High Productivity Machining: Proceedings of the International Conference on High Productivity Machining, Materials and Processing, New Orleans, Louisiana, 7-9 May 1985V. K. Sarin |
Contents
HIGH PRODUCTIVITY MACHINING IN THE FUTURE | 3 |
RESEARCH FOR HIGH PRODUCTIVITY MACHINING IN JAPAN | 15 |
SURFACE INTERFACE IN CUTTING PROCESS | 29 |
Copyright | |
21 other sections not shown
Common terms and phrases
abrasive alloys alumina angle application CALCIUM TREATED carbide tools cast iron cemented carbide ceramic coated tools cobalt-enriched composition continuous cast steel CONTINUOUSLY CAST cost crater cutter cutting conditions cutting edge cutting fluid cutting forces cutting process cutting speed cutting tool cutting tool materials deformation depth of cut developed diameter drill energy engineering feed rate flank wear FP Aluminum fracture fracture toughness ft/min grade grinding hardness heat high speed high speed steel higher inclusions increase ingot ingot-cast insert m/min machine test manganese manganese sulfide martensite material removal rate measured mechanical metal metalcutting METASAFE microstructure milling mm/rev oxide parameters pearlite performance production properties pulse rake face ratio reduced resulfurized resulphurised SFPM shear shown in Figure shows silicon spindle strand-cast substrate sulfide sulfur sulfur content superhard materials surface integrity surface roughness Table tellurium temperature titanium tool wear turning values wheel width