{"title":"杜富尔/索雷特和空间相关内部热源对多孔介质中流经垂直全锥体的非牛顿流体联合对流的影响:VHF/VMF 案例","authors":"Kuo-Ann Yih, Heng-Pin Hsu","doi":"10.1007/s12217-024-10100-4","DOIUrl":null,"url":null,"abstract":"<div><p>This paper numerically analyzes the influence of Dufour/Soret and space-dependent internal heat source (exponential decaying form) on combined convection (entire regime) of non-Newtonian fluids (power-law model of Ostwald-de-Waele) flow past a vertical full cone in porous media with the boundary conditions of VHF/VMF case. The transformed governing equations (non-similar equations) are solved by Keller box method (KBM). Numerical data for the dimensionless temperature profile, the dimensionless concentration profile, the local Nusselt number and the local Sherwood number are graphically and tabularly presented for the nine parameters: the buoyancy ratio <span>\\(N\\)</span>, the Lewis number <span>\\(Le\\)</span>, the Dufour parameter <span>\\(Df\\)</span>, the Soret parameter <span>\\(Sr\\)</span>, the cone angle parameter <span>\\(m\\)</span>, the mixed convection parameter <span>\\(\\xi\\)</span>, the VHF/VMF exponent <span>\\(\\lambda\\)</span>, the non-Newtonian fluid power-law index <span>\\(n\\)</span>, the space-dependent internal heat source coefficient <span>\\({A}^{*}\\)</span>. The increase of the buoyancy ratio <span>\\(N\\)</span> and the VHF/VMF exponent <span>\\(\\lambda\\)</span> tends to increase both the local Nusselt number and the local Sherwood number. The Nusselt number enhances with increasing the Soret parameter <span>\\(Sr\\)</span>. Increasing the Lewis number <span>\\(Le\\)</span>, the Dufour parameter <span>\\(Df\\)</span>, the space-dependent internal heat source coefficient <span>\\({A}^{*}\\)</span> enhances the Sherwood number. When the power-law index <span>\\(n\\)</span> is decreased, the local Nusselt and Sherwood numbers are increased. The physical aspects of the problem are discussed in details.</p></div>","PeriodicalId":707,"journal":{"name":"Microgravity Science and Technology","volume":null,"pages":null},"PeriodicalIF":1.3000,"publicationDate":"2024-04-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Influence of Dufour/Soret and Space-Dependent Internal Heat Source on Combined Convection of Non-Newtonian Fluids Flow Past a Vertical Full Cone in Porous Media: The VHF/VMF Case\",\"authors\":\"Kuo-Ann Yih, Heng-Pin Hsu\",\"doi\":\"10.1007/s12217-024-10100-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>This paper numerically analyzes the influence of Dufour/Soret and space-dependent internal heat source (exponential decaying form) on combined convection (entire regime) of non-Newtonian fluids (power-law model of Ostwald-de-Waele) flow past a vertical full cone in porous media with the boundary conditions of VHF/VMF case. The transformed governing equations (non-similar equations) are solved by Keller box method (KBM). Numerical data for the dimensionless temperature profile, the dimensionless concentration profile, the local Nusselt number and the local Sherwood number are graphically and tabularly presented for the nine parameters: the buoyancy ratio <span>\\\\(N\\\\)</span>, the Lewis number <span>\\\\(Le\\\\)</span>, the Dufour parameter <span>\\\\(Df\\\\)</span>, the Soret parameter <span>\\\\(Sr\\\\)</span>, the cone angle parameter <span>\\\\(m\\\\)</span>, the mixed convection parameter <span>\\\\(\\\\xi\\\\)</span>, the VHF/VMF exponent <span>\\\\(\\\\lambda\\\\)</span>, the non-Newtonian fluid power-law index <span>\\\\(n\\\\)</span>, the space-dependent internal heat source coefficient <span>\\\\({A}^{*}\\\\)</span>. The increase of the buoyancy ratio <span>\\\\(N\\\\)</span> and the VHF/VMF exponent <span>\\\\(\\\\lambda\\\\)</span> tends to increase both the local Nusselt number and the local Sherwood number. The Nusselt number enhances with increasing the Soret parameter <span>\\\\(Sr\\\\)</span>. Increasing the Lewis number <span>\\\\(Le\\\\)</span>, the Dufour parameter <span>\\\\(Df\\\\)</span>, the space-dependent internal heat source coefficient <span>\\\\({A}^{*}\\\\)</span> enhances the Sherwood number. When the power-law index <span>\\\\(n\\\\)</span> is decreased, the local Nusselt and Sherwood numbers are increased. 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Influence of Dufour/Soret and Space-Dependent Internal Heat Source on Combined Convection of Non-Newtonian Fluids Flow Past a Vertical Full Cone in Porous Media: The VHF/VMF Case
This paper numerically analyzes the influence of Dufour/Soret and space-dependent internal heat source (exponential decaying form) on combined convection (entire regime) of non-Newtonian fluids (power-law model of Ostwald-de-Waele) flow past a vertical full cone in porous media with the boundary conditions of VHF/VMF case. The transformed governing equations (non-similar equations) are solved by Keller box method (KBM). Numerical data for the dimensionless temperature profile, the dimensionless concentration profile, the local Nusselt number and the local Sherwood number are graphically and tabularly presented for the nine parameters: the buoyancy ratio \(N\), the Lewis number \(Le\), the Dufour parameter \(Df\), the Soret parameter \(Sr\), the cone angle parameter \(m\), the mixed convection parameter \(\xi\), the VHF/VMF exponent \(\lambda\), the non-Newtonian fluid power-law index \(n\), the space-dependent internal heat source coefficient \({A}^{*}\). The increase of the buoyancy ratio \(N\) and the VHF/VMF exponent \(\lambda\) tends to increase both the local Nusselt number and the local Sherwood number. The Nusselt number enhances with increasing the Soret parameter \(Sr\). Increasing the Lewis number \(Le\), the Dufour parameter \(Df\), the space-dependent internal heat source coefficient \({A}^{*}\) enhances the Sherwood number. When the power-law index \(n\) is decreased, the local Nusselt and Sherwood numbers are increased. The physical aspects of the problem are discussed in details.
期刊介绍:
Microgravity Science and Technology – An International Journal for Microgravity and Space Exploration Related Research is a is a peer-reviewed scientific journal concerned with all topics, experimental as well as theoretical, related to research carried out under conditions of altered gravity.
Microgravity Science and Technology publishes papers dealing with studies performed on and prepared for platforms that provide real microgravity conditions (such as drop towers, parabolic flights, sounding rockets, reentry capsules and orbiting platforms), and on ground-based facilities aiming to simulate microgravity conditions on earth (such as levitrons, clinostats, random positioning machines, bed rest facilities, and micro-scale or neutral buoyancy facilities) or providing artificial gravity conditions (such as centrifuges).
Data from preparatory tests, hardware and instrumentation developments, lessons learnt as well as theoretical gravity-related considerations are welcome. Included science disciplines with gravity-related topics are:
− materials science
− fluid mechanics
− process engineering
− physics
− chemistry
− heat and mass transfer
− gravitational biology
− radiation biology
− exobiology and astrobiology
− human physiology
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