Numerical simulation of hemodynamic interactions of red blood cells in micro- capillary flow 被引量：2

Numerical simulation of hemodynamic interactions of red blood cells in micro- capillary flow

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摘要 The hemodynamic interactions of red blood cells （RBCs） in a microcapillary flow are investigated in this paper. This kind of interaction is considered as the non-contact mutual interaction of cells, which is important in the suspension flow of blood, but not sufficiently understood. The distributed Lagrange multiplier/fictitious domain method in the lattice Boltzmann framework is used to solve the suspension of the RBCs. The modification of the flow due to the cells, the dependence of the cell deformation on the flow and the cell-cell interaction via the fluid are discussed. It is revealed that the long-range hydrodynamic interaction with a long interacting distance, more than about 5 times of the RBC equivalent radius, mainly has effect on the rheology properties of the suspension, such as the mean velocity, and the short-range interaction is sensitive to the shape of the cell in the microcapillary flow. The flow velocity around the cell plays a key role in the cell deformation. In the current configuration of the flow and cells, the cells repel each other along the capillary. The hemodynamic interactions of red blood cells （RBCs） in a microcapillary flow are investigated in this paper. This kind of interaction is considered as the non-contact mutual interaction of cells, which is important in the suspension flow of blood, but not sufficiently understood. The distributed Lagrange multiplier/fictitious domain method in the lattice Boltzmann framework is used to solve the suspension of the RBCs. The modification of the flow due to the cells, the dependence of the cell deformation on the flow and the cell-cell interaction via the fluid are discussed. It is revealed that the long-range hydrodynamic interaction with a long interacting distance, more than about 5 times of the RBC equivalent radius, mainly has effect on the rheology properties of the suspension, such as the mean velocity, and the short-range interaction is sensitive to the shape of the cell in the microcapillary flow. The flow velocity around the cell plays a key role in the cell deformation. In the current configuration of the flow and cells, the cells repel each other along the capillary.

作者石兴张帅王双连

机构地区 School of Aeronautics and Aerospace

出处《Journal of Hydrodynamics》 SCIE EI CSCD 2014年第2期178-186,共9页 水动力学研究与进展B辑（英文版）

基金 supported by the National Natural Science Foundation of China(Grant Nos.11372278,10902098) the Fundamental Research Funds of the Central Universities(Grant No.2010QNA40107)

关键词 ERYTHROCYTE hydrodynamic interactions fictitious domain method lattice Boltzmann method （LBM） fluid-structure interactions erythrocyte, hydrodynamic interactions, fictitious domain method, lattice Boltzmann method （LBM）, fluid-structure interactions

分类号 O353.4 [理学—流体力学]

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参考文献22

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Numerical simulation of hemodynamic interactions of red blood cells in micro- capillary flow 被引量：2

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