Selected why hydrostatic level sensors fail because of lightning strikes, even if they ordered an even sensor with integrated lightning protection. Focusing on how the lightning protection works and how lightning strikes affect hydrostatic level sensors is important in resolving this confusion.
When submersible pressure sensors, a special type of hydrostatic level sensors, were first installed into reservoirs and lakes to monitor level, the sensor would become burned or destroyed after a lightning storm or inclement weather periods. This prompted much research into the aftereffect of lightning storms on the instrumentation in reservoirs and the cabling to and from the site.
What lightning protection really means
The first thing to understand is that the result of a lightning strike is considerably different depending on how close to the pressure sensor the lightning strikes in to the ground or installation. It really is fair to say that no level sensor will survive a direct or very close nearby lightning strike, where often the whole cabin including all installed electronics will be incinerated by direct hits.
However, more distant hits is only going to raise the Voltage differential by for example 1500 Volts. In case a local lightning strike raises the electric potential of a reservoir, the level sensor might provide the shortest method for the raised voltage and current to earth. The power will then dissipate in to the ground via the particular level probe and thus destroy or damage its electronics. This may equally function as case when overhead wires have a hit.
So how exactly does lightning protection in level sensors work?
However, sensors can be protected from these lightning strikes by installing or integrating a transient voltage protection in to the hydrostatic level sensor. Due to the short nature of the voltage pulse, an element may be suited to or built-into the sensor that acts on rising differences in voltage potential. If the voltage goes above say 50 Volts, this lightning protection can short-circuit the electronic circuit to ground, allowing a path to ground for the surge and protecting the electronics around the utmost specified voltage potential.
The component would normally operate in a non-conductive state, but will be conductive for a voltage transient, allowing the voltage spike to flow harmlessly to ground. If the connection to earth is not good enough or no lightning protection is integrated within the hydrostatic level sensor, then the electronics will take the full level of energy of the voltage pulse and fail.Which means protection is only as effective as the earth grounding provided by the user.
In outdoor applications, where submersible pressure transmitters are generally used, WIKA provides an optionally integrated lightning protection in the level sensors. The sensor electronics will be protected from local power surges and transient high voltage. Lightning protection is really a mix of protection within the instrument and a good low impedance earth grounding.
Have a look at the profiles of WIKAs submersible pressure transmitters LH-20 and LH-10.
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