iTeh StandardsiTeh Standards
EURUSD
Your shopping cart is empty.
ISO

ISO 20257-1:2020

(Main)

Installation and equipment for liquefied natural gas — Design of floating LNG installations — Part 1: General requirements

Installation and equipment for liquefied natural gas — Design of floating LNG installations — Part 1: General requirements

This document provides requirements and guidance for the design and operation of floating liquefied natural gas (LNG) installations, including installations for the liquefaction, storage, vaporisation, transfer and handling of LNG, in order to have a safe and environmentally acceptable design and operation of floating LNG installations. This document is applicable to: — floating LNG liquefaction installations (plant) — FLNG; — floating LNG regasification installations (plant) — FSRU; — floating storage units — FSU. This document is applicable to offshore, near-shore or docked floating LNG installations. This document includes any jetty in the scope in case of docked floating LNG installations with regards to the mooring. This document briefly describes floating LNG mooring concepts. This document is applicable to both newbuilt and converted floating LNG installations, and addresses specific requirements. This document is not applicable to: — onshore LNG storage, liquefaction and/or regasification installations/plants, except for docked FSRU and/or FLNG installations; — offshore LNG plants based on non-floating structure (such as gravity based structure [GBS] principle); and — support onshore based facilities (such as support vessels, tugs, etc.). This document is not intended for design floating power generation facilities though relevant parts of this document can be used. This document is not intended to cover LNG as fuel bunkering applications.

Installations et équipements de gaz naturel liquéfié — Conception des installations flottantes de GNL — Partie 1: Exigences générales

Le présent document fournit des exigences et des recommandations concernant la conception et l'exploitation des installations flottantes de gaz naturel liquéfié (GNL), y compris les installations destinées à la liquéfaction, au stockage, à la vaporisation, au transfert et à la manipulation du GNL afin d'obtenir une conception et une exploitation sans danger et écologiquement acceptable des installations flottantes de GNL. Le présent document est applicable : — aux terminaux flottants de liquéfaction de GNL (installation) ? FLNG ; — aux terminaux flottants de regazéification de GNL (installation) ? FSRU ; — aux unités flottantes de stockage ? FSU. Le présent document est applicable aux installations flottantes de GNL en mer, à proximité de la côte ou à quai dans un port. Le présent document inclut tous les appontements éventuels dans son domaine d'application dans le cas d'installations flottantes de GNL à quai pour ce qui est de l'amarrage. Le présent document décrit brièvement les concepts d'amarrage du GNL flottant. Le présent document est applicable aux installations flottantes de GNL nouvellement construites aussi bien qu'aux installations converties et il couvre les exigences spécifiques. Le présent document ne s'applique pas : — aux installations/terminaux terrestres de stockage, liquéfaction et/ou regazéification de GNL, à l'exception des installations de FSRU et/ou FLNG à quai ; — aux terminaux de GNL en mer basés sur une structure non flottante (comme le principe d'une structure gravitaire) ; ni — aux installations de soutien basées à terre (comme les navires de soutien, les remorqueurs, etc.). Le présent document n'est pas destiné à la conception des installations flottantes d'alimentation en électricité bien que des parties pertinentes puissent être utilisées à ces fins. Le présent document n'a pas vocation à traiter des GNL destinés aux applications de soutage de carburant.

General Information

Status
Published
Publication Date
21-Apr-2020
ICS
75.200 - Petroleum products and natural gas handling equipment
Technical Committee
ISO/TC 67/SC 9 - Liquefied natural gas installations and equipment
Drafting Committee
ISO/TC 67/SC 9/WG 7 - Offshore installations for LNG production or regasification
Current Stage
6060 - International Standard published
Start Date
20-Apr-2020
Due Date
06-Jan-2019
Completion Date
22-Apr-2020
Ref Project

Relations

Consolidated By
ISO 28199-3:2021 - Paints and varnishes — Evaluation of properties of coating systems related to the spray application process — Part 3: Assessment of sagging, formation of bubbles, pinholing and hiding power
Effective Date
06-Jun-2022

Buy Standard

ISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installationsISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installations
PreviousNext
Standard
ISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installations
English language
155 pages
sale 15% off
Preview
sale 15% off
Preview
ISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installationsISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installations
PreviousNext
Standard
ISO 20257-1:2020 - Installation and equipment for liquefied natural gas -- Design of floating LNG installations
English language
153 pages
sale 15% off
Preview
sale 15% off
Preview
ISO 20257-1:2020 - Installations et équipements de gaz naturel liquéfié -- Conception des installations flottantes de GNLISO 20257-1:2020 - Installations et équipements de gaz naturel liquéfié -- Conception des installations flottantes de GNL
PreviousNext
Standard
ISO 20257-1:2020 - Installations et équipements de gaz naturel liquéfié -- Conception des installations flottantes de GNL
French language
167 pages
sale 15% off
Preview
sale 15% off
Preview

Standards Content (Sample)

INTERNATIONAL ISO
STANDARD 20257-1
First edition
2020-04
Corrected version
2020-09
Installation and equipment for
liquefied natural gas — Design of
floating LNG installations —
Part 1:
General requirements
Installations et équipements de gaz naturel liquéfié — Conception des
installations flottantes de GNL —
Partie 1: Exigences générales
Reference number
ISO 20257-1:2020(E)
©
ISO 2020

