Earlier last year i convinced my dad to let me install a DIY pool-water circulating system on his 16kW panels in Spain. Panels temps dropped from 85°C at 30°C ambient to about 45-50°C. Average power output on a cloud free day jumped about 17% in addition to eliminating the pool heater in spring and fall. Since this house is completely off-grid, the savings in diesel already made up for the $800 cost. The system is not perfect and was more of a prototype that worked too good to tear it down. Super cheap plastic sheets glued on the back of the panels with about 1cm gap and sealed on all four sides. Fittings are epoxied straight onto the plastic. Water flows in parallel through all panels, two redundant overpowered pumps are controlled by an ESP32 with Wifi for fault notification and temp measurements. Next upgrade would be a water to water heat exchanger to be able to run automotive coolant. In theory i could push air through the same pipe when pool-temps get to high, might test that this year

Guys please take the time to appreciate what this channel is doing. They are producing top notch content, super educational, very well produced and they at no point read any sponsored ads, they don't ask for you to join their Patreon, they don't sell you merchandise, this is unheard of in the world we live today. So much effort goes into these videos and I'm always blown away how sincerely the content is delivered, if you haven't subscribed, just click a button real quick and forget about it, or at the very least leave a like, the value proposition is very fair.

I agree this man puts out some of the best content out there for useful scientific information and self edification. I always look forward to his new content and have learned so much from his work. I dont know his name and I should but I'd like to thank him right now for all of his effort and knowledge that is so generously given to us watching. Thank you Sir! So nice to know that there are still those out there that teach just to enrich the lives of their fellow man. Bravo Sir.

This channel is a treasure!! Such diligence is so rare on KZbin, thank you for your videos!

The ONLY thing I could suggest is to run a side by side comparison of the two identical panels, one actively cooled, and one not. I'd like to see data logging and graphing the way Matthias Wandell does. Face them due south and let them run for a full 12 hours.

Love it! In my 4KW PV array in upstate New York, I was distraught in winter when an inch of snow dropped output to zero. I disconnected the array from the Controller, and fed pulsating DC from a 240 volt bridge rectifier to the panels. In an hour, enough of the snow melted to begin self-defrosting. Reconnected the controller and produced power the rest of the day instead of zero power. Wish that switching was an option of the controller! Could easily be fully automatic.

1:05 No one really does that anymore... For monocrystalline solar cells like the one you're holding, you start with a doped silicon wafer. On the front side, you would texture the surface and typically heavily dope it with phosphorus and then throw on like 80 nm of Silicon Nitride for passivation and antireflection. On the back you would just screen print an aluminum rich paste for the rear contact (Ag on the front). After the printing, you send it into a belt furnace (glorified pizza oven) at 700-800 C which burns off the organic binders in the pastes and causes the metal to contact the wafer. On the back, the aluminum actually forms a eutectic alloy with silicon that assists carrier collection. Let me know if you want more deets.

I love this guy. He takes these tiny details in his work and takes it far beyond than I can even imagine

I absolutely love this channel. Can't get enough of the discussions and the experiments. I'm thinking about how to apply these ideas to my practical life and as a nerd, I'm all in. But as a consumer, I'd probably just buy more solar panels to get more output rather than attempt to make them more efficient. Assuming I had the space to put them somewhere, of course.

30 years ago I was living in my RV in the Colorado mountains for a couple of years and getting my electrical power from PV panels. Plus I was spending my days designing a MPPT charge controller, so I spent a whole lot of time thinking about PV panels. You covered everything I experimented with, as well as contemplated regarding thermal management and optimization with the exception of reflectors in low light situations. And the use of reflectors in normal sun was something you have covered in the past. So well done. Thanks for educating many people regarding PV's. While PV cell technology is improving every day, the fundamental fact is that nothing beats the basic physics and applications knowledge for getting the most out of PV's, and you are providing it.

I have 400watts of panels mounted on the top of my motorhome. I was unaware that the heat hurts them like that. I will absolutely be making covers for them for when the motorhome is in storage now. we hit 45 C in the summer where I live. I bet those things are hitting 100 or more in the blazing sun. And if they aren't even doing anything I better have them covered! Thank you for the video! I love learning new stuff!

