Close-up of the photovoltaic module with an efficiency of 20.2% developed at the Institute for Solar Energy Research Hamelin. The bright stripes between and on top of the cells arise from the light reflection by the highly reflective cell interconnectors and the space between the solar cells.
Emmerthal (HSH/KBo). The Institute for Solar Energy Research Hamelin (ISFH), an affiliated institute of the “Leibniz Universität Hannover”, increases the module efficiency for large-area solar modules with industrial silicon-based PERC solar cells to a record value of 20.2 % with a power of 303.2W. The TÜV Rheinland confirmed this power in an independent measurement. Thereby, the ISFH surpasses the former module record efficiency of 19.5 % for industrial-type modules with p-type silicon solar cells and screen-printed metallization. The results were achieved within the project “Prozessplattform und Verlustanalyse für klimastabile hocheffiziente Photovoltaikmodule mit kristallinen PERC-Si-Solarzellen” (PERC-2-Module) funded by the German Federal Ministry for Economic Affairs and Energy (BMWi).
The module consists of 120 halved solar cells that feature an average efficiency of 20.8 %. By using the half-cell design the current of the cell strings is reduced resulting in a significant reduction of the series resistance losses. The distance between the cells is reduced to a practical minimum to increase the module efficiency. The resultant module area without frame is 1.501 m2. In order to use light hitting the cell interconnects and the space between the solar cells for current generation, high-reflective and structured materials are utilized which guide the light onto the solar cells active surface. “This record efficiency is the result of a closely joined development of the PERC solar cell technology on the one hand and of the high-efficient module processes at ISFH on the other hand”, explains Dr. Henning Schulte-Huxel, the head of the research project PERC-2-Module.
The p-type PERC solar cells were fabricated using an industrial screen printing process for front and rear side. These cells developed at ISFH are optimized for the operation in modules and show no potential-induced degradation. This was confirmed in numerous internal tests of the solar cells using the conditions of 85% relative humidity, a temperature of 85° C, and an applied voltage of 1000 V for 1000 h. This stress surpassed the standard test by more than ten times.
About 80 % of all commercially-produced solar cells consist of p-type crystalline silicon wafers in combination with a screen printed metallization. Since the material cost during module manufacturing and especially the system cost grow with the module area, the demonstrated optimization of the module efficiency is highly relevant for the reduction of the cost of electricity generated by photovoltaics.