Integral to process control in many industries, level measurement sensors fall into two main types. Point level measurement sensors are used to mark a single discrete liquid height–a preset level condition. Generally, this type of sensor functions as a high alarm, signaling an overfill condition, or as a marker for a low alarm condition. Continuous level sensors are more sophisticated and can provide level monitoring of an entire system. They measure fluid level within a range, rather than at a one point, producing an analog output that directly correlates to the level in the vessel. To create a level management system, the output signal is linked to a process control loop and to a visual indicator.
What is a Float Switch?
In these point level sensors, a magnetic float moves with the liquid surface, actuating a hermetically sealed "reed switch" in the stem. The simple, low-maintenance design installs readily; minimizes shock, vibration, and pressure; and works with a variety of media. The reed switch can be single pole, single throw (SPST) or single pole, double throw (SPDT).
Non-Contact Ultrasonic Sensors for Level Measurement
These sensors incorporate an analog signal processor, a microprocessor, binary coded decimal (BCD) range switches, and an output driver circuit. Transmit pulses and a gate signal from the microprocessor route through the analog signal processor to the sensor, which sends an ultrasonic beam to the liquid surface. The sensor detects the echo from the surface and routes it back to the microprocessor for a digital representation of the distance between the sensor and the surface level. Through constant updating of received signals, the microprocessor calculates averaged values to measure liquid level.
With a continuous sensor, the microprocessor converts the averaged value to an analog 4 to 20 mA signal linear with the liquid level. When the echo from the level does not return to the sensor within 8 seconds, the output signal from the system drops below 4 mA, indicating a low-level condition or empty pipe. With a point sensor, the microprocessor compares the averaged value with the BCD switch setting and energizes an output relay for either high or low level indication. A signal loss exceeding 8 seconds de-energizes the relays and restores their original state. The electronics incorporate a half-second delay that minimizes surface turbulence effects.
Contact Ultrasonic Sensors for Level Measurement Applications
A low-energy ultrasonic device within these sensors measures liquid level at a certain point. Consisting of a field-mounted sensor and integral solid state amplifier, contact ultrasonic sensors have no moving parts and require no calibration. Typically, they are equipped with terminal blocks for connection of a power source and external control devices. The ultrasonic signal crosses a one-half inch gap in the sensor, controlling relay switches when the gap contains liquid. The sensing level is midway along the gap for horizontally mounted sensors, at the top of the gap for vertically mounted sensors. As liquid falls below this level, the ultrasonic signal attenuates and ultimately switches the relay to its prior state.
These sensors are used in vessels or pipes to automatically operate pumps, solenoid valves, and high/low alarms. Two would be required to fill and empty tanks, and to meter liquid volumes. Compatible with most liquids, they are unaffected by coatings, clinging droplets, foam, and vapor. However, highly aerated liquids and liquids viscous enough to clog the sensor gap may cause problems.
Capacitance Level Sensors
Like ultrasonic sensors, capacitance sensors can handle point or continuous level measurement. They use a probe to monitor liquid level changes in the tank, electronically conditioning the output to capacitive and resistive values, which are converted to analog signals. The probe and the vessel wall equate to two plates of a capacitor, the liquid to the dielectric medium. Because the signal emanates from level changes alone, material build-up on the probe has no effect. Non-conductive fluid vessels may dictate dual probes or an external conducting strip.
The probe, which can be rigid or flexible, commonly employs conducting wire insulated with PTFE. Using stainless steel as the probe's base metal provides the extra sensitivity needed for measuring liquids that are non-conductive, granular, or low in dielectric properties (dielectric constant less than 4). Flexible probes must be used when there is insufficient clearance for a rigid probe, or in applications that demand very long lengths. Rigid probes offer higher stability, especially in turbulent systems, where swaying of the probe can cause signal fluctuations.