Buildout: 2015 Chevy Colorado, 2015 Fleet, and Primo Battery/Solar Setup

Esus

Senior Member
Joined
Oct 20, 2016
Messages
118
I wanted to toss some build info on here regarding my rig in the hopes that it might be useful for someone else down the road be it someone with a newer Chevy Colorado or someone looking for solar/battery details which, of course, is very frequent on WTW. I know that for myself, despite this being my second overlanding rig, I still relied on this forum heavily for the build. I put this in the Truck Campers section because most of the info is about the truck suspension and solar/electrical, not info specific to FWCs.

Vehicle and Camper Info

2015 Chevy Colorado Crew Cab with Long Box, Z71, 3.6L V6 4WD

This truck has been great so far. 269 lb-ft torque at 4000 rpm, 305 hp, 18/26 mpg. Seems to have no issue with the camper on despite being fairly close if not a little over the vehicle’s GVWR of 6,000 lbs; base payload ticks in at 1520 lbs. I’ve driven into the Rocky Mountains and back on several occasions still getting around 16-17 mpg with the camper and cab fully loaded. That will, of course, start taking bigger hits in the wind and at high speeds.

2015 FWC Fleet

I bought a used Fleet that had barely seen any use and was fully loaded: Fridge, heater, water heater, sink, stove, dual fans, awning, exterior lights, folder over couch floor plan, silver spur. Love it.

Suspension Upgrades

As I knew would be the case, the camper was a little much for the truck’s stock suspension. This is also my daily driver and the camper is not on full time. After doing quite a bit of research, I decided to add airbags, see how they worked, and go from their if additional help was needed. I opted for the Ride Rite airbags and the Airlift dual, wireless compressor. Love the setup. The compressor and wireless receiver fit nicely in the engine compartment near the battery. The wireless controller is easy to use and has two programmable presets which work nicely for camper-on/camper-off. Because each side can be controller separately, this setup can be used for additional leveling and I wired it to work even when the key is not in the ignition. So far, even on normal four-wheel trails, I haven’t felt the need to add anything else. I barely notice the airbags when the camper is off, even when left inflated to their minimum recommended (5 or 10 psi, can’t remember). I did also add a 2” leveling kit to the front because the stock Colorado has a rake on the front end. This leveled it out and added some clearance which I think makes it look and perform quite a bit better.

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Platform Modification

The Colorado has significantly higher bed rails than the Tacoma so I had to build a platform to boost the camper high enough out of the bed for the wings to clear the rails. Another gotcha with the Colorado is that the rails are raked and the bed isn’t. Another words, the rails are higher at one end than the other. Not wanting to mess with raking the platform, I just made sure the entire platform allowed for the wings to clear even at the deepest part. It was pretty straight forward. I used two 2X4s stacked to create cross supports. Four of these run east to west so to speak under a 1/2” thick piece of sanded ply (or 5/8”, I can’t remember). I then coated with heavy duty outdoor paint, threw it on some sawhorses, lowered the camper lightly onto it, and mounted it directly to the bottom of the camper.

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Battery/Charging

Next up was the battery and solar setup. I like to go off the grid. Indefinitely! Because of this, rather than upgrading the componentry for charging from the alternator while driving, I opted to put a beefy solar array in place. So I left the stock wire run and isolator in place. Often, I don’t even bother plugging the camper into the truck. It’s just not necessary.

Battery

To size, I began with the battery sizing spreadsheet floating around this forum. The default numbers weren’t very accurate so I modified those to reflect the gear in a modern FWC and then split total amps into two seasons so I could get a realistic idea of what cold vs hot weather camping would look like in amp hours. This is where I wound up for my estimated usage and needs:

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I wanted to be able to go off grid for two full days without any charging whatsoever as a base. That would equate to a ~120 ah usable battery solution. I began considering the following variables: size of my battery compartment, the fact that they would be located inside without exterior ventilation, and weight among other things (quality, price, lifecycles, etc). After thoroughly exploring various combinations of AGMs I was considering pulling the trigger on a nice Lifeline solution when I began bumping into LiFePO4 solutions here and there. I stumbled across a sub $1k Lithium with a battery management system built in and added it to my short list:

