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Numerical Simulation of Dynamic Processes of Elastoplastic Interaction between Three-Dimensional Heterogeneous Bodies on the basis of Semi-Analytical Finite Element Method. Part 1. Computational Relationships of the Semi-Analytical Finite Element Method and Algorithms for the Study of Transient Processes of Dynamic Deformation of Heterogeneous Prismatic Bodies and Bodies of Revolution

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Strength of Materials Aims and scope

On the basis of a semi-analytical finite element method, an effective approach has been developed for studying transient processes of dynamic deformation of three-dimensional heterogeneous bodies of revolution and prismatic bodies of complex shape and structure by the action of time-and space-varying pulsed stressing with allowance for the plastic properties of the material and time-varying contact interaction conditions. New types of finite elements have been created, on the basis of which computational relationships of the semi-analytical finite element method (SAFEM) for problems of dynamics have been constructed. Modified relationships of the Newmark method have been obtained, which have been formulated for the amplitude subsystems of SAFEM. Effective block iteration algorithms for the solution of large systems of nonlinear equations of SAFEM have been developed and realized.

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Authors and Affiliations

  1. Kiev National University of Construction and Architecture, Kiev, Ukraine

    V. A. Bazhenov, A. I. Gulyar & I. I. Solodei

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  1. V. A. Bazhenov
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  2. A. I. Gulyar
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  3. I. I. Solodei
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Correspondence to I. I. Solodei.

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Translated from Problemy Prochnosti, No. 5, pp. 13 – 27, September – October, 2013.

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Bazhenov, V.A., Gulyar, A.I. & Solodei, I.I. Numerical Simulation of Dynamic Processes of Elastoplastic Interaction between Three-Dimensional Heterogeneous Bodies on the basis of Semi-Analytical Finite Element Method. Part 1. Computational Relationships of the Semi-Analytical Finite Element Method and Algorithms for the Study of Transient Processes of Dynamic Deformation of Heterogeneous Prismatic Bodies and Bodies of Revolution. Strength Mater 45, 523–533 (2013). https://doi.org/10.1007/s11223-013-9489-3

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