A limited comparison of flowmeter principles – regarding service, rangeability, pressure loss, typical accuracy, upstream pipe diameters, viscosity and relative costs.
Electromagnetic flow meters – or induction flow meters – function with conductive fluids by measuring flow across a controlled magnetic field.
Mass flow meters based on the Coriolis effect.
Mass flow meters based on the thermal cooling effect of the flowing fluid.
With orifice flow meters the pressure difference over an orifice in the flow is measured. Measured pressure difference is proportional with flow velocity squared.
Turbine flow meters are made with bladed turbine rotors mounted axially in the meter. When fluid flows through the meter the rotor spins at a speed proportional to the velocity of the fluid. The spin is detected with a magnetic pick up with typically a pulse output.
Ultrasonic flow meters are non-invasive volume flow meters based on transit-time (Time of travel) or Doppler effect technology. A transit-time flow meter measures the frequency shift (difference) between upstream and downstream ultrasonic pulses projected into and across the pipe. The frequency shift is proportional to flow velocity. A Doppler flow meters measure the frequency shift when an ultrasonic signal is reflected by suspended particles or gas bubbles in motion. The frequency shift is proportional to flow velocity.
Vortex flow meters are made with an obstruction object mounted in flow. When fluid flows through the meter an alternating vortex is created downstream the object. The vortex frequency is proportional with the flow and is detected with a pressure sensor, thermistor or ultrasonic sensor.
Wedge is used as primary element in flow measurement of liquid, gas and steam according to the differential pressure principle.
A V-cone flow meter a differential pressure instrument where the differential pressure is measured before and after a cone located in the flow.
