Remote Powered Location

Re: Remote Powered Location

I think there is a bit of confusion about what each person is talking about...

First, the batteries. Typical Lead Acid batteries tend to sulfate (lead sulfate crystals grow) when a battery is below ~75% state of charge (25% of charge used). The longer the battery sits, and the lower the state of charge, the more sulfates crystallize. Once crystallized, that form of lead sulfate is an insulator and never "participates" in the battery charging/discharging cycles again... Effectively reducing the storage capacity of the battery.

So--what people are trying to say is that even if you had enough battery capacity for several months of no-sun operation, the batteries will be depleted (capacity wise) and even when you recharge them back to 100% State of Charge (SOC), the battery bank will never be the same.

Which is one reason why people here tend to recommend against adding more and more batteries to a system--because of sulfation issues.

Another issue, with standard flooded cell batteries, is (especially for "Tall" batteries) they "like" a minimum amount of current for mixing the electrolyte. That typically ranges from 5% to 10%+ rate of charge (i.e., 200 AH battery bank * 5% = 10 amps minimum rate of charge). For very large industrial cells (such as forklift/traction cells), 10% is probably the minimum rate of charge.

Another reason for the 5% minimum rate of charge is self discharge... For AGM batteries, as they age, you may get down to 1-2% self discharge per week... Not a large number.

For a large industrial flooded cell, you may get down to ~1-2% rate of self discharge in a day--a 5% rate of charge (~6 hours a day worth of sun light) vs 1-2% over 24 hours of self discharge--And your panels are struggling to just keep up with the loads.

Which gets back to your needs. It is probably financially and physically impossible for you to install enough AGM batteries to support your loads and not drop below 75% state of charge during that time period:

• 2 amps * 12 volts (I think) * 24 hours per day * 30 days per month * 2 months = 34,520 AH

Without knowing where the location is and how much "sun" you get during bad weather--it is guessing... But, if you assume a 1 hour of sun per day (0.62 derating based on 0.77 panel+charger derating * 0.80 battery efficiency):

• 2 amps * 24 hours * 14.5 volts charging * 1/1 hour of sun * 1/0.62 system derating = 1,122 watts of solar panel

Or about 1/2 that if you assume 2 hours of sun per day.

A "large" battery bank for normal off grid would be 3 days of "no-sun" and 50% maximum discharge for long life:

• 2 amps * 24 hours * 3 days * 1/0.50 max discharge * 1/14.5 volts = 288 AH battery bank

If you can use a backup genset, one option may be to find a propane powered generator from an RV wreckers (with electric start). That might be a good way to last through extended periods of fog/bad weather.

A lot of the previous discussion was centered around how to preserve your battery bank (i.e., have it last 5-10+ years, and not sulfate in two or less).

Depending on your needs--perhaps you can justify recycling the batteries early.

I guess it depends on how critical it is to have uninterrupted power 1-3 months at a time and if you can go there to manual recharge with a genset during bad weather...

The problem with solar arrays is they only work well in direct/full sun... If you have periods of poor weather--you can loose quite a bit of output. In my case, with a 3,500 watt GT system that can collect >20,000 WH on a nice day, I can collect <1,000 WH during stormy weather (5% of sunny capability). With light cloud cover--I probably get 30-50% of rated power in a day.

-Bill

Re: Remote Powered Location

Lets assume that you have weather conditions similar to Fresno CA. Assume 0.61 derating (battery losses, derating of solar panels and charge controller losses); assume fixed array. And 1kW (1,000 Watts) of solar array (smallest PV Watts will accept):

"Station Identification"
"City:","Fresno"
"State:","California"
"Lat (deg N):", 36.77
"Long (deg W):", 119.72
"Elev (m): ", 100
"PV System Specifications"
"DC Rating:"," 1.0 kW"
"DC to AC Derate Factor:"," 0.610"
"AC Rating:"," 0.6 kW"
"Array Type: Fixed Tilt"
"Array Tilt:"," 36.8"
"Array Azimuth:","180.0"

