lb ..........................................
Measured Bone-Dry Test Load Weight, lb ......................
Measured Dry Test Load Weight, lb ................................
Measured Wet Test Load Weight, lb ...............................
Measured Energy Consumption, kWh .............................
Initial RMC, % ..................................................................
Final RMC, % ...................................................................
Per-Cycle Energy Consumption, kWh .............................
EF, lb/kWh .......................................................................
Percentage Change in EF Compared to 7-lb Test, % ....
kgrant on DSKGBLS3C1PROD with BILLS
Test Number
74.1
40
2
1.99
2.05
3.40
0.953
70.30
2.84
0.970
2.06
¥36.6
74.4
38
3
2.99
3.06
5.10
1.159
70.67
2.48
1.167
2.56
¥20.9
73.8
38
5
4.99
5.17
8.50
1.593
70.52
3.73
1.637
3.04
¥6.0
4
5
73.3
33
7
7.00
7.99
11.89
2.112
69.99
2.88
2.160
3.24
0.0
In the June 2010 TP SNOPR, DOE
estimated the percentage change in EF
for an 8.45-lb test load by linearly
interpolating the results for the 7-lb and
9-lb tests. Estimates based on this
method showed the EF increase by
about 3.8 percent when the test load
size increased from 7 lb. to 8.45 lb. DOE
stated that this percentage change in EF
can be applied to all vented standardsize clothes dryer product classes
because the moisture removal
mechanisms are comparable among
them. For these reasons, DOE stated that
41 J. Y. Kao. Energy Test Results of a Conventional
Clothes Dryer and a Condensing Clothes Dryer. pp.
73.8
42
9
8.99
9.11
15.34
2.667
70.67
1.28
2.638
3.41
5.2
11–21 1999. International Appliance Technical
Conference, 49th. Proceedings. May 4–6,, 1998.
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6
74.1
38
11
10.98
11.56
18.98
3.250
72.81
5.27
3.303
3.33
2.7
7
74.4
40
13
13.01
13.57
22.04
3.796
69.35
4.29
4.005
3.25
0.3
8
74.4
36
15
15.01
15.71
25.56
4.384
70.34
4.67
4.582
3.27
1.1
if the proposed amendments to increase
the test load size to 8.45 ± .085 lb for
standard-size clothes dryers were
implemented, the current energy
conservation standards in terms of EF
for vented standard-size clothes dryer
product classes would need to be
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
increased by 3.8 percent. 75 FR 37594,
37632 (June 29, 2010).
The California Utilities/NRDC
supported DOE’s proposed revisions to
the energy conservation standards to
account for changes to the test load
weight. (California Utilities/NRDC, No.
33 at p. 6) Whirlpool commented that
the change in load size is not linear, but
that it does not have sufficient data to
fully address how this would be
reflected in total energy consumption.
Whirlpool commented that if DOE were
to make a specific request to AHAM for
such data, Whirlpool would be willing
to gather and supply information to
AHAM for aggregation and submittal to
DOE. (Whirlpool, No. 27 at p. 5) The
Joint Petitioners and AHAM supported
DOE’s proposal to revise the relevant
energy conservation standards to reflect
the new test load weight. The Joint
Petitioners and AHAM stated they do
not currently have data that would
support a specific test load weight, but
upon DOE request would gather such
data. (Joint Petitioners, No. 30 at p. 7;
AHAM, No. 31 at p. 9)
DOE conducted additional clothes
dryer testing after issuance of the June
2010 TP SNOPR on 11 representative
standard size clothes dryers to evaluate
the effects of the proposed amendment
to increase the test load size for
standard-size clothes dryers on the
measured efficiency. DOE tested these
units according to the current DOE
clothes dryer test procedure with a 7.00
± .07 lb load and at the increased test
load size of 8.45 ± .085 lb for standard-
size clothes dryers. For the ventless
clothes dryer test units, DOE
additionally used the proposed testing
method for ventless dryers presented in
section III.C.3. For each test load weight,
DOE conducted up to three tests for
each test unit and the results were
averaged. Table IV.4 below shows the
results from this testing, which indicate
that, on average, measured EF increases
by about 2.6 percent when the test load
weight is increased to 8.45 ± .085 lb for
standard-size clothes dryers. DOE
believes the 2.6 percent increase in
measured EF represents a more accurate
estimate than the 3.8 percent increase
because the 2.6 percent increase in
measured EF is based on more extensive
testing on a representative sample of
clothes dryers.
TABLE IV.4—DOE TEST RESULTS TO EVALUATE THE EFFECTS OF CHANGES TO TEST LOAD WEIGHT FOR STANDARD-SIZE
CLOTHES DRYERS
Average EF lb/kWh
Test unit
7.00 ± .07 lb
Vented Electric Standard:
Unit 1 ............................................................................................................................................
Unit 2 ............................................................................................................................................
Unit 3 ............................................................................................................................................
Unit 4 ............................................................................................................................................
Unit 5 ............................................................................................................................................
Unit 6 ............................................................................................................................................
Vented Gas:
Unit 7 ............................................................................................................................................
Unit 8 ............................................................................................................................................
Unit 9 ............................................................................................................................................
Unit 10 ..........................................................................................................................................
Unit 11 ..........................................................................................................................................
kgrant on DSKGBLS3C1PROD with BILLS
All Active Mode Amendments
DOE also analyzed how the fully
amended test procedure would affect
the measured EF as compared to the
existing test procedure. In the June 2010
TP SNOPR, DOE tested and analyzed
minimally compliant clothes dryers,
and reviewed available research. DOE
found that the proposed amendments to
the initial RMC would increase the
measured EF of minimally compliant
clothes dryers by 41 percent, while the
proposed amendments to the test load
size for standard-size clothes dryers
would increase the measured EF for
standard-size dryers by 3.8 percent.
DOE also found that because of the
proposed amendments in the June 2010
TP SNOPR, the measured EF of
minimally compliant clothes dryers
would increase by about 41 percent for
compact-size clothes dryers and about
46 percent for standard-size clothes
dryers (determined multiplying the 41
percent increase for the decrease in the
initial RMC by the 3.8 percent increase
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Jkt 223001
for the increase in test load size for
standard-size clothes dryers). 75 FR
37594, 37638 (June 29, 2010).
The Joint Petitioners stated that the
final rule amending the clothes dryer
test procedure should also amend the
standards in their Joint Petition. The
standards in the Joint Petition would be
amended according to the procedures in
section 323(e)(2), except that to
establish a representative sample of
products, DOE shall choose a sample of
minimally compliant clothes dryers that
automatically terminate the drying cycle
at no less than 4 percent RMC. (Joint
Petitioners, No. 25 at p. 6) In conducting
the analysis under 42 U.S.C. 6293(3)(2)
for the current clothes dryer energy
conservation standards, DOE notes that
as discussed in section I, EPCA requires
that in determining the amended energy
conservation standard, DOE must
measure, pursuant to the amended test
procedure, the energy efficiency, energy
use, or water use of a representative
sample of covered products that
minimally comply with the existing
PO 00000
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8.45 ± .085 lb
Percent
change
3.07
3.14
3.20
3.28
3.24
3.12
3.13
3.21
3.28
3.50
3.34
3.13
2.0
2.1
2.5
6.7
3.1
0.4
2.78
2.83
2.85
2.80
2.98
2.85
2.93
3.00
2.77
3.02
2.5
3.3
5.2
¥0.9
1.5
standard and that the average of such
energy efficiency, energy use, or water
use levels determined under the
amended test procedure shall constitute
the amended energy conservation
standard for the applicable covered
products. (42 U.S.C. 6293(e)(2)) DOE
notes that EPCA requires testing of a
representative sample of minimally
compliant products, and that the
measurement of only clothes dryers that
automatically terminate the drying cycle
at no less than 4 percent RMC would
not constitute a representative sample.
In addition, for the reasons discussed in
section III.C.2, DOE is not adopting in
today’s final rule the amendments for
automatic cycle termination proposed in
the June 2010 TP SNOPR. For these
reasons, DOE does not intend to
consider such limitations for product
testing to determine the effects of the
amended test procedure on the
measured efficiency.
DOE conducted clothes dryer testing
on a sample of 17 representative clothes
dryers after issuance of the June 2010
E:\FR\FM\06JAR2.SGM
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Federal Register / Vol. 76, No. 4 / Thursday, January 6, 2011 / Rules and Regulations
TP SNOPR to evaluate the effects of all
of the amendments on the clothes dryer
test procedure on the measured EF. DOE
tested these units according to the
amended clothes dryer test procedure in
today’s final rule. DOE conducted up to
three tests for each test unit and the
results were averaged. The results from
this testing are shown in Table IV.5. For
vented electric standard-size clothes
dryers, the measured EF increases by an
average of about 20.1 percent as a result
of the amendments to the test procedure
in today’s final rule. For vented gas
clothes dryers, the measured EF
increased by an average of about 19.8
percent. For vented electric compactsize 120V and 240V clothes dryers, the
measured EF increased by an average of
about 15.6 and 12.8 percent,
respectively. For ventless electric
compact 240V clothes dryers and
ventless electric combination washer/
dryers, the measured EF increased by an
average of about 13.6 and 11.4 percent,
respectively. DOE notes that the
increase in measured EF is greater for
the standard-size products (that is, for
vented electric standard-size and vented
gas clothes dryers) than for compact-size
products due to the additional
amendments that specify increased test
load sizes for standard-size products.
These measured increases in EF are
different from the values presented in
the June 2010 TP SNOPR, and shown
above in this section. This is because
the initial RMC was changed from 47
percent to 57.5 percent and the change
to the water temperature specified for
test load preparation. These values are
also based on more extensive testing on
a representative sample of clothes
dryers.
TABLE IV.5—DOE TEST RESULTS TO EVALUATE THE EFFECTS OF THE TEST PROCEDURE AMENDMENTS ON MEASURED
EF
Average EF lb/kWh
Test unit
Current test
procedure
Vented Electric Standard:
Unit 1 ............................................................................................................................................
Unit 2 ............................................................................................................................................
Unit 3 ............................................................................................................................................
Unit 4 ............................................................................................................................................
Unit 5 ............................................................................................................................................
Unit 6 ............................................................................................................................................
Vented Gas:
Unit 7 ............................................................................................................................................
Unit 8 ............................................................................................................................................
Unit 9 ............................................................................................................................................
Unit 10 ..........................................................................................................................................
Unit 11 ..........................................................................................................................................
Vented Electric Compact (240V):
Unit 12 ..........................................................................................................................................
Unit 13 ..........................................................................................................................................
Vented Electric Compact (120V):
Unit 14 ..........................................................................................................................................
Ventless Electric Compact (240V):
Unit 15 ..........................................................................................................................................
Ventless Electric Combo Washer-Dryer:
Unit 16 ..........................................................................................................................................
Unit 17 ..........................................................................................................................................
Table IV.6 shows how the current
energy conservation standards would be
affected by the amendments to the DOE
clothes dryer test procedure. DOE will
consider such changes in the concurrent
energy conservation standards
Amended test
procedure
Percent
change
3.07
3.14
3.20
3.28
3.24
3.12
3.69
3.77
3.83
3.92
3.96
3.72
20.4
19.5
19.6
19.4
22.5
19.1
2.78
2.83
2.85
2.80
2.98
3.36
3.40
3.42
3.37
3.50
20.6
19.9
20.2
20.5
17.6
3.19
2.93
3.56
3.35
11.4
14.2
3.23
3.74
15.6
2.37
2.69
13.6
2.01
2.50
2.27
2.76
12.5
10.3
rulemaking for clothes dryers and room
air conditioners.
TABLE IV.6—ENERGY FACTOR OF A MINIMALLY COMPLIANT CLOTHES DRYER WITH THE CURRENT AND PROPOSED
AMENDED TEST PROCEDURE
Energy factor lb/kWh
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Product class
1.
2.
3.
4.
Current test
procedure
Electric, Standard (4.4 ft3 or greater capacity) ...........................................................................................................
Electric, Compact (120 v) (less than 4.4 ft3 capacity) ................................................................................................
Electric, Compact (240 v) (less than 4.4 ft3 capacity) ................................................................................................
Gas ..............................................................................................................................................................................
Because the clothes dryer test
procedure amendments for active mode
would substantially change the existing
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EF metric, DOE has decided to create a
new appendix D1 in 10 CFR 430 subpart
B. This appendix contains a clothes
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3.01
3.13
2.90
2.67
Proposed
amended
test
procedure
3.62
3.62
3.27
3.20
dryer test procedure that manufacturers
would be required to use on the
mandatory compliance date of any
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amended clothes dryer energy
conservation standards. DOE is required
by consent decree to publish the final
rule for any amended clothes dryer
energy conservation standards
rulemaking by June 30, 2011, and the
compliance date of any amended
standards is expected to be 3 years later.
Manufacturers must continue to use
appendix D to subpart B of part 430 for
clothes dryers until compliance with
any amended energy conservation
standards at 10 CFR 430.32(h) is
required, at which point use of the
procedures at appendix D1 will be
required.
C. Active Mode—Room Air Conditioners
As discussed in section III.C.6, DOE
amends the room air conditioner test
procedure in today’s final rule to update
the references to the industry test
standards, ANSI/AHAM RAC–1–R2008
and ANSI/ASHRAE Standard 16–1983
(RA 2009). These amendments provide
more accurate and repeatable
measurements of capacity while
providing greater flexibility to
manufacturers in selecting equipment
and facilities but do not impact the
measurement of EER. Because DOE’s
review of the room air conditioner test
procedure amendments tentatively
concluded that the measured EER
would not be affected, manufacturers
must continue to use appendix F to
measure room air conditioner active
mode energy use. Manufacturers would
not be required to use the proposed
provisions for standby mode and off
mode energy use (specifically, sections
2.2, 3.2, 4.2, and 5.3) until the
mandatory compliance date of any
amended room air conditioner energy
conservation standards.
The Joint Petitioners proposed that
the final rule amending the room air
conditioner test procedure must also
amend the standards in the Joint
Petition according to the procedures in
section 323(e)(2). (Joint Petitioners, No.
25 at p. 7) As noted above, DOE believes
that the amendments to the room air
conditioner test procedure in today’s
final rule would not affect the measured
efficiency of covered products, and DOE
is not aware of any data indicating
otherwise. For these reasons, DOE
continues to believe that revisions to the
energy conservation standards for room
air conditioners are not warranted.
All representations related to standby
mode and off mode energy consumption
of both clothes dryers and room air
conditioners made 180 days after the
publication of today’s test procedure
final rule in the Federal Register and
before the compliance date of amended
energy conservation standards must be
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American Industry Classification
System (NAICS).42 The threshold
number for NAICS classification for
335224, ‘‘Household Laundry
Equipment Manufacturing,’’ which
includes clothes dryer manufacturers, is
1,000 employees. Additionally, the
V. Procedural Requirements
threshold number for NAICS
A. Review Under Executive Order 12866 classification for 335415, ‘‘AirThe Office of Management and Budget Conditioning and Warm Air Heating
Equipment and Commercial and
has determined that test procedure
Industrial Refrigeration Equipment
rulemakings do not constitute
Manufacturing,’’ which includes room
‘‘significant regulatory actions’’ under
air conditioner manufacturers, is 750
section 3(f) of Executive Order 12866,
Regulatory Planning and Review, 58 FR employees.