---------------------- Page: 1 ----------------------
ISO 20257-1:2020(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
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
CP 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Geneva
Phone: +41 22 749 01 11
Email: copyright@iso.org
Website: www.iso.org
Published in Switzerland
ii © ISO 2020 – All rights reserved

---------------------- Page: 2 ----------------------
ISO 20257-1:2020(E)

Contents Page
Foreword .vii
Introduction .viii
1 Scope . 1
2 Normative references . 1
3 Terms, definitions and abbreviated terms . 3
3.1 Terms and definitions . 3
3.2 Abbreviated terms . 8
4 Basis of design .11
4.1 Site and meteocean conditions .11
4.1.1 Site study .11
4.1.2 Earthquake .13
4.1.3 Location .13
4.1.4 Other studies .14
4.2 Design criteria .14
4.2.1 General.14
4.2.2 Topsides .15
4.2.3 Transfer systems .16
4.2.4 Hull . .20
4.2.5 LNG storage .22
4.2.6 Mooring .23
4.2.7 Pipe-work .25
5 Health, safety and the environment .26
5.1 General .26
5.1.1 Main objectives .26
5.1.2 Main principles .27
5.2 Identification of safety and environmental barriers and design requirements .27
5.2.1 General.27
5.2.2 Purpose .28
5.2.3 Safety and environmental barriers .28
5.2.4 Generic barriers .29
5.2.5 Safety and environmental barriers identification process .29
5.2.6 Safety and environmental barriers design requirements .30
5.2.7 Safety and environmental barriers design requirements certification .31
5.3 Environmental considerations .31
5.3.1 General.31
5.3.2 Floating LNG installations specificities .31
5.3.3 Environmental aspects identification .32
5.3.4 Environmental design review . .32
5.3.5 Environmental design requirements .32
5.4 Safety considerations .39
5.4.1 General.39
5.4.2 Safety strategies and philosophies .40
5.4.3 Safety reviews .40
5.4.4 Qualitative risk assessment, QRA and specific safety studies.43
5.4.5 Risk prevention measures (typical list) .47
5.4.6 Emergency response .60
5.5 Occupational health and industrial hygiene considerations .62
5.5.1 Occupational health and industrial hygiene aspects identification .62
5.5.2 Chemical exposure .62
5.5.3 Biological factor .63
5.5.4 Legionella .64
5.5.5 Thermal stress .64
© ISO 2020 – All rights reserved iii

---------------------- Page: 3 ----------------------
ISO 20257-1:2020(E)

5.5.6 Hot/cold surfaces .65
5.5.7 Support functions to operators - Project with permanent operators on-
board or in the facility .65
5.5.8 Lighting .65
5.5.9 Water availability and quality intended for human consumption .66
5.5.10 Noise and vibration .66
5.6 Ergonomics and human factor .68
6 Mooring and stationkeeping .68
6.1 General .68
6.2 Permanent stationkeeping in open waters .69
6.2.1 Stationkeeping concepts .69
6.2.2 Design requirements .70
6.3 Permanent stationkeeping in nearshore or docked conditions .70
6.3.1 Stationkeeping concepts .70
6.3.2 Design requirements .71
6.3.3 Emergency departure of floating LNG installation.72
6.4 Mooring systems for special project design conditions .72
6.4.1 Disconnectable mooring .72
6.4.2 Permanent mooring for a limited project life .73
6.5 Short-duration mooring of a visiting LNGC for loading/unloading .73
6.5.1 General.73
6.5.2 Ship-to-ship mooring in open waters .74
6.5.3 Mooring in docked or nearshore conditions .74
6.5.4 Mooring to an SPM terminal .74
6.5.5 Design requirements .74
6.6 Infrastucture design for jetty moorings .75
6.6.1 General.75
6.6.2 Jetty elevation .75
6.6.3 Corrosion protection of the marine infrastructure .75
6.6.4 LNG spillage containment .76
6.6.5 Power supply from/to jetty to the FSRU/FLNG .76
6.6.6 Navigation aids .76
6.6.7 Emergency response and evacuation route .76
6.7 Transfer of material and personnel .76
7 Hull design .77
7.1 Hull structural design .77
7.1.1 Design philosophy .77
7.1.2 Design methods .77
7.1.3 Codes and standards .77
7.1.4 Limit states for floating structures .78
7.1.5 Design situations for ULS .78
7.1.6 Design situations for SLS .78
7.1.7 Design situations for FLS .79
7.1.8 Design situations for ALS .79
7.1.9 Site-specific design . . .79
7.1.10 Cargo containment loads .80
7.1.11 Fatigue .80
7.1.12 Slamming .80
7.1.13 Green water .80
7.1.14 Topsides and external loads .81
7.1.15 Accidental loads .81
7.2 Stability and watertight integrity.81
7.2.1 General.81
7.2.2 Stability .81
7.2.3 Watertight and weathertight integrity.82
8 LNG storage .82
8.1 General .82
iv © ISO 2020 – All rights reserved

---------------------- Page: 4 ----------------------
ISO 20257-1:2020(E)