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I decided to go with the LiFePO4 for several reasons:

· I can use nearly all of the battery’s ah capacity without damaging it
· It should last for several thousand of cycles rather hundreds
· Faster charging
· You won’t damage it by using it before it is fully recharged
· The built in BMS guarantees you won’t accidentally damage it
· 3 year warranty
· I like cool new tech
· And most importantly, it only weighs 29 lbs! (weight being important to me in my mid-sized truck)

I figured 100 ah usable once I added robust solar would be sufficient especially since I was probably overkill in my energy requirements to begin with. The one drawback that should be considered with LiFePO4 is that the BMS will automatically turn off charging somewhere in the 20-30 degree F range. I don’t think this will be an issue for me because while the battery won’t charge when its that cold, it will still operate. I should be able to fire up the furnace and run it for much longer than I will need to warm the inside environment back up to acceptable charging temps.

A little side note, the battery I went with was from a company called Battle Born Batteries out of Nevada. Not only did they give me a discount when I called to order one, but they chatted with me on several occasions and answered a ton of questions which was very helpful. Good people, solid offering.

Panels

Next I had to decide how much solar to add. This can be kind of tricky. I decided to poll some people on the forum as well as estimate the amount I would need based on the average solar radiation per day that exists in the general areas I’ll be spending the majority of time in. Fortunately, around the Rocky Mountains we don’t have really high temps or high humidity, which are both major hindrances to solar efficiency. I looked at weight, power, and cost for this. I estimated somewhere between 200-300 watts of solar and then began looking at my options. It appeared to minimize weight and maximize output, 24v panels would be best if I were to go with rigid, traditional panels. That way I could get a single panel and not have to have multiple.

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But the more I poked around I kept finding very good deals on flexible panels that weighed practically nothing. The only negative thing I had heard about them was heat problems. More on that later.

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So with two Solar Cynergy flexible panels I’m getting 240 watts, virtually no additional weight at all, and they are backed by a 10 year warranty. After measuring up the panels and looking at where the pre-installed SAE plug on my Fleet was, I realized that I could easy fit a 3rd, smaller HQST in the setup and add an additional 50 watts for only $95 extra. Why not potentially oversize for such small cost? So that would be 290 watts total. Now to see if the math checks out.

Having that panel solution in mind my calculations went something like this: I looked at the average solar radiation for Denver, my baseline for the areas this rig will camp most. (UT, WY, CO). It's 5.54 kWh per square meter. Multiplied by my panel kW (.29) I get 1.6066 kWh per day, or 1606.6 Wh per day. Divide by 12.8v for 126 amp hours per day, per square meter. I’ll have ~.99 square meter of panel. So if I'm doing all of this math right, 126/.99 means I can expect to generate ~125 ah a day as a daily average in any season. But of course that's assuming I get my theoretical maximum amount of power, which of course, I won't. Considering my bad math, what other people have measured with similar setups in real life, less than ideal panel location in the morning and evening, shading from parking under trees, etc, bad weather, the ~%70 efficiency of panels to begin with, and fudge factor in general, I opted to go with ~50% of that number. So hopefully I'm still around ~60 ah per day which is more than enough to meet my likely 50 ah a day energy needs.

After all of that, Rando commented with this link: http://pvwatts.nrel.gov/pvwatts.php which of course made life a lot easier. But it also confirmed I was in the right ball park.

Controller

Wired in parallel, I’m looking at 30 amps @ 12v. Wired in series, I’m looking at 10 amps @ 36v. I decided I wanted to be able to deploy both options. Series was the front runner for several reasons:

· Easier to wire
· Won’t be pushing the limits on the wiring (stock 10awg and even an 12awg SAE adapter)
· More optimal for the controller

The one downside to series is that shade on one panel decreases the efficiency of the entire array, not just that specific panel.

