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EN ISO 13628-1:1999

(Main)

Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)

Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)

Erdöl- und Erdgasindustrien - Konstruktion und Betrieb von Unterwasser-Produktionssystemen - Teil 1: Allgemeine Anforderungen und Empfehlungen

Industries du pétrole et du gaz naturel - Conception et exploitation des systèmes de production immergés - Partie 1: Exigences générales et recommandations (ISO 13628-1:1999)

Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)

General Information

Status
Withdrawn
Publication Date
14-Feb-1999
Withdrawal Date
14-Nov-2005
ICS
75.180.10 - Exploratory, drilling and extraction equipment
Technical Committee
CEN/TC 12 - Materials, equipment and offshore structures for petroleum and natural gas industries
Drafting Committee
CEN/TC 12 - Materials, equipment and offshore structures for petroleum and natural gas industries
Current Stage
9960 - Withdrawal effective - Withdrawal
Start Date
15-Nov-2005
Completion Date
15-Nov-2005
Ref Project
SIST EN ISO 13628-1:2000 - Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)

Relations

Replaced By
EN ISO 13628-1:2005 - Petroleum and natural gas industries - Design and operation of subsea production systems - Part 1: General requirements and recommendations (ISO 13628-1:2005)
Effective Date
22-Dec-2008

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SLOVENSKI STANDARD
SIST EN ISO 13628-1:2000
01-december-2000
Petroleum and natural gas industries - Design and operation of subsea production
systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)
Petroleum and natural gas industries - Design and operation of subsea production
systems - Part 1: General requirements and recommendations (ISO 13628-1:1999)
Erdöl- und Erdgasindustrien - Konstruktion und Betrieb von Unterwasser-
Produktionssystemen - Teil 1: Allgemeine Anforderungen und Empfehlungen
Industries du pétrole et du gaz naturel - Conception et exploitation des systemes de
production immergés - Partie 1: Exigences générales et recommandations (ISO 13628-
1:1999)
Ta slovenski standard je istoveten z: EN ISO 13628-1:1999
ICS:
75.180.10 Oprema za raziskovanje in Exploratory and extraction
odkopavanje equipment
SIST EN ISO 13628-1:2000 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000
INTERNATIONAL ISO
STANDARD 13628-1
First edition
1999-02-15
Petroleum and natural gas industries —
Design and operation of subsea production
systems —
Part 1:
General requirements and recommendations
Industries du pétrole et du gaz naturel — Conception et exploitation des
systèmes de production immergés —
Partie 1: Exigences générales et recommandations
A
Reference number
ISO 13628-1:1999(E)

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SIST EN ISO 13628-1:2000
ISO 13628-1:1999(E)
Contents
1 Scope .1
2 Normative references .1
3 Terms, definitions and abbreviations.2
3.1 Terms and definitions .2
3.2 Abbreviations.2
4 Systems and interface descriptions .4
4.1 General.4
4.2 Overall system description.6
4.3 Subsea wellhead system.7
4.4 Subsea tree system and tubing hanger.8
4.5 Completion/workover riser systems.9
4.6 Mudline casing suspension system description.10
4.7 Production control system .10
4.8 Sealine systems.11
4.9 Subsea template and manifold systems .12
4.10 Production risers .13
4.11 Intervention systems.13
5 Design.14
5.1 General.14
5.2 Design criteria.14
5.3 Field development .17
5.4 Design loads.18
5.5 System design.18
©  ISO 1999
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized in any form or by any means, electronic
or mechanical, including photocopying and microfilm, without permission in writing from the publisher.
International Organization for Standardization
Case postale 56 • CH-1211 Genève 20 • Switzerland
Internet iso@iso.ch
Printed in Switzerland
ii