Most of the manufacturers supplying
51735 (Oct. 4, 1993). Accordingly, this
clothes dryers and room air conditioners
proposed action was not subject to
review under the Executive Order by the are large multinational corporations. As
part of the energy conservation
Office of Information and Regulatory
standards rulemaking for residential
Affairs (OIRA) in the Office of
clothes dryers and room air
Management and Budget (OMB).
conditioners, DOE requested comment
B. Review Under the Regulatory
on whether there are any manufacturer
Flexibility Act
subgroups, including potential small
businesses, that it should consider for
The Regulatory Flexibility Act (5
its analyses. DOE did not receive any
U.S.C. 601 et seq.) requires preparation
comments regarding whether there are
of an initial regulatory flexibility
any residential clothes dryer or room air
analysis for any rule that by law must
be proposed for public comment, unless conditioner manufacturers that would
be considered small businesses. DOE
the agency certifies that the rule, if
promulgated, will not have a significant then conducted a more focused inquiry
of the companies that could be small
economic impact on a substantial
number of small entities. As required by business manufacturers of products
covered by this rulemaking. During its
Executive Order 13272, ‘‘Proper
market survey, DOE used all available
Consideration of Small Entities in
Agency Rulemaking,’’ 67 FR 53461 (Aug. public information to identify potential
small manufacturers. DOE’s research
16, 2002), DOE published procedures
included the AHAM membership
and policies on February 19, 2003 to
directory, product databases (the AHRI,
ensure that the potential impacts of its
AHAM, CEC, and ENERGY STAR
rules on small entities are properly
databases), individual company
considered during the rulemaking
websites, and the SBA dynamic small
process. 68 FR 7990. DOE’s procedures
business search 43 to find potential small
and policies may be viewed on the
Office of the General Counsel’s Web site business manufacturers. DOE also asked
interested parties and industry
(https://www.gc.doe.gov).
DOE reviewed today’s final rule under representatives if they were aware of
any other small business manufacturers
the provisions of the Regulatory
during manufacturer interviews
Flexibility Act and the procedures and
conducted and at DOE public meetings
policies published on February 19,
for the energy conservation standards
2003. This final rule prescribes
amendments to test procedures that will rulemakings. DOE also contacted
various companies, as necessary, to
be used to test compliance with energy
determine whether they met the SBA’s
conservation standards for clothes
definition of a small business
dryers and room air conditioners that
manufacturer of covered residential
are described in detail elsewhere in the
clothes dryers or room air conditioners.
preamble. DOE certifies that this final
DOE screened out companies that did
rule will not have a significant impact
not offer products covered by this
on a substantial number of small
rulemaking, did not meet the definition
entities. The factual basis for this
of a ‘‘small business,’’ or are foreign
certification is as follows.
owned and operated.
The Small Business Administration
DOE initially identified at least 14
(SBA) considers an entity to be a small
business if, together with its affiliates, it manufacturers of residential clothes
employs less than a threshold number of
42 For more information visit: https://
workers specified in 13 CFR part 121.
www.sba.gov/.
The thresholds set forth in these
43 A searchable database of certified small
regulations are based on size standards
businesses is available online at: https://
dsbs.sba.gov/dsbs/search/dsp_dsbs.cfm.
and codes established by the North
based upon the standby mode and off
mode requirements of the amended test
procedures. The requirements are
specified in appendix D1 for clothes
dryers, and in amended appendix F for
room air conditioners.
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dryers that sold products in the United
States. DOE determined that 13 of these
companies exceeded the SBA’s
maximum number of employees or
foreign-owned and operated. Thus, DOE
identified only one potential small
business manufacturer of residential
clothes dryers but could not locate this
manufacturer on the dynamic small
business search on the SBA website. In
addition, upon further review, DOE
does not believe that the small business
is a clothes dryer manufacturer. While
the manufacturer has developed a
highly efficient technology that, while
not yet commercially available, could be
used by other manufacturers to increase
the efficiency of clothes dryers, it does
not produce clothes dryers. Because the
company plans to produce only a
technology for clothes dryers that is not
yet commercially available, this
potential small business manufacturer
has no market share of the residential
clothes dryer market.
For room air conditioners, DOE
initially identified at least 11
manufacturers of room air conditioners
that sold products in the United States.
DOE determined that 10 of these were
large or foreign-owned and operated. In
addition, DOE subsequently determined
that the one room air conditioner
manufacturer that was previously
designated as a small business
manufacturer now exceeds SBA’s
employment threshold for consideration
as a small business under the
appropriate NAICS code specified
above.
DOE received no comments on the
certification, and comments on the
testing burden are discussed elsewhere
in the preamble and did not result in
changes to the certification. For these
reasons, DOE certifies that the
amendments in today’s final rule will
not have a significant economic impact
on a substantial number of small
entities.
Based on the above, DOE has not
prepared a regulatory flexibility analysis
for this rulemaking. DOE transmitted
the certification and supporting
statement of factual basis to the Chief
Counsel for Advocacy of the SBA for
review under 5 U.S.C. 605(b).
C. Review Under the Paperwork
Reduction Act of 1995
Manufacturers of clothes dryers and
room air conditioners must certify to
DOE that their products comply with
any applicable energy conservation
standard. In certifying compliance,
manufacturers must test their products
according to the DOE test procedures for
clothes dryers and room air
conditioners, including any
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amendments adopted for those test
procedures. DOE has proposed
regulations for the certification and
recordkeeping requirements for all
covered consumer products and
commercial equipment, including
clothes dryers and room air
conditioners. 75 FR 56796 (Sept. 16,
2010). The collection-of-information
requirement for the certification and
recordkeeping is subject to review and
approval by OMB under the Paperwork
Reduction Act (PRA). This requirement
has been submitted to OMB for
approval. Public reporting burden for
the certification is estimated to average
20 hours per response, including the
time for reviewing instructions,
searching existing data sources,
gathering and maintaining the data
needed, and completing and reviewing
the collection of information.
Public comment is sought regarding:
Whether this proposed collection of
information is necessary for the proper
performance of the functions of the
agency, including whether the
information shall have practical utility;
the accuracy of the burden estimate;
ways to enhance the quality, utility, and
clarity of the information to be
collected; and ways to minimize the
burden of the collection of information,
including through the use of automated
collection techniques or other forms of
information technology. Send comments
on these or any other aspects of the
collection of information to Subid
Wagley at the ADDRESSES above, and
e-mail to
Christine_J._Kymn@omb.eop.gov.
Notwithstanding any other provision
of the law, no person is required to
respond to, nor shall any person be
subject to a penalty for failure to comply
with, a collection of information subject
to the requirements of the PRA, unless
that collection of information displays a
currently valid OMB Control Number.
D. Review Under the National
Environmental Policy Act of 1969
In this final rule, DOE is adopting test
procedure amendments that it expects
will be used to develop and implement
future energy conservation standards for
clothes dryers and room air
conditioners. DOE has determined that
this rule falls into a class of actions that
are categorically excluded from review
under the National Environmental
Policy Act of 1969 (42 U.S.C. 4321 et
seq.) and DOE’s implementing
regulations at 10 CFR part 1021.
Specifically, this rule amends an
existing rule without changing its
environmental effect, and, therefore, is
covered by the Categorical Exclusion in
10 CFR part 1021, subpart D, paragraph
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1029
A5, which applies because this rule
establishes revisions to existing test
procedures that will not affect the
amount, quality, or distribution of
energy usage, and, therefore, will not
result in any environmental impacts.
Accordingly, neither an environmental
assessment nor an environmental
impact statement is required.
E. Review Under Executive Order 13132
Executive Order 13132, ‘‘Federalism,’’
imposes certain requirements on
agencies formulating and implementing
policies or regulations that preempt
State law or that have Federalism
implications. 64 FR 43255 (August 10,
1999). The Executive Order requires
agencies to examine the constitutional
and statutory authority supporting any
action that would limit the
policymaking discretion of the States,
and to carefully assess the necessity for
such actions. The Executive Order also
requires agencies to have an accountable
process to ensure meaningful and timely
input by State and local officials in the
development of regulatory policies that
have Federalism implications. On
March 14, 2000, DOE published a
statement of policy describing the
intergovernmental consultation process
that it will follow in developing such
regulations. 65 FR 13735. DOE
examined this final rule and determined
that it will not preempt State law and
will not have a substantial direct effect
on the States, on the relationship
between the national government and
the States, or on the distribution of
power and responsibilities among the
various levels of government. EPCA
governs and prescribes Federal
preemption of State regulations as to
energy conservation for the products
that are the subject of today’s final rule.
States can petition DOE for exemption
from such preemption to the extent, and
based on criteria, set forth in EPCA. (42
U.S.C. 6297(d)) Therefore, Executive
Order 13132 requires no further action.
F. Review Under Executive Order 12988
Regarding the review of existing
regulations and the promulgation of
new regulations, section 3(a) of
Executive Order 12988, ‘‘Civil Justice
Reform,’’ 61 FR 4729 (Feb. 7, 1996),
imposes on Federal agencies the general
duty to adhere to the following
requirements: (1) Eliminate drafting
errors and ambiguity; (2) write
regulations to minimize litigation;
(3) provide a clear legal standard for
affected conduct rather than a general
standard; and (4) promote simplification
and burden reduction. Section 3(b) of
Executive Order 12988 specifically
requires that Executive agencies make
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every reasonable effort to ensure that the
regulation specifies the following: (1)
The preemptive effect, if any; (2) any
effect on existing Federal law or
regulation; (3) a clear legal standard for
affected conduct while promoting
simplification and burden reduction;
(4) the retroactive effect, if any; (5)
definitions of key terms; and (6) other
important issues affecting clarity and
general draftsmanship under any
guidelines issued by the Attorney
General. Section 3(c) of Executive Order
12988 requires Executive agencies to
review regulations in light of applicable
standards in sections 3(a) and 3(b) to
determine whether they are met or
whether it is unreasonable to meet one
or more of them. DOE has completed the
required review and determined that, to
the extent permitted by law, this final
rule meets the relevant standards of
Executive Order 12988.
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G. Review Under the Unfunded
Mandates Reform Act of 1995
Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA) (Pub. L.
104–4; 2 U.S.C. 1501 et seq.) requires
each Federal agency to assess the effects
of Federal regulatory actions on State,
local, and Tribal governments and the
private sector. For a proposed regulatory
action likely to result in a rule that may
cause the expenditure by State, local,
and Tribal governments, in the
aggregate, or by the private sector of
$100 million or more in any one year
(adjusted annually for inflation), section
202 of UMRA requires a Federal agency
to publish estimates of the resulting
costs, benefits, and other effects on the
national economy. (2 U.S.C. 1532(a),(b))
UMRA also requires a Federal agency to
develop an effective process to permit
timely input by elected officers of State,
local, and Tribal governments on a
proposed ‘‘significant intergovernmental
mandate,’’ and requires an agency plan
for giving notice and opportunity for
timely input to potentially affected
small governments before establishing
any requirements that might
significantly or uniquely affect such
governments. On March 18, 1997, DOE
published a statement of policy on its
process for intergovernmental
consultation under UMRA. 62 FR
12820. (The policy is also available at
https://www.gc.doe.gov). DOE reviewed
today’s final rule under the statutory
requirements and its policy and
determined that the rule contains
neither an intergovernmental mandate
nor a mandate that may result in an
expenditure of $100 million or more in
any year, so these requirements do not
apply.
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H. Review Under the Treasury and
General Government Appropriations
Act, 1999
Section 654 of the Treasury and
General Government Appropriations
Act, 1999 (Pub. L. 105–277) requires
Federal agencies to issue a Family
Policymaking Assessment for any rule
that may affect family well-being.
Today’s final rule will not have any
impact on the autonomy or integrity of
the family as an institution.
Accordingly, DOE has concluded that it
is not necessary to prepare a Family
Policymaking Assessment.
I. Review Under Executive Order 12630
DOE has determined, under Executive
Order 12630, ‘‘Governmental Actions
and Interference with Constitutionally
Protected Property Rights,’’ 53 FR 8859
(March 18, 1988), that this regulation
will not result in any takings that might
require compensation under the Fifth
Amendment to the U.S. Constitution.
J. Review Under the Treasury and
General Government Appropriations
Act, 2001
Section 515 of the Treasury and
General Government Appropriations
Act, 2001 (44 U.S.C. 3516 note) provides
for agencies to review most
disseminations of information to the
public under guidelines established by
each agency pursuant to general
guidelines issued by OMB. OMB’s
guidelines were published at 67 FR
8452 (Feb. 22, 2002), and DOE’s
guidelines were published at 67 FR
62446 (Oct. 7, 2002). DOE has reviewed
today’s final rule under OMB and DOE
guidelines and has concluded that it is
consistent with applicable policies in
those guidelines.
K. Review Under Executive Order 13211
Executive Order 13211, ‘‘Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use,’’ 66 FR 28355 (May
22, 2001), requires Federal agencies to
prepare and submit to OIRA a Statement
of Energy Effects for any proposed
significant energy action. A ‘‘significant
energy action’’ is defined as any action
by an agency that promulgates or is
expected to lead to promulgation of a
final rule, and that: (1) Is a significant
regulatory action under Executive Order
12866, or any successor order; and (2)
is likely to have a significant adverse
effect on the supply, distribution, or use
of energy; or (3) is designated by the
Administrator of OIRA as a significant
energy action. For any proposed
significant energy action, the agency
must give a detailed statement of any
adverse effects on energy supply,
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distribution, or use if the proposal is
implemented, and of reasonable
alternatives to the action and their
expected benefits on energy supply,
distribution, and use. Today’s regulatory
action to establish amended test
procedures for clothes dryers and room
air conditioners is not a significant
regulatory action under Executive Order
12866. It has likewise not been
designated as a significant energy action
by the Administrator of OIRA.
Moreover, it will not have a significant
adverse effect on the supply,
distribution, or use of energy. Therefore,
it is not a significant energy action, and,
accordingly, DOE has not prepared a
Statement of Energy Effects.
L. Review Under Section 32 of the
Federal Energy Administration Act of
1974
Under section 301 of the DOE
Organization Act (Pub. L. 95–91; 42
U.S.C. 7101 et seq.), DOE must comply
with section 32 of the Federal Energy
Administration Act of 1974, as amended
by the Federal Energy Administration
Authorization Act of 1977 (FEAA). (15
U.S.C. 788) Section 32 essentially
provides in part that, where a proposed
rule authorizes or requires use of
commercial standards, the rulemaking
must inform the public of the use and
background of such standards. In
addition, section 32(c) requires DOE to
consult with the Attorney General and
the Chairman of the Federal Trade
Commission (FTC) concerning the
impact of the commercial or industry
standards on competition.
The amendments to the test
procedures in today’s final rule
incorporate testing methods contained
in the commercial standard, IEC
Standard 62301. Specifically DOE is
incorporating from section 4, (‘‘General
conditions for measurements’’),
paragraph 4.2, ‘‘Test room,’’ paragraph
4.3, ‘‘Power supply,’’ paragraph 4.4,
‘‘Supply voltage waveform,’’ and
paragraph 4.5, ‘‘Power measurement
accuracy,’’ and from section 5
(‘‘Measurements’’), paragraph 5.1,
‘‘General,’’ paragraph 5.2, ‘‘Selection and
preparation of appliance or equipment,’’
and paragraph 5.3, ‘‘Procedure’’ of IEC
Standard 62301. DOE has evaluated this
standard and is unable to conclude
whether it fully complies with the
requirements of section 32(b) of the
FEAA (that is, whether it was developed
in a manner that fully provides for
public participation, comment, and
review.) DOE has consulted with the
Attorney General and the Chairman of
the FTC about the impact on
competition of using the methods
contained in this standard, and neither
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recommended against incorporation of
these standards.
M. Congressional Notification
As required by 5 U.S.C. 801, DOE will
report to Congress on the promulgation
of today’s rule before its effective date.
The report will state that it has been
determined that the rule is not a ‘‘major
rule’’ as defined by 5 U.S.C. 801(2).
VI. Approval of the Office of the
Secretary
The Secretary of Energy has approved
publication of today’s final rule.
List of Subjects in 10 CFR Part 430
Administrative practice and
procedure, Confidential business
information, Energy conservation,
Household appliances, Imports,
Incorporation by reference,
Intergovernmental relations, Small
businesses.
§ 430.23 Test procedures for the
measurement of energy and water
consumption.
Issued in Washington, DC, on December
15, 2010.
