F12 太阳能 标准查询与下载

NF C57-317*NF EN 62817:2015 光伏系统. 太阳跟踪器的设计鉴定

Photovoltaic systems - Design qualification of solar trackers

UL 6703 CRD-2015 光伏系统用连接器的UL安全标准. 节/段落参考: 主题: UL 6703范围扩展为包括交流或者直流电压高达1500 V或者更少的单极设备 (第一版: 2014年8月28日)

UL Standard for Safety Connectors for Use in Photovoltaic Systems - Section / Paragraph Reference: 1.1, Table 6.2, Table 7.1, Table 7.2, Table 9.1 Subject: Expansion of UL 6703 Scope to include single-pole devices up to 1500 V dc or less (Edition 1: Augus

KS C IEC 60904-8:2015 光伏器件.第8部分:光伏器件光谱响应的测量

Photovoltaic devices — Part 8: Measurement of spectral responsivity of a photovoltaic (PV) device

NB/T 32025-2015 光伏发电调度技术规范

Photovoltaic power generation dispatching technical specifications

NB/T 32026-2015 光伏发电站并网性能测试与评价方法

Photovoltaic power station grid-connected performance testing and evaluation methods

NF C57-111-1/A11:2015 光电(PV)组件安全性鉴定.第1部分:构造要求

Le présent amendement modifie les Articles 7 et 10, et l'Annexe ZA de la norme homologuée NF EN 61730-1 de septembre 2007.Le présent document entre dans le champ d'application de la Directive Basse Tension no2006/95/CE du 12/12/2006.

Photovoltaic (PV) module safety qualification - Part 1 : requirements for construction

BS IEC 62790:2014 光伏组件接线盒. 安全要求和试验

Junction boxes for photovoltaic modules. Safety requirements and tests

BS IEC 62852:2014 光伏系统中的直流应用连接器. 安全要求和试验

Connectors for DC-application in photovoltaic systems. Safety requirements and tests

BS 5918:2015 家用热水的太阳能加热系统. 设计和安装实践规程

This British Standard gives recommendations and guidance for the installation of common indirect solar domestic hot water (SDHW) systems for all types of building in the UK. It includes recommendations and guidance for design,handling, installation,commissioning,handover,maintenance,decommissioning and fault-finding.

Solar heating systems for domestic hot water. Code of practice for design and installation

UL 2703-2015 和平板光伏组件和板仪器一起使用的安装系统, 安装装置, 夹紧/保留设备以及接地片的UL安全标准 (第一版)

UL Standard for Safety Mounting Systems@ Mounting Devices@ Clamping/Retention Devices@ And Ground Lugs For Use With Flat-Plate Photovoltaic Modules And Panels (First Edition)

IEC 60904-2:2015 光伏设备. 第2部分: 光伏基准设备的要求

Photovoltaic devices - Part 2: Requirements for photovoltaic reference devices

ASTM E2527-15 在自然光下聚能地面光电模组和系统电性能的标准试验方法

5.1 It is the intent of this test method to provide a recognized procedure for testing and reporting the electrical performance of a photovoltaic concentrator module or system. 5.2 If an inverter is used as part of the system, this test method can provide a dc or ac rating or both. The dc or ac rating depends on whether the inverter input or output is monitored. 5.3 The test results may be used for comparison among a group of modules or systems from a single source. They also may be used to compare diverse designs, such as products from different manufacturers. Repeated measurements of the same module or system may be used for the study of changes in device performance over a long period of time or as a result of stress testing. 5.4 The test method is limited to modules and systems where the concentrated irradiance on the component cells is greater than 5000 Wm-2 at Eo. This limitation is necessary because the total irradiance is measured with a radiometer with a field of view less than 6° and because the correlation between the direct irradiance and the power produced decreases with increasing concentrator field of view. 5.5 This test method assumes that the regression equation accurately predicts the concentrator performance as a function of total irradiance with a fixed spectral irradiance, wind speed, and air temperature. The spectral distribution will be seasonal and site specific because of optical air mass, water vapor, aerosols, and other meteorological variables. 1.1 This test method covers the determination of the electrical performance of photovoltaic concentrator modules and systems under natural sunlight using a normal incidence pyrheliometer. 1.2 The test method is limited to module assemblies and systems where the geometric concentration ratio specified by the manufacturer is greater than 5. 1.3 This test method applies to concentrators that use passive cooling where the cell temperature is related to the air temperature. 1.4 Measurements under a variety of conditions are allowed; results are reported under a select set of concentrator reporting conditions to facilitate comparison of results. 1.5 This test method applies only to concentrator terrestrial modules and systems. 1.6 This test method assumes that the module or system electrical performance characteristics do not change during the period of test. 1.7 The performance rating determined by this test method applies only at the period of the test, and implies no past or future performance level. 1.8 This standard does not purport to address all of......

