| Name |
Description |
Abstract |
Status |
Publication date |
Edition |
Number of pages |
Technical committee |
ICS |
| ISO 20482:2003 |
Metallic materials — Sheet and strip — Erichsen cupping test |
ISO 20482:2003 specifies a standard test method for determining the ability of metallic sheets and strips having a thickness from 0,1 mm up to 2 mm and a width of 90 mm or greater to undergo plastic deformation in stretch forming.
|
Withdrawn |
2003-07 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 20482:2013 |
Metallic materials — Sheet and strip — Erichsen cupping test |
ISO 20482:2013 specifies a standard test method for determining the ability of metallic sheets and strips having a thickness from 0,1 mm up to 2 mm and a width of 90 mm or greater to undergo plastic deformation in stretch forming.
For materials that are thicker and when only narrower strips are available, tools of specified dimensions are provided, in which case subscripts are used, as shown in Table 1.
|
Published |
2013-11 |
Edition : 2 |
Number of pages : 7 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TS 21913:2022 |
Temperature verification method applied to dynamic fatigue testing |
This document establishes verification procedures to determine the accuracy, speed of response, and stability of temperature measurement for materials testing equipment. These procedures are specified for the expected use in fatigue tests on metals where these characteristics are important to the fidelity of tests at high or varying temperature.
The principles set out include sufficient provision for both contacting and non-contacting methods of temperature measurement.
This document is for the end-to-end verification of registered value compared with “true” specimen temperature at the point of measurement. It cannot be used to specify the correct method or location of measurement.
NOTE: The methodologies could be found applicable to test types beyond mechanical fatigue of metals, but that is outside the remit of this document.
|
Published |
2022-06 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 22394:2010 |
Hardmetals — Knoop hardness test |
ISO 22394:2010 specifies the method of the Knoop hardness test for hardmetals.
|
Withdrawn |
2010-02 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 22407:2021 |
Metallic materials — Fatigue testing — Axial plane bending method |
This document specifies the conditions for conducting the plane bending fatigue test on an axial machine, constant-amplitude, force or displacement controlled, at room temperature (ideally between 10 °C and 35 °C) on metallic specimens, without deliberately introduced stress concentrations. This document does not include the reversed/partially loading test. The purpose of the test is to provide relevant results, such as the relation between applied stress and number of cycles to failure for a given material condition, expressed by hardness and microstructure, at various stress ratios.
Although the shape, preparation and testing of specimens of rectangular and bevelled cross-section are specified, component testing and other specialized forms of testing are not included in this document.
Fatigue tests on notched specimens are not covered by this document since the shape and size of notched test pieces have not been specified in any standard so far. Guidelines are given in Annex A. However, the fatigue-test procedures described in this document can be used for testing such notched specimens.
It is possible for the results of a fatigue test to be affected by atmospheric conditions. Where controlled conditions are required, ISO 554:1976, 2.1 applies.
|
Published |
2021-06 |
Edition : 1 |
Number of pages : 18 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 22889:2007 |
Metallic materials — Method of test for the determination of resistance to stable crack extension using specimens of low constraint |
ISO 22889:2007 specifies methods for determining the resistance to stable crack extension in terms of crack opening displacement and critical crack tip opening angle for homogeneous metallic materials by the quasistatic loading of cracked specimens that exhibit low constraint to plastic deformation. Compact and middle-cracked tension specimens are notched, precracked by fatigue, and tested under slowly increasing displacement.
ISO 22889:2007 describes methods covering tests on specimens not satisfying requirements for size-insensitive fracture properties; namely, compact specimens and middle-cracked tension specimens in relatively thin gauges.
Methods are given for determining the crack extension resistance curve. Methods for determining point values of fracture toughness for the middle-cracked tension specimen are also given.
|
Withdrawn |
2007-12 |
Edition : 1 |
Number of pages : 49 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 22889:2013 |
Metallic materials — Method of test for the determination of resistance to stable crack extension using specimens of low constraint |
ISO 22889:2013 specifies methods for determining the resistance to stable crack extension in terms of crack opening displacement, δ5, and critical crack tip opening angle, ψc, for homogeneous metallic materials by the quasistatic loading of cracked specimens that exhibit low constraint to plastic deformation. Compact and middle-cracked tension specimens are notched, precracked by fatigue, and tested under slowly increasing displacement.
ISO 22889:2013 describes methods covering tests on specimens not satisfying requirements for size-insensitive fracture properties; namely, compact specimens and middle-cracked tension specimens in relatively thin gauges.
Methods are given for determining the crack extension resistance curve (R-curve). Point values of fracture toughness for compact specimens are determined according to ISO 12135. Methods for determining point values of fracture toughness for the middle-cracked tension specimen are given.
Crack extension resistance is determined using either the multiple-specimen or single-specimen method. The multiple-specimen method requires that each of several nominally identical specimens be loaded to a specified level of displacement. The extent of ductile crack extension is marked and the specimens are then broken open to allow measurement of crack extension. Single-specimen methods based on either unloading compliance or potential drop techniques can be used to measure crack extension, provided they meet specified accuracy requirements. Recommendations for single-specimen techniques are described in ISO 12135. Using either technique, the objective is to determine a sufficient number of data points to adequately describe the crack extension resistance behaviour of a material.
The measurement of δ5 is relatively simple and well established. The δ5 results are expressed in terms of a resistance curve, which has been shown to be unique within specified limits of crack extension. Beyond those limits, δ5 R-curves for compact specimens show a strong specimen dependency on specimen width, whereas the δ5 R-curves for middle-cracked tension specimens show a weak dependency.
CTOA is more difficult to determine experimentally. The critical CTOA is expressed in terms of a constant value achieved after a certain amount of crack extension. The CTOA concept has been shown to apply to very large amounts of crack extension and can be applied beyond the current limits of δ5 applications.
Both measures of crack extension resistance are suitable for structural assessment. The δ5 concept is well established and can be applied to structural integrity problems by means of simple crack driving force formulae from existing assessment procedures.
The CTOA concept is generally more accurate. Its structural application requires numerical methods, i.e. finite element analysis.
Investigations have shown a very close relation between the concept of constant CTOA and a unique R-curve for both compact and middle-cracked tension specimens up to maximum load. Further study is required to establish analytical or numerical relationships between the δ5 R-curve and the critical CTOA values.
|
Published |
2013-10 |
Edition : 2 |
Number of pages : 48 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 23296:2022 |
Metallic materials – Fatigue testing – Force controlled thermo-mechanical fatigue testing method |
This document applies to stress and/or force-controlled thermo-mechanical fatigue (TMF) testing. Both forms of control, force or stress, can be applied according to this document. This document describes the equipment, specimen preparation, and presentation of the test results in order to determine TMF properties.
|
Published |
2022-01 |
Edition : 1 |
Number of pages : 30 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 23718:2007 |
Metallic materials — Mechanical testing — Vocabulary |
ISO 23718:2007 defines the terminology that is used in mechanical testing of metals and forms a common basis for standards and general use.
|
Published |
2007-02 |
Edition : 1 |
Number of pages : 36 |
Technical Committee |
01.040.77
Metallurgy (Vocabularies)
;
77.040.10
Mechanical testing of metals
|
| ISO 23788:2012 |
Metallic materials — Verification of the alignment of fatigue testing machines |
This International Standard describes a method for verifying the alignment in a testing machine using a straingauged
measuring device. It is applicable to dynamic uniaxial tension/compression, pure torsion and combined
tension/compression plus torsion fatigue testing machines for metallic materials.
