CFD analysis of electrostatic fluid accelerators for forced convection cooling

IEEE Transactions on Dielectrics and Electrical Insulation

Volumn 15, Issue 6, 2008, Pages 1745-1753

  Jewell Larsen, N E ^a   Hsu, C P ^a   Krichtafovitch, I A ^b   Montgomery, S W ^c   Dibene II, J T ^c   Mamishev, Alexander V ^a  

^a University of Washington   (United States)

^b Kronos Air Technologies   (United States)

^c INTEL CORPORATION   (United States)

Author keywords

Electrohydrodynamics, hydrodynamics, numerical analysis, cooling, Microelectromechanical devices

Indexed keywords

AIR; COOLING; DYNAMICS; ELECTROHYDRODYNAMICS; ELECTROSTATICS; FINITE ELEMENT METHOD; FLUID DYNAMICS; FORCED CONVECTION; HEAT CONVECTION; HEAT TRANSFER; HYDRODYNAMICS; MICROELECTROMECHANICAL DEVICES; MICROELECTRONICS; NANOCANTILEVERS; NUMERICAL ANALYSIS; PUMPS; STRUCTURAL DESIGN; TEMPERATURE CONTROL; THERMAL VARIABLES CONTROL;

ACCURATE MODELING; ACCURATE MODELS; AIR VELOCITIES; AIR VELOCITY PROFILES; BACK PRESSURES; CFD ANALYSES; CHARGE DIFFUSIONS; CHARGE TRANSPORT MODELS; CHARGE TRANSPORTS; CONVECTION COOLING; CONVECTION HEAT TRANSFER COEFFICIENTS; COOLING EFFECTIVENESSES; CRITICAL ELEMENTS; DESIGN AND OPTIMIZATIONS; ELECTROSTATIC FLUID ACCELERATORS; ELECTROSTATIC INTERACTIONS; FINITE ELEMENT MODELS; FLUID DYNAMIC EFFECTS; IONIC WIND PUMPS; MICROFABRICATED CANTILEVERS; MODELING PROBLEMS; NEW APPROACHES; NUMERICAL MODELING; PUMP PERFORMANCES; SPACE CHARGES; THERMAL MANAGEMENTS;

TRANSPORT PROPERTIES;

EID: 58149114577     PISSN: 10709878     EISSN: None     Source Type: Journal    
DOI: 10.1109/TDEI.2008.4712680     Document Type: Article

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