Mass Transport in Blood Flow through a Stenosed Tube
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概要
- 論文の詳細を見る
It is pointed out that mass transport in an artery, such as LDL transport, influences the progression of stenosis severely. Mass transport in blood flow through a stenosed tube is analyzed numerically. Flow is assumed to be periodic, incompressible and axisymmetric. Non-Newtonian viscosity of blood and movement of arterial wall are considered. The effect of pulsation, non-Newtonian property of blood and wall movement on mass transport is investigated. Flow pattern, concentration pattern and distribution of concentration gradient on the wall are obtained. It is found that the effect of the vortex on mass transport on the wall changes drastically with Schmidt number. In low Schmidt number flow the strength of vortex and its center position are important. Therefore, time-mean mass transport on the wall has maximum value at certain frequency because of the vortex enhancement. On the other hand, whether the vortex downstream of the stenosis flows away or not becomes important in high Schmidt number flow.
- 一般社団法人日本機械学会の論文
- 1999-09-15
著者
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ISHIKAWA Takuji
Department of Mechanical Engineering, Fukui University
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Yamane Ryuichiro
Department Of Mechanical Engineering Kokushikan University
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Yamane Ryuichiro
Department Of Mechanical Engineering And Science Tokyo Institute Of Technology
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OSHIMA Shuzo
Department of Mechanical Engineering and Science, Tokyo Institute of Technology
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Oshima Shuzo
Department Of Mechanical Engineering And Science Tokyo Institute Of Technology
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Oshima S
Department Of Mechanical Engineering And Science Tokyo Institute Of Technology
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Yamane R
Department Of Mechanical Engineering Kokushikan University
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Ishikawa Takuji
Department Of Mechanical Engineering Fukui University
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ISHIKAWA Takuji
Graduate School of Mechanical Engineering, Tokyo Institute of Technology
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YAMANE Ryurchiro
Tokyo Institute of Technology
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