SIST EN 485-2:2016
(Main)Aluminium and aluminium alloys - Sheet, strip and plate - Part 2: Mechanical properties
Aluminium and aluminium alloys - Sheet, strip and plate - Part 2: Mechanical properties
This European Standard specifies the mechanical properties of wrought aluminium and wrought aluminium alloy sheet, strip and plate for general engineering applications.
It does not apply to semi-finished rolled products in coiled form to be subjected to further rolling (reroll stock) or to special products such as corrugated, embossed, painted, sheets and strips or to special applications such as aerospace, can stock, finstock, for which mechanical properties are specified in separate European Standards.
The chemical composition limits of the alloys are specified in EN 573-3. Temper designations are defined in EN 515.
Aluminium und Aluminiumlegierungen - Bänder, Bleche und Platten - Teil 2: Mechanische Eigenschaften
Diese Europäische Norm legt die mechanischen Eigenschaften für Bleche, Bänder und Platten aus Aluminium und Aluminium Knetlegierungen fest, die für allgemeine Anwendung bestimmt sind.
Sie gilt nicht für gewalzte Halbzeuge in aufgerollter Form, die einem weiteren Walzvorgang unterzogen werden (Vorwalzbänder), oder für spezielle Erzeugnisse, wie z. B. profilierte, geprägte oder lackierte Bänder und Bleche oder für spezielle Anwendungen, wie z. B. Luft und Raumfahrt, Getränkedosen, Wärmeaus¬tau¬scher vorgesehen sind, für die mechanische Eigenschaften in gesonderten Europäischen Normen festgelegt sind.
Die Grenzwerte der chemischen Zusammensetzung der Legierungen sind in EN 573 3 festgelegt. Die Bezeichnungen der Werkstoffzustände sind in EN 515 definiert.
Aluminium et alliages d'aluminium - Tôles, bandes et tôles épaisses - Partie 2: Caractéristiques mécaniques
La présente Norme européenne spécifie les caractéristiques mécaniques des tôles, bandes et tôles épaisses en aluminium corroyé et alliages d’aluminium corroyés pour applications courantes.
Elle ne s’applique pas aux demi-produits laminés, livrés en bobines, destinés à être relaminés (ébauches de relaminage), ni aux produits spéciaux, tels que les tôles et bandes ondulées, gravées, laquées, etc., ni aux applications spéciales, telles que la construction aéronautique, le boîtage et les échangeurs thermiques, pour lesquels les caractéristiques mécaniques sont spécifiées dans des Normes européennes séparées.
Les limites de composition chimique des alliages sont spécifiées dans l’EN 573-3. Les désignations des états métallurgiques sont définies sont définies dans l'EN 515.
Aluminij in aluminijeve zlitine - Pločevine, trakovi in plošče - 2. del: Mehanske lastnosti
Ta evropski standard določa mehanske lastnosti pločevin, trakov in plošč iz gnetenega aluminija in aluminijeve zlitine za splošno tehnično uporabo.
Ne uporablja se za valjane polizdelke v zviti obliki, ki bodo dalje valjani (material za ponovno valjanje), ali za posebne izdelke, kot so valovite, reliefne, barvane pločevine in trakovi, ali za posebne uporabe, npr. v aeronavtiki, za izdelavo pločevink in folij, za katere so mehanske lastnosti opredeljene v ločenih evropskih standardih.
Omejitve kemijske sestave zlitin so podane v standardu EN 573-3. Oznake za popuščanje so opredeljene v standardu EN 515.
General Information
Relations
Standards Content (Sample)
SLOVENSKI STANDARD
SIST EN 485-2:2016
01-oktober-2016
1DGRPHãþD
SIST EN 485-2:2014
$OXPLQLMLQDOXPLQLMHYH]OLWLQH3ORþHYLQHWUDNRYLLQSORãþHGHO0HKDQVNH
ODVWQRVWL
Aluminium and aluminium alloys - Sheet, strip and plate - Part 2: Mechanical properties
Aluminium und Aluminiumlegierungen - Bänder, Bleche und Platten - Teil 2:
Mechanische Eigenschaften
Aluminium et alliages d'aluminium - Tôles, bandes et tôles épaisses - Partie 2:
Caractéristiques mécaniques
Ta slovenski standard je istoveten z: EN 485-2:2016
ICS:
77.150.10 Aluminijski izdelki Aluminium products
SIST EN 485-2:2016 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
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SIST EN 485-2:2016
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SIST EN 485-2:2016
EN 485-2
EUROPEAN STANDARD
NORME EUROPÉENNE
July 2016
EUROPÄISCHE NORM
ICS 77.150.10 Supersedes EN 485-2:2013
English Version
Aluminium and aluminium alloys - Sheet, strip and plate -
Part 2: Mechanical properties
Aluminium et alliages d'aluminium - Tôles, bandes et Aluminium und Aluminiumlegierungen - Bänder,
tôles épaisses - Partie 2: Caractéristiques mécaniques Bleche und Platten - Teil 2: Mechanische Eigenschaften
This European Standard was approved by CEN on 12 June 2016.
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, 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
United Kingdom.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION
EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2016 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 485-2:2016 E
worldwide for CEN national Members.
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Contents Page
European foreword . 3
1 Scope . 5
2 Normative references . 5
3 Requirements . 5
4 List of alloys with mechanical property limits . 5
4.1 General . 5
4.2 Elongation . 5
4.3 List of alloys and their mechanical properties . 6
Annex A (normative) Rules for rounding . 101
Bibliography . 102
2
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SIST EN 485-2:2016
EN 485-2:2016 (E)
European foreword
This document (EN 485-2:2016) has been prepared by Technical Committee CEN/TC 132 “Aluminium
and aluminium alloys”, 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 January 2017, and conflicting national standards shall
be withdrawn at the latest by January 2017.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN shall not be held responsible for identifying any or all such patent rights.
This document supersedes EN 485-2:2013.
CEN/TC 132 affirms it is policy that in the case when a patentee refuses to grant licences on
standardized standard products under reasonable and not discriminatory condition, then this product
should be removed from the corresponding document.
Details of any patents rights identified during the development of this document will be in the CEN list
of patent declaration received (see
http://www.cencenelec.eu/ipr/Patents/PatentDeclaration/Pages/default.aspx).
CEN/TC 132 decided to revise EN 485-2:2013 as follows:
— Addition of Alloy EN AW-5042 [AlMg 3,5 Mn] in Table 24;
— Correction of Alloy EN AW-5059 [Al Mg5,5MnZnZr] in Table 28;
— Correction of Alloy EN AW-5083 [Al Mg4,5Mn0,7] in Table 30;
— Correction of Alloy EN AW-5086 [Al Mg4] in Table 31;
— Correction of Alloy EN AW-5088 [AlMg5Mn0,4] in Table 32;
— Correction of Alloy EN AW-5383 [Al Mg4,5Mn0,9] in Table 36;
— Correction of Alloy EN AW-5456 [Al Mg5Mn1] in Table 40;
— Addition of alloy EN AW-5657 [Al 99,85Mg1] in a new Table 41;
— Addition of alloy EN AW-6056 [Al Si1MgCuMn] in a new Table 45;
— Addition of alloy EN AW-7019 [Al Zn4Mg2] in a new Table 49;
— Correction of the headers in the last column “hardness” in all tables (index a).
EN 485 comprises the following parts under the general title, “Aluminium and aluminium alloys — Sheet,
strip and plate”:
— Part 1: Technical conditions for inspection and delivery
— Part 2: Mechanical properties
3
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SIST EN 485-2:2016
EN 485-2:2016 (E)
— Part 3: Tolerances on dimensions and form for hot-rolled products
— Part 4: Tolerances on shape and dimensions for cold-rolled products
According to the CEN-CENELEC Internal Regulations, the national standards organisations 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.
4
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SIST EN 485-2:2016
EN 485-2:2016 (E)
1 Scope
This European Standard specifies the mechanical properties of wrought aluminium and wrought
aluminium alloy sheet, strip and plate for general engineering applications.
It does not apply to semi-finished rolled products in coiled form to be subjected to further rolling (reroll
stock) or to special products such as corrugated, embossed, painted, sheets and strips or to special
applications such as aerospace, can stock, finstock, for which mechanical properties are specified in
separate European Standards.
The chemical composition limits of the alloys are specified in EN 573-3. Temper designations are
defined in EN 515.
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 13195, Aluminium and aluminium alloys - Specifications for wrought and cast products for marine
applications (shipbuilding, marine and offshore)
ASTM G66, Standard Test Method for Visual Assessment of Exfoliation Corrosion Susceptibility of 5xxx
Series Aluminium Alloys (ASSET Test)
ASTM G67, Standard Test Method for Determining the Susceptibility to Intergranular Corrosion of 5xxx
Series Aluminium Alloys by Mass Loss After Exposure to Nitric Acid (NAMLT Test)
3 Requirements
The mechanical properties shall be in conformity with those specified in Clause 4 or those agreed upon
between supplier and purchaser and stated on the order document.
4 List of alloys with mechanical property limits
4.1 General
Table 1 to Table 54 contain mechanical property limits values obtained by tensile testing according to
EN ISO 6892-1 after sampling and after sample preparation according to EN 485-1.
