Computational modelling of 3D turning: Influence of edge micro-geometry on forces, stresses, friction and tool wear in PcBN tooling

Journal of Materials Processing Technology

Volumn 209, Issue 11, 2009, Pages 5167-5177

  Özel, Tugrul ^a  

^a DEPARTMENT OF INDUSTRIAL AND SYSTEMS ENGINEERING   (United States)

Author keywords

Computational machining; Finite element method; Variable edge design tool geometry

Indexed keywords

3D TURNINGS; ALLOY STEELS; CHIP FORMATIONS; CHIP GEOMETRIES; COMPUTATIONAL MACHINING; COMPUTATIONAL MODELLING; CUTTING TOOL INSERTS; HIGH STRENGTHS; MECHANICAL COMPONENTS; MICRO GEOMETRIES; POLY-CRYSTALLINE CUBIC BORON NITRIDES; PROCESS SIMULATIONS; SHEAR FRICTIONS; STRESS DISTRIBUTIONS; TOOL WEARS; VARIABLE EDGE DESIGN TOOL GEOMETRY;

AEROSPACE INDUSTRY; BORON; BORON NITRIDE; CUBIC BORON NITRIDE; CUTTING TOOLS; DESIGN; FINITE ELEMENT METHOD; FRICTION; NITRIDES; STEEL; STRESS CONCENTRATION; THREE DIMENSIONAL; TRIBOLOGY; TURNING; WEAR OF MATERIALS;

COMPUTATIONAL GEOMETRY;

EID: 67349218852     PISSN: 09240136     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jmatprotec.2009.03.002     Document Type: Article

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