The methodology outlined in this International Standard is generic and can be applied to static testing machines
and in non-metallic materials testing.
|
Published |
2012-07 |
Edition : 1 |
Number of pages : 30 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 3310-1:2000/Cor 1:2004 |
Test sieves — Technical requirements and testing — Part 1: Test sieves of metal wire cloth — Technical Corrigendum 1 |
|
Withdrawn |
2004-09 |
Edition : 4 |
Number of pages : 2 |
Technical Committee |
19.120
Particle size analysis. Sieving
|
| ISO 23838:2022 |
Metallic materials — High strain rate torsion test at room temperature |
This document specifies terms and definitions, symbols and designations, principle, apparatus, test piece, procedure, data processing, evaluation of test result, test report and other contents for the torsion test at high strain rates for metallic materials by using torsional split Hopkinson bar (TSHB).
|
Published |
2022-06 |
Edition : 1 |
Number of pages : 36 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 24213:2008 |
Metallic materials — Sheet and strip — Method for springback evaluation in stretch bending |
ISO 24213:2008 specifies a method for evaluating the amount of springback of sheets of metallic materials known to exhibit large amounts of springback subjected to plane-strain stretch bending, which is a typical deformation mode generated in press-formed panels. By using this method, the amount of springback under stretch bending is evaluated accurately and quantitatively.
|
Withdrawn |
2008-03 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 24213:2017 |
Metallic materials — Sheet and strip — Method for springback evaluation in stretch bending |
ISO 24213:2017 specifies a method for evaluating the amount of springback of sheets of metallic materials known to exhibit large amounts of springback subjected to plane-strain stretch bending, which is a typical deformation mode generated in press-formed panels. By using this method, the amount of springback under stretch bending is evaluated accurately and quantitatively.
|
Published |
2017-07 |
Edition : 2 |
Number of pages : 11 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO/TR 25679:2005 |
Mechanical testing of metals — Symbols and definitions in published standards |
ISO/TR:25679:2005 enumerates the symbols and definitions used in International Standards for specific methods of mechanical testing of metallic materials, which are the responsibility of ISO Technical Committee 164, Mechanical testing of metals. The data is indexed alphabetically and via a coding system. Annex A provides an additional cross-reference between the coding system and relevant International Standard numbers.
|
Withdrawn |
2005-11 |
Edition : 1 |
Number of pages : 64 |
Technical Committee |
01.040.77
Metallurgy (Vocabularies)
;
77.040.10
Mechanical testing of metals
|
| ISO 26203-1:2010 |
Metallic materials — Tensile testing at high strain rates — Part 1: Elastic-bar-type systems |
The two parts of ISO 26203 specify methods for testing metallic sheet materials to determine the stress‑strain characteristics at high strain rates. ISO 26203-1:2010 covers the use of elastic-bar-type systems.
The strain-rate range between 10-3 to 103 s-1 is considered to be the most relevant to vehicle crash events based on experimental and numerical calculations such as the Finite Elemental Analysis (FEA) work for crashworthiness. In order to evaluate the crashworthiness of a vehicle with accuracy, reliable stress-strain characterization of metallic materials at strain rates higher than 10-3 s-1 is essential.
The test method in ISO 26203-1:2010 covers the strain-rate range above 102 s-1.
|
Withdrawn |
2010-02 |
Edition : 1 |
Number of pages : 32 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 26203-1:2018 |
Metallic materials — Tensile testing at high strain rates — Part 1: Elastic-bar-type systems |
ISO 26203-1:2018 specifies methods for testing metallic sheet materials to determine the stress-strain characteristics at high strain rates. This document covers the use of elastic-bar-type systems.
The strain-rate range between 10−3 and 103 s−1 is considered to be the most relevant to vehicle crash events based on experimental and numerical calculations such as the finite element analysis (FEA) work for crashworthiness.
In order to evaluate the crashworthiness of a vehicle with accuracy, reliable stress-strain characterization of metallic materials at strain rates higher than 10−3 s−1 is essential.
This test method covers the strain-rate range above 102 s−1.
NOTE 1 At strain rates lower than 10−1 s−1, a quasi-static tensile testing machine that is specified in ISO 7500‑1 and ISO 6892‑1 can be applied.
NOTE 2 This testing method is also applicable to tensile test-piece geometries other than the flat test pieces considered here.
|
Published |
2018-01 |
Edition : 2 |
Number of pages : 32 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 26203-2:2011 |
Metallic materials — Tensile testing at high strain rates — Part 2: Servo-hydraulic and other test systems |
ISO 26203-2:2011 gives requirements for the testing of metallic materials. Only examples for testing flat geometries are given; however, other geometries can be tested. The area of application spans a range of strain rates from 10-2 s-1 to 103 s-1. Tests are carried out between 10 °C and 35 °C and, unless otherwise specified, using a servo-hydraulic-type test system.
|
Published |
2011-10 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 28080:2021 |
Hardmetals — Abrasion tests for hardmetals |
This document specifies a generic test method to determine the abrasion wear characteristics of hardmetals.
The test is appropriate for use in situations where test laboratories have a need to simulate abrasive damage. The procedure includes information which enables the test to be used in a variety of different conditions:
a) with counterface wheels of different stiffness (for example steel and rubber);
b) wet and dry;
c) different abrasive sizes;
d) different chemical environments.
|
Published |
2021-02 |
Edition : 2 |
Number of pages : 13 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 26843:2015 |
Metallic materials — Measurement of fracture toughness at impact loading rates using precracked Charpy-type test pieces |
ISO 26843:205 specifies requirements for performing and evaluating instrumented precracked Charpy impact tests on metallic materials using a fracture mechanics approach. Minimum requirements are given for measurement and recording equipment such that similar sensitivity and comparable measurements are achieved.
Dynamic fracture mechanics properties determined using this International Standard are comparable with conventional large-scale fracture mechanics results when the corresponding validity criteria are met. Because of the small absolute size of the Charpy specimen, this is often not the case. Nevertheless, the values obtained can be used in research and development of materials, in quality control, and to establish the variation of properties with test temperature under impact loading rates.