They also contain values of bend radius and hardness following sampling and test methods as described
in EN 485-1. These values are for information only.
For some alloys they contain provisions related to inter-granular corrosion, exfoliation corrosion or
stress corrosion testing, see also EN 485-1.
4.2 Elongation
The A value is the elongation measured over a gauge length of 50 mm and expressed in percent.
50mm
The A value for elongation is the elongation measured over a gauge length of 5,65 (where S is the
S o
o
initial cross-sectional area of the test-piece), and expressed in percent.
5
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SIST EN 485-2:2016
EN 485-2:2016 (E)
4.3 List of alloys and their mechanical properties
Page
Table 1 — Aluminium EN AW-1050A [Al 99,5] 8
Table 2 — Aluminium EN AW-1070A [Al 99,7] 10
Table 3 — Aluminium EN AW-1080A [Al 99,8(A)] 12
Table 4 — Aluminium EN AW-1200 [Al 99,0] 14
Table 5 — Aluminium EN AW-1350 [Al 99,5] 16
Table 6 — Alloy EN AW-2014 [Al Cu4SiMg] 18
Table 7 — Alloy EN AW-2014A [Al Cu4SiMg(A)] 20
Table 8 — Alloy EN AW-2017A [Al Cu4MgSi(A)] 22
Table 9 — Alloy EN AW-2024 [Al Cu4Mg1] 24
Table 10 — Alloy EN AW-2618A [Al Cu2Mg1,5Ni] 25
Table 11 — Alloy EN AW-3003 [Al Mn1Cu] 26
Table 12 — Alloy EN AW-3004 [Al Mn1Mg1] 28
Table 13 — Alloy EN AW-3005 [Al Mn1Mg0,5] 30
Table 14 — Alloy EN AW-3103 [Al Mn1] 32
Table 15 — Alloy EN AW-3105 [Al Mn0,5Mg0,5] 34
Table 16 — Alloy EN AW-4006 [Al Si1Fe] 35
Table 17 — Alloy EN AW-4007 [Al Si1,5Mn] 36
Table 18 — Alloy EN AW-4015 [Al Si2Mn] 37
Table 19 — Alloy EN AW-4115 [Al Si2MnMgCu] 37
Table 20 — Alloy EN AW-5005 [Al Mg1(B)] Alloy EN AW-5005A [Al 38
Mg1(C)]
Table 21 — Alloy EN AW-5010 [AlMg 0,5Mn] 41
Table 22 — Alloy EN AW-5026 [AI Mg4,5 MnSiFe] 43
Table 23 — Alloy EN AW-5040 [Al Mg1,5Mn] 43
Table 24 — Alloy EN AW-5042 [AlMg 3,5 Mn] 44
Table 25 — Alloy EN AW-5049 [Al Mg2Mn0,8] 45
Table 26 — Alloy EN AW-5050 [Al Mg1,5(C)] 48
Table 27 — Alloy EN AW-5052 [Al Mg2,5] 50
Table 28 — Alloy EN AW-5059 [Al Mg5,5MnZnZr] 53
Table 29 — Alloy EN AW-5070 [Al Mg4MnZn] 54
Table 30 — Alloy EN AW-5083 [Al Mg4,5Mn0,7] 54
Table 31 — Alloy EN AW-5086 [Al Mg4] 57
Table 32 — Alloy EN AW-5088 [AlMg5Mn0,4] 60
Table 33 — Alloy EN AW-5154A [Al Mg3,5(A)] 61
6
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 34 — Alloy EN AW-5182 [Al Mg4,5Mn0,4] 63
Table 35 — Alloy EN AW-5251 [Al Mg2Mn0,3] 64
Table 36 — Alloy EN AW-5383 [Al Mg4,5Mn0,9] 66
Table 37 — Alloy EN AW-5449 [Al Mg2Mn0,8(B)] 68
Table 38 — Alloy EN AW-5449A [Al Mg2Mn0,8(C)] 69
Table 39 — Alloy EN AW-5454 [Al Mg3Mn] 70
Table 40 — Alloy EN AW-5456 [Al Mg5Mn1] 73
Table 41 — Alloy EN AW-5657 [Al 99,85Mg 1] 74
Table 42 — Alloy EN AW-5754 [Al Mg3] 74
Table 43 — Alloy EN AW-6016 [Al Si1,2Mg0,4] 77
Table 44 — Alloy EN AW-6025 [Al Mg2,5SiMnCu] 77
Table 45 – Alloy EN AW-6056 [Al Si1MgCuMn] 78
Table 46 — Alloy EN AW-6061 [Al Mg1SiCu] 79
Table 47 — Alloy EN AW-6082 [Al Si1MgMn] 81
Table 48 — Alloy EN AW-7010 [Al Zn6MgCu] 85
Table 49 — Alloy EN AW-7019 [Al Zn4Mg2] 88
Table 50 — Alloy EN AW-7020 [Al Zn4,5Mg1] 89
Table 51 — Alloy EN AW-7021 [Al Zn5,5Mg1,5] 91
Table 52 — Alloy EN AW-7022 [Al Zn5Mg3Cu] 91
Table 53 — Alloy EN AW-7075 [Al Zn5,5MgCu] 92
Table 54 — Alloy EN AW-8011A [Al FeSi(A)] 95
7
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 1 — Aluminium EN AW-1050A [Al 99,5]
Temper Specified Tensile Yield Elongation Bend Hardn
a
thickness strength strength a ess
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
a ≥ 2,5 150,0 60
F
O 0,2 0,5 65 95 20 20 0 t 0 t 20
0,5 1,5 65 95 20 22 0 t 0 t 20
1,5 3,0 65 95 20 26 0 t 0 t 20
3,0 6,0 65 95 20 29 0,5 t 0,5 t 20
6,0 12,5 65 95 20 35 1,0 t 1,0 t 20
12,5 80,0 65 95 20 32 20
H111 0,2 0,5 65 95 20 20 0 t 0 t 20
0,5 1,5 65 95 20 22 0 t 0 t 20
1,5 3,0 65 95 20 26 0 t 0 t 20
3,0 6,0 65 95 20 29 0,5 t 0,5 t 20
6,0 12,5 65 95 20 35 1,0 t 1,0 t 20
12,5 80,0 65 95 20 32 20
H112 ≥ 6,0 12,5 75 30 20 23
12,5 80,0 70 25 20 22
H12 0,2 0,5 85 125 65 2 0,5 t 0 t 28
0,5 1,5 85 125 65 4 0,5 t 0 t 28
1,5 3,0 85 125 65 5 0,5 t 0,5 t 28
3,0 6,0 85 125 65 7 1,0 t 1,0 t 28
6,0 12,5 85 125 65 9 2,0 t 28
12,5 40,0 85 125 65 9 28
H14 0,2 0,5 105 145 85 2 1,0 t 0 t 34
0,5 1,5 105 145 85 2 1,0 t 0,5 t 34
1,5 3,0 105 145 85 4 1,0 t 1,0 t 34
3,0 6,0 105 145 85 5 1,5 t 34
6,0 12,5 105 145 85 6 2,5 t 34
12,5 25,0 105 145 85 6 34
H16 0,2 0,5 120 160 100 1 0,5 t 39
0,5 1,5 120 160 100 2 1,0 t 39
8
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Temper Specified Tensile Yield Elongation Bend Hardn
a
thickness strength strength a ess
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
1,5 4,0 120 160 100 3 1,5 t 39
H18 0,2 0,5 135 120 1 1,0 t 42
0,5 1,5 140 120 2 2,0 t 42
1,5 3,0 140 120 2 3,0 t 42
H19 0,2 0,5 155 140 1 45
0,5 1,5 150 130 1 45
1,5 3,0 150 130 1 45
H22 0,2 0,5 85 125 55 4 0,5 t 0 t 27
0,5 1,5 85 125 55 5 0,5 t 0 t 27
1,5 3,0 85 125 55 6 0,5 t 0,5 t 27
3,0 6,0 85 125 55 11 1,0 t 1,0 t 27
6,0 12,5 85 125 55 12 2,0 t 27
H24 0,2 0,5 105 145 75 3 1,0 t 0 t 33
0,5 1,5 105 145 75 4 1,0 t 0,5 t 33
1,5 3,0 105 145 75 5 1,0 t 1,0 t 33
3,0 6,0 105 145 75 8 1,5 t 1,5 t 33
6,0 12,5 105 145 75 8 2,5 t 33
H26 0,2 0,5 120 160 90 2 0,5 t 38
0,5 1,5 120 160 90 3 1,0 t 38
1,5 4,0 120 160 90 4 1,5 t 38
H28 0,2 0,5 140 110 2 1,0 t 41
0,5 1,5 140 110 2 2,0 t 41
1,5 3,0 140 110 3 3,0 t 41
a
For information only.
