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SIST-TP CEN ISO/TR 12489:2016

(Main)

Petroleum, petrochemical and natural gas industries - Reliability modelling and calculation of safety systems (ISO/TR 12489:2013)

Petroleum, petrochemical and natural gas industries - Reliability modelling and calculation of safety systems (ISO/TR 12489:2013)

This Technical Report aims to close the gap between the state-of-the-art and the application of probabilistic calculations for the safety systems of the petroleum, petrochemical and natural gas industries. It provides guidelines for reliability and safety system analysts and the oil and gas industries to:
• understand the correct meaning of the definitions used in the reliability field;
• identify
— the safety systems which may be concerned,
— the difficulties encountered when dealing with reliability modelling and calculation of safety systems,
— the relevant probabilistic parameters to be considered;
• be informed of effective solutions overcoming the encountered difficulties and allowing to undertake
the calculations of relevant probabilistic parameters;
• obtain sufficient knowledge of the principles and framework (e.g. the modelling power and limitations) of the well-established approaches currently used in the reliability field:
— analytical formulae;[1][2][13]
— Boolean:
• reliability block diagrams;[4]
• fault trees;[5]
— sequential: event trees,[8] cause consequence diagrams[10] and LOPA;[9]
— Markovian;[6]
— Petri nets;[7]
• obtain sufficient knowledge of the principles of probabilistic evaluations:
— analytical calculations (e.g. performed on Boolean or Markovian models);[1][2][3]
— and Monte Carlo simulation (e.g. performed on Petri nets[7]);
• select an approach suitable with the complexity of the related safety system and the reliability study
which is undertaken;
• handle safety and dependability (e.g. for production assurance purpose, see 3.1.1) within the same
reliability framework.
The elementary approaches (e.g. PHA, HAZID, HAZOP, FMECA) are out of the scope of this Technical Report. Yet they are of utmost importance and ought to be applied first as their results provide the input information essential to properly undertake the implementation of the approaches described in this Technical Report: analytical formulae, Boolean approaches (reliability block diagrams, fault trees, event
trees, etc.), Markov graphs and Petri nets.
This Technical Report is focused on probabilistic calculations of random failures and, therefore, the nonrandom (i.e. systematic failures as per the international reliability vocabulary IEV 191[14]) failures are out of the scope even if, to some extent, they are partly included into the reliability data collected from the field.

Erdöl-, petrochemische und Erdgasindustrie - Zuverlässigkeit der Modellierung und Berechnung von Sicherheitssystemen (ISO/TR 12489:2013)

Pétrole, pétrochimie et gaz naturel - Modélisation et calcul fiabilistes des systèmes de sécurité (ISO/TR 12489:2013)

Petrokemična industrija ter industrija za predelavo nafte in zemeljskega plina - Zanesljivost modeliranja in izračun varnostnega sistema (ISO/TR 12489:2013)