Fracture toughness properties determined through the use of this International Standard may differ from values measured at quasistatic loading rates. Indeed, an increase in loading rate causes a decrease in fracture toughness when tests are performed in the brittle or ductile-to-brittle regimes; the opposite is observed (i.e. increase in fracture toughness) in the fully ductile regime. More information on the dependence of fracture toughness on loading (or strain) rate is given in Reference [1]. In addition, it is generally acknowledged that fracture toughness also depends on test temperature. For these reasons, the user is required to report the actual test temperature and loading rate for each test performed.
In case of cleavage fracture of ferritic steels in the ductile-to-brittle transition region, variability can be very large and cannot be adequately described by simple statistics. In this case, additional tests are required and the analysis is to be performed using a statistical procedure applicable to this type of test, see for example Reference [2].
NOTE Modifications to the analytical procedures prescribed in Reference [2] might be necessary to account for the effect of elevated (impact) loading rates.
|
Published |
2015-12 |
Edition : 1 |
Number of pages : 35 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 27306:2009 |
Metallic materials — Method of constraint loss correction of CTOD fracture toughness for fracture assessment of steel components |
ISO 27306:2009 specifies a method for converting the CTOD (Crack-Tip Opening Displacement) fracture toughness obtained from laboratory specimens to an equivalent CTOD for structural components, taking constraint loss into account. This method can also apply to fracture toughness assessment using the stress intensity factor or the J-integral concept.
ISO 27306:2009 deals with the unstable fracture that occurs from a crack-like defect or fatigue crack in ferritic structural steels. Unstable fracture accompanied by a significant amount of ductile crack extension and ductile fractures is not included in the scope hereof.
ISO 27306:2009 can be used for eliminating the excessive conservatism frequently associated with the conventional fracture mechanics methods and accurately assessing the unstable fracture initiation limit of structural components from the fracture toughness of the structural steel. This is also used for rationally determining the fracture toughness of materials to meet the design requirements of deformability of structural components.
|
Withdrawn |
2009-05 |
Edition : 1 |
Number of pages : 55 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 27306:2016 |
Metallic materials — Method of constraint loss correction of CTOD fracture toughness for fracture assessment of steel components |
In fracture assessments of steel structures containing cracks, it has generally been assumed that the fracture resistance of fracture toughness specimens is equal to the fracture resistance of structural components. However, such an assumption often leads to excessively conservative fracture assessments. This is due to a loss of plastic constraint in structural components, which are subjected mainly to tensile loading. By contrast, fracture toughness specimens hold a constrained stress state near the crack-tip due to bending mode. The loss of constraint is significant for high strength steels with high yield-to-tensile ratios (= yield stress/tensile strength) which have been extensively developed and widely applied to structures in recent years.
ISO 27306:2016 specifies a method for converting the CTOD (crack-tip opening displacement) fracture toughness obtained from laboratory specimens to an equivalent CTOD for structural components, taking constraint loss into account. This method can also apply to fracture assessment using the stress intensity factor or the J-integral concept (see Clause 9).
ISO 27306:2016 deals with the unstable fracture that occurs from a crack-like defect or fatigue crack in ferritic structural steels. Unstable fracture accompanied by a significant amount of ductile crack extension and ductile fractures are not included in the scope hereof.
The CTOD fracture toughness of structural steels is measured in accordance with the established test methods, ISO 12135[1] or BS 7448-1. The fracture assessment of a cracked component is done using an established method such as FAD (Failure Assessment Diagram) in the organization concerned, and reference is not made to the details thereof in ISO 27306:2016.
It can be used for eliminating the excessive conservatism frequently associated with the conventional fracture mechanics methods and accurately assessing the unstable fracture initiation limit of structural components from the fracture toughness of the structural steel. This is also used for rationally determining the fracture toughness of materials to meet the design requirements of performance of structural components.
|
Published |
2016-09 |
Edition : 2 |
Number of pages : 49 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| ISO 28079:2009 |
Hardmetals — Palmqvist toughness test |
ISO 28079:2009 specifies a method for measuring the Palmqvist toughness of hardmetals and cermets at room temperature by an indentation method. ISO 28079:2009 applies to a measurement of toughness, called Palmqvist toughness, calculated from the total length of cracks emanating from the corners of a Vickers hardness indentation, and it is intended for use with metal-bonded carbides and carbonitrides (normally called hardmetals, cermets or cemented carbides). The test procedures proposed in ISO 28079:2009 are intended for use at ambient temperatures, but can be extended to higher or lower temperatures by agreement. The test procedures proposed in ISO 28079:2009 are also intended for use in a normal laboratory-air environment. They are not intended for use in corrosive environments, such as strong acids or seawater.
|
Published |
2009-07 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 28080:2011 |
Hardmetals — Abrasion tests for hardmetals |
ISO 28080:2011 specifies a generic test method to determine the abrasion wear characteristics of hardmetals.
The procedure complements the ASTM G65 method for dry sand/rubber wheel abrasion, the ASTM B611 method for abrasive wear resistance of cemented carbides, and the ASTM G105 method for conducting wet sand/rubber wheel abrasion tests.
The test is appropriate for use in situations where test laboratories have a need to simulate abrasive damage. The procedure includes information which enables the test to be used in a variety of different conditions:
with counterface wheels of different stiffness (for example steel and rubber);
wet and dry;
different abrasive sizes;
different chemical environments.
|
Withdrawn |
2011-02 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
77.160
Powder metallurgy
;
77.040.10
Mechanical testing of metals
|
| ISO 3058:1998 |
Non-destructive testing — Aids to visual inspection — Selection of low-power magnifiers |
|
Published |
1998-03 |
Edition : 2 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TR 29381:2008 |
Metallic materials — Measurement of mechanical properties by an instrumented indentation test — Indentation tensile properties |
ISO/TR 29381:2008 describes methods for evaluating tensile properties of metallic materials (true stress-strain curve and derived parameters) using an instrumented indentation test.
The ranges of application of instrumented indentation tests are in line with the classification of ISO 14577-1:2002, but the range of force recommended is from 2 N to 3 kN.
ISO/TR 29381:2008 includes the following three methods, all of which are sound in principle, are capable of practical use and are appropriate for the specified materials.
Method 1: representative stress and strain;
Method 2: inverse analysis by FEA;
Method 3: neural networks.
In every method, tensile curves are derived from the experimentally measured indentation force-depth curve, from which indentation tensile properties are evaluated. The three methods described all need different user strategies and abilities to obtain the indentation tensile properties. The information required differs for each method, and is described in detail.
