BS EN 13480-8-2012+A1-2014 Metallic industrial piping - Part 8 Additional requirements for alumi

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 Incorporating corrigendum October 2014 BS EN 13480-8:2012

BSI Standards Publication

Metallic industrial piping Part 8: Additional requirements for aluminium and aluminium alloy piping

BS EN 13480-8:2012+A1:2014

BRITISH STANDARD National foreword This British Standard is the UK implementation of EN 13480-8:2012+A1:2014. It supersedes BS EN 13480-8:2012 which is withdrawn. Changes introduced in the text by CEN are indicated in the text by sidelines. The UK participation in its preparation was entrusted to Technical Committee PVE/10, Piping systems. A list of organizations represented on this committee can be obtained on request to its secretary. This publication does not purport to include all the necessary provisions of a contract. Users are responsible for its correct application. © The British Standards Institution 2014. Published by BSI Standards Limited 2014 ISBN 978 0 580 84549 9 ICS 23.040.01

Compliance with a British Standard cannot confer immunity from legal obligations. This British Standard was published under the authority of the Standards Policy and Strategy Committee on 31 December 2012.

Amendments/corrigenda issued since publication Date

Text affected

31 July 2014 Implementation of CEN amendment A1:2014 31 October 2014 Implementation of CEN Correction Notice 27 August 2014: See details in Annex Y

EN 13480-8 EN 13480-8:2012+A1

EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM

May June2014 2012 Supersedes EN EN 13480-8:2007 13480-8:2012 Supersedes

ICS 23.040.01

English Version

Metallic industrial piping - Part 8: Additional requirements for aluminium and aluminium alloy piping Tuyauteries industrielles métalliques - Partie 8: Exigences complémentaires relatives aux tuyauteries en aluminium et alliages d'aluminium

Metallische industrielle Rohrleitungen - Teil 8: Zusatzanforderungen an Rohrleitungen aus Aluminium und Aluminumlegierungen

This European Standard was approved by CEN on 8 May 2012. CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CEN member. This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management Centre has the same status as the official versions. CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.

EUROPEAN COMMITTEE FOR STANDARDIZATION COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG

Management Centre: Avenue Marnix 17, B-1000 Brussels

© 2012 CEN

All rights of exploitation in any form and by any means reserved worldwide for CEN national Members.

Ref. No. EN 13480-8:2012: E

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue 33(2014-08) Issue (2014-08)

Contents

Page

Foreword ..............................................................................................................................................................5 1

Scope ......................................................................................................................................................7

2

Normative references ............................................................................................................................7

3

Terms, definitions, symbols and units ................................................................................................9

4

General requirements ............................................................................................................................9

5 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8 5.9 5.10 5.11

Materials .................................................................................................................................................9 General....................................................................................................................................................9 Material grouping system .....................................................................................................................9 Elongation after fracture .....................................................................................................................10 Chemical composition ........................................................................................................................11 Lamellar tearing ...................................................................................................................................11 Design temperature and properties ...................................................................................................11 Prevention of brittle fracture ..............................................................................................................11 Specific requirements for fasteners made of aluminium and aluminium alloys ..........................12 Lined piping..........................................................................................................................................12 Clad products .......................................................................................................................................12 Technical delivery conditions for welding consumables ................................................................12

6 6.1 6.2 6.3 6.4 6.5 6.6 6.7 6.7.1 6.7.2 6.7.3

Design ...................................................................................................................................................12 General..................................................................................................................................................12 Time-independent nominal design stress .........................................................................................12 Straight pipes .......................................................................................................................................13 Pipe bends and elbows .......................................................................................................................13 Mitre bends ...........................................................................................................................................13 Socket welds ........................................................................................................................................14 Designing with transition joints .........................................................................................................15 Design considerations ........................................................................................................................15 Location of transition joints ...............................................................................................................15 Requirements for transition joints .....................................................................................................15

7 7.1 7.2 7.3 7.3.1 7.3.2 7.4 7.5 7.5.1 7.5.2 7.5.3 7.5.4 7.6 7.6.1 7.6.2 7.6.3 7.6.4 7.6.5 7.6.6

Fabrication and installation ................................................................................................................15 General..................................................................................................................................................15 Material grouping .................................................................................................................................16 Tolerances ............................................................................................................................................16 Welded pipes and connection dimensions of pipe fittings .............................................................16 Welded piping construction ...............................................................................................................16 Cutting and bevelling ..........................................................................................................................16 Bending and other forming.................................................................................................................17 General..................................................................................................................................................17 Definition of cold- and hot forming ....................................................................................................17 Heat treatment after cold forming ......................................................................................................17 Heat treatment after hot forming ........................................................................................................18 Welding .................................................................................................................................................19 Welding personnel ...............................................................................................................................19 Welding processes ..............................................................................................................................19 Weld joint preparation .........................................................................................................................19 Preheating ............................................................................................................................................20 Backing rings and backing strips ......................................................................................................21 Post-weld heat treatment (PWHT) ......................................................................................................21

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8 8.1 8.2 8.2.1 8.2.2 8.2.3 8.3 8.4 8.4.1 8.4.2 8.4.3 8.5 8.6

Inspection and testing ........................................................................................................................ 21 General ................................................................................................................................................. 21 Formed pressure retaining parts ....................................................................................................... 21 General ................................................................................................................................................. 21 Testing of formed parts ...................................................................................................................... 22 Destructive testing of formed and heat treated parts ...................................................................... 22 Welding ................................................................................................................................................. 23 Visual and non-destructive testing of welds .................................................................................... 23 Application of NDT .............................................................................................................................. 23 Circumferential, branch, socket and seal welds .............................................................................. 23 Longitudinal welds and spiral welded tubes/pipes ......................................................................... 24 VT and NDT Methods .......................................................................................................................... 24 Production test plates for welded pipes ........................................................................................... 25

9 9.1 9.2 9.3

Final assessment and documentation .............................................................................................. 26 General ................................................................................................................................................. 26 Pneumatic pressure test ..................................................................................................................... 27 Documentation for components ........................................................................................................ 27

Annex A (informative) Dimensional tolerances............................................................................................ 29 Annex B (normative) Transition joints .......................................................................................................... 31 Annex C (normative) Nominal design stress values ................................................................................... 31 Annex Y (informative) History of EN 13480-8 ............................................................................................... 42 Annex ZA (informative) Relationship between this European Standard and the Essential Requirements of EU Directive 97/23/EC ............................................................................................ 43 Bibliography ...................................................................................................................................................... 44 Figures Figure 6.5-1 — Mitre bend.................................................................................................................................. 14 Figure 7.6.3.1 — Socket welds .......................................................................................................................... 20 Figure A.1 — Dimensional details of spools....................................................................................................... 30 Tables Table 5.2-1 — Grouping system based on CEN ISO/TR 15608:2005 and EN AW numbers according to EN 573-3:2009 ............................................................................................................................................ 10 Table 6.2-1 — Design stresses for aluminium and aluminium alloy material .................................................... 12 Table 6.2-2 — Allowable design strength values for 6 000 series aluminium alloys in the welded condition (see 5.6) .............................................................................................................................................................. 13 Table 6.5-1 — Special symbols for subclause 6.5 ............................................................................................. 14 Table 7.3-1 — Tolerances for welded pipes....................................................................................................... 16 Table 7.5-1 — Heat treatment of flat products after cold forming ...................................................................... 18 Table 7.5-3 — Heat treatment after hot forming................................................................................................. 19 Table 8.2-1 — Destructive testing of formed and heat treated parts ................................................................. 23

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Table 8.4-1 — Extent of testing for circumferential, branch, socket and seal welds ......................................... 24 Table 8.4-2 — Extent of VT and NDT for longitudinal welds and spiral welded tubes/pipes ............................ 24 Table 8.5-1 — Techniques, methods, acceptance criteria ................................................................................ 25 Table 8.6-1 — Production test plates for welded pipes according to 8.6 a) ...................................................... 26 Table 8.6-2 — Required tests and acceptance criteria for production test plates ............................................. 26 Table 9.2-1 — Extent of NDT in case of pneumatic pressure test according to 9.2b) ...................................... 27 Table A.1 — Tolerances .................................................................................................................................... 29 Table B.1 — Testing of transition joints (T.J.) ................................................................................................... 34 Table C.1 — Extruded rod/bar, tube and profile ................................................................................................ 36 Table C.2 — Cold drawn rod/bar and tube ........................................................................................................ 37 Table C.3 — Forgings ........................................................................................................................................ 38 Table C.4 — Plate.............................................................................................................................................. 39 Table ZA.1 — Correspondence between this European Standard and Directive 97/23/EC ............................. 43

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Foreword This document (EN 13480-8:2012) has been prepared by Technical Committee CEN/TC 267 “Industrial piping and pipelines”, the secretariat of which is held by AFNOR. This European Standard shall be given the status of a national standard, either by publication of an identical text or by endorsement, at the latest by December 2012, and conflicting national standards shall be withdrawn at the latest by December 2012. Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights. CEN [and/or CENELEC] shall not be held responsible for identifying any or all such patent rights. This document has been prepared under a mandate given to CEN by the European Commission and the European Free Trade Association, and supports essential requirements of EU Directive(s). For relationship with EU Directive(s), see informative Annex ZA, which is an integral part of this document. This European Standard EN 13480 for metallic industrial piping consists of eight interdependent and not dissociable Parts which are:

 Part 1: General;  Part 2: Materials;  Part 3: Design and calculation;  Part 4: Fabrication and installation;  Part 5: Inspection and testing;  Part 6: Additional requirements for buried piping; CEN/TR 13480-7, Guidance on the use of conformity assessment procedures;

 Part 8: Additional requirements for aluminium and aluminium alloy piping. Although these Parts may be obtained separately, it should be recognised that the Parts are inter-dependant. As such the manufacture of metallic industrial piping requires the application of all the relevant Parts in order for the requirements of the Standard to be satisfactorily fulfilled. This European Standard will be maintained by a Maintenance MHD working group whose scope of working is limited to corrections and interpretations related to EN 13480. The contact to submit queries can be found at http://www.unm.fr ([email protected]). A form for submitting questions can be downloaded from the link to the MHD website. After subject experts have agreed an answer, the answer will be communicated to the questioner. Corrected pages will be given specific issue number and issued by CEN according to CEN Rules. Interpretation sheets will be posted on the website of the MHD.

