| Name |
Description |
Abstract |
Status |
Publication date |
Edition |
Number of pages |
Technical committee |
ICS |
| ISO 6190:1988 |
Acoustics — Measurement of sound pressure levels of gas turbine installations for evaluating environmental noise — Survey method |
|
Withdrawn |
1988-12 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
17.140.20
Noise emitted by machines and equipment
|
| ISO 7919-2:2009 |
Mechanical vibration — Evaluation of machine vibration by measurements on rotating shafts — Part 2: Land-based steam turbines and generators in excess of 50 MW with normal operating speeds of 1 500 r/min, 1 800 r/min, 3 000 r/min and 3 600 r/min |
ISO 7919-2:2009 establishes provisions for applying evaluation criteria for the severity of in-situ, broad-band shaft vibration measured radial (i.e. transverse) to the shaft axis at, or close to, the main bearings. These are in terms of:
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
ISO 7919-2:2009 is applicable to land-based steam turbines and generators with power outputs greater than 50 MW and a normal operating speed of 1 500 r/min, 1800 r/min, 3 000 r/min or 3 600 r/min.
|
Withdrawn |
2009-10 |
Edition : 3 |
Number of pages : 12 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
;
29.160.40
Generating sets
|
| ISO 7919-4:1996 |
Mechanical vibration of non-reciprocating machines — Measurements on rotating shafts and evaluation criteria — Part 4: Gas turbine sets |
|
Withdrawn |
1996-07 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 7919-4:2009 |
Mechanical vibration — Evaluation of machine vibration by measurements on rotating shafts — Part 4: Gas turbine sets with fluid-film bearings |
ISO 7919-4:2009 establishes provisions for evaluating the severity of in-situ, broad-band shaft vibration measured radial (i.e. transverse) to the shaft axis at, or close to, the main bearings. These are in terms of
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
ISO 7919-4:2009 is applicable to heavy-duty gas turbine sets used in electrical and mechanical drive applications, with fluid-film bearings, outputs greater than 3 MW and an operating speed range under load between 3 000 r/min and 30 000 r/min. This includes gas turbines coupled to other rotating machinery either directly or through a gearbox. In some cases, ISO 7919-4:2009 is not applicable to the evaluation of the vibration of the coupled equipment.
|
Withdrawn |
2009-10 |
Edition : 2 |
Number of pages : 14 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 7919-4:2009/Amd 1:2017 |
Mechanical vibration — Evaluation of machine vibration by measurements on rotating shafts — Part 4: Gas turbine sets with fluid-film bearings — Amendment 1 |
|
Withdrawn |
2017-08 |
Edition : 2 |
Number of pages : 5 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 10436:1993 |
Petroleum and natural gas industries — General-purpose steam turbines for refinery service |
Specifies the minimum requirements. Requirements are specified in the third edition of API Standard 611 (Std 611), August 1988, which is adopted as ISO 10436. For the purposes of international standardization, modifications have been made that are outlined.
|
Withdrawn |
1993-12 |
Edition : 1 |
Number of pages : 48 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
75.180.20
Processing equipment
|
| ISO 10437:1993 |
Petroleum and natural gas industries — Special-purpose steam turbines for refinery service |
Specifies the minimum requirements. Requirements are specified in the third edition of API Standard 612 (Std 612), November 1987, which is adopted as ISO 10437. For the purposes of international standardization, modifications have been made that are outlined.
|
Withdrawn |
1993-12 |
Edition : 1 |
Number of pages : 59 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
75.180.20
Processing equipment
|
| ISO 10437:2003 |
Petroleum, petrochemical and natural gas industries — Steam turbines — Special-purpose applications |
ISO 10437:2003 specifies requirements and gives recommendations for the design, materials, fabrication, inspection, testing and preparation for shipment of special-purpose steam turbines. It also covers the related lube-oil systems, instrumentation, control systems and auxiliary equipment. It is not applicable to general-purpose steam turbines, which are covered in ISO 10436.
|
Published |
2003-07 |
Edition : 2 |
Number of pages : 113 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
75.180.20
Processing equipment
|
| ISO 10494:1993 |
Gas turbines and gas turbine sets — Measurement of emitted airborne noise — Engineering/survey method |
Specifies methods for measuring the sound pressure levels on a measurement surface enveloping a source, and for calculating the sound power level produced by the source. Gives requirements for the test environment and instrumentation, as well as techniques for obtaining the surface sound pressure level from which the A-weighted sound power level of the source and octave or one-third-octave band sound power levels are calculated. This method may be used to perform acceptance tests.
|
Withdrawn |
1993-07 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
17.140.20
Noise emitted by machines and equipment
|
| ISO 10494:2018 |
Turbines and turbine sets — Measurement of emitted airborne noise — Engineering/survey method |
ISO 10494:2018 specifies methods for measuring the noise emission of a turbine or turbine set under steady-state operating conditions. It specifies methods for measuring the sound pressure levels on a measurement surface enveloping a source, and for calculating the sound power level produced by the source. It gives requirements for the test environment and instrumentation, as well as techniques for obtaining the surface sound pressure level from which the A-weighted sound power level of the source and octave or one-third-octave band sound power levels are calculated. These methods can be used to conduct performance tests even if the purpose of the test is simply to determine the sound pressure level around the machine.
ISO 10494:2018 is applicable to turbines and turbine sets:
- for power plant and industrial applications (e.g. stationary);
- for installation on board ships, or offshore installations, road and railway vehicles.
ISO 10494:2018 does not apply to gas turbines in aircraft applications.
ISO 10494:2018 is applicable to only the part of the turbine set (turbine, driven equipment and attached components) located above the floor and inside a continuous enveloping measurement surface bounded by this floor.
ISO 10494:2018 is applicable to steady-state operation and excludes transients such as start-up and shut-down, when the noise emission can be higher for short times. Under these conditions, this document does not apply.
|
Published |
2018-04 |
Edition : 2 |
Number of pages : 37 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
17.140.20
Noise emitted by machines and equipment
|
| ISO 10816-2:2009 |
Mechanical vibration — Evaluation of machine vibration by measurements on non-rotating parts — Part 2: Land-based steam turbines and generators in excess of 50 MW with normal operating speeds of 1 500 r/min, 1 800 r/min, 3 000 r/min and 3 600 r/min |
ISO 10816-2:2009 establishes provisions for evaluating the severity of in-situ, broad-band vibration measured radial (i.e. transverse) to the shaft axis on all main bearing housings or pedestals and in the axial direction on thrust bearings. These are in terms of:
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
ISO 10816-2:2009 is applicable to land-based steam turbines and generators with power outputs greater than 50 MW and a normal operating speed of 1 500 r/min, 1 800 r/min, 3 000 r/min or 3 600 r/min.
|
Withdrawn |
2009-10 |
Edition : 3 |
Number of pages : 14 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
;
29.160.40
Generating sets
|
| ISO 10816-4:1998 |
Mechanical vibration — Evaluation of machine vibration by measurements on non-rotating parts — Part 4: Gas turbine driven sets excluding aircraft derivatives |
|
Withdrawn |
1998-07 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 10298:2018 |
Gas cylinders — Gases and gas mixtures — Determination of toxicity for the selection of cylinder valve outlets |
ISO 10298:2018 lists the best available acute-toxicity data of gases taken from a search of the current literature to allow the classification of gases and gas mixtures for toxicity by inhalation.
|
Published |
2018-02 |
Edition : 3 |
Number of pages : 15 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 10816-4:2009 |
Mechanical vibration — Evaluation of machine vibration by measurements on non-rotating parts — Part 4: Gas turbine sets with fluid-film bearings |
ISO 10816-4:2009 establishes specific provisions for evaluating the severity of in-situ, broad-band vibration measured radial (i.e. transverse) to the shaft axis on all main bearing housings or pedestals and in the axial direction on thrust bearings. These are in terms of:
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
ISO 10816-4:2009 is applicable to heavy-duty gas turbine sets used in electrical and mechanical drive applications, with fluid-film bearings, outputs greater than 3 MW and an operating speed range under load between 3 000 r/min and 30 000 r/min.
