wire gauge for panel to controller

Welcome to the forum Mike,

In solar/battery power, details matter.
https://www.renogy.com/rover-elite-40a-mppt-solar-charge-controller/

• MPPT Controller: 15-100 VDC input
• 520 Watt solar max input for 12 volt bank (vendor spec)
• You have battery temperature compensation is turned off (no temp compensation for Lithium Ion batteries)

And need to know exactly what solar panel(s) you will be installing...

Do you have existing solar panels that you wish to continue to use? If yes, need Vmp and Imp rating for those panels

What are the Vmp/Imp ratings for your 210 Watt panels?

For MPPT solar charge controllers, the recommended Vmp-array (from very cold to very hot climates) runs around:

• 15 volt max battery charging * 1.3 minimum MPPT controller voltage requirement = Vmp-array-std~19.5 volts minimum suggested for MPPT
• 100 VDC max MPPT controller input * 0.67 arctic freezing weather = Vmp-array-std ~ 67 volts max (i.e., -40F/C condtions)

Such is why site temperatures are important... If you are on a nice Caribbean island where it is 75F all year long--Then you may have other options for series/parallel array options.

Where is the system located (nearest major city)? And/or what are the min/max temperatures for your location (Voc/Vmp change with temperature; aka panel Voc voltage rise as temperature falls, and Vmp falls as temperature rises).

Unless there is something very different about your panels (high Vmp/Voc voltages)--Yes, you can probably put them in series without any problems, and you can now run smaller AWG wiring and/or longer wiring as needed (such as park RV/Camp in shade, put panels in sun).

200 Watt panels are fairly large format... And can be difficult to move with one person. Is this a fixed installation (rack mount, RV mount) or is this a portable installation (stake to ground--prevent wind from blowing them over and making expensive modern art)?

For current vs AWG, this simplified NEC table is pretty conservative:

https://lugsdirect.com/WireCurrentAmpacitiesNEC-Table-301-16.htm

And you can use a voltage drop calculator for AWG vs Wire Length (one way run for this website) vs Current:

https://www.calculator.net/voltage-drop-calculator.html

Typically for solar panel and general wiring, you design for around 1% to 3% max voltage drop. For battery to charge controller wiring, design for ~0.05 to 0.10 volt drop max (short/heavy cables from controller to battery bank). And for 12 VDC wiring suggest a max of 0.5 VDC drop from battery to loads.

-Bill

Which version of AC inverter--The 2,000 or 3,000 Watt?

https://www.solar-electric.com/victron-multiplus-ii-inverter-charger-12-3000-120-50-2-120v.html

Guessing at 3,000 Watts, always start with the manual:

https://www.solar-electric.com/lib/wind-sun/Manual-MultiPlus-II_2x_120V.pdf (page 10-11 of manual for DC electrical)

4.2. Connection of battery cables In order to utilize the full capacity of the product, batteries with sufficient capacity and battery cables with sufficient cross-section should be used. The DC cables must be copper and rated 90ºC (194ºF). See table.

12vdc/3000watt/120 adc charging
Recommended battery capacity (Ah) 400–1200
Recommended DC fuse 400 A
Recommended cross section (mm2 ) per + and - connection terminal *, **
0 – 5 m *** 2x AWG 1/0 (5 meters => ~16.5 feet of cable length)
5 – 10 m*** 2x AWG 2/0

Recommended cable lugs Size
AWG 2/1 Molex part no. 19221-0243
AWG 1/0 Molex part no. 19221-0240

* Follow local installation rules.
** Do not locate battery cables in a closed conduit
*** “2x” means two positive and two negative cables.
Remark: Internal resistance is the important factor when working with low capacity batteries. Please consult your supplier or the relevant sections of our book ‘Energy Unlimited’, downloadable from our website.

