Hi 

Thanks for the look at your ingenious solar setup. You have done well and designed a very workable rig for your compact camping. Good for you. Looks good too ! 

The outputs are useful to look at. You do get the full output from your panels with the MPPT reg. It shows the theory is correct also. It takes the higher voltage and converts that to extra current with minimal losses even at 8 watts. Screenshot 3 shows how the lower battery voltage enables the MPPT to deliver maximum amps and thus power. 

It is a lesson for people who say I do not have anywhere to put panels.  Bravo !!

Jaahn 

-- Edited by Jaahn on Tuesday 15th of January 2019 09:34:50 PM

Hi 

Thanks for some more instructive screen shots. WOW even a couple of extra watts there, when the battery voltage is down low.

Just for peoples general information, having portable panels mounted in a ~vertical manner like that enables them to face the sun at 90deg so output is best,  but it also keeps the panels much cooler with the hot air rising off the panels and taking away heat. Win win !

Jaahn   

-- Edited by Jaahn on Wednesday 16th of January 2019 10:49:02 PM

The Kyoritsu 2046R cat IV class clamp meter photo was shot when the panels were connected all in parallel & when the panels were a bit below 120 watts, & with 10 metres of extension cables including a 2 metre 12AWG cable which was never intended to be used in this location which was mostly for a Noctua fan in the car while sleeping. If the sun is too far away any cable is better than shadow!

The Projecta solar panels overall size are 638 x 278mm, overall foot print of actual cells is 582 x 237mm, so 78% of the panel area, not brilliant. The solar cells could be stacked tighter & the frame could be reduced in size. But nevertheless when these panels are stacked behind the second spare wheel no bugs hit the forward facing panel. These panels are only 25 mm thick instead of the typical 35mm & don't twist. So total thickness of the 6 panels is only 150mm instead of 210mm, 15.3kgs including added legs & wiring. The 6 panel volume not including handle & hinges is 26.6 litres. Can't complain about that!

I am completely out of room on the roof front to back, including room for sand flag & opening of full tank holders (same space), over by about 32mm, cross bar clamps are not totally clamped on the extruded rails.

I did have a roof platform (still got it) but they are in general poorly designed & simply dead weight. I replaced the platform with a second set of cross bars & reduced weight by 16.4kg. Currently if I have everything on the roof including roof rack rails, cross bars, brackets & 50 litres of fuel & tanks, wheel (not the tyre I normally have, all I could get in Halls Creek), sand tracks, awning..... 142kg! but I can reduce this considerably for off road. Even the bracket for the second spare wheel I have machined out of 5083 alloy to reduce as much weight as possible.

The fridge I have replaced the fan with a more efficient one, shortened the power lead & inside replaced 55 cm (110 cm +& of very thin 16AWG 12 volt lead to the circuit board with 12AWG as part of making the fridge more efficient (extra insulation in another thread)

Whenarewethere wrote:

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The Projecta solar panels overall size are 638 x 278mm, overall foot print of actual cells is 582 x 237mm, so 78% of the panel area, not brilliant.

 

 

 

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The reason I asked about the clamp meter reading was that it didn't add up, nor do the panel sizes.

I have a number of Chinese Sista 60w 540mm x 630mm outside frame dimensions, the Projecta 20w solar panels overall size are 638 x 278mm, the Sista 60w panel actual solar module dimensions are 505mm x 570mm, the Projecta 20w panel actual solar module dimensions are 582 x 237mm. Clearly the panel may be labelled as 20w but the actual area compared to the 60w Chinese panel is a lot more than 1/3rd the sq area.
The other issue is the output, a cheapie 8 yr old ebay 120w panel optimistically claims the Imp is 6.57amps, yet the parallel string of panels rated at 120w shows 7.5 amps in less than optimal conditions. The 60w Sista panels have an optimistic Vmp of 3.43 amps, so 2 panel in parallel would make a 120w and 2 x 3.43 = 6.86 amps, not 7.5 amps. the Chinese panels are renowned to be a tad optimistic when it comes the stuff they write on their labels so the 6.57 amps from technology 8 yrs ago and the 6.86 amps from more recent technology should be read as the maximum with the sun and planets all correctly aligned, not what one would normally see from them even if aligned optimally angled to the sun and connected to a battery. If you get more than 5 amps consider it a bonus.

