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kSIST-TP FprCEN 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)

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)

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.

Erdöl- und Erdgasindustrie - Formeln und Berechnungen der Eigenschaften von Futterrohren, Steigrohren, Bohrgestängen und Leitungsrohren (ISO/TR 10400:2018)

Industries du pétrole et du gaz naturel - Formules et calculs relatifs aux propriétés des tubes de cuvelage, des tubes de production, des tiges de forage et des tubes de conduites utilisés comme tubes de cuvelage et tubes de production (ISO/TR 10400:2018)

Industrija za predelavo nafte in zemeljskega plina - Formule in izračuni lastnosti ohišij, cevi, vrtalnih drogovij in cevovodov (ISO/TR 10400:2018)

General Information

Status
Not Published
Public Enquiry End Date
30-Jul-2021
ICS
75.180.10 - Exploratory, drilling and extraction equipment
Technical Committee
I13 - Imaginarni 13
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
29-Sep-2021
Due Date
04-Dec-2021
Ref Project
CEN ISO/TR 10400:2021 - 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)

RELATIONS

Revised
SIST-TP CEN ISO/TR 10400:2012 - Petroleum and natural gas industries - Equations and calculations for the properties of casing, tubing, drill pipe and line pipe used as casing or tubing (ISO/TR 10400:2007)
Effective Date
21-Feb-2018
Replaces
SIST-TP CEN ISO/TR 10400:2012 - Petroleum and natural gas industries - Equations and calculations for the properties of casing, tubing, drill pipe and line pipe used as casing or tubing (ISO/TR 10400:2007)
Effective Date
29-Sep-2021

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SLOVENSKI STANDARD
kSIST-TP FprCEN ISO/TR 10400:2021
01-julij-2021

Industrija za predelavo nafte in zemeljskega plina - Formule in izračuni lastnosti

ohišij, cevi, vrtalnih drogovij in cevovodov (ISO/TR 10400:2018)

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)

Erdöl- und Erdgasindustrie - Formeln und Berechnungen der Eigenschaften von
Futterrohren, Steigrohren, Bohrgestängen und Leitungsrohren (ISO/TR 10400:2018)

Industries du pétrole et du gaz naturel - Formules et calculs relatifs aux propriétés des

tubes de cuvelage, des tubes de production, des tiges de forage et des tubes de
conduites utilisés comme tubes de cuvelage et tubes de production (ISO/TR
10400:2018)
Ta slovenski standard je istoveten z: FprCEN ISO/TR 10400
ICS:
75.180.10 Oprema za raziskovanje, Exploratory, drilling and
vrtanje in odkopavanje extraction equipment
kSIST-TP FprCEN ISO/TR 10400:2021 en,fr,de

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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kSIST-TP FprCEN ISO/TR 10400:2021
---------------------- Page: 2 ----------------------
kSIST-TP FprCEN ISO/TR 10400:2021
TECHNICAL ISO/TR
REPORT 10400
Second edition
2018-08
Petroleum and natural gas
industries — Formulae and
calculations for the properties of
casing, tubing, drill pipe and line pipe
used as casing or tubing
Industries du pétrole et du gaz naturel — Formules et calculs relatifs
aux propriétés des tubes de cuvelage, des tubes de production, des
tiges de forage et des tubes de conduites utilisés comme tubes de
cuvelage et tubes de production
Reference number
ISO/TR 10400:2018(E)
ISO 2018
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kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(E)
COPYRIGHT PROTECTED DOCUMENT
© ISO 2018

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 2018 – All rights reserved
---------------------- Page: 4 ----------------------
kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(E)
Contents Page

Foreword ........................................................................................................................................................................................................................................vi

Introduction ..............................................................................................................................................................................................................................vii

1 Scope ................................................................................................................................................................................................................................. 1

2 Normative references ...................................................................................................................................................................................... 2

3 Terms and definitions ..................................................................................................................................................................................... 2

