Title :
Numerical simulation for blood flow in Internal Carotid Artery for integration with photoelastic stress analysis
Author :
Kojima, Masahiro ; Tercero, Carlos ; Ikeda, Seiichi ; Sakai, Yasuhiko ; Fukuda, Tohio ; Arai, Fumihito ; Negoro, Makoto
Author_Institution :
Dept. of Micro-Nano Syst. Eng., Nagoya Univ., Nagoya, Japan
Abstract :
Fluid-structure interaction analysis in Internal Carotid Artery(ICA) are carried out as preparation for validation between the result of numerical simulation and photoelastic stress analysis. In this work, we assume blood vessel as an isotropic elastic medium and the wall´s Poisson ratio is 0.45 and Young´s modulus is 3.0Mpa. Our study shows various parameter on fluid dynamics of blood flow, such as the velocity profile, wall shear stress distribution, displacement of vessel wall and Mises stress. Blood flow after bifurcation generate vortex flow and decreases flow speed and wall shear stress nearly to 0Pa. This low wall shear stress can accelerate the accumulation of plaque and eventually causes vessel narrowing. Moreover, the maximum wall shear stress and Mises stress is focused on the bifurcation of ICA. These high stress may lead to aneurysm initiation.
Keywords :
Poisson ratio; Young´s modulus; bifurcation; blood vessels; fluid dynamics; haemodynamics; numerical analysis; photoelasticity; stress analysis; vortices; Mises stress; Poisson ratio; Young´s modulus; aneurysm initiation; bifurcation; blood flow; blood vessel; fluid dynamics; fluid-structure interaction analysis; internal carotid artery; isotropic elastic medium; numerical simulation; photoelastic stress analysis; plaque accumulation; velocity profile; vessel wall; vortex flow; wall shear stress distribution; Aneurysm; Stress;
Conference_Titel :
Micro-NanoMechatronics and Human Science (MHS), 2010 International Symposium on
Conference_Location :
Nagoya
Print_ISBN :
978-1-4244-7995-5
DOI :
10.1109/MHS.2010.5669515
