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This document specifies the types and order of tests for application to the airbag modules and sets out the acceptance criteria and means of categorization.

 

This document specifies the types and order of tests to be applied to the seatbelt pretensioners and sets out the associated acceptance criteria and means of categorization.

 

This document specifies the types and order of tests to be applied to the igniter and sets out the acceptance criteria and means of categorization.

 

This part of ISO/IEC 7816 specifies the power and signal structures, and information exchange between an integrated circuit card and an interface device such as a terminal. It also covers signal rates, voltage levels, current values, parity convention, operating procedure, transmission mechanisms and communication with the card. It does not cover information and instruction content, such as identification of issuers and users, services and limits, security features, journaling and instruction definitions.

 

This document provides guidance for the design, manufacture, and testing of pressure vessels to meet the performance criteria at the time of installation for the stationary storage of gaseous hydrogen. Pressure vessels fabricated of seamless metallic or welded construction (Type 1) or of composite construction (Types 2, 3, 4), regardless of reinforcement (metallic or non-metallic), are covered by this standard. This standard can be applied to pressure receptacles as defined in iso:pub:std:FDIS:79732ISO 10286:2021within the volume and pressure limits provided below. This document is not applicable to pressure vessels used for: a) solid storage matrix for hydrogen, b) liquid hydrogen, c) hybrid cryogenic high-pressure hydrogen storage applications, d) or on-board vehicle storage. This document is not applicable to closures, valves, fittings, plugs or external piping.

 

This document describes methodologies that can be applied to estimate the greenhouse gas (GHG) emissions associated with the conditioning, storage and transport of gaseous and liquid hydrogen up to the consumption gate. GHG emissions from cradle to gate (well-to-consumption gate) in the hydrogen supply chain can be assessed by combining iso:proj:88686ISO/DIS 19870-1, which defines methodologies for determining the GHG emissions associated with various pathways of hydrogen production, with this document. ISO 14044 [3] requires the goal and scope of a life cycle assessment (LCA) be clearly defined and be consistent with the intended application. Due to the iterative nature of LCA, it is possible that the LCA scope needs to be refined during the study. According to ISO 14040:2006 [4], Annex A2, the goals and scope of LCAs correspond to one of the following two approaches: a) an approach that assigns elementary flows and potential environmental impacts to a specific product system, typically as an account of the history of the product (see 4.1.2); b) an approach that studies the environmental consequences of possible (future) changes between alternative product systems (see 4.1.3). In this document, approach a) is referred to as an attributional approach, while approach b) is referred to as consequential approach. Complementary information is accessible in the ILCD handbook[5]. A carbon footprint of a product or partial CFP as defined by iso:proj:71206ISO 14067 can be estimated using either the attributional or the consequential approach, the latter corresponding to the use of “system expansion via substitution” to avoid allocation when a unit process yields multiple co-products.

 

This document describes methodologies that can be applied to estimate the greenhouse gas (GHG) emissions associated with the production of ammonia, its storage and transport, and the conversion of ammonia into hydrogen. The transport of hydrogen from the ammonia cracking facility to any delivery point up to the hydrogen consumption gate is covered in ISO 19870-2 (see Figure 2). This document describes in the annexes the requirements and evaluation methods applied to several ammonia production pathways of interest. It also describes the requirements and evaluation methods applied to several ammonia cracking pathways of interest. This document considers the GHG emissions associated with ammonia production up to the delivery gate. This document applies to and includes every steps from ammonia production to any ammonia delivery gate and to ammonia cracking. ISO 14044 requires the goal and scope of an LCA to be clearly defined and be consistent with the intended application. Due to the iterative nature of LCAs, it is possible that the LCA scope needs to be refined during the study. The goals and scopes of the methodologies correspond to either approach a) or b), given below, that iso:proj:37456ISO 14040:2006, Annex A2 gives as two possible approaches to LCAs. a) An approach that assigns elementary flows and potential environmental impacts to a specific product system, typically as an account of the history of the product. See 4.1.2. b) An approach that studies the environmental consequences of possible (future) changes between alternative product systems. See 4.1.3. In this document, approach (a) is referred to as an attributional approach, while approach (b) is referred to as a consequential approach. Complementary information is accessible in the ILCD handbook [1]. A Carbon Footprint of a Product or Partial Carbon Footprint of a Product as defined by ISO 14067 may be estimated using either the attributional or the consequential approach, the latter corresponding to the use of “system expansion via substitution” to avoid allocation when a unit process yields multiple co-products. Complementary documents in the ISO 19870-X series will consider hydrogen production and other conditioning, conversion and transport methods.

