MD Simulation and Optimization Analysis for Nanoscale Material Removal Process

Guo Kun Qu

doi:10.4028/www.scientific.net/KEM.667.102

Paper Titles

Global Stability Analysis on Combination Self-Excited Vibration of BTA Deep-Hole Boring Rotor Materials
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Hilbert Curve Fractal Stacking in the Application of Path Planning in the Molten Molding
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Investigation on Cutting Force and Temperature of Cutting Cu₅₀Zr₅₀ Metallic Glass by Molecular Dynamics Simulation
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Light Scattering of HDPE and LDPE in Laser Transmission Welding
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MD Simulation and Optimization Analysis for Nanoscale Material Removal Process
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MD Simulations of Nanomachining Monocrystalline Silicon
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Optimization Design of Diamond Circular Saw-Blade with Discontinuous Cutting and Uneven Distribution for Cutting Thin-Walled Tubes
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Research and Modeling of Blades with Complex Surfaces Based on Laser Rapid Prototyping
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Test and Analysis of Electric Arc Machining Characteristics of Titanium Alloy and High-Temperature Alloy
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 667MD Simulation and Optimization Analysis for...

MD Simulation and Optimization Analysis for Nanoscale Material Removal Process

Abstract:

To understand the thermal effects on material removal at atomic level, molecular dynamics (MD) simulation and optimization method are performed with the aid of Morse, EAM and Tersoff potential. The heat distribution is showed in 3D images under various parameters. The simulation results reveal that the heat distribution is roughly concentric around the tool edge and a steep temperature gradient is observed between diamond tool and chip. During material removal process, there is a narrow region with high temperature in shear zone where most of heat generated due to plastic deformation of workpiece material, the high temperature extends from here to chip, diamond tool and workpiece, but the highest temperature lies in chip. Compared with low speed, a higher temperature region below the tool edge implied a larger shear stress is built up in a local region and a rougher machined surface is generated at high cutting speed.

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Periodical:

Key Engineering Materials (Volume 667)

Pages:

102-107

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.667.102

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Online since:

October 2015

Authors:

Guo Kun Qu

Keywords:

Material Removal, Molecular Dynamics, Optimization, Thermal Effect

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