The main assumption in the three methods is the absence of residual stress within the test piece. Existing residual stress can affect the estimation of indentation tensile properties. A procedure for evaluating residual stress using an instrumented indentation test is given for reference.
|
Published |
2008-10 |
Edition : 1 |
Number of pages : 29 |
Technical Committee |
77.040.10
Mechanical testing of metals
|
| IEC 61340-4-4:2005 |
Electrostatics — Part 4-4: Standard test methods for specific applications - Electrostatic classification of flexible intermediate bulk containers (FIBC) |
Describes procedures for evaluating the ignition risk presented by electrostatic discharges from FIBC to flammable or explosive environments.
The requirements of this standard are applicable to all types of FIBC, tested as manufactured, prior to usage, intended for use without liners in flammable or explosive environments with minimum ignition energy of more than 0,14 mJ, and where the charging currents do not exceed 3,0 A.
NOTE - 0,14 mJ is the minimum ignition energy normally quoted for methanol. Although more sensitive materials exist, methanol has the lowest minimum ignition energy of any material that is likely to be present when FIBC are emptied. 3,0 uA is the highest charging current likely to be found in common industrial processes. This combination of minimum ignition energy and charging current represents the most severe conditions that might be expected in practice.
Compliance with the requirements of this standard does not mitigate the need for full risk assessment.
The test methods included in this standard may be used in association with other performance requirements, for example when a risk assessment has shown the minimum ignition energy of concern is less than 0,14 mJ or charging currents greater than 3,0 uA are present.
|
Withdrawn |
2005-10 |
Edition : 1 |
Number of pages : 42 |
Technical Committee |
19.080
Electrical and electronic testing
;
55.180.99
Other standards related to freight distribution of goods
|
| ISO/TTA 3:2001 |
Polycrystalline materials — Determination of residual stresses by neutron diffraction |
|
Withdrawn |
2001-09 |
Edition : 1 |
Number of pages : 48 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TTA 4:2002 |
Measurement of thermal conductivity of thin films on silicon substrates |
TTA 4:2002 proposes a standard procedure for the three-omega method for measuring the thermal conductivity of a thin, electrically insulating film, on a substrate having a thermal conductivity significantly greater than the thermal conductivity of the film.This method is applicable to a film on a silicon substrate with the following characteristics:
a) the film is electrically insulating;
b) the film has a thermal conductivity that is less than one tenth the thermal conductivity of silicon;
c) the film is uniform in thickness and the thickness lies in the range 0,25 to 1 micrometres.
d) the maximum dimensions of the film are limited by the sizes of the preparation and measurement apparatus;
e) the minimum dimensions of the film are limited by the minimum size of the circuit element that can be placed on the film surface.
NOTE A specimen approximately 15 mm by 25 mm is of an appropriate size although specimens as small as 10 mm by 10 mm are usable.
The method is directly applicable to films of silicon dioxide on silicon wafer substrates.
The method may be applicable to insulating films on other high-thermal conductivity substrates provided that the parameters of the substrate material are substituted for the parameters of silicon used in this method and the associated computer program.
The method is applicable to measurements near room temperature.
|
Withdrawn |
2002-11 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 1027:1983 |
Radiographic image quality indicators for non-destructive testing — Principles and identification |
The detection of an imperfection in a product subjected to X or gamma radiography depends on the quality of the resultant radiograph. This quality should be checked with an image quality indicator. This International Standard is intended for general application on all metals. However, for particular materials (for example, aluminium and its alloys) complementary International Standards may be used.
|
Withdrawn |
1983-10 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3057:1974 |
Non-destructive testing — Metallographic replica techniques of surface examination |
|
Withdrawn |
1974-04 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3057:1998 |
Non-destructive testing — Metallographic replica techniques of surface examination |
|
Published |
1998-03 |
Edition : 2 |
Number of pages : 2 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3058:1974 |
Non-destructive testing — Aids to visual inspection — Selection of low-power magnifiers |
|
Withdrawn |
1974-04 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3059:1974 |
Non-destructive testing — Method for indirect assessment of black light sources |
Specifies a procedure for assessing the output of black light lamps used in fluorescent magnetic particle and penetrant flaw detection techniques. Applies to both new lamps and lamps in service. May also be used for checking that specified levels of black light illumination are achieved and maintained. A control test for checking the fluorescence of penetrant liqids is specified in Annex A.
|
Withdrawn |
1974-06 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3059:2001 |
Non-destructive testing — Penetrant testing and magnetic particle testing - Viewing conditions |
|
Withdrawn |
2001-11 |
Edition : 2 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3059:2012 |
Non-destructive testing — Penetrant testing and magnetic particle testing — Viewing conditions |
ISO 3059:2012 specifies the control of the viewing conditions for magnetic particle and penetrant testing. It includes minimum requirements for the illuminance and UV-A irradiance and their measurement. It is intended for use when the human eye is the primary detection aid.
ISO 3059:2012 does not cover the use of actinic blue light sources.
|
Published |
2012-12 |
Edition : 3 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-1:2008 |
Non-destructive testing — Penetrant testing — Part 1: General principles |
ISO 3452-1:2008 defines a method of penetrant testing used to detect discontinuities, e.g. cracks, laps, folds, porosity and lack of fusion, which are open to the surface of the material to be tested. It is mainly applied to metallic materials, but can also be performed on other materials, provided that they are inert to the test media and they are not excessively porous, examples of which are castings, forgings, welds, ceramics, etc.
ISO 3452-1:2008 is not intended to be used for acceptance criteria and gives no information relating to the suitability of individual test systems for specific applications nor requirements for test equipment.
The term 'discontinuity' is used here in the sense that no evaluation concerning acceptability or non-acceptability is included.
Methods for determining and monitoring the essential properties of penetrant testing products to be used are specified in ISO 3452-2 and ISO 3452-3.
|
Withdrawn |
2008-09 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-1:2013 |
Non-destructive testing — Penetrant testing — Part 1: General principles |
ISO 3452-1:2013 specifies a method of penetrant testing used to detect discontinuities, e.g. cracks, laps, folds, porosity and lack of fusion, which are open to the surface of the material to be tested. It is mainly applied to metallic materials, but can also be performed on other materials, provided that they are inert to the test media and not excessively porous (castings, forgings, welds, ceramics, etc.)
It also includes requirements for process and control testing, but is not intended to be used for acceptance criteria and gives neither information relating to the suitability of individual test systems for specific applications nor requirements for test equipment.
|
Withdrawn |
2013-06 |
Edition : 2 |
Number of pages : 22 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-1:2021 |
Non-destructive testing — Penetrant testing — Part 1: General principles |
This document specifies a method of penetrant testing used to detect discontinuities, e.g. cracks, laps, folds, porosity and lack of fusion, which are open to the surface of the material to be tested using white light or UV-A (365 nm) radiation. It is mainly applied to metallic materials, but can also be performed on other materials, provided that they are inert to the test media and not excessively porous (castings, forgings, welds, ceramics, etc.)
This document also includes requirements for process and control testing, but is not intended to be used for acceptance criteria. It gives neither information relating to the suitability of individual test systems for specific applications nor requirements for test equipment.
