Theoretical Model of Surface Roughness for Polishing Super Hard Materials with Abrasive Waterjet

Cui Lian Che; Chuan Zhen Huang; Jun Wang; Hong Tao Zhu; Quan Lai Li

doi:10.4028/www.scientific.net/KEM.375-376.465

Paper Titles

Analysis of Optimal Clamping Schemes for Aero-Multi-Frame Monolithic Components
p.445

Model and Simulation of Slurry Velocity and Hydrodynamic Pressure in Abrasive Jet Finishing with Grinding Wheel as Restraint
p.449

Research on Dynamic Physical Simulation of HSC Comprehensive Characteristics
p.454

Study on Impact Disrepair Mathematic Model and Groove Optimization of Cutting Tools for Machining Carbon Structural Steel
p.459

Theoretical Model of Surface Roughness for Polishing Super Hard Materials with Abrasive Waterjet
p.465

A Study of Exit-Burr Formation Mechanism Using the Finite Element Method in Micro-Cutting of Aluminum Alloy
p.470

Building and Simulation of the Digital Polishing Path of Mold Free-Curved Surface
p.474

Study on the Correlativity between Grinding Parameters and Surface Residual Stresses in Ceramic
p.480

Control and Analysis of Nonlinear Error for 5-Axis Machining of Hybrid Machine Tool
p.485

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Theoretical Model of Surface Roughness for Polishing Super Hard Materials with Abrasive Waterjet

Abstract:

In this paper, the impact pressure of abrasives acting on the polished materials was deduced by Field Theory and the model of surface roughness for polishing super hard materials with Abrasive Water Jet (AWJ) was established. The model indicates that the surface roughness increases linearly with an increase in the maximum depth of abrasives indenting into materials and that the relationship between the surface roughness and polishing parameters including water pressure, abrasive pressure, the impact angle, the hardness of the polished material, the elastic distortion of abrasive, abrasive size, abrasive density, nozzle diameter and standoff.

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Periodical:

Key Engineering Materials (Volumes 375-376)

Pages:

465-469

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.375-376.465

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Online since:

March 2008

Authors:

Cui Lian Che, Chuan Zhen Huang, Jun Wang, Hong Tao Zhu, Quan Lai Li

Keywords:

Abrasive Water Jet (AWJ), Impact Pressure, Polishing Process, Surface Roughness Model

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