Supersonic nozzle flow simulations for particle coating applications: Effects of shockwaves, nozzle geometry, ambient pressure, and substrate location upon flow characteristics

Journal of Thermal Spray Technology

Volumn 20, Issue 3, 2011, Pages 514-522

  Park, Jung Jae ^a   Lee, Min Wook ^a   Yoon, Sam S ^a   Kim, Ho Young ^a   James, Scott C ^b   Heister, Stephen D ^c   Chandra, Sanjeev ^d   Yoon, Woon Ha ^e   Park, Dong Soo ^e   Ryu, Jungho ^e  

^a Korea University   (South Korea)

^b SANDIA NATIONAL LABORATORIES   (United States)

^c Purdue University   (United States)

^d UNIVERSITY OF TORONTO   (Canada)

^e Korea Institute of Material Science   (South Korea)

Author keywords

nano particle coating; nozzle optimization; shockwave; supersonic flow; thin film deposition

Indexed keywords

AMBIENT PRESSURES; CHAMBER PRESSURE; CLOSE PROXIMITY; CRITICAL DISTANCE; FLOW CHARACTERISTIC; FLOW DISTURBANCES; FLOW PROPERTIES; GAS FLOWS; NOZZLE EXITS; NOZZLE GEOMETRIES; ON FLOW; OPTIMUM CONDITIONS; PARTICLE COATINGS; SENSITIVE PARAMETER; SHOCK FORMATION; SHOCK STRUCTURE; SUPERSONIC NOZZLES; THIN-FILM COATINGS; THIN-FILM DEPOSITION;

COATINGS; GEOMETRY; NANOPARTICLES; OPTIMIZATION; SUPERSONIC AERODYNAMICS; SUPERSONIC FLOW;

NOZZLES;

EID: 79952003332     PISSN: 10599630     EISSN: None     Source Type: Journal    
DOI: 10.1007/s11666-010-9542-8     Document Type: Review

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