Isentropic Flow
Reference data and engineering information about isentropic flow for fluid mechanics applications.
Overview
Engineering reference data for Isentropic Flow in fluid mechanics.
Key Formulas
Reynolds Number
Ratio of inertial to viscous forces — determines flow regime.
Bernoulli's Equation
Conservation of energy for steady, inviscid, incompressible flow.
Continuity Equation
Conservation of mass for incompressible flow.
Darcy-Weisbach
Pressure drop due to friction in a pipe.
Variables
| Symbol | Description | Unit |
|---|---|---|
| Reynolds number | — | |
| Fluid density | kg/m³ | |
| Flow velocity | m/s | |
| Characteristic dimension | m | |
| Dynamic viscosity | Pa·s | |
| Pressure | Pa | |
| Darcy friction factor | — |
Derivation of Isentropic Relations
The condition for isentropic flow (ds = 0) is derived from the general entropy equation for a compressible fluid. For an ideal gas, this simplifies to:
Using the specific heat ratio and the ideal gas relation , equation (1) can be rearranged to establish the fundamental relationships between properties for an isentropic process:
From this, two common forms of the isentropic relationship are obtained:
Pressure-Density Relation:
Pressure-Specific Volume Relation: Using (where is specific volume, m³/kg), this becomes:
These equations (3, 4, 6) describe the essential state-to-state property relationships for an isentropic process in an ideal gas.