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http://dx.doi.org/10.12989/aas.2020.7.3.215

Numerical investigation of the effects angles of attack on the flutter of a viscoelastic plate  

Sherov, A.G. (Tashkent Institute of Engineers of Irrigation and Mechanization in Agriculture)
Khudayarov, B.A. (Tashkent Institute of Engineers of Irrigation and Mechanization in Agriculture)
Ruzmetov, K.Sh. (Tashkent State Agrarian University, Tashkent region)
Aliyarov, J. (Tashkent Institute of Engineers of Irrigation and Mechanization in Agriculture)
Publication Information
Advances in aircraft and spacecraft science / v.7, no.3, 2020 , pp. 215-228 More about this Journal
Abstract
As is shown in the paper, the Koltunov-Rzhanitsyn singular kernel of heredity (when constructing mathematical models of the dynamics problem of the hereditary theory of viscoelasticity) adequately describes real mechanical processes, best approximates experimental data for a long period of time. A mathematical model of the problem of the flutter of viscoelastic plates moving in a gas with a high supersonic velocity is given. Using the Bubnov-Galerkin method, discrete models of the problem of the flatter of viscoelastic plates flowed over by supersonic gas flow are obtained. A numerical method is developed to solve nonlinear integro-differential equations (IDE) for the problem of the hereditary theory of viscoelasticity with weakly singular kernels. A general computational algorithm and a system of application programs have been developed, which allow one to investigate the nonlinear dynamic problems of the hereditary theory of viscoelasticity with weakly singular kernels. On the basis of the proposed numerical method and algorithm, nonlinear problems of the flutter of viscoelastic plates flowed over in a gas flow at an arbitrary angle are investigated. In a wide range of changes in various parameters of the plate, the critical velocity of the flutter is determined. It is shown that the singularity parameter α affects not only the oscillations of viscoelastic systems, but the critical velocity of the flutter as well.
Keywords
mathematical model; viscoelasticity; integro-differential equations; flutter; angle of flow;
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Times Cited By KSCI : 2  (Citation Analysis)
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