One of the key challenges in Pipe Flow Dynamics is to predict the along-hole pressure distribution during the stationary fluid transport.
The
In many practical cases the stationary pressure distribution can be approximated by Isothermal or Quasi-isothermal homogenous fluid flow model.
Pipeline Flow Pressure Model is addressing this problem with account of the varying pipeline trajectory, gravity effects and fluid friction with pipeline walls.
Inputs | Outputs |
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Pipeline trajectory | along-pipe stabilized pressure distribution |
along-pipe stabilized flowrate distribution | |
Along-pipe temperature profile | along-pipe stabiliszed average flow velocity distribution |
Intake pressure , | |
Intake rate | |
Inner pipe wall roughness |
Stationary fluid flow | Homogenous fluid flow | Isothermal or Quasi-isothermal conditions | Constant cross-section pipe area along hole |
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(see Derivation of Stationary Isothermal Homogenous Pipe Flow Pressure Profile @model )
Pressure profile | Pressure gradient profile | Fluid velocity | Fluid rate | ||||
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where
correction factor for trajectory deviation |
The first term in defines the hydrostatic column of static fluid while the last term defines the friction losses under fluid movement:
In most practical applications in water producing or water injecting wells the water can be considered as incompressible and friction factor an be assumed constant along-hole ( see Darcy friction factor in water producing/injecting wells ).
Physics / Fluid Dynamics / Pipe Flow Dynamics / Pipe Flow Simulation
[ Darcy friction factor ] [ Darcy friction factor @model ] [ Derivation of Stationary Isothermal Homogenous Pipe Flow Pressure Profile @model ]
[ Homogenous Pipe Flow Temperature Profile @model ]
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