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引用次数: 18
摘要
薄膜碲化镉组件的稳定性对该技术的发展至关重要。在各种加速试验条件下进行了长期稳定性研究。加速寿命试验(ALT)在实验室中进行,以加速退化,从而在相当短的时间内量化性能变化。ALT研究试图模拟太阳能组件在其使用寿命期间在户外经历的条件,ALT结果与户外测试结果相关联,以估计组件的使用寿命、铭牌参数和产品保修。为了加速降解,实验室实验通常在高温、电压偏置和连续照明下进行。在这项研究中,实验室大小的电池(0.5 cm2)、迷你模块(15 cm × 15 cm)和全尺寸封装模块(60 cm × 120 cm)由整体互连的电池组成,在长时间内受到不同程度的照明、高温和电偏。讨论了效率、填充因子(FF)、开路电压(Voc)和短路电流(Isc)随应力时间和应力条件的变化。
Stability of thin-film CdTe module is crucial to the advancement of the technology. Long-term stability studies are carried out under a variety of accelerated test conditions. Accelerated-life-tests (ALT) are performed in the laboratory to accelerate degradation and hence quantify performance change in reasonably short periods of time. ALT studies attempt to simulate the conditions a solar module experiences outdoors during its lifetime, and ALT results are correlated to outdoor test results to estimate module service lifetimes, nameplate parameters, and product warranty. To accelerate degradation, laboratory experiments are often performed at elevated temperature, voltage bias and under continuous illumination. In this study laboratory size cells (0.5 cm2), mini-modules (15 cm × 15 cm) and full-size encapsulated modules (60 cm × 120 cm) that consist of monolithically interconnected cells were subjected to different levels of illumination, elevated temperatures and electrical biases for extended periods of time. Changes in efficiency, fill-factor (FF), open-circuit voltage (Voc) and short-circuit current (Isc) as a function stress time and stress conditions are discussed.
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