Predictive model for the full biaxial surface and subsurface residual stress profiles from turning

Kurt Jacobus; R. E. DeVor; S. G. Kapoor; R. A. Peascoe

doi:10.1115/1.1372197

Predictive model for the full biaxial surface and subsurface residual stress profiles from turning

Kurt Jacobus
, R. E. DeVor
, S. G. Kapoor
, R. A. Peascoe

Mechanical Science and Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

A model to predict the full biaxial surface and subsurface residual stresses from the turning process is presented. The model formulation includes thermomechanical coupling, plastic heating, frictional heating, convection, conduction, thermal softening and strain hardening. Calibration and validation of the model are undertaken. The predictive model stands as a tool both to optimize the turning process based on the resulting residual stresses and also to gain an in-depth understanding of the physics of residual stress development from the turning process. In addition, thorough analysis of the experimental results reveals insight into the effects of feed and depth of cut on the surface and subsurface machining-induced residual stresses.

Original language	English (US)
Pages (from-to)	537-546
Number of pages	10
Journal	Journal of Manufacturing Science and Engineering, Transactions of the ASME
Volume	123
Issue number	4
DOIs	https://doi.org/10.1115/1.1372197
State	Published - Nov 2001

ASJC Scopus subject areas

Control and Systems Engineering
Mechanical Engineering
Computer Science Applications
Industrial and Manufacturing Engineering

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10.1115/1.1372197

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abstract = "A model to predict the full biaxial surface and subsurface residual stresses from the turning process is presented. The model formulation includes thermomechanical coupling, plastic heating, frictional heating, convection, conduction, thermal softening and strain hardening. Calibration and validation of the model are undertaken. The predictive model stands as a tool both to optimize the turning process based on the resulting residual stresses and also to gain an in-depth understanding of the physics of residual stress development from the turning process. In addition, thorough analysis of the experimental results reveals insight into the effects of feed and depth of cut on the surface and subsurface machining-induced residual stresses.",

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AU - Peascoe, R. A.

PY - 2001/11

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N2 - A model to predict the full biaxial surface and subsurface residual stresses from the turning process is presented. The model formulation includes thermomechanical coupling, plastic heating, frictional heating, convection, conduction, thermal softening and strain hardening. Calibration and validation of the model are undertaken. The predictive model stands as a tool both to optimize the turning process based on the resulting residual stresses and also to gain an in-depth understanding of the physics of residual stress development from the turning process. In addition, thorough analysis of the experimental results reveals insight into the effects of feed and depth of cut on the surface and subsurface machining-induced residual stresses.

AB - A model to predict the full biaxial surface and subsurface residual stresses from the turning process is presented. The model formulation includes thermomechanical coupling, plastic heating, frictional heating, convection, conduction, thermal softening and strain hardening. Calibration and validation of the model are undertaken. The predictive model stands as a tool both to optimize the turning process based on the resulting residual stresses and also to gain an in-depth understanding of the physics of residual stress development from the turning process. In addition, thorough analysis of the experimental results reveals insight into the effects of feed and depth of cut on the surface and subsurface machining-induced residual stresses.

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Predictive model for the full biaxial surface and subsurface residual stress profiles from turning

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