packers and bridge plugs - api...

This document is not an API Standard; it is under consideration within an API technical committee but has not received all approvals required to become an API Standard. It shall not be reproduced or circulated or quoted, in whole or in part, outside of API committee activities except with the approval of the Chairman of the committee having jurisdiction and staff of the API Standards Dept. Copyright API. All rights reserved.

Packers and Bridge Plugs

API SPECIFICATION 11D1 FOURTH EDITION, XXXXXX 201X

Ballot Version November 2019


Special Notes

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Copyright © 2015 American Petroleum Institute


iii

Foreword

Nothing contained in any API publication is to be construed as granting any right, by implication or otherwise, for the manufacture, sale, or use of any method, apparatus, or product covered by letters patent. Neither should anything contained in the publication be construed as insuring anyone against liability for infringement of letters patent.

This document was produced under API standardization procedures that ensure appropriate notification and participation in the developmental process and is designated as an API standard. Questions concerning the interpretation of the content of this publication or comments and questions concerning the procedures under which this publication was developed should be directed in writing to the Director of Standards, American Petroleum Institute, 200 Massachusetts Ave. NW, Washington, DC 20001. Requests for permission to reproduce or translate all or any part of the material published herein should also be addressed to the director.

Generally, API standards are reviewed and revised, reaffirmed, or withdrawn at least every five years. A one-time extension of up to two years may be added to this review cycle. Status of the publication can be ascertained from the API Standards Department, telephone (202) 682-8000. A catalog of API publications and materials is published annually by API, 200 Massachusetts Ave. NW, Washington, DC 20001.

Suggested revisions are invited and should be submitted to the Standards Department, API, 200 Massachusetts Ave. NW, Washington, DC 20001, [email protected].


v

Contents page

Table of Contents will be generated with Final Page Proofs.


vi

Introduction

This specification has been developed by users/purchasers and suppliers/manufacturers of packers and bridge plugs and is intended for use in the petroleum and natural gas industry worldwide to give requirements and information to both parties in the selection, manufacture, testing and use. Further, this specification addresses the minimum requirements with which that the supplier/manufacturer is to comply to claim conformity with this specification.

This specification has been structured with grades of increased requirements in design validation and levels in quality control. These grades/levels allow the user/purchaser to select the grade/level required for a specific application.

There are three quality levels: Quality level QL3 is the minimum level of quality offered by this product standard. Quality level QL2 provides additional inspection and verification steps. Quality level QL1 is the highest level provided. Additional quality requirements may be specified by the user/purchaser as supplemental requirements.

There are nine design-validation grades (V0-H to V6) to provide the user/purchaser the choice of requirements to meet a specific preference or application. Design validation grade V6 is the minimum grade and represents equipment where the validation method has been defined by the supplier/manufacturer. V0-H and V3-H are for HPHT applications. The complexity and severity of the validation testing increases as the grade number decreases.

This edition now includes annexes with requirements for validation of hydrostatically set products (Annex E), determining text fixture ID (Annex F), and tubing-to-packer forces and rated performance envelopes (Annex G).

The International System of Units (SI) is used in this specification; however, US Customary (USC) or other units are also shown for reference.

It is necessary that users of this specification be aware that requirements beyond those outlined in this International Standard can be needed for individual applications. This specification is not intended to inhibit a supplier/manufacturer from offering, or the user/purchaser from accepting, alternative equipment or engineering solutions. This can be particularly applicable where there is innovative or developing technology.


1

Packers and Bridge Plugs

1 Scope

This specification provides requirements and guidelines for packers and bridge plugs as defined herein for use in the petroleum and natural gas industry. This specification provides requirements for the functional specification and technical specification, including design, design verification and validation, materials, documentation and data control, repair, shipment, and storage.

Products covered by this specification apply only to applications within casing or tubing. Products covered by other API specifications, such as API 19OH or 19LH, are not covered by this specification. Installation and maintenance of these products are outside the scope of this specification.

Within this specification the term product is used to indicate both packers and bridge plugs.

This specification includes the following annexes:

— Annex A: Use of API Monogram by Licensees;

— Annex B Requirements for HPHT Environment Equipment;

— Annex C: Requirements for HPHT Environment Operational Tools;

— Annex D: External Flow Testing Requirements;

— Annex E: Validation of Maximum Initiation Pressure for Hydrostatically Set Products;

— Annex F: Determining Test Fixture ID;

— Annex G: Tubing-To-Packer Forces and Rated Performance Envelopes

2 Normative References

The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.

API Spec 5CT, Casing and Tubing

API Spec 20A, Carbon Steel, Alloy Steel, Stainless Steel, and Nickel Base Alloy Castings for Use in the Petroleum and Natural Gas Industry, 1st Edition

API Spec Q1, Specification for Quality Management System Requirements for Manufacturing Organizations for the Petroleum and Natural Gas Industry

ANSI/NACE MR0175/ISO 151561, Petroleum and natural gas industries-Materials for use in H2S- containing environments in oil and gas production

1 American National Standards Institute, 25 West 43rd Street, 4th Floor, New York, New York 10036, www.ansi.org.


ASME Boiler and Pressure Vessel Code 2, Section VIII, Division 1, 2019 Edition

ASME Boiler and Pressure Vessel Code, Section VIII, Division 2, 2019 Edition

ASME Boiler and Pressure Vessel Code, Section VIII, Division 3, 2019 Edition

ASME Boiler and Pressure Vessel Code, Section V, Nondestructive Examination

ASME, Boiler and Pressure Vessel Code, Section IX, Welding and Brazing Qualifications

ASNT RP SNT-TC-1A, Personnel Qualification and Certification in Nondestructive Testing

ASTM D297 3, Standard Test Methods for Rubber Products-Chemical Analysis

ASTM D395, Standard Test Methods for Rubber Property—Compression Set

ASTM D412, Standard Test Methods for Vulcanized Rubber and Thermoplastic Elastomers - Tension

ASTM D429, Standard Test Methods for Rubber Property—Adhesion to Rigid Substrates

ASTM D638, Standard Test Method for Tensile Properties of Plastics

ASTM D790, Standard Test Methods for Flexural Properties of Unreinforced and Reinforced Plastics and Electrical Insulating Materials

ASTM D1414, Standard Test Methods for Rubber O-Rings

ASTM D1415, Standard Test Method for Rubber Property—International Hardness

ASTM D1708, Standard Test Method for Tensile Properties of Plastics by Use of Micro-tensile Specimens

ASTM D2240, Standard Test Method for Rubber Property—Durometer Hardness

ASTM D2990, Standard Test Methods for Tensile, Compressive, and Flexural Creep and Creep-Rupture of Plastics

ASTM D7028, Standard Test Method for Glass Transition Temperature (DMA Tg) of Polymer Matrix Composites by Dynamic Mechanical Analysis (DMA)

ASTM D7426, Standard Test Method for Assignment of the DSC Procedure for Determining Tg of a Polymer or an Elastomeric Compound

ASTM E21, Standard test methods for elevated temperature tension tests of metallic materials

ASTM E94, Standard Guide for Radiographic Examination

2 ASME International, 2 Park Avenue, New York, New York 10016-5990, www.asme.org. 3 ASTM International, 100 Barr Harbor Drive, West Conshohocken, Pennsylvania 19428, www.astm.org.


ASTM E165, Standard Test Method for Liquid Penetrant Examination

ASTM E709, Standard Guide for Magnetic Particle Testing

ISO 2859-1 4, Sampling procedures for inspection by attributes—Part 1: Sampling schemes indexed by acceptance quality limit (AQL) for lot-by-lot inspection

ISO 3601-1, Fluid power systems—O-rings—Part 1: Inside diameters, cross-sections, tolerances and designation codes

ISO 3601-3, Fluid power systems—O-rings—Part 3: Quality acceptance criteria

ISO 9712, Non-destructive testing—Qualification and certification of personnel

ISO 11357-2, Plastics—Differential Scanning Calorimetry (DSC) —Part 2: Determination of Glass Transition Temperature and Glass Transition Step Height

ISO 10893-5, Magnetic particle inspection of seamless and welded ferromagnetic steel tubes for the detection of surface imperfections

ISO 23936-2:2011, Petroleum, petrochemical and natural gas industries—Non-metallic materials in contact with media related to oil and gas production – Part 2: Elastomers

3 Terms and Definitions

For the purposes of this document, the following terms and definitions apply.

3.1 assembly Product comprised of more than one component.

3.2 bridge plug Mechanical device, with packing element, used for blocking fluid (liquid or gas) communication in casing or tubing.

3.3 casing Pipe run from the surface and intended to line the walls of a drilled well.

NOTE Casing, which does not extend to the surface is a liner.

3.4 casing size tubing size

4 International Organization for Standardization, 1, ch. de la Voie-Creuse, Case postale 56, CH-1211, Geneva 20,

Switzerland, www.iso.org.


Nominal casing or tubing outside diameter (OD).

3.5 component Individual part of an assembly.

3.6 design margin Ratio of the material minimum yield stress divided by the actual design stress in a component at the rated conditions.

3.7 design validation Process of proving a design by testing to demonstrate conformity of the product to design requirements.

3.8 design verification Process of examining the result of a given design or development activity to determine conformity with specified requirements.

3.9 drift diameter Minimum inside diameter (ID) of the product, expressed as the OD of the drift bar utilized during assembly inspection, as outlined in 7.4.13.

3.10 end connection Thread or other mechanism connecting the product to the casing or tubing.

3.11 exposed component Flow-wetted component, internally wetted component, and/or component contacted by well fluid below the packing element.

3.12 flow-wetted component Component that comes in direct contact with the dynamic movement of well fluids in the flow stream.

3.13 internally wetted component Flow-wetted component and any component out of the flow stream, but contacted by well fluids through a port or other passage to the flow-wetted area.

3.14 job-lot Batch of material or components that have undergone the same process or series of processes.

3.15 manufacturing Process and actions performed by an equipment supplier/manufacturer that are necessary to provide finished component(s), assemblies and related documentation that fulfil the requests of the user/purchaser and meet the standards of the supplier/manufacturer.


3.16 NACE service Service for products whose type 1 components are manufactured from metallic materials that comply with material requirements of the applicable section(s) of ANSI/NACE MR0175/ISO 15156.

3.17 packer Mechanical device with a packing element, used for blocking fluid (liquid or gas) communication through the annular space between casing and tubing by sealing off the space between them.

3.18 packing element Seal on the product that blocks fluid communication by sealing on the ID of the casing or tubing.

3.19 performance envelope Graph that illustrates the combined effects of differential pressure and axial loads on a product at the rated temperature.

3.20 permanent packer permanent bridge plug Bridge plug or packer that has no design feature for intact retrieval or repositioning.

3.21 pressure reversal Change in the direction of the pressure differential across the packing element from above to below or vice versa.

3.22 product family A group of assemblies where the design principles for the geometry, materials, and functionality are the same.

3.23 qualified person Individual with characteristics or abilities gained through training or experience, or both, as measured against established requirements, such as standards or tests that enable the individual to perform a required function effectively.

3.24 repositionable packer repositionable bridge plug Bridge plug or packer that meets the definition of retrievable packer (retrievable bridge plug) and has a design feature facilitating its relocation (without retrieval) while re-establishing its intended function.

3.25 retrievable packer retrievable bridge plug Bridge plug or packer that has a design feature facilitating its retrieval substantially intact.


3.26 seal Device providing a barrier to the passage of liquid and/or gas.

3.27 seal diameter The supplier/manufacturer defined diameter used to calculate hydraulically-induced loads on the product. NOTE: Annex G provides information on the use of seal diameters in calculations.

3.28 shear device Component designed to disconnect under a predetermined load.

3.29 standard service Service for products whose components are not required to comply with material requirements of the applicable section(s) of ANSI/NACE MR0175/ISO 15156.

3.30 stress factor Ratio of the calculated stress to the minimum yield strength of the material at the rated conditions.

3.31 substantive design change Change to the design, identified by the supplier/manufacturer that affects the performance of the product in the intended service condition.

3.32 temperature-cycle range Specified amount of temperature change within the product’s temperature range over which the product is designed to operate.

NOTE The temperature-cycle range is validated for V3, V1, V0, V0-H and V3-H and is applicable anywhere within the product’s temperature range, see 6.3.4.2.

3.33 temperature range Specified range of minimum and maximum temperatures over which the product is designed to operate.

3.34 tubing Pipe placed in a well to produce or inject fluids.

3.35 type 1 component type 1 weld Metallic component or weld that isolates pressure and/or is loaded in tension as the result of axial loads on the product during run-in, setting, service, or retrieval.


3.36 type 2 component type 2 weld Metallic component or weld that does not meet the criteria of a type 1 component or weld.

4 Acronyms, Abbreviations, and Symbols

AQL Acceptance quality limit

COC Certificate of compliance

FEA Finite Element Analysis

FMEA Failure Modes and Effects Analysis

HPHT High pressure high temperature

ID Inside diameter

L Length

MTR Material test report

NACE National Association of Corrosion Engineers

NDE Non-destructive examination

OD Outside diameter

QC Quality control

RGD Rapid gas decompression

t Thickness

5 Functional Specification

5.1 General

The user/purchaser shall prepare a functional specification for ordering products that conform to this specification and specify the following requirements and operating conditions, as applicable, and/or identify the supplier’s/manufacturer’s specific product. These requirements and operating conditions may be conveyed by means of a dimensional drawing, data sheet or other suitable documentation.

NOTE The supplier/manufacturer can generate internal requirements for products as the user/purchaser

5.2 Type Description

The user/purchaser should specify, as applicable, the following type:

— permanent packer or bridge plug,


— retrievable packer or bridge plug, or

— repositionable packer or bridge plug.

5.3 Well Parameters

The user/purchaser should specify, as applicable, the following well parameters:

— Dimensions, material, grade of the casing and/or tubing;

— end connections above/below the product;

— well angle from the vertical at the setting position of the product;

— deviations, dog-leg severity, and restrictions through which the product is required to pass;

— size, type, and configuration of other products and tubulars used in connection with this product;

— other lines (electrical/hydraulic) that are required to pass through or bypass the packer;

— internal receptacle profile(s), bore dimensions(s), outside diameter, inside diameter, and the respective locations;

— expected minimum and maximum values of production/injection pressures, pressure differentials, temperatures, changes in temperatures, and flow rates;

— any other relevant well parameter(s).

NOTE 1 A well schematic may be useful to identify many well parameters and related well equipment.

NOTE 2 Annex G includes information on sealing areas and pressure induced loads.

