Parametric optimization of thermoelectric elements footprint for maximum power generation

A. Rezania; Lasse Rosendahl; Hao Yin

doi:10.1016/j.jpowsour.2014.01.002

Parametric optimization of thermoelectric elements footprint for maximum power generation

A. Rezania, Lasse Rosendahl, Hao Yin

AAU Energy

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

The development studies in thermoelectric generator (TEG) systems are mostly disconnected to parametric optimization of the module components. In this study, optimum footprint ratio of n- and p-type thermoelectric (TE) elements is explored to achieve maximum power generation, maximum cost-performance, and variation of efficiency in the uni-couple over a wide range of the heat transfer coefficient on the cold junction. The three-dimensional (3D) governing equations of the thermoelectricity and the heat transfer are solved using the finite element method (FEM) for temperature dependent properties of TE materials. The results, which are in good agreement with the previous computational studies, show that the maximum power generation and the maximum cost-performance in the module occur at An/Ap < 1 due to difference in electrical resistance and heat conductivity of the considered materials.

Original language	English
Journal	Journal of Power Sources
Volume	255
Pages (from-to)	151-156
Number of pages	6
ISSN	0378-7753
DOIs	https://doi.org/10.1016/j.jpowsour.2014.01.002
Publication status	Published - 1 Jun 2014

Keywords

Heat transfer coefficient
Maximum power generation
Optimal footprint ratio
Thermoelectric uni-couple

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title = "Parametric optimization of thermoelectric elements footprint for maximum power generation",

abstract = "The development studies in thermoelectric generator (TEG) systems are mostly disconnected to parametric optimization of the module components. In this study, optimum footprint ratio of n- and p-type thermoelectric (TE) elements is explored to achieve maximum power generation, maximum cost-performance, and variation of efficiency in the uni-couple over a wide range of the heat transfer coefficient on the cold junction. The three-dimensional (3D) governing equations of the thermoelectricity and the heat transfer are solved using the finite element method (FEM) for temperature dependent properties of TE materials. The results, which are in good agreement with the previous computational studies, show that the maximum power generation and the maximum cost-performance in the module occur at An/Ap < 1 due to difference in electrical resistance and heat conductivity of the considered materials.",

keywords = "Heat transfer coefficient, Maximum power generation, Optimal footprint ratio, Thermoelectric uni-couple",

author = "A. Rezania and Lasse Rosendahl and Hao Yin",

year = "2014",

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doi = "10.1016/j.jpowsour.2014.01.002",

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T1 - Parametric optimization of thermoelectric elements footprint for maximum power generation

AU - Rezania, A.

AU - Rosendahl, Lasse

AU - Yin, Hao

PY - 2014/6/1

Y1 - 2014/6/1

N2 - The development studies in thermoelectric generator (TEG) systems are mostly disconnected to parametric optimization of the module components. In this study, optimum footprint ratio of n- and p-type thermoelectric (TE) elements is explored to achieve maximum power generation, maximum cost-performance, and variation of efficiency in the uni-couple over a wide range of the heat transfer coefficient on the cold junction. The three-dimensional (3D) governing equations of the thermoelectricity and the heat transfer are solved using the finite element method (FEM) for temperature dependent properties of TE materials. The results, which are in good agreement with the previous computational studies, show that the maximum power generation and the maximum cost-performance in the module occur at An/Ap < 1 due to difference in electrical resistance and heat conductivity of the considered materials.

AB - The development studies in thermoelectric generator (TEG) systems are mostly disconnected to parametric optimization of the module components. In this study, optimum footprint ratio of n- and p-type thermoelectric (TE) elements is explored to achieve maximum power generation, maximum cost-performance, and variation of efficiency in the uni-couple over a wide range of the heat transfer coefficient on the cold junction. The three-dimensional (3D) governing equations of the thermoelectricity and the heat transfer are solved using the finite element method (FEM) for temperature dependent properties of TE materials. The results, which are in good agreement with the previous computational studies, show that the maximum power generation and the maximum cost-performance in the module occur at An/Ap < 1 due to difference in electrical resistance and heat conductivity of the considered materials.

KW - Heat transfer coefficient

KW - Maximum power generation

KW - Optimal footprint ratio

KW - Thermoelectric uni-couple

U2 - 10.1016/j.jpowsour.2014.01.002

DO - 10.1016/j.jpowsour.2014.01.002

M3 - Journal article

SN - 0378-7753

VL - 255

SP - 151

EP - 156

JO - Journal of Power Sources

JF - Journal of Power Sources

ER -

Parametric optimization of thermoelectric elements footprint for maximum power generation

Abstract

Keywords

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