Existing ceramic technology is analyzed for producing high-speed zenith guided rocket antenna radomes made of glass ceramic OTM-357. This is the main production operations, and their disadvantages are noted. Prospects are considered for modernizing the technology.
Similar content being viewed by others
References
E. I. Suzdal’tsev, “New direction in the field of synthesizing highly thermal shock resistant radioparent glass ceramic materials,” IFZ, 74, 121 – 130 (2001).
E. I. Suzdal’tsev, M. A. Suslova, V. v. Vikulin, et al., RF Patent 2170715, Method for preparing objects of sintered glass ceramic material of lithium aluminosilicate composition, Claim 07.20.01, Byul. No. 20.
E. I. Suzdal’tsev,, “Synthesis of highly thermal shock resistant radioparent glass ceramic materials and development of manufacturing technology for aircraft radomes based on them,” Dis. Doc. Tech. Sci., Moscow (2002).
Yu. E. Pivinskii and E. I. Suzdal’tsev, (E. Yu. Pivinskii, editor), Quartz Ceramic and Refractories in 2 Vol., Vol. 2, Materials, Their Properties and Fields of Application: Reference edition [in Russian], Teploenergetik, Moscow (2008).
E. I. Suzdal’tsev, “Study of glass ceramic b-spodumene composition preparation with a controlled dielectric permittivity,” Ogneupory Tekhn. Keram., No. 5, 15 – 17 (2002).
E. I. Suzdal’tsev and T. I. Rozhkova, “Materials with controlled dielectric permittivity based on glass ceramic of lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 5, 19 – 21 (2003).
E. I. Suzdal’tsev, T. V. Zaichuk, and T. I. Roshkova,” Use of waste materials in the production of glass ceramic of lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 6, 12 – 17 (2003).
E. I. Suzdal’tsev, “Statistical analysis of the production of glass ceramic object manufacture lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 3, 12 – 18 (2004).
E. I. Suzdal’tsev, “Study of the properties of glass ceramic prepared by aqueous slip casting from glass of lithium aluminosilicate composition,” Proc. Internat. Conf. “Materials and coatings under extreme conditions,” Katsiveli, Crimea, Ukraine (2000).
E. I. Suzdal’tsev and V. I. Kurakin, “Design and theoretical model for forming the wall thickness of a ceramic preform during casting from aqueous slips into a porous mold,” Ogneupory Tekhn. Keram., No. 10, 8 – 11 (2001).
Yu. E. Pivinskii and E. I. Suzdal’tsev, (E. Yu. Pivinskii, editor), Quartz Ceramic and Refractories in 2 Vol., Vol. 1, Theoretical Bases and Production processes: Reference edition [in Russian], Teploenergetik, Moscow (2008).
Yu. E. Pivinskii, Ceramic and Refractory materials [in Russian], Stroizdat, St. Petersburg (2003).
Yu. E. Pivinskii, Theoretical Aspects of Ceramic and Refractory technology [in Russian], Stroizdat, St. Petersburg (2003).
F. Ya. Borodai, M. Yu. Rusin, A. S. Hamistaev, et al., RF Patent 2301212, Method for preparing quartz ceramic objects, Publ. 0.6.20 – 2007.
A. S. Berkman, “Intensification of casting ceramic objects by means of electrophoresis,” Trudy Keram. Inst., No. 20, 6 – 12 (1948).
V. F. Tsarev, “Effect of molding parameters on quartz ceramic properties,” Steklo Keramika., No. 11, 21 – 23 (1979).
V. F. Tsarev, L. S. Koneva, and N. V. Solonin, “Effect of evacuation and pressure on the rate of preform assembly and quartz glass ceramic density,” in: Synthesis, Manufacturing Technology and Test methods for Heat-Resistant Inorganic materials [in Russian], ONTI NITS, Moscow (1975).
