| Name |
Description |
Abstract |
Status |
Publication date |
Edition |
Number of pages |
Technical committee |
ICS |
| ISO 15548-3:2008 |
Non-destructive testing — Equipment for eddy current examination — Part 3: System characteristics and verification |
ISO 15548-3:2008 identifies the functional characteristics of a general-purpose eddy current system and provides methods for their measurement and verification.
The evaluation of these characteristics permits a well-defined description and comparability of an 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 15548-3:2008.
ISO 15548-3:2008 does not give the extent of verification nor acceptance criteria for the characteristics. These are given in the application documents.
|
Published |
2008-09 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15549:2008 |
Non-destructive testing — Eddy current testing — General principles |
ISO 15549:2008 defines the general principles to be applied to non-destructive eddy current examination of products and materials in order to ensure defined and repeatable performance.
It includes guidelines for the preparation of application documents which describe the specific requirements for the application of the eddy current method to a particular type of product.
|
Withdrawn |
2008-08 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15549:2019 |
Non-destructive testing — Eddy current testing — General principles |
This document defines the general principles to be applied to non-destructive eddy current examination of products and materials in order to ensure defined and repeatable performance.
It includes guidelines for the preparation of application documents which describe the specific requirements for the application of the eddy current method to a particular type of product.
|
Published |
2019-04 |
Edition : 2 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15708-1:2002 |
Non-destructive testing — Radiation methods — Computed tomography — Part 1: Principles |
ISO 15708-1 provides a tutorial introduction to the theory and use of computed tomography. It begins with an overview intended for the interested reader possessing a general technical background. Subsequent, more technical clauses describe the physical and mathematical basis of CT technology, the hardware and software requirements of CT equipment, and the fundamental measures of CT performance.
This part of ISO 15708 includes an extensive glossary (with discussions) of CT terminology and an extensive list of references to more technical publications on the subject. Most importantly, this part of ISO 15708 establishes consensus definitions for basic measures of CT performance, enabling purchasers and suppliers of CT systems and services to communicate unambiguously with reference to a recognized standard. It also provides a few carefully selected equations relating measures of CT performance to key system parameters.
ISO 15708-1 gives guidelines for, and defines terms for addressing the general principles of X-ray CT as they apply to industrial imaging. It also gives guidelines for a consistent set of CT performance parameter definitions, including how these performance parameters relate to CT system specifications.
|
Withdrawn |
2002-06 |
Edition : 1 |
Number of pages : 64 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15708-1:2017 |
Non-destructive testing — Radiation methods for computed tomography — Part 1: Terminology |
ISO 15708-1:2017 gives the definitions of terms used in the field of computed tomography (CT). It presents a terminology that is not only CT-specific but which also includes other more generic terms and definitions spanning imaging and radiography. Some of the definitions represent discussion points aimed at refocusing their terms in the specific context of computed tomography.
|
Published |
2017-02 |
Edition : 2 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15708-2:2002 |
Non-destructive testing — Radiation methods — Computed tomography — Part 2: Examination practices |
ISO 15708-2 describes CT procedures that can provide for non-destructive testing and evaluation. Requirements in this part of ISO 15708 are intended to control the reliability and quality of the CT images. This part of ISO 15708 is applicable for the systematic assessment of the internal structure of a material or assembly and may be used to prescribe operating CT procedures. It also provides a basis for the formation of a programme for quality control and its continuation through calibration, standardization, reference samples, inspection plans and procedures.
ISO 15708-2 gives guidelines for procedures for performing CT examinations. It is intended to address the general use of CT technology and thereby facilitate its use. This part of ISO 15708 implicitly assumes the use of penetrating radiation, specifically X-ray and gamma-ray.
|
Withdrawn |
2002-07 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15708-2:2017 |
Non-destructive testing — Radiation methods for computed tomography — Part 2: Principles, equipment and samples |
ISO 15708-2:2017 specifies the general principles of X-ray computed tomography (CT), the equipment used and basic considerations of sample, materials and geometry.
It is applicable to industrial imaging (i.e. non-medical applications) and gives a consistent set of CT performance parameter definitions, including how those performance parameters relate to CT system specifications.
ISO 15708-2:2017 deals with computed axial tomography and excludes other types of tomography such as translational tomography and tomosynthesis.
|
Published |
2017-02 |
Edition : 2 |
Number of pages : 17 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 11699-2:2018 |
Non-destructive testing — Industrial radiographic films — Part 2: Control of film processing by means of reference values |
This document specifies a procedure for the control of film processing systems.
|
Published |
2018-08 |
Edition : 2 |
Number of pages : 10 |
Technical Committee |
37.040.25
Radiographic films
|
| ISO 15708-3:2017 |
Non-destructive testing — Radiation methods for computed tomography — Part 3: Operation and interpretation |
ISO 15708-3:2017 presents an outline of the operation of a computed tomography (CT) system and the interpretation of results with the aim of providing the operator with technical information to enable the selection of suitable parameters.
It is applicable to industrial imaging (i.e. non-medical applications) and gives a consistent set of CT performance parameter definitions, including how those performance parameters relate to CT system specifications.
ISO 15708-3:2017 deals with computed axial tomography and excludes other types of tomography such as translational tomography and tomosynthesis.
|
Published |
2017-02 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 15708-4:2017 |
Non-destructive testing — Radiation methods for computed tomography — Part 4: Qualification |
ISO 15708-4:2017 specifies guidelines for the qualification of the performance of a CT system with respect to various inspection tasks.
It is applicable to industrial imaging (i.e. non-medical applications) and gives a consistent set of CT performance parameter definitions, including how those performance parameters relate to CT system specifications.
ISO 15708-4:2017 deals with computed axial tomography and excludes other types of tomography such as translational tomography and tomosynthesis.
|
Published |
2017-02 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16371-1:2011 |
Non-destructive testing — Industrial computed radiography with storage phosphor imaging plates — Part 1: Classification of systems |
ISO 16371-1:2011 specifies fundamental parameters of computed radiography systems with the aim of enabling satisfactory and repeatable results to be obtained economically. The techniques are based both on fundamental theory and test measurements. ISO 16371-1:2011 specifies the performance of computed radiography (CR) systems and the measurement of the corresponding parameters for the system scanner and storage phosphor imaging plate (IP). It describes the classification of these systems in combination with specified metal screens for industrial radiography. It is intended to ensure that the quality of images, as far as this is influenced by the scanner-IP system, is in conformity with the requirements of ISO 16371-2. ISO 16371-1:2011 relates to the requirements of film radiography defined in ISO 11699-1.
ISO 16371-1:2011 defines system tests at different levels. More complicated tests are described, which allow the determination of exact system parameters. They can be used to classify the systems of different suppliers and make them comparable for users. These tests are specified as manufacturer tests. Some of them require special tools, which are usually not available in user laboratories. Therefore, simpler user tests are also described, which are designed for a fast test of the quality of CR systems and long term stability.
There are several factors affecting the quality of a CR image including geometrical un-sharpness, signal/noise ratio, scatter and contrast sensitivity. There are several additional factors (e.g. scanning parameters), which affect the accurate reading of images on exposed IPs using an optical scanner.
