Fractal model of solid-liquid two-phase thermal transport characteristics in the rough fracture network

IF 2.5 4区 工程技术 Q2 ENGINEERING, MECHANICAL
shanshan yang, Qiong Sheng, Mingqing Zou, Mengying Wang, Ruike Cui, Shuaiyin Chen, Qian Zheng
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Abstract

To discuss the influencing factors of thermal transport features in coarse fracture networks, the heat transfer analysis model of solid-liquid two-phase flow in a rough fracture network is created in this text. By calculating the thermal resistance and thermal conductivity of rough cracks, it was found that the thermal transport capacity of cracks is inversely proportional to relative roughness and porosity, and it is directly proportional to the ratio of solid-liquid thermal conductivity and Fractal dimension. Compared with other models and existing experimental data, it is concluded that the heat transfer capacity of dual media is stronger than that of the single porous medium. Finally, the percentage of thermal conductivity in the total thermal conductivity of the three parts was compared, and it was found that the strength of thermal transport mainly depends on the heat transfer ability of the matrix, because the solid thermal conductivity is much greater than the liquid thermal conductivity, so the thermal transport ability of the matrix is stronger than that of cracks and pores.
粗糙断裂网络中固液两相热传导特性的分形模型
为探讨粗大裂缝网络热输运特征的影响因素,本文建立了粗大裂缝网络固液两相流的传热分析模型。通过计算粗糙裂缝的热阻和热导率,发现裂缝的热传输能力与相对粗糙度和孔隙率成反比,与固液热导率比值和分形维数成正比。与其他模型和现有实验数据相比,结论是双介质的传热能力强于单多孔介质。最后,比较了三部分热传导率在总热传导率中所占的比例,发现热传导的强弱主要取决于基体的传热能力,因为固体热传导率远大于液体热传导率,所以基体的热传导能力强于裂缝和孔隙的热传导能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Porous Media
Journal of Porous Media 工程技术-工程:机械
CiteScore
3.50
自引率
8.70%
发文量
89
审稿时长
12.5 months
期刊介绍: The Journal of Porous Media publishes original full-length research articles (and technical notes) in a wide variety of areas related to porous media studies, such as mathematical modeling, numerical and experimental techniques, industrial and environmental heat and mass transfer, conduction, convection, radiation, particle transport and capillary effects, reactive flows, deformable porous media, biomedical applications, and mechanics of the porous substrate. Emphasis will be given to manuscripts that present novel findings pertinent to these areas. The journal will also consider publication of state-of-the-art reviews. Manuscripts applying known methods to previously solved problems or providing results in the absence of scientific motivation or application will not be accepted. Submitted articles should contribute to the understanding of specific scientific problems or to solution techniques that are useful in applications. Papers that link theory with computational practice to provide insight into the processes are welcome.
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