4 Symbols .......................................................................................................................................................................................................................... 4

5 Conformance ..........................................................................................................................................................................................................13

5.1 References ................................................................................................................................................................................................13

5.2 Units of measurement ......... ...........................................................................................................................................................13

6 Triaxial yield of pipe body .......................................................................................................................................................................13

6.1 General ........................................................................................................................................................................................................13

6.2 Assumptions and limitations ...................................................................................................................................................13

6.2.1 General...................................................................................................................................................................................13

6.2.2 Concentric, circular cross-sectional geometry ....................................................................................14

6.2.3 Isotropic yield ...................................................................... ............................................................................................14

6.2.4 No residual stress .........................................................................................................................................................14

6.2.5 Cross-sectional instability (collapse) and axial instability (column buckling) .......14

6.3 Data requirements ............................................................................................................................................................................14

6.4 Design formula for triaxial yield of pipe body ..........................................................................................................14

6.5 Application of design formula for triaxial yield of pipe body to line pipe ........................................16

6.6 Example calculations ......................................................................................................................................................................16

6.6.1 Initial yield of pipe body, Lamé formula for pipe when external pressure,

bending and torsion are zero .............................................................................................................................16

6.6.2 Yield design formula, special case for thin wall pipe with internal pressure

only and zero axial load ..........................................................................................................................................18

6.6.3 Pipe body yield strength ........................................................................................................................................18

6.6.4 Yield in the absence of bending and torsion .........................................................................................19

7 Ductile rupture of the pipe body .......................................................................................................................................................20

7.1 General ........................................................................................................................................................................................................20

7.2 Assumptions and limitations ...................................................................................................................................................20

7.3 Data requirements ............................................................................................................................................................................21

7.3.1 General...................................................................................................................................................................................21

7.3.2 Determination of the hardening index.......................................................................................................21

7.3.3 Determination of the burst strength factor, k .....................................................................................

a 22

7.4 Design formula for capped-end ductile rupture .....................................................................................................23

7.5 Adjustment for the effect of axial force and external pressure ..................................................................24

7.5.1 General...................................................................................................................................................................................24

7.5.2 Design formula for ductile rupture under combined loads .....................................................25

7.5.3 Design formula for ductile necking under combined loads .....................................................26

7.5.4 Boundary between rupture and necking .................................................................................................27

7.5.5 Axisymmetric wrinkling under combined loads ...............................................................................27

7.6 Example calculations ......................................................................................................................................................................28

7.6.1 Ductile rupture of an end-capped pipe ......................................................................................................28

7.6.2 Ductile rupture for a given true axial load ..............................................................................................28

8 External pressure resistance ................................................................................................................................................................29

8.1 General ........................................................................................................................................................................................................29

8.2 Assumptions and limitations ...................................................................................................................................................29

8.3 Data requirements ............................................................................................................................................................................29

8.4 Design formula for collapse of pipe body .....................................................................................................................30

8.4.1 General...................................................................................................................................................................................30

8.4.2 Yield strength collapse pressure formula ...............................................................................................30

© ISO 2018 – All rights reserved iii
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kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(E)

8.4.3 Plastic collapse pressure formula ..................................................................................................................31

8.4.4 Transition collapse pressure formula .........................................................................................................33

8.4.5 Elastic collapse pressure formula ..................................................................................................................34

8.4.6 Collapse pressure under axial tensile stress .........................................................................................35

8.4.7 Collapse pressure under axial stress and internal pressure ...................................................35

8.5 Formulae for empirical constants .......................................................................................................................................35

8.5.1 General...................................................................................................................................................................................35

8.5.2 SI units ...................................................................................................................................................................................36

8.5.3 USC units ..............................................................................................................................................................................36

8.6 Application of collapse pressure formulae to line pipe ....................................................................................37

8.7 Example calculations ......................................................................................................................................................................37