To tehnično poročilo želi zapolniti vrzel med najsodobnejšo tehnologijo in uporabo verjetnostnih izračunov za varnostne sisteme v petrokemični industriji ter industriji za predelavo nafte in zemeljskega plina. Poročilo podaja smernice za analitike sistemov zanesljivosti in varnosti v industriji za predelavo nafte in zemeljskega plina, ki jim omogočajo, da:
• pravilno razumejo pomen opredelitev, uporabljenih na področju zanesljivosti;
• prepoznajo
– zadevne varnostne sisteme;
– težave, s katerimi se lahko soočijo pri obravnavanju modeliranja zanesljivosti in izračunih varnostnih sistemov;
– relevantne verjetnostne parametre, ki jih je treba upoštevati;
• so obveščeni o učinkovitih rešitvah za premagovanje težav, s katerimi se soočijo, in lahko izvedejo
izračune na podlagi relevantnih verjetnostnih parametrov;
• pridobijo zadostno znanje o načelih in ogrodjih (npr. zmožnosti in omejitve modeliranja) ustaljenih pristopov, ki se trenutno uporabljajo na področju zanesljivosti:
– analitične formule;[1][2][13]
– Boolovi:
• blokovni diagrami zanesljivosti;[4]
• drevesa napak;[5]
– zaporedni diagrami: drevesa dogodkov,[8] diagrami vzroka in posledice[10] in diagram za analizo plasti zaščite (LOPA);[9]
– modeli Markova;[6]
– Petrijeve mreže;[7]
• pridobijo zadostno znanje o načelih verjetnostnih ocen:
– analitični izračuni (izvedeni npr. na Boolovih modelih ali modelih Markova);[1][2][3]
– simulacija Monte Carlo (izvedena npr. na Petrijevih mrežah[7]);
• izberejo pristop, ki ustreza zahtevnosti zadevnega varnostnega sistema in izvedene
raziskave zanesljivosti;
• varnost in zanesljivost (npr. za zagotavljanje proizvodnje, glejte točko 3.1.1) obravnavajo v okviru istega
ogrodja zanesljivosti.
Elementarni pristopi (npr. PHA, HAZID, HAZOP, FMECA) ne spadajo v področje uporabe tega tehničnega poročila. Kljub temu so ti pristopi nadvse pomembni in jih je treba primarno uporabiti, saj njihovi rezultati zagotovijo vhodne informacije, ki so ključnega pomena za ustrezno implementacijo pristopov, opisanih v tem tehničnem poročilu: analitičnih formul, Boolovih pristopov (blokovnih diagramov zanesljivosti, dreves napak, dreves
dogodkov itn.), grafov Markova in Petrijevih mrež.
To tehnično poročilo se osredotoča na verjetnostne izračune naključnih napak, zato nenaključne napake (tj. sistematične napake, kot so poimenovane v mednarodnem izrazju na področju zanesljivosti IEV 191[14]), ne spadajo v področje uporabe tega standarda, čeprav so v določeni meri vključene v podatke o zanesljivosti, zbrane na terenu.

General Information

Status
Published
Public Enquiry End Date
24-Feb-2015
Publication Date
14-Feb-2016
ICS
75.180.01 - Equipment for petroleum and natural gas industries in general
Technical Committee
I13 - Imaginarni 13
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
05-Feb-2016
Due Date
11-Apr-2016
Completion Date
15-Feb-2016
Ref Project
CEN ISO/TR 12489:2016 - Petroleum, petrochemical and natural gas industries - Reliability modelling and calculation of safety systems (ISO/TR 12489:2013)

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SLOVENSKI STANDARD
SIST-TP CEN ISO/TR 12489:2016
01-marec-2016
3HWURNHPLþQDLQGXVWULMDWHULQGXVWULMD]DSUHGHODYRQDIWHLQ]HPHOMVNHJDSOLQD
=DQHVOMLYRVWPRGHOLUDQMDLQL]UDþXQYDUQRVWQHJDVLVWHPD ,6275
Petroleum, petrochemical and natural gas industries - Reliability modelling and
calculation of safety systems (ISO/TR 12489:2013)
Erdöl-, petrochemische und Erdgasindustrie - Zuverlässigkeit der Modellierung und
Berechnung von Sicherheitssystemen (ISO/TR 12489:2013)
Pétrole, pétrochimie et gaz naturel - Modélisation et calcul fiabilistes des systèmes de
sécurité (ISO/TR 12489:2013)
Ta slovenski standard je istoveten z: CEN ISO/TR 12489:2016
ICS:
75.180.01 Oprema za industrijo nafte in Equipment for petroleum and
zemeljskega plina na splošno natural gas industries in
general
SIST-TP CEN ISO/TR 12489:2016 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST-TP CEN ISO/TR 12489:2016

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SIST-TP CEN ISO/TR 12489:2016


CEN ISO/TR 12489
TECHNICAL REPORT

RAPPORT TECHNIQUE

January 2016
TECHNISCHER BERICHT
ICS 75.200; 75.180.01
English Version

Petroleum, petrochemical and natural gas industries -
Reliability modelling and calculation of safety systems
(ISO/TR 12489:2013)
Pétrole, pétrochimie et gaz naturel - Modélisation et Erdöl-, petrochemische und Erdgasindustrie -
calcul fiabilistes des systèmes de sécurité (ISO/TR Zuverlässigkeit der Modellierung und Berechnung von
12489:2013) Sicherheitssystemen (ISO/TR 12489:2013)


This Technical Report was approved by CEN on 28 March 2015. It has been drawn up by the Technical Committee CEN/TC 12.

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





EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2016 CEN All rights of exploitation in any form and by any means reserved Ref. No. CEN ISO/TR 12489:2016 E
worldwide for CEN national Members.

