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Multiphase pipe flows Physical phenomena Modelling approaches.

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Presentation on theme: "Multiphase pipe flows Physical phenomena Modelling approaches."— Presentation transcript:

1 Multiphase pipe flows Physical phenomena Modelling approaches

2 Horizontal gas-liquid flow patterns
Dispersed Bubble Flow Stratified Flow Stratified–Wavy Flow Plug Flow Slug Flow Annular–Dispersed Flow Benjamin bubble

3 Vertical gas-liquid flow patterns
Bubble Flow Plug or Slug Flow Churn Flow Annular Flow Wispy Annular Flow B P/S C A WA Taylor bubble Links point to

4 The effect of pipe inclination
Θ = +10°

5 The effect of pipe inclination
Θ = +2°

6 The effect of pipe inclination
Θ = +0.25°

7 The effect of pipe inclination
Θ = 0°

8 The effect of pipe inclination
Θ = −1°

9 The effect of pipe inclination
Θ = − 5°

10 The effect of pipe inclination
Θ = − 10°

11 Relative flow directions
Co-current flow (as shown above) Counter-current flows (one of the mass flow rates is negative): some of the flow patterns exist with opposite flow directions too Somewhat analogous flow patterns can be identified in liquid-liquid, liquid-solid and gas-solid systems

12 Even more complex flow patterns in three phase pipe flows
Flow classification is somewhat arbitrary and subjective in pipes hardly possible in 3D containers Further points to observe: Heat transfer phenomena Phase transition phenomena

13 Pipe flow modelling alternatives
Flow patterns Flow regimes Flow pattern maps Tasks: Model flow region boundaries Model flow behaviour within each flow region Create a single one fluid model that can correctly reflect fluid behaviour in all flow regimes and thus automatically describes flow pattern transitions

14 Parameters of one-phase pipe flow
Control (input) parameters: Pipe geometry shape size inclination wall roughness Mass flow rate Fluid properties External heat source Measured (output) parameters: Pressure drop Transported heat

15 Parameters of two-phase pipe flow
Control (input) parameters: Pipe geometry shape size inclination wall roughness Mass flow rates Fluid properties External heat source Measured (output) parameters: Pressure drop Volume (void) fraction Interfacial area density Transported heat

16 Model variables in pipe systems
Cross sectional integral quantities linear densities flow rates Cross sectional average (‘mean`) quantities ‘mean` densities ‘mean` fluxes Purpose: reduction of independent variables: (t,x,y,z)  (t,x)

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