This article presents the evaluation results on the possibility of the application of electroerosive cobalt–chromium powders for manufacturing products using additive manufacturing. The studies conducted have shown that the use of electroerosive cobalt–chromium alloy powders in additive manufacturing will enable Russian production to avoid purchasing expensive powder materials from other countries.
Similar content being viewed by others
References
A. Safdar, L. Y. Wei, A. Snis, and Z. Lai, “Evaluation of micro- structural development in electron beam melted Ti-6Al-4V,” Mater. Charact., 65, 8–15 (2012).
A. Safdar, H. Z. He, L. Y. Wei, A. Snis, et al., “Effect of process parameters settings and thickness on surface roughness of EBM produced Ti-6Al-4V,” Rapid Prototyp. J., 18, No. 5, 401–408 (2012).
L. Loeber, S. Biamino, U. Ackelid, et al., “Comparison of selective laser and electron beam melted titanium aluminides,” in: Proc. of 22nd Int. Symp. “Solid Free from Fabrication” (University of Texas, Austin. 2011) (2011), pp. 547–556.
S. Biamino, A. Penna, U. Ackelid, et al., “Electron beam melting of Ti–48Al–2Cr–2Nb alloy: microstructure and mechanical properties investigation,” Intermetallics, 19, 776–781 (2011).
D. D. Gu, W. Meiners, K. Wissenbach, and R. Poprawe, “Laser additive manufacturing of metallic components: materials, processes and mechanisms,” Int. Mater. Rev., 57, No. 3, 133–164 (2012).
B. Song, S. Dong, B. Zhang, et al., “Effects of processing parameters on microstructure and mechanical property of selective laser melted Ti6Al4V,” Mater. Des., 35, 120–125 (2012).
B. Song, S. Dong, P. Coddet, et al., “Fabrication and microstructure characterization of selective laser melted FeAl intermetallic parts,” Surf. .Coat. Tech., 206, 4704–4709 (2012).
Z. Wang, K. Guana, and M. Gaoa, “The microstructure and mechanical properties of deposited-IN718 by selective laser melting,” J. Alloys Compd., 513, 518–523 (2012).
A. G. Grigoryants, R. S. Tretyakov, and V. A. Funtikov, “Improving the quality of surface layers of parts obtained by laser additive technology,” Tekhnolog. Mashinostr., No.10, 68–73 (2015).
R. A. Latypov, E. V. Ageev, A. Y. Altukhov, and E. V. Ageeva, “Manufacture of cobalt-chromium powders by the electric discharge dispersion of wastes and their investigation,” Russ. Metallurgy (Metally), 2018, No. 12, 1177–1180 (2018).
E. V. Ageev and R. A. Latypov, “Fabrication and investigation of carbide billets from powders prepared by electroerosive dispersion of tungsten-containing wastes,” Russ. J. Non-Ferr. Metals, 55, No. 6, 577–580 (2014).
E. V. Ageev and R. A. Latypov, “Obtaining and research of hard alloy billets from powders obtained by electro-erosion dispersion of tungsten-containing waste,” Izv. Vyssh. Ucheb. Zav. Tsvetn. Metallurg., No. 5, 50–53 (2014).
M. N. Vulpe, D. N. Kolesnikov, and A. E. Morushkin, “Laser welding of billets obtained by additive technologies,” Tekhnolog. Mashinostr. Materialoved., No. 1, 142–144 (2017).
R. I. Nigmetzyanov, S. K. Sundukov, and D. S. Fatyukhin, “Influence of ultrasonic treatment on the surface roughness of parts obtained by additive technologies,” Fundament. Prikladn. Problemy Tekhn. Tekhnolog., No. 315, 47–53 (2016).
D. M. Chumakov, “Prospects for the use of additive technologies in the creation of aviation and rocket-space technology,” Tr. MAI, No. 78, 31 (2014).
A. G. Grigoryants, D. Yu. Novichenko, and I. Yu. Smurov, “Laser additive technology for the manufacture of coatings and parts from a composite material,” Izv. Vyssh. Ucheb. Zav. Mashinostr., No. 7, 38–46 (2011).
V. N. Leitsin, S. V. Ponomarev, M. A. Dmitrieva, I. V. Ivonin, and I. M. Tyryshkin, “Simulation of the sintering process of products made of low-temperature ceramics formed by additive technologies,” Fizich. Mezomekhan., 19, No. 4, 21–27 (2016).
M. A. Volosova, A. A. Okunkova, S. G. Konov, and D. V. Kotoban, “Additive technologies: from technical creativity to innovative industrial technologies,” Tekhnich, Tvorch. Molodezhi, No. 5 (87), 9–14 (2014).
M. M. Fedorov, “Development of a closed technological chain for the manufacture of gas-turbine engine parts using additive technologies,” Vest. Rybinskoy Gos. Aviatsion. Tekhnol. Akad. im. P. A. Solov’yeva, No. 1 (40), 115–118 (2017).
O. B. Kovalev, “Modeling of processes in technologies of laser additive manufacturing of bulk metal products,” Izv. RAN. Ser. Fizicheskaya, 80, No. 4, 408 (2016).
V. V. Smirnov and E. F. Shaikhutdinova, “The introduction of additive technologies for the manufacture of parts in mass production,” Vest. Kazansk. Gos. Tekhn. Univ. im. A. N. Tupoleva, No. 2–2, 90–94 (2013).
V. V. Smirnov, A. A. Ganeev, and E. F. Shaikhutdinova, “Application of additive technologies for the manufacture of parts from intermetallide titanium-based alloys,” Polzunovsk. Almanah, No. 2, 78–80 (2013).
R. A. Latypov, A. V. Serov, N. V. Serov, and I. Yu. Ignatkin, “Disposal of wastes from mechanical engineering and metallurgy during the strengthening and restoration of machine parts. Part 1,” Metallurg, No. 5. 81–87 (2021).
R. A. Latypov, A. V. Serov, N. V. Serov, and I. Yu. Ignatkin, “Disposal of wastes from mechanical engineering and metallurgy during the strengthening and restoration of machine parts. Part 2,” Metallurg, No. 6, 87–92 (2021).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Metallurg, Vol. 65, No. 12, pp. 61–64, December, 2021. Russian DOI https://doi.org/10.52351/00260827_2021_12_61.
Rights and permissions
About this article
Cite this article
Ageev, E.V., Ageeva, E.V. & Altukhov, A.Y. Evaluation of the Possibility of Application of Electroerosive Cobalt–Chromium Powders for Manufacturing Products via Additive Manufacturing. Metallurgist 65, 1423–1428 (2022). https://doi.org/10.1007/s11015-022-01288-0
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11015-022-01288-0