Bypass Diodes

Re: Bypass Diodes

Open by-pass diode-No easy way in an operating string... You could try "shading" parts of each panel. An open diode string would go high resistance" and the string current should drop dramatically and/or Vmp-string would drop dramatically when the small shadow covers cells protected by an open by-pass diode.

Shorted by-pass diode-String voltage would be down by ~12 volts or so, and/or drop in string current.

You may see browning/delamination over the panel J-box if you look closely (excessive heat from shorted diode and/or excessive shading on panel???).

-Bill

Re: Bypass Diodes

Think of a bunch of series D cell flash light batteries--Each which has a by-pass diode. Short one of the batteries, the string will loose 1.5 volts for every shorted battery.

Short a ~18 cell bypass diode, then you short out ~9 volts on that string.

That will reduce Vmp-string by ~9 volts... So that string will probably have lower output current when compared to identical parallel strings.

If this was a Vmp=18 volt array--The string with the failed diode would see zero amps.

If this was two Vmp=400 volt strings (such as a Grid Tied inverter), then 9 volt drop will probably only result in a small amount of current loss relative to the other string (Vmp 400 volts in parallel with Vmp 390 volts is almost a "no difference" situation). Vmp-array might drop a bit and be at Vmp-array 395 volts... Have not thought out the details.

And this gets to one issue I have between a 48 volt battery bank and a 12 volt battery bank.

If you have a shorted cell in a 12 volt bank, you get 10 volts--A vary obvious failure and most DC devices will not operate.

A shorted cell in a 48 volt bank means 46 volt nominal. The system will continue to operate just fine.

That is one reason I suggest weekly (or at least monthly) carefully checking the voltage of each battery (or cell) with a DMM. On a 48 VDC battery bank, it is pretty "easy" to miss a weak/failed cell in long strings.

And another reason I have not pushed 100-380 volt nominal battery banks--I would think a per cell (or, at least, per battery) voltage monitor would be needed to ensure that there are no shorted or open cells in a string. You would have a huge "nest" of extra wires (more dangers) or a bunch of vampire powered voltage monitor circuits.

And issues like this are why solar arrays are difficult to "fuse/breaker/arc fault/ground fault" protect/self diagnose. When you have huge numbers of low voltage (0.5 volt) cells and electrical junctions/wiring in series--Almost any failure that can happen will happen--And will punch holes in your safety systems.

-Bill

When a solar panel is connected "backwards" to a source like a large battery bank (and, in your case, the PWM charge controller let battery current through)--The solar cells, just "giant" diodes were "forward biased" and let >> Imp/Isc through the panel. This should not only fry the bypass diodes, but the solar cells too. Any series fuse/breaker is probably not fast enough to protect the reverse connected panel.

With a solar panel connected "correctly", the bypass diodes should not conduct any current except when one or more cells are shaded (bypass diodes are there to allow current "around" the "dark cells", rather than exceeding their reverse voltage rating of ~12-20 volt has or so).

If you have random shading on the solar panel during mid day (lots of sun on panel) from leaves, vent pipes, etc., and you have multiple panels in series, then the bypass diodes can allow current around the dark cell(s). And, at that point, if the bypass diodes are too small, they could overheat and fail (generally fail open, but can fail shorted too).

Remember that the maximum current/power from a solar panel could have been "throttled" by the charge controller doing its job... A charge controller only takes all avialable power/pushing maximum current to the battery bank if the bank needs charging (Bulk mode charging). Once the bank is over ~80% state of charge or so, the bank should be at the controller's voltage set point, (i.e., 14.8 volts for a 12 volt lead acid battery bank) and the battery+controller naturally limit the charging current to the battery bank (Absorb charge mode).

Of course, once the battery bank is full, the charge controller will drop charging voltage to "Float mode" of ~13.6 volts--And the battery will take very little charging current (usually much less than 1% rate of charge). At this point, the controller/solar array will only supply a little current to the battery bank (float charge) and supply current to any DC loads.

So--Looking at the charging current (4 amps, 10 amps, etc.), you need to know what the battery state is (is it charging and under ~14.8 volts--or whatever your set point is), and the charge controller is in Bulk, not Absorb or Float, mode charging. Before you decide to start replacing components.

You need to look at Vpanel voltage, Vbatt voltage, and Ibatt (battery current) at the same time to figure out if everything is really OK, or you have a bad panel or charge controller... You have many "confounding" issues--Possibly damaged solar panels... Not knowing enough about the operating state of the charge controller, and the battery bus voltage/state of charge/any DC loads...

From your history--I would suggest if you are having problems (full sun, low charging current, battery bank/charge controller in Bulk charge), that a new set of panels may be needed--They have been damaged, and "diodes" (many types of electronic/silicon devices) are notorious for failing down the road after being stressed.

If your bypass diodes failed shorted--That would have protected the solar cells and immediate reduced the panel's output voltage and/or current. If the diodes failed open, then the solar cells are not protected, and the solar cells could have been easily damaged. Open bypass diodes and "good" solar cells--The output of the panel is not affected.

I am not sure that your MPPT charge controller needs replacing at this point. But this is all guess work.

-Bill