I decided after only a little research that Victron was the way to go based on quality, cost, and for me, the ability to interface to my phone with Bluetooth. In my last rig I didn’t have the insight into the system that I would have liked and it proved difficult to troubleshoot because of this.

An interesting thing about solar panels is they generate quite a bit more voltage than they’re rated for and this changes with temperature (think resistance). After crunching the numbers, if a 12v panel can exceed 25v in the right conditions and I wired three of them in series, it could easily exceed the Victron 75/15. If I wire in parallel, the 30 amps would smoke that as well. So I opted for the Victron MPPT 100/30.

[SIZE=10.5pt]I saw some mention in my research that MPPT wasn't as effective with LiFePO4. I can't see how that is true because the MPPT specifically provides a boost during bulk, and LiFePO4 batteries charge to nearly 99% in bulk. MPPT seems more advantageous for lithium than for LA considering this. Also, the Victron algorithm is fully programmable which is important considering my battery's different chemistry (although with the built in BMS the manufacturer says 14.2v bulk and 13.5v float is ideal which is very typical in many LA configurations).[/SIZE]

[SIZE=10.5pt]Battery Monitor[/SIZE]

[SIZE=10.5pt]Lastly, I want to know what is happening within this setup. I need good data! Already on board with the Victron gear and having heard nothing but good things about their battery monitor, I went with the BMV700. It also interfaces with the phone via Bluetooth so I figure I can start with one dongle, switch back and forth between the solar controller and battery monitor, and if I decide to add a second dongle down the road I can. [/SIZE]

[SIZE=10.5pt]Purchase and Installation[/SIZE]

[SIZE=10.5pt]So I pulled the trigger and ended up spending about $1600 all told (battery, panels, controller, monitor, etc). [/SIZE]

[SIZE=10.5pt]The controller and the shunt fit perfectly in the existing battery compartment which made wiring very easy.[/SIZE]


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[SIZE=10.5pt]The installation of the shunt was very straightforward. The trickiest part was where I wanted to mount the lcd readout. It made sense to put it where everything else was which is on the opposite side of the camper from the battery. It turned out to be pretty straightforward to run the cable under the panel that covers the water tank, through the cabinet with the water heater, and then into a spot between two drawers very near the other switches and gauges. All it required was a 2” hole bit. Looks great and is in a very usable place. The programming was ridiculously easy as well. Just tell it how many amp hours the battery’s capacity is and boom, you’re done. [/SIZE]

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[SIZE=10.5pt]The panels were a bit trickier. As I eluded to earlier, I didn’t want to run into any of the heat issues many had mentioned with flat panels glued or mounted directly to the aluminum roof. Also, if a panel did blow out or needed to be replaced, it would be handy if it was removable. And finally, I always prefer not to penetrate the roof if possible.[/SIZE]


[SIZE=10.5pt]After combing the forums and vacillating between a bunch of possible ideas, I ended up using Weld Mount studs to create bolts without drilling into the roof. I then added a plastic/air/plastic barrier between the roof that consisted of 8mm thick clear Twinwall Polycarbonate and bolted the panels through their eyelets to the roof with polycarbonate in between. Finally, I used the remainder of the Weld Mount adhesive to glue down a nice cable management system that concluded with a Renology MC4 to SAE adaptor. Why they don’t sell these with a 90 degree angle in them in curious – I certainly couldn’t find one.[/SIZE]


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[SIZE=10.5pt]Interesting thing about that Renology adaptor - I finish installing, wiring, etc and feel like Chevy Chase in Xmas Vacation as I’m about to plug the PV wires into the controller. Boom, nothing happens. It just blinks that it doesn’t have enough juice to do any charging. I use the app and interface with the device – 0 watts, 0 volts. What the? Then, out of a cob web ridden, dark corner of my brain I remember an Amazon comment about that adapter having come with its polarity reversed. The controller instructions read that reversed PV polarity will not damage it, so… I switch the wires. Boom![/SIZE]

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[SIZE=10.5pt]Electrical system results[/SIZE]

