Transient hygrothermoelastic response in a cylinder considering non-Fourier hyperbolic heat-moisture coupling

Transient hygrothermoelastic response in a cylinder considering non-Fourier hyperbolic heat-moisture coupling

•Non-Fourier heat conduction and non-Fick diffusion of moisture.•Hyperbolic diffusion of hygrothermal coupling in an elastic cylinder.•Transient response of a cylinder subject to heat/moisture shock.•Phase lag of heat and moisture flux strongly affects hygrothermal stresses. The classical theory of...

Full description

Saved in:
Bibliographic Details
Published in:International journal of heat and mass transfer Vol. 126; pp. 1094 - 1103
Main Authors: Peng, Y., Zhang, X.-Y., Xie, Y.-J., Li, X.-F.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-11-2018
Subjects:
Cylinder
Hygrothermal stresses
Hyperbolic heat conduction
Non-classical diffusion
Non-Fourier law
Phase lag
Hyperbolic heat conduction
Cylinder
Phase lag
Non-Fourier law
Hygrothermal stresses
Non-classical diffusion
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Non-Fourier heat conduction and non-Fick diffusion of moisture.•Hyperbolic diffusion of hygrothermal coupling in an elastic cylinder.•Transient response of a cylinder subject to heat/moisture shock.•Phase lag of heat and moisture flux strongly affects hygrothermal stresses. The classical theory of heat conduction (Fourier theory) predicts an infinite speed for thermal disturbance propagation, which is physically unrealistic. By extending the classical Fourier heat conduction and Fick’s diffusion, this paper presents a hyperbolic diffusion law with different phase lags of thermal and moisture fluxes to simulate coupled heat-moisture diffusion-propagation behavior. Transient hygrothermal and elastic response of an infinitely long cylinder subjected to sudden hygrothermal loadings at the surface is studied. By using Laplace transform and decoupling technique, a closed form solution of temperature, moisture, displacements and stresses is determined. The analytical results show that the thermal and moisture relaxation times or phase lags of heat and moisture fluxes play a significant role in the early stage of transient response after heat/moisture shock. The classical results corresponding to vanishing phase lags can be recovered from the present ones. For non-vanishing phase lags, hygrothermal waves have finite propagation speeds. Numerical results are calculated and displayed graphically to show the influence of the phase lags of heat and moisture fluxes on transient hygrothermoelastic fields. A comparison between classic model and hyperbolic hygrothermal coupling model is given. Based on the non-Fourier heat conduction and non-Fick diffusion, some shortcomings induced by the classical Fourier’s and Fick’s laws can be effectively avoided.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2018.05.084