Microstructure-Level Model for the Prediction of Tool Failure in WC-Co Cutting Tool Materials

Sunghyuk Park; Shiv G. Kapoor; Richard E. DeVor

Source: Journal of Manufacturing Science and Engineering:;2006:;volume( 128 ):;issue: 003::page 739

Author:

Sunghyuk Park

Shiv G. Kapoor

Richard E. DeVor

DOI: 10.1115/1.2194233

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A model to predict tool failure due to chipping in machining via the microstructure-level finite element cutting process simulation is presented and applied to a wide variety of WC-Co tool materials. The methodology includes the creation of arbitrary microstructures comprised of WC and Co phases to simulate various grades of WC-Co alloys. Equivalent stress, strain, and strain energy are then obtained via orthogonal microstructure-level finite element machining simulations. A model was developed to predict the occurrence of tool failure based on the mixed mode fracture criterion. Turning experiments were conducted to validate the model and the results showed that the model predictions agree well with the observations from the experiments. The model was then employed to study the effects of microstructural parameters and feedrate on chipping and failure.

keyword(s): Stress , Finite element analysis , Fracture (Process) , Cutting , Failure , Ductile fracture , Machining , Engineering simulation , Simulation AND Cutting tools ,

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Microstructure-Level Model for the Prediction of Tool Failure in WC-Co Cutting Tool Materials

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contributor author	Sunghyuk Park
contributor author	Shiv G. Kapoor
contributor author	Richard E. DeVor
date accessioned	2017-05-09T00:20:43Z
date available	2017-05-09T00:20:43Z
date copyright	August, 2006
date issued	2006
identifier issn	1087-1357
identifier other	JMSEFK-27953#739_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/134147
description abstract	A model to predict tool failure due to chipping in machining via the microstructure-level finite element cutting process simulation is presented and applied to a wide variety of WC-Co tool materials. The methodology includes the creation of arbitrary microstructures comprised of WC and Co phases to simulate various grades of WC-Co alloys. Equivalent stress, strain, and strain energy are then obtained via orthogonal microstructure-level finite element machining simulations. A model was developed to predict the occurrence of tool failure based on the mixed mode fracture criterion. Turning experiments were conducted to validate the model and the results showed that the model predictions agree well with the observations from the experiments. The model was then employed to study the effects of microstructural parameters and feedrate on chipping and failure.
publisher	The American Society of Mechanical Engineers (ASME)
title	Microstructure-Level Model for the Prediction of Tool Failure in WC-Co Cutting Tool Materials
type	Journal Paper
journal volume	128
journal issue	3
journal title	Journal of Manufacturing Science and Engineering
identifier doi	10.1115/1.2194233
journal fristpage	739
journal lastpage	748
identifier eissn	1528-8935
keywords	Stress
keywords	Finite element analysis
keywords	Fracture (Process)
keywords	Cutting
keywords	Failure
keywords	Ductile fracture
keywords	Machining
keywords	Engineering simulation
keywords	Simulation AND Cutting tools
tree	Journal of Manufacturing Science and Engineering:;2006:;volume( 128 ):;issue: 003
contenttype	Fulltext

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