MSR/ressources/Rheology.md

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2024-10-15 08:56:10 +02:00
([livre](https://musee-stendhal.bm-grenoble.fr/detailstatic.aspx?RSC_BASE=SYRACUSE&RSC_DOCID=1066937&TITLE=initiation-a-la-rheologie-g-couarraze-j-l-grossiord&_lg=fr-FR) ISBN: 2-85206-660-2)
The study of the material properties that govern the flow and deformation of matter.
[[Continuum Mechanics]] is a foundation of rheology
The fundamental [[dynamics vs kinematics|dynamic physical quantity]] is the shear stress $\tau$, and the fundamentals kinematic physical quantities are shear strain $\varepsilon$ and the shear rate $\dot{\varepsilon}$ .
## Laminar shear displacement
The material presents a laminate structure, with infinity thin adjacent layers;
The strain occurs as a slipping of the different layers to each other, without transfer of matter between layers;
It is an ordered and layered movement, without mixage of the material nor variation of its volume.
-> friction between layers -> shear forces / unit of volume -> shear stress
## Boundary layer hypothesis
The layer of a material touching a solid surface is bound to it and moves with the same speed.
So between a moving plate and a static plate, the viscous materials follows a laminar shear displacement, and a gradient of speed appears between the boundary layers.
## Shear strain
$$\varepsilon(x,t)=\frac{du(x,t)}{dx}$$
With the x axis being the normal to the stacked layers. So $\varepsilon$ does not depends on the displacement $u$ but the variation of the displacement between two adjacent layers.
Usually the strain depends on the position within the material, but in some cases the variation of displacement between layers is constant, and depends only on time.
![[shear strain]]
## Shear rate
$$\dot{\varepsilon}=\frac{d\varepsilon}{dt}=\frac{d}{dt}\frac{du}{dx}=\frac{d}{dx}\frac{du}{dt}$$
so $\dot{\varepsilon}$ is often called the speed gradient, and denoted with the letter $D$
$$\dot{\varepsilon}(x,t)=\frac{dv(x,t)}{dx}$$
## Rheologic state equation
$$\varepsilon=f[\tau]$$
The goal of rheology is to find such an equation for a given material, through experiments. (also, $\varepsilon=f[\tau,P,T]$ would be more exact)
## Dynamic viscosity
$$\mu=\frac{\tau}{\dot{\varepsilon}}$$
Newtonian fluids have a $\mu$ than does not depend on shear stress, their dynamic viscosity is then called absolute viscosity and denoted $\eta$ . The rheologic state function of a Newtonian body is then :
$$\dot{\varepsilon}=\frac{\tau}{\eta}$$
## Linear viscosity
$\varepsilon=f[\tau]$ is linear
definitions :
- the creep function $f(t)$ is the strain when a constant unit stress is applied
- the relaxation function $g(t)$ is the stress when a constant unit strain is applied
$f$ and $g$ depends on the material and need to be determined experimentally
![[creep and relaxation]]
$$\varepsilon(t)=\tau(t)f(0)+\int_{0}^{t}\dot{f}(t-t')\tau(t')dt'$$
where
$$\dot{f}(u)\equiv \frac{df}{du}(u)$$
$$\tau(t)=\varepsilon(t)g(0)+\int_{0}^{t}\dot{g}(t-t')\varepsilon(t')dt'$$
where
$$\dot{g}(u)\equiv \frac{dg}{du}(u)$$
## Viscoelastic models
(see [[Viscoelasticity#Models]])