Manufacture of multipurpose composite and ceramic materials in the combustion regime and high-temperature deformation (SHS extrusion)

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Merzhanov, A.G. and Rogachev, A.S., Structural macrokinetics of SHS processes, Pure Appl. Chem., 1992, vol. 64, pp. 941–953.

Stolin, A.M., Merzhanov, A.G., Stel’makh, L.S., and Gordopolov, Yu.A., High-temperature rheology of SHS composite materials, Mekh. Kompoz. Mater., 1996, vol. 32, pp. 265–269.

Stolin, A.M. and Merzhanov, A.G., Urgent problems of high-temperature rheodynamics in technology of forced SHS compacting of powder materials, Proc. 15th Riso Int. Symp. on Materials Science, Roskilde, Denmark, 1994, p. 557.

Stolin, A.M., High-temperature rheology and nonequilibrium processes in SHS extrusion, Proc. Int. Seminar on Rheophysics Thermophysics of Nonequilibrium Systems, Minsk, 1991, part 2. p. 11.

Stolin, A.M., Methods and techniques for measuring rheological properties of SHS materials, Int. J. Self-Propag. High-Temp. Synth., 1997, vol. 6, pp. 327–344.

Buchatskii, L.M. and Stolin, A.M., High-temperature rheology of SHS materials, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1120–1129.

Merzhanov, A.G., Borovinskaya, I.P., Ratnikov, V.I., et al., USSR Inventor’s Certificate no. 736541, 1975.

Borovinskaya, I.P., Vishnyakova, G.A., Maslov, V.M., and Merzhanov, A.G., SHS of tantalum nitrides, in Combustion Processes in Chemical Engineering and Metallurgy, Merzhanov, A.G., Ed., Chernogolovka, Moscow oblast: Inst. Chem. Phys, 1975, p. 141.

Merzhanov, A.G., Stolin, A.M., Podlesov, V.V., Buchatskii, L.M., and Shishkina, T.N., Int. Patent Appl. no. PCT/SU 88/00274 1988; Eur. Patent Publ. 90/07015, 1990.

Podlesov, V.V., Buchatskii, L.M., Koshanskii, V.P., and Stolin, A.M., USSR Inventor’s Certificate no. 1223515, 1984.

Merzhanov, A.G., Stolin, A.M., and Podlesov, V.V., Patent WO 89/00342, 1989.

Vedeneev, S.V., Zhilyaeva, N.N., Stel’makh, L.S., and Stolin, A.M., Technological features of the SHS extrusion of a material based on molybdenum disilicide, in Struktura, svoistva i tekhnologiya metallicheskikh system i kermetov (Structure, Properties and Technology of Metal Systems and Cermets), Moscow: MISiS, 1989, pp. 67–77.

Vlasov, V.A., Vedeneev, S.V., Gal’chenko, Yu.A., and Stolin, A.M., Structural changes in articles extruded from an SHS material based on MoSi2 at high temperatures, in Struktura, svoistva i tekhnologiya metallicheskikh sistem i keramik (Structure, Properties and Technology of Metal Systems and Ceramics), Moscow: MISiS, 1988, p. 44.

Stolin, A.M., SHS-extrusion of long components, Int. J. Self-Propag. High-Temp. Synth., 1992, vol. 1, p. 135.

Podlesov, V.V., Radugin, A.V., Stolin, A.M., and Merzhanov, A.G., Technological basis of SHS extrusion, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1065–1074.

Shishkina, T.N., Podlesov, V.V., and Stolin, A.M., Microstructure and properties of extruded SHS materials, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1082–1090.

Podlesov, V.V., Stolin, A.M., and Merzhanov, A.G., SHS extrusion of electrode materials and their application for electric spark steel surface alloying, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1156–1165.

Merzhanov, A.G., Stolin, A.M., Buchatskii, L.M., and Vedeneev, S.V., Patent WO 91/00254, 1991.

Burov, Yu.M., Stolin, A.M., Borovinskaya, I.P., and Merzhanov, A.G., USSR Inventor’s Certificate no. 1688531, 1991.

Inadze, M.V., Podlesov, V.V., and Stolin, A.M., Patent WO 91/09979, 1989.

Levashov, E.A., Merzhanov, A.G., Stolin, A.M., Borovinskaya, I.L., Bogatov, Yu.V., Sheveleva, T.A., Sakovich, G.V., Potapov, M.G., Shalyuta, V.N., Kost, A.G., and Podlesov, V.V., RF Patent 1788061, 1991.