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This document supersedes EN 13480-8:2007+A1:2011. This new edition incorporates the Amendments/the corrigenda which have been approved previously by CEN members, and the corrected pages up to Issue 17 without any further technical change. Annex Y provides details of significant technical changes between this European Standard and the previous edition. Amendments to this new edition may be issued from time to time and then used immediately as alternatives to rules contained herein. It is intended to deliver a new Issue of EN 13480:2012 each year, consolidating these Amendments and including other identified corrections. Issue 3 (2014-08) consolidates Amendment EN 13480-8:2012/A1:2014; it includes the corrected pages listed in Annex Y. According to the CEN/CENELEC Internal Regulations, the national standards organizations of the following countries are bound to implement this European Standard: Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and the United Kingdom.

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1

Scope

This Part of EN 13480 specifies requirements for industrial piping systems made of aluminium and aluminium alloys in addition to the general requirements for industrial piping according to the series of standards EN 13480 and CEN/TR 13480-7.

2

Normative references

The following documents, in whole or in part, are normatively referenced in this document and are indispensable for its application. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies. EN 485-2:2013, Aluminium and aluminium alloys — Sheet, strip and plate — Part 2: Mechanical properties EN 485-3, Aluminium and aluminium alloys — Sheet, strip and plate — Part 3: Tolerances on dimensions and form for hot-rolled products EN 485-4, Aluminium and aluminium alloys — Sheet, strip and plate — Part 4: Tolerances on shape and dimensions for cold-rolled products EN 571-1:1997, Non-destructive testing — Penetrant testing — Part 1: General principles EN 573-3:2009, Aluminium and aluminium alloys — Chemical composition and form of wrought products — Part 3: Chemical composition and form of products EN 583-1:1998, Non-destructive testing — Ultrasonic examination — Part 1: General principles EN 583-2:2001, Non-destructive testing — Ultrasonic examination — Part 2: Sensitivity and range setting EN 583-3:1997, Non-destructive testing — Ultrasonic examination — Part 3: Transmission technique EN 583-4:2002, Non-destructive testing — Ultrasonic examination — Part 4: Examination for discontinuities perpendicular to the surface EN 583-5:2000, Non-destructive testing — Ultrasonic examination — Part 5: Characterization and sizing of discontinuities EN 583-6:2008, Non-destructive testing — Ultrasonic examination — Part 6: Time-of-flight diffraction technique as a method for detection and sizing of discontinuities EN 586-2:1994, Aluminium and aluminium alloys — Forgings — Part 2: Mechanical properties and additional property requirements EN 754 (all parts), Aluminium and aluminium alloys — Cold drawn rod/bar and tube EN 755 (all parts), Aluminium and aluminium alloys — Extruded rod/bar, tube and profiles EN 764-3, Pressure equipment — Part 3: Definition of parties involved EN 1321:1996, Destructive tests on welds in metallic materials — Macroscopic and microscopic examination of welds

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EN 1435:1997, Non-destructive examination of welds — Radiographic examination of welded joints EN 1779:1999, Non-destructive testing — Leak testing — Criteria for method and technique selection EN 10204:2004, Metallic products — Types of inspection documents EN 10246-9:2000, Non-destructive testing of steel tubes — Part 9: Automatic ultrasonic testing of the weld seam of submerged arc-welded steel tubes for the detection of longitudinal and/or transverse imperfections EN 10246-16:2000, Non-destructive testing of steel tubes — Part 16: Automatic ultrasonic testing of the area adjacent to the weld seam of welded steel tubes for the detection of laminar imperfections EN 12392:2000, Aluminium and aluminium alloys — Wrought products — Special requirements for products intended for the production of pressure equipment EN 13445-4:2009, Unfired pressure vessels — Part 4: Fabrication EN 13480-1:2012, Metallic industrial piping — Part 1: General EN 13480-2:2012, Metallic industrial piping — Part 2: Materials EN 13480-3:2012, Metallic industrial piping — Part 3: Design and calculation EN 13480-4:2012, Metallic industrial piping — Part 4: Fabrication and installation EN 13480-5:2012, Metallic industrial piping — Part 5: Inspection and testing EN ISO 148-1:2010, Metallic materials — Charpy pendulum impact test — Part 1: Test method (ISO 148-1:2009) EN ISO 3834-2:2005, Quality requirements for fusion welding of metallic materials — Part 2: Comprehensive quality requirements (ISO 3834-2:2005) EN ISO 3834-3:2005, Quality requirements for fusion welding of metallic materials — Part 3: Standard quality requirements (ISO 3834-3:2005) EN ISO 4063:2010, Welding and allied processes — Nomenclature of processes and reference numbers (ISO 4063:2009, Corrected version 2010-03-01) EN ISO 4136:2011, Destructive tests on welds in metallic materials — Transverse tensile test (ISO 4136:2001) EN ISO 5173:2010, Destructive tests on welds in metallic materials — Bend tests (ISO 5173:2009) EN ISO 6892-1:2009, Metallic materials — Tensile testing — Part 1: Method of test at room temperature (ISO 6892-1:2009) EN ISO 6892-2:2011, Metallic materials — Tensile testing — Part 2: Method of test at elevated temperature (ISO 6892-2:2011) EN ISO 7438:2005, Metallic materials — Bend test (ISO 7438:2005) EN ISO 9606-2:2004, Qualification test of welders — Fusion welding — Part 2: Aluminium and aluminium alloys (ISO 9606-2:2004)

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EN ISO 10042:2005, Welding — Arc-welded joints in aluminium and its alloys — Quality levels for imperfections (ISO 10042:2005) EN ISO 11666:2010, Non-destructive testing of welds — Ultrasonic testing — Acceptance levels (ISO 11666:2010) EN ISO 15614-2:2005, Specification and qualification of welding procedures for metallic materials — Welding procedure test — Part 2: Arc welding of aluminium and its alloys (ISO 15614-2:2005) EN ISO 17637:2011, (ISO 17637:2003)

Non-destructive

testing

of

welds

—

Visual

testing

of

fusion-welded

joints

EN ISO 17640:2010, Non-destructive testing of welds — Ultrasonic testing — Techniques, testing levels, and assessment (ISO 17640:2010) EN ISO 23277:2009, Non-destructive testing of welds — Penetrant testing of welds — Acceptance levels (ISO 23277:2006) CEN ISO/TR 15608:2005, (ISO/TR 15608:2005)

Welding

—

Guidelines

for

a

metallic

materials

grouping

system

ISO 857-1:1998, Welding and allied processes — Vocabulary — Part 1: Metal welding processes

3

Terms, definitions, symbols and units

For the purposes of this document, the terms, definitions, symbols and units of EN 13480-1:2012, EN 13480-2:2012, EN 13480-3:2012, EN 13480-4:2012 and EN 13480-5:2012 apply.

4

General requirements

The general requirements of EN 13480-1 shall apply.

5 5.1

Materials General

Materials for pressure-bearing parts compliant with the requirements of this European Standard shall be accompanied by inspection documents in accordance with EN 10204:2004. The type of inspection document should be in accordance with EN 764-5:2002 and include a declaration of compliance to the material specification. The requirements of EN 13480-2:2012 shall apply with the following additions/exclusions:

5.2

Material grouping system

Annex A of EN 13480-2:2012 is not applicable for aluminium and aluminium alloys. The allowable materials for industrial piping of aluminium and aluminium alloys shall be according to Table 5.2-1. Any product form available in the EN standards referenced in Annex C for a material and temper listed in Table 5.2-1 is acceptable for construction to this European Standard. Other materials not defined here may be used by agreement (see EN 13480-2:2012, 4.3) if they meet the requirements of 5.2 and 5.3 of this standard and a Particular Material Appraisal is produced (see EN 764-4:2002).

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Table 5.2-1 — Grouping system based on CEN ISO/TR 15608:2005 and EN AW numbers according to EN 573-3:2009 Group

Sub group

21

22

Pure aluminium with ≤ 1 % impurities or alloy content

Designation EN AW number

Chemical symbol

Temper

EN AW – 1050A

EN AW–Al 99,5

O, H111, H112

EN AW – 1070A

EN AW–Al 99,7

O, H111, H112

EN AW – 1080A

EN AW–Al 99,8(A)

O, H111, H112

EN AW – 3003

EN AW–Al Mn1Cu

O, H111, H112

EN AW – 3103

EN AW–Al Mn1

O, H111, H112

EN AW – 3105

EN AW–Al Mn0,5Mg0,5

O, H111

EN AW – 5005

EN AW–Al Mg1(B)

O, H111, H112

EN AW – 5005A

EN AW–Al Mg1(C)

O, H111, H112

EN AW – 5050

EN AW–Al Mg1,5 (C)

O, H111

EN AW – 5049

EN AW–Al Mg2Mn0,8

O, H111, H112

EN AW – 5052

EN AW–Al Mg2,5

O, H111, H112

EN AW – 5154A

EN AW–Al Mg3,5(A)

O, H111, H112

EN AW – 5251

EN AW–Al Mg2

O, H111, H112

EN AW – 5454

EN AW–Al Mg3Mn(A)

O, H111, H112

EN AW – 5754

EN AW–Al Mg3

O, H111, H112

EN AW – 5083

EN AW–Al Mg4,5Mn0,7

O, H111, H112

EN AW – 5086

EN AW–Al Mg4

O, H111

EN AW 6060

EN AW–Al MgSi

T4a

EN AW 6061

EN AW–Al Mg1SiCu

T4b, T6c

Non heat treatable alloys 22.1

22.2

22.3

22.4 23

Type of aluminium and aluminium alloys

Aluminium-manganese alloys

Aluminium-magnesium alloys with Mg ≤ 1,5 % Aluminium-magnesium alloys with 1,5 % < Mg ≤ 3,5 %

Aluminium-magnesium alloys with Mg > 3,5 %

Heat treatable alloys 23.1

Aluminium-magnesium-silicon alloys

a for seamless pipes and profiles only b for seamless pipes and flanges only c for flanges only

5.3

Elongation after fracture

Aluminium and aluminium alloys used for parts of industrial piping that are subjected to cold forming shall have a specified minimum elongation after fracture measured on a gauge length Lo  5,65 S o

(5.3-1)

that is  14 % in the longitudinal or transverse direction as defined by the material specification. Aluminium and aluminium alloys used for parts of industrial piping that are not subjected to cold forming (e.g. straight flanges and nozzles) shall have a specified minimum elongation after fracture measured on a gauge length

Lo  5,65 S o that is  10 % in the longitudinal or transverse direction as defined by the material specification.