9
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 2 — Aluminium EN AW-1070A [Al 99,7]
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
a ≥ 2,5 25,0 60
F
O 0,2 0,5 60 90 15 23 0 t 0 t 18
0,5 1,5 60 90 15 25 0 t 0 t 18
1,5 3,0 60 90 15 29 0 t 0 t 18
3,0 6,0 60 90 15 32 0,5 t 0,5 t 18
6,0 12,5 60 90 15 35 0,5 t 0,5 t 18
12,5 25,0 60 90 15 32 18
H111 0,2 0,5 60 90 15 23 0 t 0 t 18
0,5 1,5 60 90 15 25 0 t 0 t 18
1,5 3,0 60 90 15 29 0 t 0 t 18
3,0 6,0 60 90 15 32 0,5 t 0,5 t 18
6,0 12,5 60 90 15 35 0,5 t 0,5 t 18
12,5 25,0 60 90 15 32 18
H112 ≥ 6,0 12,5 70 20 20
12,5 25,0 70 20
H12 0,2 0,5 80 120 55 5 0,5 t 0 t 26
0,5 1,5 80 120 55 6 0,5 t 0 t 26
1,5 3,0 80 120 55 7 0,5 t 0,5 t 26
3,0 6,0 80 120 55 9 1,0 t 26
6,0 12,5 80 120 55 12 2,0 t 26
H14 0,2 0,5 100 140 70 4 0,5 t 0 t 32
0,5 1,5 100 140 70 4 0,5 t 0,5 t 32
1,5 3,0 100 140 70 5 1,0 t 1,0 t 32
3,0 6,0 100 140 70 6 1,5 t 32
6,0 12,5 100 140 70 7 2,5 t 32
H16 0,2 0,5 110 150 90 2 1,0 t 0,5 t 36
0,5 1,5 110 150 90 2 1,0 t 1,0 t 36
1,5 4,0 110 150 90 3 1,0 t 1,0 t 36
H18 0,2 0,5 125 105 2 1,0 t 40
10
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SIST EN 485-2:2016
EN 485-2:2016 (E)
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
0,5 1,5 125 105 2 2,0 t 40
1,5 3,0 125 105 2 2,5 t 40
H22 0,2 0,5 80 120 50 7 0,5 t 0 t 26
0,5 1,5 80 120 50 8 0,5 t 0 t 26
1,5 3,0 80 120 50 10 0,5 t 0,5 t 26
3,0 6,0 80 120 50 12 1,0 t 26
6,0 12,5 80 120 50 15 2,0 t 26
H24 0,2 0,5 100 140 60 5 0,5 t 0 t 31
0,5 1,5 100 140 60 6 0,5 t 0,5 t 31
1,5 3,0 100 140 60 7 1,0 t 1,0 t 31
3,0 6,0 100 140 60 9 1,5 t 31
6,0 12,5 100 140 60 11 2,5 t 31
H26 0,2 0,5 110 150 80 3 0,5 t 35
0,5 1,5 110 150 80 3 1,0 t 35
1,5 4,0 110 150 80 4 1,0 t 35
a
For information only.
11
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 3 — Aluminium EN AW-1080A [Al 99,8(A)]
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
a ≥ 2,5 25,0 60
F
O 0,2 0,5 60 90 15 26 0 t 0 t 18
0,5 1,5 60 90 15 28 0 t 0 t 18
1,5 3,0 60 90 15 31 0 t 0 t 18
3,0 6,0 60 90 15 35 0,5 t 0,5 t 18
6,0 12,5 60 90 15 35 0,5 t 0,5 t 18
H111 0,2 0,5 60 90 15 26 0 t 0 t 18
0,5 1,5 60 90 15 28 0 t 0 t 18
1,5 3,0 60 90 15 31 0 t 0 t 18
3,0 6,0 60 90 15 35 0,5 t 0,5 t 18
6,0 12,5 60 90 15 35 0,5 t 0,5 t 18
H112 ≥ 6,0 12,5 70 20
12,5 25,0 70 20
H12 0,2 0,5 80 120 55 5 0,5 t 0 t 26
0,5 1,5 80 120 55 6 0,5 t 0 t 26
1,5 3,0 80 120 55 7 0,5 t 0,5 t 26
3,0 6,0 80 120 55 9 1,0 t 26
6,0 12,5 80 120 55 12 2,0 t 26
H14 0,2 0,5 100 140 70 4 0,5 t 0 t 32
0,5 1,5 100 140 70 4 0,5 t 0,5 t 32
1,5 3,0 100 140 70 5 1,0 t 1,0 t 32
3,0 6,0 100 140 70 6 1,5 t 32
6,0 12,5 100 140 70 7 2,5 t 32
H16 0,2 0,5 110 150 90 2 1,0 t 0,5 t 36
0,5 1,5 110 150 90 2 1,0 t 1,0 t 36
1,5 4,0 110 150 90 3 1,0 t 1,0 t 36
H18 0,2 0,5 125 105 2 1,0 t 40
0,5 1,5 125 105 2 2,0 t 40
1,5 3,0 125 105 2 2,5 t 40
12
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SIST EN 485-2:2016
EN 485-2:2016 (E)
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
H22 0,2 0,5 80 120 50 8 0,5 t 0 t 26
0,5 1,5 80 120 50 9 0,5 t 0 t 26
1,5 3,0 80 120 50 11 0,5 t 0,5 t 26
3,0 6,0 80 120 50 13 1,0 t 26
6,0 12,5 80 120 50 15 2,0 t 26
H24 0,2 0,5 100 140 60 5 0,5 t 0 t 31
0,5 1,5 100 140 60 6 0,5 t 0,5 t 31
1,5 3,0 100 140 60 7 1,0 t 1,0 t 31
3,0 6,0 100 140 60 9 1,5 t 31
6,0 12,5 100 140 60 11 2,5 t 31
H26 0,2 0,5 110 150 80 3 0,5 t 35
0,5 1,5 110 150 80 3 1,0 t 35
1,5 4,0 110 150 80 4 1,0 t 35
a
For information only.
13
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 4 — Aluminium EN AW-1200 [Al 99,0]
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min.
radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
a ≥ 2,5 150,0 75
F
O 0,2 0,5 75 105 25 19 0 t 0 t 23
0,5 1,5 75 105 25 21 0 t 0 t 23
1,5 3,0 75 105 25 24 0 t 0 t 23
3,0 6,0 75 105 25 28 0,5 t 0,5 t 23
6,0 12,5 75 105 25 33 1,0 t 1,0 t 23
12,5 80,0 75 105 25 30 23
H111 0,2 0,5 75 105 25 19 0 t 0 t 23
0,5 1,5 75 105 25 21 0 t 0 t 23
1,5 3,0 75 105 25 24 0 t 0 t 23
3,0 6,0 75 105 25 28 0,5 t 0,5 t 23
6,0 12,5 75 105 25 33 1,0 t 1,0 t 23
12,5 80,0 75 105 25 30 23
H112 ≥ 6,0 12,5 85 35 16 26
12,5 80,0 80 30 16 24
H12 0,2 0,5 95 135 75 2 0,5 t 0 t 31
0,5 1,5 95 135 75 4 0,5 t 0 t 31
1,5 3,0 95 135 75 5 0,5 t 0,5 t 31
3,0 6,0 95 135 75 6 1,0 t 1,0 t 31
6,0 12,5 95 135 75 8 2,0 t 31
12,5 40,0 95 135 75 8 31
H14 0,2 0,5 105 155 95 1 1,0 t 0 t 37
0,5 1,5 115 155 95 3 1,0 t 0,5 t 37
1,5 3,0 115 155 95 4 1,0 t 1,0 t 37
3,0 6,0 115 155 95 5 1,5 t 1,5 t 37
6,0 12,5 115 155 90 6 2,5 t 37
12,5 25,0 115 155 90 6 37
H16 0,2 0,5 120 170 110 1 0,5 t 42
0,5 1,5 130 170 115 2 1,0 t 42
1,5 4,0 130 170 115 3 1,5 t 42
14
---------------------- Page: 16 ----------------------
SIST EN 485-2:2016
EN 485-2:2016 (E)
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min.
radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
H18 0,2 0,5 150 130 1 1,0 t 45
0,5 1,5 150 130 2 2,0 t 45
1,5 3,0 150 130 2 3,0 t 45
H19 0,2 0,5 160 140 1 48
0,5 1,5 160 140 1 48
1,5 3,0 160 140 1 48
H22 0,2 0,5 95 135 65 4 0,5 t 0 t 30
0,5 1,5 95 135 65 5 0,5 t 0 t 30
1,5 3,0 95 135 65 6 0,5 t 0,5 t 30
3,0 6,0 95 135 65 10 1,0 t 1,0 t 30
6,0 12,5 95 135 65 10 2,0 t 30
H24 0,2 0,5 115 155 90 3 1,0 t 0 t 37
0,5 1,5 115 155 90 4 1,0 t 0,5 t 37
1,5 3,0 115 155 90 5 1,0 t 1,0 t 37
3,0 6,0 115 155 90 7 1,5 t 37
6,0 12,5 115 155 85 9 2,5 t 36
H26 0,2 0,5 130 170 105 2 0,5 t 41
0,5 1,5 130 170 105 3 1,0 t 41
1,5 4,0 130 170 105 4 1,5 t 41
a
For information only.
