Did you ever look at those hybrid panels that produced hot water by cooling the panels with water? I think they were an Aussie or New Zealand firm. Their primary goal was to reduce degradation due to heat but the byproduct surpassed their expectations.

Thanks so much for the feedback 👍

A retired engineer? Lmfao u do realize us actual.hard working blue collar.men hate engineers because they are stupid as can be... just pop the hood onnypur new truck and tell me unarent cussing a dumb fuckin engineer.. and thats with every trade ive done we all hate book smart engineers its really not much dofferent than a home inspector that knows nothing but knows it all

Agreed. This video should have included a series connection. Nobody is going to run in two parallel. I expect the results wouldn’t be as exciting with parallel though. Also, most aren’t doing 100 foot runs.

@@ryanyoder7573 The results are still valid. They show the effect of Voltage drop over a distance. 100 is a nice number. Also, 100' to a ground mounted array would not be odd. Not all rooftops are in direct sun.

@@steveurbach3093 yes they are valid they are just way more compelling due to the low voltage used which produces a high drop

@@ryanyoder7573 I will run five in parallel. My system is designed to be 12 volts, and the controller can't do 24v, even. I will be using a shorter, 4 gauge cable. It would be nice to have different design constraints.

@@jamesalles139Don’t forget to fuse EACH panel if you wire them in parallel! Fuse rating is the one written on the panel labels.

what is No. 2, 4, 6 for a cross section?

@@jensschroder8214c’mon now…do a web search, don’t bother the man after he gave us words of true wisdom. Sincerely.

But also , aluminum isn’t as good in tropical climates, especially here on the big island of Hawaii, where we have heat, moisture, sulphuric acid, hydrochloric acid, and salt. Aluminum turns into aluminum oxide here at an astonishing rate. Copper is much less prone to corrosion.

I always see the suggestion for 24V batter or 48V battery, but at least in my research I don't see inverters sold to handle this, they usually say 12V... Can we use bigger battery anyway? Also Eco Flow Power station requieres the XT60 Solar Connector wires to connect to solar pannel wires. Does the XT60 solar connector wire need to be the same size as the XT60 solar connector wire?

​@@adivasworldvictron makes several 24 and 48 volt inverters, along with several other manufacturers.

You didn't watch the whole video. He said as much in the end.

He's trying to avoid the High(er) Voltage legal requirements.. you can laugh at my comment... 'electric fence' [just spike it through.]

@@tsclly2377 makes sense he'd want to stay in (legally speaking) low voltage when possible. it also depends on the local regulations. in some areas they may require anything over low voltage to be professionally installed. and yes I know the low V and high amp is much more of a fire risk. The laws tend to be quite dumb.

It's like Bell vs Tesla all over again!

"Series is best." Yes and no. From a resistive loss point of view 'yes'. If you have (partial) shadowing over the day (trees, posts, corners etc.) the story may well be different and individual MPPT's may be the better solution.

I think most marine equipment are also 48 V .. so it opens up appliance options that avoid conversion to 120VAC which means even less losses

The losses in the circuit are determined by the resistance of the wire and the electric current according to the formula P = I^2 x R . If the voltage is multiplied by 2, the current required to supply the same power to the load will be divided by 2. Therefore, the loss in the wire will be divided by 4, allowing the use of a thinner and cheaper wire.

@@nathanneimansweet. Thanx.

Using microinverters on the roof solves a lot of the design complexity of figuring out parallel vs series wiring of your panels, including what gauge wire to run. More important, they alleviate the issue of one panel being in shade taking down the output of a substantial part of the system. While the microinverters themselves add cost to an installation, they should save money in labor costs (assuming you are paying someone to install a system,) due to the simplicity of the wiring. You incur losses converting back to DC to charge a battery backup, to be sure. If you have short runs, no or very little shade, and are charging a battery with your solar, DC direct wiring is probably best. If, like me, you have areas of your roof that move in and out of shade during the day, long runs back to the battery and panel, microinverters are probably better overall - probably. That, and we don't actually SEE the sun in the winter for months at a time. First 10 days of the year this year we had 5 minutes of actual direct sun :D Basically, there are many ways to peel this banana, and everyone needs to find the right one for their situation :) Videos like this provide data to help make those kinds of decisions.

​@@smarouchoc7300micro inverters are the bain of the industry. Enphase has worked the system to defend their optimizer/micro-inverter business territory. Making up requirements not even considered by other countries.m like "rapid shutdown". Micro-inverters assume the power will be fed to the grid not stored local. For my system they are completely useless even counterproductive. Grid tied is great if you want to sell power for a quarter and buy it later for a dollar. Unless you have shading, optimizers are a waste. I want my solar power to work if the grid fails.

