Load cells
A load cell is a transducer which emits an electrical signal when a load is applied. The electrical signal is proportional to the force being applied. Strain gauge load cells work in a similar way to the paddle consistency meters. The electrical signal can be calibrated to measure the weight/ fill capacity of a tank or hopper. Some starch mixing tanks, for example, use load cells to weigh the amount of starch for each batch.
The downside to load cells are, they have to be mounted in such a way that all of the weight/ load is on the load cell. The load cell can become deformed/ inaccurate if the transmitter is overloaded and as such fail-safes have to be fitted to prevent overloads. After a time the load cell loses its accuracy due to constant deformation of the transducer. Compared with the ultrasonic level transmitter the operating range is low.
Ultrasonic level transmitter
If the tank, when empty took 5 mili seconds to send and receive the signal, at 50% fill volume the transmitter would record a 2.5 mili second delay.
Ultrasonic transmitters have a high rate of accuracy and tend to maintain their calibration over time. The transmitter can work on lower ranges than load cell transmitters.
The disadvantage of ultrasonic transmitters can be the substance you're trying to measure, for example in a starch silo lots of dust is produced when filling. this dust can obstruct the ultrasonic transmitter giving a false or erratic reading
Guided wave radar
fundamentals of guided wave radar level measurement come directly from Time Domain Reflectometry (TDR), a technology that has been employed for decades to find breaks in underground cables and in-wall cable installations in large buildings. TDR instruments launch low amplitude, high-frequency pulses onto the transmission line, cable, or waveguide under test, and then sequentially sample the reflected signal amplitudes.
Guided wave Transmitters work on a similar principle as ultrasonic transmitters. the only difference is how the wave is emitted. the radar wave is sent through a "cable probe" that spans the height of the tank for example. the radar wave travels down the cable and reflects back. the transmitter uses time of flight principle to calculate a level.
the pulses traveling through the probe are disturbed by the liquid or dry powder medium and reflects the signal back early giving a level reading.
Guided wave Transmitters work on a similar principle as ultrasonic transmitters. the only difference is how the wave is emitted. the radar wave is sent through a "cable probe" that spans the height of the tank for example. the radar wave travels down the cable and reflects back. the transmitter uses time of flight principle to calculate a level. the pulses traveling through the probe are disturbed by the liquid or dry powder medium and reflects the signal back early giving a level reading.
Hydrostatic Transmitters
Hydrostatic transmitters are similar construction to pressure transmitters. the transmitter design is the same the application and calculations behind the transmitter vary. Placed at the 0 level of a tank or silo the hydrostatic transmitter will measure a hydrostatic head or "total head pressure" which is basically the pressure exerted by the water column in the tank.
So, the filling height is calculated from the distance of the medium surface to the measuring point by the pressure measurement. The weight force of the liquid column, thus the hydrostatic pressure, however, is not only directly proportional to the filling height but also varies with the specific gravity of the medium and the force of gravity.
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