1. Exploring the limits of concentration for UHCPV
- Author
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Robert L. Sandstrom, Alhassan Badahdah, Yaseen G. Alharbi, Brent A. Wacaser, Peter D. Kirchner, Theodore G. Van Kessel, Hussam Khonkar, Yves Martin, and Naim Moumen
- Subjects
Work (thermodynamics) ,Materials science ,Field (physics) ,Equivalent series resistance ,business.industry ,Photovoltaic system ,Thermal ,Optoelectronics ,Adaptive optics ,Suns in alchemy ,business ,Engineering physics ,Power density - Abstract
Practical multi receiver ultra high (1000+ Suns) concentration photovoltaic (UHCPV) systems experience large radiation, thermal and electrical loads in addition to large power density transients under routine operation. This report is a summary of the issues involved in determining the practical limits to concentration. How high is too high? Explorations into UHCPV have both theoretical and experimental aspects. Understanding the theoretical device physics and circuit limitations is often essential to determining which experiments to do and in interpreting results. On the experimental side the work can be divided into two fields depending on the type of light source. The first is artificial or simulated sources and the second is working in the field with direct solar irradiation. Both fields have advantages and disadvantages. Direct solar radiation was selected for the current experiments due to the low cost and ability to produce ultra high concentrations (4000+) over relatively large areas (25+ mm2). Several experimental examples from these direct solar measurements shed light on some of the basic theories of how concentrated light affects the performance of multi junction photovoltaic cells. Out of these examples and theoretical foundations we conclude that for practical devices the first order constraint to optimum efficiency at ultra high concentrations is the series resistance. We also present a simple model based on published data and our results that can be used to predict the total system series resistance needed to optimize a system for a particular concentration.
- Published
- 2011