Stationary Boundary Problems of Coupled Thermoelasticity for a Half-Plane and Their Solution

Capa

Citar

Texto integral

Acesso aberto Acesso aberto
Acesso é fechado Acesso está concedido
Acesso é fechado Somente assinantes

Resumo

Using the model of coupled thermoelasticity, the boundary value problems of the dynamics of a thermoelastic half-space are solved for plane deformation with periodic surface force and thermal effects associated with the desired boundary functions by linear algebraic relations. Green’s tensors are constructed for the stated boundary value problems, using their properties, analytical solutions of these problems are obtained. To solve them, we have used the method of incomplete separation of variables, the Fourier transform, and the properties of fundamental solutions. The presented algorithm solves the classical four boundary value problems of thermoelasticity, as well as non-classical ones with coupled thermal and force characteristics at the boundary of the half-plane.

Sobre autores

L. Alekseyeva

Institute of Mathematics and Mathematical Modeling, 050010, Almaty, Republic of Kazakhstan

Email: alexeeva@math.kz
Казахстан, Алматы

B. Alipova

University of Kentucky, 40506, Lexington, KY, USA; International IT University, 050040, Almaty, Republic of Kazakhstan

Autor responsável pela correspondência
Email: alipova.bakhyt@gmail.com
США, Лексингтон; Казахстан, Алматы

Bibliografia

  1. Новацкий В. Теория упругости. М.: Мир, 1970. 256 с.
  2. Новацкий В. Динамические задачи термоупругости. М.: Мир, 1970. 256 с.
  3. Купрадзе В.Д., Гегелиа Т.Г., Башелейшвили М.О., Бурчуладзе Т.В. Трехмерные задачи математической теории упругости и термоупругости. М.: Наука, 1976. 664 с.
  4. Dargush G.E., Banerdjee P.K. Boundary element methods in three-dimensional thermoelasticity // Int. J. Solid Struct. 1990. V. 26. № 2. P. 199–216. https://doi.org/10.1016/0020-7683(90)90052-W
  5. Sah J., Tasaka N. Boundary element analysis of linear coupled thermoelasticity problems by using Laplace transformation // Proc 1st. Japan-U.S. Symp. on BEM. Oxford, New York: Pergamon Press, 1988. P. 535–544.
  6. Алексеева Л.А., Купесова Б.Н. Метод обобщенных функций в краевых задачах связанной термоэластодинамики // Прикл. мат. мех. 2001. Т. 65. № 2. С. 334–345.
  7. Alexeyeva L.A., Alipova B.N. Fundamental and generalized solutions of the equations of motion of a thermoelastic half-plane with a free boundary // Computat. Math. Math. Phys. 2019. V. 59. № 5. P. 782–790.
  8. Alexeyeva L.A., Dadayeva A.N. Shock thermoelastic waves as generalized solutions of thermoelasticity equations // ISAAC 9-th Congress: Abstracts. Krakow, Poland, 2013. P. 19–20.
  9. Алексеева Л.А., Дадаева А.Н. О единственности решений краевых задач термоупругости с учетом термоударных волн // Вест. КазНТУ им. К. Сатпаева. Cер.: Мат. мех. инф. 2013. № 28. С. 11–18.
  10. Alexeyeva L.A., Alipova B.N., Dadayeva A.N. Shock waves as generalized solutions of thermoelastodynamics equations. On the uniqueness of boundary value problems solutions // Am. Inst. Phys. Conf. Proc. 2017. V. 1798. P. 020003-1-020003-8. https://doi.org/10.1063/1.4972595
  11. Владимиров В.С. Обобщенные функции в математической физике. М.: Наука, 1979. 320 с.
  12. Владимиров В.С. Уравнения математической физики. М.: Наука, 1988. 512 с.
  13. Кеч В., Теодореску П. Введение в теорию обобщенных функций с приложениями в технике. М.: Мир, 1978. 518 с.

Declaração de direitos autorais © Л.А. Алексеева, Б.Н. Алипова, 2023

Este site utiliza cookies

Ao continuar usando nosso site, você concorda com o procedimento de cookies que mantêm o site funcionando normalmente.

Informação sobre cookies