Surprising Power Gains By Cooling Solar Panels

I prevent my panels from getting too hot by keeping them in the shade.

the company DualSun has a panel that can take in pool water to heat the pool while cooling the panels. If no pool, they can also be used to preheat water for your water heaters or go to any heat exchanger. It's a pretty cool system.

The problem is less the water, since you can simply capture it with a rainwater harvesting system and re-use it. The question is if you gain more power than you need to have a pump running all day. Maybe it helps if you just turn the pump on for about 20 seconds every minute, but that might drastically reduce the lifespan of the pump and might leave your panels covered in mineral residue left by the evaporating water.

I would reclaim the water at the bottom, run it down into a geothermal system, in the ground, then when the water cools, it's pumped back up to start the cycle again. Many other uses for that hot water, hot water storage tank for baths, etc.

Being in a desert area I can't do the water idea but I did put a fan under one of my panels and got a better watt hour return than without the fan. Just moving air on the underside helped a lot!

Saves $4, almost $5 on electric bill. Water bill goes up $6. Celebrates with a $7 beer.

You can watercool the panel by making the backside watertight and pump water through it, and use that water in your heat tank or swimming pool heating.
All in all, it's not worth the effort unless you really have a lot of difference between night and day, but the year itself is not changing that much. So if you do have cold nights, the heat is good for storage in a heat tank, and at night it keeps the temperature of the panels stable plus it lowers the amount of electricity needed to heat up cold water to 65+ celsius after it went through the heat tank. Be aware that you should either have cold water or hot water, but not in between due to legions disease that thrives between 20 and 60.

Thanks for making this excellent comparison. One cooling option is to use thermal conductive glue to attach aluminum heat sinks to the back of the panel. You could even hook up a separate solar powered fan to draw air over the heat sinks.

there's no way the extra 5% justifies the cost/waste of the water. Thanks for the video!

I went in 2015-2017 to a energy convention and there was a company who had solar panels with hoses at the backside.
It had a couple of functions.
It was to cool the solar panel and to heat the water for your pool, shower.
Somehow I never saw it again as the idea sounded good.

Thanks for doing the test. I think the 5% extra energy production seems low and probably will scale up to more if done over a home sized array of 2000+ watts. I've hosed down a solar arrays in the middle of the day and noticed upwards 10% power increase on just the watt output.
But, in addition to using up a lot of water, a big problem with is *hard water* stains on the panel's glass from using normal city tap water. Those minerals will get _baked in_ even harder with the intense daily UV and heating. Personal experience.
As someone else mentioned, this can only be practical with a heat sink system on the back of the panel:
(a) no hard water stains
(b) low to zero water waste as water is circulated
Requires a lot more materials like hosing, valve, heatsink, anti-bacterial additives, etc. If its going to give 10% energy gain then might as well spend 10% more on panels and spend less money and time. The ever falling prices of solar panels makes that the best alternative to get more energy output.
However...
I do like this idea of having a substantial behind-the-panel cooling system that would also save the heated water to a solar tank. That way, the house is getting much more energy efficiency from solar panels well beyond the ~21% efficiency of the latest generation solar panels.
Look up "2-in1 DualSun SPRING hybrid panel" that has all the heatsink and hosing built into each panel. The manufacturer claims it can give that 5% to 15% panel energy output efficiency improvement as well as heat the water to 70°C. This is a double benefit that's kind of a no-brainer if it can be made and installed economically. But it really shows what our sun is capable of when the correct set of technology is applied!

i think the data is tainted due to the sprinkler tube being set up in a way that partially shaded the panel. i would say it needs to be rerun and setup in a way where each panel is equally shaded... 0% shaded.
i like the experiment though, curious to know what the real results would be

Love the video! I was thinking of using radiant PEX on the back side of the panels with a closed loop evaporative cooler in the summer to cool the panels and my shop, then the same concept for winter to melt the snow, still a closed loop system but this time pulling the heat with copper heat exchange from the wood burning stove in my garage.. Im very curious of the 5% gain would be much higher without water flowing acrosse the panel surface, but cooling it from the back.