On my RV I have considered installing a copper spiral on the back of the panel to act as a hot water maker. After seeing your results I imagine it would also be worthwhile as a secondary benefit of cooling the panel and improving efficiency. On an RV or boat everything should have at least 2 uses/benefits.

i still have a hard time understanding why this channel doesnt have 6 million + subscribers already. no doubt one of my favorite channels of all time.

You know, If every school kid had a teacher like you in every grade we would be in such amazing shape as a nation!

When I installed my Australian arrays I was tempted by the Dualsun panels using a water loop to dump heat into the 50K liter pool as a heat sink. I think you’ve inspired me to revisit active cooling for the next array to compare performance directly. Maybe I’ll find room for a sunnovate panel too.

Here in Australia we sometimes have forced air ventilation of roof spaces to reduce the heat gain through the ceiling, so in those cases you could even just redirect that existing airflow to behind the panels for an even greater efficiency gain and very low capital outlay. Likewise with air conditioners, commercial buildings usually have about 0.7 air changes per hour, so all that chilled air being discarded could be blown behind the panels.

We typically just add a little more solar :) Also, it seems like your aluminum backing is trapping hot air causing your starting temperature to be higher than it would with an open back and angled panel.

What I'd really like to see is fully integrated heat management in homes. One big ole heat pump, and a manifold to direct hot and cold water. Hook up your fridge, pool heater, ac, heat, solar, battery packs, everything.

I really love the idea of thermal electric combined solar panels. You can have water run through the panels, cooling them down increasing their efficiency, and use that to heat your pool, or shower water, (with a heatpump) Thermal pvt panels are slowly happening, and although slightly more expensive, can be especially useful on a small roof where more cheap panels are not possible.

How about using the 'waste' heat for drying the dessicant in your alternative air conditioner? I would love to see you do that as a video (including analysis of the overall system power consumption, etc.).

I always appreciate how rigorous, well thought-out, and well executed your experiments and videos are. Please keep up the good work!

I really like what you guys are doing in terms of your production quality!! IMO Arguably the best content and articulation of such on KZbin. Keep up the awesome work guys!!

If I heard correctly you gained 5 watts while losing 3 watts. This was in full sun with zero clouds. If it was cloudy you still lose 3 watts in cooling fans, but do you still gain 5 watts? I’m guessing no. Great video. I like the use of the square casting shadow to find perfect angle

lol. I love this channel. the first 2 minutes are unapologetically technical, yet doesn't talk down to the audience at all.

It would be interesting to see the effect of just the heat sink fins and an open back vs the closed back and fans. I feel like the convective flow over the fins might be enough to tip the energy balance toward the passive design without fans.

i get that by introducing an MPPT (Maximum Power Point Tracker) you introduce a blackbox, however the MPP is temperature dependent, so in your test without air cooling the power delivered by the panel is actually lower than optimal. which biases your setup more towards the air cooled test. That being said with or without MPPT cooling the panel will always make sense from an efficiency perspective. Love your videos

Thank you for the solar panel video. I've been in the process of installing, designing, modifying my solar power system, batteries included. Please make more solar power videos and solar panel videos. I enjoy how you give examples and instructions on how your test are performed. You are a smart man.

It would be fun to see this combined with overclocking panels with reflectors. How much can you squeeze from a small array??

I wonder if just the heat sinking passively would have relevance 🤔. Of course active would prove better but if passive heat sinking did have a significant gain then it may prove to be useful in certain applications. Would you guys be interested in doing a follow up with just the heatsinks in a passive setup? Just to show hard results and relevance. And thank you btw for your content!

I continue to be impressed by the editing on these videos especially for the intros. And how long the takes are, it's not easy to do that many lines in a row! Each of these videos is a masterclass, kudos to you and to the budding scientists and engineers you are inspiring.

Professor, great video. I love to learn, even at 68 yrs old. I have to say, you’re my go to channel if I want to learn about your projects. This project has really excited me. Thanks for taking your valuable time to teach us.

Thank you AGAIN for taking a complex issue and making it completely understandable. Your hard work isn't overlooked or unappreciated. 😎👍🏼

Man, you made my day. I've always wondered what the difference is if you add active cooling. We don't have panels yet, but now I have a better idea of what to do about efficiency when we do get them. Thank you.