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SIST-TP CEN ISO/TR 12489:2016
CEN ISO/TR 12489:2016 (E)
Contents Page
European foreword . 3
2

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SIST-TP CEN ISO/TR 12489:2016
CEN ISO/TR 12489:2016 (E)
European foreword
This document (CEN ISO/TR 12489:2016) has been prepared by Technical Committee ISO/TC 67
“Materials, equipment and offshore structures for petroleum, petrochemical and natural gas industries”
in collaboration with Technical Committee CEN/TC 12 “Materials, equipment and offshore structures
for petroleum, petrochemical and natural gas industries” the secretariat of which is held by NEN.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN [and/or CENELEC] shall not be held responsible for identifying any or all such patent
rights.
Endorsement notice
The text of ISO/TR 12489:2013 has been approved by CEN as CEN ISO/TR 12489:2016 without any
modification.


3

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SIST-TP CEN ISO/TR 12489:2016

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SIST-TP CEN ISO/TR 12489:2016
TECHNICAL ISO/TR
REPORT 12489
First edition
2013-11-01
Petroleum, petrochemical and natural
gas industries — Reliability modelling
and calculation of safety systems
Pétrole, pétrochimie et gaz naturel — Modélisation et calcul
fiabilistes des systèmes de sécurité
Reference number
ISO/TR 12489:2013(E)
©
ISO 2013

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

COPYRIGHT PROTECTED DOCUMENT
© ISO 2013
All rights reserved. Unless otherwise specified, 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 on the internet or an intranet, without prior
written permission. Permission can be requested from either ISO at the address below or ISO’s member body in the country of
the requester.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Published in Switzerland
ii © ISO 2013 – All rights reserved

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

Contents Page
Foreword .v
Introduction .vi
1 Scope . 1
2 Analysis framework . 2
2.1 Users of this Technical Report . 2
2.2 ISO/TR 12489 with regard to risk and reliability analysis processes . 2
2.3 Overview of the reliability modelling and calculation approaches considered in this
Technical Report . 4
2.4 Safety systems and safety functions . 7
3 Terms and definitions . 8
3.1 Basic reliability concepts . 8
3.2 Failure classification.20
3.3 Safety systems typology .24
3.4 Maintenance issues .25
3.5 Other terms .28
3.6 Equipment-related terms .29
4 Symbols and abbreviated terms .30
5 Overview and challenges .33
5.1 General considerations about modelling and calculation challenges .33
5.2 Deterministic versus probabilistic approaches .35
5.3 Safe failure and design philosophy .35
5.4 Dependent failures .36
5.5 Human factors .37
5.6 Documentation of underlying assumptions .40
6 Introduction to modelling and calculations.41
6.1 Generalities about safety systems operating in “on demand” or “continuous” modes .41
6.2 Analytical approaches .44
7 Analytical formulae approach (low demand mode) .47
7.1 Introduction .47
7.2 Underlying hypothesis and main assumptions .47
7.3 Single failure analysis .48
7.4 Double failure analysis .50
7.5 Triple failure analysis .55
7.6 Common cause failures .56
7.7 Example of implementation of analytical formulae: the PDS method .57
7.8 Conclusion about analytical formulae approach .57
8 Boolean and sequential approaches .58
8.1 Introduction .58
8.2 Reliability block diagrams (RBD) .58
8.3 Fault Tree Analysis (FTA) .59
8.4 Sequence modelling: cause consequence diagrams, event tree analysis, LOPA .61
8.5 Calculations with Boolean models .61
8.6 Conclusion about the Boolean approach .64
9 Markovian approach .65
9.1 Introduction and principles .65
9.2 Multiphase Markov models .68
9.3 Conclusion about the Markovian approach .69
10 Petri net approach .69
10.1 Basic principle .69
10.2 RBD driven Petri net modelling .71
© ISO 2013 – All rights reserved iii