The quality factors can be determined most accurately by the manufacturer tests as described in ISO 16371-1:2011. Individual test targets, which are recommended for practical user tests, are described for quality assurance. These tests can be carried out either separately or by the use of the CR Phantom (Annex B). This CR Phantom incorporates many of the basic quality assessment methods and those associated with the correct functioning of a CR system, including the scanner, for reading exposed plates and in correctly erasing IPs for future use of each plate.
The CR System classes in ISO 16371-1:2011 do not refer to any particular manufacturer's Imaging Plates. A CR system class results from the use of a particular imaging plate together with the exposure conditions (particularly total exposure), the scanner type and the scanning parameters.
|
Published |
2011-10 |
Edition : 1 |
Number of pages : 25 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16371-2:2017 |
Non-destructive testing — Industrial computed radiography with storage phosphor imaging plates — Part 2: General principles for testing of metallic materials using X-rays and gamma rays |
ISO 16371-2:2017 specifies fundamental techniques of computed radiography with the aim of enabling satisfactory and repeatable results to be obtained economically. The techniques are based on the fundamental theory of the subject and tests measurements. ISO 16371-2:2017 specifies the general rules for industrial computed X-rays and gamma radiography for flaw detection purposes, using storage phosphor imaging plates (IP). It is based on the general principles for radiographic examination of metallic materials on the basis of films, as specified in ISO 5579. The basic set-up of radiation source, detector and the corresponding geometry are intended to be applied in accordance with ISO 5579 and corresponding product standards such as ISO 17636 for welding and EN 12681 for foundry.
ISO 16371-2:2017 does not lay down acceptance criteria of the imperfections. Computed radiography (CR) systems provide a digital grey value image which can be viewed and evaluated on basis of a computer only. This practice describes the recommended procedure for detector selection and radiographic practice. Selection of computer, software, monitor, printer and viewing conditions are important but not the main focus of ISO 16371-2:2017.
The procedure it specifies provides the minimum requirements and practice to permit the exposure and acquisition of digital radiographs with a sensitivity of imperfection detection equivalent to film radiography and as specified in ISO 5579. Some application standards, e.g. EN 16407, can require different and less stringent practice conditions.
|
Published |
2017-09 |
Edition : 1 |
Number of pages : 31 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16526-1:2011 |
Non-destructive testing — Measurement and evaluation of the X-ray tube voltage — Part 1: Voltage divider method |
ISO 16526-1:2011 specifies a method for the direct and absolute measurement of the average high voltage of constant potential (DC) X-ray systems on the secondary side of the high voltage generator. The intention is to check the correspondence with the indicated high voltage value on the control unit of the X-ray system.
This method is applied to assure a reproducible operation of X-ray systems because the voltage influences particularly the penetration of materials and the contrast of X-ray images and also the requirements concerning the radiation protection.
|
Published |
2011-12 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16827:2012 |
Non-destructive testing — Ultrasonic testing — Characterization and sizing of discontinuities |
ISO 16827:2012 specifies the general principles and techniques for the characterization and sizing of previously detected discontinuities in order to ensure their evaluation against applicable acceptance criteria. It is applicable, in general terms, to discontinuities in those materials and applications covered by ISO 16810.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 52 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 7963:1985 |
Welds in steel — Calibration block No. 2 for ultrasonic examination of welds |
Lays down the dimensions, type of steel and directives for the use of block No. 2 for the calibration of ultrasonic equipment for the examination of welds in steel. Covers material, preparation and method of use.
|
Withdrawn |
1985-09 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 16526-2:2011 |
Non-destructive testing — Measurement and evaluation of the X-ray tube voltage — Part 2: Constancy check by the thick filter method |
ISO 16526-2:2011 specifies a constancy check of a X-ray system where mainly the X-ray voltage is checked and also the tube current and the constitution of the target which can be changing due to ageing of the tube.
The thick filter method is based on a measurement of the dose rate behind a defined thick filter using defined distances between the X-ray tube, the filter and the measuring device.
This method is very sensitive to changes of the voltage, but it does not provide an absolute value for the X-ray tube voltage. Therefore, a reference value is needed and, it is recommended to find this reference, for example, within the acceptance test of the system.
The thick filter method is a rather simple technique and may be applied by the operator of an X-ray system to perform regularly a constancy check of the system.
The method can also be applied for consistency checks after changing components which may affect the X-ray tube voltage.
This method can be applied for all types of X-ray systems, i. e. for constant potential, half wave and impulse wave generators with a tube current larger than 1 mA.
|
Published |
2011-12 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16526-3:2011 |
Non-destructive testing — Measurement and evaluation of the X-ray tube voltage — Part 3: Spectrometric method |
ISO 16526-3:2011 specifies the test method for a non-invasive measurement of X-ray tube voltages using the energy spectrum of X-rays (spectrometric method). It covers the voltage range from 10 kV to 500 kV.
The intention is to check the correspondence of the actual voltage with the indicated value on the control panel of the X-ray unit. It is intended to measure the maximum energy only and not the complete X-ray spectrum.
The procedure is applicable for tank type and constant potential X-ray units.
|
Published |
2011-12 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16809:2012 |
Non-destructive testing — Ultrasonic thickness measurement |
ISO 16809:2012 specifies the principles for ultrasonic thickness measurement of metallic and non-metallic materials by direct contact, based on measurement of time-of-flight of ultrasonic pulses only.
|
Withdrawn |
2012-11 |
Edition : 1 |
Number of pages : 32 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16809:2017 |
Non-destructive testing — Ultrasonic thickness measurement |
ISO 16809:2017 specifies the principles for ultrasonic thickness measurement of metallic and non-metallic materials by direct contact, based on measurement of time of flight of ultrasonic pulses only.
|
Published |
2017-11 |
Edition : 2 |
Number of pages : 37 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16810:2012 |
Non-destructive testing — Ultrasonic testing — General principles |
ISO 16810:2012 defines the general principles required for the ultrasonic examination of industrial products that permit the transmission of ultrasound.
The specific conditions of application and use of ultrasonic examination, which depend on the type of product examined, are described in documents which could include: a) product standards; b) specifications; c) codes; d) contractual documents; e) written procedures.
Unless otherwise specified in the referencing documents the minimum requirements of ISO 16810:2012 are applicable.
ISO 16810:2012 does not define: 1) extent of examination and scanning plans; 2) acceptance criteria.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16811:2012 |
Non-destructive testing — Ultrasonic testing — Sensitivity and range setting |
ISO 16811:2012 specifies the general rules for setting the timebase range and sensitivity (i.e. gain adjustment) of a manually operated ultrasonic flaw detector with A-scan display in order that reproducible measurements may be made of the location and echo height of a reflector.
ISO 16811:2012 is applicable to techniques employing a single contact probe with either a single or twin transducers, but excludes the immersion technique and techniques employing more than one probe.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 38 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16823:2012 |
Non-destructive testing — Ultrasonic testing — Transmission technique |
ISO 16823:2012 specifies the principles of transmission techniques.
Transmission techniques can be used for: a) detection of imperfections; b) determination of attenuation.
The general principles required for the use of ultrasonic examination of industrial products are described in ISO 16810.
The transmission technique is used for examination of flat products, e.g. plates and sheets.