Cathy Zoi,
Assistant Secretary, Energy Efficiency and
Renewable Energy.
*
For the reasons stated in the preamble,
part 430 of chapter II of title 10, of the
Code of Federal Regulations, is
amended as set forth below:
■
PART 430—ENERGY CONSERVATION
PROGRAM FOR CONSUMER
PRODUCTS
1. The authority citation for part 430
continues to read as follows:
■
Authority: 42 U.S.C. 6291–6309; 28 U.S.C.
2461 note.
2. Section 430.3 is amended by:
a. Redesignating paragraphs (e)(1)
through (e)(9) as (e)(2) through (e)(10).
■ b. Adding a new paragraph (e)(1).
■ c. Removing the word ‘‘Standard’’ from
paragraph (g)(3).
■ d. Redesignating paragraphs (g)(1), (2),
and (3) as paragraphs (g)(3), (1), and (4),
respectively.
■ e. Adding new paragraphs (g)(2) and
(5).
■ d. Removing in paragraph (1)(1),
‘‘Appendix N to Subpart B’’, and adding
in its place, ‘‘Appendix D1, Appendix F
and Appendix N to Subpart B’’.
The additions read as follows:
■
■
§ 430.3 Materials incorporated by
reference.
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*
*
*
*
*
(e) * * *
(1) ANSI/ASHRAE Standard 16–1983
(‘‘ANSI/ASHRAE 16’’) (RA 2009),
(Reaffirmation of ANSI/ASHRAE
Standard 16–1983 [RA 1999]), Method
of Testing for Rating Room Air
Conditioners and Packaged Terminal
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Air Conditioners, ASHRAE approved
October 18, 1988, and reaffirmed June
20, 2009. ANSI approved October 20,
1998 and reaffirmed June 25, 2009. IBR
approved for Appendix F to Subpart B.
*
*
*
*
*
(g) * * *
(2) AHAM HLD–1–2009 (‘‘AHAM
HLD–1’’), Household Tumble Type
Clothes Dryers, (2009), IBR approved for
Appendix D1 to Subpart B.
*
*
*
*
*
(5) ANSI/AHAM RAC–1–2008
(‘‘ANSI/AHAM RAC–1’’), Room Air
Conditioners, (2008; ANSI approved
July 7, 2008), IBR approved for
Appendix F to Subpart B.
*
*
*
*
*
■ 3. Section 430.23 is amended by
revising paragraphs (d) and (f) to read as
follows:
*
*
*
*
(d) Clothes dryers. (1) The estimated
annual operating cost for clothes dryers
shall be—
(i) For an electric clothes dryer, the
product of the following three factors:
(A) The representative average-use
cycle of 283 cycles per year,
(B) The per-cycle combined total
energy consumption in kilowatt-hours
per-cycle, determined according to 4.6
of appendix D1 to this subpart, and
(C) The representative average unit
cost of electrical energy in dollars per
kilowatt-hour as provided by the
Secretary, the resulting product then
being rounded off to the nearest dollar
per year, and
(ii) For a gas clothes dryer, the
product of the representative averageuse cycle of 283 cycles per year times
the sum of:
(A) The product of the per-cycle gas
dryer electric energy consumption in
kilowatt-hours per cycle, determined
according to 4.2 of appendix D1 to this
subpart, times the representative
average unit cost of electrical energy in
dollars per kilowatt-hour as provided by
the Secretary plus,
(B) The product of the per-cycle gas
dryer gas energy consumption, in Btus
per cycle, determined according to 4.3
of appendix D1 to this subpart, times
the representative average unit cost for
natural gas or propane, as appropriate,
in dollars per Btu as provided by the
Secretary, the resulting product then
being rounded off to the nearest dollar
per year plus,
(C) The product of the per-cycle
standby mode and off mode energy
consumption in kilowatt-hours per
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cycle, determined according to 4.5 of
appendix D1 to this subpart, times the
representative average unit cost of
electrical energy in dollars per kilowatthour as provided by the Secretary.
(2) The energy factor, expressed in
pounds of clothes per kilowatt-hour, for
clothes dryers shall be either the
quotient of a 3-pound bone-dry test load
for compact dryers, as defined by 2.7.1
of appendix D to this subpart before the
date that appendix D1 becomes
mandatory, or the quotient of a 7-pound
bone-dry test load for standard dryers,
as defined by 2.7.2 of appendix D to this
subpart before the date that appendix
D1 becomes mandatory, as applicable,
divided by the clothes dryer energy
consumption per cycle, as determined
according to 4.1 for electric clothes
dryers and 4.6 for gas clothes dryers of
appendix D to this subpart before the
date that appendix D1 becomes
mandatory, the resulting quotient then
being rounded off to the nearest
hundredth (.01). Upon the date that
appendix D1 to this subpart becomes
mandatory, the energy factor is
determined in accordance with 4.7 of
appendix D1, the result then being
rounded off to the nearest hundredth
(.01).
(3) Upon the date that appendix D1 to
this subpart becomes mandatory, the
combined energy factor is determined in
accordance with 4.8 of appendix D1, the
result then being rounded off to the
nearest hundredth (.01).
(4) Other useful measures of energy
consumption for clothes dryers shall be
those measures of energy consumption
for clothes dryers which the Secretary
determines are likely to assist
consumers in making purchasing
decisions and which are derived from
the application of appendix D to this
subpart before the date that appendix
D1 becomes mandatory and appendix
D1 upon the date that appendix D1 to
this subpart becomes mandatory.
*
*
*
*
*
(f) Room air conditioners. (1) The
estimated annual operating cost for
room air conditioners, expressed in
dollars per year, shall be determined by
multiplying the following three factors:
(i) The combined annual energy
consumption for room air conditioners,
expressed in kilowatt-hours per year, as
determined in accordance with
paragraph (f)(4) of this section, and
(ii) A representative average unit cost
of electrical energy in dollars per
kilowatt-hour as provided by the
Secretary, the resulting product then
being rounded off to the nearest dollar
per year.
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(2) The energy efficiency ratio for
room air conditioners, expressed in Btus
per watt-hour, shall be the quotient of:
(i) The cooling capacity in Btus per
hour as determined in accordance with
5.1 of appendix F to this subpart
divided by:
(ii) The electrical input power in
watts as determined in accordance with
5.2 of appendix F to this subpart, the
resulting quotient then being rounded
off to the nearest 0.1 Btu per watt-hour.
(3) The average annual energy
consumption for room air conditioners,
expressed in kilowatt-hours per year,
shall be determined by multiplying
together the following two factors:
(i) Electrical input power in kilowatts
as determined in accordance with 5.2 of
appendix F to this subpart, and
(ii) The representative average-use
cycle of 750 hours of compressor
operation per year, the resulting product
then being rounded off to the nearest
kilowatt-hour per year.
(4) The combined annual energy
consumption for room air conditioners,
expressed in kilowatt-hours per year,
shall be the sum of:
(i) The average annual energy
consumption as determined in
accordance with paragraph (f)(4) of this
section, and
(ii) The standby mode and off mode
energy consumption, as determined in
accordance with 5.3 of appendix F to
this subpart, the resulting sum then
being rounded off to the nearest
kilowatt-hour per year.
(5) The combined energy efficiency
ratio for room air conditioners,
expressed in Btu’s per watt-hour, shall
be the quotient of:
(i) The cooling capacity in Btus per
hour as determined in accordance with
5.1 of appendix F to this subpart
multiplied by the representative
average-use cycle of 750 hours of
compressor operation per year, divided
by
(ii) The combined annual energy
consumption as determined in
accordance with paragraph (f)(4) of this
section multiplied by a conversion
factor of 1,000 to convert kilowatt-hours
to watt-hours, the resulting quotient
then being rounded off to the nearest 0.1
Btu per watt-hour.
*
*
*
*
*
■ 4. Appendix D to subpart B of part 430
is amended by adding introductory note
to read as follows:
Appendix D to Subpart B of Part 430–
Uniform Test Method for Measuring the
Energy Consumption of Clothes Dryers
Note: Manufacturers must continue to use
appendix D to subpart B of part 430 until the
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energy conservation standards for clothes
dryers at 10 CFR 430.32(h) are amended to
require mandatory compliance using
appendix D1.
*
*
*
*
*
5. Appendix D1 is added to subpart B
of part 430 to read as follows:
■
Appendix D1 to Subpart B of Part 430–
Uniform Test Method for Measuring the
Energy Consumption of Clothes Dryers
Note: Appendix D1 to subpart B of part 430
is informational only. Manufacturers must
continue to use appendix D to subpart B of
part 430 until compliance with any amended
energy conservation standards for clothes
dryers at 10 CFR 430.32(h) is required, at
which time manufacturers must use
appendix D1.
1. Definitions
1.1 ‘‘Active mode’’ means a mode in
which the clothes dryer is connected to a
main power source, has been activated and
is performing the main function of tumbling
the clothing with or without heated or
unheated forced air circulation to remove
moisture from the clothing, remove wrinkles
or prevent wrinkling of the clothing, or both.
1.2 ‘‘AHAM’’ means the Association of
Home Appliance Manufacturers.
1.3 ‘‘AHAM HLD–1’’ means the test
standard published by the Association of
Home Appliance Manufacturers, titled
‘‘Household Tumble Type Clothes Dryers’’
(2009), AHAM HLD–1–2009 (incorporated by
reference; see § 430.3).
1.4 ‘‘Automatic termination control’’
means a dryer control system with a sensor
which monitors either the dryer load
temperature or its moisture content and with
a controller which automatically terminates
the drying process. A mark, detent, or other
visual indicator or detent which indicates a
preferred automatic termination control
setting must be present if the dryer is to be
classified as having an ‘‘automatic
termination control.’’ A mark is a visible
single control setting on one or more dryer
controls.
1.5 ‘‘Bone dry’’ means a condition of a
load of test clothes which has been dried in
a dryer at maximum temperature for a
minimum of 10 minutes, removed, and
weighed before cool down, and then dried
again for 10-minute periods until the final
weight change of the load is 1 percent or less.
1.6 ‘‘Compact’’ or ‘‘compact size’’ means a
clothes dryer with a drum capacity of less
than 4.4 cubic feet.
1.7 ‘‘Conventional clothes dryer’’ means a
clothes dryer that exhausts the evaporated
moisture from the cabinet.
1.8 ‘‘Cool down’’ means that portion of
the clothes drying cycle when the added gas
or electric heat is terminated and the clothes
continue to tumble and dry within the drum.
1.9 ‘‘Cycle’’ means a sequence of
operation of a clothes dryer which performs
a clothes drying operation, and may include
variations or combinations of the functions of
heating, tumbling, and drying.
1.10 ‘‘Drum capacity’’ means the volume
of the drying drum in cubic feet.
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1.11 ‘‘IEC 62301’’ means the test standard
published by the International
Electrotechnical Commission (‘‘IEC’’), titled
‘‘Household electrical appliances–
Measurement of standby power,’’ Publication
62301 (first edition June 2005) (incorporated
by reference; see § 430.3).
1.12 ‘‘Inactive mode’’ means a standby
mode that facilitates the activation of active
mode by remote switch (including remote
control), internal sensor, or timer, or that
provides continuous status display.
1.13 ‘‘Moisture content’’ means the ratio
of the weight of water contained by the test
load to the bone-dry weight of the test load,
expressed as a percent.
1.14 ‘‘Moisture sensing control’’ means a
system which utilizes a moisture sensing
element within the dryer drum that monitors
the amount of moisture in the clothes and
automatically terminates the dryer cycle.
1.15 ‘‘Off mode’’ means a mode in which
the clothes dryer is connected to a main
power source and is not providing any active
or standby mode function, and where the
mode may persist for an indefinite time. An
indicator that only shows the user that the
product is in the off position is included
within the classification of an off mode.
1.16 ‘‘Standard size’’ means a clothes
dryer with a drum capacity of 4.4 cubic feet
or greater.
1.17 ‘‘Standby mode’’ means any product
modes where the energy using product is
connected to a main power source and offers
one or more of the following user-oriented or
protective functions which may persist for an
indefinite time:
(a) To facilitate the activation of other
modes (including activation or deactivation
of active mode) by remote switch (including
remote control), internal sensor, or timer.
(b) Continuous functions, including
information or status displays (including
clocks) or sensor-based functions. A timer is
a continuous clock function (which may or
may not be associated with a display) that
provides regular scheduled tasks (e.g.,
switching) and that operates on a continuous
basis.
1.18 ‘‘Temperature sensing control’’
means a system which monitors dryer
exhaust air temperature and automatically
terminates the dryer cycle.
1.19 ‘‘Ventless clothes dryer’’ means a
clothes dryer that uses a closed-loop system
with an internal condenser to remove the
evaporated moisture from the heated air. The
moist air is not discharged from the cabinet.
2. Testing Conditions
2.1 Installation. Install the clothes dryer
in accordance with manufacturer’s
instructions. For conventional clothes dryers,
as defined in 1.7, the dryer exhaust shall be
restricted by adding the AHAM exhaust
simulator described in 3.3.5.1 of AHAM
HLD–1 (incorporated by reference; see
§ 430.3). For ventless clothes dryers, as
defined in 1.19, the dryer shall be tested
without the AHAM exhaust simulator. Where
the manufacturer gives the option to use the
dryer both with and without a duct, the dryer
shall be tested without the exhaust simulator.
All external joints should be taped to avoid
air leakage. If the manufacturer gives the
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option to use a ventless clothes dryer, as
defined in 1.19, with or without a
condensation box, the dryer shall be tested
with the condensation box installed. For
ventless clothes dryers, the condenser unit of
the dryer must remain in place and not be
taken out of the dryer for any reason between
tests. For drying testing, disconnect all
console lights or other lighting systems on
the clothes dryer which do not consume
more than 10 watts during the clothes dryer
test cycle. For standby and off mode testing,
the clothes dryer shall also be installed in
accordance with section 5, paragraph 5.2 of
IEC 62301 (incorporated by reference; see
§ 430.3). For standby and off mode testing, do
not disconnect console lights or other
lighting systems.
2.2 Ambient temperature and humidity.
2.2.1 For drying testing, maintain the
room ambient air temperature at 75 ± 3 ° F
and the room relative humidity at 50 ± 10
percent relative humidity.
2.2.2 For standby and off mode testing,
maintain room ambient air temperature
conditions as specified in section 4,
paragraph 4.2 of IEC 62301 (incorporated by
reference; see § 430.3).
2.3 Energy supply.
2.3.1 Electrical supply. Maintain the
electrical supply at the clothes dryer terminal
block within 1 percent of
120/240 or 120/208Y or 120 volts as
applicable to the particular terminal block
wiring system and within 1 percent of the
nameplate frequency as specified by the
manufacturer. If the dryer has a dual voltage
conversion capability, conduct the test at the
highest voltage specified by the
manufacturer.
2.3.1.1 Supply voltage waveform. For the
clothes dryer standby mode and off mode
testing, maintain the electrical supply voltage
waveform indicated in section 4, paragraph
4.4 of IEC 62301 (incorporated by reference;
see § 430.3).
2.3.2 Gas supply.
2.3.2.1 Natural gas. Maintain the gas
supply to the clothes dryer immediately
ahead of all controls at a pressure of 7 to 10
inches of water column. If the clothes dryer
is equipped with a gas appliance pressure
regulator for which the manufacturer
specifies an outlet pressure, the regulator
outlet pressure shall be approximately that
recommended by the manufacturer. The
hourly Btu rating of the burner shall be
maintained within ± 5 percent of the rating
specified by the manufacturer. The natural
gas supplied should have a heating value of
approximately 1,025 Btus per standard cubic
foot. The actual heating value, Hn2, in Btus
per standard cubic foot, for the natural gas to
be used in the test shall be obtained either
from measurements made by the
manufacturer conducting the test using a
standard continuous flow calorimeter as
described in 2.4.6 or by the purchase of
bottled natural gas whose Btu rating is
certified to be at least as accurate a rating as
could be obtained from measurements with
a standard continuous flow calorimeter as
described in 2.4.6.