8.2 Sloshing loads .83
8.2.1 Intermediate filling levels: Operating conditions of FSRU/FLNG .83
8.2.2 Intermediate filling levels: Operating conditions of cargo transfers (STS) .84
8.3 Boil-off gas management .84
8.4 Rollover prevention management .84
8.4.1 Background.84
8.4.2 Detection and prevention .85
8.5 Vent systems for LNG storage.85
8.5.1 General.85
8.5.2 Pressure relief systems.85
8.5.3 Vacuum relief systems . . .86
9 LNG transfer system .87
9.1 Functional requirements .87
9.2 Design of transfer systems .88
9.2.1 Operating envelope . .88
9.2.2 Transfer system design .89
10 Boil-off gas handling and recovery .91
10.1 General .91
10.2 BOG collection system .91
10.3 System of gas return to LNGC or to FLNG facility.92
10.4 Boil-off gas recovery .92
10.5 Gas compressor .92
10.6 Flare/vent .92
11 Low temperature pipework .92
11.1 General .92
11.2 Piping components .93
11.2.1 General.93
11.3 Pipe .93
11.3.1 General.93
11.3.2 Pipe joints .93
11.3.3 Pipe supports .94
11.3.4 Compensation of contractions due to cold .94
11.3.5 Differential displacement between offshore structures .94
11.4 Valves .94
11.4.1 Relief valves .95
11.5 Thermal insulation .95
11.5.1 General.95
11.5.2 Piping insulation .96
11.5.3 Fire behaviour .96
11.5.4 Gas absorption .96
11.5.5 Moisture resistance .96
11.5.6 Differential movements .97
11.5.7 Thickness determination .97
11.6 Prevention of zinc contamination of austenitic steel .97
12 Utilities systems .97
12.1 Classification of systems .97
12.1.1 Essential services .97
12.1.2 Emergency services .98
12.2 Electrical .98
12.2.1 Design and engineering principles . .98
12.2.2 Electrical system design .99
12.2.3 Design and selection of equipment and cables .102
12.3 Instrument air sy
...

INTERNATIONAL ISO
STANDARD 20257-1
First edition
2020-04
Installation and equipment for
liquefied natural gas — Design of
floating LNG installations —
Part 1:
General requirements
Installations et équipements de gaz naturel liquéfié — Conception des
installations flottantes de GNL —
Partie 1: Exigences générales
Reference number
ISO 20257-1:2020(E)
©
ISO 2020

---------------------- Page: 1 ----------------------
ISO 20257-1:2020(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
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
CP 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Geneva
Phone: +41 22 749 01 11
Fax: +41 22 749 09 47
Email: copyright@iso.org
Website: www.iso.org
Published in Switzerland
ii © ISO 2020 – All rights reserved

---------------------- Page: 2 ----------------------
ISO 20257-1:2020(E)

Contents Page
Foreword .vii
Introduction .viii
1 Scope . 1
2 Normative references . 1
3 Terms, definitions and abbreviated terms . 3
3.1 Terms and definitions . 3
3.2 Abbreviated terms . 8
4 Basis of design .11
4.1 Site and meteocean conditions .11
4.1.1 Site study .11
4.1.2 Earthquake .13
4.1.3 Location .13
4.1.4 Other studies .14
4.2 Design criteria .14
4.2.1 General.14
4.2.2 Topsides .15
4.2.3 Transfer systems .16
4.2.4 Hull . .20
4.2.5 LNG storage .22
4.2.6 Mooring .23
4.2.7 Pipe-work .25
5 Health, safety and the environment .26
5.1 General .26
5.1.1 Main objectives .26
5.1.2 Main principles .26
5.2 Identification of safety and environmental barriers and design requirements .27
5.2.1 General.27
5.2.2 Purpose .27
5.2.3 Safety and environmental barriers .28
5.2.4 Generic barriers .28
5.2.5 Safety and environmental barriers identification process .29
5.2.6 Safety and environmental barriers design requirements .30
5.2.7 Safety and environmental barriers design requirements certification .30
5.3 Environmental considerations .31
5.3.1 General.31
5.3.2 Floating LNG installations specificities .31
5.3.3 Environmental aspects identification .31
5.3.4 Environmental design review . .32
5.3.5 Environmental design requirements .32
5.4 Safety considerations .39
5.4.1 General.39
5.4.2 Safety strategies and philosophies .39
5.4.3 Safety reviews .40
5.4.4 Qualitative risk assessment, QRA and specific safety studies.42
5.4.5 Risk prevention measures (typical list) .46
5.4.6 Emergency response .59
5.5 Occupational health and industrial hygiene considerations .61
5.5.1 Occupational health and industrial hygiene aspects identification .61
5.5.2 Chemical exposure .61
5.5.3 Biological factor .62
5.5.4 Legionella .63
5.5.5 Thermal stress .63
© ISO 2020 – All rights reserved iii

---------------------- Page: 3 ----------------------
ISO 20257-1:2020(E)