Sundrum Solar has modules that attach to back of conventional solar panels and then use that heat generated for hot water needs, can be swimming pool, car wash, hotels or space heating.

to be clear, efficiency increases below STC. The flow meter was a nice addition. One additional test would be periodic water flow. Save water and allows the water to evaporate, cooling the panels. This will depend on humidity which varies by day and region. Also, if the heated water could be used for things like swimming pool heating or hot water preheating, it gets a bit more cost effective. Water also block longer wavelengths of light (so red more than blue), so cooling the back of the panels might be more effective.

This is informative. I wonder if an internal cooling solution may yield even better results. Not only because the actual cells would be cooled but your also avoid any potential loss of sunlight hitting the cells due to the reflection and refraction from the water cascading down the glass.
Might he something to consider for a future aide by side test.

Maybe you should recommend dual use panels. They harvest the heat with watercooling loops on the back of the panels. So you 1. cool your panels down to get a better efficiency (more Wh) and 2. You can harvest the warm water from the system via heat exchanger.This way you have not wasted any water and get the dual purpose use out of the sun energy

I love your videos.
I’ve been researching a solar heater for my pool. It may be possible to combine the tubes from a solar header with panels to make a cooling system.

Thank you for all your efforts Scott, this video represents pretty much what YT *should be* about in my mind 🙂👍 A temp diff of almost 50% for a 5% gain in yield sounds pretty sobering to be honest. Even if this would vary up to 10%, will be it worth the extra investment for the required material, electricity (water pump) and the water itself, which will become a more valuable resource in the coming decades? BTW - have you observed a significant efficiency gain during winter then?

when i was getting my degree in this field, i met a guy that installs flat fin tubing on the back of panels and the water was cooling the panels and was used to generate heat through thermo heat generators, and some went to domestic use.
the important thing to remember is to use as clean a water as you can if you are going to wet the panels to prevent degrading by mineral build up and water is a universal solvent and will destroy the frame over time

I did a project on this effect in my heat and mass transfer class, the math behind it is very interesting but it's only a viable option at certain temperatures, I primarily studied the effects of wind on the efficiency

What if the water recirculates?

Nice video. I have 800w of ground mount Rich solar panels connected to an EcoFlow Pro and run the sprinkler in the heat of the day. I almost always get at least a 10% increase. It might be because I’m in Oklahoma and it’s 108 today 🤪. I checked my panels and even with water cooling they were 90+ degrees

Majority of the cooling is from water exaporating off the panel so this could probably be done with much less water at intervals. A supprisingly effectave way to cool your house when the ac cant keep up is to hose off your roof a few times throughout the day.

You do a really nice job on these videos. Thanks for all the hard work you put in making your videos. Keep up the great work.

As a standalone fixture, the potential savings are probably offset by the water and power pumping it. However, if were done as a multifaceted system that is cleaning the panels (keeping pv efficiency ratio up), cooling the panel and also heating water for internal use, then the compounding effect could make it a more efficient and cost worthy approach. I think we'll see more cooling systems in future, as pv panels become more efficient and cost effective.

Apparently the temperature coefficient changes with the age of the panel because I have some 14 yo panels with extensive spider cracks that have degraded by about 10-15% at STC, (basically when it's cool out), but when they really heat up in the summer the power output crashes. It was a simple test I did when they were very hot I took a hose and hosed down the panels. I saw over a 40% rise in amperage on my Amprobe. There could have been some SMALL variations in solar input but the sky was clear that day. It was an eye opener for me.

Water drops may also locally concentrate sunlight to a very small area, etching the silicon of the panel.

Try a much slower drip rate.
BTW it's really common in FL to have hybrid panels that channel pool water through the inside of a solar panel to both cool the panel and heat the pool.

