Russian Internet Journal of Industrial Engineering

The overview of existing models for iron oxides reducing and an analysis of their applicability to technogenic formations is presented.  The thermodynamic analysis data of iron oxides reducing reactions through solid and gas phases and experiment results presenting features of technogenic iron oxide reducing under conditions of solid-phase diffusion (limited diffusion) and partially liquid-phase diffusion (easier diffusion) of iron oxide ions. It is shown that under conditions of iron oxide ions solid-phase diffusion the reduction processes rate is significantly affected by the briquettingpressure, which increases the contact area of reacting substances. The briquetting pressure does not affect the reduction processesrate under conditions of partially liquid-phase diffusionof iron oxide ions. An ion-diffusion catalytic mechanism is proposed to describe the observed effects of technogenic iron oxide reducing

Rodzevich A.P. Fiziko-khimicheskie osnovy metallur-gicheskikh protsessov: uchebnoe posobie [Physical and Chemical Bases of Metallurgical Processes: educational textbook], Tomsk, 2010, 298 p. (in Russ.)

Gerasimenko A.A. Zashchita ot korrozii, stareniya i biopovrezhdeniy mashin, oborudovaniya i sooruzheniy: spravochnik [Protection Against Corrosion Aging and Bio-Damage of Machinery, Equipment And Structures], Moscow, Mashinostroenie, 1987, 668 p. (in Russ.)

Gorshkov V.S. Physical Chemistry of Silicates and Other Refractory Compound/ V.S. Gorshkov, V. G. Saveliev. N. F. Fedorov. - Moscow: Higher school (Educational Textbook), 1988. – 400 p. (in Russ.)

Gruner L. Etudes sur les hauts-formeause, Annales des Mines, 1872, pp. 1-14.

Rostovtsev S.T., Simonov V.K. et al. Mechanism of carbon-thermal reduction of metal oxides [Mekhanizm ugletermicheskogo vosstanovleniya okislov metallov], Mekhanizm i kinetika vosstanovleniya metallov: Sb. nauch. tr. [Mechanism and kinetics of metal reduction], Moscow, Science, 1970, pp 24-31. (in Russ.)

Senin A.V., Pashkeevd I.Y., Mikhalov G.G. Gas -phase-solid-phase mechanism for recovery of ore materials [Gazofazno-tverdofaznyy mekhanizm vosstanovleniya rudnykh materialov], Ferrosplavy: Trudy nauchno-prakticheskoy konferentsii [Prospects for the development of metallurgy and mechanical engineering using completed basic research and R&D: Ferroalloys Conf. Proc.], Ekaterinburg, 2018, pp. 72-80. (in Russ.)

Tleugabulov S.M., Abikov S.B. Fundamentals and prospects for the development of reduction steel melting [Osnovy i perspektivy razvitiya vosstanovitel'noy plavki stali], Metally [Metals], 2018, no.2, pp. 72-77. (in Russ.)

Averin V.V., Korneev V.P., Dybanov V.G. Solid-phase reduction of electrofurnace slurry by carbon, Steel in Translation, 2010, vol. 40, no. 9, pp. 792-795. DOI: 10.3103/s0967091210090020

Popel S.I., Sotnikov A.I., Boronenkov V.N. Teoriya metallurgicheskikh protsessov: uchebnoe posobie dlya vuzov [Theory of Metallurgical Processes: educational textbook for universities], Moscow, Metallurgy, 1986, 463 p. (in Russ.)

Chufarov G.I., Men A.N., Balakirev V.F. Termodinamika protsessov vosstanovleniya okislov metallov [Thermodynamics of Metal Oxide Reduction Processes], Moscow, Metallurgy, 1970, 400 p. (in Russ.)

Roshchin V.E., Roshchin A.V. Electronic processes during metals recovery and extracting from ores [lektronnye protsessy pri vosstanovlenii i izvlechenii metallov iz rud], Elektrometallurgiya [Electrometallurgy], 2020, no.3, pp. 14-24. (in Russ.)

Baikov A.A. Sobranie izbrannykh trudov [Collection of selected works. In 2 books. Book 2], Moscow-Leningrad, AS USSR, 1948, 500 p. (in Russ.)

Komatsu W. Role of contacts in solid state reactions, Reactivity of Solids: Proc. 5th Int. Symp. on Reactivity of Solids (Munich, 1963), Amsterdam, Elsevier, 1964, 576 p.

Levitas V.I. Continuum mechanical fundamentals of mechanochemistry, High Pressure Surface Science and Engineering. Section 3, Bristol, Institute of Physics Publishing, 2004, pp. 159-292. DOI: 10.1201/9780429144097-6

Drickamer H.G., Frank C.W. Electronic Transitions and the High Pressure Chemistry and Physics of Solids, London, 1973.

Roshchin V.E., Roshchin A.V. Electron Mechanism of Reduction Process in Blast and Ferroalloy Furnaces, CIS Iron and Steel Review, 2019, vol.17, pp. 14-24. DOI: 10.17580/cisisr.2019.01.03

Roshchin V.E., Roshchin A.V. Physics of the solid-phase oxidation and reduction of metals, Russ. Metall., 2015, 2015, pp. 354-359. DOI: 10.1134/s0036029515050146

Roshchin V.E., Gamov P.A., Roshchin A.V., Salikhov S.P. The electronic theory of reduction and the extraction of metals from ore, Steel in Translation, 2019, vol. 49, no.5, pp. 319–327. DOI: 10.3103/s0967091219050127

Roshchin V.E., Gamov P.A., Roshchin A.V., Bilgenov A.S. Electron and Mass Transfer during Solid Carbon Reduction of Metals in Solid Complex Oxides, Russ. Metall., 2020, 2020, pp. 50-59. DOI: 10.1134/S0036029520010103

Roshchin V.E., Roshchin A.V., Berdnikov A.A., Goykhenberg Yu.N. Formation and sublimation of intermediate products of the reduction of silicon from its dioxide [Obrazovanie i sublimatsiya promezhutochnykh produktov vosstanovleniya kremniya iz ego dioksida], Metally [Metals], 2008, no.4, pp. 14-28. (in Russ.)