5.5.6 Hot/cold surfaces .64
5.5.7 Support functions to operators - Project with permanent operators on-
board or in the facility .64
5.5.8 Lighting .64
5.5.9 Water availability and quality intended for human consumption .65
5.5.10 Noise and vibration .65
5.6 Ergonomics and human factor .66
6 Mooring and stationkeeping .66
6.1 General .66
6.2 Permanent stationkeeping in open waters .67
6.2.1 Stationkeeping concepts .67
6.2.2 Design requirements .68
6.3 Permanent stationkeeping in nearshore or docked conditions .68
6.3.1 Stationkeeping concepts .68
6.3.2 Design requirements .69
6.3.3 Emergency departure of floating LNG installation.70
6.4 Mooring systems for special project design conditions .71
6.4.1 Disconnectable mooring .71
6.4.2 Permanent mooring for a limited project life .71
6.5 Short-duration mooring of a visiting LNGC for loading/unloading .72
6.5.1 General.72
6.5.2 Ship-to-ship mooring in open waters .72
6.5.3 Mooring in docked or nearshore conditions .72
6.5.4 Mooring to an SPM terminal .72
6.5.5 Design requirements .73
6.6 Infrastucture design for jetty moorings .73
6.6.1 General.73
6.6.2 Jetty elevation .74
6.6.3 Corrosion protection of the marine infrastructure .74
6.6.4 LNG spillage containment .74
6.6.5 Power supply from/to jetty to the FSRU/FLNG .74
6.6.6 Navigation aids .74
6.6.7 Emergency response and evacuation route .74
6.7 Transfer of material and personnel .75
7 Hull design .75
7.1 Hull structural design .75
7.1.1 Design philosophy .75
7.1.2 Design methods .76
7.1.3 Codes and standards .76
7.1.4 Limit states for floating structures .76
7.1.5 Design situations for ULS .76
7.1.6 Design situations for SLS .77
7.1.7 Design situations for FLS .77
7.1.8 Design situations for ALS .77
7.1.9 Site-specific design . . .78
7.1.10 Cargo containment loads .78
7.1.11 Fatigue .78
7.1.12 Slamming .79
7.1.13 Green water .79
7.1.14 Topsides and external loads .79
7.1.15 Accidental loads .79
7.2 Stability and watertight integrity.80
7.2.1 General.80
7.2.2 Stability .80
7.2.3 Watertight and weathertight integrity.80
8 LNG storage .81
8.1 General .81
iv © ISO 2020 – All rights reserved

---------------------- Page: 4 ----------------------
ISO 20257-1:2020(E)

8.2 Sloshing loads .81
8.2.1 Intermediate filling levels: Operating conditions of FSRU/FLNG .81
8.2.2 Intermediate filling levels: Operating conditions of cargo transfers (STS) .82
8.3 Boil-off gas management .83
8.4 Rollover prevention management .83
8.4.1 Background.83
8.4.2 Detection and prevention .83
8.5 Vent systems for LNG storage.84
8.5.1 General.84
8.5.2 Pressure relief systems.84
8.5.3 Vacuum relief systems . . .85
9 LNG transfer system .85
9.1 Functional requirements .85
9.2 Design of transfer systems .86
9.2.1 Operating envelope . .86
9.2.2 Transfer system design .87
10 Boil-off gas handling and recovery .89
10.1 General .89
10.2 BOG collection system .89
10.3 System of gas return to LNGC or to FLNG facility.90
10.4 Boil-off gas recovery .90
10.5 Gas compressor .90
10.6 Flare/vent .91
11 Low temperature pipework .91
11.1 General .91
11.2 Piping components .91
11.2.1 General.91
11.3 Pipe .91
11.3.1 General.91
11.3.2 Pipe joints .92
11.3.3 Pipe supports .92
11.3.4 Compensation of contractions due to cold .92
11.3.5 Differential displacement between offshore structures .92
11.4 Valves .92
11.4.1 Relief valves .93
11.5 Thermal insulation .94
11.5.1 General.94
11.5.2 Piping insulation .94
11.5.3 Fire behaviour .94
11.5.4 Gas absorption .94
11.5.5 Moisture resistance .95
11.5.6 Differential movements .95
11.5.7 Thickness determination .95
11.6 Prevention of zinc contamination of austenitic steel .95
12 Utilities systems .96
12.1 Classification of systems .96
12.1.1 Essential services .96
12.1.2 Emergency services .96
12.2 Electrical .97
12.2.1 Design and engineering principles . .97
12.2.2 Electrical system design .97
12.2.3 Design and selection of equipment and cables .100
12.3 Instrument air system
...

NORME ISO
INTERNATIONALE 20257-1
Première édition
2020-04
Installations et équipements de gaz
naturel liquéfié — Conception des
installations flottantes de GNL —
Partie 1:
Exigences générales
Installation and equipment for liquefied natural gas — Design of
floating LNG installations —
Part 1: General requirements
Numéro de référence
ISO 20257-1:2020(F)
©
ISO 2020

---------------------- Page: 1 ----------------------
ISO 20257-1:2020(F)

DOCUMENT PROTÉGÉ PAR COPYRIGHT
© ISO 2020
Tous droits réservés. Sauf prescription différente ou nécessité dans le contexte de sa mise en œuvre, aucune partie de cette
publication ne peut être reproduite ni utilisée sous quelque forme que ce soit et par aucun procédé, électronique ou mécanique,
y compris la photocopie, ou la diffusion sur l’internet ou sur un intranet, sans autorisation écrite préalable. Une autorisation peut
être demandée à l’ISO à l’adresse ci-après ou au comité membre de l’ISO dans le pays du demandeur.
ISO copyright office
Case postale 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Genève
Tél.: +41 22 749 01 11
E-mail: copyright@iso.org
Web: www.iso.org
Publié en Suisse
ii © ISO 2020 – Tous droits réservés

