通过响应面方法优化纳米流体 MHD 蠕动血流的压力梯度

Saima Muhammad, Dilawar Hussain, Munawwar Ali Abbas
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引用次数: 0

摘要

本研究的重点是利用响应面方法(RSM)优化 MHD 蠕动纳米流体流的压力梯度。通过忽略惯性力并采用长波长近似,求解了包括连续性、运动、纳米粒子和浓度力在内的控制方程。采用扰动法对由此产生的非线性耦合偏微分方程进行分析求解。在考虑所有物理参数的情况下,给出了浓度、温度和压力上升的数学和图形输出结果。数值计算用于评估摩擦力和压力上升的表达式。磁流体力学在各种微通道设计中都有不同的应用,可对脉动和非脉动连续流的泵送流体进行有效的流量控制。最后,采用响应面方法 (RSM) 进行敏感性分析和优化。方差分析表是在 MINITAB-19 统计软件的帮助下生成的。灵敏度结果以表格和图形的形式显示,得出的结论是,在低水平时,M 比其他输入参数对 ΔPat 更敏感,而在中高水平时,输入参数 Nt 在其他参数中最为敏感。此外,流动的温度和压力对不同的磁性、热泳和布朗运动参数值具有不同的响应。
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Optimizing pressure gradient on the MHD peristaltic blood flow of nanofluids by - response surface methodology

This study focuses on optimization of pressure gradient on MHD peristaltic nanofluid flow by response surface methodology (RSM). The governing equations, including continuity, motion, nanoparticle, and concentration force are solved by disregarding inertial forces and employing the approximation of long-wavelength. The perturbation method is used to solve the resultant nonlinear coupled partial differential equation analytically. Mathematical and graphical outputs for concentration, temperature, and pressure rise, considering all physical parameters, are presented. Numerical computation is applied to assess expressions for friction forces and pressure rise. Magnetohydrodynamics has various applications in various microchannel designs for efficacious flow control in pumping fluids for both pulsating and non-pulsating continuous flow. Finally, Response Surface Methodology (RSM) is used for performing sensitivity analysis and its optimization. ANOVA tables are generated with the help of MINITAB-19 which is a statistical software. The sensitivity results are displayed in tabular and graphical form and concluded that M is more sensitive than other input parameters for ΔPat the low level and the input parameter Nt is most sensitive among others at middle and high levels. Further, Temperature and pressure of the flow has different responses for various values of magnetic, thermophoresis and Brownian motion parameter.

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来源期刊
Results in Control and Optimization
Results in Control and Optimization Mathematics-Control and Optimization
CiteScore
3.00
自引率
0.00%
发文量
51
审稿时长
91 days
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