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

10.3 Conclusion about Petri net approach .74
11 Monte Carlo simulation approach .74
12 Numerical reliability data uncertainty handling .74
13 Reliability data considerations .75
13.1 Introduction .75
13.2 Reliability data sources.76
13.3 Required reliability data .78
13.4 Reliability data collection .80
14 Typical applications .80
14.1 Introduction .80
14.2 Typical application TA1: single channel .82
14.3 Typical application TA2: dual channel .97
14.4 Typical application TA3: popular redundant architecture .110
14.5 Typical application TA4: multiple safety system .119
14.6 Typical application TA5: emergency depressurization system (EDP) .124
14.7 Conclusion about typical applications .135
Annex A (informative) Systems with safety functions .136
Annex B (informative) State analysis and failure classification .146
Annex C (informative) Relationship between failure rate, conditional and unconditional failure
intensities and failure frequency .152
Annex D (informative) Broad models for demand mode (reactive) safety systems .160
Annex E (informative) Continuous mode (preventive) safety systems .167
Annex F (informative) Multi-layers safety systems/multiple safety systems .170
Annex G (informative) Common cause failures .173
Annex H (informative) The human factor .180
Annex I (informative) Analytical formulae .186
Annex J (informative) Sequential modelling .207
Annex K (informative) Overview of calculations with Boolean models.213
Annex L (informative) Markovian approach .221
Annex M (informative) Petri net modelling.239
Annex N (informative) Monte Carlo simulation approach .248
Annex O (informative) Numerical uncertainties handling .252
Bibliography .255
iv © ISO 2013 – All rights reserved

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
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
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of any
patent rights identified during the development of the document will be in the Introduction and/or on
the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the meaning of ISO specific terms and expressions related to conformity
assessment, as well as information about ISO’s adherence to the WTO principles in the Technical Barriers
to Trade (TBT) see the following URL: Foreword - Supplementary information
The committee responsible for this document is ISO/TC 67, Materials, equipment and offshore structures
for petroleum, petrochemical and natural gas industries.
This first edition of ISO/TR 12489 belongs of the family of reliability related standards developed
by ISO/TC 67:
— ISO 14224, Petroleum, petrochemical and natural gas industries — Collection and exchange of reliability
and maintenance data for equipment
— ISO 20815, Petroleum, petrochemical and natural gas industries — Production assurance and
reliability management
© ISO 2013 – All rights reserved v

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

Introduction
Safety systems have a vital function in petroleum, petrochemical and natural gas industries where
safety systems range from simple mechanical safety devices to safety instrumented systems.
They share three important characteristics which make them difficult to handle:
1) They should be designed to achieve good balance between safety and production. This implies a
high probability of performing the safety action as well as a low frequency of spurious actions.
2) Some of their failures are not revealed until relevant periodic tests are performed to detect and
repair them.
3) A given safety system rarely works alone. It generally belongs to a set of several safety systems (so-
called multiple safety systems) working together to prevent accidents.
Therefore improving safety may be detrimental to dependability and vice versa. These two aspects
should therefore, ideally, be handled at the same time by the same reliability engineers. However, in
reality they are generally considered separately and handled by different persons belonging to different
departments. Moreover this is encouraged by the international safety standards, which exclude
dependability from their scopes, and the international dependability (see 3.1.1) standard, which excludes
safety from theirs. This may lead to dangerous situations (e.g. safety system disconnected because of
too many spurious trips) as well as high production losses.
The proof of the conservativeness of probabilistic calculations of safety systems is generally required
by safety authorities. Unfortunately, managing the systemic dependencies introduced by the periodic
tests to obtain conservative results implies mathematical difficulties which are frequently ignored. The
impact is particularly noticeable for redundant safety systems and multiple safety systems. Awareness
of these challenges is important for reliability engineers as well as safety managers and decision makers,
utilizing reliability analytical support.
Most of the methods and tools presently applied in reliability engineering have been developed since
the 1950s before the emergence of personal computers when only pencil and paper were available. At
that time the reliability pioneers could only manage simplified models and calculations but this has
completely changed because of the tremendous improvement in the computation means achieved over
the past 30 years. Nowadays, models and calculations which were once impossible are carried out
with a simple laptop computer. Flexible (graphical) models and powerful algorithms based on sound
mathematics are now available to handle “industrial size” systems (i.e. many components with complex
interactions). This allows the users to focus on the analysis of the systems and assessment of results,
rather than on the calculations themselves. All the approaches described in this Technical Report have
been introduced in the petroleum, petrochemical and natural gas industries as early as the 1970s where
they have proven to be very effective. They constitute the present time state-of-the-art in reliability
calculations. Nevertheless some of them have not been widely disseminated in this sector although
they can be of great help for reliability engineers to overcome the problems mentioned above. This is
particularly true when quantitative reliability or availability requirements need confirmation and/or
when the objective of the reliability study lay beyond the scope of the elementary approaches.
The present document is a “technical” report and its content is obviously “technical”. Nevertheless, it
only requires a basic knowledge in probabilistic calculation and mathematics and any skilled reliability
engineer should have no difficulties in using it.
vi © ISO 2013 – All rights reserved