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
6 Materials and corrosion protection. 39
6.1 Material evaluation . 39
6.2 Metallic materials. 40
6.3 Non-metallic materials . 41
6.4 Bolting materials for subsea applications . 42
6.5 External corrosion protection . 42
6.6 Design limitations for materials . 43
7 Manufacturing and testing. 45
7.1 Manufacturing and testing. 45
7.2 Test procedures. 45
7.3 Integration testing . 46
8 Operations. 47
8.1 Transportation and handling. 47
8.2 Installation. 48
8.3 Drilling and completion. 49
8.4 Hook-up and commissioning . 50
8.5 Well intervention. 55
8.6 Maintenance . 56
8.7 Decommissioning. 57
9 Documentation. 59
9.1 General . 59
9.2 Engineering and manufacturing . 59
9.3 Operating and maintenance . 59
9.4 As-built/as-installed documentation. 59
Annex A (informative) Description of subsea production system . 60
Annex B (informative) Marking colours . 107
Annex C (informative) Integration testing of subsea production equipment. 109
Annex D (informative) Typical procedures for commissioning. 114
Annex E (informative) Documentation for operation. 117
Annex F (informative) Data sheets . 122
Bibliography. 128
iii

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(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.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 3.
Draft International Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote.
International Standard ISO 13628-1 was prepared by Technical Committee ISO/TC 67, Materials, equipment and
offshore structures for petroleum and natural gas industries, Subcommittee SC 4, Drilling and production
equipment.
ISO 13628 consists of the following parts, under the general title Petroleum and natural gas industries — Design
and operation of subsea production systems:
 Part 1: General requirements and recommendations
 Part 2: Flexible pipe systems for subsea and marine applications
 Part 3: Through flowline (TFL) systems
 Part 4: Subsea wellhead and tree equipment
 Part 5: Subsea control umbilicals
 Part 6: Subsea production control systems
 Part 7: Workover/completion riser systems
 Part 8: Remotely Operated Vehicle (ROV) interfaces on subsea production systems
 Part 9: Remotely Operated Tool (ROT) intervention systems
Annexes A, B, C, D, E and F of this part of ISO 13628 are for information only.
iv

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
Introduction
This part of ISO 13628 has been prepared to provide general requirements, recommendations and overall guidance
for the user to the various areas requiring consideration during development of a subsea production system for the
petroleum and natural gas industries. The functional requirements defined in this part of ISO 13628 will allow
alternatives in order to suit specific field requirements. The intention is to facilitate and complement the decision
process rather than replace individual engineering judgement and, where requirements are non-mandatory, provide
positive guidance for the selection of an optimum solution.
This part of ISO 13628 constitutes the overall subsea production system standard, with the intention that the more
detailed requirements for the subsystems are retained in the complementary parts of ISO 13628. However, in some
areas (e.g. structures, manifolds, marking) detailed requirements are included herein, as these subjects are not
covered in a subsystem standard.
This part of ISO 13628 was developed on the basis of API RP 17A, Design and Operation of Subsea Production
Systems, and other relevant documents on subsea production systems.
v

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SIST EN ISO 13628-1:2000

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SIST EN ISO 13628-1:2000
INTERNATIONAL STANDARD  © ISO ISO 13628-1:1999(E)
Petroleum and natural gas industries — Design and operation of
subsea production systems —
Part 1:
General requirements and recommendations
1 Scope
This part of ISO 13628 provides general requirements and overall recommendations for development of complete
subsea production systems from the design phase to decommissioning. This part of ISO 13628 forms a top-level
document to govern other standards dealing with subsystems typically forming a part of a subsea production
system.
The complete subsea production system comprises several subsystems necessary to produce hydrocarbons from
one or more subsea wells to a given processing facility located offshore (fixed, floating or subsea) or onshore, or to
inject water/gas through subsea wells. This part of ISO 13628 and the subsystem standards apply as far as the
interface limits described in clause 4.
Specialized equipment, such as split trees and trees and manifolds in atmospheric chambers, are not specifically
discussed because of their limited use. However, the information presented is applicable to those types of
equipment.
2 Normative references
The following normative documents contain provisions which, through reference in this text, constitute provisions of
this part of ISO 13628. For dated references, subsequent amendments to, or revisions of, any of these publications
do not apply. However, parties to agreements based on this part of ISO 13628 are encouraged to investigate the
possibility of applying the most recent editions of the normative documents indicated below. For undated
references, the latest edition of the normative document referred to applies. Members of ISO and IEC maintain
registers of currently valid International Standards.
ISO 898-1, Mechanical properties of fasteners made of carbon steel and alloy steel — Part 1: Bolts, screws and
studs.
ISO 898-2, Mechanical properties of fasteners made of carbon steel and alloy steel — Part 2: Nuts with specified
proof load value.
ISO 10423, Petroleum and natural gas industries — Drilling and production equipment — Wellhead and christmas
tree equipment.
ISO 13628-3, Petroleum and natural gas industries — Design and operation of subsea production systems —
Part 3: Through flowline (TFL) systems.
1)
ISO 13628-4:— , Petroleum and natural gas industries — Design and operation of subsea production systems —
Part 4: Subsea wellhead and tree equipment.

