Stand Alone, PV/Genny Hybrid Questions

Re: Stand Alone, PV/Genny Hybrid Questions

24 Sharp NE170-U1
2 Outback MX 60 Charge controllers
16 Interstate UL-16 Batteries
1 Xantrex XW 6048 Inverter

The system will be installed in Indianola Iowa.

ISG;

I indicated in my Jan. 20 post that there could be a problem with the Sharp 170 modules wired in series groups of three. It turns out that this is indeed an issue for the proposed combination of equipment. In fact, it’s my view that it’s a non-starter.

Here are the details.

Reference information:

• Sharp NE-170U1: http://www.sharpusa.com/files/SESG-170U1.pdf
• Weather data: www.weather.com
• MX60 specifications: http://www.outbackpower.com/pdf/manuals/mx60_pv_mppt.pdf
• NEC 2008, Article 690 (in general), 690-7 (in particular)

The National Electrical Code (NEC) Article 690.7 requires a PV array’s “maximum voltage” be calculated based on module manufacturer’s spec and a temperature correction factor based on local ambient conditions.

The Sharp module’s STC Voc spec is 43.2 V (ref 25 C), and the Voc temperature coefficient is -0.36%/C. The record low temperature for Indianola, IA is -37 C (-35 F), and the average low temperature (in January) is -13 C (9 F).

The PV module’s temperature-corrected Voc for -37 C is: (43.2 + ((-37 – 25) x -0.36% x 43.2))) = 52.84 V. The Voc of a series string of three modules is 52.84 V x 3 = 158.53 V. This value exceeds the maximum input voltage specification for the MX60 controller (150 VDC), and it also exceeds the maximum voltage spec for commonly available DC circuit breakers (also 150 V) used in PV combiner boxes.

This input voltage may/will damage the MX60, and, because the controller records the highest Voc, this operation may also void the controller’s warranty. Should your installation require a permit and inspection, the inspector may fail the system because of this design defect.

The module’s temperature-corrected Voc for -13 C is: (43.2 + ((-13 – 25) x -0.36% x 43.2))) = 49.11 V. The Voc of a series string of three modules is 49.11 V x 3 = 147.33 V. This value exceeds the maximum operational voltage specification for the MX60 controller (141 VDC).

Operating the controller at between 141 VDC and 150 VDC will cause the controller to suspend operation until the array warms up and its Voc drops to below 141 VDC. Since the array Voc will hit ~141 V when the ambient temp drops to ~0 C (~32 F), I would expect the controller to suspend operation on many mornings from November through March.

In summary, the combination of the selected PV modules, the charge controller, and, probably, the PV combiner box’ DC circuit breakers, would not, in my view, be suitable for your system’s environment. This particular compatibility issue is sometimes referred to as the “72 V array problem”, and three of your “24 V” nominal PV modules in series add up to “72 V”.

The 150 VDC limit is common for solar charge controllers. This is the limit for all OutBack charge controllers, and the same limit is used by many of our competitors. I know of one charge controller with a higher input voltage specs, but NAWS, this site’s sponsor, apparently no longer stocks this particular model.

Note that rewiring the array for series strings of two modules instead of three really isn’t an option. Due to high ambient summer temperatures {29 C (85 F) average in July, 45 C (113 F) record}, this array configuration’s operating voltage in the summer would be too low to fully charge the flooded-cell batteries.

You may not have many options at this point. One would be to consider adding ‘Low Temperature Overvoltage Bypass” devices. These devices bypass one module when the temperature drops below a specific threshold, and then they reconnect the module when the temperature increases. You’d need eight for your present array (one for each series string).

See: http://www.apollo-solar.net/specsheets/ApolloSolarLTOBSpecs.pdf

Another option would be to work with your customer’s dealer/installer to take back the Sanyo 170 modules and credit them for a different product. I’d be happy to provide you with a list of module configurations that would both meet the NEC code requirements and function correctly in your location. The list will be short, however, due to the combination of the product specs, high- and low ambient temperatures, and a 48 V (nominal) flooded-cell battery system.

I’m sorry to be the bearer of such bad news. But, I hope this helps, and that you’ll ultimately end up with the system performance you’re expecting.