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SIST-TP CEN ISO/TR 12489:2016
TECHNICAL REPORT ISO/TR 12489:2013(E)
Petroleum, petrochemical and natural gas industries —
Reliability modelling and calculation of safety systems
1 Scope
This Technical Report aims to close the gap between the state-of-the-art and the application of probabilistic
calculations for the safety systems of the petroleum, petrochemical and natural gas industries. It provides
guidelines for reliability and safety system analysts and the oil and gas industries to:
• understand the correct meaning of the definitions used in the reliability field;
• identify
— the safety systems which may be concerned,
— the difficulties encountered when dealing with reliability modelling and calculation of
safety systems,
— the relevant probabilistic parameters to be considered;
• be informed of effective solutions overcoming the encountered difficulties and allowing to undertake
the calculations of relevant probabilistic parameters;
• obtain sufficient knowledge of the principles and framework (e.g. the modelling power and
limitations) of the well-established approaches currently used in the reliability field:
[1][2][13]
— analytical formulae;
— Boolean:
[4]
• reliability block diagrams;
[5]
• fault trees;
[8] [10] [9]
— sequential: event trees, cause consequence diagrams and LOPA;
[6]
— Markovian;
[7]
— Petri nets;
• obtain sufficient knowledge of the principles of probabilistic evaluations:
[1][2][3]
— analytical calculations (e.g. performed on Boolean or Markovian models);
[7]
— and Monte Carlo simulation (e.g. performed on Petri nets );
• select an approach suitable with the complexity of the related safety system and the reliability study
which is undertaken;
• handle safety and dependability (e.g. for production assurance purpose, see 3.1.1) within the same
reliability framework.
The elementary approaches (e.g. PHA, HAZID, HAZOP, FMECA) are out of the scope of this Technical
Report. Yet they are of utmost importance and ought to be applied first as their results provide the input
information essential to properly undertake the implementation of the approaches described in this
Technical Report: analytical formulae, Boolean approaches (reliability block diagrams, fault trees, event
trees, etc.), Markov graphs and Petri nets.
© ISO 2013 – All rights reserved 1

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SIST-TP CEN ISO/TR 12489:2016
ISO/TR 12489:2013(E)

This Technical Report is focused on probabilistic calculations of random failures and, therefore, the non-
[14]
random (i.e. systematic failures as per the international reliability vocabulary IEV 191 ) failures are out
of the scope even if, to some extent, they are partly included into the reliability data collected from the field.
2 Analysis framework
2.1 Users of this Technical Report
This Technical Report is intended for the following users, in a role defining the scope of work of reliability
models (customer or decision-maker), executing reliability analysis or as a risk analyst using these
calculations:
• Installation/Plant/Facility: operating facility staff, e.g. safety, maintenance and engineering personnel.
• Owner/Operator/Company: reliability staff or others analysing or responsible for reliability
studies for safety related equipment located in company facilities.
• Industry: groups of companies collaborating to enhance reliability of safety systems and safety
functions. The use of this Technical Report supports “reliability analytical best practices” for the
[54]
benefit of societal
...

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SIST EN ISO 15156-3:2021(Main)
Petroleum and natural gas industries - Materials for use in H2S-containing environments in oil and gas production - Part 3: Cracking-resistant CRAs (corrosion-resistant alloys) and other alloys (ISO 15156-3:2020)
EN ISO 15156-3:2020

This document gives requirements and recommendations for the selection and qualification of CRAs
(corrosion-resistant alloys) and other alloys for service in equipment used in oil and natural gas
production and natural gas treatment plants in H2S-containing environments whose failure can pose
a risk to the health and safety of the public and personnel or to the environment. It can be applied to
help avoid costly corrosion damage to the equipment itself. It supplements, but does not replace, the
materials requirements of the appropriate design codes, standards, or regulations.
This document addresses the resistance of these materials to damage that can be caused by sulfide
stress cracking (SSC), stress corrosion cracking (SCC), and galvanically induced hydrogen stress
cracking (GHSC).
This document is concerned only with cracking. Loss of material by general (mass loss) or localized
corrosion is not addressed.
Table 1 provides a non-exhaustive list of equipment to which this document is applicable, including
exclusions.
This document applies to the qualification and selection of materials for equipment designed and
constructed using load controlled design methods. For design utilizing strain-based design methods,
see ISO 15156-1:2020, Clause 5.
This document is not necessarily suitable for application to equipment used in refining or downstream
processes and equipment.