NOTE 1 Methods for determining and monitoring the essential properties of penetrant testing products to be used are specified in ISO 3452-2 and ISO 3452-3.
NOTE 2 The term "discontinuity" is used in this document in the sense that no evaluation concerning acceptability or non-acceptability is included.
NOTE 3 CEN/TR 16638 addresses penetrant testing using actinic blue light.
|
Published |
2021-05 |
Edition : 3 |
Number of pages : 23 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-2:2000 |
Non-destructive testing — Penetrant testing — Part 2: Testing of penetrant materials |
|
Withdrawn |
2000-04 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-2:2006 |
Non-destructive testing — Penetrant testing — Part 2: Testing of penetrant materials |
SO 3452-2:2006 specifies the technical requirements and test procedures for penetrant materials for their type testing and batch testing. It also details on-site control tests and methods.
|
Withdrawn |
2006-08 |
Edition : 2 |
Number of pages : 32 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-2:2013 |
Non-destructive testing — Penetrant testing — Part 2: Testing of penetrant materials |
ISO 3452-2:2013 specifies the technical requirements and test procedures for penetrant materials for their type testing and batch testing. ISO 3452-2:2013 covers the temperature range 10 °C to 50 °C. Additional tests in ISO 3452-5:2008 or ISO 3452-6:2008 may be required outside this range.
On-site control tests and methods are detailed in ISO 3452‑1:2013.
|
Withdrawn |
2013-11 |
Edition : 3 |
Number of pages : 24 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-2:2021 |
Non-destructive testing — Penetrant testing — Part 2: Testing of penetrant materials |
This document specifies the technical requirements and test procedures for penetrant materials for their type testing and batch testing. This document covers the temperature range from 10 °C to 50 °C. Additional tests in ISO 3452-5 or ISO 3452-6 can be required outside this range.
On-site control tests and methods are detailed in ISO 3452‑1.
|
Published |
2021-05 |
Edition : 4 |
Number of pages : 24 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-3:1998 |
Non-destructive testing — Penetrant testing — Part 3: Reference test blocks |
|
Withdrawn |
1998-12 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-3:1998/Cor 1:2001 |
Non-destructive testing — Penetrant testing — Part 3: Reference test blocks — Technical Corrigendum 1: . |
|
Withdrawn |
2001-02 |
Edition : 1 |
|
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-3:2013 |
Non-destructive testing — Penetrant testing — Part 3: Reference test blocks |
ISO 3452-3:2013 describes two types of reference blocks: Type 1 reference blocks are used to determine the sensitivity levels of both fluorescent and colour contrast penetrant product families; Type 2 reference blocks are used for routine assessment of the performance of both fluorescent and colour contrast penetrant testing.
The reference blocks are to be used in accordance with ISO 3452-1:2013.
|
Published |
2013-11 |
Edition : 2 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-4:1998 |
Non-destructive testing — Penetrant testing — Part 4: Equipment |
|
Published |
1998-12 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-5:2008 |
Non-destructive testing — Penetrant testing — Part 5: Penetrant testing at temperatures higher than 50 degrees C |
ISO 3452-5:2008 specifies the requirements for non-destructive testing using penetrant, particular to applications at higher temperatures (higher than 50 °C) as well as the method for qualification of suitable testing products.
|
Published |
2008-12 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452-6:2008 |
Non-destructive testing — Penetrant testing — Part 6: Penetrant testing at temperatures lower than 10 degrees C |
ISO 3452-6:2008 specifies the requirements for non-destructive testing using penetrant, particular to applications at low temperatures (lower than + 10 °C) as well as the method for qualification of suitable testing products.
|
Published |
2008-12 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3452:1984 |
Non-destructive testing — Penetrant inspection — General principles |
Applies to penetrant inspection on materials and components both during manufacture and in service. Does not deal with levels of acceptance or rejection. Penetrant inspection is used to locate laps, folds, cracks, porosity and fissures, which are open to the surface of a material or component. It can be used with materials irrespective of their physical properties.
|
Withdrawn |
1984-09 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3453:1984 |
Non-destructive testing — Liquid penetrant inspection — Means of verification |
These tests are intended to ensure that the penetrant system works correctly and that there has been no harmful deterioration of the process materials during service. Generally, the frequency of checking penetrant materials and black light sources will depend on the frequency and conditions of usage. Specific and maximum intervals should be recommended by the manufacturer.
|
Withdrawn |
1984-12 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3999-1:2000 |
Radiation protection — Apparatus for industrial gamma radiography — Part 1: Specifications for performance, design and tests |
|
Withdrawn |
2000-04 |
Edition : 1 |
Number of pages : 31 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3999:1977 |
Apparatus for gamma radiography — Specification |
Specifies the constructional requirements of portable, mobile and fixed apparatus for industrial radiography of category I (sealed source not removed for exposure) and II (sealed source projected out of the container by an operator at a distance). Operational usage of exposure containers is not covered. As the transport of apparatus is concerned, the requirements of the relevant transport regulations have also to be satisfied.
|
Withdrawn |
1977-09 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9934-2:2002 |
Non-destructive testing — Magnetic particle testing — Part 2: Detection media |
ISO 9934-2 specifies the significant properties of magnetic particle testing products (including magnetic ink, powder, carrier liquid, contrast aid paints) and the methods for checking their properties.
This document failed to convert
|
Withdrawn |
2002-12 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 3999:2004 |
Radiation protection — Apparatus for industrial gamma radiography — Specifications for performance, design and tests |
ISO 3999:2004 specifies the performance, design and test requirements of apparatus for gamma radiography with portable, mobile and fixed exposure containers of the various categories defined in Clause 4.
It applies to apparatus designed to allow the controlled use of gamma radiation emitted by a sealed radioactive source for industrial radiography purposes, in order that persons will be safeguarded when the apparatus is used in conformity with the regulations in force regarding radiation protection.
It is emphasised, however, that so far as transport of apparatus and sealed radioactive source is concerned, compliance with ISO 3999:2004 is no substitute for satisfying the requirements of relevant international transport regulations (IAEA Regulations for the safe transport of radioactive materials: IAEA-STI-PUB 998, Safety Standards Series ST-1 and ST-2, and/or the relevant national transport regulations).
The operational use of apparatus for industrial gamma radiography is not covered by ISO 3999:2004. Users of this equipment shall comply with national regulations and codes of practice.
|
Published |
2004-12 |
Edition : 2 |
Number of pages : 32 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/DIS 4773 |
Non-destructive testing — Ultrasonic guided wave testing using the phased array technique |
|
Under development |
|
Edition : 1 |
Number of pages : 16 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 5576:1997 |
Non-destructive testing — Industrial X-ray and gamma-ray radiology — Vocabulary |
|
Published |
1997-08 |
Edition : 1 |
Number of pages : 35 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 5577:2000 |
Non-destructive testing — Ultrasonic inspection — Vocabulary |
|
Withdrawn |
2000-05 |
Edition : 1 |
Number of pages : 45 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 5577:2017 |
Non-destructive testing — Ultrasonic testing — Vocabulary |
ISO 5577:2017 defines the terms used in ultrasonic non-destructive testing and forms a common basis for standards and general use. This document does not cover terms used in ultrasonic testing with phased arrays.