2.3.2.2 Propane gas. Maintain the gas
supply to the clothes dryer immediately
ahead of all controls at a pressure of 11 to
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13 inches of water column. If the clothes
dryer is equipped with a gas appliance
pressure regulator for which the
manufacturer specifies an outlet pressure, the
regulator outlet pressure shall be
approximately that recommended by the
manufacturer. The hourly Btu rating of the
burner shall be maintained within ± 5 percent
of the rating specified by the manufacturer.
The propane gas supplied should have a
heating value of approximately 2,500 Btus
per standard cubic foot. The actual heating
value, Hp, in Btus per standard cubic foot, for
the propane gas to be used in the test shall
be obtained either from measurements made
by the manufacturer conducting the test
using a standard continuous flow calorimeter
as described in 2.4.6 or by the purchase of
bottled gas whose Btu rating is certified to be
at least as accurate a rating as could be
obtained from measurement with a standard
continuous calorimeter as described in 2.4.6.
2.4 Instrumentation. Perform all test
measurements using the following
instruments as appropriate.
2.4.1 Weighing scale for test cloth. The
scale shall have a range of 0 to a maximum
of 30 pounds with a resolution of at least 0.2
ounces and a maximum error no greater than
0.3 percent of any measured value within the
range of 3 to 15 pounds.
2.4.1.2 Weighing scale for drum capacity
measurements. The scale should have a range
of 0 to a maximum of 500 pounds with
resolution of 0.50 pounds and a maximum
error no greater than 0.5 percent of the
measured value.
2.4.2 Kilowatt-hour meter. The kilowatthour meter shall have a resolution of 0.001
kilowatt-hours and a maximum error no
greater than 0.5 percent of the measured
value.
2.4.3 Gas meter. The gas meter shall have
a resolution of 0.001 cubic feet and a
maximum error no greater than 0.5 percent
of the measured value.
2.4.4 Dry and wet bulb psychrometer. The
dry and wet bulb psychrometer shall have an
error no greater than ± 1 °F.
2.4.5 Temperature. The temperature
sensor shall have an error no greater than
± 1 °F.
2.4.6 Standard Continuous Flow
Calorimeter. The calorimeter shall have an
operating range of 750 to 3,500 Btu per cubic
feet. The maximum error of the basic
calorimeter shall be no greater than 0.2
percent of the actual heating value of the gas
used in the test. The indicator readout shall
have a maximum error no greater than 0.5
percent of the measured value within the
operating range and a resolution of 0.2
percent of the full-scale reading of the
indicator instrument.
2.4.7 Standby mode and off mode watt
meter. The watt meter used to measure
standby mode and off mode power
consumption of the clothes dryer shall have
the resolution specified in section 4,
paragraph 4.5 of IEC 62301 (incorporated by
reference; see § 430.3). The watt meter shall
also be able to record a ‘‘true’’ average power
as specified in section 5, paragraph 5.3.2(a)
of IEC 62301.
2.5 Lint trap. Clean the lint trap
thoroughly before each test run.
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2.6 Test Clothes.
2.6.1 Energy test cloth. The energy test
cloth shall be clean and consist of the
following:
(a) Pure finished bleached cloth, made
with a momie or granite weave, which is a
blended fabric of 50-percent cotton and 50percent polyester and weighs within +10
percent of 5.75 ounces per square yard after
test cloth preconditioning, and has 65 ends
on the warp and 57 picks on the fill. The
individual warp and fill yarns are a blend of
50-percent cotton and 50-percent polyester
fibers.
(b) Cloth material that is 24 inches by 36
inches and has been hemmed to 22 inches by
34 inches before washing. The maximum
shrinkage after five washes shall not be more
than 4 percent on the length and width.
(c) The number of test runs on the same
energy test cloth shall not exceed 25 runs.
2.6.2 Energy stuffer cloths. The energy
stuffer cloths shall be made from energy test
cloth material, and shall consist of pieces of
material that are 12 inches by 12 inches and
have been hemmed to 10 inches by 10 inches
before washing. The maximum shrinkage
after five washes shall not be more than 4
percent on the length and width. The number
of test runs on the same energy stuffer cloth
shall not exceed 25 runs after test cloth
preconditioning.
2.6.3 Test Cloth Preconditioning.
A new test cloth load and energy stuffer
cloths shall be treated as follows:
(1) Bone dry the load to a weight change
of ± 1 percent, or less, as prescribed in
section 1.5.
(2) Place the test cloth load in a standard
clothes washer set at the maximum water fill
level. Wash the load for 10 minutes in soft
water (17 parts per million hardness or less),
using 60.8 grams of AHAM standard test
detergent Formula 3. Wash water
temperature is to be controlled at 140 ° ± 5
°F (60 ° ± 2.7 °C). Rinse water temperature
is to be controlled at 100 ° ± 5 °F (37.7 ± 2.7
°C).
(3) Rinse the load again at the same water
temperature.
(4) Bone dry the load as prescribed in
section 1.5 and weigh the load.
(5) This procedure is repeated until there
is a weight change of 1 percent or less.
(6) A final cycle is to be a hot water wash
with no detergent, followed by two warm
water rinses.
2.7 Test loads.
2.7.1 Compact size dryer load. Prepare a
bone-dry test load of energy cloths which
weighs 3.00 pounds ± .03 pounds.
Adjustments to the test load to achieve the
proper weight can be made by the use of
energy stuffer cloths, with no more than five
stuffer cloths per load. Dampen the load by
agitating it in water whose temperature is
60 °F ± 5 °F and consists of 0 to 17 parts per
million hardness for approximately 2
minutes in order to saturate the fabric. Then,
extract water from the wet test load by
spinning the load until the moisture content
of the load is between 54.0–61.0 percent of
the bone-dry weight of the test load.
2.7.2 Standard size dryer load. Prepare a
bone-dry test load of energy cloths which
weighs 8.45 pounds ± .085 pounds.
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Adjustments to the test load to achieve the
proper weight can be made by the use of
energy stuffer cloths, with no more than five
stuffer cloths per load. Dampen the load by
agitating it in water whose temperature is
60 °F ± 5 °F and consists of 0 to 17 parts per
million hardness for approximately 2
minutes in order to saturate the fabric. Then,
extract water from the wet test load by
spinning the load until the moisture content
of the load is between 54.0–61.0 percent of
the bone-dry weight of the test load.
2.7.3 Method of loading. Load the energy
test cloths by grasping them in the center,
shaking them to hang loosely, and then
dropping them in the dryer at random.
2.8 Clothes dryer preconditioning.
2.8.1 Conventional clothes dryers. For
conventional clothes dryers, before any test
cycle, operate the dryer without a test load
in the non-heat mode for 15 minutes or until
the discharge air temperature is varying less
than 1 °F for 10 minutes—whichever is
longer—in the test installation location with
the ambient conditions within the specified
test condition tolerances of 2.2.
2.8.2 Ventless clothes dryers. For ventless
clothes dryers, before any test cycle, the
steady-state machine temperature must be
equal to ambient room temperature described
in 2.2.1. This may be done by leaving the
machine at ambient room conditions for at
least 12 hours between tests.
3. Test Procedures and Measurements
3.1 Drum Capacity. Measure the drum
capacity by sealing all openings in the drum
except the loading port with a plastic bag,
and ensuring that all corners and depressions
are filled and that there are no extrusions of
the plastic bag through the opening in the
drum. Support the dryer’s rear drum surface
on a platform scale to prevent deflection of
the drum surface, and record the weight of
the empty dryer. Fill the drum with water to
a level determined by the intersection of the
door plane and the loading port. Record the
temperature of the water and then the weight
of the dryer with the added water and then
determine the mass of the water in pounds.
Add or subtract the appropriate volume
depending on whether or not the plastic bag
protrudes into the drum interior. The drum
capacity is calculated as follows:
C = w/d
C = capacity in cubic feet.
w = weight of water in pounds.
d = density of water at the measured
temperature in pounds per cubic feet.
3.2 Dryer Loading. Load the dryer as
specified in 2.7.
3.3 Test cycle Operate the clothes dryer at
the maximum temperature setting and, if
equipped with a timer, at the maximum time
setting and dry the load until the moisture
content of the test load is between 2.5 and
5 percent of the bone-dry weight of the test
load, but do not permit the dryer to advance
into cool down. If required, reset the timer
or automatic dry control. If the dryer
automatically stops during a cycle because
the condensation box is full of water, the test
is stopped, and the test run is invalid, in
which case the condensation box shall be
emptied and the test re-run from the
beginning. For ventless dryers, as defined in
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1.19, during the time between two cycles, the
door of the dryer shall be closed except for
loading (and unloading).
3.4 Data recording. Record for each test
cycle:
3.4.1 Bone-dry weight of the test load
described in 2.7.
3.4.2 Moisture content of the wet test
load before the test, as described in 2.7.
3.4.3 Moisture content of the dry test load
obtained after the test described in 3.3.
3.4.4 Test room conditions, temperature,
and percent relative humidity described in
2.2.1.
3.4.5 For electric dryers—the total
kilowatt-hours of electric energy, Et,
consumed during the test described in 3.3.
3.4.6 For gas dryers:
3.4.6.1 Total kilowatt-hours of electrical
energy, Ete, consumed during the test
described in 3.3.
3.4.6.2 Cubic feet of gas per cycle, Etg,
consumed during the test described in 3.3.
3.4.6.3 Correct the gas heating value,
GEF, as measured in 2.3.2.1 and 2.3.2.2, to
standard pressure and temperature
conditions in accordance with U.S. Bureau of
Standards, circular C417, 1938.
3.5 Test for automatic termination field
use factor. The field use factor for automatic
termination can be claimed for those dryers
which meet the requirements for automatic
termination control, defined in 1.4.
3.6 Standby mode and off mode power.
Establish the testing conditions set forth in
Section 2 ‘‘Testing Conditions’’ of this
appendix, omitting the requirement to
disconnect all console light or other lighting
systems on the clothes dryer that do not
consume more than 10 watts during the
clothes dryer test cycle in section 2.1. If the
clothes dryer waits in a higher power state
at the start of standby mode or off mode
before dropping to a lower power state, as
discussed in section 5, paragraph 5.1, note 1
of IEC 62301 (incorporated by reference; see
§ 430.3),wait until the clothes dryer passes
into the lower power state before starting the
measurement. Follow the test procedure
specified in section 5, paragraph 5.3 of IEC
62301 for testing in each possible mode as
described in 3.6.1 and 3.6.2, except allow the
product to stabilize for 30 to 40 minutes and
use an energy use measurement period of
10 minutes. For units in which power varies
over a cycle, as described in section 5,
paragraph 5.3.2 of IEC 62301, use the average
power approach described in paragraph
5.3.2(a) of IEC 62301, except allow the
product to stabilize for 30 to 40 minutes and
use an energy use measurement period not
less than 10 minutes.
3.6.1 If a clothes dryer has an inactive
mode, as defined in 1.12, measure and record
the average inactive mode power of the
clothes dryer, PIA, in watts.
3.6.2 If a clothes dryer has an off mode,
as defined in 1.15, measure and record the
average off mode power of the clothes dryer,
POFF, in watts.
4. Calculation of Derived Results From Test
Measurements
4.1 Total Per-cycle electric dryer energy
consumption. Calculate the total electric
dryer energy consumption per cycle, Ece,
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expressed in kilowatt-hours per cycle and
defined as:
Ece = [53.5/(Ww¥Wd)] × Ett × field use,
Where:
53.5 = an experimentally established value
for the percent reduction in the moisture
content of the test load during a
laboratory test cycle expressed as a
percent.
field use = field use factor.
= 1.18 for clothes dryers with time
termination control systems only
without any automatic termination
control functions.
= 1.04 clothes dryers with automatic control
systems that meet the requirements of
the definition for automatic control
systems in 1.4, 1.14 and 1.18, including
those that also have a supplementary
timer control, or that may also be
manually controlled.
Ww = the moisture content of the wet test
load as recorded in 3.4.2.
Wd = the moisture content of the dry test load
as recorded in 3.4.3.
4.2 Per-cycle gas dryer electrical
energy consumption. Calculate the gas
dryer electrical energy consumption per
cycle, Ege, expressed in kilowatt-hours
per cycle and defined as:
Ege = [53.5/(Ww¥Wd)] × Ete × field use,
Where:
Ete = the energy recorded in 3.4.6.1 field use,
53.5, Ww, Wd as defined in 4.1.
4.3 Per-cycle gas dryer gas energy
consumption. Calculate the gas dryer
gas energy consumption per cycle, Ege.
expressed in Btus per cycle as defined
as:
Egg = [53.5/(Ww ¥ Wd)] × Etg × field use
× GEF
Where:
Etg = the energy recorded in 3.4.6.2
GEF = corrected gas heat value (Btu per cubic
feet) as defined in 3.4.6.3, field use, 53.5,
Ww, Wd as defined in 4.1.
4.4 Total per-cycle gas dryer energy
consumption expressed in kilowatthours. Calculate the total gas dryer
energy consumption per cycle, Ecg,
expressed in kilowatt-hours per cycle
and defined as:
Ecg = Ege + (Egg/3412 Btu/kWh)
Where:
Ege as defined in 4.2
Egg as defined in 4.3
4.5 Per-cycle standby mode and off
mode energy consumption. Calculate
the dryer inactive mode and off mode
energy consumption per cycle, ETSO,
expressed in kWh per cycle and defined
as:
ETSO = [(PIA × SIA) + (POFF × SOFF)] × K/
283
Where:
PIA = dryer inactive mode power, in watts, as
measured in section 3.6.1;
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POFF = dryer off mode power, in watts, as
measured in section 3.6.2.
If the clothes dryer has both inactive mode
and off mode, SIA and SOFF both equal
8,620 ÷ 2 = 4,310, where 8,620 is the
total inactive and off mode annual hours;
If the clothes dryer has an inactive mode but
no off mode, the inactive mode annual
hours, SIA, is equal to 8,620 and the off
mode annual hours, SOFF, is equal to 0;
If the clothes dryer has an off mode but no
inactive mode, SIA is equal to 0 and SOFF
is equal to 8,620
Where:
K = 0.001 kWh/Wh conversion factor for
watt-hours to kilowatt-hours; and
283 = representative average number of
clothes dryer cycles in a year.
4.6 Per-cycle combined total energy
consumption expressed in kilowatthours. Calculate the per-cycle combined
total energy consumption, ECC,
expressed in kilowatt-hours per cycle
and defined for an electric clothes dryer
as:
ECC = Ece + ETSO
Where:
Ece = the energy recorded in 4.1, and
ETSO = the energy recorded in 4.7, and
defined for a gas clothes dryer as:
ECC = Ecg + ETSO
Where:
Ecg = the energy recorded in 4.4, and
ETSO = the energy recorded in 4.7.
4.7 Energy Factor in pounds per
kilowatt-hour. Calculate the energy
factor, EF, expressed in pounds per
kilowatt-hour and defined for an electric
clothes dryer as:
EF = Wbonedry/Ece
Where:
Wbonedry = the bone dry test load weight
recorded in 3.4.1, and
Ece = the energy recorded in 4.1, and
and defined for a gas clothes dryer as:
EF = Wbonedry/Ecg
Where:
Wbonedry = the bone dry test load weight
recorded in 3.4.1, and
Ecg = the energy recorded in 4.4,
4.8 Combined Energy Factor in
pounds per kilowatt-hour. Calculate the
combined energy factor, CEF, expressed
in pounds per kilowatt-hour and
defined as:
kgrant on DSKGBLS3C1PROD with BILLS
CEF = Wbonedry/ECC
Where:
Wbonedry = the bone dry test load weight 3.4.1,
and
ECC = the energy recorded in 4.6
6. Appendix F to subpart B of part 430
is revised to read as follows:
■
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Jkt 223001
Appendix F to Subpart B of Part 430–
Uniform Test Method for Measuring the
Energy Consumption of Room Air
Conditioners
Note: Manufacturers are not required to use
the test procedures and calculations that refer
to standby mode and off mode energy
consumption, (specifically, sections 2.2, 3.2,
4.2, and 5.3 of this appendix F) until the
compliance date of any amended energy
conservation standards for room air
conditioners at 10 CFR 430.32(b).
