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29.09.2022

Microstructure and Elemental Composition of Powders Obtained Under Conditions of Electroerosive Metallurgy of Heat-Resistant Nickel Alloy ZhS6U Wastes in Water

verfasst von: E. V. Ageev, V. O. Podanov, A. E. Ageeva

Erschienen in: Metallurgist | Ausgabe 5-6/2022

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Abstract

This work is based on experimental studies aimed at examining the microstructure and elemental composition of powders obtained under electroerosive metallurgy conditions of the wastes of the heat-resistant nickel alloy ZhS6U in water. Accordingly, the high efficiency of the use of electroerosive dispersion technology is revealed. This technology ensures the production of spherical powders suitable for practical use at low energy costs. The rapid crystallization process of molten materials under conditions of electroerosive metallurgy of ZhS6U wastes in water contributes in making the particles spherical and elliptical shaped and the appearance of oxygen on its surface with a uniform distribution of Al, Cr, Fe, Co, Ni, Nb, Mo, Ti, and W.

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Literatur
1.
Zurück zum Zitat M. S. Belyaev, L. V. Morozova, M. A. Gorbovets, and A. V. Slavin, “High-cycle fatigue of single-crystal heat-resistant nickel alloy under the conditions of stress concentration,” Metallurgist, 63, No. 11–12, 1237–1247 (2020). M. S. Belyaev, L. V. Morozova, M. A. Gorbovets, and A. V. Slavin, “High-cycle fatigue of single-crystal heat-resistant nickel alloy under the conditions of stress concentration,” Metallurgist, 63, No. 11–12, 1237–1247 (2020).
2.
Zurück zum Zitat V. Ya. Chekhovskoi and V. E. Peletskii, “The thermophysical properties of KhN55VMTKYu nickel-based heat-resistant alloy,” High Temp., 43, No. 1, 51–57 (2005). V. Ya. Chekhovskoi and V. E. Peletskii, “The thermophysical properties of KhN55VMTKYu nickel-based heat-resistant alloy,” High Temp., 43, No. 1, 51–57 (2005).
3.
Zurück zum Zitat A. B. Korostelev, S. N. Zherebtsov, I. P. Sokolov, and D. A. Chumak-Zhun, “Modification of heat-resistant nickel alloy with a combined inoculators,” Metallurgist, 54, No. 9–10, 711–713 (2011).CrossRef A. B. Korostelev, S. N. Zherebtsov, I. P. Sokolov, and D. A. Chumak-Zhun, “Modification of heat-resistant nickel alloy with a combined inoculators,” Metallurgist, 54, No. 9–10, 711–713 (2011).CrossRef
4.
Zurück zum Zitat T. V. Svistunova and G. V. Estulin, “Effect of rare earth metals on the properties of heat-resistant nickel-chrome alloy,” Met. Sci Heat Treat., 3, No. 9–10, 432–434 (1961).CrossRef T. V. Svistunova and G. V. Estulin, “Effect of rare earth metals on the properties of heat-resistant nickel-chrome alloy,” Met. Sci Heat Treat., 3, No. 9–10, 432–434 (1961).CrossRef
5.
Zurück zum Zitat F. A. Baskov, M. Y. Bychkova, Z. A. Sentyurina, I. A. Logachev, and A. I. Logacheva, “Structure and properties of EP741NP heatresistant nickel alloy produced by selective laser melting,” Russ. J. Non-Ferr. Met., 62, No. 3, 302–310 (2021).CrossRef F. A. Baskov, M. Y. Bychkova, Z. A. Sentyurina, I. A. Logachev, and A. I. Logacheva, “Structure and properties of EP741NP heatresistant nickel alloy produced by selective laser melting,” Russ. J. Non-Ferr. Met., 62, No. 3, 302–310 (2021).CrossRef
6.
Zurück zum Zitat E. N. Eremin, Yu. O. Filippov, N. A. Davletkildeev, and G. N. Minnekhanov, “Investigation of the structure of the ZhS6U alloy by atomic force microscopy,” Omsk. Nauch. Vestn., No. 1 (97), 24–29 (2011). E. N. Eremin, Yu. O. Filippov, N. A. Davletkildeev, and G. N. Minnekhanov, “Investigation of the structure of the ZhS6U alloy by atomic force microscopy,” Omsk. Nauch. Vestn., No. 1 (97), 24–29 (2011).
7.
Zurück zum Zitat E. N. Eremin, Yu. O. Filippov, and A. E. Matalasova, “Study of carbide phases in ZhS6U alloy,” Omsk. Nauch. Vestn., No. 3 (133), 59–63 (2014). E. N. Eremin, Yu. O. Filippov, and A. E. Matalasova, “Study of carbide phases in ZhS6U alloy,” Omsk. Nauch. Vestn., No. 3 (133), 59–63 (2014).
8.
Zurück zum Zitat E. N. Eremin, Yu. O. Filippov, G. N. Minnekhanov, and B. E. Lopaev, “Study of phase transformations in ZhS6U alloy by thermal analysis methods,” Omsk. Nauch. Vestn., No. 1 (117), 63–68 (2013). E. N. Eremin, Yu. O. Filippov, G. N. Minnekhanov, and B. E. Lopaev, “Study of phase transformations in ZhS6U alloy by thermal analysis methods,” Omsk. Nauch. Vestn., No. 1 (117), 63–68 (2013).
9.