A shed costs a lot more and is WAY more work than conduit and heavier gauge wire. Though a small enclosure for a combiner box at the panels is very practical, but the combiners are generally set up to be outdoors. So they don’t need a totally weather proof enclosure like an inverter and charge controller will. That makes a BIG difference in time money and effort. Plus, the batteries need excellent weather protection, and you don’t want your batteries a long distance from the inverter or your breaker box, or the end use point(s). So in my case I don’t put panels on my roof because that is a whole can of worms for installation and roof repairs/replacement short and long term. I have a nice exposed hill that I put my panels on and it is just simpler to run 4 AWG into a weather proof cement board cabinet close to the cabin with the controller/inverter/ batteries.

@@5400bowen You are still going to have significant loss at any long distance with 4AWG.

@@solarcabin the numbers from many experts disagree with you…4 gauge for 50 feet carrying 72 volts at up to 1980 watts from the panels…quite sufficient. And do you know that the wire gets thicker as the numbers go down? You keep mentioning 10 and 12 gauge..that is WAY smaller than 4 gauge…way smaller…

@@5400bowen Off Grid 20 years teaching people to install solar and yes I am very aware of how wire gauge works. You will still have loss at at any significant distance with that gauge.

The Gauge of wire has absolutley nothing to do with voltage, using that as a method to size a conductor is a dangerous road to walk.

You are doing it wrong. IEEE guidelines suggest that line loss (I-squared R) losses should not exceed 2% in solar systems. Our system is 2.5KW at about 130VDC input to the charge controller. The line run is about 60' which required #4 AWG to not exceed 2% loss.

Depending on the voltage and lengths...it could be very wrong.

Yep, this is my second channel and Everyday Home Repairs is the bigger one for sure.

Why does this guy look like Johny sins?

Thank you for sharing your insights on wire thickness and cost considerations for DIY solar kits. It's important to find the right balance between wire gauge and cost efficiency. Maximizing voltage and minimizing cable runs are indeed effective strategies. By the way, have you heard about the Segway Portable PowerStation Cube Series? It's a versatile and reliable power solution for outdoor enthusiasts and RV lovers. It offers massive capacity, powerful output, fast recharging, and comprehensive protections. Plus, it's designed with Segway's UltraSeal Technology for waterproof performance. Check it out if you're interested!

This is why I chose an EG4 inverter. it can handle 500 volts mppt. so the amperage is 10 or less.

All over the cost of 30-40 feet of wire?

There are so many different application that a longer run could be needed. If you can keep it short that would be preferred for sure.

Yeah, Series is usually my default 👍 if possible.

Hahaha, don't worry I won't get worked up either way. I just made the shirt a while back because of a few videos I did in the past there were no shortage of passionate people on both sides of the argument.

We are here to help 👍

I tell you the bigger the better, but in terms of wire thicknes not gauge

Agreed 👍 thanks for the feedback!

You bet!

Sadly, approx. 2/3 of grid power from our local utility companies is lost during transmission (but yes, customers are still paying for the full 100%). With Solar on your own rooftop there is hardly any loss with appropriate wire size.

@@acordia91 Average grid losses are only around 5%, not 66%. The reason is because those overhead wires are running at much, much higher voltages. The basic trade-off is: double the voltage, halve the current, power losses over the wire wind up being only 1/4 rather than 1/2 because you aren't only reducing the current, you are also doubling the voltage. The reason it works like this is because wire losses result in a voltage drop based on (current x resistance). But POWER losses are a function of (current x voltage) and not only did you halve the current, you also doubled the voltage so even though the voltage drop is only halved, POWER losses are 1/4th rather than 1/2 because that voltage drop is relative to a doubled voltage.

20+ years off grid. You should keep your wire runs under 30 feet and 8 gauge for12 volt. 10 gauge for 24 volt and 12 gauge for 48 volt. You can reduce loss by moving the controller and inverter closer to the panels and use an inverter to run 110 AC to your home. A shed works for that. I recommend 24 volt in series and a run under 30 feet with 10 or 8 gauge wire for off grid.

@@acordia91nice observations.