I always like to suggest not to "oversize" the AC inverter... It can waste a bit more power (larger AC inverters usually take more "tare" or "on with no loads" current that smaller inverters. Battery bank size, wire AWG, weight, costs etc. are all higher with the larger AC inverter.

I am not a big fan of installing large battery banks under sleeping platforms... But lets face it, RVs have limited amount of space and it is critical that Li Ion batteries be kept >~40F for use. Smoke (and propane) alarms to alert you to any issues early.

Please use fuses/circuit breakers/wiring of good quality where needed (pretty much every wire/branch circuit that leaves the battery bus needs a fuse/breaker to limit short circuit current (over current protection is to prevent wiring fires--Size protection to wire capacity).

Protect wiring from sharp edges and chaffing/vibration. Protect against loose metal objects falling on bus bars...

-Bill

Yep--two + cables in parallel and two - cables in parallel...

Just as an example... The maximum current pull from the inverter would be (generic math):

• 3,000 Watts * 1/0.85 AC inverter efficiency * 1/10.5 volts battery cutoff = 336 Amps

If there is a chance you will be using near 3 kWatts for longer periods of time (>a few seconds of starting surge current--Which can be 2x the 3 kWatt rating of the inverter):

• 336 Amps * 1.25 NEC "continuous current derating" = 420 Amp rated branch wiring and overcurrent protection...

The manual talks about 400 Amp fuse and wiring--Good enough...

The basic NEC wire ampacity ratings:

https://lugsdirect.com/WireCurrentAmpacitiesNEC-Table-301-16.htm

Two parallel high temp insulation rated wiring: 1/0 = 170 amps. 2x170a= 340 Amps

So all of that works out OK. You could use 1x heavy cable (every 3 AWG change in number, is 2x more (or less) circular array).

You probably will much prefer 2x parallel + cables vs 1x "extra thick" copper cable (350 cirkmill) or 0.373 vs 0.681 inches of stranded copper wire (plus insulation thickness).


-Bill

You would (normally) terminate each cable end with the crimp connectors (as recommended by the mfg.) and then you would take the 2x + connector ends and "stack them" on the positive breaker/fuse connection and on the + inverter DC input connection. Ideally, both cables should be the same length (if one cable in a pair is longer, the extra resistance will cause more current to flow on the shorter/lower resistance cable and could cause it to overheat under heavy loads). Same with the negative pair of cables.

One of the recommended Molex crimp lugs with bolt hole:

https://www.molex.com/molex/products/part-detail/ring_and_spade_ter/0192210243

https://www.molex.com/molex/products/family/battery_cable_lugs (random example)

"Exposed" or enclosed wiring... This is where it gets complicated. The above Victron recommendation is for cables in "free air". If you put them in conduit, that limits air circulation and can cause them to "run hot" and potentially melt the insulation. One answer is to go with heaver AWG cable (more expense, larger conduit).

The NEC (US National Electric Code) has all sorts of deratings for temperature, conduit fill, conduit type, moisture exposure, etc... Needless to say, the answer is "complicated".

And you don't want high current (400 amp fuse/breaker) cables to be exposed to where they can can be damaged (road debris) or a modern issue living in wilderness--Rodents/rats/etc. eating the insulation.

It has been too many decades for me to lookup/interpret how to use the NEC to make these calculations (I am not an electrician).

As for the AC shore power connection... I am not sure I would suggest armored cable in a location that gets wet/mud/road salt/vibration and such.

EMT (the light weight metal conduit)--Not going to last long with road salt (in my humble opinion).

Non-Metal PVC Conduit is good for wet/outside/buried... Might be a good choice. You have to pull the wiring.

Or direct burial 6/3+Ground "Romex" type cable? Good for wet/sunlight.

https://www.homedepot.com/p/Southwire-125-ft-6-3-Black-Stranded-Romex-SIMpull-CU-NM-B-W-G-Wire-63950002/202316279

Again--Not my area of expertise. Just my personal suggestions. Others here have a lot more experience and may have better solutions.

-Bill