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Yu. I. Butenko, "A modified method of asymptotic integration: application to the construction of the theory of orthotropic rods. Part I," Mech. Solids. 36 (4), 70-82 (2001)
Year 2001 Volume 36 Number 4 Pages 70-82
Title A modified method of asymptotic integration: application to the construction of the theory of orthotropic rods. Part I
Author(s) Yu. I. Butenko (Kazan)
Abstract The ways of justifying the theory of plates is the subject matter of current discussion in the literature. In this connection, the applicability of the classical theory based on the Kirchhoff hypotheses is being contrasted with that of the Reissner-Timoshenko theory. It is known that a refinement of the basic stress state (called the penetrating solution, or the solution of the internal problem, in terms of the asymptotic methods) can be achieved by refining the equations of bending of plates and a more precise statement of the boundary conditions. In the present paper, we consider as a model the plane problem for an orthotropic strip and construct multi-term asymptotic expansions which yield a refinement for the internal problem, as well as the boundary layer problem (rapid decay away from the edge), and as a result, we obtain more precise boundary conditions. The symmetric problem and the problem of bending are constructed for the strip with the accuracy ε2 (ε=h/a is a small parameter). It is shown that the Reissner-Timoshenko model for the rod does not take into account the boundary layer solutions, and therefore, the refinements of the basic stress state are due only to more precise equations of equilibrium. At the same time, the consideration of a more complex model of rod bending (for instance, with the accuracy ε2 for all parameters of the problem) leads to refinements in the internal problem with the parameter ε under the geometrical boundary conditions. This fact should be taken into account when constructing a theory of plate design.

The longstanding problem of the construction of the theory of beams, plates, and shells is, in essence, an asymptotic problem [1-4]. In [3, 4], an asymptotic method is proposed for the integration of elasticity equations in order to obtain the corresponding equations of the theory of plates and shells. In fact, this method leads to the successive integration of the desired quantities with respect to the transverse coordinate and their representation as power series in that coordinate.

On the other hand, the desired quantities can be directly represented as a series in powers of the transverse coordinate and the corresponding differential equations can be obtained on the basis of variational principles. The choice of the specific variational principle depends on the choice of the basic unknown quantities.

Representation of the displacements as power series in the transverse coordinate and subsequent application of variational principles for the construction of the theory of plates and shells are described in [5-7]. However, this approach encounters substantial computational difficulties, which are mainly due to the fact that the resulting differential equations and boundary conditions involve the basic (internal) stress state (BSS) and the boundary layer solutions (BLS). For theories capable of application it is desirable to have separate (mutually independent) methods for the determination of the internal solution (BSS) at the points of the entire structure and the solution rapidly decaying away from the edge (BLS).

When constructing approximate theories (models), the difficulties of separating the stress states can be overcome by asymptotic methods applied to the system of equations obtained by variational methods [5-7], as shown in the present paper for the theory of orthotropic beams treated in geometrically and physically linear formulations. The method proposed here is in a certain sense close to the method of symbolic integration of elasticity equations [8] and leads to results which, in many aspects, coincide with those of [3, 9] obtained for the plane elasticity problem by the asymptotic method. The representation of the displacements as asymptotic series with respect to the transverse coordinate has been used in [10, 11] for the construction of nonclassical theories of plates and shells.
References
1.  I. I. Vorovich, "Some results and problems of the asymptotic theory of plates and shells," Proceedings of the First All-Union Workshop on Numerical Methods in the Theory of Shells and Plates [in Russian], pp. 51-149, Izd-vo Tbilisskogo Un-ta, Tbilisi, 1975.
2.  A. L. Goldenveizer, Theory of Thin Elastic Shells [in Russian], Nauka, Moscow, 1976.
3.  A. L. Goldenveizer, "An approximate theory of plate bending obtained by the method of asymptotic integration of elasticity equations," PMM [Applied Mathematics and Mechanics], Vol. 26, No. 4, pp. 668-686, 1962.
4.  A. L. Goldenveizer, "An approximate theory of shells obtained by the method of asymptotic integration of elasticity equations," PMM [Applied Mathematics and Mechanics], Vol. 27, No. 4, pp. 593-608, 1963.
5.  Kh. M. Mushtari and I. G. Teregulov, "On the theory of shells of medium thickness," Doklady AN SSSR, Vol. 128, No. 6, pp. 1144-1147, 1959.
6.  I. G. Teregulov, "On the theory of plates of medium thickness," Proceedings of the Conference on the Theory of Plates and Shells, pp. 367-375, Izd-vo Kazanskogo Un-ta, Kazan, 1961.
7.  I. G. Teregulov, "On the construction of refined theory of plates and shells," PMM [Applied Mathematics and Mechanics], Vol. 26, No. 2, pp. 346-350, 1962.
8.  A. I. Lur'e, Three-Dimensional Problems in Elasticity [in Russian], Gostekhizdat, Moscow, 1955.
9.  L. A. Agalovyan, Asymptotic Theory of Anisotropic Plates and Shells [in Russian], Nauka, Moscow, 1997.
10.  V. V. Vasil'ev and S. A. Lur'e, "On the construction of nonclassical theories of plates," Izv. AN SSSR. MTT [Mechanics of Solids], No. 2, pp. 148-167, 1990.
11.  V. V. Vasil'ev and S. A. Lur'e, "On the problem of refining the theory of shallow shells," Izv. AN SSSR. MTT, No. 6, pp. 139-146, 1990.
12.  A. Nayfeh, Perturbation Methods [Russian translation], Mir, Moscow, 1976.
13.  M. I. Vishik and L. A. Lyusternik, "Regular degeneration and boundary layer for linear differential equations with a small parameter," Uspekhi Mat. Nauk, Vol. 12, No. 5, pp. 3-122, 1957.
14.  S. P. Timoshenko and J. Goodier, Theory of Elasticity [Russian translation], Nauka, Moscow, 1975.
Received 05 February 1999
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