NOTE Terms for phased array ultrasonic testing are defined in EN 16018.
|
Published |
2017-02 |
Edition : 2 |
Number of pages : 38 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 5580:1985 |
Non-destructive testing — Industrial radiographic illuminators — Minimum requirements |
The function of illuminators is to allow the viewing of radiographs. The illuminator system shall guarantee the same safety of personnel as an electric apparatus concerning maximum voltage, insulation and earthing.
|
Published |
1985-03 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/DIS 5580 |
Non-destructive testing — Industrial radiographic illuminators — Minimum requirements |
The function of illuminators is to allow the viewing of radiographs. The illuminator system shall guarantee the same safety of personnel as an electric apparatus concerning maximum voltage, insulation and earthing.
|
Under development |
|
Edition : 2 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 5655:1982 |
Photography — Film for industrial radiography — Sizes, quantity packaging and labelling |
|
Withdrawn |
1982-12 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
;
37.040.20
Photographic paper, films and plates. Cartridges
|
| ISO/DIS 5735-1 |
Railway infrastructures — Non-destructive testing on rails in track — Part 1: Requirements for ultrasonic inspection and evaluation principles |
|
Under development |
|
Edition : 1 |
Number of pages : 53 |
Technical Committee |
19.100
Non-destructive testing
;
45.080
Rails and railway components
|
| ISO 9712:1992 |
Non-destructive testing — Qualification and certification of personnel |
|
Withdrawn |
1992-05 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9712:1999 |
Non-destructive testing — Qualification and certification of personnel |
|
Withdrawn |
1999-05 |
Edition : 2 |
Number of pages : 22 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9934-2:2015 |
Non-destructive testing — Magnetic particle testing — Part 2: Detection media |
ISO 9934-2:2015 specifies the significant properties of magnetic particle testing products (including magnetic ink, powder, carrier liquid, contrast aid paints) and the methods for checking their properties.
|
Published |
2015-09 |
Edition : 2 |
Number of pages : 21 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9712:2005 |
Non-destructive testing — Qualification and certification of personnel |
ISO 9712:2005 specifies the qualification and certification of personnel involved in non-destructive testing (NDT). It is applicable to proficiency in one or more of the following methods: acoustic emission testing; eddy current testing; infrared thermographic testing; leak testing (hydraulic pressure tests excluded); magnetic particle testing; penetrant testing; radiographic testing; strain testing; ultrasonic testing; visual testing (direct unaided visual tests and visual tests carried out during the application of another NDT method are excluded).
|
Withdrawn |
2005-02 |
Edition : 3 |
Number of pages : 25 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9712:2005/Cor 1:2006 |
Non-destructive testing — Qualification and certification of personnel — Technical Corrigendum 1 |
|
Withdrawn |
2006-11 |
Edition : 3 |
Number of pages : 1 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9712:2012 |
Non-destructive testing — Qualification and certification of NDT personnel |
This International Standard specifies requirements for principles for the qualification and certification of personnel who perform industrial non-destructive testing (NDT).
The system specified in this International Standard can also apply to other NDT methods or to new techniques within an established NDT method, provided a comprehensive scheme of certification exists and the method or technique is covered by International, regional or national standards or the new NDT method or technique has been demonstrated to be effective to the satisfaction of the certification body.
The certification covers proficiency in one or more of the following methods: a) acoustic emission testing; b) eddy current testing; c) infrared thermographic testing; d) leak testing (hydraulic pressure tests excluded); e) magnetic testing; f) penetrant testing; g) radiographic testing; h) strain gauge testing; i) ultrasonic testing; j) visual testing (direct unaided visual tests and visual tests carried out during the application of another NDT method are excluded).
|
Withdrawn |
2012-06 |
Edition : 4 |
Number of pages : 31 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9712:2021 |
Non-destructive testing — Qualification and certification of NDT personnel |
This document specifies requirements for the qualification and certification of personnel who perform industrial non-destructive testing (NDT) in the following methods.
a) acoustic emission testing;
b) eddy current testing;
c) leak testing (hydraulic pressure tests excluded);
d) magnetic testing;
e) penetrant testing;
f) radiographic testing;
g) strain gauge testing;
h) thermographic testing;
i) ultrasonic testing;
j) visual testing (direct unaided visual tests and visual tests carried out during the application of another NDT method are excluded).
The system specified in this document is also applicable to other NDT methods or to NDT techniques within an established NDT method, provided a comprehensive scheme of certification exists and the NDT method or NDT technique is covered by international, regional or national standards or the NDT method or the NDT technique has been demonstrated to be effective to the satisfaction of the certification body.
NOTE 1 The term "industrial" implies the exclusion of applications in the field of medicine.
NOTE 2 CEN/TR 14748 provides guidance on the methodology for qualification of non-destructive tests.
NOTE 3 This document specifies requirements for what are, in effect, third party conformity assessment schemes. These requirements do not directly apply to conformity assessment by second or first parties, but relevant parts of this document can be referred to in such arrangements.
NOTE 4 The term “direct unaided visual testing” implies where there is an uninterrupted optical path from the observer’s eye to the test area and the observer uses no tools or devices (e.g. mirror, endoscope, fibre optic).
NOTE 5 Calculations of strain based on other NDT methods are excluded.
|
Published |
2021-12 |
Edition : 5 |
Number of pages : 42 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 9934-1:2001 |
Non-destructive testing — Magnetic particle testing — Part 1: General principles |
|
Withdrawn |
2001-12 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9934-1:2015 |
Non-destructive testing — Magnetic particle testing — Part 1: General principles |
ISO 9934-1:2015 specifies general principles for the magnetic particle testing of ferromagnetic materials. Magnetic particle testing is primarily applicable to the detection of surface-breaking discontinuities, particularly cracks. It can also detect discontinuities just below the surface but its sensitivity diminishes rapidly with depth.
This part of ISO 9934 specifies the surface preparation of the part to be tested, magnetization techniques, requirements and application of the detection media, and the recording and interpretation of results. Acceptance criteria are not defined. Additional requirements for the magnetic particle testing of particular items are defined in product standards (see the relevant ISO or EN standards).
