Hydrogen-Fueled Micro-Thermophotovoltaic Power Generator: Flame Regimes and Flame Stability
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Hydrogen-Fueled Micro-Thermophotovoltaic Power Generator: Flame Regimes and Flame Stability

Authors: Hosein Faramarzpour

Abstract:

This work presents the optimum operational conditions for a hydrogen-based micro-scale power source, using a verified mathematical model including fluid dynamics and reaction kinetics. Thereafter, the stable operational flame regime is pursued as a key factor in optimizing the design of micro-combustors. The results show that with increasing velocities, four H2 flame regimes develop in the micro-combustor, namely: 1) periodic ignition-extinction regime, 2) steady symmetric regime, 3) pulsating asymmetric regime, and 4) steady asymmetric regime. The first regime that appears in 0.8 m/s inlet velocity is a periodic ignition-extinction regime which is characterized by counter flows and tulip-shape flames. For flow velocity above 0.2 m/s, the flame shifts downstream, and the combustion regime switches to a steady symmetric flame where temperature increases considerably due to the increased rate of incoming energy. Further elevation in flow velocity up to 1 m/s leads to the pulsating asymmetric flame formation, which is associated with pulses in various flame properties such as temperature and species concentration. Further elevation in flow velocity up to 1 m/s leads to the pulsating asymmetric flame formation, which is associated with pulses in various flame properties such as temperature and species concentration. Ultimately, when the inlet velocity reached 1.2 m/s, the last regime was observed, and a steady asymmetric regime appeared.

Keywords: Thermophotovoltaic generator, micro combustor, micro power generator, combustion regimes, flame dynamic.

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[1] J. Li, Q. Li, Y. Wang, Z. Guo, X. Liu, Fundamental flame characteristics of premixed H2–air combustion in a planar porous micro-combustor, Chemical engineering journal 283 (2016) 1187-1196.
[2] H. Daneshvar, R. Prinja, N.P. Kherani, Thermophotovoltaics: Fundamentals, challenges and prospects, Applied Energy 159 (2015) 560-575.
[3] M. Bianchi, C. Ferrari, F. Melino, A. Peretto, Feasibility study of a Thermo-Photo-Voltaic system for CHP application in residential buildings, Applied Energy 97 (2012) 704-713.
[4] E.S. Barbieri, P.R. Spina, M. Venturini, Analysis of innovative micro-CHP systems to meet household energy demands, Applied Energy 97 (2012) 723-733.
[5] K. Qiu, A. Hayden, Increasing the efficiency of radiant burners by using polymer membranes, Applied Energy 86(3) (2009) 349-354.
[6] M. Malushte, S. Kumar, Flame dynamics in a stepped micro-combustor for non-adiabatic wall conditions, Thermal Science and Engineering Progress 13 (2019) 100394.
[7] Y. Ju, B. Xu, Theoretical and experimental studies on mesoscale flame propagation and extinction, Proceedings of the Combustion Institute 30(2) (2005) 2445-2453.
[8] K. Maruta, T. Kataoka, N.I. Kim, S. Minaev, R. Fursenko, Characteristics of combustion in a narrow channel with a temperature gradient, Proceedings of the combustion institute 30(2) (2005) 2429-2436.
[9] G. Pizza, C.E. Frouzakis, J. Mantzaras, A.G. Tomboulides, K. Boulouchos, Dynamics of premixed hydrogen/air flames in mesoscale channels, Combustion and Flame 155(1-2) (2008) 2-20.
[10] M. Akram, S. Kumar, Experimental studies on dynamics of methane–air premixed flame in meso-scale diverging channels, Combustion and flame 158(5) (2011) 915-924.
[11] A. Yamamoto, H. Oshibe, H. Nakamura, T. Tezuka, S. Hasegawa, K. Maruta, Stabilized three-stage oxidation of gaseous n-heptane/air mixture in a micro flow reactor with a controlled temperature profile, Proceedings of the Combustion Institute 33(2) (2011) 3259-3266.
[12] H. Nakamura, A. Fan, S. Minaev, E. Sereshchenko, R. Fursenko, Y. Tsuboi, K. Maruta, Bifurcations and negative propagation speeds of methane/air premixed flames with repetitive extinction and ignition in a heated microchannel, Combustion and Flame 159(4) (2012) 1631-1643.
[13] A. Fan, S. Minaev, E. Sereshchenko, Y. Tsuboi, H. Oshibe, H. Nakamura, K. Maruta, Dynamic behavior of splitting flames in a heated channel, Combustion, Explosion, and Shock Waves 45 (2009) 245-250.
[14] A. Brambilla, C.E. Frouzakis, J. Mantzaras, A. Tomboulides, S. Kerkemeier, K. Boulouchos, Detailed transient numerical simulation of H2/air hetero-/homogeneous combustion in platinum-coated channels with conjugate heat transfer, Combustion and Flame 161(10) (2014) 2692-2707.
[15] T. Kamada, H. Nakamura, T. Tezuka, S. Hasegawa, K. Maruta, Study on combustion and ignition characteristics of natural gas components in a micro flow reactor with a controlled temperature profile, Combustion and Flame 161(1) (2014) 37-48.
[16] A. Majda, J. Sethian, The derivation and numerical solution of the equations for zero Mach number combustion, Combustion science and technology 42(3-4) (1985) 185-205.
[17] I. Bahrabadi-Jovein, S. Seddighi, J. Bashtani, Sulfur Dioxide Removal Using Hydrogen Peroxide in Sodium-and Calcium-Based Absorbers, Energy & Fuels 31(12) (2017) 14007–14017.
[18] J. Bashtani, S. Seddighi, I. Bahrabadi-Jovein, Control of nitrogen oxide formation in power generation using modified reaction kinetics and mixing, Energy 145 (2018) 567-581.
[19] A. Alipoor, K. Mazaheri, Combustion characteristics and flame bifurcation in repetitive extinction-ignition dynamics for premixed hydrogen-air combustion in a heated micro channel, Energy 109 (2016) 650-663.
[20] S. Turns, An Introduction to Combustion: Concepts and Applications, McGraw-Hill, Mc Graw Hill2000.
[21] G. Pizza, J. Mantzaras, C.E. Frouzakis, Flame dynamics in catalytic and non-catalytic mesoscale microreactors, Catalysis Today 155(1-2) (2010) 123-130.
[22] G. Pizza, C.E. Frouzakis, J. Mantzaras, A.G. Tomboulides, K. Boulouchos, Three-dimensional simulations of premixed hydrogen/air flames in microtubes, Journal of Fluid Mechanics 658 (2010) 463-491.
[23] T. Poinsot, D. Veynante, Theoretical and numerical combustion, RT Edwards, Inc.2005.
[24] V. Toro, A. Mokhov, H. Levinsky, M. Smooke, Combined experimental and computational study of laminar, axisymmetric hydrogen–air diffusion flames, Proceedings of the Combustion Institute 30(1) (2005) 485-492.
[25] D.G. Norton, D.G. Vlachos, Combustion characteristics and flame stability at the microscale: a CFD study of premixed methane/air mixtures, Chemical engineering science 58(21) (2003) 4871-4882.