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SIST EN ISO 10427-3:2005

(Main)

Petroleum and natural gas industries - Equipment for well cementing - Part 3: Performance testing of cementing float equipment (ISO 10427-3:2003)

Petroleum and natural gas industries - Equipment for well cementing - Part 3: Performance testing of cementing float equipment (ISO 10427-3:2003)

ISO 10427-3:2003 describes testing practices to evaluate the performance of cementing float equipment for the petroleum and natural gas industries.
ISO 10427-3:2003 is applicable to float equipment that will be in contact with water-based fluids used for drilling and cementing wells. It is not applicable to float equipment performance in non-water-based fluids.

Erdöl- und Erdgasindustrie - Ausrüstungen für die Bohrloch-Zementierung - Teil 3: Festigkeitsprüfung der Zementierung schwimmender Ausrüstungen (ISO 10427-3:2003)

Industries du pétrole et du gaz naturel - Equipement de cimentation de puits - Partie 3: Essais de performance des équipements de cimentation des cuvelages (ISO 10427-3:2003)

L'ISO 10427-3:2003 décrit les méthodes d'essai permettant d'évaluer les performances des équipements de cimentation des cuvelages pour les industries du pétrole et du gaz naturel.
L'ISO 10427-3:2003 s'applique aux équipements des cuvelages en contact avec les fluides à base d'eau utilisés pour le forage et la cimentation des puits. Elle ne s'applique pas aux performances des équipements des cuvelages utilisés avec des fluides non à base d'eau.

Industrija za predelavo nafte in zemeljskega plina – Oprema za cementiranje vrtin – 3. del: Preskušanje lastnosti opreme za cementiranje plavajočih struktur (ISO 10427-3:2003)

General Information

Status
Published
Publication Date
28-Feb-2005
ICS
75.180.10 - Exploratory, drilling and extraction equipment
Technical Committee
I13 - Imaginarni 13
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
01-Mar-2005
Due Date
01-Mar-2005
Completion Date
01-Mar-2005
Ref Project
EN ISO 10427-3:2004 - Petroleum and natural gas industries - Equipment for well cementing - Part 3: Performance testing of cementing float equipment (ISO 10427-3:2003)

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SLOVENSKI STANDARD
SIST EN ISO 10427-3:2005
01-marec-2005
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GHO3UHVNXãDQMHODVWQRVWLRSUHPH]DFHPHQWLUDQMHSODYDMRþLKVWUXNWXU ,62

Petroleum and natural gas industries - Equipment for well cementing - Part 3:
Performance testing of cementing float equipment (ISO 10427-3:2003)
Erdöl- und Erdgasindustrie - Ausrüstungen für die Bohrloch-Zementierung - Teil 3:
Festigkeitsprüfung der Zementierung schwimmender Ausrüstungen (ISO 10427-3:2003)
Industries du pétrole et du gaz naturel - Equipement de cimentation de puits - Partie 3:
Essais de performance des équipements de cimentation des cuvelages (ISO 10427-
3:2003)
Ta slovenski standard je istoveten z: EN ISO 10427-3:2004
ICS:
75.180.10 Oprema za raziskovanje in Exploratory and extraction
odkopavanje equipment
SIST EN ISO 10427-3:2005 en,fr
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN ISO 10427-3:2005

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SIST EN ISO 10427-3:2005
EUROPEAN STANDARD
EN ISO 10427-3
NORME EUROPÉENNE
EUROPÄISCHE NORM
October 2004
ICS 75.180.10

