Much has been made of the lower losses on the panel to controller path with MPPT because the amps are less. So once you have your loss measured, how valuable is it to improve on that if you don't like the loss amount you have?EG, before I changed it all, I had a 1% loss on that path, but now I have a 2% loss. It can be reduced with a lot of bother, but is it worth it? Others with a similar problem might be interested in the calculations here.At the time, the Vmp at the panel end was 29.0 and at the controller it is 28.5, so loss is 0.5/29 = 1.7% so with some work in my case this could be reduced to half that, say. So what? Panel rated watts 255w. At Nominal Operating Cell Temperature (NCOT) of 45C (and today it came to 45C with the IR gun) and ambient 20C, you get a spec -0.43%/C drop in power for a total of 8.6% at NOCT so 8.6% of 255 is 22 so now you are down to 233w. Add line loss of 1.7% so now you are at ( 1.7% of 233 = 4w) so input to the controller is say 233-4 = 229wOutput from the controller was 215w at the time (12.7v x 17a) so loss in the controller is 229-215 = 14w/229 = 6%. (Reasonable mid-90s controller efficiency)So what would the amps to the battery be if only that lousy 1.7% line loss on the panel to controller path could be cut in half?Still starting at 233, now subtract 2 instead of 4w = 231w to controller with same 94% efficiency, loss is 13.86 instead of 14w Output is 217 instead of 215wSo with same batt v, you get 217/12.7 = 17.1a instead of 17a.Hmmm. How much bother is worth 0.1 amp when you are already getting 17? BTW, yes, I have a new 255w panel instead of the 230w panel for the 5er, and I will post some test results when the sky is right to allow testing someday soon. :)

It's all about balance BFL, what is it worth to you is what's important. 255w sounds like a Mono.

Unless I have an issue of poor performance that I believe can be improved I am not even taking the time to measure. Reason is for the exact reason BFL13 illustrates... lots of effort for little gain.

JiminDenver wrote:It's all about balance BFL, what is it worth to you is what's important. 255w sounds like a Mono.It is a poly Canadian Solar (made in China) CS6P-255P with Vmp 30.2, Imp 8.43 and Voc 37.4, Isc 9.0I have it on the Eco-Worthy and they seem to be working well together. I need proper blue sky to do proper testing, whenever that happens.

It's easy to calculate the loss, all you need to know is wire guage, wire length, and max current. Once you have the number, it's up to you to see if you want to improve.I agree with BFL, for a few % not really worth the effort and cost. And it is easy to do the process in reverse. Figure what loss you will live with, once you know the current and length, easy to determine minimum wire gauge to meet that loss. Keeps you from either (a) spending to much on to large wire or (b) redoing the whole wiring because you used way to small wire or way to long a run.

BFL13 wrote:JiminDenver wrote:It's all about balance BFL, what is it worth to you is what's important. 255w sounds like a Mono.It is a poly Canadian Solar (made in China) CS6P-255P with Vmp 30.2, Imp 8.43 and Voc 37.4, Isc 9.0I have it on the Eco-Worthy and they seem to be working well together. I need proper blue sky to do proper testing, whenever that happens.My 220w is a Canadian solar. I'll be interested in how it works out. I've seen the Eco-w's for $85 in auction on ebay.

Solar-Panel to Controller Loss | Good Sam Community

87 Replies

BFL13
Explorer II
May 31, 2015
Salvo wrote:
You realize you have an improbable scenario. The maximum power point voltage is 27.5V while the battery is 30V. I doubt you'll see any current.

BFL13 wrote:

EG at 800 and 45C (NOCT list of specs), you get INPUT 185w, (no line loss) (27.5v x 6.71a) and if controller is 95% eff then OUTPUT watts is about 185 -9 = 176w and divide that by 30v = 5.87 amps

Why can't 5.87 amps charge the battery at 30v ?

The question is why can't the 24v battery get any current at 30v as long as "panel voltage" is higher than 30.0 volts?

If the controller is PWM, panel voltage will be Vbatt plus line loss, so the 'real' panel voltage we are talking about must be (the same as when you take) Voc. ??? There is no Vmp with PWM.

The Voc for the 65C IV curve is about 32v so why won't the 30v battery get any current at 65C? I admit I am very confused!

But if the controller is an "MPPT" now you have the buck converter in there, which changes how you get any amps out to the battery. So if now the input voltage has to be higher than 30 by 1 volt you need 31 volts input. Input is Vmp in Bulk, and with Vabs set to 30, you will be in Bulk till you get there.

The specs say the panel's Vmp at STC is only 30.2 with a 25C panel so how can you have Vmp at 31 at even higher panel temps?

Does this mean I can get to 30v with the 60 cell panel with PWM (which I did), but not with MPPT? Meanwhile Morningstar is saying you need MPPT to the rescue because PWM can't do it! Huh? ( It turns out they really mean any controller that can handle two 60 cell panels in series for the Voc input limit)

I suppose I could just test for how far up the MPPT controller can get the 24v batts , comparing Vmp which I can measure easily, and Vbatt to see when there is a cut off in amps. All work and no play! (except for swimming up at the lake of course :) )
Salvo
Explorer
May 31, 2015
You realize you have an improbable scenario. The maximum power point voltage is 27.5V while the battery is 30V. I doubt you'll see any current.

