Shape calibration of high strength metal sheets by electromagnetic forming

E. Iriondo; J. L. Alcaraz; G. S. Daehn; M. A. Gutiérrez; P. Jimbert

doi:10.1016/j.jmapro.2013.01.007

Shape calibration of high strength metal sheets by electromagnetic forming

E. Iriondo, J. L. Alcaraz^*, G. S. Daehn, M. A. Gutiérrez, P. Jimbert

^*Corresponding author for this work

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Research output: Contribution to journal › Article › peer-review

49 Citations (Scopus)

Abstract

Electromagnetic (EM) forming is an emerging technique that is gaining acceptance for its complementary benefits to conventional metal forming techniques. In this work an innovative application of this impulse forming technique has been demonstrated: the EM shape calibration and correction of springback (sidewall curl) of DP600 and TRIP700 high strength steel (HSS) workpieces. This method has been applied as a second corrective step to previously deep drawn U-channels. The experimental results confirm the sidewall curl angle correction, achieving them with a 22 kJ discharge for DP600 samples and 24 kJ for TRIP700. On the other hand, an uncoupled multiphysical simulation strategy has been carried out in order to virtually validate the EM shape calibration method. The EM fields were simulated by Maxwell 3D and then the Pamstamp code was used to obtain the deformation process.

Original language	English
Pages (from-to)	183-193
Number of pages	11
Journal	Journal of Manufacturing Processes
Volume	15
Issue number	2
DOIs	https://doi.org/10.1016/j.jmapro.2013.01.007
Publication status	Published - Apr 2013

Keywords

Electromagnetic forming
High strength steels
Springback calibration

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.jmapro.2013.01.007

Cite this

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title = "Shape calibration of high strength metal sheets by electromagnetic forming",

abstract = "Electromagnetic (EM) forming is an emerging technique that is gaining acceptance for its complementary benefits to conventional metal forming techniques. In this work an innovative application of this impulse forming technique has been demonstrated: the EM shape calibration and correction of springback (sidewall curl) of DP600 and TRIP700 high strength steel (HSS) workpieces. This method has been applied as a second corrective step to previously deep drawn U-channels. The experimental results confirm the sidewall curl angle correction, achieving them with a 22 kJ discharge for DP600 samples and 24 kJ for TRIP700. On the other hand, an uncoupled multiphysical simulation strategy has been carried out in order to virtually validate the EM shape calibration method. The EM fields were simulated by Maxwell 3D and then the Pamstamp code was used to obtain the deformation process.",

keywords = "Electromagnetic forming, High strength steels, Springback calibration",

author = "E. Iriondo and Alcaraz, {J. L.} and Daehn, {G. S.} and Guti{\'e}rrez, {M. A.} and P. Jimbert",

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TY - JOUR

T1 - Shape calibration of high strength metal sheets by electromagnetic forming

AU - Iriondo, E.

AU - Alcaraz, J. L.

AU - Daehn, G. S.

AU - Gutiérrez, M. A.

AU - Jimbert, P.

PY - 2013/4

Y1 - 2013/4

N2 - Electromagnetic (EM) forming is an emerging technique that is gaining acceptance for its complementary benefits to conventional metal forming techniques. In this work an innovative application of this impulse forming technique has been demonstrated: the EM shape calibration and correction of springback (sidewall curl) of DP600 and TRIP700 high strength steel (HSS) workpieces. This method has been applied as a second corrective step to previously deep drawn U-channels. The experimental results confirm the sidewall curl angle correction, achieving them with a 22 kJ discharge for DP600 samples and 24 kJ for TRIP700. On the other hand, an uncoupled multiphysical simulation strategy has been carried out in order to virtually validate the EM shape calibration method. The EM fields were simulated by Maxwell 3D and then the Pamstamp code was used to obtain the deformation process.

AB - Electromagnetic (EM) forming is an emerging technique that is gaining acceptance for its complementary benefits to conventional metal forming techniques. In this work an innovative application of this impulse forming technique has been demonstrated: the EM shape calibration and correction of springback (sidewall curl) of DP600 and TRIP700 high strength steel (HSS) workpieces. This method has been applied as a second corrective step to previously deep drawn U-channels. The experimental results confirm the sidewall curl angle correction, achieving them with a 22 kJ discharge for DP600 samples and 24 kJ for TRIP700. On the other hand, an uncoupled multiphysical simulation strategy has been carried out in order to virtually validate the EM shape calibration method. The EM fields were simulated by Maxwell 3D and then the Pamstamp code was used to obtain the deformation process.

KW - Electromagnetic forming

KW - High strength steels

KW - Springback calibration

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Shape calibration of high strength metal sheets by electromagnetic forming

Abstract

Keywords

UN SDGs

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