If done right it should work fine just make sure that you use a couple of heat sinks on the LM317 if you can find the T3 mount type it has better heat transfer than the 220 type just make sure that you the right wattage resistor because if you are going to use one amp output mode

Think it would be better if I hacked the otherwise useless 24V linear PSU which uses 3 TO3 series pass transistors and a LM723. Just need to hack in a viable current limit and should be good to go. It'll be more efficient with the solar panels I'd think because it won't need to drop as many volts since the PSU transformer output is higher voltage... (The linear psu was already rated for 6A continuous so this will be better than any LM317 design I could hack up short of one that also has series pass transistors.)

however will need to redesign the psu to run totally off the solar panels, currently it uses two windings on the transformer to allow for instant on/off.

Still want to target a SMPS solution somehow. Need to get efficiency up so arbitrage is viable instead of trying to target just absorbing excess.

There is an issue with the volt / current meter module the current meter is a little over one amp off in its reading results which I will probably remove it and use a different meter module after I run some more tests today if the sun will corporates will me long enough to determine if it can or cannot charge 12 volt battery packs on one solar panel

I would be very interested in what you come up with if you can get this to work

Also how well dose a GTI work on 220 volt without using a neutral tap for 120 volt circuits

I am having hard time understanding how you could get this to work correctly and not not have issues with this setup now a 220 volt device no issues doing this

120V GTI works because there's an autotransformer somewhere and it could be outside your house. Same with 240V but I'd not get one for 240V w/o a ground tap. And definitely not a 220V one rated for 50Hz.

Well did some testing on a 12 volt battery pack with the boost converter and results are what I expected it to be at 12 volts what ever the voltage is the battery pack voltage is very close to that and the same thing with the current is very close to the same between the solar panel and the battery pack voltage

Which is what I expected now the current did come up to 6 amps until the battery voltage was at 13.5 volts and this also what I saw with the MPPT solar panel charging controller so this part looks good so there description seems to be accurate in that does function like a MPPT charging controller to some extent now when it is in the boost mode the current is almost half of what the solar panel current is which is what you expect being in the boost mode so the results are decent

Now weather or not it can handle 100 amps input I with what has been mentioned above maybe it can but I have my doubts because they are using the enclosure as a heat sink and a cooling fan which actually does come on when the enclosure get to warm

I just not sure if the enclosure can dissipate that much heat that 100 amps input from the solar panels I do not think that I will ever get that close to what they claim it can handle

I have a concept about running one of my battery testing machines on a solar panel / battery pack setup I think it might be feasible to do it because it runs on 24 volts switching power supply and the functioning controller is running on 12 volts from a linear voltage regulator a LM7812 ic chip

I am thinking that it should work because the buck converter only controls the current output from the buck converter which is a XL4015 ic chip so I think I can use a couple of these 24 volt battery packs from BH and it should work ( I going to give some more consideration think about what could go wrong with this concept)

I am very interested in your project about doing a SMPS power supply for a solar panel charging system

I think as higher the voltage difference is heat becomes a problem and thus limits you current output.

I became aware of this because of the difference of input current versus the output current which would mean that the mosfets are switching harder which would increase the possibility of generating more heat

Now if you keep the voltage difference to a minimum of what is needed then you get more current output and less chance of producing more heat than necessary now I could be wrong about this assumption if I am wrong please correct me if I am wrong about my assumptions

More testing needs to be done to understand how much difference in current will produce an acceptable result and not be a danger of thermal runaway situation and destroy the entire circuit to point of no return

Nohing to correct here Sam… you are on the right path! The circuit shouldn't be allowing thermal runaway to the point of no return. It should go into protection mode.