SIST EN 62282-6-100:2010

SLOVENSKI STANDARD
01-september-2010
Tehnologija gorivnih celic - 6-100. del: Tehnologija mikro gorivnih celic - Varnost
(IEC 62282-6-100:2010)
Fuel cell technologies - Part 6-100: Micro fuel cell power systems - Safety (IEC 62282-6-
100:2010)
Brennstoffzellentechnologien - Teil 6-100: Mikro-Brennstoffzellen-Energiesysteme -
Sicherheit (IEC 62282-6-100:2010)
Technologies des piles à combustible - Partie 6-100: Système à micro-piles à
combustible - Sécurité (CEI 62282-6-100:2010)
Ta slovenski standard je istoveten z: EN 62282-6-100:2010
ICS:
27.070 Gorilne celice Fuel cells
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

EUROPEAN STANDARD
EN 62282-6-100
NORME EUROPÉENNE
April 2010
EUROPÄISCHE NORM
ICS 27.070
English version
Fuel cell technologies -
Part 6-100: Micro fuel cell power systems -
Safety
(IEC 62282-6-100:2010)
Technologies des piles à combustible -  Brennstoffzellentechnologien -
Partie 6-100: Système à micro-piles Teil 6-100: Mikro-Brennstoffzellen-
à combustible - Sécurité Energiesysteme - Sicherheit
(CEI 62282-6-100:2010) (IEC 62282-6-100:2010)

This European Standard was approved by CENELEC on 2010-04-01. CENELEC members are bound to comply
with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard
the status of a national standard without any alteration.

Up-to-date lists and bibliographical references concerning such national standards may be obtained on
application to the Central Secretariat or to any CENELEC member.

This European Standard exists in three official versions (English, French, German). A version in any other
language made by translation under the responsibility of a CENELEC member into its own language and notified
to the Central Secretariat has the same status as the official versions.

CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus,
the Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,
Latvia, Lithuania, Luxembourg, Malta, the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia,
Spain, Sweden, Switzerland and the United Kingdom.

CENELEC
European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung

Management Centre: Avenue Marnix 17, B - 1000 Brussels

© 2010 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members.
Ref. No. EN 62282-6-100:2010 E

Foreword
The text of document 105/255/FDIS, future edition 1 of IEC 62282-6-100, prepared by IEC TC 105, Fuel
cell technologies, was submitted to the IEC-CENELEC parallel vote and was approved by CENELEC as
EN 62282-6-100 on 2010-04-01.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN and CENELEC shall not be held responsible for identifying any or all such patent
rights.
The following dates were fixed:
– latest date by which the EN has to be implemented
at national level by publication of an identical
(dop) 2011-01-01
national standard or by endorsement
– latest date by which the national standards conflicting
(dow) 2013-04-01
with the EN have to be withdrawn
Annex ZA has been added by CENELEC.
__________
Endorsement notice
The text of the International Standard IEC 62282-6-100:2010 was approved by CENELEC as a European
Standard without any modification.
In the official version, for Bibliography, the following notes have to be added for the standards indicated:
IEC 62282-5-1 NOTE  Harmonized as EN 62282-5-1.
IEC 61025 NOTE  Harmonized as EN 61025.
IEC 60812 NOTE  Harmonized as EN 60812.
__________
- 3 - EN 62282-6-100:2010
Annex ZA
(normative)
Normative references to international publications
with their corresponding European publications

The following referenced documents are indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced
document (including any amendments) applies.

