Научная электронная библиотека ULRICH'S Periodicals Directory

Сибирский государственный университет
науки и технологий имени академика М.Ф. Решетнева

Сибирский аэрокосмический журнал
ISSN 2712-8970 (Print) ISSN 2782-5760 (on-line)

Сведения об образовательной организации

UDK UDC 539.3 Doi: 10.31772/2587-6066-2019-20-4-423-435
THE METHOD OF EQUIVALENT STRENGTH CONDITIONS IN CALCULATING COMPOSITE STRUCTURES WITH A REGULAR STRUCTURE USING MULTIGRID FINITE ELEMENTS
Matveev А. D.
Institute of Computational Modeling; 50/44, Akademgorodok, Krasnoyarsk, 660036, Russian Federation; E-mail: mtv241@mail.ru
Plates, beams and shells with non-uniform and micro-inhomogeneities regular structure are widely used in aviation and rocket and space technology. At the preliminary design stage, it is initially important to know whether the design safety factor meets the specified strength conditions. To determine the margin factor, it is necessary to solve the elasticity problem for the designed structure by the finite element method (FEM), taking into account its inhomogeneous structure, which requires large computer resources. In this paper, we propose a method of equivalent strength conditions (MESC) for calculating the static strength of elastic structures with a inhomogeneous regular structure. The proposed method is reduced to the calculation of the strength of isotropic homogeneous bodies using equivalent strength conditions. The MESC is based on the following statement. For any composite body V0 , there exists such an isotropic homogeneous body Vb and such a number p (equivalence coefficient) that if the body Vb stock coefficient satisfies 0 nb the equivalent strength conditions 0 pn1  nb  pn2 , then the body V0 stock coefficient satisfies n0 the given strength conditions n1  n0  n2 , and Vice versa, n1 , n2 – given, the coefficients 0 nb , n0 , meet the exact solutions of elasticity problems constructed for bodies V0 , Vb . The method under consideration is reduced to FEM strength calculation of isotropic homogeneous bodies, which is the easiest to implement and requires less computer memory than a similar calculation of composite bodies taking into account their inhomogeneous structure. The procedure for determining the equivalence coefficients for a number of composite plates, beams and shells of rotation is described. High-precision multigrid finite elements generating discrete models of small dimension and solutions with small error are used in the construction of elastic solutions according to FEM for isotropic homogeneous bodies. The adjusted equivalent strength conditions are of the form pn1(1 1)  nb  pn2 (1 2 ) , where nb is the body Vb reserve coefficient and the values 1 , 2 correspond to the approximate solution constructed for the body Vb . Implementation of FEM for multigrid discrete models requires several 103 106 times less computer memory than for basic models. The calculation of the strength of a beam with a micro-homogeneous regular structure with the help of MESC is given.
Keywords: elasticity, composites, equivalent strength conditions, multigrid finite elements, plates, beams, shells.
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Matveev Alexander Danilovich – Cand. Sc., associate Professor, senior researcher; Institute of computational
modeling SB RAS. E-mail: mtv241@mail.ru.


  THE METHOD OF EQUIVALENT STRENGTH CONDITIONS IN CALCULATING COMPOSITE STRUCTURES WITH A REGULAR STRUCTURE USING MULTIGRID FINITE ELEMENTS