David Chojniak, Michael Schachtner, S. Kasimir Reichmuth, Alexander J. Bett, Michael Rauer, Jochen Hohl-Ebinger, Alexandra Schmid, Gerald Siefer, Stefan W. Glunz
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引用次数: 0
Abstract
Solar simulators based on light-emitting diodes (LEDs) usually consist of many spectrally different LEDs, which in sum produce a sun-like spectrum. On the one hand, this results in the advantage of a high spectral tunability of these systems and on the other hand, however, also in the challenge of a high number of parameters which have to be set for the adjustment of a suitable simulator spectrum. Multijunction solar cells consisting of series-connected subcells are very sensitive to spectral irradiance conditions, which are affecting the current and the fill factor of the device. A precise adjustment of the simulator spectrum based on the spectral responsivity of the subcells is therefore essential for accurate multijunction measurements. Therefore, the number of spectrally different light sources used should be at least as high as the number of subcells in the device under test. However, for the measurement of multijunction devices, the much higher number of spectrally different light sources in common LED solar simulators results in a plethora of different simulator spectra, potentially suitable for the measurement. Furthermore, the nonlinear intensity characteristics of the utilized LEDs as well as the distance-dependent illumination uniformity of such solar simulators add complexity when aiming for a precise spectral adjustment. To tackle these challenges, a new spectral adjustment procedure which is based on a least square's solution algorithm and the definition of appropriate boundary conditions for the calculation of suitable simulator settings is introduced in this publication. Focusing on measurements carried out under constant illumination makes the presented method especially applicable for perovskite-on-silicon multijunction devices. Therefore, an adapted method for the determination of the solar simulator's spectral properties, considering thermal influences which are particularly relevant when carrying out continuous illumination measurements, is introduced in this work. The presented method is verified applying it on a Wavelabs SINUS 220 LED solar simulator by performing a measurement comparison on a multijunction solar cell with Fraunhofer ISE CalLab's well-established multilight source solar simulator.
基于发光二极管(LED)的太阳模拟器通常由许多光谱不同的发光二极管组成,这些发光二极管共同产生类似太阳的光谱。一方面,这使得这些系统具有光谱可调性高的优势,但另一方面,也带来了大量参数的挑战,这些参数必须通过设置来调整合适的模拟器光谱。由串联子电池组成的多接面太阳能电池对光谱辐照条件非常敏感,而光谱辐照条件会影响设备的电流和填充因子。因此,根据子电池的光谱响应度精确调整模拟器光谱对于精确测量多接面太阳能电池至关重要。因此,所使用的光谱不同的光源数量至少应与被测设备中子电池的数量相同。然而,在测量多接面器件时,普通 LED 太阳能模拟器中光谱不同的光源数量要多得多,因此会产生大量不同的模拟器光谱,可能适合测量。此外,所使用的 LED 的非线性强度特性以及此类太阳能模拟器随距离变化的照明均匀性,也增加了精确光谱调整的复杂性。为了应对这些挑战,本出版物介绍了一种新的光谱调整程序,该程序基于最小平方求解算法和适当边界条件的定义,用于计算合适的模拟器设置。该方法侧重于在恒定光照下进行测量,因此特别适用于硅基包晶多结器件。因此,考虑到在进行持续光照测量时特别相关的热影响,本著作介绍了一种用于确定太阳能模拟器光谱特性的调整方法。通过对多接面太阳能电池与弗劳恩霍夫 ISE CalLab 成熟的多光源太阳能模拟器进行测量比较,在 Wavelabs SINUS 220 LED 太阳能模拟器上验证了所介绍的方法。
期刊介绍:
Progress in Photovoltaics offers a prestigious forum for reporting advances in this rapidly developing technology, aiming to reach all interested professionals, researchers and energy policy-makers.
The key criterion is that all papers submitted should report substantial “progress” in photovoltaics.
Papers are encouraged that report substantial “progress” such as gains in independently certified solar cell efficiency, eligible for a new entry in the journal''s widely referenced Solar Cell Efficiency Tables.
Examples of papers that will not be considered for publication are those that report development in materials without relation to data on cell performance, routine analysis, characterisation or modelling of cells or processing sequences, routine reports of system performance, improvements in electronic hardware design, or country programs, although invited papers may occasionally be solicited in these areas to capture accumulated “progress”.