This part of ISO 9934 does not apply to the residual magnetization method.
|
Withdrawn |
2015-09 |
Edition : 2 |
Number of pages : 16 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9934-1:2016 |
Non-destructive testing — Magnetic particle testing — Part 1: General principles |
ISO 9934-1:2016 specifies general principles for the magnetic particle testing of ferromagnetic materials. Magnetic particle testing is primarily applicable to the detection of surface-breaking discontinuities, particularly cracks. It can also detect discontinuities just below the surface but its sensitivity diminishes rapidly with depth.
ISO 9934-1:2016 specifies the surface preparation of the part to be tested, magnetization techniques, requirements and application of the detection media, and the recording and interpretation of results. Acceptance criteria are not defined. Additional requirements for the magnetic particle testing of particular items are defined in product standards (see the relevant International Standards or European standards).
ISO 9934-1:2016 does not apply to the residual magnetization method.
|
Published |
2016-12 |
Edition : 3 |
Number of pages : 17 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9934-3:2015 |
Non-destructive testing — Magnetic particle testing — Part 3: Equipment |
ISO 9934-3:2015 describes three types of equipment for magnetic particle testing:
- portable or transportable equipment;
- fixed installations;
- specialized testing systems for testing components on a continuous basis, comprising a series of processing stations placed in sequence to form a process line.
Equipment for magnetizing, demagnetizing, illumination, measurement, and monitoring are also described.
This part of ISO 9934 specifies the properties to be provided by the equipment supplier, minimum requirements for application and the method of measuring certain parameters. Where appropriate, measuring and calibration requirements and in-service checks are also specified.
|
Published |
2015-09 |
Edition : 2 |
Number of pages : 12 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 9935:1992 |
Non-destructive testing — Penetrant flaw detectors — General technical requirements |
Specifies general requirements, requirements for functional units for surface examination, for functional units for control of UV radiation, and safety requirements. Annex A describes a designation system for penetrant flaw detectors.
|
Withdrawn |
1992-10 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 10375:1997 |
Non-destructive testing — Ultrasonic inspection — Characterization of search unit and sound field |
|
Withdrawn |
1997-04 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 10878:2013 |
Non-destructive testing — Infrared thermography — Vocabulary |
ISO 10878:2013 defines terms used in infrared thermography for non-destructive testing and forms a common basis for standard general use.
|
Published |
2013-11 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 10880:2017 |
Non-destructive testing — Infrared thermographic testing — General principles |
ISO 10880:2017 provides general principles for infrared thermographic testing in the field of industrial non-destructive testing (NDT).
|
Published |
2017-02 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 11537:1998 |
Non-destructive testing — Thermal neutron radiographic testing — General principles and basic rules |
|
Withdrawn |
1998-07 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 11774:2011 |
Non-destructive testing — Performance-based qualification |
ISO/TS 11774:2011 provides a method for qualification of non-destructive testing (NDT) personnel, procedures, and equipment for specific non-destructive tests conducted in accordance with documented procedures established within a performance-based qualification programme.
Implementation of ISO/TS 11774:2011 requires cooperation between applicable industry sector committees (ISCs) and qualification bodies to ensure that specific performance expectations are addressed.
The qualification methodology described in ISO/TS 11774:2011 is based upon the ability of a candidate to demonstrate capability in detecting and sizing critical discontinuities equivalent to those to be detected and sized in the performance-based qualification programme as established by the ISC.
It is possible that second party (employer-based) qualification and approval (e.g. in accordance with ANSI/ASNT CP-189) or qualification and third party certification (e.g. in accordance with ISO 9712 or EN 473), followed by on-the-job training does not provide the required degree of confidence for safety critical inspections, and ISO/TS 11774:2011 provides criteria to assist in preparing an individual for performance-based qualification examinations.
Qualification to ISO/TS 11774:2011 is limited to the specific applications, using the specific documented procedure in the performance-based qualification programme.
|
Published |
2011-11 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 12706:2000 |
Non-destructive testing — Terminology - Terms used in penetrant testing |
|
Withdrawn |
2000-11 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 12706:2009 |
Non-destructive testing — Penetrant testing — Vocabulary |
ISO 12706:2009 defines technical terms relating to penetrant testing.
In addition to terms used in English and French, two of the three official ISO languages, ISO 12706:2009 gives the equivalent terms in German; these are published under the responsibility of the member body for Germany (DIN), and are given for information only. Only the terms and definitions given in the official languages can be considered as ISO terms and definitions.
|
Published |
2009-10 |
Edition : 2 |
Number of pages : 10 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 12707:2016 |
Non-destructive testing — Magnetic particle testing — Vocabulary |
ISO 12707:2016 defines general terms specifically associated with magnetic particle testing.
|
Published |
2016-03 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 12710:2002 |
Non-destructive testing — Ultrasonic inspection — Evaluating electronic characteristics of ultrasonic test instruments |
ISO 12710 describes a set of procedures for the measurement of any performances in an ultrasonic test instrument that has a display screen.
This International Standard establishes the procedures for measuring performance characteristics of components of pulse-echo ultrasonic non-destructive testing instruments including both analog and digital type instruments with screen displays. The aim is to establish uniformity of evaluation techniques, to form a basis for data correlation and for interpretation of results obtained from different laboratories and at different times. Note that ISO 12710 establishes no acceptance criteria; such criteria should be specified by user parties.
The usual components of ultrasonic non-destructive testing instruments and the performance characteristics for which procedures for measuring these characteristics are described including:
line regulation; battery discharge time; battery charge time; pulse shape; pulse amplitude; pulse rise time; pulse length; pulse frequency spectrum; vertical linearity; frequency response; noise and sensitivity; dB controls; horizontal linearity; clock (pulse repetition rate); delay and width; resolution; alarm level; gain uniformity; analog output; back-echo gate linearity.
|
Withdrawn |
2002-09 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 12713:1998 |
Non-destructive testing — Acoustic emission inspection — Primary calibration of transducers |
|
Published |
1998-07 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 12714:1999 |
Non-destructive testing — Acoustic emission inspection — Secondary calibration of acoustic emission sensors |
This International Standard specifies a method for the secondary calibration of acoustic emission sensors as
receivers of elastic waves at the surface of a solid medium. The International Standard is applicable to laboratory
tertiary standard sensors and acoustic emission applications sensors.
The secondary calibration yields the frequency response of a sensor to waves of a type normally encountered in
acoustic emission work, namely Rayleigh waves. The source producing the signal used for the calibration is
mounted on the same surface of a test block as the sensor under test (SUT). The sensitivity of the sensor is
determined for excitation within the range of 100 kHz to 1 MHz. Sensitivity values are usually determined at
frequencies approximately 10 kHz apart. The units of the calibration are volts per unit of mechanical input
(displacement, velocity or acceleration).
|
Published |
1999-07 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 12715:1999 |
Ultrasonic non-destructive testing — Reference blocks and test procedures for the characterization of contact search unit beam profiles |
|
Withdrawn |
1999-09 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 12715:2014 |
Non-destructive testing — Ultrasonic testing — Reference blocks and test procedures for the characterization of contact probe sound beams |
ISO 12715:2014 introduces two metal reference blocks, the hemicylindrical-stepped (HS) block and the side-drilled-hole (SDH) block. ISO 12715:2014 establishes procedures for measuring the sound beam profiles generated by probes in contact with the test object. The probes include straight-beam, angle-beam (refracted compressional and refracted shear wave), focused beam, and dual-element probes. The side dimension of the probe has to be no greater than 25 mm.