Further, it is used for examinations e.g.: 1) where the shape, dimensions or orientation of possible imperfections are unfavourable for direct reflection; 2) in materials with high attenuation; 3) in thin products.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16826:2012 |
Non-destructive testing — Ultrasonic testing — Examination for discontinuities perpendicular to the surface |
ISO 16826:2012 defines the principles for tandem‑ and longitudinal-longitudinal-transverse (LLT) wave‑examination for the detection of discontinuities perpendicular to the surface.
The general principles required for the ultrasonic examination of industrial products are described in ISO 16810. A list of symbols and equations is given in ISO 16811.
The tandem‑ or LLT‑examination should be used for the detection of planar discontinuities with distance to the surface greater than 15 mm. ISO 16826:2012 has been prepared for the examination of metallic materials with a thickness between 40 mm and 500 mm with parallel or concentric surfaces. It can, however, be used for other materials and smaller thickness provided special measures are taken.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16828:2012 |
Non-destructive testing — Ultrasonic testing — Time-of-flight diffraction technique as a method for detection and sizing of discontinuities |
ISO 16828:2012 defines the general principles for the application of the time-of-flight diffraction (TOFD) technique for both detection and sizing of discontinuities in low alloyed carbon steel components. It can also be used for other types of materials, provided the application of the TOFD technique is performed with necessary consideration of geometry, acoustical properties of the materials, and the sensitivity of the examination.
Although it is applicable, in general terms, to discontinuities in materials and applications covered by ISO 16810, it contains references to the application on welds. This approach has been chosen for reasons of clarity as to the ultrasonic probe positions and directions of scanning.
Unless otherwise specified in the referencing documents, the minimum requirements of ISO 16828:2012 are applicable.
Unless explicitly stated otherwise, ISO 16828:2012 is applicable to the following product classes as defined in ISO 16811: a) class 1, without restrictions; b) classes 2 and 3, restrictions apply as stated in Clause 9.
The inspection of products of classes 4 and 5 requires special procedures. These are also addressed in Clause 9.
Techniques for the use of TOFD for weld inspection are described in ISO 10863.
The related acceptance criteria are given in ISO 15626.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 16829:2017 |
Non-destructive testing — Automated ultrasonic testing — Selection and application of systems |
The information in ISO/TS 16829:2017 covers all kinds of ultrasonic testing on components or complete manufactured structures for either correctness of geometry, for material properties (quality or defects), and for fabrication methodology (e.g. weld testing).
ISO/TS 16829:2017 enables the user, along with a customer specification, or a given test procedure or any standard or regulation to select:
- ultrasonic probes, probe systems and controlling sensors;
- manipulation systems including controls;
- electronic sub-systems for the transmission and reception of ultrasound;
- systems for data storage and display;
- systems and methods for evaluation and assessment of test results.
With regard to their performance, ISO/TS 16829:2017 also describes procedures for the verification of the performance of the selected test system.
This includes
- tests during the manufacturing process of products (stationary testing systems), and
- tests with mobile systems.
|
Published |
2017-10 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16831:2012 |
Non-destructive testing — Ultrasonic testing — Characterization and verification of ultrasonic thickness measuring equipment |
ISO 16831:2012 specifies methods and acceptance criteria for assessing the performance of instruments for measuring thickness using pulse-echo ultrasound.
ISO 16831:2012 covers both direct (digital) reading and waveform display types using single or dual element probes.
ISO 16831:2012 can be used for verifying equipment covered by EN 12668 when used for thickness measurement.
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16836:2019 |
Non-destructive testing — Acoustic emission testing — Measurement method for acoustic emission signals in concrete |
This document establishes a measurement method for acoustic emission signals in concrete.
|
Published |
2019-01 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
;
91.080.40
Concrete structures
|
| ISO 16837:2019 |
Non-destructive testing — Acoustic emission testing — Test method for damage qualification of reinforced concrete beams |
This document specifies a test for damage qualification of reinforced concrete beams in services as bridges, docks and buildings.
|
Published |
2019-01 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
;
91.080.40
Concrete structures
|
| ISO 16838:2019 |
Non-destructive testing — Acoustic emission testing — Test method for classification of active cracks in concrete structures |
The following documents are referred to in the text in such a way that some or all of their content constitutes requirements of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 12713, Non-destructive testing — Acoustic emission inspection — Primary calibration of transducers
ISO 12714, Non-destructive testing — Acoustic emission inspection — Secondary calibration of acoustic emission sensors
ISO 12716, Non-destructive testing — Acoustic emission inspection — Vocabulary
ISO/TR 13115, Non-destructive testing — Methods for absolute calibration of acoustic emission transducers by the reciprocity technique
|
Published |
2019-01 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
;
91.080.40
Concrete structures
|
| ISO 16946:2015 |
Non-destructive testing — Ultrasonic testing — Specification for step wedge calibration block |
ISO 16946:2015 specifies the dimensions, material, and manufacture of a step wedge steel block for the calibration of ultrasonic instruments.
|
Withdrawn |
2015-04 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 16946:2017 |
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.
|
Published |
2017-03 |
Edition : 2 |
Number of pages : 4 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 17405:2014 |
Non-destructive testing — Ultrasonic testing — Technique of testing claddings produced by welding, rolling and explosion |
ISO 17405:2014 specifies the techniques for manual ultrasonic testing of claddings on steel applied by welding, rolling, and explosion using single-element or dual-element probes. The test is intended to cover detection of two-dimensional or three-dimensional discontinuities in the cladding and in the region of the interface.
ISO 17405:2014 does not give acceptance criteria nor define the extent of testing.
|
Withdrawn |
2014-07 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 17405:2022 |
Non-destructive testing — Ultrasonic testing — Technique of testing claddings produced by welding, rolling and explosion |
This document specifies the techniques for manual ultrasonic testing of claddings on steel applied by welding, rolling and explosion using single-transducer or dual-transducer probes.
The test is intended to cover detection of two-dimensional or three-dimensional discontinuities in the cladding and in the region of the interface.
This document does not give acceptance criteria nor define the extent of testing.
|
Published |
2022-04 |
Edition : 2 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18081:2016 |
Non-destructive testing — Acoustic emission testing (AT) — Leak detection by means of acoustic emission |
ISO 18081:2016 specifies the general principles required for leak detection by acoustic emission testing (AT). It is addressed to the application of the methodology on structures and components, where a leak flow as a result of pressure differences appears and generates acoustic emission (AE).
It describes phenomena of the AE generation and influence of the nature of fluids, shape of the gap, wave propagation and environment.
The different application methods, instrumentation and presentation of AE results is discussed. Also included are guidelines for the preparation of application documents which describe specific requirements for the application of the AE method.
Different application examples are given.
Unless otherwise specified in the referencing documents, the minimum requirements of this International Standard are applicable.
|
Published |
2016-06 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/CD 18081 |
Non-destructive testing — Acoustic emission testing (AT) — Leak detection by means of acoustic emission |
ISO 18081:2016 specifies the general principles required for leak detection by acoustic emission testing (AT). It is addressed to the application of the methodology on structures and components, where a leak flow as a result of pressure differences appears and generates acoustic emission (AE).
It describes phenomena of the AE generation and influence of the nature of fluids, shape of the gap, wave propagation and environment.
The different application methods, instrumentation and presentation of AE results is discussed. Also included are guidelines for the preparation of application documents which describe specific requirements for the application of the AE method.
Different application examples are given.
