I would suggest you take all those schematics and throw them in the trash. They all have changes or additions that I did not put on ANY drawing I created. Or if I did, they are incorrect. I know I NEVER used the term "UPS" or "MPPT" nor do I have that little picture of a "light bulb" that appears on so many of these drawings. These drawings were someone else's version of something I posted. They are way too complicated for a beginner. A beginner needs a basic setup and needs to learn the principles involved. Some of these schematics show what NOT to do, which is why I know they were altered because they do things I would NEVER do. Like running a load directly on a "UPS" instead of running that energy THROUGH the load and collecting it on the other side. That's a BASIC mistake.

There are basic principles I have been trying to show.
bistander claimed on his thread that I SAID a boost module is a free energy device. I actually said "I figured out YEARS ago that the boost module was a free energy device." What I SHOULD have said is, a boost module USED CORRECTLY is a free energy device. There's a HUGE difference. If you don't get that, you do not understand the most basic concept of using potentials. And not EVERY boost module will work on the system the way it needs to. And not EVERY boost module is efficient enough to give you good results.

If you run a boost module connected directly to a battery you might put in 100 watts and expect to get around 85 watts out the secondary on an "average" boost module. There is nothing "free energy" about that now is there? FAR less out than in. But if you run the boost module on the 3 battery system, or between potential differences, you input 100 watts and still get 85 watts out. But THIS time you recover some of what went THROUGH the primary of the boost module to the charge battery. If you recover LESS than 15 watts, you have nothing special. But if you recover MORE than 15 watts, you have a gain, and that GAIN is free energy. You are GENERATING energy here. You put some in and you get MORE OUT than what you put in when you combine the "generated" energy (85% of input energy) with the "recovered" energy (more than 15% of input energy). If NO energy was being recovered, battery 3 WOULD NOT CHARGE.

So how do you make sure that you get that gain? Well, the first thing is testing the crap out of a bunch of different boost modules to see which is the most efficient. There is one out there, very expensive I might add, that "CLAIMS" 95% efficiency, but when run under higher input voltages actually shows a return of 99.7%. So how much of the "input" do I have to recover to achieve that gain? If you couldn't do the math, the answer is .3%.

So now we look at means of recovery. A capacitor is best because it basically takes everything you want to give it up to its limit. Unfortunately you have to have a BIG cap. A cap in parallel with a battery will also work, and is better at collecting the energy that the battery cannot immediately accept . But you are still limited by the impedance of the battery. This is where the lithium batteries come in or the lithium/graphine hybrid. Their ability to accept what they are given without FIGHTING BACK can be the difference between success and failure. Battery impedance is a KILLER. More batteries in parallel to receive the "charge" energy the better.

I look at some of those circuits above and I see loads running on outputs. NEVER. NEVER. NEVER run a load unless it is between potentials. NEVER!!!! Now it can't be avoided if you only have one battery, but if you have THREE, eliminate that boost module running off a single battery to give you a higher potential source. You eliminate one BIG strike against success right there.

Think of a river flowing from the mountain top to the ocean. You can put hydroelectric dams along the river, but each dam produces less power than the one upstream (at least in this analogy). The Colorado in Arizona is an example. There must be four or five dams on the Colorado, and by the time it gets to Mexico, it is a stream not a river. Your system is going to flow downhill from the source, and you can tap it along the way to produce energy Each time you tap it you get out less until you get out very little. The HIGHER the source ( the farther up the mountain you go) the more times you can tap the source to produce and recover energy. Start with a 12 volt battery and you have to BOOST it to at least 24 volts to get your downhill flow. Start with 48 volts, and you have the difference between 48 and 36. The difference between 36 and 24. The difference between 24 and 12. From my count, that is 3 times you get to tap the flow of energy. YES, there will be losses. But if you use the RIGHT boost modules (three in this example) and the right batteries (ten in this example) and you run the outputs from the boost modules THROUGH loads back to the individual batteries at the top of the mountain, interesting things happen.

I would NEVER recommend starting with something this complex. Most people don't even understand how this really works and are incapable of putting together a functioning circuit. And then they will blame me because it did not work. Once you DO understand the principles and can build a simple circuit on your own, you certainly don't need ME to show you the benefits of a potential difference circuit. You will SEE the reasons on your bench. Or lighting up your shop.

HERE ARE THE TWO SIMPLEST CIRCUITS YOU CAN RUN
If you have only one battery, the simplest circuit is to run a boost module directly on it, positive to positive and negative to negative. Take the positive output of the boost module set to about 26 volts and run it to the positive IN of a SECOND boost module. Take the negative IN of that boost module and connect it back to the positive of your source battery. Now take the positive output of that second boost module(set to 26 volts also) and run it through a load back to the positive of that source battery. DON'T forget the diode!!! It gives you a voltage loss, but you may need it to protect your boost module. Then again, you may not. Want to fry a $30.00 boost module to find out? It may be worth it in the long run, but certainly NOT the short term. I wanted to add that with a single battery system, the capacitor across the battery is INCREDIBLY IMPORTANT, and it should be as huge as you can find. Because it will collect ANY energy it receives and outputs whatever it has in it, it is the lake being fed by a river at the top of the dam, and can provide as much over the top of the battery as is required while your battery slowly fills it up. If your system is outputting MORE than what is being consumed by the circuit and the load, you can ELIMINATE any "battery" issues of impedance with that capacitor. Set BOTH boost modules to around 26 volts.

If you have 3 batteries, put two in series and connect the boost module positive in to the positive output of the two batteries in series. Connect the negative in of the boost module to the positive of the third battery. Connect the negative of the third battery to the negative of the two batteries in series. Take the output of the boost module set to 26 volts and run it through a load to the positive of the third battery. You will have to rotate your batteries to keep up the potential difference and keep the batteries charged. Again, do not forget the diode!. Set boost module for 26 volts.

I have included a schematic for both circuits.

I am currently running something similar to the single battery circuit shown here. Just not using these same components, and because my output voltages are higher, I have to buck the voltage down before the load. But the principles are the same. And I am running 30 watts of load, and have run it with 70 watts of load for short periods to see what would happen to my battery voltage. It's called research.

Hey Turion,
I connected everything exactly as your schematic. I'm using lead acid deep cell not lithium battery. I put a simple on/off switch between the negative IN on the second boost module that connects to the returns to positive of the battery. Of course there's a diode in line there also.

When I flip the switch to connect that negative IN to that return , it makes the 25 watt bulbs go almost out and the module heats up without a fan on it. But if I cut that switch off the bulb lights up to normal.

I've checked all connections, got both modules set to same 26 volts.

Any ideas? I tried different valued diodes (new ones). I'm trying but cannot get any run times.

Yeah,
You should listen to someone who knows what they are doing and that's obviously not ME. I guess I wasn't thinking when I drew that schematic. No wonder bistander asked if I had ever run that circuit before.

Yeah,
You should listen to someone who knows what they are doing and that's obviously not ME. I guess I wasn't thinking when I drew that schematic. Here is what I am ACTUALLY running. Instead of a second boost I am running a DC to DC converter, which acts much the same, but is more efficient. And I have a cap across the input. It probably isn't necessary, but that DC to DC is like $130 rather than $30, so I take no chances. I am changing the picture on the previous post to the correct one. The main ISSUE is which side of the diode the LOAD is on. It changes the relationship between potential differences. No wonder bistander asked if I had ever run that circuit before.

How do we design the circuits to be MORE efficient?
What parts of the "basic circuit" could be eliminated or replaced with more efficient parts?
Is sending the energy directly back to the source the BEST use of what comes out of the secondary of the boost module? [/COLOR]