Physiological non-Newtonian blood flow through single stenosed artery

IF 0.7 Q4 MECHANICS

Theoretical and Applied Mechanics Pub Date : 2016-07-12 DOI:10.1063/1.4958361

Khairuzzaman Mamun, M. M. Rahman, M. Akhter, M. Ali

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引用次数: 14

Abstract

A numerical simulation to investigate the Non-Newtonian modeling effects on physiological flows in a three dimensional idealized artery with a single stenosis of 85% severity is given. The wall vessel is considered to be rigid. Oscillatory physiological and parabolic velocity profile has been imposed for inlet boundary condition. Determination of the physiological waveform is performed using a Fourier series with sixteen harmonics. The investigation has a Reynolds number range of 96 to 800. Low Reynolds number k ? w model is used as governing equation. The investigation has been carried out to characterize two Non-Newtonian constitutive equations of blood, namely, (i) Carreau and (ii) Cross models. The Newtonian model has also been investigated to study the physics of fluid. The results of Newtonian model are compared with the Non-Newtonian models. The numerical results are presented in terms of velocity, pressure, wall shear stress distributions and cross sectional velocities as well as the streamlines contour. At early systole pressure differences between Newtonian and Non-Newtonian models are observed at pre-stenotic, throat and immediately after throat regions. In the case of wall shear stress, some differences between Newtonian and Non-Newtonian models are observed when the flows are minimum such as at early systole or diastole. In general, the velocities at throat regions are highest at all-time phase. However, at pick systole higher velocities are observed at post-stenotic region. Downstream flow of all models creates some recirculation regions at diastole.

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通过单个狭窄动脉的生理非牛顿血流

本文通过数值模拟研究了非牛顿模型对单个狭窄程度为85%的三维理想动脉生理血流的影响。壁管被认为是刚性的。在进口边界条件下，施加了振荡的生理和抛物速度剖面。生理波形的测定是使用具有16次谐波的傅立叶级数进行的。调查的雷诺数范围为96到800。低雷诺数k ?采用W模型作为控制方程。对血液的两个非牛顿本构方程进行了研究，即(i) careau模型和(ii) Cross模型。牛顿模型也被用来研究流体的物理特性。将牛顿模型的计算结果与非牛顿模型进行了比较。给出了速度、压力、壁面剪应力分布、横截面速度以及流线轮廓的数值计算结果。在早期收缩期，牛顿模型和非牛顿模型在狭窄前、喉咙和喉咙后立即观察到压力差异。在壁面剪切应力的情况下，当流量最小时，例如在收缩或舒张早期，牛顿模型和非牛顿模型之间存在一些差异。一般来说，喉部的速度在所有阶段都是最高的。然而，在收缩时，在狭窄后区域观察到较高的速度。所有模型的下游流动在舒张时产生一些再循环区域。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Theoretical and Applied Mechanics MECHANICS-

CiteScore

0.90

自引率

0.00%

发文量

审稿时长

32 weeks

期刊介绍： Theoretical and Applied Mechanics (TAM) invites submission of original scholarly work in all fields of theoretical and applied mechanics. TAM features selected high quality research articles that represent the broad spectrum of interest in mechanics.