| Name |
Description |
Abstract |
Status |
Publication date |
Edition |
Number of pages |
Technical committee |
ICS |
| ISO 8494:2013 |
Metallic materials — Tube — Flanging test |
ISO 8494:2013 specifies a method for determining the ability of metallic tubes of circular cross-section to undergo plastic deformation during flange formation.
ISO 8494:2013 is intended for tubes having an outside diameter no greater than 150 mm and a wall thickness no greater than 10 mm, although the range of diameters or wall thickness for which ISO 8494:2013 is applicable may be more exactly specified in the relevant product standard.
|
Published |
2013-11 |
Edition : 3 |
Number of pages : 3 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8495:1986 |
Metallic materials — Tube — Ring-expanding test |
|
Withdrawn |
1986-10 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8495:1998 |
Metallic materials — Tube — Ring-expanding test |
|
Withdrawn |
1998-10 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8495:2013 |
Metallic materials — Tube — Ring-expanding test |
ISO 8495:2013 specifies a method for a ring-expanding test on tubes, that is used to reveal defects both on the surfaces and within the tube wall by expanding the test piece using a conical mandrel until fracture occurs. It may be also used to assess the ability of tubes to undergo plastic deformation.
The ring-expanding test is applicable to tubes having an outside diameter from 18 mm up to and including 150 mm and a wall thickness from 2 mm up to and including 16 mm.
|
Published |
2013-11 |
Edition : 3 |
Number of pages : 3 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8496:1986 |
Metallic materials — Tube — Ring tensile test |
|
Withdrawn |
1986-10 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8496:1998 |
Metallic materials — Tube — Ring tensile test |
|
Withdrawn |
1998-10 |
Edition : 2 |
Number of pages : 2 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 8496:2013 |
Metallic materials — Tube — Ring tensile test |
ISO 8496:2013 specifies a method for a ring tensile test of tubes to reveal surface and internal defects by subjecting the test piece to strain until fracture occurs. This test may also be used to assess the ductility of tubes.
The ring tensile test is applicable to tubes having an outside diameter exceeding 150 mm and a wall thickness no greater than 40 mm. The inside diameter shall be greater than 100 mm.
|
Published |
2013-11 |
Edition : 3 |
Number of pages : 2 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9513:1989 |
Metallic materials — Verification of extensometers used in uniaxial testing |
|
Withdrawn |
1989-11 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9513:1999 |
Metallic materials — Calibration of extensometers used in uniaxial testing |
|
Withdrawn |
1999-04 |
Edition : 2 |
Number of pages : 10 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9513:1999/Cor 1:2000 |
Metallic materials — Calibration of extensometers used in uniaxial testing — Technical Corrigendum 1 |
|
Withdrawn |
2000-07 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9513:2012 |
Metallic materials — Calibration of extensometer systems used in uniaxial testing |
ISO 9513:2012 specifies a method for the static calibration of extensometer systems used in uniaxial testing, including axial and diametral extensometer systems, both contacting and non-contacting.
|
Published |
2012-12 |
Edition : 3 |
Number of pages : 45 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9649:2016 |
Metallic materials — Wire — Reverse torsion test |
ISO 9649:2016 specifies a method for determining the ability of metallic wire of diameter dimension from 0,3 mm to 10,0 mm inclusive to undergo plastic deformation during reverse torsion. This test is used to detect surface defects, as well as to assess ductility.
|
Published |
2016-05 |
Edition : 2 |
Number of pages : 4 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 9649 |
Metallic materials — Wire — Reverse torsion test |
ISO 9649:2016 specifies a method for determining the ability of metallic wire of diameter dimension from 0,3 mm to 10,0 mm inclusive to undergo plastic deformation during reverse torsion. This test is used to detect surface defects, as well as to assess ductility.
|
Under development |
|
Edition : 3 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TR 10108:1989 |
Steel — Conversion of hardness values to tensile strength values |
Describes the bands for conversion of hardness to tensile strength established to hardness scales of Brinell and Vickers as well as rules for their use. Applies to any steel but only to products in full section (thickness over 2 mm).
|
Withdrawn |
1989-08 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10113:1991 |
Metallic materials — Sheet and strip — Determination of plastic strain ratio |
Specifies a method for determining the plastic strain ratio of flat metallic products. Describes the principle, the test equipment, the test piece, the test procedure, the expression of results, and the contents of the test report.
|
Withdrawn |
1991-05 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10113:2006 |
Metallic materials — Sheet and strip — Determination of plastic strain ratio |
ISO 10113:2006 specifies a method for determining the plastic strain ratio of flat products (sheet and strip) made of metallic materials.
|
Withdrawn |
2006-09 |
Edition : 2 |
Number of pages : 10 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10113:2020 |
Metallic materials — Sheet and strip — Determination of plastic strain ratio |
This document specifies a method for determining the plastic strain ratio of flat products (sheet and strip) made of metallic materials.
|
Published |
2020-01 |
Edition : 3 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10250:1994 |
Metallic materials — Hardness testing — Tables of Knoop hardness values for use in tests made on flat surfaces |
Gives a table for calculation of Knoop hardness values for use in tests carried out in accordance with ISO 4545.
|
Withdrawn |
1994-09 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10275:1993 |
Metallic materials — Sheet and strip — Determination of tensile strain hardening exponent |
The principle of the test method specified is subjecting a test piece to uniaxial tensile strain at a prescribed constant rate within the region of uniform plastic strain. It is valid only for that part of the stress-strain curve in the plastic range where the curve is continuous and monotonic. The tensile strain hardening exponent is calculated either by considering a portion of the stress-strain curve in the plastic strain region, or by considering the whole of the uniform plastic strain region.
|
Withdrawn |
1993-02 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10275:2007 |
Metallic materials — Sheet and strip — Determination of tensile strain hardening exponent |
ISO 10275:2007 specifies a method for determining the tensile strain hardening exponent of flat products (sheet and strip) made of metallic materials.