5.4 Operational Parameters

The user/purchaser should specify, as applicable, any of the following operational parameters:

— installation method, including conveyance method, such as; tubing, wireline, tractor, or coil tubing;

— setting method and allowable pressures during setting;

— anticipated running/pulling speed(s);

— setting depth;

— retrieving or repositioning method and number of repositioning’s, if applicable;

— anticipated loading conditions, applied to the product prior to and during setting, during use, and during retrieving, including combined loading (pressure, tension/compression, torque) and loading due to perforating events; expected setting temperature and anticipated temperature cycle during well operations;


— size, type, and configuration of devices, service tools, or well servicing activities that will interface with or run through the product;

— flow rates, exposure time, and composition of fluids flowing across or exposed to the packing element;

— well stimulation operations, including its parameters, such as acidizing (composition of the acid and acid returns), the pressure, the temperature, the acid flow rate and the exposure time, and other chemicals used during the stimulation;

— well cementing operations, including its parameters, such as cement types and volumes, spacers, plugs, pressure, flow rates, and top of cement;

— sand consolidation and fracturing operations, including sand/proppant description and volume, fluid flow rate, proppant/fluid ratio or sand/fluid ratio, chemical composition, pressure, and temperature;

— intended removal and/or milling operations;

— service life;

— any other relevant operational parameters.

5.5 Environmental Compatibility

General

If the user/purchaser has access to the corrosion property data of the operating environment based on historical data and/or research, he shall state to the supplier/manufacturer which material(s), metals or non-metals, has/have the ability to perform as required within the corrosion environment per the requirements of 5.5.3, as applicable. Otherwise, material compatibility shall be specified according to 5.5.2.

Well Environment

The user/purchaser should specify, as applicable, any of the following well environment parameters:

a) completion and packer fluid composition, pH, and existence of bromides (Zn, Ca, Na), formates (Cs, K, Na), chlorides (K, Ca, Na), acetates (Cs);

b) mud type, mud density, and pH;

c) aromatic and aliphatic solvents where present (type/amount);

d) inhibitor treatments (type, concentration, and pH);

— oxygen scavenger systems;

— emulsifier systems;

— continuous or batch treatment;


— chemical composition of fluid exposures;

— duration and temperature of exposure;

— details of injected fluids where applicable.

e) For production service, provide comment on produced fluids such as oil, gas, water, water cut, con-centrations of CO2, H2S. For injection service, provide comment on injected fluids such as water, pH, inhibitors, oxygen levels

In cases where the user/purchaser has access to historical data and/or research which is applicable to the functional specification, the user/purchaser should state to the supplier/manufacturer which material(s) has the ability to perform as required within a similar environment.

Material Designation

5.5.3.1 If the user/purchaser chooses to specify a service environment for metallic materials, the following designations may be used:

— standard service;

— NACE service.

5.5.3.2 Metallic material selection may be made for a group of components using the following designa-tions:

— flow-wetted components;

— internally wetted components;

— exposed components;

— other components.

5.6 Design Validation

The user/purchaser shall specify the required design validation grade. This specification provides seven standard design validation grades (V6 to V0), as defined in 6.5. Additionally, HPHT design validation grades V0-H and V3-H are provided in Annex B and may be selected by the user/purchaser.

5.7 Quality Control

The user/purchaser shall specify the required quality level. This specification provides three quality levels (QL3, QL2, and QL1) of quality control, as defined in 7.4.


6 Technical Specification

6.1 General

The supplier/manufacturer shall prepare a technical specification that conforms to the requirements defined in the functional specification. If the technical specification does not fully meet the functional requirements, the supplier/manufacturer shall identify the differences to the user/purchaser. The supplier/manufacturer shall also provide the user/purchaser with the product data sheet, as detailed in 7.2.3.

6.2 Technical Characteristics

The following criteria shall be met:

a) The product shall set and seal in the tubing or casing, without the need for a designed receptacle or profile, and remain set until the product is removed or retrieved. Exceptions to this are the effects of casing or tubing failure.

b) While set and in service, the product shall perform in accordance with the supplier/manufacturers technical specification.

c) Where applicable, the product shall not compromise well intervention operations.

6.3 Design Requirements

General

Products manufactured according to this specification shall be designed and developed in conformance with API Specification Q1.

Products conforming to this specification shall be manufactured to drawings and specifications that are substantially the same as those of the same size, type and model product that was validated.

Design Documentation

Design of products manufactured to this specification shall include documentation of those designs. This documentation shall include, as applicable; design requirements, assumptions, analysis methods, comparison with previous designs or operating history of similar products, calculations, manufacturing drawings and specifications, design reviews, and/or physical testing results (such as design validation testing).

Materials

6.3.3.1 General

Materials and/or the service being provided shall be stated by the supplier/manufacturer and shall be suitable for the service environment specified in the functional specification. The supplier/manufacturer shall have documented specifications for all materials, and all materials used shall comply with the supplier’s/manufacturer’s documented specifications. Materials specifications and/or procedures shall be approved by a qualified person.


All components/materials used in tested or delivered equipment, except common hardware that do not affect the performance, (such as; nuts, bolts, set screws and spacers), shall be verified as conforming to documented requirements.

The user/purchaser may specify materials for the specific use and corrosion environment in the functional specification. For use in H2S-containing service and when required by user/purchaser as per Section 5.5.3; metallic materials shall conform to ANSI/NACE MR0175/ISO 15156 as applicable to the defined service environment (Section 5.5.2). If the supplier/manufacturer proposes to use another material, the supplier/manufacturer shall state that this material has performance characteristics suitable for all parameters specified in the Well Environment (Section 5.5.2).

6.3.3.2 Metals

Specifications

The supplier's/manufacturer's specifications shall define the following:

a) chemical composition limits;

b) material condition;

NOTE Material condition could include heat treatment, cold working, etc.

c) mechanical property limits, as applicable:

1) tensile strength;

2) yield strength;

3) elongation;

4) hardness;

5) Charpy impact toughness.

Table 1 – Parameters for Metals

Parameter Specification

Tensile strength ASTM A370

Yield strength ASTM A370

Elongation ASTM A370

Hardness ASTM E10, ASTM E18

Charpy impact toughness ASTM A370


Mechanical Testing

When mechanical testing is required by the user/purchaser, the test sample shall be from the same heat of material and experience the same thermomechanical processing along with the raw material used to manufacture the component it qualifies.

NOTE Test sample may be a sacrificial test piece or prolongation.

NOTE If remelted the same heat refers to the remelted heat.

Heat Treatment

The heat treatment process parameters shall be defined in a heat treatment procedure. Hardness testing is the only mechanical property test required after stress relieving.

NOTE API 20H provides general guidance for batch heat treating process qualification.

6.3.3.3 Non-metals

General

The supplier’s/manufacturer’s documented specifications for non-metallic compounds shall include handling, storage, and labelling requirements, including the cure date, batch number, compound identification and shelf life, appropriate to each compound, and shall define those characteristics critical to the performance. For packing elements, tensile strength and hardness shall be included in the specification. When included on the specification, properties including acceptance criteria, shall be determined by the specifications listed in Tables 2 for elastomers and Table 3 for thermoplastics or by an equivalent international standard. The specification shall state if the parameters are measured on actual components.

Table 2—Parameters for Elastomeric Materials

Parameter, as applicable Specification, or equivalent

Tensile strength ASTM D1414 or ASTM D412

Tensile modulus ASTM D1414 or ASTM D412

Elongation ASTM D1414 or ASTM D412

Compression set ASTM D395 or ASTM D1414

Density ASTM D297

Hardness ASTM D2240 or ASTM D1415

Table 3—Parameters for Thermoplastic Materials

Parameter, as applicable Specification, or equivalent

Tensile strength (at either break or yield as applicable)

ASTM D638 or D1708


Elongation (at either break or yield as applicable)

ASTM D638 or D1708

Hardness ASTM D2240

Compound Selection

The supplier/manufacturer shall have a documented procedure that provides for the selection of non-metallic material types and the specific compounds as approved to the supplier’s/manufacturer’s specification(s) for use in product designs.

The documented procedure(s) shall, as a minimum, address

a) functional requirements;

b) technical specifications;

c) material type and compound history of use;

d) geometric component design;

e) chemical stability of materials in well fluids.

Records of material type and compound selection shall become a portion of the design documentation (see 7.2).

Bond Strength Validations

For component designs where the bond strength of a non-metallic material to a substrate is integral to performance, the acceptance criteria shall be defined and the strength of the bonding interface shall be validated with a representative bond test. The bond test for elastic materials shall conform to the require-ments of ASTM D429 or an equivalent supplier/manufacturer referenced testing program that includes measured acceptance criteria.

Environmental Evaluation of Non-Metallic Materials

If required by the user/purchaser, non-metallic materials shall be evaluated as agreed upon between the user/purchaser and supplier/manufacturer. Records of agreed evaluation shall be maintained.

NOTE The ISO 23936 family of standards are commonly referenced standards for evaluating the chemical stability of polymeric materials based on material properties.

Performance Rating

6.3.4.1 General

The supplier/manufacturer shall state the pressure, temperature, and axial performance ratings, as applicable for the specific products.


The effect of temperature on the performance of the materials used shall be documented and included in the outputs of design.

For type 1 components the supplier/manufacturer shall apply a de-rated yield strength for each material, corresponding to the maximum rated temperature. Determination of the temperature de-rated yield strength factor(s) for design shall be conducted following a documented procedure.

NOTE Temperature de-rated yield strength factor(s) are typically determined through statistical analysis of actual test data or reference to industry recognized published data, such as ASME BPVC Section 2 Part D.

6.3.4.2 Rated Performance Envelope

For products validated to grade V4 through grade V0, V3-H, and V0-H, a rated performance envelope is required. The ratings illustrated in the rated performance envelope shall be supported by documented val-idation testing. The rated performance envelope shall be approved by a qualified person.

An example envelope is illustrated in Figure 1.

The area within the lines forming the boundaries defines the maximum rated performance envelope of the product when it is set.

Rated performance envelopes shall meet the following criteria:

a) The product(s) covered by the envelope shall be specified.

b) The validation grade covered shall be specified.

NOTE The user purchaser may request that the rated performance envelope notes whether the product was validated by testing or by design scaling.

c) The rated performance envelope shall represent the supplier/manufacturer’s maximum rating at the maximum rated temperature. The envelope shall be applicable over the entire specified temperature range.

NOTE: Low temperature rating evaluation is addressed in 6.5.5.8 and Annex B.

d) The ratings of end connections shall not be considered in the product ratings.

e) Products with IDs shall be represented with the ID not plugged unless it is specified on the envelope.

f) Shear devices shall be represented at 100 % of their minimum shear value.

g) The minimum and maximum casing or tubing IDs shall be specified. The envelope shall be applicable over the entire specified ID range.

h) The validated temperature range and temperature-cycle range (where temperature cycling is required by the validation grade) shall be specified (see Figure 2 for a graphical representation of temperature range and the temperature-cycle range).

i) Axis and sign conventions shall be oriented as shown in Figure 1.


j) More than one graph may be displayed with the envelope if a legend is included for explanation. For example, various shear device options, plugged, unplugged, alternate temperatures, alternate rated IDs, can be displayed.

k) “Above” and “below” on the pressure axis are defined as above and below the product and not internal to the product. If the envelope includes ratings based on pressure internal to the product, this shall be specified on the envelope or illustrated as an additional graphic.

l) The Product Data Sheet can contain information required for the Performance Envelope.

NOTE Annex G includes information on sealing areas and pressure induced loads.

Figure 1—Example of a Rated Performance Envelope

6.3.4.3 Temperature-Cycle Range and Temperature Range

Figure 2 is an illustration of the temperature-cycle range (3.32), which is the temperature change over which the product is designed to operate, and the temperature range (3.33), which is the range of temperature over which the product is designed to operate.

As shown in Figure 2, the temperature-cycle range is applicable anywhere within the product’s temperature range.


The information is provided to aid in clarification of the use of these terms and how the design ratings apply. The temperature-cycle range is required because of the behavior of the product packing element.

Figure 2—Examples of Temperature-Cycle Ranges and Temperature Ranges

6.4 Design Verification

Designs verified in accordance with prior editions of ISO 14310 or API 11D1 shall be considered as meeting the design verification requirements of this specification.

Design verification shall be performed to ensure that each product design meets the supplier’s/manufacturer’s technical specifications. Design verification may include activities such as design reviews, design calculations, and comparing the new design with similar proven designs.

The minimum material condition and minimum material yield strength including the applicable temperature de-rating, shall be used in the calculations.

Design margin(s) and the mode(s) of stress shall be identified for each type 1 component and other relevant components, as determined by the supplier/manufacturer, using a documented methodology.

If corrosion or corrosion/erosion allowances are included in the design, the design verification and validations shall consider these allowances.


Verification results shall be approved by a qualified person and records of the results shall become a portion of the design documentation.

6.5 Design Validation Requirements

General

This specification specifies nine grades of design validation for which the product shall be supplied. Products shall be supplied to at least the design validation grade specified.

The validation grades are the following:

— V6: supplier/manufacturer-defined;

— V5: liquid test;

— V4: liquid test plus axial loads;

— V3: liquid test plus axial loads plus temperature cycling;

— V2: gas test plus axial loads;

— V1: gas test plus axial loads plus temperature cycling;

— V0: gas test plus axial loads plus temperature cycling plus zero bubble acceptance criterion;

— V3-H: Validation testing for liquid HPHT service per Annex B;

— V0-H: Validation testing for gas HPHT service per Annex B.

Products previously validated in accordance with prior editions of ISO 14310 or API 11D1 shall be considered as meeting the design validation testing requirements of the same validation grade of this specification when assessed and approved by a qualified person. The assessment and approval shall be documented.

Bridge plugs may be run and tested without axial load; however, all validation grades are applicable.

Products qualified to higher grades of design validation may be considered qualified for the lower grades of design validation in accordance with Table 4.

Table 4—Design Validation Grade Hierarchy

Design Validation Grade Grades Covered

V0-H V0-H, V3-H, V0, V1, V2, V3, V4, V5, and V6

V3-H V3-H, V3, V4, V5, and V6

V0 V0, V1, V2, V3, V4, V5, and V6

V1 V1, V2, V3, V4, V5, and V6

V2 V2, V4, V5, and V6

V3 V3, V4, V5, and V6


V4 V4, V5, and V6

V5 V5 and V6

V6 V6

Products validated to grade V5 through grade V0-H shall not be rated for use in casing or tubing sizes and masses (weights) that can have a maximum ID larger than the nominal fixture ID used in the validation test (refer to 6.5.2d). The supplier/manufacture may determine the corresponding casing or tubing size(s) and weight(s) for the product. NOTE Testing in test fixtures is performed to validate the performance of the product and does not simulate actual casing or tubing conditions such as ovality, straightness, surface finish or wear. Special features, which are specific components or sub-assemblies that provide additional functional capability not validated in the defined tests, shall be identified and validated to their rated limits through documented procedures and acceptance criteria.

The supplier/manufacturer shall document all parameters and results of the evaluations that demonstrate conformance to the validation grade.

Common Validation Requirements

The following requirements apply to product validation testing grade V5 through grade V0-H:

a) The validation tested product shall conform to the requirements of Sections 7.1, 7.2.1, 7.4.1, 7.4.2, 7.4.3, 7.4.12, 7.4.14, and 7.4.15.

b) Testing shall be conducted by qualified person(s). The results shall be approved by a qualified person other than the person performing the test. These records shall become part of the design documentation and included in the validation test report (see 6.5.6)

c) The product shall be set utilizing procedures, methods and tools identified in referenced supplier/manufacturer procedures.

d) Test fixture requirements:

1) Validation testing shall be performed within a test fixture that is designed to have no OD plastic deformation at the planned test or proof test pressures. This fixture simulates sup-ported casing or tubing to validate the performance of the product.