|
Withdrawn |
2009-10 |
Edition : 2 |
Number of pages : 16 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 10816-4:2009/Amd 1:2017 |
Mechanical vibration — Evaluation of machine vibration by measurements on non-rotating parts — Part 4: Gas turbine sets with fluid-film bearings — Amendment 1 |
|
Withdrawn |
2017-08 |
Edition : 2 |
Number of pages : 4 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 11042-1:1996 |
Gas turbines — Exhaust gas emission — Part 1: Measurement and evaluation |
Contains the methods used for the measurement and evaluation of the emission of the exhaust gases from gas turbines and defines appropriate emission terms. Presents requirements for the test environment and instrumentation as well as the accuracy of measurement and correction of data. Does not apply to gas turbines used in aircraft.
|
Published |
1996-08 |
Edition : 1 |
Number of pages : 33 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
13.040.40
Stationary source emissions
|
| ISO 11042-2:1996 |
Gas turbines — Exhaust gas emission — Part 2: Automated emission monitoring |
Establishes the monitoring programme and the requirements for the selection and operation of hardware to be used for continuous gas emission measurements. Monitores the concentration and absolute magnitude of specified emissions in the exhaust gas as well as related gaseous components. Requires that the following parameters be continuously monitored: emissions, diluent gases (oxygen, carbon dioxide), exhaust gas flow, fuel consumption and gas turbine performance.
|
Published |
1996-08 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
13.040.40
Stationary source emissions
|
| ISO 11086:1996 |
Gas turbines — Vocabulary |
Gives terms and definitions used in the field of gas turbines. It applies to open-cycle gas turbines (using normal combustion systems), closed-cycle, semiclosed-cycle and combined-cycle gas turbines.
|
Published |
1996-04 |
Edition : 1 |
Number of pages : 63 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
01.040.27
Energy and heat transfer engineering (Vocabularies)
|
| ISO 14661:2000 |
Thermal turbines for industrial applications (steam turbines, gas expansion turbines) — General requirements |
|
Withdrawn |
2000-06 |
Edition : 1 |
Number of pages : 72 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 14661:2000/Amd 1:2002 |
Thermal turbines for industrial applications (steam turbines, gas expansion turbines) — General requirements — Amendment 1: Data sheets for thermal turbines for industrial applications |
|
Withdrawn |
2002-11 |
Edition : 1 |
Number of pages : 62 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 18888:2017 |
Gas turbine combined cycle power plants — Thermal performance tests |
ISO 18888:2017 specifies standard rules for preparing, conducting, evaluating and reporting thermal performance tests on combined cycle and cogeneration power plants driven by gas turbines for base and part load operation with or without supplementary firing.
ISO 18888:2017 is applicable to
- thermal performance tests for general information,
- thermal acceptance tests for determining the performance of the combined cycle plant in relation to a contractual guarantee, and
- comparative tests designed to check the performance differentials of the combined cycle and cogeneration power plants, for testing before and after modifications, upgrades or overhauls.
It can be used to determine the following thermal performance test goals and expected values, under specific operating and reference conditions within defined test boundaries:
- electrical power output;
- heat rate or thermal efficiency;
- process steam and/or district heat w/o generation of electrical power output by means of a steam turbine.
ISO 18888:2017 does not apply to individual equipment component testing, which is covered by corresponding standards.
It is not intended to be applied to the following test goals:
- environmental testing for example emissions, noise;
- vibration testing;
- operational testing;
- absolute or comparative performance of specific components of the combined cycle covered by dedicated standards (e.g. gas turbines).
|
Published |
2017-10 |
Edition : 1 |
Number of pages : 73 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
27.100
Power stations in general
|
| ISO 19372:2015 |
Microturbines applications — Safety |
ISO 19372:2015 covers the safety requirements for industrial, commercial, and residential automated stationary microturbine (micro gas turbine) engine generator assemblies with an individual system or subsystem output rating with nominal supply voltages not exceeding 1 000 V for alternating current (A.C.) and not exceeding 1 500 V for direct current (D.C.), 500 kW per individual unit/subsystem or less that are intended for installation and use in ordinary and hazardous location using liquid or gaseous fuels and the safety related control and detection systems and essential auxiliaries for all types of open cycles, closed-cycle, and semi-closed (simple, combined, regenerative, reheat, etc.) used in onshore and offshore applications including floating production platforms.
|
Published |
2015-02 |
Edition : 1 |
Number of pages : 89 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 19859:2016 |
Gas turbine applications — Requirements for power generation |
ISO 19859:2016 specifies the minimum technical and documentation requirements for the evaluation and procurement of gas turbine systems for electrical power generation.
It applies to simple cycle and combined cycle gas turbines for both onshore and offshore applications, where applicable. It also applies to gas turbines used in cogeneration (see ISO 11086:1996, Annex B). Testing of the gas turbine in combination with a generator is included in the scope.
It is not applicable to gas turbines used for all types of propulsion including aircraft, mobile barges, floating production vessels and marine propulsion applications and microturbines.
ISO 19859:2016 defines the requirements for gas turbine power generation from an international perspective based on the content of existing, recognized ISO and IEC standards to the greatest extent practical. Nonetheless, it is recognized that within the industry other codes or standards are used, some of which are included in the text of this International Standard. The use of other such codes and standards is permissible provided an appropriate and acceptable level of requirements, functional design and safety is achieved and agreement has been reached for their use between the Purchaser and Contractor and such use is suitably documented.
Consideration should be given to applying/using standards in the following hierarchical order: international; regional; national; local.
ISO 19859:2016 identifies the requirements for both the Purchaser and Contractor attributable to the design and procurement of a gas turbine power generation package.
The defined requirements apply to the scope of supply, except where excluded, encompassing the following equipment and the associated selected options, located within the power generation package, (see 3.14), listed below:
- gas turbine package;
- load shaft coupling and clutch, as applicable;
- air inlet system;
- exhaust system;
- fuel equipment;
- control equipment;
- electrical equipment;
- additional auxiliary systems, including starting, lubrication, barring, compressor wash, pipework, drains and vents;
- fire and gas protection;
- cooling water equipment.
Where applicable to the integrity of the gas turbine package, the interface and applicable design requirements are included for equipment, utilities and supplies that interface with the power generation package.
The following equipment is excluded from the scope of supply, but references are included where required for interface or performance measurement:
- generator and auxiliary systems, except the module control option;
- steam turbine and auxiliary systems;
- equipment external to the power generation package.
Data sheets in Annex A of this International Standard are provided for defining requirements and exchanging information between the Purchaser and the Contractor.
The Purchaser fills in the data sheets for the tender and forwards them to the Contractor. The Contractor responds by completing the applicable data sheets for their tender.
Annex A identifies the different types of data sheets and how they are to be used.
Where the Contractor does not comply with a selected requirement of this International Standard, this is detailed as an exception, referencing the applicable clause and describing the deviation and any alternatives available in a document listing all the exceptions taken.
Where the text in this International Standard requests procedures and operating, maintenance and commissioning manual information or equipment that would require the disclosure/supply of proprietary information/equipment which the Contractor is not prepared to release, such exceptions are listed. Where this situation exists, the Contractor will be prepared to release appropriate personnel and equipment to undertake all the tasks that otherwise would be undertaken by the Purchaser.