The method is valid only for that part of the stress-strain curve in the plastic range where the curve is continuous and monotonic.
|
Withdrawn |
2007-06 |
Edition : 2 |
Number of pages : 10 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 10275:2020 |
Metallic materials — Sheet and strip — Determination of tensile strain hardening exponent |
This document specifies a method for determining the tensile strain hardening exponent n of flat products (sheet and strip) made of metallic materials.
The method is valid only for that part of the stress-strain curve in the plastic range where the curve is continuous and monotonic (see 8.4).
In the case of materials with a serrated stress-strain curve in the work hardening range (materials which show the Portevin-Le Chatelier effect, e.g. AlMg-alloys), the automatic determination (linear regression of the logarithm true stress vs. the logarithm true plastic strain, see 8.7) is used to give reproducible results.
|
Published |
2020-08 |
Edition : 3 |
Number of pages : 10 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 11531:1994 |
Metallic materials — Earing test |
Specifies a method for determining the ear height of metal sheet and strip of nominal thickness from 0,1 mm to 3 mm after deep drawing by measuring the height of any earing with an accuracy of ± 0,05 mm.
|
Withdrawn |
1994-04 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 1513:1980 |
Paints and varnishes — Examination and preparation of samples for testing |
|
Withdrawn |
1980-06 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
87.040
Paints and varnishes
|
| ISO 11531:2015 |
Metallic materials — Sheet and strip — Earing test |
ISO 11531:2015 specifies a method for determining the ear height of metal sheet and strip of nominal thickness from 0,1 mm to 3 mm after deep drawing.
|
Withdrawn |
2015-11 |
Edition : 2 |
Number of pages : 5 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 11531:2022 |
Metallic materials — Sheet and strip — Earing test |
This document specifies a method for determining the ear height of metal sheet and strip of nominal thickness from 0,1 mm to 3 mm after deep drawing.
|
Published |
2022-09 |
Edition : 3 |
Number of pages : 6 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12004-1:2008 |
Metallic materials — Sheet and strip — Determination of forming-limit curves — Part 1: Measurement and application of forming-limit diagrams in the press shop |
ISO 12004-1:2008 provides guidelines for developing forming-limit diagrams and forming-limit curves for metal sheets and strips of thicknesses from 0,3 mm to 4 mm.
|
Withdrawn |
2008-10 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12004-1:2020 |
Metallic materials — Determination of forming-limit curves for sheet and strip — Part 1: Measurement and application of forming-limit diagrams in the press shop |
This document specifies a procedure for developing forming-limit diagrams and forming-limit curves for metal sheets and strips of thicknesses from 0,3 mm to 4 mm.
|
Published |
2020-10 |
Edition : 2 |
Number of pages : 8 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12004-2:2008 |
Metallic materials — Sheet and strip — Determination of forming-limit curves — Part 2: Determination of forming-limit curves in the laboratory |
ISO 12004-2:2008 specifies the testing conditions to be used when constructing a forming-limit curve (FLC) at ambient temperature and using linear strain paths. The material considered is flat, metallic and of thickness between 0,3 mm and 4 mm.
|
Withdrawn |
2008-10 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12004-2:2021 |
Metallic materials — Determination of forming-limit curves for sheet and strip — Part 2: Determination of forming-limit curves in the laboratory |
This document specifies testing conditions for use when constructing a forming-limit curve (FLC) at ambient temperature and using linear strain paths. The material considered is flat, metallic and of thickness between 0,3 mm and 4 mm.
NOTE The limitation in thickness of up to 4 mm is proposed, giving a maximum allowable thickness to the punch diameter ratio.
|
Published |
2021-02 |
Edition : 2 |
Number of pages : 27 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12004:1997 |
Metallic materials — Guidelines for the determination of forming-limit diagrams |
Provides guidelines for developing forming-limit diagrams and forming-limit curves for metal sheets and strips of nominal thicknesses from 0,2 mm to 3 mm.
|
Withdrawn |
1997-01 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/CD TR 12105 |
Metallic materials — Fatigue testing — General principles |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12106:2003 |
Metallic materials — Fatigue testing — Axial-strain-controlled method |
ISO 12106:2003 specifies a method of testing uniaxially loaded specimens under strain control at constant amplitude, uniform temperature and a strain ratio of -1.
It can also be used as a guide for testing under other conditions.
|
Withdrawn |
2003-03 |
Edition : 1 |
Number of pages : 35 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12106:2017 |
Metallic materials — Fatigue testing — Axial-strain-controlled method |
ISO 12106:2017 specifies a method of testing uniaxially deformed specimens under strain control at constant amplitude, uniform temperature and fixed strain ratios including at Re = −1 for the determination of fatigue properties. It can also be used as a guide for testing under other R-ratios, as well as elevated temperatures where creep deformation effects may be active.
|
Published |
2017-03 |
Edition : 2 |
Number of pages : 38 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12107:2003 |
Metallic materials — Fatigue testing — Statistical planning and analysis of data |
ISO 12107:2003 presents methods for the experimental planning of fatigue testing and the statistical analysis of the resulting data. The purpose is to determine the fatigue properties of metallic materials with both a high degree of confidence and a practical number of specimens.
