Journal ArticleDOI
On a variant of the Maxwell and Oldroyd-B models within the context of a thermodynamic basis
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In this paper, the authors developed models within a thermodynamic standpoint that are very similar in form to the classical Maxwell and Oldroyd-B models but differ from them in one important aspect, the manner in which they unload instantaneously from the deformed configuration.Abstract:
In this paper we develop models within a thermodynamic standpoint that are very similar in form to the classical Maxwell and Oldroyd-B models but differ from them in one important aspect, the manner in which they unload instantaneously from the deformed configuration. As long as the response is not instantaneous, the models that are derived cannot be differentiated from the Maxwell and Oldroyd-B models, respectively. The models can be viewed within the context of materials whose natural configuration evolves, the evolution being determined by the maximization of the rate of entropy production of the material. However, the underpinnings to develop the model are quite different from an earlier development by Rajagopal and Srinivasa [8] in that while the total response of the viscoelastic fluid satisfies the constraint of an incompressible material, the energy storage mechanism associated with the elastic response is allowed to be that for a compressible elastic solid and the dissipative mechanism associated with the viscous response allowed to be that for a compressible fluid, the total deformation however being isochoric. The analysis calls for a careful evaluation of firmly held customs in viscoelasticity wherein it is assumed that it is possible to subject a material to a purely instantaneous elastic response without any dissipation whatsoever. Finally, while the model developed by Rajagopal and Srinivasa [8] arises from the linearization of the non-linear elastic response that they chose and leads to a model wherein the instantaneous elastic response is isochoric, here we develop the model within the context of a different non-linear elastic response that need not be linearized but the instantaneous elastic response not necessarily being isochoric.read more
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Book ChapterDOI
Derivation of Equations for Continuum Mechanics and Thermodynamics of Fluids
Josef Málek,Vít Průša +1 more
TL;DR: In this article, the authors present a phenomenological theory of constitutive relations, which is based on the Cauchy stress tensor and the kinematical quantities of a material.
Journal ArticleDOI
Thermodynamics of viscoelastic rate-type fluids with stress diffusion
TL;DR: In this paper, the authors proposed thermodynamically consistent models for viscoelastic rate-type fluids with stress diffusion and derived variants of compressible/incompressible Maxwell/Oldroyd-B models with a stress diffusion term in the evolution equation.
Journal ArticleDOI
On thermodynamics of incompressible viscoelastic rate type fluids with temperature dependent material coefficients
TL;DR: In this article, a class of thermodynamically consistent variants of the Maxwell/Oldroyd-B type models for incompressible viscoelastic fluids are derived and a temperature evolution equation for the temperature is explicitly formulated, and it is shown to be consistent with the laws of thermodynamics and the evolution equations for the mechanical quantities.
Journal ArticleDOI
Thermodynamics of viscoelastic rate-type fluids with stress diffusion
TL;DR: In this paper, the authors proposed thermodynamically consistent models for viscoelastic rate-type fluids with stress diffusion and derived variants of compressible/incompressible Maxwell/Oldroyd-B models with a stress diffusion term in the evolution equation.
Journal ArticleDOI
Derivation of the Variants of the Burgers Model Using a Thermodynamic Approach and Appealing to the Concept of Evolving Natural Configurations
TL;DR: This work shows how to develop rate-type fluid models that include the classical Burgers' model as well as variants of Burgers’ model using a thermodynamic approach based on constitutive assumptions for two scalar quantities and appealing to the concept of natural configuration associated with the placement of the body that evolves as the body deforms.
References
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Book
Non-Linear Elastic Deformations
TL;DR: In this paper, the influence of non-linear elastic systems on a simple geometric model for elastic deformations is discussed, and the authors propose a planar and spatial euler introduction to nonlinear analysis.
Journal ArticleDOI
On the Dynamical Theory of Gases
TL;DR: The theory of transport processes in gases, such as diffusion, heat conduction, and viscosity, is developed on the assumption that the molecules behave like point-centres of force as mentioned in this paper.
Journal ArticleDOI
On the Formulation of Rheological Equations of State
TL;DR: The invariant forms of rheological equations of state for a homogeneous continuum, suitable for application to all conditions of motion and stress, are discussed in this article, where the right invariance properties can most readily be recognized if the frame of reference is a co-ordinate system convected with the material.
Journal ArticleDOI
A thermodynamic frame work for rate type fluid models
TL;DR: In this paper, the authors develop a thermodynamic approach for modeling a class of viscoelastic fluids based on the notion of an evolving natural configuration, where the material has a family of elastic responses governed by a stored energy function that is parametrized by the ''natural configurations''. Changes in the current natural configuration result in dissipative behavior that is determined by a rate of dissipation function.