2) The fixture nominal ID shall be the maximum ID for which the product will be rated and the fixture ID tolerance shall be a maximum of ± 0.76 mm (± 0.030 in.).

NOTE Annex F provides information on determining maximum and minimum test fixture IDs. The test fixture for this packer is designed with a nominal ID equal to the maximum possible ID of this casing weight.

3) Unsupported casing or tubing applications may require additional testing which is outside the scope of this specification.


4) Inflatable packing elements are energized to form a seal by applying fluid pressure directly to the element. Test products with inflatable packing elements horizontally, centralization at one end of the test fixture is acceptable.

5) Products with no anchoring devices or anchoring devices that hold in one direction may be restrained by the test fixture to prevent movement in the un-anchored direction(s).

e) Time period for stabilization at each test step is at the discretion of the supplier/manufacturer.

f) Recorded temperature measurements shall be representative of the product as installed within the test fixture.

g) Gas bubble detection shall be at atmospheric pressure.

h) Additional test points are at the discretion of the supplier/manufacturer or can be specified by the user/purchaser without invalidating the required test points.

i) Test those products having shear-release features at their maximum rated shear load. For safety, the shear device can be replaced with a stronger shear device that can adequately withstand the maximum shear load.

j) Contingency setting methods shall be validated to documented supplier/manufacturer procedures and acceptance criteria.

k) Use the supplier’s/manufacturer’s specified methods to retrieve the retrievable-type products at the end of the test. The release loads required to remove the product shall be measured and rec-orded.

l) Repositionable products shall undergo supplemental validation testing that includes resetting and testing in accordance with the requirements and acceptance criteria of the supplier/manufacturer.

m) For packers, axial loads shall be applied to the top of the packer. For bridge plugs, the location and direction of the applied axial loads shall be documented and noted on the performance envelope. When performing validation testing, pressure induced loads into the packer from the test fixture configurations shall be considered and compensated for in the product testing.

Applied axial loads shall be in addition to the pressure induced loads.

Pressure induced loads from above shall be calculated using the cross sectional area from the fixture ID to the nominal tubing OD or documented seal diameter for products that are directly connected to the tubing, and from the fixture ID to the minimum sealing ID for products with internal sealing surfaces (bores).

Pressure induced loads from below shall be calculated using the cross sectional area from the fixture ID to the nominal tubing OD or documented seal diameter for products directly connected to the tubing, and from the fixture ID to the minimum sealing ID for products with internal sealing surfaces (bores).

NOTE Annex G includes information on sealing areas and pressure induced loads.

Validation Test Pressure Reversals

One pressure reversal may be achieved by either of the following sequences:


— Above to below, or

— Below to above.

Two pressure reversals may be achieved by either of the following sequences:

— Above to below to above, or

— Below to above to below.

Three pressure reversals may be achieved by either of the following sequences:

— Above to below to above to below, or

— Below to above to below to above.

Validation Test Procedure

The supplier/manufacturer shall develop procedures for validation testing. These procedures shall be documented and referenced with revision level or included in the final report of the results. The procedures shall include pre- and post-test inspection activities and identify critical areas to be inspected. The supplier/manufacturer shall document all test parameters and results of the evaluations that demonstrate conformance to this document.

Validation testing shall be discontinued if the product fails to perform within the limits specified, except, when such failure(s) are determined to be the result of a failure with the test facility or test fixture and the failure and its correction do not affect the validity of the test results. Failures in the test facility or test fixture and justification for validity of test results shall be included in the final report of the results.

Measuring and Monitoring Equipment

Measuring and monitoring equipment used during the validation testing process shall be calibrated in accordance with the requirements of 7.4.16.

All applied pressures are defined as gauge unless otherwise specified and shall be recorded on time-based equipment.

Axial loads shall be recorded on time-based equipment.

All applied temperatures shall be recorded on time-based equipment.

NOTE Where pressure is used to generate an axial load it is acceptable to record pressure in lieu of load.

Table 5—Test Media

Media Requirement


Liquid Use a liquid test medium of water, with or without additives, or hydraulic oil. The den-sity shall be less than 1100 kg/m3 (68.67 lb/ft3). Liquid shall be visibly free from par-ticulate matter or other material that can plug a small leak.

Gas Use a gas test medium of air, nitrogen, or other gas or mixture of gases.

Validation Test Requirements

The steps within each test shall be performed in the order shown.

6.5.6.1 Grade V6—Supplier/Manufacturer-defined

The supplier/manufacturer defines the requirements, validation method and acceptance criteria.


6.5.6.2 Grade V5—Liquid Test

The supplier/manufacturer shall adhere to the following test parameters and criteria in Table 6 for conformance to this validation grade. The test media shall be liquid per Table 5.

Table 6—Grade V5—Liquid Test

Step Procedure and Acceptance Criteria Data to Be Recorded

a) Record test data as specified and perform pre-test inspection.

− Validation test number − Date − Description of test media − Measured fixture ID − Product identification

b) Set product with the minimum rated setting force or pressure (+/- 10%) at or above maximum rated temperature.

− Actual temperature − Setting force or pressure

c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above maximum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pressure hold. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

− Start to end of each hold period o Time o Temperature o Pressure(s)

− Direction of each pressure hold (above or below)

− Test step passed? (yes or no)

d) Perform post-test inspection. − Inspection results


6.5.6.3 Grade V4—Liquid Plus Axial Load Test


Table 7—Grade V4—Liquid Plus Axial Load Test


a) Record test data as specified and perform pre-test inspec-tion.

− Validation test number − Date − Description of test media − Measured fixture ID

b) Set product with the minimum rated setting force or pres-sure (+/- 10%) at or above maximum rated temperature.


c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above maximum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pres-sure hold. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

− Start of each hold period o Time o Temperature o Pressure(s)

− Direction of each pres-sure hold (above or be-low)


d)

Test to all intersection points of the rated performance en-velope. Maintain a minimum hold period of 15 min for each enve-lope point. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

− Start of each hold period o Time o Temperature o Pressure(s) o Axial load (pressure)



e) Perform post-test inspection. − Inspection results


6.5.6.4 Grade V3—Liquid Plus Axial Loads Plus Temperature Cycling Test


Table 8—Grade V3—Liquid Plus Axial Load Plus Temperature Cycling Test




b) Set product with the minimum rated setting force or pressure (+/- 10%) at or above the maximum rated temperature.


c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above maximum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pressure hold. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

− Start to end of each hold period o Time o Temperature o Pressure(s) o Axial load (pressure)



d)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 15 min for each envelope point. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.




e)

Start this temperature cycle step at or above the maximum rated temperature and decrease the temperature by at least the maximum rated temperature cycle range. Perform a minimum 15 min pressure hold at or above maxi-mum rated differential pressure at the low end of the temper-ature cycle range. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

− Start to end of each Tem-perature cycle step o Time o Temperature o Pressure(s) o Axial load (pressure)


Test step passed? (yes or no)


f)

Increase the temperature to at or above the maximum rated temperature and perform a minimum 15 min pressure hold at or above the maximum rated differential pressure. Acceptance Criteria: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization.

g) Perform post-test inspection. − Inspection results


6.5.6.5 Grade V2—Gas Plus Axial Load Test

The supplier/manufacturer shall adhere to the following test parameters and criteria in Table 9 for conformance to this validation grade. The test media shall be gas per Table 5.

Table 9—Grade V2—Gas Plus Axial Load Test






c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above the maxi-mum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pressure hold. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.



− Gas accumulation − Test step passed? (yes or

no)

d)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 15 min for each envelope point. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.




no)

e) Perform post-test inspection. − Inspection results


6.5.6.6 Grade V1—Gas Plus Axial Loads Plus Temperature Cycling Test

The supplier/manufacturer shall adhere to the following test parameters and criteria Table 10 for conformance to this validation grade. The test media shall be gas per Table 5.

Table 10—Grade V1—Gas Plus Axial Loads Plus Temperature Cycling Test






c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above the maxi-mum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pressure hold. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.

− Start to End of each hold period o Time o Temperature o Pressure(s) o Axial load (pressure)



no)

d)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 15 min for each envelope point. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.




no)

e)

Start this temperature cycle step at or above the maximum rated temperature and decrease the temperature by at least the maximum rated temperature cycle range. Perform a minimum 15 min pressure hold at or above maxi-mum rated differential pressure at the low end of the temper-ature cycle. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.

− Start to end of each Tem-perature cycle step o Time o Temperature o Pressure(s) o Axial load (pressure)

− Direction of pressure hold (above or below)


no)


f)

Increase the temperature to at or above the maximum rated temperature and perform a minimum 15 min pressure hold at or above the maximum rated differential pressure. Acceptance Criteria: no more than 20 cm3 of gas accumu-lated in a graduated cylinder over the hold period after suffi-cient time has been allowed for stabilization. The bubble rate shall not increase during the hold period.



6.5.6.7 Grade V0—Gas Plus Axial Loads Plus Temperature-Cycling Test Plus Zero-Bubble Acceptance Criterion

The supplier/manufacturer shall adhere to the following test parameters and criteria in Table 11 for conformance to this validation grade. The test media shall be gas per Table 5.

Table 11—Grade V0—Gas Plus Axial Loads Plus Temperature Cycling Test Plus Zero-Bubble Acceptance Criterion






c)

Perform a minimum of two pressure reversals at or above maximum rated differential pressure at or above the maxi-mum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 15 min for each pressure hold. Acceptance Criteria: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabiliza-tion.




d)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 15 min for each envelope point. Acceptance Criteria: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabiliza-tion.




no)

e)

Start this temperature cycle step at or above the maximum rated temperature and decrease the temperature by at least the maximum rated temperature cycle range. Perform minimum 15 min pressure hold at or above maxi-mum rated differential pressure is required at the low end of the temperature cycle range. Acceptance Criteria: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabiliza-tion.

− Start to end of each tem-perature cycle step o Time o Temperature o Pressure(s) o Axial load (pressure)




f)

Increase the temperature to at or above the maximum rated temperature and perform a minimum 15 min pressure hold at or above the maximum rated differential pressure. Acceptance Criteria: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabiliza-tion.


6.5.6.8 Low Temperature Rating Validation

For validation grades V0, V1 and V3 where the low temperature rating is not validated during the temper-ature-cycle range test, the low temperature rating of the product shall be validated. Low temperature rat-ing validation is not required for validation grades V2, V4, V5, and V6. For products validated to prior editions of API 11D1, Methods A, B, or C shall be selected. For the current edition, Method A or B shall be used to validate the low temperature rating. Note: Prior editions of this specification did not contain requirements for validating the low temperature rating. a) Method A – Product validation testing The low temperature rating may be validated by product testing per the requirements of sections 6.5.5.4 (V3), 6.5.5.6 (V1), or 6.5.5.7 (V0). The low temperature rating is the lowest temperature achieved during the temperature-cycle range test.

Additional V0, V3, V1 validation tests may be conducted at a setting temperature other than the maximum rated temperature. To establish the low temperature rating the product shall be set at or above the minimum rated temperature plus the temperature-cycle range.

There is only one temperature-cycle range for a validated product design. Where the temperature-cycle ranges in multiple tests are different, the final rated temperature-cycle range of the product shall be the smaller temperature-cycle range of the validated temperature-cycle ranges. (see B.3.3.4.4).

Example: A product was tested multiple times under the requirements of V0 validation testing with the following tem-perature-cycle ranges achieved: 50°F to 200°F and 250°F to 350°F. The published temperature range of the prod-uct is 50°F to 350°F, and the temperature-cycle range is 100°F. b) Method B – Component validation testing The low temperature rating shall be validated using supplier/manufacturer defined component testing of the packing element. Component testing shall adequately simulate the pressure and loading conditions that would be present if the entire assembly were tested. The supplier/manufacturer shall have a documented procedure for the component testing, along with sup-porting test data. A qualified person shall approve the low temperature rating. Low temperature validation tests are considered to validate other products of the same product family us-ing the same non-metallic seal materials and configuration. c) Method C – Verification methods


The low temperature rating shall be based on supplier/manufacturer defined non-metallic material verifi-cation methods. The supplier/manufacturer shall have a documented procedure, along with adequate test data to confirm the accuracy of the verification method. A qualified person shall approve the low tempera-ture rating. The low temperature rating shall not be lower than 38ᵒC (100ᵒF).

Validation Test Report

A final report shall be prepared and approved by qualified personnel and shall be retained as part of the design documentation for the product. The report shall include the following information as a minimum:

a) Identification of product supplier/manufacturer;

b) Test facility name, location;

c) Date(s) testing was conducted;

d) Date and unique identification of the validation test report;

e) Validation test performed, grade passed, summary of results, including comparison to supplier/manufacturer acceptance criteria, with reference to the applicable industry standard with edition;

f) Identification of the validation test procedures used and records required (see 6.5.3);

g) Equipment type, size, description, model,

h) Product identification and serial number, as applicable;

i) Reference to validation-tested products:

j) Drawings and/or documents that show applicable dimensions and tolerances of components, and material specifications, including revision;

k) Traceability records for components in the validation-tested product, if applicable;

l) pre-test and post-test dimensional and visual inspection results of critical operational areas of the test fixture, including measured OD and ID, as determined by the supplier/manufacturer.

m) List of performance envelope tested points and rated performance envelope, if applicable;

n) Results of specific inspections and tests with acceptance criteria evaluation and acceptance justification, such as:

1) photograph(s) and/or visual inspections including any evidence of malfunction(s), anomalies, or damage,

2) pre-test and post-test dimensional inspection of critical operational areas,

3) drift testing.


o) Remarks (describing any non-specified equipment or procedures requested by manufacturer, unusual conditions observed during test, etc.);

6.6 Final Design Approval

The supplier/manufacturer shall conduct a review of the final design. The review of the final design shall include the review and approval of the following:

a) functional requirements,

b) technical specification,

c) design verifications,

d) design validation records (including any evaluation for scaling, if applicable),

e) design outputs and a bill of materials including material specifications.

The documentation of the review of the final design shall be approved by a qualified person. Records of the review of the final design, including the completed action items, and approval shall be maintained with the design documentation.

6.7 Design Changes

All design changes shall be documented and reviewed against the design verification and design validation to determine if the change is a substantive design change. A design that undergoes a substantive change becomes a new design requiring design verification as specified in 6.4 and design validation as specified in 6.5; however, scaling may be applied in accordance with 6.8 to achieve design validation. Design changes identified as non-substantive shall include documented justification.

The supplier/manufacturer shall, as a minimum, address the following:

a) stress levels or stress factors of the modified or changed components;

b) material changes;

c) functional changes.