It provides a method for the analysis of fatigue life properties at a variety of stress levels using a relationship that can linearly approximate the material's response in appropriate coordinates. Specifically, it addresses the fatigue life for a given stress, and the fatigue strength for a given fatigue life.
It is limited to the analysis of fatigue data for materials exhibiting homogeneous behaviour due to a single mechanism of fatigue failure. This refers to the statistical properties of test results that are closely related to material behaviour under the test conditions.
|
Withdrawn |
2003-03 |
Edition : 1 |
Number of pages : 26 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12107:2012 |
Metallic materials — Fatigue testing — Statistical planning and analysis of data |
ISO 12107:2012 presents methods for the experimental planning of fatigue testing and the statistical analysis of the resulting data. The purpose is to determine the fatigue properties of metallic materials with both a high degree of confidence and a practical number of specimens.
|
Published |
2012-08 |
Edition : 2 |
Number of pages : 36 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12108:2002 |
Metallic materials — Fatigue testing — Fatigue crack growth method |
ISO 12108 is intended to provide specifications for generation of fatigue crack growth rate data. Test results are expressed in terms of the fatigue crack growth rate as a function of crack-tip stress intensity factor range as defined by the theory of linear elastic fracture mechanics.
This International Standard describes a method of subjecting a precracked notched specimen to a cyclic force. The crack length is measured as a function of the number of elapsed force cycles. From the collected crack length and corresponding force cycles relationship the fatigue crack growth rate is determined and is expressed as a function of stress intensity factor range.
ISO 12018 describes tests for determining the fatigue crack growth rate from the threshold stress-intensity factor range to the onset of unstable crack extension as the maximum stress intensity factor approaches controlled instability. It is primarily intended for use in evaluating isotropic metallic materials under predominantly linear-elastic stress conditions and with force applied only perpendicular to the crack plane (mode I stress condition), and with a constant stress ratio.
|
Withdrawn |
2002-12 |
Edition : 1 |
Number of pages : 39 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12108:2012 |
Metallic materials — Fatigue testing — Fatigue crack growth method |
ISO 12108:2012 describes tests for determining the fatigue crack growth rate from the fatigue crack growth threshold stress-intensity factor range to the onset of rapid, unstable fracture.
ISO 12108:2012 is primarily intended for use in evaluating isotropic metallic materials under predominantly linear-elastic stress conditions and with force applied only perpendicular to the crack plane (mode I stress condition), and with a constant stress ratio.
|
Withdrawn |
2012-08 |
Edition : 2 |
Number of pages : 43 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12108:2018 |
Metallic materials — Fatigue testing — Fatigue crack growth method |
This document describes tests for determining the fatigue crack growth rate from the fatigue crack growth threshold stress-intensity factor range, ΔKth, to the onset of rapid, unstable fracture.
This document is primarily intended for use in evaluating isotropic metallic materials under predominantly linear-elastic stress conditions and with force applied only perpendicular to the crack plane (mode I stress condition), and with a constant force ratio, R.
|
Published |
2018-07 |
Edition : 3 |
Number of pages : 53 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12110-1:2013 |
Metallic materials — Fatigue testing — Variable amplitude fatigue testing — Part 1: General principles, test method and reporting requirements |
ISO 12110-1:2013 establishes general principles for fatigue testing of laboratory specimens under a sequence of cycles the amplitude of which varies from cycle to cycle.
This sequence of cycles is called loading time history (see 3.7) and is usually derived from loading measurements performed on components or structures submitted to true service loadings.
Detailed description of service loads recording is relevant to each laboratory or industrial sector and is therefore outside the scope of ISO 12110-1:2013.
The aim of the two parts of ISO 12110 is to set requirements and give some guidance on how to perform a variable amplitude fatigue test in order to produce consistent results for comparison purposes taking into account the typical scatter of fatigue data. Achieving this should help designers to correlate models and experimental data obtained from various sources.
Since ISO 12110-1:2013 involves mainly loading time histories and control signal generation, one expects it might be applied to strain or fatigue crack growth rate controlled loading conditions as well as to force-controlled loading conditions. This is theoretically true but precautions may be taken when applying this document to loading modes other than force-controlled loading mode.
ISO 12110-1:2013 relates to variable amplitude loading under force control mode which corresponds to most of the variable amplitude fatigue tests performed worldwide at the date of publication.
ISO 12110-1:2013 applies to the single actuator loading mode which corresponds to uniaxial loading in many cases.
The variable amplitude loading time histories referred in this document are deterministic; that is why ISO 12110-1:2013 deals with variable amplitude loading instead of random loading.
The following issues are not within the scope of ISO 12110-1:2013 and therefore will not be addressed: constant amplitude tests with isolated overloads or underloads; tests on large components or structures;environmental effects like corrosion, creep linked to temperature/time interactions leading to frequency and waveform effects; multiaxial loading.
|
Published |
2013-07 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12110-2:2013 |
Metallic materials — Fatigue testing — Variable amplitude fatigue testing — Part 2: Cycle counting and related data reduction methods |
ISO 12110-2:2013 presents cycle counting techniques and data reduction methods which are used in variable amplitude fatigue testing. For each test or test series, cycle counting is mandatory whereas data reduction methods are optional.
ISO 12110-2:2013 supports ISO 12110-1 which contains the general principles and describes the common requirements about variable amplitude fatigue testing. ISO 12110-2:2013, the term "loading" refers either to force, stress, or strain since the methods presented here are valid for all.