[SIZE=10.5pt]I’ve been monitoring the system with the app and everything looks great. Interestingly it charges at over 9 amps even in my imperfect parking spot in my driveway (there is a large tree in the way for a lot of the day but it is not heavily leaved this early in the season). I suspect that has to do with the MPPT boost. The rig is not parked east to west either. Also interesting, in fairly mild temps (not even below freezing), the panel voltage hit 75.8v – already exceeding the limit of the 75/15 controller that I didn’t go with. I’ll be glad to have the 100/30 when the temps get truly cold. So far the highest yield I’ve produced with the array in a day has been 680 Wh. Divide that by 12.8v and you get 53 ah - gotta love research/math validation! Works for me, I think I’m set![/SIZE]

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[SIZE=10.5pt]Also, it turns out the readout from the LCD is plenty sufficient for the battery monitor and the Bluetooth works great for the solar controller, so I’ll probably stick with single dongle for the foreseeable future. [/SIZE]

[SIZE=10.5pt]Road Test [/SIZE]

[SIZE=10.5pt]Hitting Colorado, Utah, Idaho, and Wyoming for a nice leisurely climbing trip in about a week. If anything notable pops up I’ll be sure to update. If I can lend a hand or if anyone would like more detail on something, feel free to comment or PM me. And a big thanks to everyone on the forums that lent their brains and experience to my newest build![/SIZE]

[SIZE=10.5pt]Cheers![/SIZE]

[SIZE=10.5pt]-Eric[/SIZE]
 
What an excellent detailed report! I'm a little older so my learning curve is slightly slower, but I follow you. Go luck and drive safely. I'd like to adapt my solar controller to a blue tooth, great idea for monitoring the system when not standing in front of the display.
 
Great report. I am really interested in the Colorado - Duramax Diesel so enjoyed seeing the mounting questions. Having gone though similar solar builds a couple of times it is great to see what others do as well. I am really interested in the Li batteries and once the cost comes down more will probably give them a go. Especially liked seeing how you mounted the bolts for the panels as I think that is a common issue.
 
michgoblue said:
Great report. I am really interested in the Colorado - Duramax Diesel so enjoyed seeing the mounting questions. Having gone though similar solar builds a couple of times it is great to see what others do as well. I am really interested in the Li batteries and once the cost comes down more will probably give them a go. Especially liked seeing how you mounted the bolts for the panels as I think that is a common issue.
Being a 2015 Colorado, the diesel wasn't an option for me at the time. If I had to do it all over and it was 2016 or later, I would have gotten the diesel, converted it to a flatbed, and got the flatbed fleet - man that would be a sweet rig! Thanks and cheers!
 
Esus said:
I wanted to toss some build info on here regarding my rig in the hopes that it might be useful for someone else down the road be it someone with a newer Chevy Colorado or someone looking for solar/battery details which, of course, is very frequent on WTW. I know that for myself, despite this being my second overlanding rig, I still relied on this forum heavily for the build. I put this in the Truck Campers section because most of the info is about the truck suspension and solar/electrical, not info specific to FWCs.


[SIZE=10.5pt]Road Test [/SIZE]

[SIZE=10.5pt]Hitting Colorado, Utah, Idaho, and Wyoming for a nice leisurely climbing trip in about a week. If anything notable pops up I’ll be sure to update. If I can lend a hand or if anyone would like more detail on something, feel free to comment or PM me. And a big thanks to everyone on the forums that lent their brains and experience to my newest build![/SIZE]

[SIZE=10.5pt]Cheers![/SIZE]

[SIZE=10.5pt]-Eric[/SIZE]
awesome write up Eric!
 
Nice rig Eric. Check out Bucklands big Main to Alaska thread/blog he has the the diesel and did air bags added a leaf, stiffer sway bar and upgraded shocks. Very curious how his trip goes. I like the little Diesel. Maybe a replacement for my Subaru in a couple of yrs.
 
Taken the rig out for several ~3 days trips and one 9 day trip. The solar/LiFePO4 setup has worked flawlessly so far. I've used a total of 1335 Ah and I've seen the solar generate over a kilowatt of energy on a good day! I don't even bother plugging the camper into my truck anymore for the little trickle it provides over the long 10 awg wire to the separator when I'm actually driving.

