光伏组件上尘埃粒子静电力的衰减

C. Jiang, H. Moutinho, B. To, C. Xiao, L. Simpson, M. Al‐Jassim
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摘要

由于太阳能组件污染造成的光伏(PV)能量损失已经变得越来越重要,因为太阳能组件的部署现在已经达到了数百吉瓦的规模,并且还在继续快速增长。我们已经报道了使用原子力显微镜(AFM)直接测量的强电场诱导的尘埃颗粒在太阳能电池板上的吸引力和附着力(Fes),比范德华力和水毛细力强1到2个数量级,通过观察系统电压诱导的污染率的增加得到了证实。在这里,我们报告了fees在污染上的另一个特性-在关闭太阳能电池板上的高压后,持续时间长或衰减缓慢。Fes的衰减时间在1到10小时的范围内变化,这取决于两个因素:1)在关闭电压之前,电池或/和颗粒都被高压充电;2)在电压关闭后,电池是如何连接到地面的——通过电源电子设备连接,直接连接到地面,或者电漂浮。fees衰变可以从以下几个方面来理解:1)粒子和电池中的净电荷耗散,2)模块玻璃电介质中偶极极化的热无序,以及3)粒子和模块玻璃的静电相互作用引起的电荷再分配。这种持续数小时的高温会严重影响太阳下山后太阳能电池板的污染,特别是与冷凝水结合在一起。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Decay of Electrostatic Force of Dust Particles on Photovoltaic Modules
Photovoltaic (PV) energy yield loss due to solar module soiling has become increasingly important as solar module deployment is now at the hundreds of gigawatts scale and continues to grow rapidly. We have reported on direct measurements—using atomic force microscopy (AFM)—of strong electric-field-induced attraction and adhesion force (Fes) of dust particles onto solar panel that are 1 to 2 orders of magnitude stronger than the van der Waals and water capillary forces, corroborated by observing the increase in system voltage-induced soiling rate. Here, we report another characteristic of Fes on soiling—long lasting or slow decay after turning off the high voltage applied to solar panels. The Fes decay time varies in a wide time range of 1 to 10 hours, depending on two factors: 1) either/both the cell or/and particle were charged with high voltage before the voltages were turned off; and 2) how the cell was connected to the ground after the voltage was turned off—either connected through the power supply electronics, directly connected to the ground, or electrically floated. The Fes decay is understood in terms of 1) net electrical charge dissipations in both particle and cell, 2) thermal disordering of dipole polarization in the module glass dielectrics, and 3) charge redistribution by the electrostatic interaction of particle and module glass. This long-lasting Fes for hours can significantly affect the solar panel soiling after sunset, especially combined with water condensation.
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