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Abstract-An experimental study on combustion in porous media and thermoelectric generation was performed. The reactor was composed of two types of porous media where flame stabilization was reached at the interface of them. An external thermoelectric module was placed to harvest the thermal energy produced in the system. Maximum values of voltage and current obtained were 503 mV and 150 mA respectively.

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Numerical Study of Reciprocal Flow Porous Media Burners Coupled With Thermoelectric Generation

Henríquez-Vargas

Loyola

Sanhueza

et al. 2015

J Por Media

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Numerical study of a waste heat recovery thermogenerator system

Donoso-García

Henríquez-Vargas

2019

J Braz. Soc. Mech. Sci. Eng.

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This paper presents a numerical study on waste heat recovery from a fluid stream using thermoelectric elements for energy harvesting. Two fluids were tested, air and steam, and the voltage and overall efficiency were computed for different sets of operational conditions. The mathematical description considered turbulent regime and coupled transport phenomena for the description of the main thermoelectric effects. Numerical solution was achieved using ANSYS/FLUENT commercial software with complementary implementations of user-defined scalars and user-defined functions to account for the mathematical model specific needs. The system global efficiency was computed for a pair of heat extraction conditions and different operational variables giving values within [0.11-9.22] (%). It was found that the global efficiency increases with the fluid temperature and the decrease in the external thermal resistance. For all cases studied, the global efficiency was greater when air was used as a heat carrier fluid due to its specific heat values which were about half the steam ones. Keywords Waste heat • Thermoelectricity • Heat recovery • Seebeck effect List of symbols c p Specific heat capacity c 1 Turbulent model parameter c 2 Turbulent model parameter c Turbulent model parameter Mass transport tensor D Square duct side D Mass diffusivity Electric field intensity vector e Height External field acceleration G k Rate of k generation H Specific enthalpy h Heat transfer coefficient Unitary tensor I Current Electric current density vector Effective conductivity tensor k Turbulent kinetic energy

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