oSIST prEN 485-2:2026
(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 document 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 specified in EN 515.
Aluminium und Aluminiumlegierungen - Bänder, Bleche und Platten - Teil 2: Mechanische Eigenschaften
Dieses Dokument legt die mechanischen Eigenschaften von Blechen, Bändern und Platten aus Aluminium und Aluminiumknetlegierungen für allgemeine technische Anwendungen fest.
Es gilt nicht für halbfertige Walzprodukte in Rollenform, die weiter gewalzt werden sollen (Vorwalzband), oder für Spezialprodukte wie gewellte, geprägte, lackierte Bleche und Bänder oder für spezielle Anwendungen wie Luft- und Raumfahrt, Dosenmaterial, Vormaterial für Wärmeaustauscher (Finstock), für die die mechanischen Eigenschaften in anderen europäischen Normen festgelegt sind.
Die Grenzen der chemischen Zusammensetzung der Legierung sind in EN 573 3 angegeben. Die Bezeichnungen der Werkstoffzustände sind in EN 515 angegeben.
Aluminium et alliages d’aluminium - Tôles, bandes et tôles épaisses - Partie 2 : Caractéristiques mécaniques
Le présent document spécifie les caractéristiques mécaniques des tôles, bandes et tôles épaisses en aluminium corroyé et alliages d’aluminium corroyés à usage général.
Il 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 données dans l’EN 573 3. Les désignations des états métallurgiques sont spécifiées dans l’EN 515.
Aluminij in aluminijeve zlitine - Pločevina, trakovi in plošče - 2. del: Mehanske lastnosti
General Information
- Status
- Not Published
- Public Enquiry End Date
- 04-Mar-2026
- Technical Committee
- INEK - Nonferrous metals
- Current Stage
- 4020 - Public enquire (PE) (Adopted Project)
- Start Date
- 16-Jan-2026
- Due Date
- 05-Jun-2026
Relations
- Effective Date
- 08-Oct-2025
Overview
oSIST prEN 485-2:2026 is a European draft standard developed by CEN (European Committee for Standardization) that specifies the mechanical properties of wrought aluminium and aluminium alloy sheet, strip, and plate intended for general engineering purposes. This standard ensures the quality and consistency of aluminium flat-rolled products and plays a critical role in materials selection for manufacturers and engineers across various industries.
This part of the EN 485 series sets mechanical property limits - including tensile strength, yield strength, elongation, and guidelines for bend radius and hardness - for a wide range of standard aluminium alloys and tempers. It is a key reference for specifying products used in engineering projects where reliable mechanical performance is essential.
Key Topics
Scope and Applicability
- Covers mechanical properties for aluminium and aluminium alloy sheets, strips, and plates for general engineering.
- Specifically excludes products that are reroll stock, special finished products (e.g., corrugated, embossed, painted), and special use cases like aerospace, can stock, or finstock.
- Alloy chemical composition limits are defined in EN 573-3; temper designations reference EN 515.
Mechanical Properties Coverage
- Tensile strength
- Yield strength
- Minimum elongation after tensile testing
- Bend radius and hardness (provided for informational purposes)
- Special corrosion resistance criteria for certain alloys
Product Categories
- Applies to wrought aluminium and aluminium alloy sheet, strip, and plate in flat pieces, not to those in coil form for further processing.
Referenced Test Methods
- Tensile testing performed per EN ISO 6892-1
- Sampling and test piece preparation per EN 485-1
Applications
The specifications set out in oSIST prEN 485-2:2026 are critical for a wide range of industries and applications that rely on aluminium flat products. Typical uses include:
- General Engineering: Structural parts, machine components, and fabrication work that require consistent mechanical properties and predictable performance.
- Transport Vehicles: Body panels, chassis parts, and frames for automotive, rail, and commercial vehicles.
- Construction and Architecture: Building facades, roofing, cladding, and structural elements that require lightweight and corrosion-resistant materials.
- Industrial Equipment: Mechanical parts, casings, and supports where specific strength and formability are needed.
- Electrical and Consumer Goods: Enclosures, panels, and fixtures in electrical appliances and consumer products.
