input voltage drop

If you have series/parallel strings of panels... You have a couple of quick test options:

1. If you have a circuit breaker combiner box, you can turn off one string and then the other... Record the string current and voltage. Frequently, things fail one at a time, and the "weak string" can be identified and you can then do further testing (i.e., disconnect panels and check Voc/Isc numbers). If you have, for example, fuses/fuse holders, generally not a good idea to use the "fuses" as a functional quick disconnect as it is (quite) likely that you will have DC arcs which can ruin the holders or even set a holder on fire. Depending on how easy to get to the panels, you could try covering one string at a time with dark tarps/blankets to see if the "dark string" is carrying "its share" of voltage/current.
2. Get an AC+DC Current Clamp meter. You need the DC function of the meter and can quickly check the current from each string--Again, double check operation of each string.

It sounds like you have a failed panel with 30 volt drop (Vmp~30 volts?)... MPPT controllers "track for maximum power point"--But with a "failing panel", you don't know if it is tracking the "lower voltage or higher voltage power peak (i.e,. 60 volt peak of both string, or 90 volt peak of one string).

Examples of AC+DC current clamp DMMs (digital multi meters):

https://www.amazon.com/UNI-T-Digital-Handheld-Resistance-Capacitance/dp/B0188WD1NE (lower cost, "good enough")
https://www.amazon.com/Auto-Ranging-Resistance-Klein-Tools-CL800/dp/B019CY4FB4 (higher function, mid priced)

When doing your checks, crimp connections fail--You may see melting of plastic, or the wire may pull from crimp connections). Or you may see corrosion from water intrusion.

Look closely at panels... You may see streaks on cells/glass, water intrusion, corrosion, browning of cells, cracked cells, etc. I had failed panels due to j-box overheating (see some browning--"Coffee Stains"--on glass side of panel over j-boxes).

When testing panels--Try to do all checking quickly under "same sun, same direction wrt sun--With multiple panels, they should all be very close to each other (Vmp/Imp/Voc/Isc)--With in 10% or so of each other. Any panels that are 50% or greater deviation are probably "bad".

-Bill

Some panels have not been lasting as long as expected due to rear backsheet failures from UV/Temperature/etc. issues:

https://www.nist.gov/news-events/news/2020/03/nist-study-uncovers-potential-driver-premature-solar-panel-failures
https://www.dupont.com/solar-photovoltaic-materials/mast_linked_content/WHAT-TO-KNOW-ABOUT-PV-PANEL-FAILURES.html
-Bill

Can you read the Vmp/Voc/Imp/Isc numbers on the panels? Or get the model number and look them up?

There is something inconsistant about your readings...

If the panels are Vmp~30 volts... And you have 4 panels in series--That should be around 4*30=120Volts...

65 volts per string / 4 series panels = 16 volts or so per panel

That could mean that each panel is Vmp~18 volts (standard test conditions), or possibly you do not have 4 series * 2 parallel strings, but 2 series * 4 parallel strings (as an example).

An "issue" with off grid solar power systems is that the charge controller and the battery bank + loads "decide" how much current/power the system will draw from the solar array. So while your array may be capable of outputting (typical max is 8 * 235 Watts * 0.77 solar derating factors = ) 1,448 Watts on a cool clear day--A relatively charged battery bank with no much in the way of loads could draw much less power (1% float charge current * 370 AH battery bank * 27.2 volts float charge on battery bank = ) 101 Watts float charging or (101 Watts / 27.2 volts charging = ) 3.7 Amps into your battery bank--A perfectly working system (which does not tell you much about the 'health" of the solar array.

Your 65 Volt array reading--An MPPT controller will search (or track) for the optimum Vmp of the array (solve the Pmp=Vmp*Imp equation)... For example

65 Volt Vmp-array / 2 panels in series = 32.5 Volts Vmp-array (actual) -- Which is pretty close to a normal value for many panels.

-Bill

Have you measured the Voc-array (voltage open circuit of each string/full array)?

You have a 24 volt battery bank (?) and seeing ~60+ volts at the array/MPPT controller input... So it appears the MPPT controller is functional and the "measured by MPPT" is simply way below what would be expected--Roughly:

• 4 panels in series * 30.7 volts Vmp * 0.81 (Vmp temperature derating on hot/sunny day) = 99.5 volts nominal minimum expected array Vmp voltage.
• 235 Watt panel / 30.7 volts Vmp = 7.65 Imp approximate per panel/per string max current (what are you seeing)?

That you are almost 40 volts under that would indicate something failing at the panels (or shorted bypass diodes in panels, etc.).

If your max current is 1/2 or less of Imp, that would also suggest problems with panels or wiring.