The following issues are not within the scope of this document and therefore are not addressed: constant amplitude tests with isolated overloads or underloads; large components or structures; environmental effects like corrosion, creep, etc. linked to temperature/time interactions leading to frequency and waveform effects; multiaxial loading.
|
Published |
2013-07 |
Edition : 1 |
Number of pages : 33 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12111:2011 |
Metallic materials — Fatigue testing — Strain-controlled thermomechanical fatigue testing method |
ISO 12111:2011 is applicable to the TMF (thermomechanical fatigue) testing of uniaxially loaded metallic specimens under strain control. Specifications allow for any constant cyclic amplitude of mechanical strain and temperature with any constant cyclic mechanical strain ratio and any constant cyclic temperature-mechanical strain phasing.
|
Published |
2011-08 |
Edition : 1 |
Number of pages : 25 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TR 12112:2018 |
Metallic materials — Principles and designs for multiaxial fatigue testing |
ISO/TR 12112:2018 discusses the general principles of multiaxial fatigue testing and the design recommendations for specific classes of multiaxial testing machines and test specimens.
|
Published |
2018-04 |
Edition : 1 |
Number of pages : 32 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12135:2002 |
Metallic materials — Unified method of test for the determination of quasistatic fracture toughness |
International Standard ISO 12135 specifies methods for determining fracture toughness in terms of K, δ, J and R-curves for homogeneous metallic materials subjected to quasistatic loading. Specimens are notched, precracked by fatigue and tested under slowly increasing displacement.
|
Withdrawn |
2002-12 |
Edition : 1 |
Number of pages : 94 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12135:2002/Cor 1:2008 |
Metallic materials — Unified method of test for the determination of quasistatic fracture toughness — Technical Corrigendum 1 |
|
Withdrawn |
2008-06 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12135:2016 |
Metallic materials — Unified method of test for the determination of quasistatic fracture toughness |
ISO 12135:2016 specifies methods for determining fracture toughness in terms of K, δ, J and R-curves for homogeneous metallic materials subjected to quasistatic loading. Specimens are notched, precracked by fatigue and tested under slowly increasing displacement. The fracture toughness is determined for individual specimens at or after the onset of ductile crack extension or at the onset of ductile crack instability or unstable crack extension. In some cases in the testing of ferritic materials, unstable crack extension can occur by cleavage or ductile crack initiation and growth, interrupted by cleavage extension. The fracture toughness at crack arrest is not covered by this document. In cases where cracks grow in a stable manner under ductile tearing conditions, a resistance curve describing fracture toughness as a function of crack extension is measured. In most cases, statistical variability of the results is modest and reporting the average of three or more test results is acceptable. In cases of cleavage fracture of ferritic materials in the ductile-to-brittle transition region, variability can be large and additional tests may be required to quantify statistical variability. Special testing requirements and analysis procedures are necessary when testing weldments and these are described in ISO 15653 which is complementary to this document.
When fracture occurs by cleavage or when cleavage is preceded by limited ductile crack extension, it may be useful to establish the reference temperature for the material by conducting testing and analysis in accordance with ASTM E1921.[2]
|
Withdrawn |
2016-11 |
Edition : 2 |
Number of pages : 98 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12135:2021 |
Metallic materials — Unified method of test for the determination of quasistatic fracture toughness |
This document specifies methods for determining fracture toughness in terms of K, δ, J and R-curves for homogeneous metallic materials subjected to quasistatic loading. Specimens are notched, precracked by fatigue and tested under slowly increasing displacement. The fracture toughness is determined for individual specimens at or after the onset of ductile crack extension or at the onset of ductile crack instability or unstable crack extension. In cases where cracks grow in a stable manner under ductile tearing conditions, a resistance curve describing fracture toughness as a function of crack extension is measured. In some cases in the testing of ferritic materials, unstable crack extension can occur by cleavage or ductile crack initiation and growth, interrupted by cleavage extension. The fracture toughness at crack arrest is not covered by this document. Special testing requirements and analysis procedures are necessary when testing weldments, and these are described in ISO 15653 which is complementary to this document.
Statistical variability of the results strongly depends on the fracture type, for instance, fracture toughness associated with cleavage fracture in ferritic steels can show large variation. For applications that require high reliability, a statistical approach can be used to quantify the variability in fracture toughness in the ductile-to-brittle transition region, such as that given in ASTM E1921. However, it is not the purpose of this document to specify the number of tests to be carried out nor how the results of the tests are to be applied or interpreted.
|
Published |
2021-07 |
Edition : 3 |
Number of pages : 100 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TR 12735-1:1996 |
Mechanical testing of metals — Symbols used with their definitions — Part 1: Symbols and definitions in published standards |
Enumerates the symbols and definitions used in published International Standards for specific methods of mechanical testing of metallic materials which are the responsibility of ISO TC 164.
|
Withdrawn |
1996-12 |
Edition : 1 |
Number of pages : 35 |
Technical Committee |
01.040.77
Metallurgy (Vocabularies)
;
77.040.10
Mechanical testing of metals
|
| ISO/TR 12735-2:1996 |
Mechanical testing of metals — Symbols used with their definitions — Part 2: Recommendations for the development of symbols and definitions |
Contains recommendations on the choice of definitions and symbols to be used in International Standards for methods of mechanical testing of metallic materials.
|
Withdrawn |
1996-12 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
01.040.77
Metallurgy (Vocabularies)
;
77.040.10
Mechanical testing of metals
|
| ISO 12737:1996 |
Metallic materials — Determination of plane-strain fracture toughness |
Method for determining the plan-strain fracture toughness of homogeneous metallic materials using a specimen that is notched and precracked by fatigue.