1. Definitions.
1.1 ‘‘Active mode’’ means a mode in
which the room air conditioner is connected
to a mains power source, has been activated
and is performing the main function of
cooling or heating the conditioned space, or
circulating air through activation of its fan or
blower, with or without energizing active aircleaning components or devices such as
ultraviolet (UV) radiation, electrostatic filters,
ozone generators, or other air-cleaning
devices.
1.2 ‘‘ANSI/AHAM RAC–1’’ means the test
standard published jointly by the American
National Standards Institute and the
Association of Home Appliance
Manufacturers, titled ‘‘Room Air
Conditioners,’’ Standard RAC–1–2008
(incorporated by reference; see § 430.3).
1.3 ‘‘ANSI/ASHRAE 16’’ means the test
standard published jointly by the American
National Standards Institute and the
American Society of Heating, Refrigerating,
and Air-Conditioning Engineers titled
‘‘Method of Testing for Rating Room Air
Conditioners and Packaged Terminal Air
Conditioners,’’ Standard 16–1983 (RA 2009)
(incorporated by reference; see § 430.3).
1.4 ‘‘IEC 62301’’ means the test standard
published by the International
Electrotechnical Commission, (‘‘IEC’’), titled
‘‘Household electrical appliances—
Measurement of standby power,’’ Publication
62301 (first edition June 2005), (incorporated
by reference; see § 430.3).
1.5 ‘‘Inactive mode’’ means a standby
mode that facilitates the activation of active
mode by remote switch (including remote
control) or internal sensor or which provides
continuous status display.
1.6 ‘‘Off mode’’ means a mode in which
a room air conditioner is connected to a
mains power source and is not providing any
active or standby mode function and where
the mode may persist for an indefinite time.
An indicator that only shows the user that
the product is in the off position is included
within the clasification of an off mode.
1.7 ‘‘Standby mode’’ means any product
modes where the where the energy using
product is connected to a mains power
source and offers one or more of the
following user oriented or protective
functions which may persist for an indefinite
time:
(a) To facilitate the activation of other
modes (including activation or deactivation
of active mode) by remote switch (including
remote control), internal sensor, or timer.
(b) Continuous functions, including
information or status displays (including
clocks) or sensor-based functions. A timer is
a continuous clock function (which may or
PO 00000
Frm 00065
Fmt 4701
Sfmt 4700
1035
may not be associated with a display) that
provides regular scheduled tasks (e.g.,
switching) and that operates on a continuous
basis.
2. Test methods.
2.1 Cooling. The test method for testing
room air conditioners in cooling mode shall
consist of application of the methods and
conditions in ANSI/AHAM RAC–1 sections
4, 5, 6.1, and 6.5 (incorporated by reference;
see § 430.3), and in ANSI/ASHRAE 16
(incorporated by reference; see § 430.3).
2.2 Standby and off modes. The method
for testing room air conditioners in standby
and off modes shall consist of application of
the methods and conditions in IEC 62301
(incorporated by reference; see § 430.3), as
modified by the requirements of this
standard. The testing may be conducted in
test facilities used for testing cooling
performance. If testing is not conducted in
such a facility, the test facility shall comply
with IEC 62301 section 4.2.
3. Test conditions.
3.1 Cooling mode. Establish the test
conditions described in sections 4 and 5 of
ANSI/AHAM RAC–1 (incorporated by
reference; see § 430.3) and in accordance
with ANSI/ASHRAE 16 (incorporated by
reference; see § 430.3).
3.2 Standby and off modes.
3.2.1 Test room conditions. Maintain the
indoor test conditions as required by section
4.2 of IEC 62301 (incorporated by reference;
see § 430.3). If the standby and off mode
testing is conducted in a facility that is also
used for testing cooling performance,
maintain the outdoor test conditions either as
required by section 4.2 of IEC 62301 or as
described in section 3.1. If the unit is
equipped with an outdoor air ventilation
damper, close this damper during testing.
3.2.2 Power supply. Maintain power
supply conditions specified in section 4.3 of
IEC 62301 (incorporated by reference; see
§ 430.3). Use room air conditioner nameplate
voltage and frequency as the basis for power
supply conditions. Maintain power supply
voltage waveform according to the
requirements of section 4.4 of IEC 62301.
3.2.3 Watt meter. The watt meter used to
measure standby mode and off mode power
consumption of the room air conditioner
shall have the resolution specified in section
4, paragraph 4.5 of IEC 62301 (incorporated
by reference; see § 430.3). The watt meter
shall also be able to record a ‘‘true’’ average
power specified in section 5, paragraph
5.3.2(a) of IEC 62301.
4. Measurements.
4.1 Cooling mode. Measure the quantities
delineated in section 5 of ANSI/AHAM RAC–
1 (incorporated by reference; see § 430.3).
4.2 Standby and off modes. Establish the
testing conditions set forth in section 3.2.
Prior to the initiation of the test
measurements, the room air conditioner shall
also be installed in accordance with section
5, paragraph 5.2 of IEC 62301 (incorporated
by reference; see § 430.3). For room air
conditioners that drop from a higher power
state to a lower power state as discussed in
section 5, paragraph 5.1, note 1 of IEC 62301,
allow sufficient time for the room air
conditioner to reach the lower power state
before proceeding with the test measurement.
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kgrant on DSKGBLS3C1PROD with BILLS
Follow the test procedure specified in section
5, paragraph 5.3 of IEC 62301 for testing in
each possible mode as described in 4.2.1 and
4.2.2, except allow the product to stabilize
for 5 to 10 minutes and use an energy use
measurement period of 5 minutes. For units
in which power varies over a cycle, as
described in section 5, paragraph 5.3.2 of IEC
62301, use the average power approach in
paragraph 5.3.2(a).
4.2.1 If a room air conditioner has an
inactive mode, as defined in 1.5, measure
and record the average inactive mode power
of the room air conditioner, PIA, in watts.
4.2.2 If a room air conditioner has an off
mode, as defined in 1.6, measure and record
the average off mode power of the room air
conditioner, POFF, in watts.
5. Calculations.
5.1 Calculate the cooling capacity
(expressed in Btu/hr) as required in section
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15:19 Jan 05, 2011
Jkt 223001
6.1 of ANSI/AHAM RAC–1 (incorporated by
reference; see § 430.3) and in accordance
with ANSI/ASHRAE 16 (incorporated by
reference; see § 430.3).
5.2 Determine the electrical power input
(expressed in watts) as required by section
6.5 of ANSI/AHAM RAC–1 (incorporated by
reference; see § 430.3) and in accordance
with ANSI/ASHRAE 16 (incorporated by
reference; see § 430.3).
5.3 Standby mode and off mode annual
energy consumption. Calculate the standby
mode and off mode annual energy
consumption for room air conditioners, ETSO,
expressed in kilowatt-hours per year,
according to the following:
ETSO = [(PIA × SIA) + (POFF × SOFF)] × K
Where:
PIA= room air conditioner inactive mode
power, in watts, as measured in section
4.2.1
PO 00000
Frm 00066
Fmt 4701
Sfmt 9990
POFF = room air conditioner off mode power,
in watts, as measured in section 4.2.2.
If the room air conditioner has both inactive
mode and off mode, SIA and SOFF both
equal 5,115 ÷ 2 = 2,557.5, where 5,115
is the total inactive and off mode annual
hours;
If the room air conditioner has an inactive
mode but no off mode, the inactive mode
annual hours, SIA, is equal to 5,115 and
the off mode annual hours, SOFF, is equal
to 0;
If the room air conditioner has an off mode
but no inactive mode, SIA is equal to 0
and SOFF is equal to STOT;
K = 0.001 kWh/Wh conversion factor for
watt-hours to kilowatt-hours.
[FR Doc. 2010–32118 Filed 1–5–11; 8:45 am]
BILLING CODE 6450–01–P
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]]>Agencies
[Federal Register Volume 76, Number 4 (Thursday, January 6, 2011)]
[Rules and Regulations]
[Pages 972-1036]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2010-32118]
[[Page 971]]
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Part III
Department of Energy
-----------------------------------------------------------------------
10 CFR Part 430
Energy Conservation Program for Consumer Products: Test Procedures for
Clothes Dryers and Room Air Conditioners; Final Rule
��Federal Register / Vol. 76 , No. 4 / Thursday, January 6, 2011 /
Rules and Regulations��
[[Page 972]]
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DEPARTMENT OF ENERGY
10 CFR Part 430
[Docket No. EERE-2008-BT-TP-0010]
RIN 1904-AC02
Energy Conservation Program for Consumer Products: Test
Procedures for Clothes Dryers and Room Air Conditioners
AGENCY: Office of Energy Efficiency and Renewable Energy, Department of
Energy.
ACTION: Final rule.
-----------------------------------------------------------------------
SUMMARY: The U.S. Department of Energy (DOE) amends its test procedures
for residential clothes dryers and room air conditioners under the
Energy Policy and Conservation Act (EPCA). The amendments provide for
measurement of standby mode and off mode power use by these products
and also amend the active mode test procedures for these products. For
standby and off mode energy use, these amendments incorporate into the
DOE test procedures relevant provisions from the International
Electrotechnical Commission (IEC) Standard 62301, ``Household
electrical appliances--Measurement of standby power,'' (first edition
June 2005), including language to clarify application of these
provisions for measuring standby mode and off mode power consumption in
clothes dryers and room air conditioners. In addition, DOE is adopting
definitions of modes based on the relevant provisions from IEC Standard
62301 Second Edition Committee Draft for Vote. For active mode energy
use, DOE adopts testing methods for ventless clothes dryers, test cloth
preconditioning requirements for clothes dryer energy tests, test
conditions for gas clothes dryers, test conditions for clothes dryer
drum capacity measurement, amendments to clarify current clothes dryer
usage patterns and capabilities and to update the references to
industry standards in the room air conditioner and clothes dryer test
procedures.
DATES: This rule is effective February 7, 2011. The incorporation by
reference of certain publications listed in the rule is approved by the
Director of the Federal Register on February 7, 2011.
ADDRESSES: You may review copies of all materials related to this
rulemaking at the U.S. Department of Energy, Resource Room of the
Building Technologies Program, 950 L'Enfant Plaza, SW., Suite 600,
Washington, DC, (202) 586-2945, between 9 a.m. and 4 p.m., Monday
through Friday, except Federal holidays. Please call Ms. Brenda Edwards
at the above telephone number for additional information regarding
visiting the Resource Room.
FOR FURTHER INFORMATION CONTACT: Mr. Subid Wagley, 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) 287-1414. E-mail:
Subid.Wagley@ee.doe.gov.
Ms. Elizabeth Kohl, U.S. Department of Energy, Office of the
General Counsel, GC-71, 1000 Independence Avenue, SW., Washington, DC
20585-0121. Telephone: (202) 586-7796. E-mail:
Elizabeth.Kohl@hq.doe.gov.
SUPPLEMENTARY INFORMATION: This final rule incorporates by reference
into part 430 the following industry standards:
(1) AHAM HLD-1-2009 (``AHAM HLD-1''), ``Household Tumble Type
Clothes Dryers,'' (2009).
Copies of AHAM HLD-1 are available from the Association of Home
Appliance Manufacturers, 1111 19th Street, NW., Suite 402, Washington,
DC 20036, (202) 872-5955, or https://www.aham.org/.
(2) ANSI/AHAM RAC-1-2008 (``ANSI/AHAM RAC-1''), ``Room Air
Conditioners,'' (2008; ANSI approved July 7, 2008).
Copies of ANSI/AHAM RAC-1 are available from the American National
Standards Institute, 11 West 42nd Street, New York, New York 10036,
(212) 642-4936, or https://webstore.ansi.org/.
(3) ANSI/ASHRAE Standard 16-1983 (``ANSI/ASHRAE 16'') (RA 2009),
(Reaffirmation of ANSI/ASHRAE Standard 16-1983 [RA 1999]), ``Method of
Testing for Rating Room Air Conditioners and Packaged Terminal Air
Conditioners,'' ASHRAE approved October 18, 1988, and reaffirmed June
20, 2009; ANSI approved October 20, 1998 and reaffirmed June 25, 2009.
Copies of ANSI/ASHRAE 16 are available from the American National
Standards Institute, 11 West 42nd Street, New York, New York 10036,
(212) 642-4936, or https://webstore.ansi.org/.
(4) International Electrotechnical Commission (IEC) Standard 62301
(``IEC 62301''), ``Household electrical appliances--Measurement of
standby power (first edition June 2005).''
Copies of IEC 62301 are available from the American National
Standards Institute, 11 West 42nd Street, New York, New York 10036,
(212) 642-4936, or https://webstore.iec.ch/.
Table of Contents
I. Background and Authority
II. Summary of the Proposal
III. Discussion
A. Products Covered by the Test Procedure Changes
B. Clothes Dryer and Room Air Conditioner Standby Mode and Off
Mode Test Procedures
1. Incorporating by Reference IEC Standard 62301 for Measuring
Standby Mode and Off Mode Power in Clothes Dryers and Room Air
Conditioners
2. Determination of Modes To Be Incorporated
3. Adding Specifications for the Test Methods and Measurements
for Clothes Dryer and Room Air Conditioner Standby Mode and Off Mode
Testing
a. Clothes Dryers
b. Room Air Conditioners
4. Calculation of Energy Use Associated With Standby Modes and
Off Mode
a. Clothes Dryers
b. Room Air Conditioners
5. Measures of Energy Consumption
a. Clothes Dryers
b. Room Air Conditioners
C. Clothes Dryer and Room Air Conditioner Active Mode Test
Procedures
1. Correction of Text Describing Energy Factor Calculation for
Clothes Dryers
2. Automatic Cycle Termination for Clothes Dryers
3. Test Procedure for Ventless Clothes Dryers
4. Detergent Specifications for Clothes Dryer Test Cloth
Preconditioning
5. Changes To Reflect Current Usage Patterns and Capabilities
a. Clothes Dryer Number of Annual Cycles
b. Clothes Dryer Initial Remaining Moisture Content
c. Clothes Dryer Test Load Weight
d. Room Air Conditioner Annual Operating Hours
e. Room Air Conditioner Part-Load Performance
f. Room Air Conditioner Ambient Test Conditions
6. Room Air Conditioner Referenced Test Procedures
7. Clothes Dryer Referenced Test Procedure
8. Technical Correction for the Per-Cycle Gas Dryer Continuously
Burning Pilot Light Gas Energy Consumption
9. Clarification of the Gas Supply Test Conditions for Gas
Clothes Dryers
10. Other Clothes Dryer Test Procedure Issues
a. Test Cloth Specifications
b. Relative Humidity Measurement Specifications
c. Calculations of EF and CEF
d. Measurement of Kilowatt Electricity Demand
e. Clarifications to the Measurement of Drum Capacity
f. Test Procedure Language
D. Compliance With Other EPCA Requirements
1. Test Burden
2. Integration of Standby Mode and Off Mode Energy Consumption
Into the Energy Efficiency Metrics
IV. Effects of Test Procedure Revisions on Compliance With Standards
A. Standby Mode and Off Mode
[[Page 973]]
B. Active Mode--Clothes Dryers
C. Active Mode--Room Air Conditioners
V. Procedural Requirements
A. Review Under Executive Order 12866
B. Review Under the Regulatory Flexibility Act
C. Review Under the Paperwork Reduction Act of 1995
D. Review Under the National Environmental Policy Act of 1969
E. Review Under Executive Order 13132
F. Review Under Executive Order 12988
G. Review Under the Unfunded Mandates Reform Act of 1995
H. Review Under the Treasury and General Government
Appropriations Act, 1999
I. Review Under Executive Order 12630
J. Review Under the Treasury and General Government
Appropriations Act, 2001
K. Review Under Executive Order 13211
L. Review Under Section 32 of the Federal Energy Administration
Act of 1974
M. Congressional Notification
VI. Approval of the Office of the Secretary
I. Background and Authority
Title III of the Energy Policy and Conservation Act of 1975 (42
U.S.C. 6291, et seq.; ``EPCA'' or, in context, ``the Act'') sets forth
a variety of provisions designed to improve energy efficiency. Part B
of Title III, Public Law 94-163 (42 U.S.C. 6291-6309, as codified)
establishes the ``Energy Conservation Program for Consumer Products
Other Than Automobiles,'' a program covering most major household
appliances including clothes dryers and room air conditioners (all of
which are referred to below as ``covered products'').\1\ (42 U.S.C.
