2020
DOI: 10.1177/0954405420971070
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Effects of cutter path orientations on milling force, temperature, and surface integrity when ball end milling of TC17 alloy

Abstract: To explore the effects of cutter path orientations on milling force, temperature, and surface integrity, end ball milling experiments of TC17 titanium alloy were accomplished derived from different cutter path orientations. The experiment results of milling force and temperature were obtained. Combining with the thermo-mechanical coupling, this paper analyzes the impact of the cutter path orientations on the surface roughness, surface topography, in-depth residual stress, microhardness distributions, and micro… Show more

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Cited by 13 publications
(8 citation statements)
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“…e experimental material is titanium alloy TC17, which is an α + β dual-phase alloy rich in α phase. Its chemical composition is depicted in Table 1, and its fundamental material properties are presented in Table 2 [17,18]. e experimental piece is Φ60 mm × 280 mm bar material.…”
Section: Experimental Conditions and Methodsmentioning
confidence: 99%
“…e experimental material is titanium alloy TC17, which is an α + β dual-phase alloy rich in α phase. Its chemical composition is depicted in Table 1, and its fundamental material properties are presented in Table 2 [17,18]. e experimental piece is Φ60 mm × 280 mm bar material.…”
Section: Experimental Conditions and Methodsmentioning
confidence: 99%
“…Under the conditions of high temperature and high pressure, the tool is prone to wear. 14,15 Tool wear is usually the result of the interaction and mutual influence of different wear mechanisms. The main mechanisms include abrasive wear, adhesive wear, diffusion wear, oxidation wear, and plastic deformation.…”
Section: Incremental Model Of Abrasive Wear Ratementioning
confidence: 99%
“…4,5 The cutting forces acting on the tool increase the wear, causing surface roughness and form defect, with this, it causes dimensional errors by changing the position of the cutting edge. 6 The resulting tool deflection deviates from the contact points of the tool, causing excessive force concentration in some areas of the cutting edge and wear faster than the normal course of the tool. 7 These reasons revealed the necessity to control the tool deflection according to the machining parameters and surface forms.…”
Section: Introductionmentioning
confidence: 99%