含纳米流体饱和多孔介质的时间周期热边界效应:振荡模式的CGLE模型

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY Advances in Materials Science Pub Date : 2022-12-01 DOI:10.2478/adms-2022-0022
P. Kiran, S. H. Manjula
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引用次数: 2

摘要

摘要利用复矩阵微分算子理论研究了纳米流体非线性对流的稳定性。利用有限振幅分析方法,研究了饱和纳米流体并进行热调制的多孔介质中的非线性对流。采用复金兹堡-朗道方程(CGLE)来确定有限振幅对流,以评估传热传质。对流的小振幅被认为是确定传热和传质通过多孔介质。系统的热调制预计会随时间呈正弦变化,如图所示。三种不同的调制IPM, OPM和LBMO进行了研究,发现OPM和LBMO的情况下是用来调节传热和传质。此外,还发现调制频率(ωf从2到70不等)降低了传热和传质,而调制幅度(δ1从0.1到0.5不等)提高了传热和传质。
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Time-Periodic Thermal Boundary Effects on Porous Media Saturated with Nanofluids: CGLE Model for Oscillatory Mode
Abstract The stability of nonlinear nanofluid convection is examined using the complex matrix differential operator theory. With the help of finite amplitude analysis, nonlinear convection in a porous medium is investigated that has been saturated with nanofluid and subjected to thermal modulation. The complex Ginzburg-Landau equation (CGLE) is used to determine the finite amplitude convection in order to evaluate heat and mass transfer. The small amplitude of convection is considered to determine heat and mass transfer through the porous medium. Thermal modulation of the system is predicted to change sinusoidally over time, as shown at the boundary. Three distinct modulations IPM, OPM, and LBMOhave been investigated and found that OPM and LBMO cases are used to regulate heat and mass transfer. Further, it is found that modulation frequency (ωf varying from 2 to 70) reduces heat and mass transfer while modulation amplitude (δ1varying from 0.1 to 0.5 ) enhances both.
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Advances in Materials Science
Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
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