Nonisothermal Axisymmetric Forging

P. Dadras; P. R. Burte

Source: Journal of Manufacturing Science and Engineering:;1986:;volume( 108 ):;issue: 004::page 288

Author:

P. Dadras

P. R. Burte

DOI: 10.1115/1.3187079

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: An approximate solution for nonisothermal upset forging is presented. A finite difference thermal analysis and an upper-bound deformation solution are used for this purpose. The thermal analysis is for a homogeneous state of strain, it ignores deformation heating, but accounts for all modes of heat flow during the transfer of the billet to the tooling and throughout the deformation. The upper-bound solution is based on admissible velocity field equations, the recorded temperature data from the thermal analysis, and constitutive equations for temperature, strain, and strain rate-dependence of flow stress. The size of the chilled zone is determined by minimization of total power for the deformation process. Theoretical predictions for load-displacement behavior and the size of the chilled zone are compared with the experimental results for 304 stainless and AISI 1042 steels.

keyword(s): Forging , Deformation , Thermal analysis , Flow (Dynamics) , Temperature , Stress , Constitutive equations , Displacement , Equations , Tooling , Steel , Heat AND Heating ,

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Nonisothermal Axisymmetric Forging

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contributor author	P. Dadras
contributor author	P. R. Burte
date accessioned	2017-05-08T23:22:53Z
date available	2017-05-08T23:22:53Z
date copyright	November, 1986
date issued	1986
identifier issn	1087-1357
identifier other	JMSEFK-27721#288_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/101361
description abstract	An approximate solution for nonisothermal upset forging is presented. A finite difference thermal analysis and an upper-bound deformation solution are used for this purpose. The thermal analysis is for a homogeneous state of strain, it ignores deformation heating, but accounts for all modes of heat flow during the transfer of the billet to the tooling and throughout the deformation. The upper-bound solution is based on admissible velocity field equations, the recorded temperature data from the thermal analysis, and constitutive equations for temperature, strain, and strain rate-dependence of flow stress. The size of the chilled zone is determined by minimization of total power for the deformation process. Theoretical predictions for load-displacement behavior and the size of the chilled zone are compared with the experimental results for 304 stainless and AISI 1042 steels.
publisher	The American Society of Mechanical Engineers (ASME)
title	Nonisothermal Axisymmetric Forging
type	Journal Paper
journal volume	108
journal issue	4
journal title	Journal of Manufacturing Science and Engineering
identifier doi	10.1115/1.3187079
journal fristpage	288
journal lastpage	294
identifier eissn	1528-8935
keywords	Forging
keywords	Deformation
keywords	Thermal analysis
keywords	Flow (Dynamics)
keywords	Temperature
keywords	Stress
keywords	Constitutive equations
keywords	Displacement
keywords	Equations
keywords	Tooling
keywords	Steel
keywords	Heat AND Heating
tree	Journal of Manufacturing Science and Engineering:;1986:;volume( 108 ):;issue: 004
contenttype	Fulltext

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