Unless otherwise specified in the referencing documents, the minimum requirements of this International Standard are applicable.
|
Under development |
|
Edition : 2 |
|
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 18173:2005 |
Non-destructive testing — General terms and definitions |
ISO/TS 18173:2005 defines the general technical terms that are used in many non-destructive testing disciplines.
|
Published |
2005-01 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 18175:2004 |
Non-destructive testing — Evaluating performance characteristics of ultrasonic pulse-echo testing systems without the use of electronic measurement instruments |
ISO 18175:2004 describes procedures for evaluating the following performance characteristics of ultrasonic pulse-echo examination instruments:
horizontal limit and linearity;
vertical limit and linearity;
resolution-entry surface and far surface;
sensitivity and noise;
accuracy of calibrated gain controls.
ISO 18175:2004 may be used for the evaluation of a complete examination system, including transducer, instrument, interconnections, fixtures and connected alarm and auxiliary devices, primarily in cases where such a system is used repeatedly without change or substitution. This International Standard is not intended to be used as a substitute for calibration of a system to inspect any given material.
|
Withdrawn |
2004-03 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18211:2016 |
Non-destructive testing — Long-range inspection of above-ground pipelines and plant piping using guided wave testing with axial propagation |
ISO 18211:2016 specifies a method for long-range testing of carbon and low-alloy steel above-ground pipelines and plant piping using guided ultrasonic waves with axial propagation applied on the entire circumferential pipe section, in order to detect corrosion or erosion damage.
The guided wave testing (GWT) method allows for fast inspection of above-ground pipelines, plant piping and cased road crossings, giving a qualitative screening and localization of probable corroded and eroded areas. GWT is typically performed on operating piping systems.
ISO 18211:2016 is applicable to the following types of pipes:
a) above-ground painted pipelines;
b) above-ground insulated pipelines;
c) painted plant piping;
d) insulated plant piping.
NOTE Pipe sections within road crossings with external casings (without bitumen or plastic coating) are a special case of buried pipe where there is no soil pressure on the OD of the pipe. ISO 18211 :2016 applies to these cased road crossings.
Other types of pipes not included in the above list need dedicated approaches due to increased complexity.
|
Published |
2016-07 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18249:2015 |
Non-destructive testing — Acoustic emission testing — Specific methodology and general evaluation criteria for testing of fibre-reinforced polymers |
ISO 18249:2015 describes the general principles of acoustic emission testing (AT) of materials, components, and structures made of fibre-reinforced polymers (FRP) with the aim of
- materials characterization,
- proof testing and manufacturing quality control,
- retesting and in-service testing, and
- health monitoring.
This International Standard has been designed to describe specific methodology to assess the integrity of fibre-reinforced polymers (FRP), components, or structures or to identify critical zones of high damage accumulation or damage growth under load (e.g. suitable instrumentation, typical sensor arrangements, and location procedures).
It also describes available, generally applicable evaluation criteria for AT of FRP and outlines procedures for establishing such evaluation criteria in case they are lacking.
ISO 18249:2015 also presents formats for the presentation of acoustic emission test data that allows the application of qualitative evaluation criteria, both online during testing and by post-test analysis, and that simplify comparison of acoustic emission test results obtained from different test sites and organizations.
NOTE The structural significance of the acoustic emission cannot in all cases definitely be assessed based on AT evaluation criteria only but can require further testing and assessment (e.g. with other non-destructive test methods or fracture mechanics calculations).
|
Published |
2015-05 |
Edition : 1 |
Number of pages : 20 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18251-1:2017 |
Non-destructive testing — Infrared thermography — Part 1: Characteristics of system and equipment |
ISO 18251-1:2017 describes the main components, and their characteristics, constituting an infrared (IR) imaging system and related equipment used in non-destructive testing (NDT). It also aims to assist the user in the selection of an appropriate system for a particular measurement task.
The following items are specified:
- objective lens;
- detector;
- image processor;
- display;
- thermal stimulation source;
- accessories.
|
Published |
2017-02 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18251-2:2023 |
Non-destructive testing — Infrared thermography — Part 2: Test method for integrated performance of system and equipment |
This document specifies a test method for integrated performance parameters specified in ISO 18251-1 of an infrared (IR) imaging system and related equipment used in non-destructive testing (NDT). It also aims to assist the user in the selection of an appropriate system for a particular testing task.
|
Published |
2023-02 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18490:2015 |
Non-destructive testing — Evaluation of vision acuity of NDT personnel |
ISO 18490:2015 specifies the form of the optotype, the quality requirements for the chart, the test procedure, and the acceptance level for near vision acuity of NDT personnel. It also addresses the qualification requirements for personnel permitted to carry out the test.
ISO 18490:2015 only addresses near vision acuity under defined conditions similar to those encountered during routine NDT inspection. It does not address an individual's overall visual acuity and users are advised to consider the need for a general eye examination by specialist medical personnel to ensure general vision acuity is appropriate for job function.
ISO 18490:2015 does not address colour vision requirements.
|
Published |
2015-06 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 18563-1:2015 |
Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 1: Instruments |
ISO 18563-1:2015 identifies the functional characteristics of a multichannel ultrasonic phased array instrument used for phased array probes and provides methods for their measurement and verification.
ISO 18563-1:2015 can partly be applicable to ultrasonic phased array instruments in automated systems, but then, other tests might be needed to ensure satisfactory performance. When the phased array instrument is a part of an automated system, the acceptance criteria can be modified by agreement between the parties involved.
ISO 18563-1:2015 gives the extent of the verification and defines acceptance criteria within a frequency range of 0,5 MHz to 10 MHz.
The evaluation of these characteristics permits a well-defined description of the ultrasonic phased array instrument and comparability of instruments.
|
Withdrawn |
2015-06 |
Edition : 1 |
Number of pages : 39 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18563-1:2022 |
Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 1: Instruments |
This document specifies the functional characteristics of multi-channel ultrasonic phased array instruments used for array probes and provides methods for their measurement and verification.
This document is also applicable to ultrasonic phased array instruments in automated systems; but other tests can be needed to ensure satisfactory performance. When the phased array instrument is a part of an automated system, the acceptance criteria can be modified by agreement between the parties involved.
This document also can partly be applicable to FMC instruments and TFM instruments.
This document gives the extent of the verification and defines acceptance criteria within a frequency range of 0,5 MHz to 10 MHz.
|
Published |
2022-08 |
Edition : 2 |
Number of pages : 47 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 7963:2006 |
Non-destructive testing — Ultrasonic testing —- Specification for calibration block No. 2 |
ISO7963:2005 specifies the dimensions, material, manufacture and methods of use for calibration block No. 2 for calibrating and checking ultrasonic testing equipment
|
Withdrawn |
2006-09 |
Edition : 2 |
Number of pages : 9 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 18563-2:2017 |
Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 2: Probes |
ISO 18563-2:2017 specifies the characterization tests performed at the end of the fabrication of a phased array probe. It defines both methodology and acceptance criteria.
ISO 18563-2:2017 is applicable to the following phased array probes used for ultrasonic non-destructive testing in contact technique (with or without a wedge) or in immersion technique, with centre frequencies in the range 0,5 MHz to 10 MHz:
a) non-matrix array probes:
- linear;
- encircling;
- partial annular sectorial (type "daisy");
b) 2D-matrix array probes.