Ensuring compliance with the mechanical property limits defined in oSIST prEN 485-2:2026 helps manufacturers, fabricators, and end-users to:
- Achieve reliable product performance and safety
- Meet procurement and project specifications
- Facilitate regulatory and quality assurance processes
Related Standards
To ensure harmonized and comprehensive use, oSIST prEN 485-2:2026 should be considered alongside related standards such as:
- EN 485-1: Technical conditions for inspection and delivery of aluminium and aluminium alloy sheet, strip, and plate.
- EN 485-3: Tolerances on dimensions and form for hot-rolled products.
- EN 485-4: Tolerances on shape and dimensions for cold-rolled products.
- EN 573-3: Specification of chemical composition limits for aluminium alloys.
- EN 515: Temper designations for aluminium and aluminium alloys.
- EN ISO 6892-1: Methods for tensile testing at room temperature.
- Other sector-specific standards for marine, aerospace, or food packaging applications.
Practical Value
By adopting oSIST prEN 485-2:2026, companies and professionals in metals manufacturing, fabrication, engineering design, and quality assurance can:
- Standardize procurement and production processes
- Ensure compatibility and interchangeability of flat aluminium products
- Enhance product traceability and documentation
- Avoid material failures and ensure compliance with international quality benchmarks
oSIST prEN 485-2:2026 is a foundational document for anyone working with aluminium flat products across Europe and internationally, supporting quality, safety, and innovation in aluminium engineering and design.
Frequently Asked Questions
oSIST prEN 485-2:2026 is a draft published by the Slovenian Institute for Standardization (SIST). Its full title is "Aluminium and aluminium alloys - Sheet, strip and plate - Part 2: Mechanical properties". This standard covers: This document 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 specified in EN 515.
This document 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 specified in EN 515.
oSIST prEN 485-2:2026 is classified under the following ICS (International Classification for Standards) categories: 77.150.10 - Aluminium products. The ICS classification helps identify the subject area and facilitates finding related standards.
oSIST prEN 485-2:2026 has the following relationships with other standards: It is inter standard links to SIST EN 485-2:2016+A1:2018. Understanding these relationships helps ensure you are using the most current and applicable version of the standard.
oSIST prEN 485-2:2026 is available in PDF format for immediate download after purchase. The document can be added to your cart and obtained through the secure checkout process. Digital delivery ensures instant access to the complete standard document.
Standards Content (Sample)
SLOVENSKI STANDARD
01-marec-2026
Aluminij in aluminijeve zlitine - Pločevina, trakovi in plošče - 2. del: Mehanske
lastnosti
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: prEN 485-2
ICS:
77.150.10 Aluminijski izdelki Aluminium products
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
DRAFT
EUROPEAN STANDARD
NORME EUROPÉENNE
EUROPÄISCHE NORM
December 2025
ICS 77.150.10 Will supersede EN 485-2:2016+A1:2018
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 draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee
CEN/TC 132.
If this draft becomes a European Standard, 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.
This draft European Standard was established by CEN 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, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Türkiye and
United Kingdom.
Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are
aware and to provide supporting documentation.
Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without
notice and shall not be referred to as a European Standard.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION
EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2025 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 485-2:2025 E
worldwide for CEN national Members.
Contents Page
European foreword . 3
1 Scope . 4
2 Normative references . 4
3 Terms and definitions . 4
4 Requirements . 4
5 List of alloys with mechanical property limits . 4
5.1 General . 4
5.2 Elongation . 5
5.3 List of alloys and their mechanical properties . 5
Annex A (normative) Rules for rounding . 81
Annex B (informative) Comments regarding alloy EN AW-4115A . 82
Bibliography . 83
European foreword
This document 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 CEN Enquiry.
This document will supersede EN 485-2:2016+A1:2018.