15
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 5 — Aluminium EN AW-1350 [Al 99,5]
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
a
2,5 150,0 60
F
O 0,2 0,5 65 95 20 20 0 t 0 t 20
0,5 1,5 65 95 20 22 0 t 0 t 20
1,5 3,0 65 95 20 26 0 t 0 t 20
3,0 6,0 65 95 20 29 0,5 t 0,5 t 20
6,0 12,5 65 95 20 35 1,0 t 1,0 t 20
12,5 80,0 65 95 20 32 20
H111 0,2 0,5 65 95 20 20 0 t 0 t 20
0,5 1,5 65 95 20 22 0 t 0 t 20
1,5 3,0 65 95 20 26 0 t 0 t 20
3,0 6,0 65 95 20 29 0,5 t 0,5 t 20
6,0 12,5 65 95 20 35 1,0 t 1,0 t 20
12,5 80,0 65 95 20 32 20
H112 0,2 0,5 75 30 20 23
0,5 1,5 75 30 20 23
1,5 3,0 75 30 20 23
3,0 6,0 75 30 20 23
6,0 12,5 75 30 20 23
12,5 80,0 75 30 20 23
H12 0,2 0,5 85 125 65 2 0,5 t 0 t 28
0,5 1,5 85 125 65 4 0,5 t 0 t 28
1,5 3,0 85 125 65 5 0,5 t 0,5 t 28
3,0 6,0 85 125 65 7 1,0 t 1,0 t 28
6,0 12,5 85 125 65 9 2,0 t 28
12,5 40,0 85 125 65 9 28
H14 0,2 0,5 105 145 85 2 1,0 t 0 t 34
0,5 1,5 105 145 85 2 1,0 t 0,5 t 34
1,5 3,0 105 145 85 4 1,0 t 1,0 t 34
3,0 6,0 105 145 85 5 1,5 t 34
16
---------------------- Page: 18 ----------------------
SIST EN 485-2:2016
EN 485-2:2016 (E)
a
Temper Specified Tensile Yield Elongation Bend Hardness
thickness strength strength a
min. radius
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50
mm
6,0 12,5 105 145 85 6 2,5 t 34
12,5 25,0 105 145 85 6 34
H16 0,2 0,5 120 160 100 1 0,5 t 39
0,5 1,5 120 160 100 2 1,0 t 39
1,5 4,0 120 160 100 3 1,5 t 39
H18 0,2 0,5 140 120 1 1,0 t 42
0,5 1,5 140 120 2 2,0 t 42
1,5 3,0 140 120 2 3,0 t 42
H19 0,2 0,5 150 130 1 45
0,5 1,5 150 130 1 45
1,5 3,0 150 130 1 45
H22 0,2 0,5 85 125 55 4 0,5 t 0 t 27
0,5 1,5 85 125 55 5 0,5 t 0 t 27
1,5 3,0 85 125 55 6 0,5 t 0,5 t 27
3,0 6,0 85 125 55 11 1,0 t 1,0 t 27
6,0 12,5 85 125 55 12 2,0 t 27
H24 0,2 0,5 105 145 75 3 1,0 t 0 t 33
0,5 1,5 105 145 75 4 1,0 t 0,5 t 33
1,5 3,0 105 145 75 5 1,0 t 1,0 t 33
3,0 6,0 105 145 75 8 1,5 t 1,5 t 33
6,0 12,5 105 145 75 8 2,5 t 33
H26 0,2 0,5 120 160 90 2 0,5 t 38
0,5 1,5 120 160 90 3 1,0 t 38
1,5 4,0 120 160 90 4 1,5 t 38
H28 0,2 0,5 140 110 2 1,0 t 41
0,5 1,5 140 110 2 2,0 t 41
1,5 3,0 140 110 3 3,0 t 41
a
For information only.
17
---------------------- Page: 19 ----------------------
SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 6 — Alloy EN AW-2014 [Al Cu4SiMg]
a
Temper Specified Tensile Yield Elongation a Hardness
Bend radius
thickness strength strength
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
O ≥ 0,4 1,5 220 140 12 0,5 t 0 t 55
1,5 3,0 220 140 13 1,0 t 1,0 t 55
3,0 6,0 220 140 16 1,5 t 55
6,0 9,0 220 140 16 2,5 t 55
9,0 12,5 220 140 16 4,0 t 55
12,5 25,0 220 10 55
T3 ≥ 0,4 1,5 395 245 14 111
1,5 6,0 400 245 14 112
T4 ≥ 0,4 1,5 395 240 14 b b 110
3,0 t 3,0 t
1,5 6,0 395 240 14 b b 110
5,0 t 5,0 t
6,0 12,5 400 250 14 b 112
8,0 t
12,5 40,0 400 250 10 112
40,0 100,0 395 250 7 111
T451 ≥ 0,4 1,5 395 240 14 b b 110
3,0 t 3,0 t
1,5 6,0 395 240 14 b b 110
5,0 t 5,0 t
6,0 12,5 400 250 14 b 112
8,0 t
12,5 40,0 400 250 10 112
40,0 100,0 395 250 7 111
T42 ≥ 0,4 6,0 395 230 14 110
6,0 12,5 400 235 14 111
12,5 25,0 400 235 12 111
T6 ≥ 0,4 1,5 440 390 6 b 133
5,0 t
1,5 6,0 440 390 7 b 133
7,0 t
6,0 12,5 450 395 7 b 135
10 t
12,5 40,0 460 400 6 138
40,0 60,0 450 390 5 135
60,0 80,0 435 380 4 131
80,0 100,0 420 360 4 126
18
---------------------- Page: 20 ----------------------
SIST EN 485-2:2016
EN 485-2:2016 (E)
a
Temper Specified Tensile Yield Elongation a Hardness
Bend radius
thickness strength strength
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
100, 125,0 410 350 4 123
0
125, 160,0 390 340 2
0
T651 ≥ 0,4 1,5 440 390 6 b 133
5,0 t
1,5 6,0 440 390 7 b 133
7,0 t
6,0 12,5 450 395 7 b 135
10 t
12,5 40,0 460 400 6 138
40,0 60,0 450 390 5 135
60,0 80,0 435 380 4 131
80,0 100,0 420 360 4 126
100, 125,0 410 350 4 123
0
125, 160,0 390 340 2
0
T62 ≥ 0,4 12,5 440 390 7 133
12,5 25,0 450 395 6 135
Whenever a new application of this alloy is contemplated, and if this application involves special
properties such as corrosion resistance, toughness, fatigue strength, it is strongly recommended that the
user consult the producer in order to make a precise and appropriate selection of the material.
a
For information only.
b
Appreciably smaller cold bend radii can be achieved immediately after quenching.
19
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SIST EN 485-2:2016
EN 485-2:2016 (E)
Table 7 — Alloy EN AW-2014A [Al Cu4SiMg(A)]
a
Temper Specified Tensile Yield Elongation a Hardness
Bend radius
thickness strength strength
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
O ≥ 0,2 0,5 235 110 1,0 t 55
0,5 1,5 235 110 14 2,0 t 55
1,5 3,0 235 110 16 2,0 t 55
3,0 6,0 235 110 16 2,0 t 55
T4 ≥ 0,2 0,5 400 225 b 110
3,0 t
0,5 1,5 400 225 13 b 110
3,0 t
1,5 6,0 400 225 14 b 110
5,0 t
6,0 12,5 400 250 14
12,5 25,0 400 250 12
25,0 40,0 400 250 10
40,0 80,0 395 250 7
T451 ≥ 0,2 0,5 400 225 b 110
3,0 t
0,5 1,5 400 225 13 b 110
3,0 t
1,5 6,0 400 225 14 b 110
5,0 t
6,0 12,5 400 250 14
12,5 25,0 400 250 12
25,0 40,0 400 250 10
40,0 80,0 395 250 7
T6 ≥ 0,2 0,5 440 380 b 150
5,0 t
0,5 1,5 440 380 6 b 150
5,0 t
1,5 3,0 440 380 7 b 150
6,0 t
3,0 6,0 440 380 8 b 150
6,0 t
6,0 12,5 460 410 8
12,5 25,0 460 410 6
25,0 40,0 450 400 5
40,0 60,0 430 390 5
...