10

(5.3-2)

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5.4

Chemical composition

The chemical composition shall be in accordance with the material specification. NOTE EN 12392:2000, 5.1.3 recommends a maximum hydrogen level of 0,2 ml per 100 g aluminium, measured in the liquid metal during casting for parts to be welded. EN 12392:2000, 4.1, recommends a maximum lead content not exceeding 150 μg/g.

5.5

Lamellar tearing

Specific requirements to avoid lamellar tearing for industrial piping of aluminium and aluminium alloys are not applicable. NOTE Specific requirements apply to steel (see EN 1011-2:2001) whereas in EN 1011-4:2000 no requirement is given because lamellar tearing is not a recognized phenomenon.

5.6

Design temperature and properties

NOTE 1

See also EN 13480-2:2012, 4.2.2.

EN 13480-2:2012, 4.2.2.1, 2nd paragraph is not applicable for aluminium and aluminium alloys. Nominal design stress values are given in Table C.1, Table C.2, Table C.3 and Table C.4. Design temperatures that exceed the respective temperature limit in Annex C are not permitted. For materials of group 22.4 temperatures above 80 °C may result in grain boundary precipitation of Al3-Mg2. These materials may be used at temperatures above 80 °C up to 200 °C only for non-corrosive service. NOTE 2 For further material properties see EN 12392:2000.

For welded parts and heat treated parts after forming only the values equivalent to the O temper shall be used for design when 6 000 series flanges, etc. are welded. Nominal design stresses are given in C.6. The weld area shall be based on the O temper but the flange strength away from the weld (2t) may be based on the actual temper (T4 or T6). For aluminium and aluminium alloys values of 0,2 % proof strength (or 1 % proof strength for material group 21-1 000 series aluminium) for temperatures above 20 °C shall be established by linear interpolation between two adjacent values in the tables in Annex C. For material of group 22.4: For short periods, higher temperatures are permitted (e.g. when defrosting refrigerating plant) up to 150 °C are permissible provided that the pressure is reduced to half the working pressure for a period up to 8 h and to atmospheric pressure for a period up to 24 h.

5.7

Prevention of brittle fracture

EN 13480-2:2012, Annex B is not applicable. All materials of Table 5.2-1 are suitable for any minimum metal temperature without impact testing. NOTE

See also EN 1252-1 and EN 12392:2000, 8.4.

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5.8

Specific requirements for fasteners made of aluminium and aluminium alloys

Threads of bolts and studs shall be rolled. Regarding prevention of brittle fracture for materials of fasteners 5.7 applies. NOTE 1 Other manufacturing techniques may be agreed by the parties involved. In this case, special considerations regarding the application and testing requirements may be necessary. Such requirements are not addressed by this standard. NOTE 2 Materials other than aluminium and aluminium alloys may be used for bolting for piping constructions according to this European Standard. The designer should give special consideration to these different bolting materials.

5.9

Lined piping

Specific requirements for lined piping are not applicable for aluminium and aluminium alloys.

5.10 Clad products Specific requirements for clad products are not applicable for aluminium and aluminium alloys.

5.11 Technical delivery conditions for welding consumables The requirements of EN 13480-2:2012, 4.3.5 shall apply.

6 6.1

Design General

The requirements of EN 13480-3:2012 shall apply with the following additions/exclusions.

6.2

Time-independent nominal design stress

The design stresses for aluminium and aluminium alloys materials shall be in accordance with the Table 6.2-1. Table 6.2-1 — Design stresses for aluminium and aluminium alloy material Group according to Table 5.2-1

12

Design stresses at design condition

Design stresses at test condition

21

f = [Rp1,0,t / 1.5]

ftest = [Rp1,0,20 / 1.05]

22

f = min ([Rp0,2,t / 1.5] or [Rm,20 / 2.4])

ftest = [Rp0,2, 20 / 1.05]

23

f = min ([Rp0,2,t / 1.5] or [Rm,20 / 3])

ftest = [Rp0,2, 20 / 1.05]

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Table 6.2-2 — Allowable design strength values for 6 000 series aluminium alloys in the welded condition (see 5.6) Material designation

Value of f for design temperature (°C) not exceeding 50

75

100

125 a

150

175 a

EN AW 6060

40

40

40

38

-

-

EN AW 6061

55

55

55

54

51

43

NOTE

Data are derived from EN 13445-8:2009.

a

For maximum design temperature see 5.6. Values for 125 °C (EN AW 6060) and 175 °C (EN AW 6061) shall be used for interpolation only.

6.3

Straight pipes

In general, straight pipes shall be designed in accordance with EN 13480-3:2012, 6.1. For D0/Di > 1,2, Formula (6.3-1) may be used. In this case pipes shall be seamless or tested in accordance with 8.4.3 and 8.6 for z = 1,0 and the maximum allowable pressure pa shall be determined as follows:

 2  D  1 x Rp 0, 2, t x ln 0  x pa    Di  1,5  3

(6.3-1)

For material group 21 Rp1,0,t shall be used instead of Rp0,2,t.

6.4

Pipe bends and elbows

The standard method for calculation of bends and elbows for aluminium and aluminium alloys shall be the method described in EN 13480-3:2012, B.4.1.3. NOTE 1 This clause should not be understood as to prohibit the other methods given in EN 13480-3, but to reflect the actual situation at the bend manufacturers. NOTE 2

6.5

Also see 6.2.3 and EN 13480-3:2012, Formula B.4.1-11.

Mitre bends

EN 13480-3:2012, 6.3 may be used for the design of mitre bends for aluminium and aluminium alloys. Alternatively the method described in Formulae (6.5-1) to (6.5-4) may also be used for multiple mitre bends for aluminium and aluminium alloys according to Figure 6.5-1 with a maximum angle Θ of 22,5°. The pressure limit given in EN 13480-3:2012, 6.3.1 is not applicable for this method. NOTE 1 Current experiences are available up to pressures of 63 bar for time independent design stresses, however this does not prohibit the calculation of mitre bends to the given formula for use of higher pressures, but shows the reference pressure for which mitre bends made of aluminium and aluminium alloys and designed to the rules are in safe operation. NOTE 2

Source: FDBR Guideline, Design of power piping, July 1995

The following symbols apply for the alternative method in addition to those mentioned in Clause 3.

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Table 6.5-1 — Special symbols for subclause 6.5 Symbol

Description

Unit

σv

Equivalent stress intensity

MPa (N/mm2)

paa

Maximum allowable pressure

MPa (N/mm2)

div

Design inside diameter

mm

a

a

See footnote in EN 13480-3:2012, Table

B d

3.2-1.



 v  pa   i iv  0,5   f 2e z 

(6.5-1)

shall be met with regard to internal pressure loading, where with the smaller value of  d  e  0,8  d iv  e   e  r1   iv  2  tan    r2 

(6.5-2)

b 2  tan 

(6.5-3)

the value Bi is found as follows Bi 

r  0,25  d iv r  0,5  d iv  e 

(6.5-4)

Figure 6.5-1 — Mitre bend

6.6

Socket welds

Socket welds may only be used for pipes DN 50 and below.

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6.7

Designing with transition joints

6.7.1

Design considerations

The use of transition joints shall be considered during design analysis. Transition joints should be treated as elements within the piping and the designer should consider all the loadings likely to arise under the design conditions. 6.7.2

Location of transition joints

A transition joint shall be positioned so that it does not undergo undue loading effects such as tensile and shear forces or bending and torsional moments. Where appropriate, the transition joint fabricator shall provide allowable loads or criteria for assessing pressure and combined external loads. In general, positioning transition joints directly against piping elbows shall as far as possible be avoided. 6.7.3

Requirements for transition joints

Transition joints shall meet the requirements of Annex B.

6.8

Port-hole extruded tubes

Port-hole-extruded tubes in accordance with EN 755 series may be used up to and including DN 25, provided that a joint efficiency of 0,7 is applied. When these tubes are subject to a combined pressure-leak-test for the entire length the joint efficiency may be set to a factor of 1. If this test is carried out by the tube manufacturer, the test pressure shall be PT 

en  0,95  Rpx De

(6.8-1)

by the piping manufacturer, the test pressure shall be PT  1,43  PS

(6.8-2)

The combined pressure-leak test for achieving a joint efficiency factor of 1 is to be carried out before integration in the piping system either using helium or a gas mixture containing helium, depending on the application. It does not replace the pressure test as specified in 9.1 and 9.2.