1)
To be published.
1

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
ISO 13628-6, —
Petroleum and natural gas industries — Design and operation of subsea production systems
Part 6: Subsea production control systems.
ISO 13819-1, Petroleum and natural gas industries — Offshore structures — Part 1: General requirements.
ISO 13819-2, Petroleum and natural gas industries — Offshore structures — Part 2: Fixed steel structures.
ANSI/ASME B31.8, Gas Transmission and Distribution Piping Systems.
2)
API RP 17C , TFL (Trough Flowline) Systems.
3)
API RP 17G , Design and Operation of Completion/Workover Riser Systems.
ASTM A 193, Specification for Alloy — Steel and Stainless Steel Bolting Materials for High Temperature Service.
ASTM A 320, Specification for Alloy Steel Bolting Materials for Low-Temperature Service.
3 Terms, definitions and abbreviations
For the purposes of this part of ISO 13628, the following terms, definitions and abbreviations apply.
3.1 Terms and definitions
3.1.1
sealine
flowline, service line, cable, umbilical or pipeline
NOTE For description of pressure and temperature ratings, the definition given in the applicable subsystem standard and
other relevant standards and design codes is used.
3.2 Abbreviations
ADS atmospheric diving suit
API American Petroleum Institute
BOP blow-out preventer
BS&W basic sediment and water
CRA corrosion-resistant alloy
DCV directional control valve
DFI design, fabrication, installation
DFO documentation for operation
EDP emergency disconnect package
EFC European Federation of Corrosion
ESD emergency shutdown

2)
For the purposes of this part of ISO 13628, API RP 17C will be replaced by ISO 13628-3 when the latter becomes publicly
available.
3)
For the purposes of this part of ISO 13628, API RP 17G will be replaced by ISO 13628-7 when the latter becomes publicly
available.
2

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
ESP electrical submersible pump
FAT factory acceptance test
FPU floating production unit
GOR gas-oil ratio
GRP glass-fibre-reinforced plastic
HAT highest astronomical tide level
HAZOP hazards in operation analysis
HB Brinell hardness
HIPPS high integrity pipeline protection system
HPU hydraulic power unit
HV Vickers hardness
IMR inspection, maintenance and repair
IRJ instrument riser joint
ISO International Organization for Standardization
LAT lowest astronomical tide level
LMRP lower marine riser package (for drilling)
LMV lower master valve
LRP lower riser package (for workover)
MIV methanol injection valve
NACE National Association of Corrosion Engineers
NDE nondestructive examination
PC personal computer
PCDA plant control and data acquisition system
PCS production control system
PGB permanent guide base
PLC programmable logical controller
PMV production master valve
PRE pitting-resistance equivalent
PSD process shutdown
PSV production swab valve
PWV production wing valve
3

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
P&A plug and abandonment
RAL “Reichsausschuss für Lieferbedingungen”. A colour system used by German paint manufacturers
ROT remotely operated tool
ROV remotely operated vehicle
SAS safety and automation system
SAFOP safety in operation analysis
SCM subsea control module
SCSSV surface-controlled subsurface safety valve
SEM subsea electronic module
SMYS specified minimum yield strength
TFL through-flowline system
THRT tubing hanger running tool
TLP tension leg platform
TRSCSSV tubing-retrievable surface-controlled subsurface safety valve
TRT tree running tool
UNS unified numbering system
UPS uninterruptable power supply
UTM universal transversal mercator
VDU visual display unit
WHP wellhead pressure
XT tree
XTRT tree running tool
4 Systems and interface descriptions
4.1 General
Complete subsea production systems range in complexity from a single satellite well with a flowline linked to a fixed
platform, to several wells on a template producing to a floating facility.
The elements of a typical subsea production system are shown in Figure 1. These are wellheads (both subsea and
mudline casing suspension systems) and trees, sealines and end connections, controls, control lines, single-well
structures, templates and manifolds, ROVs/ROTs and completion/workover and production risers (both rigid and
flexible). In some areas (not covered by subsystem standards), detailed requirements are included (these apply to
structures, manifold piping, materials, colour and marking).
The objective of this subclause is to describe the systems in general and define the subsystem interfaces. For a
detailed description of subsystems and components, see annex A.
4