I did run into one issue that I thought I'd share. I didn't exactly understand how the Victron BMV 700 worked (or any shunt based battery meter for that matter) initially. I followed the directions for it and the directions for the solar controller to the letter, but independently. This led me to connecting the negative from the solar controller directly to the battery rather than the shunt. Consequently, I was getting discharge data but the meter was not aware of the solar recharge. I was a bit confused when I looked at my meter after a single day and it said my setup had 0% left while everything was running fine in full sun! Anyways, problem solved and kind of a no-brainer in hindsight.

The panels haven't budged with the mounting system. I'm calling that one a win. I had some strange warping the day I mounted them that I think was from the mounting process, but I haven't had a single problem since including a drive through the Utah desert at noon in June in full sun. Boom.

Cheers,
Eric
 
Thanks for the update! I ended up getting a great deal on a 2017 Colorado Diesel Crew Cab Long Bed Z71 and have loved it the couple trips I have taken so far! I also bought 2 of the 120 watt panels and have a mount and room ready for a 3rd but it has not been needed. Even parking in dark shade of trees over 4th of July I still managed enough juice to keep my VMAX 155 AGM Solar Tank topped. Still, I am building a connector for the truck just in case due to all the rainy days we get here in the PNW.

I was surprised about the bed being sloped relative to the bedsides but remembered reading here that was the case. I built a quick a dirty platform (got the truck the weekend before the 4th and wanted to use the camper), so once Summer is over I will pull the platform and perhaps trim it some so that it looks level to the bedrails. That 3/8" difference just bugs me!

My Duramax has been great with and without the camper. Didn't have time for the airbags before July 4th but it handled fine for a couple hundred mile trip and I got 25+ mpg. Added Firestone Airbags with the dual valve remote wireless and look forward to seeing how it rides with the camper for our next trip in August.

My only concern is that the max amps I have seen from the solar has been 8ah - that seems a little low for the 240w panels. I haven't had a ton of direct sun overhead though to tell if I truly have an efficiency issue.

Anyway your posts here really helped a lot as I was setting up my camper and truck!
 
Eric, et al,

I have read your solar posts as well as Vic Harder's (great thread - maybe the best) and others.

My system will be very similar to yours with the major difference being that I will be using two Lifeline GPL-4CT AGM 220Ah batteries instead of the LiFePO batteries you used.

I plan to use the Victron 75/15 MPPT and the BVM-702. Plus Blue Sea battery switch.

Question: I do not see an inline fuse in your system description (maybe I overlooked it). Did you use one (or more) and where did you put it (them)?

I am only referring to the solar charging part of the system here as I do not plan on connecting my camper electrical to the truck electrical.

Do you have a wiring diagram for your system?

Background: I am replacing two worn out 9 year old 220Ah FLA batteries and adding solar comprising 2-Grape 100 Watt panels. I have done calculations and sizing and plan to add a 120 W flexiable deployable panel and/or perhaps replace one of the 100 Watt panels with a 150 watt panel if this system produces inadequate power. I already have an IOTA converter/charger with IQ-4 for the shore power side.

Regards,

Craig
(this was previously sent as a PM)
 
michgoblue said:
My only concern is that the max amps I have seen from the solar has been 8ah - that seems a little low for the 240w panels. I haven't had a ton of direct sun overhead though to tell if I truly have an efficiency issue.
Hey Michgoblue - stoked for you with the Colorado. What a great truck right? Glad my post proved valuable to a fellow Colorado owner!

Are your panels wired in series? When you consider all of the collective inefficiencies and real world application, 8 amps seems pretty reasonable. My 290w are wired in series and I get about 10a in direct sun. Hope that helps.
 
ckent323 said:
Question: I do not see an inline fuse in your system description (maybe I overlooked it). Did you use one (or more) and where did you put it (them)?