This is by far the best channel on youtube. Your science communication skills are on the same level as Carl Sagan, and the production quality is amazing. These videos provide a very important public service, you and your team deserve to be recognized for what you do. Your videos inspired me to get back into design and sustainable engineering. Thank you!

Word class methodology. Showing the meters clearly and continuously is virtually unseen on youtube. Thanks! love how realistic and well thought the analysis is.

When my wife and I went to Taos NM in 2017 to spend some time learning about Earthships, I suggested that they do this without fans to try to improve their panels. It is always breezy out there and I figured making and attaching fins to the backs of the panels would help dissipate the heat and boost the panel efficiency/increase the longevity. Glad to know it works... too bad they aren't interested in testing and gathering hard data to prove anything.

Currently my panels here in the Northeast are putting out 8kW. I want to add more panels/efficiency for those days when we see no sun. Thanks for the videos, they're very informative.

That was the best scientific video I've seen in a while. Incredibly detailed and professional. Subscribed!

I’d like to see a few more iterations on this idea. I’d love to see temps and wattage of a panel by itself. Then another with the back panel where the fans are mounted to see if passively cooling with just fins had any effect. A modification I’d be interested in seeing would be to use boxed fins with air directed through, and also water directed through fully boxed radiator fins to see if water could carry away more heat than active air cooling. Not sure if a pump could match the efficiency of simple fans. I may try to get a similar setup to try experimenting. I just got panels installed on my roof and would love to extend their lives and make them more efficient.

It would be really cool to see the effects of the air cooling with the solar concentrators installed on the same panel. The temp differential between ambient and the peaked heat from the concentrated panel load may have much higher yields on performance!

Love to see the test of air cooling and your flat concentrators. Thanks for the videos. ❤

Any chance you could show a better picture of how you attached the heat sinks to the back of the panel? Usually there is a vinyl cover on the back of the panel, I am guessing you removed that and put the heat sinks right up against the panel? Any thoughts on keeping moisture out? Also have any thoughts on how to actively cool bi-facial panels? Very cool method of cooling the panels.

This takes me back to the video about using reflectors to boost the output from a single solar panel, since one big issue with doing so was that exposing the panel to over twice the amount of sunlight would probably fry it, this seems like it would be a great way to reach the top rated power output even on less than ideal conditions

As always a well made video with proper physiks. Living in an area with moderate temperaturs I'm currently leaning more towards just adding more panels instead of optimizing them for peak power. I have issues with not having enough power in the winter and low lights (panels are cold there anyway). As I can't store the power long enough to be usefull. In the summer the panels produce more than enough power already. And the roof is not full yet ;). Also moving parts are not what I like to have (but that is just me). I clearly see areas with limited space and enough storage to benefit exactly from what you tried there.

I love what you're doing with this channel. Bringing really clear and understandable important information to a wide audience. Big time Kudos!

It boggles my brain how good the content is on your channel. I'm super happy I ended up finding it!

I really appreciate your videos. You actually build and test the things I just sit around and think about forever stuck in a state of analysis paralysis. I was surprized yesterday how warm the panels are when the ambient air near freezing and the aluminum frame of the panel (black, shoulda been light) is comfortably warm. I just got them this fall and really wonder what the temp of that frame is going to be in August? The cats sure seem to like to hang out behind them on a chilly morning. One thing not mentioned is the reasonably expected lifespan of the fan motors. If you installed 100 of those fans, how many of them would not have seized bearings in 10 years? I wonder if electrostatically charging the air with HV, moving air with no moving parts might be a better option? Dyson fan for clues. I think closed circuit liquid cooling is where it is at, much easier to utilize that collected heat elsewhere which could be considerable on many sq ft of panels. After watching your solar water heater/PV drag race, I'm sure you are readily aware of the heat potential, well over half the radiant energy caught by that PV panel becomes heat at the panel that must be convected or radiated or in the case of liquid cooling, conducted away. You would have a hybrid solar water heater/PV that makes flowing electrons too! Maybe use a sheet of coroplast(styrene) or polycarbonate greenhouse panel to make a heat exchanger that can be glued on the back face of the panel, would be pretty easy to fashion multiple circuits with and exacto and a soldering iron if that seemed beneficial. If you used silane for glue it could be easily reversible to not mess up your panel if it doesnt work out. Coroplast can be purchased with a decent layer of thermal insulation sandwiched on, and greenhouse panels can be purchased that have 2 or 3 layers deep for insulation purposes. Thanks for doing and sharing what you learned.

