1 equipment grounding conductors, 2 grounding electrode conductors, 3 system bonding jumpers – Magnum Energy MSH-M Series User Manual

Page 24

©

2013 Magnum Energy, Inc.

Installation

2.6.1

Equipment Grounding Conductors

The inverter case and all other noncurrent-carrying exposed metal surfaces in the entire electrical

system—that may be accidentally energized—must be grounded. The equipment-grounding conductor

must be sized to safely carry the maximum ground-fault current likely to be imposed on it from

where a ground-fault may occur. In accordance with the NEC, use Table 2-3 to size the equipment-

grounding conductors according to the rating of the overcurrent device protecting the circuit.

CAUTION: The connections and wiring for the equipment-grounding conductor must be

continuous to allow fault currents to properly operate overcurrent devices. Whenever

equipment is removed that disconnects the bonding connection between the grounding

electrode conductor and the exposed conducting surfaces, a bonding jumper must be

installed while the equipment is being removed.

AC Side – The AC equipment grounding conductor (EGC–AC) is sized per Table 2-3 and is connected

to the inverter’s AC equipment grounding terminal shown in Figure 2-8.
DC Side – Since the currents on the DC side are much higher than the AC side, the equipment

grounding needs are different. The DC equipment grounding conductor (EGC–DC) is sized per Table

2-3 and connected to the DC equipment grounding terminal on the inverter as shown in Item 7,

Figure 1-2. For marine installations, the DC equipment grounding conductor (EGC-DC) is normally

required to be of an ampacity equal to that of the DC positive conductor (see Section 2.6.4).

Info:

See Section 2.6.6 for information on connecting DC equipment grounding

conductors greater than #2 AWG (33.6 mm

2

).

Info:

The equipment grounding conductors (EGC) and the grounding electrode

conductors (GEC) must be either insulated (green or green with a yellow stripe) or bare
copper. However, for conductors larger than #6 AWG (13.3 mm

2

) the exposed insulation

can be colored green, or covered with green tape or green adhesive labels.

Table 2-3, Equipment Grounding Conductor Sizing

Rating of

Overcurrent Device

Minimum Size of

Copper Ground Wire

Rating of

Overcurrent Device

Minimum Size of

Copper Ground Wire

20 amps

#12 AWG (3.3 mm

2

)

200 amps

#6 AWG (13.3 mm

2

)

30 - 60 amps

#10 AWG (5.3 mm

2

)

300 amps

#4 AWG (21.1 mm

2

)

100 amps

#8 AWG (8.4 mm

2

)

400 amps

#3 AWG (26.7 mm

2

)

2.6.2

Grounding Electrode Conductors

AC Side – The size of the AC grounding electrode conductor (GEC–AC) depends on the size of the

largest ungrounded conductor feeding the AC load center. For ungrounded conductors that are #2

AWG (33.6 mm

2

) or smaller, use a minimum #8 AWG (8.4 mm

2

) copper conductor.

DC Side – When the DC (GEC-DC) and AC (GEC-AC) grounding electrode conductors are connected

to a single grounding electrode, the size of the DC grounding electrode conductor cannot be smaller

than the largest conductor in the DC system (usually the battery-to-inverter cable).

2.6.3

System Bonding Jumpers

AC Side – The AC system bonding jumper (SBJ) provides the neutral-to-ground “bond” between

the grounded conductor (AC neutral) and the equipment grounding conductor, and is required in

only one place in the AC electrical system. When the MSH-M is connected to an external AC source

(i.e., shorepower), the external AC source must provide the bond. However, when the external AC

source is disconnected and the inverter is providing the AC power (i.e., inverting), an internal relay

inside the inverter connects the neutral and ground to provide the bond. See Section 2.6.5 for more

information on the neutral-to-ground switching feature.
DC Side – The size of the system bonding jumper (SBJ) in the DC electrical system must not be

smaller than the DC grounding electrode conductor (GEC–DC) used.