Yes. Our solar systems from 1 to 20 megawatts in MA only consider 7 months of optimum solar. The other 5 months of winter are a bonus. And our 10ga wires run hundreds of feet from 500volts in 2013 to the 1200 volt systems now in 2024. The important thing for homeowners is to not cheap out and be sure they're using PV wire...and of course having a licensed electrician install the system. In MA only licenses can even touch solar.

@@Icehso140 Wow! At 500 volts (and even better 1200) the calculation shifts dramatically. Your professionals know what they are doing to bring up the voltage from the panels. People doing smaller systems should understand that three things affect the wire size calculation: the voltage (often 100 or less), the watts delivered (again, I think 80% rated or even lower to save $) and the distance. Again, I contend that you don't need to care so much about maximum efficiency on the best days of the year at noon. You need sufficient efficiency on the medium days that are more numerous in your area when the power produced will be good but less. Optimizing wire gauge for the the highest possible output that you only get when there's more sun than your system is designed for is not usually the best use of funds. Exceptions would be maybe running AC on the sunniest days or a grid-connected system that pays back. But good to recognize that seeing that 80% of panel rating may only happen for short periods and when you least need it. Might make more sense to spend that money on more panel for the shorter or cloudier days. Of course, it's an iterative process. More watts bigger wire...

@@ceeweedsl Thanks for the reply. I played with a battery backup/inverter setup for running my furnace for a few hours. Cost: one battery, 2500 watt pure sinewave inverter, battery switch...$700. Add 2 panels and charge controller...another $300. But I have nearly unlimited funds...as long as my wife doesn't see this. LOL But if someone can add a panel or two, it would be good, and Amazon has a pair of decent panels for less than $200. Buying used panels that are still good works to. Solar technology has increased efficiency times 3 over the last 10 years, and the panels we installed 10 years ago are still working within warranty. As they get switched out ,they become viable used panels for homeowner projects. (As long as a licensed electrician supervises the installation. )

I think you are right. I am thinking about stepping up the testing equipment. Do you know of any higher quality power analyzers with a wide range of voltage and amperage capability?

@@everydaysolar For what I am doing, I couldn't justify more expensive meters, so I can't recommend anything. I did get some cheap "voltage reference" devices to test my meters, but they only go up to about 10 volts. Until you get better gear, you might try repeating the test with the meters swapped, then average the results.

@@everydaysolar Use A-B switching and operating conditions as stable as possible. Connect one device to the A side, note its results, swap to the B side, and note the results, swap back to the A side and note the results again, ensuring they read the same as before. If not, try again. Do this multiple times so you get at least three sets of good results at a given light level. Repeat at different light levels. Your records and a bit of work in Excel will allow you to cross-calibrate the two devices - "correct" the readings of the B device to match the A ( which you chose as the "standard").

Yes, when testing electrical values, it is best to repeat the test multiple times, pulling the test probes off and checking again. Rubbing them on the contacts as you watch the meter readings. A lot of electrical and electronics pros do it. False readings are quite common from faulty contact of the probes.

@@gregvanpaassenI’m sorry, what are the A and B sides?

That is a ridiculous pain in the butt. Just do it correctly and use a VDI chart that you can find on Google.

I think it's P = I`2 X R

That's great and all if you're retired and have all kinds of time on your hands. Or you could simply use a VDI chart and be done in about 30 seconds.

Are you meaning run two leads instead of one when you say double them up? Or double the gauges? Because the first one is something I’ve been saying (and of course have known) for a long time. When I ran my Romex 75 feet from the post inverter breaker box, I did just that. Two ten amp wires can carry 20 amps, and connecting them at either end is perfectly fine. Imagine the multi strands inside insulation. It is the same thing. And better for heat dissipation. Nice clear correct info, by the way.

Yes running 2 leads to give you a great big lead is a great way to solve lack of instantaneous power. I had a problem with a 5KW inverter that had the recommended size battery leads that kept going into fault mode with any sudden large motor load. I doubled the Cables and the problem went away. Very easy to do in an existing installation as well because you can keep your down time to a minimum, and 2 smaller cables are normally cheaper and can give a larger square area of cable. In this situation I was looking at installing soft starts on the motors but didn't need to. (Still keen to try them out though, so I may still do one anyway) 🙂@@5400bowen

@@garyrussell5559 I also heard that electricity runs on the outside of wires, hence multi strand wire (did I already mention that about multi strand?). Two smaller wires have more surface area for that to happen. It never occurred to me that a double lead was better for high surge devices, seems peculiar. But like my brother said, electricity is magic! And you of course saw what I said about running two strands of Romex because it was rated at 50 feet at my power levels and it is a 75 foot run? The rest of your reply is so pleasantly accurate! Aloha from the big island of Hawaii!!