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SIST EN ISO 15156-2:2021(Main)
Petroleum and natural gas industries - Materials for use in H2S-containing environments in oil and gas production - Part 2: Cracking-resistant carbon and low-alloy steels, and the use of cast irons (ISO 15156-2:2020)
EN ISO 15156-2:2020

This document gives requirements and recommendations for the selection and qualification of carbon
and low-alloy steels for service in equipment used in oil and natural gas production and natural gas
treatment plants in H2S-containing environments, whose failure can pose a risk to the health and safety
of the public and personnel or to the environment. It can be applied to help to avoid costly corrosion
damage to the equipment itself. It supplements, but does not replace, the materials requirements of the
appropriate design codes, standards or regulations.
This document addresses the resistance of these steels to damage that can be caused by sulfide stress
cracking (SSC) and the related phenomena of stress-oriented hydrogen-induced cracking (SOHIC) and
soft-zone cracking (SZC).
This document also addresses the resistance of these steels to hydrogen-induced cracking (HIC) and its
possible development into stepwise cracking (SWC).
This document is concerned only with cracking. Loss of material by general (mass loss) or localized
corrosion is not addressed.
Table 1 provides a non-exhaustive list of equipment to which this document is applicable, including
exclusions.
This document applies to the qualification and selection of materials for equipment designed and
constructed using load controlled design methods. For design utilizing strain-based design methods,
see ISO 15156-1:2020, Clause 5.
Annex A lists SSC-resistant carbon and low alloy steels, and A.2.4 includes requirements for the use of
cast irons.
This document is not necessarily suitable for application to equipment used in refining or downstream
processes and equipment.

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SIST EN ISO 17782:2019(Main)
Petroleum, petrochemical and natural gas industries - Scheme for conformity assessment of manufacturers of special materials (ISO 17782:2018)
EN ISO 17782:2018

This document establishes a procedure for verifying that the manufacturer of special materials for
the petroleum, petrochemical and natural gas industries has sufficient competence and experience
of the relevant material grades of metal, and the necessary facilities and equipment, to manufacture
these materials in the required shapes and sizes with acceptable properties according to the applicable
standard, material specification and/or material data sheet specified by the purchaser.
This document is applicable to manufacturers of various materials, product forms and manufacturing
processes when specified by the purchaser. This document has been established considering especially,
but not exclusively:
a) duplex stainless steel;
b) high alloyed austenitic stainless steel;
c) nickel-based alloys;
d) titanium and its alloys.
This document is also applicable to the processes of induction bending and strain-hardened products.

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SIST EN ISO 17781:2017(Main)
Petroleum, petrochemical and natural gas industries - Test methods for quality control of microstructure of austenitic/ferritic (duplex) stainless steel (ISO 17781:2017)
EN ISO 17781:2017

This document specifies quality control testing methods and test conditions for the characterization
of microstructure in relation to relevant properties in ferritic/austenitic (duplex) stainless steel
components supplied in the solution annealed condition and fabrication welds in the as welded
condition.
This document supplements the relevant product and fabrication standards with respect to destructive
testing methods including sampling of test specimens, test conditions and test acceptance criteria to
show freedom from deleterious intermetallic phases and precipitates in duplex stainless steels. In
addition, this document specifies the documentation of testing and test results by the testing laboratory.
NOTE 1 This document is based upon experience with duplex stainless steels in offshore oil and gas industry
applications including topside and subsea hydrocarbon service, sea water service, as well as structural use.
NOTE 2 The austenite spacing is relevant to the susceptibility of duplex stainless steels to hydrogen-induced
stress cracking (HISC) in subsea applications where cathodic protection is applied. This falls outside the scope of
this document. Reference is made to DNV/GL RP-F112[4].