Merzhanov, A.G., Stolin, A.M., Buchatskii, L.M., et al., Eur. Patent. 89910469, 1991.

Borovinskaya, I.P., Ratnikov, V.I., and Vishnyakova, G.A., Some chemical aspects of power SHS compacting, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1059–1064.

Buchatskii, L.M. and Stolin, A.M., Deformation of porous materials under nonisothermal conditions, Plast. Massy, 1991, no. 9, p. 22.

Merzhanov, A.G. and Stolin, A.M., Power SHS compacting and high-temperature rheodynamics, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1057–1058.

Vlasov, V.A. and Stolin, A.M., Thermal treatment of hard alloys based on SHS titanium carbide, Int. J. Self-Propag. High-Temp. Synth., 1994, vol. 3, pp. 343–351.

Shishkina, T.N., Stolin, A.M., and Podlesov, V.V., The influence of SHS production methods used on the material structure formation, Int. J. Self-Propag. High-Temp. Synth., 1995, vol. 4, pp. 35–41.

Stel’makh, L.S. and Stolin, A.M., Methodology of mathematic modeling of the SHS production of articles, Vses. shkola-seminar po avtomatizatsii khimicheskikh issledovanii (Proc. All-Union School-Seminar on Automation of Chemical Research), Tbilisi, 1988, p. 93.

Stelmakh, L.S. and Stolin, A.M., Mathematical modeling of SHS processes, Proc. All-Union School-Seminar on Automation of Chemical Research, Tbilisi, 1988, p. 26.

Stel’makh, L.S., Thermal regimes of the extrusion of rheologically complex refractory compounds, Materialy Mezhd. shkoly-seminara “Teplo- i massoobmen v khimicheski reagiruyushchikh sistemakh” (Proc. Int. Workshop on Heat and Mass Transfer in Reactive Systems), Minsk, 1989, part 2, p. 21.

Zhilyaeva, N.N. and Stel’makh, L.S., Thermal regimes of SHS compacting, Teploi massoobmen v khimicheski reagiruyushchikh sistemakh: Materialy Mezhd. shkolyseminara (Proc. Int. Workshop on Heat and Mass Transfer in Reactive Systems), Minsk, 1989, part 2, p. 44.

Stel’makh, L.S., Stolin, A.M., and Merzhanov, A.G., Mathematical modelling of SHS extrusion. I. Thermal models, J. Eng. Phys. Thermophys., 1993, vol. 65, pp. 690–695.

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Stel’makh, L.S., Zhilyaeva, N.N., and Stolin, A.M., Nonisothermal rheodynamics in SHS pressing of powder materials, J. Eng. Phys. Thermophys., 1991, vol. 61, pp. 831–833.

Stel’makh, L.S. and Stolin, A.M., Quasi-steady-state regime and the limiting cases of the hot extrusion of powder materials, Dokl. Akad. Nauk, 1992, vol. 322, pp. 732–736.

Stel’makh, L.S., Zhilyaeva, N.N., and Stolin, A.M., Rheodynamics and heat exchange of powder material hot compacting, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1136–1144.

Stel’makh, L.S., Zhilyaeva, N.N., and Stolin, A.M., Mathematical modeling of SHS compacting thermal regimes, J. Eng. Phys. Thermophys., 1992, vol. 63, pp. 1145–1150.

Stel’makh, L.S. and Stolin, A.M., Mathematical simulation of SHS extrusion. II. Rheodynamic models, J. Eng. Phys. Thermophys., 1993, vol. 65, pp. 696–699.

Stel’makh, L.S., Stolin, A.M., and Merzhanov, A.G., Macrorheological theory of SHS compaction, Doklady Akad. Nauk, 1995, vol. 344, pp. 72–77.

Stelmakh, L.S., Zinenko, Zh.A., Stolin, A.M., and Merzhanov, A.G., The peculiarities of densification of SHS materials with competition interaction between hydrodynamic and thermal factors, Proc. 3rd Int. Symp. on Self-Propagating High-Temperature Synthesis (SHS-95), Wuhan, China, 1995, p. 36.

Stelmakh, L.S. and Stolin, A.M., Macrorheological theory of hot compaction of composites, Mech. Compos. Mater., 1995, vol. 31, pp. 598–602.

