A BRIEF OVERVIEW OF STATIONARY TWO-DIMENSIONAL THERMOELASTIC STATE MODELS IN HOMOGENEOUS AND PIECEWISE-HOMOGENEOUS BODIES WITH CRACKS
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Published:2023
Issue:3
Volume:9
Page:60-70
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ISSN:2411-8001
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Container-title:Ukrainian Journal of Mechanical Engineering and Materials Science
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language:
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Short-container-title:UJMEMS
Author:
Zelenyak VolodymyrORCID, , Kolyasa LiubovORCID, Klapchuk MyroslavaORCID, ,
Abstract
Purpose. A two-dimensional mathematical model of the problem of thermo-elasticity for piecewise-homogeneous component plate containing a crack has been built. The stress intensity coefficients in the vertices of the crack increase affecting strength of the body significantly. This leads to the growth of a crack and, as a result, to further local destruction of a material. Therefore, such a model reflects, to some extent, the destruction mechanism of the elements of engineering structures with cracks. Methodology. Based on the method of the function of a complex variable we have studied the two-dimensional thermoelastic state for the body with crack as stress concentrators. As result, the problem of thermoelasticity was reduced to a system of two singular integral equations (SIE) of the first and second kind, a numerical solution of which was found by the method of mechanical quadratures. Findings. The two-dimensional mathematical model of the thermoelastic state has been built in order to determine the stress intensity factors at the top of the crack and inclusion. The systems of singular integral equations of the first and second kinds of the specified problem on closed (contour of inclusion) and open (crack) contours are constructed. The influence of thermophysical and mechanical properties of inclusion on the SIF sat the crack types was investigated. The dependences of the stress intensity factor which characterizes the distribution of the intensity of stresses at the vertices of a crack have been built, as well as its elastic and thermoelastic characteristics of inclusion. This would make it possible to analyze the intensity of stresses in the neighborhoods of crack vertices depending on the geometrical and mechanical factors. As a result, this allows to determine the critical values of temperature in the three-component plate containing a crack in order to prevent the growth of the crack, as well as to prevent the local destruction of the body. It was found that the appropriate selection of mechanical and thermophysical characteristics of the components of a three-component plate containing a crack can be useful to achieve an improvement in body strength in terms of the mechanics of destruction by reducing stress intensity factors at the crack’s vertices. Originality. The solutions of the new two-dimensional problem of thermoelasticity for a specified region due to the action of constant temperature as well as due to local heating by a heat flux were obtained. The studied model is the generalization of the previous models to determine the two-dimensional thermoelastic state in a piecewise homogeneous plate weakened by internal cracks. Practical value. The practical application of this model is a more complete description of the stress-strain state in piecewise homogeneous structural elements with cracks operating under temperature loads. The results of numerical calculations obtained from the solution of systems of equations and presented in the form of graphs can be used in the design of rational modes of operation of structural elements. This takes into account the possibility of preventing the growth of cracks by the appropriate selection of composite components with appropriate mechanical characteristics.
Publisher
Lviv Polytechnic National University
Subject
Cell Biology,Developmental Biology,Embryology,Anatomy
Reference45 articles.
1. [1]. Choi, H. J. "Thermoelastic interaction of two offset interfacial cracks in bonded dissimilar half-planes with a functionally grade interlayer", Acta Mechanica, vol. 225, pp. 2111-2131, 2014. 2. [2]. Brock, L. M. "Contours for planar cracks growing in three dimensions: Coupled thermoelastic solid (planar crack growth in 3D)", Journal of Thermal Stresses, vol.39, pp. 345-359, 2016. 3. [3]. Elfakhakhre, N. R. F., Nik long, N. M. A. and Eshkuvatov, Z. K. "Stress intensity factor for multiple cracks in half plane elasticity", AIP Conference, 1795(1), 2017. 4. [4]. Rashidova, E. V. and Sobol, B. V. "An equilibrium internal transverse crack in a composite elastic half-plane", Journal of Applied Mathematics and Mechanics, vol.81, pp. 236-247, 2017. 5. [5]. Chen, H., Wang, Q., Liu, G.R., Wang, Y. and Sun, J. "Simulation of thermoelastic crack problems using singular edge-based smoothed finite element method", International Journal of Mechanical Sciences, vol.115-116, pp. 123-134, 2016.
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