Flow Meters Turndown Ratio
Reference data and engineering information about flow meters turndown ratio for fluid mechanics applications.
Overview
Engineering reference data for Flow Meters Turndown Ratio 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 | — |
Turndown Ratio - Rangeability
The turndown ratio (TR), or rangeability, compares the span of a flow measurement device. It is expressed as:
Where:
- = Turndown Ratio
- = Maximum flow (within specified accuracy and repeatability)
- = Minimum flow (within specified accuracy and repeatability)
Turndown Ratio Example: Orifice Meter
For an orifice meter with a maximum flow of 12 kg/s and a minimum flow of 3 kg/s, the turndown ratio is:
This is typically expressed as a turndown ratio of 4:1. In general, orifice plates have a turndown ratio between *3:1 and 5:1.
Turndown Ratio and Measurement Signal
Flow meters based on differential pressure principles (e.g., orifice or venturi) use the pressure drop across an obstruction to indicate flow rate. According to the Bernoulli equation, the differential pressure increases with the square of the flow velocity.
This relationship means that a large turndown ratio can cramp the measurement signal at low flow rates, potentially reducing accuracy and sensitivity in the lower end of the measurement range.
Variables
| Symbol | Description | Unit (Example) |
|---|---|---|
| TR | Turndown Ratio | - |
| q_max | Maximum Flow Rate | kg/s, m³/h |
| q_min | Minimum Flow Rate | kg/s, m³/h |