Do you have a wiring diagram for your system?
Craig,

I responded to your PM before I saw this post so I'll copy my reply here as well:

Because I wired my panels in series, the 10 awg wire that came pre-installed is vastly sufficient to transmit the most energy the panels could possibly generate, so I opted not to fuse that portion. I probably should have a fuse between the controller and the battery, but again, the wire is really oversized for the length of run and energy that's capable of being produced by the PV. I'm probably just being lazy and I wouldn't tell you not to fuse your setup... but really a PV array of this size can only generate so much energy. Just my two cents.

I had a really nice complex wiring diagram for my last rig, but this one is so simple I never bothered to create one - especially since it's not connected to the truck. Just remember to connect the negative of your solar to the load side of the BMV shunt and not the battery!

Cheers,
Eric
 
Eric,

Thanks for the prompt response. I ordered most of my parts from PKYS today (free shipping and better price than Amazon).

Charge Controller - Victron 75/15
Battery Monitor - Victron BVM-702
VeDirect Cable to monitor - Victron 5M
VE direct to bluetooth - Victron smart dongle
Dc Source Select Switch - Blue Sea 6007
40 Amp Circuit Breaker - Blue Sea 7138 187-40
Busbar - MiniBus 5 x 8-32 Common Bus Bar with Cover - Blue Sea 2314
Dual Power Post 2 x 3/8 Studs - Blue Sea 2017


Batteries and Panels were bought separately. I got a slightly lower price with free shipping buying the batteries online from Powerstride instead of buying in person. I am in Solvang,Calif and they manufacture in and ship from San Dimas, CA about 150 miles from here so I should have them within 10 days or so.

Any recommendation on entry gland? I am looking at the Link Solar roof entry gland. Alternatively I could drape wires down the back and use a Zamp or equivalent sidewall port (trade off of roof penetration versus wires available for snagging).

Also any recommendations on the MC4 connectors and cable? Is one brand as good as another (looking at Renology and Signstek at amazon)?

Anything missing?

Regards,

Craig
 
That Link solar is nice. Is it going UNDER your panels or next to them? I have mine UNDER mine, so I just bought a cheap plastic electronics hobby box, drilled holes in it, two MC4 cable glands, wire nuts, and 3m 4200 to seal it all to the roof under my panel.

If you can, lay out all the parts on a piece of cardboard to check placement of components, pre-wire it, and then use your cardboard template to make a base out of wood to mount into your battery box or where-ever you are putting the controller bits. Best to keep the controller CLOSE to the batteries, as the wire should be short and the temp sensor is in the controller, not on the batteries.

Speaking of temp sensor, since you are getting the 702, you have the option of adding battery temp to your battery info... nice to have.

As for missing, are you connecting to the truck charging system? The Blue Sea ML-ACR is nice!

Vic
 
Vic,

Thanks for your comment!! I forgot to include the temp sensor to my order. I was able to add it however and avoid shipping cost. ;-)

BTW: I do not plan to connect the camper to the truck. I may change my mind but before doing that I think I will add more panels (plus whatever is required to accommodate them).

I am working on a write-up of my design similar to what you did, but omitting a lot of the investigative stuff that you already did and shared for all of us - THANK YOU!

That write up will cover my calculations, questions, decisions and final design. It references and heavily leverages the work and comments by you Rando, ntsqd, ESUS, and others.

Regards,

Craig
 
Craig,

My current rig was pre-wired for solar so I didn't have to do much. I did use a product almost identical to the Link gland on my previous van and although I was a little nervous punching a hole in my roof, it ended up working perfectly.

Looks like you'll be MC4 the whole way so this won't be an issue, but the Renology MC4 to SAE adapter I bought came with the polarity reversed! Based on the Amazon reviews I definitely wasn't the only one. Just something to keep in mind if you plug everything in and nothing works. Fortunately, your Victron controller won't be damaged if this were to occur.

You did mention the possibility of adding more panels later if needed - that 75/15 controller might not be sized to be future proof if so. With my 290 watt setup (3 panels in series) I've already exceed the voltage the 75 v controller could handle. Glad I went with the 100/30. Just a thought.