Standard Test Method for Electrical Performance of Concentrator Terrestrial Photovoltaic Modules and Systems Under Natural Sunlight

ASTM E1171-15 循环温度和湿度环境中光伏模组的的标准试验方法

4.1 The useful life of photovoltaic modules may depend on their ability to withstand repeated temperature cycling with varying amounts of moisture in the air. These test methods provide procedures for simulating the effects of cyclic temperature and humidity environments. An extended duration damp heat procedure is provided to simulate the effects of long term exposure to high humidity. 4.2 The durations of the individual environmental tests are specified by use of this test method; however, commonly used durations are 50 and 200 thermal cycles, 10 humidity-freeze cycles, and 1000 h of damp heat exposure, as specified by module qualification standards such as IEC 61215 and IEC 61646. Longer durations can also be specified for extended duration module stress testing. 4.3 Mounting—Test modules are mounted so that they are electrically isolated from each other, and in such a manner to allow free air circulation around the front and back surfaces of the modules. 4.4 Current Biasing: 4.4.1 During the thermal cycling procedure, test modules are operated without illumination and with a forward-bias current equal to the maximum power point current at standard reporting conditions (SRC, see Test Methods E1036) flowing through the module circuitry. 4.4.2 The current biasing is intended to stress the module interconnections and solder bonds in ways similar to those that are believed to be responsible for fill-factor degradation in field-deployed modules. 4.5 Effects of Test Procedures—Data generated using these test methods may be used to evaluate and compare the effects of simulated environment on test specimens. These test methods require determination of both visible effects and electrical performance effects. 4.5.1 Effects on modules may vary from none to significant changes. Some physical changes in the module may be visible when there are no apparent electrical changes in the module. Similarly, electrical changes may occur with no visible changes in the module. 4.5.2 All conditions of measurement, effects of cycling, and any deviations from this test method must be described in the report so that an assessment of their significance can be made. 4.6 Sequencing—If these test methods are performed as part of a combined sequence with other environmental or non-environmental tests, the results of the final electrical tests (6.2) and visual inspection (6.3) determined at the end of one test may be used as the initial electrical tests and visual inspection for the next test; duplication of these tests is not necessary unless so specified. 1.1 These test methods pr......

Standard Test Methods for Photovoltaic Modules in Cyclic Temperature and Humidity Environments

GOST R 54350-2015 光器件. 光要求和试验方法

Light devices. Light requirements and test methods

ASTM E973-15 测定光电装置与光电参比电池之间光谱不协调参数的标准试验方法

5.1 The calculated error in the photovoltaic device current determined from the spectral mismatch parameter can be used to determine if a measurement will be within specified limits before the actual measurement is performed. 5.2 The spectral mismatch parameter also provides a means of correcting the error in the measured device current due to spectral mismatch. 5.2.1 The spectral mismatch parameter is formulated as the fractional error in the short-circuit current due to spectral and temperature differences. 5.2.2 Error due to spectral mismatch is corrected by multiplying a reference cell’s measured short-circuit current by M , a technique used in Test Methods E948 and E1036. 5.3 Because all spectral quantities appear in both the numerator and the denominator in the calculation of the spectral mismatch parameter (see 8.1), multiplicative calibration errors cancel, and therefore only relative quantities are needed (although absolute spectral quantities may be used if available). 5.4 Temperature-dependent spectral mismatch is a more accurate method to correct photovoltaic current measurements compared with fixed-value temperature coefficients.3 1.1 This test method provides a procedure for the determination of a spectral mismatch parameter used in performance testing of photovoltaic devices. 1.2 The spectral mismatch parameter is a measure of the error introduced in the testing of a photovoltaic device that is caused by the photovoltaic device under test and the photovoltaic reference cell having non-identical quantum efficiencies, as well as mismatch between the test light source and the reference spectral irradiance distribution to which the photovoltaic reference cell was calibrated. 1.2.1 Examples of reference spectral irradiance distributions are Tables E490 or G173. 1.3 The spectral mismatch parameter can be used to correct photovoltaic performance data for spectral mismatch error. 1.4 Temperature-dependent quantum efficiencies are used to quantify the effects of temperature differences between test conditions and reporting conditions. 1.5 This test method is intended for use with linear photovoltaic devices in which short-circuit is directly proportional to incident irradiance. 1.6 The values stated in SI units are to be regarded as standard. No other units of measurement ar......

Standard Test Method for Determination of the Spectral Mismatch Parameter Between a Photovoltaic Device and a Photovoltaic Reference Cell

ASTM E772-15 太阳能转换相关标准术语

1.1 This terminology pertains to the conversion of solar energy into other forms of energy by various means, including thermal absorption (i.e., solar thermal) and the photovoltaic effect (i.e., photovoltaics). 1.2 This terminology also pertains to instrumentation used to measure solar radiation. 1.3 This terminology also pertains to glass for solar energy applications. 1.4 Fundamental terms associated with electromagnetic radiation that are indicates as derived units in Standard IEEE/ASTM SI 10 are not repeated in this terminology. 1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.

Standard Terminology of Solar Energy Conversion

KS B ISO 9459-4:2014 太阳能加热.家用热水系统.第4部分:借助于组合测验和计算机模拟的系统性能特征评价

Solar heating — Domestic water heating systems — Part 4: System performance characterization by means of component tests and computer simulation

DB44/T 1511-2014 液冷式光伏光热一体化组件

本标准规定了液冷式光伏光热一体化组件的术语和定义、产品分类与标记、要求、试验方法、检验规则、标志、包装、运输、贮存以及检测报告。 本标准适用于液冷式光伏光热一体化组件。

Liquid-cooled photovoltaic photothermal integrated module

DB44/T 1507-2014 太阳能光伏充电站技术要求

本标准规定了太阳能光伏充电站的性能、结构、安全等方面的通用技术要求。 本标准适用于广东省境内太阳能光伏充电站。

Technical requirements for solar photovoltaic charging stations

UL 6703 CRD-2014 光伏系统用连接器的UL安全标准. 节/段落参考: 1.1, 4.7, 10.2, 11.2, 11.3主题: 交流电路用单极连接器 (第一版: 2014年8月28日)

UL Standard for safety Connectors for Use in Photovoltaic Systems - Section / Paragraph Reference: 1.1, 4.7, 10.2, 11.2, 11.3 Subject: Single Pole Connectors used in AC Circuits (Edition 1: August 28, 2014)