6291(1)-(2) and 6292(a)(2) and (8))
---------------------------------------------------------------------------
\1\ All references to EPCA refer to the statute as amended
including through the Energy Independence and Security Act of 2007,
Public Law 110-140. For editorial reasons, upon codification in the
U.S. Code, Part B was re-designated Part A.
---------------------------------------------------------------------------
Under the Act, this program consists essentially of four parts: (1)
Testing; (2) labeling; (3) the establishment of Federal energy
conservation standards; and (4) certification and enforcement
procedures. The Federal Trade Commission (FTC) is responsible for
labeling, and DOE implements the remainder of the program. The testing
requirements consist of test procedures that, pursuant to EPCA,
manufacturers of covered products must use as the basis for certifying
to DOE that their products comply with applicable energy conservation
standards adopted under EPCA and for representations about the
efficiency of those products. Similarly, DOE must use these test
requirements to determine whether the products comply with EPCA
standards. Under 42 U.S.C. 6293, EPCA sets forth criteria and
procedures for DOE's adoption and amendment of such test procedures.
EPCA provides that any test procedures prescribed or amended under this
section shall be reasonably designed to produce test results which
measure energy efficiency, energy use or estimated annual operating
cost of a covered product during a representative average use cycle or
period of use and shall not be unduly burdensome to conduct. (42 U.S.C.
6293(b)(3))
In any rulemaking to amend a test procedure, DOE must also
determine to what extent, if any, the proposed test procedure would
alter the measured energy efficiency of any covered product as
determined under the existing test procedure. (42 U.S.C. 6293(e)(1)) If
DOE determines that the amended test procedure would alter the measured
efficiency of a covered product, DOE must amend the applicable energy
conservation standard accordingly. In determining the amended energy
conservation standard, the Secretary shall measure, pursuant to the
amended test procedure, the energy efficiency, energy use, or water use
of a representative sample of covered products that minimally comply
with the existing standard. The average of such energy efficiency,
energy use, or water use levels determined under the amended test
procedure shall constitute the amended energy conservation standard for
the applicable covered products. (42 U.S.C. 6293(e)(2)) EPCA also
states that models of covered products in use before the date on which
the amended energy conservation standard becomes effective (or
revisions of such models that come into use after such date and have
the same energy efficiency, energy use, or water use characteristics)
that comply with the energy conservation standard applicable to such
covered products on the day before such date shall be deemed to comply
with the amended energy conservation standard. (42 U.S.C. 6293(e)(3))
EPCA also states that the Secretary's authority to amend energy
conservation standards under 42 U.S.C. 6293(e) shall not affect the
Secretary's obligation to issue final rules as described in 42 U.S.C.
6295. (42 U.S.C. 6293(e)(4))
DOE's test procedures for clothes dryers are found at 10 CFR part
430, subpart B, appendix D. DOE established its test procedure for
clothes dryers in a final rule published in the Federal Register on
September 14, 1977 (the September 1977 TP Final Rule). 42 FR 46145. On
May 19, 1981 DOE published a final rule (the May 1981 TP Final Rule) to
amend the test procedure by establishing a field-use factor for clothes
dryers with automatic termination controls, clarifying the test cloth
specifications and clothes dryer preconditioning, and making editorial
and minor technical changes. 46 FR 27324. The existing clothes dryer
test procedure incorporates by reference two industry test standards:
(1) The Association of Home Appliance Manufacturers (AHAM) Standard
HLD-1-1974, ``AHAM Performance Evaluation Procedure for Household
Tumble Type Clothes Dryers'' (AHAM Standard HLD-1-1974); and (2) AHAM
Standard HLD-2EC, ``Test Method for Measuring Energy Consumption of
Household Tumble Type Clothes Dryers'' December 1975 (AHAM Standard
HLD-2EC). The test procedure includes provisions for determining the
energy factor (EF) for clothes dryers, which is a measure of the total
energy required to dry a standard test load of laundry to a ``bone
dry'' \2\ state.
---------------------------------------------------------------------------
\2\ ``Bone dry'' is defined in the DOE clothes dryer test
procedure as ``a condition of a load of test clothes which has been
dried in a dryer at maximum temperature for a minimum of 10 minutes,
removed and weighed before cool down, and then dried again for 10-
minute periods until the final weight change of the load is 1
percent or less.'' (10 CFR subpart B, appendix D, section 1.2)
---------------------------------------------------------------------------
DOE's test procedures for room air conditioners are found at 10 CFR
part 430, subpart B, appendix F. DOE established its room air
conditioner test procedure on June 1, 1977, and redesignated and
amended it on June 29, 1979. 42 FR 27898; 44 FR 37938. The existing
room air conditioner test procedure incorporates by reference two
industry test standards: (1) American National Standard (ANS) (since
renamed American National Standards Institute (ANSI)) Z234.1-1972,
``Room Air Conditioners;'' \3\ and (2) American Society of Heating,
Refrigerating, and Air-Conditioning Engineers (ASHRAE) Standard 16-69,
``Method of Testing for Rating Room Air Conditioners.'' \4\ The DOE
test procedure includes provisions for determining the energy
efficiency ratio (EER) of room air conditioners, which is the ratio of
the cooling capacity in British thermal units (Btu) to the power input
in watts (W).
---------------------------------------------------------------------------
\3\ ANSI standards are available at https://www.ansi.org.
\4\ ASHRAE standards are available at https://www.ashrae.org.
---------------------------------------------------------------------------
As currently drafted, the test procedures for the products at issue
in this rulemaking do not account for standby mode and off mode energy
consumption, except in one narrow product class. Specifically, for gas
clothes dryers with constant burning pilot lights, DOE's current test
procedure for clothes dryers addresses the standby energy use of such
pilot lights. EPCA, however, states that gas clothes dryers shall not
be equipped with a constant burning pilot for
[[Page 974]]
products manufactured on or after January 1, 1988. (42 U.S.C.
6295(g)(3)) As discussed in section III.C.8, DOE amends the clothes
dryer test procedure in today's final rule to remove any provisions for
measuring constant burning pilot lights.
EPCA directs DOE to amend its test procedures to include measures
of standby mode and off mode energy consumption. EPCA further directs
DOE to amend the test procedures to integrate such energy consumption
into a single energy descriptor for that product. If that is
technically infeasible, DOE must prescribe a separate standby mode and
off mode energy-use test procedure, if technically feasible. (42 U.S.C.
6295(gg)(2)(A)) Any such amendment must consider the most current
versions of the International Electrotechnical Commission (IEC)
Standard 62301 [``Household electrical appliances--measurement of
standby power,'' First Edition 2005-06 (IEC Standard 62301)]
5 6 and IEC Standard 62087 [``Methods of measurement for the
power consumption of audio, video, and related equipment,'' Second
Edition 2008-09]. Id.
---------------------------------------------------------------------------
\5\ IEC standards are available at: https://www.iec.ch.
\6\ Multiple editions of this standard are referenced in this
final rule. Unless otherwise indicated, the terms ``IEC Standard
62301'' or ``IEC Standard 62301 First Edition'' refer to ``Household
electrical appliances--measurement of standby power,'' First Edition
2005-06.
---------------------------------------------------------------------------
EPCA also provides that amendments to the test procedures to
include standby mode and off mode energy consumption will not determine
compliance with previously established standards. (U.S.C.
6295(gg)(2)(C)) The test procedure amendments regarding provisions for
standby mode and off mode in today's final rule shall become effective
30 days after the publication of the rule in the Federal Register. DOE
notes, however, that the procedures and calculations for standby mode
and off mode energy consumption need not be performed at this time to
determine compliance with the current energy conservation standards.
Manufacturers would be required to use the amended test procedures'
standby mode and off mode provisions starting on the compliance date of
any final rule establishing amended energy conservation standards for
clothes dryers and room air conditioners that address standby mode and
off mode energy consumption. In addition, starting 180 days after
publication of today's test procedure final rule, any representations
as to the standby mode and off mode energy consumption must be based
upon results generated under the applicable provisions of this test
procedure. (42 U.S.C. 6293(c)(2))
DOE published a notice of proposed rulemaking (NOPR) on December 9,
2008 (the December 2008 TP NOPR), in which it proposed a number of
revisions and additions to its test procedures for clothes dryers and
room air conditioners. These consisted largely of provisions to address
the new statutory requirement to expand test procedures to incorporate
a measure of standby mode and off mode energy consumption. 73 FR 74639.
DOE also proposed amendments to correct text describing the EF
calculation for clothes dryers and the text referencing room air
conditioner industry test standards. 73 FR 74650. The proposals in the
NOPR were addressed at a public meeting on December 17, 2008 (the
December 2008 Public Meeting). In addition, DOE invited written
comments, data, and information on the December 2008 TP NOPR through
February 23, 2009.
DOE received oral comments from interested parties at the December
2008 Public Meeting and subsequently received four written comments.
The principal test procedure issues on which interested parties
commented were: (1) Establishing multiple low power or standby modes
for both clothes dryers and room air conditioners; (2) the number of
annual hours associated with active, standby, and off modes for the
calculation of energy use; (3) considering an additional standby mode
(a ``network mode''); (4) clarifying the definitions of standby and off
mode; (5) harmonizing mode definitions and testing procedures with
international standards, in particular IEC Standard 62301 Second
Edition, Committee Draft 2 (IEC Standard 62301 CD2); and (6)
integrating of standby and off mode energy use and active mode energy
use into a single energy-use metric.
DOE determined after the December 2008 TP NOPR was published that
it would consider a revised version of IEC Standard 62301, i.e., IEC
Standard 62301 Second Edition, which at that time was expected to be
published in July 2009. DOE anticipated, based on review of drafts of
the updated IEC Standard 62301, that the revisions could include
different mode definitions. Subsequently, DOE received information that
IEC Standard 62301 Second Edition would not be published until late
2010. To allow for the consideration of standby and off mode power
consumption in the concurrent energy conservation standards rulemaking,
DOE published a SNOPR on June 29, 2010 (hereafter referred to as the
June 2010 TP SNOPR), proposing mode definitions based on the new mode
definitions from the most recent draft version of IEC Standard 62301
Second Edition which, at that time, was designated as IEC Standard
62301 Second Edition Committee Draft for Vote (IEC Standard 62301 CDV).
75 FR 37594. The IEC circulated IEC Standard 62301 CDV on August 28,
2009. IEC Standard 62301 CDV contained the most recent proposed
amendments to IEC Standard 62301, including new mode definitions, at
the time the June 2010 TP SNOPR was issued. IEC Standard 62301 CDV
revised the proposed mode definitions from previous draft versions of
IEC Standard 62301 and addressed comments received by interested
parties in response to those drafts. As a result, DOE stated in the
June 2010 TP SNOPR that the mode definitions in IEC Standard 62301 CDV
represent the best definitions available for the supporting analysis.
Id.
DOE also determined after publication of the December 2008 TP NOPR
to conduct a rulemaking to amend the active mode test procedure for
clothes dryers and room air conditioners. As part of this rulemaking,
DOE intended to address issues on which it requested comment in the
concurrent energy conservation standards rulemaking, discussed below.
In the June 2010 TP SNOPR, DOE proposed the following test procedure
amendments for the measurement of active mode energy consumption for
clothes dryers and room air conditioners: (1) Procedures for more
accurately measuring the effects of different automatic termination
technologies in clothes dryers; (2) provisions for ventless clothes
dryers, which are being considered under an amended energy conservation
standard; (3) updated detergent specifications for clothes dryer test
cloth preconditioning; (4) changes to better reflect current usage
patterns and capabilities for the covered products; (5) updated
references to external test procedures; and (6) clarifications to the
test conditions for gas clothes dryers. 75 FR 37594 (June 29, 2010).
The proposals in the SNOPR were addressed at a public meeting on
July 14, 2010 (July 2010 Public Meeting). In addition, DOE invited
written comments, data, and information on the June 2010 TP SNOPR
through August 30, 2010. DOE received oral comments from interested
parties at the July 2010 Public Meeting and subsequently received 13
written comments. The principal test procedure issues on which
interested parties commented were: (1) The consideration of the most
recent draft IEC Standard 62301 Second Edition, Final Draft
International
[[Page 975]]
Standard (IEC Standard 62301 FDIS); (2) the settings used for standby
and off mode testing; (3) the allocation of hours to different standby
and off modes; (4) the clothes dryer cycle settings selected for
automatic cycle termination testing methods; (5) the inclusion of the
cool-down period for clothes dryer automatic cycle termination tests;
(6) revisions to the water temperature for clothes dryer test load
preparation; (7) test conditions for ventless clothes dryers; (8) the
consideration of the effects of clothes dryers on HVAC energy use; (9)
the initial remaining moisture content (RMC) value for clothes dryers;
(10) the number of room air conditioner annual operating hours; and
(11) the consideration of fan-only active mode for room air
conditioners.
Test procedure amendments for the measurement of active mode energy
consumption for clothes dryers and room air conditioners will become
effective 30 days after the publication of today's final rule in the
Federal Register. In addition, DOE also notes that as of 180 days after
the publication of today's test procedure final rule, any
representations with respect to the energy use or efficiency or cost of
energy consumed of the products that are the subject of this rulemaking
must be based upon results generated under the applicable provisions of
these amended test procedures. (42 U.S.C. 6293(c)(2))
This test procedure rulemaking fulfills the 7-year review
requirement prescribed by EPCA. At least once every 7 years, the
Secretary shall review test procedures for all covered products and
amend test procedures with respect to any covered product or publish
notice in the Federal Register of any determination not to amend a test
procedure. (42 U.S.C. 6293(b)(1)(A))
DOE is also conducting a concurrent energy conservation standards
rulemaking for residential clothes dryers and room air conditioners.
For clothes dryers, EPCA establishes prescriptive standards for clothes
dryers, requiring that gas dryers manufactured on or after January 1,
1988 not be equipped with a constant burning pilot and further
requiring that DOE conduct two cycles of rulemakings to determine if
more stringent standards are justified. (42 U.S.C. 6295(g)(3) and (4))
On May 14, 1991, DOE published a final rule in the Federal Register
establishing the first set of performance standards for residential
clothes dryers (56 FR 22250); the new standards became effective on May
14, 1994. 10 CFR 430.32(h). DOE has initiated the second cycle of
clothes dryer standards rulemakings by publishing a notice of
availability of a framework document, discussed in more detail below.
72 FR 57254 (October 9, 2007).
For room air conditioners, EPCA establishes performance standards
that became effective on January 1, 1990, and directs DOE to conduct
two cycles of rulemakings to determine if more stringent standards are
justified. (42 U.S.C. 6295(c)(1) and (2)) On March 4, 1994, DOE
published a NOPR for several products, including room air conditioners.
59 FR 10464. On September 24, 1997, DOE published a final rule
establishing an updated set of performance standards, with an effective
date of October 1, 2000. 62 FR 50122; 10 CFR 40.32(b). DOE initiated
the second cycle of room air conditioner standards rulemakings
concurrent with the clothes dryer rulemaking. 72 FR 57254 (October 9,
2007).