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
A schematic drawing illustrating typical elements of a subsea production system is shown in Figure 2.
Key
1 Running and retrieving tools 7 Production controls
2 Installation and workover controls 8 Production riser
3 Completion riser and control lines 9 Riser base
4 Satellite well 10 Manifold
5 Template 11 Export
6 Sealines
Figure 1 — Typical development scenarios
5

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
NOTE For satellite wells directly tied back to the platform, several of the above-mentioned elements are eliminated.
Figure 2 — Typical elements in a subsea production system
4.2 Overall system description
4.2.1 General
Subsea production or injection systems are used to develop reservoirs, or parts of reservoirs, of a nature which
dictates drilling of the wells from more than one location. Subsea production systems may also be used to develop
reservoirs or parts of reservoirs beyond the reach of platform drilling facilities. Deep water may also in itself dictate
development of a field by means of subsea completions.
The main elements of a subsea production or injection system are:
 a wellhead system with associated casing strings and production/injection tubing;
 a structural foundation and a guidance system for orientation and lateral guidance of modules during
installation/retrieval. This unit is not always used;
 a set of flow and pressure control valves normally integrated in a tree;
 a production control system for remote monitoring and control of all subsea functions;
6

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
 a protective structure (optional);
 a sealine system;
 a manifold system (optional);
 installation and intervention equipment and tools with associated control systems.
The elements of the subsea production/injection system may be configured in numerous ways, dictated by specific
field requirements and by operator strategy.
The most common configurations are:
 single satellite wells tied individually to a surface processing facility;
 one or more satellite wells tied individually to a subsea manifold located a given distance from the surface
processing facility;
 multiple wells located on a common template incorporating a manifold.
In the following, the main characteristics of these scenarios are briefly described.
4.2.2 Single satellites
For relatively shallow water, this configuration is characterized by short offset (outside the drilling reach of the host
platform if this is a combined drilling production facility) and, if an infrastructure with a surplus of tie-in capacity
exists, this scenario can be very effective. In terms of required permanent works this is basically a single satellite
development copied a number of times over. Usually the flowline and umbilical are required to be installed as first-
end tie-in at the infrastructure and second end pull-in at the satellites in order to limit congestion on the seabed
around the infrastructure.
Flowline and umbilical are for some systems connected directly to the tree structure. This approach offers some
rationalization in hardware.
4.2.3 Manifold/satellite cluster
This concept is based on tie-in of a number of single satellites to a central manifold. The manifold in turn is tied to
the infrastructure by means of one or more sealines. An arrangement including two production flowlines with same
size, service and control lines is quite common. This arrangement facilitates operation of wells at two different
pressure levels simultaneously, as well as convenient round-trip pigging.
The system has flexibility with respect to simultaneous drilling and production, which can save some drilling time,
and has flexibility with respect to installing wells in optimal locations rather than in batches at the same location, ref.
template arrangement described below.
4.2.4 Template
This concept includes some of the features described in the previous subclause, but with some notable differences.
The wells and the manifolds are located on the same structure. Headers and lines often have much of the same
configuration as the manifold/cluster option. Template designs have some additional mechanical tolerance problems
relative to cluster designs.
4.3 Subsea wellhead system
4.3.1 General
The main function of a subsea wellhead system is to serve as a structural and pressure-containing anchoring point
on the seabed for the drilling and completion systems and for the casing strings in the well. The wellhead system
incorporates internal profiles for support of the casing strings and isolation of the annuli. In addition, the system
incorporates facilities for guidance, mechanical support and connection of the systems used to drill and complete
the well.
7