Definitely put your controller close to the battery like Vic mentioned. Good stuff!

Good luck, have fun putting everything together!
 
+1 to what Esus just said. My 75/15 is not big enough to handle the 265w on the roof, about 10% of the time. The rest of the time it is just fine.
 
Esus said:
Hey Michgoblue - stoked for you with the Colorado. What a great truck right? Glad my post proved valuable to a fellow Colorado owner!

Are your panels wired in series? When you consider all of the collective inefficiencies and real world application, 8 amps seems pretty reasonable. My 290w are wired in series and I get about 10a in direct sun. Hope that helps.
Yeah I love the Colorado. It drives so nice I forget it is a truck (and how long it is). I put my panels in parallel but can pretty easily switch them back. I have a MPPT controller and tested them both ways and really didn't see a difference.

Anyway thanks again for the info and good to hear my 8 amps is not so far off what I should expect - its just a lot less than the rating! When I had 3 x 120W panels on my old camper I thought I got more amps, but it may have also been conditions - lots of clouds and shade last couple of times I have been out.
 
michgoblue said:
Yeah I love the Colorado. It drives so nice I forget it is a truck (and how long it is). I put my panels in parallel but can pretty easily switch them back. I have a MPPT controller and tested them both ways and really didn't see a difference.

Anyway thanks again for the info and good to hear my 8 amps is not so far off what I should expect - its just a lot less than the rating! When I had 3 x 120W panels on my old camper I thought I got more amps, but it may have also been conditions - lots of clouds and shade last couple of times I have been out.
It really does ride nice. With the riser in the front, the bags at 5 psi when the camper is not on, and E rated tires that are slightly larger than the stock size, mine seems a lot more like a truck now. Still a great ride though.

The reason I asked about series vs parallel is that I would expect you to see more amps in parallel. Parallel keeps the voltage the same and multiplies amps. With two panels, I would expect you to see something close to 20, not 10. Assuming your panels are in the 120 watt range. 120w/12v = 10a. In parallel you multiply amps by number of panels. In series you'd remain at 10a but double the voltage.
 
ckent323 said:
Vic,

Thanks for your comment!!

BTW: I do not plan to connect the camper to the truck. I may change my mind but before doing that I think I will add more panels (plus whatever is required to accommodate them).
It adds a whole lot of complexity to connect the two, but also adds a lot of flexibility. I have yet to find the time to do a trip report or post much info on the success of my build after my first 4 week excursion, but it is working beautifully.

With my 225AH batteries, I have yet to see more than 8% draw down overnight. Meaning I get up in the morning and the batteries are still at 92% or more. I did let the batteries discharge 3 days in a row without solar and got to 80%. (Southern Utah this May was not too hot.. so fridge and fan got less of a workout than you might expect).

I added a Blue Sea voltmeter and ammeter in the cab of the truck so I can monitor what is happening to both the camper and truck batteries, and how much current is flowing between them. I also have the Blue Sea 7622 and remote switch that allows me to connect/disconnect the two battery banks remotely.

That allows me to say that, after that discharge to 80% (45Ah) , I went for a drive and then the alternator started pumped 55A into the camper batteries with only about .4v voltage drop from alternator to camper. Woot!

Long and short of it, if I didn't have solar I could recharge a 3 day discharge in a bit over one hour of driving.

I'm happy!
 
I hear ya Vic. When I drove the Pan Am I had a voltage sensitive relay with a toggle switch and volt meter wired to the dash and large wires from the engine battery to the relay in the van. I only had 200 watts of solar and as we all know, heat and humidity are the enemy of solar. As such, in Central America I relied heavily on the occasional drive to recharge when the fridge was really cranking in that crazy heat (not to mention cranking the fantastic fan every night). That setup was great because we were constantly plugging away at the drive. Conversely, in my current rig, in the Rocky Mountains and surrounding deserts, where I often park in one spot for days, I opted for pure solar. It's so cheap and easy these days. I can sit at Indian Creek for weeks without so much as turning the ignition key! Assuming I have a cohort to drive to the cliffs...
 

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