EN 485-2:2016+A1:2018:
— introduction of Clause 3 as required by last CEN template
— renumbering of tables according to alloy sequence of EN 573-3
— merging of mechanical property values for tempers with identical figures
— introduction of mechanical property requirements for alloy EN AW-3005A
— introduction of mechanical property requirements for alloy EN AW-3105B
— introduction of mechanical property requirements for alloy EN AW-4115A
— modification about minimum thicknesses in for mechanical property requirements of alloy EN AW-
— introduction of mechanical property requirements for alloy EN AW-5050A
— introduction of mechanical property requirements for alloy EN AW-6005A
— introduction of mechanical property requirements for alloy EN AW-8006
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
1 Scope
This document 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
specified 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 485-1, Aluminium and aluminium alloys — Sheet, strip and plate — Part 1: Technical conditions for
inspection and delivery
EN 13195, Aluminium and aluminium alloys — Specifications for wrought and cast products for marine
applications (shipbuilding, marine and offshore)
EN ISO 6892-1, Metallic materials — Tensile testing — Part 1: Method of test at room temperature
(ISO 6892-1)
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 Terms and definitions
No terms and definitions are listed in this document.
4 Requirements
The mechanical properties shall be according to Clause 4 or those agreed upon between supplier and
purchaser and stated on the order document.
Rounding for expression of test results to determine compliance with the mechanical properties specified
in this document shall be according to Annex A.
NOTE Regarding the chemical composition, application and form of products for alloy EN AW-4115A, see
Annex B.
5 List of alloys with mechanical property limits
5.1 General
Table 1 to Table 56 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.
5.2 Elongation
The A value is the elongation measured over a gauge length of 50 mm and expressed in percent.
50 mm
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.
5.3 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)] 18
Table 8 — Alloy EN AW-2017A [Al Cu4MgSi(A)] 19
Table 9 — Alloy EN AW-2618A [Al Cu2Mg1,5Ni] 20
Table 10 — Alloy EN AW-2024 [Al Cu4Mg1] 21
Table 11 — Alloy EN AW-3003 [Al Mn1Cu] 22
Table 12 — Alloy EN AW-3103 [Al Mn1] 24
Table 13 — Alloy EN AW-3004 [Al Mn1Mg1] 26
Table 14 — Alloy EN AW-3005 [Al Mn1Mg0,5] — Alloy EN AW-3005A [Al Mn1Mg0,5(A)] 28
Table 15 — Alloy EN AW-3105 [Al Mn0,5Mg0,5] — Alloy EN AW-3105B [Al Mn0,5Mg0,5(B)] 30
Table 16 — Alloy EN AW-4006 [Al Si1Fe] 32
Table 17 — Alloy EN AW-4007 [Al Si1,5Mn] 33
Table 18 — Alloy EN AW-4015 [Al Si2Mn] 33
Table 19 — Alloy EN AW-4115 [Al Si2MnMgCu] — Alloy EN AW-4115A [Al Si2MnMgCu(A)] 34
Table 20 — Alloy EN AW-5005 [Al Mg1] — Alloy EN AW-5005A [Al Mg1(A)] 35
Table 21 — Alloy EN AW-5010 [AlMg 0,5Mn] 37
Table 22 — Alloy EN AW-5026 [AI Mg4,5 MnSiFe] 38
Table 23 — Alloy EN AW-5040 [Al Mg1,5Mn] 39
Table 24 — Alloy EN AW-5042 [AlMg 3,5 Mn] 39
Table 25 — Alloy EN AW-5049 [Al Mg2Mn0,8] 40
Table 26 — Alloy EN AW-5449 [Al Mg2Mn0,8] — Alloy EN AW-5449A [Al Mg2Mn0,8(A)] 42
Table 27 — Alloy EN AW-5050 [Al Mg1,5] 42
Table 28 — Alloy EN AW-5050A [Al Mg1,5(A)] 43
Table 29 — Alloy EN AW-5251 [Al Mg2Mn0,3] 44
Table 30 — Alloy EN AW-5052 [Al Mg2,5] 46
Table 31 — Alloy EN AW-5154A [Al Mg3,5(A)] 48
Table 32 — Alloy EN AW-5454 [Al Mg3Mn] 50
Table 33 — Alloy EN AW-5754 [Al Mg3] 52
Table 34 — Alloy EN AW-5456 [Al Mg5Mn1] 53
Table 35 — Alloy EN AW-5657 [Al 99,85Mg 1] 54
Table 36 — Alloy EN AW-5059 [Al Mg5,5MnZnZr] 55
