Finite Element Analysis of Temperature Field in Vibration Milling

Xue Hui Shen; Ming Yu Wang

doi:10.4028/www.scientific.net/KEM.693.1030

Paper Titles

A Study on Heat Transfer in High-Speed Grinding of Titanium Matrix Composites
p.1003

Experimental Optimization of Process Parameters for Turning TC11 Titanium Alloy Using Taguchi Methodology Design
p.1009

Experimental Study on the Wear of Single Crystal Diamond Tools in Ultra-Precision Cutting of Titanium Alloy
p.1015

Finite Element Analysis of SiCp/Al Model of Unit Cell during Ultrasonic Vibration Scratching
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Finite Element Analysis of Temperature Field in Vibration Milling
p.1030

Finite Element Deformation Analysis of Long Thin Cantilever Shape Parts in High Speed Ball End Milling of Titanium Alloy Ti-6Al-4V with PCD Tools at Various Tool Inclination Angles
p.1038

Finite Element Simulation of the Cutting Process for Inconel 718 Alloy Using a New Material Constitutive Model
p.1046

Finite Element Simulation on the Distribution of Discharge Gas in Hollow Cathode Plasma
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Heat Conduction in Coated Tools during Cutting Based on Finite Element Simulation
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 693Finite Element Analysis of Temperature Field in...

Finite Element Analysis of Temperature Field in Vibration Milling

Abstract:

The purpose of this paper is to investigate the variation of temperature field of ultrasonic vibration assisted milling compared with that of conventional milling by FEM method. An equivalent two-dimensional finite element model was built to simplify the complexity of calculation. As results, the temperature field distribution, the variation of tool tip temperature and the change of heat generation rate in ultrasonic vibration assisted milling were analyzed compared with that in conventional milling process. According to analytical results, the application of ultrasonic vibration in milling process can significantly improve the distribution of cutting temperature, and reduce the impacts of thermal deformation and various thermal effects to cutting process.

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Periodical:

Key Engineering Materials (Volume 693)

Pages:

1030-1037

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.693.1030

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Online since:

May 2016

Authors:

Xue Hui Shen*, Ming Yu Wang

Keywords:

FEM, Milling, Temperature Field, Vibration Cutting

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