Regards,

Jim Goodnight / "crewzer"
Eastern Regional Sales Manager
OutBack Power Systems

Re: Stand Alone, PV/Genny Hybrid Questions

ISG,

So your saying that if we continue as planned which was two seperate arrays each with 6 strings in parallel of 2 panels in series, for a combined Voc of 86.4 without calculating temp coefficient. This would not work in the summer due to low voltage, but if we change that to 3 panels groups in series it will melt/shutdown the controllers in the winter.

Right. The “high Voc in winter” issue is detailed in my post above. In brief, Vmp in summer is the corresponding issue. The STC Vmp of a series pair of modules is 34.8 V x 2 = 69.6 V. But, when it’s 35 C (95 F) in the summer and the modules are fully illuminated, their cell temperature will reach ~65 C, depending on mounting configuration and wind conditions. At 40 C above STC, figure on a voltage drop of ~16%, or from 69.6 V down to ~58.5 V measured at the array combiner box. Deducting another ~4 V for voltage drop in the wiring and inside the controller’s DC-DC buck converter results in ~54.5 V available to the batteries.

54.5 V is way below the (somewhat murky) charging and EQ requirements for the 48 V Interstate L-16 battery bank. See: http://www.batteries-faq.com/activekb/questions.php?questionid=1

I was just informed that the customer purchased four 12v Caterpillar batteries that he wants to add to his bank of Ul-16's. I am not to sure about combining two different types of batteries due to the Ah capacity of each, won't this cause problems during recharge?

It’s generally not a good idea to mix battery manufacturers. Differences in chemistries, capacities, age, and overall health usually ends up with one bank detrimentally affecting the other. IOW, it’ll work, but “one plus one will equal something less than two”.

Also I have a copy of the NEC 2005, is this to outdated?

Your local AHJ (Authority Having Jurisdiction, typically the local electrical inspector) probably has the last say in which version of the NEC is applicable. However, the 2008 NEC Article 690.7 is substantially changed from the 2005 version. The 2008 version defers to manufacturers’ specs for maximum voltage calculations instead of using the coarse temperature correction factors in 2005 NEC Table 690-7. If manufacturers’ specs aren’t available, then the 2008 version provides a more finely graduated Table.

HTH,
Jim / crewzer

Re: Stand Alone, PV/Genny Hybrid Questions

ISG,

Is there an easy solution for this summer issue?

Easy? Technically speaking, yes. Easy and “cheap”? That’s probably another story.

Building on some of the suggestions above, you could consider going with a 24 V battery system. One approach would involve returning/selling the XW6048 and replacing it with an XW4024. You’d also need to go from two charge controllers to three. Three 1,360 W STC eight-module PV sub arrays would each be wired up as 2 (modules per series string) x 4 (series strings in parallel). There’d be no high- or low-voltage array problems in the summer or winter.

Will the "murky" charging voltage damage the longevity of the batteries? Will he have to run the genny daily to top off the batteries?

Undercharged batteries -- "deficit recharging" -- will indeed shorten both their life (number of charge/discharge cycles) as well as their capacity. The generator would probably be needed on a regular basis during warm/hot weather – perhaps every other day, depending on insolation and load factors.

Can we wire the batteries in 24v or 36v bank and have the MPPT step down the voltage?

No. The 48 V inverter requires a 48 V battery bank to operate.

... I am running four KC130's in series and haven't had an issue. The lowest solar input voltage I have seen on our MX-60 on a hot summer day was 62, but it typically runs in the upper 60's in summer.

Yeah, Brock’s in a sweet zone. :cool: His array has a slightly higher voltage, his location’s ambient temps are generally cooler (less array voltage drop in the summer), and his 48 V AGM battery bank requires a lower charging voltage (~57.4 V) than does the Interstate flooded-cell battery bank.

HTH,
Jim / crewzer

Re: Stand Alone, PV/Genny Hybrid Questions

Is there an easy solution for this summer issue?

:roll: "Thinking" out loud: Another possibility would be to design and install a switching network for each six modules that would configure them for 2 (in series) x 3 (in parallel) for winter operation (i.e., ~Sep. 21 - ~Mar. 21), 3 x 2 for summer (~Mar. 21 - ~Sep. 21), and still use a 48 V battery bank and inverter.

hmmmm....
Jim / crewzer

Re: Stand Alone, PV/Genny Hybrid Questions

I agree... it's a pretty "sketchy" concept...

Jim / crewzer