---------------------- Page: 2 ----------------------
ISO 20257-1:2020(F)

Sommaire Page
Avant-propos .viii
Introduction .ix
1 Domaine d'application . 1
2 Références normatives . 1
3 Termes, définitions et abréviations . 3
3.1 Termes et définitions . 3
3.2 Abréviations . 9
4 Base de conception.12
4.1 Site et conditions océano-météorologiques .12
4.1.1 Étude du site .12
4.1.2 Séisme .13
4.1.3 Emplacement .14
4.1.4 Autres études .14
4.2 Critères de conception.15
4.2.1 Généralités .15
4.2.2 Superstructures .16
4.2.3 Systèmes de transfert .17
4.2.4 Coque .21
4.2.5 Stockage de GNL .23
4.2.6 Amarrage .25
4.2.7 Tuyauterie .27
5 Santé, sécurité et environnement (HSE) .28
5.1 Généralités .28
5.1.1 Objectifs principaux .28
5.1.2 Grands principes .28
5.2 Identification des barrières relatives à la sécurité et à l'environnement et des
exigences de conception .29
5.2.1 Généralités .29
5.2.2 Objectif .29
5.2.3 Barrières relatives à la sécurité et à l'environnement .30
5.2.4 Barrières génériques .30
5.2.5 Procédé d'identification des barrières relatives à la sécurité et à
l'environnement .31
5.2.6 Exigences de conception des barrières relatives à la sécurité et à
l'environnement .32
5.2.7 Certification des exigences de conception des barrières relatives à la
sécurité et à l'environnement .33
5.3 Considérations environnementales .33
5.3.1 Généralités .33
5.3.2 Spécificités des installations flottantes de GNL .33
5.3.3 Identification des aspects liés à l'environnement .34
5.3.4 Revue de la conception en matière d'environnement .34
5.3.5 Exigences de la conception en matière d'environnement .34
5.4 Aspects liés à la sécurité .42
5.4.1 Généralités .42
5.4.2 Stratégies et philosophies de sécurité .42
5.4.3 Revues de sécurité .43
5.4.4 Évaluation qualitative des risques, évaluation quantitative des risques et
études spécifiques de sécurité .46
5.4.5 Mesures de prévention des risques (liste type) .50
5.4.6 Réponse d'urgence .65
5.5 Considérations de santé au travail et d'hygiène industrielle .66
© ISO 2020 – Tous droits réservés iii

---------------------- Page: 3 ----------------------
ISO 20257-1:2020(F)

5.5.1 Identification des aspects de santé au travail et d'hygiène industrielle .66
5.5.2 Exposition aux produits chimiques .67
5.5.3 Facteur biologique .68
5.5.4 Légionnelle .69
5.5.5 Stress thermique .69
5.5.6 Surfaces chaudes/froides .70
5.5.7 Fonction de soutien aux opérateurs - Projet avec opérateurs permanents
à bord ou dans l'installation . .70
5.5.8 Éclairage .71
5.5.9 Disponibilité et qualité de l'eau destinée à la consommation .71
5.5.10 Bruit et vibrations .71
5.6 Ergonomie et facteur humain.73
6 Amarrage et maintien en position .74
6.1 Généralités .74
6.2 Maintien en position permanent en eaux libres .74
6.2.1 Concepts de maintien en position .74
6.2.2 Exigences de conception .75
6.3 Maintien en position permanent à proximité de la côte ou à quai .76
6.3.1 Concepts de maintien en position .76
6.3.2 Exigences de conception .77
6.3.3 Départ en urgence d'une installation flottante de GNL .78
6.4 Systèmes d'amarrage en conditions de conception spécifiques à un projet .78
6.4.1 Ancrage déconnectable .78
6.4.2 Amarrage permanent pour une durée de vie de projet limitée.79
6.5 Amarrage de courte durée d'un méthanier en visite pour chargement/ déchargement .79
6.5.1 Généralités .79
6.5.2 Amarrage navire/navire en eaux libres .80
6.5.3 Amarrage à quai ou à proximité de la côte .80
6.5.4 Amarrage à un terminal SPM .80
6.5.5 Exigences de conception .80
6.6 Conception de l'infrastructure pour les amarrages sur appontement .81
6.6.1 Généralités .81
6.6.2 Élévation de l'appontement .81
6.6.3 Protection de l'infrastructure maritime contre la corrosion .82
6.6.4 Confinement de déversement de GNL .82
6.6.5 Alimentation électrique de/vers l'appontement au FSRU/à la FLNG .82
6.6.6 Aides à la navigation .82
6.6.7 Interventions en urgence et voies d'évacuation .82
6.7 Transfert de matériel et de personnel .83
7 Conception de coque .83
7.1 Conception de la structure de coque .83
7.1.1 Philosophie de conception .83
7.1.2 Méthodes de conception .84
7.1.3 Codes et normes .84
7.1.4 États limites pour les structures flottantes .84
7.1.5 Situations conceptuelles pour les ULS .85
7.1.6 Situations conceptuelles pour les SLS .85
7.1.7 Situations conceptuelles pour les FLS .85
7.1.8 Situations conceptuelles pour les ALS .85
7.1.9 Considérations spécifiques au site .86
7.1.10 Charges de confinement de la cargaison .86
7.1.11 Fatigue .87
7.1.12 Tossage .87
7.1.13 Embarquement d'eau .87
7.1.14 Superstructures et charges externes .87
7.1.15 Charges accidentelles . . .88
7.2 Stabilité et intégrité de l'étanchéité .88
iv © ISO 2020 – Tous droits réservés