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SIST EN ISO 13628-1:2000
© ISO
ISO 13628-1:1999(E)
4.3.2 Wellhead system elements
A typical wellhead system consists of the following elements:
a) a drilling guidebase with a central opening for drilling of the first section of the well and facilities for attachment
of guidelines. The temporary guidebase, acts as a support for the permanent guidebase, providing a controlled
reference point for wellhead elevation. Note that on single satellite wells the drilling guidebase may be omitted if
there are no requirements for accurately controlled elevation of the wellhead. On multiple well templates, the
drilling guidebase forms an integral part of the template;
b) a permanent guidebase with facilities for attachment to the conductor housing, and guidance of the drilling and
completion equipment (universal guide frame, BOP, production tree). If used together with a temporary
guidebase, the permanent guidebase incorporates a gimbal arrangement on the under side (curved profiles
that interfaces with a cone landing area on the temporary guidebase) to compensate for any angular
misalignment between the temporary guidebase and the permanent guidebase due to the seabed topography,
and the verticality of the well;
NOTE On satellite wells, depending on the overall tree configuration, the permanent guidebase may be replaced by
a production guidebase, prior to installation of the tree, incorporating facilities for pull-in and connection of the sealines
and connection to the tree. Alternatively, a production guidebase can be designed to serve as both the drilling guidebase
and the production guidebase. It can be either permanent or retrievable. The sealines may also be connected directly to
the tree.
c) a conductor housing welded to the conductor casing, which forms the initial anchoring point to the seabed. The
conductor housing incorporates an internal landing shoulder for the wellhead housing, and facilities on the
outside for attachment of the permanent guidebase. The conductor housing may be installed together with the
permanent guidebase;
d) a wellhead housing with internal profiles for support of all subsequent casing strings and the tubing hanger, and
external profiles for attachment of the drilling and completion equipment (BOP, tree) and landing in 762 mm
(30 in) housing;
e) casing hangers with seal and lock-down assemblies for suspension of the casing strings and isolation of the
annuli.
4.3.3 Running and retrieving tools
Dedicated tools are used to install, test and retrieve the various elements of the wellhead system. The tools are
activated by either mechanical manipulation of the drill string (push, pull, rotation) or in some cases by hydraulic
functions through the drill string or dedicated hydraulic lines. These tools interface with dedicated handling profiles
in the associated equipment.
4.3.4 Miscellaneous wellhead equi
...

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SIST EN ISO 10423:2022

This document specifies requirements and gives recommendations for the performance, dimensional and functional interchangeability, design, materials, testing, inspection, welding, marking, handling, storing, shipment, and purchasing of wellhead and tree equipment for use in the petroleum and natural gas industries.
This document does not apply to field use or field testing.
This document does not apply to repair of wellhead and tree equipment except for weld repair in conjunction with manufacturing.
This document does not apply to tools used for installation and service (e.g. running tools, test tools, wash tools, wear bushings, and lubricators).
This document supplements API Spec 6A, 21st edition (2018), the requirements of which are applicable with the exceptions specified in this document.

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CEN
EN ISO 19901-10:2022(Main)
Petroleum and natural gas industries - Specific requirements for offshore structures - Part 10: Marine geophysical investigations (ISO 19901-10:2021)
SIST EN ISO 19901-10:2022

This document provides requirements and guidelines for marine geophysical investigations. It is applicable to operators/end users, contractors and public and regulatory authorities concerned with marine site investigations for offshore structures for petroleum and natural gas industries.
This document provides requirements, specifications, and guidance for:
a)   objectives, planning, and quality management;
b)   positioning;
c)   seafloor mapping, including instrumentation and acquisition parameters, acquisition methods, and deliverables;
d)   sub-seafloor mapping, including seismic instrumentation and acquisition parameters, and non-seismic-reflection methods;
e)   reporting;
f)    data integration, interpretation, and investigation of geohazards.
This document is applicable to investigation of the seafloor and the sub-seafloor, from shallow coastal waters to water depths of 3 000 m and more. It provides guidance for the integration of the results from marine soil investigations and marine geophysical investigations with other relevant datasets.
NOTE 1 The depth of interest for sub-seafloor mapping depends on the objectives of the investigation. For offshore construction, the depths of investigation are typically in the range 1 m below seafloor to 200 m below seafloor. Some methods for sub-seafloor mapping can also achieve much greater investigation depths, for example for assessing geohazards for hydrocarbon well drilling.
There is a fundamental difference between seafloor mapping and sub-seafloor mapping: seafloor signal resolution can be specified, while sub-seafloor signal resolution and penetration cannot. This document therefore contains requirements for the use of certain techniques for certain types of seafloor mapping and sub-seafloor mapping (similarly, requirements are given for certain aspects of data processing). If other techniques can be shown to obtain the same information, with the same or better resolution and accuracy, then those techniques may be used.
Mapping of pre-drilling well-site geohazards beneath the seafloor is part of the scope of this document.
NOTE 2 This implies depths of investigation that are typically 200 m below the first pressure-containment casing string or 1 000 m below the seafloor, whichever is greatest. Mapping of pre-drilling well-site geohazards is therefore the deepest type of investigation covered by this document.
In this document, positioning information relates only to the positioning of survey platforms, sources and receivers. The processes used to determine positions of seafloor and sub-seafloor data points are not covered in this document.
Guidance only is given in this document for the use of marine shear waves (A.8.3.3), marine surface waves (A.8.3.4), electrical resistivity imaging (A.8.3.5) and electromagnetic imaging (A.8.3.6).

