Good Sam Community

Morningstar has a calculator that will check your setup. On their website search String Calculator. If they don't have your panel you can enter it's specs. They only support their calculators and if you don't have one choose something like the MPPT 60. You'll get the information for the panels including Voc etc. With a non Morningstar controller the panel hookup information may not be correct but there is still a lot of good information.

Voc Voltage Open Circuit

The specs for your controller will include a voltage limit. The voltage used for that limit is the open circuit voltage (Voc) of your panels added up if they are in series or for just one if they are in parallel.

Those panel spec Vocs are for 25C temperature (about 77F) and voltage goes up when it is colder than that. So they warn to allow more than rated Voc when camping in the cold so you don't hit that total Voc limit and fry your controller.

BFL13 wrote:

Vintage465 wrote:
All great info. Personally, I need the best charging when it's cold. I like to winter camp and the recharging in the morning when it's clear and cold is what I need. I think when It is hot thru the night I will have the fantastic fan on and the drain that it has will be overcome the following morning with the solar before it get's hot.

That is why they say to add up your rated Vocs in a series string and then x 1.25 for margin for when it is cold out. If you go over the controller's Voc limit, it fries--no second chances!

I think I'm not in danger of exceeding my Voc's.........but I'd be more sure if I knew what Voc's are. Not real into acronyms here. I'm under the wattage, amps and voltage for what my controller is rated for. All panels in parallel.

Vintage465 wrote:
All great info. Personally, I need the best charging when it's cold. I like to winter camp and the recharging in the morning when it's clear and cold is what I need. I think when It is hot thru the night I will have the fantastic fan on and the drain that it has will be overcome the following morning with the solar before it get's hot.

That is why they say to add up your rated Vocs in a series string and then x 1.25 for margin for when it is cold out. If you go over the controller's Voc limit, it fries--no second chances!

I found this video to be very helpful. Good luck and we love to talk to anyone about this. I have four 12v batteries on a 100watt panel in series and so far am impress what I can do.

https://youtu.be/kF_cVEYxj3E

All great info. Personally, I need the best charging when it's cold. I like to winter camp and the recharging in the morning when it's clear and cold is what I need. I think when It is hot thru the night I will have the fantastic fan on and the drain that it has will be overcome the following morning with the solar before it get's hot.

now that panel prices have come down, and efficiency up so panels are less expensive and smaller for many cases PWM makes sense given the price.

There is at least one case I often encounter where MPPT and series connected panels pays off vs. PWM or parallel MPPT

I have 3 175ish W portable panels. In a few cases when we camp the only location that gives reasonable sunshine is located 100-150 ft from the trailer. For cabling I made up a bunch of cables using 30A RV cables with anderson connectors and paralling the ground with on of the other two wires. So basically I have a cable with one wire #8 and one wire #10. Now stuff 30ish+ amps down that cable with 3 panels in parallel vs 10A in series with an MPPT controller at the batteries. MPPT wins in the series with about a 10% current gain vs parallel.

As far as my experience with MPPT vs PWM, the experiments I did for comparison did show an advantage to MPPT even with short cables, but not as high as one might think. Many MPPT controllers are most efficient with series connected panels with voltage near the max rated for the controller and least efficient with 12V parallel connected panels. That was born out in my experiments with the 12V parallel connected panels have more output than my PWM controller but on the order of 5%. while the series connected setup with 3 series 12V panels had better performance. I have the data archived somewhere.

In any event, IMHO with todays prices if you have room spending the money on and extra panel and PWM controller will get you more AMPS than spending the money on a MPPT controller.

I think what I don't like about NOTC specs is the suggestion that getting 80% is normal, when I would get full Isc aiming at a high sun as being normal. I got the idea they listed the NOTC numbers as some sort of salesman excuse thing. I am muddled in my thinking about all that. "Nominal" does not equal "Normal" I guess.

These guys use "Normal" for NOTC. Only they call it NMOT. they use "nominal" in the warranty statement. They give a graph for low light compared with STC performance

http://www.wegosolar.com/products.php?product=HSQ%252d310M%252dBLK-Hanwha-310-Watt-60Cell-Solar-Pane...

EDIT--I see my Canadian Solar brand panel specs use "Nominal" for NOTC. It probably makes sense in the original Swahili ?