Table 37 — Alloy EN AW-5070 [Al Mg4MnZn] 56
Table 38 — Alloy EN AW-5182 [Al Mg4,5Mn0,4] 56
Table 39 — Alloy EN AW-5083 [Al Mg4,5Mn0,7] 57
Table 40 — Alloy EN AW-5383 [Al Mg4,5Mn0,9] 58
Table 41 — Alloy EN AW-5086 [Al Mg4] 61
Table 42 — Alloy EN AW-5088 [AlMg5Mn0,4] 63
Table 43 — Alloy EN AW-6005A [Al SiMg(A)] 64
Table 44 — Alloy EN AW-6016 [Al Si1,2Mg0,4] 65
Table 45 — Alloy EN AW-6025 [Al Mg2,5SiMnCu] 65
Table 46 — Alloy EN AW-6056 [Al Si1MgCuMn] 66
Table 47 — Alloy EN AW-6061 [Al Mg1SiCu] 67
Table 48 — Alloy EN AW-6082 [Al Si1MgMn] 68
Table 49 — Alloy EN AW-7010 [Al Zn6MgCu] 69
Table 50 — Alloy EN AW-7019 [Al Zn4Mg2] 72
Table 51 — Alloy EN AW-7020 [Al Zn4,5Mg1] 73
Table 52 — Alloy EN AW-7021 [Al Zn5,5Mg1,5] 74
Table 53 — Alloy EN AW-7022 [Al Zn5Mg3Cu] 74
Table 54 — Alloy EN AW-7075 [Al Zn5,5MgCu] 75
Table 55 — Alloy EN AW-8006 [Al Fe1,5Mn] 78
Table 56 — Alloy EN AW-8011A [Al FeSi(A)] 79
Table 1 — Aluminium EN AW-1050A [Al 99,5(A)]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 150,0 60
O 0,2 0,5 65 95 20 20 0 t 0 t 20
H111 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
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
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
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.
Table 2 — Aluminium EN AW-1070A [Al 99,7(A)]
a
Temper Specified Tensile Yield strength Elongation Bend Hardness
a
thickness strength radius
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
a
F ≥ 2,5 25,0 60
O 0,2 0,5 60 90 15 26 0 t 0 t 18
H111 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
12,5 25,0 60 90 15 32 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
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
a
Temper Specified Tensile Yield strength Elongation Bend Hardness
a
thickness strength radius
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A A 180° 90°
50 mm
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.
Table 3 — Aluminium EN AW-1080A [Al 99,8(A)]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 25,0 60
O 0,2 0,5 60 90 15 26 0 t 0 t 18
H111 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
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
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.
Table 4 — Aluminium EN AW-1200 [Al 99,0]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 150,0 75
O 0,2 0,5 75 105 25 19 0 t 0 t 23
H111 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
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
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.
Table 5 — Aluminium EN AW-1350 [Al 99,5]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F 2,5 150,0 60
O 0,2 0,5 65 95 20 20 0 t 0 t 20
H111 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
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
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
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.
Table 6 — Alloy EN AW-2014 [Al Cu4SiMg]
a a
Temper Specified Tensile Yield strength Elongation Bend radius Hardness
thickness strength
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
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
b b
T4 ≥ 0,4 1,5 395 240 14 3,0 t 3,0 t 110
b b
T451 1,5 6,0 395 240 14 5,0 t 5,0 t 110
b
6,0 12,5 400 250 14 8,0 t 112
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
b
T6 ≥ 0,4 1,5 440 390 6 5,0 t 133
b
T651 1,5 6,0 440 390 7 7,0 t 133
b
6,0 12,5 450 395 7 10 t 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, 125,0 410 350 4 123
125, 160,0 390 340 2
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.
Table 7 — Alloy EN AW-2014A [Al Cu4SiMg(A)]
a a
Temper Specified Tensile Yield strength Elongation Bend radius Hardness
thickness strength
min.
