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Abstract

Shear angle is classically considered constant. In the study, a series of straight orthogonal cutting tests of ultra-precision machining revealed that shear angle cyclically evolved with each lamellar chip formation, i.e. cyclic shear angle. It grew up from an initial shear angle of 0° to a final shear angle 90°-α (α: tool rake angle) and underwent a series of transient shear angles like classical shear angles and a critical shear angle. The critical shear angle is the sum of the half of the tool rake angle and the characteristic shear angle determined by material anisotropy without the friction effect. Moreover, a new model was developed. Further, a series of face turning tests of ultra-precision machining verified that the cyclic shear angle was the intrinsic mechanism of cyclic cutting forces and lamellar chip formation to induce twin-peak high-frequency multimode diamond-tool-tip vibration. Significantly, the study draws up an understanding of shear angle for the discrepancy among the classical models.

Keywords

Chip formation shear angle tool vibration ultra-precision machining

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References

Turkes

Orak

Neşeli

, et al. Modelling of dynamic cutting force coefficients and chatter stability dependent on shear angle oscillation. Int J Adv Manuf Technol 2017; 91: 679–686.

Mir

Luo

Cheng

, et al. Investigation of influence of tool rake angle in single point diamond turning of silicon. Int J Adv Manuf Technol 2018; 94: 2343–2355.

Lee

Sze

, et al. Effect of material anisotropy on shear angle prediction in metal cutting – a mesoplasticity approach. Int J Mech Sci 2003; 45: 1739–1749.

Merchant

. Mechanics of the metal cutting process, I. Orthogonal cutting and a type 2 chip. J Appl Phys 1945; 16: 267–275.

Merchant

. Mechanics of the metal cutting process, II. Plasticity conditions in orthogonal cutting. J Appl Phys 1945; 16: 318–324.

Lee EH and Shaffer BW. The theory of plasticity applied to a problem of machining. Providence, RI: Division of Applied Mathematics, 1949.

Stabler

. The fundamental geometry of cutting tools. Proc Instn Mech Engrs 1951; 165: 14–26.

Wright

. Predicting the shear plane angle in machining from work material strain-hardening characteristics. J Manuf Sci Eng 1982; 104: 285–292.

Zhang

Xiong

, et al. Microwave formation mechanisms in surface generation of ultra-precision machining. Int J Adv Manuf Technol 2019; 104: 1239–1244.

10.

Abdulkadir

Abou-El-Hossein

Jumare

, et al. Ultra-precision diamond turning of optical silicon—a review. Int J Adv Manuf Technol 2018; 96: 173–208.

11.

Lou

. Improving machinability of titanium alloy by electro-pulsing treatment in ultra-precision machining. Int J Adv Manuf Technol 2017; 93: 2299–2304.

12.

Rahman

Kumar

. Influence of relative tool sharpness (RTS) on different ultra-precision machining regimes of Mg alloy. Int J Adv Manuf Technol 2018; 96: 3545–3563.

13.

Gao

Chen

, et al. Influence of air-induced vibration of aerostatic bearing on the machined surface quality in ultra-precision flycutting. Proc IMechE, Part C: J Mechanical Engineering Science 2018; 232: 117–125.

14.

Dong

Zhang

Xiong

. Surface integrity under diamond tool wear effects in ultra-precision raster milling of a Zn–Al–Cu alloy. Proc IMechE, Part C: J Mechanical Engineering Science 2019; 233: 1111–1118.

15.

Zhang

Dong

. Effect of particle size on the ultraprecision polishing process of titanium alloy Ti6Al4V. Proc IMechE, Part C: J Mechanical Engineering Science 2019; 233: 4490–4496.

16.

Ding

Cheng

, et al. Dynamic optimization method with applications for machine tools based on approximation model. Proc IMechE, Part C: J Mechanical Engineering Science 2018; 232: 2009–2022.

17.

Sun

Chen

, et al. Effect of motor rotor eccentricity on aerostatic spindle vibration in machining processes. Proc IMechE, Part C: J Mechanical Engineering Science 2018; 232: 1331–1342.

18.

Wang

Chen

, et al. An investigation on surface finishing in ultra-precision raster milling of aluminum alloy 6061. Proc IMechE, Part B: J Engineering Manufacture 2015; 229: 1289–1301.

19.

Liu

Fang

, et al. Experimental study on size effect of tool edge and subsurface damage of single crystal silicon in nano-cutting. Int J Adv Manuf Technol 2018; 98: 1093–1101.

20.

Sze YK. The effect of preferred orientation in the single point diamond turning of polycrystalline materials. Dissertation, The Hong Kong Polytechnic University, Hong Kong, 2005.

21.

Liu

, et al. Influences of chip serration on micro-topography of machined surface in high-speed cutting. Int J Mach Tools Manuf 2015; 89: 202–207.

22.

Zhang

. A theoretical and experimental investigation into multimode tool vibration with surface generation in ultra-precision diamond turning. Int J Mach Tools Manuf 2013; 72: 32–36.

Cyclic shear angle for lamellar chip formation in ultra-precision machining

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