普朗特流体蠕动流经椭圆管道时的流变学效应:综合分析

Muhammad Hasnain Shahzad, Aziz Ullah Awan, Sohail Nadeem, N. Ameer Ahammad, Haneen Hamam, Ahmed Alamer, Sidra Shafique
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引用次数: 0

摘要

这项研究对通过椭圆形通道蠕动流动的非牛顿流体进行了理论研究。此外,还全面考虑了针对该椭圆形管道问题的普朗特流体方法。该数学研究采用了非牛顿普朗特流体模型。多项式方法用于分析以非线性形式出现的偏微分方程,并为温度和速度曲线提供精确的解析解。这项研究首次利用具有十一个常数的八度新阶多项式,通过椭圆域精确求解普朗特流体流动的温度方程。为了充分理解数学结论,研究还提供了全面的图形分析。速度剖面图清楚地表明,沿着椭圆形管道的次轴,非牛顿效应更为强烈。突出截留现象的流线型图形显示了靠近蠕动管道边界壁的特定封闭轮廓。
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Rheological effects in peristaltic flow of Prandtl fluid through elliptical duct: A comprehensive analysis
This research venture comprehends a theoretical examination of non‐Newtonian fluid flowing peristaltic via an elliptical channel. Furthermore, the Prandtl fluid method for this elliptic duct problem is thoroughly considered. This mathematical inquiry adopts a non‐Newtonian Prandtl fluid model. A polynomial methodology is used to analyze partial differential equations that appear in nondimensional form and deliver an exact analytical solution for the temperature and velocity profile. This study is the first to utilize a novel order polynomial of degree eight having eleven constants to precisely solve the temperature equation for Prandtl fluid flow via an elliptic domain. A comprehensive graphical analysis is also provided to understand the mathematical conclusions fully. The graphs of the velocity profiles clearly show that the non‐Newtonian effects are more potent along the minor axis of the elliptical duct. The streamlined graphs accentuating the trapping phenomenon show specific closed contours close to the boundary wall of the peristaltic duct.
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