Ю.В. Захарова, Л.Г. Лохматова

12

Инженерный журнал: наука и инновации

# 11·2016

Simulation of stress-strain state

of defected composite shells

© Yu.V. Zakharova, L.G. Lokhmatova

Bauman Moscow State Technical University, Moscow, 105005, Russia

The paper examines an important problem of modeling the stress-strain state of the

defected composite shells. The issue is a promising one because presently shells made of

composite materials often serve as elements of different bearing constructions and it is often

impossible to avoid defects even at the manufacturing stage. We propose a mathematical

model of deformation of defected cylindrical shells made of composite materials. The model is

based on Timoshenko hypothesis. We examined defects of disbond type and with the help of

this model we described an algorithm for solving the problem of stress-strain state of defected

cylindrical shells. For the numerical solution of the problem we used the finite element

method. The presented results of numerical simulations have established patterns of influence

of local imperfections in the structure on the stress-strain state of cylindrical shell made of

composite materials with defects such as disbonds.

Keywords:

stress-strain state, cylindrical shell, composite materials, Timoshenko shell

model, disbonds.

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