The methodology of ISO 12715:2014 provides guidelines for probes to be used for different metals including forged or rolled steel, aluminium, or titanium alloy products. The frequency range of the probes used in ISO 12715:2014 extends from 1 MHz to 15 MHz, where 1 MHz to 5 MHz is best suited for steels and 5 MHz to 15 MHz is best for fine grain structured alloys such as aluminium products.
|
Withdrawn |
2014-06 |
Edition : 2 |
Number of pages : 24 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 12716:2001 |
Non-destructive testing — Acoustic emission inspection — Vocabulary |
This International Standard defines the terminology that is used in acoustic emission inspection and forms a
common basis for standards and general use.
|
Published |
2001-06 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 12718:2008 |
Non-destructive testing — Eddy current testing — Vocabulary |
ISO 12718:2008 defines terms used in eddy current testing.
In addition to terms used in English and French, two of the three official ISO languages, this document gives the equivalent terms in German; these are published under the responsibility of the member body for Germany (DIN), and are given for information only. Only the terms and definitions given in the official languages can be considered as ISO terms and definitions.
|
Withdrawn |
2008-08 |
Edition : 1 |
Number of pages : 41 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 12718:2019 |
Non-destructive testing — Eddy current testing — Vocabulary |
This document defines terms used in eddy current testing.
|
Published |
2019-07 |
Edition : 2 |
Number of pages : 39 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO/CD 16946 |
Non-destructive testing — Ultrasonic testing — Specification for step wedge calibration block |
ISO 16946:2017 specifies the dimensions, material, and manufacture of a step wedge steel block for the calibration of ultrasonic instruments.
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Under development |
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Edition : 3 |
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Technical Committee |
19.100
Non-destructive testing
|
| ISO 12721:2000 |
Non-destructive testing — Thermal neutron radiographic testing — Determination of beam L/D ratio |
This International Standard defines an empirical technique for the measurement of the effective collimation ratio
and effective L/D of thermal neutron radiography beams for values between 20 and 1 000. The technique is based
upon analysis of a neutron radiographic image and is independent of measurements and calculations based on
physical dimensions of the collimator system. The device described in this International Standard has been
developed and tested using Gd foil converters with a single emulsion, high resolution film in vacuum cassettes.
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Published |
2000-04 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TR 13115:2011 |
Non-destructive testing — Methods for absolute calibration of acoustic emission transducers by the reciprocity technique |
ISO/TR 13115:2011 describes the method of three-transducer calibration for calibrating frequency responses of absolute sensitivity by means of a reciprocity technique using three reversible acoustic emission transducers of the same kind, the method of two-transducer calibration for calibrating frequency responses of reception sensitivity of an optional acoustic emission transducer by using one acoustic emission transducer, the transmission responses of which have been calibrated by three-transducer calibration, the method for impulse response calibration for calibrating impulse responses of absolute sensitivity through inverse Fourier transform of the frequency responses measured by the three-transducer calibration, and the method for representing the calibration results.
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Published |
2011-12 |
Edition : 1 |
Number of pages : 18 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15548-1:2008 |
Non-destructive testing — Equipment for eddy current examination — Part 1: Instrument characteristics and verification |
ISO 15548-1:2008 identifies the functional characteristics of a general-purpose eddy current instrument and provides methods for their measurement and verification.
The evaluation of these characteristics permits a well-defined description and comparability of eddy current equipment.
By careful choice of the characteristics, a consistent and effective eddy current examination system can be designed for a specific application.
Where accessories are used, these are characterised using the principles of ISO 15548-1:2008.
ISO 15548-1:2008 gives neither the extent of verification nor acceptance criteria for the characteristics. They are given in the application documents.
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Withdrawn |
2008-09 |
Edition : 1 |
Number of pages : 29 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15548-1:2008/Cor 1:2010 |
Non-destructive testing — Equipment for eddy current examination — Part 1: Instrument characteristics and verification — Technical Corrigendum 1 |
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Withdrawn |
2010-03 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15548-1:2013 |
Non-destructive testing — Equipment for eddy current examination — Part 1: Instrument characteristics and verification |
ISO 15548-1:2013 identifies the functional characteristics of a general-purpose eddy current instrument and provides methods for their measurement and verification.
The evaluation of these characteristics permits a well-defined description and comparability of eddy current equipment.
By careful choice of the characteristics, a consistent and effective eddy current examination system can be designed for a specific application.
Where accessories are used, these are characterized using the principles of ISO 15548-1:2013.
ISO 15548-1:2013 gives neither the extent of verification nor acceptance criteria for the characteristics. They are given in the application documents.
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Published |
2013-12 |
Edition : 2 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15548-2:2008 |
Non-destructive testing — Equipment for eddy current examination — Part 2: Probe characteristics and verification |
ISO 15548-2:2008 identifies the functional characteristics of a probe and its interconnecting elements and provides methods for their measurement and verification.
The evaluation of these characteristics permits a well-defined description and comparability of eddy current equipment.
By careful choice of the characteristics, a consistent and effective eddy current examination system can be designed for a specific application.
Where accessories are used, these should be characterised using the principles of ISO 15548-2:2008.
ISO 15548-2:2008 does not give the extent of verification nor acceptance criteria for the characteristics. These are given in the application documents.
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Withdrawn |
2008-09 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15548-2:2013 |
Non-destructive testing — Equipment for eddy current examination — Part 2: Probe characteristics and verification |
ISO 15548-2:2013 identifies the functional characteristics of a probe and its interconnecting elements and provides methods for their measurement and verification.
The evaluation of these characteristics permits a well-defined description and comparability of eddy current equipment.
By careful choice of the characteristics, a consistent and effective eddy current examination system can be designed for a specific application.
Where accessories are used, these should be characterised using the principles of ISO 15548-2:2013.
ISO 15548-2:2013 does not give the extent of verification nor acceptance criteria for the characteristics. These are given in the application documents.
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Published |
2013-12 |
Edition : 2 |
Number of pages : 27 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-2:2013 |
Non-destructive testing — Image quality of radiographs — Part 2: Determination of the image quality value using step/hole-type image quality indicators |
ISO 19232-2:2013 specifies a device and a method for the determination of the image quality of radiographs using step/hole-type image quality indicators.
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Published |
2013-06 |
Edition : 2 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
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