ISO 18563-2:2017 does not give methods and acceptance criteria to characterize the performance of an ultrasonic phased array instrument or the performance of a combined system. These are given in ISO 18563?1 and in ISO 18563?3.
|
Published |
2017-07 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 18563-3:2015 |
Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 3: Combined systems |
ISO 18563-3:2015 addresses ultrasonic test systems implementing linear phased array probes, in contact (with or without wedge) or in immersion, with centre frequencies in the range of 0,5 MHz?10 MHz.
It provides methods and acceptance criteria for verifying the performance of combined equipment (i.e. instrument, probe and cables connected). The methods described are suitable for users working under on-site or shop floor conditions. Its purpose is for the verification of the correct operation of the system prior to testing, and also the characterization of sound beams or verification of the absence of degradation of the system.
The methods are not intended to prove the suitability of the system for particular applications, but are intended to prove the capability of the combined equipment to generate ultrasonic beams according to the settings used.
The calibration of the system for a specific application is outside of the scope of part of ISO 18563 and it is intended that it be covered by the test procedure.
ISO 18563-3:2015 does not address the following:
- encircling arrays;
- series of apertures having a different number of elements;
- different settings for transmitting and receiving (e.g. active aperture, number of active elements, delays);
- techniques using post-processing of the signals of individual elements in a more complex manner than a simple delay law (e.g. full matrix capture).
|
Published |
2015-12 |
Edition : 1 |
Number of pages : 34 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/DIS 18563-3 |
Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 3: Complete systems |
ISO 18563-3:2015 addresses ultrasonic test systems implementing linear phased array probes, in contact (with or without wedge) or in immersion, with centre frequencies in the range of 0,5 MHz?10 MHz.
It provides methods and acceptance criteria for verifying the performance of combined equipment (i.e. instrument, probe and cables connected). The methods described are suitable for users working under on-site or shop floor conditions. Its purpose is for the verification of the correct operation of the system prior to testing, and also the characterization of sound beams or verification of the absence of degradation of the system.
The methods are not intended to prove the suitability of the system for particular applications, but are intended to prove the capability of the combined equipment to generate ultrasonic beams according to the settings used.
The calibration of the system for a specific application is outside of the scope of part of ISO 18563 and it is intended that it be covered by the test procedure.
ISO 18563-3:2015 does not address the following:
- encircling arrays;
- series of apertures having a different number of elements;
- different settings for transmitting and receiving (e.g. active aperture, number of active elements, delays);
- techniques using post-processing of the signals of individual elements in a more complex manner than a simple delay law (e.g. full matrix capture).
|
Under development |
|
Edition : 2 |
Number of pages : 34 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-1:2004 |
Non-destructive testing — Image quality of radiographs — Part 1: Image quality indicators (wire type) — Determination of image quality value |
ISO 19232-1:2004 specifies a device and a method for the determination of the image quality of radiographs using wire type image quality indicators.
|
Withdrawn |
2004-07 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-1:2004/Cor 1:2007 |
Non-destructive testing — Image quality of radiographs — Part 1: Image quality indicators (wire type) — Determination of image quality value — Technical Corrigendum 1 |
|
Withdrawn |
2007-07 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-1:2013 |
Non-destructive testing — Image quality of radiographs — Part 1: Determination of the image quality value using wire-type image quality indicators |
ISO 19232-1:2013 specifies a device and a method for the determination of the image quality of radiographs using wire-type image quality indicators.
|
Published |
2013-06 |
Edition : 2 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-2:2004 |
Non-destructive testing — Image quality of radiographs — Part 2: Image quality indicators (step/hole type) — Determination of image quality value |
ISO 19232-2:2004 specifies a device and a method for the determination of the image quality of radiographs using step/hole type image quality indicators.
|
Withdrawn |
2004-07 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-2:2004/Cor 1:2007 |
Non-destructive testing — Image quality of radiographs — Part 2: Image quality indicators (step/hole type) — Determination of image quality value — Technical Corrigendum 1 |
|
Withdrawn |
2007-07 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-3:2004 |
Non-destructive testing — Image quality of radiographs — Part 3: Image quality classes for ferrous metals |
ISO 19232-3:2004 specifies the minimum image quality values to ensure a uniform radiographic quality. It applies to the two types of image quality indicator as detailed in ISO 19232-1 for wire type image quality indicators and ISO 19232-2 for step/hole type image quality indicators as well as for the two techniques described in ISO 5579. Values are specified for both the basic and improved radiographic techniques specified in ISO 5579 and for ferrous metals.
|
Withdrawn |
2004-07 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-3:2013 |
Non-destructive testing — Image quality of radiographs — Part 3: Image quality classes |
ISO 19232-3:2013 specifies the minimum image quality values to ensure a uniform radiographic quality. It applies to the two types of image quality indicator as detailed in ISO 19232-1 for wire-type IQI and ISO 19232-2 for step/hole-type IQI and for the two techniques described in ISO 5579. Values are specified for the two classes of radiographic technique specified in ISO 5579.
|
Published |
2013-06 |
Edition : 2 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-4:2004 |
Non-destructive testing — Image quality of radiographs — Part 4: Experimental evaluation of image quality values and image quality tables |
ISO 19232-4:2004 gives instructions for the determination of image quality values and image quality tables used in radiographic testing.
|
Withdrawn |
2004-07 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-4:2013 |
Non-destructive testing — Image quality of radiographs — Part 4: Experimental evaluation of image quality values and image quality tables |
ISO 19232-4:2013 gives instructions for the determination of image quality values and image quality tables.
If the IQI requirements specified in ISO 19232‑3 cannot be used because, for example, the absorption coefficients of the IQI material and the inspected material differ by more than 30 %, test exposures are necessary to determine acceptance of image quality values. The image quality values achieved by the test exposures are required for all exposures made under the same radiographic conditions.
|
Published |
2013-06 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-5:2004 |
Non-destructive testing — Image quality of radiographs — Part 5: Image quality indicators (duplex wire type) — Determination of image unsharpness value |
ISO 19232-5:2004 specifies a method of determining the image unsharpness of radiographs and realtime radioscopic systems.
|
Withdrawn |
2004-07 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-5:2013 |
Non-destructive testing — Image quality of radiographs — Part 5: Determination of the image unsharpness value using duplex wire-type image quality indicators |
ISO 19232-5:2013 specifies a method of determining the total image unsharpness of radiographs and real-time radioscopic systems.
|
Withdrawn |
2013-06 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19232-5:2018 |
Non-destructive testing — Image quality of radiographs — Part 5: Determination of the image unsharpness and basic spatial resolution value using duplex wire-type image quality indicators |
This document specifies a method of determining the total image unsharpness and basic spatial resolution of radiographs and radioscopic images. The IQI with up to 13 wire pairs can be used effectively with tube voltages up to 600 kV. The IQI with more than 13 wire pairs can be used effectively at tube voltages lower than 225 kV. When using source voltages in the megavolt range, it is possible that the results are not be completely satisfactory.
|
Published |
2018-08 |
Edition : 3 |
Number of pages : 11 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19675:2017 |
Non-destructive testing — Ultrasonic testing — Specification for a calibration block for phased array testing (PAUT) |
ISO 19675:2017 specifies requirements for the dimensions, material and manufacture of a steel block for calibrating ultrasonic test equipment used in ultrasonic testing with the phased array technique.
|
Published |
2017-01 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 19835:2018 |
Non-destructive testing — Acoustic emission testing — Steel structures of overhead travelling cranes and portal bridge cranes |
This document describes the acoustic emission (AE) testing technique used to perform structural integrity evaluation on steel structures of overhead travelling cranes and portal bridge cranes.
