Abstract
Based on the applied theory of shells, an energy-consistent resolving system of equations is constructed, and a complex numerical method is developed which, within the framework of an explicit variational-difference scheme, makes it possible to solve both quasi-static and dynamic problems of nonlinear nonaxisymmetric deformation and loss of stability of composite cylindrical shells. The reliability of the developed method is substantiated by comparing calculation results with experimental data. The characteristic forms and critical buckling loads of GRP cylindrical shells as functions of the level of preloading by a quasi-static internal pressure and of the subsequent dynamic loading by an external pressure are analyzed for various reinforcement patterns in a wide range of loading rate.
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Acknowledgements
The method of calculating composite cylindrical shells under combined loads was developed at a financial support of the Ministry of Science and Higher Education of the Russian Federation (task 0729-2020-0054), and numerical analysis of loss of stability of shells was carried out at a financial support of RFBR grants ((№ 18-08-01234, № 19-08-00828).
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Abrosimov, N.A., Elesin, A.V., Igumnov, L. (2021). Computer Simulation of the Process of Loss of Stability of Composite Cylindrical Shells Under Combined Quasi-static and Dynamic Loads. In: dell'Isola, F., Igumnov, L. (eds) Dynamics, Strength of Materials and Durability in Multiscale Mechanics. Advanced Structured Materials, vol 137. Springer, Cham. https://doi.org/10.1007/978-3-030-53755-5_9
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