Transit-time Flow meter
Applications:
u Water (hot water, cooling water, potable water, sea water etc.)
u Petroleum products
u Chemicals, including alcohol, acids, etc
u HVAC, energy measurement system
u Beverage, food and pharmaceutical processors
u Secondary sewage, waste treatment, etc.
u Power plants (nuclear power plants, thermal & hydropower plants), heat energy boiler feed water.
u Metallurgy and miming applications
u Pipeline leak detection, inspection, tracking and collection
u
Principle of Measurement
The transit time flow meter utilizes two transducers that function as both ultrasonic transmitters and receivers. The transducers are clamped on the outside of a closed pipe at a specific distance from each other. The transducers can be mounted in V-method in which case the ultra sound transverses the pipe twice, or W-method in which case the ultra sound transverses the pipe four times, or in Z-method in which case the transducers are mounted on opposite sides of the pipe and the ultra sound transverses the pipe only once. The selection of mounting method depends on pipe and liquid characteristics. When flow meter works, two transducers transmit and receive the ultrasonic signal which travels firstly downstream and then travels upstream (Figure 1). Because ultra sound travels faster downstream than upstream, there will be a difference of time of flight (△t). When the flow is still, the time difference(△t) is zero. Therefore, as long as we know the time of flight both downstream and upstream, we can work out the time difference, and then the flow velocity (V) and flow volume (Q) via the following formula.
Where:
V: Liquid velocity
K: Constant
D: Distance between the two transducers
dt: difference in time of flight
Advantages
- No Moving Parts.
- External Clamp On, no need to cut into the lines or shut the process down to install.
- High Accuracy, 1% of reading.
- Very sensitive to low flow measurement.
- Field Programmable can be used on pipes from 1" up to 200".
- Digital Signals will NOT Drift.
- Measures virtually ANY liquid that is sonically conductive.
Disadvantages
- Requires full pipe.
- Old or corroded pipes may impede acoustic signal.
- Too much aeration or turbulence can destroy signal.
- Doppler Flow Meter
Applications:
u Raw sewage
u Activated sludge
u Ground water
u Pulp and paper slurries
u Chemical slurries
u Drainage
u Mining recirculation
Principle of Measurement
The flow meter operates by transmitting an ultrasonic sound from its transmitting transducer, the sound will be reflected by useful sonic reflectors suspended within the liquid and recorded by the receiving transducer. If the sonic reflectors are moving within the sound transmission path, sound waves will be reflected at a frequency shifted (Doppler frequency) from the transmitted frequency. The shift in frequency will be directly related to the speed of the moving particle or bubble. This shift in frequency is interpreted by the instrument and converted to various user defined measuring units.
There must be some particles large enough to cause longitudinal reflection – particles larger than 100 micron.
When install the transducers, the installation location must have enough straight pipe length upstream and downstream. Commonly, the upstream needs 10D and downstream needs 5D straight pipe length, where D is pipe diameter.
The Doppler ultrasonic flow meter is designed to measure volumetric flow of liquid within closed conduit, the pipe line must be full of liquids, and there must be a certain amount of air bubbles or suspended solids in liquid.
Transducers are clamp-on or hot-tapped insertion types, user don’t need to shut down the pipe flow when install transducers.
Advantages
- Doppler meters may be used where other meters don't work. This might be liquid slurries, aerated liquids or liquids with some small or large amount on suspended solids. The advantages can be summarized to:
- Obstruct less flow
- Can be installed outside the pipes
- The pressure drop is equal to the equivalent length of a straight pipe
- Low flow cut off
- Corrosion resistant
- Relative low power consumption
Disadvantages
- Can’t measure the clean liquid.
- Unsuitable for highly accurate measurement applications.
