A novel theory of generalized thermoelasticity based on thermomass motion and two-temperature heat conduction

AbstractThis work aims to study the influence of the rotation on a thermoelastic solid sphere in the context of the hyperbolic two-temperature generalized thermoelasticity theory based on the mechanical damage consideration. Therefore, a mathematical model of thermoelastic, homogenous, and isotropic solid sphere with a rotation based on the mechanical damage definition has been constructed. The governing equations have been written in the context of hyperbolic two-temperature generalized thermoelasticity theory. The bounding surface of the sphere is thermally shocked and without volumetric deformation. The singularities of the studied functions at the center of the sphere have been deleted using L’Hopital’s rule. The numerical results have been represented graphically with various mechanical damage values, two-temperature parameters, and rotation parameter values. The two-temperature parameter has significant effects on all the studied functions. Damage and rotation have a major impact on deformation, displacement, stress, and stress–strain energy, while their effects on conductive and dynamical temperature rise are minimal. The thermal and mechanical waves propagate with finite speeds on the thermoelastic body in the hyperbolic two-temperature theory and the one-temperature theory (Lord-Shulman model).

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Neural network method for solving parabolic two-temperature microscale heat conduction in double-layered thin films exposed to ultrashort-pulsed lasers

International Journal of Heat and Mass Transfer ◽

10.1016/j.ijheatmasstransfer.2021.121616 ◽

2021 ◽

Vol 178 ◽

pp. 121616

Author(s):

Aniruddha Bora ◽

Weizhong Dai ◽

Joshua P. Wilson ◽

Jacob C. Boyt

Keyword(s):

Neural Network ◽

Thin Films ◽

Heat Conduction ◽

Pulsed Lasers ◽

Neural Network Method ◽

Network Method ◽

Ultrashort Pulsed Lasers ◽

Two Temperature

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Analytical Solution to Steady-State Heat-Conduction Problems With Irregularly Shaped Boundaries

Journal of Heat Transfer ◽

10.1115/1.3449844 ◽

1971 ◽

Vol 93 (4) ◽

pp. 449-454 ◽

Cited By ~ 9

Author(s):

D. M. France

Keyword(s):

Heat Conduction ◽

Steady State ◽

Analytical Solution ◽

Least Squares ◽

Series Solution ◽

Point Matching ◽

State Heat ◽

Temperature Heat ◽

Steady State Heat ◽

Least Squares Approach

A method of obtaining an analytical solution to two-dimensional steady-state heat-conduction problems with irregularly shaped boundaries is presented. The technique of obtaining the coefficients to the series solution via a direct least-squares approach is compared to the “point-matching” scheme. The two methods were applied to problems with known solutions involving the three heat-transfer boundary conditions, temperature, heat flux, and convection coefficient specified. Increased accuracy with substantially fewer terms in the series solution was obtained via the least-squares technique.

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Magnetic field on surface waves propagation in gravitational thermoelastic media with two temperature and initial stress in the context of three theories

Thermal Science ◽

10.2298/tsci20s1285b ◽

2020 ◽

Vol 24 (Suppl. 1) ◽

pp. 285-299

Author(s):

Jamel Bouslimi ◽

Sayed Abo-Dahab ◽

Khaled Lotfy ◽

Sayed Abdel-Khalek ◽

Eied Khalil ◽

...

Keyword(s):

Magnetic Field ◽

Surface Waves ◽

Initial Stress ◽

Half Space ◽

Generalized Thermoelasticity ◽

Phase Lag ◽

Mathematical Methods ◽

Numerical Work ◽

Suitable Material ◽

Two Temperature

In this paper is investigating the theory of generalized thermoelasticity under two temperature is used to solve boundary value problems of 2-D half-space its bound?ary with different types of heating under gravity effect. The governing equations are solved using new mathematical methods under the context of Lord-Shulman, Green-Naghdi theory of type III (G-N III) and the three-phase-lag model to inves?tigate the surface waves in an isotropic elastic medium subjected to gravity field, magnetic field, and initial stress. The general solution obtained is applied to a spe?cific problem of a half-space and the interaction with each other under the influence of gravity. The physical domain by using the harmonic vibrations is used to obtain the exact expressions for the Waves velocity and attenuation coefficients for Stoneley waves, Love waves, and Rayleigh waves. Comparisons are made with the results between the three theories. Numerical work is also performed for a suitable material with the aim of illustrating the results. The results obtained are calculated numerical?ly and presented graphically with some comparisons in the absence and the presence the influence of gravity, initial stress and magnetic field. It clears that the results ob?tained agree with the physical practical results and agree with the previous results if the gravity, two temperature, and initial stress neglect as special case from this study.

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Effect of Deformation on Semi–infinite Viscothermoelastic Cylinder Based on Five Theories of Generalized Thermoelasticity

Mathematical Journal of Interdisciplinary Sciences ◽

10.15415/mjis.2017.61003 ◽

2017 ◽

Vol 6 (1) ◽

pp. 17-35 ◽

Cited By ~ 3

Author(s):

D. K. Sharma ◽

Himani Mittal ◽

Sita Ram Sharma ◽

Inder Parkash

Keyword(s):

Heat Conduction ◽

Laplace Transformation ◽

Numerical Technique ◽

Equations Of Motion ◽

Generalized Thermoelasticity ◽

Dynamical Problem ◽

Infinite Cylinder ◽

Matlab Software ◽

Voigt Model ◽

Laplace Transformations

We considera dynamical problem for semi-infinite viscothermoelastic semi infinite cylinder loaded mechanically and thermally and investigated the behaviour of variations of displacements, temperatures and stresses. The problem has been investigated with the help of five theories of the generalized viscothermoelasticity by using the Kelvin – Voigt model. Laplace transformations and Hankel transformations are applied to equations of constituent relations, equations of motion and heat conduction to obtain exact equations in transformed domain. Hankel transformed equations are inverted analytically and for the inversion of Laplace transformation we apply numerical technique to obtain field functions. In order to obtain field functions i.e. displacements, temperature and stresses numerically we apply MATLAB software tools. Numerically analyzed results for the temperature, displacements and stresses are shown graphically.

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