A bullet ● at the beginning of a paragraph in the text of this International Standard indicates an optional requirement (see A.3).
|
Published |
2016-08 |
Edition : 1 |
Number of pages : 147 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
;
29.160.99
Other standards related to rotating machinery
|
| ISO 19860:2005 |
Gas turbines — Data acquisition and trend monitoring system requirements for gas turbine installations |
ISO 19860:2005 applies to data-acquisition and trend-monitoring systems for gas turbine installations and associated systems. ISO 19860:2005 classifies and defines monitoring systems and their technical terms and establishes a system for conversion and validation of measured quantities in order to enable a comparison of the various systems, their features and their performances.
|
Published |
2005-03 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 20816-2:2017 |
Mechanical vibration — Measurement and evaluation of machine vibration — Part 2: Land-based gas turbines, steam turbines and generators in excess of 40 MW, with fluid-film bearings and rated speeds of 1 500 r/min, 1 800 r/min, 3 000 r/min and 3 600 r/min |
ISO 20816-2:2017 is applicable to land-based gas turbines, steam turbines and generators (whether coupled with gas and/or steam turbines) with power outputs greater than 40 MW, fluid-film bearings and rated speeds of 1 500 r/min, 1 800 r/min, 3 000 r/min or 3 600 r/min. The criteria provided in ISO 20816-2:2017 can be applied to the vibration of the gas turbine, steam turbine and generator (including synchronizing clutches). ISO 20816-2:2017 establishes provisions for evaluating the severity of the following in-situ, broad-band vibration:
a) structural vibration at all main bearing housings or pedestals measured radial (i.e. transverse) to the shaft axis;
b) structural vibration at thrust bearing housings measured in the axial direction;
c) vibration of rotating shafts radial (i.e. transverse) to the shaft axis at, or close to, the main bearings.
These are in terms of the following:
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
ISO 20816-2:2017 is not applicable to the following:
i) electromagnetic excited vibration with twice line frequency at the generator stator windings, core and housing;
ii) aero-derivative gas turbines (including gas turbines with dynamic properties similar to those of aero-derivatives);
NOTE ISO 3977‑3 defines aero-derivatives as aircraft propulsion gas generators adapted to drive mechanical, electrical or marine propulsion equipment. Large differences exist between heavy-duty and aero-derivative gas turbines, for example, in casing flexibility, bearing design, rotor-to-stator mass ratio and mounting structure. Different criteria, therefore, apply for these two turbine types.
iii) steam turbines and/or generators with outputs less than or equal to 40 MW or with rated speeds other than 1 500 r/min, 1 800 r/min, 3 000 r/min or 3 600 r/min (although generators seldom fall into this latter category) (see ISO 7919‑3 and ISO 10816‑3);
iv) gas turbines with outputs less than or equal to 40 MW or with rated speeds other than 1 500 r/min, 1 800 r/min, 3 000 r/min or 3 600 r/min (see ISO 7919‑3 or ISO 7919‑4 and ISO 10816‑3 or ISO 10816‑4);
v) the evaluation of combustion vibration but does not preclude monitoring of combustion vibration.
|
Published |
2017-07 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
;
29.160.40
Generating sets
|
| ISO 20816-4:2018 |
Mechanical vibration — Measurement and evaluation of machine vibration — Part 4: Gas turbines in excess of 3 MW, with fluid-film bearings |
This document is applicable to land-based gas turbines with fluid-film bearings and power outputs greater than 3 MW and an operating speed under load between 3 000 r/min and 30 000 r/min. In some cases (see the list of exclusions below), this includes other rotating machinery coupled either directly or through a gearbox. The evaluation criteria provided in this document are applicable to the vibration of the main input and output bearings of the gearbox but are not applicable to the vibration of the internal gearbox bearings nor to the assessment of the condition of those gears. Specialist techniques required for evaluating the condition of gears are outside the scope of this document.
This document is not applicable to the following:
i) gas turbines with power outputs greater than 40 MW at rated speeds of 1 500 r/min, 1 800 r/min, 3 000 r/min or 3 600 r/min (see ISO 20816-2);
ii) aero-derivative gas turbines (including gas turbines with dynamic properties similar to those of aero-derivatives);
NOTE ISO 3977-3 defines aero-derivatives as aircraft propulsion gas generators adapted to drive mechanical, electrical or marine propulsion equipment. Large differences exist between heavy-duty and aero-derivative gas turbines, for example, in casing flexibility, bearing design, rotor-to-stator mass ratio and mounting structure. Different criteria, therefore, apply for these two turbine types.
iii) gas turbines with outputs less than or equal to 3 MW (see ISO 7919-3 and ISO 10816-3);
iv) turbine driven generators (see ISO 20816-2, ISO 7919-3 and ISO 10816-3);
v) turbine driven pumps (see ISO 10816-7);
vi) turbine driven rotary compressors (see ISO 7919-3 and ISO 10816-3);
vii) the evaluation of gearbox vibration (see this clause) but does not preclude monitoring of gearbox vibration;
viii) the evaluation of combustion vibration but does not preclude monitoring of combustion vibration;
ix) rolling element bearing vibration.
This document establishes provisions for evaluating the severity of the following in-situ broad-band vibrations:
a) structural vibration at all main bearing housings or pedestals measured radial (i.e. transverse) to the shaft axis;
b) structural vibration at thrust bearing housings measured in the axial direction;
c) vibration of rotating shafts radial (i.e. transverse) to the shaft axis at, or close to, the main bearings.
These are in terms of the following:
- vibration under normal steady-state operating conditions;
- vibration during other (non-steady-state) conditions when transient changes are taking place, including run up or run down, initial loading and load changes;
- changes in vibration which can occur during normal steady-state operation.
|
Published |
2018-06 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.040
Gas and steam turbines. Steam engines
|
| ISO 21789:2009 |
Gas turbine applications — Safety |
ISO 21789:2009 covers the safety requirements for gas turbine applications using liquid or gaseous fuels and the safety-related control and detection systems and essential auxiliaries for all types of open cycles (simple, combined, regenerative, reheat, etc.) used in onshore and offshore applications including floating production platforms.
It applies to driven machinery only where an integral part of the gas turbine (e.g. a gearbox integral to the gas turbine) or located within the gas turbine enclosure and forming part of the enclosure hazardous area classification (e.g. a generator within the gas turbine enclosure), or where the driven machinery has a direct effect on the operational safety of the gas turbine.
It details the anticipated significant hazards associated with gas turbines and specifies the appropriate preventative measures and processes for reduction or elimination of these hazards. It addresses the risks of injury or death to humans and risks to the environment. Equipment damage without risk to humans or the environment is not covered.
It excludes gas turbines used primarily for direct and indirect propulsion, special heat source applications and in research and development programmes. It also excludes gas turbines for closed-cycle and semi-closed cycle applications, and compressed-air energy storage plants. Where appropriate, it can be used to give general guidance in such applications.
It is not applicable to machinery or safety components that were manufactured before the date of its publication.
|
Withdrawn |
2009-02 |
Edition : 1 |
Number of pages : 82 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 21789:2022 |
Gas turbine applications — Safety |
This document covers the safety requirements for aero derivative and industrial gas turbine prime mover applications using liquid or gaseous fuels and the safety related control and detection systems and essential auxiliaries for all types of open cycles (simple, combined, regenerative, reheat, etc.) used in onshore and offshore applications including floating production platforms.
This document applies to mechanical, electrical, and pressure equipment components and systems necessary for the functionality of the prime mover. For example, but not limited to, a core gas turbine auxiliary gearbox, an output transmission gear box, combustion system, air filtration, gas turbine controls, oil systems, and fuel system. This document also covers integration of safety risks within the overall installation, e.g. exhaust purging or drainage.
This document details the anticipated significant hazards associated with aero derivative and industrial gas turbine prime movers and specifies the appropriate preventative measures and processes for reduction or elimination of these hazards. This document addresses the risks of injury or death to humans and risks to the environment. Equipment damage without risk to humans or the environment is not covered.
The overall objective of this document is to ensure that equipment is designed, constructed, operated and maintained throughout its life in accordance with ISO 12100:2010.
