Researches on Effect of Impact Micro-Damages in Contact Layer on Machinability in Quick-Point Grinding

Shi Chao Xiu; Suo Xian Yuan; Guang Qi Cai

doi:10.4028/www.scientific.net/KEM.389-390.229

Paper Titles

Computer Aided Design and Grinding for Helical Drill Points
p.205

A New CBN Crystal for Improved Grinding Performance in Vitrified Bonds
p.211

Study on Two Kinds of Grinding Wheels for Dynamic Friction Polishing of CVD Diamond Film
p.217

Fundamental Study on the Precision Abrasive Machining Using a Cavitation in Reversing Suction Flow
p.223

Researches on Effect of Impact Micro-Damages in Contact Layer on Machinability in Quick-Point Grinding
p.229

Study on Abrasive Geometry of Quick-Point Grinding
p.235

Model-Based Compensation of Geometry-Errors when Grinding Material Compounds
p.240

A New Type of Drill Grinder Based on the Special Universal Joint
p.246

Simulation of Dynamic Performance for Hydro-Hybrid Spindle-Bearing System of Superhigh Speed Grinder
p.252

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Researches on Effect of Impact Micro-Damages in Contact Layer on Machinability in Quick-Point Grinding

Abstract:

Due to the high grinding speed and the less contact length, there is the super high material strain rate in the contact layer during quick-point grinding process. Based on the principle of micro-damages mechanics, it is the impact process between the workpiece and the grits on the wheel in the process. The weakening effects of the super high strain rate caused by the mechanical impact micro-damages and the adiabatic shearing damage can lower the dynamic strength of the material in contact layer and the micro-plastic pile-up deformation on the ground surface in the process. Therefore, it is possible to improve the surface integrity of the workpiece since the materials removal mechanism is changed in quick-point grinding process. In this paper, the impact performances and the model of quick point grinding process were studied. Based on the above, the model of the ground surface roughness related to the plastic pile-up deformation was established. The effects of the strain rate on the ground surface roughness and the materials removal ratio were analyzed. In addition, the grinding experiment was performed to testify such investigations. It is indicated that quick-point grinding is an impact process assuredly during the removing material process.