Ground fault protection device

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Wiring diagram of a stand alone PV system with a charge controller with DC lighting control and an inverter for AC loads. The fround fault protection device (GFPD) is identified as (1).
Wiring diagram of a stand alone PV system with a charge controller with DC lighting control and an inverter for AC loads. The This system is experiencing an DC ground fault an ungrounded conductor in the PV source.

A ground fault protection device (GFPD) uses a low current breaker (.5-1 A) to create a connection between a conductor (wire) and ground on the DC side of a PV system, which creates a grounded conductor. This breaker is ganged (connected) to another breaker through which the positive PV source wire passes. In the event of a DC ground fault, the low current breaker will trip removing the connection between the grounded conductor and the ground, but will also open (disconnect) the ungrounded conductor of the PV source circuit. A GFPD is recommended for systems with a DC system ground to improve safety, although they may be difficult to find in many locations.

A GFPD plays an important role in a PV system with a DC system ground by helping to prevent fires from ground faults that go undetected by overcurrent protection devices (OCPDs). A ground fault can go undetected because the OCPDs for the PV source are sized to the maximum current of the PV source, which means that OCPDs are often ineffective against DC ground faults occuring at the PV source as it doesn't exceed their current rating. This can lead to a fire because PV modules will continue to provide current as long as there is sunshine and a circuit. The diagram at right shows how a GFPD operates during a ground fault on an ungrounded DC conductor:

  1. A fault occurs on a DC ungrounded conductor of a system.
  2. The current from the fault follows the equipment grounding conductor (EGC) back to the busbar for the grounded conductor to complete the circuit. Current surges from the PV source.
  3. The current of the GFPD on the connection between ground and the grounded conductor is exceeded. The device disconnects the DC system ground and opens the PV source circuit. The fault is disabled.

This has the benefit of reducing the potential of a fire resulting from the ground fault, but also creates a new hazard. A grounded conductor, like the black DC wire in the diagram, will have a voltage of 0 V to ground - grounded conductors are generally safe to touch. An ungrounded conductor, like the red DC wire in the diagram, will have the voltage of the PV source relative to ground and is not safe to touch. The new hazard is created because of two things that happen when a GFPD activates during a ground fault:

  1. The previously ungrounded (red) conductor with the PV source votlage relative to ground effectively becomes a grounded conductor with 0 V to ground.
  2. The previously safe grounded (black) conductor with 0 V is turned into an ungrounded conductor by removing its ground, which means that it may have the full voltage of the PV source relative to ground.

This creates a hazard for system users or anyone troubleshooting the problem as the issue may not be readily apparent and safe/unsafe conductors of a system have switched roles due to the GFPD. Ground faults should be taken very seriously and any troubleshooting should be done by someone with experience dealing with ground faults.