Modeling and Experimental Evaluation of Passive Heat Sinks for Miniature High-Flux Photovoltaic Concentrators

Author:

Sun Jian1,Israeli Tomer2,Reddy T. Agami1,Scoles Kevin3,Gordon Jeffrey M.45,Feuermann Daniel6

Affiliation:

1. Department of Civil, Architectural and Environmental Engineering, Drexel University, Philadelphia, PA

2. Department of Mechanical Engineering Ben-Gurion University of the Negev, Beer Sheva 84105, Israel

3. Department of Electrical and Computer Engineering, Drexel University, Philadelphia, PA

4. Department of Solar Energy and Environmental Physics Jacob Blaustein Institute for Desert Research Ben-Gurion University of the Negev, Sede Boqer Campus 84990, Israel

5. The Pearlstone Center for Aeronautical Engineering Studies Department of Mechanical Engineering Ben-Gurion University of the Negev, Beersheva 84105, Israel

6. Department of Solar Energy and Environmental Physics Jacob Blaustein Institute for Desert Research Ben-Gurion University of the Negev Sede Boqer Campus 84990, Israel

Abstract

An important consideration in the practical realization of high-concentration photovoltaic devices is the heat rejection at high power densities to the environment. Recently, optical designs for generating solar flux in excess of 1000 suns on advanced solar cells–while respecting flux homogeneity and system compactness–were suggested with the introduction of solar fiber-optic mini-dish concentrators, tailored specifically to high-flux photovoltaic devices [1]. At the core of the design is the miniaturization of the smallest building block in the system–the concentrator and the cell–permitting low-cost mass production and reliance on passive heat rejection of solar energy that is not converted to electricity. First, this paper proposes a relatively simple 1-D axi-symmetric model for predicting the thermal and electrical performance of such mini-dish high-flux concentrators. Experimental measurements were performed with a real-sun solar simulator, indoors under controllable conditions, at flux levels up to 5,000 suns. A CFD (Computational Fluid Dynamics) model was also developed for model-validation. Both the modeling approaches predict heat sink temperatures within experimental uncertainty of a couple of degrees. Next, the 1-D axi-symmetric model is used to evaluate the sensitivity of different solar cell model assumptions, environmental effects (such as outdoor temperature, and the wind speed), heat sink size and geometry, thermal contact resistance, etc. It was confirmed that the miniaturization of the solar cell module permits passive heat rejection, such that solar cell temperatures should not reach more than 80 °C at peak insolation and stagnation conditions. Though the cell rated efficiency degrades by only 1-2% in absolute terms, higher cell temperatures may compromise the integrity of the cell circuitry and of the encapsulation. The 1-D axi-symmetric model also allows optimization of the heat sink geometric dimensions for a given volume. Hour-by-hour performance simulation results for such an optimized design configuration were performed for one month in summer and one month in winter for two locations namely Philadelphia, PA and Phoenix, AZ. The insight gained from this study is important for the proper design of the various components and materials to be used in PV mini-dishes. Equally important is that it allows similar types of analyses to be performed and well-informed design choices to be made for mini-dishes that have to operate under different climatic conditions with cells of different performance and concentration ratios.© 2005 American Institute of Physics.  

Publisher

ASME International

Subject

Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment

Reference17 articles.

1. Feuermann, D., and Gordon, J. M., 1999, “Solar Fiber-Optic Mini-Dishes: A New Approach to the Efficient Collection of Sunlight,” Sol. Energy, 65, pp. 159–170.

2. Feuermann, D., and Gordon, J. M., 2001, “High-Concentration Photovoltaic Designs Based on Miniature Parabolic Dishes,” Sol. Energy 70, pp. 423–430.

3. Reddy, T. A., Shetty, S., Jian S., Scoles, K., Eisenstein, B., Feuermann, D., and Gordon, J. M., 2003. “Preliminary Design and Experimental Results from a New Miniaturized and Modular High-Concentration Solar Photovoltaic Mini-Dish Program,” report submitted to US DOE, June.

4. Feuermann, D., Gordon, J. M., and Huleihil, M., 2002, “Solar Fiber-Optic Mini-Dish Concentrators: First Experimental Results and Field Experience,” Sol. Energy, 72, pp. 459–472.

5. Spectrolab, 2001, Triple Junction Solar Cells, Spectrolab Inc., 12500 Gladstone Avenue, Sylmar, CA, www. Spectrolab.com

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