|
Withdrawn |
1996-11 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 12737:2005 |
Metallic materials — Determination of plane-strain fracture toughness |
ISO 12737:2005 specifies the ISO method for determining the plane-strain fracture toughness of homogeneous metallic materials using a specimen that is notched and precracked by fatigue, and subjected to a slowly increasing crack displacement force.
|
Withdrawn |
2005-08 |
Edition : 2 |
Number of pages : 18 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/ASTM DIS 52927 |
Additive manufacturing — General principles — Main characteristics and corresponding test methods |
|
Under development |
|
Edition : 1 |
Number of pages : 23 |
Technical Committee |
25.030
Additive manufacturing
|
| ISO 12737:2010 |
Metallic materials — Determination of plane-strain fracture toughness |
ISO 12737:2010 specifies the ISO method for determining the plane-strain fracture toughness of homogeneous metallic materials using a specimen that is notched and precracked by fatigue, and subjected to slowly increasing crack displacement force.
|
Withdrawn |
2010-12 |
Edition : 3 |
Number of pages : 18 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 13314:2011 |
Mechanical testing of metals — Ductility testing — Compression test for porous and cellular metals |
ISO 13314:2011 specifies a test method for compressive properties of porous and cellular metals with a porosity of 50 % or more. Compressive tests can be carried out at ambient temperature under quasi-static strain rate conditions.
|
Published |
2011-12 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14317:2006 |
Sintered metal materials excluding hardmetals — Determination of compressive yield strength |
ISO 14317:2006 specifies a method for the determination of the compressive yield strength of sintered metal materials, excluding hardmetals.
This method is applicable to sintered materials, excluding hardmetals, that may or may not have been subjected to heat treatment after sintering, and also to materials that have been sized or coined after sintering.
|
Withdrawn |
2006-11 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 14317:2015 |
Sintered metal materials excluding hardmetals — Determination of compressive yield strength |
ISO 14317:2015 specifies a method for the determination of the compressive yield strength of sintered metal materials, excluding hardmetals.
This method is applicable to sintered materials (excluding hardmetals) that might or might not have been subjected to heat treatment after sintering and also to materials that have been sized or coined after sintering.
|
Published |
2015-04 |
Edition : 2 |
Number of pages : 5 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 14556:2000 |
Steel — Charpy V-notch pendulum impact test — Instrumented test method |
|
Withdrawn |
2000-05 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14556:2000/Amd 1:2006 |
Steel — Charpy V-notch pendulum impact test — Instrumented test method — Amendment 1: Annex D — Instrumented Charpy V-notch pendulum impact test of sub-size test pieces |
|
Withdrawn |
2006-07 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14556:2015 |
Metallic materials — Charpy V-notch pendulum impact test — Instrumented test method |
ISO 14556:2015 specifies a method of instrumented Charpy V-notch pendulum impact testing on metallic materials and the requirements concerning the measurement and recording equipment.
With respect to the Charpy pendulum impact test described in ISO 148‑1, this test provides further information on the fracture behaviour of the product under impact testing conditions.
General information about instrumented impact testing can be found in Reference [1] to Reference [5].
|
Published |
2015-09 |
Edition : 2 |
Number of pages : 20 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14556 |
Metallic materials — Charpy V-notch pendulum impact test — Instrumented test method |
|
Under development |
|
Edition : 3 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-1:2002 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 1: Test method |
ISO 14577-1 specifies the method of instrumented indentation test for the determination of hardness and other materials parameters for the three ranges:
macro (test force between 2 N and 30 kN);
micro (test force less than 2 N; indentation depth greater than 0, 2 m);
nano (indentation depth equal to or less than than 0,2 m).
|
Withdrawn |
2002-10 |
Edition : 1 |
Number of pages : 25 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-1:2015 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 1: Test method |
ISO 14577-1:2015 specifies the method of instrumented indentation test for determination of hardness and other materials parameters for the following three ranges: macro range: 2 N ≤ F ≤ 30 kN; micro range: 2 N > F; h > 0,2 µm; and nano range: h ≤ 0,2 µm.
For the nano range, the mechanical deformation strongly depends on the real shape of indenter tip and the calculated material parameters are significantly influenced by the contact area function of the indenter used in the testing machine. Therefore, careful calibration of both instrument and indenter shape is required in order to achieve an acceptable reproducibility of the materials parameters determined with different machines.
The macro and micro ranges are distinguished by the test forces in relation to the indentation depth.
Attention is drawn to the fact that the micro range has an upper limit given by the test force (2 N) and a lower limit given by the indentation depth of 0,2 µm.
The determination of hardness and other material parameters is given in Annex A.
At high contact pressures, damage to the indenter is possible. For this reason in the macro range, hardmetal indenters are often used. For test pieces with very high hardness and modulus of elasticity, permanent indenter deformation can occur and can be detected using suitable reference materials. It is necessary that its influence on the test result be taken into account.
This test method can also be applied to thin metallic and non-metallic coatings and non-metallic materials. In this case, it is recommended that the specifications in the relevant standards be taken into account (see also 6.3 and ISO 14577‑4).
|
Published |
2015-07 |
Edition : 2 |
Number of pages : 46 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 1522:1973 |
Paints and varnishes — Pendulum damping test |
|
Withdrawn |
1973-12 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
87.040
Paints and varnishes
|
| ISO 14577-2:2002 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 2: Verification and calibration of testing machines |
ISO 14577-2 specifies the method of verification and calibration of testing machines for carrying out the instrumented test in accordance with ISO 14577-1.
