Dynamic response of a long cylinder under thermal shock in micropolar thermoelasticity

In this manuscript, the dynamic response of a long cylinder subjected to an asymmetric thermal shock is investigated within the framework of generalized micropolar thermoelasticity. The displacement and micro-rotation are assumed to vanish at the surface. Laplace transformation techniques are used to solve the problem. The solution is obtained in the transformed field using an innovative direct approach. Furthermore, we obtain the inverse transformations using a numerical method based on Fourier expansion. The obtained results are carefully presented through graphical representations and discussed extensively across different relaxation time values. It is evident that the relaxation time parameter significantly influences all the distributions. The displacement distributions are always continuous, whereas all other functions, including temperature variation, stress distribution, and micro-rotation, exhibit discontinuity at the wave front. The results obtained hold significant importance in various technological applications and in the manufacturing of mechanical components.

[1]  H. Sherief,et al.  Fractional order model of micropolar thermoelasticity and 2D half-space problem , 2022, Acta Mechanica.

[2]  H. Sherief,et al.  Generalized three-dimensional thermoelastic treatment in spherical regions , 2022, Journal of Thermal Stresses.

[3]  H. Sherief,et al.  New fractional order model of thermoporoelastic theory for a porous infinitely long cylinder saturated with fluid , 2021, Waves in Random and Complex Media.

[4]  M. Marin,et al.  The Effects of Fractional Time Derivatives in Porothermoelastic Materials Using Finite Element Method , 2021, Mathematics.

[5]  H. Sherief,et al.  Exact solution of a 2D problem of thermoelasticity without energy dissipation for an infinitely long cylinder , 2021, Mathematics and Mechanics of Solids.

[6]  N. Eldabe,et al.  The effect of Joule heating and viscous dissipation on the boundary layer flow of a magnetohydrodynamics micropolar‐nanofluid over a stretching vertical Riga plate , 2021, Heat Transfer.

[7]  Hany H. Sherief,et al.  Effect of a 2D axisymmetric cylindrical heat source on a thermoelastic thick plate , 2021, Mathematical Methods in the Applied Sciences.

[8]  H. Sherief,et al.  Two-dimensional axisymmetric thermoelastic problem for an infinite-space with a cylindrical heat source of a different material under Green–Lindsay theory , 2020, Mechanics Based Design of Structures and Machines.

[9]  Faris Alzahrani,et al.  An Eigenvalues Approach for a Two-Dimensional Porous Medium Based Upon Weak, Normal and Strong Thermal Conductivities , 2020, Symmetry.

[10]  Mohamed F. Zaky,et al.  Effect of a general body force on a 2D generalized thermoelastic body with a cylindrical cavity , 2019, Mathematical Methods in the Applied Sciences.

[11]  Baljeet Singh,et al.  Reflection of plane waves from a micropolar thermoelastic solid half-space with impedance boundary conditions , 2019, Journal of Ocean Engineering and Science.

[12]  M. Marin,et al.  About finite energy solutions in thermoelasticity of micropolar bodies with voids , 2019, Boundary Value Problems.

[13]  H. Sherief,et al.  Fractional order theory of thermo-viscoelasticity and application , 2019, Mechanics of Time-Dependent Materials.

[14]  R. Lianngenga Effect of inertial coefficients in the propagation of plane waves in micropolar porous materials , 2017 .

[15]  I. Abbas,et al.  2D deformation in initially stressed thermoelastic half-space with voids , 2016 .

[16]  A. Zenkour,et al.  Nonlinear Transient Thermal Stress Analysis of Temperature-Dependent Hollow Cylinders Using a Finite Element Model , 2014 .

[17]  Ibrahim A. Abbas,et al.  Finite element analysis of the thermoelastic interactions in an unbounded body with a cavity , 2007 .

[18]  F. Hamza,et al.  THEORY OF GENERALIZED MICROPOLAR THERMOELASTICITY AND AN AXISYMMETRIC HALF-SPACE PROBLEM , 2005 .

[19]  P. M. Naghdi,et al.  Thermoelasticity without energy dissipation , 1993 .

[20]  P. M. Naghdi,et al.  ON UNDAMPED HEAT WAVES IN AN ELASTIC SOLID , 1992 .

[21]  P. M. Naghdi,et al.  A re-examination of the basic postulates of thermomechanics , 1991, Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences.

[22]  G. Honig,et al.  A method for the numerical inversion of Laplace transforms , 1984 .

[23]  J. Ignaczak A NOTE ON UNIQUENESS IN THERMOELASTICITY WITH ONE RELAXATION TIME , 1982 .

[24]  Hany H. Sherief,et al.  Generalized thermoelasticity for anisotropic media , 1980 .

[25]  J. Ignaczak UNIQUENESS IN GENERALIZED THERMOELASTICITY , 1979 .

[26]  H. Lord,et al.  A GENERALIZED DYNAMICAL THEORY OF THERMOELASTICITY , 1967 .

[27]  A. Eringen,et al.  LINEAR THEORY OF MICROPOLAR ELASTICITY , 1965 .

[28]  H. Sherief On uniqueness and stability in generalized thermoelasticity , 1987 .

[29]  W. Nowacki,et al.  Theory of asymmetric elasticity , 1986 .

[30]  H. Sherief On generalized thermoelasticity , 1980 .

[31]  K. A. Lindsay,et al.  Thermoelasticity , 1972 .

[32]  Cemal Eringen Foundations of micropolar thermoelasticity , 1970 .

[33]  T. R. Tauchert,et al.  The linear theory of micropolar thermoelasticity , 1968 .

[34]  W. Nowacki COUPLE STRESSES IN THE THEORY OF THERMOELASTICITY III , 1968 .