solar diagram

Re: solar diagram

You really don't need the 30 Amp circuit breaker between the solar panels and the charge controller. The two solar panels can never generate enough current to ever pop the breaker.

I would highly suggest a Remote Battery Temperature Sensor for faster and more accurate battery charging.

-Bill

Re: solar diagram

The "normal stuff"

The frame of the solar panels should be grounded to your RV chassis (to prevent shock).

Normally, there would be a heavy gauge wire from the battery negative terminal to the chassis ground.

Place all fuses/circuit breakers close to the source of power (battery bank). Each breaker/fuse should be rated for the wire capacity that leaves the breaker (i.e., a 14 gauge wire should have a 15-20 amp fuse/breaker). Always plan on the fuse+wire to be, at least, 1.25x larger than the maximum continuous planned load current.

My personal suggestion, I really like battery monitors. Granted they are not perfect but they do a good job of letting people see how well the battery is being recharged after use. Probably the number 1 killer of batteries is simply to much discharging and too little recharging (also known as "deficit charging"). In any case, you should also have a good quality hydrometer to check the battery cells occasionally for proper charge levels.

You don't show an AC Battery charger (shore power / generator). Most people cannot put enough solar panels on an RV to generate 100% of their needed power. Adding a heavy load, such as recharging a trolling motor pack, is probably going to make the deficit worse.

Just to give you an idea... Assuming you are in very nice weather, you tilt the panels towards the noon day sun, and you have a good 5 hours of noon time sun per day (summer months)--realistically (assuming a 0.52 derating factor for system)--the amount of daily useful solar charge you can use from your AC inverter would be:

• 2x 135 Watts * 5 hours of full sun * 0.52 system efficiency = 702 Watt*Hours per day

So, if you pull just 700 watts through your 1,750 watt inverter -- You can expect about 1 hour of use per day...

So--that gets back to our classic song here--- Conservation, conservation, conservation... Convert lighting to LED/Florescent, avoid phantom loads (unplug cell phone chargers, radio, tv, etc. when not in use), turn off inverter when not in use, etc...

If you want 120 VAC power much of the time (say at night to turn on a light/appliance without flipping the DC breaker)--take a look at a Morning Star 300 watt 12 volts Pure Sine Wave inverter (around $260)... It is very efficient, clean power, and has a "standby mode" that does not draw much power when there are no AC loads (requires around 8 watts of AC load to "turn on"). It also has a remote power off line that may be handy for you too.

An AC inverter will pull around 8 watts of load with no external power--leave it on 24 hours per day:

• 8 watts * 24 hours = 192 Watt*Hours per day

Or almost 1/3rd of your daily power supplied by the solar panels.

Do you have your backup power source and charger picked out / operational yet?

-Bill