Love this channel. The way he explains everything definitely inspires people to understand these technologies and encourage others to pursue such sciences.

yeah I just thought up of and started experimenting with attaching those thermoelectric generator pad things to the back of some solar panels a couple weeks ago

MTBF would be my primary argument against adding dc/dc voltage regulators, fans and heat sinking. I'd be curious to see the performance uplift of just adding the heatsink without the backplate and fans. Either way, excellent bit of content as always!

A really interesting episode. My only problem with the power differential was that the baseline was the modified panel with a mostly enclosed back. Are the aluminium fins compensating for this passive airflow that would otherwise keep the panels cool?

Fantastic content! Would love to see more on solar efficiency in future videos. Please make some content on tying it all together with something like heat pumps. This channel is one of the best things on YT.

Love this type of detailed testing an explaining. Keep it up. Testing all the things I’ve wanted to test but haven’t been able to because of time and money constraints.

Water heating type of these panels are pretty popular in the Mediterranean. We had one installed about 15 years ago. The water was so warm that I'd had to introduce cold water at the combination tap.

This absolutely explains my recent frustration 😤 I have a 1800watts panel array and I have noticed drastic drop in watt output within a year, it is currently given me 400watts at peak value as opposed to 900+watts when it was first installed. I have called the technicians many times to come and test why and explain, they all have no idea why. But this video gives me an understanding why. Thank you, subscribing...

KZbinr Robert Murray Smith has an episode that shows how to greatly increase the output of solar cells. One involves amber filters and focusing devices. You should look at the video. It's episode 1664.

Glad to see you back in action! Please take this as positive feedback… you might want to run your audio through a low pass filter to remove the low frequencies that the wind or moving around is causing. Watching you video on my surround sound system causes my house to shake! Thank you. Keep them coming!

I have learned something watching this channel since the beginning, whatever comes out of this man's mouth you can take it to the bank.i love learning and I appreciate this channel and all that you share with us.

Great video and channel! I'd be curious to add into the wear and tear of fans, replacements etc into the total life cycle cost. Depending on the setup storm's may not make having small computer fans very beneficial. Still, if a company looks closely at this like the one example you gave I'm sure they can find better fan designs that are more storm resistant instead of off the shelf computer fans.

Always enjoy your practical experiments and analysis, very interested to see net gain in relatively temperate climates, I’ve been thinking about this for some time but hadn’t considered your approach for homemade heatsink which had made the capital cost prohibitive from my perspective. I do think the heat recovery point you made at the end makes the cost benefit case more attractive even for a domestic Instalation if you can divert that heat through and existing air source heat pump and into your hot water (in theory this would increase efficiency/reduce cost of producing hot water). Nice job 👍👍👍

Love this- absolutely bs-free experimental set-up- both as a learning exercise and more importantly a platform for playing around yourself. These types of things ALWAYS seem to leave out critical details (as you alluded to with the Rice paper on graphene) that are obvious [only] when you actually get 'burned'.

I remember nighthawk in light showed a really efficient way to always center the solar panel with 4 slights smaller ones at each of the edges connected to motors. It would seem weird but if you can get small enough panels it could work really well.

You could improve things significantly with a fluorescent polyethylene film over the panel to absorb UV and re-radiate the energy at visible light spectra the panel can use. This will also stop IR and UV frequencies heating the panel. And double the surface area available for your air cooling, as you can pass air through the cavity on the front as well as behind the panels.

Firstly. ALWAYS top notch content. No one does it better. I had 3 ideas after watching this. 1) why not use Thermo Electric Cells adhered to the right angle heat syncs? Heat on one side cooler on the other... maybe enough to run the fans. 2) If a water sync like a lake is not available... consider using the trick of digging down 4-6 feet and burying pipe. Get some precooled air. 3) the approach using the buried pipe can be done using convection heating to move the air without power depending on where is installed.

I've wondered. Can't you collect the heat from the panel and use it to heat your house in the winter time? Perhaps you could also use this heat combined with a heat pump to pump heat into the ground during the summer, then extract that heat in the winter. AKA stabilize the ground as geothermal heat pumps tend to work well when they start, but it takes around 8 years fore the ground to stabilize. At that point the heat pump looses a lot of it's performance.

