ArticleName |
Obtaining of complex-alloyed nickel aluminides and complex ligatures by metal oxides’ metallothermy |
ArticleAuthorData |
Institute of Materials Science of Khabarovsk Science Center of the Far Eastern Branch of Russian Academy of Sciences, Khabarovsk, Russia:
V. V. Gostishchev, Senior Researcher of Laboratory “Engineering and Tool Materials”, e-mail: V-gostishev@mail.ru S. N. Khimukhin, Head of Laboratory “Engineering and Tool Materials”
Pacific National University, Khabarovsk, Russia:
E. D. Kim, Post-Graduate Student E. Kh. Ri, Head of a Chair “Foundry and Metals Technology” |
Abstract |
Modern heat-resistant nickel-aluminum based materials obtain high performance data due to the integrated introduction of alloying elements, including rare earth metals. Our article shows the results of obtaining of multicomponent ligatures and complex-alloyed nickel-aluminum alloys by aluminothermy of initial metal oxides with additives of special ligature containing cerium and lanthanum. Thermodynamic assessment of aluminothermic reactions of reduction of initial metal oxides is given. These reactions have their thermodynamic parameters in an environment favorable for the formation of refractory metal alloys. The melting process temperature enables the secondary production of alloys. Differential thermal analysis investigated the transformations in the aluminothermic systems: NiO – Al, Cr2O3 – Al, МоО3 – Al, WO3 – Al, TiO2 – Al, V2O3 – Al. Reduction of oxides becomes active after aluminum melting at the temperature of ~ 659 oC and proceeds by a heterogeneous mechanism, the beginning of which corresponds to the range of 800–1100 oC. We defined the charge composition, which ensures the maximum release of the metals in alloys (82–93 wt.%). During the alloy production, especially in the case of the synthesis of composite alloy based on the intermetallic system Ni – Al, aluminum excess (relative to the estimated) is introduced into the charge composition. X-ray phase and elemental analyses defined the composition of the obtained alloys. The microstructure was investigated. For example the ligature #1 is shown by several phases with different ratio of aluminium, chromium, molybdenum and tungsten. At the same time, the ligature #2 also contains titanium, vanadium, cerium and lanthanum in the form of reciprocal solid solutions. Aluminide alloys have a compositional structure: nickel-aluminum matrix distributed the inclusions of the alloying elements in solid solutions. Investigations were carried out using the equipment of the Center of Multiple Access “Applied Materials Science” (Pacific National University) with the financial support of the Ministry of Education and Science of the Russian Federation within the state tasks No. 11.7208.2017/7.8 and 11.3014.2017/4.6. |
References |
1. Grinberg B. A., Ivanov M. A. Intermetallides Ni3Al and TiAl: microstructure, deformation behavior. Ekaterinburg : RAN, Uralskoe otdelenie, Inatitut fiziki metallov, 2002. 359 p. 2. Berdovsky N. Y. Intermetallics Research Progress. Nova Science Publishers Release Date. 2008. 290 p. 3. Ferro R., Saccone A. Intermetallic chemistry. Department of Chemistry, University of Genoa, Italy. Ed. Robert W. Cambridge : Cahn FRS Department of Materials Science and Metallurgy, University of Cambridge, 2008. 786 p. 4. Povarova K. B. Physicochemical principles of creating the thermally stable alloys on basis of aluminides of transition metals. Materialovedenie. 2007. No. 12. pp. 20–27. 5. Povarova K. B., Kazanskaya N. K., Drozdov A. A., Bazyleva O. A., Kostina M. V., Antonova A. V., Morozov A. E. Influence of rare-earth metals on the hightemperature strength of Ni3Al-based alloys. Metally. 2011. No. 1. pp. 55–63. 6. Milenkovic S., Schneider A., Frommeyer G. Constitutional and microstructural investigation of the pseudobinary NiAl – W system. Intermetallics. 2011. Vol. 19, No. 3. pp. 342–349. 7. Enayati M. N., Karimzadeh F., Anvari S. Z. Synthesis of nanocrystalline NiAl by mechanical alloying. Journal of Materials Processing Technology. 2008. Vol. 200, No. 1–3. pp. 312–315. 8. Skachkov O. A., Povarova K. B., Drozdov A. A., Morozov A. E. Powder alloys NiAl. II. Compacting of NiAl powders, obtained by various methods. Metally. 2012. No. 3. pp. 88–92. 9. Abuzin Yu. A., Karashaev M. M. Investigation of aluminothermic reactions in powder systems Nb2O5 (WO3; MoO3; Fe2O3; NiO) – Al after mechanical activation. Mezhdunarodnyy nauchno-issledovatelskiy zhurnal. 2016. No. 7-4 (49). pp. 6–9. 10. Slutskiy A. G., Kalinichenko A. S., Sheynert V. A. Investigation of the process of obtaining of molybdenium-bearing ligature by secondary metallurgy. Nauka i tekhnika. 2012. No. 4. pp. 13–16. 11. Parsa M. R., Soltanieh M. On the formation of Al3Ni2 intermetallic compound by aluminothermic reduction of nickel oxide. Materials Characterization. 2011. Vol. 62. pp. 691–696. 12. Ilinykh S. A., Krasikov S. A., Ponomarenko A. A., Sitnikova O. A., Gelchinskiy B. R., Krashanshish V. A. Phase-formation with metallothermic obtaining of Al – Ti – Ni – Mo alloys. Collection of proceedings of the 13-th international scientific-technical conference “Engineering of surface and renovation of products”, 3–7 June 2013. Kiev, 2013. pp. 116–118. 13. Kozlovskiy G. A., Makhov S. V., Moskvitin V. I., Popov D. A. Technical and economic efficiency of production of aluminum master alloys containing Ti, Zr and B from different raw materials. Tsvetnye Metally. 2017. No. 3. pp. 53–56. 14. Perdomo L. et al. Obtención simultánea de ferromanganeso y materiales abrasivos por reducción aluminotérmica usando pirolusita sin tostación previa y residuos sólidos industriales. Minería y Geología. 2015. Vol. 31, No. 2. pp. 95–112. 15. Padhan A. M. Enhanced magnetic properties of NiO powders by the mechanical activation of aluminothermic reduction of NiO prepared by a ball milling process. Journal of Magnetism & Magnetic Materials. 2016. Vol. 418. pp. 253–259. 16. Lyakishev N. P., Pliner Yu. L., Ignatenko G. F., Lappo S. I. Aluminothermy. Moscow : Metallurgiya. 1978. 424 p. 17. Gostishchev V. V., Astapov I. A., Medneva A. V., Ri Khosen, Khimukhin S. N. Fabrication of alloyed aluminum nickelides by metallothermy of metals oxides. Izvestiya vuzov. Tsvetnaya metallurgiya. 2015. No. 6. pp. 63–69. |