ISO 19880-8:2019/DAmd 1

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23-Sep-2020
Completion Date
22-Sep-2020
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DRAFT AMENDMENT
ISO 19880-8:2019/DAM 1
ISO/TC 197 Secretariat: SCC
Voting begins on: Voting terminates on:
2020-06-30 2020-09-22
Gaseous hydrogen — Fuelling stations —
Part 8:
Fuel quality control
AMENDMENT 1
Hydrogène gazeux — Stations de remplissage —
Partie 8: Contrôle qualité du carburant
AMENDEMENT 1
ICS: 43.060.40; 71.100.20
THIS DOCUMENT IS A DRAFT CIRCULATED
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
IN ADDITION TO THEIR EVALUATION AS
BEING ACCEPTABLE FOR INDUSTRIAL,
This document is circulated as received from the committee secretariat.
TECHNOLOGICAL, COMMERCIAL AND
USER PURPOSES, DRAFT INTERNATIONAL
STANDARDS MAY ON OCCASION HAVE TO
BE CONSIDERED IN THE LIGHT OF THEIR
POTENTIAL TO BECOME STANDARDS TO
WHICH REFERENCE MAY BE MADE IN
Reference number
NATIONAL REGULATIONS.
ISO 19880-8:2019/DAM 1:2020(E)
RECIPIENTS OF THIS DRAFT ARE INVITED
TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
PROVIDE SUPPORTING DOCUMENTATION. ISO 2020
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ISO 19880-8:2019/DAM 1:2020(E)
COPYRIGHT PROTECTED DOCUMENT
© ISO 2020

All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may

be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting

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Published in Switzerland
ii © ISO 2020 – All rights reserved
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ISO 19880-8:2019/DAM 1:2020(E)
Foreword

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bodies (ISO member bodies). The work of preparing International Standards is normally carried out

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electrotechnical standardization.

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described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the

different types of ISO documents should be noted. This document was drafted in accordance with the

editorial rules of the ISO/IEC Directives, Part 2 (see www .iso .org/ directives).

Attention is drawn to the possibility that some of the elements of this document may be the subject of

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expressions related to conformity assessment, as well as information about ISO's adherence to the

World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT) see www .iso .org/

iso/ foreword .html.
This document was prepared by Technical Committee TC 197, Hydrogen technologies.
A list of all parts in the ISO 19880 series can be found on the ISO website.

Any feedback or questions on this document should be directed to the user’s national standards body. A

complete listing of these bodies can be found at www .iso .org/ members .html.
© ISO 2020 – All rights reserved iii
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ISO 19880-8:2019/DAM 1:2020(E)
Gaseous hydrogen — Fuelling stations —
Part 8:
Fuel quality control
AMENDMENT 1
Normative references
Add the following document before ISO 19880-1.
ISO 14687, Hydrogen fuel — Product specification
first paragraph
Replace the paragraph with the following:

The quality requirements of hydrogen fuel dispensed to PEM fuel cells for road vehicles are listed

in Grade D of ISO 14687.
8.4
first paragraphs
Replace Replace the first paragraph with

“It is necessary to evaluate the possible consequences on a fuel cell vehicle if any impurity exceeds the

threshold value of ISO 14687 Grade D.”
Second paragraphs
Replace the second paragraph with

“An estimation of the concentration above the ISO 14687 Grade D threshold values at which the severity

increases (if applicable) is named “Level 1”, and is given in column 5 for each impurity where the

“severity class” is not already 4.”
8.4 Table 4
Replace Table 4 with the following table:
© ISO 2020 – All rights reserved 1
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ISO 19880-8:2019/DAM 1:2020(E)
Table 4 — Impact of impurities on fuel cell powertrain
Severity class
Severity class
ISO 14687 (from ISO 14687
(greater than
Impurity Grade D Grade D Level 1 value
Level 1
threshold value threshold value
threshold)
to Level 1)
[μmol/mol] [μmol/mol]
b b
Total non-H gases 300 UD UD 4
b b
Helium He 300 UD UD 4
b b
Nitrogen N 300 UD UD 4
b b
Argon Ar 300 UD UD 4
b b
Oxygen O 5 UD UD 4
Carbon dioxide CO 2 1 3 4
Carbon monoxide CO 0,2 2-3 1 4
Methane CH 100 1 300 4
Water H O 5 4 NA 4
Total sulphur H S
0,004 4 NA 4
compounds basis
Ammonia NH 0,1 4 NA 4
Total hydrocarbons CH
4 c
2 1-4 NA 4
except methane basis
Formaldehyde HCHO 0,2 2-3 1 4
Formic acid HCOOH 0,2 2-3 1 4
Halogens 0,05 4 NA 4
Maximum particulate
concentration (liquid 1 mg/kg 4 NA 4
and solid)
Key
UD: Undetermined.
NA: Not Applicable.