English version
Petroleum and natural gas industries - Equipment for well
cementing - Part 3: Performance testing of cementing float
equipment (ISO 10427-3:2003)
Industries du pétrole et du gaz naturel - Equipement de Erdöl- und Erdgasindustrie - Ausrüstungen für die Bohrlock-
cimentation de puits - Partie 3: Essais de performance des Zementierung - Teil 3: Festigkeitsprüfung der Zementierung
équipements de cimentation des cuvelages (ISO 10427- schwimmender Ausrüstungen (ISO 10427-3:2003)
3:2003)
This European Standard was approved by CEN on 30 September 2004.
CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European
Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national
standards may be obtained on application to the Central Secretariat or to any CEN member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by translation
under the responsibility of a CEN member into its own language and notified to the Central Secretariat has the same status as the official
versions.
CEN members are the national standards bodies of Austria, Belgium, Cyprus, Czech Republic, Denmark, Estonia, Finland, France,
Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Slovakia,
Slovenia, Spain, Sweden, Switzerland and United Kingdom.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION
EUROPÄISCHES KOMITEE FÜR NORMUNG
Management Centre: rue de Stassart, 36  B-1050 Brussels
© 2004 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN ISO 10427-3:2004: E
worldwide for CEN national Members.

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SIST EN ISO 10427-3:2005
EN ISO 10427-3:2004 (E)






Foreword



The text of ISO 10427-3:2003 has been prepared by Technical Committee ISO/TC 67
"Materials, equipment and offshore structures for petroleum and natural gas industries" of the
International Organization for Standardization (ISO) and has been taken over as EN ISO 10427-
3:2004 by Technical Committee CEN/TC 12 "Materials, equipment and offshore structures for
petroleum and natural gas industries" the secretariat of which is held by AFNOR.

This European Standard shall be given the status of a national standard, either by publication of
an identical text or by endorsement, at the latest by April 2005, and conflicting national
standards shall be withdrawn at the latest by April 2005.

According to the CEN/CENELEC Internal Regulations, the national standards organizations of
the following countries are bound to implement this European Standard: Austria, Belgium,
Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary,
Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland,
Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.



Endorsement notice

The text of ISO 10427-3:2003 has been approved by CEN as EN ISO 10427-3:2004 without any
modifications.

2

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SIST EN ISO 10427-3:2005


INTERNATIONAL ISO
STANDARD 10427-3
First edition
2003-04-01


Petroleum and natural gas industries —
Equipment for well cementing —
Part 3:
Performance testing of cementing float
equipment
Industries du pétrole et du gaz naturel — Matériel pour la cimentation
des puits —
Partie 3: Mode opératoire des tests des équipements de cimentation
des cuvelages




Reference number
ISO 10427-3:2003(E)
©
ISO 2003

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(E)
PDF disclaimer
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©  ISO 2003
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 either ISO at the address below or
ISO's member body in the country of the requester.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Published in Switzerland

ii © ISO 2003 — All rights reserved

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(E)
Contents Page
Foreword. iv
Introduction . v
1 Scope. 1
2 Functions of cementing float equipment. 1
3 Float equipment performance criteria . 2
3.1 General. 2
3.2 Durability under downhole conditions . 2
3.3 Differential pressure capability from below . 2
3.4 Ability to withstand force exerted through cementing plugs from above . 2
3.5 Drillability of the equipment. 2
3.6 Ability to pass lost circulation materials . 2
3.7 Flow coefficient of the valve . 2
3.8 Reverse-flow resistance of casing fill-up valves . 2
4 Apparatus and materials. 3
4.1 Flow loop. 3
4.2 Circulating test fluid . 4
4.3 High-temperature/high-pressure test cell. 5
5 Durability test. 7
5.1 Test set-up. 7
5.2 Test categories. 7
5.3 Procedure. 8
6 Static high-temperature/high-pressure test . 8
6.1 Test categories. 8
6.2 Procedure. 9
7 Test results. 9
Annex A (informative) Results of performance tests on cementing float equipment . 10
Bibliography . 11



