Abstract
The article is devoted to construction of mathematical models for analysis of stress-strain state of the ship’s plate. The model is based on the theory of plates pocket on the basis of mathematical models created a complex software, which together allow us to speak about building a handy tool both for research and for practical use, which allows to quickly calculate and evaluate the fatigue-stress state of the ship’s deck. As a practical example taken container for which it was solve stress-strain state of its hatches, taking into account load containers on deck.
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Notes
- 1.
The free encyclopedia, ANSYS, url: https://ru.wikipedia.org/wiki/ANSYS.
- 2.
Mechanica sive motus sciontia analytice exponenta, 2 volumes, St. Petersburg, 1736 German translation Wolfers (Wolfers, JP, Greifswald), 1848 and 1850.
References
Bojcov, G. V., Palij, O. M., Postnov, V. A., & Chuvikovskij, V. S. (1982). Handbook of structural mechanics of the ship in three volumes, Plates. Theory of elasticity, plasticity and creep. Numerical methods, Shipbuilding. Vol. 2.
Chernyi, S. (2015). The implementation of technology of multi-user client-server applications for systems of decision making support. Metallurgical and Mining Industry, 3, 60–65.
Chernyi, S., & Zhilenkov, A. (2015a). Analysis of complex structures of marine systems with attraction methods of neural systems. Metallurgical and Mining Industry, 1, 37–44.
Chernyi, S., & Zhilenkov, A. (2015b). Modeling of complex structures for the ship’s power complex using XILINX system. Transport and Telecommunication, 16(1), 73–82.
Chernyi, S., Zhilenkov, A., Sokolov, S., & Titov, I. (2015). Seif-contained drilling rig automatic control system efficiency improvement by means of assuring compatibility and integration methods development. Metallurgical and Mining Industry, 7(3), 66–73.
Chernyi, S. (2016). Analysis of the energy reliability component for offshore drilling platforms within the Black Sea. Neftyanoe Khozyaystvo–Oil Industry, 1(2), 106–110.
Goloskokov, D. P. (2004). Uravneniya matematicheskoy fiziki. Resheniye zadach v sistemeMaple [Equations of mathematical physics. The solution of tasks in the system Maple]. Saint-Petersburg: Piter, 538.
Han, F. L., Wang, C. H., Hu, A. K., & Liu, Y. C. (2014). Fatigue strength assessment analysis of large container ship. Applied Mechanics and Materials, 602–605, 385–389.
Jasnickij, L. N. (2005). For whom the tolls ANSYS, or why so many were falling aircraft missiles to explode, collapse of the building. 1(342).
Malyh, M. D. (2012). Proceedings of the seminar Finite Element Method on the example of the first boundary value problem for the Poisson equation. Physics Department of Moscow State University.
Mathai, A., John, G. P., & Jin, M. J. (2013). Ultimate torsional strength analysis of container ship. International Journal of Engineering Science and Technology., 5(3), 512–518.
Postnov, V. A., Rostovcev, D. M., Suslov, V. P., & Kochanov, J. P. (1987). Structural mechanics of the ship and the theory of elasticity: The Textbook for high schools: in 2 volumes. Shipbuilding, 2.
Zhilenkov, A., & Chernyi, S. (2015). Investigation performance of marine equipment with specialized information technology. Procedia Engineering, 100, 1247–1252.
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Nyrkov, A., Sokolov, S., Maltsev, V., Chernyi, S. (2017). Mathematical Foundations and Software Simulation of Stress-Strain State of the Plate Container Ship. In: Zhang, D., Wei, B. (eds) Mechatronics and Robotics Engineering for Advanced and Intelligent Manufacturing. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-319-33581-0_24
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DOI: https://doi.org/10.1007/978-3-319-33581-0_24
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