R R
m p0,2
mm MPa MPa % HBW
over up to min. max. min. max. A50 mm A 180° 90°
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
b
T4 ≥ 0,2 0,5 400 225 3,0 t 110
b
T451 0,5 1,5 400 225 13 3,0 t 110
b
1,5 6,0 400 225 14 5,0 t 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
b
T6 ≥ 0,2 0,5 440 380 5,0 t 150
b
T651 0,5 1,5 440 380 6 5,0 t 150
b
1,5 3,0 440 380 7 6,0 t 150
b
3,0 6,0 440 380 8 6,0 t 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, 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.
Table 8 — Alloy EN AW-2017A [Al Cu4MgSi(A)]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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 1,5 225 145 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
b b
T4 ≥ 0,4 1,5 390 245 14 3,0 t 3,0 t 110
b b
T451 1,5 6,0 390 245 15 5,0 t 5,0 t 110
b
6,0 12,5 390 260 13 8,0 t 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 ≥ 0,4 3,0 390 235 14 109
3,0 12,5 390 235 15 109
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.
Table 9 — Alloy EN AW-2618A [Al Cu2Mg1,5Ni]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
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.
Table 10 — Alloy EN AW-2024 [Al Cu4Mg1]
a a
Specified Tensile Yield Elongation Bend radius Hardness
Temper
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 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 ≥ 0,4 1,5 425 275 12 4,0 t 120
1,5 6,0 425 275 14 5,0 t 120
b b
T3 ≥ 0,4 1,5 435 290 12 4,0 t 4,0 t 123
b b
T351 1,5 3,0 435 290 14 4,0 t 4,0 t 123
b b
3,0 6,0 440 290 14 5,0 t 5,0 t 124
b
6,0 12,5 440 290 13 8,0 t 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 ≥ 0,4 6,0 425 260 15 119
6,0 12,5 425 260 12 119
12,5 25,0 420 260 8 118
T8 ≥ 0,4 1,5 460 400 5 138
T851 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 ≥ 0,4 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 11 — Alloy EN AW-3003 [Al Mn1Cu]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 80,0 95
O 0,2 0,5 95 135 35 15 0 t 0 t 28
H111 0,5 1,5 95 135 35 17 0 t 0 t 28
1,5 3,0 95 135 35 20 0 t 0 t 28
3,0 6,0 95 135 35 23 1,0 t 1,0 t 28
6,0 12,5 95 135 35 24 1,5 t 28
12,5 50,0 95 135 35 23 28
H112 ≥ 6,0 12,5 115 70 10 35
12,5 80,0 100 40 18 29
H12 0,2 0,5 120 160 90 3 1,5 t 0 t 38
0,5 1,5 120 160 90 4 1,5 t 0,5 t 38
1,5 3,0 120 160 90 5 1,5 t 1,0 t 38
3,0 6,0 120 160 90 6 1,0 t 38
6,0 12,5 120 160 90 7 2,0 t 38
12,5 40,0 120 160 90 8 38
H14 0,2 0,5 145 185 125 2 2,0 t 0,5 t 46
0,5 1,5 145 185 125 2 2,0 t 1,0 t 46
1,5 3,0 145 185 125 3 2,0 t 1,0 t 46
3,0 6,0 145 185 125 4 2,0 t 46
6,0 12,5 145 185 125 5 2,5 t 46
12,5 25,0 145 185 125 5 46
H16 0,2 0,5 170 210 150 1 2,5 t 1,0 t 54
0,5 1,5 170 210 150 2 2,5 t 1,5 t 54
1,5 4,0 170 210 150 2 2,5 t 2,0 t 54
H18 0,2 0,5 190 170 1 1,5 t 60
0,5 1,5 190 170 2 2,5 t 60
1,5 3,0 190 170 2 3,0 t 60
H19 0,2 0,5 210 180 1 65
0,5 1,5 210 180 2 65
1,5 3,0 210 180 2 65
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
H22 0,2 0,5 120 160 80 6 1,0 t 0 t 37
0,5 1,5 120 160 80 7 1,0 t 0,5 t 37
1,5 3,0 120 160 80 8 1,0 t 1,0 t 37
3,0 6,0 120 160 80 9 1,0 t 37
6,0 12,5 120 160 80 11 2,0 t 37
H24 0,2 0,5 145 185 115 4 1,5 t 0,5 t 45
0,5 1,5 145 185 115 4 1,5 t 1,0 t 45
1,5 3,0 145 185 115 5 1,5 t 1,0 t 45
3,0 6,0 145 185 115 6 2,0 t 45
6,0 12,5 145 185 110 8 2,5 t 45
H26 0,2 0,5 170 210 140 2 2,0 t 1,0 t 53
0,5 1,5 170 210 140 3 2,0 t 1,5 t 53
1,5 4,0 170 210 140 3 2,0 t 2,0 t 53
H28 0,2 0,5 190 160 2 1,5 t 59
0,5 1,5 190 160 2 2,5 t 59
1,5 3,0 190 160 3 3,0 t 59
a
For information only.