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.ODVWQRVWLAluminium und Aluminiumlegierungen - Bänder, Bleche und Platten - Teil 2: Mechanische EigenschaftenAluminium et alliages d'aluminium - Tôles, bandes et tôles épaisses - Partie 2: Caractéristiques mécaniquesAluminium and aluminium alloys - Sheet, strip and plate - Part 2: Mechanical properties77.150.10Aluminijski izdelkiAluminium productsICS:Ta slovenski standard je istoveten z:FprEN 485-2kSIST FprEN 485-2:2016en,fr,de01-februar-2016kSIST FprEN 485-2:2016SLOVENSKI
STANDARD
kSIST FprEN 485-2:2016
EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
FINAL DRAFT
FprEN 485-2
December
t r s w ICS
y yä s w rä s r Will supersede EN
v z wæ tã t r s uEnglish Version
Aluminium and aluminium alloys æ Sheetá strip and plate æ Part
tã Mechanical properties Aluminium et alliages d 5aluminium æ Tôlesá bandes et tôles épaisses æ Partie
tã Caractéristiques mécaniques Aluminium und Aluminiumlegierungen æ Bänderá Bleche und Platten æ Teil
tã Mechanische EigenschaftenThis draft European Standard is submitted to CEN members for unique acceptance procedureä It has been drawn up by the
If this draft becomes a European Standardá CEN members are bounwhich stipulate the conditions for giving this European Standard the status of a national standard without any alterationä
This draft European Standard was established by CEN in three ofer language made by translation under the responsibility of a CEN member into its own language and notified to the CENæCENELEC Management Centre has the same status as the official versionsä
CEN members are the national standards bodies of Austriaá Belgiumá Bulgariaá Croatiaá Cyprusá Czech Republicá Denmarká Estoniaá Finlandá Former Yugoslav Republic of Macedoniaá Franceá Germanyá Greeceá Hungaryá Icelandá Irelandá Italyá Latviaá Lithuaniaá Luxembourgá Maltaá Netherlandsá Norwayá Polandá Portugalá Romaniaá Slovakiaá Sloveniaá Spainá Swedená Switzerlandá Turkey andUnited Kingdomä
Recipients of this draft are invited to submitá with their commentsá notification of any relevant patent rights of which they are aware and to provide supporting documentationä
Warning ã This document is not a European Standardä It is distributed for review and commentsä It is subject to change without notice and shall not be referred to as a European Standardä
EUROPEAN COMMITTEE FOR STANDARDIZATION COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre:
Avenue Marnix 17,
B-1000 Brussels
9
t r s w CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Membersä Refä Noä FprEN
v z wæ tã t r s w EkSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 2 Contents Page European foreword . 3 1 Scope . 4 2 Normative references . 4 3 Requirements . 4 4 List of alloys with mechanical property limits . 4 4.1 General . 4 4.2 Elongation . 4 4.3 List of alloys and their mechanical properties . 5 Annex A (normative)
Rules for rounding . 96 Bibliography . 97
kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 3 European foreword This document (FprEN 485-2:2015) has been prepared by Technical Committee CEN/TC 132 “Aluminium and aluminium alloys”, the secretariat of which is held by AFNOR. This document is currently submitted to the Unique Acceptance Procedure. This document will supersede EN 485-2:2013. CEN/TC 132 affirms it is policy that in the case when a patentee refuses to grant licences on standardised standard products under reasonable and not discriminatory condition, then this product should be removed from the corresponding document. Details of any patents rights identified during the development of this document will be in the CEN list of patent declaration received (see http://www.cencenelec.eu/ipr/Patents/PatentDeclaration/Pages/default.aspx). CEN/TC 132 decided to revise EN 485-2:2013 as follows: — Addition of Alloy EN AW-5042 [AlMg 3,5 Mn] in Table 24; — Correction of Alloy EN AW-5059 [Al Mg5,5MnZnZr] in Table 28; — Correction of Alloy EN AW-5083 [Al Mg4,5Mn0,7] in Table 30; — Correction of Alloy EN AW-5086 [Al Mg4] in Table 31; — Correction of Alloy EN AW-5088 [AlMg5Mn0,4] in Table 32; — Correction of Alloy EN AW-5383 [Al Mg4,5Mn0,9] in Table 36; —
Correction of Alloy EN AW-5456 [Al Mg5Mn1] in Table 40; — Addition of alloy EN AW-5657 [Al 99,85Mg1] in a new Table 41; — Addition of alloy EN AW-6056 [Al Si1MgCuMn] in a new Table 45; — Addition of alloy EN AW-7019 [Al Zn4Mg2] in a new Table 49; — Correction of the headers in the last column "hardness" in all tables (index a). EN 485 comprises the following parts under the general title, "Aluminium and aluminium alloys — Sheet, strip and plate": — Part 1: Technical conditions for inspection and delivery — Part 2: Mechanical properties — Part 3: Tolerances on dimensions and form for hot-rolled products — Part 4: Tolerances on shape and dimensions for cold-rolled products kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 4 1 Scope This European Standard specifies the mechanical properties of wrought aluminium and wrought aluminium alloy sheet, strip and plate for general engineering applications. It does not apply to semi-finished rolled products in coiled form to be subjected to further rolling (reroll stock) or to special products such as corrugated, embossed, painted, sheets and strips or to special applications such as aerospace, can stock, finstock, for which mechanical properties are specified in separate European Standards. The chemical composition limits of the alloys are specified in EN 573-3. Temper designations are defined in EN 515. 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 13195, Aluminium and aluminium alloys — Specifications for wrought and cast products for marine applications (shipbuilding, marine and offshore) ASTM G66, Standard Test Method for Visual Assessment of Exfoliation Corrosion Susceptibility of 5xxx Series Aluminium Alloys (ASSET Test) ASTM G67, Standard Test Method for Determining the Susceptibility to Intergranular Corrosion of 5xxx Series Aluminium Alloys by Mass Loss After Exposure to Nitric Acid (NAMLT Test) 3 Requirements The mechanical properties shall be in conformity with those specified in Clause 4 or those agreed upon between supplier and purchaser and stated on the order document. 4 List of alloys with mechanical property limits 4.1 General Table 1 to Table 54 contain mechanical property limits values obtained by tensile testing according to EN ISO 6892-1 after sampling and after sample preparation according to FprEN 485-1. They also contain values of bend radius and hardness following sampling and test methods as described in FprEN 485-1. These values are for information only. For some alloys they contain provisions related to inter-granular corrosion, exfoliation corrosion or stress corrosion testing, see also FprEN 485-1. 