---------------------- Page: 4 ----------------------
ISO 20257-1:2020(F)

7.2.1 Généralités .88
7.2.2 Stabilité .88
7.2.3 Intégrité de l'étanchéité à l'eau et aux intempéries.89
8 Stockage de GNL .90
8.1 Généralités .90
8.2 Charges de ballottement (sloshing) .90
8.2.1 Niveaux intermédiaires de remplissage : conditions d'exploitation des
FSRU/FLNG . .90
8.2.2 Niveaux intermédiaires de remplissage : conditions d'exploitation des
transferts de cargaison (navire/navire (STS)) .91
8.3 Gestion des gaz d'évaporation (BOG) .92
8.4 Gestion de la prévention de roll-over .92
8.4.1 Contexte .92
8.4.2 Détection et prévention .92
8.5 Réseaux d'évents pour le stockage du GNL .93
8.5.1 Généralités .93
8.5.2 Systèmes de décharge de pression .93
8.5.3 Systèmes de surpression.94
9 Système de transfert de GNL .94
9.1 Exigences fonctionnelles particulières .94
9.2 Conception des systèmes de transfert .95
9.2.1 Enveloppe de fonctionnement .95
9.2.2 Conception du système de transfert .96
10 Manipulation et récupération des gaz d'évaporation .98
10.1 Généralités .98
10.2 Système de collecte des BOG .99
10.3 Retour gaz vers le méthanier ou vers l'installation flottante de GNL .100
10.4 Récupération des gaz d'évaporation .100
10.5 Compresseur de gaz .100
10.6 Torches/évents .100
11 Tuyauterie basse température .101
11.1 Généralités .101
11.2 Composants de tuyauteries .101
11.2.1 Généralités .101
11.3 Tuyauterie .101
11.3.1 Généralités .101
11.3.2 Raccordements de tuyauteries .102
11.3.3 Supports de tuyauterie .102
11.3.4 Compensation des contractions dues au froid .102
11.3.5 Déplacements différentiels entre structures en mer .102
11.4 Robinetterie .103
11.4.1 Soupapes de décharge .103
11.5 Isolation thermique .104
11.5.1 Généralités .104
11.5.2 Isolation des tuyauteries .104
11.5.3 Comportement au feu .105
11.5.4 Absorption de gaz .105
11.5.5 Résistance à l'humidité.105
11.5.6 Mouvements différentiels .105
11.5.7 Détermination de l'épaisseur . .105
11.6 Prévention de la contamination de l'acier austénitique par le zinc .106
12 Réseaux de commodités .106
12.1 Classification des systèmes .106
12.1.1 Services essentiels .106
12.1.2 Services d'urgence .107
12.2 Électricité .107
© ISO 2020 – Tous droits réservés v

---------------------- Page: 5 ----------------------
ISO 20257-1:2020(F)

12.2.1 Conception et principes généraux .107
12.2.2 Conception du système électrique .108
12.2.3 Conception et sélection des équipements et des câbles .111
12.3 Système d'air d'instrumentation .112
12.4 Systèmes hydrauliques.112
13 Systèmes de contrôle et de surveillance de procédé et de sécurité .
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

This May Also Interest You

ISO
ISO/TS 18683:2021(Main)
Guidelines for safety and risk assessment of LNG fuel bunkering operations

This document gives guidance on the risk-based approach to follow for the design and operation of the LNG bunker transfer system, including the interface between the LNG bunkering supply facilities and receiving LNG fuelled vessels. This document provides requirements and recommendations for the development of a bunkering site and facility and the LNG bunker transfer system, providing the minimum functional requirements qualified by a structured risk assessment approach taking into consideration LNG properties and behaviour, simultaneous operations and all parties involved in the operation. This document is applicable to bunkering of both seagoing and inland trading vessels. It covers LNG bunkering from shore or ship, mobile to ship and ship to ship LNG supply scenarios, as described in Clause 4.

  • Technical specification
    38 pages
    English language
    sale 15% off
ISO
ISO 20257-2:2021(Main)
Installation and equipment for liquefied natural gas — Design of floating LNG installations — Part 2: Specific FSRU issues

This document provides specific requirements and guidance for the design and operation of floating LNG storage and regasification units (FSRU) described in ISO 20257-1. This document is applicable to offshore, near-shore or docked FSRUs and to both new-built and converted FSRUs. This document includes requirements to the jetty when an FSRU is moored to a jetty.

