Motivation

Numerical quadrature solution of  Pressure Profile in Homogeneous Steady-State Pipe Flow @model


Outputs

Pressure distribution along the pipe

Flowrate distribution along the pipe

Flow velocity distribution along the pipe

Inputs

Intake temperature 

Along-pipe temperature profile 

Intake pressure 

Fluid density 

Intake flowrate 

Fluid viscosity 

Pipeline trajectory TVDss

Pipe cross-section area  

Pipeline trajectory inclination, 

Inner pipe wall roughness

Assumptions

Steady-State flowQuasi-isothermal flow

Homogenous flow

Constant cross-section pipe area along hole

Constant inclination



Equations

Pressure profile along the pipe


L = L(p) = \int_{p_0}^{p} \frac{ \rho(p) - j_m^2 \, c(p) }{G \, \rho^2(p) - F(\rho(p))} \, dp



where

mass flux

mass flowrate

Intake volumetric flowrate

Intake fluid density 

elevation drop along pipe trajectory

Darcy friction factor 

Reynolds number in Pipe Flow

dynamic viscosity as function of fluid temperature  and density 

fluid compressibility

characteristic linear dimension of the pipe

(or exactly a pipe diameter in case of a circular pipe)

gravity acceleration along pipe 





See Derivation of Pressure Profile in G-Proxy Pipe Flow @model



Alternative forms

Density form


L = L(\rho) =\int_{\rho_0}^{\rho} \frac{ 1/c(\rho) - j_m^2/\rho  }{G \, \rho^2 - F(\rho)} \, d\rho


Pressure-Density form


L = \int_{p_0}^{p} \frac{ \rho \, dp}{G \, \rho^2 - F(\rho)} 
- j_m^2 \cdot \int_{\rho_0}^{\rho} \frac{1}{\rho} \, \frac{d \rho}{G \, \rho^2 - F(\rho)}

This form is useful for derivation of Pressure Profile in GF-Proxy Pipe Flow @model 


Approximations

Pressure Profile in GF-Proxy Pipe Flow @model


See also

Physics / Fluid Dynamics / Pipe Flow Dynamics / Pipe Flow Simulation / Pressure Profile in Homogeneous Quasi-Isothermal Steady-State Pipe Flow @model

Pressure Profile in GF-Proxy Pipe Flow @model ]