Stolin, A.M., Stelmakh, L.S., Zhilyaeva, N.N., and Khusid, B.M., The phenomenological theory of high-temperature deformation of self-propagating high-temperature synthesis (SHS) products, J. Mater. Synth. Process., 1995, vol. 3, pp. 19–23.

Vedeneev, S.V., Zhilyaeva, N.N., Stel’makh, L.S., and Stolin, A.M., Technological regimes of extrusion of high-temperature heating elements based on MoSi2, in Silitsidy i ikh primenenie v tekhnike (Silicides and Their Technical Applications), Kiev: IPM, 1990, p. 59.

Stel’makh, L.S., Stolin, A.M., Baronin, G.S., and Loseva, A.S., Mathematical simulation of solid-phase extrusion of composite materials, Vestn. Tambov. Gos. Tekh. Univ., 2009, vol. 15, p. 127–136.

Stolin, A.M., Stel’makh, L.S., and Zhilyaeva, N.N., An analytical model of the stress state of an axisymmetric elastic body under conditions of a two-dimensional temperature field, J. Eng. Phys. Thermophys., 1989, vol. 56, pp. 472–477.

Stel’makh, L.S. and Stolin, A.M., Thermoelastic stresses in a finite cylinder in the case of two-dimensional temperature field, J. Eng. Phys. Thermophys., 1989, vol. 56, pp. 695–702.

Stel’makh, L.S., Stolin, A.M., Polyakov, B.B., and Dvoretskii, D.S., Methodology of thermal design of mold equipment for SHS compacting and development of processing regimes, in Entsiklopediya inzhenerakhimika (Chemical Engineer’s Encyclopedia), 2009, no. 12, pp. 16–26.

Stel’makh, L.S., Stolin, A.M., Polyakov, B.B., and Dvoretskii, D.S., Thermal design of mold equipment for SHS compacting and optimization of processing regimes, Inzh. Fiz., 2010, no. 1, pp. 25–33.

Stelmakh, L.S., Stolin, A.M., and Dvoretskii, D.S., Nonisothermal method for calculating the mold equipment of an apparatus for compacting the hot products of self-propagating high-temperature synthesis, Theor. Found. Chem. Eng., 2010, vol. 44, pp. 192–200.

Stel’makh, L.S., Stolin, A.M., and Parshin, D.A., Specific features of SHS compacting with the use of nanomaterials as a metallic binder, Inzh. Fiz., 2010, no. 7, pp. 30–36.

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Belyaeva, N.A., Stolin, A.M., and Stelmakh, L.S., Dynamic of solid-state extrusion of viscoelastic cross-linked polymeric materials, Theor. Found. Chem. Eng., 2008, vol. 42, pp. 565–574.

Belyaeva, N.A., Stolin, A.M., and Stel’makh, L.S., Dynamics of solid-state extrusion of viscoelastic cross-linked polymeric materials, Teor. Osn. Khim. Tekhnol., 2008, vol. 42, p. 579.

Belyaeva, N.A., Stolin, A.M., Pugachev, D.V., and Stel’makh, L.S., Unstable modes of deformation in solid-phase extrusion of viscoelastic structured systems, Dokl. Phys. Chem., 2008, vol. 42, pp. 144–147.

Belyaeva, N.A., Stolin, A.M., and Stel’makh, L.S., Kinetics of compacting and structuring in the solidphase extrusion of a viscoelastic medium, Inzh. Fiz., 2007, No. 5, pp. 34–41.

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Stolin, A.M., Kozlov, V.V., and Kalugin, A.V., Method of mould free SHS compaction and measurement of formation performance data, Proc. 5th Int. Symp. on Self-Propagating High-Temperature Synthesis (SHS-99), Moscow, 1999, p. 116.

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Stolin, A.M. and Stel’makh, L.S., On the role of deformation factors in the combustion of porous powder materials, J. Non-Ferrous Met., 2007, vol. 48, pp. 76–80.

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Stel’makh, L.S. and Stolin, A.M., Mathematical modeling of the SHS technology, in Kontseptsiya razvitiya SVS kak oblasti nauchno-tekhnicheskogo progressa (Conception of SHS Development as an Area of Scientific and Technological Progress), Merzhanov, A.G., Ed., Chernogolovka, Moscow oblast: Territoriya, 2003.

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