Changes to a component or series of components may be identified as a substantive design change and require design validation. This may be done by testing only the component or series of components rather than the entire assembly. The test shall adequately simulate the loading conditions that would be present if the entire assembly were tested. The supplier/manufacturer shall document the detailed test results and analysis that demonstrate that the component test adequately simulates the required loading conditions. Evaluation results shall be approved by a qualified person other than the person performing them, and records of the results shall become a portion of the design documentation.

6.8 Design Validation by Scaling

General

Scaling may be used to validate variations in a product family in accordance with the requirements and limitations of 6.8.2. This applies to products validated to grade V5 through grade V0 in accordance with 6.5.


Each scaled product requires design verification, evaluation, and justification that the scaled design meets the requirements of this section. The design scaling activities shall be included in the design documentation and shall be approved by a qualified person, other than the person who performed the design.

For designs validated by scaling prior to the publication of this edition the design stress levels in relation to material mechanical properties shall be based on supplier/manufacturer documented design criteria in effect when the scaled design was created. For designs validated by scaling after the publication of this edition, the supplier/manufacturer shall establish and document the maximum stress factors within the previously validated design’s components and in the components of the scaled design. The mode of stress and same method of calculation(s)/verification(s) shall be applied to the type 1 components of the base design and the scaled design. For each type 1 component; the scaled design’s stress factors may exceed the maximum stress factors of the similar components of the validated design with additional analysis and justification. Where other failure modes limit performance, other criteria may be used in lieu of stress factor.

Limitations of Scaling

The limitations for scaling are:

a) The scaled design shall not be rated for IDs larger than the rated ID for the previously validated product.

b) Packing elements and anti-extrusion components shall have identical material specifications and drawing dimensions as the previously validated product.

c) The ID of the packing element(s) and OD of the component under the packing element(s) shall be the same as the previously validated product.

Scaling shall not be used to validate products with higher pressure ratings, a higher temperature rating, larger temperature range, a larger temperature-cycle range, higher axial load ratings, or higher combined loads than the previously validated product.

7 Supplier’s/Manufacturer’s Requirements

7.1 General

Products shall be manufactured to a quality plan and under a quality management system which is in conformance to API Specification Q1.

7.2 Documentation and Data Control

General

The supplier/manufacturer shall establish and maintain documented procedures to control all documents and data that relate to the requirements of this specification. These documents and data shall be maintained to demonstrate conformance to specified requirements. All documents and data shall be legible and shall be stored and retained in such a way that they are readily retrievable in facilities that provide a suitable environment to prevent damage or deterioration and to prevent loss. Documents and data may be in any form or type of media, such as hard copy or electronic media. All documents and data shall be available to, and auditable by, the user/purchaser.


All documentation and data associated with design verification, design validation and design change justification shall be maintained for ten years after the date of last manufacture.

Quality-control documentation includes all documents and data necessary to demonstrate conformance to 7.4.1 through 7.4.16. Quality-control documentation shall be retained by the supplier/manufacturer for a minimum of five years from date of manufacture.

Operating Manual

An operating manual shall be available for all products supplied in accordance with this specification.

Operating manuals shall contain at least the following information:

a) manual reference number;

b) operational procedures and related operational tools;

c) pre-installation inspection procedures;

d) storage recommendations;

e) a representative drawing showing major dimensions (ODs, IDs, and lengths);

f) special precautions and handling.

Product Data Sheet

Product data sheets shall be supplied at delivery to the user/purchaser, as required in 6.1, and shall contain at least the following information, where applicable:

a) name of supplier/manufacturer;

b) manufacturer product number;

c) manufacturer product name;

d) product type;

e) product characteristics;

f) service provided;

g) metallic materials;

h) non-metallic materials;

i) drift diameter;

j) maximum OD;

k) minimum ID;


l) overall length;

m) temperature range;

n) temperature-cycle range for V3, V1, V0, V3-H, and V0-H;

o) rated performance envelope for V4 through V0-H;

p) pressure rating for V6 and V5;

q) top connection(s);

r) bottom connection(s);

s) casing or tubing range, size and mass and/or minimum and maximum casing or tubing IDs;

t) conveyance method;

u) maximum conveyance OD, inclusive of running/repositioning equipment, as applicable;

v) setting method, including minimum (maximum, as applicable) setting force/pressure;

w) retrieval method (if retrievable);

x) repositioning method (if repositionable);

y) quality level;

z) design validation grade;

aa) validation by scaling or test (V0-H or V3-H);

bb) edition of this specification under which the validation test was conducted;

cc) seal diameter, as applicable;

dd) hydrostatic setting pressure range, as applicable;

ee) operating manual reference number.

7.3 Product Identification

Each product furnished to this specification shall be permanently identified according to the supplier’s/manufacturer’s specifications. The supplier’s/manufacturer’s specifications shall define the type, method of application, and location of the identifications. The following information shall be included as a minimum:

a) manufacturer’s identification;

b) manufacturer’s product number;

c) date of manufacture (month/year);


d) quality level;

e) design validation grade;

f) for quality level QL1, a unique serial and traceability number.

7.4 Quality Control

General

Products shall be supplied to at least the quality level specified. Quality requirements are detailed in 7.4.2 through 7.4.16 and summarized in Table 12. Where there are no requirements listed in 7.4.2 through 7.4.16, the word “None” appears in Table 12.

Table 12—Summary of Quality Requirements

Item Quality Level a

QL3 QL2 QL1

Metallic material COC or MTR COC or MTR MTR for type 1 components

COC or MTR for type 2 components

Non-metallic material COC or MTR COC or MTR COC or MTR

Castings COC COC COC

Heat treatment COC (subcontractor) Job-lot verification (supplier/manufacturer)

COC (subcontractor) Job-lot verification (supplier/manufacturer)

COC (subcontractor) Job-lot verification (supplier/manufacturer)

Heat treat certificate for type 1 components

Metallic component traceability

Traceable to job-lot for type 1 components

Traceable to job-lot for type 1 components

Heat traceable for type 1 components

Non-metallic component traceability

Traceable to manufacturer, production batch, and production date



Component dimensions Sampling plan Sampling plan 100 % for type 1 components

Welding

Type 1 welds Visual Surface NDE per sampling plan

Surface NDE 100 %

Type 2 welds Visual Visual Visual

Hardness

Type 1 components None Sampling plan 100 %


Type 2 components None None None

Component NDE

Type 1 components None Surface NDE per sampling plan

Surface NDE 100 % Ultrasonic inspection of raw material

Type 2 components None None Visual

Shear Device Verification

Shear devices Shear verification Shear verification Shear verification

Assembly Verification

Assembly verification None Functional test ID drift

Functional test ID drift

OD dimensional

Torque documentation

Assembly traceability None None Assembly serialization

QC documentation Supplier/manufacturer retained

Supplier/manufacturer retained

Supplier/manufacturer retained

a “None” indicates that there are no requirements listed in 7.4.2 through 7.4.16.

Material

Material, metallic or non-metallic, used in the manufacture of components shall meet one of the following requirements:

— COC to the supplier/manufacturer stating that the material meets the supplier’s/manufacturer’s documented specifications, or

— MTR to the supplier/manufacturer so that the supplier/manufacturer can verify that the material meets the supplier’s/manufacturer's documented specifications.

For Type 1 components supplied to quality levels QL1 and QL2, the supplier/manufacturer shall provide an MTR that verifies the material meets the supplier/manufacturer documented specification. Records of verification shall be maintained.

The supplier/manufacturer shall ensure that mechanical properties for non-metallic materials detailed on the material specification are supplied for each batch of non-metallic material, mixed or processed at one time.

Castings

The casting subcontractor or supplier shall provide a COC to the supplier/manufacturer stating that the casting meets the supplier’s/manufacturer’s documented specifications.


Coatings and Surface Treatments

The application of coatings and surface treatments shall be controlled using documented procedures, acceptance criteria, and qualified personnel.

Surface Hardening

Where a surface hardening process is utilized a documented specification shall be followed which defines the test specimen; process evaluation; acceptance criteria; and frequency requirements for testing.

Heat Treatment

7.4.6.1 General

Heat treatment of components or raw material shall meet the following requirements.

a) If heat treatment is performed by a subcontractor, the subcontractor shall provide a COC to the supplier/manufacturer that the heat treatment meets the supplier’s/manufacturer’s documented specifications and that heat treatment equipment conforms to 7.4.6.2.

b) If heat treatment is performed by the supplier/manufacturer, heat treatment shall comply with the supplier’s/manufacturer’s documented specifications and heat treatment equipment shall conform to 7.4.6.2.

c) For type 1 components, a heat treatment certificate showing actual times and temperatures is required for quality level QL1.

7.4.6.2 Heat-treating Equipment Qualification

Furnace Survey and Calibration

Each furnace shall have been surveyed within one year prior to heat treating operations.

Heat treating furnaces shall be calibrated in accordance with internationally recognized standards such as AMS 2750, API 20H, or API 6A.

NOTE: Heat treating furnaces include Batch-type and continuous-type heat treating furnaces.

Instrumentation

Instrumentation shall meet the following requirements:

a) Automatic controlling and recording instruments shall be used.

b) Thermocouples shall be located in the furnace working zone(s) and protected from furnace atmospheres.

c) The controlling and recording instruments used for the heat treatment processes shall have an accuracy of ± 1 % of their full-scale range.


d) Temperature-controlling and -recording instruments shall be calibrated at least once every three months until a documented calibration history can be established. Calibration intervals shall then be established based on repeatability, degree of usage and documented calibration history.

e) Equipment used to calibrate the production equipment shall have an accuracy of ± 0.25 % of the full-scale range.

Component Traceability

Component traceability shall meet the following requirements:

a) Type 1 components shall be traceable to the job-lot for quality levels QL2 and QL3.

b) Type 1 components shall be traceable to a unique heat of material, for quality level QL1.

c) Components that are castings, or are manufactured from castings, may be excluded from traceability for levels QL3 and QL2.

d) Non-metal components shall be traceable to the manufacturer, production batch, and production date.

Component Dimensional Inspection

Component dimensional inspection shall be performed and shall meet the following requirements.

a) Thread tolerances, inspection requirements, gauges, gauging practice, gauge calibration and certification shall conform to the specified thread-manufacturer's documented specifications.

b) Dimensional tolerances of O-rings shall be in accordance with ISO 3601-1 Class A or equivalent. Other custom geometries, custom O-ring sizes, and packing elements shall meet dimensional tolerances of the supplier’s/manufacturer’s documented specifications.

c) Type 2 components and all type 1 components for quality levels QL2 and QL3 shall be dimensionally inspected per a sampling plan that meets the requirements of a standard, such as ISO 2859-1 or ANSI/ASQ Z1.4.

d) Type 1 components shall be 100 % dimensionally inspected for quality level QL1.

Welds

Type 1 welds shall meet the following requirements:

a) Welding and brazing procedure and personnel qualification shall be in accordance with ASME Boiler and Pressure Vessel Code, Section IX or equivalent.

b) Weld materials not listed in the ASME Boiler and Pressure Vessel Code, Section IX shall be applied using weld procedures qualified in accordance with the methods of ASME Boiler and Pressure Vessel Code, Section IX or equivalent.

c) Welding of components for NACE service products shall meet the requirements of ANSI/NACE MR0175/ISO 15156.


Type 2 welds shall meet the documented requirements of the supplier/manufacturer.

Hardness Inspection of Components

Hardness inspection of components shall meet the following requirements:

a) Type 1 components for quality level QL2 shall be hardness-inspected per a sampling plan that meets the requirements of an international standard or national standard, such as ISO 2859-1 or ANSI/ASQ Z1.4.

b) 100 % of type 1 components for quality level QL1 shall be hardness inspected.

c) Type 2 components do not require hardness inspection.

d) Hardness inspection of metallic components shall meet the requirements of an international standard or national standard, such as ASTM E10, ASTM E18, ISO 6506-1, ISO 6507-1, or ISO 6508-1.

e) The durometer hardness of O-rings or other elastomeric packing elements shall be determined in accordance with an international standard or national standard, such as ASTM D2240 or ASTM D1415. A test specimen manufactured from each batch may be used.

NDE of Components/Welds

NDE of components and welds shall meet the following requirements:

a) Welds shall be visually inspected per the requirements of an International Standard or national standard, such as the ASME Boiler and Pressure Vessel Code, Section V, Article 9.

b) NDE for metallic components shall be magnetic-particle inspection or liquid-penetrant inspection.

c) Sampling procedures and the criteria for acceptance or rejection of a batch lot shall be in accordance with ISO 2859-1, general inspection level II, at a 2.5 AQL for O-Rings and a 1.5 AQL for other packing elements, until a documented variation history can be established. Sampling procedures shall then be established based on the documented variation history. Type 1 components shall be 100 % visually inspected for quality level QL1.

d) Visual inspection of O-rings shall be in accordance with ISO 3601-3 Grade S or equivalent. Other non-metallic components shall be visually inspected in accordance with the supplier’s/manufacturer’s documented specifications at a minimum of 2x magnification.

e) Type 1 components and welds shall be magnetic particle or liquid penetrant inspected for surface defects to verify conformance with the supplier’s/manufacturer’s written specifications. The applied magnetic particle or liquid penetrant inspections shall conform to the following requirements.

1) Wet magnetic particle examinations shall be conducted per ISO 10893-5, ISO 13665, or ASTM E709. Indications shall be described as one of the following:

i. relevant indication: only those indications with major dimensions greater than 1.6 mm (1/16 in.) shall be considered relevant whereas inherent indications not associ-ated with a surface rupture (i.e., magnetic permeability variations, non-metallic stringers etc.) shall be considered non relevant;


ii. linear indication: any indication in which the length is equal to or greater than three times its width;

iii. rounded indication: any indication which is circular or elliptical in which the length is less than three times its width.

iv. The acceptance criteria shall be:

− any relevant indication greater than or equal to 4.8 mm (3/16 in.) shall be considered unacceptable;

− no relevant linear indications shall be allowed for weldments;

− no more than ten relevant indications shall be present in any 39 cm2 (6 in.2) area;

− four or more rounded relevant indications in a line separated by less than 1.6 mm (1/16 in.) shall be considered unacceptable.

2) Liquid-penetrant examinations shall be conducted per ISO 12095 or ASTM E165 with ac-ceptance criteria of:

i. no relevant linear indications;

ii. no relevant rounded indications greater than 5 mm (3/16 in.); or

iii. no more than four or more relevant rounded indications in a line separated by 1.5 mm (1/16 in.) or less edge to edge.

f) NDE acceptance criteria shall be according to the supplier’s/manufacturer’s documented specifications.

g) All NDE instructions shall be approved by a level III examiner qualified in accordance with ISO 9712.

NOTE For the purposes of these provisions, ASNT RP SNT-TC-1A is equivalent to ISO 9712.

h) Type 1 metallic components and welds for quality level QL2 shall be NDE-inspected per a sampling plan that meets the requirements of an International Standard or national standard, such as ISO 2859-1 or ANSI/ASQ Z1.4.

i) Type 1 metallic components and welds for quality level QL1 shall be 100 % NDE-inspected using liquid-penetrant or magnetic particles.

j) Type 2 metallic components for quality level QL1 shall be visually inspected per the supplier’s/manufacturer’s documented specifications.

k) Ultrasonic inspection of raw material used for Type 1, QL1 components shall be required in accordance with 7.4.12.


