K82 化学电源 标准查询与下载

JIS C 8500:2017 原电池.总则

Primary batteries -- General

BS EN 62282-4-102:2017 燃料电池技术.电动工业卡车燃料电池动力系统.性能试验方法

Fuel cell technologies. Fuel cell power systems for industrial electric trucks. Performance test methods

BS EN 60623:2017 含有碱性或其他非酸性电解质的二次电池和电池组 通风镍镉方形可充电单电池

Secondary cells and batteries containing alkaline or other non-acid electrolytes. Vented nickel-cadmium prismatic rechargeable single cells

DIN EN 60086-5:2017 原电池.第5部分:水溶液电解质电池安全(IEC 60086-5-2016);德文版本EN 60086-5-2016

Primary batteries - Part 5: Safety of batteries with aqueous electrolyte (IEC 60086-5:2016); German version EN 60086-5:2016

IEC 62282-4-102:2017 燃料电池技术. 第4-102部分: 电动工业卡车燃料电池动力系统. 性能试验方法

This document covers performance test methods of fuel cell power systems intended to be used for electrically powered industrial trucks. The scope of this document is limited to electrically powered industrial trucks. Hybrid trucks that include an internal combustion engine are not included in the scope. The scope of this standard will be applicable to material-handling equipment, e. g. forklifts. This document applies to gaseous hydrogen-fuelled fuel cell power systems and direct methanol fuel cell power systems for electrically powered industrial trucks. The following fuels are considered within the scope of this standard: gaseous hydrogen, and; methanol. This document does not apply to reformer-equipped fuel cell power systems. This document covers fuel cell power systems whose fuel source container is permanently attached to either the industrial truck or the fuel cell power system. A fuel source container of the detachable type is not permitted. This document applies to DC type fuel cell power systems, with a rated output voltage not exceeding 150 V DC for indoor and outdoor use. Fuel cell power systems intended for operation in potentially explosive atmospheres are excluded from the scope of this document. This document does not cover the fuel storage systems using liquid hydrogen. All systems with integrated energy storage systems are covered by this document. This includes systems, for example, batteries for internal recharges or recharged from an external source.

Fuel cell technologies - Part 4-102: Fuel cell power systems for industrial electric trucks - Performance test methods

DIN EN 60086-3:2017 原电池.第3部分:手表电池(IEC 60086-3-2016);德文版本EN 60086-3-2016

Primary batteries - Part 3: Watch batteries (IEC 60086-3:2016); German version EN 60086-3:2016

BS EN 62282-6-200:2017 燃料电池技术 微型燃料电池动力系统 性能测试方法

Fuel cell technologies. Micro fuel cell power systems. Performance test methods

IEC TS 62282-7-1:2017 燃料电池技术.第7-1部分:试验方法.燃料电池(PEFC)用单电池性能测试

This document covers cell assemblies, test station setup, measuring instruments and measuring methods, performance test methods, and test reports for PEFC single cells. This document is used for evaluating: a) the performance of membrane electrode assemblies (MEAs) for PEFCs in a single cell configuration; b) materials or structures of PEFCs in a single cell configuration; or, c) the influence of impurities in fuel and/or in air on the fuel cell performance.

Fuel cell technologies - Part 7-1: Test methods - Single cell performance tests for polymer electrolyte fuel cells (PEFC)

ASTM D7606-17 高压氢气和相关燃料电池原料气体取样的标准实施规程

5.1  Hydrogen is delivered to fuel cell powered automotive vehicles and stationary appliances at pressures up to 87.5 MPa. The quality of hydrogen delivered is a significant factor in maximizing fuel cell efficiency and life span. Contamination can occur during the production of fuel cell feed gases, contaminating storage containers, station tubing, and fuel lines used for fuel delivery. Collection of a representative fuel sample without the introduction of contaminants even as low as parts-per-billion (ppb) per contaminant during collection is crucial for assessing the quality of fuel in real world applications. 5.2 This practice is intended for application to high pressure, high purity hydrogen; however, the apparatus design and sampling techniques may be applicable to collection of other fuel cell feed gases. Many of the techniques used in this practice can be applied to lower pressure/lower purity gas streams. 1.1 This standard practice describes a sampling procedure of high pressure hydrogen at fueling stations operating at 35 or 70 megapascals (MPa) using a hydrogen quality sampling apparatus (HQSA). 1.2 This practice does not include the analysis of the acquired sample. Applicable ASTM standards include but are not limited to test methods referenced in Section 2 of this practice. 1.3 This practice is not intended for sampling and measuring particulate matter in high pressure hydrogen. For procedures on sampling and measuring particulate matter see ASTM D7650 and D7651. 1.4 The values stated in SI units are standard. The values stated in inch-pounds are for information only. 1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard Practice for Sampling of High Pressure Hydrogen and Related Fuel Cell Feed Gases