A. G. Dobrovol’skii, Slip Casting [in Russian], Metallurgiya, Moscow (1974).
Koiti Nihara and Dzyunit Tatami, “New tendencies in the study and development of engineering ceramics,” Ceramics Japan, 38, No. 4, 301 – 303 (2003).
Wang Sushai, CuiWenliang, Yang Xianfeng, et al., “Forming of large thin-walled fuzed silica shapes by gel casting,” Key Engineering Materials Vols., Nos. 336 – 338, 1005 – 1008 (2007).
Yematsu Keizo, “Forming methods, science and applications,” Ceramics Japan, 40, No. 9, 686 – 702 (2005).
“Preparation of ceramic radomes GD- 1 by gel molding,” Proc. of the 8th DoD Electromag. Windows Symposium (2000).
E. I. Suzdal’tsev, M. Yu. Rusin, D. V. Kharitonov, et al., RF Patent 2222505, Method for preparing objects of sintered glass ceramic materials lithium aluminosilicate composition, Publ. 0.27.04, Byul. No. 3.
E. I. Suzdal’tsev, T. V. Zaichuk, and T. I. Rozhkova, “Use of waste materials in the production of glass ceramic of lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 6, 12 – 17 (2003).
M. Ya. Rusin, and A. G. Romashin, “State and prospects for creating aircraft radomes,” 2nd Internat. Sci. Conf. “Space rocket technology: fundamental and applied problems, Part. 1,” 18 – 21 November 2003.
A. S. Khamistaev, “Analysis of the structure and technological solutions of glass ceramic radomes,” 2nd Internat. Sci. Conf. “Space rocket technology: fundamental and applied problems, Part. 1,” 18 – 21 November 2003.
E. I. Suzdal’tsev, V. V. Vikulin, M. Yu. Rusin, et al., RF Patent 2211810, Method for preparing highly dense aqueous slips based on lithium aluminosilicate glass, Publ. 09.10.2003, Byul. No. 25.
E. I. Suzdal’tsev, “Effect of heat treatment conditions on structure and property formation of glass and glass ceramic of lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 4, 16 – 24 (2002).
E. I. Suzdal’tsev, “Features of structure and property formation for sitall of lithium aluminosilicate composition during heat treatment,” IFZh, 75, No. 2, 125 – 131 (2002).
E. I. Suzdal’tsev and V. N. Kurakin, “Analysis of the effect of synthesis conditions on the properties of glass ceramic materials and construction of a mathematical model for glass and ceramic heat treatment of lithium aluminosilicate composition,” Ogneupory Tekhn. Keram., No. 9, 37 – 41 (2001).
L. K. Bondareva, et al., “Solidification and sintering of glass powders in the system Li2O–Al2O3–SiO2,” Neorgan. Materially, 22, No. 9, 1487 – 1492 (1986).
V. I. Solov’ev, “Role of crystallization catalysts in sitall powder technology,” in: Catalytic Crystallization of Glass: Coll. Works [in Russian], MPSM SSSR, Moscow (1986).
V. A. Leshina and É. P. Dain, “Study of crystallization of chemical charges in the system Li2O–Al2O3–SiO2,” in: Catalytic Crystallization of Glass: Coll. Works [in Russian], MPSM SSSR, Moscow (1986).
V. N. Filipovich, A. N. Kalinina, and D. D. Dmitriev, “Surface growth of crystals as a catalyst for volumetric crystallization glass in sitall powder technology,” [in Russian], MPSM SSSR, Moscow (1986).
V. I. Solov’ev, et al., “Prospects for developing sitall powder technology,” Steklo Keram., No. 3, 12 – 15 (1992).
E. A. Vorob’ev, “Machining of radioparent sharp-pointed aircraft radomes,” Instrument, No. 10, 22 – 23 (1998).
E. M. Maslov, Grinding Theory [in Russian], Mashinostroenie, Moscow (1974).
A. G. Épov, A. G. Ustinov, G. A. Kharakhonov, et al., “Features of internal treatment technology for complex objects RPO-50,” XVII Sci. and Tech. Conf. “Construction and technology for preparing of non-metallic materials,” Proc. 14 – 17 October (2004).