As stated above, DOE initiated the second cycle of residential
clothes dryer and room air conditioner energy conservation standards
rulemakings by publishing a notice in the Federal Register announcing
the availability of a framework document to initiate a rulemaking to
consider amended energy conservation standards for residential clothes
dryers and room air conditioners on October 9, 2007 (hereafter the
October 2007 Framework Document). 72 FR 57254. In the October 2007
Framework Document, DOE identified specific ways in which it could
revise its test procedures for these two products and requested comment
from interested parties on whether it should adopt such revisions.
Specifically, DOE sought comment on potential amendments to the clothes
dryer test procedure to: (1) Reflect lower remaining moisture content
(RMC) \7\ in clothes loads; (2) account for fewer annual use cycles;
and (3) add the capability to test ventless clothes dryers. (Framework
Document, STD No. 1 at pp. 4-6) \8\ DOE received comments in response
to the October 2007 Framework Document that it should consider changes
to the clothes dryer test load size. For room air conditioners, DOE
requested input on potential amendments to the test procedure to: (1)
Incorporate the most recent ANSI and ASHRAE test standards; (2) reduce
the annual operating hours; and (3) measure part-load performance.
(Framework Document, STD No. 1 at pp. 6-7) DOE received comments in
response to the October 2007 Framework Document that it should consider
changes to the ambient test conditions for room air conditioners.
---------------------------------------------------------------------------
\7\ RMC is the ratio of the weight of water contained by the
test load to the bone-dry weight of the test load, expressed as a
percent.
\8\ A notation in this form provides a reference for information
that is in the docket of DOE's rulemaking to develop energy
conservation standards for clothes dryers and room air conditioners
(Docket No. EERE-2007-BT-STD-0010), which is maintained in the
Resource Room of the Building Technologies Program. This notation
indicates that the statement preceding the reference was made in
DOE's Framework Document, which is document number 1 in the docket
for the clothes dryer and room air conditioner energy conservation
standards rulemaking, and appears at pages 4-6 of that document.
---------------------------------------------------------------------------
EPCA directs DOE to incorporate standby and off mode energy use
into any final rule establishing or revising a standard for a covered
product adopted after July 1, 2010. (42 U.S.C. 6295(gg)(3)) DOE is
required by consent decree to publish a final rule setting forth any
revised efficiency standards for clothes dryers and room air
conditioners by June 30, 2011. As result, this final rule must
incorporate standby and off mode energy use.
II. Summary of the Proposal
In today's final rule, DOE amends its test procedures for clothes
dryers and room air conditioners to: (1) Use in the concurrent
development of energy conservation standards that address the energy
use of these products when in standby mode and off mode, as well as in
the implementation of any amended standards; (2) address the statutory
requirement to expand test procedures to incorporate measures of
standby mode and off mode power consumption; (3) adopt changes to the
water temperature for clothes dryer test load preparation; (4) expand
the clothes dryer test procedures to accommodate ventless clothes
dryers being considered for coverage under an amended energy
conservation standard; (5) adopt technical changes to better reflect
current usage patterns and capabilities for the covered products; (6)
update detergent specifications for clothes dryer test cloth
preconditioning; (7) update the references to external test procedures;
(8) clarify the test conditions for gas clothes dryers; and (9) clarify
the test conditions for clothes dryer drum capacity measurements. As
discussed in this section, DOE is not adopting the technical changes
and procedures to more accurately measure the effects of different
automatic cycle termination technologies in clothes dryers proposed in
the June 2010 TP SNOPR. The following paragraphs summarize the
amendments.
Standby and Off Mode
In today's final rule, DOE incorporates by reference into both the
clothes dryer and room air conditioner test procedures specific clauses
from IEC
[[Page 976]]
Standard 62301 regarding test conditions and test procedures for
measuring standby mode and off mode power consumption. DOE also
incorporates into each test procedure the definitions of ``active
mode,'' ``standby mode,'' and ``off mode'' based on the definitions
provided in IEC Standard 62301 CDV. Further, DOE adopts additional
language in each test procedure to clarify how clauses from IEC
Standard 62301 and the mode definitions from IEC Standard 62301 CDV are
to be applied when measuring standby mode and off mode power
consumption.\9\
---------------------------------------------------------------------------
\9\ EISA 2007 directs DOE to also consider IEC Standard 62087
when amending its test procedure to include standby mode and off
mode energy consumption. See 42 U.S.C. 6295(gg)(2)(A). As explained
subsequently in this notice, because IEC Standard 62087 addresses
the methods of measuring the power consumption of audio, video, and
related equipment, it is inapplicable to the products at issue in
this rulemaking.
---------------------------------------------------------------------------
For reasons discussed in section III.B.2 for clothes dryers, DOE
adopts a definition and testing procedures for a single standby mode,
rather than the multiple standby modes--``inactive'' mode, ``cycle
finished'' mode, and ``delay start'' mode--as proposed in the December
2008 TP NOPR. 73 FR 74639, 74645 (December 9, 2008). DOE also adopts
new methods to calculate clothes dryer standby mode and off mode energy
use, as well as a new measure of energy efficiency--Combined Energy
Factor (CEF)--that includes energy use in standby mode and off mode.
The standby mode and off mode amendments do not change the method to
calculate the existing clothes dryer energy efficiency metric for
active mode, the energy factor (EF).
Similarly, for reasons discussed in section III.B.2 for room air
conditioners, DOE adopts a definition and testing procedures for a
single standby mode, rather than the multiple standby modes--
``inactive'' mode, ``delay start'' mode, and ``off-cycle'' mode--as
proposed in the December 2008 TP NOPR. 73 FR 74639, 74645. DOE also
adopts new methods to calculate room air conditioner standby mode and
off mode energy use and a new measure of energy efficiency--Combined
Energy Efficiency Ratio (CEER)--that includes energy use in the standby
mode and the off mode. The standby mode and off mode amendments do not
change the method used to calculate the existing room air conditioner
energy efficiency metric for active mode, the energy efficiency ratio
(EER).
In the December 2008 TP NOPR, DOE also proposed that standby mode
and off mode testing be conducted with room-side air temperature at 74
2 degrees Fahrenheit ([deg]F), with a temperature control
setting of 79 [deg]F. 73 FR 74639, 74646. Upon further consideration,
however, DOE determined that, because the proposed test procedure would
be limited to measuring a single standby mode and an off mode, the
proposed close tolerance on ambient temperature and the proposed
temperature setting of 79 [deg]F, which were relevant only for an off-
cycle standby mode measurement, would not be required. Therefore, DOE
is not adopting those requirements for testing conditions in today's
final rule.
In the June 2010 TP SNOPR, DOE proposed that standby mode and off
mode testing for both clothes dryers and room air conditioners be
conducted at the settings that produce the highest power consumption
level, consistent with the particular mode definition under test. 75 FR
37594, 37604 (June 29, 2010). Upon further consideration, however, DOE
believes that provisions for testing in the settings that produce the
highest power consumption level would not be representative of consumer
usage. For the reasons discussed in section III.B.2, DOE believes the
provisions in section 5.2 of IEC Standard 62301 that specify the
appliance be installed and set up in accordance with manufacturers'
instructions, or if no instructions are given, the appliance be tested
at factory or ``default'' settings, is more representative of consumer
usage. Therefore, DOE amends the test procedure in today's final rule
to incorporate by reference section 5.2 of IEC Standard 62301 for
standby and off mode testing for both clothes dryers and room air
conditioners in today's final rule.
For the reasons discussed in section III.B.5, DOE revises the
estimated annual operating cost calculation for both clothes dryers and
room air conditioners (Estimated Annual Operating Cost and Annual
Energy Cost, respectively) to integrate the cost of energy use in the
standby mode and off mode.
Amendments to the Water Temperature for Clothes Dryer Test Load
Preparation
The existing DOE clothes dryer test procedure requires that the
test load be agitated in water whose temperature is 100 [deg]F 5 [deg]F. In the June 2010 TP SNOPR, DOE stated that it did not
have data indicating whether a different water temperature for clothes
dryer test load preparation would be more representative of current
consumer usage, but that if consumer usage data is made available that
indicates a 60 [deg]F 5 [deg]F water temperature is more
representative of consumer use, DOE may adopt this alternate approach.
75 FR 37594, 37615 (June 29, 2010). As discussed in section III.C.2,
DOE believes that the cold water rinse cycle is more representative of
typical consumer use based on the rinse temperature use factors in the
DOE clothes washer test procedure and the Energy Information
Administration (EIA) 2005 ``Residential Energy Consumption Survey''
(RECS) 10 11 data reporting the percentage of clothes washer
cycles for which consumers use cold water for the rinse cycle.
Therefore, DOE amends the clothes dryer test procedure in today's final
rule to change the water temperature for clothes dryer test load
preparation to 60 [deg]F 5 [deg]F. This temperature is
more representative of the clothes load temperature after a cold rinse
cycle at the end of the wash cycle.
---------------------------------------------------------------------------
\10\ U.S. Department of Energy-Energy Information
Administration. Residential Energy Consumption Survey 2005 Public
Use Data Files, 2005. Washington, DC. Available online at: https://www.eia.doe.gov/emeu/recs/.
\11\ EIA's 2005 RECS is the latest available version of this
survey.
---------------------------------------------------------------------------
Provisions for Testing Ventless Clothes Dryers
In today's final rule, DOE amends the current clothes dryer test
procedure to include provisions for testing ventless clothes dryers.
These provisions are based upon an alternate test procedure developed
by DOE and proposed in the June 2010 TP SNOPR that provide separate
definitions for a ``conventional clothes dryer'' and a ``condensing
clothes dryer.'' These provisions also qualify the requirement for an
exhaust simulator so that it would apply only to conventional clothes
dryers. Further, DOE includes in the test procedure additional language
based on provisions from European Standard EN 61121, ``Tumble dryers
for household use--Methods for measuring the performance,'' Edition 3
2005 (the EN Standard 61121). These provisions clarify the alternate
test procedure developed by DOE. EN Standard 61121 is an
internationally-accepted test standard that specifies methods for
testing ventless clothes dryers. The clarifications require that if a
ventless clothes dryer is equipped with a condensation box, the clothes
dryer shall be tested with such condensation box installed as specified
by the manufacturer. A condensation box stores condensed moisture
removed from the air exiting the drum. The box is later emptied by the
user. In addition, the clarifications also state that if the clothes
dryer stops the test cycle because the condensation box is full, the
[[Page 977]]
test is not valid because the unit would not be operating as intended
by the manufacturer to condense moisture in the air exiting the clothes
dryer drum. In such cases, the condensation box must be emptied and the
test re-run from the beginning. The clarifications also state that the
condenser heat exchanger cannot be taken out of the clothes dryer
between tests to clarify the test procedure and ensures that all
manufacturers are testing products under the same conditions. Finally,
DOE adopts clarifications that address clothes dryer preconditioning
for ventless clothes dryers, as discussed in section III.C.3.
Amendments To Reflect Current Usage Patterns and Capabilities
DOE amends the test procedure for clothes dryers to reflect current
usage patterns and capabilities. These amendments are based on DOE's
analysis of consumer usage patterns data. As proposed in the June 2010
SNOPR, DOE revises the number of annual use cycles from the 416 cycles
per year currently specified by the DOE test procedure to 283 cycles
per year for all types (that is, product classes) of clothes dryers.
This revision is based on DOE's analysis of data from the 2005 RECS for
the number of laundry loads (clothes washer cycles) washed per week and
the frequency of clothes dryer use. In addition, as proposed in the
2010 SNOPR, DOE changes the 7-pound (lb) clothes dryer test load size
specified by the current test procedure for standard-size clothes
dryers to 8.45 lb. This revision is based on the historical trends of
clothes washer tub volumes and the corresponding percentage increase in
clothes washer test load sizes (as specified by the DOE clothes washer
test procedure). DOE assumes these historical trends proportionally
impact clothes dryer load sizes. DOE believes most compact clothes
dryers are used in conjunction with compact-size clothes washers,
however, and DOE does not have any information to suggest that the tub
volume of such clothes washers has changed significantly. Therefore,
DOE is not changing the 3-lb test load size currently specified in its
clothes dryer test procedure for compact clothes dryers in today's
final rule.
In the June 2010 TP SNOPR, DOE also proposed to revise the 70-
percent initial RMC required by the test procedure to 47 percent so as
to accurately represent the condition of a laundry load after a wash
cycle. This proposal was based on analysis of shipment-weighted RMC
data for clothes washers submitted by AHAM and a distribution analysis
of RMC data for clothes washer models listed in the December 22, 2008
California Energy Commission (CEC) directory. 75 FR 37594, 37599 (June
29, 2010). In response to comments from interested parties on the June
2010 TP SNOPR, DOE determined that an initial clothes dryer RMC of 57.5
percent more accurately represents the moisture content of laundry
loads after a wash cycle for the purposes of clothes dryer testing. As
discussed in section III.5.b, this RMC is derived from the 47-percent
shipment-weighted RMC for clothes washers, but was derived without
applying an RMC correction factor as required by the DOE clothes washer
test procedure. For these reasons, DOE revises the initial clothes
dryer RMC from 70 percent to 57.5 percent in today's final rule.
Clothes Dryer Automatic Cycle Termination
In the June 2010 TP SNOPR, DOE proposed to revise its clothes dryer
test procedure to include definitions of and provisions for testing
both timer dryers and automatic termination control dryers using
methodology provided in Australia/New Zealand (AS/NZS) Standard 2442.1:
1996, ``Performance of household electrical appliances--Rotary clothes
dryers, Part 1: Energy consumption and performance'' (AS/NZS Standard
2442.1) and AS/NZS Standard 2442.2: 2000, ``Performance of household
electrical appliances--Rotary clothes dryers, Part 2: Energy labeling
requirements'' (AS/NZS Standard 2442.2). 75 FR 37594, 37598 (June 29,
2010). DOE proposed to incorporate the testing methods from these
international test standards, along with a number of clarifications, to
measure the energy consumption for both timer dryers and automatic
termination control dryers. The measurement would account for the
amount of over-drying energy consumption, that is, the energy consumed
by the clothes dryer after the load reaches an RMC of 5 percent. 75 FR
37594, 37599 (June 29, 2010).
DOE conducted testing of representative clothes dryers using the
automatic cycle termination test procedure proposed in the June 2010 TP
SNOPR; however, the test results showed that all of the clothes dryers
tested significantly over-dried the DOE test load to near bone dry. In
addition, the measured EF values were significantly lower than EF
values obtained using the existing DOE test procedure, and the test
data indicated that clothes dryers equipped with automatic termination
controls were less efficient than timer dryers. DOE believes the test
procedure amendments for automatic cycle termination proposed in the
June 2010 TP SNOPR do not adequately measure the energy consumption of
clothes dryers equipped with such systems using the test load specified
in the DOE test procedure. DOE believes that clothes dryers with
automatic termination sensing control systems, which infer the RMC of
the load from the properties of the exhaust air such as temprature and
humidity, may be designed to stop the cycle when the consumer load has
a higher RMC than the RMC obtained using the proposed automatic cycle
termination test procedure in conjunction with the existing test
load.\12\ Manufacturers have indicated, however, that test load types
and test cloth materials different than those specified in the DOE test
procedure do not produce results as repeatable as those obtained using
the test load as currenty specified. In addition, DOE presented data in
the May 1981 TP Final Rule from a field use survey conducted by AHAM as
well as an analysis conducted by the National Bureau of Standards (now
known as the National Institute of Standards and Technology (NIST)) of
field test data on automatic termination control dryers. Analysis of
this data showed that clothes dryers equipped with an automatic cycle
termination feature consume less energy than timer dryers by reducing
over-drying. 46 FR 27324 (May 19, 1981).