It describes a direct verification method for checking the main functions of the testing machine and an indirect verification method suitable for the determination of the repeatability of the testing machine.
This part of ISO 14577 is also applicable for transportable testing machines.
|
Withdrawn |
2002-10 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-2:2015 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 2: Verification and calibration of testing machines |
ISO 14577-2:2015 specifies the method of verification and calibration of testing machines for carrying out the instrumented indentation test in accordance with ISO 14577‑1:2015.
It describes a direct verification method for checking the main functions of the testing machine and an indirect verification method suitable for the determination of the repeatability of the testing machine. There is a requirement that the indirect method be used in addition to the direct method and for the periodic routine checking of the testing machine in service.
It is a requirement that the indirect method of verification of the testing machine be carried out independently for each test method.
ISO 14577-2:2015 is also applicable for transportable testing machines.
|
Published |
2015-07 |
Edition : 2 |
Number of pages : 25 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-3:2002 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 3: Calibration of reference blocks |
ISO 14577-3 specifies a method for the calibration of reference blocks to be used for the indirect verification of testing machines for the instrumented indentation test, as specified in ISO 14577-2.
|
Withdrawn |
2002-10 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-3:2015 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 3: Calibration of reference blocks |
ISO 14577-3:2015 specifies a method for the calibration of reference blocks to use for the indirect verification of testing machines for the instrumented indentation test as specified in ISO 14577‑2:2015.
|
Published |
2015-08 |
Edition : 2 |
Number of pages : 8 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-4:2007 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 4: Test method for metallic and non-metallic coatings |
ISO 14577-4:2007 specifies a method for testing coatings that is particularly suitable for testing in the nano/micro range applicable to thin coatings.
This test method is limited to the examination of single layers when the indentation is carried out normal to the test piece surface, but graded and multilayer coatings can also be measured in cross-section if the thickness of the individual layers or gradations is greater than the spatial resolution of the indentation process.
The test method is not limited to any particular type of material. Metallic, non-metallic and organic coatings are included in the scope of ISO 14577-4:2007.
The application of ISO 14577-4:2007 regarding measurement of hardness is only possible if the indenter is a pyramid or a cone with a radius of tip curvature small enough for plastic deformation to occur within the coating. The hardness of visco-elastic materials, or materials exhibiting significant creep will be strongly affected by the time taken to perform the test.
|
Withdrawn |
2007-05 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-4:2016 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 4: Test method for metallic and non-metallic coatings |
ISO 14577-4:2016 specifies a method for testing coatings which is particularly suitable for testing in the nano/micro range applicable to thin coatings. However, the application of this method of this part of ISO 14577 is not needed if the indentation depth is such a small fraction of the coating thickness that in any possible case a substrate influence can be neglected and the coating can be considered as a bulk material. Limits for such cases are given.
This test method is limited to the examination of single layers when the indentation is carried out normal to the test piece surface, but graded and multilayer coatings can also be measured in cross-section if the thickness of the individual layers or gradations is greater than the spatial resolution of the indentation process.
The test method is not limited to any particular type of material. Metallic and non-metallic coatings are included in the scope of this part of ISO 14577. In this part of ISO 14577, the term coating is used to refer to any solid layer with homogeneous properties different to that of a substrate it is connected to. The method assumes that coating properties are constant with indentation depth. Composite coatings are considered to be homogenous if the structure size is less than the indentation size.
The application of this part of ISO 14577 regarding measurement of indentation hardness is only possible if the indenter is a pyramid or a cone with a radius of tip curvature small enough for plastic deformation to occur within the coating. The hardness of visco-elastic materials or materials exhibiting significant creep will be strongly affected by the time taken to perform the test.
|
Published |
2016-11 |
Edition : 2 |
Number of pages : 19 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 14577-5:2022 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 5: Linear elastic dynamic instrumented indentation testing (DIIT) |
This document specifies the method of linear elastic dynamic instrumented indentation test for determination of indentation hardness and indentation modulus of materials showing elastic-plastic behaviour when oscillatory force or displacement is applied to the indenter while the load or displacement is held constant at a prescribed target value or while the indenter is continuously loaded to a prescribed target load or target depth.
|
Published |
2022-10 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/ASTM DIS 52928 |
Additive manufacturing of metals— Feedstock materials — Powder life cycle management |
|
Under development |
|
Edition : 1 |
Number of pages : 23 |
Technical Committee |
25.030
Additive manufacturing
|
| ISO/TR 14577:1995 |
Metallic materials — Hardness test — Universal test |
Specifies the method of universal hardness test for metallic materials using indentation depths equal or greater than 3 m. Can also be used for all other materials.
|
Withdrawn |
1995-12 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TR 14936:1998 |
Metallic materials — Strain analysis report |
|
Withdrawn |
1998-02 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/CD TR 15262 |
Mechanical tests on metallic materials — Uncertainty in low-cycle fatigue |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/CD TR 15263 |
Measurement uncertainties in mechanical tests on metallic materials — The evaluation of uncertainties in tensile testing |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 15363:2000 |
Metallic materials — Tube ring hydraulic pressure test |
|
Withdrawn |
2000-08 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 15363:2017 |
Metallic materials — Tube ring hydraulic pressure test |
ISO 15363:2017 specifies the ring hydraulic pressure test for metallic tubes. It is generally applied to tubes with an outside diameter greater than 120 mm and outside diameter to thickness ratio of not less than 20.