So, what is the true capacity of these panels rather than the information printed on the label? Anyone have a lightbox to flash test these panels as per STC standards?

 

T1 Terry    

T1 Terry wrote:

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The reason I asked about the clamp meter reading was that it didn't add up, nor do the panel sizes.

I have a number of Chinese Sista 60w 540mm x 630mm outside frame dimensions, the Projecta 20w solar panels overall size are 638 x 278mm, the Sista 60w panel actual solar module dimensions are 505mm x 570mm, the Projecta 20w panel actual solar module dimensions are 582 x 237mm. Clearly the panel may be labelled as 20w but the actual area compared to the 60w Chinese panel is a lot more than 1/3rd the sq area.
The other issue is the output, a cheapie 8 yr old ebay 120w panel optimistically claims the Imp is 6.57amps, yet the parallel string of panels rated at 120w shows 7.5 amps in less than optimal conditions. The 60w Sista panels have an optimistic Vmp of 3.43 amps, so 2 panel in parallel would make a 120w and 2 x 3.43 = 6.86 amps, not 7.5 amps. the Chinese panels are renowned to be a tad optimistic when it comes the stuff they write on their labels so the 6.57 amps from technology 8 yrs ago and the 6.86 amps from more recent technology should be read as the maximum with the sun and planets all correctly aligned, not what one would normally see from them even if aligned optimally angled to the sun and connected to a battery. If you get more than 5 amps consider it a bonus.

So, what is the true capacity of these panels rather than the information printed on the label? Anyone have a lightbox to flash test these panels as per STC standards?

T1 Terry    

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 Hi Terry 

I do not want to start anything here but you are the living end Terry. Just because the post has some discussion about the performance of MPPT you choose to cast aspersions on the panels and insult the poster. You infer they are more than that said by the poster. No wonder you have been banned from other forums. You have no idea of reasonable discussion. Every discussion is slanted to your biased point of view. 

Indeed what does it matter. He has designed a very neat system that suits his use well. It performs as it should and he does actually give reading for different circumstances. His only crime is they do not support your bias against MPPT. 

Jaahn

Clamp meter, Victron MPPT & voltage & amp meters all give readings within more than reasonable tolerances of each other.

A bucket of water over the solar panels provides far more improvement than fiddling around with electrics!

Jaahn wrote:

---

Hi 

 [a] Thanks for some more instructive screen shots. WOW even a couple of extra watts there, when the battery voltage is down low.

Just for peoples general information, having portable panels mounted in a ~vertical manner like that enables them to face the sun at 90deg so output is best,  but it also keeps the panels much cooler with the hot air rising off the panels and taking away heat. Win win !

Jaahn   

-- Edited by Jaahn on Wednesday 16th of January 2019 10:49:02 PM

---

 [a]Yes ,that is when the max input is obtained with a Mppt  ..Something that some do not seem to understand. Especially those who have batteries that operate around 14V  

yes , I found it well worthwhile  to mount my panels on a tilt & swivel arrangement on the roof of the Lawson motor home .Three positioning gave me max available output from sunrise to sunset .The  4 vents on the roof limited the area where I could fit panels

just a simple answer ,with no white herrings thrown in
We ALL know that the panels derate with heat, so you do not need to continually repeat that !
What most of us accept is that the bigger the difference between the battery voltage & the panel output voltage the more useful a MPPT will be .
AS I pointed out to you a loooong time ago ,you have tailored your set up to suit LI batteries [after a lot of experimenting you have come up with a set up that is very suitable for Lis with their near constant voltage & & the panels you use [which will also derate with heat]output voltage leaves nothing to convert .

That is not the same as with the many ,many users of LA batteries whose SOC voltage varies widely [<2V in normal operation ]& panels with a higher output voltage ,[even though they will derate with heat ]The derating rate will be the same in both cases!!!
Don't you /or can't you understand THAT!!!!!
Even a 1volt difference is significant when charging
Your graphs /specs are irrelevant since they apply in all cases!!

