Russian Internet Journal of Industrial Engineering

In domestic practice development of the production technology of rail grinding wheels has outstripped the development of technology for the production of zirconium electrocorundum; the electrocorundum meets the requirements of non-thermal metal treatment. Among the artificial abrasives the leading place belongs to corundum and corundum based alloys (zirconium electrocorundum). At the moment the domestic factories of the abrasive industry are producing zirconium electrocorundum of the pre-eutectic composition (containing about 25% of zirconium dioxide) for rough grinding applied for the rough processing of the rolled products. The zirconium electrocorundum for the final non-thermal metal treatment is not produced by domestic factories; there are no technical requirements for such a material. This work was targeted to develop compositions and parameters for melting of prototypes for the industrial scale production of zirconium electrocorundum with specified and controlled properties. The grain of zirconium electrocorundum in the grinding wheels used in rail grinding trains has specific properties. According to the principles of non-thermal material processing, the structural and phase state of the grinding grain should provide high strength and durability under normal conditions, and at the same time it should tend to shear during the thermal exposure. The design of domestic electrocorundum for rail grinding with properties which are not inferior in comparison with the imported analogues is a strategic issue

Orlova T.N., Dulichenko I.V., Orlov I.Yu. Improving the cutting properties of the abrasive tool for grinding rail rails х Povyshenie rezhushchikh svoystv abrazivnogo instrumenta dlya shlifovaniya zheleznodorozhnykh rel'sov], Cbornik statey mezhdunarodnoy nauchno-tekhnicheskoy konferentsii "Protsessy abrazivnoy obrabotki, abrazivnye instrumenty i materialy" [A collection of articles of the international scientific-technical conference "Abrasive machining processes, abrasive tools and materials"], (Volgograd - Volzhsky, January 1 - December 31, 2011), Volgograd, 2012, pp. 39-42. (in Russ.)

The problems of technospheric safety and ecology were discussed [Obsuzhdeny problemy tekhnosfernoy bezopasnosti i ekologii], Zheleznodorozhnyy transport [Railway Transport], 2014, no.12, pp. 44-46. (in Russ.)

Ilinykh A.S. Shalamova O.A., Yurkova E.O. Improving the Organization of Work on Rail Grinding Based on the Cost of the Rails Vital Cycle [Sovershenstvovanie organizatsii rabot po rel'soshlifovaniyu na osnove otsenki stoimosti zhiznennogo tsikla rel'sov], Vestnik Sibirskogo gosudarstvennogo universiteta putey soobshcheniya [Bulletin of the Siberian State University of Communications], 2018, no.1 (44), pp. 26-32. (in Russ.)

Zubov A.S. Issledovanie i razrabotka protsessa polucheniya abrazivnogo materiala dlya silovogo shlifovaniya na osnove korunda: avtoref. dis. kand. tekhn. nauk [Research and development of the process of obtaining abrasive material for force grinding on the basis of corundum: author. PhD dissertation], Chelyabinsk, 1982, 27 p. (in Russ.)

Mikhailov G.G., Kuznetsov Yu.S., Zubov A.S. et al. Some questions of the theory and practice of production of zirconium electrocorundum [Nekotorye voprosy teorii i praktiki proizvodstva tsirkonievogo elektrokorunda], Cbornik statey "Teoreticheskie i eksperimental'nye issledovaniya abrazivnykh materialov" [A collection of articles "Theoretical and experimental studies of abrasive materials"], Sverdlovsk, USSR Academy of Sciences, Ural Scientific Center, 1982, pp. 54-69. (in Russ.)

Zhekhanova N.B. Requirements for abrasive materials for roughing grinding of zirconium oxide [Trebovaniya k abrazivnym materialam dlya obdirochnogo shlifovaniya iz tsirkonievogo elektrokorunda], Dep. in VNIITEMR, ms. 91, Chelyabinsk, 1991, no.57, 10 p. (in Russ.)

Rowse Robert A., Watson George R. Zirconia-alumina abrasive grain and grinding tools, Patent US 3891408, 1972.

Gallmann Wolfgang, Meltgen Paul. Sposob polucheniya abrazivnogo zerna na osnove tsirkonievogo elektrokorunda [A method of obtaining abrasive grain based on zirconium oxide electrocorundum], Patent RF 2138463, 1994. (in Russ.)

