Hot deformation behavior of superaustenitic stainless steel S32654 was investigated with hot compression tests at temperatures of 950-1250 ℃ and strain rates of 0001-10 s-1. Above 1150 ℃, with strain rate lower than 01 s-1, the flow curves exhibit nearly steady-state behavior, while at higher strain rate, continuous flow softening occurs. To provide a precise prediction of flow behavior for the alloy, the constitutive modeling considering effect of strain was derived on the basis of the obtained experimental data and constitutive relationship which incorporated Arrhenius term and hyperbolic-sine type equation. The material constants α, n, Q and lnA are found to be functions of the strain and can be fitted employing eighth-order polynomial. The developed constitutive model can be employed to describe the deformation behavior of superaustenitic stainless steel S32654.
Abstract
Hot deformation behavior of superaustenitic stainless steel S32654 was investigated with hot compression tests at temperatures of 950-1250 ℃ and strain rates of 0001-10 s-1. Above 1150 ℃, with strain rate lower than 01 s-1, the flow curves exhibit nearly steady-state behavior, while at higher strain rate, continuous flow softening occurs. To provide a precise prediction of flow behavior for the alloy, the constitutive modeling considering effect of strain was derived on the basis of the obtained experimental data and constitutive relationship which incorporated Arrhenius term and hyperbolic-sine type equation. The material constants α, n, Q and lnA are found to be functions of the strain and can be fitted employing eighth-order polynomial. The developed constitutive model can be employed to describe the deformation behavior of superaustenitic stainless steel S32654.
关键词
S32654 /
Superaustenitic stainless steel /
Hot deformation /
constitutive model
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Key words
S32654 /
Superaustenitic stainless steel /
Hot deformation /
constitutive model
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参考文献
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