Analysis of Shear-rate Dependent Blood-Flow Models Through Idealized Bifurcating Geometries with Traction-Free and Resistance Outlet Boundary Conditions

Gonzalez, Francisco

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https://hdl.handle.net/2142/95792 Copy

Description

Title

Analysis of Shear-rate Dependent Blood-Flow Models Through Idealized Bifurcating Geometries with Traction-Free and Resistance Outlet Boundary Conditions

Author(s)

Gonzalez, Francisco

Contributor(s)

Bodony, Daniel

Issue Date

2016

Keyword(s)

Aerospace Engineering

Abstract

Arterial blood-flow is simulated using the shear-rate dependent Carreau-Yasuda fluid model through idealized bifurcating arterial geometries. Given that the whole cardiovascular system would be too large and complex to model, a resistance boundary condition is used to incorporate the downstream domains in a truncated geometry. The pressure and flow-rate of a truncated geometry with resistance outlet boundary conditions are compared to the pressure and flow-rate at the same region of a non-truncated geometry with traction-free outlet boundary conditions.

Publisher

Office of Minority Student Affairs

Type of Resource

other

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http://hdl.handle.net/2142/95792

Copyright and License Information

Copyright 2016 Francisco Gonzalez

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