6.9

Alternative methods

Design by Analysis (DBA) according to EN 13445-3:2009 may be applied, using the method based on stress categories only.

7 7.1

Fabrication and installation General

The requirements of EN 13480-4:2012 shall apply with the following additions/exclusions. NOTE Reference to EN 14717 may be useful to avoid and reduce the possible environmental impacts of aluminium and aluminium alloy piping.

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7.2

Material grouping

Aluminium and aluminium alloy materials and their grouping shall be in accordance with Table 5.2-1.

7.3

Tolerances

7.3.1

Welded pipes and connection dimensions of pipe fittings

Table 7.3-1 applies for welded pipes fabricated in accordance with this European Standard. Connection dimensions of pipe fittings (e.g. elbows, tees, reducers) shall comply with Table 7.3-1. Greater values may be acceptable provided they are verified by design calculation. NOTE 1

For pipe/fitting to flange connection, see EN 1092-4:2002, Table 9.

NOTE 2

Other tolerances may be applied if specified by the designer (see EN 13480-1:2012, 3.1.6).

NOTE 3

For tolerances of material fabricated to other European Standards, see applicable European Standard (e.g.

EN 12392:2000, Clause 7 or EN 1092-4:2002, 5.9).

Table 7.3-1 — Tolerances for welded pipes Type of tolerance

Tolerance

Mean external diameter

± 1,5 %

Out of roundness

maximum 1,5 % for the ratio e/D < 0,01 maximum 1,0 % for the ratio e/D ≥ 0,01

Wall thickness

As for sheet, strip or plate

Reference

EN 13480-4:2012, Formula (7.4.1-1) EN 485-3; EN 485-4

Out of roundness shall be calculated in accordance with EN 13480-4:2012, Formula (7.4.1-1). The determination of the out of roundness need not consider the elastic deformation due to dead-weight of the pipe. 7.3.2

Welded piping construction

EN 13480-4:2012, 5.6 is not applicable for piping in aluminium and aluminium alloys. Guidance for the tolerances of piping spools made of aluminium and aluminium alloys is given in Annex A. EN 13480-4:2012, 7.4 is applicable for aluminium and aluminium alloys, except 7.4.4 concerning induction forming. The requirements according to EN 13480-4:2012, 9.9 shall apply with the following modification for aluminium and aluminium alloys: Replace the reference to EN 25817 with EN ISO 10042.

7.4

Cutting and bevelling

In addition to the requirements of EN 13480-4:2012, 6.1 the following shall apply for industrial piping of aluminium and aluminium alloys:

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Aluminium and its alloys shall be cut to size and shape preferably by machining or by thermal cutting process, e.g. plasma arc cutting, or by a combination of both. Additionally, hydro mechanical methods of edge preparation are acceptable. Flame cutting is not permitted. For plates of  25 mm thickness cold shearing is permissible. Edges that are cut by thermal process or by cold shearing shall be dressed back by machining unless the manufacturer can demonstrate that the material and the weldability has not been adversely affected by the cutting process. The surface to be welded shall be thoroughly cleaned of aluminium oxide traces and greases by mechanical means or by pickling. Chloride containing detergents are prohibited.

7.5

Bending and other forming

7.5.1

General

The requirements of EN 13480-4:2012, Clause 7 shall apply with the following additions/exclusions. 7.5.2

Definition of cold- and hot forming

Cold forming of material groups 21 and 22 shall be carried out at temperatures below 200 °C. Cold and hot forming of material of group 23.1 is not allowed. Hot forming of aluminium and its alloys shall be carried out in a temperature range of 320 °C to 450 °C. The last stage of the hot forming process shall be completed above 300 °C; otherwise, a subsequent heat treatment to achieve the O Temper is required. 7.5.3 7.5.3.1

Heat treatment after cold forming General

For heat treatment after cold forming the requirements of EN 13480-4:2012, 7.2 are not applicable for industrial piping of aluminium and aluminium alloys. For aluminium and aluminium alloys, the heat treatment shall be carried out as follows: The heat treatment parameters shall be in accordance with the material specification of the material manufacturer. The general heat treatment parameters shall be: the heating rate shall be as rapid as possible; the holding temperature shall be in the range between 320 °C and 380 °C depending on the alloy type; the holding time at the holding temperature shall be between 10 min and 60 min depending on the ratio of cold forming; the cooling shall be performed in still air, the cooling rate needs not to be controlled. 7.5.3.2

Flat products

For aluminium and aluminium alloys heat treatment shall be carried out in accordance with Table 7.5-1.

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Table 7.5-1 — Heat treatment of flat products after cold forming Material groups according to Table 5.2-1

Ratio of deformationd Vd (%)

21

≤ 15 %

21

no a

> 15 %

22.1b, 22.2b, 22.3b, 22.4b b

Heat treatment

b

b

22.1 , 22.2 , 22.3 , 22.4

yes , annealing

≤5%

b

no c

>5%

yes , annealing

a With levels of cold forming and a ratio of deformation above 15 % for materials of group 21 or above, if it can be demonstrated in specific cases that the residual elongation after rupture after cold forming remains at least 10 %, then in these cases annealing is not required. b

Elongation prior to forming ≥ 14 %.

c

With levels of cold forming and a ratio of deformation above 5 % for materials of group 22 or above, if proof can be furnished in specific cases that the residual elongation after rupture after cold forming remains at least 10 %, then in these cases annealing is not required. d

For Vd (%) for cylinders and cones, see EN 13480-4:2012, 7.1.3; for Vd (%) for dished circular products, see EN 13445-4:2009, 9.2.1.

7.5.3.3

Pipes

For aluminium and aluminium alloys heat treatment shall be carried out in accordance with Table 7.5-2. Table 7.5-2 — Heat treatment of pipes after cold forming Material groups according to Table 5.2-1

External diameter of the tube

rm

do

≥ 1,3 De

all diameters

no

21 21

< 1,3 De

all diameters

yes, annealing

a

a

a

a

≥ 2,5 De

all diameters

no

a

a

a

a

< 2,5 De

all diameters

yes, annealing

22.1 , 22.2 , 22.3 , 22.4 22.1 , 22.2 , 22.3 , 22.4 NOTE a

7.5.4

Heat treatment

Mean bending radius of the pipe

For do and rm see EN 13480-4:2012, Figure

7.2.2-1.

Elongation prior to forming ≥ 14 %.

Heat treatment after hot forming

For heat treatment after hot forming the requirements of EN 13480-4:2012, 7.3 are not applicable for industrial piping of aluminium and aluminium alloys. For aluminium and aluminium alloys the heat treatment shall be carried out in accordance with Table 7.5-3 and as following: The heat treatment parameters shall be in accordance with the material specification of the material manufacturer. The general heat treatment parameters shall be: a)

the heating rate shall be as rapid as possible;

b)

the holding temperature shall be in the range between 320 °C and 380 °C depending on the alloy type;

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c)

the holding time at the holding temperature shall be between 10 min and 60 min depending on the ratio of cold forming;

d)

the cooling shall be performed in still air, the cooling rate needs not to be controlled. Table 7.5-3 — Heat treatment after hot forming

Material groups according to Table 5.2-1

21, 22

7.6 7.6.1

Hot forming conditions

Heat treatment

Heat treatment should be applied if the forming process of the last forming stage is completed at ≤ 300 °C.

Yes, annealing

No subsequent heat treatment should be applied if the forming process of the last forming stage is completed above 300 °C.

no

Welding Welding personnel

The requirements according to EN 13480-4:2012, 9.1 shall apply with the following modification for aluminium and aluminium alloys: Replace the reference to EN 287-1 by EN ISO 9606-2:2004. 7.6.2

Welding processes

The requirements according to EN 13480-4:2012, 9.3 shall apply with the following modification for aluminium and aluminium alloys: Qualification of welding procedure specifications (WPQR). The requirements according to EN 13480-4:2012, 9.3.1 shall apply with the following modifications for aluminium and aluminium alloys: Replace reference to EN ISO 15614-1 by EN ISO 15614-2:2005. Furthermore, impact testing is not applicable for piping of aluminium and aluminium alloys, see 5.7. Oxy fuel gas welding processes according to EN ISO 4063:2010 are not permitted. For qualification of welding procedures for EN AW 6061 material, the result of the tensile tests carried out in accordance with EN ISO 15614-2:2005 shall show the following data with T = 1: minimum Rm = 165 MPa; minimum Rp0,2 = 110 MPa. 7.6.3

Weld joint preparation

The weld joint preparation shall be in accordance with the applicable WPS. Assembly and welding of socket welds shall be in accordance with Figure 7.6.3-1. It is important that the 1,5 mm internal gap is maintained prior to welding to allow for weld shrinkage and the fillet weld leg length shall be 1,25 times the pipe minimum thickness calculated for pressure or 3 mm, whichever is the greater. Where the size of fillet weld permits, it should be completed in two runs with the stop/start positions of the second run staggered relative to the first.

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Key a

Approximate gap before welding

Cx (min) = 1 ¼ t but not less than 3 mm t = Minimum thickness calculated under consideration of the maximum allowable pressure Figure 7.6.3.1 — Socket welds 7.6.4

Preheating

In addition to the requirements according to EN 13480-4:2012, 9.11.1 the following shall apply for industrial piping of aluminium and aluminium alloys:

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Preheating of aluminium is not required for metallurgical reasons and is therefore not mandatory. Preheating may be applied by the manufacturer for practical reasons, e.g. a heating at about 50 °C may facilitate the elimination of traces of moisture. For aluminium alloys containing 3,0 % or more magnesium an extended preheating and interpass time at temperatures of 150 °C and above may result in grain boundary precipitation of Al3-Mg2 disintegration in weld areas. Manufacturing procedures should be designed to avoid significant times above 150 °C for these alloys. 7.6.5

Backing rings and backing strips

In addition to the requirements according to EN 13480-4:2012, 9.12 the following shall apply for industrial piping of aluminium and aluminium alloys: Permanent backing strips shall not be used for longitudinal seams. Permanent backing rings may be used for circumferential seams in all categories only under the following conditions: a)

non–destructive examination is carried out in accordance with the design/joint efficiency to the same quality and acceptance criteria as a single sided butt weld;

b)

the inside of the piping is not subject to corrosion;

c)

backing ring material shall be of the same aluminium sub group as the piping unless the combination of other backing ring material has been proven by a WPQR according to EN ISO 15614-2:2005.

