The volume of ceramic paving block used in construction is growing from year to year to improve the resistance to environmental influences and the decorative properties of road pavement as well as modern buildings and structures. It is important to obtain ceramic paving block based on compositions consisting of mineral and technogenic raw materials that prevent premature wear under the influence of a saline environment in regions with heightened salinity. Intensive scientific research is being conducted around the world to develop the production of ceramic paving blocks and other related building materials for regions with high humidity and salinity. Particular attention is paid to improving the firing process for ceramic bodies, the introduction of modifying additives into the composition, and the development of technologies for obtaining new materials with crystalline structures and the formation of their properties.
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References
A. A. Pashchenko, General Technology of Silicates [in Russian], Vysh. Shkola, Kiev (1983).
I. B. Reva, Building Ceramics Based on Compositions of Fusible Clays with Non-Plastic Natural and Technogenic Components, Author’s Abstract of Candidate’s Thesis [in Russian], Tomsk (2005).
V. V. Inchik, Efflorescence and Salt Corrosion of Brick Walls, Author’s Abstract of Doctoral’s Thesis [in Russian], St. Petersburg (2000).
Z. R. Kadyrova, Z. M. Kuryazov, Z. K. Babaev, and D. S. Dzhabberganov, “Anorthite ceramic based on loess loam,” Glass Ceram., 78(7 – 8), 337 – 341 (2021).
V. S. Lesovik, L. Kh. Zagorodnyuk, Z. K. Babaev, and Z. B. Dzhumaniyazov, “Analysis of the causes of brickwork efflorescence in the Aral sea region,” Glass Ceram., 77(7 – 8), 277 – 279 (2020).
Z. K. Babayev, Sh. M. Masharipova, A. A. Musayev, and F. A. Ataeva, “Waste from ceramic bricks, as a raw material for the production of restoration materials,” Int. J. Emerging Trends Eng. Res., 8(8), 4390 – 4393 (2020).
E. V. Mironenko, Physical and Chemical Processes of Efflorescence in Brickwork and Methods for Their Elimination, Author’s Abstract of Candidate’s Thesis [in Russian], Samara (2001).
Yu. V. Ustinova and T. P. Nikiforova, “Salt corrosion of building structures,” Internet-Vest. VolgGASU, Ser. Politekh., No. 2(33), 1 – 14 (2014).
S. V. Fedosov and S. M. Bazanov, Sulfate Corrosion of Concrete [in Russian], ASV, Moscow (2003).
Z. K. Babaev, Sh. M. Masharipova, and J. S. Dzhabberganov, “Products of decomposition and efflorescence in the masonry of architectural monuments of ancient Khiva,” Universum: Tekhn. Nauki, No. 9(66) (2019).
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Translated from Steklo i Keramika, No. 2, pp. 53 – 60, February, 2023
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Lesovik, V.S., Zagorodnyuk, L.K., Babaev, Z.K. et al. Ceramic Road-Brick for Side-Walk Pavement in the Regional Surrounds of the Aral Sea. Glass Ceram 80, 78–82 (2023). https://doi.org/10.1007/s10717-023-00560-2
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DOI: https://doi.org/10.1007/s10717-023-00560-2