 

ISO 20492-1 specifies two methods for testing the durability of edge seals of insulating glass units by means of climate tests: the final frost/dew point method and the moisture-penetration index method. This document is applicable to pre-assembled, permanently sealed, insulating glass units with one or two cavities, and with capillary tubes that are intentionally left open to equalize pressure inside the unit with the surrounding atmosphere. This document is not applicable to sealed, insulating glass units that contain a spandrel glass coating. This document does not apply to insulating glass (IG) units whose function is decorative only.

 

This document establishes two methods for testing the resistance to fogging of pre-assembled, permanently sealed insulating glass units or insulating glass units with capillary tubes intentionally left open. This document is not applicable to sealed, insulating glass units containing a spandrel glass coating due to testing limitations. This document does not apply to insulating glass (IG) units whose function is decorative only.

 

This document specifies two methods of test for insulating glass units, including a determination of the gas leakage rate and a determination of gas concentration tolerances. This document is applicable to pre-assembled, permanently sealed, insulating glass units with one or two cavities. It is not applicable to insulating glass units with capillary or breather tubes.

 

ISO 20492-4 specifies methods for testing the edge seal strength, and partially testing the water and gas permeation through sealants, of glass insulating units. Other parts of ISO 20492 designate two approaches to the standardization of insulating glass units. The methods in ISO 20492-4 are applicable only to approach 2, as defined and used in the other parts of ISO 20492. In cases where there is no protection against direct ultraviolet radiation at the edges, such as structural sealant glazing systems, it is necessary that additional European technical specifications be followed. See References [4] and [5].

 

 

This part of ISO 15638 provides the following for cooperative telematics applications for regulated commercial freight vehicles (4.37): a) A framework (4.20) for the provision of cooperative telematics application services for regulated commercial freight vehicles; b) A description of the concept of operation, regulatory aspects and options and the role models; c) A conceptual architecture (4.7) using an on-board unit and wireless communications to a regulator (4.25) or its agent; d) References for the key documents on which the architecture (4.7) is based; e) Details of the architecture (4.7) of the Facilities Layer; f) A taxonomy of the organisation of generic procedures; g) Common terminology for the ISO 15638 family of standards. This part of ISO 15638 is based on a (multiple) service provider (4.39) oriented approach. ISO 15638 has been developed for use in the context of regulated commercial freight vehicles. There is nothing however to prevent a jurisdiction extending or adapting the scope to include other types of regulated vehicles, as it deems appropriate. NOTE The specific ‘approval’ procedures for specific application services are a matter for the jurisdiction (4.24) and are outside the scope of this (or any) part of 15638. However, approval authorities (4.6) are encouraged to use the guidance of ISO 17000 and ISO/IEC 17065:2012 when developing and implementing such procedures.

 

In general terms, Miner’s rule is a common approach to calculate how the accumulation of a specific load that varies over time effects the time until failure. This international standard specifies the application of Miner’s rule for calculating the design time until failure of plastics pipes and piping systems of plastics materials under varying, but known, load conditions. Miner’s rule can also be applied reciprocally to calculate the tolerable load levels along a desired design time. This international standard specifies particularly the application of Miner’s rule to calculate stress or pressure regimes, respectively, that are tolerable during a targeted design time for plastics or composite pipes. Further, the application of Miner’s rule on the effect of accumulated damage on polyolefins caused by oxidative attack under varying temperatures and times on the design life is specified. It is necessary to apply Miner's rule to each failure mechanism separately. Thus, for mechanical failure due to internal pressure, other failure mechanisms, such as oxidative or dehydrochlorinative degradative failure mechanisms, are to be neglected (assuming, of course, no interaction). A material may be used only when it is proven to conform to all failure mechanism criteria. NOTE Miner's rule is an empirically based procedure and is only a first approximation to reality.

 

This document specifies a test method to determine if a fitting will fail in crushing mode under compression before a predefined percentage deformation of moulded fittings for thermoplastics piping systems and recommends a specification (see annex A). It applies to fittings made from unplasticized poly(vinyl chloride) (PVC-U), high-impact poly(vinyl chloride) (PVC-HI), chlorinated poly(vinyl chloride)(PVC-C), polyethylene(PE), polypropylene(PP), Acrylonitrile-butadiene-styrene (ABS), Poly (vinylidene difluoride) (PVDF),and poly(phenyl sulfone)(PPSU). It can be applied to moulded fittings made from other thermoplastics as well. However, the test conditions should be taken into consideration.

 

This document specifies procedures and data exchange format interface(s) between sensor fusion actors in P-ITS-S (nomadic device), V-ITS-S, R-ITS-S and C-ITS-S for seamless positioning by nomadic device. This document defines the process for coordinating and sharing PVT datasets among ITS components, including P-ITS-S, V-ITS-S, R-ITS-S, and C-ITS-S, for each specific use case. This document does not provide data security and authentication protocols.