7.6.6

Post-weld heat treatment (PWHT)

The requirements according to EN 13480-4:2012, 9.14 are not applicable for industrial piping of for aluminium and aluminium alloys. The following shall apply for aluminium and aluminium alloys: a)

stress relieving heat treatment is normally not necessary or desirable for welded aluminium piping except there is a risk of stress corrosion due to the operation service. Annealing heat treatment carried out for obtaining the delivery state O is the only usable heat treatment;

b)

for material group 23.1 PWHT is not permitted;

c)

the heat treatment parameters (annealing) shall be in accordance with the material specification of the material manufacturer or those as stated in 7.5.3.

8

Inspection and testing

8.1

General

The requirements according to EN 13480-5:2012 shall apply with the following additions/exclusions:

8.2 8.2.1

Formed pressure retaining parts General

EN 13480-5:2012, 7.2.1 shall not apply to aluminium and aluminium alloys.

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The requirements for testing and inspection specified below shall apply to all formed parts of aluminium and aluminium alloys fabricated according to this European Standard. Formed parts, fabricated, tested and inspected according to EN 13445-8 can be used without any further testing and inspection. NOTE If harmonized European Standards for formed parts (e.g. elbows, tees, reducers, welded pipes) are available and requirements for testing and inspection are specified in these harmonized European Standards, the requirements of the harmonized European Standards apply. At the time this European Standard was prepared, no such harmonized European Standard is available.

Cold drawn tubes according to EN 754 series and extruded tubes according to EN 755 series are not considered to be formed parts manufactured under this European Standard. For these tubes, the requirements of EN 754 and EN 755 series apply. The tests specified in the European Standards for the base material shall be performed for the base material. 8.2.2

Testing of formed parts

The requirements according to EN 13480-5:2012, 7.2.4 shall not apply to aluminium and aluminium alloys. The following examinations shall be carried out on formed parts of aluminium and aluminium alloys: a)

verification of wall thickness,

b)

dimensional check (ovality, angle of bend etc.),

c)

examination for surface imperfection (VT).

8.2.3

Destructive testing of formed and heat treated parts

The requirements according to EN 13480-5:2012, 7.2.5 shall not apply to aluminium and aluminium alloys. Destructive testing to verify the heat treatment shall be performed for piping with DN > 25 for hot formed parts and cold formed parts with subsequent heat treatment. No mechanical tests in respect of forming are required for: — cold-formed flat products and pipes for which heat treatment is not required by Table 7.5-1 and Table 7.5-2; and — cold-formed and heat-treated welded pipes and reducers. One test shall be performed for parts of the same cast, wall thickness range and heat treatment lot. The wall thickness range shall be by ± 20 % of the average wall thickness of the parts. The tests specified in Table 8.2-1 shall be performed. Destructive testing is not required for formed parts with welds for which the manufacturer holds a welding procedure approval that includes heat treatment.

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Table 8.2-1 — Destructive testing of formed and heat treated parts Size of formed part

Type of test

Requirements

Tensile strength and elongation after rupture/fracture

Tensile strength as for the EN base material standard and elongation after rupture/fracture ≥ 10 % (see 5.2)

Flattening test a

EN 12392:2000, 5.3.6

EN 12392:2000, Table 3

Tensile test

Tensile strength and elongation after rupture/fracture

Tensile strength as for the EN base material standard and elongation after rupture/fracture ≥ 10 % (see 5.2)

Tensile test DN < 100

Testing criteria

or

DN > 100 a

The flattening tests are performed if tensile test specimen cannot be obtained from the formed part. The flattening tests are performed over the full section of the formed part.

8.3

Welding

The requirements according to EN 13480-5:2012, 7.3 shall apply.

8.4 8.4.1

Visual and non-destructive testing of welds Application of NDT

The requirements according to EN 13480-5:2012, 8.1.1.1 shall apply with the following modification for aluminium and aluminium alloys: The method for surface testing shall be PT. 8.4.2

Circumferential, branch, socket and seal welds

The requirements according to EN 13480-5:2012, 8.2 shall apply with the following additions/exclusions for aluminium and aluminium alloys: In EN 13480-5:2012, 8.2.1 b) replace reference to material groups 1.1, 1.2 and 8.1 with material groups 21, 22 and 23.1. The extent of VT and NDT for circumferential, branch and seal welds shall be in accordance with Table 8.4-1.

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Table 8.4-1 — Extent of testing for circumferential, branch, socket and seal welds All Circumferential welds Material Cate- welds Group gory Surface Volumetric testing testing

VT % I 21, 22

II

100

III I 23.1

II III

a

100

Socket welds

Branch welds Surface testing

Branch diameter

PT %

RT/UT %

0

5

0

5

0

10

0

5

a

5

5

5

10

5

25

a

en mm

PT %

Branch diameter

0 All

All

Surface testing

Volumetric testing en RT/UT mm %

0

All

0

> DN 100

0 > 15

All

10 10

> DN 50

en mm

0 5

All

PT % 0

All

5

10

N/A

5

0

5

5

0 >7

Surface testing

PT %

en mm

Seal welds

10

All

10

All

N/A

10 10

For weld configurations and dimensions, where UT or RT does not allow a clear assessment, PT shall be carried out

8.4.3

Longitudinal welds and spiral welded tubes/pipes

The requirements according to EN 13480-5:2012, 8.3 for longitudinal welds shall apply with the following additions/exclusions for aluminium and aluminium alloys: The extent of VT and NDT for longitudinal welds and spiral welded tubes/pipes shall be in accordance with Table 8.4-2. For material group 23.1, longitudinal welds and spiral welded tubes/pipes are not permitted. Table 8.4-2 — Extent of VT and NDT for longitudinal welds and spiral welded tubes/pipes

8.5

Joint coefficient

VT

PT

RT or UT

Z

%

%

%

Z  0,7

100

0

0

0,7 < Z  0,85

100

0

10

0,85 < Z  1,0

100

0

100

VT and NDT Methods

The requirements according to EN 13480-5:2012, 8.4.1 and EN 13480-5:2012, 8.4.3 shall apply with the following additions/exclusions for aluminium and aluminium alloys: Sub-clauses 8.4.2 and 8.4.4 shall not apply. Techniques, methods, acceptance criteria for welds in aluminium and aluminium alloys shall follow the European Standards given in Table 8.5-1 and the footnotes given in Table 8.5-1. RT is first preferred for en < 8 mm and least preferred en > 40 mm. UT testing of aluminium and aluminium alloys may be applied for en ≥ 4mm if qualified in accordance with Note e of Table 8.5-1.

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Table 8.5-1 — Techniques, methods, acceptance criteria Technique (abbreviations)

Methods

Acceptance criteria

Visual inspection (VT)

EN ISO 17637:2011

EN ISO 10042:2005 Acceptance level Ba

Radiography (RT)

EN 1435:1997 class Bb

EN ISO 10042:2005 Acceptance level Bc

Ultrasonic Testing (UT)

Manual UT, EN 17640:2010

EN ISO 11666:2010 Acceptance level 2d

Automatic UT, EN 10246-9:2000 and EN 10246-16:2000e For thickness en (mm) 4 ≤ en < 40 class A 40 ≤ en < 100 class B en ≥ 100 class C

Penetrant Testing (PT)

EN 571-1:1997 + testing parameters of EN ISO 23277:2009, Table A.1

EN ISO 23277:2009, Acceptance level 2

a

For imperfections 1.11 (502) (excess weld metal for butt weld), 1.12 (503) (excessive convexity for fillet welds), 1.14 (504) (excess penetration), 3.1 (507) (linear misalignment, for circumferential welds only), 1.10 (5011) (continuous undercut, but max depth 0,2 mm) 1.18 (5013/515) (shrinkage groove/root concavity), 1.16 (511) (incompletely filled groove) according to EN ISO 10042:2005, level C is sufficient.

b

However, the minimum number of exposure for circumferential weld testing may correspond to the requirements of class A of EN 1435:1997, class A.

c

For imperfections No 2.7 (2016) (wormholes isolated), 2.8 (303) (Oxide inclusion), 2.9 (3041) (tungsten inclusion), 2.3 (2011) (Pore isolated), 2.5 (2013) (clustered (localized) porosity) according to EN ISO 10042:2005, level C is sufficient.

d

No planar imperfections accepted. For en ≥ 60 mm UT shall include examination for imperfections perpendicular to the surface in accordance with EN 583-4:2002.

e

EN 10246-9:2000 and EN 10246-16:2000 were formerly applied to steel tubes and shall further be used as the reference standards for acceptable methods of automatic ultrasonic testing of aluminium and aluminium alloy materials according to this European Standard.

8.6

Production test plates for welded pipes

Production test plates are required for welded pipes manufactured according to this European Standard in the case of joint coefficient of 0,85 < z  1,0. If a joint coefficient of 0,85 or less is specified by the designer, no production test plates are required. The number of test plates specified under a) or b) takes into account the tolerance of a material group to weld procedure variables, the welding process and the quality requirements for welding. a)

For aluminium materials of groups 21, 22.1, 22.3 and 22.4 production test plates in accordance with Table 8.6-1 shall be required, if all of the following requirements are met:

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the quality requirements of EN ISO 3834-2:2005 or EN ISO 3834-3:2005 are fulfilled; the welding process is fully mechanised (see ISO 857-1:1998) ensuring that the welding procedure is applied consistently, 

the wall thickness en  30 mm.

