An experimentally validated numerical modeling technique for perforated plate heat exchangers

Journal of Heat Transfer

Volumn 132, Issue 11, 2010, Pages

  White, M J ^a   Nellis, G F ^b   Klein, S A ^b   Zhu, W ^c   Gianchandani, Y ^c  

^a FERMI NATIONAL ACCELERATOR LABORATORY   (United States)

^b Wisconsin Electric Machines and Power Electronics Consortium   (United States)

^c UNIVERSITY OF MICHIGAN   (United States)

Author keywords

axial conduction; cryogenic; heat exchanger; MEMS; perforated plate

Indexed keywords

AXIAL CONDUCTION; AXIAL LENGTH; COMPACT HEAT EXCHANGER; CRYOSURGICAL PROBES; EXPERIMENTAL TESTING; FLOWING FLUID; FLUID PASSAGE; HEAT LOADS; HIGH CONDUCTIVITY; HIGH RESISTANCE; HIGH-TEMPERATURE SYSTEMS; IN-SITU MEASUREMENT; INTERNAL TEMPERATURE DISTRIBUTION; LOW CONDUCTIVITY; MANUFACTURING METHODS; MASS FLOW RATE; MATERIAL PROPERTY; MICRO ELECTRO MECHANICAL SYSTEM; NUMERICAL MODELING; NUMERICAL MODELS; OPERATING CONDITION; PLATE HEAT EXCHANGERS; PLATINUM RESISTANCE THERMOMETERS; PLATINUM WIRE; TEMPERATURE DIFFERENCES; TEMPERATURE RANGE; WALL MATERIALS; WORKING FLUID;

ABILITY TESTING; COMPOSITE MICROMECHANICS; CRYOGENICS; FLUIDS; HEAT EXCHANGERS; HEAT RESISTANCE; HYDRAULICS; INLET FLOW; MATHEMATICAL MODELS; MEMS; MICROELECTROMECHANICAL DEVICES; NUMERICAL METHODS; PLATINUM; TEMPERATURE DISTRIBUTION; THERMOANALYSIS; THERMOMETERS;

PERFORATED PLATES;

EID: 79952077029     PISSN: 00221481     EISSN: 15288943     Source Type: Journal    
DOI: 10.1115/1.4000673     Document Type: Article

References (21)

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