Ultrasonic Inspection

Ultrasonic inspection of forgings and wrought products shall be carried out as follows:

a) method: in accordance with ASTM E428 and ASTM A388;

b) any of the following calibration methods:

1) back reflection technique: the instrument shall be set so that the first back reflection is 75 % +/-5 % of the screen height when the transducer is placed on an indication-free area of the forging or wrought product,

2) flat bottom hole technique: the distance amplitude curve shall be based on a 3.2 mm (1/8 in.) flat bottom hole for thicknesses up to and including 101.6 mm (4 in.) and a 6.4 mm (1/4 in.) flat bottom hole for thicknesses greater than 101.6 mm (4 in.),

3) angle beam technique: the distance amplitude curve shall be based on a notch of a depth equal to the lesser of 9.5 mm (3/8 in.) or 3 % of the nominal section thickness [9.5 mm (3/8 in.) maximum], a length of approximately 25.4 mm (1 in.) and a width no greater than twice its depth;

c) acceptance criteria: any of the following forging or wrought product defects shall be basis for rejection:

1) back reflection technique: indications greater than 50 % of the referenced back reflection accompanied by a complete loss of back reflection,

2) flat bottom hole technique: indications equal to or larger than the indications observed from the calibration flat bottom hole,

3) angle beam technique: amplitude of the discontinuities exceeding those of the reference notch.

Shear Device Verification

At least one shear device per job-lot shall be sheared in accordance with the supplier’s/manufacturer’s documented procedure to verify that the shear value meets the supplier’s/manufacturer’s documented specification.

Assembly Verification

7.4.14.1 General

The supplier’s/manufacturer’s functional testing equipment shall conform to the requirements of 7.4.15 and be conducted by a qualified person. All pressures are defined as gauge unless otherwise specified and shall be recorded on time-based equipment for the duration of its application.

Any sealing plug installed after the completion of the assembly verification testing shall be internally or externally tested to verify full integrity in conformance with the supplier’s/manufacturer’s procedures and acceptance requirements.


Fixtures or clamping devices are allowed to prevent initiation of the setting sequence, provided they do not affect the integrity of the test results.

Special features not tested in the defined functional testing shall be tested in accordance with the sup-plier’s/manufacturer’s procedures and acceptance criteria.

A visual inspection shall be performed of all accessible surfaces by a qualified person after all testing is successfully completed. Observed damage shall be documented in the functional test documentation and the acceptance adjusted as applicable.

7.4.14.2 Functional Testing

Functional testing shall conform to the following:

a) For quality level QL1, an internal pressure test shall be performed on each product by pressurizing to a minimum of 50% of the equipment internal to external differential rating using either liquid or gas as the test medium. One-piece mandrels or mandrels with only internal metal-to-metal sealing connec-tions are excluded from this requirement. Test duration and acceptance criteria shall be defined by the sup-plier’s/manufacturer’s documented procedures.

b) For quality level QL2, a low-pressure, internal test shall be performed on each product by pressuriz-ing to a minimum of 350 kPa (approximately 50 psi) using either liquid or gas as the test medium. One-piece mandrels or mandrels with only internal metal-to-metal sealing connections are excluded from this requirement. Test duration and acceptance criteria shall be defined by the supplier’s/manu-facturer’s documented procedures.

c) For quality levels QL2 and QL1, ID drift each product per the supplier’s/manufacturer’s documented specifications.

1) ID drift shall apply only to product IDs not designed as sealing surfaces (sealbores). Drift-bar diameter shall match the rated drift diameter of the product. The drift-bar shall be a minimum length of four times the specified inside diameter of the product, or 610 mm (24 in.), whichever is greater.

2) For products with sealing IDs (sealbores), the drift test shall be conducted per the supplier’s/manufacturer's documented specifications and acceptance criteria.

3) Bridge plugs are exempted from this requirement.

d) For quality level QL1, the OD shall be inspected according to the supplier’s/manufacturer’s documented specifications. OD dimensional inspection shall verify that the entire OD of the assembly is less than, or equal to, the maximum specified OD.

e) For quality level QL1, actual torque values for all metal-to-metal sealing connections shall be rec-orded and verified to be within the supplier’s/manufacturer’s documented specifications. End connec-tions are specifically excluded from this requirement.

7.4.14.3 Functional Test Documentation

A functional test record shall be prepared for each product tested and shall include:

a) Identification of product manufacturer;


b) date of functional test and date of record;

c) model designation or other identification;

d) product number with unique serial number, as applicable;

e) remarks (describing any non-specified equipment or procedures requested by manufacturer, unusual conditions observed during test, etc.);

f) testing limits applied and testing results compared to the acceptance criteria;

g) results of specific evaluations, such as;

1) visual inspections, drift testing;

2) operational tools used (if any);

3) special features, as applicable;

h) test fixtures, test fluids, and lubricants;

i) test approval by a qualified person other than the person performing the test.

Assembly Traceability

Assembly serialization using unique identifiers shall be used to provide traceability of all type 1 components within each assembly for quality level QL1.

Calibration Systems

Measuring and testing equipment used for acceptance shall be identified, controlled, calibrated, and adjusted at specific intervals in accordance with an internationally recognized standard, such as ISO/IEC 17025.

Technologies for measuring and testing equipment with verifiable accuracies equal to, or better than, those listed in this specification may be applied with appropriate documentation and when approved by a qualified person.

Pressure measuring devices shall be:

a) readable to at least ± 0.5 % of the full-scale range or less, as required to perform the specified measurement;

b) calibrated to maintain ± 2 % accuracy of the full-scale range or less, as required to perform the specified measurement(s);

c) used only within the calibrated range;

d) calibrated with a master pressure measuring device or a dead-weight tester.


Calibration intervals for pressure measuring devices shall be a maximum of three months until a documented calibration history can be established. Calibration intervals shall then be established based on repeatability, degree of usage and documented calibration history.

Personnel Qualifications

Personnel performing NDE evaluations and interpretations shall be qualified in accordance with ISO 9712, to at least Level II, or equivalent.

NOTE For the purposes of these provisions, SNT-TC-1A is equivalent to ISO 9712.

Personnel performing visual examinations shall have an annual eye examination, applicable to the discipline to be performed, in accordance with ISO 9712.

NOTE For the purposes of these provisions, SNT-TC-1A is equivalent to ISO 9712.

All other personnel performing inspection for acceptance shall be qualified per the supplier’s/manufacturer’s documented specifications.

8 Repair/Redress

Products returned for repair or redress after delivery shall conform to the requirements of sections 7 or return the product to a condition meeting all requirements stated in the edition in effect at the time of original manufacture.

Repaired or redressed products shall be permanently marked for traceability back to the repair.

Documentation of the replaced and /or repaired components and all subsequent testing results shall be included in records traceable to the product assembly.

9 Shipment/Storage

Products shall be stored per the documented specifications of the supplier/manufacturer to prevent deterioration (for example caused by atmospheric conditions, debris, radiation, etc.) prior to transport.

Products shall be packaged for transport per the documented specifications of the supplier/manufacturer to prevent normal handling loads and contamination from harming the equipment. These specifications shall address the protection of external sealing elements, sealing surfaces, and exposed threaded connections.


47

Annex A (informative)

Use of API Monogram by Licensees

To be populated prior to publication.


48

Annex B (informative)

Requirements for HPHT Environment Equipment

B.1 General

This annex applies to packers and bridge plugs for use in HPHT environments with a pressure rating greater than 103.4 MPa (15,000 psi) or with a temperature rating greater than 177 °C (350 °F). The requirements specified in this annex are in addition to sections 1 through 9 of this specification. This annex was developed considering the guidelines of API TR 1PER15K-1.

This annex may be specified by the user/purchaser for non-HPHT products. Activities required by this annex shall be performed by a qualified person(s). All results shall conform to the acceptance criteria and be supported by approved documentation.

B.2 Functional Specification for HPHT Equipment

The user/purchaser shall prepare a functional specification for the HPHT equipment. The functional specification shall include, where applicable, internal test pressure requirements (Section 7.4.13.2).

NOTE Products under standard operating conditions have very low load cycles over their operational life. For information regarding investigations of load cycling see ASME Boiler and Pressure Vessel Code, Section VIII, Div 3, Article KD-3 or Article KD-4 or Div 2 Part 5.

B.3 Technical Specification

B.3.1 Design Requirements

B.3.1.1 Metals

B.3.1.1.1 Temperature Effects

When elevated temperature tensile testing is performed it shall be per ASTM E21. The test material samples shall be taken from heat(s) representative of those to be used for the intended components and shall be removed from midwall or midradius unless the equipment supplier/manufacturer determines that a more appropriate testing location is required. Alternate testing locations may be selected to better represent a component’s highest stress location or, for cold worked material, lowest strength location due to material anisotropy.

Temperature effects for other relevant properties should be considered.

B.3.1.1.2 Castings

Castings shall not be used for type 1 components that are integral to the tubing string.

NOTE Castings are typically used for slips, cones, and drag blocks, which are components primarily loaded only in compression and drillable bridge plug assemblies and are not integral to the tubing string.

The following requirements shall apply:


a) All castings, with the exception of slips and primarily compression loaded components shall conform to the requirements of API Specification 20A, CSL3.

b) Slips and components primarily loaded in compression manufactured as castings shall conform to documented requirements defined by the supplier/manufacturer. These requirements shall include specifications for, as described in API Specification 20A:

1) Microstructure

2) chemistry

3) volumetric NDE

4) 100 % dimensional inspections

Materials not included API Specification 20A shall be tested to supplier/manufacturer requirements.

B.3.1.1.3 Welding

Welding, including overlays and brazing shall require the following:

a) All type 1 welds shall be volumetrically inspected by radiographic or ultrasonic techniques to ver-

ify conformance with the supplier’s/manufacturer’s written specifications. Final NDE shall be per-formed after all welding, post-weld heat treatment and applicable machining operations on welded areas. Where the final geometry is impractical to perform volumetric inspection on, the inspection shall be conducted prior to final machining. The applied radiographic and ultrasonic techniques shall conform to the following requirements:

1) Radiographic inspection of weldments shall be performed in accordance with ASTM E94 and

to the acceptance criteria of ASME Boiler and Pressure Vessel Code, Section VIII, Division 1, UW-51, where applicable by supplier/manufacturer requirements.

2) Ultrasonic inspection of weldments shall be performed in accordance with ASME Boiler and

Pressure Vessel Code, Section V, Article 5 and with the following acceptance criteria, where applicable by supplier/manufacturer requirements.

i. Indications characterized as cracks, lack of fusion, or incomplete penetration are un-acceptable regardless of length.

ii. Other imperfections are unacceptable if the indications exceed the reference level amplitude and have lengths which exceed:

-L > 6.4 mm (1/4 in.) for t ≤ 19 mm (3/4 in.)

-L > 1/3 t for 19 mm < t ≤ 57.2 mm (3/4 in. < t ≤ 21/4 in.)

-L > 19 mm (3/4 in.) for t > 57.2 mm (21/4 in.)

where t is the thickness of the weld excluding any allowable reinforcement. For a butt weld joining two members having different thicknesses at the weld, t is the thinner of these


two thicknesses. If a full penetration weld includes a fillet weld, the thickness of the throat of the fillet shall be included in t.

b) Welding of sub-assemblies (such as rupture disk installations) shall conform to the supplier/man-ufacturer documented specifications and acceptance criteria.

B.3.1.2 Non-metals

B.3.1.2.1 Elastomeric Compound Assessment

The supplier/manufacturer shall conduct compound assessment testing per documented procedures con-taining and/or referencing acceptance criteria. These assessments shall include (but may not be limited to) ageing testing, and compression set testing on elastomeric materials.

a) Ageing testing shall be conducted on an elastomeric compound per ISO 23936-2 section 7.2 or the supplier’s /manufacturer’s documented procedure. The service temperature shall be equal or lower than the maximum rated operating temperature of the equipment.

b) Compression set testing shall be conducted on an elastomeric compound per ASTM D395 or ASTM D1414 when critical to equipment performance. This evaluation shall determine the retained elastic properties after prolonged action of compressive stresses.

c) When required by the functional specification, rapid gas decompression (RGD) testing shall be conducted by the supplier/manufacturer on an elastomeric material per ISO 23936-2, Annex B with acceptance criteria of 0 or 1 for the component cross section. Ageing testing may require agree-ment between the user/purchaser and the supplier/manufacturer for test fluid(s), test temperatures, test pressures, test times, specimen shape, and trapped gas.

Unless agreed otherwise between the supplier/manufacturer and the user/purchaser, testing pa-rameters shall be:

1) fluid composition;

2) test temperature: 100 °C (±2 °C) [212 °F (±5 °F)];

3) test pressure: 15 MPa (+1, −0.5 MPa) [2176 psi (+145 psi, −73 psi)];

4) depressurization rate: 2 MPa/min (±0.2 MPa/min) [290 psi/min (±29 psi/min)].

Packing elements, because of their thick cross section and functionality in service, do not require conform-ance to RGD acceptance criteria. The ISO 23936-2 test procedure and sample configuration is not rele-vant to the functionality of sealing systems like packing elements where volumetric expansion is restricted. ISO 23936-2 Annex B testing is relevant to thin cross sectional seals like O-rings and other similar sized geometries.

NOTE ISO 23936-1 contains guidance for the qualification of thermoplastic materials.

B.3.1.2.2 Material Specifications

For elastomeric materials, the supplier’s/manufacturer’s specification shall include requirements and ac-ceptance criteria for all of the parameters determined per the applicable specification listed in Table 1 or equivalent.


For thermoplastic materials, the supplier’s/manufacturer’s specification shall include requirements and acceptance criteria for all of the following parameters, determined per the specification listed in Table 3 or equivalent, and the following parameters listed in Table B.1, as applicable.

Table B.1 – Parameters for Thermoplastic Materials

Parameter Specification

Modulus of elasticity ASTM D638

Flexural modulus ASTM D790

Creep failure ASTM D2990

B.3.2 Design Verification Requirements

B.3.2.1 General

Design verification shall be performed in conformance with the following:

a) The performance limits of the product shall be determined on an individual component basis at the maximum rated temperature. The design shall consider all operational loading conditions defined in the functional requirements and by the technical specifications. A stress analysis methodology that considers the applied loads and combined stresses shall be used to determine the maximum state of stress of each component of the assembly other than that of common hardware.

b) The supplier/manufacturer shall perform and document a combined loading analysis and generate a rated product performance envelope based upon that analysis (see 6.3.4.2).

B.3.2.2 Design Analysis of Type 1 Components

Figure B.1 illustrates the following requirements for design analysis.

Finite Element Analysis (FEA) shall be performed on type 1 components for the maximum operating load cases at the maximum rated temperature to evaluate for plastic collapse, local failure and, as applicable, buckling using ASME Boiler and Pressure Vessel Code, Section VIII, Division 2, Part 5 or ASME Boiler and Pressure Vessel Code, Section VIII Division 3, article KD-2 and the supplier/manufacturer documented design margins and load factors (see B.3.2.1).