This document approaches gas turbine safety from an international perspective based on the content of existing, recognized ISO and IEC standards to the greatest extent possible. Where no ISO or IEC standard exists, other codes or standards (such as EN, NFPA, etc.) have been included.
Minimum functional safety levels cannot be addressed in this document, as minimum functional safety levels are both application and site specific.
This document excludes the following items;
— exhaust-system structural design;
— driven equipment;
— micro turbines as covered by ISO 19372:2015;
— gas turbines used primarily for direct and indirect propulsion;
— gas turbines used for mobile applications;
— special heat source applications;
— gas turbines in research and development programs;
— compressed-air energy storage plants.
Where appropriate, this document can be used to give general guidance in such applications.
This document is not applicable to machinery or safety components manufactured before the date of its publication.
|
Published |
2022-07 |
Edition : 2 |
Number of pages : 88 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 10298:2018/Amd 1:2021 |
Gas cylinders — Gases and gas mixtures — Determination of toxicity for the selection of cylinder valve outlets — Amendment 1 |
|
Published |
2021-10 |
Edition : 3 |
Number of pages : 1 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 21905:2020 |
Gas turbine exhaust systems with or without waste heat recovery |
This document specifies requirements and gives recommendations for the design, materials of construction, modelling, controlling, fabrication, inspection, testing, installation, start-up and operation of industrial gas turbine (GT) exhaust systems with or without waste heat recovery unit (WHRU). Gas turbines can be on-shore or off-shore for such sectors as oil and gas, chemical and process industries, utilities, or other intensive energy users.
For this document, the exhaust system means all items in the turbine exhaust gas stream between the GT exhaust gas collector outlet flange and the termination/s to the atmosphere.
The following items are not covered by this document:
— heat recovery steam generator equipment (HRSG);
— supplementary fired systems;
— auxiliary fired systems;
— exhaust gas collector (also known as exhaust plenum);
— fire detection and extinguishing systems;
— emissions controls equipment intended to modify the gaseous composition of the exhaust gas;
— WHRUs that are of the firetube type, where the turbine exhaust gas (TEG) passes through the tubes.
|
Published |
2020-03 |
Edition : 1 |
Number of pages : 96 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| ISO 26382:2010 |
Cogeneration systems — Technical declarations for planning, evaluation and procurement |
ISO 26382:2010 describes the technical declarations for a cogeneration system (CGS) that simultaneously supplies electric power and heating and/or cooling, for planning, evaluation and procurement.
It applies to the identification of investigation items for project evaluation, CGS evaluation, and primary information works for CGS procurement.
It also specifies necessary check items in CGS planning, provides a procedure to obtain the satisfactory configuration of the CGS for each project, and includes a detailed process diagram of the key development steps.
|
Published |
2010-02 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
27.040
Gas and steam turbines. Steam engines
|
| IWA 33-1:2019 |
Technical guidelines for the development of small hydropower plants — Part 1: Vocabulary |
This document defines the professional technical terms and definitions commonly used for small hydropower (SHP) plants.
|
Published |
2019-12 |
Edition : 1 |
Number of pages : 60 |
Technical Committee |
27.140
Hydraulic energy engineering
|
| IWA 33-2:2019 |
Technical guidelines for the development of small hydropower plants — Part 2: Site selection planning |
This document specifies the general principles of site selection planning for small hydropower (SHP) projects, and the methodologies, procedures and outcome requirements of SHP plant site selection.
|
Published |
2019-12 |
Edition : 1 |
Number of pages : 30 |
Technical Committee |
27.140
Hydraulic energy engineering
|
| IWA 33-3:2021 |
Technical guidelines for the development of small hydropower plants — Part 3: Design principles and requirements |
This document specifies the general principles and basic requirements of design for small hydropower (SHP) projects up to 30 MWe, mainly including hydrology, geology, energy calculations, project layout, hydraulics, electromechanical equipment selection, construction planning, project cost estimates, economic appraisal, social and environmental assessments.
Application of this document is intended to be site specific, with the principles and requirements of design applied in accordance with the needs of proposed hydropower plant.
|
Published |
2021-03 |
Edition : 1 |
Number of pages : 80 |
Technical Committee |
27.140
Hydraulic energy engineering
|
| ISO 10816-5:2000 |
Mechanical vibration — Evaluation of machine vibration by measurements on non-rotating parts — Part 5: Machine sets in hydraulic power generating and pumping plants |
|
Withdrawn |
2000-04 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.140
Hydraulic energy engineering
|
| ISO 19283:2020 |
Condition monitoring and diagnostics of machines — Hydroelectric generating units |
This document focuses on recommended condition monitoring techniques for detecting and diagnosing developing machine faults associated with the most common potential failure modes for hydro unit components. It is intended to improve the reliability of implementing an effective condition monitoring approach for hydroelectric generating units (hydro units). It is also intended to help create a mutual understanding of the criteria for successful hydro unit condition monitoring and to foster cooperation between the various hydropower stakeholders.
This document is intended for end-users, contractors, consultants, service providers, machine manufacturers and instrument suppliers.
This document is machine-specific and is focused on the generator, shaft/bearing assembly, runner (and impeller for pumped storage applications), penstock (including the main inlet valve), spiral case and the upper draft tube of hydro units. It is primarily intended for medium to large sized hydro units with more than 50 MVA installed capacity, but it is equally valid for smaller units in many cases. It is applicable to various types of turbines such as Francis, Kaplan, Pelton, Bulb and other types. Generic auxiliary systems such as for lubrication and cooling are outside the scope, with the exception of some monitoring techniques that are related to condition monitoring of major systems covered by this document, such as oil analysis. Transmission systems, civil works and the foundation are outside the scope.
This document covers online (permanently installed) and portable instrument condition monitoring and diagnostic techniques for operational hydro units. Offline machine testing, i.e. that which is only done during shutdown, although very important, is not part of the scope of this document. Nor is one-time acceptance and performance testing within the scope. The condition monitoring techniques presented in this document cover a wide range of continuous and interval-based monitoring techniques under generalized conditions for a wide range of applications. Therefore, the actual monitoring approach required for a specific application can be different than that which is recommended in this generalized document.
|
Published |
2020-04 |
Edition : 1 |
Number of pages : 62 |
Technical Committee |
17.160
Vibrations, shock and vibration measurements
;
27.140
Hydraulic energy engineering
|
| ISO 17225-6:2014 |
Solid biofuels — Fuel specifications and classes — Part 6: Graded non-woody pellets |
ISO 17225-6:2014 determines the fuel quality classes and specifications of graded non-woody pellets.
|
Withdrawn |
2014-05 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
27.190
Biological sources and alternative sources of energy
;
75.160.40
Biofuels
|
| ISO 19882:2018 |
Gaseous hydrogen — Thermally activated pressure relief devices for compressed hydrogen vehicle fuel containers |
This document establishes minimum requirements for pressure relief devices intended for use on hydrogen fuelled vehicle fuel containers that comply with ISO 19881, IEC 62282-4-101, ANSI HGV 2, CSA B51 Part 2, EC79/EU406, SAE J2579, or the UN GTR No. 13.
The scope of this document is limited to thermally activated pressure relief devices installed on fuel containers used with fuel cell grade hydrogen according to SAE J2719 or ISO 14687 for fuel cell land vehicles, and Grade A or better hydrogen according to ISO 14687 for internal combustion engine land vehicles. This document also contains requirements for thermally activated pressure relief devices acceptable for use on-board light duty vehicles, heavy duty vehicles and industrial powered trucks such as forklifts and other material handling vehicles, as it pertains to UN GTR No. 13.
Pressure relief devices designed to comply with this document are intended to be used with high quality hydrogen fuel such as fuel complying with SAE J2719 or ISO 14687 Type 1 Grade D.
