1. 江南大学 理学院,江苏 无锡,中国,214122
2. 江苏省轻工光电工程技术研究中心,江苏 无锡,214000
3. 无锡尚德太阳能电力有限公司, 江苏 无锡 214000
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李超, 邵剑波, 席曦等. 多波段LED太阳模拟器及其测试系统的研制[J]. 发光学报, 2019,40(5): 635-642
LI Chao, SHAO Jian-bo, XI Xi etc. Development of LED Solar Simulator and Solar Cell Test System[J]. Chinese Journal of Luminescence, 2019,40(5): 635-642
李超, 邵剑波, 席曦等. 多波段LED太阳模拟器及其测试系统的研制[J]. 发光学报, 2019,40(5): 635-642 DOI: 10.3788/fgxb20194005.0635.
LI Chao, SHAO Jian-bo, XI Xi etc. Development of LED Solar Simulator and Solar Cell Test System[J]. Chinese Journal of Luminescence, 2019,40(5): 635-642 DOI: 10.3788/fgxb20194005.0635.
为了克服传统氙灯太阳模拟器成本高、寿命短、功耗大等缺点,提高太阳电池测试的准确性,本文首先设计了一种基于11种波段的LED太阳模拟器,在光谱匹配度、不均匀度和不稳定度上均达到IEC60904-9-2007规定的A级标准。在此基础上,开发了配套的太阳电池测试系统,经过光源控制、数据处理、温度修正以及参数计算,得到太阳电池的电特性参数。实验结果表明,系统可以准确测得单晶硅太阳电池片的各项参数,且结果稳定,从而验证了光源的可靠性及测试方法的科学性。
The commonly-used xenon solar simulator has the disadvantage of high cost, short life circle and high power consumption. In order to improve the accuracy of the solar cell test, a multi-wavelength LED solar simulator was designed. The spectral matching, non-uniformity and instability of the irradiance satisfy the class A standard specified in IEC60904-9-2007. Moreover, a corresponding solar cell test syst-em was developed, having the function of light source control, data processing, temperature calibration and parameter calculation. The experiment results showed that the electrical characteristics of monocrystalline sili-con solar cell could be accurately obtained, and the results were stable, comfirming the reliability of the light source and the scientificalness of the test method.
太阳模拟器LED测试温度修正
solar simulatorLEDtesttemperature calibration
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