Analysis of the construction of TEG thermoelectric generator using CFD tools

The article consists of an analysis of the construction of a thermoelectric generator with an automotive application (ATEG – Automotive Thermoelectric Generator). It works based on the thermoelectric effect in which thermal energy is converted into electricity. This is done in thermoelectric modules...

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Hauptverfasser:	Ziółkowski, Andrzej, Fuć, Paweł, Dobrzyński, Michał
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Boundary conditions Compression tests Computational fluid dynamics Computer simulation Exhaust gases External walls Fins Flux density Gas temperature Heat Heat exchangers Heat flux Kinetic energy Mass flow rate Mathematical models Modules Motor vehicles Numerical analysis Stress concentration Temperature distribution Thermal energy Thermoelectric generators Thermoelectricity Turbulence
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creator	Ziółkowski, Andrzej Fuć, Paweł Dobrzyński, Michał
description	The article consists of an analysis of the construction of a thermoelectric generator with an automotive application (ATEG – Automotive Thermoelectric Generator). It works based on the thermoelectric effect in which thermal energy is converted into electricity. This is done in thermoelectric modules (TEM). The construction of the ATEG uses a rectangular heat exchanger, to which 24 modules were attached in six rows. Each of them was assigned one cooler. In the first stage of research the boundary conditions for computer simulations were defined: mass flow rate and exhaust gas temperature. The adopted values were based on measurements made in the real operating conditions (RDE tests) for a motor vehicle equipped with a compression-ignition engine. Next, the ATEG model geometry developed in the CAD modeling software was imported into Ansys CFX v16. For the needs of numerical analysis, all unnecessary elements that did not affect the results of operation were removed. Subsequent calculations were made regarding the distribution of velocity, pressure and parameters influencing the heat exchange value, such as the kinetic energy of turbulence and the kinetic energy of turbulence dissipation rate. The final stage of the research was to perform the simulation of heat exchange parameters – temperature distribution and heat flux density on the surface of the exchanger fins and on the external walls.
doi_str_mv	10.1063/1.5092055
format	Conference Proceeding
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Subsequent calculations were made regarding the distribution of velocity, pressure and parameters influencing the heat exchange value, such as the kinetic energy of turbulence and the kinetic energy of turbulence dissipation rate. The final stage of the research was to perform the simulation of heat exchange parameters – temperature distribution and heat flux density on the surface of the exchanger fins and on the external walls.</description><identifier>ISSN: 0094-243X</identifier><identifier>EISSN: 1551-7616</identifier><identifier>DOI: 10.1063/1.5092055</identifier><identifier>CODEN: APCPCS</identifier><language>eng</language><publisher>Melville: American Institute of Physics</publisher><subject>Boundary conditions ; Compression tests ; Computational fluid dynamics ; Computer simulation ; Exhaust gases ; External walls ; Fins ; Flux density ; Gas temperature ; Heat ; Heat exchangers ; Heat flux ; Kinetic energy ; Mass flow rate ; Mathematical models ; Modules ; Motor vehicles ; Numerical analysis ; Stress concentration ; Temperature distribution ; Thermal energy ; Thermoelectric generators ; Thermoelectricity ; Turbulence</subject><ispartof>AIP Conference Proceedings, 2019, Vol.2078 (1)</ispartof><rights>Author(s)</rights><rights>2019 Author(s). 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Subsequent calculations were made regarding the distribution of velocity, pressure and parameters influencing the heat exchange value, such as the kinetic energy of turbulence and the kinetic energy of turbulence dissipation rate. 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Subsequent calculations were made regarding the distribution of velocity, pressure and parameters influencing the heat exchange value, such as the kinetic energy of turbulence and the kinetic energy of turbulence dissipation rate. The final stage of the research was to perform the simulation of heat exchange parameters – temperature distribution and heat flux density on the surface of the exchanger fins and on the external walls.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/1.5092055</doi><tpages>8</tpages><oa>free_for_read</oa></addata></record>
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source	AIP Journals Complete
subjects	Boundary conditions Compression tests Computational fluid dynamics Computer simulation Exhaust gases External walls Fins Flux density Gas temperature Heat Heat exchangers Heat flux Kinetic energy Mass flow rate Mathematical models Modules Motor vehicles Numerical analysis Stress concentration Temperature distribution Thermal energy Thermoelectric generators Thermoelectricity Turbulence
title	Analysis of the construction of TEG thermoelectric generator using CFD tools
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