As photovoltaic modules become more widely disseminated in high-power or utility-power applications, their ability to withstand high voltage relative to ground becomes a reliability issue. Long-term effects of exposure to high-voltage stress in the field are investigated. Starting in early 1998, four commercially available PV modules inaugurated the high-voltage stress test at the Outdoor Test Facility at NREL. Modules representing both crystalline and amorphous silicon technologies were deployed on the high-voltage stress testbed located outdoors in order to simulate and assess operation in high-voltage stress testbed located outdoors in order to simulate and assess operation in high-voltage array configurations. They were biased at positive and negative polarity 600 V at all times-except for 1 min at noon each day, when they were subjected to 2200 V bias-and their leakage currents to ground were monitored continuously. The ubiquitous effects of moisture on leakage conductance are analyzed. Module leakage conductance is found to be thermally activated with a characteristic energy that depends on relative humidity. Separate current paths likely responsible for leakage conductance are analyzed and identified at opposite ends of the relative humidity range. Leakage current data are integrated against time to arrive at accumulated charge due to long-term, high-voltage exposure. Published in 2002 by John Wiley & Sons, Ltd.
展开▼
机译:随着光伏模块在大功率或公用电源应用中的传播越来越广泛,它们承受相对于地面的高压的能力成为可靠性问题。研究了暴露于高压应力下的长期影响。从1998年初开始,四个可商用的光伏模块在NREL的户外测试设施中进行了高压应力测试。在室外的高压应力测试台上部署了代表晶体硅和非晶硅技术的模块,以模拟和评估在室外的高压应力测试台上的运行,以模拟和评估在高压阵列配置下的运行。它们一直都以600 V的正极和负极偏置,除了每天中午1分钟(承受2200 V的偏置)外,它们对地的漏电流都得到连续监测。分析了水分对泄漏电导的普遍影响。发现模块泄漏电导被依赖于相对湿度的特征能量热激活。在相对湿度范围的相对两端分析并确定可能导致泄漏电导的独立电流路径。泄漏电流数据随时间进行积分,以得出由于长期高压暴露而产生的累积电荷。 John Wiley&Sons,Ltd.于2002年出版。
展开▼
