Hydrostatic level sensors (generally known as submersible pressure transmitter) are very often installed in outdoor applications, primarily in the water and wastewater industries, where open bodies of water, deep wells or boreholes are monitored. An excellent connection to ground is vital when installing hydrostatic level sensors, since no grounding or poor grounding can lead to destruction or damage to the level sensor.
Common failures from improper grounding
Hydrostatic level sensors in outdoor applications are connected via cables to the PLC or routed to local telemetric systems. These cables can become an antenna, conducting electromagnetic or aerial voltage spikes down the wires to the sensor, causing an overload in the electronics and thereby premature failure. The media that’s measured may itself store energy like a capacitor. This is due to lightning strikes, electrical surges or simply static electricity. When there is not just a sufficiently low impedance ground connection for the level sensor, this might cause voltage surges that flash through the electronics causing them to overload and burn out.
Even though the voltage difference is too low to cause an overload of the electronics, it can cause electrolytic action because of the difference in voltage potential. This electrolytic action causes the metal housing material of the hydrostatic level sensor to be ? Elite away? over long-term operation. Electrolytic corrosion pits will form in the material that may cause the diaphragm or housing to perforate, ultimately causing premature failure of the level sensor. This may be mistaken for chemical corrosion but is, actually, due to the difference in voltage potential between the sensor and the surrounding liquid. With out a good ground the sensor becomes a sacrificial anode and is inevitably eaten away.
How exactly to properly ground and protect a hydrostatic level sensor
WIKA level sensors are available with optionally integrated lightning protection that acts on dangerous differences in the voltage potential between electronics, cabling and transmitter body, and routes any harmful voltages to ground before they can damage the inner circuitry. However, if the grounding for the transducer is poor, it’ll still have nowhere else to go but into the electronics or body of the sensor, causing a premature failure.
Regarding metallic and plastic tanks, any isolated metal parts should be connected to a common ground having an impedance of < 100 Ohms. In applications onboard ships, where, in essence metal tanks are always present, all the different ground potentials ought to be linked to the ship?s main ground point during docking. In lakes and reservoirs, a minimal impedance link with ground could be hard to achieve, but will be really worth the effort as it saves the hydrostatic level sensor electronics from failure. On artificial constructions or rock sites, even long copper spikes driven into the ground may not give a low-enough impedance to ground, so earthing grids may be embedded into the ground to achieve a suitable resistance to ground.
Grounding of hydrostatic level sensors is really a basic requirement for the reliable operation of level sensors, especially in outdoor applications, where overvoltage spikes and surges because of lightning strikes can occur regularly. Distraught to provide adequate grounding can lead to the failure of the particular level sensor.
Check out the profiles of WIKAs submersible pressure transmitters LH-20 and LS-10.
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