Off-Grid Grounding

I don't have much time right now--But a comment or two...

The drawing you have is almost electrically correct. It is missing a ~80 circuit breaker from the Battery+ to the charge controller Vbatt+ connection. Also, from the Battery+ to the charge controller+ should be heavy gauge wire (gauge not listed, but thinner line suggests smaller awg wire--Circuit Breakers are there to protect THE WIRING against short circuits. You should keep the wiring from the Battery+ to the circuit breaker short and well supported/insulated (using smaller awg is "allowed" for ~16" runs or less--i.e., very little chance that length will get shorted somehow).

Next--For most systems (larger/fixed installation say larger than ~1,500-3,000 Watt AC power/inverter/genset), the Battery- connection is generally connected to the common ground for the installation.

Another issue--AC and DC wiring, you can run ground wires and a single ground rod just about any way you like (within reason)... However, if you have a good chance for lightning strikes in/near to your home... Lightning has "different" rules. RF energy wants to take the "straight line" from strike to ground... If you add 20' of 6 AWG ground wire, it may take a hop off the cable and go elsewhere.

For Lightning, multi-point grounds (ground rod at based of solar array, ground rod at electric box+surge suppressors entering the home), etc.

And, while there is a lot of arguments both ways--My suggestion is that each ground rod be connected by 6 AWG cable (direct bury is nice--dirt connections help) between the main ground of the home/power system, and radiating out to other "local ground rods" at the base of the solar array, outside electrical box entrance to home, etc. The interconnect 6 AWG prevents the (for example) panel mount from becoming electrically "hot" with >40 VDC or VAC (i.e., a 120 VAC wire shorts to the frame, the fault current runs back to local ground rod, back through 6 AWG to home ground rod, then back to system AC+DC central ground, then back to the AC breaker (and it gets trip from short).

So, tell us a bit more about your system... Amount of loads (WH per day, AH @ xx volts per day), what the loads are (LED lighting, 1.5 hp deep well pump, etc.). Where the array will be mounted relative to the charge controller/battery bank, etc...

-Bill

For a starting point... Lets look at 1,000 WH per day rule of thumb design (nominal choices). Assuming 2 days storage and 50% maximum discharge (longer battery life):

• 1,000 WH * 1/0.85 inverter eff * 1/12 volt battery bank * 2 days storage * 1/0.50 discharge = 392 AH @ 12 volt battery bank

2x 200 AH @ 6 volt golf cart batteries * 2 parallel strings (4x batteries total) will give you a 400 AH @ 12 volt battery bank

The maximum AC inverter I would suggest would be a 1,000 Watt inverter (based on 400 AH @ 12 volt per 1,000 Watt inverter or max solar panels).

The actual inverter I would suggest would be a 300 Watt 12 volt TSW inverter from MorningStar. It has remote on/off and a "search mode" to reduce standby current. 300 Watt continuous (600 Watt peak) will supply a cabin very nicely (LED lighting, laptop/LED TV, cell phone charger, 12 volt RV pump for water pressure).

To charge such a flooded cell battery bank, I would suggest 5% to 13% rate of charge--For a full time off grid system, 10%+ rate of charge suggested:

• 400 AH * 14.5 volts charging * 1/0.77 panel+controller derating * 0.10 rate of charge = 753 Watt array "nominal" for full time off grid (good battery charging current)

Then there is sizing the array based on your load and hours of sun... Not sure which is closest to your place, but here is a fixed array tilted to best year round performance::
http://www.solarelectricityhandbook.com/solar-irradiance.html

Grand Forks
Average Solar Insolation figures

Measured in kWh/m2/day onto a solar panel set at a 42° angle from vertical:
(For best year-round performance)

Jan	Feb	Mar	Apr	May	Jun
2.32	3.46	4.21	4.94	5.22	5.19
Jul	Aug	Sep	Oct	Nov	Dec
5.40	5.24	4.42	3.53	2.62	2.10

This one may have more choices (enter in your city/state):
http://pvwatts.nrel.gov/pvwatts.php

If you toss the bottom three months (have to use a genset when there), February "break even" month:

• 1,000 WH per day * 1/0.52 off grid AC system eff * 1/3.46 hours of sun (Feb) = 556 Watt array (Feb)

A 753 Watt array will "break even" down to:

• 1,000 WH per day * 1/0.52 system eff * 1/753 Watt array = 2.55 hours of (noon time equivalent sun) per day (pretty deep winter).

Get a roughly 40 Amp AC battery charger and a Honda eu2000i (1,600 watt) genset--And you would be set to go.

Also, to better estimate your AC loads, you can get a kill-a-watt type meter--Also very handy for conservation measurements of your plug in appliances at home.

-Bill

I am not an expert in the sense that I can pick/design "your system". I look at more of an educational discussion that helps you to design a system that will reliably meet your needs.

Regarding metal roofs/walls--Forgot to answer that one. In general, metal roofs do not supply any special/better lightning protection (from damage) than any other construction. If you are in a lightning area--Then you should do the lightning rods/cabling just as you would on any structure. A metal roof may keep you a bit safer--But unless the roof has lightning grounding bonding cables attached and taking the energy to ground (vs a steel framed building where the frame does help)--You will still be subject to damage as the energy finds "some paths" to ground (in my humble, not an expert, opinion).

Using a well designed lightning rod+cable+ground system helps reduce the chances of the lightning getting near you and your stuff inside the home/building.

-Bill

I am not sure you can over do lightning protection, but you can do it wrong.

Read up about how to do it and what to avoid.

-Bill