When FEA has identified plastic strain in excess of 0.2 %, a ratcheting analysis shall be performed per ASME BPVC Section VIII, Division 3, KD-234 or ASME BPVC Section VIII, Division 2 clause 5.5.7. The material performance data shall be obtained via testing per B.3.1.1.

These requirements do not apply to components which are intended to be plastically deformed in order for them to perform correctly. Intentionally plastically deformed component designs shall conform to supplier/manufacturer documented design analysis methodology and acceptance criteria.


Global Plastic Collapse Analysis(Div. 2: 5.2.4 or Div. 3: KD-231)

Local Failure Analysis(Div. 2: 5.3.3 or Div. 3:KD-232)

Plastic Strain> .2%

Buckling Analysis (as applicable)

(Div. 2: 5.4 or Div. 3: KD-233)

All Analysis Pass?

Evaluate Load Factors between Div. 2 and Div. 3, Geometry, or

Loading ConditionsRatcheting Analysis

(Div. 2: 5.5.7 or Div. 3: KD-234)

Perform Documentation of Component Design Verification

per B.3.2.3

Start

Yes

No

No Yes

Figure B.1 – HPHT Design Flow Chart

NOTE A fatigue screening may be performed per ASME BPVC Section VIII, Division 2, Paragraph 5.5.2. API 579/ASME FFS-1 provides information on conducting fatigue analysis. Load cases to be used in the fatigue screening are provided in the functional specification.


B.3.2.3 Documentation of Component Design Verification

A summary report of each component’s design shall include:

a) calculated stress,

b) stress mode,

c) stress factor,

d) maximum temperature,

e) applied loads,

f) maximum allowable stress, and

g) temperature de-rated minimum yield strength.

Documentation of FEA results shall include:

1) description of the numerical method used, including name and version of computer software;

2) component dimensions which resulted in the highest state of stress;

3) loading conditions;

4) mesh sensitivity review;

5) numerical analysis results, showing the acceptance criteria utilized;

6) evidence of verification by a qualified person other than the individual who created the original analysis.

The FEA study shall be electronically archived such that the study is capable of being re-evaluated at a later time.

The design verification summary report shall be approved by a qualified person other than the one who developed and tested the original design and it shall be included in the design documentation.

B.3.3 Design Validation Requirements

B.3.3.1 General

Products shall be validated to their rated limits in conformance with the requirements of sections 6.5 and the requirements of this annex. Product operational tool designs shall be validated to the requirements of Annex C.

All final design validation activities shall be contained in reports that are a portion of that product’s design documentation.

B.3.3.2 Non-metallic Component Validations

Validation of non-metallic components shall require the following:

a) Inspections according to the supplier’s/manufacturer’s specifications, dimensional requirements, documented procedures, and acceptance criteria.


b) Component validation testing at product limits of loading(s) and maximum/minimum operating temperatures. Components successfully tested in the validation testing of the product (see B.3.3) can be considered as validated as a component when all aspects of the component’s functionality are tested.

c) Records of inspections, component validation testing, and final approval shall become a portion of the design documentation of the product (see 7.2).

B.3.3.3 Validation Testing, Failure Mode, and Effects Analysis

The supplier/manufacturer shall conduct an FMEA, fault-tree analysis, or other reliability assessment method to determine if validation testing per this annex sufficiently validates the design for the intended application and further determine the requirements for additional validations.

Reliability assessment methods shall conform to the requirements of an international standard or to the supplier’s/manufacturer’s documented procedures that are based upon an international standard. The approved report of this assessment shall become a part of the products design documentation.

B.3.3.4 Design Validation Requirements

B.3.3.4.1 General

This section contains the requirements for design validation of products for use in HPHT environments and contains two grades of design validation V0-H and V3-H.

B.3.3.4.2 Requirements

The supplier/manufacturer shall adhere to the requirements of 6.5 and to the following test parameters and criteria for conformance to validation grade V0-H or V3-H.

a) The test product shall be manufactured to the requirements of B.5. Any substantive design changes (see 6.7) require all testing phases to be performed on the new design.

b) Perform a drift test per 7.4.14.

B.3.3.4.3 Retrievable Product Requirements

A retrieving test is required for retrievable products. This validation testing shall be performed a minimum of one time on each product design at the conclusion of testing of one of the phase 1, phase 2, or phase 3 tests (see B.3.3.4.4). The release loads required to remove the product shall be measured and recorded. The operating manual’s specified retrieval methods and required procedures shall be used as the release method for design validation of the releasing features.

NOTE Releasing methods include, but are not limited to; shift to release, cut to release, and shear to release.

NOTE For cut-to-retrieve packers, a test with a single cutter operational tool can validate cutting with other tools with the same functional performance provided the tools function in applicable diameter ranges, cross sections, and materials.

Operational tools are defined in Annex C with the applicable validation requirements.

A test report (6.5.7) shall be prepared for the validation of the retrieving feature(s).


B.3.3.4.4 Validation Testing Scope

Each product design shall be successfully tested in each of the following test phases (1, 2, and 3). This applies to products in conformance with validation grades V0-H and V3-H as identified in each phase:

‒ Phase 1. A maximum ID/maximum temperature test. The product shall be set in the maximum specified fixture ID with a tolerance of −0.0 mm/+0.76 mm (−0.000/+0.030 in.).

‒ Phase 2. A maximum ID/minimum temperature test. The product shall be set in the maximum specified fixture ID with a tolerance of −0.0 mm/+0.76 mm (−0.000/+0.030 in.). This testing is not required if the temperature range is tested in Phase 1.

‒ Phase 3. A minimum ID/maximum temperature test. The product shall be set in minimum specified fixture ID with a tolerance of –0.76 mm/+0.0 mm (–0.030/+0.000 in.). In the case where the minimum casing or tubing ID is less than the specified drift, the drift dimension shall be used as the fixture ID.

NOTE There is only one temperature-cycle range rating for a validated product. Where the temperature-cycle range in test phases 1, 2, and 3 are different, the final rated temperature-cycle range of the product is the smaller temperature-cycle range of the validated temperature-cycle ranges.

The test phases may be completed in any order. The steps within each testing phase shall be performed in the order shown. Repair or redress of a product during a testing phase requires the testing to re-start at the beginning of that phase.

B.3.3.4.5 Validation Testing Process, Grade V3-H and V0-H, Phase 1, (Maximum ID/Maximum Temperature)

The supplier/manufacturer shall adhere to the following test parameters and criteria in Table B.2 for conformance to this Phase of the validation grade. The test media for grade V3-H shall be liquid per Table 5; the test media for grade V0-H shall be gas per Table 5.

Table B.2 Grade V3-H and V0-H Phase 1 — Validation Testing Process, Maximum ID/Maximum Temperature



− Validation test number − Date − Description of test media − Measured fixture OD and

ID − Fixture hardness


b)

For products with an atmospheric pressure chamber assem-bly (may include a rupture disc) a pressure integrity test of the test fixture with the product installed shall be performed to a minimum of 80 % of the minimum rated setting pressure (see step c) for a minimum of 30 minutes at the maximum rated temperature. This pressure is applied to the inside and out-side of the product simultaneously. Acceptance Criteria: the ability of the product to set as de-signed and to complete the tests of this phase.

− Actual temperature − Setting force or pressure − Start and end time of hold

c) Set product with the minimum rated setting force or pressure (+/- 10%) in fixture per B.3.3.4.4, Phase 1 at or above the maximum rated temperature.


d)

Perform a minimum of three pressure reversals at or above the maximum rated differential pressure at or above the maxi-mum rated temperature, refer to 6.5.3. Maintain a minimum hold period of 30 min for each pressure hold. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold pe-riod after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.

− Start to end of hold period o Time o Temperature o Pressure(s) o Axial load (pressure)



e)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 30 min for each envelope point. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold pe-riod after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.




f)

Start this temperature cycle step at or above the maximum rated temperature and decrease the temperature by a mini-mum of the temperature cycle range. Perform a pressure test at or above the maximum rated dif-ferential pressure from below. Maintain a minimum hold period of 30 min for each pressure hold.

− Start to end of hold period o Time o Temperature o Pressure(s) o Axial loads (pres-

sure) − Test step passed? (yes or

no)


Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold pe-riod after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.

g)





h) Increase temperature to or above the maximum rated temper-ature.

− Temperature

h)

Perform a pressure test at or above the maximum rated dif-ferential pressure from below. Maintain a minimum hold period of 30 min for each pressure hold. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold pe-riod after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.

− Start to end of hold period o Time o Temperature o Pressure(s)


i) Perform post-test inspection. − Inspection results

B.3.3.4.6 Validation Testing Process, Grade V3-H and V0-H, Phase 2, (Maximum ID/Minimum Temperature)


Table B.3 Grade V3-H and V0-H Phase 2 — Validation Testing Process, Maximum ID/Minimum Temperature




− Validation test number − Date − Description of test media − Measured fixture OD and

ID − Fixture hardness

b)

For products with an atmospheric pressure chamber assembly (may include a rupture disc) a pressure integrity test of the test fixture with the product installed shall be performed to a minimum of 80 % of the minimum rated setting pressure (see step d) for a minimum of 30 minutes at the minimum rated temperature. This pressure is applied to the inside and outside of the product simultaneously. Acceptance Criteria: the ability of the product to set as de-signed and to complete the tests of this phase.

− Actual temperature − Setting force or pressure − Start and end time of hold

c) Set product with the minimum rated setting force or pressure (+/- 10%) in fixture per B.3.3.4.4, Phase 2 at or above the min-imum rated temperature plus the temperature-cycle range.


d)

Perform a minimum of three pressure reversals at or above the maximum rated differential pressure, refer to 6.5.3. Maintain a minimum hold period of 30 min for each pressure hold. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.

− Start to end of hold period o Time o Temperature o Pressure(s) o Axial loads (pressure)

− Direction of each pressure Hold (above or below)


e)

Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 30 min for each envelope point. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.


− Direction of each pressure Hold (above or below)


f) Decrease temperature to the minimum rated temperature or below. − Temperature


g)

Perform a pressure test at or above the maximum rated differ-ential pressure from below. Test to all intersection points of the rated performance enve-lope. Maintain a minimum hold period of 30 min for each envelope point. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.



h) Increase temperature to or above the minimum rated tempera-ture plus the temperature-cycle range.



i)

Perform a pressure test at or above the maximum rated differ-ential pressure from below. Maintain a minimum hold period of 30 min for each pressure hold. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold period after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.

j) Perform post-test inspection − Inspection results

B.3.3.4.7 Validation Testing Process, Grade V3-H and V0-H, Phase 3, (Minimum ID/Maximum Temperature)


Table B.4 Validation Testing Process, Grade V3-H and V0-H, Phase 3, (Minimum ID/Maximum Temperature)


a) Record test data as specified and perform pre-test inspection. − Validation test number − Date − Description of test media


− Measured fixture OD and ID

− Fixture hardness

b)

Set product with the minimum rated setting force or pressure (+/- 10%) in fixture per B.3.3.4.4, Phase 3 at or below the maximum rated temperature minus the temperature-cycle range.


c) Increase the temperature to or above the maximum rated temperature. − Temperature

d)





e) Decrease temperature by a minimum of the temperature-cy-cle range.

− Temperature

f)

Perform one pressure reversal from the maximum rated dif-ferential pressure from above to the maximum rated differen-tial pressure from below. Maintain a minimum hold period of 30 min for each pressure hold. Acceptance Criteria for V3-H: no more than 1 % reduction in the maximum rated differential pressure over the hold pe-riod after sufficient time has been allowed for stabilization. Acceptance Criteria for V0-H: zero bubbles of gas observed over the hold period after sufficient time has been allowed for stabilization.



g) Perform post-test inspection. − Inspection Results

B.3.3.5 Design Validation by Scaling

B.3.3.5.1 General

The scaling of validated product designs shall conform to the requirements of 6.7, 6.8 and the following.


B.3.3.5.2 Design Scaling Parameters

The supplier/manufacturer shall establish and document the maximum stress factors within the previously validated design’s components and in the components of the scaled design. The mode of stress and same method of calculation(s)/verification(s) shall be applied to the identified components of the validated design and the scaled design. For each component; the scaled design’s stress factors shall not exceed the maximum stress factors of the same components of the validated design. The supplier/manufacturer shall ensure that the scaled design conforms to the applicable validation grade and functional testing requirements.

B.4 Operational Tool Testing Requirements

Each operational tool design required for the functionality of the product shall be verified, validated and functionally tested in accordance with the requirements of Annex C.

B.5 Manufacturing Requirements

B.5.1 Serialization Requirements

Type 1 components shall be individually serialized. Prior to product assembly the individual serialization information for type 1 components shall be verified and included on the assembly documentation for that product (see 7.4.15).

B.5.2 Non-metallic Material Supplier Qualifications

The supplier/manufacturer shall purchase goods and services only from approved suppliers.

The supplier/manufacturer shall develop and/or receive from the subsupplier of nonmetal components a process specification that details the controls necessary for the production of the nonmetal item to meet the supplier/manufacturer’s specifications.

Each supplier shall be evaluated to ensure that the applicable controls of all materials, compounds and component processes effectively ensure consistent conformance to the material and technical specifications. These evaluations shall be performed by qualified individuals.

Supplier evaluation records shall identify the materials/components that are approved to be provided by each specific supplier. Supplier documented evaluation records shall include the necessary corrective measures and verification of their implementation.

B.5.3 Functional Testing Requirements

Functional testing shall conform to 7.4.14, quality level QL1, and the requirements defined in this section.

An internal pressure test shall be performed on each product by pressurizing to the rated internal test pressure or the internal test pressure in the functional requirements whichever is greater using either liquid or gas as the test medium.

Fluid charged and atmospheric chamber(s) shall be pressure tested to the chamber’s maximum rated pressure. In the event that the design does not allow direct measurement an alternate means of validation shall be documented. Activation devices such as rupture discs are excluded from this requirement.


Unless otherwise specified by the supplier/manufacturer, gas pressure-relieving (bleed-down) operations shall be performed at a rate of 6.9 bar (100 psi) per minute or less when the pressures are less than 103.4 bar (1500 psi). All pressure test holds shall have a minimum duration of 15 minutes after pressure and temperature stabilization.

The loss of applied pressure after stabilization shall be less than 1 % of the applied pressure during the hold period. No leakage shall be visible or observed during testing.


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Annex C (normative)

Requirements for HPHT Operational Tools

C.1 General

This annex includes the requirements for design verification (including interface capabilities), manufacturing, design validation, design evaluation and reporting requirements for operational tools. These tools are identified in product data sheets or operating manuals for HPHT products. End connections of the operational tools are not included in the requirements of this annex.

These operational tools are required for the primary product to perform as designed.

Typically, operational tools include setting, running/pulling, and releasing tools. Not included in the requirements of this annex are contingency tools, milling tools, and destructive removal systems. These may be identified or referenced on the data sheet in the operating manual.