This document applies to the testing of steel structures of in-service overhead travelling cranes and portal bridge cranes. Testing of other kinds of cranes can refer this document.
This testing method is not intended to be an alone NDT standard method for the evaluation of the structural integrity of overhead travelling cranes and portal bridge cranes. Other NDT methods are used to verify and supplement the AT results.
This document does not establish evaluation criteria.
|
Published |
2018-05 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
19.100
Non-destructive testing
;
53.020.20
Cranes
|
| ISO 5579:1985 |
Non-destructive testing — Radiographic examination of metallic materials by X- and gamma rays — Basic rules |
|
Withdrawn |
1985-08 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
77.040.20
Non-destructive testing of metals
|
| ISO 20339:2017 |
Non-destructive testing — Equipment for eddy current examination — Array probe characteristics and verification |
ISO 20339:2017 identifies the functional characteristics of eddy current array probes and their 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 array probes.
Where relevant, this document gives recommendations for acceptance criteria for the characteristics.
|
Published |
2017-03 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20484:2017 |
Non-destructive testing — Leak testing — Vocabulary |
ISO 20484:2017 defines the terms used in leak testing.
|
Published |
2017-03 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 20485:2017 |
Non-destructive testing — Leak testing — Tracer gas method |
ISO 20485:2017 describes the techniques to be applied for the detection of a leak, using a tracer gas and a tracer gas specific leak detector.
|
Published |
2017-11 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20486:2017 |
Non-destructive testing — Leak testing — Calibration of reference leaks for gases |
ISO 20486:2017 specifies the calibration of those leaks that are used for the adjustment of leak detectors for the determination of leakage rate in everyday use. One type of calibration method is a comparison with a reference leak. In this way, the leaks used for routine use become traceable to a primary standard. In other calibration methods, the value of vapour pressure was measured directly or calculated over a known volume.
The comparison procedures are preferably applicable to helium leaks, because this test gas can be selectively measured by a mass spectrometer leak detector (MSLD) (the definition of MSLD is given in ISO 20484).
Calibration by comparison (see methods A, As, B and Bs below) with known reference leaks is easily possible for leaks with reservoir and leakage rates below 10−7 Pa·m3/s.
Figure 1 gives an overview of the different recommended calibration methods.
|
Published |
2017-12 |
Edition : 1 |
Number of pages : 32 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20669:2017 |
Non-destructive testing — Pulsed eddy current testing of ferromagnetic metallic components |
ISO 20669:2017 specifies the pulsed eddy current (PEC) testing technique used to perform thickness measurement on ferromagnetic metallic components with or without the presence of coating, insulation and weather sheeting.
ISO 20669:2017 applies to the testing of in-service components made of carbon steel and low-alloy steel in the temperature of −100 °C to 500 °C (temperature measured at metal surface). The range of wall thickness of components is from 3 mm to 65 mm and the range of thickness of coatings is from 0 mm to 200 mm. The tested components also include piping of diameter not less than 50 mm.
The technique described in this document is sensitive to the geometry of the component and applying the technique to components outside of its scope will result in unpredictable inaccuracy. This document does not apply to the testing of crack defects and local metal loss caused by pitting.
ISO 20669:2017 does not establish evaluation criteria. The evaluation criteria shall be specified by the contractual agreement between parties.
|
Published |
2017-03 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20769-1:2018 |
Non-destructive testing — Radiographic inspection of corrosion and deposits in pipes by X- and gamma rays — Part 1: Tangential radiographic inspection |
This document specifies fundamental techniques of film and digital radiography with the object of enabling satisfactory and repeatable results to be obtained economically. The techniques are based on generally recognized practice and fundamental theory of the subject.
This document applies to the radiographic examination of steel pipes for service induced flaws such as corrosion pitting, generalized corrosion and erosion. Besides its conventional meaning, "pipe" as used in this document is understood to cover other cylindrical bodies such as tubes, penstocks, boiler drums and pressure vessels.
Weld inspection for typical welding process induced flaws is not covered, but weld inspection is included for corrosion/erosion type flaws.
The pipes can be insulated or not, and can be assessed where loss of material due, for example, to corrosion or erosion is suspected either internally or externally.
This document covers the tangential inspection technique for detection and through-wall sizing of wall loss, including with the source:
a) on the pipe centre line; and
b) offset from pipe centre line by the pipe radius.
ISO 20769-2 covers double wall radiography, and note that the double wall double image technique is often combined with tangential radiography with the source on the pipe centre line.
This document applies to tangential radiographic inspection using industrial radiographic film techniques, computed radiography (CR) and digital detector arrays (DDA).
|
Published |
2018-09 |
Edition : 1 |
Number of pages : 37 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 23865:2021 |
Non-destructive testing — Ultrasonic testing — General use of full matrix capture/total focusing technique (FMC/TFM) and related technologies |
This document gives general provisions for applying ultrasonic testing with arrays using FMC/TFM techniques and related technologies. It is intended to promote the adoption of good practice either at the manufacturing stage or for in-service testing of existing installations or for repairs.
Some examples of applications considered in this document deal with characterization and sizing in damage assessment.
Materials considered are low-alloyed carbon steels and common aerospace grade aluminium and titanium alloys, provided they are homogeneous and isotropic, but some recommendations are given for other materials (e.g. austenitic ones).
This document does not include acceptance levels for discontinuities.
For the application of FMC/TFM to testing of welds, see ISO 23864.
|
Published |
2021-01 |
Edition : 1 |
Number of pages : 42 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20769-2:2018 |
Non-destructive testing — Radiographic inspection of corrosion and deposits in pipes by X- and gamma rays — Part 2: Double wall radiographic inspection |
This document specifies fundamental techniques of film and digital radiography with the object of enabling satisfactory and repeatable results to be obtained economically. The techniques are based on generally recognized practice and fundamental theory of the subject.
This document applies to the radiographic examination of pipes in metallic materials for service induced flaws such as corrosion pitting, generalized corrosion and erosion. Besides its conventional meaning, "pipe" as used in this document is understood to cover other cylindrical bodies such as tubes, penstocks, boiler drums and pressure vessels.
Weld inspection for typical welding process induced flaws is not covered, but weld inspection is included for corrosion/erosion type flaws.
The pipes can be insulated or not, and can be assessed where loss of material due, for example, to corrosion or erosion is suspected either internally or externally.
This document covers double wall inspection techniques for detection of wall loss, including double wall single image (DWSI) and double wall double image (DWDI).
Note that the DWDI technique described in this document is often combined with the tangential technique covered in ISO 20769-1.