4.2 Elongation The A50mm value is the elongation measured over a gauge length of 50 mm and expressed in percent. The A value for elongation is the elongation measured over a gauge length of 5,65 oS(where So is the initial cross-sectional area of the test-piece), and expressed in percent. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 5 4.3 List of alloys and their mechanical properties Page Table 1 — Aluminium EN AW-1050A [Al 99,5] 7 Table 2 — Aluminium EN AW-1070A [Al 99,7] 9 Table 3 — Aluminium EN AW-1080A [Al 99,8(A)] 11 Table 4 — Aluminium EN AW-1200 [Al 99,0] 13 Table 5 — Aluminium EN AW-1350 [Al 99,5] 15 Table 6 — Alloy EN AW-2014 [Al Cu4SiMg] 17 Table 7 — Alloy EN AW-2014A [Al Cu4SiMg(A)] 19 Table 8 — Alloy EN AW-2017A [Al Cu4MgSi(A)] 21 Table 9 — Alloy EN AW-2024 [Al Cu4Mg1] 22 Table 10 — Alloy EN AW-2618A [Al Cu2Mg1,5Ni] 24 Table 11 — Alloy EN AW-3003 [Al Mn1Cu] 25 Table 12 — Alloy EN AW-3004 [Al Mn1Mg1] 27 Table 13 — Alloy EN AW-3005 [Al Mn1Mg0,5] 29 Table 14 — Alloy EN AW-3103 [Al Mn1] 31 Table 15 — Alloy EN AW-3105 [Al Mn0,5Mg0,5] 33 Table 16 — Alloy EN AW-4006 [Al Si1Fe] 34 Table 17 — Alloy EN AW-4007 [Al Si1,5Mn] 35 Table 18 — Alloy EN AW-4015 [Al Si2Mn] 36 Table 19 — Alloy EN AW-4115 [Al Si2MnMgCu] 36 Table 20 — Alloy EN AW-5005 [Al Mg1(B)] Alloy EN AW-5005A [Al Mg1(C)] 37 Table 21 — Alloy EN AW-5010 [AlMg 0,5Mn] 39 Table 22 — Alloy EN AW-5026 [AI Mg4,5 MnSiFe] 40 Table 23 — Alloy EN AW-5040 [Al Mg1,5Mn] 40 Table 24 — Alloy EN AW-5042 [AlMg 3,5 Mn] 42 Table 25 — Alloy EN AW-5049 [Al Mg2Mn0,8] 43 Table 26 — Alloy EN AW-5050 [Al Mg1,5(C)] 44 Table 27 — Alloy EN AW-5052 [Al Mg2,5] 46 Table 28 — Alloy EN AW-5059 [Al Mg5,5MnZnZr] 48 Table 29 — Alloy EN AW-5070 [Al Mg4MnZn] 49 Table 30 — Alloy EN AW-5083 [Al Mg4,5Mn0,7] 50 Table 31 — Alloy EN AW-5086 [Al Mg4] 51 Table 32 — Alloy EN AW-5088 [AlMg5Mn0,4] 55 Table 33 — Alloy EN AW-5154A [Al Mg3,5(A)] 56 Table 34 — Alloy EN AW-5182 [Al Mg4,5Mn0,4] 58 Table 35 — Alloy EN AW-5251 [Al Mg2Mn0,3] 59 Table 36 — Alloy EN AW-5383 [Al Mg4,5Mn0,9] 62 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 6 Table 37 — Alloy EN AW-5449 [Al Mg2Mn0,8(B)] 64 Table 38 — Alloy EN AW-5449A [Al Mg2Mn0,8(C)] 64 Table 39 — Alloy EN AW-5454 [Al Mg3Mn] 64 Table 40 — Alloy EN AW-5456 [Al Mg5Mn1] 66 Table 41 — Alloy EN AW-5657 [Al 99,85Mg 1] 68 Table 42 — Alloy EN AW-5754 [Al Mg3] 69 Table 43 — Alloy EN AW-6016 [Al Si1,2Mg0,4] 70 Table 44 — Alloy EN AW-6025 [Al Mg2,5SiMnCu] 71 Table 45 – Alloy EN AW-6056 [Al Si1MgCuMn] 72 Table 46 — Alloy EN AW-6061 [Al Mg1SiCu] 73 Table 47 — Alloy EN AW-6082 [Al Si1MgMn] 74 Table 48 — Alloy EN AW-7010 [Al Zn6MgCu] 77 Table 49 — Alloy EN AW-7019 [Al Zn4Mg2] 80 Table 50 — Alloy EN AW-7020 [Al Zn4,5Mg1] 81 Table 51 — Alloy EN AW-7021 [Al Zn5,5Mg1,5] 82 Table 52 — Alloy EN AW-7022 [Al Zn5Mg3Cu] 83 Table 53 — Alloy EN AW-7075 [Al Zn5,5MgCu] 83 Table 54 — Alloy EN AW-8011A [Al FeSi(A)] 87 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 7 Table 1 — Aluminium EN AW-1050A [Al 99,5] Temper Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa Hardnessa
Rm Rp0,2
mm MPa MPa %
HBW
over up to min. max. min. max. A50 mm A 180° 90°
Fa
·
tá w 150,0 60
O 0,2 0,5 65 95 20
20
0 t 0 t 20
0,5 1,5 65 95 20
22
0 t 0 t 20
1,5 3,0 65 95 20
26
0 t 0 t 20
3,0 6,0 65 95 20
29
0,5 t 0,5 t 20
6,0 12,5 65 95 20
35
1,0 t 1,0 t 20
12,5 80,0 65 95 20
32
20 H111 0,2 0,5 65 95 20
20
0 t 0 t 20
0,5 1,5 65 95 20
22
0 t 0 t 20
1,5 3,0 65 95 20
26
0 t 0 t 20
3,0 6,0 65 95 20
29
0,5 t 0,5 t 20
6,0 12,5 65 95 20
35
1,0 t 1,0 t 20
12,5 80,0 65 95 20
32
20 H112
·
xá r 12,5 75
30
20
23
12,5 80,0 70
25
20
22 H12 0,2 0,5 85 125 65
2
0,5 t 0 t 28
0,5 1,5 85 125 65
4
0,5 t 0 t 28
1,5 3,0 85 125 65
5
0,5 t 0,5 t 28
3,0 6,0 85 125 65
7
1,0 t 1,0 t 28
6,0 12,5 85 125 65
9
2,0 t 28
12,5 40,0 85 125 65
9
28 H14 0,2 0,5 105 145 85
2
1,0 t 0 t 34
0,5 1,5 105 145 85
2
1,0 t 0,5 t 34
1,5 3,0 105 145 85
4
1,0 t 1,0 t 34
3,0 6,0 105 145 85
5
1,5 t 34
6,0 12,5 105 145 85
6
2,5 t 34
12,5 25,0 105 145 85
6
34 H16 0,2 0,5 120 160 100
1
0,5 t 39
0,5 1,5 120 160 100
2
1,0 t 39
1,5 4,0 120 160 100
3
1,5 t 39 H18 0,2 0,5 135
120
1
1,0 t 42 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 8 Temper Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa Hardnessa
Rm Rp0,2
mm MPa MPa %
HBW
over up to min. max. min. max. A50 mm A 180° 90°
0,5 1,5 140
120
2
2,0 t 42
1,5 3,0 140
120
2
3,0 t 42 H19 0,2 0,5 155
140
1
45
0,5 1,5 150
130
1
45
1,5 3,0 150
130
1
45 H22 0,2 0,5 85 125 55
4
0,5 t 0 t 27
0,5 1,5 85 125 55
5
0,5 t 0 t 27
1,5 3,0 85 125 55
6
0,5 t 0,5 t 27
3,0 6,0 85 125 55
11
1,0 t 1,0 t 27
6,0 12,5 85 125 55
12
2,0 t 27 H24 0,2 0,5 105 145 75
3
1,0 t 0 t 33
0,5 1,5 105 145 75
4
1,0 t 0,5 t 33
1,5 3,0 105 145 75
5
1,0 t 1,0 t 33
3,0 6,0 105 145 75
8
1,5 t 1,5 t 33
6,0 12,5 105 145 75
8
2,5 t 33 H26 0,2 0,5 120 160 90
2
0,5 t 38
0,5 1,5 120 160 90
3
1,0 t 38
1,5 4,0 120 160 90
4
1,5 t 38 H28 0,2 0,5 140
110
2
1,0 t 41
0,5 1,5 140
110
2
2,0 t 41
1,5 3,0 140
110
3
3,0 t 41 a For information only. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 9 Table 2 — Aluminium EN AW-1070A [Al 99,7] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
Fa
·
tá w 25,0 60
O 0,2 0,5 60 90 15
23
0 t 0 t 18
0,5 1,5 60 90 15
25
0 t 0 t 18
1,5 3,0 60 90 15
29
0 t 0 t 18
3,0 6,0 60 90 15
32
0,5 t 0,5 t 18
6,0 12,5 60 90 15
35
0,5 t 0,5 t 18
12,5 25,0 60 90 15
32
18 H111 0,2 0,5 60 90 15
23
0 t 0 t 18
0,5 1,5 60 90 15
25
0 t 0 t 18
1,5 3,0 60 90 15
29
0 t 0 t 18
3,0 6,0 60 90 15
32
0,5 t 0,5 t 18
6,0 12,5 60 90 15
35
0,5 t 0,5 t 18
12,5 25,0 60 90 15
32
18 H112
·
xá r 12,5 70
20
20
12,5 25,0 70
20
H12 0,2 0,5 80 120 55
5
0,5 t 0 t 26
0,5 1,5 80 120 55
6
0,5 t 0 t 26
1,5 3,0 80 120 55
7
0,5 t 0,5 t 26
3,0 6,0 80 120 55
9
1,0 t 26
6,0 12,5 80 120 55
12
2,0 t 26 H14 0,2 0,5 100 140 70
4
0,5 t 0 t 32
0,5 1,5 100 140 70
4
0,5 t 0,5 t 32
1,5 3,0 100 140 70
5
1,0 t 1,0 t 32
3,0 6,0 100 140 70
6
1,5 t 32
6,0 12,5 100 140 70
7
2,5 t 32 H16 0,2 0,5 110 150 90
2
1,0 t 0,5 t 36
0,5 1,5 110 150 90
2
1,0 t 1,0 t 36
1,5 4,0 110 150 90
3
1,0 t 1,0 t 36 H18 0,2 0,5 125
105
2
1,0 t 40
0,5 1,5 125
105
2
2,0 t 40
1,5 3,0 125
105
2
2,5 t 40 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 10 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
H22 0,2 0,5 80 120 50
7
0,5 t 0 t 26
0,5 1,5 80 120 50
8
0,5 t 0 t 26
1,5 3,0 80 120 50
10
0,5 t 0,5 t 26
3,0 6,0 80 120 50
12
1,0 t 26
6,0 12,5 80 120 50
15
2,0 t 26 H24 0,2 0,5 100 140 60
5
0,5 t 0 t 31
0,5 1,5 100 140 60
6
0,5 t 0,5 t 31
1,5 3,0 100 140 60
7
1,0 t 1,0 t 31