I live in Alaska and have a place with a small solar system. The panels are mounted so in the winter the snow reflects some of the sun on them. I have seen them put out 30% more than advertised when it is close to zero F and the sun it bright on a late March day.

Yeah! I've noticed this in my van one day after it rained. Also, it's counterintuitive but my panel covers a ventilation vent in the van, and running the fan produces more power despite the fan load than not.
One great use case for this is for an off grid tiny shack house with a single slope roof where nearly the entire roof is solar to block the sun. The water would keep the roof and shack cooler. In my case during those direct sun hours I'm running a 12v pump to filter rain water used for bathing, washing, cleaning and irrigation so might as well run it over the roof achieve this affect, which i think will also disinfect and heat the water.

It looked like the PVC was casting a thin shadow across the top of the panel. that will cause a big drop in efficiency. Ideally you would only need to use as much water as necessary to evaporate on the panel and not run off.

Well the panels could be manufactured to just have a heatsink and water to run trough them. So you can connect like 10 of them and make a closed loop to a simple head dispenser with a fan.
Would that be worth it? Dont know maybe if you have 800w large panels?

If the mini power meters are not calibrated, you may need to swap their positions to convince both read the same manner.

I have an old panel that is made with a bunch of ~12cm silicon wafers affixed to a white surface. The white area is obviously not completely wasted space if it serves to cool the wafers. Keeping the wafers round also reduces silicon waste too.

"My current power bill" . . . I see what you did there ;-)

As a boater on a liveaboard boat, sailing from point A to point B.... floating "flexible" panels on the water not only provides all the "free" real-estate needed for a 4KW system, it cools the panels and makes them more efficient. When not in use, it is rolled up on a spool (like your garden hose) and stowed there for later use....

Wouldn't it be easier to just put it in the shade or in an airconditioned sunroom? Will that spray cool the panel if the wind blows the spray some other direction? What about the shadow of the sprayer? How much water do you think it will use a day; and what percentage of the day will it actually cool the panels?

I'd say some improvements are from cooling and some of the improvements are from light magnification from water droplets. Cool test tho. I'd say cooling the back side of the panel would give you a better knowledge of cooling alone without magnifying light on the front side

I've certainly noticed this. My array produces more power on cool sunny days than on hot sunny days. My highest production days are actually during the winter! Of course it helps a lot that it only snows for a few minutes per decade in San Diego. This is why you should never mount solar panels with their backs against something solid, unless it's a good heat exchanger. They need the air flow to cool the backs. I think spraying the backs might work better than spraying the glass because they are in better thermal contact with the silicon layers.

I wonder how your test would compare to a nursery misting setup. An on/off timer could be set up by ambient temp n the system runs on water preasure, with very low water usage.

omg thank you for showing both Celsius and Fahrenheit scales. much appreciated effort

I remember reading years ago (early 2000's) that solar panels were more efficient in slightly overcast days, I have no idea if it was accurate or not, but this would kind of back up the theory that the panels work better at a cooler temp. Either way pretty interesting to me, thanks for making and posting this.

I wonder what would happen if you just attached black radiator fins to the back of the panel? Passive systems are always the best if you can.

I wonder about cooling the back of the panel using a large tank. I figured on running the pump to absorb heat in the day and to radiate it off at night. But would it work and would it pay for itself? I really don't know.

You can have a combined system that incorporates a passive solar water heater in the solar panels system.

I only thoughts is the gains in efficiency come from just cooling down the panel or does the water flowing across the surface have a reflection or amplification effect on the light?

I not only have this set up for my 12.4K W backyard fence mounted system but I also have low pressure misters that clean my solar panel and pull my solar panels from 130° down to 88° increasing my total power production by 1200 W which is enough to run a small air conditioning unit.
I also have a smaller version of a whole home water softener for lime scale.

