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Portable Power Thermoelectric Generator – Design and Characterization

Published online by Cambridge University Press:  01 February 2011

Ramesh Koripella ,
Lon E Bell  and
Doug Crane
Ramesh Koripella
Affiliation:
rkoripella@bsst.comrkoripella@gmail.com, BSST, LLC, Irwindale, California, United States
Lon E Bell
Affiliation:
lbell@bsst.com, BSST, LLC, Irwindale, California, United States
Doug Crane
Affiliation:
dcrane@bsst.com, BSST, Irwindale, California, United States
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Abstract

High energy density and power density are two important considerations in the design of a portable power source. High efficiency of energy conversion is one of the important factors in achieving high energy density. We report on the design, fabrication and characterization of a high efficiency and power density thermoelectric generator. Segmented thermoelectric elements with a high temperature-weighted average zT are used in the fabrication of the generator to achieve high energy conversion efficiency. A comprehensive model of the generator has been developed that includes temperature dependent thermoelectric properties for the segmented thermoelectric element design, and system level thermal and electrical losses. These models are used to guide the design of a high efficiency thermoelectric generator. A 14W size portable thermoelectric generator was built and its performance for converting thermal energy into electrical energy was characterized and compared to the model predictions. The magnitude of individual loss mechanisms and their effect on overall system efficiency are presented. The evolution of the device design and critical design parameters that have been incorporated or modified to minimize performance losses and improved device robustness are discussed. Important future design optimizations that can further reduce losses for improved performance were identified.

Keywords

thermoelectricdevicesenergy generation
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1267: Symposium DD – Thermoelectric Materials 2010-Growth, Properties, Novel Characterization Methods and Applications , 2010 , 1267-DD02-04
Copyright
Copyright © Materials Research Society 2010

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References

1 Caillat, T., Fleurial, J.P. Snyder, G.J. and Borshchevsky, A. 2001, 20th International Conference on Thermoelectrics, Beijing, China, IEEE, p. 282285 Google Scholar
2 Snyder, G. J. in Thermoelectric Handbook Macro to Nano, Rowe, D.M., Editor, 2006, CRC Press: Boca Raton, FL, p. 9–1 .Google Scholar
3 Kang, Y.S. Niino, M. Nishida, I.A. Yoshino, J., 1998, 17th International Conference on Thermoelectrics, IEEE, p. 429432.Google Scholar
4 Saber, H.H. El-Genk, , 2002, 21st International Conference on Thermoelectrics, IEEE, p. 404407.Google Scholar
5 Siivola, E. Thomas, P. Coonley, K. Reddy, A. Posthill, J. Cook, B. Venkatasubramanian, R., 2005, 25th International Conference on Thermoelectrics, IEEE, p. 6467.Google Scholar
6 Rowe, D.M. CRC Handbook of Thermoelectrics, 1995, CRC Press Google Scholar
7 Angrist, S.W. 1982, Direct Energy Conversion, Allyn and Bacon, Inc, Boston: 4th Ed, p. 126128.Google Scholar
8 Crane, D.T. LaGrandeur, J.W. Harris, F. Bell, L.E. 2009, Journal of Electronic Materials, 38 (7), p. 1375.Google Scholar
9 Crane, D.T. Kossakovski, D. Bell, L.E. 2009, Journal of Electronic Materials, 38 (7), p. 1382.Google Scholar