Why can't I use a Xantrex C-Series Controller with higher voltage panels?

Re: Why can't I use a Xantex C-Series Controller with higher voltage panels?

bajajoe@hughes.net wrote: »

I keep looking at various sites on what voltages are required to charge a vented lead acid battery. The general answer I seem to find is that for a 24 volt system is bulk charging up to 30 volts, absorption 28.4 to 31 and float 25.6 to 26.4. And that Equalization should be at 10% over full charge. Since full charge for a 24 volt system is less than what? 28 volts, you can equalize at 30 or 31 volts if you can maintain that level.

Yep, all correct... Except that Vmp is rated at ~25C ... Which only occurs at two times in a panel's life... One for markting (and MFG) test (i.e., a bright light simulating the sun is turned on over a room temperature panel for a few seconds)... And on a Zero Degree C day (or colder) in full sun.

Typically a solar panel "cell" operates at 10C to 30C (or more?) over ambient temperature. And the cell voltage falls by ~ -0.5% per ^oC above 25^oC. So if you have a hot day (35^oC or 95^oF) and a 20^oC rise (no wind, lots of sun), the Vmp~30 volts at 25C becomes:

• 30 Volts Vmp - (30 volts Vmp * (35C+20C-25C) * -0.5% per ^oC) = 30 volts - 4.5 volts = 25.5 volts Vmp on a "hot day"

While the Vmp*Imp curve is not a peak but fairly rounded (perhaps + 5%)--That still means that on a pretty hot day (on your roof top), that your Vmp is low enough that you will loose significant charging current when you try to finish the charge (absorb) at 28.4 volts. Without allowing for wiring voltage drop (typically 1-3%) and another volt or so drop at the at charge controller.

That is why we use the "marketing" Vmp specification of ~17.5-18.6 as the "optimum" Vmp point for charging a 12 volt battery bank (or 35-37.2 volts for a 24 volt bank) to take into account all of these issues.

Even then you can see that it is difficult to get Vmp~35 volts and equalize charge a "cold" battery bank (say high desert and the batteries are in a cool basement). It sort of works because we usually recommend a 10% rate of charge for solar charging, and you only need ~2.5 to 5% rate of charge for equalization (another of those rules of thumbs that bury lots of little hidden nuggets like this).

My understanding of the operation of a "typical" solar panel is that Current Short Circuit would be the maximum current at zero volts (i.e. short circuit), the maximum voltage would be at zero current (i.e. Voltage Open Circuit). That you then have a point on the curve that graphs voltage versus current of Current Max Power and Voltage Max Power, which is the point on the curve just before current heads to zero and voltage max's out.

Note that solar panels are, more or less, "current sources"... This means that once the panel's output voltage is at around Vmp, the lower the output voltage/load (say a 24 volt Vmp panel charging a 12 volt battery) will simply be outputting Imp all the way to near zero output volts (yes, Isc is a bit larger than Imp--for for our example here--they are close enough to equal).

Once the solar panel voltage rises much above Vmp (5-10% of Vmp higher) the current rapidly begins to drop off and hit "zero" amps at Voc (again, Voc is also voltage sensitive--on on very cold days, you have to be careful that Voc-cold-array is not higher than the maximum input voltage for the charge controller).

So therefor if I have done an adequate job of wiring and minimized loss between panels and regulator, and it is not real hot outside, and I have a panel that is at 30.4 volts at max power voltage I should be able to obtain that or even 31 volts with Voltage Open Circuit at 36 or higher volts. Where am I misunderstanding this.

As soon as you bring that panel out on a nice 68F day (~18C)--Your solar cells are going to be ~20C (36F) higher--Or higher than the 25C/77F used to generate your "paper" specification.

And, remember, if you are in cold weather, there is a -5mV per degree C (per cell) in battery charging voltage set point... Say your battery is at 0C (32F). For a 24 volt battery bank your 29 volt set point becomes:

• 29 volts + (-0.005V per C * 0C - 25C STC * 12 cells) = 29 volts + 1.5 volts = 30.5 volts

So, your Vmp rating in cold weather under full sun is not at OC but ~20C, and the battery is now really cold and need that extra 1.5 volts to properly charge.

These is no easy way around this with current equipment.

There are switching power supply topologies that can "boost" solar array voltage ("boost" and "buck boost"). However, at this time most (all?) MPPT controllers only use a buck type power supply--Which can only "drop" voltages across the power supply (boost can only raise voltages, and buck-boost can do both--but both cost more money to build and are not as efficient).

-Bill

Re: Why can't I use a Xantex C-Series Controller with higher voltage panels?

niel wrote: »

the term 24v panel can be misleading. a true 24v panel, that is one that can deliver proper charge voltages to a 24v lead acid battery, will have 72 cells. a 72 cell pv will typically have a vmp (voltage at max power) in the mid 30s with around 36v to 37v being quite typical nowadays and open circuit voltages that go much much higher than that up into the 40v+ range. by this you see that the deeper the loading on the pv the lower its voltage shall go. the vmp point will be the optimal amount of voltage and current to give you the best overall power from the pv.

At Standard Test Conditions--Which almost never apply to a solar panel installed in the "wild" except during winter (very cold weather). Which is why we always derate panels so they will work the 9 months of the year it is not winter.

-Bill