Pressure relief devices can be of any design or manufacturing method that meets the requirements of this document.
This document does not apply to reseating, resealing, or pressure activated devices.
Documents which apply to hydrogen fuel vehicles and hydrogen fuel subsystems include IEC 62282- 4- 101, SAE J2578 and SAE J2579.
Annex A presents an informative record of recommended fuel container, fuel storage subsystem and vehicle level requirements. The statements in Annex A are intended as recommendations for consideration of inclusion by the organizations and committees developing standards on these sub system and vehicle level standards.
Annex B presents a rationale for the design qualification tests in this document.
|
Published |
2018-11 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
27.075
Hydrogen technologies
;
43.060.40
Fuel systems
|
| ISO/CD 19884-1 |
Gaseous hydrogen — Cylinders and tubes for stationary storage — Part 1: General Requirements |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
27.075
Hydrogen technologies
;
23.020.35
Gas cylinders
|
| ISO/CD 19885-1 |
Gaseous hydrogen — Fuelling protocols for hydrogen-fuelled vehicles — Part 1: Design and development process for fuelling protocols |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
27.075
Hydrogen technologies
;
43.060.40
Fuel systems
|
| ISO/CD 19887 |
Gaseous Hydrogen — Fuel system components for hydrogen fuelled vehicles |
|
Under development |
|
Edition : 1 |
|
Technical Committee |
27.075
Hydrogen technologies
;
43.060.40
Fuel systems
|
| ISO/DIS 24078 |
Hydrogen in energy systems — Vocabulary |
|
Under development |
|
Edition : 1 |
Number of pages : 44 |
Technical Committee |
27.075
Hydrogen technologies
;
01.040.27
Energy and heat transfer engineering (Vocabularies)
|
| ISO 8573-1:1991 |
Compressed air for general use — Part 1: Contaminants and quality classes |
|
Withdrawn |
1991-12 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-1:2001 |
Compressed air — Part 1: Contaminants and purity classes |
|
Withdrawn |
2001-02 |
Edition : 2 |
Number of pages : 8 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-1:2001/Cor 1:2002 |
Compressed air — Part 1: Contaminants and purity classes — Technical Corrigendum 1 |
|
Withdrawn |
2002-04 |
Edition : 2 |
Number of pages : 2 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-1:2010 |
Compressed air — Part 1: Contaminants and purity classes |
ISO 8573-1:2010 specifies purity classes of compressed air with respect to particles, water and oil independent of the location in the compressed air system at which the air is specified or measured.
ISO 8573-1:2010 provides general information about contaminants in compressed-air systems as well as links to the other parts of ISO 8573, either for the measurement of compressed air purity or the specification of compressed-air purity requirements.
In addition to the above-mentioned contaminants of particles, water and oil, ISO 8573-1:2010 also identifies gaseous and microbiological contaminants.
Guidance is given in Annex A on the application of ISO 8573-1:2010.
|
Published |
2010-04 |
Edition : 3 |
Number of pages : 9 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-2:1996 |
Compressed air for general use — Part 2: Test methods for aerosol oil content |
Describes test methods for the sampling and quantitative analysis of aerosol oil content and liquid oil (excluding oil vapour) normally present in the air discharged from compressors and compressed air systems. Gives detailed instructions on the equipment to be used and the test methods to be employed for the measurement of oil content. Applies to compressed air systems up to 30 bar working pressure, but excluding systems intended for medical use or for direct breathing.
|
Withdrawn |
1996-06 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-2:2007 |
Compressed air — Part 2: Test methods for oil aerosol content |
ISO 8573-2:2007 specifies test methods for the sampling and quantitative analysis of oil aerosols and liquid oil that can typically be present in compressed air. Test methods for oil vapour are excluded from ISO 8573-2:2007 as they are covered by ISO 8573-5.
Two different methods are described, method A and method B. Method B is subdivided into two parts to clearly distinguish between procedures for obtaining the quantity of oil for analysis.
|
Withdrawn |
2007-02 |
Edition : 2 |
Number of pages : 25 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO/IEC 9797-3:2011/Amd 1:2020 |
Information technology — Security techniques — Message Authentication Codes (MACs) — Part 3: Mechanisms using a universal hash-function — Amendment 1 |
|
Published |
2020-02 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
35.030
IT Security
|
| ISO 8573-2:2018 |
Compressed air — Contaminant measurement — Part 2: Oil aerosol content |
ISO 8573-2:2018 specifies test methods for the sampling and quantitative analysis of liquid oil and oil aerosols that can typically be present in compressed air. Test methods for oil vapour are excluded from this document as they are covered by ISO 8573‑5.
Two different methods are described, Method A and Method B. Method B is subdivided into two parts to clearly distinguish between procedures for obtaining the quantity of oil for analysis.
Method A describes an oil collection technique using inline coalescing filters whereas Method B utilizes sampling discs in a holder from which the collected oil is extracted with a solvent and analysed by infrared spectrometry or gas chromatography with flame ionization detection.
ISO 8573-2:2018 also includes descriptions of alternative oil aerosol detection by the use of indicator type devices, see Annex E.
|
Published |
2018-02 |
Edition : 3 |
Number of pages : 45 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-3:1999 |
Compressed air — Part 3: Test methods for measurement of humidity |
This part of ISO 8573 provides guidance on selection from the available suitable methods for measurement of
humidity in compressed air and specifies the limitations of the various methods.
It does not provide methods for measurement of water content in states other than vapour.
This part of ISO 8573 specifies sampling techniques, measurement, evaluation, uncertainty considerations and
reporting for the air contamination parameter humidity.
It gives guidance for the conversion of humidity statements to the standard format.
|
Published |
1999-06 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-4:2001 |
Compressed air — Part 4: Test methods for solid particle content |
|
Withdrawn |
2001-06 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-4:2001/Cor 1:2002 |
Compressed air — Part 4: Test methods for solid particle content — Technical Corrigendum 1 |
|
Withdrawn |
2002-04 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-4:2019 |
Compressed air — Contaminant measurement — Part 4: Particle content |
This document provides a method for sampling compressed air and a guide for choosing suitable measuring equipment to determine its particle size and concentration by number (to be referenced as "concentration" throughout this document). It also describes the limitations of the various measurement methods and describes the evaluation and uncertainty considerations.
This document will report the particle size and concentration of all types of particle combined and does not aim to be able to segregate the separate solid and liquid particle fractions. When it is required that the concentration of a specific fraction is to be determined then recourse to the relevant standard method from the ISO 8573 series is recommended.
NOTE 1 The test methods described in this document are those suitable for determining the purity classes given in ISO 8573‑1.
NOTE 2 Particle content determined as concentration by mass is dealt with in ISO 8573‑8.
NOTE 3 This document does not address instances where non-isothermal conditions exist, and separate arrangements should be made where particles may be formed by vapour condensation or lost through evaporation.
|
Published |
2019-02 |
Edition : 2 |
Number of pages : 26 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-5:2001 |
Compressed air — Part 5: Test methods for oil vapour and organic solvent content |
|
Published |
2001-12 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-6:2003 |
Compressed air — Part 6: Test methods for gaseous contaminant content |
ISO 8573-6:2003 provides a selection of suitable test methods for the measurement of contamination gases in compressed air. It specifies sampling technique, measurement and evaluation, uncertainty considerations and reporting for the applicable gaseous contaminants carbon monoxide, carbon dioxide, sulphur dioxide, nitric oxide, nitrogen dioxide, and hydrocarbons in the range C1 to C5 (see ISO 8573-5 for C6 and above). The methods given are also suitable for other gases.