I might just go back, Find & repost that loooong post that I posted some time ago which could help others understand the above differences in greater detail.
Why cannot you just accept that you have ,with a lot of experimenting, tailored a system that is imminently suitable for use with LI batteries,but would not perform anywhere near the same with LAs?


"there are none so blind ,as those who do not want to see"

At the end of the day if we cannot sleep in our car solar is irrelevant then I will go back to my previous custom built esky where ice would last a week & stayed cool for 10 days!

The thread I started is about a custom built solar setup that would not take over the car. I simply bought the MPPT controller as it seemed to have more options in reducing wire resistance. A bit like my 300 amp continuous welding cable jumper leads with 2mm solid copper clamps, even 2 sets end to end (12 metres +&- ) have never failed to start a car!

I simply don't have room for panels to take over the car & no off the shelf folding kit I found by the date I needed it would do the job. In the forth photo under the Victron controller there is a fridge custom mounting bracket which might be more interesting reducing the height of the Waeco bracket to 6mm rather than a few watts here or there on a particular solar setup!

I am simply showing you my custom build to squash X parts into Y space. If you want a parts list of the legs I have added to the solar panels I can post that. I have bought anodised aluminiun & nylon hinges with stainless pins. All screws & bolts & Nyloc nuts are stainless 304 or 316. Anderson plugs are original & soldered everything & heatshrinked.

Maybe I am getting up to 126 watts without water on a not perfect day because I have not skimped on wiring, it is pretty much all 6AWG on a tiny setup!

The Projecta panels come with a 20 page instruction manual covering mounting, mounting hole spacings, charging, connecting multiple panels in series, parallel & series & parallel for people like me, with diodes & cable size for various distances, but I am well on top of that particular issue!

Projecta SPP20 specs:
Polycrystalline
Rated power 20 watts
Open circuit 21 volts
Short circuit 1.25 amps
Peak power 17.5 volts
Peak power current 1.14 amps
Test conditions 1000W/m2 25C
Tempered low iron glass

Panels were $42 each in 2018, the cheapest part of this whole project so to speak!


I did spray water on the rear as well as an after thought, maybe it was keeping the panels well into the upper end of 136 watts & brief moments into 137 watt territory & this was not even a stunningly clear Sydney day. But water on the front reached 136 watts without problems.

On a hot sunny day I will put blocks on the bottom edge to lift the entire panel off the ground for increasing free air flow. If I can design some folding legs I might give that a go.

A few more screenshot figures. The battery current & load current you will need to add together for total current. Some battery figure are negative as the load was higher.

The highest wattage to date without water cooling is 126 to very occasionally into 127 watts & this was not with a perfect Sydney sky.

The other half of this entire project, almost entirely for the fridge, is reducing electricity consumption in the first place! It's about my fridge (another little project is in the wings in this department!). Reducing consumption from 0.0140 kWh to 0.0116 kWh under a 35C ambient temperature over a 3 day test (I did get it down to 0.0082 kWh but an extra 60mm of XPS insulation on the fridge was a bit thick) has more benefits than fiddling at the other end. It's easier to save than earn!

Photos:
Screenshots: No water.
Screenshots: Water cooling.
Screenshots: 1 to 22 watts (today was a miserable day & really no break in the cloud but nevertheless the panels hit 122 watts briefly)
Screenshots: 24 to 122 watts.
Fridge (Waeco replacement) 6mm high mounting bracket so we can sleep in the car & not feel it.
Stainless front guide for fridge.
Stainless rear guide for fridge.

Thankyou for posting the specs on the panel label, it does answer the question. The peak power current of 1.14 amps x 6 panels = 6.84 amps and not the 7.5 amps shown on the multimeter clamped around the cable at the solar panel output, not the MPPT controller output. This clearly shows the panel output is significantly more than the labelled specs so the output from the MPPT controller will/should be greater than 120w and all your screen shots show that.
I agree with your logic for choosing an MPPT controller to minimise the cable size required when using portable panels. I have said in the past that this was a good idea if that was going to be the only charger/controller working on the battery because the long cable runs required posed a serious voltage drop unless quite heavy cable was used.