Table 12 — Alloy EN AW-3103 [Al Mn1]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 80,0 90
O 0,2 0,5 90 130 35 17 0 t 0 t 27
H111 0,5 1,5 90 130 35 19 0 t 0 t 27
1,5 3,0 90 130 35 21 0 t 0 t 27
3,0 6,0 90 130 35 24 1,0 t 1,0 t 27
6,0 12,5 90 130 35 28 1,5 t 27
12,5 50,0 90 130 35 25 27
H112 ≥ 6,0 12,5 110 70 10 34
12,5 80,0 95 40 18 28
H12 0,2 0,5 115 155 85 3 1,5 t 0 t 36
0,5 1,5 115 155 85 4 1,5 t 0,5 t 36
1,5 3,0 115 155 85 5 1,5 t 1,0 t 36
3,0 6,0 115 155 85 6 1,0 t 36
6,0 12,5 115 155 85 7 2,0 t 36
12,5 40,0 115 155 85 8 36
H14 0,2 0,5 140 180 120 2 2,0 t 0,5 t 45
0,5 1,5 140 180 120 2 2,0 t 1,0 t 45
1,5 3,0 140 180 120 3 2,0 t 1,0 t 45
3,0 6,0 140 180 120 4 2,0 t 45
6,0 12,5 140 180 120 5 2,5 t 45
12,5 25,0 140 180 120 5 45
H16 0,2 0,5 160 200 145 1 2,5 t 1,0 t 51
0,5 1,5 160 200 145 2 2,5 t 1,5 t 51
1,5 4,0 160 200 145 2 2,5 t 2,0 t 51
4,0 8,0 160 200 145 2 2,0 t 1,5 t 51
H18 0,2 0,5 185 165 1 1,5 t 58
0,5 1,5 185 165 2 2,5 t 58
1,5 3,0 185 165 2 3,0 t 58
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
H19 0,2 0,5 200 175 1 62
0,5 1,5 200 175 2 62
1,5 3,0 200 175 2 62
H22 0,2 0,5 115 155 75 6 1,0 t 0 t 36
0,5 1,5 115 155 75 7 1,0 t 0,5 t 36
1,5 3,0 115 155 75 8 1,0 t 1,0 t 36
3,0 6,0 115 155 75 9 1,0 t 36
6,0 12,5 115 155 75 11 2,0 t 36
H24 0,2 0,5 140 180 110 4 1,5 t 0,5 t 44
0,5 1,5 140 180 110 4 1,5 t 1,0 t 44
1,5 3,0 140 180 110 5 1,5 t 1,0 t 44
3,0 6,0 140 180 110 6 2,0 t 44
6,0 12,5 140 180 110 8 2,5 t 44
H26 0,2 0,5 160 200 135 2 2,0 t 1,0 t 50
0,5 1,5 160 200 135 3 2,0 t 1,5 t 50
1,5 4,0 160 200 135 3 2,0 t 2,0 t 50
H28 0,2 0,5 185 155 2 1,5 t 58
0,5 1,5 185 155 2 2,5 t 58
1,5 3,0 185 155 3 3,0 t 58
a
For information only.
