The 3D dynamics and strength of metal-composite finite-length cylinders under nonaxisymmetric internal explosion loading have been studied by a numerical-analytical method. The strength verification has been performed using three fracture criteria for a transtropic material: the maximum-stress criterion, the maximum-strain criterion, and the generalized Mises criterion. The influence of the explosive charge shift along the radius and axis with respect to the shell’s center of symmetry on the stress-strain state and strength of the cylinder has been investigated. The reinforced composites with low ultimate tensile strengths perpendicular to the reinforcement fibers have been found ineffective for such shells.
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Translated from Problemy Prochnosti, No. 6, pp. 73 – 89, November – December, 2017.
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Lepikhin, P.P., Romashchenko, V.A. & Beiner, O.S. A Numerical Study of 3D Dynamics and Strength of Metal-Composite Cylinders Under Internal Explosion Loading. Strength Mater 49, 796–808 (2017). https://doi.org/10.1007/s11223-018-9925-5
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DOI: https://doi.org/10.1007/s11223-018-9925-5