9 Joint strength .........................................................................................................................................................................................................37

9.1 General ........................................................................................................................................................................................................37

9.2 API casing connection tensile joint strength ..............................................................................................................37

9.2.1 General...................................................................................................................................................................................37

9.2.2 Round thread casing joint strength ..............................................................................................................38

9.2.3 Buttress thread casing joint strength..........................................................................................................40

9.3 API tubing connection tensile joint strength .............................................................................................................42

9.3.1 General...................................................................................................................................................................................42

9.3.2 Non-upset tubing joint strength ......................................................................................................................42

9.3.3 Upset tubing joint strength ..................................................................................................................................43

9.4 Line pipe connection joint strength ...................................................................................................................................44

10 Pressure performance for couplings ............................................................................................................................................44

10.1 General ........................................................................................................................................................................................................44

10.2 Internal yield pressure of round thread and buttress couplings ..............................................................44

10.3 Internal pressure leak resistance of round thread or buttress couplings ........................................45

11 Calculated masses ............................................................................................................................................................................................48

11.1 General ........................................................................................................................................................................................................48

11.2 Nominal linear masses ..................................................................................................................................................................48

11.3 Calculated plain-end mass .........................................................................................................................................................48

11.4 Calculated finished-end mass..................................................................................................................................................49

11.5 Calculated threaded and coupled mass ..........................................................................................................................49

11.5.1 General...................................................................................................................................................................................49

11.5.2 Direct calculation of e , threaded and coupled pipe .....................................................................50

11.6 Calculated upset and threaded mass for integral joint tubing ....................................................................50

11.6.1 General...................................................................................................................................................................................50

11.6.2 Direct calculation of e , upset and threaded pipe ...........................................................................51

11.7 Calculated upset mass ...................................................................................................................................................................51

11.7.1 General...................................................................................................................................................................................51

11.7.2 Direct calculation of e , upset pipe ..............................................................................................................52

11.8 Calculated coupling mass ............................................................................................................................................................52

11.8.1 General...................................................................................................................................................................................52

11.8.2 Calculated coupling mass for line pipe and round thread casing and tubing ..........52

11.8.3 Calculated coupling mass for buttress thread casing ....................................................................55

11.9 Calculated mass removed during threading ...............................................................................................................56

11.9.1 General...................................................................................................................................................................................56

11.9.2 Calculated mass removed during threading pipe or pin ends ...............................................56

11.9.3 Calculated mass removed during threading integral joint tubing box ends .............58

11.10 Calculated mass of upsets ...........................................................................................................................................................59

11.10.1 General...................................................................................................................................................................................59

11.10.2 Calculated mass of external upsets ...............................................................................................................59

11.10.3 Calculated mass of internal upsets ................................................................................................................60

11.10.4 Calculated mass of external-internal upsets .........................................................................................61

12 Elongation .................................................................................................................................................................................................................61

13 Flattening tests ....................................................................................................................................................................................................62

13.1 Flattening tests for casing and tubing ..............................................................................................................................62

iv © ISO 2018 – All rights reserved
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kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(E)

13.2 Flattening tests for line pipe.....................................................................................................................................................62

14 Hydrostatic test pressures ......................................................................................................................................................................63

14.1 Hydrostatic test pressures for plain-end pipe and integral joint tubing ............................................63

14.2 Hydrostatic test pressure for threaded and coupled pipe ..............................................................................64

15 Make-up torque for round thread casing and tubing ..................................................................................................64

16 Guided bend tests for submerged arc-welded line pipe...........................................................................................65

16.1 General ........................................................................................................................................................................................................65

16.2 Background .............................................................................................................................................................................................67

16.2.1 Values of ε ...................................................................................................................................................................67

eng

16.2.2 Values of A .................................................................................................................................................................67

gbtj

17 Determination of minimum impact specimen size for API couplings and pipe ..............................67

17.1 Critical thickness ................................................................................................................................................................................67

