27.070 燃料电池 标准查询与下载

IEC 62282-8-102:2019 燃料电池技术.第8-102部分:反向模式下使用燃料电池组件的能量储存系统.包括可逆操作的质子交换膜单电池和电池组性能试验程序

Fuel cell technologies - Part 8-102: Energy storage systems using fuel cell modules in reverse mode - Test procedures for the performance of single cells and stacks with proton exchange membrane, incl

T/GHDQ 45-2019 高寒地区质子交换膜燃料电池电堆低温特性通用技术条件

主要补充制定了车用燃料电池发电系统在-20℃、-30℃和-40℃温度下的性能指标。

General technical conditions of automotive fuel cell stack subzero character in frigid region

T/GHDQ 39-2019 高寒地区车用燃料电池发动机低温起动技术条件

要补充制定了车用燃料电池发电系统在-20℃、-30℃和-40℃温度下的性能指标。

Technical conditions of vehicle-based fuel cell engine cold-start in frigid regions

T/GHDQ 47-2019 高寒地区车用氢燃料电池电堆低温寿命测试技术条件

主要补充制定了车用燃料电池发电系统在-20℃、-30℃和-40℃温度下的性能指标。

Technical conditions of fuel cell stack life test at subzero environment for fuel cell vehicles in frigid regions

T/GHDQ 44-2019 高寒地区车用质子交换膜燃料电池电堆低温冷起动通用技术条件

主要补充制定了车用燃料电池发电系统在-20℃、-30℃和-40℃温度下的性能指标。

General technical conditions of automotive proton exchange membrane fuel cell stack subzero startup in frigid region

T/GHDQ 46-2019 高寒地区质子交换膜燃料电池发电系统性能技术条件

主要补充制定了车用燃料电池发电系统在-20℃、-30℃和-40℃温度下的性能指标。

Performance requirements and test methods of fuel cell system for electric vehicles in frigid regions

BS EN IEC 62282-6-400:2019 燃料电池技术 微型燃料电池动力系统 电源和数据互换性

What is BS EN IEC 62282 ‑ 6 ‑ 400 - Micro fuel cell power systems about?   BS EN IEC 62282 series covers fuel cell technologies. BS EN IEC 62282 ‑ 6 ‑ 400 is the sixth part of the multi-series of documents that specifies the interchangeability of power and data between micro fuel cell power systems and electronic devices to provide the micro fuel cell power system compatibility for a variety of electronic devices while maintaining the safety and performance of the micro fuel cell system.   BS EN IEC 62282 ‑ 6 ‑ 400 covers power interfaces and their connector configuration. The power management circuitry and power-sharing methodology are also provided.   ...

Fuel cell technologies - Micro fuel cell power systems. Power and data interchangeability

IEC 62282-6-400:2019 燃料电池技术.第6-400部分:微型燃料电池动力系统.功率和数据互换性

Fuel cell technologies - Part 6-400: Micro fuel cell power systems - Power and data interchangeability

IEC 62282-3-100:2019 RLV 燃料电池技术.第3-100部分:固定式燃料电池动力系统.安全性

Fuel cell technologies - Part 3-100: Stationary fuel cell power systems - Safety

IEC 62282-3-100:2019 燃料电池技术 - 第3-100部分:固定式燃料电池电力系统 - 安全

Fuel cell technologies - Part 3-100: Stationary fuel cell power systems - Safety

BS EN IEC 62282-5-100:2018 燃料电池技术 便携式燃料电池电源系统 安全

Fuel cell technologies. Portable fuel cell power systems. Safety

EN IEC 62282-5-100:2018 燃料电池技术 第 5-100 部分：便携式燃料电池电源系统 安全

Fuel cell technologies - Part 5-100: Portable fuel cell power systems - Safety

IEC 62282-5-100:2018 燃料电池技术.第5-100部分:便携式燃料电池装置.安全性

This part of IEC 62282 covers construction@ marking and test requirements for portable fuel cell power systems. These fuel cell systems are movable and not fastened or otherwise secured to a specific location. The purpose of the portable fuel cell power system is to produce electrical power. This document applies to AC and DC type portable fuel cell power systems@ with a rated output voltage not exceeding 600 V AC@ or 850 V DC for indoor and outdoor use. These portable fuel cell power systems cannot be used in hazardous locations as defined in IEC 60050-426:2008@ 426-03-01 unless there are additional protective measures in accordance with IEC 60079-0[5]1). This document does not apply to portable fuel cell power systems that are 1) permanently connected (hard wired) to the electrical distribution system@ 2) permanently connected to a utility fuel distribution system@ 3) exporting power to the grid@ 4) for propulsion of road vehicles@ 5) intended to be used on board passenger aircraft. Fuel cells that provide battery charging for hybrid vehicles where the battery provides power and energy for propulsion of the vehicle are not included in the scope of this document The following fuels and fuel feedstocks are considered within the scope of this document: ? natural gas@ ? liquefied petroleum gas@ such as propane and butane@ ? liquid alcohols@ for example methanol@ ethanol@ ? gasoline@ ? diesel@ ? kerosene@ ? hydrogen@ ? chemical hydrides. This document does not preclude the use of similar fuels or oxidants from sources other than air provided the unique hazards are addressed through additional requirements. The overall design of a portable fuel cell power system anticipated by this document forms an assembly of some or all of the following systems (see Figure 1)@ integrated as necessary@ to perform designated functions@ as follows: Fuel processing system ?C chemical processing equipment including any associated heat exchangers and controls required to convert input fuel to a composition suitable for the fuel cell stack. Oxidant processing system ?C subsystem that meters@ conditions@ processes and may pressurize the incoming oxidant supply for use within the fuel cell power system. Thermal management system ?C subsystem intended to provide cooling and heat rejection in order to maintain thermal equilibrium within the fuel cell power system@ and@ if necessary@ to provide for the recovery and utilization of excess heat and to assist in heating the fuel cell power systems during start-up. Power conditioning system ?C equipment which is used to change the magnitude or waveform of the voltage@ or otherwise alter or regulate the output of a power source. Automatic control system ?C assembly of sensors@ actuators@ valves@ switches and logic components (including process controllers) that maintains the fuel cell power system parameters within the manufacturer??s specified limits without manual intervention. Fuel cell module ?C assembly@ including a fuel cell stack(s)@ which electrochemically converts chemical energy to electric energy and thermal energy intended to be integrated into a power generation system. Fuel supply system ?C either integral to the portable fuel cell power system or supplied through a removable and refillable container assembly. On-board energy storage system ?C an internal energy source intended to aid or complement the fuel cell module in providing power to internal or external loads. Ventilation systems ?C subsystem of the fuel cell power system that provides@ by mechanical means@ air to its cabinet. Water treatment systems ?C provides for treatment and purification of recovered or added water for use within the portable fuel cell power system. These requirements are not intended to prevent the design and construction of a portable fuel cell power system not specifically described in this document@ provided that such alternatives have been considered and equivalent testing yields equivalent safety performance to that specified in this document. In considering alternative designs or construction@ this document can be used to evaluate the alternative materials or methods to be used as to their ability to yield equivalent performance to that specified in this document. This document does not cover requirements of pressurized or non-pressurized fuel supply containers upstream of the appliance gaseous or liquid fuel supply connector that are not integral to the portable fuel cell power system. All pressures in this document are considered to be gauge pressures@ unless otherwise specified.