To me it is so easy. Whatever the conditions or time of day, aim the panel and see what Isc is. Connect up and see that is the same as the amps to the battery with PWM and your equipment is working right.

I found that Isc per panel wattage is about the same so I can estimate what a 255 watt panel ought to do if it were PWM, then see what it really gets. I use a 130w panel with 8.2 Isc as baseline.

255/130 x 8.2 = 16 amps So I thought I would see more than 16 with my MPPT. Not really. So after much poking around it turned out to be panel heating reducing input watts so output watts was lower and divide that by battery voltage and there you are. It did come out a little ahead in the morning with lower Isc at lower sun, but mid-day about the same.

Salvo posted his results back when showing his MPPT did much better than PWM/direct early in the day, then the results got close by high noon.

I had the thought the 20 amp MPPT controller would clip the amps so it would be stuck at 20, but it was doing 18.x with MPPT compared with 18.6 with PWM in that test with three 100s.

Heat coefficients for 12v panels are not the same as with 24v panels so that might throw things off a bit, but not enough to matter.

It is not whether or not NOTC works for you, it is that NOTC info shows that panel get hot as you know, they get hot even with 80% 'sun'.

The biased white paper shows when PWM=MPPT, this is a large range, bigger than the blue shaded area, I'll suggest 40-100C

NOTC does not work for me. I would get full Isc when conditions seemed to be more NOTCish. I assumed when I got full Isc that meant it was like Standard conditions. You don't know how much air pressure is compared with temperature and light. To get all of those variables to line up per NOTC would be difficult. One component will be ahead of the other in real life.

With MPPT, to check it, you first check Isc of the panel, get rated Isc in the prevailing conditions, then connect up and see what amps to the battery are when the battery is low enough to have the MPPT in Bulk. That will be as good as it gets for amps to the battery except for edge of cloud events

My Tracer has a setting for temperature but I just leave it at 25C. Not sure what that is about.

Here is how I had the panel when I was doing the temp meaurements with the IR gun at the back of it. Lots of breezeway. As mentioned, the temp is not the same everywhere so it would be hard to get each cell's temp and do its voltage calculation from the coefficient and add up all those voltages to get your "panel voltage". It sort of works as an average using the middle of the panel. (Not showing are the bungee cords I had all over the back of that to stop it blowing away)



My Eco-Worthy has a funny program for seeing how much better it is doing than PWM would be. It is sort of bogus, but it turns out that its PV amps reading is the same as the Isc reading by meter, so you don't have to disconnect the panel to get that figure with the Eco-W.

Many panels have published NOTC.
This test is @ 80% or 800 watts per square meter vs 1000.
20C air blowing on the panel @ 20C.

45C temps in these conditions! with a breeze and space behind the panel for air flow.

"Both conductive and convective heat transfer are significantly affected by the mounting conditions of the PV module. A rear surface which cannot exchange heat with the ambient (i.e., a covered rear surface such as that directly mounted on a roof with no air gap), will effectively have an infinite rear thermal resistance. Similarly, convection in these conditions is limited to the convection from the front of the module. Roof integrated mounting thus causes higher operating temperature, often increasing the temperature of the modules by 10°C."

https://www.pveducation.org/pvcdrom/modules-and-arrays/nominal-operating-cell-temperature

Lwiddis wrote:
Interesting article.

“The MPPT controller will harvest more power from the solar array. The performance advantage is substantial (10% to 40%) when the solar cell temperature is low (below 45°C...”

I don't camp much when the temp exceeds 113 degrees F for me or my panels.

Typically panel temp is about 20C above ambient, which I can confirm from my measurements. So when it is nice out at 25C, panel is 55C and down 10% in watts at around 50C

I cannot understand the way they do panel specs at panel 25C which would mean ambient is just above freezing. Sort of weird.

The MPPT guys all talk about power but PWM could care less about power--just the amps. So all that power being wasted by PWM is bogus, since you still get the rated Isc so the power does not matter.

The main thing is that you need the buck converter in the MPPT to do 24-12 with 24v panels, which PWM controllers cannot do. They can do 12-12 or 24-24, while an MPPT can do either 24-12 or 12-12 or 24-24 so you have a choice between series and parallel with 12v panels.