Definitely interesting any efficiency boost to solar without massively increasing cost seems worth it. I would be curious to see the temp difference with the back panel with fans removed rather than just off.

That really helpful for me. I have to learn new thing here. thank you for your effort doing this experiment for everyone.

I think you can make it even more efficient.. You could attach a small electric water vapor thingy to the back, that blows out a little bit of water every so often, at the back of the solar panel, covering the inside of the back in a thin layer of water.. this, together with the fans, would cool off the back of the panel even more, due to evaporative cooling.. It would literally cost almost no extra electricity to add this to the system.

Great video! Very well explained and interesting topic, a small correction in the manufacturing. The vast majority of solar cells today are made by starting with a P-type silicon wafer, and then doping that from the outside by hot gas diffusion, greating the P-N junction. The front and back electrical contacts are usually applied as a solder paste, and then baked in an oven. On the back, an aluminium paste is also applied to create a very heavily P-doped layer, which help reduce carrier recombination, and increases the efficiency. It is usually only 2nd and 3rd gen solar cells that start with a substrate, and then deposit the thinner layers on top, as this is a much more expensive process.

This channel is one of the perks of the Internet

There is another cost consideration. How much cost is the cooling system adding overall? Because if I just want 5% more power I could add 5% more panels (assuming there is available space). As much as I appreciate the efficiency and potential life extension of your system, I generally favour the KISS principle. Fewer moving parts is almost always a good idea, especially on an installation with an expected lifespan of 20 years or more. Finally, to make the most of your system you would probably need to add a temperature monitoring system for each panel so that you can identify any problems with the fans and know when to service them. Maybe there is a better way to use passive cooling to keep the system simpler and without moving parts? Could be the ideal compromise. Enjoyed the video, btw!

Love all the engineering and scientific principles demonstrated in your videos. Very accessible to young people.

Rotating and moving up and down to peak the panel output, Plus a passive heat sync is more efficient than putting fans on the back. Most Solar panels are not even pointed directly at the sun for any meaningful amount of time. So, they never see peak efficiency... but for a couple of minutes a day.

Great video as always! Would it be possible to filter out the wavelengths that only add to heating on the front surface of the solar panel via reflection?

Good to see you back making bangers after what happened!

Very illuminating. People always forget about the heat and the heavy metals. Thanks for sharing.

For some reason I have an urge to visit the Country Kitchen. 🧐

I was wondering if you could convection cool the sun panel. Add an insulated chimney on top to create stronger draft. In fact you could do an entire video of whether is there a limit to that kind of cooling

Thank you sir, very well done. I was inspired by your Peltier cooler two years ago and decided to build our own for our insulated battery enclosure. Both heats and cools based on internal temp. Now I must thank you again, our East-West Facing system called the SA4 acts very much like a greenhouse in summer. Going forward will install a fan on one of the ends of the array to allow fresh air to flow under the panels when ambient temperature rises above 20 degrees C. This will surely increase gains, and thankfully our Grid Tie Inverters all come with a 120V outlet at source to power the fan. Keep up the great content, as a solar installer, it's a pleasure seeing these experiments.

Always solid content and we are getting it from a first rate technical instructor. I believe I have watched all but 2-3 of your presentations. Congrats ~ Allan J

I really enjoy these energy videos. I've been way ahead of you on this so far. If you store the extracted heat in an underground insulated tank/pool, you're offsetting your home heating costs in the winter, while chilling your fluid for panel cooling in the summer. You can also run a closed loop ethylene glycol loop into an aquifer for a few hundred dollars and only run it's pump when ambient temps are over 30-35F. It takes very little energy to move fluid in a loop.

Thank you for excellent explanation for a total newbie. This is so rarely seen this days - technical topics explained with easy to get language without excessive jargon. Thank you for sharing your knowledge and experience!!! Keep on doing!

The main issue I see here is that the cost to add the fans and metal to the panel. Sure you gain 2 watts of power but how long would it take to recoup the cost of the additional materials. The second part would be that those fans will most likely go fail somewhere between 5-10 years so the cost of replacing the fans needs to be factored as well.