Validation grades do not apply to operational tools.

The activities required by this annex shall be performed by competent, qualified person(s). All results shall conform to the acceptance criteria and be supported by documentation.

Post manufacturing operational tool redress, repair, and servicing is not covered by this annex.

C.2 Design Verification

Each operational tool design and its operational/interface capability shall be supported by design verification records/reports to the ratings of the operational tool. Reports shall be approved by the supplier’s/manufacturer’s qualified person. Each tool’s operational capabilities shall conform to the requirements of the functional specification of the primary product.

Design verification by evaluation shall include activities such as design reviews, design calculations, comparison with similar designs, and historical records of defined operating conditions. Verification results shall be approved and records of the results shall become a portion of the operational tools design documentation.

C.3 Design Validation Requirements

C.3.1 General

Design validation of all features and capabilities shall be accomplished by evaluation or validation testing to the tools performance ratings and capabilities.

When previously validated operational tools from the primary product supplier/manufacturer are specified, the interface and performance of the operational tool design may be validated by a review of reports of the operational tools testing and performance rating. The review shall be documented and approved by a qualified person of the supplier/manufacturer.


The supplier/manufacturer shall have on file material specifications and drawings that show all the applicable dimensions and tolerances of the components contained in the validation-tested or approved product.

Pre-test and post-test dimensional and visual inspection of critical operational areas, as determined by the supplier/manufacturer, shall be conducted, documented and maintained by the supplier/manufacturer. The assembly results and dimensional inspection results shall be approved by a qualified person other than the person performing them and records of the results shall become a portion of the design documentation.

All testing and evaluations shall be performed to documented procedures and acceptance criteria with approvals. Testing shall conform to the requirements of 7.2, 7.4.6.2.2, and 7.4.16 as applicable to requirements for operational tools.

C.3.2 Tools from Alternate Suppliers

For operational tools provided by a supplier other than the primary product supplier/manufacturer, the interface and performance of the operational tool design shall be validated by a review of reports of the tools successful testing or applicable use and performance validation ratings.

The review shall be documented and approved by a qualified person of the supplier/manufacturer. This report shall be retained in conformance with the requirements of 7.2.

C.3.3 Testing During Previous Product Validations

An operational tool that has had all of its functional capabilities successfully validated to its ratings in the performance of product validation testing, (design validation of the primary product) shall be considered as meeting the requirements of this annex after the resulting documentation is approved by a qualified person.

Any operational capabilities that have not been validated during the product validation testing shall be validated separately to the requirements of this annex.

C.3.4 Testing Requirements

Testing equipment, fixtures (where applicable) and procedures shall conform to the requirements of section 7. Design validations shall be performed with instruments which are calibrated to 7.4.16. All measurements for acceptance shall be within the calibrated range(s) of the testing equipment.

The design and performance of the test fixture shall replicate the interface of the operational tool within its designated product and shall not influence the testing results. Design validation by testing shall be done with the entire product or with a fixture with the equivalent fits, clearances and loads as the affected portion of the product.

Validation testing shall be discontinued if the operational tool or its interface fails to perform within the limits specified, except, when such failures are determined to be a result o f a failure within the test facility alone, and that failure and its correction do not affect the validity of the testing and its results.

During validation testing of hydraulically operated tools, fluid metering may be used to provide readable control signals during the testing if necessary to simulate downhole conditions.


C.3.5 Final Design Validation Report

A final report of the design validations shall conform to applicable sections of 6.5.6.

C.4 Design Changes

Design changes to a validated operational tool shall conform to 6.7.

C.5 Design Validation Scaling

Design validation scaling shall conform to the requirements of 6.8.2. This scaling shall not be used to cover operational tools with higher pressure ratings, higher temperature ratings, or higher axial load ratings than the validation tested operational tools of the same family.

C.6 Manufacturing Requirements

C.6.1 General

Operational tools shall be manufactured to the requirements of 7.4 (as applicable) with a minimum of quality level QL3.

C.6.2 Assembly Requirements

The assembly of the operational tool shall follow the supplier’s/manufacturer’s documented procedures utilizing components that conform to documented specifications. A bill of materials shall be prepared for each assembly.

C.6.3 Functional Testing

Each operational tool manufactured shall be functionally tested prior to shipment.

Operational tool assembly processing and functional testing shall conform to supplier’s/manufacturer’s documented procedures which shall include the requirements for the fluids, lubricants, methods, and acceptance criteria. A functional testing report shall be prepared for each operational tool successfully tested that includes as a minimum:

a) the operational tools unique identification, such as part number;

b) the procedure identification and records required by those procedures;

c) results of the successfully completed functional test;

d) the date and location of the testing and the testing results approval by a qualified person.

C.6.4 Documentation, Data Control, and Operations Manual

The documentation and data control for the operational tools shall meet the requirements of 7.2.1 and an operations manual per 7.2.2 shall be supplied with each operational tool.


C.6.3 Product Identification

Operational tools shall be permanently and uniquely identified according to the supplier’s/manufacturer’s specifications. The supplier’s/manufacturer’s specifications shall define the type, method of application and location of the identifications. The following information shall be included as a minimum:

a) manufacturer’s identification;

b) manufacturer’s product number;

c) date of manufacture (month/year).


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Annex D (informative)

Requirements for External Flow Testing

D.1 Scope

This annex defines the requirements for product external flow testing.

NOTE External flow testing (sometimes called swab testing) simulates a condition that exists when an unset product is moved through casing or tubing filled with fluid or when fluid is passed externally around a stationary product inside a casing or tubing.

D.2 General

D.2.1 Testing Requirements

Each product shall be tested within the limits specified in the external flow test procedure. The test results, design documentation and external flow ratings shall be maintained to the requirements of 6.2 as applicable. The supplier’s/manufacturer’s external flow ratings shall be within the testing results recorded. The test procedures, testing results and ratings shall become a portion of the products design documentation.

The product shall be decentralized in the fixture so that one side of the product rests on the ID of the test fixture.

Two or more tests shall be run using a new packing element of the same part number and revision, material specification and construction for each test. Each test shall consist of a flow test from above and below. The test procedure shall define the direction(s) of flow.

The external flow test shall be conducted with water or other liquid approved by a qualified person.

D.2.2 Personnel

Preparation, testing, and approval of results shall be conducted by qualified personnel.

D.2.3 Measuring and Monitoring Equipment

Measuring and monitoring equipment used during the testing shall be calibrated to 7.4.16. All measurements for acceptance shall be within the calibrated range(s) of the testing equipment. All pressures are defined as gauge unless otherwise specified and shall be recorded on time based equipment. Flow rates shall be recorded on time based equipment.

The temperature shall be measured in the flow stream as close as practical to the packing element. The pressure shall be measured above and below the packing element as close as practical to the packing element.


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D.2.4 Procedures

The supplier/manufacturer shall develop procedures for conducting the external flow tests which shall be documented and included in the final report of the results. The procedures shall as a minimum include the parameters defined in D.4. The procedures shall include acceptance criteria.

D.3 Test Fixture

The functionally tested product shall be installed in a section of casing/fixture with an ID equal to a minimum ID of the rated casing or tubing range +/-0.762 mm (+/- 0.030 in.). In the case where the minimum casing or tubing ID is less than the specified drift, the drift dimension shall be used as the fixture ID.

The actual ID of the test casing/fixture shall be recorded in the test report. The end of the test product shall be closed to direct all flow entering the fixture to flow around the outside of the product.

See Figures D.1 and D.2 for an illustration of an example test fixture.

Key 1 pressure gage 4 test chamber 2 product 5 ported extension 3 packing elements 6 top of product

Figure D.1 – Test setup for flow test from above

Key 1 pressure gage 4 test chamber 2 product 5 ported extension 3 packing elements 6 bottom of product

Figure D.2 – Test setup for flow test from below

D.4 Test Procedure

Conduct the external flow testing according to the following steps.


69

a) Perform a visual and dimensional inspection according to documented procedures.

b) The test fluid shall be a minimum of 82.2 °C (180 °F) throughout the testing.

c) Pump the heated test fluid through the fixture starting at the supplier/manufacturer defined starting flow rate for a minimum of 5 minutes, while monitoring pressure drop across the packing element.

d) Increase the flow rate step-wise until the flow rate meets or exceeds the supplier/manufacturer defined maximum external flow rate.

e) Pump the heated test fluid through the test fixture for a minimum of two hours at the defined maximum external flow rate.

f) The test is concluded when the pressure or flow rate meets the supplier’s/manufacturer’s stated ac-ceptance criteria.

g) Perform a visual and dimensional inspection according to documented procedures.

h) Perform steps a) through g) from the opposite direction of flow.

D.5 Report

A test report shall be prepared that includes, as a minimum:

a) identification of tool tested including, unique identifier and serial number as applicable;

b) date and location of testing;

c) procedures utilized and records required;

d) results of visual and dimensional inspection;

e) identification of personnel performing the test;

f) results of testing including comparison to the supplier/manufacturer acceptance criteria and discussion of the pertinent results;

g) approvals from a qualified person;

h) bill of materials and component’s traceability records;

i) measured casing/fixture ID;

j) test fixture orientation;

k) remarks (describing any non-specified equipment or procedures requested by manufacturer, unusual conditions observed during test, etc.).


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Annex E (informative)

Validation of Maximum Initiation Pressure for Hydrostatically Set Products

E.1 Scope

This annex includes the requirements for design validation for hydrostatic setting feature at maximum initiation pressure. This test does not establish product validation grade. Product validation grade requirements are in sections 6.5.6.

E.2 Design Validation Requirements

E.2.1 General

Activities required by this annex shall be performed by a qualified person(s). Results shall conform to the acceptance criteria and be supported by approved documentation.

The hydrostatic set product shall be validated with one of the methods listed below:

a) A test conducted in accordance with E.2.2;

b) A review of field performance of the product installed at initiation pressure within the tolerance of the setting device, in accordance with E.2.3.

NOTE Field performance test and review may not sufficiently evaluate all of the parameters that effect suc-cessful performance.

E.2.2 Validation Test

The supplier/manufacturer shall adhere to the following test parameters and criteria in Table E.1 for con-formance to this test.

Table E.1 – Maximum Initiation Pressure Test


a)

Assemble the product with the hydrostatic setting device and perform pre-test inspection.

The test media shall be in accordance with Table 5.

− Product Identification

− Date

− Description of Test Media

b) Set product at or above maximum rated temperature, using maximum rated initiation pressure.

− Fixture ID

− Pressure

− Temperature


71

It is acceptable for the tolerances associated with the initiation device to vary above or below the maximum allowable initia-tion pressure as per the manufacturers documented specifi-cations.

c) Perform a validation grade V4 or higher test with the excep-tion of setting at minimum rated setting force or pressure, per step b.

− Reference applicable Val-idation Grade Test Table

E.2.3 Field Performance Evaluation

Field performance evaluation shall be conducted and approved by qualified person(s). The evaluation shall include a minimum of seven installations. Data for the seven installations shall include:

a) Identification of product installed,

b) Rated initiation pressure,

c) Applied pressure,

d) Calculated hydrostatic pressure at setting depth,

e) Estimated temperature at setting depth, and

f) Results indicating successful product activation.

The maximum rated initiation pressure shall be the minimum of the applied plus hydrostatic pressure during the seven installations.

Records of the installations and evaluation establishing the maximum initiation pressure shall be available for review by the user/purchaser and shall become part of the design documentation of the product per 7.2.

E.2.4 Scaling

Scaling may be used to validate the maximum initiation pressure in a product family (see 6.8.1, 6.8.2) in accordance with all of the requirements below:

a) Equal to or less than maximum initiating pressure,

b) Equal to or less than maximum differential pressure rating,

c) Equal to or less than maximum setting force,

d) Equal to or less than maximum temperature rating, and

e) Equivalent initiating device mechanism.


72

Annex F (informative)

Determining Test Fixture ID

F.1 General

This annex may be used for determining the test fixture IDs (see 6.5.2.d.2 and B.3.3.4.4) and is based on API Specification 5CT.

F.2 Calculation of Test Fixture IDs

F.2.1 Casing and Tubing OD Tolerance

Per API 5CT, the OD tolerances based on nominal dimensions are as follows:

• For ODnom < 4-1/2”, +/- 0.79 mm (+/- 0.031 in) • For ODnom > 4-1/2”, (+1% / -0.5%)* ODnom

F.2.2 Mass Tolerance

Per API 5CT, the single length mass tolerances are +6.50% / -3.50%, or as specified.

F.2.3 Inside Diameter

F.2.3.1 General

Per API 5CT, the inside diameter is governed by the outside diameter and mass tolerances.

F.2.3.2 Maximum ID Calculations

Determine the fixture ID using the maximum OD and the minimum mass tolerances.

Two equations to determine the mass per unit length for maximum ID calculations are as follows (using -3.50% single length mass tolerance):

π / 4 * (ODmax2 – IDmax2) * ϱ

π / 4 * (ODnom2 – IDnom2) * ϱ * .965

Setting the two equations equal to each other and simplifying gives:

(ODmax2 – IDmax2) = (ODnom2 – IDnom2) * .965

Solving for IDmax:


73

𝑰𝑰𝑰𝑰𝒎𝒎𝒎𝒎𝒎𝒎 = �𝑶𝑶𝑰𝑰𝒎𝒎𝒎𝒎𝒎𝒎 𝟐𝟐 − .𝟗𝟗𝟗𝟗𝟗𝟗 ∗ (𝑶𝑶𝑰𝑰𝒏𝒏𝒏𝒏𝒎𝒎

𝟐𝟐 − 𝑰𝑰𝑰𝑰𝒏𝒏𝒏𝒏𝒎𝒎 𝟐𝟐)

F.2.3.3 Minimum ID Calculations

The fixture ID shall be the greater of API drift or the minimum casing ID using the minimum casing OD and the maximum mass tolerances.

Two equations to determine the casing mass per unit length for minimum ID calculations are as follows (using +6.50% single length mass tolerance):

π / 4 * (ODmin2 – IDmin2) * ϱ

π / 4 * (ODnom2 – IDnom2) * ϱ * 1.065

Setting the two equations equal to each other and simplifying gives:

(ODmin2 – IDmin2) = (ODnom2 – IDnom2) * 1.065

Solving for IDmin:

𝑰𝑰𝑰𝑰𝒎𝒎𝒎𝒎𝒏𝒏 = �𝑶𝑶𝑰𝑰𝒎𝒎𝒎𝒎𝒏𝒏 𝟐𝟐 − 𝟏𝟏.𝟎𝟎𝟗𝟗𝟗𝟗 ∗ (𝑶𝑶𝑰𝑰𝒏𝒏𝒏𝒏𝒎𝒎

𝟐𝟐 − 𝑰𝑰𝑰𝑰𝒏𝒏𝒏𝒏𝒎𝒎 𝟐𝟐)


74

Annex G (informative)

Tubing-To-Packer Forces and Rated Performance Envelopes G.1 General

This annex is intended to provide guidance to users/purchasers on how to accurately compare tubing-to-packer forces to rated performance envelopes. This annex is not intended to train the reader on how to perform tubing-to-packer force calculations. The generation of rated performance envelopes is covered by section 6.3.4.2.