Agreed. Real world amperage is usually much lower than rated. Especially Winter and cloudy days, morning and afternoon.

@@ceeweedsl Very true, and one of the most disappointing things you discover when completely Off Grid is that in Spring, summer and Autumn, your battery bank is normally fully charged before noon and the solar is pretty much dumped after that. In winter however I could triple the amount of solar panels and still struggle to charge my batteries on most days. My last array of solar panels I installed are completely for the winter sun and are almost upright. Panel angle lets you squeeze that last bit of current. I've found with Solar, when you miss, you tend to miss by a mile 🙂

@andrew_koala2974 Through. The voltage loss between your solar panels and your charge controller means a lot less than between your controller and your battery.

@andrew_koala2974 The phenomena of electricity takes place outside of the wire

Not a bad idea, thanks for the feedback.

It would be interesting to see how accurate the meters are. I was going to comment a similar idea, I have found I would rather like an existing comment then to duplicate a comment.

I wind up duplicating a lot because I haven’t read all the comments and replies yet. This video and comments are a cut above.

In another video he had 4 panels in series going to the battery, and it was over the rated input voltage for the battery unit, so it would not charge. The unit blocked it. He had to reduce it to 3 panels in series to get it to accept a charge.

With AC, you need to consider reactive circuits . The phase of current and voltage shift.

@@chuckmaddison2924and the skin effect. AC current moved in less area of the wire. DC current moves in the whole area of the cable.

@ajarivas72 Skin is related to frequency. This is why in rf pipe can be used in the big stuff.

That is 100% untrue. The voltage drop is the same whether it is DC or AC. End of subject!

And that heat cooks your wire. Even the metal is more quickly degraded from heat, and especially the insulation. Wire for outdoor use should be white.

run it through the attic. Yes, there's still some heat but not as much.

@@georgeperez4770 a valid thought. Or use white wire, or run it straight down as much as possible, or as I do with the cabins we build in Hawaii, use white roofing. But just look up videos on insurance and roofing companies reaction to roof mounted panels. When the roof needs replacing, yer gonna bleed hard. Some insurance companies have started refusing to insure homes with roof mounted panels…

Yup, most people forget the square. Perhaps the device he is charging cannot handle the higher voltage.

The current flow is what is charging the batteries. parallel panels allow for more current and faster charging times. The solar charge controller regulates the amount of current delivered to the battery it recharges. I

@@zaneenaz4962 Battery charges have a current regulator (something like a constant current regulator) Batteries are never charged directly using the PV voltage as it too high. the Battery charger will step down the voltage and supply higher current for the batteries. Basically it will use a Buck step-down converter will will drop the voltage and supply more amps than the PV panels can provide.

@@zaneenaz4962 Not really true. With an MPPT, what matters is POWER. The MPPT is a buck converter which will convert that power into current. If you have 2 panels of 10A each and 25V they can be wired in series as 50 V at 10A or in parallel as 25V and 20A. The POWER is the same either way: 500W. The MPPT will convert them both into the same number of Amps at whatever the battery voltage is (ignoring slight differences in efficiency at different voltages). Ignoring losses, that would be about 41A at 12V.

@@cccmmm1234 The power transfer is noted, but would you not also be increasing the resistance when the panels are in series? ....and the buck converter efficiencies are typically below 90% (another source of loss) As the systems scale up i suppose these loses drop off as lower percentage of the overall system. Leaves me to wonder if my 300W systems might not behave like your 500W.

Thanks for the feedback and I would like to test a higher voltage as I agree that is a more practical and smart solution. The little power analyzers are pretty limited in the amount of voltage they can handle so that was the limiting factor for this test. I am thinking about stepping up to some mid-grade testing equipment which would expand the capabilities.

(this phenomena is also why people are moving away from 12V battery packs and to 48V battery packs for new ground-up builds. Because the losses and heat in the compartment at 48V are just 1/16th losses and heat at 12V). Now that 48V LFP battery packs are so easy to find.)

The amount of power running through a 4 ga CCA wire that we are referencing here... there is going to be negligible difference CCA vs OFC. Now if your running a 5000 watt stereo amplifer pulling current directly from the battery, then yeh OFC is a must have.

@@KingMrBigE nope - 500 watts of panels can be around 30 amps. Use the calculator and see for yourself. If you can tolerate more than 10% voltage drop, than I don't care either. Your charge controller adapts to the lower voltage, an amplifier can't. I just don't want to waste the precious power if I can avoid it.

