论文信息 - IR-imaging and non-destructive loss analysis on thin film solar modules and cells

IR-imaging and non-destructive loss analysis on thin film solar modules and cells

CIGS thin film solar modules, despite their high efficiency, may contain three different kinds of macroscopic defects referred to as bulk defects, interface defects and interconnect defects. These occur due to the film’s sensitivity to inhomogeneities during the manufacturing process and decreasing the electrical power output from a cell or module. In this study, we present infrared (IR) imaging and contactless loss analyses of defects contained in commercially manufactured thin film solar modules. We investigated different relations between the emitted IR-signal (using illuminated lock-in thermography ILIT) and the respective open circuit cell voltage (Voc) as well as the maximum power point (Pmpp). A simulation study, using the 2D finite element method (FEM), provides a deeper understanding as to the impact on electrical performance when defects are present on the cell or module.

[1] Frank W. Fecher,et al. Lock‐in thermography as a tool for quality control of photovoltaic modules , 2013 .

[2] Frank W. Fecher,et al. Influence of a shunt on the electrical behavior in thin film photovoltaic modules – A 2D finite element simulation study , 2014 .

[3] Wilhelm Warta,et al. Realistic evaluation of power losses in solar cells by using thermographic methods , 2004 .

[4] Wilhelm Warta,et al. Spatially resolved evaluation of power losses in industrial solar cells by illuminated lock‐in thermography , 2004 .

[5] Wilhelm Warta,et al. Investigation of series resistance losses by illuminated lock‐in thermography , 2005 .

[6] T. Walter,et al. 2D network simulation and luminescence characterization of Cu(In,Ga)Se2 thin film modules , 2012 .

[7] Frank W. Fecher,et al. The influence of defects on the cellular open circuit voltage in CuInGaSe2 thin film solar modules—An illuminated lock-in thermography study , 2014 .