Table 13 — Alloy EN AW-3004 [Al Mn1Mg1]
a a
Specified Tensile Yield Elongation Bend radius Hardness
Temper
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
a
F ≥ 2,5 80,0 155
O 0,2 0,5 155 200 60 13 0 t 0 t 45
H111 0,5 1,5 155 200 60 14 0 t 0 t 45
1,5 3,0 155 200 60 15 0,5 t 0 t 45
3,0 6,0 155 200 60 16 1,0 t 1,0 t 45
6,0 12,5 155 200 60 16 2,0 t 45
12,5 50,0 155 200 60 14 45
H12 0,2 0,5 190 240 155 2 1,5 t 0 t 59
0,5 1,5 190 240 155 3 1,5 t 0,5 t 59
1,5 3,0 190 240 155 4 2,0 t 1,0 t 59
3,0 6,0 190 240 155 5 1,5 t 59
H14 0,2 0,5 220 265 180 1 2,5 t 0,5 t 67
0,5 1,5 220 265 180 2 2,5 t 1,0 t 67
1,5 3,0 220 265 180 2 2,5 t 1,5 t 67
3,0 6,0 220 265 180 3 2,0 t 67
H16 0,2 0,5 240 285 200 1 3,5 t 1,0 t 73
0,5 1,5 240 285 200 1 3,5 t 1,5 t 73
1,5 4,0 240 285 200 2 2,5 t 73
H18 0,2 0,5 260 230 1 1,5 t 80
0,5 1,5 260 230 1 2,5 t 80
1,5 3,0 260 230 2 80
H19 0,2 0,5 270 240 1 83
0,5 1,5 270 240 1 83
a a
Specified Tensile Yield Elongation Bend radius Hardness
Temper
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
H22 0,2 0,5 190 240 145 4 1,0 t 0 t 58
H32 0,5 1,5 190 240 145 5 1,0 t 0,5 t 58
1,5 3,0 190 240 145 6 1,5 t 1,0 t 58
3,0 6,0 190 240 145 7 1,5 t 58
H24 0,2 0,5 220 265 170 3 2,0 t 0,5 t 66
H34 0,5 1,5 220 265 170 4 2,0 t 1,0 t 66
1,5 3,0 220 265 170 4 2,0 t 1,5 t 66
H26 0,2 0,5 240 285 190 3 3,0 t 1,0 t 72
H36 0,5 1,5 240 285 190 3 3,0 t 1,5 t 72
1,5 3,0 240 285 190 3 2,5 t 72
H28 0,2 0,5 260 220 2 1,5 t 79
H38 0,5 1,5 260 220 3 2,5 t 79
a
For information only.
Table 14 — Alloy EN AW-3005 [Al Mn1Mg0,5] — Alloy EN AW-3005A [Al Mn1Mg0,5(A)]
a a
Specified Tensile Yield Elongation Bend radius Hardness
Temper
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
a
F ≥ 2,5 80,0 115
O 0,2 0,5 115 165 45 12 0 t 0 t 33
H111 0,5 1,5 115 165 45 14 0 t 0 t 33
1,5 3,0 115 165 45 16 1,0 t 0,5 t 33
3,0 6,0 115 165 45 19 1,0 t 33
H12 0,2 0,5 145 195 125 3 1,5 t 0 t 46
0,5 1,5 145 195 125 4 1,5 t 0,5 t 46
1,5 3,0 145 195 125 4 2,0 t 1,0 t 46
3,0 6,0 145 195 125 5 1,5 t 46
H14 0,2 0,5 170 215 150 1 2,5 t 0,5 t 54
0,5 1,5 170 215 150 2 2,5 t 1,0 t 54
1,5 3,0 170 215 150 2 1,5 t 54
3,0 6,0 170 215 150 3 2,0 t 54
H16 0,2 0,5 195 240 175 1 1,0 t 61
0,5 1,5 195 240 175 2 1,5 t 61
1,5 4,0 195 240 175 2 2,5 t 61
H18 0,2 0,5 220 200 1 1,5 t 69
0,5 1,5 220 200 2 2,5 t 69
1,5 3,0 220 200 2 69
H19 0,2 0,5 235 210 1 73
0,5 1,5 235 210 1 73
H22 0,2 0,5 145 195 110 5 1,0 t 0 t 45
0,5 1,5 145 195 110 5 1,0 t 0,5 t 45
1,5 3,0 145 195 110 6 1,5 t 1,0 t 45
3,0 6,0 145 195 110 7 1,5 t 45
a a
Specified Tensile Yield Elongation Bend radius Hardness
Temper
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
H24 0,2 0,5 170 215 130 4 1,5 t 0,5 t 52
0,5 1,5 170 215 130 4 1,5 t 1,0 t 52
1,5 3,0 170 215 130 4 1,5 t 52
H26 0,2 0,5 195 240 160 3 1,0 t 60
0,5 1,5 195 240 160 3 1,5 t 60
1,5 3,0 195 240 160 3 2,5 t 60
H28 0,2 0,5 220 190 2 1,5 t 68
0,5 1,5 220 190 2 2,5 t 68
1,5 3,0 220 190 3 68
a
For information only.
