
Stressed deformed condition of orthotropic spherical shell, lowered by two circular hole
Author(s) -
Barna Rakhmankulova,
Nurilla Noraliev,
Kamol Djamalov,
Sholpan Ziyaeva
Publication year - 2020
Publication title -
iop conference series materials science and engineering
Language(s) - English
Resource type - Journals
eISSN - 1757-899X
pISSN - 1757-8981
DOI - 10.1088/1757-899x/896/1/012070
Subject(s) - orthotropic material , rigidity (electromagnetism) , finite element method , composite number , shell (structure) , shearing (physics) , materials science , composite material , structural engineering , software package , stress (linguistics) , software , engineering , computer science , linguistics , philosophy , programming language
Methods of calculating the shell structures from composite materials and studying the concentration of strains near the holes are devoted to a rather large number of works. However, most of the research was carried out within the framework of the classical Kirchhoff-Love hypothesis, which does not take into account the interlayer and lateral shifts characteristic of composite materials. Application of finite elements method to solve the problems on orthotropic shells of composites, weakened by several holes is reported within the improved theory of Timoshenko type. A numerical algorithm has been developed using the finite element method and a software package has been implemented on a computer that makes it possible to solve problems of stress concentration near two apertures in shells of composite materials. Shearing parameter has been studied for its influence on stress concentration near two circular holes internal pressure for orthotropic spherical shells. Specific results are presented for the cases of large and small holes, taking into account the rigidity of the reinforcing elements. Thus, this software package can be applied to the calculation of the elements of shell structures from orthotropic composite materials weakened by several holes.
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