NOTE  When an international publication has been modified by common modifications, indicated by (mod), the relevant EN/HD
applies.
Publication Year Title EN/HD Year

IEC 60050-426 2008 International Electrotechnical Vocabulary - - -
Part 426: Equipment for explosive
atmospheres
IEC 60079-15 2005 Electrical apparatus for explosive gas EN 60079-15 2005
atmospheres -
Part 15: Construction, test and marking of
type of protection "n" electrical apparatus

IEC 60086-4 - Primary batteries - EN 60086-4 -
Part 4: Safety of lithium batteries

IEC 60086-5 - Primary batteries - EN 60086-5 -
Part 5: Safety of batteries with aqueous
electrolyte
IEC 60695-1-1 - Fire hazard testing - EN 60695-1-1 -
Part 1-1: Guidance for assessing the fire
hazard of electrotechnical products - General
guidelines
IEC 60695-2-11 - Fire hazard testing - EN 60695-2-11 -
Part 2-11: Glowing/hot-wire based test
methods - Glow-wire flammability test method
for end-products
IEC 60695-11-10 - Fire hazard testing - EN 60695-11-10 -
Part 11-10: Test flames - 50 W horizontal and
vertical flame test methods
IEC 60730-1 (mod) 1999 Automatic electrical controls for household EN 60730-1 2000
+ A1 (mod) 2003 and similar use - + corr. August 2007
+ A2 (mod) 2007 Part 1: General requirements + A1 2004
- - + A2 2008
- - + A11 2002
- - + A14 2005
- - + A13 2004
- - + A12 2003
- - + A15 2007
+ A16 2007
+ corr. March 2010
IEC 60950-1 (mod) 2005 Information technology equipment - Safety - EN 60950-1 2006
Part 1: General requirements + A11 2009

IEC 61032 1997 Protection of persons and equipment by EN 61032 1998
enclosures - Probes for verification

Publication Year Title EN/HD Year

IEC 62133 2002 Secondary cells and batteries containing EN 62133 2003
alkaline or other non-acid electrolytes -
Safety requirements for portable sealed
secondary cells, and for batteries made from
them, for use in portable applications

IEC 62281 2004 Safety of primary and secondary lithium cells EN 62281 2004
and batteries during transport

ISO 175 - Plastics - Determination of the effects - -
of liquid chemicals, including water

ISO 188 - Rubber, vulcanized or thermoplastic - - -
Accelerated ageing and heat-resistance tests

ISO 1817 - Rubber, vulcanized - Determination of the - -
effect of liquids
ISO 9772 - Cellular plastics - Determination of horizontal - -
burning characteristics of small specimens
subjected to a small flame
ISO 15649 - Petroleum and natural gas industries - Piping - -

ISO 16000-3 - Indoor air - - -
Part 3: Determination of formaldehyde and
other carbonyl compounds - Active sampling
method
ISO 16000-6 - Indoor air - - -
Part 6: Determination of volatile organic
compounds in indoor and test chamber air by
active sampling on Tenax TA sorbent, thermal
desorption and gas chromatography using
MS/FID
ISO 16017-1 - Indoor, ambient and workplace air - Sampling - -
and analysis of volatile organic compounds by
sorbent tube/thermal desorption/capillary gas
chromatography -
Part 1: Pumped sampling
IEC 62282-6-100 ®
Edition 1.0 2010-03
INTERNATIONAL
STANDARD
colour
inside
Fuel cell technologies –
Part 6-100: Micro fuel cell power systems – Safety

INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
PRICE CODE
XN
ICS 27.070 ISBN 2-8318-1078-0
– 2 – 62282-6-100 © IEC:2010(E)
CONTENTS
FOREWORD.9
1 Scope.11
1.1 General .11
1.2 Fuels and technologies covered .11
1.3 Equivalent level of safety.13
2 Normative references .13
3 Terms and definitions .14
4 Materials and construction of micro fuel cell power systems, micro fuel cell power
units and fuel cartridges .18
4.1 General .18
4.2 FMEA / hazard analysis.18
4.3 General materials .18
4.4 Selection of materials.18
4.5 General construction .19
4.6 Fuel valves.19
4.7 Materials and construction – system.20
4.8 Ignition sources.20
4.9 Enclosures and acceptance strategies.21
4.9.1 Parts requiring a fire enclosure.21
4.9.2 Parts not requiring a fire enclosure .21
4.9.3 Materials for components and other parts outside fire enclosures .22
4.9.4 Materials for components and other parts inside fire enclosures .23
4.9.5 Mechanical enclosures .24
4.10 Protection against fire, explosion, corrosivity and toxicity hazard.24
4.11 Protection against electrical hazards .25
4.12 Fuel supply construction.25
4.12.1 Fuel cartridge construction .25
4.12.2 Fuel cartridge fill requirement .26
4.13 Protection against mechanical hazards.26
4.13.1 Piping and tubing other than fuel lines.26
4.13.2 Exterior surface and component temperature limits .26
4.13.3 Motors .27
4.14 Construction of electric device components.28
4.14.1 Limited power sources.28
4.14.2 Devices that use electronic controllers.29
4.14.3 Electrical conductors/wiring .29
4.14.4 Output terminal area.30
4.14.5 Electric components and attachments.30
4.14.6 Protection.30
5 Abnormal operating and fault conditions testing and requirements.31
5.1 General .31
5.2 Compliance testing.31
5.3 Passing criteria .32
5.4 Simulated faults and abnormal conditions for limited power and SELV circuits .32
5.5 Abnormal operation – electromechanical components .32
5.6 Abnormal operation of micro fuel cell power systems or units with integrated
batteries .33

