Difference between revisions of "Grounding system sizing and selection"
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Revision as of 14:49, 1 December 2020
Properly grounding all non-current carrying metallic equipment in the electrical system, as well as both the AC and DC side of a PV system, is recommended to help mitigate electrical fires, lighting and electrocution risks to system users. This is no easy task though as designing and installing a proper grounding system is one of the more complicated aspects of off-grid PV system design as there are many different components that are required in order for a grounding system to function properly. The appropriate design varies regionally based upon not only the electrical code, but also the building, soil type and available materials.
Step 1: Determine the type of grounding electrode
Determining the right grounding electrode for a particular project is best done by consulting local electricians. There are some general principles with regard to choosing a grounding electrode:
| Type | Description |
|---|---|
| Ground rod | Ground rods are driven into the ground - typically with a hammer. They must penetrate 2.5-3 m of ground in order to be able to establish a solid connection with the earth, which can be extremely difficult to achieve in rocky soil. |
| Ground plate | In locations where |
| (3) Charge controller output circuit | = Current rating of the charge controller |
| (4) Charge controller load circuit | = Current rating of the charge controller lighting/load circuit |
| (5) DC branch circuit | = Sum of all loads on the circuit from the DC load evaluation. |
| (6) Inverter input circuit | = Final inverter continuous duty rating ÷ Low voltage disconnect parameter ÷ Inverter efficiency parameter |
| (7) Inverter output circuit | = Final inverter continuous duty rating ÷ Inverter AC voltage |
| (8) AC branch circuit | = Sum of all loads on the circuit from the AC load evaluation. |
| (9) Energy storage circuit | = Larger of Inverter input circuit current or Charge controller charging circuit current |