|
Published |
2003-05 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-7:2003 |
Compressed air — Part 7: Test method for viable microbiological contaminant content |
ISO 8573-7:2003 specifies a test method for distinguishing viable, colony-forming, microbiological organisms (e.g. yeast, bacteria, endotoxins) from other solid particles which may be present in compressed air. One of a series of standards aimed at harmonizing air contamination measurements, it provides a means of sampling, incubating and determining the number of microbiological particles. The test method is suitable for determining purity classes in accordance with ISO 8573-1, and is intended to be used in conjunction with ISO 8573-4 when there is need to identify solid particles that are also viable, colony-forming units.
|
Published |
2003-05 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO/DIS 19880-2 |
Gaseous hydrogen — Fuelling stations — Part 2: Dispensers and dispensing systems |
This document describes the safety requirements and test methods for the components and systems
that enable the transfer of compressed hydrogen to a hydrogen vehicle as addressed in ISO 19880-1 by a hydrogen dispenser with dispensing pressures up to the H70 pressure class.
|
Under development |
|
Edition : 1 |
Number of pages : 33 |
Technical Committee |
43.060.40
Fuel systems
;
71.100.20
Gases for industrial application
|
| ISO 8573-8:2004 |
Compressed air — Part 8: Test methods for solid particle content by mass concentration |
ISO 8573-8:2004 specifies test methods for determining the solid particle mass concentration in compressed air, expressed as the mass of solid particles with maximum particle size limits. The methods' limitations are also specified. One of a series of standards aimed at harmonizing air contamination methods, it identifies sampling techniques and also gives requirements for evaluation, uncertainty considerations and reporting for the air purity parameter solid particles by mass concentration. The test methods are suitable for determining the purity classes in accordance with ISO 8573-1. (Particle content based on counting particles is dealt with in ISO 8573-4.)
|
Published |
2004-02 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 8573-9:2004 |
Compressed air — Part 9: Test methods for liquid water content |
ISO 8573-9:2004 specifies test methods for determining the liquid water content in compressed air, expressed as the liquid water mass concentration. The methods' limitations are also specified. One of a series of standards aimed at harmonizing air contamination methods, it identifies sampling techniques, specifies measurement procedures and also gives requirements for evaluation, uncertainty considerations and reporting for the air purity parameter liquid water. The test methods are suitable for determining the purity classes in accordance with ISO 8573-1. (Water vapour content is dealt with in ISO 8573-3.)
|
Published |
2004-02 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 10156-2:2005 |
Gas cylinders — Gases and gas mixtures — Part 2: Determination of oxidizing ability of toxic and corrosive gases and gas mixtures |
ISO 10156-2:2005 specifies a test and a calculation method to be used for determining whether or not a gas (or a gas mixture) is more oxidizing than air. It applies only to toxic and corrosive gases and gas mixtures.
|
Withdrawn |
2005-08 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10156:1990 |
Gases and gas mixtures — Determination of fire potential and oxidizing ability for the selection of cylinder valve outlets |
|
Withdrawn |
1990-12 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10156:1996 |
Gases and gas mixtures — Determination of fire potential and oxidizing ability for the selection of cylinder valve outlets |
Specifies two methods for determining whether or not a gas is flammable in air and whether a gas is more or less oxidizing than air. Replaces the first edition.
|
Withdrawn |
1996-02 |
Edition : 2 |
Number of pages : 12 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10156:2010 |
Gases and gas mixtures — Determination of fire potential and oxidizing ability for the selection of cylinder valve outlets |
ISO 10156:2010 specifies methods for determining whether or not a gas or gas mixture is flammable in air and whether a gas or gas mixture is more or less oxidizing than air under atmospheric conditions.
It is intended to be used for the classification of gases and gas mixtures including the selection of gas cylinder valve outlets.
It does not cover the safe preparation of these mixtures under pressure and at temperatures other than ambient.
|
Withdrawn |
2010-04 |
Edition : 3 |
Number of pages : 25 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10156:2010/Cor 1:2010 |
Gases and gas mixtures — Determination of fire potential and oxidizing ability for the selection of cylinder valve outlets — Technical Corrigendum 1 |
|
Withdrawn |
2010-09 |
Edition : 3 |
Number of pages : 1 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10156:2017 |
Gas cylinders — Gases and gas mixtures — Determination of fire potential and oxidizing ability for the selection of cylinder valve outlets |
ISO 10156:2017 specifies methods for determining whether or not a gas or gas mixture is flammable in air and whether a gas or gas mixture is more or less oxidizing than air under atmospheric conditions.
ISO 10156:2017 is intended to be used for the classification of gases and gas mixtures including the selection of gas cylinder valve outlets.
ISO 10156:2017 does not cover the safe preparation of these mixtures under pressure and at temperatures other than ambient.
|
Published |
2017-07 |
Edition : 4 |
Number of pages : 27 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 10298:1995 |
Determination of toxicity of a gas or gas mixture |
Describes a test method for the determination of the toxicity of a gas or gas mixture in order to eliminate difficulties involved in the application of ISO 5145. A calculation method enables the toxicity of gas mixtures to be determined in the absence of valid experimental data.
|
Withdrawn |
1995-12 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO/IEC 9797:1989 |
Data cryptographic techniques — Data integrity mechanism using a cryptographic check function employing a block cipher algorithm |
|
Withdrawn |
1989-11 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
35.030
IT Security
|
| ISO 12500-1:2007 |
Filters for compressed air — Test methods — Part 1: Oil aerosols |
ISO 12500-1:2007 specifies the test layout and test procedures required for testing coalescing filters used in compressed-air systems to determine their effectiveness in removing oil aerosols.
ISO 12500-1:2007 provides the means to indicate performance characteristics of the pressure drop and the capability of removing oil aerosols.
ISO 12500-1:2007 defines one method of presenting filter performance as outlet oil aerosol concentration stated in milligrams per cubic metre from results obtained under standard rating parameters.
|
Published |
2007-06 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
23.100.60
Filters, seals and contamination of fluids
;
71.100.20
Gases for industrial application
|
| ISO 12500-2:2007 |
Filters for compressed air — Test methods — Part 2: Oil vapours |
ISO 12500-2:2007 specifies the test layout and test procedures required for testing hydrocarbon vapour adsorbent filters used in compressed air systems to determine their effectiveness in removing hydrocarbon vapours. The performance characteristics to be identified are the adsorptive capacity and the pressure drop.
ISO 12500-2:2007 defines one method of presenting filter performance as hydrocarbon-vapour capacity, expressed in milligrams, from results obtained under test conditions.
|
Published |
2007-06 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
23.100.60
Filters, seals and contamination of fluids
;
71.100.20
Gases for industrial application
|
| ISO 13338:1995 |
Determination of tissue corrosiveness of a gas or gas mixture |
Gives a complete list of the corrosiveness for pure gases and a calculation method relating to the corrosiveness of gas mixtures which is applicable in the absence of experimental data to each of their components.
|
Withdrawn |
1995-11 |
Edition : 1 |
Number of pages : 10 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 13338:2017 |
Gas cylinders — Gases and gas mixtures — Determination of tissue corrosiveness for the selection of cylinder valve outlets |
ISO 13338:2017 provides:
- for pure gases and some liquids, a complete list indicating their corrosiveness;
- for gas mixtures, a calculation method, in the absence of experimental data, relating to the corrosiveness of each of their components;
in order to determine the corrosiveness of gases and gas mixtures on tissue so that a suitable outlet connection can be assigned to each of them.
|
Withdrawn |
2017-05 |
Edition : 2 |
Number of pages : 8 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 13338:2022 |
Gas cylinders — Gases and gas mixtures — Determination of corrosiveness for the selection of cylinder valve outlet |
This document specifies the following, in order to determine the corrosiveness of gases and gas mixtures so that a suitable outlet connection can be assigned to each of them:
— for pure gases and some liquids, a complete list indicating their corrosiveness;
— for gas mixtures, a calculation method, in the absence of experimental data, relating to the corrosiveness of each of their components.
|
Published |
2022-05 |
Edition : 3 |
Number of pages : 7 |
Technical Committee |
23.020.35
Gas cylinders
;
71.100.20
Gases for industrial application
|
| ISO 13984:1999 |
Liquid hydrogen — Land vehicle fuelling system interface |
This International Standard specifies the characteristics of liquid hydrogen refuelling and dispensing systems on land
vehicles of all types in order to reduce the risk of fire and explosion during the refuelling procedure and thus to provide
a reasonable level of protection from loss of life and property.
