Skip to main content
Speclore

Water Flow Measurement

Reference data and engineering information about water flow measurement for fluid mechanics applications.

waterflowmeasurement

Overview

Engineering reference data for Water Flow Measurement in fluid mechanics.

Key Formulas

Reynolds Number

Re=ρvDμRe = \frac{\rho v D}{\mu}

Ratio of inertial to viscous forces — determines flow regime.

Bernoulli's Equation

P+12ρv2+ρgh=constP + \frac{1}{2}\rho v^2 + \rho g h = \text{const}

Conservation of energy for steady, inviscid, incompressible flow.

Continuity Equation

A1v1=A2v2A_1 v_1 = A_2 v_2

Conservation of mass for incompressible flow.

Darcy-Weisbach

ΔP=fLDρv22\Delta P = f \frac{L}{D} \frac{\rho v^2}{2}

Pressure drop due to friction in a pipe.

Variables

SymbolDescriptionUnit
ReReReynolds number
ρ\rhoFluid densitykg/m³
vvFlow velocitym/s
DDCharacteristic dimensionm
μ\muDynamic viscosityPa·s
PPPressurePa
ffDarcy friction factor

Common Water Flow Measurement Devices

The USBR manual describes several standard devices for measuring irrigation water. Key types include:

  • Weirs (sharp-crested, broad-crested): Structures over which water flows, with flow rate calculated from upstream head.
  • Flumes (Parshall, Cutthroat, HSMB): Constricted channel sections that accelerate flow, creating a unique head-discharge relationship.
  • Orifices (submerged, unsubmerged): Precisely sized openings in a bulkhead or pipe, with flow proportional to the square root of head.
  • Meters (propeller, electromagnetic, ultrasonic): Inline instruments that measure velocity or volume directly.

Key Formulas for Primary Devices

The fundamental equations for calculating discharge (QQ) from head (HH) for common devices are:

For a rectangular weir (Thomson's formula): Q=Cd232gbH3/2Q = C_d \frac{2}{3} \sqrt{2g} \cdot b \cdot H^{3/2}

For a Parshall flume (free-flow discharge): Q=CHnQ = C \cdot H^n where CC and nn are constants specific to the flume size.

For a submerged circular orifice: Q=CdA2gHQ = C_d A \sqrt{2gH} where AA is the orifice area.

Selection Criteria

Choosing the appropriate device depends on several factors:

  1. Flow Range: The device must handle expected minimum and maximum flows.
  2. Accuracy Requirements: Applications range from ±2% (high-value water) to ±10% (general irrigation).
  3. Head Loss: Available hydraulic gradient; flumes typically cause less head loss than weirs.
  4. Sediment & Debris Load: Orifices are prone to clogging; flumes perform better in sediment-laden canals.
  5. Maintenance & Inspection Access: Devices require periodic cleaning and calibration checks.

Definitions of Critical Terms

  • Head (HH): The vertical distance from the water surface upstream of the device to a specific measurement point (e.g., weir crest or flume throat).
  • Discharge Coefficient (CdC_d): An empirical factor that accounts for energy losses and the contraction of the flow stream. It is device-specific and varies with Reynolds number.
  • Free Flow: Flow condition where the downstream water level does not affect the discharge measurement.
  • Submerged Flow: Flow condition where the downstream water level is high enough to reduce the discharge through the device for a given upstream head.

References