Buried screen-printed contacts for silicon solar cells

Jamshidi Gohari, Ebrahim

January 2012

A Simple way to improve solar cell efficiency is to enhance the absorption of light and reduce the shading losses. One of the main objectives for the photovoltaic roadmap is the reduction of metalized area on the front side of solar cell by fin lines. Industrial solar cell production uses screen-printing of metal pastes with a limit in line width of 70-80 μm. This paper will show a combination of the technique of laser grooved buried contact (LGBC) and Screen-printing is able to improve in fine lines and higher aspect ratio. Laser grooving is a technique to bury the contact into the surface of silicon wafer. Metallization is normally done with electroless or electrolytic plating method, which a high cost. To decrease the relative cost, more complex manufacturing process was needed, therefore in this project the standard process of buried contact solar cells has been optimized in order to gain a laser grooved buried contact solar cell concept with less processing steps. The laser scribing process is set at the first step on raw mono-crystalline silicon wafer. And then the texturing etch; phosphorus diffusion and SiNx passivation process was needed once. While simultaneously optimizing the laser scribing process did to get better results on screen-printing process with fewer difficulties to fill the laser groove. This project has been done to make the whole production of buried contact solar cell with fewer steps and could present a cost effective opportunity to solar cell industries. / <p>In collaboration with Institute for Photovoltaics <strong><em>IPV</em></strong>, University of Stuttgart.</p>

Laser scribing

Buried Contacts

Screen-printing

screen-printed.

Využití laserových procesů při výrobě solárních článků / Application of laser processes in crystalline silicon solar cells fabrication

Zapletal, Petr

January 2009

Master's thesis is aimed at the use of given type of laser in the solar cells manufacturing. The first part of thesis is focused on photovoltaic theory, lasers and photovoltaic applications of solid-state lasers. Second part of thesis is practical realization of theoretical analysis. The evaluation of laser usability for variety of applications on solar cells and recommendation for entry settings on laser.