E. I. Suzdal’tsev, T. I. Rozhkova, and T. V. Zaichuk, “Ion exchange strengthening of glass ceramic material of β-spodumene composition,” XVII Sci. and Tech. Conf. “Construction and technology for preparing of non-metallic materials,” Proc. 14 – 17 October (2004).
E. I. Suzdal’tsev, T. I. Rozhkova, T. V. Zaichuk, et al., “Strengthening of glass ceramic material of lithium aluminosilicate composition prepared by ceramic technology,” Ogneupory Tekhn. Keram., No. 5, 18 – 27 (2005).
E. I. Suzdal’tsev, T. I. Rozhkova, T. V. Zaichuk, et al., “Study of the correlation of the surface quality of specimens of β-spodumene ceramic with the degree of strengthening with ion exchange,” Ogneupory Tekhn. Keram., No. 12, 14 – 16 (2005).
E. I. Suzdal’tsev, T. I. Rozhkova, T. V. Zaichuk, et al., “Ion-exchange strengthening of glass ceramic composition and strength degradation under the action of external factors,” XVII Internat. Sci. Tech. Conf., “Construction and technology for preparing objects of non-metallic materials,” Obninsk, 23 – 25 October, 2007.
T. I. Rozhkova, “Study of the process and development of ion-exchange strengthening of radioparent objects based on lithium aluminosilicate composition,” Diss. Cand. Tech. Sci., Moscow (2009).
A. G. Romashin, E. I. Suzdal’tsev, T. I. Rozhkova, et al., RF Patent. 22722004, Method for strengthening objects of glass ceramic materials of β-spodumene composition by ion-exchange, Publ. 0.3.20.06, Byul. No. 8.
E. I. Suzdal’tsev, T. I. Rozkova, T. V. Zaichuk, D. V. Kharitonov, et al., RF Patent 2305078, Device for strengthening objects of glass ceramic materials by ion-exchange, Publ. 08.27.07, Byul. No. 24.
E. I. Suzdal’tsev,, E. I. Rusin, D. V. Kharitonov, et al., RF Patent 2222504, Method for preparing objects of glass ceramic material of lithium aluminosilicate composition, Publ. 01.27.04, Byul. No. 3.
J. D. Walton and N. E. Poulos, “Slip cast metal fiber-reinforced ceramics,” J. Amer. Ceram. Soc., 41, No. 7, 472 – 473 (1962).
J. D. Walton and N. E. Poulos, “Slip cast fuzed silica,” Special Report, Atlanta, Georgia, No. 43, 460 – 463 (1964).
N. A. Toropov, V. P. Barzakovskii, et al., Silicate System Composition Diagrams [in Russian], Nauka, Moscow (1965).
E. I. Suzdal’tsev, “fabrication of high-density quartz ceramics: research and practical aspects. Part 4. Properties of mixed quartz glass slips and preforms prepared by casting into porous molds,” Refractories and Industrial Ceramics, 46, No. 6, 391 – 395 (2005).
Author information
Authors and Affiliations
Additional information
Translated from Novye Ogneupory, No. 9, pp. 34 – 44, September 2010.
Parts 1 – 3 published in Novye Ogneupory, Nos. 6 – 8 (2010).
Rights and permissions
About this article
Cite this article
Suzdal’tsev, E.I., Kharitonov, D.V. & Anashkina, A.A. Analysis of existing radioparent refractory materials, composites and technology for creating high-speed rocket radomes. Part 4. Ceramic technology for producing glass ceramic radomes. Advantages and disadvantages. Prospects for modernization. Refract Ind Ceram 51, 349–357 (2011). https://doi.org/10.1007/s11148-011-9324-y
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11148-011-9324-y