Table 15 — Alloy EN AW-3105 [Al Mn0,5Mg0,5] — Alloy EN AW-3105B [Al Mn0,5Mg0,5 (B)]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 80,0 100
O 0,2 0,5 100 155 40 14 0 t 29
H111 0,5 1,5 100 155 40 15 0 t 29
1,5 3,0 100 155 40 17 0,5 t 29
H12 0,2 0,5 130 180 105 3 1,5 t 41
0,5 1,5 130 180 105 4 1,5 t 41
1,5 3,0 130 180 105 4 1,5 t 41
H14 0,2 0,5 150 200 130 2 2,5 t 48
0,5 1,5 150 200 130 2 2,5 t 48
1,5 3,0 150 200 130 2 2,5 t 48
H16 0,2 0,5 175 225 160 1 56
0,5 1,5 175 225 160 2 56
1,5 3,0 175 225 160 2 56
H18 0,2 0,5 195 180 1 62
0,5 1,5 195 180 1 62
1,5 3,0 195 180 1 62
H19 0,2 0,5 215 190 1 67
0,5 1,5 215 190 1 67
H22 0,2 0,5 130 180 105 6 41
0,5 1,5 130 180 105 6 41
1,5 3,0 130 180 105 7 41
H24 0,2 0,5 150 200 120 4 2,5 t 47
0,5 1,5 150 200 120 4 2,5 t 47
1,5 3,0 150 200 120 5 2,5 t 47
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
H26 0,2 0,5 175 225 150 3 55
0,5 1,5 175 225 150 3 55
1,5 3,0 175 225 150 3 55
H28 0,2 0,5 195 170 2 61
0,5 1,5 195 170 2 61
a
For information only.
Table 16 — Alloy EN AW-4006 [Al Si1Fe]
a a
Temper Specified Tensile Yield Elongation Bend radius Hardness
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
a
F ≥ 2,5 6,0 95
O 0,2 0,5 95 130 40 17 0 t 28
0,5 1,5 95 130 40 19 0 t 28
1,5 3,0 95 130 40 22 0 t 28
3,0 6,0 95 130 40 25 1,0 t 28
H12 0,2 0,5 120 160 90 4 1,5 t 38
0,5 1,5 120 160 90 4 1,5 t 38
1,5 3,0 120 160 90 5 1,5 t 38
H14 0,2 0,5 140 180 120 3 2,0 t 45
0,5 1,5 140 180 120 3 2,0 t 45
1,5 3,0 140 180 120 3 2,0 t 45
b
T4 0,2 0,5 120 160 55 14 35
0,5 1,5 120 160 55 16 35
1,5 3,0 120 160 55 18 35
3,0 6,0 120 160 55 21 35
a
For information only.
b
The T4 temper is not normally supplied by the producers of wrought products such as circles, strips and sheets.
It is obtained by rapid cooling after heating at a relatively elevated temperature, above 500°C. This thermal cycle is
routinely achieved when enamelling the finished products made out of this alloy, such as frying pans, pressure
cookers, pans, etc.
Table 17 — Alloy EN AW-4007
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