© ISO 2003 — All rights reserved iii

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(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 2.
The main task of technical committees is to prepare International Standards. 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.
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.
ISO 10427-3 was prepared by Technical Committee ISO/TC 67, Materials, equipment and offshore structures
for petroleum, petrochemical and natural gas industries, Subcommittee SC 3, Drilling and completion fluids,
and well cements.
This first edition cancels and replaces the first edition of ISO 18165, which has undergone an ISO number
change and a minor revision.
ISO 10427 consists of the following parts, under the general title Petroleum and natural gas industries —
Equipment for well cementing:
 Part 1: Casing bow-spring centralizers
 Part 2: Centralizer placement and stop-collar testing
 Part 3: Performance testing of cementing float equipment
iv © ISO 2003 — All rights reserved

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(E)
Introduction
This part of ISO 10427 is based on API Recommended Practice 10F, second edition, November, 1995.
Users of this part of ISO 10427 should be aware that further or differing requirements may be needed for
individual applications. This part of ISO 10427 is not intended to inhibit a vendor from offering, or the
purchaser from accepting, alternative equipment or engineering solutions for the individual application. This
may be particularly applicable where there is innovative or developing technology. Where an alternative is
offered, the vendor should identify any variations from this part of ISO 10427 and provide details.
In this part of ISO 10427, where practical, U.S. Customary units are included in brackets for information.

© ISO 2003 — All rights reserved v

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SIST EN ISO 10427-3:2005

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SIST EN ISO 10427-3:2005
INTERNATIONAL STANDARD ISO 10427-3:2003(E)

Petroleum and natural gas industries — Equipment for well
cementing —
Part 3:
Performance testing of cementing float equipment
1 Scope
This part of ISO 10427 describes testing practices to evaluate the performance of cementing float equipment
for the petroleum and natural gas industries.
This part of ISO 10427 is applicable to float equipment that will be in contact with water-based fluids used for
drilling and cementing wells. It is not applicable to float equipment performance in non-water-based fluids.
2 Functions of cementing float equipment
The term “cementing float equipment” refers to one or more check valves incorporated into a well casing string
that prevent fluid flow up the casing while allowing fluid flow down the casing. The primary purpose of
cementing float equipment is to prevent cement that has been placed in the casing/wellbore annulus from
flowing up the casing (U-tubing). In some cases, such as liner cementing, float equipment may be the only
practical means of preventing U-tubing. In other cases, the float equipment serves to allow the cement to set
in the annulus without having to increase the pressure inside the casing to prevent U-tubing. Increased
pressure in the casing while cement sets is generally undesirable because it can result in gaps (micro-annuli)
in the cemented annulus.
Float equipment is also sometimes used for the purpose of lessening the load on the drilling rig. Since float
equipment blocks fluid flow up the casing, the buoyant force acting on casing run with float equipment is
greater than the buoyant force acting on casing run without float equipment. If either the height or the density
of the fluid placed inside casing equipped with float equipment while the casing is being run is less than that of
the fluid outside the casing, the suspended weight of the casing is reduced compared with what it would be
without the float equipment.
The ability of float equipment to prevent fluid flow up the casing is also important in certain well control
situations. If the hydrostatic pressure of the fluid inside the casing becomes less than the pressure of
formation fluids in formations near the bottom of the casing, fluids from the well may try to flow up the casing.
In such a situation, the float equipment becomes a primary well control device.
Float equipment is also sometimes used as a device to assist in pressure testing of casing. This is normally
done by landing one or more cementing plugs on top of the float equipment assembly. The plugs seal the
casing so that the pressure integrity of the casing may be tested.
Float equipment is also used by some operators as a device to lessen the free fall of cement inside the casing.
The free fall of cement is the tendency of cement to initially fall due to the density differences between the
cement and the fluid in the well. The float equipment lessens the free fall, to some extent, by providing a
constriction in the flow path.
Casing fill-up float equipment is a special type of float equipment that allows the casing to fill from the bottom
as the casing is run. This is desirable, in some cases, to help reduce pressure surges as the casing is lowered.
Fill-up type float equipment also helps ensure that the collapse pressure of the casing is not exceeded. Once
the casing is run, the check valve mechanism of fill-up type float equipment is activated. This is normally done
by either pumping a surface-released ball through the equipment or by circulating above a certain rate.
© ISO 2003 — All rights reserved 1

