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Face milling sections of W2 tool steel using a magnetic chuck and backup bl...
Available to PurchasePublished: 01 January 1989
Fig. 3 Face milling sections of W2 tool steel using a magnetic chuck and backup blocks. Dimensions in figure given in inches Speed, m/min (sfm) 106 (350) Feed at 330–685 mm/min (13–27 in./min), mm/tooth (in./tooth) 0.15–0.33 (0.006–0.013) Depth of cut, mm (in.) 0.76–4.6 (0.030
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Published: 01 January 1989
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Details of face milling cutter used to climb cut age-hardened Inconel X-750...
Available to PurchasePublished: 01 January 1989
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Simultaneous face milling of parallel surfaces on opposite sides of a casti...
Available to PurchasePublished: 01 January 1989
Fig. 26 Simultaneous face milling of parallel surfaces on opposite sides of a casting. Dimensions in figure given in inches Cutter details Type Face mill, inserted blade Size, mm (in.) 152 (6) diameter Number of teeth 12 Material Carbide-tip blades Operating
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Published: 01 January 1989
Fig. 21 Recommended angles for face milling cutters; all angles are positive. Angle High-speed steel, degrees Disposable carbide, degrees Brazed carbide, degrees Axial rake 12–25 5–7 3–10 Radial rake 10–12 0–5 3–10
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Inserted-blade cutter for the face milling of magnesium at high peripheral ...
Available to PurchasePublished: 01 January 1989
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Effect of cutting speed and setup on tool life in face milling solution-tre...
Available to PurchasePublished: 01 January 1989
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
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Effect of cutting speed and feed in the face milling of solution-treated an...
Available to PurchasePublished: 01 January 1989
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
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Theoretical surfaces produced in models of face milling with a sharp-nose m...
Available to PurchasePublished: 01 January 1989
Fig. 6(a) Theoretical surfaces produced in models of face milling with a sharp-nose milling tool (Type A), a round tool (Type B), and a round-nose tool (Type C). Source: Ref 5
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Theoretical surface roughness for a face milling cutter containing teeth wi...
Available to PurchasePublished: 01 January 1989
Fig. 7 Theoretical surface roughness for a face milling cutter containing teeth with a zero nose radius. Source: Ref 5
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Theoretical surface roughness for turning or face milling tools with round ...
Available to PurchasePublished: 01 January 1989
Fig. 8 Theoretical surface roughness for turning or face milling tools with round cutting edges. Source: Ref 5
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Theoretical surface roughness for turning or face milling tools with a radi...
Available to PurchasePublished: 01 January 1989
Fig. 9 Theoretical surface roughness for turning or face milling tools with a radius of 0.39 mm (0.0156 in.) and various ECEAs. Source: Ref 5
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Surfaces produced by the face milling of Ti-6Al-4V (aged, 35 HRC). (a) With...
Available to PurchasePublished: 01 January 1989
Fig. 11 Surfaces produced by the face milling of Ti-6Al-4V (aged, 35 HRC). (a) With gentle machining conditions, a slight white layer is visible, but changes in microhardness are undetected. 1000×. (b) With abusive conditions, an overheated white layer about 0.01 mm (0.0004 in.) deep
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Change in deflection versus tool wearland for the face milling of 4340 stee...
Available to PurchasePublished: 01 January 1989
Fig. 22 Change in deflection versus tool wearland for the face milling of 4340 steel (quenched and tempered to 52 HRC) Tool 100 mm (4 in.) diam single-tooth face mill with Carboloy 370 (C-6) carbide End cutting edge angle 5° Peripheral clearance 8° Cutting speed, m/min (ft
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Face milling of a steel plate in one pass per side. Dimensions in figure gi...
Available to PurchasePublished: 01 January 1989
Fig. 32 Face milling of a steel plate in one pass per side. Dimensions in figure given in inches Cutter details Type Face mill, inserted blade Size 406 mm (16 in.) in diameter, 95 mm (3 3 4 in.) thick Number of teeth 32 Material Carbide-tipped blades
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Workpiece after face milling. Burr formation was observed at the cutting ed...
Available to PurchasePublished: 01 November 2010
Fig. 10 Workpiece after face milling. Burr formation was observed at the cutting edge and the side and face of the exit. Source: Ref 34
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Published: 01 January 1989
Fig. 6 Tool geometry for face mill Material Hardness, HB High-speed steel Indexable carbide Brazed carbide Corner angle, degrees End cutting edge angle, degrees Axial relief angle, degrees Radial relief angle, degrees Axial rake angle, degrees Radial rake angle
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Face mill cutter shown in position to generate a pinion by the fixed-settin...
Available to PurchasePublished: 01 January 1989
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Published: 01 December 1998
Book Chapter
Milling
Available to PurchaseBook: Machining
Series: ASM Handbook
Volume: 16
Publisher: ASM International
Published: 01 January 1989
DOI: 10.31399/asm.hb.v16.a0002144
EISBN: 978-1-62708-188-7
..., and special type. The article discusses mechanical-electric, mechanical-hydraulic, mechanical-electric-hydraulic, and numerical control of milling machines. It describes various types of milling cutters, such as peripheral mills, face mills, end mills, and special mills. Milling cutters, such as solid milling...
Abstract
This article commences with a schematic illustration of a wide range of cutter configurations available for use in milling operations. It describes the various types of milling machines classified based on the type of construction, such as knee-and-column type, bed-type, planer-type, and special type. The article discusses mechanical-electric, mechanical-hydraulic, mechanical-electric-hydraulic, and numerical control of milling machines. It describes various types of milling cutters, such as peripheral mills, face mills, end mills, and special mills. Milling cutters, such as solid milling cutters, inserted-blade cutters, and indexable-insert cutters, are also discussed. The article explains the capabilities and limitations of peripheral milling, face milling, and end milling methods. It concludes with a comparison of milling with broaching, planing or shaping, and grinding.
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