This International Standard is applicable to the design and installation of liquid hydrogen (LH2) fuelling and dispensing
systems. It describes the system intended for the dispensing of liquid hydrogen to a vehicle, including that portion of the
system that handles cold gaseous hydrogen coming from the vehicle tank, that is, the system located between the land
vehicle and the storage tank.
|
Published |
1999-03 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
43.060.40
Fuel systems
;
71.100.20
Gases for industrial application
|
| ISO 13985:2006 |
Liquid hydrogen — Land vehicle fuel tanks |
ISO 13985:2006 specifies the construction requirements for refillable fuel tanks for liquid hydrogen used in land vehicles as well as the testing methods required to ensure that a reasonable level of protection from loss of life and property resulting from fire and explosion is provided.
It is applicable to fuel tanks intended to be permanently attached to land vehicles.
|
Published |
2006-11 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
43.060.40
Fuel systems
;
71.100.20
Gases for industrial application
|
| ISO 14175:1997 |
Welding consumables — Shielding gases for arc welding and cutting |
|
Withdrawn |
1997-03 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
25.160.20
Welding consumables
;
71.100.20
Gases for industrial application
|
| ISO 15042:2017/Amd 1:2020 |
Multiple split-system air conditioners and air-to-air heat pumps — Testing and rating for performance — Amendment 1 |
|
Published |
2020-10 |
Edition : 2 |
Number of pages : 1 |
Technical Committee |
23.120
Ventilators. Fans. Air-conditioners
;
27.080
Heat pumps
|
| ISO 14175:2008 |
Welding consumables — Gases and gas mixtures for fusion welding and allied processes |
ISO 14175:2008 specifies requirements for the classification of gases and gas mixtures used in fusion welding and allied processes including, but not limited to:
tungsten arc welding (Process 141);
gas-shielded metal arc welding (Process 13);
plasma arc welding (Process 15);
plasma arc cutting (Process 83);
laser welding (Process 52);
laser cutting (Process 84);
arc braze welding (Process 972).
Process numbers are in accordance with ISO 4063.
The purpose of ISO 14175:2008 is to classify and designate shielding, backing, process and assist gases in accordance with their chemical properties and metallurgical behaviour as the basis for correct selection by the user and to simplify the possible qualification procedures.
|
Published |
2008-03 |
Edition : 2 |
Number of pages : 9 |
Technical Committee |
25.160.20
Welding consumables
;
71.100.20
Gases for industrial application
|
| ISO 14687-1:1999 |
Hydrogen fuel — Product specification — Part 1: All applications except proton exchange membrane (PEM) fuel cell for road vehicles |
|
Withdrawn |
1999-03 |
Edition : 1 |
Number of pages : 9 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14687-2:2012 |
Hydrogen fuel — Product specification — Part 2: Proton exchange membrane (PEM) fuel cell applications for road vehicles |
ISO 14687-2:2012 specifies the quality characteristics of hydrogen fuel in order to ensure uniformity of the hydrogen product as dispensed for utilization in proton exchange membrane (PEM) fuel cell road vehicle systems.
|
Withdrawn |
2012-12 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
43.060.40
Fuel systems
;
71.100.20
Gases for industrial application
|
| ISO/TS 14687-2:2008 |
Hydrogen fuel — Product specification — Part 2: Proton exchange membrane (PEM) fuel cell applications for road vehicles |
ISO/TS 14687-2:2008 specifies the quality characteristics of hydrogen fuel in order to assure uniformity of the hydrogen product as dispensed for utilization in proton exchange membrane (PEM) fuel cell road vehicle systems.
|
Withdrawn |
2008-03 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
43.060.40
Fuel systems
;
71.100.20
Gases for industrial application
|
| ISO 14687-3:2014 |
Hydrogen fuel — Product specification — Part 3: Proton exchange membrane (PEM) fuel cell applications for stationary appliances |
ISO 14687-3:2014 specifies the quality characteristics of hydrogen fuel in order to ensure uniformity of the hydrogen product for utilization in stationary proton exchange membrane (PEM) fuel cell power systems.
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Withdrawn |
2014-02 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14687:2019 |
Hydrogen fuel quality — Product specification |
This document specifies the minimum quality characteristics of hydrogen fuel as distributed for utilization in vehicular and stationary applications.
It is applicable to hydrogen fuelling applications, which are listed in Table 1.
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Published |
2019-11 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14687-1:1999/Cor 1:2001 |
Hydrogen fuel — Product specification — Part 1: All applications except proton exchange membrane (PEM) fuel cell for road vehicles — Technical Corrigendum 1 |
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Withdrawn |
2001-04 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14687-1:1999/Cor 2:2008 |
Hydrogen fuel — Product specification — Part 1: All applications except proton exchange membrane (PEM) fuel cell for road vehicles — Technical Corrigendum 2 |
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Withdrawn |
2008-03 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO/CD 14687 |
Hydrogen fuel quality — Product specification |
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Under development |
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Edition : 2 |
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Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14951-2:1999 |
Space systems — Fluid characteristics — Part 2: Hydrogen propellant |
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Withdrawn |
1999-09 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
49.140
Space systems and operations
;
71.100.20
Gases for industrial application
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| ISO/TR 15916:2004 |
Basic considerations for the safety of hydrogen systems |
ISO/TR 15916:2004 provides guidelines for the use of hydrogen in its gaseous and liquid forms. It identifies the basic safety concerns and risks, and describes the properties of hydrogen that are relevant to safety. Detailed safety requirements associated with specific hydrogen applications are treated in separate International Standards.
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Withdrawn |
2004-02 |
Edition : 1 |
Number of pages : 61 |
Technical Committee |
71.020
Production in the chemical industry
;
71.100.20
Gases for industrial application
|
| ISO 18122:2015 |
Solid biofuels — Determination of ash content |
ISO 18122:2015 specifies a method for the determination of ash content of all solid biofuels.
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Withdrawn |
2015-10 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
27.190
Biological sources and alternative sources of energy
;
75.160.40
Biofuels
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| ISO/TR 15916:2015 |
Basic considerations for the safety of hydrogen systems |
ISO/TR 15916:2015 provides guidelines for the use of hydrogen in its gaseous and liquid forms as well as its storage in either of these or other forms (hydrides). It identifies the basic safety concerns, hazards and risks, and describes the properties of hydrogen that are relevant to safety. Detailed safety requirements associated with specific hydrogen applications are treated in separate International Standards.
"Hydrogen" in this paper means normal hydrogen (1H2), not deuterium (2H2) or tritium (3H2).
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Published |
2015-12 |
Edition : 2 |
Number of pages : 62 |
Technical Committee |
71.020
Production in the chemical industry
;
71.100.20
Gases for industrial application
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| ISO/AWI TR 15916 |
Basic considerations for the safety of hydrogen systems |
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Under development |
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Edition : 3 |
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Technical Committee |
71.020
Production in the chemical industry
;
71.100.20
Gases for industrial application
|
| ISO 16110-1:2007 |
Hydrogen generators using fuel processing technologies — Part 1: Safety |
ISO 16110-1:2007 applies to packaged, self-contained or factory matched hydrogen generation systems with a capacity of less than 400 m3/h at 0 °C and 101,325 kPa, herein referred to as hydrogen generators, that convert an input fuel to a hydrogen-rich stream of composition and conditions suitable for the type of device using the hydrogen (e.g. a fuel cell power system or a hydrogen compression, storage and delivery system).
