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    刘宏升

    • 教授     博士生导师   硕士生导师
    • 主要任职:能源与动力学院副院长
    • 性别:男
    • 毕业院校:大连理工大学
    • 学位:博士
    • 所在单位:能源与动力学院
    • 学科:工程热物理
    • 办公地点:能源与动力学院918房间
    • 联系方式:电话:0411-84706902 Email:lhsh@dlut.edu.cn
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    Numerical investigation on the thermal non-equilibrium in low-velocity reacting flow within porous media

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    论文类型:期刊论文

    发表时间:2014-10-01

    发表刊物:INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER

    收录刊物:SCIE、EI

    卷号:77

    页面范围:585-599

    ISSN号:0017-9310

    关键字:Thermal non-equilibrium; Reacting flow; Porous media; Reaction heat

    摘要:This paper addresses the thermal non-equilibrium problem for a low-velocity reacting flow within isotropic porous media. The method of volume-averaging is employed to derive the macroscopic thermal transport equation for the fluid phase inside the porous medium including a heat source due to a homogenous chemical reaction, which is then closed by representing the temperature deviation through a constitutive equation. Theoretical treatment indicates that the contribution of the non-equilibrium due to reaction heat to the macroscopic heat transfer comes up in terms of an additional energy source rather than affecting thermal transport properties. Through dimensional analysis, this term can be interpreted as a convective transport of the reaction heat. Numerical computations are conducted by solving the closure problems at the pore scale for the fluid phase in a spatially periodic representative elementary volume (REV). Simulation results show that the convective coefficient related with the reaction heat is dependent on the Thiele modulus number, and the arrangement of cylinders. For the inline case, when the Peclet number is less than 10, a part of reaction heat will feed back to the upstream due to local conductivity, for Peclet number greater than 10 this part of energy will be transmitted to the downstream. For the staggered case, the same conclusion holds for smaller Peclet number, while the non-equilibrium will gradually decay to zero as the Peclet number increases. In addition, the other effective coefficients, such as effective conductivity, surface convective heat transfer coefficient are calculated with and without inertia. (C) 2014 Elsevier Ltd. All rights reserved.