62282-6-100 © IEC:2010(E) – 3 –
5.7 Abnormal operation – simulation of faults based on hazard analysis.33
6 Instructions and warnings for micro fuel cell power systems, micro fuel cell power
units and fuel cartridges .34
6.1 General .34
6.2 Minimum markings required on the fuel cartridge.34
6.3 Minimum markings required on the micro fuel cell power system .34
6.4 Additional information required either on the fuel cartridge or on
accompanying written information or on the micro fuel cell power system or
micro fuel cell power unit.35
6.5 Technical documentation.35
7 Type tests for micro fuel cell power systems, micro fuel cell power units and fuel
cartridges .36
7.1 General .36
7.2 Leakage measurement of methanol and the measuring procedure.37
7.3 Type tests .44
7.3.1 Pressure differential tests .44
7.3.2 Vibration test .46
7.3.3 Temperature cycling test .47
7.3.4 High temperature exposure test.48
7.3.5 Drop test .48
7.3.6 Compressive loading test .49
7.3.7 External short-circuit test.50
7.3.8 Surface, component and exhaust gas temperature test.51
7.3.9 Long-term storage test .51
7.3.10 High-temperature connection test .56
7.3.11 Connection cycling tests .56
7.3.12 Emission test.59
Annex A (normative) Formic acid micro fuel cell power systems.64
Annex B (normative) Hydrogen stored in hydrogen absorbing metal alloy and micro
fuel cell power systems.96
Annex C (normative) Reformed methanol micro fuel cell power systems . 145
Annex D (normative) Methanol clathrate compound micro fuel cell power systems.159
Annex E (normative) Borohydride micro fuel cell power systems: Class 8 (corrosive)
compounds in indirect borohydride fuel cells.183
Annex F (normative) Borohydride micro fuel cell power systems: Class 4.3 (water
reactive) compounds in indirect borohydride fuel cells . 234
Annex G (normative) Borohydride micro fuel cell power systems: Class 8 (corrosive)
compounds in direct borohydride fuel cells.284
Annex H (normative) Butane solid oxide micro fuel cell power systems. 331
Bibliography.370

Figure 1 – Micro fuel cell power system block diagram.12
Figure 2 – Fuel cartridge leakage and mass loss test flow chart for pressure differential,
vibration, drop, and compressive loading tests.38
Figure 3 – Fuel cartridge leakage and mass loss test flow chart for temperature cycling
test and high temperature exposure test .39
Figure 4 – Micro fuel cell power system or micro fuel cell power unit leakage and mass
loss test flow chart for pressure differential, vibration, temperature cycling, drop and
compressive loading tests.40

