Mesoscopic model for SiCp/Al composites and simulation on the cutting process

Xiao Ju Shui; Yi Du Zhang; Qiong Wu

doi:10.4028/www.scientific.net/AMM.487.189

Mesoscopic model for SiC_p/Al composites and simulation on the cutting process

Xiao Ju Shui
, Yi Du Zhang
, Qiong Wu

School of Mechanical Engineering and Automation

Beihang University

Research output: Contribution to journal › Conference article › peer-review

13 Scopus citations

Abstract

For deep application of the FEM on the study of cutting mechanism of SiC_P/Al, the article completed the algorithm to generate the mesoscopic model of SiC_P/Al with the parameterization of the shape and volume fraction of SiC based on the ABAQUS scripting language python. Two-dimensional randomly distributed circular particles model, circular mixed with regular polygon particles model and arbitrary polygon model are generated with volume fraction of 30% and cutting simulations were carried out on the models. Results show that cutting force of SiC_P/Al with uniform distribution and size of circular particles will be relatively stable and during the cutting process, stress field changes with the shape and distribution of the particles and the relative position of the particles and tool. Poor surface quality was mainly caused by the interaction among the tool, the particles and the matrix material.

Original language	English
Pages (from-to)	189-194
Number of pages	6
Journal	Applied Mechanics and Materials
Volume	487
DOIs	https://doi.org/10.4028/www.scientific.net/AMM.487.189
State	Published - 2014
Event	2013 International Conference on Mechanical Structures and Smart Materials, ICMSSM 2013 - Xiamen, China Duration: 16 Nov 2013 → 17 Nov 2013

Keywords

Mesoscopic model
SiC/Al composites
Simulation on cutting process

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10.4028/www.scientific.net/AMM.487.189

Cite this

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title = "Mesoscopic model for SiCp/Al composites and simulation on the cutting process",

abstract = "For deep application of the FEM on the study of cutting mechanism of SiCP/Al, the article completed the algorithm to generate the mesoscopic model of SiCP/Al with the parameterization of the shape and volume fraction of SiC based on the ABAQUS scripting language python. Two-dimensional randomly distributed circular particles model, circular mixed with regular polygon particles model and arbitrary polygon model are generated with volume fraction of 30\% and cutting simulations were carried out on the models. Results show that cutting force of SiCP/Al with uniform distribution and size of circular particles will be relatively stable and during the cutting process, stress field changes with the shape and distribution of the particles and the relative position of the particles and tool. Poor surface quality was mainly caused by the interaction among the tool, the particles and the matrix material.",

keywords = "Mesoscopic model, SiC/Al composites, Simulation on cutting process",

author = "Shui, \{Xiao Ju\} and Zhang, \{Yi Du\} and Qiong Wu",

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language = "英语",

volume = "487",

pages = "189--194",

journal = "Applied Mechanics and Materials",

issn = "1660-9336",

publisher = "Trans Tech Publications Ltd",

note = "2013 International Conference on Mechanical Structures and Smart Materials, ICMSSM 2013 ; Conference date: 16-11-2013 Through 17-11-2013",

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TY - JOUR

T1 - Mesoscopic model for SiCp/Al composites and simulation on the cutting process

AU - Shui, Xiao Ju

AU - Zhang, Yi Du

AU - Wu, Qiong

PY - 2014

Y1 - 2014

N2 - For deep application of the FEM on the study of cutting mechanism of SiCP/Al, the article completed the algorithm to generate the mesoscopic model of SiCP/Al with the parameterization of the shape and volume fraction of SiC based on the ABAQUS scripting language python. Two-dimensional randomly distributed circular particles model, circular mixed with regular polygon particles model and arbitrary polygon model are generated with volume fraction of 30% and cutting simulations were carried out on the models. Results show that cutting force of SiCP/Al with uniform distribution and size of circular particles will be relatively stable and during the cutting process, stress field changes with the shape and distribution of the particles and the relative position of the particles and tool. Poor surface quality was mainly caused by the interaction among the tool, the particles and the matrix material.

AB - For deep application of the FEM on the study of cutting mechanism of SiCP/Al, the article completed the algorithm to generate the mesoscopic model of SiCP/Al with the parameterization of the shape and volume fraction of SiC based on the ABAQUS scripting language python. Two-dimensional randomly distributed circular particles model, circular mixed with regular polygon particles model and arbitrary polygon model are generated with volume fraction of 30% and cutting simulations were carried out on the models. Results show that cutting force of SiCP/Al with uniform distribution and size of circular particles will be relatively stable and during the cutting process, stress field changes with the shape and distribution of the particles and the relative position of the particles and tool. Poor surface quality was mainly caused by the interaction among the tool, the particles and the matrix material.

KW - Mesoscopic model

KW - SiC/Al composites

KW - Simulation on cutting process

UR - https://www.scopus.com/pages/publications/84892715961

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DO - 10.4028/www.scientific.net/AMM.487.189

M3 - 会议文章

AN - SCOPUS:84892715961

SN - 1660-9336

VL - 487

SP - 189

EP - 194

JO - Applied Mechanics and Materials

JF - Applied Mechanics and Materials

T2 - 2013 International Conference on Mechanical Structures and Smart Materials, ICMSSM 2013

Y2 - 16 November 2013 through 17 November 2013

ER -

Mesoscopic model for SiC_p/Al composites and simulation on the cutting process

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Keywords

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