Processability and cracking behaviour of novel high-alloyed tool steels processed by laser powder bed fusion

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Processability and cracking behaviour of novel high-alloyed tool steels processed by laser powder bed fusion. / Galbusera, Francesco; Demir, Ali Gökhan; Platl, Jan et al.
In: Journal of materials processing technology, Vol. 302.2022, No. April, 117435, 04.2022.

Research output: Contribution to journalArticleResearchpeer-review

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Galbusera F, Demir AG, Platl J, Turk C, Schnitzer R, Previtali B. Processability and cracking behaviour of novel high-alloyed tool steels processed by laser powder bed fusion. Journal of materials processing technology. 2022 Apr;302.2022(April):117435. Epub 2021 Nov 18. doi: 10.1016/j.jmatprotec.2021.117435

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@article{cabf5178b2c94bb39df04793634524df,
title = "Processability and cracking behaviour of novel high-alloyed tool steels processed by laser powder bed fusion",
abstract = "Concerning tooling applications, Laser Powder Bed Fusion (LPBF) enables new features such as internal cooling channels that can be implemented in cutting or shaping tools. Thus, higher cutting speeds are feasible thanks to the more efficient cooling that could not be obtained by channels fabricated with conventional methods. However, the alloys exploited for the cutting tools production usually contain high levels of carbon, which makes their LPBF processability challenging due to their high crack-susceptibility. In this work, an approach based on the use of basic physical/empirical indicators has been employed to map the processability of six novel high-alloyed tool steel grades. A large experimental campaign with variable energy densities, single and double passes, as well as different focal points was designed. The results exhibit highly dense but cracked parts. In particular, the LPBF processability deteriorates with increasing carbon content, suggesting that mostly chemistry, rather than process parameters, plays a key role in the determination of the LPBF feasibility. The cooling rate, cooling time between 800 °C and 500 °C, equivalent carbon content, solidification interval, martensite start temperature and volumetric energy density were employed as indicators to provide a rapid classification of processability. The work demonstrates that the combined use of the indicators can better explain the cracking behaviour of carbon-containing tool steels. At a screening level, this approach based on complementar use of physical/empirical tools, may significantly shorten the experimental effort during the design of new compositions, especially when dealing with crack susceptible alloys like carbon-containing tool steels.",
author = "Francesco Galbusera and Demir, {Ali G{\"o}khan} and Jan Platl and Christoph Turk and Ronald Schnitzer and Barbara Previtali",
note = "Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",
year = "2022",
month = apr,
doi = "10.1016/j.jmatprotec.2021.117435",
language = "English",
volume = "302.2022",
journal = "Journal of materials processing technology",
issn = "0924-0136",
publisher = "Elsevier",
number = "April",

}

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TY - JOUR

T1 - Processability and cracking behaviour of novel high-alloyed tool steels processed by laser powder bed fusion

AU - Galbusera, Francesco

AU - Demir, Ali Gökhan

AU - Platl, Jan

AU - Turk, Christoph

AU - Schnitzer, Ronald

AU - Previtali, Barbara

N1 - Publisher Copyright: © 2021 Elsevier B.V.

PY - 2022/4

Y1 - 2022/4

N2 - Concerning tooling applications, Laser Powder Bed Fusion (LPBF) enables new features such as internal cooling channels that can be implemented in cutting or shaping tools. Thus, higher cutting speeds are feasible thanks to the more efficient cooling that could not be obtained by channels fabricated with conventional methods. However, the alloys exploited for the cutting tools production usually contain high levels of carbon, which makes their LPBF processability challenging due to their high crack-susceptibility. In this work, an approach based on the use of basic physical/empirical indicators has been employed to map the processability of six novel high-alloyed tool steel grades. A large experimental campaign with variable energy densities, single and double passes, as well as different focal points was designed. The results exhibit highly dense but cracked parts. In particular, the LPBF processability deteriorates with increasing carbon content, suggesting that mostly chemistry, rather than process parameters, plays a key role in the determination of the LPBF feasibility. The cooling rate, cooling time between 800 °C and 500 °C, equivalent carbon content, solidification interval, martensite start temperature and volumetric energy density were employed as indicators to provide a rapid classification of processability. The work demonstrates that the combined use of the indicators can better explain the cracking behaviour of carbon-containing tool steels. At a screening level, this approach based on complementar use of physical/empirical tools, may significantly shorten the experimental effort during the design of new compositions, especially when dealing with crack susceptible alloys like carbon-containing tool steels.

AB - Concerning tooling applications, Laser Powder Bed Fusion (LPBF) enables new features such as internal cooling channels that can be implemented in cutting or shaping tools. Thus, higher cutting speeds are feasible thanks to the more efficient cooling that could not be obtained by channels fabricated with conventional methods. However, the alloys exploited for the cutting tools production usually contain high levels of carbon, which makes their LPBF processability challenging due to their high crack-susceptibility. In this work, an approach based on the use of basic physical/empirical indicators has been employed to map the processability of six novel high-alloyed tool steel grades. A large experimental campaign with variable energy densities, single and double passes, as well as different focal points was designed. The results exhibit highly dense but cracked parts. In particular, the LPBF processability deteriorates with increasing carbon content, suggesting that mostly chemistry, rather than process parameters, plays a key role in the determination of the LPBF feasibility. The cooling rate, cooling time between 800 °C and 500 °C, equivalent carbon content, solidification interval, martensite start temperature and volumetric energy density were employed as indicators to provide a rapid classification of processability. The work demonstrates that the combined use of the indicators can better explain the cracking behaviour of carbon-containing tool steels. At a screening level, this approach based on complementar use of physical/empirical tools, may significantly shorten the experimental effort during the design of new compositions, especially when dealing with crack susceptible alloys like carbon-containing tool steels.

UR - http://www.scopus.com/inward/record.url?scp=85120907536&partnerID=8YFLogxK

U2 - 10.1016/j.jmatprotec.2021.117435

DO - 10.1016/j.jmatprotec.2021.117435

M3 - Article

VL - 302.2022

JO - Journal of materials processing technology

JF - Journal of materials processing technology

SN - 0924-0136

IS - April

M1 - 117435

ER -