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Thermal-stress analysis of a damaged solid sphere using hyperbolic two-temperature generalized thermoelasticity theory

Hamdy M. Youssef, Alaa A. El‐Bary, Eman A. N. Al-Lehaibi

2021Scientific Reports17 citationsDOIOpen Access PDF

Abstract

This 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).

Topics & Concepts

Thermoelastic dampingIsotropyContext (archaeology)Rotation (mathematics)Stress (linguistics)Deformation (meteorology)Gravitational singularityMechanicsMathematical analysisDeformation theoryWork (physics)Isotropic solidPhysicsThermalClassical mechanicsMaterials scienceMathematicsGeometryThermodynamicsComposite materialGeologyOpticsPhilosophyPaleontologyLinguisticsThermoelastic and Magnetoelastic PhenomenaElasticity and Wave PropagationNonlocal and gradient elasticity in micro/nano structures
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