Pulsatile Blood Flow in a Channel of Small Exponential Divergence—I. The Linear Approximation for Low Mean Reynolds Number

D. J. Schneck; Simon Ostrach

Source: Journal of Fluids Engineering:;1975:;volume( 097 ):;issue: 003::page 353

Author:

D. J. Schneck

Simon Ostrach

DOI: 10.1115/1.3447314

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: The pulsating flow of a viscous, incompressible fluid through rigid circular channels having walls which diverge at a slow exponential rate is examined analytically. Linearized solutions for low mean Reynolds numbers reveal that viscous effects lead to radially dependent phase shifts between different layers of fluid oscillating in the axial direction, and characteristic phase lags between flow and pressure curves. When the Reynolds number and channel divergence are each small, the flow does not separate, but there is a downstream attenuation of both flow and pressure, together with the appearance of a finite radial velocity component. Utilizing data relevant to basal conditions existing in the major blood vessels of the human coronary circulation, it is found (in the absence of any persistent flow anomalies) that the shear stress at the wall is at least one to two orders of magnitude lower than values reported to be damaging to vascular endothelium.

keyword(s): Channels (Hydraulic engineering) , Reynolds number , Approximation , Blood flow , Flow (Dynamics) , Pressure , Fluids , Incompressible fluids , Pulsatile flow , Stress , Phase shift , Shear (Mechanics) AND Blood vessels ,

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Pulsatile Blood Flow in a Channel of Small Exponential Divergence—I. The Linear Approximation for Low Mean Reynolds Number

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contributor author	D. J. Schneck
contributor author	Simon Ostrach
date accessioned	2017-05-08T22:58:53Z
date available	2017-05-08T22:58:53Z
date copyright	September, 1975
date issued	1975
identifier issn	0098-2202
identifier other	JFEGA4-26873#353_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/87631
description abstract	The pulsating flow of a viscous, incompressible fluid through rigid circular channels having walls which diverge at a slow exponential rate is examined analytically. Linearized solutions for low mean Reynolds numbers reveal that viscous effects lead to radially dependent phase shifts between different layers of fluid oscillating in the axial direction, and characteristic phase lags between flow and pressure curves. When the Reynolds number and channel divergence are each small, the flow does not separate, but there is a downstream attenuation of both flow and pressure, together with the appearance of a finite radial velocity component. Utilizing data relevant to basal conditions existing in the major blood vessels of the human coronary circulation, it is found (in the absence of any persistent flow anomalies) that the shear stress at the wall is at least one to two orders of magnitude lower than values reported to be damaging to vascular endothelium.
publisher	The American Society of Mechanical Engineers (ASME)
title	Pulsatile Blood Flow in a Channel of Small Exponential Divergence—I. The Linear Approximation for Low Mean Reynolds Number
type	Journal Paper
journal volume	97
journal issue	3
journal title	Journal of Fluids Engineering
identifier doi	10.1115/1.3447314
journal fristpage	353
journal lastpage	360
identifier eissn	1528-901X
keywords	Channels (Hydraulic engineering)
keywords	Reynolds number
keywords	Approximation
keywords	Blood flow
keywords	Flow (Dynamics)
keywords	Pressure
keywords	Fluids
keywords	Incompressible fluids
keywords	Pulsatile flow
keywords	Stress
keywords	Phase shift
keywords	Shear (Mechanics) AND Blood vessels
tree	Journal of Fluids Engineering:;1975:;volume( 097 ):;issue: 003
contenttype	Fulltext

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