How to Wire a GFCI Circuit Breaker? 1, 2, 3 & 4 Poles GFCIs Wiring

Single-Phase and Three-Phase GFCI Breaker Wiring Circuit Diagrams and Installation

A Ground-Fault Circuit Interrupter (GFCI) is a safety device designed to protect people from electrical shock by monitoring the electrical current flowing through a circuit. It detects imbalances between the hot and neutral wires, which can indicate a ground fault where electricity is leaking out of the circuit.

If a ground fault is detected, the GFCI quickly cuts off the electrical power to prevent shock and potential electrocution. GFCIs are commonly installed in areas with higher risk of electrical hazards, such as bathrooms, kitchens, and outdoor spaces.

Good to Know:

GFCI and RCD or RCCB are Same.

In North America, it is commonly known as GFCI (Ground Fault Circuit Interrupter) or GFI (Ground Fault Interrupter) or ALCI (Appliance Leakage Current Interrupter).

In America, it is commonly known as GFCIGround Fault Circuit Interrupter” or “GFIGround Fault Interrupter” or ALCIAppliance Leakage Current Interrupter“.

In Europe and Australia, the same device is known as RCD (Residual Current Device) or RCCB (Residual Current Circuit Breaker). When an overcurrent protection device such as an MCB is combined with an RCD (RCD + MCB), it is known as an RCBO (Residual Current Circuit Breaker with Overcurrent Protection). These devices are also referred to as safety switches.  RCDs are modern devices used nowadays, which is actually a Current Operated ELCB, replacing the old-school Voltage Operated ELCBs.

Voltage-operated ELCBs have been replaced with the latest RCD devices due to some disadvantages of ELCBs (such as their reliance on a proper earth connection).

GFCIs and RCDs are used to protect against electric shock in case of ground faults and leakage currents by tripping the circuit. According to IEC and NEC, it is mandatory to use and install these devices in areas with water exposure, such as laundries, kitchens, spas, bathrooms, and other outdoor installations.

Keep in mind that the difference between single-pole and two-pole normal circuit breakers and a GFCI is that there is a built-in white wire on the backside of the GFCI, and it must be connected to the neutral busbar in the main supply, or it will not work and protect the circuit properly. Additionally, you may read about the difference between GFCI and AFCI Breakers in the previous post.

Difference between 1 & 2 Poles MCB and GFCI Breaker Terminals & Wiring

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Requirement of GFCI in NEC 2020

The current codes have been updated with new requirements for GFCI protection in the National Electrical Code (NEC) 2020 for 250V outlets and receptacles in specific locations in dwelling units.

According to 210.8(A) – NEC 2020 for Dwelling Units, all 120-240V outlets installed in the locations specified in 210.8(A)(1) through (A)(11) and supplied by single-phase branch circuits rated 150V or less to ground shall have ground-fault circuit-interrupter (GFCI) protection for personnel:

Non-Dwelling Units:

Specific Locations and Equipment:

Now that you have an idea, we will show different wiring circuit diagrams for single-pole, two-pole, three-pole, and four-pole (both single-phase and three-phase) GFCI circuit breakers.

Wiring a Single Pole GFCI Breaker

The following wiring diagram shows a 15A, 120V ordinary outlet wired and protected by a single-phase 5A, 120V, single-pole GFCI circuit breaker.

As shown in the figure, the built-in white wire in the GFCI should be directly connected to the neutral bar in the main panel board.

The Line (Hot, Live, or Phase) is connected directly to the GFCI input, and the output is connected to the line terminal of the ordinary outlet/receptacle. The silver screw labeled “N” on the GFCI is connected to the silver screw on the outlet via the output neutral wire from the GFCI to the outlet. The ground terminal (green screw labeled “G”) of the outlet is connected to the ground bar in the main distribution board.

This way, the 15A, 120V outlet is GFCI protected by the 15A GFCI breaker. You may use #14 AWG wire between the outlet and the GFCI. According to the 80% load rule in the NEC, no more than a 12A load should be connected to this 15A GFCI-protected outlet.

15A × 80% = 12A

You may safely connect up to 1440 watts load appliances to the 14A, 120V GFCI protected outlet.

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How to wire a Single Pole GFCI Circuit Breaker

The same wiring configuration can be arranged for a 20A, 120V circuit using the correct wire size, proper circuit breaker rating, and suitable ratings for switches and outlets.

Wiring a 2-Pole GFCI without Neutral

The following wiring configuration shows a 20A, 240V receptacle wired and protected by a single-phase, 20A, 240V, double-pole GFCI circuit breaker.

Similar to the wiring diagram for a 1-pole GFCI circuit breaker, the built-in white wire on the back of the two-pole GFCI must be connected to the neutral bar in the main panel. The 2-pole GFCI should be installed in the two hot slots in the main panel. This configuration allows HOT 1 and HOT 2 to provide the 240V input supply to the GFCI.

The two output line wires (HOT 1 and HOT 2) from the GFCI are connected to the line terminals (L1 and L2) of the 20A, 240V outlet/receptacle. Finally, the ground wire from the ground terminal bar is connected to the ground screw on the outlet.

This setup ensures that the 20A, 240V outlet is protected by the 20A GFCI circuit breaker. You may use #8 to #10 AWG wire between the outlet and the GFCI. According to the 80% load rule in the NEC, no more than a 24A load should be connected to this 20A GFCI-protected outlet.

