Short-term creep and strength of fibrous polypropylene structures
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Abstract
The short-term creep and strength of fibrous polypropylene structures are investigated. On the basis of these characteristics, we develop the models of linear and nonlinear viscoelastic deformation of materials, specify the fields of their applicability, and study criteria used for the evaluation of the static strength and durability of these composites.
Keywords
short-term creep static strength durability fibrous structures models of viscoelastic deformation of materials equations of statePreview
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References
- 1.M. N. Belitsin, Synthetic Threads (Structure, Properties, and Computational Methods) [in Russian], Izd. Legkaya Industriya, Moscow (1970).Google Scholar
- 2.W. E. Morton and J. W. S. Hearle, Physical Properties of Textile Fibres, Textile Institute, Butterworths, Manhester-London (1962).Google Scholar
- 3.A. V. Matukonis, Structure and Mechanical Properties of Inhomogeneous Threads [in Russian], Izd. Legkaya Industriya, Moscow (1971).Google Scholar
- 4.N. I. Kudryashova and B. A. Kudryashov, High-Speed Tension of Textile Materials [in Russian], Izd. Legkaya Industriya, Moscow (1974).Google Scholar
- 5.A. N. Solov’ev and G. N. Kukin, “Properties of chemical fibers and threads,” in: Properties and Specific Features of the Procedures of Treatment of Chemical Fibers [in Russian], Khimiya, Moscow (1975), pp. 401–486.Google Scholar
- 6.R. F. Zimialis, Mechanical Properties of Chemical Threads in High-Speed Tests and Prediction of the Quality of Textile Materials [in Russian], Author’s Abstract of the Doctor Degree Thesis (Tech. Sci.), Kaunas (1984).Google Scholar
- 7.J. W. S. Hearle, “Mechanics of threads and nonwoven fabric,” in: T.-W. Chou and F. K. Ko (Eds.), Textile Structural Composites, Elsevier, Amsterdam-Oxford-New York-Tokyo (1989), pp. 46–89.Google Scholar
- 8.GOST 25552-82. Twisted and Woven Articles. Testing Methods [in Russian], Introduced on 24.12.1982.Google Scholar
- 9.Yu. N. Rabotnov, Elements of the Hereditary Mechanics of Solid Bodies [in Russian], Nauka, Moscow (1977).Google Scholar
- 10.R. M. Christensen, Theory of Viscoelasticity, Academic Press, New York-London (1971).Google Scholar
- 11.V. P. Golub, “Experimental investigations of high-temperature processes of creep, fatigue, and damage. I. Methods of investigations,” Prikl. Mekh., 37, No 4, 3–38 (2001).Google Scholar
- 12.V. P. Golub, Yu. M. Kobzar’, and P. V. Fernati, “Nonlinear creep of viscoelastic organic fibers in tension,” Prikl. Mekh., 41, No 7, 102–115 (2005).Google Scholar
- 13.M. N. Stepnov, Statistical Methods of Processing of the Results of Mechanical Tests [in Russian], Mashinostroenie, Moscow (1985).Google Scholar
- 14.M. A. Koltunov, Creep and Relaxation [in Russian], Vysshaya Shkola, Moscow (1976).Google Scholar
- 15.J. D. Ferry, Viscoelastic Properties of Polymers, New York (1970).Google Scholar
- 16.M. I. Rozovskii, “Creep and long-term fracture of materials,” Zh. Tekhn. Fiz., 21, No. 11, 21–29 (1951).Google Scholar
- 17.V. I. Krylov, Approximate Calculation of Integrals [in Russian], Nauka, Moscow (1967).Google Scholar
- 18.P. M. Ogibalov and B. E. Pobedrya, “Nonlinear mechanics of polymers,” Mekh. Polimer., No. 1, 12–23 (1972).Google Scholar
- 19.S. A. Shesterikov and M. A. Yumasheva, “Concretization of the equations of state in the theory of creep,” Izv. AN SSSR, Mekh. Tverd. Tela, No. 1, 86–94 (1984).Google Scholar
- 20.H. Altenbach, “Topical problems and applications of creep theory,” Int. Appl. Mech., 39, No. 6, 631–656 (2003).CrossRefGoogle Scholar
- 21.Yu. N. Rabotnov and S. T. Mileiko, Short-Term Creep [in Russian], Nauka, Moscow (1970).Google Scholar
- 22.V. S. Gudramovich, Theory of Creep and Its Application to the Numerical Analysis of the Elements of Thin-Walled Structures [in Russian], Naukova Dumka, Kiev (2005).Google Scholar
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