Outputs

$\begin{array}{l}\{ s_\alpha \}_{\alpha=1..n}\end{array}$	phase holdup
$\begin{array}{l}\{ q_\alpha \}_{\alpha=1..n}\end{array}$	phase volumetric flowrate

Inputs

$\begin{array}{l}A\end{array}$	pipe cross-sectional area
$\begin{array}{l}\{ \dot m_\alpha \}_{\alpha = 1..n}\end{array}$	phase mass flowrates
$\begin{array}{l}\{ \rho_\alpha \}_{\alpha = 1..n}\end{array}$	phase densities

Solver

(1)	$\begin{array}{l}\displaystyle s_\alpha = \frac{\dot m_\alpha}{\rho_\alpha \, u_\alpha} \cdot \left( \sum_\beta \frac{\dot m_\beta}{\rho_\beta \, u_\beta} \right)^{-1}\end{array}$

(2)	$\begin{array}{l}\displaystyle q_\alpha = s_\alpha \, u_\alpha \, A\end{array}$

Derivation

Given the multiphase flow of $\begin{array}{l}n\end{array}$ phases: $\begin{array}{l}\alpha = 1..n\end{array}$ and mass flowrates $\begin{array}{l}\dot m_\alpha\end{array}$

(3)	$\begin{array}{l}\displaystyle \dot m = \sum_\alpha \dot m_\alpha\end{array}$

(4)	$\begin{array}{l}\displaystyle A = \sum_\alpha A_\alpha\end{array}$

(5)	$\begin{array}{l}\displaystyle \sum_\alpha s_\alpha = 1\end{array}$

(6)	$\begin{array}{l}\displaystyle u_m = \sum_\alpha s_\alpha \cdot \dot u_\alpha\end{array}$

(7)	$\begin{array}{l}\displaystyle q_\alpha = \dot m_\alpha / \rho_\alpha = A_\alpha \, u_\alpha \Rightarrow \dot m_\alpha = \rho_\alpha \, A_\alpha \, u_\alpha\end{array}$

For homogeneous pipe flow: $\begin{array}{l}u_\alpha = u_m, \, \forall \alpha \in [1..n]\end{array}$ and volumetric shares are going to be:

(8)	$\begin{array}{l}\displaystyle s_\alpha = \frac{\dot m_\alpha}{\rho_\alpha} \cdot \left( \sum_\beta \frac{\dot m_\beta}{\rho_\beta} \right)^{-1}\end{array}$

Page tree

Outputs

Inputs

Solver

Derivation

See also

Page tree

Multiphase Pipe Flow

Outputs

Inputs

Solver

Derivation

See also