Design of Press Tools to Investigate the Hot Stamping Behaviour of Alternative Coatings for Press-Hardened Steel Parts

Damien Close; Peter Feuser; Régis Lallement

doi:10.4028/www.scientific.net/KEM.639.227

Paper Titles

Formability Enhancement in Incremental Forming for an Automotive Aluminium Alloy Using Laser Assisted Incremental Forming
p.195

Local Prevention of Hardening for Punching of Hot-Stamped Parts
p.205

Numerical Analysis and Experimental Validation of the Thermo-Mechanical Flow Behaviour of the Hot Stamping Steel MBW^® 1500
p.213

Tribological Behaviour of Lubricants in Hot Stamping of AA6016
p.221

Design of Press Tools to Investigate the Hot Stamping Behaviour of Alternative Coatings for Press-Hardened Steel Parts
p.227

Investigation of Weld Seam Structures of Tailor Welded Blanks for Hot Stamping
p.235

Improvement of the Ductility of Press-Hardened Plane Sheets through a Modified Heat Treatment
p.243

Experimental Verification of a Benchmark Forming Simulation
p.251

Flexible Rolling of Process Adapted Semi-Finished Parts and its Application in a Sheet-Bulk Metal Forming Process
p.259

HomeKey Engineering MaterialsKey Engineering Materials Vol. 639Design of Press Tools to Investigate the Hot...

Design of Press Tools to Investigate the Hot Stamping Behaviour of Alternative Coatings for Press-Hardened Steel Parts

Abstract:

Due to oxidation and decarburization during heat treatment prior to hot stamping, various coating products have been developed in the last decades. Press-Hardened Steel (PHS) components for passenger cars are generally coated by aluminized or galvanized (GI) coatings. The aluminized coating presents a good formability at high temperature and permits forming and quenching components in the same press tools with a so called direct hot stamping method. Due to a strong cracking in the base material during direct hot stamping induced by liquid-metal embrittlement (LME), galvanized coated products must be pre-formed at low temperature and undergo heat treatment in separate press units. Moreover, the oxide scale formed on GI parts must be removed by abrasive blasting, whereas aluminized parts can be directly painted after hot forming. However, higher performance in corrosion resistance has been observed for galvanized parts, in particular in cosmetic and cut-edge corrosion. This increase is linked to the sacrificial effect or cathodic protection provided by the layer containing zinc. Daimler AG is investigating the possibility of improving performance of PHS body parts in terms of suitability for direct hot stamping and corrosion protection by developing new coating materials. In the following article, the main particularities and challenges involved in both current coating products will be introduced. The development of specific press tools for this study, as well as the corresponding simulation of hot forming will be presented. Finally, the hot forming behaviour and anticorrosive properties of both current products will be presented.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 639)

Pages:

227-234

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.639.227

Citation:

Cite this paper

Online since:

March 2015

Authors:

Damien Close*, Peter Feuser, Régis Lallement

Keywords:

Coating, Hot Stamping, Ultra-High Strength Steel

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Kolleck, R.; Veit, R.; Merklein, M.; Lechler, J.; Geiger, M.: Investigation on induction heating for hot stamping of boron alloyed steels. Annals of the CIRP 58/1/2009, pp.275-278.

DOI: 10.1016/j.cirp.2009.03.090

Google Scholar

[2] Fan, D.W. F; Cooman, B.C.D.: State-of-the-Knowledge on Coating Systems for Hot Stamped Parts. Steel Research Int. 83 (2012) No. 5, pp.412-433.

DOI: 10.1002/srin.201100292

Google Scholar

[3] Merklein, M.; Lechler, J.; Geiger, M.: Characterization of the Flow Properties of the Quenchable Ultra High Strength Steel 22MnB5. Annals of the CIRP 55/1/2006, pp.229-236.

DOI: 10.1016/s0007-8506(07)60404-1

Google Scholar

[4] Hensen, G.; Melfo, W.; Chen, S.; Bleeker, R.; Verloop, W.: Developing Zinc Coated Boron Steel: Balancing Microcrack Performance and Corrosion Protection. Proceedings of 4th International Conference on Hot Sheet Metal Forming of High Performance Steel, Lulea, Sweden, 2013, pp.463-470.

Google Scholar

[5] Singh, J.P.; Hall, J.N.; Coryelle, J. J: Challenges with Zinc-Coated Press Hardened Steel; Proceedings of 4th International Conference on Hot Sheet Metal Forming of High Performance Steel, Lulea, Sweden, 2013, pp.433-444.

Google Scholar

[6] Dosdat, L.; Petitjean, J.; Vietoris, T.; Clauzeau, O.: Corrosion Resistance of Different Metallic Coatings on Press-Hardened Steels for Automotive. Steel Research Int. 82 (2011) No. 6, pp.726-733.

DOI: 10.1002/srin.201000291

Google Scholar

[7] Zhong-Xiang, G.; Kai, Wang.; Yi-Sheng, Z.; Bin, Z.: Cracking and interfacial debonding of the Al-Si coating in hot stamping of pre-coated boron steel. Applied Surface Science 316, 2014, pp.595-603.

DOI: 10.1016/j.apsusc.2014.08.043

Google Scholar

[8] Luckeneder, G.; Autengruber, R.; Stellnberger, K. -H.; Faderl, J.; Kurz, T.: Einflussfaktoren auf die Korrosionsschutzleistung von pressgehärteten Stahlwerkstoffen. ASMET: 3-Länder-Korrosionstagung, Linz, Austria, (2014).

Google Scholar

[9] Close, D.; Lallement, R.; Feuser, P.; Bold, J.: Challenges in Corrosion Protection for Press-Hardened Steels; Tagungsband zum 9. Erlanger Workshop Warmblechumformung, Erlangen, Germany, 2014, pp.31-52.

Google Scholar

[10] Allély, C.; Dosdat, L.; Clauzeau, O.; Ogle, K.; Volovitch, P.; Anticorrosion mechanisms of aluminized steel for hot stamping; Surface & Coatings Technology 238, 2014, pp.188-196.

DOI: 10.1016/j.surfcoat.2013.10.072

Google Scholar