Thanks for the review of the concept. IMO, I guess another upside would be removing the dust build-up. Being from the SW-US, the other issues are: 1) Wasting water (I guess if you want to get complex, you could recirc it, but the more complex, the more things to break/maintain), 2) hard-water crusting/build-up on the panels (can be hard to remove), 3) what is pumping the water and what is its energy draw of that pump compared to the increase in power production (assuming you're not just tapping city water)? 4) if you have multiple rows of panels/large system, the plumbing to ensure all panels are cooled is a bit difficult. Finally, what about a simple air circ fan? Is that enough to actually cool the panel/... Probably not.

Is it the effect of cooling the table or just having water running over the panel. Could you try it with hot water or some how have the panel on a cool table.

I live in southern Mississippi and temps can be 110+ F for weeks. I wonder if cooling with atmospheric water would prolong the panel's life over time.
Having a loop that feeds from the gutter on my roof could catch the water and feed it into a "U" shaped system that would make a small pump work easier. Problem is the water would eventually reach a temp not very far from air temp, maybe a 10F drop from air temp cooled just by evaporation. I could use a float value to keep the system at a needed level.
One con would be the increased constant humidity might encourage mold or mildew growth. Another is the pump isn't going to last forever, and keeping debree out is an ongoing issue.

I would think maybe using the sub-ambient atmospheric window cooling panels might be a better option, you won't have the light scattering like you do with the water droplets

59 degrees F is about 15 C. You forgot to subtract 32 before 5/9! Love the everyday home stuff!

Wonder if you can get better results from a mist instead of a stream since it will evaporate quicker and carry away heat.

You would also need to account for the water's absorption spectra vs. what wavelengths of light the panels use.

Such a cool experiment! Can't to wait to see what else you've got planned!

Nice experiment! I have rain barrels and a solar roof, I wonder if I could run something like this on hot days when I have full barrels. Would be interesting to measure how much water evaporates.
I really wish there was some product that was solar panels+water (pre?)heating. Not surprising solar installers don't want to do plumbing but would be interesting if it worked out well. Bonus would be the circulating thermal fluid could help keep the cells clear of snow, too.

People have been playing around with this idea since the 1980s! It is 100% impractical, but it does work! 😂 not a single commercial application of this idea has ever been implemented successfully. There is a warehouse north of Los Angeles that is stacked with gently used solar panels and you can pick up a 300 W module for about $40.

You could collect rain water, filter with a sand/charcoal. And use a small solar water pump to cycle the water… might do this for my solar shed 😁

Good test. You know many people have wanted to try this.

We can place finned heatsinks behind the panels and wet these heatsinks regularly with micro sprays. In this way, semi-passive cooling can be achieved by evaporation on the increased surface of the heatsinks with fins. If we ignore the heatsink cost, I think this will be the most viable solution that provides the highest efficiency... I love your videos, keep it up. Thanks.

Ok, I have been thinking about this for a while so I cannot wait to watch this

I wonder if it would be more efficient if the panels were cooled peiodically instead of continuously like that. Maybe every 10 minutes or so to run the water for 2 minutes. The reason being is that I wonder if the light refracting through the water has any effect on efficiency.

Does it have to be from the front? Can you have cooling from the rear? Maybe a close loop cooling.

there is already a similar solution by using some hygroscopic foam at the backside of the panels. This foam is taking up the moisture during the cool nights and releasing it during the hot day. By this evaporation a cooling efect of the panels is obtained.

