Amirkabir University of Technology Amirkabir Journal of Mechanical Engineering 2008-6032 53 5 2021 07 23 Study of the effective parameters on the performance of a micro thermophotovoltaic system with micro porous combustion chamber Study of the effective parameters on the performance of a micro thermophotovoltaic system with micro porous combustion chamber 2921 2934 3967 10.22060/mej.2020.17903.6686 FA Mohammadsaaber Khosravi Department of Mechanical Engineering, University of Kashan, Kashan, Iran Seyed Abdolmehdi Hashemi 0000-0001-7169-7173 Journal Article 2020 02 10 The advantage of micro thermophotovoltaic systems is the direct conversion of heat energy into electrical energy without any moving parts. For an adequate performance of thermophotovoltaic systems, uniform and high temperature along the micro-chamber wall is required. In the present study, a laminar premixed combustion of hydrogen-air in a micro porous chamber is studied. Non-equilibrium thermal condition between gas and solid phases and radiative transport equation in solid phase is considered . Using numerical simulation, the effect of several parameters on the radiation efficiency of thermophotovoltaic system including equivalence ratio, porosity, porous thermal conductivity and inlet mixture velocity have been studied. The results show that increasing the equivalence ratio up to 1 increases the wall temperature and increasing the thermal conductivity of the porous medium, results in a more uniform temperature distribution. Also decreasing the inlet velocity, porosity and thermal conductivity of the porous medium increases the system's radiation efficiency. The convection heat transfer between the gas and solid phases inside the porous and the radiation and conduction heat transfer in the porous for the porosity of 0.4 and 0.8 were compared and it was shown that the role of radiation heat transfer inside the porous is negligible. The advantage of micro thermophotovoltaic systems is the direct conversion of heat energy into electrical energy without any moving parts. For an adequate performance of thermophotovoltaic systems, uniform and high temperature along the micro-chamber wall is required. In the present study, a laminar premixed combustion of hydrogen-air in a micro porous chamber is studied. Non-equilibrium thermal condition between gas and solid phases and radiative transport equation in solid phase is considered . Using numerical simulation, the effect of several parameters on the radiation efficiency of thermophotovoltaic system including equivalence ratio, porosity, porous thermal conductivity and inlet mixture velocity have been studied. The results show that increasing the equivalence ratio up to 1 increases the wall temperature and increasing the thermal conductivity of the porous medium, results in a more uniform temperature distribution. Also decreasing the inlet velocity, porosity and thermal conductivity of the porous medium increases the system's radiation efficiency. The convection heat transfer between the gas and solid phases inside the porous and the radiation and conduction heat transfer in the porous for the porosity of 0.4 and 0.8 were compared and it was shown that the role of radiation heat transfer inside the porous is negligible. Microcombustor Porous Media numerical simulation Non-equilibrium thermal radiation efficiency https://mej.aut.ac.ir/article_3967_b607ba543ad05417b8507ee86c54fcb7.pdf