Linear and nonlinear mathematical models for determining the temperature field and subsequently analyzing temperature regimes in isotropic spatial media with semi-through foreign inclusions subjected to internal and external thermal loads are developed. For this purpose, the heat transfer coefficient for such structures is described as a single unit using asymmetric unit functions, which makes it possible to consider boundary value problems of heat transfer with one linear and nonlinear differential equations of heat transfer with discontinuous and singular coefficients and linear and nonlinear boundary conditions on the boundary surfaces of the media. In the case of a nonlinear boundary value problem, the introduced linearizing function is used to linearize the original nonlinear heat conduction equation and nonlinear boundary conditions, and as a result, a partially linearized second-order differential equation with partial derivatives and discontinuous and singular coefficients is obtained relative to the linearizing function with partially linearized boundary conditions. For the final linearization of the partially linearized differential equation and boundary conditions, the temperature is approximated by one of the spatial coordinates on the boundary surfaces of the inclusion by piecewise linear functions, as a result of which both the differential equation and boundary conditions become fully linearized. To solve the resulting linear boundary value problem, the Hankel integral transformation method is used, which results in an analytical solution that determines the introduced linearizing function. As an example, the linear dependence of the thermal conductivity coefficient of structural materials of a structure on temperature, which is often used in many practical problems, is chosen. As a result, analytical relations in the form of quadratic equations were obtained to determine the temperature distribution in a thermally sensitive layer with a foreign semi-through inclusion under external heating in the form of a heat flux. A numerical analysis of the temperature behavior as a function of spatial coordinates for given values of geometric and thermophysical parameters is performed. The influence of a foreign inclusion on the temperature distribution is investigated if the VK94-I ceramic is chosen as the material of the medium and the inclusion is silver. To determine the numerical values of temperature in the above structures, as well as to analyze heat transfer processes inside these structures caused by internal and external thermal loads, software tools have been developed that have been used to perform a geometric image of the temperature distribution depending on spatial coordinates. The obtained numerical temperature values indicate that the developed mathematical models for analyzing heat transfer processes in spatially heterogeneous environments with internal and external heating correspond to a real physical process. The software also makes it possible to analyze such environments subjected to internal and external thermal loads in terms of their thermal resistance. As a result, it becomes possible to increase it and protect it from overheating, which can cause the destruction of not only individual elements but also the entire structure.
[1] Haopeng, S., Kunkun, X., & Cunfa, G. (2021). Temperature, thermal flux and thermal stress distribution around an elliptic cavity with temperature-dependent material properties. International Journal of Solids and Structures, 216, 136–144. https://doi.org/10.1016/j.ijsolstr.2021.01.010
[2] Zhang, Z., Zhou, D., Fang, H., Zhang, J., & Li, X. (2021). Analysis of layered rectangular plates under thermo-mechanical loads considering temperature-dependent material properties. Applied Mathematical Modelling, 92, 244–260. https://doi.org/10.1016/j.apm.2020.10.036
[3] Gong, J., Xuan, L., Ying, B., & Wang, H. (2019). Thermoelastic analysis of functionally graded porous materials with temperature-dependent properties by a staggered finite volume method. Composite Structures, 224, 111071. https://doi.org/10.1016/j.compstruct.2019.111071
[4] Demirbas, M. D. (2017). Thermal stress analysis of functionally graded plates with temperature-dependent material properties using theory of elasticity. Composites Part B: Engineering, 131, 100–124. https://doi.org/10.1016/j.compositesb.2017.08.005
[5] Ghannad, M., Yaghoobi, M. P. (2015). A thermoelasticity solution for thick cylinders subjected to thermo-mechanical loads under various boundary conditions. International Journal of Advanced Design & Manufacturing Technology, Vol. 8, 4, 1–12
[6] Yaghoobi, M. P., & Ghannad, M. (2020). An analytical solution for heat conduction of FGM cylinders with varying thickness subjected to non-uniform heat flux using a first-order temperature theory and perturbation technique. International Communications in Heat and Mass Transfer, 116, 104684. https://doi.org/10.1016/j.icheatmasstransfer.2020.104684
[7] Eker, M., Yarımpabuç, D., & Celebi, K. (2020). Thermal stress analysis of functionally graded solid and hollow thick-walled structures with heat generation. Engineering Computations, 38(1), 371–391. http://dx.doi.org/10.1108/EC-02-2020-0120
[8] Bayat, A., Moosavi, H., Bayat, Y. (2015). Thermo-mechanical analysis of functionally graded thick spheres with linearly time-dependent temperature. Scientia Iranica, Vol. 22, Issue 5, 1801–1812.
[9] Havrysh, V. I., & Grysjuk, Y. I. (2022). Temperature fields in heterogeneous enviroments with consideration of thermal sensitivity. Lviv: Publishing house of Lviv Politechnic National University, 120.
[10] Havrysh, V. I., Baranetskiy, Ya. O., & Kolyasa, L. I. (2018). Investigation of temperature modes in thermosensitive non-uniform elements of radioelectronic devices. Radio electronics, computer science, management, 3(46), 7–15. https://doi.org/10.15588/1607-3274-2018-3-1
[11] Havrysh, V. I., Kolyasa, L. I., & Ukhanska, O. M. (2019). Determination of temperature field in thermally sensitive layered medium with inclusions. Naukovyi Visnyk NHU, 1, 94–100. https://doi.org/10.29202/nvngu/2019-1/5
[12] Podstrigach, Ia. S., Lomakin, V. A., & Koliano, Iu. M. (1984). Termouprugost tel neodnorodnoi struktury. Moscow: Nauka, 368. [In Russian].
[13] Koliano, Iu. M. (1992). Metody teploprovodnosti i termouprugosti neodnorodnogo tela. Kyiv: Naukova dumka, 280. https://doi.org/10.1192/bjp.161.2.280 b
[14] Korn, G., & Korn, T. (1977). Spravochnik po matematike dlia nauchnykh rabotnikov i inzhenerov. Moscow: Nauka, 720. [In Russian].
[15] Kikoina, I. K. (1976). Tablitcy fizicheskikh velichin. Spravochnik. Moscow: Atomizdat, 1008. [In Russian].