Guided wave radar technology is suitable for the continuous level measurement of liquids and bulk solids. Unaffected by shifts in pressure, temperature or product specific gravity, this technology is ideal for applications with a variety of process applications.
MAGNETIC LEVEL INDICATOR/BRIDLE
Magnetic Level Indicators (MLI) have revolutionized the global visual indication market by offering a safer, reliable, and high-visibility alternative to common gauge glass assemblies. Utilizing a combination of proven buoyancy principles along with the benefits magnetism, MLIs can be customized to fit virtually any process connection arrangement on the vessel. The chamber and magnetic float is available in a variety of materials and pressure ratings to accommodate the wide variety of complex process applications present in the world’s major industrial facilities.
A low-energy pulse, generated by the JUPITER electronics, travels the length of the magnetostrictive wire. A return signal is generated from the precise location where the magnetic field of a float intersects the wire. A timer precisely measures the elapsed time between the generation of the pulse and the return of the acoustic signal. Each cycle occurs ten times per second, providing real-time and highly accurate level data.
Nuclear (radiation-based) technology is ideal for the continuous, non-contact level measurement of liquids and bulk solids under extreme process conditions. Measurement is independent of pressure, temperature and product properties and can be installed on the outside of process vessels during ongoing production.
Pulse Burst Radar emits short bursts of energy to a liquid surface. Ultra-high-speed timing circuitry measures the time of the signal reflected off the liquid surface.
In Radio Frequency/Capacitance, the liquid acts as an isolator between two conductors (probe and tank wall). When level rises, there is more gain of capacity into an analog or digital signal.
The level measurement is made by emitting an ultrasonic pulse from the transducer, then measuring the time required for the echo to reflect from the liquid surface and return to the transducer. The powerful electronics measure the time of the round trip pulse and, by knowing the speed of sound, calculate the distance.
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