Effect of Inclined Mechanical Load on a Rotating Microelongated Two Temperature Thermoelastic Half Space with Temperature Dependent Properties

Purpose:The objective of the present work is to study the disturbances in a rotating microelongated thermoelastic solid half-space with two temperature and temperature dependent properties. The problem has been modeled by employing Lord-Shulman and Green-Lindsay theories to carry out the investigation.Methods:To explore the impact of inclined mechanical load on microelongated thermoelastic half space, normal mode technique has been applied and the analytical expressions for the displacement components, stresses, temperature fields and microelongation are obtained.Results:In order to illustrate the analytical results, the numerical solution is carried out for aluminum epoxy like material. Influences of rotation, two temperatures, temperature dependent properties and time on the physical quantities are analyzed for Green-Lindsay theory.Conclusions:Theoretical and numerical results show the significant dependence of physical fields under consideration on rotation, elongation parameter, temperature dependent properties, two temperature parameter and inclination angle. Also the results of the present study have been compared with the previously published results for validation.

Automated summary

The purpose of this study is to investigate disturbances in a rotating microelongated thermoelastic solid half-space with two temperature and temperature dependent properties. The problem was modeled using Lord-Shulman and Green-Lindsay theories. The impact of inclined mechanical load on the microelongated thermoelastic half-space was explored using the normal mode technique, and analytical expressions for the displacement components, stresses, temperature fields, and microelongation were obtained. Numerical solutions were carried out for an aluminum epoxy-like material to illustrate the analytical results. Theoretical and numerical results showed the significant dependence of physical fields on rotation, elongation parameter, temperature dependent properties, two temperature parameter, and inclination angle. The results were compared with previously published results for validation.