It applies to hydrogen generators using one or a combination of the following input fuels:
— natural gas and other methane-rich gases derived from renewable (biomass) or fossil fuel sources, e.g. landfill gas, digester gas, coal mine gas;
— fuels derived from oil refining, e.g. diesel, gasoline, kerosene, liquefied petroleum gases such as propane and butane;
— alcohols, esters, ethers, aldehydes, ketones, Fischer-Tropsch liquids and other suitable hydrogen-rich organic compounds derived from renewable (biomass) or fossil fuel sources, e.g. methanol, ethanol, di-methyl ether, biodiesel;
— gaseous mixtures containing hydrogen gas, e.g. synthesis gas, town gas.
ISO 16110-1:2007 is applicable to stationary hydrogen generators intended for indoor and outdoor commercial, industrial, light industrial and residential use.
It aims to cover all significant hazards, hazardous situations and events relevant to hydrogen generators, with the exception of those associated with environmental compatibility (installation conditions), when they are used as intended and under the conditions foreseen by the manufacturer.
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Published |
2007-03 |
Edition : 1 |
Number of pages : 75 |
Technical Committee |
71.020
Production in the chemical industry
;
71.100.20
Gases for industrial application
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| ISO 16110-2:2010 |
Hydrogen generators using fuel processing technologies — Part 2: Test methods for performance |
ISO 16110-2:2010 provides test procedures for determining the performance of packaged, self-contained or factory matched hydrogen generation systems with a capacity less than 400 m3/h at 0 °C and 101,325 kPa, referred to as hydrogen generators, that convert a fuel to a hydrogen‑rich stream of composition and conditions suitable for the type of device using the hydrogen (e.g. a fuel cell power system, or a hydrogen compression, storage and delivery system).
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Published |
2010-02 |
Edition : 1 |
Number of pages : 38 |
Technical Committee |
71.020
Production in the chemical industry
;
71.100.20
Gases for industrial application
|
| ISO 16111:2008 |
Transportable gas storage devices — Hydrogen absorbed in reversible metal hydride |
ISO 16111:2008 defines the requirements applicable to the material, design, construction, and testing of transportable hydrogen gas storage systems, referred to as “metal hydride assemblies” (MH assemblies) which utilize shells not exceeding 150 l internal volume and having a maximum developed pressure (MDP) not exceeding 25 MPa (250 bar).
It only applies to refillable storage MH assemblies where hydrogen is the only transferred media. Storage MH assemblies intended to be used as fixed fuel-storage onboard hydrogen fuelled vehicles are excluded.
ISO 16111:2008 is intended to be used for certification purposes.
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Withdrawn |
2008-11 |
Edition : 1 |
Number of pages : 38 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO/TS 16111:2006 |
Transportable gas storage devices — Hydrogen absorbed in reversible metal hydride |
ISO/TS 16111:2006 defines the requirements applicable to the safe design and use of transportable hydrogen gas storage canisters, including all necessary shut-off valve, pressure-relief devices (PRD), and appurtenances, intended for use with reversible metal hydride hydrogen storage systems. ISO/TS 16111:2006 only applies to refillable storage canisters where hydrogen is the only transferred media. Storage canisters intended to be used as fixed fuel storage onboard hydrogen fuelled vehicles are excluded.
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Withdrawn |
2006-10 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 16111:2018 |
Transportable gas storage devices — Hydrogen absorbed in reversible metal hydride |
This document defines the requirements applicable to the material, design, construction, and testing of transportable hydrogen gas storage systems, referred to as "metal hydride assemblies" (MH assemblies) which utilize shells not exceeding 150 l internal volume and having a maximum developed pressure (MDP) not exceeding 25 MPa.
This document is applicable to refillable storage MH assemblies where hydrogen is the only transferred media. It is not applicable to storage MH assemblies intended to be used as fixed fuel-storage onboard hydrogen fuelled vehicles.
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Published |
2018-08 |
Edition : 2 |
Number of pages : 43 |
Technical Committee |
71.100.20
Gases for industrial application
|
| ISO 14084-1:2015 |
Process diagrams for power plants — Part 1: Specification for diagrams |
ISO 14084-1:2015 specifies types of process diagrams for power plants and rules and guidelines for the preparation and representation of information in such diagrams.
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Published |
2015-06 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
27.100
Power stations in general
;
01.080.30
Graphical symbols for use on mechanical engineering and construction drawings, diagrams, plans, maps and in relevant technical product documentation
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| ISO 17268:2006 |
Compressed hydrogen surface vehicle refuelling connection devices |
ISO 17268:2006 applies to design, safety and operation verification of Compressed Hydrogen Surface Vehicle (CHSV) refuelling connection devices hereinafter referred to as nozzle and receptacle. CHSV Refuelling nozzles and receptacles consist of the following components, as applicable:
Receptacle and protective cap (mounted on vehicle); andNozzle.
ISO 17268:2006 applies to devices which have working pressures of 25 MPa and 35 MPa, hereinafter referred to as the following:
H25 - 25 MPa at 15 °CH35 - 35 MPa at 15 °C
ISO 17268:2006 applies to nozzles and receptacles which (1) prevent hydrogen fuelled vehicles from being refuelled by dispenser stations with working pressures higher than the vehicle; (2) allow hydrogen vehicles to be refuelled by dispenser stations with working pressures equal to or lower than the vehicle fuel system working pressure; (3) prevent hydrogen fuelled vehicles from being refuelled by other compressed gases dispensing stations; and (4) prevent other gaseous fuelled vehicles from being refuelled by hydrogen dispensing stations.
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Withdrawn |
2006-04 |
Edition : 1 |
Number of pages : 19 |
Technical Committee |
43.180
Diagnostic, maintenance and test equipment
;
71.100.20
Gases for industrial application
|
| ISO 17268:2012 |
Gaseous hydrogen land vehicle refuelling connection devices |
ISO 17268:2012 defines the design, safety and operation characteristics of gaseous hydrogen land vehicle (GHLV) refuelling connectors consisting of, as applicable, a receptacle and a protective cap (mounted on vehicle), and a nozzle.
It applies to refuelling connectors which have working pressures of 11 MPa, 25 MPa, 35 MPa and 70 MPa, referred to as
H11 - 11 MPa at 15 °C,
H25 - 25 MPa at 15 °C,
H35 - 35 MPa at 15 °C,
H35HF - 35 MPa at 15 °C (high flow for commercial vehicle applications), and
H70 - 70 MPa at 15 °C.
Nozzles and receptacles that meet the requirements of ISO 17268:2012 will only allow GHLVs to be filled by fuelling stations dispensing hydrogen with nominal working pressures equal to or lower than the vehicle fuel system working pressure. They will not allow GHLV to be filled by fuelling stations dispensing blends of hydrogen with natural gas.
Refuelling connectors dispensing blends of hydrogen with natural gas are excluded from the scope of ISO 17268:2012.
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Withdrawn |
2012-12 |
Edition : 2 |
Number of pages : 35 |
Technical Committee |
43.180
Diagnostic, maintenance and test equipment
;
71.100.20
Gases for industrial application
|
| ISO 17268:2020 |
Gaseous hydrogen land vehicle refuelling connection devices |
This document defines the design, safety and operation characteristics of gaseous hydrogen land vehicle (GHLV) refuelling connectors.
GHLV refuelling connectors consist of the following components, as applicable:
— receptacle and protective cap (mounted on vehicle);
— nozzle;
— communication hardware.
This document is applicable to refuelling connectors which have nominal working pressures or hydrogen service levels up to 70 MPa.
This document is not applicable to refuelling connectors dispensing blends of hydrogen with natural gas.
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Published |
2020-02 |
Edition : 3 |
Number of pages : 45 |
Technical Committee |
43.180
Diagnostic, maintenance and test equipment
;
71.100.20
Gases for industrial application
|