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Dynamic uniform deformation for electromagnetic uniaxial tension

Journal Article


Abstract


  • To compare with quasi-static uniaxial tensioning, researchers designed an electromagnetic uniaxial tension method using a runway coil. However, the requirements to obtain a uniformly deformed sample and the ways the stress changes on the sample using a runway coil have not been studied in the past. In this study, a three-dimensional (3D) sequential coupling method was developed to analyze the factors affecting on-sheet deformation inhomogeneity under electromagnetic uniaxial tension. Two main process parameters, comprising the die type and the relative position of the coil and sheet, were evaluated. Under the optimal parameters, the experiment and simulation both obtained uniformly deformed samples with different discharge conditions, and the simulation method had a high accuracy in modeling the deformation process. The stress state of the sample is approximately unidirectional tensile stress before 240 μs. After 240 μs, the three main stresses showed significant oscillations.

Publication Date


  • 2019

Published In


Citation


  • Cui, X., Zhang, Z., Yu, H., Cheng, Y., & Xiao, X. (2019). Dynamic uniform deformation for electromagnetic uniaxial tension. Metals, 9(4). doi:10.3390/met9040425

Scopus Eid


  • 2-s2.0-85067011601

Volume


  • 9

Issue


  • 4

Abstract


  • To compare with quasi-static uniaxial tensioning, researchers designed an electromagnetic uniaxial tension method using a runway coil. However, the requirements to obtain a uniformly deformed sample and the ways the stress changes on the sample using a runway coil have not been studied in the past. In this study, a three-dimensional (3D) sequential coupling method was developed to analyze the factors affecting on-sheet deformation inhomogeneity under electromagnetic uniaxial tension. Two main process parameters, comprising the die type and the relative position of the coil and sheet, were evaluated. Under the optimal parameters, the experiment and simulation both obtained uniformly deformed samples with different discharge conditions, and the simulation method had a high accuracy in modeling the deformation process. The stress state of the sample is approximately unidirectional tensile stress before 240 μs. After 240 μs, the three main stresses showed significant oscillations.

Publication Date


  • 2019

Published In


Citation


  • Cui, X., Zhang, Z., Yu, H., Cheng, Y., & Xiao, X. (2019). Dynamic uniform deformation for electromagnetic uniaxial tension. Metals, 9(4). doi:10.3390/met9040425

Scopus Eid


  • 2-s2.0-85067011601

Volume


  • 9

Issue


  • 4