Zubov A.S., Dubynin A.A., Kuznetsov A.V., Filimonov A.L. Tsirkonievyy elektrokorund, sposob ego polucheniya i kristallizator dlya ego polucheniya [Zirconium electrocorundum, method of its production and mold for its production], Patent RF 2144502, 1998, Bull. No.2. (in Russ.)

Chen J.-W., Chiao Y-H. Martensitic nucleation in ZrO2, Actamet, 1983, vol. 31, no.10, pp. 1627-1638. DOI: 10.1016/0001-6160(83)90161-X

Morozova А.G., Chaplygin B.A., Kuzmenko N.G. et al. To the issue of regulation of the structural and phase state of zirconium electrocorundum of eutectic composition [K voprosu regulirovaniya strukturnogo i fazovogo sostoyaniya tsirkonievogo elektrokorunda evtekticheskogo sostava], Cbornik nauchnykh trudov "Abrazivnoe proizvodstvo" [Collection of Scientific Works "Abrasive Production"], Chelyabinsk, SUSU publishing house, 2005, pp. 3-5. (in Russ.)

Udalov Yu.P., Grishchenko D.V., Petrov Yu.B. et al. Monotectic crystallization of melts in the ZrO2-Al 2O3 system, Glass Physics and Chemistry, 2006, vol.32, no.4, pp. 479-485. DOI: 10.1134/S1087659606040122

Taran Yu.N., Mazur V.N. Struktura evtekticheskikh splavov [Structure of eutectic alloys], Moscow, Metallurgy, 1978, 312 p. (in Russ.)

Stryukov D.O. Growing profiled oxide eutectics using the Stepanov method (EFG) [Vyrashchivanie profilirovannykh ok-sidnykh evtektik metodom Stepanova (EFG)], Sbornik materialov XIII Rossiyskoy ezhegodnoy konferentsii molodykh nauchnykh sotrudnikov i aspirantov "Fiziko-khimiya i tekhnologiya neorganicheskikh materialov" [A collection of materials from the XIII Russian annual conference of young researchers and graduate students "Physical chemistry and technology of inorganic materials"], (Moscow, October 18-21, 2016), Moscow, 2016, pp. 216-217. (in Russ.)

Gladkov V.E., Berezin V.M., Zhekhanov N.B. The effect of non-equilibrium crystallization conditions on the volume ratio of the structural components in the alloy of 75 wt.% Al2O3 - 25 wt.% ZrO2 [Vliyanie neravnovesnykh usloviy kristallizatsii na ob''emnoe sootnoshenie strukturnykh so-stavlyayushchikh v splave 75 mas % Al2O3 – 25 mas % ZrO2], Chelyabinskiy fiziko-matematicheskiy zhurnal [Chelyabinsk Physics and Mathematics Journal], 2012, no.31 (285), pp. 34-39. (in Russ.)

Shalamov V.A., Aksenov V.A., Schelokov S.V., Ilinykh A.S. Formation of the quality of the surface layer of the rail based on the optimization of thermal effects during grinding [Formirovanie kachestva poverkhnostnogo sloya rel'sa na osnove optimizatsii teplovogo vozdeystviya pri shlifovanii], Sbornik dokladov VII Vserossiyskoy nauchno-prakticheskoy konferentsii "Progressivnye tekhnologii v transportnykh sistemakh" [A collection of reports of the VII All-Russian Scientific and Practical Conference "Progressive technologies in transport systems"], (Orenburg, 01-02 December 2005), Orenburg, 2005, pp. 373-380. (in Russ.)

Guskov A. Model of directed crystallization of binary alloy, Computational Materials Science, 2000, vol. 17, is. 2-4, pp. 555-559. DOI: 10.1016/S0927-0256(00)00087-2

Morozova A.G., Chaplygin B.A. et al. Sposob polucheniya tsirkonievogo elektrokorunda s vysokim soderzhaniem tetragonal'noy modifikatsii dioksida tsirkoniya [A method of producing zirconium electrocorundum with a high content of tetragonal modification of zirconium dioxide], Patent RF 2317964, 2006, Bull. No.6. (in Russ.)

Kurtman A.V. Khritokhin N.A., Andreev O.V. Rentgenografiya [X-ray], Tyumen, Tyumen State University, 1993, 70 p. (in Russ.)

Anosov V.Ya., Ozerova M.I., Fialkov Yu.A. Osnovy fiziko-khimicheskogo analiza [Fundamentals of physical and chemical analysis], Moscow, Science, 1976, 503 p. (in Russ.)