Experimental investigations of processing the high carbon cold-work tool steel 1.2358 by laser metal deposition for the additive manufacturing of cold forging tools

Hentschel O, Scheitler CJ, Fedorov A, Junker D, Gorunov A, Haimerl A, Merklein M, Schmidt M (2017)

Publication Type: Journal article

Publication year: 2017

Journal

Journal of Laser Applications Laser Institute of America

Book Volume: 29

Article Number: 022307

Journal Issue: 2

DOI: 10.2351/1.4983247

Abstract

In the field of tool making, Laser Beam Melting of metals has been already used to fabricate injection moulds with complex inner cooling channels made out of the low-carbon maraging tool steel X3NiCoMoTi18-9-5 (1.2709). Furthermore, laser metal deposition (LMD) is an established technology for the repair of worn-out tools and the deposition of wear resistance coatings based on metal matrix composites. However, at the moment, the processing of high-carbon tool steels for the additive manufacturing of complete cold forging tools has only been investigated to a limited extent. Within the scope of the presented research, the processing of the high-carbon cold-work tool steel 60CrMoV18-5 (1.2358) by LMD is analyzed in detail. In this context, geometrically simple cuboidal structures are directly generated on dissimilar substrate plates made out of the hot-work tool steel X37CrMoV5-1(1.2343) via the application of various process parameter combinations. The manufactured cuboidal structures are metallographically prepared and subsequently analyzed with respect to substrate bonding, relative density, defect formation, microstructure, chemical composition, and microhardness. In this context, the influence of the particle size distribution of the used tool steel powder on the LMD process itself and the resulting relative density are extensively researched. For this purpose, high-speed camera measurements of the powder particle stream were conducted in order to determine both the powder particle stream diameter and the lateral powder particle distribution with regard to the distance z from the powder nozzle. Furthermore, the influence of an additional substrate preheating (maximum preheating temperature of 400 °C) on the resulting microstructure and hardness of the additively generated samples is the subject of the presented investigations.

Authors with CRIS profile

Oliver Hentschel Lehrstuhl für Photonische Technologien Christian Josef Scheitler Lehrstuhl für Photonische Technologien Aleksandr Fedorov Lehrstuhl für Photonische Technologien Daniel Junker Institute of Manufacturing Technology Marion Merklein Institute of Manufacturing Technology Michael Schmidt Lehrstuhl für Photonische Technologien

Involved external institutions

Kazan National Research Technical University named after A.N. Tupolev RU Russian Federation (RU) Schaeffler Technologies AG & Co. KG DE Germany (DE)

How to cite

APA:

Hentschel, O., Scheitler, C.J., Fedorov, A., Junker, D., Gorunov, A., Haimerl, A.,... Schmidt, M. (2017). Experimental investigations of processing the high carbon cold-work tool steel 1.2358 by laser metal deposition for the additive manufacturing of cold forging tools. Journal of Laser Applications, 29(2). https://doi.org/10.2351/1.4983247

MLA:

Hentschel, Oliver, et al. "Experimental investigations of processing the high carbon cold-work tool steel 1.2358 by laser metal deposition for the additive manufacturing of cold forging tools." Journal of Laser Applications 29.2 (2017).

BibTeX: Download