"Energy Specifications"
"Cost of Electricity:","12.5 cents/kWh"

"Results"
"Month", "Solar Radiation (kWh/m^2/day)", "AC Energy (kWh)", "Energy Value ($)"
1, 3.01, 53, 6.62
2, 4.55, 73, 9.12
3, 5.85, 102, 12.75
4, 6.78, 113, 14.12
5, 7.04, 117, 14.62
6, 7.20, 112, 14.00
7, 7.37, 116, 14.50
8, 7.47, 117, 14.62
9, 6.91, 108, 13.50
10, 6.11, 103, 12.88
11, 4.45, 75, 9.38
12, 2.79, 50, 6.25
"Year", 5.80, 1139, 142.38

PV Watts is based on ~20 year average measured solar conditions... Short term averages can vary +/- 20% over a month or year time frame (weather, other conditions).

So, for December, 1kW of panels gives about 50kW of useful power to your loads, or:

• 50,000 WH / 30 days per month = 1,667 Watt*Hours per day (December avg) for 1,000 Watts of panels

For 135 watts of panels:

• 1,667 WH * 135W/1,000W of panels = 225 WH per day (avg December)
• 225 WH / 12 volts = 18.75 AH per day

Your loads are ~1.9 AH * 24 hours per day = 45.6 AH per day load

From PV Watts (pick the "hourly output function), here is a "Bad Sun" day (426 WH per bad day per 1kW of solar panel):

1968, 12, 14, 07:00, 0
1968, 12, 14, 08:00, 0
1968, 12, 14, 09:00, 2
1968, 12, 14, 10:00, 12
1968, 12, 14, 11:00, 71
1968, 12, 14, 12:00, 138
1968, 12, 14, 13:00, 46
1968, 12, 14, 14:00, 92
1968, 12, 14, 15:00, 53
1968, 12, 14, 16:00, 12
1968, 12, 14, 17:00, 0
1968, 12, 14, 18:00, 0

And here is a "Good Sun" day from December (2,143 WH per good day per 1kW of panels):

1968, 12, 30, 08:00, 0
1968, 12, 30, 09:00, 5
1968, 12, 30, 10:00, 30
1968, 12, 30, 11:00, 335
1968, 12, 30, 12:00, 399
1968, 12, 30, 13:00, 456
1968, 12, 30, 14:00, 419
1968, 12, 30, 15:00, 283
1968, 12, 30, 16:00, 205
1968, 12, 30, 17:00, 11
1968, 12, 30, 18:00, 0

So, you can easily collect more power per good day (2,143 wh vs 1,667 WH average) or collect less (426 WH vs 1,667 WH on bad day--both based on 1,000 watt array) in December worst month of average power generation...

And compare to a typical August day:

1985, 8, 15, 06:00, 0
1985, 8, 15, 07:00, 10
1985, 8, 15, 08:00, 164
1985, 8, 15, 09:00, 300
1985, 8, 15, 10:00, 405
1985, 8, 15, 11:00, 496
1985, 8, 15, 12:00, 509
1985, 8, 15, 13:00, 511
1985, 8, 15, 14:00, 483
1985, 8, 15, 15:00, 424
1985, 8, 15, 16:00, 293
1985, 8, 15, 17:00, 166
1985, 8, 15, 18:00, 15
1985, 8, 15, 19:00, 0

The 9am to 6pm is only possible during the middle of summer... During winter, your generation is significantly less (with fixed array).

Your system may be a bit small to justify a Battery Monitor (such as a Trimetric)... But perhaps a DC AH/Watt Hour meter ($60) may be worth while for you to totalize your daily load and daily power generation.

I understand your frustration--but I am still having problems trying to figure out how to answer your questions.

During Summer, you have lots of sun available (say >7 hours of full noon time sun equivalent per day). A 135 Watt panel will output:

• 7 hours of sun * 135 watts * 0.61 derating * 1/14.5 volts = 39.8 AH per day (long term average)

Still a bit less than the 45.6 AH per day you are using... But--again these are averages, so some days your charging will exceed usage, and other days may not quite.

-Bill