﻿﻿ ﻿ ﻿﻿ New formulae for dynamical thermal stresses
 Conţinutul numărului revistei Articolul precedent Articolul urmator 154 0 SM ISO690:2012ŞEREMET, Victor. New formulae for dynamical thermal stresses. In: Journal of Thermal Stresses, 2002, vol. 25, pp. 123-152. ISSN 0149-5739. DOI: https://doi.org/10.1080/014957302753384388 EXPORT metadate: Google Scholar Crossref CERIF DataCiteDublin Core
Journal of Thermal Stresses
Volumul 25 / 2002 / ISSN 0149-5739 /ISSNe 1521-074X

 New formulae for dynamical thermal stresses
DOI:https://doi.org/10.1080/014957302753384388

Pag. 123-152

 Şeremet Victor State Agrarian University of Moldova Disponibil în IBN: 26 februarie 2024

Rezumat

A generalization of the function of influence of a unit heat source to the displacements is suggested for the boundary value problems in the dynamical uncoupled thermoelasticity. This generalization is a convolution over time and bulk of two influence functions. One of them is a Green's function for the heat conduction problem. The other is a function of influence of unit concentrated forces onto bulk dilatation. Broad possibilities are shown in constructing these influence functions. In particular, the theorem on dilatation constructing is proved. To calculate the convolutions successfully the following properties of the introduced function are found to be useful. (1) In coordinates of the point of observation, the function satisfies the equations used to find the Green's functions in the problem of heat conduction, with the unit heat source being replaced by the influence function of concentrated force onto dilatation; and (2) in coordinates of the point of heat source application, it satisfies the boundary value problem used to find Green's matrix, with the unit concentrated forces being replaced by derivatives of Green's function in the problem of heat conduction. Based on the introduced influence function, some new integral formulae for displacements and stresses are obtained, which are a generalization of Mysel's formula in the theory of dynamical thermal stresses. The proposed formulae have certain advantages allowing us to unite the two-staged process of finding the solutions for boundary value problems in thermoelasticity in a single stage. It is established that, based on the obtained results it becomes possible to compile a whole handbook on the influence functions and integral solutions for boundary value problems in dynamical thermoelasticity. As examples, the solutions for two boundary value problems in the theory of dynamical thermal stresses for the half-space and quarter-space are presented.

Cuvinte-cheie
boundary value problems, Green's function, Heat conduction, Integral equations, Matrix algebra, problem solving, Surface phenomena, Thermoelasticity