Effect of microstructure on abrasive wear behavior of thermally sprayed WC-10Co-4Cr coatings

Wear

Volumn 268, Issue 11-12, 2010, Pages 1309-1319

  Kumari, Kanchan ^a   Anand, K ^a   Bellacci, Michelangelo ^b   Giannozzi, Massimo ^b  

^a GENERAL ELECTRIC COMPANY   (United States)

^b GE OIL AND GAS   (Italy)

Author keywords

Abrasion; Microstructure; Thermal spraying; WC 10Co 4Cr; Wear mechanism

Indexed keywords

ABRASION RESISTANCE; ABRASION TESTS; ABRASIVE MATERIALS; ABRASIVE WEAR BEHAVIOR; ABRASIVE WEAR RESISTANCE; ABRASIVE WEARS; BINDER PHASE; COATING COMPOSITIONS; COATING HARDNESS; COATING MICROSTRUCTURES; COATINGS INDUSTRY; DRY SAND; EROSIVE WEAR; GRAIN SIZE; HIGH VELOCITY OXY-FUEL; LOW POROSITY; MEAN FREE PATH; MICROSTRUCTURAL FEATURES; MICROSTRUCTURAL PARAMETERS; PULSED COMBUSTION; QUALITY COATINGS; RUBBER WHEELS; SPRAYING PROCESS; THERMAL SPRAY PROCESS; WC GRAIN SIZE; WC-10CO-4CR; WC-CO COATING; WEAR MECHANISMS;

ABRASION; ABRASIVES; BINDERS; CHEMICAL INDUSTRY; CHROMATE COATINGS; CHROMIUM; CORROSION RESISTANCE; GRAIN SIZE AND SHAPE; MICROSTRUCTURAL EVOLUTION; PROTECTIVE COATINGS; RUBBER COATINGS; SPRAYED COATINGS; STRIPPING (REMOVAL); THERMAL SPRAYING; TITRATION; TRIBOLOGY; TUNGSTEN CARBIDE; WEAR RESISTANCE;

ABRASIVE COATINGS;

EID: 77951129729     PISSN: 00431648     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.wear.2010.02.001     Document Type: Article

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