BFL13 wrote:

EG at 800 and 45C (NOCT list of specs), you get INPUT 185w, (no line loss) (27.5v x 6.71a) and if controller is 95% eff then OUTPUT watts is about 185 -9 = 176w and divide that by 30v = 5.87 amps

Why can't 5.87 amps charge the battery at 30v ?
BFL13
Explorer II
May 31, 2015
EDIT I just remembered about those buck converters where input voltage had to be at least 1 volt above output voltage

http://www.ebay.ca/itm/DC-DC-Adjustable-Buck-Converter-4-5-30V-to-1-2-29V-15A-Step-down-voltage-Module-/251961012008?pt=LH_DefaultDomain_0&hash=item3aaa0bef28

But when I was at the 30v on the 24v I was using the Solar30, which does not have a buck converter and no Vmp to worry about either.
---------------------------

Ok, but Voc is at the bottom of the IV curve where I got that 45C/35. Anyway, we did that earlier for the power coefficient, where my 255 at 45C vs 25C loses 20 times 0.43% = 8.6%= 22w to 233W.

I see how the top of the knees go left to lower voltages with higher temps so that is the Vmp getting lower in voltage. Current holds ok going left but the lower V makes lower INPUT watts to the controller.

I am confused about where along the Vmp is so low you can't charge the battery to 30v anymore. Help! :(

EG at 800 and 45C (NOCT list of specs), you get INPUT 185w, (no line loss) (27.5v x 6.71a) and if controller is 95% eff then OUTPUT watts is about 185 -9 = 176w and divide that by 30v = 5.87 amps

Why can't 5.87 amps charge the battery at 30v ?

To get no amps at 30v, watts would have to be under 30w output and 31.5w input. That would be a really hot panel!!!! But it could easily be a low light situation to have watts that low.

Help!
CA_Traveler
Explorer III
May 31, 2015
BFL13 wrote:
Salvo is using Vmp but it looks like it is Voc that counts?

Here are the IV curves for my 255 panel and its other specs. The I-V curves for temperatures shows what I have seen and reported where at 45C, voltage is 35v

I am stuck on how to interpret the insolation IV curves as to how low for low light you need to go to get a Voc of 30v.
Voc and it's temp comp is important so that the controller input voltage is not exceeded.

Your posted link shows just over 30V for 45C - the grey curve. From your link use the Pmax temp coff.

Where did the idea that Voc is used to determine power - it's not and Voc is not part of the IR curves.
Salvo
Explorer
May 31, 2015
The controller begins to lose performance when Vmp = 29.6V, which occurs with 34C panel temperature.

Beside temperature, lower irradiance will also impact performance. At 800W/m^2, Vmp drops to 27.5V. That's equivalent to 13.75V for a 12V battery. You're in a world of hurt now.

BFL13 wrote:

Salvo is using Vmp but it looks like it is Voc that counts?
CA_Traveler
Explorer III
May 31, 2015
Sal, Minor typeo in formula should be .004V/C.

red31, Voc is not involved in the temp comp loss.
BFL13
Explorer II
May 31, 2015
Thanks for the calculations!

Salvo is using Vmp but it looks like it is Voc that counts?

Here are the IV curves for my 255 panel and its other specs. The I-V curves for temperatures shows what I have seen and reported where at 45C, voltage is 35v

http://www.canadiansolar.com/down/en/Datasheet_Quartech_CS6P-P_en.pdf

My own measurements of 45C and 35.2 Voc seems to validate my IR gun method of pointing it up under the tilted panel for how to do that.

I am stuck on how to interpret the insolation IV curves as to how low for low light you need to go to get a Voc of 30v.

The actual amps reduction doesn't matter as that just means taking longer to raise the Vbatt.

You get both things together so there are many scenarios! Low light but low temp too, etc. The NOCT panel specs combine 45C panel with 800 light, but that is just one scenario.

-------------
Tee hee, Morningstar must have missed how I got the 24v bank to 30v with my Solar30 on the 60 cell 255 at 45C :)
jrnymn7
Explorer
May 31, 2015
...81C, really?

If that's the case, I think Morningstar was just playing it safe. And it just happens to encourage 60 cell panel owners to buy their mppt, rather than a pwm.

If you were charging 6v's, on a hot day, I would think 29v at the batts would suffice. And on a cooler day, both Vpanel and Vabs would rise together.

Morningstar is saying you cannot use a 60 cell panel with a pwm controller, so what should one use to calculate panel voltage when using a pwm cc... Voc or Vmp or ???
Salvo
Explorer
May 31, 2015
The 60-cell panel Vmp = 31.26V. The question is: at what temperature does Vmp drop to 29.6V. I'm saying Vmp is at the edge of the IV curve cliff and therefore a valid interpretation where the controller can't output 29.6V.

Did you say you had 1.7% line loss between panel and controller?

Controller input voltage after line loss is:

Vin = Vmp * (1-1.7%) = 30.73V

Now we calculate the temperature rise that causes the voltage to drop from 30.73V to 29.6V. Vmp temp coefficient = 0.4%/C

Delta T = (1- (29.6V / 30.73V)) / 0.005V/C = 9.2C

At 34.2C (25C + 9.2C) the controller will have difficulty supplying 29.6V to the battery.

BFL13 wrote:
The question is how high must panel temperature be so you can no longer get the 24v battery to say 29.6v ( twice 14.8)?
red31
Explorer
May 31, 2015
BFL13 wrote:

The question is how high must panel temperature be so you can no longer get the 24v battery to say 29.6v ( twice 14.8)?

When Voc approaches 30v.

@ -.34%/C, 37 Voc,

7/37 =.19 19%

19/.34 = 56C

56+25 = 81C

Forum Discussion

Solar-Panel to Controller Loss

87 Replies

About Technical Issues

Related Content

Solar panel

Solar panel

Solar panels/controller advice

Sway Control

cheap solar panels