If you simply default to a huge wire like that you are considered an electrical hack! Do what is correct and don't default to big wire as that is pure sloppy workmanship.

@@boblatkey7160 whoa. back off. I didn't default to anything. (5) 100 watt panels, 6 amps each, 12v, 30amps system. 20 feet of 4 gauge wire - you run that through the calculator. I prefer 3% voltage loss or less. THAT is good design.

@@jamesalles139 the difference between a CCA vs a OFC 4ga cable is not 10%...

Delta Pro is 15 amps.

​@@jacobpetersen5662 Thanks for the correction. The user manual I had when I wrote that comment, specified 13A, the current one specifies 15A. However, it does only slightly change the calculation (613,25W va. 532,35).

Thanks for the feedback 👍

You seem to be confused about ampacity vs voltage drop calculations. There are times when ampacity matters a lot, and so maybe that approach worked if you were pushing those limits more than voltage drop. An example would be short runs of high amperage, higher voltages. At that point voltage drop is out of the picture and ampacity is the limit. But for solar panel runs, not likely. An 8 ga will handle 40 amps and stay cool enough but that doesn't mean it's a good choice for 35 amps @ 12v over 300 feet. Nor is upsizing to 6ga adequate in that case. Use a Voltage drop calc and don't worry about ampacity in this usage.

this is true. its a fulty test

This is a common myth. Skin effect only starts being a thing at radio frequencies from around a few MHz and up. At 60 Hz it varies between zero and virtually indistinguishable from zero, so the full cross-section of the conductor is in play.

They have cool products but I have seen their use case more in the large solar farm application where you can get rid of combiner boxes with 1 massive wire that has a bunch of leads coming off to each string of panels. Which of their products were you considering?

And why don’t “Friends don’t let friends tape outlets” ?

Yeah, if you can crank up the voltage and keep current as low as possible that is ideal 👍

yes

Isn't the distance of those connections so short that the effect would be trivial? You also have to go with the AWG of the connections to the panel itself.

Yeah, not a bad call out as a I think the 10 AWG test had a little more cloud cover and as such dropped the current resulting in a little less line loss than if the test had full sun. Overall I think the results are still valid within a reasonable error band.

And because the conditions differed, it invalidated the test. Current should have been equal and at the maximum design level to get accurate loss results. Cables will also have to be derated depending on how many cables are in the conduit and outside temperatures encountered, as all loss turns to heat and adds up, creating a safety issue if not considered. Is the conduit in direct sunlight, that's another thing to consider. Check the temperature rating of the cables as that needs to be considered also. Yes, there is a lot to consider for the DIY installer. @@everydaysolar

Yeah, that would have been a good addition. I was keeping the voltage low for the power analyzer limitations so it was a bit misleading as compared to what you would setup in most real work applications.

👍

Oversimplification. Sometimes it is better to take that money and expend it elsewhere.

@@cccmmm1234 well he did say “you can afford”. I’m assuming that also takes into account other expenses.

Great answer

Yes, that's what she said.

I haven’t found one as I am looking for something similar for data collection on upcoming projects. The unit I was using is basically from the RC car and drone industry. If I find one you will see it being used on this channel 👍

That would halve the resistance so would halve the power loss.

those 2 wires would also need to be VERY close in length and quality or you can get some serious current sharing issues over those kinds of distances. This is so important for any electrical using multiple (because of pipe size limits and bigger is hard to pull or bend) conductors on a phase, that there is a NEC section

@@steveurbach3093 to an extent. They just have to be close enough- not perfectly matched. If one wire is conducting more current than the other, then the voltage across it will increase. This tends to have a balancing effect. ie. it would be unlikely to see 75% down one wire and 25% down the other unless there was a really bad mismatch. A few feet on a hundred foot cable wouldn't make much difference. A 50 ft difference on a 100ft cable would.

@@steveurbach3093 They only need to be VERY close if you are depending on the calculation to be VERY accurate. You can actually run an 8ga and a 10ga and you will get the resistance relief. It's not a problem. And yes there are sections about it in the code because it's done at larger sizes.

The voltage drop results in less Power (Voltage x Current) at end of the wire run as compared to the start.

But its the same amount of power (watts) going through the wire at any point. @@everydaysolar

​@@McDIYno, same current but not same voltage every where along the wire. Some power is used to overcome the resistance of the wire

If crimped correcting you should be good assuming you are not going over the limit for current on the wire gauge.