– 4 – 62282-6-100 © IEC:2010(E)
Figure 5 – Micro fuel cell power system or micro fuel cell power unit leakage and mass
loss test flow chart for external short-circuit test .41
Figure 6 – Micro fuel cell power system or micro fuel cell power unit leakage and mass
loss test flow chart for 68 kPa low external pressure test .42
Figure 7 – Micro fuel cell power system or micro fuel cell power unit leakage and mass
loss test flow chart for 11,6 kPa low external pressure test .43
Figure 8 – Temperature cycling.48
Figure 9 – Fuel cartridge leakage and mass loss test flow chart for long-term storage test .55
Figure 10 – Operational emission rate testing apparatus.60
Figure 11 – Operational emission concentration testing apparatus.60
Figure A.1 – Formic acid micro fuel cell power system block diagram – Replaces
Figure 1 .64
Figure A.2 – Fuel cartridge leakage and mass loss test flow chart for pressure
differential, vibration, drop, and compressive loading tests – Replaces Figure 2 .70
Figure A.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 .71
Figure A.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss flow chart for pressure differential, vibration, temperature cycling test, drop,
and compressive loading tests – Replaces Figure 4.72
Figure A.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 .73
Figure A.6 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 68 kPa low external pressure test – Replaces Figure 6.74
Figure A.7 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 11,6 kPa low external pressure test – Replaces Figure 7.75
Figure A.9 – Fuel cartridge leakage and mass loss test flow chart for long-term
storage test – Replaces Figure 9 .82
Figure A.10 – Operational emission rate testing apparatus – Replaces Figure 10 .83
Figure A.11 – Operational emission concentration testing apparatus – Replaces
Figure 11 .84
Figure A.12 – Hydrogen emission test procedure for operating micro fuel cell power
system .92
Figure B.2 – Fuel cartridge leakage test flow chart for pressure differential, vibration,
drop, and compressive loading tests – Replaces Figure 2. 107
Figure B.3 – Fuel cartridge leakage test flow chart for temperature cycling test and
high temperature exposure test – Replaces Figure 3 .108
Figure B.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss flow chart for pressure differential, vibration, temperature cycling, drop, and
compressive loading tests – Replaces Figure 4.109
Figure B.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 110
Figure B.8 – Temperature cycling – Replaces Figure 8 . 120
Figure B.9 – Fuel cartridge hydrogen leakage and mass loss test flow chart for long-
term storage test – Replaces Figure 9 .131
Figure B.10 – Operational emission rate testing apparatus – Replaces Figure 10 .137
Figure B.12 – Hydrogen emission test procedure for operating micro fuel cell power
system .141
Figure C.1 – General block diagram of a reformed methanol micro fuel cell power
system – Replaces Figure 1.145
Figure C.10 – Operational emission rate testing apparatus – Replaces Figure 10 . 149

62282-6-100 © IEC:2010(E) – 5 –
Figure C.11 – Operational emission concentration testing apparatus – Replaces
Figure 11 .150
Figure C.12 – Hydrogen emission test procedure for operating micro fuel cell power
system .155
Figure D.1 – Methanol clathrate compound micro fuel cell power system block diagram
– Replaces Figure 1.159
Figure D.2 – Fuel cartridge leakage and mass loss test flow chart for pressure
differential, vibration, drop, and compressive loading tests – Replaces Figure 2 . 165
Figure D.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 . 166
Figure D.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for pressure differential, vibration, temperature cycling, drop
and compressive loading tests – Replaces Figure 4.167
Figure D.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 168
Figure D.9 – Fuel cartridge leakage and mass loss test flow chart for long-term storage
test – Replaces Figure 9 .179
Figure D.12 – Fuel cartridge of methanol clathrate compound.160
Figure D.13 – Usage of methanol clathrate compound with micro fuel cell power unit .160
Figure E.1 – Micro fuel cell power system block diagram for liquid Class 8 (corrosive)
borohydride compound fuel with onboard fuel processing – Replaces Figure 1 . 183
Figure E.2 – Fuel cartridge leakage test flow chart for vibration, drop, compressive
loading – Replaces Figure 2 .197
Figure E.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 . 198
Figure E.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for pressure differential, vibration, temperature cycling, drop
and compressive loading tests – Replaces Figure 4.199
Figure E.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 200
Figure E.6 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 68 kPa low external pressure test – Replaces Figure 6. 201
Figure E.7 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 11,6 kPa low external pressure test – Replaces Figure 7. 202
Figure E.8 – Temperature cycling – Replaces Figure 8 . 207
Figure E.9 – Fuel cartridge hydrogen leakage and mass loss test flowchart for long-
term storage test – Replaces Figure 9 .213
Figure E.10 – Operational emission rate testing apparatus – Replaces Figure 10 .223
Figure E.11 – Operational emission concentration testing apparatus – Replaces
Figure 11 .223
Figure E.12 – Hydrogen emission test procedure for operating micro fuel cell power
system – Replaces Figure 12.230
Figure E.13 – Micro fuel cell power system block diagram for liquid Class 8 (corrosive)
borohydride compound fuel with fuel cartridge fuel processing. 184
Figure E.14 – Micro fuel cell power system block diagram for solid Class 8 (corrosive)
borohydride compound fuel with fuel cartridge fuel processing and cartridge fuel
management.185
Figure E.15 – Micro fuel cell power system block diagram for solid Class 8 (corrosive)
compound fuel with cartridge fuel processing and fuel management internal to the
micro fuel cell power unit .186
Figure E.16 – Fuel cartridge leakage test flow chart for external pressure test. 231

