Influence of Preheating Temperature on Microstructure Evolution and Hardness of High‐Speed Steel AISI M50 Processed by Laser Powder Bed Fusion

Qin, Siyuan; Saewe, Jasmin; Kunz, Johannes; Herzog, Simone; Kaletsch, Anke; Schleifenbaum, Johannes Henrich; Broeckmann, Christoph

doi:10.1002/srin.202200784

Cited by 7 publications

(2 citation statements)

References 28 publications

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“…If soft martensitic steels can be processed into dense samples using the PBF-LB/M process, the AM of carbon martensitic steels is only possible via the design of appropriate alloys [1][2][3][4] or additional measures, such as preheating. [5][6][7] The maximum application temperature of soft-martensitic or C-martensitic hardening tool steels is limited by Ostwald ripening of the corresponding precipitations and recovery and recrystallization of the metal matrix. In addition to precipitationhardening austenites, hard phasecontaining Co-base materials offer a high potential for wear protection applications at higher temperatures.…”

Section: Introductionmentioning

confidence: 99%

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Laser Powder Bed Fusion of Hard‐Phase Containing Co‐Base Alloy

Vehrs,

Röttger,

Roj

et al. 2024

Adv Eng Mater

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This work considers the processing of the hard‐phase containing CoCrW‐alloy Celsit F using powder bed fusion‐laser beam/metal (PBF‐LB/M), whereby a suitable process window for producing dense parts having a low‐defect density is determined. Several cuboid specimens are manufactured by varying the exposure parameters (laser power, hatch distance, scanning speed). With the help of quantitative image analysis, the samples are evaluated regarding crack density and porosity, and optimal exposure parameters are derived. Dense samples with a low defect density can be produced if the energy density is 60–70 J mm−3 and the base‐plate is preheated to 800 °C. Choosing lower energy densities leads to increased pore formation, whereas higher energy densities result in increased ablation and cracking. With a view to a later application in which additively manufactured hot work tools are made of Celsit F, the possibility of introducing internal cavities as potential cooling channels is considered. It can be shown that the hardness sideways is lower than above and below the cavity due to a changed microstructure and locally different heat dissipation. The results of this work give a first guideline for the PBF‐LB/M‐processing of wear‐resistant CoCrW alloys with a high hard phase volume content to tools for hot working.

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Section: Introductionmentioning

confidence: 99%

“…If soft martensitic steels can be processed into dense samples using the PBF‐LB/M process, the AM of carbon martensitic steels is only possible via the design of appropriate alloys [ 1–4 ] or additional measures, such as preheating. [ 5–7 ]…”

Section: Introductionmentioning

confidence: 99%

Laser Powder Bed Fusion of Hard‐Phase Containing Co‐Base Alloy

Vehrs,

Röttger,

Roj

et al. 2024

Adv Eng Mater

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Fracture and Wear Behavior of Functionally Graded 316L–TiC Composite Fabricated by Selective Laser Melting Additive Manufacturing

Yazdani,

Tekeli,

Rabieifar

et al. 2024

steel research int.

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Herein, the tribological and fracture behavior of multilayer 316L–TiC composites produced by the selective laser melting additive manufacturing process is investigated. The results show a robust interface between the layers and no cracks are detected even after a flexural strain of 0.4. The hardness of the composite layers with 5 and 10 wt% TiC increases by 75.5 and 104.8% compared to the hardness of the pure 316L stainless steel layer. Transverse rupture strength measurements show that a layer of pure 316L significantly improves the rupture strength of the multilayer samples. Wear test results show that the inclusion of TiC particles increases wear resistance, with the composite layer containing 10 wt% TiC demonstrating the highest wear resistance.

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