---------------------------------------------------------------------------
\12\ To investigate this, DOE conducted additional testing using
a test load similar to that specified in AHAM Standard HLD-1-2009,
which consists of cotton bed sheets, towels, and pillow cases. For
tests using the same automatic cycle termination settings as were
used in the testing described earlier (i.e., normal cycle setting
and highest temperature setting, the alternate test load was dried
to 1.7 to 2.2 percent final RMC, with an average RMC of 2.0 percent.
In comparison, the same clothes dryer under the same cycle settings
dried the DOE test load to 0.3 to 1.2 percent RMC, with an average
RMC of 0.7 percent. Thus, DOE concluded that the proposed automatic
cycle termination control test procedures may not stop at an
appropriate RMC when used with the current test load.
---------------------------------------------------------------------------
For the reasons discussed above, DOE believes the test procedure
amendments for automatic cycle termination proposed in the June 2010 TP
SNOPR do not adequately measure the energy consumption of clothes
dryers equipped with such systems. As a result, DOE is not adopting the
amendments for automatic cycle termination proposed in the June 2010 TP
SNOPR. 75 FR 37594, 37598-99 (June 29, 2010). If data is made available
to develop a test procedure that accurately measures the energy
consumption of clothes dryers equipped with automatic termination
controls, DOE may consider revised amendments in a future rulemaking.
[[Page 978]]
DOE received comments in response to the June 2010 TP SNOPR that it
should revise the definition of ``automatic termination control'' in
the current clothes dryer test procedure. Commenters felt the
definition should more clearly account for electronic controls by
specifying that a preferred automatic termination control setting can
also be indicated by any other visual indicator (in addition to a mark
or detent). DOE agrees this clarification should be added and is
amending the definition of ``automatic termination control'' in the
clothes dryer test procedure to include it.
DOE also received comments stating that the field-use factor for
clothes dryers with automatic cycle termination applied in the per-
cycle energy consumption calculation excludes sensing technologies that
do not meet the definitions of ``temperature sensing control'' or
``moisture sensing control,'' which are narrowly defined to require
that the control system use either a temperature sensor that monitors
the exhaust air or a moisture sensor contained within the drum. DOE
believes the definition of ``automatic termination control'' more
broadly applies to any sensing system that monitors either the dryer
load temperature or its moisture content and that this definition would
not limit the emergence of any new sensor technologies that monitor the
moisture content or temperature in other ways from applying the field
use factor for automatic cycle termination. For these reasons, DOE
amends the test procedure to specify that the field use factor applies
to clothes dryers that meet the requirements for the definitions of
``automatic termination control.''
Other Changes
For clothes dryers, DOE also revises the detergent specifications
for test cloth preconditioning to update the detergent specified in the
test procedure, eliminates an unnecessary reference to an obsolete
industry clothes dryer test standard, and amends the test conditions
for gas clothes dryers to specify the required gas supply pressure.
DOE also received comments related to clothes dryers from
interested parties on issues not addressed in the June 2010 TP SNOPR.
Commenters suggested that DOE clarify the provisions for the
measurement of drum capacity to specify that the clothes dryer's rear
drum surface be supported on a platform scale to ``prevent deflection
of the drum surface * * *'' instead of ``prevent deflection of the
dryer.'' As discussed in section III.C.10.e, DOE agrees with these
comments and adopts that provision in today's final rule. In addition,
DOE received comments in response to the June 2010 TP SNOPR that it
should expressly state the equations for EF and CEF in the test
procedure to provide optimal clarity for the regulated industry. DOE
agrees with comments that the equations for EF and CEF should be
included in 10 CFR part 430, subpart B, appendix D1 for completeness.
Therefore, DOE amends the clothes dryer test procedure in today's final
rule to include those calculations and to clarify in 10 CFR part
430.23(d)(2) and (3) that the EF and CEF must be determined in
accordance with the appropriate sections in 10 CFR part 430, subpart B,
appendix D1.
For room air conditioners, DOE updates the references in its
current room air conditioner test procedure to incorporate the most
recent ANSI and ASHRAE test standards--ANSI/AHAM RAC-1-R2008, ``Room
Air Conditioners,'' (ANSI/AHAM RAC-1-R2008) and ANSI/ASHRAE Standard
16-1983 (RA 2009) ``Method of Testing for Rating Room Air Conditioners
and Packaged Terminal Air Conditioners'' (ANSI/ASHRAE Standard 16-1983
(RA 2009)). DOE has also determined that the 750 annual operating hours
specified by the current DOE test procedure is representative of
current usage patterns, based upon its interpretation of data from the
2005 RECS. Therefore, DOE is not amending the annual usage hours
specified by the current DOE test procedure for room air conditioners.
As noted in section I, EPCA requires that DOE determine to what
extent, if any, test procedure amendments would alter the measured
energy efficiency of any covered product as determined under the
existing test procedure. (42 U.S.C. 6293(e)(1)) If DOE determines that
the amended test procedure would alter the measured efficiency of a
covered product, DOE must amend the applicable energy conservation
standard. In determining the amended energy conservation standard, DOE
must measure, pursuant to the amended test procedure, the energy
efficiency, energy use, or water use (as applicable) of a
representative sample of covered products that minimally comply with
the existing standard. (42 U.S.C. 6293(e)(2)) Under 42 U.S.C.
6295(gg)(2)(C), EPCA provides that amendments to the test procedures
that include standby mode and off mode energy consumption will not
determine compliance with previously established standards. (U.S.C.
6295(gg)(2)(C))
These amended clothes dryer and room air conditioner test
procedures are effective 30 days after the publication of today's final
rule in the Federal Register. Because the amendments to the test
procedures for measuring standby mode and off mode energy consumption
do not alter the existing measures of energy consumption or efficiency
for clothes dryers and room air conditioners, the amendments do not
affect a manufacturer's ability to comply with current energy
conservation standards. Manufacturers will not be required to use the
amended test procedures' standby mode and off mode provisions until the
mandatory compliance date of any amended clothes dryer and room air
conditioner energy conservation standards. All representations related
to standby mode and off mode energy consumption of both clothes dryers
and room air conditioners made 180 days after the publication of
today's final rule must be based upon the standby and off mode
requirements of the amended test procedures. (42 U.S.C. 6293(c)(2)) DOE
examines how each of the amendments to the active mode provisions in
its clothes dryer and room air conditioner test procedures in today's
final rule will affect the measured efficiency of products in section
IV.
III. Discussion
A. Products Covered by the Test Procedure Changes
Today's amendments to DOE's clothes dryer test procedure cover both
electric and gas clothes dryers, DOE defines a clothes dryer to mean a
cabinet-like appliance designed to dry fabrics in a tumble-type drum
with forced air circulation, with blower(s) driven by an electric
motor(s) and either gas or electricity as the heat source.
Porticos Inc. (Porticos) commented in response to the June 2010 TP
SNOPR that DOE's definition for an electric clothes dryer excludes
every possible alternative from consideration. Porticos stated that any
alternate innovative clothes dryer technology, such as microwave,
radio-frequency, vacuum, desiccant, and vapor-compression, would not
meet the current electric clothes dryer definition, and direct
comparisons would not be possible. Porticos commented that a better
definition would be ``an electrical appliance for drying clothes'' and
that any more limiting verbiage serves only to exclude new entrants
from the marketplace. (Porticos, No. 23 at p. 1) Porticos also
commented that DOE should reexamine the test procedures to remove any
explicit or implicit reference to a particular technology or
[[Page 979]]
approach to clothes drying. (Porticos, No. 23 at p. 2)
DOE notes that the definition of a clothes dryer in the CFR does
not prohibit other products (that is, those that do not fall under the
definition of a clothes dryer) from being introduced to the market. For
example, spin dryers or drying cabinets that do not use a heat source,
forced air circulation, or a tumble-type drum are currently
commercially available. Under the product definition suggested by
Porticos, DOE notes that blow dryers, fans, or heat lamps could be
considered covered products. DOE is also not aware of any commercially
available microwave, radio-frequency, vacuum, desiccant, or vapor-
compression clothes dryers. As a result, no data is available by which
DOE could develop standards for such dryers. For these reasons, DOE is
not revising the definition of a clothes dryer in today's final rule.
DOE's regulations define a room air conditioner as a consumer
product which is powered by a single-phase electric current and which
is an encased assembly designed as a unit for mounting in a window or
through the wall for the purpose of providing delivery of conditioned
air to an enclosed space. It includes a prime source of refrigeration
and may include a means for ventilating and heating. It does not
include packaged terminal air conditioners.\13\ This definition and the
amendments discussed below cover room air conditioners designed for
single- or double-hung windows with or without louvered sides and with
or without reverse cycle, as well as casement-slider and casement-only
window-type room air conditioners. DOE is not changing the definition
for room air conditioners in today's final rule.
---------------------------------------------------------------------------
\13\ DOE's regulations define a packaged terminal air
conditioner as a wall sleeve and a separate encased combination of
heating and cooling assemblies specified by the builder and intended
for mounting through the wall. It includes a prime source of
refrigeration, separable outdoor louvers, forced ventilation, and
heating availability energy.
---------------------------------------------------------------------------
B. Clothes Dryer and Room Air Conditioner Standby Mode and Off Mode
Test Procedures
1. Incorporating by Reference IEC Standard 62301 for Measuring Standby
Mode and Off Mode Power in Clothes Dryers and Room Air Conditioners
As noted in the December 2008 TP NOPR, DOE considered, pursuant to
EPCA, the most current versions of IEC Standard 62301 and IEC Standard
62087 for measuring power consumption in standby mode and off mode. (42
U.S.C. 6295(gg)(2)(A)) 73 FR 74639, 74643-44 (December 9, 2008).\14\
DOE noted that IEC Standard 62301 provides for measuring standby power
in electrical appliances, including clothes dryers and room air
conditioners, and, therefore, is applicable to the proposed amendments
to the clothes dryer and room air conditioner test procedures. 73 FR
74643-44 (December 9, 2008).
---------------------------------------------------------------------------
\14\ DOE notes that IEC Standard 62087 specifies methods of
measuring the power consumption of TV receivers, videocassette
recorders (VCRs), set top boxes, audio equipment, and multi-function
equipment for consumer use. IEC Standard 62087 does not include
measurement for the power consumption of electrical appliances such
as clothes dryers and room air conditioners. Therefore, IEC Standard
62087 is not applicable to the amendments to the clothes dryer and
room air conditioner test procedures.
---------------------------------------------------------------------------
DOE proposed in the December 2008 TP NOPR to incorporate by
reference into the DOE test procedures for clothes dryers and room air
conditioners specific clauses from IEC Standard 62301 for measuring
standby mode and off mode power: from section 4 (``General conditions
for measurements''); paragraph 4.2, ``Test room''; paragraph 4.4,
``Supply voltage waveform''; and paragraph 4.5, ``Power measurement
accuracy''; as well as from section 5 (``Measurements''); paragraph
5.1, ``General''; and paragraph 5.3, ``Procedure.'' DOE also proposed
to reference these same provisions in the DOE test procedure for room
air conditioners, as well as section 4, paragraph 4.3, ``Power
supply.'' 73 FR 74639, 74644 (December 9, 2008).
In the December 2008 TP NOPR, DOE noted that EPCA (42 U.S.C.
6295(gg)(2)(A)) requires that in developing any amended test
procedures, DOE consider the most current version of IEC Standard
62301. The IEC is currently developing an updated version of this
standard, IEC Standard 62301 Second Edition. 73 FR 74639, 74644
(December 9, 2008). At the time of publication of the December 2008 TP
NOPR, however, IEC Standard 62301 was the ``current version, which DOE
was required by EPCA to consider. DOE incorporated sections from IEC
Standard 62301 in the proposed amendments to the test procedure in the
December 2008 TP NOPR. 73 FR 74639, 74644 (December 9, 2008).
DOE did not receive any objections to the proposed testing methods
and procedures referenced in IEC Standard 62301 in response to the
December 2008 TP NOPR. As a result, the June 2010 TP SNOPR did not
affect DOE's proposal in the December 2008 TP NOPR to incorporate by
reference the clauses presented above from IEC Standard 62301. 75 FR
37594, 37602 (June 29, 2010).
DOE anticipated, based on review of draft versions of IEC Standard
62301 Second Edition, that the revisions to IEC Standard 62301 could
include different mode definitions. DOE received information, however,
that IEC Standard 62301 Second Edition would not be available until
late 2010. To allow for consideration of standby and off mode power
consumption in the concurrent energy conservation standards rulemaking,
DOE proposed in the June 2010 TP SNOPR the new mode definitions from
the most recent draft version of IEC Standard 62301 Second Edition, IEC
Standard 62301 CDV. The definitions of standby mode, off mode, and
active mode in IEC Standard 62301 CDV expand upon the EPCA mode
definitions and provide additional guidance as to which functions are
associated with each mode. 75 FR 37594, 37602 (June 29, 2010). The
comments received by IEC on IEC Standard 62301 CD2, and the resulting
amended mode definitions proposed in IEC Standard 62301 CDV,
demonstrate significant participation of interested parties in the
development of definitions that represent a substantial improvement
over those in IEC Standard 62301. Id. These definitions are discussed
in detail in Section III.B.2.
In response to the June 2010 TP SNOPR, AHAM, Alliance Laundry
Systems (ALS), and Whirlpool Corporation (Whirlpool) commented in
support of referencing the most recent draft version of IEC Standard
62301 Second Edition, designated as IEC Standard 62301 FDIS, for test
methods and mode definitions rather than IEC Standard 62301 First
Edition and IEC Standard 62301 CDV. (AHAM, Public Meeting Transcript,
No. 20 at pp. 18, 26-27; AHAM, No. 27 at p. 2; ALS, No. 24 at p. 1;
Whirlpool, No. 27 at p. 1)
AHAM and Whirlpool commented that IEC Standard 62301 FDIS will soon
be formally adopted by IEC, and it contains a number of clarifications
to the definitions and test procedures not present in IEC Standard
62301 CDV. According to AHAM and Whirlpool, this will allow for optimum
international harmonization, giving clarity and consistency to the
regulated community and decreasing testing burden. (AHAM, No. 31 at p.
2; Whirlpool, No. 27 at p. 1) Additionally, AHAM commented that no
technical edits can be made to the standard after the FDIS version, so
most countries allow a legal reference to this version. (AHAM, Public
Meeting Transcript, No. 20 at pp. 14-15)
AHAM commented that IEC Standard 62031 FDIS incorporates comments
from energy efficiency advocates,
[[Page 980]]
including the addition of an uncertainty power measurement section that
would limit the possibility for different measurement results from
different test labs. (AHAM, Public Meeting Transcript, No. 20 at pp.
16, 18, 26-27) AHAM also noted that IEC Standard 62301 FDIS includes a
new sampling measurement method and an average reading measurement
method. (AHAM, Public Meeting Transcript, No. 20 at pp. 13-18) AHAM
commented that if DOE chooses not to adopt the IEC Standard 62301 FDIS,
AHAM supports the use of IEC Standard 62301 CDV as the main referenced
document. (AHAM, No. 31 at p. 2) Pacific Gas and Electric Company
(PG&E), Southern California Gas Company (SCGC), Southern California
Edison (SCE), and Natural Resources Defense Council (NRDC) (hereafter
``the California Utilities/NRDC''), stated in a jointly filed comment
that they support harmonization with international standards and
support the use of the definitions and test procedures in IEC Standard
62301 CDV. (California Utilities/NRDC, No. 33 at p. 2)
According to publicly available information, the IEC currently
anticipates that the final version of IEC Standard 62301 Second Edition
will likely be published in early 2011. Therefore, the second edition
is not available for DOE's consideration or incorporation by reference.
DOE is aware that there are significant differences between IEC
Standard 62301 First Edition and IEC Standard 62301 FDIS, which is the
latest draft version of IEC Standard 62301 Second Edition. DOE notes
that these changes in methodology were first introduced only at the IEC
Sta
