Dimensionless Numbers: Difference between revisions

Revision as of 13:15, 2 June 2015

Froude Number

Definition: $Fr=\propto \left[{\frac {\rho U^{2}/l}{\rho g}}\right]^{1/2}={\frac {U}{\sqrt {gl}}}$ , where $g$ is the gravitational acceleration, and $U$ and $l$ are the characteristic velocity and length scales.
Interpretation: The square root of the ratio of inertia force to gravity force.
Analysis: The Froude number describes different regimes of open channel flow, including hydraulic jumps. $Fr=1$ describes critical flow; $Fr>1$ describes supercritical flow; $Fr<1$ describes subcritical flow. The Froude number is analogous to the Mach number in compressible flow.

Grashof Number

Definition: $Gr={\frac {g\beta \Delta TV}{\nu ^{2}}}$ , where $g$ is the gravitational acceleration, $\beta$ is the volumetric thermal expansion coefficient, $\Delta T$ is the temperature differrence, $V$ is the volume, and $\nu$ is the kinematic viscosity.
Interpretation: The ratio of buoyant forces to viscous forces.
Analysis: When $Gr\gg 1$ , the viscous force is negligible compared to the buoyancy and inertial forces, and the flow starts a transition to the turbulent regime.

Mach Number

Definition: $M=U/c$ , where $U$ is the characteristic velocity scale, and $c$ is the speed of sound.
Interpretation: The ratio of inertia force to compressibility force.
Analysis: Compressibility effects can be neglected if $M<0.3$ .

Prandtl Number

Definition: $Pr=\nu /\kappa$ , where $\nu$ is the viscosity, and $\kappa$ is the thermal diffusivity.
Interpretation: The ratio of momentum diffusivity (i.e. kinematic viscosity) to heat diffusivity.
Analysis: The typical Prandtl number for water is around 7 for water (At 20 degrees Celsius). See also Schmidt number.

Reynolds Number

Definition: $Re={\frac {UL}{\nu }}$ , where $U$ and $L$ are the characteristic velocity and length scales, and $\nu$ is the kinematic viscosity.
Interpretation: The ratio of inertia force to viscous force.
Analysis: Small Reynolds numbers are often associated with viscous flows, whereas large Reynolds numbers are typically found in turbulent flows.

Richardson Number (flux)

Definition: $Rf={\frac {-g\alpha {\overline {wT'}}}{-{\overline {uw}}U_{z}}}$ , where the overlines denote the ensemble averages of variables.
Interpretation: The ratio of the buoyant destruction of turbulent kinetic energy to the shear production.
Analysis: The flux Richardson number is related to the gradient Richardson number by $Ri={\frac {\nu _{T}}{\kappa _{T}}}Rf$ , where the ratio $\nu _{T}/\kappa _{T}$ is the turbulent Prandtl number.

Richardson Number (gradient)

Definition: $Ri=N^{2}/U_{z}^{2}$ , where $N$ is the buoyancy frequency, and $U$ is the background horizontal velocity.
Interpretation: The ratio between the strength of stratification and velocity shear.
Analysis: The gradient Richardson number is used for determining the linear stability of an inviscid stratified flow. A sufficient condition for the flow to be linearly stable is that the local Richardson number exceed 0.25 throughout the flow. However, $Ri<0.25$ does not mean the flow is necessarily unstable (the criterion is not sufficient). When the flow is not a parallel shear flow, the meaning of $Ri$ is not clear.

Rossby Number

Definition: $Ro={\frac {U}{fL}}$ , where $U$ is the characteristic velocity, and $f$ is the Coriolis frequency, and $L$ is the characteristic length scale.
Interpretation: The ratio of the advective forces to the Coriolis pseudo-forces.
Analysis: When $Ro\ll 1$ , Coriolis effects dominate and the system approaches geostrophic balance.

Schmidt Number

Definition: $Sc=\nu /\kappa$ , where $\nu$ is the viscosity, and $\kappa$ is the mass diffusivity.
Interpretation: The ratio of momentum diffusivity (i.e. kinematic viscosity) to mass diffusivity.
Analysis: The typical Schmidt number for water is around 500, depending on the temperature and salinity. For direct numerical simulations, $Sc=1$ is commonly used in the literature. See also Prandtl number.

@@ Line 1: / Line 1: @@
+<div id="Fr"></div>
+;'''Froude Number'''
+* Definition: <math> Fr = \propto \left[ \frac{\rho U^{2}/l}{\rho g}\right] ^{1/2} = \frac{U}{\sqrt{gl}} </math>, where <math> g </math> is the gravitational acceleration, and <math> U </math> and <math> l </math> are the characteristic velocity and length scales.
+* Interpretation: The square root of the ratio of inertia force to gravity force.
+* Analysis: The Froude number describes different regimes of open channel flow, including hydraulic jumps. <math> Fr = 1 </math> describes critical flow; <math> Fr > 1 </math> describes supercritical flow; <math> Fr < 1 </math> describes subcritical flow. The Froude number is analogous to the [[#M|Mach number]] in compressible flow.
 <div id="Gr"></div>
 ;'''Grashof Number'''
@@ Line 27: / Line 33: @@
 * Definition: <math> Rf = \frac{-g\alpha\overline{wT'}}{-\overline{uw}U_z} </math>, where the overlines denote the ensemble averages of variables.
 * Interpretation: The ratio of the buoyant destruction of turbulent kinetic energy to the shear production.
-* Analysis: It is related to the [[#Ri|gradient Richardson number]] by <math> Ri = \frac{\nu_T}{\kappa_T}Rf </math>, where the ratio <math> \nu_T/\kappa_T </math> is the ''turbulent [[#Pr|Prandtl number]]''.
+* Analysis: The flux Richardson number is related to the [[#Ri|gradient Richardson number]] by <math> Ri = \frac{\nu_T}{\kappa_T}Rf </math>, where the ratio <math> \nu_T/\kappa_T </math> is the ''turbulent [[#Pr|Prandtl number]]''.
 <div id="Ri"></div>
@@ Line 33: / Line 39: @@
 * Definition: <math> Ri = N^2/U_z^2 </math>, where <math> N </math> is the [[Glossary#Buoyancy Frequency|buoyancy frequency]], and <math> U </math> is the background horizontal velocity.
 * Interpretation: The ratio between the strength of stratification and velocity shear.
-* Analysis: A sufficient condition for the flow to be ''linearly stable'' is that the local Richardson number exceed 0.25 throughout the flow. However, <math> Ri < 0.25 </math> does not mean the flow is necessarily unstable (the criterion is not sufficient). When the flow is not a parallel shear flow, the meaning of <math> Ri </math> is not clear.
+* Analysis: The gradient Richardson number is used for determining the linear stability of an inviscid stratified flow. A sufficient condition for the flow to be ''linearly stable'' is that the local Richardson number exceed 0.25 throughout the flow. However, <math> Ri < 0.25 </math> does not mean the flow is necessarily unstable (the criterion is not sufficient). When the flow is not a parallel shear flow, the meaning of <math> Ri </math> is not clear.
 <div id="Ro"></div>

Dimensionless Numbers: Difference between revisions

Revision as of 13:15, 2 June 2015

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