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Literature cited
V. V. Kovriga, E. S. Osipova, I. I. Farberova, and K. Ya. Artanova, “Temperature-time superposition as applied to the relaxation properties of fiberglass and its binder,” Mekh. Polira., No. 2, 360–363 (1972).
V. S. Ekel'chik, S. N. Kostritskii, and M. Z. Tsirkin, “Temperature-time relationship for the strength and deformability of fiberglasses in the transversal direction,” in: First All-Union Conference on Composition Polymer Materials and Their Application in the National Economy. Theses of Papers [in Russian], Vol. 2, Tashkent (1980), p. 51.
R. D. Maksimov, Ch. L. Daugste, and E. A. Sokolov, “Characteristic features of the observance of the temperature-time analogy during the physically nonlinear creep of a polymer material,” Mekh. Polim., No. 3, 415–426 (1974).
Yu. S. Urzhumtsev and R. D. Maksimov, Predicting the Deformability of Polymer Materials [in Russian], Riga (1975).
Yu. S. Pervushin, V. P. Pavlov, and V. V. Zainullin, “On the application of the temperature-time analogy to computation of creep strains in fiberglasses in a nonsteady temperature field,” Probl. Prochn., No. 7, 27–29 (1976).
R. Sheperi, “Viscoelastic behavior of composition materials,” in: Composition Materials. Vol. 2. Mechanics of Composition Materials [in Russian], Moscow (1978), pp. 102–195.
W. J. Griffith, D. H. Morse, and H. F. Brinson, “Accelerated characterization of graphite/epoxy composites,” Advances in Composite Materials. Proceedings of the Third International Conference on Composition Materials, Vol. 1, Paris (1980), pp. 461–471.
H. T. Hahn and T. T. Chiao, “Long-term behavior of composite materials,” Advances in Composite Materials. Proceedings of the Third International Conference on Composition Materials, Vol. 1, Paris (1980), pp. 584–596.
V. V. Moskvitin, Strength of Viscoelastic Materials [in Russian], Moscow (1972).
Yu. N. Rabotnov, Elements of the Hereditary Mechanics of Solids [in Russian], Moscow (1976).
A. F. Kregers, “An algorithm for determination of the parameters of the resolvent (kernel) of one-dimensional linear v.iscoelasticity from given parameters of the kernel (resolvent) represented by the sum of the, exponents., “ Algoritmy Programmy, No. 1, 27 (1975).
E. A. Sokolov and R. D. Maksimov, “Possibility of predicting the creep of a polymer-fiberreinforced plastic from component properties,” Mekh. Polim., No. 6, 1005–1012 (1978).
Yu. V. Suvorova, I. V. Viktorova, and G. P. Mashinskaya, “Long-term strength and failure of organoplastics,” Mekh. Kompozitn, Mater., No. 6, 1010–1013 (1980).
G. M. Gunyaev, Structure and Properties of Fibrous Polymer Composites [in Russian], Moscow (1981).
V. N. Efimova and R. D. Maksimov, “Comparative analysis of the temperature-time relationship between the deformation properties of polyvinyl chloride in the linear and nonlinear regions of viscoelasticity,” Mekh. Polim., No. 2, 213–219 (1977).
É. Z. Plume, “An algorithm for confirming the observance of the temperature-time analogy in temperature-time relationships of the deformation and strength properties of polymers,” Algoritmy Programmy, No. 2, 34 (1978).
A. F. Kregers, “An algorithm for searching the minimum of a multiple-variable function by the descent method,” Algoritmy Programmy, No. 2, 9 (1974).
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Translated from Mekhanika Kompozitnykh Materialov, No. 6, pp. 1081–1089, November–December, 1982.
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Maksimov, R.D., Plume, É.Z. Predicting the creep of unidirectional reinforced plastic with thermorheologically simple structural components. Mech Compos Mater 18, 737–744 (1983). https://doi.org/10.1007/BF00604160
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DOI: https://doi.org/10.1007/BF00604160