A hybrid predictive model and validation for chip flow in contour finish turning operations with coated grooved tools

M. Hagiwara; S. Chen; I. S. Jawahir

doi:10.1016/j.jmatprotec.2008.03.063

A hybrid predictive model and validation for chip flow in contour finish turning operations with coated grooved tools

M. Hagiwara, S. Chen, I. S. Jawahir

Producción científica: Article › revisión exhaustiva

6 Citas (Scopus)

Resumen

Unlike straight turning, the effective cutting conditions and tool geometry in contour turning operations are continuously changing with changing workpiece profile. This causes a wide variation in chip flow during the operation. Unfavorable chip flow can cause scratch/damage the machined surface, and lead to tool failure due to chip build up at the cutting edge. This paper presents a new methodology to predict the chip side-flow angle for complex grooved tool inserts in contour turning operations as well as experimental validation. Computer program has been developed to apply the predictive model to any contour workpiece profile and the capability of the predictive program is also presented in this paper.

Idioma original	English
Páginas (desde-hasta)	1417-1427
Número de páginas	11
Publicación	Journal of Materials Processing Technology
Volumen	209
N.º	3
DOI	https://doi.org/10.1016/j.jmatprotec.2008.03.063
Estado	Published - feb 1 2009

ASJC Scopus subject areas

Ceramics and Composites
Computer Science Applications
Metals and Alloys
Industrial and Manufacturing Engineering

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title = "A hybrid predictive model and validation for chip flow in contour finish turning operations with coated grooved tools",

abstract = "Unlike straight turning, the effective cutting conditions and tool geometry in contour turning operations are continuously changing with changing workpiece profile. This causes a wide variation in chip flow during the operation. Unfavorable chip flow can cause scratch/damage the machined surface, and lead to tool failure due to chip build up at the cutting edge. This paper presents a new methodology to predict the chip side-flow angle for complex grooved tool inserts in contour turning operations as well as experimental validation. Computer program has been developed to apply the predictive model to any contour workpiece profile and the capability of the predictive program is also presented in this paper.",

keywords = "Chip side-flow, Contour turning operations, Predictive model, Simulation program, User interface",

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AU - Chen, S.

AU - Jawahir, I. S.

PY - 2009/2/1

Y1 - 2009/2/1

N2 - Unlike straight turning, the effective cutting conditions and tool geometry in contour turning operations are continuously changing with changing workpiece profile. This causes a wide variation in chip flow during the operation. Unfavorable chip flow can cause scratch/damage the machined surface, and lead to tool failure due to chip build up at the cutting edge. This paper presents a new methodology to predict the chip side-flow angle for complex grooved tool inserts in contour turning operations as well as experimental validation. Computer program has been developed to apply the predictive model to any contour workpiece profile and the capability of the predictive program is also presented in this paper.

AB - Unlike straight turning, the effective cutting conditions and tool geometry in contour turning operations are continuously changing with changing workpiece profile. This causes a wide variation in chip flow during the operation. Unfavorable chip flow can cause scratch/damage the machined surface, and lead to tool failure due to chip build up at the cutting edge. This paper presents a new methodology to predict the chip side-flow angle for complex grooved tool inserts in contour turning operations as well as experimental validation. Computer program has been developed to apply the predictive model to any contour workpiece profile and the capability of the predictive program is also presented in this paper.

KW - Chip side-flow

KW - Contour turning operations

KW - Predictive model

KW - Simulation program

KW - User interface

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JO - Journal of Materials Processing Technology

JF - Journal of Materials Processing Technology

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ER -

A hybrid predictive model and validation for chip flow in contour finish turning operations with coated grooved tools

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ASJC Scopus subject areas

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