Unless the requirements for production test plates given in a) apply, for all material production test plates are required for each lot of welded pipes. A lot is defined as 100 m or fraction thereof of all pipes of the same material and temper as well as the wall thickness range qualified in the WPQR. After 10 consecutive test plates have successfully passed the test, testing can be reduced to 200 m or fraction thereof. After further 10 consecutive test plates have successfully passed the test, testing can be reduced to 500 m or fraction thereof, but at least 1 production test plate per year shall be tested. Table 8.6-1 — Production test plates for welded pipes according to 8.6 a) Longitudinal welds

Spiral welds

One test plate per 200 ma or a fraction thereof of longitudinal welds for the same material and temper

One test plate per coil but at minimum one test plate per max [25 pipes; 375 m weld length]

a

After 10 consecutive test plates have successfully passed the test, testing can be reduced to 300 m of longitudinal welds. After further 10 consecutive test plates have successfully passed the test, testing can be reduced to 500 m of longitudinal welds, but at least 1 production test plate per year shall be tested.

If production test plates are required either by a) or b) the tests specified in Table 8.6-2 shall be performed and the given acceptance criteria shall be met. Table 8.6-2 — Required tests and acceptance criteria for production test plates Required test

Acceptance criteria a

According to EN ISO 15614-2:2005

a

1 root bend test RBB according to EN ISO 5173:2010

According to EN ISO 15614-2:2005

1 transverse tensile test according to EN ISO 4136:2011

According to EN ISO 15614-2:2005

1 macroscopic examination according to EN 1321:1996

According to EN ISO 15614-2:2005

1 face bend test FBB according to EN ISO 5173:2010

a

9 9.1

2 side bend tests SBB for en > 12 mm.

Final assessment and documentation General

The requirements according to EN 13480-5:2012, Clause 9 shall apply with the following additions/exclusions for aluminium and aluminium alloys:

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9.2

Pneumatic pressure test

The requirements according to 9.3.3 of EN 13480-5:2012 shall apply with the following additions/exclusions for aluminium and aluminium alloys: a)

The pneumatic test pressure shall be in accordance with EN 13480-5:2012, 9.3.3. Piping subject to this pressure shall be located in an enclosed and restricted area and adequate measures being taken to prevent parts shooting away in the case of explosion. Alternatively the piping shall be located in an area enough far away from any individuals (public or manufacturers employees) such that in the case of explosion, people will not be affected by the blast (This does not include damage from projectiles).

b)

Alternatively a test may be performed at a test pressure of 1.1 times the maximum allowable pressure. Before initial pressure tested, NDT (UT or RT, see Table 8.5-1 of this European Standard) shall be performed as shown in Table 9.2-1. Table 9.2-1 — Extent of NDT in case of pneumatic pressure test according to 9.2b) Type of weld

Extent of NDT

Circumferential welds a; branch and nozzle welds DN  100

10 %b,c RT or UT, cross sections with longitudinal welds to be covered

Branch and nozzle welds DN  100 and socket welds

Material groups 21and 22

5 % PT

Material group 23.1

20 % PT

Longitudinal welds, if not already subject to a NDT or pressure test at the pipe manufacturer’s premises

100 % RT or UT

a

See footnote a in Table 8.4-1.

b

Up to DN  600, 10 % of welds to be tested 100 %, from DN > 600, 10 % of the total length of welds.

c

25 % for circumferential welds for material group 23.1 for category III.

Where, during pneumatic test, the piping has been subjected to the pressure in accordance with 9.2 a), EN 13480-5:2012, Formula (9.3.3-1) shall apply for the inspection pressure. Where the alternative 1.1 times the maximum allowable pressure has been used in accordance with 9.2 b), the pressure shall be dropped to the maximum allowable pressure for inspection of the piping.

9.3

Documentation for components

This clause is applicable if the component manufacturer supplies single components manufactured under the provisions of this European Standard to other parties. Components which are manufactured from materials such as plates, coils and bars shall meet all the relevant requirements of this European Standard related to the manufacturing process used; for instance in the manufacturing of welded dished ends or welded pipes. In order to prove the conformity to this European Standard of the pressure equipment containing the component, the equipment manufacturer shall obtain either the documents a) to f) from the component supplier:

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a)

inspection documents (of the plates, coils, bars …), and as relevant,

b) non-destructive testing reports, c) destructive testing reports, d) heat treatment information, e) for welded components, a statement that welding procedure approvals and welder/welding operator approvals conform to the requirements of this European Standard, f)

for components with NDT, a statement that NDT operator qualifications conform to the requirements of this European Standard,

or this information in the form of a component certificate. Under 9.3 e), the component manufacturer shall also state that the welders/welding operators and welding procedures are approved if the components are ordered for categories II and III. Under 9.3 f), the component manufacturer shall also state that the NDT operator qualification is approved if the components are ordered for piping category III. If further information/documentation is required, the equipment manufacturer shall specify this in the component order. For recognized third party see EN 764-3. NOTE 1

Forgings (including forged flanges), castings and seamless tubes are generally considered to be materials.

NOTE 2 Current practice may require components to be delivered with certificates based on EN 10204 or corresponding requirement, when they are placed on the market as such. NOTE 3

28

See EN 764-5 for inspection documents.

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue33(2014-08) (2014-08) Issue

Annex A (informative) Dimensional tolerances Guidance for the tolerances of piping spools made of aluminium and its alloys is given in Table A.1, for all diameters. Table A.1 — Tolerances Dimensions number according to Figure A.1 Dimension 1

EN ISO 13920, class B

Dimension 2

See EN 13480-4:2012, 7.4

Dimension 3

± 3 mm

Dimension Dimension Dimension 4 5 6

1°

1°

1°

max. 5 mm at bolt circle

max. 5 mm

max. 5 mm at flange periphery

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Dimension No 1:

face-to-face dimensions; centre-to-face dimensions; location of attachments; centre-to-centre dimensions.

Dimension No 2:

out-of-roundness of bends

Dimension No 3:

lateral translation of branches or connections.

Dimension No 4:

rotation of flanges, from the indicated position, measured as shown.

Dimension No 5:

bevels on butt weld or plain ends – state diameter to which bevel applies.

Dimension No 6:

out-of-alignment of flanges from the indicated position, measured across the full gasket face diameter.

Figure A.1 — Dimensional details of spools

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Annex B (normative) Transition joints

B.1 General Annex B shall apply for transition joints. The transition joint shall join aluminium and aluminium alloys to austenitic stainless steel piping or equipment. A transition joint is a prefabricated, non-separable, component consisting of dissimilar metal parts. A transition joint is a component that is used to join items of pressure equipment together in situations where a permanent leak tight joint is required and fusion welding cannot be used because the materials are incompatible with regard to fusion welding. Transition joints may employ several metallic materials in the metallurgical bond interface. Care shall be taken to ensure that materials used in the interface are compatible to the fluid service and design temperature of the transition joint. A transition joint does not rely on flanges or bolting to maintain leak tightness although some designs of transition joint may be provided with additional external mechanical reinforcement to protect the bond interface from external forces and moments.

B.2 Materials For the ends of the transition joints aluminium and aluminium alloys (base metal 1) according to Clause 5 and austenitic stainless steel (base metal 2) according to EN 13480-2:2012 shall be used.

B.3 Design The ends of the transition joints shall be calculated to withstand at least the same pressure as the connected piping using the design rules of the applicable clauses in EN 13480. The transition joint shall withstand a pressure of 4 times the design pressure without leakage.

B.4 Permanent joining process The dissimilar metal parts of a transition joint shall be joined by explosion bonding, friction welding or special forging processes.

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B.5 Testing B.5.1 Qualification testing (QT) B.5.1.1

Qualification of permanent joining process

In order to reduce the number of qualification tests, transition joints shall be grouped on the basis of diameter as shown below.  Group I DN < 100.  Group II 100  DN < 400.  Group III DN  400. Qualification testing shall be carried out on a minimum of two samples out of groups I to III. The qualification test shall cease to be valid if relevant aspects of the design or the manufacturing process or the material subgroup (see Clause 5 and EN 13480-2:2012) combinations are changed. Testing methods, test conditions and scope shall be in accordance with Table B.1. B.5.1.2

Procedure for thermal shock testing of transition joints

Thermal shock testing shall include immersion in liquid nitrogen to cool down the transition joint to -196 °C followed by total immersion in hot water (T ≥ 80 °C). The joint shall be returned to room temperature (usually by immersing in cold water) before the test is repeated. A minimum of 5 thermal cycles is required. B.5.1.3

Qualification of personnel

Personnel for carrying out permanent joining shall be qualified in line with the principles in EN ISO 9606-2 and EN ISO 15614-2. Qualification of personnel NDE and Visual Inspection shall be in accordance with EN 13480-5:2012, 8.4.3. B.5.2 Component testing (CT) of production joints

Each transition joint shall be subject to inspection and testing. Testing methods, test conditions and scope shall be in accordance with Table B.1.

B.6 Marking Each transition joint shall be marked by electrochemical etching, engraving or laser marking with the following:  transition joint fabricators name or mark;  material designation or material number (on base metal 1 and 2 sides);  unique reference number.

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A tag shall be firmly attached to the transition joint with a good visible warning regarding the temperature limitation (if any) at the bond interface during welding.

B.7 Documentation For all transition joints, independent of material and size, inspection documents according to EN 10204:2004 shall be delivered, showing the results of all required tests. The inspection document shall include a statement that all requirements of the applicable specification and this annex have been met. If further information or documentation is required, the purchaser shall specify this in the order. The inspection documents for base metal 1 and 2 shall be attached.