3,0 6,0 100 140 60
9
1,5 t 31
6,0 12,5 100 140 60
11
2,5 t 31 H26 0,2 0,5 110 150 80
3
0,5 t 35
0,5 1,5 110 150 80
3
1,0 t 35
1,5 4,0 110 150 80
4
1,0 t 35 a For information only. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 11 Table 3 — Aluminium EN AW-1080A [Al 99,8(A)] Temper Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
Fa
·
tá w 25,0 60
O 0,2 0,5 60 90 15
26
0 t 0 t 18
0,5 1,5 60 90 15
28
0 t 0 t 18
1,5 3,0 60 90 15
31
0 t 0 t 18
3,0 6,0 60 90 15
35
0,5 t 0,5 t 18
6,0 12,5 60 90 15
35
0,5 t 0,5 t 18 H111 0,2 0,5 60 90 15
26
0 t 0 t 18
0,5 1,5 60 90 15
28
0 t 0 t 18
1,5 3,0 60 90 15
31
0 t 0 t 18
3,0 6,0 60 90 15
35
0,5 t 0,5 t 18
6,0 12,5 60 90 15
35
0,5 t 0,5 t 18 H112
·
xá r 12,5 70
20
12,5 25,0 70
20
H12 0,2 0,5 80 120 55
5
0,5 t 0 t 26
0,5 1,5 80 120 55
6
0,5 t 0 t 26
1,5 3,0 80 120 55
7
0,5 t 0,5 t 26
3,0 6,0 80 120 55
9
1,0 t 26
6,0 12,5 80 120 55
12
2,0 t 26 H14 0,2 0,5 100 140 70
4
0,5 t 0 t 32
0,5 1,5 100 140 70
4
0,5 t 0,5 t 32
1,5 3,0 100 140 70
5
1,0 t 1,0 t 32
3,0 6,0 100 140 70
6
1,5 t 32
6,0 12,5 100 140 70
7
2,5 t 32 H16 0,2 0,5 110 150 90
2
1,0 t 0,5 t 36
0,5 1,5 110 150 90
2
1,0 t 1,0 t 36
1,5 4,0 110 150 90
3
1,0 t 1,0 t 36 H18 0,2 0,5 125
105
2
1,0 t 40
0,5 1,5 125
105
2
2,0 t 40
1,5 3,0 125
105
2
2,5 t 40 H22 0,2 0,5 80 120 50
8
0,5 t 0 t 26
0,5 1,5 80 120 50
9
0,5 t 0 t 26 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 12 Temper Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
1,5 3,0 80 120 50
11
0,5 t 0,5 t 26
3,0 6,0 80 120 50
13
1,0 t 26
6,0 12,5 80 120 50
15
2,0 t 26 H24 0,2 0,5 100 140 60
5
0,5 t 0 t 31
0,5 1,5 100 140 60
6
0,5 t 0,5 t 31
1,5 3,0 100 140 60
7
1,0 t 1,0 t 31
3,0 6,0 100 140 60
9
1,5 t 31
6,0 12,5 100 140 60
11
2,5 t 31 H26 0,2 0,5 110 150 80
3
0,5 t 35
0,5 1,5 110 150 80
3
1,0 t 35
1,5 4,0 110 150 80
4
1,0 t 35 a For information only. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 13 Table 4 — Aluminium EN AW-1200 [Al 99,0] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
Fa
·
tá w 150,0 75
O 0,2 0,5 75 105 25
19
0 t 0 t 23
0,5 1,5 75 105 25
21
0 t 0 t 23
1,5 3,0 75 105 25
24
0 t 0 t 23
3,0 6,0 75 105 25
28
0,5 t 0,5 t 23
6,0 12,5 75 105 25
33
1,0 t 1,0 t 23
12,5 80,0 75 105 25
30
23 H111 0,2 0,5 75 105 25
19
0 t 0 t 23
0,5 1,5 75 105 25
21
0 t 0 t 23
1,5 3,0 75 105 25
24
0 t 0 t 23
3,0 6,0 75 105 25
28
0,5 t 0,5 t 23
6,0 12,5 75 105 25
33
1,0 t 1,0 t 23
12,5 80,0 75 105 25
30
23 H112
·
xá r 12,5 85
35
16
26
12,5 80,0 80
30
16
24 H12 0,2 0,5 95 135 75
2
0,5 t 0 t 31
0,5 1,5 95 135 75
4
0,5 t 0 t 31
1,5 3,0 95 135 75
5
0,5 t 0,5 t 31
3,0 6,0 95 135 75
6
1,0 t 1,0 t 31
6,0 12,5 95 135 75
8
2,0 t 31
12,5 40,0 95 135 75
8
31 H14 0,2 0,5 105 155 95
1
1,0 t 0 t 37
0,5 1,5 115 155 95
3
1,0 t 0,5 t 37
1,5 3,0 115 155 95
4
1,0 t 1,0 t 37
3,0 6,0 115 155 95
5
1,5 t 1,5 t 37
6,0 12,5 115 155 90
6
2,5 t 37
12,5 25,0 115 155 90
6
37 H16 0,2 0,5 120 170 110
1
0,5 t 42
0,5 1,5 130 170 115
2
1,0 t 42
1,5 4,0 130 170 115
3
1,5 t 42 H18 0,2 0,5 150
130
1
1,0 t 45 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 14 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
0,5 1,5 150
130
2
2,0 t 45
1,5 3,0 150
130
2
3,0 t 45 H19 0,2 0,5 160
140
1
48
0,5 1,5 160
140
1
48
1,5 3,0 160
140
1
48 H22 0,2 0,5 95 135 65
4
0,5 t 0 t 30
0,5 1,5 95 135 65
5
0,5 t 0 t 30
1,5 3,0 95 135 65
6
0,5 t 0,5 t 30
3,0 6,0 95 135 65
10
1,0 t 1,0 t 30
6,0 12,5 95 135 65
10
2,0 t 30 H24 0,2 0,5 115 155 90
3
1,0 t 0 t 37
0,5 1,5 115 155 90
4
1,0 t 0,5 t 37
1,5 3,0 115 155 90
5
1,0 t 1,0 t 37
3,0 6,0 115 155 90
7
1,5 t 37
6,0 12,5 115 155 85
9
2,5 t 36 H26 0,2 0,5 130 170 105
2
0,5 t 41
0,5 1,5 130 170 105
3
1,0 t 41
1,5 4,0 130 170 105
4
1,5 t 41 a For information only. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 15 Table 5 — Aluminium EN AW-1350 [Al 99,5] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
Fa 2,5 150,0 60
O 0,2 0,5 65 95 20
20
0 t 0 t 20
0,5 1,5 65 95 20
22
0 t 0 t 20
1,5 3,0 65 95 20
26
0 t 0 t 20
3,0 6,0 65 95 20
29
0,5 t 0,5 t 20
6,0 12,5 65 95 20
35
1,0 t 1,0 t 20
12,5 80,0 65 95 20
32
20 H111 0,2 0,5 65 95 20
20
0 t 0 t 20
0,5 1,5 65 95 20
22
0 t 0 t 20
1,5 3,0 65 95 20
26
0 t 0 t 20
3,0 6,0 65 95 20
29
0,5 t 0,5 t 20
6,0 12,5 65 95 20
35
1,0 t 1,0 t 20
12,5 80,0 65 95 20
32
20 H112 0,2 0,5 75
30
20
23
0,5 1,5 75
30
20
23
1,5 3,0 75
30
20
23
3,0 6,0 75
30
20
23
6,0 12,5 75
30
20
23
12,5 80,0 75
30
20
23 H12 0,2 0,5 85 125 65
2
0,5 t 0 t 28
0,5 1,5 85 125 65
4
0,5 t 0 t 28
1,5 3,0 85 125 65
5
0,5 t 0,5 t 28
3,0 6,0 85 125 65
7
1,0 t 1,0 t 28
6,0 12,5 85 125 65
9
2,0 t 28
12,5 40,0 85 125 65
9
28 H14 0,2 0,5 105 145 85
2
1,0 t 0 t 34
0,5 1,5 105 145 85
2
1,0 t 0,5 t 34
1,5 3,0 105 145 85
4
1,0 t 1,0 t 34
3,0 6,0 105 145 85
5
1,5 t 34
6,0 12,5 105 145 85
6
2,5 t 34
12,5 25,0 105 145 85
6
34 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 16 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
H16 0,2 0,5 120 160 100
1
0,5 t 39
0,5 1,5 120 160 100
2
1,0 t 39
1,5 4,0 120 160 100
3
1,5 t 39 H18 0,2 0,5 140
120
1
1,0 t 42
0,5 1,5 140
120
2
2,0 t 42
1,5 3,0 140
120
2
3,0 t 42 H19 0,2 0,5 150
130
1
45
0,5 1,5 150
130
1
45
1,5 3,0 150
130
1
45 H22 0,2 0,5 85 125 55
4
0,5 t 0 t 27
0,5 1,5 85 125 55
5
0,5 t 0 t 27
1,5 3,0 85 125 55
6
0,5 t 0,5 t 27
3,0 6,0 85 125 55
11
1,0 t 1,0 t 27
6,0 12,5 85 125 55
12
2,0 t 27 H24 0,2 0,5 105 145 75
3
1,0 t 0 t 33
0,5 1,5 105 145 75
4
1,0 t 0,5 t 33
1,5 3,0 105 145 75
5
1,0 t 1,0 t 33
3,0 6,0 105 145 75
8
1,5 t 1,5 t 33
6,0 12,5 105 145 75
8
2,5 t 33 H26 0,2 0,5 120 160 90
2
0,5 t 38
0,5 1,5 120 160 90
3
1,0 t 38
1,5 4,0 120 160 90
4
1,5 t 38 H28 0,2 0,5 140
110
2
1,0 t 41
0,5 1,5 140
110
2
2,0 t 41
1,5 3,0 140
110
3
3,0 t 41 a For information only. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 17 Table 6 — Alloy EN AW-2014 [Al Cu4SiMg] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
O
·
rá v 1,5
220
140 12
0,5 t 0 t 55
1,5 3,0
220
140 13
1,0 t 1,0 t 55
3,0 6,0
220
140 16
1,5 t 55
6,0 9,0
220
140 16
2,5 t 55
9,0 12,5
220
140 16
4,0 t 55
12,5 25,0
220
10
55 T3
·
rá v 1,5 395
245
14
111
1,5 6,0 400
245
14
112 T4
·
rá v 1,5 395
240
14
3,0 t b 3,0 t b 110
1,5 6,0 395
240
14
5,0 t b 5,0 t b 110
6,0 12,5 400
250
14
8,0 t b 112
12,5 40,0 400
250
10
112
40,0 100,0 395
250
7
111 T451
·
rá v 1,5 395
240
14
3,0 t b 3,0 t b 110
1,5 6,0 395
240
14
5,0 t b 5,0 t b 110
6,0 12,5 400
250
14
8,0 t b 112
12,5 40,0 400
250
10
112
40,0 100,0 395
250
7
111 T42
·
rá v 6,0 395
230
14
110
6,0 12,5 400
235
14
111
12,5 25,0 400
235
12
111 T6
·
rá v 1,5 440
390
6
5,0 t b 133
1,5 6,0 440
390
7
7,0 t b 133
6,0 12,5 450
395
7
10 t b 135
12,5 40,0 460
400
6
138
40,0 60,0 450
390
5
135
60,0 80,0 435
380
4
131
80,0 100,0 420
360
4
126
100,0 125,0 410