– 6 – 62282-6-100 © IEC:2010(E)
Figure F.1 – Borohydride micro fuel cell power system block diagram for Class 4.3
(water reactive) compound fuel in indirect borohydride fuel cell system; fuel
management in micro fuel cell power unit – Replaces Figure 1 . 235
Figure F.2 – Fuel cartridge leakage test flow chart for pressure differential, vibration,
drop, and compressive loading tests – Replaces Figure 2. 247
Figure F.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 . 248
Figure F.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for pressure differential, vibration, temperature cycling, drop
and compressive loading tests – Replaces Figure 4.249
Figure F.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 250
Figure F.6 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 68 kPa low external pressure test – Replaces Figure 6. 251
Figure F.7 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 11,6 kPa low external pressure test – Replaces Figure 7. 252
Figure F.8 – Temperature cycling – Replaces Figure 8 .257
Figure F.9 – Fuel cartridge leakage and mass loss test flow chart for long-term
storage test – Replaces Figure 9 .263
Figure F.10 – Operational emission rate testing apparatus – Replaces Figure 10 . 273
Figure F.11 – Operational emission concentration testing apparatus – Replaces Figure
11 .273
Figure F.12 – Borohydride micro fuel cell power system block diagram for Class 4.3
(water reactive) compound fuel in indirect borohydride fuel cell system; fuel
management in fuel cartridge.236
Figure F.13 – Hydrogen emission test procedure for operating micro fuel cell power
system .280
Figure F.14 – Fuel cartridge leakage test flow chart for low external pressure test. 281
Figure G.1 – Direct borohydride micro fuel cell power system block diagram –
Replaces Figure 1.284
Figure G.2 – Fuel cartridge leakage test flow chart for pressure differential, vibration,
drop, and compressive loading tests – Replaces Figure 2. 295
Figure G.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 . 296
Figure G.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss flow chart for pressure differential, vibration, temperature cycling, drop, and
compressive loading tests – Replaces Figure 4.297
Figure G.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 298
Figure G.6 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 68 kPa low external pressure test – Replaces Figure 6. 299
Figure G.7 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 11,6 kPa low external pressure test – Replaces Figure 7. 300
Figure G.8 – Temperature cycling – Replaces Figure 8.306
Figure G.9 – Fuel cartridge hydrogen leakage and mass loss test flow chart for long-
term storage test – Replaces Figure 9 .311
Figure G.10 – Operational emission rate testing apparatus – Replaces Figure 10 . 320
Figure G.11 – Operational emission concentration testing apparatus – Replaces
Figure 11 .321
Figure G.12 – Hydrogen emission test procedure for operating micro fuel cell power
system .328

