How do you calculate battery capacity in
amp-hours (Ah) at different “C” rates?
For instance, I know that a
battery with a capacity of 200 Ah at C/20 has a different capacity at
C/100.
When you size a PV system with a battery bank of, say, 800 Ah, how do you tell what C-rate the battery bank is using?
C-rates are also called “hourly rates,” and are
based on the length of time of discharge. A C/20 rate means that battery
capacity is calculated based on completely discharging it over the
course of 20 hours. So, if you have a 1,000 amp-hour battery bank,
charging or discharging at 50 amps would be a C/20 rate (1,000 Ah ÷ 50 A
= 20 hrs.).
The informal solar industry standard for
comparing deep-cycle battery capacity is at the C/20 rate, because it
approximates the 24-hour discharge period of most off-grid systems. Many
battery manufacturers’ data sheets also provide capacity information
for C/5 and C/100 rates, which are useful in other industries.
It is possible to calculate battery capacity at
any given C-rate, if you know Peukert’s exponent for the battery.
Peukert was a German scientist who derived the formula for the
relationship between battery capacity and discharge rate. Battery
manufacturers do not typically provide Peukert data on their spec
sheets, but it may be available by contacting them.
It = C × [C ÷ (I × H)] k – 1; where
H = rated discharge time in hours;
C = rated capacity at that discharge rate;
I = actual discharge current in amps;
k = Peukert exponent
It = effective capacity at the discharge rate “I”
H = rated discharge time in hours;
C = rated capacity at that discharge rate;
I = actual discharge current in amps;
k = Peukert exponent
It = effective capacity at the discharge rate “I”
Most flooded lead-acid batteries have a Peukert
exponent between 1.2 and 1.4, while most absorbed glass mat (AGM)
batteries are between 1.05 and 1.2—but keep in mind that these figures
will increase as the batteries age. Peukert’s exponent for a given
battery can also be calculated if the manufacturer provides you with the
capacity ratings at two different discharge rates. That math is
complicated, but there’s a helpful spreadsheet (and detailed information
on applying Peukert’s law) at www.smartgauge.co.uk/peukert_depth.html
A typical renewable energy system will be
charging or discharging at different C-rates throughout the course of
any given 24 hours. With a battery monitoring system that logs data to a
computer spreadsheet, it’s possible to calculate the C-rate at any
given instant. And though it seems strange, your usable battery bank
capacity is continuously changing.
Fortunately for the typical home RE system
owner, discharge C-rates are, on average, quite low. Consider a 48 V
battery bank of 1,000 Ah in a system that’s designed to provide 10 kWh
of backup energy per day. Those 10 kWh equal 208 Ah. This divided by 24
hours equals 8.7 A. That’s a daily average rate of C/115 (1,000 ÷ 8.7),
far slower than the C/20 rate used for comparison when selecting
batteries. It’s true that large loads that are used during those 24
hours will increase Peukert effects and reduce usable battery capacity,
but this example is also figured with no solar input. On sunny days, the
C-rate of discharge will be even slower.
Folks working with electric vehicles must pay
closer attention to Peukert’s law. A typical EV’s battery bank has much
lower capacity than one in a typical solar home, since both battery
weight and bulk must be minimized in vehicles. Also, EV motors use
battery energy at very high rates—under some conditions, the battery
might be fully discharged in less than an hour.
For solar energy applications, simply using
proper system sizing guidelines such as online spreadsheets or
consultation with your local RE dealer will keep the batteries’ C-rates
reasonable, usually much better than C/20. Peukert’s exponent will only
raise its ugly head if you drastically undersize your battery bank for
your loads, or in specialized applications like electric vehicles.
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