BS EN 60086-3:2016 原电池.手表电池

Primary batteries. Watch batteries

BS EN 60086-2:2016 原电池.物理和电气规范

Primary batteries. Physical and electrical specifications

BS EN 60086-5:2016 原电池.水电解质电池的安全性

Primary batteries. Safety of batteries with aqueous electrolyte

BS EN 60086-1:2016 原电池.概述

Primary batteries. General

IEC 62282-3-400:2016 燃料电池技术. 第3-400部分: 固定式燃料电池动力系统. 带热电联合输出的小型固定式燃料电池动力系统

This part of IEC 62282 applies to small stationary fuel cell power systems serving as a heating appliance providing both electric power and useful heat with or without a supplementary heat generator providing peak load function. This standard applies to fuel cell power systems that are intended to be permanently connected to the electrical system of the customer (end user). Direct connection to the mains (parallel operation) is also within the scope of this standard. NOTE 1 Parallel operation is subject to the permission of the local electric power supply utility. This standard is limited to gas and liquid fuelled fuel cell CHP appliances that have a heat input based on lower heating value of less than or equal to 70 kW. For some regional applications@ the output electric power is limited. Specific limitations are given in Clause C.1 for Japan. This standard applies to systems as shown in Figure 1. One is a system where both stationary fuel cell power system and supplementary heat generator are installed in one enclosure without any partition. This standard does not have to apply to the supplementary heat generator of systems where the stationary fuel cell power system and the supplementary heat generator are not built in one enclosure@ and whose ducts are not common (that is@ each appliance has its own dedicated duct system). This standard applies to systems intended for operation on the following supplied input fuels: ?C natural gas and other methane rich gases; ?C fuels derived from oil refining (liquefied petroleum gases@ propane@ and butane); ?C hydrogen as supply gas for the CHP generator. NOTE 2 It is possible that other fuels such as alcohols (methanol@ ethanol)@ kerosene@ or hydrogen for the supplementary heat generatorwill be added in future amendments or revisions. This part of IEC 62282 applies to systems where: ?C the heat transfer fluid (heat output) is water or a mixture of water and additives to prevent corrosion and to prevent freezing; ?C the heat transfer fluid circuit (heat output) can be designed for open or sealed operation; ?C the maximum temperature of the heat transfer fluid (heat output) does not exceed 100 ?? or the value given in Clause B.1 for Europe or in Clause D.1 for the USA; ?C the maximum pressure of the heat transfer fluid (heat output) circuit does not exceed 0@3 MPa@ or the limits given in Clause B.1 for Europe@ or C.4.3 for Japan or Clause D.1 for the USA; ?C the maximum pressure of the domestic hot water circuit@ if installed@ does not exceed 0@1 MPa@ or the limits as given in Clause D.1 for the USA. This standard applies to systems with either condensing or non-condensing conditions in the exhaust gas. This standard applies to appliances ?C with ducts included as part of the appliance (Type B@ Type C) and ?C without ducts (Type A) Duct systems are shown in Annex F. The chimney in the figures is part of the building and is not within the scope of this standard. Different combustion air/flue duct circuit configurations are accommodated@ see Annex F. This standard applies to both indoor and outdoor installations. This standard applies to type testing only. This standard specifies the requirements for construction@ safety@ installation@ fitness for purpose@ rational use of energy@ marking@ and performance measurement of these appliances. This standard also provides regional and country specific requirements to facilitate the worldwide application of this IEC standard. These essential regional and country specific requirements are given in Annex B for Europe@ in Annex C for Japan and in Annex D for the USA. If the user or manufacturer chooses a regional specific annex to apply this standard@ then that annex applies to the appliance in its entirety without mixing requirements between annexes. The chosen regional or country specific annex becomes normative

Fuel cell technologies - Part 3-400: Stationary fuel cell power systems - Small stationary fuel cell power system with combined heat and power output

DB44/T 1885-2016 无人机用锂离子电池组 技术要求

航拍、植保、消防等民用无人机用锂离子电池组

Technical requirements for lithium-ion battery packs for drones

SN/T 1414.5-2016 进出口蓄电池安全检验方法 第5部分：电动汽车用单体锂离子电池

Safety Inspection Methods for Imported and Exported Batteries Part 5: Single Lithium-Ion Batteries for Electric Vehicles

NB/T 42082-2016 全钒液流电池 电极测试方法

All-vanadium redox flow battery electrode testing method

NB/T 42081-2016 全钒液流电池 单电池性能测试方法

All-vanadium redox flow battery single cell performance test method

NB/T 42080-2016 全钒液流电池用离子传导膜 测试方法

Test method for ion conductive membranes for all-vanadium redox flow batteries

IEC 60086-5:2016 原电池组.第5部分:电解质为水溶液的电池组的安全性

This part of IEC 60086 specifies tests and requirements for primary batteries with aqueous electrolyte to ensure their safe operation under intended use and reasonably foreseeable misuse.

Primary batteries - Part 5: Safety of batteries with aqueous electrolyte