Installation – Magnum Energy ME-G Series User Manual

Page 13

©

2015 Sensata Technologies

Installation

2.4.1

DC Wire Sizing

It is important to use the correct DC wire to achieve maximum effi ciency from the system and to

reduce fi re hazards associated with overheating. Always keep your wire runs as short as practical

to prevent low voltage shutdowns and to keep the DC breaker from nuisance tripping (or open

fuses) because of increased current draw. See Table 2-1 to select the required minimum DC wire

size (and corresponding overcurrent device) required based on your inverter model. The cable

sizes listed in Table 2-1 are required in order to reduce stress on the inverter, minimize voltage

drops, increase system effi ciency, and ensure the inverter’s ability to surge heavy loads.
If the distance from the inverter to the battery bank is >5 feet (1.5m), the DC wire needs to be

increased. Longer distances cause an increase in resistance, which affects the performance of

the inverter. Use the overcurrent device previously determined from Table 2-1 and then refer to

Table 2-2 to determine the minimum DC wire size needed for various distances.

2.4.2

DC Overcurrent Protection

DC overcurrent protection is not included in the inverter—for safety reasons and to comply with

electrical code regulations—it must be provided as part of the installation. The DC overcurrent

protection device must be installed in the positive DC cable line, it can be a fuse or a circuit

breaker, and it must be DC rated. It must be correctly sized according to the size of DC cables

being used, which means it is required to open before the cable reaches its maximum current

carrying capability, thereby preventing a fi re. The NEC requires both overcurrent protection and

a disconnect switch. If a circuit breaker is used as the overcurrent protection device, it can also

be used as the required DC disconnect.
If a fuse is used as an overcurrent device, a Class-T type or equivalent is recommended. This fuse

type is rated for DC operation, can handle the high short-circuit currents, and has a time delay

that allows for momentary current surges from the inverter without opening the fuse. However,

because the fuse can be energized from both directions, the NEC requires that it be installed in

a manner such that the power must be disconnected on both ends of the fuse before servicing.
Use Table 2-1 to select the DC overcurrent device needed based on the recommended minimum

wire size for your particular inverter model (may not meet all local code or NEC requirements).

Table 2-1, Recommended DC Wire/Overcurrent Device for Rated Use

Maximum

Continuous

Current

1

In Free Air

DC Grounding

Electrode Wire

Size

4

Minimum DC Wire

Size (rating)

2

Maximum DC

Fuse Size

3

ME2012-G

267 amps

#2/0 AWG (67.4 mm

2

)

300 amps

300 amps with

time delay

#6 AWG

(13.3 mm

2

)

ME2512-G

333 amps

#4/0 AWG (107.16 mm

2

)

400 amps

400 amps with

time delay

#6 AWG

(13.3 mm

2

)

ME3112-G

413 amps

#4/0 AWG (107.16 mm

2

)

400 amps

400 amps with

time delay

5

#6 AWG

(13.3 mm

2

)

Note

1

– Maximum continuous current is based on the inverter’s continuous power rating at the lowest input

voltage with an inverter ineffi ciency factored in.
Note

2

– Copper wire rated with 90°C (194°F) insulation at an ambient temperature of 30°C (86°F), with a

multiple cable fi ll factor (0.8) de-rating (if needed).
Note

3

– The next larger standard size overcurrent device may be used if the de-rated cable ampacity falls

between the standard overcurrent devices found in the NEC.
Note

4

– Per the NEC, the DC grounding electrode conductor can be a #6 AWG (33.6 mm

2

) conductor if

that is the only connection to the grounding electrode and that grounding electrode is a rod, pipe, or plate

electrode.