The objective of this test is to ascertain the value of the hoop stress required to produce a specified total circumferential (hoop) strain.
|
Published |
2017-07 |
Edition : 2 |
Number of pages : 9 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 15461:2018 |
Steel forgings — Testing frequency, sampling conditions and test methods for mechanical tests |
ISO 15461:2018 gives guidelines for the simplification and harmonization of the specifications for mechanical testing of open die and closed die forgings in International Standards and other technical delivery conditions for forgings of steel.
ISO 15461:2018
a) offers various options for
the frequency of testing, and
sampling conditions,
b) introduces a designation system for the options, mentioned under (a), and
c) specifies the test methods for
room temperature tensile tests,
elevated temperature tensile tests,
impact tests, and
uniformity checks by hardness tests.
|
Published |
2018-01 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
;
77.140.85
Iron and steel forgings
|
| ISO/TR 15461:1997 |
Steel forgings — Testing frequency, sampling conditions and test methods for mechanical tests |
|
Withdrawn |
1997-12 |
Edition : 1 |
Number of pages : 25 |
Technical Committee |
77.040.10
Mechanical testing of metals
;
77.140.85
Iron and steel forgings
|
| ISO 15579:2000 |
Metallic materials — Tensile testing at low temperature |
|
Withdrawn |
2000-06 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16630:2009 |
Metallic materials — Sheet and strip — Hole expanding test |
ISO 16630:2009 describes a method of determining the hole expansion ratio in metallic sheets and strips with a thickness range of 1,2 mm to 6,0 mm inclusive and a width of at least 90 mm. This test is normally applicable to sheet metal and is used to assess the suitability of the product for forming flanges.
|
Withdrawn |
2009-07 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TS 16630:2003 |
Metallic materials — Method of hole expanding test |
ISO/TS 16630:2003 describes a method of determining the hole expansion ratio in metallic sheets and strips with a thickness range of 1,2 mm to 6 mm inclusive and a width of at least 90 mm.
|
Withdrawn |
2003-05 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16630:2017 |
Metallic materials — Sheet and strip — Hole expanding test |
ISO 16630 describes a method of determining the hole expansion ratio in metallic sheets and strips with a thickness range of 1,2 mm to 6,0 mm inclusive and a width of at least 90 mm.
NOTE This test is normally applicable to sheet metal and is used to assess the suitability of the product for forming flanges.
|
Published |
2017-09 |
Edition : 2 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16808:2014 |
Metallic materials — Sheet and strip — Determination of biaxial stress-strain curve by means of bulge test with optical measuring systems |
ISO 16808:2014 specifies a method for determination of the biaxial stress-strain curve of metallic sheets having a thickness below 3 mm in pure stretch forming without significant friction influence. In comparison with tensile test results, higher strain values can be achieved.
|
Withdrawn |
2014-08 |
Edition : 1 |
Number of pages : 26 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16808:2022 |
Metallic materials — Sheet and strip — Determination of biaxial stress-strain curve by means of bulge test with optical measuring systems |
This document specifies a method for determination of the biaxial stress-strain curve of metallic sheets having a thickness below 3 mm in pure stretch forming without significant friction influence. In comparison with tensile test results, higher strain values can be achieved.
NOTE In this document, the term "biaxial stress-strain curve" is used for simplification. In principle, in the test the "biaxial true stress-true strain curve" is determined.
|
Published |
2022-05 |
Edition : 2 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16842:2014 |
Metallic materials — Sheet and strip — Biaxial tensile testing method using a cruciform test piece |
ISO 16842:2014 specifies the method for measuring the stress-strain curves of sheet metals subject to biaxial tension using a cruciform test piece fabricated from a sheet metal sample. The applicable thickness of the sheet shall be 0,1 mm or more and 0,08 times or less of the arm width of the cruciform test piece. The test temperature shall range from 10 °C to 35 °C. The amount of plastic strain applicable to the gauge area of the cruciform test piece depends on the force ratio, slit width of the arms, work hardening exponent (n-value), and anisotropy of a test material.
|
Withdrawn |
2014-10 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16842:2021 |
Metallic materials — Sheet and strip — Biaxial tensile testing method using a cruciform test piece |
This document specifies the method for measuring the stress-strain curves of sheet metals subject to biaxial tension using a cruciform test piece fabricated from a sheet metal sample. The applicable thickness of the sheet is 0,1 mm or more and 0,08 times or less of the arm width of the cruciform test piece (see Figure 1). The test temperature ranges from 10 °C to 35 °C. The amount of plastic strain applicable to the gauge area of the cruciform test piece depends on the force ratio, slit width of the arms, work hardening exponent (n-value) (see Annex B) and anisotropy of a test material.
|
Published |
2021-07 |
Edition : 2 |
Number of pages : 24 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16859-1:2015 |
Metallic materials — Leeb hardness test — Part 1: Test method |
ISO 16859-1:2015 covers the determination of a dynamic hardness of metallic materials using seven different Leeb scales (HLD, HLS, HLE, HLDL, HLD+15, HLC, HLG).
|
Published |
2015-09 |
Edition : 1 |
Number of pages : 20 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16859-2:2015 |
Metallic materials — Leeb hardness test — Part 2: Verification and calibration of the testing devices |
ISO 16859-2:2015 specifies methods for direct and indirect verification of test instruments used for determining Leeb hardness in accordance with ISO 16859‑1, and also describes when these two types of verification are to be performed.
