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Ñêà÷àòü ïîëíóþ âåðñèþ ñòàòüè (â PDF ôîðìàòå)
A. I. Kuzmichyov, L. Yu. Tsybulsky, S. O. Maikut, and I. M. Drozd A review of induction-heating facilities’ application to micro- and nanodispersed material technology is presented. The technology is mainly based on the processes of induction evaporation in a gas environment and induction melting of a source material as well as on electromagnetic confinement of a melt. The induction heating is a universal and perspective method. It allows to create the strongly nonequilibrium conditions in the processing chamber and can be used in both laboratory practice and industrial production. Key words: induction heating, induction evaporation, coating on powders, microparticles, nanoparticles, vaporization in gas. https://doi.org/10.15407/nnn.15.01.0141 REFERENCES 1. M. I. Samoilovich, Global’naya Tekhnologicheskaya Revolyuciya ili Nanotekhnologicheskaya Initsiativa [The Global Technological Revolution or Nanotechnological Initiative] http://www.nanostructure.narod.ru/obrazec.htm (in Russian). 2. A. I. Gusev, Nanomaterialy, Nanostruktury, Nanotekhnologii [Nanomaterials, Nanostructures, Nanotechnologies] (Moscow: Fizmatlit: 2005) (in Russian). 3. S. C. Tjong and H. Chen, Mat. Sci. Eng., 45: 1 (2004). https://doi.org/10.1016/j.mser.2004.07.001 4. A. I. Kuzmichev and L. Yu. Tsybulsky, Advances in Induction and Microwave Heating of Mineral and Organic Materials (Ed. S. Grundas) (InTech Publisher: 2011), ch. 13, p. 269. 5. G. I. Babat, Induktsionnyi Nagrev Metallov i Ego Promyshlennoe Primenenie [Induction Heating of Metals and Its Industrial Application] (Moscow-Leningrad: Ehnergiya: 1965) (in Russian). 6. Device for Coating Particulate Material, Pat. 2398517 USA. B22F9/12; B22F9/02; C23C14/22. (Publ. 16.04.1946). 7. An Apparatus for Coating Metal Vaporized Materials, Pat. 3260235 USA, C23C14/24; C23C14/22. (Publ. 12.07.1966). 8. V. I. Petrov and Ye. A. Shafranovskiy, Izvestiya RAN. Ser. Fizicheskaya, 64, No. 8: 1548 (2000) (in Russian). 9. M. Ya. Gen, M. S. Ziskin, and Yu. I. Petrov, Doklady AN SSSR, 127, No. 2: 366 (1959) (in Russian). 10. I. V. Frishberg, L. I. Kvater, B. P. Kuz'min, S. V. Gribovskiy, Gazofaznyi Metod Polucheniya Poroshkov [The Gas-Phase Method for the Fabrication of Powders] (Moscow: Nauka: 1978) (in Russian). 11. G. A. Libenson and V. S. Panov, Oborudovanie Tsekhov Poroshkovoy Metallurgii [Facilities of Powder Metallurgy Shops] (Moscow: Metallurgiya: 1983) (in Russian). 12. V. G. Gopienko, M. E. Smagorinskiy, A. A. Grigoriev, and A. D. Belavin, Spechyonnyye Materialy iz Alyuminievykh Poroshkov [Sintered Materials from Aluminium Powders] (Moscow: Metallurgiya: 1993) (in Russian). 13. Aluminium-Properties and Physical Metallurgy (Metals Park, Ohio: American Society for Metals: 1984). 14. Sposob Polucheniya Aehrozoley Metallov [A Method for Fabrication of Metal Aerosols], Aut. Svid. SSSR 814432 (Publ. 23.03.1981) (in Russian). 15. M. Ya. Gen and A. V. Miller, Poverhnost': Fizika, Khimiya, Mekhanika, 2: 150 (1983) (in Russian). 16. J. Bigot, A. G. Goursat, G. Vernet, J. F. Rimpert, J. Foulard, and T. Sarle, Protsess Proizvodstva Metallicheskikh Poroshkov iz Metallicheskogo Rasplavlennogo Materiala [Procede de Fabrication de Poudres Metalliques a Partip d'Unmaterial Metalliqueen Fusion], Pat. No. 2545394 France (EP 0125161) (11.09.1984) (in French). 17. Ch. Pul and F. Oujenc, Nanotekhnologii [Nanotechnologiesy] (Moscow: Tekhnosfera: 2005) (Russian translation). 18. A. P. Vlasov and K. P. Savinkov, Vysokochastotnaya Metallizatsiya [High-Frequency Metallization] (Moscow: Mashgiz: 1960) (in Russian). 19. J. M. Wentzell, J. Vac. Sci. Technol., 11, No. 6:1035 (1974). https://doi.org/10.1116/1.1318676 20. I. L. Mersie, Production des Poudres Fines par l’Explosion a Pression Atmospherique (La Technique Modern: 1986) (in French). |
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