An interesting test that comes with some design flaws that could greatly improve the system, and a series of variables that compound my interest. 1) Fan alignment. You have top mounted intake fans, which is generally a bad location since hot air rises and you fight the natural convection. The panels should be flipped upside down. You also aim the fans so they blow at a nearby surface (the back of the panel), rather than in the direction of desired flow, thereby decreasing CFM due to the pressure losses. Bottom mount the fans, perpendicular to the panel with ducted shrouds to focus the air down into the heatsink channels. 2) Convection has a worse heat exchange than convection. While you state that it doesn't make sense for your setup, I imagine economics of scale against a say 8x3 panel array would improve the numbers on running a pump and radiator. 3) Useful work. Most buildings, be it commercial, industrial, or residential, require how water. Pumping 40° coolant through a heat exchanger in a modified heat-pump style home water heater reduces the workload for a radiator, and re-coops lost power to running the water heater. 4) Temperature delta. While 3W vs 10W to run a few fans is a better solution than 30W vs 10W, lower latitude areas also have worse temperature deltas than NE: Dropping the panel to 30°C isn't a realistic option when outside ambient is already 48°C. A heat pump is a far more efficient for moving heat than ambient convection in high temperature areas, regardless of variables other than scale.

I love the channel! This father and son work hard and it's educational. Thank you very much.

The back of the panel is shiny. Shiny equals low emissivity. It needs to be black if it is looking at grass! There is also room to place a reflective surface behind the array to reflect the sky. The sky is transparent to IR at 8µ to 15µ and acts as a super cool heat dump.

A couple things come to mind. First, I'd really like to see the unmodified panel's performance rather than measuring the performance of the panel with heat fins attached but blocked by the outer sheet trapping the heat and not allowing convection heat to flow upwards. I'm speculating that there's no heat sink compound between the fins and the outer sheet of aluminum and just trapping heat inside. With my rooftop solar system on a sunny day, there's significant convection warm air flowing upwards between the panels and the roof deck that whisk away the heat. Second, the longevity of the fans vs the solar panels. How often do they need replacing? Third, what is the performance look like with the air heat sink attached but the rear panel removed so that it can just dissipate into the open air. I would guess that would be the best of both worlds. More surface area without adding mechanical devices to the mix.

A clear scientific demonstration of the value of keeping the solar panel temperature in a safe range. Thank you🌹. The refrigerator runs on 100 watts power through the day. A 12 volt 8A panel can supply this power for 6-8 hours a day for twenty years. This greatly exceeds the cost of the panel. So it's a great saving. No power failure. Safe.

In a previous video you showed a set of DIY wing reflectors that helped increase how many photons the panel gets, I imagine those would have the same effect as being in an area like the southwest of raising panel temps. It would be interesting to see the effect of that active cooled panel with the wing reflectors attached to see how much more of a difference it makes.

I continue to wonder why solar panels aren't designed to have water cooling to preheat hot water for the home as a win win.

Excellent video! Thinking of a solar project in the spring, Lots of helpful data. Very interesting how you "play-out" the various arguments for/against, plus/minus. I'm a Broadcast Engineer and my wife has a degree in English. You were able to hold her attention too!! Many Thanks!

This video sponsored by Country Kitchen 😂

Thanks so much for the great engineering videos and the detailed explanations. As an engineer myself, I always learn quite a bit from your videos.

You are changing the world and I dream to do the same really soon! Thank you friends! Hugs from Brazil!

This is fascinating! I well knew that heat reduces power output, but this video really illustrates how dramatically this works. Thank you!

This video - like all from this channel - is a watch and re-watch deal. Not because it is hard to understand, quite the opposite; but because there's just so much info from MP's brain that it takes a bit for my brain to absorb. Or adsorb. Some manner of sorbing at any rate. Thanks guys

Thank you very much for all your videos, I really appreciate what you all have done. Keep it and and thank you again, take care and have a positively wonderful journey 🙏🏾🧘🏾‍♂️🔥✌🏾😇

What a fantastic channel. This is only my second video, but I am blown away. Loved your previous HHO Hydroxy generator video also. You are clear and concise in your explanation. I wish I had someone like you in my college physics class. Cant wait for more content...

This is great what you have done. You do such an excellent job explain8ng the engineering behind what you are doing. I get an answer to the question and get to learn the solution process. I have a mechanical engineering degree and loved this. Great work.

Excellent ! Thank you for sharing this with such detail, I have solar panels and had no idea of the heat issue. Good work