17.2 Calculated coupling blank thickness .................................................................................................................................68

17.3 Calculated wall thickness for transverse specimens ...........................................................................................71

17.4 Calculated wall thickness for longitudinal specimens .......................................................................................71

17.5 Minimum specimen size for API couplings .................................................................................................................71

17.6 Impact specimen size for pipe ................................................................................................................................................73

17.7 Larger size specimens ....................................................................................................................................................................73

17.8 Reference information ...................................................................................................................................................................74

Annex A (informative) Discussion of formulae for triaxial yield of pipe body ......................................................75

Annex B (informative) Discussion of formulae for ductile rupture ..................................................................................88

Annex C (informative) Rupture test procedure ..................................................................................................................................126

Annex D (informative) Discussion of formulae for fracture ..................................................................................................128

Annex E (informative) Discussion of historical collapse formulae ................................................................................135

Annex F (informative) Development of probabilistic collapse performance properties........................149

Annex G (informative) Calculation of design collapse strength from collapse test data .........................188

Annex H (informative) Calculation of design collapse strengths from production quality data.....191

Annex I (informative) Collapse test procedure ...................................................................................................................................205

Annex J (informative) Discussion of formulae for joint strength .....................................................................................211

Annex K (informative) Tables of calculated performance properties in SI units ............................................219

Annex L (informative) Tables of calculated performance properties in USC units .......................................221

Bibliography .........................................................................................................................................................................................................................223

© ISO 2018 – All rights reserved v
---------------------- Page: 7 ----------------------
kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(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 of the voluntary nature of standards, the meaning of ISO specific terms and

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

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

.org/iso/foreword .html.

This document was prepared by Technical Committee ISO/TC 67, Materials, equipment and offshore

structures for petroleum, petrochemical and natural gas industries, Subcommittee SC 5, Casing, tubing

and drill pipe.

This second edition cancels and replaces the first edition (ISO/TR 10400:2007), which has been

technically revised.

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

complete listing of these bodies can be found at www .iso .org/members .html.
vi © ISO 2018 – All rights reserved
---------------------- Page: 8 ----------------------
kSIST-TP FprCEN ISO/TR 10400:2021
ISO/TR 10400:2018(E)
Introduction

Performance design of tubulars for the petroleum and natural gas industries, whether it is formulated

by deterministic or probabilistic calculations, compares anticipated loads to which the tubular can

be subjected to the anticipated resistance of the tubular to each load. Either or both of the load and

resistance can be modified by a design factor.

Both deterministic and probabilistic approaches to performance properties are addressed in this

document. The deterministic approach uses specific geometric and material property values to calculate

a singl
...

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SIST
SIST EN ISO 13680:2020(Main)
Petroleum and natural gas industries - Corrosion-resistant alloy seamless tubular products for use as casing, tubing, coupling stock and accessory material - Technical delivery conditions (ISO 13680:2020)
EN ISO 13680:2020

This document specifies the technical delivery conditions for corrosion-resistant alloy seamless
tubular products for casing, tubing, coupling stock and accessory material (including coupling stock
and accessory material from bar) for two product specification levels:
— PSL-1, which is the basis of this document;
— PSL-2, which provides additional requirements for a product that is intended to be both corrosion
and cracking resistant for the environments and qualification method specified in Annex G and in
the ISO 15156 series.
At the option of the manufacturer, PSL-2 products can be provided in lieu of PSL-1.
NOTE 1 The corrosion-resistant alloys included in this document are special alloys in accordance with
ISO 4948-1 and ISO 4948-2.
NOTE 2 For the purpose of this document, NACE MR0175 is equivalent to the ISO 15156 series.
NOTE 3 Accessory products can be manufactured from coupling stock and tubular material, or from solid bar
stock or from bored and heat heat-treated bar stock as covered in Annex F.
This document contains no provisions relating to the connection of individual lengths of pipe.
This document contains provisions relating to marking of tubing and casing after threading.
This document is applicable to the following five groups of products:
a) group 1, which is composed of stainless alloys with a martensitic or martensitic/ferritic structure;
b) group 2, which is composed of stainless alloys with a ferritic-austenitic structure, such as duplex
and super-duplex stainless alloy;
c) group 3, which is composed of stainless alloys with an austenitic structure (iron base);
d) group 4, which is composed of nickel-based alloys with an austenitic structure (nickel base);
e) group 5, which is composed of bar only (Annex F) in age-hardened (AH) nickel-based alloys with
austenitic structure.
NOTE 4 Not all PSL-1 categories and grades can be made cracking resistant in accordance with the
ISO 15156 series and are, therefore, not included in PSL-2.