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CEN
EN ISO 24200:2022(Main)
Petroleum, petrochemical and natural gas industries - Bulk material for offshore projects - Pipe support (ISO 24200:2022)
SIST EN ISO 24200:2022

This document specifies the requirements for design including shape and dimensions, material as well as strength for pipe support. Applicable pipe size range varies depending on support types. This document covers topside systems for fixed or floating offshore oil and gas projects. This document is applicable to design temperature of support within the range between –46 °C up to 200 °C.
This document is limited to metallic pipes, covering the following pipe supports:
—    clamped shoe;
—    welded shoe;
—    U-bolt;
—    U-strap;
—    bracing for branch connection;
—    trunnion and stanchion;
—    guide support (guide, hold-down, guide and hold-down, line stop).

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EN ISO 19901-5:2021(Main)
Petroleum and natural gas industries - Specific requirements for offshore structures - Part 5: Weight management (ISO 19901-5:2021)
SIST EN ISO 19901-5:2022

This document specifies requirements for managing and controlling the weight and centre of gravity (CoG) of offshore facilities by means of mass management during all lifecycle phases including; conceptual design, front end engineering design (FEED), detail engineering, construction and operations. These can be new facilities (greenfield) or modifications to existing facilities (brownfield).
Weight management is necessary throughout operations, decommissioning and removal to facilitate structural integrity management (SIM). The provisions of this document are applicable to fixed and floating facilities of all types.
Weight management only includes items with static mass.
Snow and ice loads are excluded as they are not considered to be part of the facility. Dynamic loads are addressed in ISO 19904-1, ISO 19901-6 and ISO 19901-7.
This document specifies:
a) requirements for managing and controlling weights and CoGs of assemblies and entire facilities;
b) requirements for managing weight and CoG interfaces;
c) standardized terminology for weight and CoG estimating and reporting;
d) requirements for determining not-to-exceed (NTE) weights and budget weights;
e) requirements for weighing and determination of weight and centre of gravity (CoG) of tagged equipment, assemblies, modules and facilities;
This document can be used:
f) as a basis for costing, scheduling or determining suitable construction method(s) or location(s) and installation strategy;
g) as a basis for planning, evaluating and preparing a weight management plan and reporting system;
h) as a contract reference;
i) as a means of refining the structural analysis or model.

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CEN
EN ISO 35102:2021(Main)
Petroleum and natural gas industries - Arctic operations - Escape, evacuation and rescue from offshore installations (ISO 35102:2020)
SIST EN ISO 35102:2022

This document establishes the principles, specifies the requirements and provides guidance for the development and implementation of an escape, evacuation and rescue (EER) plan. It is applicable to offshore installation design, construction, transportation, installation, offshore production/exploration drilling operation service life inspection/repair, decommissioning and removal activities related to petroleum and natural gas industries in the arctic and cold regions.
Reference to arctic and cold regions in this document is deemed to include both the Arctic and other locations characterized by low ambient temperatures and the presence or possibility of sea ice, icebergs, icing conditions, persistent snow cover and/or permafrost.
This document contains requirements for the design, operation, maintenance, and service-life inspection or repair of new installations and structures, and to modification of existing installations for operation in the offshore Arctic and cold regions, where ice can be present for at least a portion of the year. This includes offshore exploration, production and accommodation units utilized for such activities. To a limited extent, this document also addresses the vessels that support ER, if part of the overall EER plan.
While this document does not apply specifically to mobile offshore drilling units (MODUs, see ISO 19905‑1) many of the EER provisions contained herein are applicable to the assessment of such units in situations when the MODU is operated in arctic and cold regions.
The provisions of this document are intended to be used by stakeholders including designers, operators and duty holders. In some cases, floating platforms (as a type of offshore installations) can be classified as vessels (ships) by national law and the EER for these units are stipulated by international maritime law. However, many of the EER provisions contained in this document are applicable to such floating platforms.
This document applies to mechanical, process and electrical equipment or any specialized process equipment associated with offshore arctic and cold region operations that impacts the performance of the EER system. This includes periodic training and drills, EER system maintenance and precautionary down-manning as well as emergency situations.
EER associated with onshore arctic oil and gas facilities are not addressed in this document, except where relevant to an offshore development.

