Confused with % of Battery discharge

Re: Confused with % of Battery discharge

A 48 Volt Bank at resting voltage at 77F is around 45% state of charge (see generic bank voltage chart from Battery FAQ--12.00 volts).

However, the actual resting voltage is really dependent on the initial specific gravity of the electrolyte fill...

So, what was your "full charge" Specific Gravity?

One thread here
Another thread here

So, to pull from earlier posts:

Well mixed electrolyte is important--so if you notice all cells not coming back to "full charge" level of s.g., then there is a good chance that "mixing" (equalization) will bring the s.g. back up to your logged readings (keep these as your "good batteries" / "fully equalized" numbers.

The amount of variation you are seeing is not that great (less than 0.030 between all cells). And having "high" s.g. is not always a good thing either.

I ran across this page on why different types of batteries have different starting s.g. fills... Is pretty interesting:

Specific Gravity vs Applications
1.285 Heavily cycled batteries such as for forklifts (traction).
1.260 Automotive (SLI)
1.250 UPS – Standby with high momentary discharge current requirement.
1.215 Geral applications such as power utility and telephone.

As mentioned earlier, the specific gravity (spgr.) of a fully charged industrial battery, or traction battery, is generally 1.285, depending on the manufacturer and type. Some manufacturers use specific gravities as high as 1.320 in an attempt to gain additional Ah capacity, but at the cost of a shorter cycle life.

...

Higher Gravity = vs Lower Gravity =
More capacity / Less capacity
Shorter life / Longer life
Higher momentary discharge rates / Lower momentary discharge rates
Less adaptable to "floating: operation / More adaptable to "floating" operation
More standing loss / Less standing loss

Also on that page is the formula between cell resting voltage and specific gravity:

Specific gravity = single-cell open-circuit voltage - 0.845 (example: 2.13v – 0.845 = 1.285)
Or
Single-cell open circuit voltage = specific gravity + 0.845.

So, if you are getting 46 volts after resting, if the formula is correct (and your battery is around 77F) your specific gravity should be:

• 46v/24cells - 0.845 = 1.072 (dead?)
• 47v/24cells - 0.845 = 1.113 (~20% state of charge)

Yuasa states that the temperature correction for SG is:

• specific gravity changes by +.001 for every -3 degrees Fahrenheit.

J.R. Buchanan did a nice set of charts on battery SG and temperature based on a 100% charge = 1.265 SG.

By the way, do you have a Battery Monitor?

-Bill

Re: Confused with % of Battery discharge

Please feel free to step in Mike--Maybe I can rest my math/reading skills for a bit. :roll:

-Bill

Re: Confused with % of Battery discharge

Yes, Specific Gravity is "better" for checking state of charge... But you also need to know the initial SG (or SG when new and fully 100% charged) as the starting point.

SG measurements are a pain (go to shed, spill acid, drop pliers on battery bank, run like he11, etc.).

Voltage measurements are OK--if battery has rested for a few hours (no charging, no discharging). Somebody here commented that voltage measurements are less accurate at less than 40% state of charge.

And, then you have AGM/Sealed batteries where you cannot measure the specific gravity.

-Bill "pushing audredger down hill" B.

Re: Confused with % of Battery discharge

Actually, the formula for Battery Cell Voltage vs Specific Gravity (at 77F) is:

Specific gravity = single-cell open-circuit voltage - 0.845
(example: 2.13v – 0.845 = 1.285)
Or
Single-cell open circuit voltage = specific gravity + 0.845

Somebody else here (sorry, I don't remember who) said that the equation is less accurate below 40% state of charge.

-Bill