Zurück zum Zitat O. V. Novikova, V. A. Kochetkov, A. I. Vinogradov, A. A. Zhukov, A. A. Tikhonov, and S.F. Marinin, “The use of gas isostatic pressing to improve the operational reliability of turbine blades made of a ZhS6U-type heat-resistant alloy,” Zagotovit. Proizvod. Mashinostr., No. 8, 54–56 (2007). O. V. Novikova, V. A. Kochetkov, A. I. Vinogradov, A. A. Zhukov, A. A. Tikhonov, and S.F. Marinin, “The use of gas isostatic pressing to improve the operational reliability of turbine blades made of a ZhS6U-type heat-resistant alloy,” Zagotovit. Proizvod. Mashinostr., No. 8, 54–56 (2007).
10.
Zurück zum Zitat E. V. Ageeva, N. M. Khor’yakova, and E. V. Ageev, “Morphology of copper powder produced by electrospark dispersion from waste,” Russ. Eng. Res., 34, No. 11, 694–696 (2014). E. V. Ageeva, N. M. Khor’yakova, and E. V. Ageev, “Morphology of copper powder produced by electrospark dispersion from waste,” Russ. Eng. Res., 34, No. 11, 694–696 (2014).
11.
Zurück zum Zitat E. V. Ageeva, N. M. Khor’yakova, and E. V. Ageev, “Morphology and composition of copper electrospark powder suitable for sintering,” Russ. Eng. Res., 35, No. 1, 33–35 (2015). E. V. Ageeva, N. M. Khor’yakova, and E. V. Ageev, “Morphology and composition of copper electrospark powder suitable for sintering,” Russ. Eng. Res., 35, No. 1, 33–35 (2015).
12.
Zurück zum Zitat R. A. Latypov, E. V. Ageeva, O. V. Kruglyakov, and G. R. Latypova, “Electroerosion micro- and nanopowders for the production of hard alloys,” Russ. Metallurgy (Metally), 2016, No. 6, 547–549 (2016).CrossRef R. A. Latypov, E. V. Ageeva, O. V. Kruglyakov, and G. R. Latypova, “Electroerosion micro- and nanopowders for the production of hard alloys,” Russ. Metallurgy (Metally), 2016, No. 6, 547–549 (2016).CrossRef
13.
Zurück zum Zitat R. A. Latypov, E. V. Ageev, G. R. Latypova, A. Y. Altukhov, and E. V. Ageeva, “Elemental composition of the powder particles produced by electric discharge dispersion of the wastes of a VK8 hard alloy,” Russ. Metallurgy (Metally), 2017, No. 12, 1083–1085 (2017).CrossRef R. A. Latypov, E. V. Ageev, G. R. Latypova, A. Y. Altukhov, and E. V. Ageeva, “Elemental composition of the powder particles produced by electric discharge dispersion of the wastes of a VK8 hard alloy,” Russ. Metallurgy (Metally), 2017, No. 12, 1083–1085 (2017).CrossRef
14.
Zurück zum Zitat 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).CrossRef 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).CrossRef
15.
Zurück zum Zitat R. A. Latypov, E. V. Ageev, A. Y. Altukhov, and E. V. Ageeva, “Effect of temperature on the porosity of the additive products made of the dispersed wastes of cobalt-chromium alloys,” Russ. Metallurgy (Metally), 2019, No. 12, 1300–1303 (2019).CrossRef R. A. Latypov, E. V. Ageev, A. Y. Altukhov, and E. V. Ageeva, “Effect of temperature on the porosity of the additive products made of the dispersed wastes of cobalt-chromium alloys,” Russ. Metallurgy (Metally), 2019, No. 12, 1300–1303 (2019).CrossRef
16.
Zurück zum Zitat R. A. Latypov, A. V. Serov, N. V. Serov, and I. Yu. Ignatkin, “Reclamation of machinery manufacturing and metallurgy waste during hardening and restoration of machine parts. Part 1,” Metallurg, No. 5, 81–87 (2021); Part 2, Metallurg, No. 6, 87–92. R. A. Latypov, A. V. Serov, N. V. Serov, and I. Yu. Ignatkin, “Reclamation of machinery manufacturing and metallurgy waste during hardening and restoration of machine parts. Part 1,” Metallurg, No. 5, 81–87 (2021); Part 2, Metallurg, No. 6, 87–92.
17.
Zurück zum Zitat E. V. Ageev, E. V. Ageeva, and A. Yu. Altukhov, “Additive products from electroerosive cobalt-chromium powder,” Metallurg, No. 10, 78–81 (2021). E. V. Ageev, E. V. Ageeva, and A. Yu. Altukhov, “Additive products from electroerosive cobalt-chromium powder,” Metallurg, No. 10, 78–81 (2021).
18.
Zurück zum Zitat E. V. Ageev, E. V. Ageeva, and A. Yu. Altukhov, “Evaluation of the possibility of using electroerosive cobalt-chromium powders for the manufacturing of products by additive manufacturing,” Metallurg, No. 12, 61–64 (2021). E. V. Ageev, E. V. Ageeva, and A. Yu. Altukhov, “Evaluation of the possibility of using electroerosive cobalt-chromium powders for the manufacturing of products by additive manufacturing,” Metallurg, No. 12, 61–64 (2021).
Metadaten
Titel
Microstructure and Elemental Composition of Powders Obtained Under Conditions of Electroerosive Metallurgy of Heat-Resistant Nickel Alloy ZhS6U Wastes in Water
verfasst von
E. V. Ageev
V. O. Podanov
A. E. Ageeva
Publikationsdatum
29.09.2022
Verlag
Springer US
Erschienen in
Metallurgist / Ausgabe 5-6/2022
Print ISSN: 0026-0894
Elektronische ISSN: 1573-8892
DOI
https://doi.org/10.1007/s11015-022-01362-7

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