B.8 Protection against overheating The bond interface of a transition joint may be temperature sensitive and stringent measures shall be taken by the manufacturer of pressure equipment to control and limit the maximum temperature of the interface in accordance with the transition joint fabricator’s recommendations. Each transition joint with temperature sensitive bond interface shall be provided with a thermal sensitive indicator. The indicator shall enable the welder to check the temperature which shall be within the given limit.

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Table B.1 — Testing of transition joints (T.J.) Id.-No.

1 1.1 1.1a

1.1b

1.2

1.3 1.4

2 2.1e

2.2 2.3

2.4

3 3.1

3.2 3.3 a b c d e f g

34

Test; requirements / Scope for QT Scope for CT test standard a Destructive tests Testing specified under either Id.-No. 1.1a or 1.1b Impact test for notch orientation along each of the 1 set each 1 set each bond interfaces; KV ≥ 14 J (single), ≥ 18 J (mean) / EN ISO 148-1:2010 Metallographic evaluation of micro section (each bond 1 interface); requirements see b footnote Side bend test (Not applicable for special forging process); 2 90°, d = 12 x a, no cracks / EN ISO 7438:2005 Hydrostatic pressure proof 1 T.J. out of test; 4 x design pressure group I, II, III

Tensile test in z-directiong; tensile load ≥ base metal 1/ EN ISO 6892-1:2009 and EN ISO 6892-2:2011 Non-destructive tests UT after each explosion clad;> 50 % full scale echo/ EN 583 series Helium leak test of T.J.; leak rate < 10-8 mbar l / s / EN 1779:1999 Dye penetration test of T.J.; EN ISO 23277:2009 acceptance level 1/ EN 5711:1997 Pressure test; 1,43 x design pressure

2

2d

Test conditions

Test temperature: Ambient

200X

Test temperature: Ambient T.J. thermally cycledc Test temperature: Ambient In combination with Id.-No. 2.4 Specimen shall include base metal 1 and 2 Specimen thermally cycledc Test temperature: Ambient UT with normal beam, Ø 25 mm, 2,25 MHz No disbonding permitted in plate areas, which are to be used for the T.J. machining

100 %

100 %

2

all

T.J. thermally cycledc for QT Test temperature: Ambient

2

all

T.J. thermally cycledc for QT Test temperature: Ambient

1

f

Visual examinations of transition joints Visual examination; free from foreign material, All test pieces corrosion or any flaws > 0,3 mm Dimensional check All test pieces Check of markings All test pieces

all

T.J. thermally cycledc for QT Test temperature: Ambient in combination with Id.-No. 1.3 for QT

100 %

-

100 % 100 %

-

For explosion clad T.J. each finally clad plate (except for Id.-No. 1.3). No non-metallic phases or inclusions, no pores or other not binding areas, full bonding of joint metals. See B.5.1.2. Alternatively testing in accordance with Id.-No. 2.4 / CT. For explosion clad T.J only. If testing according to Id.-No. 1.4 / CT is not performed. As an alternative for special forging processes this test may be replaced by a hydrostatic proof test as in Id.-No 1.3 at 7 times the test pressure.

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue33(2014-08) (2014-08) Issue

Annex C (normative) Nominal design stress values

C.1 General Material properties given in EN 12392:2000, Table 5 and Table 6, are considered when establishing the nominal design stress values given in Table C.1, Table C.2, Table C.3 and Table C.4. Nominal design stress values given in italics are time-dependent. For determining the exact temperatures for which the time-dependent strength values become dominant, see EN 12392:2000, Table 5 and Table 6.

35

36

b

a

O/H111

H112

b

b

40 40

O/H111

H112

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

H112

O/H111

EN AW-5052

EN AW-5154A

EN AW-5251

EN AW-5454

EN AW-5754

EN AW-5083

EN AW-5083

EN AW-5086

95

125

110

80

85

60

85

70

80

63,3

83,3

73,3

53,3

56,7

40,0

56,7

46,7

53,3

26,7

26,7

26,7

23,3

23,3

25,6

20,0

20 °C

Italic numerical values are creep-range values. The nominal design stress values are based on Rp1,0-strength values.

H112

EN AW-5049

EN AW-5005A

40

O/H111

EN AW-5005

35

O/H111

EN AW-3103

35

O/H111

23

20

MPa

EN AW-3003

EN AW-1070A

EN AW-1050A

Temper

EN AW number

Rp0,2/20°C

63,3

83,3

73,3

53,3

56,7

40,0

56,7

46,7

53,3

26,7

26,7

26,7

23,3

23,3

24,5

19,3

50 °C

62,1

83,3

73,3

52,0

55,3

39,3

55,3

45,9

52,2

26,0

26,0

25,9

22,0

22,0

23,5

18,7

75 °C

62,1

79,3

71,6

50,7

54,0

38,0

54,0

44,5

50,7

25,3

25,3

25,1

21,3

21,3

21,5

16,7

100 °C

MPa

45,6

48,7

42,8

40,7

45,3

32,6

46,7

36,8

25,1

32,0

32,0

34,3

20,7

20,7

20,4

13,3

125 °C

27,2

28,7

25,2

26,0

31,3

27,3

29,3

29,1

17,5

24,7

24,7

26,7

19,3

19,3

19,4

10,0

150 °C

Value of f for design temperaturea

Table C.1 — Extruded rod/bar, tube and profile

Mechanical properties for extruded rod/bar, tube and profile shall comply with EN 755-2:2013.

C.2 Extruded rod/bar, tube and profile

BS 13480-8:2012+A1:2014 BSEN EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue Issue3 (2014-08) 3 (2014-08)

16,5

16,0

14,1

15,3

21,3

18,0

18,7

21,5

12,6

18,0

18,0

19,8

17,3

17,3

—

8,0

175 °C

10,8

10,0

8,8

10,7

15,3

12,7

12,0

14,4

9,1

14,7

14,7

16,0

15,3

15,3

—

6,3

200 °C

a

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

O/H111

EN AW-3003

EN AW-3103

EN AW-5005

EN AW-5005A

EN AW-5049

EN AW-5052

EN AW-5154A

EN AW-5754

EN AW-5083

EN AW-5086

95

110

80

85

65

80

40

40

35

35

MPa

Italic numerical values are creep-range values.

Temper

EN AW number

Rp0,2/20°C

63,3

73,3

53,3

56,7

43,3

53,3

26,7

26,7

23,3

23,3

20 °C

63,3

73,3

53,3

56,7

43,3

53,3

26,7

26,7

23,3

23,3

50 °C

62,1

73,3

52,0

55,3

42,7

52,0

26,0

25,9

22,0

22,0

75 °C

62,1

71,6

50,7

54,0

41,3

50,7

25,3

25,1

21,3

21,3

100 °C

45,6

42,8

40,7

46,7

34,2

44,0

22,8

23,3

20,7

20,7

125 °C

27,2

25,2

26,0

29,3

27,1

30,7

20,4

21,5

19,3

19,3

150 °C

Value of f for design temperaturea MPa

Table C.2 — Cold drawn rod/bar and tube

Mechanical properties for cold drawn rod/bar and tube shall comply with EN 754-2:2013.

C.3 Cold drawn rod/bar and tube

16,5

14,1

15,3

18,7

20,0

22,0

18,0

19,8

17,3

17,3

175 °C

10,8

8,8

10,7

12,0

13,3

16,0

14,7

16,0

15,3

15,3

37

200 °C

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38

a

T (10 %)

L (12 %)

Test direction

H112

H112 H112

Temper

Italic numerical values are creep-range values.

EN AW-5754 EN AW-5083

EN AW number

110

80 120

MPa

Rp0,2/20°C

73,3

53,3 80,0

20 °C

73,3

53,3 80,0

50 °C

73,3

52,2 80,0

75 °C

Table C.3 — Forgings

Mechanical properties for forgings shall comply with EN 586-2:1994.

C.4 Forgings

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69,8

50,7 76,2

100 °C

42,8

23,2 46,7

125 °C

25,2

14,9 27,5

150 °C

Value of f for design temperaturea MPa

14,1

8,8 15,4

175 °C

8,8

6,1 9,6

200 °C

O/H111

O/H111

O/H111

EN AW-5005

EN AW-5005A

H112

O/H111

40

12,5 ≤ t < 80

40

12,5 ≤ t < 80

35

35

40

70

6 ≤ t < 12,5

35

70

6 ≤ t < 12,5

35

O/H111

H112

15

O/H111 t ≤ 50

20

6 ≤ t ≤ 12,5

H112

25

12,5 < t ≤ 80 15

30

20

MPa

6 ≤ t ≤ 12,5

Wall thickness mm

O/H111

H112

O/H111

Temper

EN AW-3105

EN AW-3103

EN AW-3003

EN AW-1080A

EN AW-1070Ac

EN AW-1050A

c

EN AW number

23,3

23,3

26,7

26,7

45,8

23,3

26,7

46,7

23,3

14,7

22,2

16,7

16,7

20,0

20,0

20 °C

23,3

23,3

26,7

26,7

45,8

23,3

26,7

46,7

23,3

14,0

21,3

16,0

16,1

19,3

19,3

50 °C

Table C.4 — Plate Rp0,2/20°C

Mechanical properties for plates shall comply with EN 485-2:2013.