You may not only wish to replace the array, but do something about your single (?) 40 amp MPPT controller... The "optimum" max array for your controller would be around:

• 40 amps * 29 volts battery charging * 1/0.77 panel+controller deratings = 1,506 Watt array "optimum" suggested maximum
• 1,506 Watts array / 235 watt panels = 6.4 panels @ 235 Watts
• 235 Watt array * 8 panels = 1,880 Watt rated array

Your present 8*235 Watt panels are a bit large for your current 40 amp MPPT solar charge controller (single unit?). Everything should work, but the controller will clip the available array output to 40 amps when charging.

A good quality MPPT controller should be able to manage the over-sized array just fine--No damage to controller or array would be expected (assuming good cooling airflow to charge controller).

-Bill

I was suggesting with the charge controller is disconnected from the array, to read the Voc-array (with an off grid system, there is no way to "guarantee" that the MPPT controller is not drawing some current from the array)... I am wondering what the voltage of 4 panels in series with zero load is (just using a separate volt meter which draws very little current)... Do the array strings get anywhere near 120+ Volts?

I don't understand how the array produces 62 volts or so with 4 panels in series unless you have one or two "dead" panels (or shorted bypass diodes in the J-Box).

I am a bit confused about the configuration... Do you have a 4s x 2p array connected to one charge controller, or have 4s x 1p array connected to one controller and 4s x 1p array string connected to a second 40 amp MPPT controller?

You don't have the 4s x 2p array connected to the Vpanel input of both controllers inputs--Correct?

-Bill

If each controller has 2 series * 2 parallel--Then no "Combiner Box" (from panels to charge controller with fuses/breakers per strong) is needed.

The J-Box I was typing about was in regards to the boxes on the rear of the solar panels. Sometimes there is a cover that you can unscrew... Many of the newer panels are simply sealed boxes (no service access) with the two +/- pigtails coming out of the box.

So seeing 62 some odd volts on the array when the sun is up and the MPPT controller is running is perfectly OK operation (at least from the 2x2 array voltage side).

Do you have a range of current that you have seen from the array? With Imp~7.65 volts--A well working 2x2 array should be, at best, have a maximum output current of 7.65 to (2x) 15.3 Amps (depending on sunlight conditions, battery state of charge, loading). As an example for the math:

• 7.65 Amps (1/2 the max array current) * 62 volts = 474 Watts (not clear day, battery bank mostly charged, not too much DC loads)
• 474 Watts * 0.95 (typical MPPT controller eff) * 1/28 volts battery charging = 16.1 amps (nominal, OK functioning) out of charge controller

From your first post in the thread:
The 90 Volts at the controller does not make a lot of sense for a 2s x 2p array... The 60-67 volt range would be in the normal range (all things considered).

What we need to know is the Wattage (and or Volts * Amperes) from each array and the battery state of charge (battery bank below 80% SoC will draw much of the power the array can provide). A full battery bank and not much DC bus loading, the controller will draw only the power from the array to hold the battery bank at charging voltage (~29.0 VDC) or float charging (~27.6 volts or so).

With solar power systems, and especially off grid systems, it is "difficult" to figure out how well the array is working... You could have solar panel issues, wiring issues, or simply a "full battery bank and zero loads"...

As a first guess--Look at the array current... If you are seeing between 50% and 100% of array rated Imp current (7.65 to 15.3 amps)--Everything is usually find (with Vmp-array voltage in your 6X volt range).

If you want to do some quick and dirty tests... Log the controller vmp-array and Imp-array. Then quickly cover one panel in a 2 x 2 string. Log the Vmp-array and Imp-array... If all is working OK, then your Imp-array should drop by about 1/2 (i.e., one parallel string is shaded, and not producing power). Then repeat by covering another panel on the other string and Log. Again, Vmp-array should be roughly the same, and Imp-array should be roughly 1/2 again.

You can repeat for the second controller too... Ideally, both controllers should be reading the same input and output voltages/currents.... HOWEVER, charge controllers have a "memory" and slightly different calibrations--So it is possible that one controller will "supply more current" than the other in some conditions (one controller is in float while the other is  still in bulk charging). Or you could be near 29.0 volt set point, and one controller is reading "29.2 volts" and cutting back on the current, etc....

At this point, I don't see anything wrong with your systems... But it will take the tarp testing, and logging Vmp-array and Imp-array values (with a discharged battery bank and/or high DC Bus current loading) to see if your system is performing at "peak" efficiency.

In general, solar panels don't all fail at once in the same way at the same time. The idea here is to test each one (drop one from system at a time) and see how much the output (current/power) falls. Ideally, they should all fall within the same amount (on the same array) withing 10% or so (i.e., 7 amps vs 7.7 amps).

-Bill