This document applies to in-service double wall radiographic inspection using industrial radiographic film techniques, computed digital radiography (CR) and digital detector arrays (DDA).
|
Published |
2018-09 |
Edition : 1 |
Number of pages : 30 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 20807:2004 |
Non-destructive testing — Qualification of personnel for limited application of non-destructive testing |
ISO 20807:2004 establishes a system for the qualification of personnel who perform NDT applications of a limited, repetitive or automated nature, such as:
eddy current and electromagnetic sorting of materials;
eddy current and electromagnetic testing of tubular products during manufacture;
normal beam ultrasonic testing of plate materials during manufacture;
ultrasonic thickness testing.
|
Published |
2004-03 |
Edition : 1 |
Number of pages : 30 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 21432:2019 |
Non-destructive testing — Standard test method for determining residual stresses by neutron diffraction |
This document describes the test method for determining residual stresses in polycrystalline materials by neutron diffraction. It is applicable to both homogeneous and inhomogeneous materials including those containing distinct phases.
The principles of the neutron diffraction technique are outlined. Suggestions are provided on:
— the selection of appropriate diffracting lattice planes on which measurements should be made for different categories of materials,
— the specimen directions in which the measurements should be performed, and
— the volume of material examined in relation to the material grain size and the envisaged stress state.
Procedures are described for accurately positioning and aligning test pieces in a neutron beam and for precisely defining the volume of material sampled for the individual measurements.
The precautions needed for calibrating neutron diffraction instruments are described. Techniques for obtaining a stress-free reference are presented.
The methods of making individual measurements by neutron diffraction are described in detail. Procedures for analysing the results and for determining their statistical relevance are presented. Advice is provided on how to determine reliable estimates of residual stresses from the strain data and on how to estimate the uncertainty in the results.
|
Published |
2019-12 |
Edition : 1 |
Number of pages : 45 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 21432:2005 |
Non-destructive testing — Standard test method for determining residual stresses by neutron diffraction |
ISO/TS 21432:2005 gives the standard test method for determining residual stresses in polycrystalline materials by neutron diffraction. It is applicable to homogeneous and inhomogeneous materials and to test pieces containing distinct phases.
|
Withdrawn |
2005-07 |
Edition : 1 |
Number of pages : 40 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 21432:2005/Cor 1:2008 |
Non-destructive testing — Standard test method for determining residual stresses by neutron diffraction — Technical Corrigendum 1 |
|
Withdrawn |
2008-01 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 22232-1:2020 |
Non-destructive testing — Characterization and verification of ultrasonic test equipment — Part 1: Instruments |
This document specifies methods and acceptance criteria within the frequency range of 0,5 MHz to 15 MHz, for assessing the electrical performance of digital ultrasonic instruments for pulse operation using A-scan display, for manual ultrasonic non-destructive testing with single- or dual-transducer probes. This document is also applicable for multi-channel instruments. This document can partly be applicable to ultrasonic instruments in automated systems, but other tests can be needed to ensure satisfactory performance.
This document excludes ultrasonic instruments for continuous waves.
This document also excludes ultrasonic phased array instruments, see e.g. ISO 18563-1. If a phased array instrument has dedicated connectors for single- or dual-transducer probes this document is applicable for these channels.
|
Published |
2020-07 |
Edition : 1 |
Number of pages : 40 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/DIS 24367 |
Non-destructive testing — Acoustic emission testing — Metallic pressure equipment |
|
Under development |
|
Edition : 1 |
Number of pages : 26 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/DIS 24489 |
Non-destructive testing — Acoustic emission testing — Detection of corrosion at atmospheric and low-pressure metallic storage tank floors |
|
Under development |
|
Edition : 1 |
Number of pages : 20 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 22232-2:2020 |
Non-destructive testing — Characterization and verification of ultrasonic test equipment — Part 2: Probes |
This document specifies the characteristics of probes used for non-destructive ultrasonic testing in the following categories with centre frequencies in the range of 0,5 MHz to 15 MHz, focusing or without focusing means:
a) single- or dual-transducer contact probes generating longitudinal and/or transverse waves;
b) single-transducer immersion probes.
Where material-dependent ultrasonic values are specified in this document they are based on steels having a sound velocity of (5 920 ± 50) m/s for longitudinal waves, and (3 255 ± 30) m/s for transverse waves.
This document excludes periodic tests for probes. Routine tests for the verification of probes using on-site procedures are given in ISO 22232-3.
If parameters in addition to those specified in ISO 22232-3 are to be verified during the probe's life time, as agreed upon by the contracting parties, the procedures of verification for these additional parameters can be selected from those given in this document.
This document also excludes ultrasonic phased array probes, therefore see ISO 18563-2.
|
Published |
2020-09 |
Edition : 1 |
Number of pages : 56 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 22232-3:2020 |
Non-destructive testing — Characterization and verification of ultrasonic test equipment — Part 3: Combined equipment |
This document specifies methods, tolerances and acceptance criteria for verifying the performance of combined ultrasonic test equipment (i.e. instrument, probes and cables connected) by the use of appropriate standard calibration blocks.
These methods are specifically intended for manual test equipment, i.e. ultrasonic instruments according to ISO 22232-1, and for manual ultrasonic non-destructive testing with single- or dual-transducer probes according to ISO 22232-2. This document is also applicable for multi-channel instruments. For automated test equipment, different tests can be needed to ensure satisfactory performance.
The specified methods are intended for the use by operators working under site or shop floor conditions.
These methods are not intended to prove the suitability of the equipment for particular applications.
This document excludes ultrasonic instruments for continuous waves.
This document also excludes ultrasonic phased array systems, see e. g. ISO 18563-3. If a phased array instrument is used in combination with single- or dual-transducer probes, this document is applicable to this combination.
|
Published |
2020-10 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 22290:2020 |
Non-destructive testing — Infrared thermographic testing — General principles for thermoelastic stress measuring method |
This document provides general principles for thermoelastic stress measuring method of infrared thermographic testing in the field of industrial non-destructive testing (NDT).
|
Published |
2020-11 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 22809:2007 |
Non-destructive testing — Discontinuities in specimens for use in qualification examinations |
ISO/TS 22809:2007 has been established to consider and define types of discontinuities to be exhibited in test specimens for use in non-destructive testing examinations.
|
Published |
2007-11 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
19.100
Non-destructive testing
;
03.100.30
Management of human resources
|
| ISO 23159:2020 |
Non-destructive testing — Gamma ray scanning method on process columns |
This document is used for non-destructive testing by the gamma ray scanning method for troubleshooting and testing process columns in industries. This document is applicable to the testing of all kinds of separation processes columns and pipes. This includes columns with different tray configurations and with packed beds.
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Published |
2020-06 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 23243:2020 |
Non-destructive testing — Ultrasonic testing with arrays — Vocabulary |
This document defines terms used in ultrasonic testing with arrays. This includes phased array technology and signal processing technology using arrays, e. g. the full-matrix capture (FMC) (3.3.1.28) and the total focusing technique (TFM) (3.3.1.35).
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Published |
2020-11 |
Edition : 1 |
Number of pages : 20 |
Technical Committee |
19.100
Non-destructive testing
;
01.040.19
Testing (Vocabularies)
|
| ISO 23345:2021 |
Jewellery and precious metals — Non destructive precious metal fineness confirmation by ED-XRF |
This document describes a non-destructive method to verify (confirm) the precious metal fineness of finished and semifinished jewellery item(s) considered homogeneous by ED-XRF (energy dispersive X-ray fluorescence), including alloys according to ISO 9202.
