Optimization of a waste heat recovery system with thermoelectric generators by three-dimensional thermal resistance analysis

[Display omitted] •The waste heat recovery system is modeled by three-dimensional thermal resistance.•This is a time-saving and efficient method to estimate power generation from TEGs.•Relations between power generation and varied factors can be rapidly revealed.•TEGs positions and uniformity of vel...

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Bibliographic Details
Published in:Energy conversion and management 2016-10, Vol.126, p.581-594
Main Authors: Huang, Gia-Yeh, Hsu, Cheng-Ting, Fang, Chun-Jen, Yao, Da-Jeng
Format: Article
Language:English
Subjects:
Modeling
Thermal resistance
Thermoelectric generator
Waste heat recovery system
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Summary:[Display omitted] •The waste heat recovery system is modeled by three-dimensional thermal resistance.•This is a time-saving and efficient method to estimate power generation from TEGs.•Relations between power generation and varied factors can be rapidly revealed.•TEGs positions and uniformity of velocity profile should be considered together.•Power generation is more sensitive to either internal or external flow velocity. Three-dimensional (3D) thermal resistance analysis provides a rapid and simple method to estimate the power generated from a waste heat recovery system with thermoelectric generators (TEGs), and facilitates an optimization of the system. Such a system comprises three parts – a waste heat recovery chamber, TEG modules and a cooling system. A fin-structured duct serves as a waste heat recovery chamber, which is attached to the hot sides of the TEGs; the cold sides of the TEGs are attached to a cooling system. The waste heat recovery chamber harvests energy from exhaust heat that the TEGs convert into electricity. The estimation of generated power is an important part of the system design. Methods of Computational Fluid Dynamics (CFD) assist the analysis and improve the performance with great accuracy but great computational duration. The use of this method saves much time relative to such CFD methods. In 3D thermal resistance analysis, a node of unknown temperature is located at the centroid of each cell into which the system is divided. The relations of unknown temperatures at the cells are based on the energy conservation and the definition of thermal resistance. The temperatures of inlet waste hot gas and ambient fluid are known. With these boundary conditions, the unknown temperatures in the system are solved, enabling estimation of the power generated with TEGs. A 3D model of the system was simulated with FloTHERM; its numerical solution matched the solution of the 3D thermal resistance analysis within 6%. The power generated with the same system with TEGs (TMH400302055, Wise Life Technology, Taiwan) was measured; the experimental result is consistent with the result obtained from the 3D thermal resistance analysis; the relative deviation is approximately 10%. The power generated is affected by many variables; the positions of the TEGs, the uniformity of the internal flow of the velocity profile and the internal and external flow velocities are considered in our 3D thermal resistance analysis. According to the results, both the positio
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2016.08.038