Off grid 20+ years and heat loss is an obvious factor you can mitigate. I don't recommend using water though and the way solar installers mitigate it is by adding additional panels to make up what is lost in high temperatures and on cloudy overcast days.
However, for DIY solar I recommend not putting your panels on a roof that is black or dark as that will increase heat loss even more and use a ground mount system over dirt or light colored rock. You can also increase air flow to the back side of the panels by removing obstructions and if possible set them so the natural wind patterns flows across the panels. Even a light breeze makes a difference.
A ground mount system with adjustable tilt and angle or a solar tracker is optimal.
I also recommend a ground mount system so you can wash the dust and bird crap off your panels and check and do any maintenance needs. My system gets washed off a few times a week.
My system is 1.4Kw ground mount with 600Ah LIFEPO4 batteries and Geneverse 200Ah and ALLPOWERS 200AH power station for extra capacity and that runs everything: water pump, lights, microwave, laptop, evap cooler, ebikes and recharges lots of tools and gadgets.

This video gives me the idea of using patio misters to cool my 6 100w panels. Misting systems are very cheap and use little water, interesting. Thanks for the idea!

Question: what if you put a water tank beneath the solar panel and used electricity to circulate the water then passed your hot water line for your house through this tank (in a zig zag to maximize heat transfer) before the line goes into your hot water tank? Would the increased electrical production and/or reduced degredation of solar cells by heat outweigh the electrical usage of operating a pump like this?
Another idea I had was to have a buried water tank fed by the gutter with a wind driven archimedes screw pulling water up to the roof then over onto solar panels with that water going down the gutters and back into the water tank. Presumably, as long as the water is kept deep enough with a large enough capacity, it should remain cool enough to cool the panels off whenever the wind blows. While the wind wouldn't likely blow continuously, you aren't using electricity so aside from the startup cost it shouldn't cost you anything to run while you'd have some gains when it ran. I suggest wind because depending on the height of your roof that could be allot of electricity to run a pump with that much lift.

What if you had a system like this, recycled the water, and ran it through a small chiller, just to keep the water from heating up? Would that be efficient for a whole home system and conserve water? Great Video

I was in between Phoenix and Tucson this summer driving past a huge solar farm. I can't imagine how much their losses are in that 115 deg sun. I also couldn't imagine trying to cool them either.

Thank you for this test. I can currently not use it, because it is to hard to acces my roof (2 stories) but i think this could be valid solution for everyone, that collects rainwater like i do. That would cost no water in that case and also makes installation easier, as the water only needs to be distributed but gets collected with the system that already collects rain water. As long, as the extra energy gained is more than what the pump needs, it should be usefull.

Nice video and info but I think you will find 59F is closer to 15C not 33C. I can see with a roof with water capture that the loss of water could be minimised outside of evaporation and that with enough hot days, solar on hand or a separate solar pump perhaps this still makes sense. Simplified with a sprinkler or misting system perhaps both cost and installation time could also be reduced.

If you tilt one panel, you have to tilt the other panel. Panel tilt can affect the panel output.

That's actually less of an improvement than I expected, but now that I think of it, cooling the outside of the glass isn't going to cool the solar cells by much due to glass being a pretty good insulator. Also, one risks cracking the glass. Generally speaking it isn't worth trying to cool the panels due to the extra complication. Easier to just add additional panel(s).

Actually a negative power loss if you (should) distill your water to prevent lime buildup on your panels.

I have to wonder if there is a increase in power from the magnifying effects of the water and if having a mister would be more effective to increase power that way or creating a steady completely covering flow over the face of the panel would be more effective. Likely a full front of panel covering with water would be best as it would even out any magnification and provide the best cooling.

POSSIBLE FOLLOW UP TEST:
Consider a follow up test, to determine the quantity of power required, to run a pump to pump the water from a bucket, then use a rain gutter at bottom to direct the water back into the source bucket.
Then subtract the power required from the power gained to get a net gain or loss from water cooling.
thx

I thought about having passive fin or pin sinks on the back for cooling. I have a pair of pin sinks perfectly capable of handling 70w tdp passively.

I can see a line of shade from the water line to the cooled panel. That's bound to affect the measuring.
If you drill the holes on the side of the pipe, you could place it further away and probably get better results.

This is also why early in the morning you can have your charge controllers trip on over voltage if you string is close to the max on your charge controller.