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(E)
3 Float equipment performance criteria
3.1 General
There are a number of performance criteria, listed below, that may be used to evaluate the suitability of a
particular piece of float equipment for a given well.
3.2 Durability under downhole conditions
Float equipment should still function after a fluid containing abrasive solids has been circulated through the
equipment for a period of time. The equipment should function in various orientations and while exposed to
elevated temperatures and pressures.
3.3 Differential pressure capability from below
Float equipment should be capable of withstanding a differential pressure with the higher pressure being
exerted from below the check valve, because the hydrostatic pressure of the fluid occupying the annulus
immediately after the cement has been placed is usually greater than the hydrostatic pressure of the
corresponding column of fluid inside the casing, or while the casing is being run.
3.4 Ability to withstand force exerted through cementing plugs from above
Float equipment should be able to withstand a force exerted through cementing plugs from above. Some
operators occasionally pressure-test the casing by increasing the pressure shortly after a cementing plug (top
plug) used to separate the cement from the displacement fluid has landed downhole. This can cause a force
to be applied to the float equipment that could cause the equipment to fail.
3.5 Drillability of the equipment
Float equipment should be easy to drill through, since in many cases, float equipment must be drilled out after
cementing.
3.6 Ability to pass lost circulation materials
Float equipment may be required to allow easy passage of lost circulation material (LCM). On occasion, the
fluid that is circulated through cementing float equipment contains LCM designed to bridge on highly
permeable, vugular or fractured formations to lessen the amount of fluid that is lost to the formations. Since
float equipment generally provides a constricted flow area for fluid passage, there can be a tendency for the
LCM to bridge on the float equipment valve and partially or totally block fluid circulation. Therefore, the ease
with which the LCM can pass through the float equipment may be a performance criterion for some wells.
3.7 Flow coefficient of the valve
Since float equipment provides a constriction in the flow path, there will be a pressure loss associated with
circulating fluid through the float valve. If the pressure loss through the float equipment is too high, circulation
rates can be limited. In some cases, however, a large pressure loss is desirable to reduce free fall of the
cement. The flow coefficient of the valve provides a means of estimating the pressure loss for a given fluid
density and a given rate.
3.8 Reverse-flow resistance of casing fill-up valves
One of the functions of casing fill-up float equipment is to reduce pressure surges as the casing is run by
allowing flow into the casing from the bottom. Therefore, the resistance of the valve to reverse flow is
indicative of the relative performance of the valve in reducing surge pressure.
2 © ISO 2003 — All rights reserved

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SIST EN ISO 10427-3:2005
ISO 10427-3:2003(E)
4 Apparatus and materials
4.1 Flow loop
4.1.1 General
Figure 1 shows a diagram of one possible configuration of a flow loop for durability testing. Other
configurations are possible. The major components of the loop are the mud tank, the piping network, the
pump and the instrumentation. These components are discussed in the following paragraphs.

Key
1 hopper 8 flow meter
2 compartment 1 9 LP safety valve
3 agitator 10 pressure transducer
4 compartment 2 11 hose
5 mud tank 12 float collar
6 temperature probe 13
...

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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, marine surface waves, electrical resistivity imaging and electromagnetic imaging.

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

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

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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SIST
SIST 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)
EN ISO 18797-2:2021

This document specifies the selection criteria and minimum requirements for protective coating systems for field maintenance and repair of risers exposed to conditions in the splash zone.
This document does not cover the selection of techniques and materials used to restore integrity of the risers to be coated.
This document neither covers the selection of additional mechanical protective materials that are not part of the described coating systems included in this document.

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SIST-TP 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)
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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