Search Results for cutting speed

Fig. 5 Effect of carbon and pearlite content on cutting speed. Cutting speed for 60-min tool life in steels containing different amounts of carbon and pearlite; 0.65 mm 2 (0.001 in. 2 ) cross-sectional cutting area; carbide tool More

Fig. 1 Effect of cutting oil on the relation of tool life to cutting speed of single-point turning tools. Depth of cut 2.5 mm (0.100 in.); feed, 0.032 mm/rev (0.00125 in./rev); T1 high-speed steel tools ground with 0° back rake angle and 0° side rake angle. Tool life was taken as the time More

Fig. 9 Effect of cutting speed and cutting fluids in drilling solution-treated and aged Ti-6Al-4V having 375 HB hardness. Cutting fluids, wear rates, and tool life: A, chemical emulsion (1:15), 0.15 mm (0.006 in.) wear at 13 m/min (43 sfm), 250 holes; B, heavy-duty soluble oil (1:15), 0.15 mm More

Fig. 11 Effect of cutting speed and cutting fluid in tapping solution-treated and aged Ti-6Al-4V with 375 HB hardness. Cutting fluid; A, phosphated (nonchlorinated) oil, 150 holes, and B, chlorinated oil, 9.1 m/min (30 sfm). Tap was a chromium-plated, spiral-point, three-flute 8 mm ( 5 16 More

Fig. 15 Oxygen-assisted laser cutting showing the influence of cutting speed on cut quality. Courtesy of Air Liquide-CTAS Cutting and Welding R&D Laboratory More

Fig. 1 Idealized cutting speed versus cutting temperature plot as devised by Salomon. Source: Ref 4 More

Fig. 4 Effect of cutting speed on chip formation of AISI 4340 steel. (a) Cutting speed of 120 m/min (400 sfm). (b) Cutting speed of 975 m/min (3200 sfm). Source: Ref 1 More

Fig. 9 Effect of cutting speed and cutting fluid on tool life when turning ferritic malleable iron. Feed, 0.25 mm/rev (0.01 in./rev). Depth of cut, 1.57 mm (0.062 in.). The tool life end point was chosen to be 0.04 mm (0.015 in.) of uniform wear or 0.75 mm (0.03 in.) of localized wear. More

Fig. 34 Cutting force as a function of cutting speed More

Fig. 1 Effect of cutting speed on cutting force for different aluminum alloys More

Fig. 7 Effect of hardness on cutting speed for 30 min tool life, using high-speed steel (HSS) and carbide tools More

Fig. 18 Effect of phosphorus on cutting speed (tool life) for a 0.19S-18Cr-8Ni austenitic stainless steel compared to a similar steel containing only sulfur or selenium. Source: Ref 23 More

Fig. 1 Effect of cutting speed and feed on tool life in turning annealed Ti-5Al-5Sn alloy with 321 HB hardness. Feed rates: A, 0.38 mm/rev (0.015 in./rev); B, 0.25 mm/rev (0.010 in./rev); and C, 0.18 mm/rev (0.007 in./rev). Tool material was C-2 (883) carbide throwaway inserts. The depth More

Fig. 2 Effect of cutting speed and depth of cut on tool life in turning annealed Ti-5Al-2Sn having 321 HB hardness. Depths of cut: A, 3.18 mm (0.125 in.), B, 1.6 mm (0.062 in.); and C, 0.75 mm (0.030 in.). Tool material was C-2 (883) carbide throwaway inserts. Feed rate was 0.25 mm/rev (0.010 More

Fig. 3 Effect of cutting speed and setup on tool life in face milling solution-treated and aged Ti-6Al-4V with 363 HB hardness. Type of setup: A, conventional milling; B, work on center; and C, climb milling. Cutter was a 100 mm (4 in.) diam single-tooth face mill with C-2 (883) carbide More

Fig. 4 Effect of cutting speed and tool material in turning β-forged Ti-6Al-4V having 331 HB hardness. High-speed tool steel materials: A, M2; B, T15; and C, M42. Feed rate was 0.25 mm (0.010 in.). Depth of cut was 0.25 mm/rev (0.010 in./rev). Cutting fluid was phosphated oil. Tool life end More

Fig. 5 Effect of cutting speed and feed in the peripheral end milling of solution-treated and aged Ti-6Al-6Sn-4Zr-2Mo having 321 HB hardness. Feed rate: A, 0.08 mm/tooth (0.003 in./tooth); B, 0.05 mm/tooth (0.002 in./tooth); and C, 0.025 mm/tooth (0.001 in./tooth). Cutter was a four-flute, 25 More

Fig. 6 Effect of cutting speed and depth of cut in the peripheral end milling of solution-treated and aged Ti-6Al-4V having 363 HB hardness. Depth of cut: A, 1.6 mm (0.062 in.) and B, 0.8 mm (0.03 in.). Cutter was a four-flute 19 mm ( 3 4 in.) diam tool made of M42 high-speed tool More

Fig. 7 Effect of cutting speed and feed in the face milling of solution-treated and aged Ti-6Al-2Sn-4Zr-2Mo having 321 HB hardness. Feed rate: A, 0.25 mm/tooth (0.010 in./tooth) and B, 0.13 mm/tooth (0.005 in./tooth). The cutter was a 100 mm (4 in.) diam single-tooth face mill with a C-2 (883 More

Fig. 2 Cutting speed ranges in machining of various material. Source: Ref 3 More