Fuel cell technologies - Part 5-100: Portable fuel cell power systems - Safety

CAN/CSA-C22.2 No.62282-2-2018 燃料电池技术 第2部分：燃料电池模块

1 Scope This part of IEC 62282 provides the minimum requirements for safety and performance of fuel cell modules and applies to fuel cell modules with the following electrolyte chemistry: – alkaline; – polymer electrolyte (including direct methanol fuel cells) 1; – phosphoric acid; – molten carbonate; – solid oxide; – aqueous solution of salts. Fuel cell modules can be provided with or without an enclosure and can be operated at significant pressurization levels or close to ambient pressure. This standard deals with conditions that can yield hazards to persons and cause damage outside the fuel cell modules. Protection against damage inside the fuel cell modules is not addressed in this standard, provided it does not lead to hazards outside the module. These requirements may be superseded by other standards for equipment containing fuel cell modules as required for particular applications. This standard does not cover road vehicle applications. This standard is not intended to limit or inhibit technological advancement. An appliance employing materials or having forms of construction differing from those detailed in the requirements of this standard may be examined and tested according to the purpose of these requirements and, if found to be substantially equivalent, may be considered to comply with this standard. The fuel cell modules are components of final products. These products require evaluation to appropriate end-product safety requirements.

Fuel cell technologies — Part 2: Fuel cell modules

DIN 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(IEC/TS 62282-7-1-2017)

This Technical Specification covers cell assemblies, test station setup, measuring instruments and measuring methods, performance test methods, and test reports for PEFC single cells. This Technical Specification 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) (IEC/TS 62282-7-1:2017)

EN 62282-3-201:2017 燃料电池技术 第 3-201 部分：固定式燃料电池动力系统 小型燃料电池动力系统的性能测试方法

IEC 62282-3-201:2017 provides test methods for the electrical, thermal and environmental performance of small stationary fuel cell power systems that meet the following criteria: - rated electric power output of less than 10 kW; - grid-connected/independent operation or stand-alone operation with single-phase AC output or 3-phase AC output not exceeding 1 000 V, or DC output not exceeding 1 500 V; - maximum allowable working pressure of less than 0,1 MPa (gauge) for the fuel and oxidant passages; - gaseous fuel (natural gas, liquefied petroleum gas, propane, butane, hydrogen, etc.) or liquid fuel (kerosene, methanol, etc.); - air as oxidant. This document describes type tests and their test methods only. This document covers fuel cell power systems whose primary purpose is the production of electric power. This new edition includes the following significant technical changes with respect to the previous edition: revision of test set-up, revision of measurement instruments, introduction of ramp-up test, introduction of rated operation cycle efficiency, introduction of electromagnetic compatibility (EMC) test, revision of exhaust gas test, introduction of typical durations of operation cycles.

Fuel cell technologies - Part 3-201: Stationary fuel cell power systems - Performance test methods for small fuel cell power systems

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

IEC 62282-3-201:2017 燃料电池技术 - 第3-201部分:固定燃料电池电力系统 - 小型燃料电池电力系统的性能测试方法

Fuel cell technologies - Part 3-201: Stationary fuel cell power systems - Performance test methods for small fuel cell power systems

T/CEEIA 265-2017 无人机燃料电池燃料系统技术规范

本标准规定了无人机燃料电池燃料系统的通用要求、单体设备、电气和监控系统、技术要求，及安装、试验检测、标志、包装和运输要求。 本标准适用于以压缩氢气为燃料、为微型（

Technical specification of fuel cell fuel system for unmanned aerial vehicle

T/CEEIA 264-2017 无人机燃料电池发电系统技术规范

本标准规定了无人机燃料电池发电系统的通用要求、技术要求、以及安装、试验检测、标志、包装和运输要求。 本标准适用于以氢气为燃料、为微型（

Technical specification of fuel cell power system for unmanned aerial vehicle