C.5 Plate

22,8

22,7

25,3

25,5

44,7

22,0

25,5

44,7

22,0

13,3

20,4

15,3

15,6

18,7

18,7

75 °C

22,2

22,0

24,0

24,0

42,0

21,3

24,0

42,0

21,3

12,7

18,7

14,0

13,9

16,7

16,7

100 °C

20,0

20,4

30,0

19,8

34,7

20,7

19,8

34,7

20,7

12,0

17,8

13,3

11,1

13,3

13,3

125 °C

17,9

18,8

23,3

14,9

26,0

19,3

14,9

26,0

19,3

11,3

16,9

12,7

8,3

10,0

10,0

150 °C

Value of f for design temperaturea MPa

15,8

17,3

17,3

11,0

19,3

19,3

11,0

19,3

17,3

—

—

—

6,7

8,0

8,0

175 °C

39

12,8

14,0

14,0

8,8

15,3

15,3

8,8

15,3

15,3

—

—

—

5,3

6,4

6,3

200 °C

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue33(2014-08) (2014-08) Issue

40

EN AW-5754

EN AW-5454

EN AW-5251

EN AW-5154A

EN AW-5052

EN AW-5049

EN AW-5050

EN AW number

70

12,5 < t ≤ 80

90

12,5 < t ≤ 80

H112

90 80

25 < t ≤ 80

100

12,5 < t ≤ 25

6 < t ≤ 12,5

90

H112 80

85

O/H111

O/H111

60 40 < t ≤ 120

125

6 < t ≤ 12,5

85

80

6 < t ≤ 12,5

65

80

25 < t ≤ 80 0,2 < t ≤ 80

90

12,5 < t ≤ 25

O/H111

H112

O/H111

H112

O/H111

H112

100

80

O/H111 6 < t ≤ 12,5

55

H112

53,3

60,0

66,7

53,3

60,0

56,7

40,0

60,0

83,3

56,7

46,7

53,3

43,3

53,3

60,0

66,7

53,3

53,3

60,0

66,7

53,3

60,0

56,7

40,0

60,0

83,3

56,7

46,7

53,3

43,3

53,3

60,0

66,7

53,3

36,7

30,0

30,0 36,7

50 °C

20 °C

Table C.4 (2/3) Rp0,2/20°C MPa

45

Wall thickness mm

O/H111

Temper

BS 13480-8:2012+A1:2014 BSEN EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue Issue3 (2014-08) 3 (2014-08)

52,2

58,7

65,2

52,0

58,6

55,3

39,3

58,6

81,3

55,3

45,8

52,4

42,7

52,2

58,7

65,2

52,0

36,0

29,3

75 °C

50,7

57,0

63,3

50,7

57,1

54,0

38,0

57,1

79,3

54,0

44,5

50,9

41,3

50,7

57,0

63,3

50,7

34,7

28,7

100 °C

23,2

26,1

29,0

40,7

32,6

45,3

32,6

33,6

46,7

46,7

27,6

31,5

34,2

25,1

28,3

31,4

44,0

29,8

25,8

125 °C

14,9

16,7

18,6

26,0

22,6

31,3

27,3

21,1

29,3

29,3

26,3

30,1

27,1

17,5

19,7

21,9

30,7

24,9

22,9

150 °C

Value of f for design temperaturea MPa

8,8

9,9

11,0

15,3

15,4

21,3

18,0

13,4

18,7

18,7

12,7

14,5

20,0

12,6

14,1

15,7

22,0

20,0

20,0

175 °C

6,1

6,9

7,6

10,7

11,0

15,3

12,7

8,6

12,0

12,0

8,5

9,7

13,3

9,1

10,3

11,4

16,0

14,7

14,7

200 °C

The nominal design stress values are based on Rp1,0-strength values.

66,7

Yield strength at room temperature of 125 MPa shell be guaranteed and verified by the plate manufacturer.

66,7

66,7

73,3

76,7

83,3

60,0

63,3

70,0

73,3

76,7

83,3

75 °C

c

66,7

66,7

73,3

76,7

83,3

60,0

63,3

70,0

73,3

76,7

83,3

50 °C

Italic numerical values are creep-range values.

100

66,7

100 40 < t ≤ 80

73,3

76,7

83,3

110

125

6 < t ≤ 40

60,0

80 < t ≤ 120

90

250 < t ≤ 300

63,3

115

95

200 < t ≤ 250

70,0

73,3

76,7

83,3

20 °C

40 < t ≤ 80

105

110

115

125

120 < t ≤ 200

80 < t ≤ 120

50 < t ≤ 80

t ≤ 50 b

MPa

63,5

63,3

69,8

73,0

79,3

57,1

60,3

66,6

69,8

73,0

79,3

100 °C

38,4

48,0

42,8

44,8

48,7

35,0

37,0

40,9

42,8

44,8

48,7

125 °C

22,9

28,7

25,2

26,4

28,7

20,6

21,8

24,1

25,2

26,4

28,7

150 °C

Value of f for design temperaturea MPa

b

H112

O/H111

H112

O/H111

Temper

Rp0,2/20°C

a

EN AW-5086

EN AW-5083

EN AW number

Wall thickness mm

Table C.4 (3/3)

13,9

17,3

14,1

14,7

16,0

11,5

12,2

13,4

14,1

14,7

16,0

175 °C

41

9,1

11,3

8,8

9,2

10,0

7,2

7,6

8,4

8,8

9,2

10,0

200 °C

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue33(2014-08) (2014-08) Issue

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue 33(2014-08) Issue (2014-08)

Annex Y (informative) History of EN 13480-8

Y.1 Differences between EN 13480-8:2007 and EN 13480-8:2012 Significant technical changes include: — the Normative References have been updated; — in 5.2 requirements for inspection documents were added; — in 5.6 the requirements on design temperature and properties have been revised; — subclause 6.8 on port-hole extruded tubes has been added; — subclause 6.9 on alternative methods for design was added; — in 8.2.3 the requirements on destructive testing of formed and heat treated parts have been revised; — a normative Annex C including allowable design stress values has been added. NOTE

The changes referred include the significant technical changes but is not an exhaustive list of all modifications.

Y.2 List of corrected pages of Issue 2 (2013-08) Pages 5, 6 and 35.

Y.3 List of corrected pages of Issue 3 (2014-08) Pages 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 31, 32, 34, 35 (34a), 36 (34b), 37 (34c), 38 (34d), 39 (34e), 40 (34f), 41 (34g), 42 (35), 43 (36) and 44 (37).

42

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue33(2014-08) (2014-08) Issue

Annex ZA (informative) Relationship between this European Standard and the Essential Requirements of EU Directive 97/23/EC This European Standard has been prepared under a mandate given to CEN by the European Commission to provide a means of conforming to Essential Requirements of the New Approach Directive 97/23/EC of the European Parliament and of the Council of 29 May 1997 on the approximation of the laws of the Member States concerning pressure equipment. Once this standard is cited in the Official Journal of the European Union under that Directive and has been implemented as a national standard in at least one Member State, compliance with the clauses of this standard given in Table ZA.1 confers, within the limits of the scope of this standard, a presumption of conformity with the corresponding Essential Requirements of that Directive and associated EFTA regulations. Table ZA.1 — Correspondence between this European Standard and Directive 97/23/EC Clauses of this European Standard

Content

Pressure Equipment Directive 97/23/EC, Annex I

Clause 5

Provision and consideration of appropriate material properties

2.2.3 (b), 5th indent

5.3, 5.7

Materials sufficiently ductile and tough

4.1 (a)

5.4, 7.2, 7.4, 7.5, 7.6, Annex B

Material suitable for intended processing procedure

4.1 (d)

5.6

Ambient and operational temperatures

2.2.1, 2nd indent

6, Annex B

Design for adequate strength

2.2

6.2

Nominal design stress

7.1.2

6.3, 6.4, 6.5, 6.6

Calculation method — Design by Formula (DBF)

2.2.3 (a)

6.9

Calculation method – Design by Analysis (DBA)

2.2.3 (a)

7.6, Annex B

Operating procedure to carry out permanent joints

3.1.2

Qualified personnel to carry out permanent joints

3.1.2

7.4, 7.6.3, 7.6.5

Preparation of component parts

3.1.1

7.5

Forming

3.1.1

7.5.3, 7.5.4, 7.6.6

Heat treatment

3.1.4

8.4, 8.6

Appropriate joint factors

2.2.3 (b), 6th indent

8.4, 8.5, Annex B

Internal and surface defect

3.2.1

8.4.3, 8.6

Joint efficiency

7.2

9.2, Annex B

Proof test

3.2.2

WARNING — Other requirements and other EU Directives may be applicable to the product(s) falling within the scope of this standard.

43

BS EN 13480-8:2012+A1:2014 BS EN 13480-8:2012 EN 13480-8:2012+A1:2014 (E) EN 13480-8:2012 (E) Issue 33(2014-08) Issue (2014-08)

Bibliography

EN 764-4:2002, Pressure equipment — Part 4: Establishment of technical delivery conditions for metallic materials EN 764-5:2002, Pressure Equipment — Part 5: Compliance and Inspection Documentation of Materials EN 1011-2:2001, Welding — Recommendations for welding of metallic materials — Part 2: Arc welding of ferritic steels EN 1011-4:2000, Welding — Recommendations for welding of metallic materials — Part 4: Arc welding of aluminium and aluminium alloys EN 1092-4:2002, Flanges and their joints — Circular flanges for pipes, valves, fittings and accessories, PN designated — Part 4: Aluminium alloy flanges EN 1252-1, Cryogenic vessels — Materials — Part 1: Toughness requirements for temperatures below -80°C EN 13445-3:2009, Unfired pressure vessels — Part 3: Design EN 13445-8:2009, Unfired pressure vessels — Part 8: Additional requirements for pressure vessels of aluminium and aluminium alloys EN 14717, Welding and allied processes — Environmental check list CEN/TR 13480-7, Metallic industrial piping — Part 7: Guidance on the use of conformity assessment procedures EN ISO 13920, Welding — General tolerances for welded constructions — Dimensions for lengths and angles — Shape and position (ISO 13920:1996) FDBR Guideline, Design of power piping, July 19951)

1)

44

To be obtained from: Vulkan-Verlag, Huyssenallee 52-56, D-45128 Essen.

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