20A × 80% = 16A

A maximum load of 5760 watts may be safely connected to this 20A, 240V outlet with ground fault protection.

Good to Know: In a 240V single-phase circuit, the 2-pole GFCI does not require an output neutral wire for the load circuit. Instead, one of the hot wires (out of the two hot wires) serves as the returning path for the current, completing the circuit and allowing it to function properly (similar to the phase and neutral connection in a 120V circuit).

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How to wire a Two-Pole GFCI Circuit Breaker

 

Wiring a Two-Pole GFCI with Neutral

The following wiring diagram shows a hot water tub spa or whirlpool spa wired and protected through a 2-pole GFCI circuit breaker using a three-wire system (two hot wires, one neutral, and one ground).

As we know, in a 240V system, there is typically no need to connect the neutral. However, in some cases (when required), appliances should be connected to the neutral according to the manufacturer’s specifications and user manuals.

In this 4-wire GFCI wiring diagram, the built-in white wire from the GFCI is connected to the neutral busbar in the main panel. Two lines from the main panel (L1 and L2, single-phase 240V) are connected to the input terminals of the GFCI, which is installed in the L1 and L2 terminal slots in the panel or load center.

As shown in the figure, the three output terminals are connected to the spa control box according to the printed markings: the middle terminal is neutral, and the first and last terminals are the two lines (L1 and L2). Finally, the ground wire from the ground busbar is connected to the ground terminal in the spa control box.

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Wiring a Three Poles GFCI Circuit Breaker
Wiring Single Phase, 2-P and 3-P GFCI Breaker

If the 2-pole GFCI breaker has only two output terminal screws, you will have to arrange a separate neutral from the neutral busbar in the main panel or load center. For example, the following wiring diagram shows a 2-pole GFCI breaker with two output terminals (L1 and L2) installed with a NEMA 14-50R outlet rated at 50A, 240V, which is used for heavy-duty EV charging, stoves, laundries, etc.

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How to Install 14-50R Receptacle with 2-Pole GFCI
Wiring a 14-50R Receptacle with 2-Pole GFCI

If the 2-pole GFCI breaker has three output terminal screws, you may directly wire the neutral to the center screw labeled “N”, and Line 1 and Line 2 to the first and last terminal screws, connecting to the outlet or any other load.

For example, the following wiring diagram shows a 2-pole GFCI breaker with three output terminals installed with a NEMA 14-50R receptacle rated at 50A, 240V, which is used for heavy-duty electric vehicle charging, mobile connectors, electric ranges, etc.

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Wiring a 14-50R Outlet with 2-Pole GFCI and Neutral
Wiring a 14-50R Outlet with 2-Pole GFCI and Neutral

Wiring a 3-Phase, 3-Pole GFCI Breaker

The following wiring diagram demonstrates how to wire a 20A, 120/208V, three-phase, three-pole GFCI breaker using a four-wire system (three hot wires, one neutral, and one ground).

As shown in the wiring diagram, the pigtail of the built-in white wire is connected to the neutral busbar in the load center. The three hot conductors (black, red, blue) are connected to the input terminals of the 3-phase GFCI.

Similarly, the output terminals are wired through the same phase wires from the GFCI to the three-phase load. If a neutral is needed, it should be connected from the neutral bar located in the main panel or load center.

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How to Wire 3-Phase, 3-Poles GFCI Breaker

It should be noted that this three-line wire supply arrangement will provide a 208V, three-phase supply to the load points. The same wiring diagram applies to a 240V, three-phase supply or any other three-phase power while wiring a 3-pole, 3-phase GFCI breaker.

Good to Know:

The wiring connections are same for both GFCI and AFCI breakers in both single phase and three phase circuits.

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Wiring a 3-Phase, 4-Pole GFCI Breaker (RCD/RCBO)

Since there are no official 4-pole GFCI products available, you may use a 4-pole RCCB or RCBO for the same purpose when needed. Although it’s unclear what specific scenario in North America would require a 4-pole GFCI, as a 3-pole GFCI with an additional neutral from the neutral bar can often suffice, this solution addresses a query from a member who needs all four wires secured in a single unit.

If you encounter a situation where you need to install and wire a 4-pole GFCI in a three-phase circuit, a quick fix is to wire a 4-pole RCCB, which functions similarly to a GFCI.

In the three-phase wiring diagram for GFCI, RCD, or RCBO, the three lines (L1, L2, and L3) and neutral are connected as inputs to the RCCB from the main board, following an MCB for overcurrent protection.

The lower four terminals and ground wire of the RCBO are connected to the spa control box in the following sequence: Red (L1), Yellow (L2), Blue (L3), Black (Neutral), and Green/Yellow (Ground/Earth).

The following diagrams show the three-phase four-pole RCBO (RCCB + MCB) circuit breaker used to control and protect a hot water spa.

Wiring a Three Poles RCBO (MCB + RCB or RCD)Circuit Breaker

For three-phase spa wiring, use 12 or 10 gauge wire for each line. For example, use #12 or 4.0mm² wire for up to 12kW, three-phase 415V – 480V systems where the maximum current is 18.2A. Use #8 or 6.0mm² wire for the same 12kW spa in a three-phase 208V system where the maximum current is 33.3A. For higher wattage, use the appropriate wire size according to the table and user manual.

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Precautions:

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