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EN ISO 18797-2:2021(Main)
Petroleum, petrochemical and natural gas industries - External corrosion protection of risers by coatings and linings - Part 2: Maintenance and field repair coatings for riser pipes (ISO 18797-2:2021)
SIST EN ISO 18797-2:2021

This document specifies the selection criteria and minimum requirements for protective coating systems for maintenance and field repair of risers exposed to conditions in the splash zone. It is applicable for maintenance requirements and field repairs of riser coatings.
This document does not apply to the selection of techniques and materials used to restore integrity of the risers to be coated, nor does it apply to the selection of additional mechanical protective materials that are not part of the coating systems described in this document.
New construction shop applied riser coatings are covered in ISO 18797-1. Compatible maintenance and repair coating systems specified in ISO 18797-1 are covered in this document.

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CEN
CEN ISO/TR 10400:2021(Main)
Petroleum and natural gas industries - Formulae and calculations for the properties of casing, tubing, drill pipe and line pipe used as casing or tubing (ISO/TR 10400:2018)
SIST-TP CEN ISO/TR 10400:2021

This document illustrates the formulae and templates necessary to calculate the various pipe properties given in International Standards, including
—          pipe performance properties, such as axial strength, internal pressure resistance and collapse resistance,
—          minimum physical properties,
—          product assembly force (torque),
—          product test pressures,
—          critical product dimensions related to testing criteria,
—          critical dimensions of testing equipment, and
—          critical dimensions of test samples.
For formulae related to performance properties, extensive background information is also provided regarding their development and use.
Formulae presented here are intended for use with pipe manufactured in accordance with ISO 11960 or API 5CT, ISO 11961 or API 5D, and ISO 3183 or API 5L, as applicable. These formulae and templates can be extended to other pipe with due caution. Pipe cold-worked during production is included in the scope of this document (e.g. cold rotary straightened pipe). Pipe modified by cold working after production, such as expandable tubulars and coiled tubing, is beyond the scope of this document.
Application of performance property formulae in this document to line pipe and other pipe is restricted to their use as casing/tubing in a well or laboratory test, and requires due caution to match the heat-treat process, straightening process, yield strength, etc., with the closest appropriate casing/tubing product. Similar caution is exercised when using the performance formulae for drill pipe.
This document and the formulae contained herein relate the input pipe manufacturing parameters in ISO 11960 or API 5CT, ISO 11961 or API 5D, and ISO 3183 or API 5L to expected pipe performance. The design formulae in this document are not to be understood as a manufacturing warranty. Manufacturers are typically licensed to produce tubular products in accordance with manufacturing specifications which control the dimensions and physical properties of their product. Design formulae, on the other hand, are a reference point for users to characterize tubular performance and begin their own well design or research of pipe input properties.
This document is not a design code. It only provides formulae and templates for calculating the properties of tubulars intended for use in downhole applications. This document does not provide any guidance about loads that can be encountered by tubulars or about safety margins needed for acceptable design. Users are responsible for defining appropriate design loads and selecting adequate safety factors to develop safe and efficient designs. The design loads and safety factors will likely be selected based on historical practice, local regulatory requirements, and specific well conditions.
All formulae and listed values for performance properties in this document assume a benign environment and material properties conforming to ISO 11960 or API 5CT, ISO 11961 or API 5D and ISO 3183 or API 5L. Other environments can require additional analyses, such as that outlined in Annex D.
Pipe performance properties under dynamic loads and pipe connection sealing resistance are excluded from the scope of this document.
Throughout this document tensile stresses are positive.

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