There may be variation on how rated performance envelopes are generated with respect to which seal diameters (3.27) are used for the underlying analysis behind the rated performance envelopes. Variation of the seal diameter has a direct impact on the size and shape of a packer’s rated performance envelope. This same seal diameter is also a key factor in tubing movement calculations and subsequently tubing-to-packer force calculations. As a consequence, there is potential for misalignment between how rated per-formance envelopes are used in conjunction with tubing movement calculations; this annex is intended to inform the reader about this potential for misalignment.

Where the tubing-to-packer interface and/or geometries differ from the following examples, further evalua-tion is recommended.

G.2 The Basic Effects

When temperatures and/or pressures change in a wellbore, conditions are created which will cause the tubing string to change its length. The tubing will either shorten or elongate. If the tubing string is con-strained (e.g., anchored at the packer) forces are generated on both the packer and the wellhead be-cause the end of the tubing is prevented from moving freely.

There are four different effects that create these length changes. All of these effects need to be combined together to get the total effect for the packer installation. The four tubing movement effects are:

a) piston effect (including buoyancy)

b) buckling effect

c) ballooning effect

d) temperature effect

The piston effect, buckling effect, and ballooning effect result from changes in conditions in the system. The temperature effect is related only to temperature change of the pipe. While some of the effects are related to each other, each must be calculated independently. Each effect will have a magnitude and di-rection. Once each effect is known, they are combined along with any mechanically applied loads (such as slack off or overpull after the packer is set); this total force is called the tubing-to-packer force.


75

The components of the tubing-to-packer forces can be calculated either by hand or by using tubing move-ment simulation software or programs. In either case, it is important to ensure that the tubing connection to the packer is correctly defined, both in geometry, and in how it is engaged to the packer.

The interpretation of tubing-to-packer force outputs when used with a rated performance envelope is cov-ered in section G.9.

G.3 Typical Tubing-to-Packer Connection Types

The calculation of the tubing-to-packer load on the packer will depend on the type of tubing-to-packer connection being considered.

The connection type defines if, and how, tubing movement may be restricted. If tubing movement is re-stricted, tubing movement programs convert the movement into loads at the top of the packer. As illus-trated in Figure G.1, for the purpose of tubing movement analysis, tubing-to-packer connections can be categorized as follows:

a) Integral connection(s) which permits no tubing lengthening or shortening. The packer is threaded directly to the tubing. Tubing movement fully constrained.

b) Seal assembly which permits limited tubing lengthening or shortening. The tubing is terminated using a seal assembly that mates with seal surface within the packer. Limited tubing movement is accommodated between an upper and lower constraint, limited can be defined as zero allow-able movement in the case of anchored seal assemblies.

c) Stroke through seal bore packers which permit tubing lengthening or shortening. The tubing is terminated using a seal assembly that passes through the packer, without mechanical inter-action with the packer. Additional tubing may be attached to the bottom of the seal assembly. Large tubing movements are accommodated as long as the seal assembly maintains sealing engagement with the packer seal bore throughout its movement.


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INTEGRAL CONNECTIONS

SEAL BORE PACKER W/ TAILPIPE

STROKE THROUGH SEAL BORE PACKER

Figure G.1 – Typical Tubing-to-Packer Connection Types

G.4 Seal Diameter

Tubing-to-packer forces include all the loads being applied to the top of the packer as a result of the tub-ing movement effects listed in section F.2. The rated performance envelope for the packer will account for all internal hydraulic forces acting on the packer, whereas the tubing movement calculations should ac-count for all hydraulic forces acting on the tubing.

Differentiating between internal loads on the packer versus hydraulically-induced loads on the tubing is accomplished by defining a seal diameter, to which packer loads and tubing loads can be calculated.

Internal hydraulically-induced packer loads will result from pressures acting on packer components be-tween the casing ID and the seal diameter and will be accounted for in the rated performance envelope.

Hydraulic effects acting on the tubing, defined by the hydraulic area up to the seal diameter shall be in-cluded when calculating the tubing-to-packer forces.

The seal diameter is defined by the supplier/manufacturer and may be displayed on the rated perfor-mance envelope, product data sheet (see 7.2.3), in specifications, or communicated by the supplier/man-ufacturer to the user/purchaser directly.

Typically, packers with seal bores define the seal diameter as the seal bore diameter. However, for pack-ers with integral connections, the seal diameter may align with key diameters such as:

— Tubing OD, or

— Reference diameter used for a particular packer chassis (such as mandrel OD under the ele-ments).


77

NOTE The seal diameter has a direct impact on the magnitude of the tubing-to-packer forces as well as the size and shape of a rated performance envelope.

NOTE Tubing-to-packer forces calculated based on one rated performance envelope’s seal diameter cannot be used to evaluate a different rated performance envelope with a different seal diameter.

NOTE A supplier/manufacturer may utilize a different seal diameter for differential pressures from above or below.


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G.5 Seal Diameter Equivalent to Tubing OD

When a supplier/manufacturer defines a seal diameter to be equivalent to tubing OD for a packer, the rated performance envelope accounts for all internal hydraulically-induced loads generated on the packer from casing ID to tubing OD for pressure differentials acting on the packer from either above or below.

As illustrated in Figure G.2, tubing movement calculations should include all loads generated on the tub-ing due to pressure differentials from below acting on the hydraulic area defined by the tubing ID to the tubing OD.

For pressure differentials from above, due to the seal diameter being equal to the tubing OD, there are no additional hydraulic areas created at the top tubing-packer interface that need to be compensated for in addition to the already accounted for loads created by any tubing size changes above the tubing-packer interface (e.g. tapered string).

HYDRAULIC FORCES EVALUATED BY SUPPLIER/MANUFACTURER AND INCLUDED IN RATED PERFORMANCE ENVELOPE

HYDRAULIC FORCES EVALUATED BY USER/PURCHASER AND INCLUDED IN TUBING-TO-

PACKER FORCES (PISTON EFFECT)

Packer Mandrel

Tubing Connection

Below

Tubing Connection

Above



ALL TUBING MOVEMENT EFFECTS CALCULATED ON THE TUBING FROM THE TUBING HANGER

DOWN TO THE TUBING-PACKER INTERFACE ARE ACCOUNTED FOR BY THE TUBING-TO-PACKER

FORCE CALCULATION

Tubing OD

Figure G.2 – Seal Diameter Equivalent to Tubing OD


79

G.6 Seal Diameter Larger Than Tubing OD

When a supplier/manufacturer defines a seal diameter to be equivalent to a reference diameter which is larger than the tubing OD for a packer, the rated performance envelope accounts for all internal hydrau-lically-induced loads generated on the packer from casing ID to the reference diameter for pressure differ-entials acting on the packer from either above or below.

As illustrated in Figure G.3, tubing movement calculations should include all loads generated on the tub-ing due to pressure differentials from below acting on the hydraulic area defined by the tubing ID to the reference diameter. The calculations should also include all loads generated on the tubing due to pres-sure differentials from above acting on the hydraulic area defined by the tubing OD to the reference diam-eter.

HYDRAULIC FORCES EVALUATED BY SUPPLIER/MANUFACTURER AND INCLUDED

IN RATED PERFORMANCE ENVELOPEHYDRAULIC FORCES EVALUATED

BY USER/PURCHASER AND INCLUDED IN TUBING-TO-


Packer Mandrel

Tubing Connection

Below

Tubing Connection

Above



Tubing OD

Reference Diameter

Figure G.3 – Seal Diameter Equivalent to Reference Diameter (Larger Than Tubing OD)


80

G.7 Seal Diameter Equivalent to Packer ID or Tubing ID

When a supplier/manufacturer defines a seal diameter to be equivalent to the packer ID or tubing ID for a packer, the rated performance envelope accounts for all internal hydraulically-induced loads generated on the packer from casing ID to the tubing ID or packer ID for pressure from below. For pressure from above, the rated performance envelope accounts for all hydraulically-induced loads generated on the packer from the Casing ID to the tubing OD.

As illustrated in Figure G.4, standard tubing movement calculations and the rated performance envelope may conflict with respect to hydraulically-induced loads acting on the tubing cross-section. The tubing movement calculations or rated performance envelope may have redundant hydraulically-induced forces.

HYDRAULIC FORCES EVALUATED BY SUPPLIER/MANUFACTURER AND INCLUDED IN RATED

PERFORMANCE ENVELOPE

HYDRAULIC FORCES EVALUATED BY SUPPLIER/MANUFACTURER AND INCLUDED IN RATED PERFORMANCE

ENVELOPE MAY OVERLAP WITH TUBING-TO-PACKER FORCES (PISTON EFFECT) EVALUATED BY USER/PURCHASER

Packer Mandrel

Tubing Connection

Below

Tubing Connection

Above



ALL TUBING MOVEMENT EFFECTS CALCULATED ON THE TUBING FROM THE TUBING HANGER

DOWN TO THE TUBING-PACKER INTERFACE ARE ACCOUNTED FOR BY THE TUBING-TO-PACKER

FORCE CALCULATION

Tubing OD

Figure G.4 – Seal Diameter Equivalent to Packer ID or Tubing ID


81

G.8 Seal Bore Packers

Seal bore packers typically define the seal diameter as the packer’s seal bore diameter.

Tubing movement calculations typically account for all loads acting on the tubing, and include hydraulically-induced loads acting on the seal assembly that is sealing inside the packer’s seal bore. If the seal assembly is anchored into the packer, the loads that are transferred into the packer by the anchor, or by the no-go, should be included in the tubing-to-packer forces.

As illustrated in Figures G.5 & G.6, if the packer has tubing attached below, the piston effects acting on the tubing, if any, should be included within the tubing movement calculations.

In addition to the tubing-to-packer forces, tubing movement calculations should also include the loads acting on the anchor mechanism (if applicable) to evaluate the operational limitations of such devices.




Tubing Connection

Below

Packer Mandrel

Packer Seal Bore



LOAD ON ANCHOR (IF APPLICABLE) EVALUATED BY USER/PURCHASER

WHEN CALCULATING TUBING MOVEMENT FORCES

Figure G.5 – Seal Bore Packers with Tailpipe – Tubing OD Smaller Than or Equal to Packer Seal Bore ID.




Packer Mandrel

Packer Seal BoreLOAD ON ANCHOR (IF APPLICABLE)

EVALUATED BY USER/PURCHASER WHEN CALCULATING TUBING

MOVEMENT FORCES

Figure G.6 – Stroke Through Packers – Tubing OD Smaller or Equal to Packer Seal Bore ID


82

G.9 Rated Performance Envelopes and Seal Diameters

Referring to the definition of rated performance envelopes in Section 6.3.4, the vertical axis of the rated performance envelope represents the tubing-to-packer force being applied to the top of the packer, and the horizontal axis represents the differential pressure acting on the packer. The combination of differen-tial pressure and tubing-to-packer force acting on the packer should be compared to the rated perfor-mance envelope. If the combined load falls on or within the rated performance envelope, the packer oper-ational limits are not exceeded. If the combined load falls outside of the rated performance envelope, the packer maximum operational limits may be exceeded.

Rated performance envelopes for a packer are generated using a specific seal diameter(s) even if the seal diameter(s) is/are not listed on the rated performance envelope or product data sheet. If another rated performance envelope has been generated based on (a) different seal diameter(s) for the same packer, the rated performance envelope should be reviewed by a qualified person to ensure that the rated performance envelope’s intersection points represent the loads that were originally validated. Figure F.7 is an example of a rated performance envelope for the same packer generated using three different seal diameters. The outer rated performance envelope represents a packer with a seal diameter equivalent to a reference diameter such as a mandrel OD under the elements. The intermediate rated performance en-velope represents the same packer with a seal diameter equal to tubing OD. The inner rated performance envelope represents the same packer with a seal diameter equivalent to tubing ID. The rated perfor-mance envelope’s intersection points represent the same loads that were originally validated. Refer to section G.4 – Seal Diameter, for further explanation on why the rated performance envelopes are differ-ent.

Figure G.7 – Packer Rated Performance Envelope Using Three Different Seal Diameters


83

Figures G.8 and G.9 illustrate two rated performance envelopes for the same packer, with the first rated performance envelope having a seal diameter equal to tubing OD, and the second rated performance en-velope having a seal diameter equal to tubing ID. The rated performance envelopes also contain opera-tional loads calculated using the same respective seal diameters.

-55,603

-44,482

-33,362

-22,241

-11,121

0

11,121

22,241-55.16 -41.37 -27.58 -13.79 0 13.79 27.58 41.37 55.16

-125,000

-100,000

-75,000

-50,000

-25,000

0

25,000

50,000

-8,000 -6,000 -4,000 -2,000 0 2,000 4,000 6,000 8,000

(Com

pres

sive

) F

OR

CES

(daN

) (T

ensi

le)

(Above) PRESSURE (MPa) (Below)

(Com

pres

sive

) F

OR

CES

(lbs

) (T

ensi

le)

(Above) PRESSURE (psi) (Below)

Tubing OD

Load Point Calculated using Tubing OD

Figure G.8 – Seal Diameter Equal to Tubing OD


84

-55,603

-44,482

-33,362

-22,241

-11,121

0

11,121

22,241-55.16 -41.37 -27.58 -13.79 0 13.79 27.58 41.37 55.16

-125,000

-100,000

-75,000

-50,000

-25,000

0

25,000

50,000

-8,000 -6,000 -4,000 -2,000 0 2,000 4,000 6,000 8,000

(Com

pres

sive

) F

OR

CES

(daN

) (T

ensi

le)


(Com

pres

sive

) F

OR

CES

(lbs

) (T

ensi

le)


Tubing ID

Load Point Calculated using Tubing ID

Figure G.9 – Seal Diameter Equal to Tubing ID

When different seal diameters are used for the rated performance envelope and the calculation of tubing-to-packer forces, incorrect assessments will result. An example of this situation can be seen in Figure G.10, which illustrates the rated performance envelope from Figure G.9, using a seal diameter equal to tubing ID. Figure G.10 also includes an operational load point from Figure G.8, calculated using a seal diameter equal to tubing OD instead of tubing ID.

In this example, the operational load cannot be accurately compared to the performance limits of the packer due to the differences in the seal diameter.


85

-55,603

-44,482

-33,362

-22,241

-11,121

0

11,121

22,241-55.16 -41.37 -27.58 -13.79 0 13.79 27.58 41.37 55.16

-125,000

-100,000

-75,000

-50,000

-25,000

0

25,000

50,000

-8,000 -6,000 -4,000 -2,000 0 2,000 4,000 6,000 8,000

(Com

pres

sive

) F

OR

CES

(daN

) (T

ensi

le)


(Com

pres

sive

) F

OR

CES

(lbs

) (T

ensi

le)


Tubing ID

Load Point Calculated using Tubing OD

Figure G.10 – Rated Performance Envelope Using Tubing ID Seal Diameter with Operational Load Using Tubing OD as Seal Diameter


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87

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