Combined refractory materials due to their physical and mechanical properties and high stability have been widely used in recent years in metallurgical assemblies with sudden changes in temperature regime, as well as during prolonged downtime or temporary shutdown. Silica refractory can be prepared from clay, chamotte with the addition of silicon production waste (microsilica), as well as with addition of aluminum fluoride production waste (silica gel). In the course of research samples of refractories with different content of modifying additions of technogenic waste in the form of microsilica and silica gel are prepared. The physical and mechanical properties of samples are studied. Examples of using microsilica and silica gel are considered, and based on the results obtained an optimum composition is proposed providing refractory material with high strength and thermal conductivity. Improved properties suggest that microsilica and silica gel may be used as raw materials for the manufacture of combined refractory materials.
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References
K. KJ. Strelov, Theoretical Bases of Refractory Material Technology [in Russian], Metallurgiya, Moscow (1985).
K. K. Strelov, I. D. Kashcheev, and P. S. Mamykin, Refractory Technology. 4th. Ed. [in Russian], Metallurgiya, Moscow (1988).
V. A. Perepelitsyn, F. L. Kapustin, A. A. Ponomarenko, et al., “Secondary mineral resources for refractory manufacture. Part 1. Silica technogenic materials,” Refract. Ind. Ceram., 58(3), 259 – 268 (2017).
R. B. Heimann, Classic and Advanced Ceramics — from Fundamentals to Applications, Wiley VGH, Weinheim (2010).
S. A. Suvorov, V. V. Kozlov, S. N. Bocharov, and N. V. Arbuzova, “Formation of mix texture and material structure of periclase carbonized refractory,” Conf. of Refractory Workers and metallurgist (6 – 7 April, 2017, Moscow), Novye Ogneupory, No. 3, 59 (2017).
Source: http://xn-80aplem.xn-p1ai/analytics/Mirovoj-rynokkremnia.
D. B. Shirinova, “Treatment of aluminum fluoride production waste for useful product,” Nauka Tekhnika Obraz. Olimp. Ivanovo, 107 – 119 (2017).
S. A. Kaprielov, A. V. Sheinfel’d, V. M. Gazizulin, and Yu. N. Voronov, “Effective way of utilizing ultrafine furnace gas cleaning products,” Stal’, No. 5, 83 – 85 (2992).
V. G. Batrakov, S. S. Kaprielov, and A. V. Sheinfel’d, “Efficiency of using ultrafine ferroalloy production waste,” Beton. Zhelez., No. 8, 24 – 25 (1989).
S. S. Kaprielov, A. V. Sheinfel’d, A. I. Tverdostupov, and Yu. F. Telkov, “Use of ferroalloy production waste,” Shakht. Stroit., No. 9, 26 – 28 (1990).
V. Mann, V. Pingin, A. Zherdev, et al., “SPL-recycling and reprocessing,” Light Metals. The Minerals, Metals & Materials Series, 571 – 578 (2017).
N. V. Nemchinova, G. G. Mineev, A. A. Tyutrin, and A. A. Yakovleva, “Utilization of dust from silicon production,” Steel in Translation, 47(12), 763 – 767 (2017).
V. V. Kondrat’ev, N. V. Nemchinova, N. A. Ivanov, et al., “New production solutions processing silicon and aluminum production waste,” Metallurgist, 57(5/6), 455 – 459 (2013).
V. A. Sergeev, Yu. F. Sergeeva, S. V. Mamyachenkov, et al., “Processing of technogenic lead containing intermediates using complexing agent solutions,” Metallurgist, 57, No. 1/2, 80 – 82 (2013).
O. A. Polyakh, V. V. Rudneva, N. F. Yakushevich, et al., “Use of technogenic waste from metallurgical enterprises for producing silicon carbide,” Izv. Vuz. Chern. Met., No. 8, 5 – 12 (2014).
S. T. yagafarova and R. N. Shiryaeva, “Study of the possibility of utilizing production waste as raw material for building materials,” Contemporary Paradigm of natural and Engineering Science: Coll. materials International Sci.-Pract. Conf. (E. P. Tkacheva, editor), Belgorod (2019).
Yu. A. Alekhin, “Overseas experience of using waste in production of materials,” Industrial Building Materials. Series 11, Use of waste, subsidiary products in the Manufacture of Building materials and Objects. Environmental protection: express inform. Domestic experience, VNIIÉSM, Moscow 91987).
R. Stonis, I. Pundiene, V. Antonovich, et al., “Study of the effect of replacing microsilica in heat-resistant concrete with additive based on metakaolin,” Refract. Ind. Ceram., 54(3), 232 – 237 (2013).
D. Munkkhtuvshin, V. B. balabanov, and K. N. Putsenko, “Experience of using micro- and nano-silica additives from silica production waste in concrete technology,” Izv. Vuz. Izvest. Stroit. Nedvizh., 7(3(22)), 107 – 115 (2017).
I. V. Kornienko, L. V. Gorshkova, and G. V. Gakshteter, “Expereince of using metallurgical production waste as a heatresistant concrete component,” Tekhnol. Beton., No. 10, 29 – 33 (2013).
V. Sumitha, P. T. Ravichandran, and K. Divya Krishnan, “Study on behaviour of self-healing concrete using silica gel,” Int. J. Eng. Technol., 7(2.12), 411 – 414 (2018).
V. Yu. Bazhin, M. V. Dvoinikov, M. V. Glaz’ev, and A. A. Kunshin, “Study of the properties of plugging solutions with addition of aluminum fluoride production waste,” Construction of onshore and offshore oil and gas boreholes (I. M. Gubkin RGU Oil and Gas), Moscow 92020).
ASTM C20. Standard Test Methods for Apparent Porosity, Water Absorption, Apparent Specific Gravity and Bulk Modulus of Burned Refractory Brick and Shapes, ASTM International (2010).
ASTM C356-10. Standard Test Method for Linear Shrinkage of Preformed High-Temperature Thermal Insulation Subjected to Soaking Heat, ASTM International (2010).
ASTM C133. Standard Test Methods for Cold Crushing Strength and Modulus of Rupture of Refractories, ASTM International (2015).
M. A. Vartanyan, R. I. Gerasimov, O. V. Pyren’kin, et al., “Study of heat insulation material thermal conductivity by a hot-wire method,” Refract. Ind. Ceram., 57(3), 332 – 333 (2016).
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Translated from Novye Ogneupory, No. 11, pp. 21 – 26, November, 2020.
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Bazhin, V.Y., Glaz’ev, M.V. Combined Refractory Materials with Addition of Technogenic Waste for Metallurgical Assemblies. Refract Ind Ceram 61, 644–648 (2021). https://doi.org/10.1007/s11148-021-00535-2
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DOI: https://doi.org/10.1007/s11148-021-00535-2