 

This document defines the top-level semantic architecture of Traditional Chinese Medicine (TCM) informatics as a discipline. It establishes a unified framework for representing and organizing TCM knowledge — including theoretical concepts, diagnostic reasoning, treatment principles, and related terminology — in a form understandable to both humans and computer systems. The framework incorporates a categorial structure to formalize the relationships among concepts and knowledge entities within TCM, providing the semantic basis for data interoperability, knowledge sharing, and computational reasoning. It supports consistent exchange and integration of TCM information across clinical documentation, research databases, education systems, and AI-driven decision-support applications.

 

This document specifies a method for determination of the content of mercury (Hg) using (cold) vapour generation apparatus coupled to an atomic absorption spectrophotometer and a method using a direct amalgamation technique. It is applicable to aqua regia digests prepared according to prEN 17768. It is applicable to organic fertilizers and organo-mineral fertilizers. This document is applicable to the fertilizing product blends where a blend is a mix of at least two of the following components: fertilizers, liming materials, soil improvers, growing media, inhibitors, plant biostimulants and where the following category: organic fertilizers or organo-mineral fertilizers is the highest % in the blend by mass or volume, or in case of liquid form by dry mass. If organic fertilizers and organo-mineral fertilizers are not the highest % in the blend, the European Standard for the highest % of the blend applies. In case a fertilizing product blend is composed of components in equal quantity, the user decides which standard to apply. Variations in analytical methods for fertilizing product blends can lead to differing results as some components or matrix interactions can affect the outcome. Validation procedures have shown that developed standard methods are robust and reliable across diverse product compositions, but possible interferences and unexpected results when analysing fertilizing product blends are possible. NOTE It is also possible to use other suitable methods for the determination of mercury described in Annex A if users prove that the method gives the same results as the methods described in this document.

 

This document specifies the procedure for the determination and calculation of the dry matter content of organic and organo-mineral fertilizers for which the results of the performed analysis are to be calculated to the dry matter content basis. This document is applicable and validated for several types of matrices as indicated in Annex A. This document is applicable to the component materials “by-products”, “thermal oxidation materials and derivatives”, or “recovered high-purity materials”, when used as components of fertilizing products, as well as the fertilizing products blends where a blend is a mix of at least two of the following components: fertilizers, liming materials, soil improvers, growing media, inhibitors, plant biostimulants and where the following category organic fertilizers, organo-mineral fertilizers is the highest % in the blend by mass or volume, or in the case of liquid form by dry mass. If the organic fertilizer or the organo-mineral fertilizers is not the highest % in the blend, the European Standard for the highest % of the blend applies. In case a fertilizing product blend is composed of components in equal quantity, the user decides which standard to apply. Variations in analytical methods for fertilizing product blends can lead to differing results as some components or matrix interactions can affect the outcome. Validation procedures have shown that developed standard methods are robust and reliable across diverse product compositions, but possible interferences and unexpected results when analysing fertilizing product blends are possible.

 

This document specifies the characteristics of valves made from polyethylene (PE) for piping systems in the field of the supply of gaseous fuels. NOTE 1 For the purpose of this document the term gaseous fuels include for example natural gas, methane, butane, propane, hydrogen, manufactured gas, biogas, and mixtures of these gases. It is applicable to unidirectional and bi-directional isolating valves with spigot ends or electrofusion sockets intended to be fused with PE pipes or fittings conforming to ISO/DIS 4437-2 and ISO/DIS 4437-3 respectively. Valves made from materials other than PE, designed for the supply of gaseous fuels conforming to the relevant standards can be used in PE piping systems according to ISO 4437 series, provided that they have PE connections for butt fusion or electrofusion ends, including integrated material transition joints, conforming to ISO/DIS 4437-3. It also specifies the test parameters for the test methods referred to in this document. In conjunction with parts 1, 2, 3 and 5 of the ISO/DIS 4437 series, it is applicable to PE valves, their joints and to joints with components of PE and other materials intended to be used under the following conditions: a) a maximum operating pressure, MOP, up to and including 10 bar11 1 bar = 0,1 MPa =105 Pa; 1 MPa = 1 N/mm2. at a reference temperature of 20 °C for design purposes; b) an operating temperature between -20 °C to 40 °C. ISO/DIS 4437 (all parts) covers a range of maximum operating pressures and gives requirements concerning colours. It is the responsibility of the purchaser or specifier to make the appropriate selections from these aspects, taking into account their particular requirements and any relevant national regulations and installation practices or codes. This document covers valve bodies designed for connection with pipes with a nominal outside diameter dn = 400 mm.