Two phenomenological models to predict the single peak flow stress curves up to the peak during hot deformation

Soheil Solhjoo; Antonis I. Vakis; Yutao T. Pei

doi:10.1016/j.mechmat.2016.12.001

Two phenomenological models to predict the single peak flow stress curves up to the peak during hot deformation

Soheil Solhjoo, Antonis I. Vakis, Yutao T. Pei

Advanced Production Engineering

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Based on both linear and nonlinear estimations of work hardening rate versus strain curves, two mathematical models have been developed to predict the stress-strain curves under hot working conditions up to the peak stress. The models were validated for a mechanically alloyed Al6063/0.75Al2O3/0.75Y2O3 nanocomposite compressed under different hot forming conditions. The predicted results from both models are found to be in accord with the experimental flow stress curves up to the peak. For the present system, the linear model is found to more accurately predict the flow stress (with an average error of 0.81%) relative to the nonlinear model (with an average error of 2.06%).

Originele taal-2	English
Pagina's (van-tot)	61-66
Aantal pagina's	6
Tijdschrift	Mechanics of Materials
Volume	105
Vroegere onlinedatum	2016
DOI's	https://doi.org/10.1016/j.mechmat.2016.12.001
Status	Published - feb.-2017

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10.1016/j.mechmat.2016.12.001

Two phenomenological models to predict the single peak flow stress curvesFinal publisher's version, 1,55 MBLicentie: Taverne

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title = "Two phenomenological models to predict the single peak flow stress curves up to the peak during hot deformation",

abstract = "Based on both linear and nonlinear estimations of work hardening rate versus strain curves, two mathematical models have been developed to predict the stress-strain curves under hot working conditions up to the peak stress. The models were validated for a mechanically alloyed Al6063/0.75Al2O3/0.75Y2O3 nanocomposite compressed under different hot forming conditions. The predicted results from both models are found to be in accord with the experimental flow stress curves up to the peak. For the present system, the linear model is found to more accurately predict the flow stress (with an average error of 0.81%) relative to the nonlinear model (with an average error of 2.06%).",

author = "Soheil Solhjoo and Vakis, {Antonis I.} and Pei, {Yutao T.}",

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language = "English",

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T1 - Two phenomenological models to predict the single peak flow stress curves up to the peak during hot deformation

AU - Solhjoo, Soheil

AU - Vakis, Antonis I.

AU - Pei, Yutao T.

PY - 2017/2

Y1 - 2017/2

N2 - Based on both linear and nonlinear estimations of work hardening rate versus strain curves, two mathematical models have been developed to predict the stress-strain curves under hot working conditions up to the peak stress. The models were validated for a mechanically alloyed Al6063/0.75Al2O3/0.75Y2O3 nanocomposite compressed under different hot forming conditions. The predicted results from both models are found to be in accord with the experimental flow stress curves up to the peak. For the present system, the linear model is found to more accurately predict the flow stress (with an average error of 0.81%) relative to the nonlinear model (with an average error of 2.06%).

AB - Based on both linear and nonlinear estimations of work hardening rate versus strain curves, two mathematical models have been developed to predict the stress-strain curves under hot working conditions up to the peak stress. The models were validated for a mechanically alloyed Al6063/0.75Al2O3/0.75Y2O3 nanocomposite compressed under different hot forming conditions. The predicted results from both models are found to be in accord with the experimental flow stress curves up to the peak. For the present system, the linear model is found to more accurately predict the flow stress (with an average error of 0.81%) relative to the nonlinear model (with an average error of 2.06%).

U2 - 10.1016/j.mechmat.2016.12.001

DO - 10.1016/j.mechmat.2016.12.001

M3 - Article

SN - 1872-7743

VL - 105

SP - 61

EP - 66

JO - Mechanics of Materials

JF - Mechanics of Materials

ER -