Ergun

Chemical Reactor Design Toolbox Reference Manual

ChemReactorDesign.Basic.Liquid.Transport.Ergun

Ergun.svg

Description

The component generates a volumetric flow rate due to a pressure difference between the ports for flow in a porous medium (after Ergun). To allow for a change in sign upon reversal of flow direction and to eliminate singularities due to flow reversal a modified relation is used

\begin{equation*} \Delta p = 150 \frac{(1-\overline{\varepsilon})^2} {\overline{\varepsilon}^3} \frac{\mu}{d_p^2} \, \frac{L}{A} + 1.75 \frac{(1-\overline{\varepsilon})} {\overline{\varepsilon}^3} \frac{\rho}{d_p} \, \frac{L}{A^{2}} \, q \, \sqrt{q^{2} + q_{small}^{2}} \end{equation*}

Then the molar flow rates become

\begin{equation*} F_{i} = q \, \left(c_{i}\right)_{upstream} \end{equation*}

The energy flow rate is determined as

\begin{equation*} \Phi = \sum_{i}^{N} F_{i} \, \left({\overline H}_{i}(T)\right)_{upstream} + F_{tot} \, \Big(H_{res}(T,p)\Big)_{upstream} \end{equation*}

with

\begin{equation*} F_{tot} = \sum_{i}^{N} F_{i} \end{equation*}

The positive flow direction is from port A to port B.

Ports

Conserving

  • Liquid conserving port 

    Port_A = Liquid;  %

  • Liquid conserving port 

    Port_B = Liquid;  %

Input

  • Physical signal that represents the cross sectional area 

    Ain = {0,'m^2'};

    Dependencies: The port is only visible when areaInput is set to On.

  • Physical signal that represents the voidage 

    epsbIn = {1,'1'};

    Dependencies: The port is only visible when inputPorosity is set to On.

Output

  • Physical signal that represents the volumetric flow rate at upstream conditions 

    qout = {1,'l/s'};

    Dependencies: The port is only visible when flowOutput is set to On.

Parameters

Options

  • Option to select porosity input 

    porosityInput = OnOff.Off;

    On | Off

  • Option to select area input 

    areaInput = OnOff.Off;

    On | Off

  • Option to select flow output 

    flowOutput = OnOff.Off;

    On | Off

Geometry

  • Cross sectional area 

    A0 = {1,'m^2'};

    Dependencies: The parameter is only visible when areaInput is set to Off.

  • Transport distance 

    delta  = {1.0e-03,'m'};

Mass Transport

  • Voidage fraction 

    epsb = {1,'1'};

    Dependencies: The parameter is only visible when inputPorosity is set to Off.

  • Particle diameter 

    dp = {1.0e-06,'m'};

Nomenclature

\(A\) cross sectional area
\(c_{i}\) concentration of species Ai
\(d_{p}\) particle diameter
\(F_{i}\) molar flow rate of species Ai
\({\overline H}_{i}(T)\) molar enthalpy of species Ai
\(\Delta H_{res}\) departure enthalpy of the mixture
\(L\) length
\(N\) total number of species
\(q\) volumetric flow rate
\(t\) time
\(T\) temperature
\(\overline \varepsilon\) voidage (porosity)
\(\rho\) density
\(\mu\) viscosity
\(\Phi\) energy flow rate