The threshold value is according to hydrogen specification of Grade D of ISO 14687.

The severity class (from ISO 14687 Grade D threshold value to Level 1) and Level 1 value for this impurity is

undetermined because no specific study was done yet on that in order to be modified to be aligned with the new threshold

value. It needs to be covered in the next edition of this international standard.

A higher value is to be considered for risk assessment approach until more specific data is available.

Particulates are based upon mass density mg/kg.
Annex A
A.15 first paragraph
Replace “ISO 14687-2” with “Grade D of ISO 14687” in the second last sentence.
Annex B
Table B.1
Replace Table B.1 with the following table:
2 © ISO 2020 – All rights reserved
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ISO 19880-8:2019/DAM 1:2020(E)
© ISO 2020 – All rights reserved 3
Table B.1 — Probability of occurrence for off-site SMR
Probabil-
Possible causes ity
Impurity Threshold Typical barriers employed in this process
For the source studied with
barriers
μmol/mol
— PSA
Inert gas Present in natural gas and syn-
300 UD
N gas PSA malfunction
— Double analysis PSA outlet <100 μmol/mol

Inert gas Only ATR and POx present in O — PSA. Not sized to remove Ar. Ar content may be higher if H comes from ATR, POX or

2 2
300 UD
Ar typical 0,6 % in syngas from ATR feeds with high Ar content
Not present in syngas. O is un-
stable in the condition of reform-
O 5 — PSA cannot be used with significant O content for safety reasons 0
2 2
ing and shift reactions. Combines
with H , CO CH
2 4

— PSA adsorption strength of MS, activated carbon, silicagel higher for CO than CO. A

CO 2 Present in syngas (%) 0
CO content lower than 10μmol/mol insures a CO content lower than 2 μmol/mol
Normal operation below thresh-

CO 0,2 old. Occasional peaks at μmol/ — Double analysis at the PSA outlet + trip if the CO>1-10 μmol/mol at PSA outlet 4

mol level

— In most cases CO is sizing the PSA, therefore CO<10 μmol/mol ==> C H < 100 μmol/

CH 100 Present in syngas at % level mol 2
depending on users' specification (Europe pipeline 2 μmol/mol).
— PSA adsorbed in alumina and MS adsorption strength higher than CO .
H O 5 Syngas saturated in H O 0
2 2
A CO content lower than 10 μmol/mol insures a H O content lower than 5 μmol/mol.
Key
UD: Undetermined.

The probability of occurrence for this impurity is undetermined because no specific study was done yet on that in order to be modified to be aligned with the new threshold

value. It needs to be covered in the next edition of this international standard.

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ISO 19880-8:2019/DAM 1:2020(E)
4 © ISO 2020 – All rights reserved
Table B.1 (continued)
Probabil-
Possible causes ity
Impurity Threshold Typical barriers employed in this process
For the source studied with
barriers
μmol/mol
— Desulphuration upstream reformer (typical values: normal < 10 ppb,
maximum < 20 ppb, guarantee < 50 ppb,)
— Typical dilution factor 2,5 (1mole natural gas produces 2,5 mole H )

— Pre-reformer catalyst poisoning by sulphur is irreversible. Sulphur trapped at this

stage.
In case of breakthrough, process condition cannot be achieved
TS 0,004 TS from natural gas 0

— Reformer catalyst poisoning by sulphur is irreversible. Sulphur trapped at this stage.

In case of breakthrough, process condition cannot be achieved

— Shift catalyst poisoning by sulphur is irreversible. Sulphur trapped at this stage.

