Geodesic
Evaluation of the reliability of structures under creep for stochastic generalized models
Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, no. 3 (2012), pp. 53-71.

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The nonlinear stochastic model of uniaxial creep and creep rupture strength with three stages of deformation is suggested. The method for the identification of stochastic parameters of model by series of experimental creep curves is developed. The stochastic linearization of model for analytical evaluation of the probability of no-failure for stretchable rod by deformation criterion is obtained. The checking of accordance of the method with the experimental data for the creep of samples made of 12Kh18N10T steel under temperature $\rm 850\,^\circ C$ is implemented. The generalization of the approach developed to describe the deformation of structural elements of constructions in terms “generalized load, generalized displacement, time” is obtained. The feature is considered as a unit (specific sample with complex structure). A complete analogy between the curves of uniaxial creep model and generalized creep curves in coordinates “generalized displacement – time” is established for fixed values of the generalized displacement for a feature. Based on the analogy, the generalized stochastic model of rheological deformation of structural elements is proposed. The method for evaluating the reliability of structural elements under creep on parametric failure criteria, implemented in the model example of creep of thick-walled tubes under internal pressure, is developed. The results of the calculations and recommendations for operation life defining are given.
Keywords: creep, creep rupture strength, stochastic model, linearization, structural element, reliability, parametric failure criterion, probability of no-failure, steady creep stage. 
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V. P. Radchenko; M. V. Shershneva; S. N. Kubyshkina. Evaluation of the reliability of structures under creep for stochastic generalized models. Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, no. 3 (2012), pp. 53-71. http://geodesic.mathdoc.fr/item/VSGTU_2012_3_a5/

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