Two-dimensional FSI simulation of closing dynamics of a tilting disk mechanical heart valve

Journal of Medical Devices, Transactions of the ASME

Volumn 4, Issue 1, 2010, Pages

  Govindarajan, V ^a   Udaykumar, H S ^a,b   Herbertson, L H ^c   Deutsch, S ^c   Manning, K B ^c   Chandran, K B ^a,b  

^a University of Iowa   (United States)

^b UNIVERSITY OF IOWA   (United States)

^c PENNSYLVANIA STATE UNIVERSITY   (United States)

Author keywords

Computer simulation; Fluid dynamics; FSI; Major orifice region; Minor orifice region; Platelet activation; Tilting disk valve

Indexed keywords

ACTIVATION PARAMETER; BILEAFLET; CARTESIAN MESH; CLOSING DYNAMICS; CLOSING PHASE; FIXED GRIDS; FLOW SOLVER; FLOWTHROUGH; FLUID MOTIONS; GAP WIDTHS; HIGH SHEAR; JET FLOW; LAGRANGIAN PARTICLE DYNAMICS; LAMINAR REGIME; LARGE SHEAR; LOCAL MESH REFINEMENT; MECHANICAL HEART VALVES; MECHANICAL VALVES; MINOR ORIFICE REGION; PIV MEASUREMENTS; PLATELET ACTIVATION; RECIRCULATIONS; RESIDENCE TIME; SHEAR LAYER; THROMBUS FORMATION; TILTING DISK; VALVE CLOSURE; VORTICAL STRUCTURES;

ACTIVATION ANALYSIS; BLOOD SUBSTITUTES; COMPUTATIONAL METHODS; DISKS (STRUCTURAL COMPONENTS); DYNAMIC ANALYSIS; FLUID DYNAMICS; FLUID STRUCTURE INTERACTION; FLUIDS; HEART VALVE PROSTHESES; HOUSING; ORIFICES; PLATELETS; TWO DIMENSIONAL; VORTEX FLOW;

VALVES (MECHANICAL);

ARTICLE; COMPUTER SIMULATION; FLUID FLOW; HEART VALVE PROSTHESIS; HUMAN; MATHEMATICAL ANALYSIS; MECHANICS; PROSTHETIC VALVE THROMBOSIS; SHEAR STRESS; THROMBOCYTE ACTIVATION;

EID: 77955123985     PISSN: 19326181     EISSN: 1932619X     Source Type: Journal    
DOI: 10.1115/1.4000876     Document Type: Article

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