Complex investigations of anorthite-containing building ceramics based on clay and metallurgical sludge waste were conducted. Component compositions were selected to obtain ceramic products with anorthite as the predominant phase. The physicomechanical characteristics, phase formation, and morphology of the prepared ceramic samples were investigated. It was determined that the structure of the anorthite phase in the composition of ceramic samples forms at metallurgical sludge waste content ranging from 10 to 50 wt.%. The strength metrics of the ceramic samples increase on account of the prismatic and acicular crystals of the anorthite phase which are uniformly distributed throughout the ceramic body.
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References
R. Li, Y. Zhou, C. Li, et al., “Recycling of industrial waste iron tailings in porous bricks with low thermal conductivity,” Constr. Build. Mater., 213, 43 – 50 (2019).
A. Andrews, G. Amoah, S. Anaman, et al., “Fabrication of lightweight anorthite bodies from lithomargic clay,” Int. J. Appl. Ceram. Tec., 3(3), 609 – 613 (2016).
R. Taurino, A. Karamanov, R. Rosa, et al., “New ceramic materials from MSWI bottom ash obtained by an innovative microwave- assisted sintering process,” J. Eur. Ceram. Soc., 37(1), 323 – 331 (2017).
H. Zouaoui and J. Bouaziz, “Physical and mechanical properties improvement of a porous clay ceramic,” J. Appl. Clay Sci., 150, 131 – 137 (2017).
A. K. Kairakbaev, E. S. Abdrakhimova, and V. Z. Abdrakhimov, “Effect of different coal-enrichment wastes on the physical and mechanical properties and phase composition of heat-insulation materials,” Glass Ceram., 74(1 – 2), 55 – 59 [Steklo Keram., No. 2, 23 – 28 (2017)].
T. G. Cota, E. L. Reis, R. M. F. Lima, et al., “Incorporation of waste from ferromanganese alloy manufacture and soapstone powder in red ceramic production,” J. Appl. Clay Sci., 161, 274 – 281 (2018).
C. Coletti, L. Marita, G. Cultrone, et al., “Use of industrial ceramic sludge in brick production: Effect on aesthetic quality and physical properties,” Constr. Build. Mater., 124, 219 – 227 (2016).
Z. B. Tong, J. T. Sun, J. Wang, et al., “Iron reduction and diopside- based glass ceramic preparation based on mineral carbonation of steel slag,” Environ. Sci. Pollut. Res., 28(1), 796 – 804 (2020).
M. Coronado, T. Blanco, N. Quijorna, et al., “Types of waste, properties and durability of toxic waste-based fired masonry bricks,” in: Eco-Efficient Masonry Bricks and Blocks: Design, Properties and Durability (2015), Vol. 55, pp. 129 – 188.
A. M. Salakhov, G. D. Ashmarin, R. A. Salakhova, and V. P. Morozov, “Ceramic materials made of low-melt clays modified with glass fiber production waste,” Glass Ceram., 71(3 – 4), 77 – 80 (2014) [Steklo Keram., No. 3, 3 – 7 (2014)].
V. A. Sviderskii, S. V. Strashnenko, and L. P. Chernyak, “Ceramics from mining by-products and alumina production wastes,” Glass Ceram., 64(1 – 2), 51 – 54 (2007) [Steklo Keram., No. 2, 17 – 20 (2007)].
L. I. Khudyakova, O. V. Voiloshnikov, and I. Y. Kotova, “Building ceramic from mining wastes,” Glass Ceram., 75(7 – 8), 264 – 267 (2018) [Steklo Keram., No. 7, 19 – 23 (2018)].
H. Tomaszewski, “Effect of the intergranular phase structure on the thermomechanical properties of alumina ceramics,” J. Ceram. Int., 14(2), 93 – 99 (1988).
A. A. Lavrinenko, N. Yu. Svechnikova, N. S. Konovnitsyna, et al., “Using bituminous coal flotation waste in the production of ceramic bricks,” Chem. Solid Fuel, No. 6, 64 – 68 (2018).
A. Mergen and Z. Aslanoglu, “Low-temperature fabrication of anorthite ceramics from kaolinite and calcium carbonate with boron oxide addition,” J. Ceram. Int., Nî. 29, 667 – 70 (2003).
S. Kavalci, E. Yalamac, and S. Akkurt, “Effects of boron addition and intensive grinding on synthesis of anorthite ceramics,” J. Ceram. Int., Nî. 34, 1629 – 1635 (2008).
K. Okada, N. Watanabe, K. V. Jha, et al., “Effects of grinding and firing conditions on CaAl2Si2O8 phase formation by solid-state reaction of kaolinite with CaCO3,” Appl. Clay Sci., 23(5 – 6), 329 – 336 (2003).
A. A. Lavrinenko, N. Yu. Svechnikova, N. S. Konovnitsyna, et al., “Utilization of bituminous coal flotation wastes in the manufacture of ceramic brick,” Solid Fuel Chem., 52(6), 406 – 410 (2018).
V. A. Vlasov, N. K. Skripnikova, M. A. Semenovykh, and, et al., “Ceramic wall materials using technogenic iron-containing raw material,” Stroit. Mater., No. 8, 33 – 37 (2020).
V. A. Vlasov, M. A. Semenovykh, N. K. Skripnikova, and V. V. Shekhovtsov, “Particularities of using unconditioned forms of raw material for obtaining anorthite ceramics,” Vest. Tomsk. Gos. Arkh.-Stroit. Univ., 22(5), 122 – 1288 (2020).
Kamal Tabi, Hanaa Hajjou, Mohamed Waqif, and Latifa Saâdi, “Effect of CaO/SiO2 ratio on phase transformation and properties of anorthite-based ceramics from coal fly ash and steel slag,” J. Ceram. Int., 46(6), 7550 – 7558 (2020).
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Translated from Steklo i Keramika, No. 6, pp. 29 – 35, June, 2021.
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Shekhovtsov, V.V., Skripnikova, N.K., Semenovykh, M.A. et al. Anorthite-Containing Building Ceramic Using Metallurgical Sludge Waste. Glass Ceram 78, 237–241 (2021). https://doi.org/10.1007/s10717-021-00386-w
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DOI: https://doi.org/10.1007/s10717-021-00386-w