基底流体、其温度和热源对对流-辐射条件下通过滑动多孔微通道的 MHD Couette-Poiseuille 纳米流体的影响:熵分析

IF 1.3 4区 工程技术 Q3 ENGINEERING, MECHANICAL
P. Mondal, D. K. Maiti
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引用次数: 0

摘要

摘要本研究的目的是分析纳米流体在垂直通道内的流动、传热和熵产。垂直微通道由两个平行的多孔滑板组成。热流体从左侧注入,从右侧成功注入。通道内的流体流动是由于施加的有利/不利压力梯度(由于Couette-Poiseuille流动)、右板运动、由于通道内存在热产生/吸收的通道板的温差以及施加恒定的横向磁场而引起的浮力而引起的。用射击法对得到的控制方程进行了数值求解。常规的流体选择为水和乙二醇-水混合物。纳米颗粒分别为Al2O3和CuO。纳米流体模型考虑了基液温度、布朗运动、纳米颗粒的直径和浓度以及基液的物理性质。研究了压力梯度P(入口处)、基液温度、产热/吸收、纳米颗粒体积分数密度对流动和传热特性(速度和温度分布、努塞尔数(Nu)分布、熵产和贝让数)的影响。本文讨论了注射/吸力、辐射和对流边界条件的存在如何干扰流动和换热特性曲线的出现顺序(由于上述参数的变化)。对由热流、流体摩擦和焦耳热引起的不可逆性对总熵生成的个别贡献进行了批判性分析。最后,我们试图找到一个最优条件,在该条件下,局部和全局熵产生在信道中最小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Base Fluids, Its Temperature and Heat Source on MHD Couette–Poiseuille Nanofluid Flow through Slippy Porous Microchannel with Convective-Radiative Condition: Entropy Analysis

Base Fluids, Its Temperature and Heat Source on MHD Couette–Poiseuille Nanofluid Flow through Slippy Porous Microchannel with Convective-Radiative Condition: Entropy Analysis

Base Fluids, Its Temperature and Heat Source on MHD Couette–Poiseuille Nanofluid Flow through Slippy Porous Microchannel with Convective-Radiative Condition: Entropy Analysis

The intention behind this research work is to analyze the flow, heat transfer and entropy generation in a vertical channel filled with a nanofluid. The vertical microchannel is made of two parallel porous and slippy plates. The hot fluid is injected from the left side and succeeded from the right side. Fluid flow within the channel is induced due to an applied favorable/adverse pressure gradient (due to Couette–Poiseuille flow), right plate movement, buoyancy force due to the temperature difference of the channel plates in the presence of heat generation/absorption inside the channel and subjected to a constant applied transverse magnetic field. The resulting governing equations are solved numerically by the shooting method. The conventional fluids are chosen as water, and ethylene glycol-water mixture. The nanoparticles are selected as Al2O3 and CuO. Nanofluids modeling, which takes care of base fluid temperature, Brownian motion, diameter and concentration of nano particles, and base fluid physical properties are considered here. Roles of pressure gradient P (at the inlet), temperature of base fluids, heat generation/absorption, the density of the nanoparticle volume fraction on flow and heat transfer characteristics (velocity and temperature distribution, Nusselt number (Nu) distribution, entropy generation and Bejan Number) are investigated here. How the sequence of appearance of curves of flow and heat transfer characteristics (due to variation of aforesaid parameters) are disturbed by the presence of injection/suction, radiation and convective boundary condition is discussed here. A critical analysis is conducted on the individual contribution of irreversibilities due to heat flow, fluid friction and Joule heating to the total entropy generation. At last, we try to find an optimum condition at which local and global entropy generation are minimally generated in the channel.

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来源期刊
Journal of Engineering Thermophysics
Journal of Engineering Thermophysics THERMODYNAMICS-ENGINEERING, MECHANICAL
CiteScore
2.30
自引率
12.50%
发文量
0
审稿时长
3 months
期刊介绍: Journal of Engineering Thermophysics is an international peer reviewed journal that publishes original articles. The journal welcomes original articles on thermophysics from all countries in the English language. The journal focuses on experimental work, theory, analysis, and computational studies for better understanding of engineering and environmental aspects of thermophysics. The editorial board encourages the authors to submit papers with emphasis on new scientific aspects in experimental and visualization techniques, mathematical models of thermophysical process, energy, and environmental applications. Journal of Engineering Thermophysics covers all subject matter related to thermophysics, including heat and mass transfer, multiphase flow, conduction, radiation, combustion, thermo-gas dynamics, rarefied gas flow, environmental protection in power engineering, and many others.
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