Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models

Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models

Inserting porous media into the micro-scale combustor space could enhance heat recirculation from the flame zone, and could thus extend the flammability limits and improve flame stability. In the context of porous micro-combustors, the pore size is comparable to the combustor characteristic length....

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Main Authors: Qingqing Li, Jiansheng Wang, Jun Li, Junrui Shi
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Applied Sciences
Subjects:
micro-combustor
porous media
numerical simulation
alumina sphere
pore-scale model
volume-averaged model
Online Access:https://www.mdpi.com/2076-3417/11/16/7496
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spelling doaj-d1eb6119457b4d1c83b2137773047c342021-08-26T13:30:15ZengMDPI AGApplied Sciences2076-34172021-08-01117496749610.3390/app11167496Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged ModelsQingqing Li0Jiansheng Wang1Jun Li2Junrui Shi3Key Laboratory of Efficient Utilization of Low and Medium Grade Energy, Ministry of Education, Tianjin University, Tianjin 300350, ChinaKey Laboratory of Efficient Utilization of Low and Medium Grade Energy, Ministry of Education, Tianjin University, Tianjin 300350, ChinaKey Laboratory of Efficient Utilization of Low and Medium Grade Energy, Ministry of Education, Tianjin University, Tianjin 300350, ChinaSchool of Transportation and Vehicle Engineering, Shandong University of Technology, Zibo 255000, ChinaInserting porous media into the micro-scale combustor space could enhance heat recirculation from the flame zone, and could thus extend the flammability limits and improve flame stability. In the context of porous micro-combustors, the pore size is comparable to the combustor characteristic length. It is insufficient to treat the porous medium as a continuum with the volume-averaged model (VAM). Therefore, a pore-scale model (PSM) is developed to consider the detailed structure of the porous media to better understand the coupling among the gas mixture, the porous media and the combustor wall. The results are systematically compared to investigate the difference in combustion characteristics and flame stability limits. A quantified study is undertaken to examine heat recirculation, including preheating and heat loss, in the porous micro-combustor using the VAM and PSM, which are beneficial for understanding the modeled differences in temperature distribution. The numerical results indicate that PSM predicts a scattered flame zone in the pore areas and gives a larger flame stability range, a lower flame temperature and peak solid matrix temperature, a higher peak wall temperature and a larger <i>R<sub>p-hl</sub></i> than a VAM counterpart. A parametric study is subsequently carried out to examine the effects of solid matrix thermal conductivity (<i>k<sub>s</sub></i>) on the PSM and VAM, and then the results are analyzed briefly. It is found that for the specific configurations of porous micro-combustor considered in the present study, the PSM porous micro-combustor is more suitable for simplifying to a VAM with a larger <i>Φ</i> and a smaller <i>k<sub>s</sub></i>, and the methods can be applied to other configurations of porous micro-combustors.https://www.mdpi.com/2076-3417/11/16/7496micro-combustorporous medianumerical simulationalumina spherepore-scale modelvolume-averaged model
collection DOAJ
language English
format Article
sources DOAJ
author Qingqing Li
Jiansheng Wang
Jun Li
Junrui Shi
spellingShingle Qingqing Li
Jiansheng Wang
Jun Li
Junrui Shi
Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
Applied Sciences
micro-combustor
porous media
numerical simulation
alumina sphere
pore-scale model
volume-averaged model
author_facet Qingqing Li
Jiansheng Wang
Jun Li
Junrui Shi
author_sort Qingqing Li
title Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
title_short Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
title_full Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
title_fullStr Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
title_full_unstemmed Fundamental Numerical Analysis of a Porous Micro-Combustor Filled with Alumina Spheres: Pore-Scale vs. Volume-Averaged Models
title_sort fundamental numerical analysis of a porous micro-combustor filled with alumina spheres: pore-scale vs. volume-averaged models
publisher MDPI AG
series Applied Sciences
issn 2076-3417
publishDate 2021-08-01
description Inserting porous media into the micro-scale combustor space could enhance heat recirculation from the flame zone, and could thus extend the flammability limits and improve flame stability. In the context of porous micro-combustors, the pore size is comparable to the combustor characteristic length. It is insufficient to treat the porous medium as a continuum with the volume-averaged model (VAM). Therefore, a pore-scale model (PSM) is developed to consider the detailed structure of the porous media to better understand the coupling among the gas mixture, the porous media and the combustor wall. The results are systematically compared to investigate the difference in combustion characteristics and flame stability limits. A quantified study is undertaken to examine heat recirculation, including preheating and heat loss, in the porous micro-combustor using the VAM and PSM, which are beneficial for understanding the modeled differences in temperature distribution. The numerical results indicate that PSM predicts a scattered flame zone in the pore areas and gives a larger flame stability range, a lower flame temperature and peak solid matrix temperature, a higher peak wall temperature and a larger <i>R<sub>p-hl</sub></i> than a VAM counterpart. A parametric study is subsequently carried out to examine the effects of solid matrix thermal conductivity (<i>k<sub>s</sub></i>) on the PSM and VAM, and then the results are analyzed briefly. It is found that for the specific configurations of porous micro-combustor considered in the present study, the PSM porous micro-combustor is more suitable for simplifying to a VAM with a larger <i>Φ</i> and a smaller <i>k<sub>s</sub></i>, and the methods can be applied to other configurations of porous micro-combustors.
topic micro-combustor
porous media
numerical simulation
alumina sphere
pore-scale model
volume-averaged model
url https://www.mdpi.com/2076-3417/11/16/7496
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AT junli fundamentalnumericalanalysisofaporousmicrocombustorfilledwithaluminaspheresporescalevsvolumeaveragedmodels
AT junruishi fundamentalnumericalanalysisofaporousmicrocombustorfilledwithaluminaspheresporescalevsvolumeaveragedmodels
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