62282-6-100 © IEC:2010(E) – 7 –
Figure G.13 – Fuel cartridge leakage test flow chart for low external pressure test . 301
Figure H.1 – Butane solid oxide micro fuel cell power system block diagram –
Replaces Figure 1.331
Figure H.2 – Fuel cartridge leakage and mass loss test flow chart for vibration, drop
and compressive loading tests – Replaces Figure 2.338
Figure H.3 – Fuel cartridge leakage and mass loss test flow chart for temperature
cycling test and high temperature exposure test – Replaces Figure 3 . 339
Figure H.4 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for pressure differential, vibration, temperature cycling, drop
and compressive loading tests – Replaces Figure 4.340
Figure H.5 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for external short-circuit test – Replaces Figure 5 . 341
Figure H.6 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 68 kPa low external pressure test – Replaces Figure 6. 342
Figure H.7 – Micro fuel cell power system or micro fuel cell power unit leakage and
mass loss test flow chart for 11,6 kPa low external pressure test – Replaces Figure 7. 343
Figure H.8 – Temperature cycling – Replaces Figure 8 . 349
Figure H.9 – Fuel cartridge leakage and mass loss test flow chart for long-term
storage test – Replaces Figure 9 .356
Figure H.10 – Operational emission rate testing apparatus – Replaces Figure 10 . 361
Figure H.11 – Operational emission concentration testing apparatus . 362

Table 1 – Summary of material flammability requirements.22
Table 2 – Temperature limits .27
Table 3 – Limits for inherently limited power sources .28
Table 4 – Limits for power sources not inherently limited (Over-current protection
required).29
Table 5 – List of type tests.36
Table 6 – Laboratory standard conditions .37
Table 7 – Emission limits .63
Table A.5 – List of type tests – Replaces Table 5.68
Table A.6 – Laboratory standard conditions – Replaces Table 6 .69
Table A.7 – Emission limits – Replaces Table 7 .93
Table A.8 – Occupational exposure limits .93
Table B.5 – List of type tests – Replaces Table 5. 105
Table B.6 – Laboratory standard conditions – Replaces Table 6 . 106
Table B.7 – Emission limits – Replaces Table 7 .142
Table C.5 – List of type tests – Replaces Table 5 .148
Table C.6 – Laboratory standard conditions – Replaces Table 6 . 149
Table C.7 – Emission limits – Replaces Table 7. 156
Table C.8 – Occupational exposure limits .156
Table D.5 – List of type tests – Replaces Table 5 .163
Table D.6 – Laboratory standard conditions – Replaces Table 6 . 164
Table E.5 – List of type tests – Replaces table 5. 194
Table E.6 – Laboratory standard conditions – Replaces Table 6 . 195
Table E.7 – Emission limits – Replaces Table 7 .229

– 8 – 62282-6-100 © IEC:2010(E)
Table F.5 – List of type tests – Replaces Table 5.244
Table F.6 – Laboratory standard conditions – Replaces Table 6 .245
Table F.7 – Emission limits – Replaces Table 7 .279
Table G.5 – List of type tests – Replaces Table 5 .292
Table G.6 – Laboratory standard conditions – Replaces Table 6. 293
Table G.7 – Emission limits – Replaces Table 7.327
Table H.5 – List of type tests – Replaces Table 5 .336
Table H.6 – Laboratory standard conditions – Replaces Table 6 . 337
Table H.7 – Emission Limits – Replaces Table 7. 365
Table H.8 – Occupational exposure limits .366

62282-6-100 © IEC:2010(E) – 9 –
INTERNATIONAL ELECTROTECHNICAL COMMISSION
____________
FUEL CELL TECHNOLOGIES –
Part 6-100: Micro fuel cell power systems –
Safety
FOREWORD
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indispensable for the correct application of this publication.
9) Attention is drawn to the possibility that some of the elements of this IEC Publication may be the subject of
patent rights. IEC shall not be held responsible for identifying any or all such patent rights.
International Standard IEC 62282-6-100 has been prepared by IEC technical committee 105:
Fuel cell technologies
This standard cancels and replaces IEC/PAS 62282-6-1 published in 2006. This first edition
constitutes a technical revision.
The text of this standard is based on the following documents:
FDIS Report on v
...