Laser Beam Structured Sheets – A New Potential for Sheet Metal Forming

Reimund Neugebauer; Maik Ahnert

doi:10.4028/www.scientific.net/KEM.504-506.119

Paper Titles

Study of True Stress-Strain Curve after Necking for Application in Ductile Fracture Criteria in Tube Hydroforming of Aerospace Material
p.95

Failure Prediction in Sheet Metal Forming Depending in Pre-Straining and Bending Superposition
p.101

A Procedure for the Evaluation of Flow Stress of Sheet Metal by Hydraulic Bulge Test Using Elliptical Dies
p.107

Methodology to Produce Locally Heat-Treated EN AW-5182 Aluminum Alloy Sheet Metal Parts
p.113

Laser Beam Structured Sheets – A New Potential for Sheet Metal Forming
p.119

Elasto-Plastic Models with Continuously Distributed Dislocations and Disclinations
p.125

Failure Evaluation of Spot Welds for Advanced High Strength Steel Sheets
p.131

Processing of New Solar Absorbers in Steel Design Based on Partially Cold Roll Bonded Hybrid Semi-Finished Parts
p.137

Increase the Deformability of NiCo Single Crystals Using of Electrical Pulse-Like Currents
p.143

HomeKey Engineering MaterialsKey Engineering Materials Vols. 504-506Laser Beam Structured Sheets – A New Potential for...

Laser Beam Structured Sheets – A New Potential for Sheet Metal Forming

Abstract:

The increasing requirements of car body manufacturers concerning formability and load of sheet metal structures necessitate new approaches in forming technology. Especially the requirements as regards local loads and local forming behaviour of the components vary significantly. In the field of welding technology there is a verified effect of emerging higher strengths in the welding seam. Using a laser, similar effects can be applied to change the material properties locally. In the current investigation the use of a laser beam allows for creating very small heat-affected areas of a width from 0.5 mm up to 5 mm. These areas are characterised by a significantly higher hardness and strength. Depending on the sheet metal material, areas of higher and lower hardness can be produced. Using laser heat-affected zones in sheet metal makes it possible to increase the drawing depth without necking or cracks. The heat-affected zones increased the stiffness in the critical necking area and hence moved the critical strains to the surrounding area. The required formability was guaranteed by the adjacent areas and the draw depth can be increased.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volumes 504-506)

Pages:

119-124

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.504-506.119

Citation:

Cite this paper

Online since:

February 2012

Authors:

Reimund Neugebauer, Maik Ahnert

Keywords:

Deep-Drawing, Failure Analysis, Laser Hardening, Sheet Metal Forming

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] F. Riedel, K. Wagenknecht, M. Flock, Vergleich, Weiterentwicklung und Anwendungs-potenzial verschiedener modernster Fügeverfahren für die Herstellung von Magnesium-Automobiltüren, Große Schweißtechnische Tagung 2009, Essen 14.-19.09.2009, DVS-Berichte Band 258 (2009) 108-113.

Google Scholar

[2] F.-W. Bach, B.-A. Behrens, T. Plorin, u. a., Verstärkungskonzepte für Blech- und Strukturwerkstoffe, wt Werkstatttechnik online, Band 98 (2008) 837-842.

DOI: 10.37544/1436-4980-2008-10-837

Google Scholar

[3] R. Neugebauer, S. Scheffler, R. Poprawe, u. a., Verbesserung der Umformeigenschaften von schwer umformbaren Werkstoffen durch lokal vorinitialisierten Wärmeeintrag, EFB-Forschungsbericht Nr. 251 (2006).

Google Scholar

[4] M. Ahnert, T. Kühn, A. Jahn, Funktions- und Werkstoffangepasste Laserbehandlung zur Verbesserung der Umformbarkeit und des Verhaltens bei schlagartiger Belastung, Journal of the University of Applied Science Mittweida, Band 5 (2009) 85-88.

Google Scholar

[5] A. Jahn, J. Standfuß, B. Brenner, u. a., Bessere Umformeigenschaften und Belastbarkeit von Karosseriebauteilen durch lokales Laserstrahlverfestigen, Schweißen und Schneiden. 61 (2009), 5, S. 249-253.

Google Scholar