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SIST
SIST EN ISO 20321:2020(Main)
Petroleum, petrochemical and natural gas industries - Safety of machineries - Powered elevators (ISO 20321:2020)
EN ISO 20321:2020

This document specifies general safety requirements for the design, testing and production of powered elevators. The requirements are applicable for on- and off-shore applications of such elevators in the petroleum, petrochemical and natural gas industries.
This document does not cover any other type of elevator. It is not applicable to the following types of products: lifting nubbins, lifting plugs, lifting subs, internal gripping devices, equipment for lifting tubular from and onto a vessel. This list is not exclusive.

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SIST EN ISO 19905-3:2020(Main)
Petroleum and natural gas industries - Site-specific assessment of mobile offshore units - Part 3: Floating unit (ISO 19905-3:2017)
EN ISO 19905-3:2019

ISO 19905-3 specifies requirements and gives guidance for the site-specific assessment of mobile floating units for use in the petroleum and natural gas industries. It addresses the installed phase, at a specific site, of manned non-evacuated, manned evacuated and unmanned mobile floating units.
ISO 19905-3 addresses mobile floating units that are monohull (e.g. ship-shaped vessels or barges); column-stabilized, commonly referred to as semi-submersibles; or other hull forms (e.g. cylindrical/conical shaped). It is not applicable to tension leg platforms. Stationkeeping can be provided by a mooring system, a thruster assisted mooring system, or dynamic positioning. The function of the unit can be broad, including drilling, floatel, tender assist, etc. In situations where hydrocarbons are being produced, there can be additional requirements.
The requirements of ISO 19905-3 apply to the hull and stationkeeping system for all types of mobile units. The activity specific operating guideline document requirements can be modified to be appropriate to the situation being assessed.
ISO 19905-3 does not address all site considerations, and certain specific locations can require additional assessment.
ISO 19905-3 is applicable only to mobile floating units that are structurally sound and adequately maintained, which is normally demonstrated through holding a valid RCS classification certificate.
ISO 19905-3 does not address design, transportation to and from site, or installation and removal from site.
ISO 19905-3 sets out the requirements for site-specific assessments, but generally relies on other documents to supply the details of how the assessments are to be undertaken. In general:
- ISO 19901‑7 is referenced for the assessment of the stationkeeping system;
- ISO 19904‑1 is referenced to determine the metocean actions on the unit;
- ISO 19906 is referenced for arctic and cold regions;
- the hull structure and airgap are assessed by use of a comparison between the site-specific metocean conditions and its design conditions, as set out in the RCS approved operations manual;
- ISO 13624‑1 and ISO/TR 13624‑2[1] are referenced for the assessment of the marine drilling riser of mobile floating drilling units. Equivalent alternative methodologies can be used;
- IMCA M 220[5] is referenced for developing an activity specific operating guidelines. Agreed alternative methodologies can be used.
NOTE 1 The scope of ISO 19904‑1 specifically states that its requirements do not apply to mobile units, but the methodologies given for assessing metocean actions can be used.
NOTE 2 RCS rules and the IMO MODU code[4] provide guidance for design and general operation of mobile floating units.

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