Modeling Material Removal Rate of Heavy Belt-Grinding in Manufacturing of U71Mn Material

Rong Quan Wang; Jian Yong Li; Yue Ming Liu; Wen Xi Wang

doi:10.4028/www.scientific.net/KEM.693.1082

Paper Titles

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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Influence of Edge Preparation Parameters on the Cutting Edge in Drag Finishing
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Microfabrication and Characterization of Tool Embedded Ni-Chrome Thin Film Micro-Sensors for Cutting Force Measurement
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Modeling Material Removal Rate of Heavy Belt-Grinding in Manufacturing of U71Mn Material
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Process Optimization of Lapping Sapphire Substrate with Fixed Diamond Abrasive Pad
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Reliability of Al₂O₃/TiC Micro-Nano-Composite Ceramic Tool in the Machining of Stainless Steel
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Research on Dental Ceramic Grinding: A Review
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Research on the Effects of Tapping Performances with Multiple-Type Parameters
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 693Modeling Material Removal Rate of Heavy...

Modeling Material Removal Rate of Heavy Belt-Grinding in Manufacturing of U71Mn Material

Abstract:

The heavy belt-grinding is a new machining method, which combined the characters of heavy-duty grinding and belt-grinding together, with high efficiency and low cost. In the present paper the removal rate model of heavy belt-grinding in manufacturing of U71Mn steel is established. It is assumed that the distribution of the abrasive particles protrusion height of the abrasive belt surface closes to Gaussian distribution. The model is presented by calculating the removal volumes of all abrasive grains contributing to cutting action based on the probability theory, elastic-plastic mechanics and abrasive cutting theory. It is analysis that the material removal rate depends essentially on the mechanical properties of the workpiece and the belt and the grinding conditions. It is proportional to the average pressure, belt velocity and the indentation depth and is inverse proportion to the grain size.

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Periodical:

Key Engineering Materials (Volume 693)

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1082-1089

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https://doi.org/10.4028/www.scientific.net/KEM.693.1082

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Online since:

May 2016

Authors:

Rong Quan Wang, Jian Yong Li, Yue Ming Liu*, Wen Xi Wang

Keywords:

Heavy Belt-Grinding, Material Removal Rate, U71Mn Steel

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