In case of breakthrough, process condition cannot be achieved
— PSA adsorption of H S before CO, CO , species
2 2
— H S adsorption in pipe and vessels. Strong affinity with steel
— PSA adsorption strength of alumina and molecular sieve higher than CO. A CO
NH 0,1 Traces present in syngas 0
content lower than 10μmol/mol insures a NH content lower than 0,1 μmol/mol

Traces of C2+ after reforming — PSA C2 C3, C4, C5+adsorbed by activated carbon layer. A CO content lower than

THC 2 0
reaction 10 μmol/mol insures a THC (C H excluded) content lower than 2 μmol/mol
— PSA. Formaldehyde adsorption strength of alumina and molecular sieve higher

May be present in syngas. than CO. A CO content lower than 10 μmol/mol insures a HCHO content lower than

HCHO 0,2 UD

essentially liquid 0,1 μmol/mol. To guarantee 0,01 μmol/mol would require more experience of

measuring at those levels
— PSA. Formic adsorption strength of alumina and molecular sieve higher than
May be present in syngas

HCOOH 0,2 CO. A CO content lower than 10 μmol/mol insures a HCOOH content lower than 0

essentially liquid
0,2 μmol/mol
Key
UD: Undetermined.

The probability of occurrence for this impurity is undetermined because no specific study was done yet on that in order to be modified to be aligned with the new threshold

value. It needs to be covered in the next edition of this international standard.

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ISO 19880-8:2019/DAM 1:2020(E)
© ISO 2020 – All rights reserved 5
Table B.1 (continued)
Probabil-
Possible causes ity
Impurity Threshold Typical barriers employed in this process
For the source studied with
barriers
μmol/mol
— Any Cl present in natural gas would be stopped by HDS

— Pre-reformer catalyst poisoning by Cl irreversible Cl trapped at this stage. If

breakthrough, process condition cannot be achieved

— Reformer catalyst poisoning by Cl irreversible. Cl trapped at this stage I break

Halogens 0,05 Present in natural gas 0
through, process condition cannot be achieved

— Shift catalyst poisoning by Cl irreversible. Cl trapped at this stage. I break through,

process condition cannot be achieved
— PSA adsorption of Cl before CO, CO , species
Not present in natural gas in N
Europe (<10 μmol/mol). Passes
He 300 0
through the whole process. Dilu-
tion factor 2,5
Key
UD: Undetermined.

The probability of occurrence for this impurity is undetermined because no specific study was done yet on that in order to be modified to be aligned with the new threshold

value. It needs to be covered in the next edition of this international standard.

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ISO 19880-8:2019/DAM 1:2020(E)
Table B.2
Replace Table B.2 with the following table:
Table B.2 — Probability of occurrence for pipeline
Typical barriers Probability
Causes possible
Impurity Threshold employed in with
For the item studied
this process barriers
μmol/mol
Air intake if some areas are at negative
Inert gas pressure Inlet pressure PSL trip on
300 UD
N From seal gas or purge gas compressors
Wrong purging after maintenance
1 % Ar in the air.
Inert gas 100 μmol/mol would
300 No potential UD
Ar mean 1 % air in the pipe
Never been observed
Air intake if some areas are at negative Inlet pressure PSL trip on
O 5 1
pressure compressors
2 μmol/mol of C O would
mean 0,5 % air in the
CO 2 From Air:C O at 400 μmol/mol in the air 0
2 2
pipe
Never been observed
CO 0,2 No potential 0
CH 100 No potential 0
H > 40 bar ==> leak from
H O 5 Wrong drying after pressure hydraulic test H O to H unlikely during 0
2 2 2
operation.
TS 0,004 No potential 0
NH 0,1 No potential 0
THC 2 No potential 0
HCHO 0,2 No potential UD
HCOOH 0,2 No potential 0
Halogens 0,05 From cleaning material after maintenance 1
He 300 No potential 0
Key
UD: Undetermined.

The probability of occurrence for this impurity is undetermined because no specific study was done yet on that in order

to be modified to be aligned with the new threshold value. It needs to be covered in the next edition of this international

standard.
6 © ISO 2020 – All rights reserved
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ISO 19880-8:2019/DAM 1:2020(E)
Table B.3
Replace Table B.3 with the following table:
Table B.3
...

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