The direct verification involves checking that individual instrument performance parameters fall within specified limits, whereas the indirect verification utilizes hardness measurements of reference test blocks, calibrated in accordance with ISO 16859‑3, to check the overall performance of the instrument for testing in the direction of gravity. The indirect method can be used on its own for the periodic performance checking in service.
|
Published |
2015-09 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 16859-3:2015 |
Metallic materials — Leeb hardness test — Part 3: Calibration of reference test blocks |
ISO 16859-3:2015 specifies a method for the calibration of reference test blocks that are used for the indirect verification of Leeb hardness testers according to ISO 16859‑2 and for the periodic checking according to ISO 16859‑1.
The procedures necessary to ensure metrological traceability of the calibration machine are also specified.
|
Published |
2015-09 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 17340:2014 |
Metallic materials — Ductility testing — High speed compression test for porous and cellular metals |
ISO 17340:2014 specifies methods for high speed compression testing, at room temperature, of porous and cellular metals having a porosity of 50 % or more. The speed range applicable to this test method is 0,1 m/s to 100 m/s (or 1 s−1 to 103 s−1 in terms of the initial strain rate when the specimen height is 100 mm).
|
Withdrawn |
2014-05 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 17340:2020 |
Metallic materials — Ductility testing — High speed compression test for porous and cellular metals |
This document specifies methods for high speed compression testing, at room temperature, of porous and cellular metals having a porosity of 50 % or more. The speed range applicable to this test method is 0,1 m/s to 100 m/s (or 1 s−1 to 103 s−1 in terms of the initial strain rate when the specimen height is 100 mm).
|
Published |
2020-05 |
Edition : 2 |
Number of pages : 17 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 18265:2003 |
Metallic materials — Conversion of hardness values |
ISO 18265:2003 specifies the principles of the conversion of hardness values and gives general information on the use of conversion tables.
The conversion tables apply to
unalloyed and low-alloy steels and cast iron;steels for quenching and tempering;cold working steels;high speed steels;hardmetals;non-ferrous metals and alloys.
|
Withdrawn |
2003-11 |
Edition : 1 |
Number of pages : 74 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 18265:2013 |
Metallic materials — Conversion of hardness values |
ISO 18265:2013 specifies the principles of the conversion of hardness values to equivalent values in other hardness scales and to estimates of tensile strength. It gives general information on the use of the conversion tables.
The conversion tables in Annexes A to G apply to unalloyed and low alloy steels and cast steel, steels for quenching and tempering, steels for cold working, high speed steels, tool steels, hardmetals, and non-ferrous metals and alloys.
Annex H gives information about the effects of changes of the test procedure in the standards specifying the hardness tests.
Converted values obtained using ISO 18265:2013 are only directly applicable to the exact material tested. For all other materials, they provide an indicator only. In all cases, the converted values are not intended as replacements for values obtained by the correct standard method. In particular, tensile strength estimates are the least reliable converted values in ISO 18265:2013.
|
Published |
2013-10 |
Edition : 2 |
Number of pages : 85 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 18338:2015 |
Metallic materials — Torsion test at ambient temperature |
ISO 18338:2015 specifies the method for torsion test at room temperature of metallic materials. The tests are conducted at room temperature to determine torsional properties.
|
Withdrawn |
2015-09 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 18338:2021 |
Metallic materials — Torsion test at room temperature |
This document specifies the method for torsion test at room temperature of metallic materials. The tests are conducted at room temperature to determine torsional properties.
|
Published |
2021-12 |
Edition : 2 |
Number of pages : 17 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/DTS 19096 |
Metallic materials — Instrumented indentation test for hardness and materials parameters — Evaluation of stress change using indentation force differences |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 19819:2004 |
Metallic materials — Tensile testing in liquid helium |
ISO 19819:2004 specifies the method of tensile testing of metallic materials in liquid helium (boiling point at - 269 °C or 4,2 K) and defines the mechanical properties that can be determined.
ISO 19819:2004 may also apply to tensile testing at cryogenic temperatures (less than - 196 °C or 77 K), which requires special apparatus, smaller specimens, and concern for serrated yielding, adiabatic heating and strain-rate effects.
|
Withdrawn |
2004-08 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 20032:2007 |
Method for evaluation of tensile properties of metallic superplastic materials |
ISO 20032:2006 specifies a method for evaluating the tensile properties of metallic superplastic materials which exhibit fine-grained superplasticity, without significant work-hardening or dynamic microstructure evolution, by means of a tensile test at constant cross-head velocity, for flat-form test pieces, without an extensometer attached.
|
Withdrawn |
2007-02 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 20032:2013 |
Method for evaluation of tensile properties of metallic superplastic materials |
ISO 20032:2013 specifies a method for evaluating the tensile properties of metallic superplastic materials which exhibit what is called "Fine-Grained Superplasticity", without significant work-hardening or dynamic microstructure evolution, by means of a tensile test at constant cross-head velocity, for flat-form test pieces, without an extensometer attached.
|
Published |
2013-08 |
Edition : 2 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 20064:2019 |
Metallic materials — Steel — Method of test for the determination of brittle crack arrest toughness, Kca |
This document specifies a test method for the determination of brittle crack arrest toughness.
It is applicable to ferritic steel base metals exhibiting ductile to brittle transition behaviour. Applicable materials are rolled steel plates. It is intended for materials with a tensile strength of 950 MPa or less and a test piece thickness of 200 mm or less. The range of arrest temperatures is between −196 °C and +100 °C. This document can be applied to flat rolled steel plates but not to flattened steel pipes because the flattening can cause changes in arrest toughness.
|
Published |
2019-07 |
Edition : 1 |
Number of pages : 45 |
Technical Committee |
77.040.10
Mechanical testing of metals
|