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Semianalytic Finite-Element Method in Continuum Creep Fracture Mechanics Problems for Complex-Shaped Spatial Bodies and Related Systems. Part 1. Resolving Relationships of the Semianalytic Finite-Element Method and Algorithms for Solving the Continuum Creep Fracture Problems

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Abstract

The paper presents physical equations of continuum creep fracture mechanics. Resolving relationships have been derived for a heterogeneous circular nonclosed finite element. The authors have constructed algorithms for solving the creep problem by using Kachanov–Rabotnov scalar parameter of damageability and modeling the conditions of interaction in systems with spatial bodies.

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Authors and Affiliations

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

    A. I. Gulyar & S. O. Piskunov

  2. State Scientific and Technical Center for Nuclear and Radiation Safety, Kiev, Ukraine

    E. E. Maiboroda

Authors
  1. V. A. Bazhenov
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  2. A. I. Gulyar
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  3. E. E. Maiboroda
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  4. S. O. Piskunov
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Bazhenov, V.A., Gulyar, A.I., Maiboroda, E.E. et al. Semianalytic Finite-Element Method in Continuum Creep Fracture Mechanics Problems for Complex-Shaped Spatial Bodies and Related Systems. Part 1. Resolving Relationships of the Semianalytic Finite-Element Method and Algorithms for Solving the Continuum Creep Fracture Problems. Strength of Materials 34, 425–433 (2002). https://doi.org/10.1023/A:1021017708480

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