Not concerned for this test as we were consistent in the measuring technique across the 8, 10, and 12 gauge wires so there could be a small about of line loss in the 12 gauge leads going into the energy monitor but it would be consistent across each of the 3 trials.

​@@everydaysolarYep it effects accuracy but not precision of the measurements.

I have not tested losses at MC4 connectors or on MC4 parallel branch splitters. I think you should be fine with your setup and I have purchased several splitters from Amazon and had good luck so far.

@@everydaysolar I appreciate the fast reply. As said, mine was a slap-together system, somewhere between tinkering and small scale backup for emergencies. Useful that I've not paid a dime to charge my phones, tablets, or flashlights for years, though. Thanks.

Thanks for the feedback.

Dc works by the cross section of the wire(s). Look up the cross section of what ever wires you want and total the cross sections of multiple wires ans compareto the cross section of the bigger single wire. This doesn't work for AC due to skin effect.

@@ghz24 Thank you for the info.

No, there is the maximum current a wire can handle which is usually much higher than the current you would want to carry to keep line loss percentage lower than 3%.

That should not be a line loss issue since it is reduced for such a short length but you would want to make sure that thinner gauge can handle the current load from a failure/heat generation standpoint as opposed to an efficiency/line loss perspective.

I just did a video on a nice little ground mount and touched on the grounding at the end. Not sure that will be ideal for your 200W but depends on the size kzbin.info/www/bejne/f5jIkoSpZrSIqqc

@@everydaysolar Thanks ! I was actually watching it when I saw your comment. Have you ever installed any solar panels on a wood fence? I really like the ground mount but I don’t have a ton of ground space. I am looking at ways to mount solar panels on my fence. I have 6 200 watt panels.

Yeah, that would help compare apples to apples. Thanks for the feedback!

If you were charging a battery there is absolutely no benefit from facing some panels in different directions. What you want is the maximum amount of amp hours delivered to the battery and that will only cut into that.

Yep. Plus, easier to work with.

@@boblatkey7160 If that's *all* you are doing then that is probably the best way to go. However, if you are charging batteries and running loads all day and night, such as in an off grid household then things become quite different. Having some west facing panels makes a massive improvement to battery life because it lengthens the time each day the loads are purely solar powered, before dipping into the stored charge in the battery. It all depends on how large the solar array is and how big the battery is. 2 x 100 watts into a 100AH battery, for example, you probably want to point 'em the same direction.

I think that's why he spread them out quite a bit

As @bbalaskan89 mentioned I tried to lay the wires out to avoid unwanted impacts of large coils but the testing setup definitely isn't "lab-grade" and a bit of a quick and dirty look are the losses from each size of wire.

Hmmmm, thanks for the feedback. I would expect a much higher line loss. I am curious now how your losses are so low for a 250' run. Do you know the Voltage and Amperage at the panels? Are you bringing in 4 panels together in series across and then those 2 strings in parallel into your charge controller? What are you using for a charge controller? Thanks for the feedback!

@@everydaysolar When you use high voltage everything works better. !2/2 is suitable for 20 amps that's about what my panels put out hooked in series but you're panels will only supply the amount of power that the charge controller asks for. The exact current output will depend on the load's power consumption and the solar panel's current output capabilities.

Current-Voltage Relationship: The current output of a solar panel is directly related to the voltage across its terminals. As the voltage increases, the current output typically decreases, and vice versa. This relationship is governed by the current-voltage characteristic of the solar panel, which is influenced by factors like the material properties and design of the solar cells. Temperature Dependence: Solar panel performance is affected by temperature. Generally, as the temperature of the solar panel increases, its current output decreases. This is due to the fact that increased temperature can lead to higher internal resistance within the solar cells, reducing their ability to generate current. Power Tolerance: Solar panel manufacturers specify a power tolerance rating, which indicates the allowable deviation from the labeled power output. For example, a solar panel with a "+/- 5% power tolerance" means the actual power output may vary by up to 5% from the labeled value. This tolerance also applies to the current output of the solar panel. Series and Parallel Connections: Solar panels can be connected in series or parallel configurations to increase the overall current or voltage output of the system. When solar panels are connected in series, the current remains relatively constant, while the voltage adds up. On the other hand, when connected in parallel, the voltage remains constant, while the current adds up.

Sure, some. But any loss is consistent with each wire gauge tested so although the percentage losses shown might be slightly affected the overall message is the same. 8 is better than 10 is better than 12.