Physically-Based Constitutive Modelling of As-Cast CL70 Steel for Hot Deformation

In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformation for as-cast CL70 steel, the hot deformation behaviors of as-cast CL70 steel were studied by isothermal compression tests which used a Gleeble-1500D thermal mechanical simulation t...

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Published in	Metals and materials international Vol. 27; no. 6; pp. 1728 - 1738
Main Authors	Chen, Fei, Zhao, Xiaodong, Ren, Jinyu, Chen, Huiqin, Zhang, Xiaofeng
Format	Journal Article
Language	English
Published	Seoul The Korean Institute of Metals and Materials 01.06.2021 Springer Nature B.V 대한금속·재료학회
Subjects	Characterization and Evaluation of Materials Chemistry and Materials Science Compression tests Constitutive models Deformation Dislocation density Dynamic recrystallization Engineering Thermodynamics Heat and Mass Transfer Heat treating High temperature Low alloy steels Machines Magnetic Materials Magnetism Manufacturing Materials Science Mathematical models Metallic Materials Model accuracy Process parameters Processes Recovery Solid Mechanics Strain Thermal simulation Work hardening Yield strength 재료공학 Constitutive model As-cast CL70 steel Hot deformation behavior
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Abstract	In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformation for as-cast CL70 steel, the hot deformation behaviors of as-cast CL70 steel were studied by isothermal compression tests which used a Gleeble-1500D thermal mechanical simulation tester for the deformation temperatures ranging from 1173 to 1523 K and the strain rates ranging from 0.001 to 1 s −1 . Flow stress curves of the steel were obtained under high temperature. The flow stress constitutive models of the work hardening-dynamical recovery period and dynamical recrystallization period were established for as-cast CL70 steel. In work hardening-dynamic recovery period, the flow stress was predicted by employing the evolution rule of dislocation density in the constitutive model. In dynamic recrystallization period, the flow stress after the critical strain was predicted by employing the dynamic recrystallization kinetics in the constitutive model. To improve the prediction accuracy of the model, the dynamic recovery coefficient is modified in the traditional physically-based constitutive model. The results indicate that the proposed physically-based constitutive model has high accuracy in predicting the flow stress under hot deformation for as-cast CL70 steel. Graphic Abstract
AbstractList	In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformation for as-cast CL70 steel, the hot deformation behaviors of as-cast CL70 steel were studied by isothermal compression tests which used a Gleeble-1500D thermal mechanical simulation tester for the deformation temperatures ranging from 1173 to 1523 K and the strain rates ranging from 0.001 to 1 s −1 . Flow stress curves of the steel were obtained under high temperature. The flow stress constitutive models of the work hardening-dynamical recovery period and dynamical recrystallization period were established for as-cast CL70 steel. In work hardening-dynamic recovery period, the flow stress was predicted by employing the evolution rule of dislocation density in the constitutive model. In dynamic recrystallization period, the flow stress after the critical strain was predicted by employing the dynamic recrystallization kinetics in the constitutive model. To improve the prediction accuracy of the model, the dynamic recovery coefficient is modified in the traditional physically-based constitutive model. The results indicate that the proposed physically-based constitutive model has high accuracy in predicting the flow stress under hot deformation for as-cast CL70 steel. Graphic Abstract In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformationfor as-cast CL70 steel, the hot deformation behaviors of as-cast CL70 steel were studied by isothermal compression testswhich used a Gleeble-1500D thermal mechanical simulation tester for the deformation temperatures ranging from 1173 to1523 K and the strain rates ranging from 0.001 to 1 s−1. Flow stress curves of the steel were obtained under high temperature. The flow stress constitutive models of the work hardening-dynamical recovery period and dynamical recrystallizationperiod were established for as-cast CL70 steel. In work hardening-dynamic recovery period, the flow stress was predicted byemploying the evolution rule of dislocation density in the constitutive model. In dynamic recrystallization period, the flowstress after the critical strain was predicted by employing the dynamic recrystallization kinetics in the constitutive model. To improve the prediction accuracy of the model, the dynamic recovery coefficient is modified in the traditional physicallybasedconstitutive model. The results indicate that the proposed physically-based constitutive model has high accuracy inpredicting the flow stress under hot deformation for as-cast CL70 steel. KCI Citation Count: 0 In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformation for as-cast CL70 steel, the hot deformation behaviors of as-cast CL70 steel were studied by isothermal compression tests which used a Gleeble-1500D thermal mechanical simulation tester for the deformation temperatures ranging from 1173 to 1523 K and the strain rates ranging from 0.001 to 1 s−1. Flow stress curves of the steel were obtained under high temperature. The flow stress constitutive models of the work hardening-dynamical recovery period and dynamical recrystallization period were established for as-cast CL70 steel. In work hardening-dynamic recovery period, the flow stress was predicted by employing the evolution rule of dislocation density in the constitutive model. In dynamic recrystallization period, the flow stress after the critical strain was predicted by employing the dynamic recrystallization kinetics in the constitutive model. To improve the prediction accuracy of the model, the dynamic recovery coefficient is modified in the traditional physically-based constitutive model. The results indicate that the proposed physically-based constitutive model has high accuracy in predicting the flow stress under hot deformation for as-cast CL70 steel.
Author	Chen, Fei Zhao, Xiaodong Ren, Jinyu Chen, Huiqin Zhang, Xiaofeng
Author_xml	– sequence: 1 givenname: Fei surname: Chen fullname: Chen, Fei organization: College of Materials Science and Engineering, Taiyuan University of Science and Technology – sequence: 2 givenname: Xiaodong surname: Zhao fullname: Zhao, Xiaodong organization: College of Materials Science and Engineering, Taiyuan University of Science and Technology – sequence: 3 givenname: Jinyu surname: Ren fullname: Ren, Jinyu organization: College of Materials Science and Engineering, Taiyuan University of Science and Technology – sequence: 4 givenname: Huiqin surname: Chen fullname: Chen, Huiqin email: chen_huiqin@126.com organization: College of Materials Science and Engineering, Taiyuan University of Science and Technology – sequence: 5 givenname: Xiaofeng surname: Zhang fullname: Zhang, Xiaofeng organization: Technique Center, Tai Yuan Heavy Industry Transit Equipment Co.,Ltd
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Snippet	In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformation for as-cast CL70 steel, the hot... In order to conduct numerical simulation of plasticity forming and confirm the processing parameters of heat deformationfor as-cast CL70 steel, the hot...
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SubjectTerms	Characterization and Evaluation of Materials Chemistry and Materials Science Compression tests Constitutive models Deformation Dislocation density Dynamic recrystallization Engineering Thermodynamics Heat and Mass Transfer Heat treating High temperature Low alloy steels Machines Magnetic Materials Magnetism Manufacturing Materials Science Mathematical models Metallic Materials Model accuracy Process parameters Processes Recovery Solid Mechanics Strain Thermal simulation Work hardening Yield strength 재료공학
Title	Physically-Based Constitutive Modelling of As-Cast CL70 Steel for Hot Deformation
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