This document is not suitable for any coated items. WD-XRF (wavelength dispersive X-ray fluorescence) equipment cannot be used.
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Published |
2021-06 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
19.100
Non-destructive testing
;
39.060
Jewellery
|
| ISO/R 626:1967 |
Withdrawal of ISO/R 626-1967 |
|
Withdrawn |
1967-10 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO/R 627:1967 |
Withdrawal of ISO/R 627-1967 |
|
Withdrawn |
1967-10 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO/R 947:1969 |
Recommended practice for radiographic inspection of circumferential fusion welded butt joints in steel pipes up to 50 mm (2 in) wall thickness |
|
Withdrawn |
1969-01 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 24543:2022 |
Non-destructive testing — Acoustic emission testing — Verification of the receiving sensitivity spectra of piezoelectric acoustic emission sensors |
This document specifies a method for the determination of the receiving sensitivity spectra of a piezoelectric acoustic emission sensor, in absolute units of volts output per motion input, whereby the motion can be particle displacement (e.g. in nanometres) or particle velocity (e.g. in millimetres per second) over a frequency range used for acoustic emission testing, from 20 kHz to about 1,5 MHz, whereby the sensor is stimulated by a motion pulse in normal direction to the sensor’s face from a directly coupled piezoelectric transmitter.
This document also specifies a method for the determination of the transmitting sensitivity spectrum of a piezoelectric transmitter in absolute units, for example, in nanometres output per volt input, by measuring both the particle displacement pulse over the transmitter’s active face and the transmitter’s input voltage spectrum, using a scanning laser vibrometer.
This document does not include the known cancellation effects on a sensor’s response, when the angle of incidence differs from normal (90°) or when the length of the wave passing across the sensor’s sensitive face is shorter than about 10 times the dimension of the sensor’s sensitive face.
This document does not specify a method to measure the influence of different materials on a sensor’s sensitivity, but this effect is addressed in Annex F.
NOTE The methods described in this document can be considered for use with other than piezoelectric sensors, which detect motion at a flat face and work in the same frequency range.
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Published |
2022-09 |
Edition : 1 |
Number of pages : 60 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO 24647:2023 |
Non-destructive testing — Robotic ultrasonic test systems — General requirements |
This document specifies the necessary system hardware components, the characteristics, the component requirements and conditions for the application of robotic ultrasonic test systems.
This document specifies the general requirements and acceptance criteria for robotic ultrasonic test systems.
This document is applicable to robotic ultrasonic test systems composed of one or more robot(s). Some of the characteristics of a robot ultrasonic testing system can be application-specific.
This document is applicable to conventional straight-beam probes and immersion technique.
This document is also applicable for phased array equipment, but additional tests can be necessary.
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Published |
2023-02 |
Edition : 1 |
Number of pages : 34 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TR 25107:2006 |
Non-destructive testing — Guidelines for NDT training syllabuses |
ISO/TR 25107:2005 gives guidelines for non-destructive testing (NDT) training syllabuses, with the intention of harmonising and maintaining the general standard of training of NDT personnel for industrial needs. It also establishes the minimum requirements for effective structured training of NDT personnel to ensure eligibility for qualification examinations leading to third-party certification according to recognized standards. In addition to non-destructive testing in general, its guidelines for syllabuses cover acoustic emission, eddy current, leak, magnetic particle, penetrant, radiographic, ultrasonic and visual testing.
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Withdrawn |
2006-07 |
Edition : 1 |
Number of pages : 81 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 25107:2019 |
Non-destructive testing — NDT training syllabuses |
This document gives requirements and recommendations for non-destructive testing (NDT) training syllabuses, with the intention of harmonizing and maintaining the general standard of training of NDT personnel for industrial needs.
It also establishes the minimum requirements for effective structured training of NDT personnel to ensure eligibility for qualification examinations leading to third-party certification according to recognized standards. In addition to non-destructive testing in general, its guidelines for syllabuses cover acoustic emission testing, eddy current testing, leak testing, magnetic testing, penetrant testing, radiographic testing, ultrasonic testing, visual testing, thermographic testing, and strain gauge testing.
ISO/TS 25108 gives requirements and recommendations for NDT training organizations.
|
Published |
2019-09 |
Edition : 1 |
Number of pages : 97 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TR 25108:2006 |
Non-destructive testing — Guidelines for NDT personnel training organizations |
ISO/TR 25108:2005 gives guidelines for non-destructive testing (NDT) training organizations, with the intention of harmonizing and maintaining the general standard of training of NDT personnel for industrial needs. It also establishes the minimum requirements for effective structured training of NDT personnel to ensure eligibility for qualification examinations leading to third-party certification according to recognized standards.
|
Withdrawn |
2006-07 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/TS 25108:2018 |
Non-destructive testing — NDT personnel training organizations |
This document gives requirements and recommendations for non-destructive testing (NDT) training organizations, with the intention of harmonizing and maintaining the general standard of training of NDT personnel for industrial needs.
It also establishes the minimum requirements for effective structured training of NDT personnel to ensure eligibility for qualification examinations leading to third-party certification according to recognized standards.
NOTE ISO/TS 25107 gives requirements and recommendations for NDT training syllabuses intended for training.
|
Published |
2018-10 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
19.100
Non-destructive testing
|
| ISO/R 598:1967 |
Withdrawal of ISO/R 598-1967 |
|
Withdrawn |
1967-08 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO/R 615:1967 |
Methods for determining the mechanical properties of the weld metal deposited by electrodes 3,15 mm or more in diameter |
|
Withdrawn |
1967-09 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO/R 617:1967 |
Calculation of rectangular symmetrical fillet welds statically loaded in such a way that the transverse section is not under any normal stress |
|
Withdrawn |
1967-09 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 1106-1:1984 |
Recommended practice for radiographic examination of fusion welded joints — Part 1: Fusion welded butt joints in steel plates up to 50 mm thick |
The detection of flaws in an item submitted to X- or gamma-radiographic examination depends on the particularities of the technique employed. This part of ISO 1106 specifies general techniques of weld radiography with the object of enabling satisfactory results to be obtained economically. The techniques are based on generally accepted practice and the fundamental theory of the subject.
|
Withdrawn |
1984-12 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 1106-2:1985 |
Recommended practice for radiographic examination of fusion welded joints — Part 2: Fusion welded butt joints in steel plates thicker than 50 mm and up to and including 200 mm in thickness |
Specifies general techniques of weld radiography with the object of enabling satisfactory results to be obtained economically. The techniques are based on generally accepted practice and the fundamental theory of the subject. Does not lay down radiographic criteria of acceptance for the joints, but is concerned with the radiographic techniques to be used.
|
Withdrawn |
1985-05 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
25.160.40
Welded joints and welds
|
| ISO 1106-3:1984 |
Recommended practice for radiographic examination of fusion welded joints — Part 3: Fusion welded circumferential joints in steel pipes of up to 50 mm wall thickness |
The detection of flaws in an item submitted to X- or gamma-radio-graphic examination depends on the particularities of the technique employed. This part of ISO 1106 specifies general techniques of weld radiography with the object of enabling satisfactory results to be obtained economically. The techniques are based on generally accepted practice and the fundamental theory of the subject.
|
Withdrawn |
1984-12 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
25.160.40
Welded joints and welds
|