J.A. Arsecularatne scite author profile

This paper presents a mechanics model for predicting the forces of cutting aluminium-based SiC/Al 2 O 3 particle reinforced MMCs. The force generation mechanism was considered to be due to three factors: (a) the chip formation force, (b) the ploughing force, and (c) the particle fracture force. The chip formation force was obtained by using Merchant's analysis but those due to matrix ploughing deformation and particle fracture were formulated, respectively, with the aid of the slip line field theory of plasticity and the Griffith theory of fracture. A comparison of the model predictions with the authors' experimental results and those published in the literature showed that the theoretical model developed has captured the major material removal/deformation mechanisms in MMCs and describes very well the experimental measurements.

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Machining of metal matrix composites: Effect of ceramic particles on residual stress, surface roughness and chip formation

Pramanik

Zhang

Arsecularatne

2008

International Journal of Machine Tools and Manufacture

221

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a b s t r a c tMachining forces, chip formation, surface integrity and shear and friction angles are important factors to understand the machinability of metal matrix composites (MMCs). However, because of the complexity of the reinforcement mechanisms of the ceramic particles, a fair assessment of the machinability of MMCs is still a difficult issue. This paper investigates experimentally the effects of reinforcement particles on the machining of MMCs. The major findings are: (1) the surface residual stresses on the machined MMC are compressive; (2) the surface roughness is controlled by feed;(3) particle pull-out influences the roughness when feed is low; (4) particles facilitate chip breaking and affect the generation of residual stresses; and (5) the shear and friction angles depend significantly on feed but are almost independent of speed. These results reveal the roles of the reinforcement particles on the machinability of MMCs and provide a useful guide for a better control of their machining processes.

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An FEM investigation into the behavior of metal matrix composites: Tool–particle interaction during orthogonal cutting

Pramanik

Zhang

Arsecularatne

2007

International Journal of Machine Tools and Manufacture

200

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Recent advances in understanding the fatigue and wear behavior of dental composites and ceramics

Kruzic

Arsecularatne

Tanaka

et al. 2018

Journal of the Mechanical Behavior of Biomedical Materials

110

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