  • Standard
    40 pages
    English language
    sale 15% off
  • Standard
    43 pages
    French language
    sale 15% off
  • Standard
    43 pages
    French language
    sale 15% off
  • Draft
    40 pages
    English language
    sale 15% off
ISO
ISO 20088-2:2020(Main)
Determination of the resistance to cryogenic spill of insulation materials — Part 2: Vapour exposure

This document describes a method for determining the resistance of Cryogenic Spill Protection (CSP) systems to vapour generated from a cryogenic liquid release where the liquid content is practically zero. It is applicable where CSP systems are installed on carbon steel. The test provided in this document is not applicable to high pressure cryogenic liquid releases that can be found in refrigeration circuits and in LNG streams immediately post-liquefaction.

  • Standard
    15 pages
    English language
    sale 15% off
  • Standard
    15 pages
    French language
    sale 15% off
ISO
ISO 20088-3:2018(Main)
Determination of the resistance to cryogenic spillage of insulation materials — Part 3: Jet release

This document describes a method for determining the resistance of a cryogenic spill protection (CSP) system to a cryogenic jet as a result of a pressurized release which does not result in immersion conditions. It is applicable where CSP systems are installed on carbon steel and will be in contact with cryogenic fluids. A cryogenic jet can be formed upon release from process equipment operating at pressure (e.g. some liquefaction processes utilize 40 to 60 bar operating pressure). Due to high pressure discharge, the cryogenic spillage protection can be compromised by the large momentum combined with extreme cryogenic temperature. Although the test uses liquid nitrogen as the cryogenic liquid, the test described in this document is representative of a release of LNG, through a 20 mm orifice or less, at a release pressure of 6 barg or less, based upon simulated parameters 1 m from the release point. Confidence in this test being representative is based upon a comparison of the expected dynamic pressure of the simulated release in comparison with dynamic pressure from releases in accordance with this document. It is not practical in this test to cover the whole range of cryogenic process conditions found in real plant conditions; in particular the test does not cover high pressure cryogenic jet releases that might be found in refrigeration circuits and in LNG streams immediately post-liquefaction. Liquid nitrogen is used as the cryogenic medium due to the ability to safely handle the material at the pressures described in this document. The test condition is run at nominally 8 barg pressure. ISO 20088-1 covers cryogenic release scenarios which can lead to pooling conditions for steel work protected by cryogenic spill protection as a result of a jet release or low pressure release of LNG or liquid nitrogen. ISO 20088-2 covers vapour phase exposure conditions as a result of a jet release or low pressure release of LNG or liquid nitrogen.

  • Standard
    23 pages
    English language
    sale 15% off
  • Standard
    23 pages
    French language
    sale 15% off
ISO
ISO 20088-1:2016(Main)
Determination of the resistance to cryogenic spillage of insulation materials — Part 1: Liquid phase

ISO 20088-1:2016 describes a method for determining the resistance to liquid cryogenic spillage on cryogenic spillage protection (CSP) systems. It is applicable where CSP systems are installed on carbon steel and will be in contact with cryogenic fluids. Liquid nitrogen is used as the cryogenic medium since it has a lower boiling point than liquid natural gas or liquid oxygen and it is not flammable. Additionally, it can be safely used for experiment. Future parts of the standard will cover vapour phase and jet exposure conditions. The test laboratory is responsible to conduct an appropriate risk assessment according to local regulation in order to consider the impact of liquid and gaseous nitrogen exposure to equipment and personnel.

  • Standard
    19 pages
    English language
    sale 15% off
  • Standard
    19 pages
    English language
    sale 15% off
  • Standard
    20 pages
    French language
    sale 15% off
ISO
ISO/TR 17177:2015(Main)
Petroleum and natural gas industries — Guidelines for the marine interfaces of hybrid LNG terminals

ISO/TR 17177:2015 provides guidance for installations, equipment and operation at the ship to terminal and ship to ship interface for hybrid floating and fixed LNG terminals that might not comply with the description of "Conventional LNG Terminal" included in ISO 28460. ISO/TR 17177:2015 is intended to be read in conjunction with ISO 28460 to ensure the safe and efficient LNG transfer operation at these marine facilities. ISO/TR 17177:2015 also addresses high pressure natural gas (HPNG) at the transfer interface at facilities where liquefaction or regasification is undertaken, but does not describe requirements for the process plant generally forming part of the terminal facility. These guidelines are based around facilities that are currently in operation or under development.

  • Technical report
    28 pages
    English language
    sale 15% off
ISO
ISO 28460:2010(Main)
Petroleum and natural gas industries — Installation and equipment for liquefied natural gas — Ship-to-shore interface and port operations

ISO 28460:2010 specifies the requirements for ship, terminal and port service providers to ensure the safe transit of an LNG carrier through the port area and the safe and efficient transfer of its cargo. It is applicable to pilotage and vessel traffic services (VTS); tug and mooring boat operators; terminal operators; ship operators; suppliers of bunkers, lubricants and stores and other providers of services whilst the LNG carrier is moored alongside the terminal. ISO 28460:2010 includes provisions for a ship's safe transit, berthing, mooring and unberthing at the jetty; cargo transfer; access from jetty to ship; operational communications between ship and shore; all instrumentation, data and electrical connections used across the interface, including OPS (cold ironing), where applicable; the liquid nitrogen connection (where fitted); ballast water considerations. ISO 28460:2010 applies only to conventional onshore LNG terminals and to the handling of LNGC's in international trade. However, it can provide guidance for offshore and coastal operations.

