Compositions prepared on the basis of fine corundum and aluminophosphate binders modified with B3+, Cr3+, Mo6+, and Zr4+ ions are considered. The influence of the ions listed on thermophysical properties of aluminophosphate compositions is studied. Results of comparative tests for the composites obtained in an arc plasmatron flow with estimation of surface melting temperature of the specimens are presented. Results of moisture adsorption studies of the composites with various relative humidity are shown.
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References
A. S. Wagh, Chemically Bonded Phosphate Ceramics: Twenty-First Century Materials with Diverse Applications, Elsevier, USA (2016).
S. L. Golynko-Voll’fson, M. M. Sychev, L. G. Sudakas, and L. I. Skobko, Chemical Bases of Phosphate Binder and Coating Technology and Application [in Russian], Khimiya, Leningrad (1968).
M. M. Sychev, Inorganic Adhesives, 2nd. Ed [in Russian], Khimiya, Leningrad (1986).
L. G. Sudakas, Phosphate Binder Systems [in Russian], Kvintet, St. Petersburg (2008).
Ch. G. Pak, V. A. Abysov, and V. A. Batrashov, “Heat-resistant phosphate cellular materials of variable density,” Vestn. YuUrGU Stroit, Arkhit, No. 15, 4 – 5 (2010).
V. A. Abysov nd Ch. G. Pak, and P. I. Serov, “Heat-resistant heat insulation materials based on refractory fibers, phosphate and magnesia binders,” Proc. Internat. Conf. of Refractory Workers and Metallurgists, Moscow 7 – 8 April 2016, Novye Ogneupory, No. 3, 45 (2016).
O. Yu. Tikhonenko, V. A. D’yakonov, N. V. Nefedova, and A. A. Stepko, “Study of synthesis process for modified pheophate binders ad refractory composites based upon them,” Uspekhi Khim. Khim. Tekhnol., 33(8), 42 – 44 (218) (2019).
O. Yu. Tikhonenko, V. A. D’yakonov, N. V. Nefedova, and A. A. Stepko, ““Study of synthesis process for modified phosphate binders ad refractory composites based upon them,” Uspekhi Khim. Khim. Tekhnol., 34(7), 94 – 96 (2020).
H. A. Colorado, Z.Wang, and J.-M. Yang, “Inorganic phosphate cement fabricated with wollastonite, barium titanate and phosphoric acid,” Cement & Concrete Composites, No. 62, 13 – 21 (2015).
M.Wang, Z. Liang, S. Yan, et al., “The preparation and property analysis of B4C modified inorganic amorphous aluminum phosphates-based intumescent flame retardant coating,” Construction and Building Materials, 359, Article No. 129480 (2022).
Y. Chen, X. Wang, C. Yu, et al., “Properties of inorganic high-temperature adhesive for high-temperature furnace connection,” Ceram. Int., 45(7), part A, 8684 – 8689 (2019).
X.-W. Wu, Z.-B. Li, C.-Q. Shi, et al., “High thermal resistant fireproof and waterproof aluminum dihydrogen phosphate-expanded perlite composite thermal insulation board,” Environmental Progress & Sustainable Energy, 37(4), 1319 – 1326 (2017).
V. Z. Abdrakhimov, I, Yu. Roshchupkina, E. S. Adrakhimova, et al., “Heat-resistant composite based upon phosphate binders and high-alumina waste,” Izv, Vuzov. Stroit, No. 8, 33 – 40 (2015)
A. I. Khlystov, S. V. Sokolova, M. V. Konnov, et al., “synthesis of phosphate binders based upon mineral slurry waste,” Ogenupory Tekhn. Keram., No. 7/8, 77 – 80 (2013).
GOST 28818. Electrocorundum grinding materials. Technical specifications, Izd. Standartov, Moscow (2004).
V. V. Pechkovskii, R. Ya. Mel’nikova, E. D. Dzyuba, et al., Infrared Spectra Atlas of Phosphates, Orthophosphates [in Russian], Nauka, Moscow (1981).
R. Ya. Mel’nikova, V. V. Pechkovski, E. D. Dzhuba, and I. E. Malashonok, Atlas of Infrared Spectra of Phosphates. Condensed Phosphates [in Russian], Moscow (1985).
A. I. Orlova, S. G. samoilov, G. N. Kzantsev, et al., “Study of zirconium phosphate Zr3(PO4)4 on heating,” Kristallografiya, 54(3), 464 – 471 (2009).
O. Yu. Tikhonenko, V. A. D’yakonov, N. V. Nefedova, and A. A. Stepko, “Effect of zirconium phosphate Zrn(PO4)m synthesis conditions on phosphate refractory properties,” Uspekhi Khim. Khim. Tekhnol., 35(6), 115 – 117 (2021).
Yu. V. Polezhaev, Heat Protection, A. V. Lykov, editor [in Russian], Énergiya, Moscow (1976).
V. A. Dyakonov, A. D. Kamalov, and B. F. Pronin, “Study of dielectric properties of silica materials under increased moisture conditions,” Konst. Komp. Materialov., No. 3(147), 48 – 52 (2017).
GOST 29244–91. Small containers for conditioning and testing using aqueous solutions for maintenance of constant relative moisture values, Idz. Standartov, Moscow (2004).
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Translated from Novye Ogneupory, No. 3, pp. 48 – 54, March, 2023.
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Tikhonenko, O.Y., D’yakonov, V.A. Research and Comparative Analysis of Refractory Compositions Based on Modified Aluminophosphate Binders. Refract Ind Ceram 64, 152–158 (2023). https://doi.org/10.1007/s11148-023-00818-w
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DOI: https://doi.org/10.1007/s11148-023-00818-w