350
4
123
125,0 160,0 390
340
2
kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 18 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
T651
·
rá v 1,5 440
390
6
5,0 t b 133
1,5 6,0 440
390
7
7,0 t b 133
6,0 12,5 450
395
7
10 t b 135
12,5 40,0 460
400
6
138
40,0 60,0 450
390
5
135
60,0 80,0 435
380
4
131
80,0 100,0 420
360
4
126
100,0 125,0 410
350
4
123
125,0 160,0 390
340
2
T62
·
rá v 12,5 440
390
7
133
12,5 25,0 450
395
6
135 Whenever a new application of this alloy is contemplated, and if this application involves special properties such as corrosion resistance, toughness, fatigue strength, it is strongly recommended that the user consult the producer in order to make a precise and appropriate selection of the material. a For information only. b Appreciably smaller cold bend radii can be achieved immediately after quenching. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 19 Table 7 — Alloy EN AW-2014A [Al Cu4SiMg(A)] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
O
·
rá t 0,5
235
110
1,0 t 55
0,5 1,5
235
110 14
2,0 t 55
1,5 3,0
235
110 16
2,0 t 55
3,0 6,0
235
110 16
2,0 t 55 T4
·
rá t 0,5 400
225
3,0 t b 110
0,5 1,5 400
225
13
3,0 t b 110
1,5 6,0 400
225
14
5,0 t b 110
6,0 12,5 400
250
14
12,5 25,0 400
250
12
25,0 40,0 400
250
10
40,0 80,0 395
250
7
T451
·
rá t 0,5 400
225
3,0 t b 110
0,5 1,5 400
225
13
3,0 t b 110
1,5 6,0 400
225
14
5,0 t b 110
6,0 12,5 400
250
14
12,5 25,0 400
250
12
25,0 40,0 400
250
10
40,0 80,0 395
250
7
T6
·
rá t 0,5 440
380
5,0 t b 150
0,5 1,5 440
380
6
5,0 t b 150
1,5 3,0 440
380
7
6,0 t b 150
3,0 6,0 440
380
8
6,0 t b 150
6,0 12,5 460
410
8
12,5 25,0 460
410
6
25,0 40,0 450
400
5
40,0 60,0 430
390
5
60,0 90,0 430
390
4
90,0 115,0 420
370
4
115,0 140,0 410
350
4
T651
·
rá t 0,5 440
380
5,0 t b 150 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 20 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
0,5 1,5 440
380
6
5,0 t b 150
1,5 3,0 440
380
7
6,0 t b 150
3,0 6,0 440
380
8
6,0 t b 150
6,0 12,5 460
410
8
12,5 25,0 460
410
6
25,0 40,0 450
400
5
40,0 60,0 430
390
5
60,0 90,0 430
390
4
90,0 115,0 420
370
4
115,0 140,0 410
350
4
Whenever a new application of this alloy is contemplated, and if this application involves special properties such as corrosion resistance, toughness, fatigue strength, it is strongly recommended that the user consult the producer in order to make a precise and appropriate selection of the material. a For information only. b Appreciably smaller cold bend radii can be achieved immediately after quenching. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 21 Table 8 — Alloy EN AW-2017A [Al Cu4MgSi(A)] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa Hardnessa
Rm Rp0,2
mm MPa MPa %
HBW over up to min. max. min. max. A50 mm A 180° 90°
O
·
rá v 1,5
225
145 12
0,5 t 0 t 55
1,5 3,0
225
145 14
1,0 t 1,0 t 55
3,0 6,0
225
145 13
1,5 t 55
6,0 9,0
225
145 13
2,5 t 55
9,0 12,5
225
145 13
4,0 t 55
12,5 25,0
225
145
12
55 T4
·
rá v 1,5 390
245
14
3,0 t b 3,0 t b 110
1,5 6,0 390
245
15
5,0 t b 5,0 t b 110
6,0 12,5 390
260
13
8,0 t b 111
12,5 40,0 390
250
12
110
40,0 60,0 385
245
12
108
60,0 80,0 370
240
7
80,0 120,0 360
240
6
105
120,0 150,0 350
240
4
101
150,0 180,0 330
220
2
180,0 200,0 300
200
2
T451
·
rá v 1,5 390
245
14
3,0 t b 3,0 t b 110
1,5 6,0 390
245
15
5,0 t b 5,0 t b 110
6,0 12,5 390
260
13
8,0 t b 111
12,5 40,0 390
250
12
110
40,0 60,0 385
245
12
108
60,0 80,0 370
240
7
80,0 120,0 360
240
6
105
120,0 150,0 350
240
4
101
150,0 180,0 330
220
2
180,0 200,0 300
200
2
T452 150,0 180,0 330
220
2
180,0 200,0 300
200
2
T42
·
rá v 3,0 390
235
14
109
3,0 12,5 390
235
15
109 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 22 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa Hardnessa
Rm Rp0,2
mm MPa MPa %
HBW over up to min. max. min. max. A50 mm A 180° 90°
12,5 25,0 390
235
12
109 Whenever a new application of this alloy is contemplated, and if this application involves special properties such as corrosion resistance, toughness, fatigue strength, it is strongly recommended that the user consult the producer in order to make a precise and appropriate selection of the material. a For information only. b Appreciably smaller cold bend radii can be achieved immediately after quenching. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 23 Table 9 — Alloy EN AW-2024 [Al Cu4Mg1] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
O
·
rá v 1,5
220
140 12
0,5 t 0 t 55
1,5 3,0
220
140 13
2,0 t 1,0 t 55
3,0 6,0
220
140 13
3,0 t 1,5 t 55
6,0 9,0
220
140 13
2,5 t 55
9,0 12,5
220
140 13
4,0 t 55
12,5 25,0
220
11
55 T4
·
rá v 1,5 425
275
12
4,0 t
120
1,5 6,0 425
275
14
5,0 t
120 T3
·
rá v 1,5 435
290
12
4,0 t b 4,0 t b 123
1,5 3,0 435
290
14
4,0 t b 4,0 t b 123
3,0 6,0 440
290
14
5,0 t b 5,0 t b 124
6,0 12,5 440
290
13
8,0 t b 124
12,5 40,0 430
290
11
122
40,0 80,0 420
290
8
120
80,0 100,0 400
285
7
115
100,0 120,0 380
270
5
110
120,0 150,0 360
250
5
104 T351
·
rá v 1,5 435
290
12
4,0 t b 4,0 t b 123
1,5 3,0 435
290
14
4,0 t b 4,0 t b 123
3,0 6,0 440
290
14
5,0 t b 5,0 t b 124
6,0 12,5 440
290
13
8,0 t b 124
12,5 40,0 430
290
11
122
40,0 80,0 420
290
8
120
80,0 100,0 400
285
7
115
100,0 120,0 380
270
5
110
120,0 150,0 360
250
5
104 T42
·
rá v 6,0 425
260
15
119
6,0 12,5 425
260
12
119
12,5 25,0 420
260
8
118 T8
·
rá v 1,5 460
400
5
138
1,5 6,0 460
400
6
138 kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 24 Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
6,0 12,5 460
400
5
138
12,5 25,0 455
400
4
137
25,0 40,0 455
395
4
136 T851
·
rá v 1,5 460
400
5
138
1,5 6,0 460
400
6
138
6,0 12,5 460
400
5
138
12,5 25,0 455
400
4
137
25,0 40,0 455
395
4
136 T62
·
rá v 12,5 440
345
5
129
12,5 25,0 435
345
4
128 Whenever a new application of this alloy is contemplated, and if this application involves special properties such as corrosion resistance, toughness, fatigue strength, it is strongly recommended that the user consult the producer in order to make a precise and appropriate selection of the material. a For information only. b Appreciably smaller cold bend radii can be achieved immediately after quenching. Table 10 — Alloy EN AW-2618A [Al Cu2Mg1,5Ni] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa % HBW over up to min. max. min. max. A50 mm A 180° 90°
T851 > 6,0 12,5 420
375
5
12,5 40,0 420
375
5
40,0 80,0 410
370
5
80,0 100,0 405
365
4
100,0 140,0 395
360
4
a No data available. kSIST FprEN 485-2:2016
FprEN 485-2:2015 (E) 25 Table 11 — Alloy EN AW-3003 [Al Mn1Cu] Temper
Specified thickness Tensile strength Yield strength Elongation min. Bend radiusa
Hardnessa
Rm Rp0,2
mm MPa MPa %
HBW over up
...
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