  • Standard
    35 pages
    English language
    sale 15% off
  • Standard
    28 pages
    English language
    sale 15% off
  • Standard
    30 pages
    French language
    sale 15% off
ISO
ISO/TS 16486-7:2023(Main)
Plastics piping systems for the supply of gaseous fuels — Unplasticized polyamide (PA-U) piping systems with fusion jointing and mechanical jointing — Part 7: Assessment of conformity

This document gives guidance and requirements for the assessment of conformity of compounds, products, joints and assemblies in accordance with the applicable part(s) of the ISO 16486 series which are intended to be included in the manufacturer’s quality plan as part of the quality management system and for the establishment of certification procedures. NOTE 1 A basic test matrix in Annex B provides an overview of the testing scheme. It is recommended for the manufacturer to have a management system such as ISO 9001[4] or equivalent. NOTE 2 If certification is involved, certification bodies and inspection bodies operating according to ISO/IEC 17065 and ISO/IEC 17020 are considered to be competent. In conjunction with the other parts of the ISO 16486 series (see Clause 2), this document is applicable to unplasticized polyamide (PA-U) piping systems intended to be buried and used for the supply of gaseous fuels. It is applicable to PA-U pipes, fittings and valves, as well as to their joints and to joints with components of other materials intended to be used under the following conditions: a) a maximum operating pressure (MOP) up to and including 18 bar[1] (the MOP is limited to 16 bar for CEN member countries, where ISO 16486-6 is replaced by CEN/TS 12007-6[1]); b) an operating temperature of 20 °C as the reference temperature. NOTE 3 For operating temperatures different to 20 °C, derating coefficients can be used (see ISO 16486-6). CEN member countries use CEN/TS 12007-6[1] and ISO/TS 16486-7 (this document) as a basis, but they can also request additional requirements. For non-CEN member countries, information for dealing with special cases for PA-U can be found in ISO/TS 16486-7 (this document) and PPI TR-3.[7] For mechanical fittings conforming to ISO 17885, guidance for assessment of conformity is not given in this document. When requested, a quality plan based on the tests mentioned can be set up in agreement between user and manufacturer. The ISO 16486 series covers a range of maximum operating pressures and gives requirements concerning colours. NOTE 4 It is the responsibility of the purchaser or specifier to make the appropriate selections from these aspects, taking into account their particular requirements and any relevant national regulations and installation practices or codes. [1] 1 bar = 0,1 MPa = 105 Pa; 1 MPa = 1 N/mm2.

  • Technical specification
    33 pages
    English language
    sale 15% off
  • Draft
    33 pages
    English language
    sale 15% off
  • Draft
    33 pages
    English language
    sale 15% off
ISO
ISO 22974:2023(Main)
Petroleum and natural gas industry — Pipeline transportation systems — Pipeline integrity assessment specification

This document specifies requirements and gives recommendations on the integrity assessment of pipelines of various applications as part of pipeline systems. This document is mainly applicable to onshore pipeline systems, connecting wells, production plants, process plants, refineries and storage facilities, including any section of a pipeline constructed within the boundaries of such facilities for connection purpose, according to ISO 19345-1. The principles can also be used for offshore pipelines where applicable and practical. This document applies to rigid, steel pipelines. It is not applicable for flexible pipelines or those constructed from other materials, such as glass-reinforced plastics. This document does not cover all conditions which might be related to pipeline integrity. A competent pipeline integrity engineer can evaluate whether additional requirements are necessary. This document does not cover the assessment of pipeline defect(s) found during fabrication/construction or installation, which would need to be done in accordance with the applicable standards of design, construction, material procurement and welding process applicable at that time. However, this document can be applied to the ongoing monitoring and assessment of known flaws from the time of construction.

  • Standard
    24 pages
    English language
    sale 15% off
  • Standard
    26 pages
    French language
    sale 15% off
  • Draft
    24 pages
    English language
    sale 15% off
  • Draft
    36 pages
    French language
    sale 15% off
ISO
ISO 24139-2:2023(Main)
Petroleum and natural gas industries — Corrosion resistant alloy clad bends and fittings for pipeline transportation system — Part 2: Clad fittings

This document specifies the technical delivery conditions regarding design, geometric dimensions, materials, manufacturing procedures, inspection methods, non-destructive testing, marking, package and storage for factory-made, seamless and welded, corrosion resistant alloy (CRA) clad fittings for use in pipeline transportation systems for the petroleum and natural gas industries as defined in ISO 13623. This document is applicable to CRA clad fittings for use in transportation or process pipelines transporting corrosive media-containing single-phase or multi-phase fluid such as oil, gas and water for the petroleum and natural gas industries. It can also be used as reference in other fields. The clad fittings specified in this document include clad elbows, clad reducers, clad tees and clad caps. Two technical delivery conditions classes for clad fittings are designated. Class B provides a standard quality level for clad fittings and Class S provides technical requirements for sour-service conditions. Fabricated laterals, fabricated lap joint stub ends and other fittings employing circumferential or intersection welds are considered as pipe fabrication and are outside the scope of this document.

  • Standard
    48 pages
    English language
    sale 15% off
  • Standard
    53 pages
    French language
    sale 15% off