Product Manual
Table Of Contents
- 1.0 Introduction
- 2.0 Installation
- 3.0 Operation
- 4.0 Maintenance and Troubleshooting
- Appendix A – Specifi cations and Optional Equipment
- Appendix B - Battery Information
- Appendix C – Power Consumption and Output Waveforms
- Appendix D – Inverter/Charger Terminology
- Appendix E – Warranty and Service Information
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© 2013 Magnum Energy, Inc.
I nst alla t ion
2 .6 .4 Grounding on Boa t s
When installing the MS-PE Series inverter/charger on a boat, there are several considerations that
must be followed when grounding to ensure a safe installation, prevent galvanic corrosion, and
adhere to local codes and industry standards.
Ensure a Safe Grou nd Conne ct ion
When AC on the boat is being supplied by shorepower, the onboard neutral should be connected
to safety ground on the dock. Consequently, neutral and safety ground should not be connected
anywhere on the boat when shorepower is present. When AC on the boat is being supplied by
the MS-PE Series inverter, the inverter’s output neutral is connected to safety ground through an
internal relay using its neutral-to-ground connection (see Figure 2-16).
The DC ground terminal on the MS-PE Series must also be connected to the boat’s safety ground
bus. This ensures that both the inverter’s AC and DC ground terminals are connected to the boat’s
safety ground bus as a safety measure to provide protection against faults, and to provide a path
for AC fault currents while the boat is connected to shorepower.
Prevent ing t he Risk of Corrosion
The inverter’s AC and DC ground terminals must be connected to the boat’s safety ground to
provide an important safety feature. However, this ground connection introduces the risk of galvanic
corrosion and/or electrolysis of the boat’s underwater metallic hardware.
Two possible solutions are typically used to maintain the correct onboard grounding requirements
while greatly reducing (if not eliminating) the risk of galvanic corrosion. These solutions would be
either using a galvanic isolator or an onboard isolation transformer.
Galvanic isolators allow high AC voltage faults to pass, but block low voltage corrosion/electrolysis
currents from conducting.
Marine isolation transformers enable the shorepower to be connected to one side of the transformer
while the boat’s AC wiring system is connected to the other side. Since transformers do not allow
DC currents to pass, the problem with galvanic corrosion is eliminated.
Re com m e nded I nverter / Char ger Grounding Re quirem ents
• D C Grounding Conne ct ions:
1. The DC grounding conductor (equipment ground) shall be:
a) Connected from the metallic case or chassis of the inverter/charger to the engine negative
terminal or its bus;
b) and, an ampacity equal to that of the DC positive conductor (under certain conditions
there may be an exception to allow this conductor to be one size smaller—refer to local
standards).
2. The inverter/charger’s negative battery terminal and DC grounded conductor (negative
cable) shall not be connected to the inverter case or chassis at the inverter/charger itself.
• AC Groun ding Connect ions:
1. The AC grounding conductor (green w/yellow stripe) shall be connected to the inverter/
charger in a manner so that the AC ground connection will not be disconnected in servicing.
This conductor is in addition to and independent of the DC grounding conductor.
2. The neutral for AC power sources shall be grounded only at the following points:
a) The shorepower neutral is grounded only through the shorepower cable and not grounded
on board the boat.
b) The inverter neutral shall be grounded at the inverter, and the output neutral shall be
disconnected from ground when the inverter is operating in the charger/pass-through mode.
c) On systems using an isolation transformer or a polarization transformer, the inverter
neutral (and the transformer secondary neutral) may be grounded at the AC main grounding
bus instead of at the inverter.