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SIST EN ISO 14224:2016(Main)
Petroleum, petrochemical and natural gas industries - Collection and exchange of reliability and maintenance data for equipment (ISO 14224:2016, Corrected version 2016-10-01)
EN ISO 14224:2016

This International Standard provides a comprehensive basis for the collection of reliability and maintenance (RM) data in a standard format for equipment in all facilities and operations within the petroleum, natural gas and petrochemical industries during the operational life cycle of equipment. It describes data collection principles and associated terms and definitions that constitute a “reliability language” that can be useful for communicating operational experience. The failure modes defined in the normative part of this International Standard can be used as a “reliability thesaurus” for various quantitative as well as qualitative applications. This International Standard also describes data quality control and assurance practices to provide guidance for the user.
Standardization of data collection practices facilitates the exchange of information between parties, e.g. plants, owners, manufacturers and contractors. This International Standard establishes requirements that any in-house or commercially available RM data system is required to meet when designed for RM data exchange. Examples, guidelines and principles for the exchange and merging of such RM data are addressed. This International Standard also provides a framework and guidelines for establishing performance objectives and requirements for equipment reliability and availability performance.
Annex A contains a summary of equipment that is covered by this International Standard.
This International Standard defines a minimum amount of data that is required to be collected, and it focuses on two main issues:
— data requirements for the categories of data to be collected for use in various analysis methodologies;
— standardized data format to facilitate the exchange of reliability and maintenance data between plants, owners, manufacturers and contractors.
The following main categories of data are to be collected:
a) equipment data, e.g. equipment taxonomy, equipment attributes;
b) failure data, e.g. failure cause, failure consequence;
c) maintenance data, e.g. maintenance action, resources used, maintenance consequence, down time.
NOTE Clause 9 gives further details on data content and data format.
The main areas where such data are used are the following:
1) reliability, e.g. failure events and failure mechanisms;
2) availability/efficiency, e.g. equipment availability, system availability, plant production availability;
3) maintenance, e.g. corrective and preventive maintenance, maintenance plan, maintenance supportability;
4) safety and environment, e.g. equipment failures with adverse consequences for safety and/or environment.
This International Standard does not apply to the following:
i.   data on (direct) cost issues;
ii.    data from laboratory testing and manufacturing (e.g. accelerated lifetime testing), see also 5.2;
iii.    complete equipment data sheets (only data seen relevant for assessing the reliability performance are included);
iv.   additional on-service data that an operator, on an individual basis, can consider useful for operation and maintenance;
v.   methods for analysing and applying RM data (however, principles for how to calculate some basic
vi.   reliability and maintenance parameters are included in the annexes).

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SIST EN ISO 23936-2:2012(Main)
Petroleum, petrochemical and natural gas industries - Non-metallic materials in contact with media related to oil and gas production - Part 2: Elastomers (ISO 23936-2:2011)
EN ISO 23936-2:2011

ISO 23936 describes general principles and gives requirements and recommendations for the selection and qualification of non-metallic materials for service in equipment used in oil and gas production environments, where the failure of such equipment could pose a risk to the health and safety of the public and personnel, or to the environment. It can be applied to help avoid failures of the equipment itself. It supplements, but does not replace, the material requirements given in the appropriate design codes, standards or regulations.
ISO 23936-2:2011 describes the requirements and procedures for qualification of elastomeric material used in equipment for oil and gas production.

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SIST EN ISO 23936-1:2022(Main)
Oil and gas industries including lower carbon energy - Non-metallic materials in contact with media related to oil and gas production - Part 1: Thermoplastics (ISO 23936-1:2022)
EN ISO 23936-1:2022

This document gives general principles, specifies requirements and gives recommendations for the
assessment of the stability of non-metallic materials for service in equipment used in oil and gas
exploration and production environments. This information aids in material selection. It can be applied
to help avoid costly degradation failures of the equipment itself, which could pose a risk to the health
and safety of the public and personnel or the environment. This document also provides guidance
for quality assurance. It supplements but does not replace, the material requirements given in the
appropriate design codes, standards or regulations.
This document addresses the resistance of thermoplastics to the deterioration in properties that can
be caused by physical or chemical interaction with produced and injected oil and gas-field media, and
with chemical treatment. Interaction with sunlight and ionizing radiation are excluded from the scope
of this document.
This document is not necessarily suitable for application to equipment used in refining or downstream
processes and equipment.
The equipment considered includes, but is not limited to, non-metallic pipelines, piping, liners, seals,
gaskets and washers.
Blistering by rapid gas decompression is not included in the scope of this document.
This document applies to the assessment of the stability of non-metallic materials in simulated
hydrocarbon production conditions to aid the selection of materials for equipment designed and
constructed using conventional design criteria. Designs utilizing other criteria are excluded from its
scope.

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