Had a friend that did copper panel backing with water lines running through it to pull heat from the the solar panel back in 07 as a some form of Master thesis, find myself looking for that final document now. To compare Results. He used his to heat the hot water/warm the house come winter. Wish I had the money to do something like that with my house, but that would be fresh constructions I am pretty sure for my design.

Do panels output more in the cold winter time?

The other question is how much power are you using to cool it and how much of an increase does it provide?

Awesome test, with a large enough system it's worth running a chiller and recirculation of water. I got up to 16% gain. Love these tests 👍

I’m curious as to why you didn’t get 10% if that’s what the charts say. Could it be because of the uneven temp top to bottom? I mean, if it is 75F at the center of the panel, it’s colder above and hotter below as the water runs down. If you have a pool it might make sense to cycle the water over the panels. Most pools have a bottom drain you can draw the coldest water from. The bottom of our pool doesn’t get above the mid 60’s in the summer unless there is mixing. Over time the pool water would warm up and reduce the delta but at least you wouldn’t be paying for the water. Oh, you’d burn up more pool chemical, but those are typically included in your pool service.

This has been on the table for decades.... Powerlabs, Engineering with Rosie, ..... have done this. The major point is cost efficiency. No use cooling the panels if the cooling costs more than the additional power from the grid would. I have seen water and air cooled panels (backside cooled) that use the extracted heat for heating purposes, but all those systems don't work well if you can't dump the heat somewhere. Running water over the front might even redude the light input into the cell.

Thank you for the testing..really appreciate it.. I think refraction help to improve the efficiency. This is how ETFE panel works.

this will work on moutain areas where plenty of water fall exists . you just have to install all the solar panel by the water fall & direct a small amount of water toward the panels . many mountain villages got no power so it can work for them not for flat landers.

What about having the panels mounted on top of a radiator system that could optionally also have the water looped through? No losing water to evaporation and the wind will help as well depending on how the radiator grill is designed.

5% is 5% but that's a lot of water you'll be wasting. However, you could maybe use a "pump" that would recirculate the water? The only other possible issue is that the recirculating water may become a little warmer which can be resolved by having a really large water reservoir to re-cool the returning water?

I'm going to do an experiment using pool heater panels underneath photovoltaic panels hopefully I see similar results as this experiment. If anything I'm sure I'll have hot water LOL

"Combined heat and power" is so often an explicit benefit (steam from power plants at large scale, cars at small scale) that I'm surprised there aren't more systems doing it! I know water and electricity don't "mix" and it would be more complexity, but I would have thought all the puzzle pieces are already here given existing products like water-cooled CPU coolers. Must be missing something still.... 🤔

Enhancement would be to swap the watering system to the other panel to nullify any panel performance discrepancies.

Is it really the cooling, or the increased refraction of the water that adds more sunlight to the panel? Perhaps add cooling to the underside with a fan or water or something for a comparison.

Great video! You can also filter the water and pump it back through a heat exchanger. While not ideal, and it is more complex, there are ways to do this without using the water once and throwing it out.

Some from of PV/HW hybrid panel could be the future to collect as much combined solar energy as possible in 1 panel. Likely to be expensive to manufacture & difficult to install though.

would love to see this test by cooling the back plane. Such a closed loop system could (pre) heat water for your hot water system.

Very interesting, but..... is it because it is being cooled down, or is it because the water is magnifying the solar energy, therefore providing the difference in input? I have similar panels and they are great, but it could just be magnification, not temperature related.

one guy did a flat rear cover then cut long opening on the bottom and put 3 120mm fans on the top. this seems to work amazingly

You should consider doing a project like this using a reservoir, rather than running the hose. The reservoir should heat up as the water goes over the panels, where it would collect at the bottom and get pumped back to the panel again. This way, the water would get heated, and evaporation would decrease the temperature. You could attach a hose using a float valve to keep the reservoir at a level you prefer. This way, you only lose water to evaporation.