I've said my bit, you have verified what I was saying, so no need for me to post any further on your thread. I wonder if all those claiming just how much better the MPPT controller made the "120w" of solar perform will now admit they didn't bother to actually look at the over all picture but rather run with the end numbers .......

T1 Terry

Last year in the Kimberley region l had not fired up the Victron software to monitor the system as I had my own panel meters (6th photo from top of thread). It was easy to see solar input. There was plenty of sun around as we were trying to keep out of it most of the time, & the amp meter was pretty much topping out at 3.8 amps & a touch into 3.9 amps.

For argument sake let's say that the Projecta panels are performing a bit above specifications of 6.84 amps (6 X 20 watts), this alone shows that it is simply false economy investing in no name Chinese products.

But it still does not account for the additional Victron Voodoo! So getting 3.7 to 3.9 amps series (7.4 to 7.8 amps) converted to 9.2 to 9.6 amps being pumped into the batteries. Even hitting 10 amps, maybe it could be higher but the 75/10 MPPT cuts off at 10 amps.

7.4amps converted to 9.2amps into battery.

7.8amps converted to 9.6amps into battery.

8.0amps converted to 10.0amps into battery.

So an additional 1.8 to 2.0 amps above the panels' output. Or 2.5amps or more above the panels' specifications.

Whenarewethere wrote:

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Last year in the Kimberley region l had not fired up the Victron software to monitor the system as I had my own panel meters (6th photo from top of thread). It was easy to see solar input. There was plenty of sun around as we were trying to keep out of it most of the time, & the amp meter was pretty much topping out at 3.8 amps & a touch into 3.9 amps.

For argument sake let's say that the Projecta panels are performing a bit above specifications of 6.84 amps (6 X 20 watts), this alone shows that it is simply false economy investing in no name Chinese products.

But it still does not account for the additional Victron Voodoo! So getting 3.7 to 3.9 amps series (7.4 to 7.8 amps) converted to 9.2 to 9.6 amps being pumped into the batteries. Even hitting 10 amps, maybe it could be higher but the 75/10 MPPT cuts off at 10 amps.

7.4amps converted to 9.2amps into battery.

7.8amps converted to 9.6amps into battery.

8.0amps converted to 10.0amps into battery.

So an additional 1.8 to 2.0 amps above the panels' output. Or 2.5amps or more above the panels' specifications.

---

I think you will find you have already answered that earlier. The higher voltage gained by connecting the panels in series reduced the losses through the cable running from the solar array to the controller. A test would be to connect a single panel through the wiring used for all 6 panels direct to the battery and then measure the amps flowing. Multiply that figure by 6 to cover all the panels output with reduced resistance and that would tell you the true array output.

Another way of looking at it, the current at the panels x voltage at the panels gives the watts output, is this more or less than the output from the MPPT controller to the battery?

 

T1 Terry 

T1 Terry wrote:

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It appears you are now in conflict with another member of the MPPT choir  

Quote:

For the benefit of those with an open mind

https://www.morningstarcorp.com/parallel-charging-using-multiple-controllers-separate-pv-arrays/

As a further explanation , a true mppt controller has two entirely separate operations

[a] the MPPT section,  which operates independent of battery voltage  ,tracking the panels peak power point continuously..It does NOT sample battery voltage when doing that. It simply is not concerned with battery SOC voltage

It then  uses a 2nd stage to convert that MPPT  DC power into a suitable DC power  source for charging the battery [in simple words, that section becomes a  PWM DC charger]

That second stage,PWM  ,the battery charging stage, is independent  of the first  stage[MPPT]

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Yes, that puzzles me, too. AFAICT, an MPPT controller does not have separate hardware for MPPT and PWM modes. Instead it uses the same hardware for both modes, but switches to a different routine in the firmware. In MPPT mode the duty cycle regulates the panel's power output, whereas in "PWM mode" the duty cycle regulates the battery voltage.

It's a kit, not a commercial product, but the software is instructive:

http://web.archive.org/web/20140626064134/http://www.timnolan.com/index.php?page=arduino-ppt-solar-charger (project page)

http://web.archive.org/web/20140626064134/http://www.timnolan.com/uploads/Arduino%20Solar/ppt.pde (software)