Image via WikipediaTo recondition your lead acid battery you will need Epsom Salt and a quart of distilled or rain water. Warm up the water to about 150 degrees (very hot but not boiling). The temperature doesn't need to be exact by any means and will still work even if the water is at room temperature, it just won't work as well. Mix 10 heaping table spoons full of Epsom Salt into the water and stir until most or all is dissolved. Then simply pour this warm solution into your battery where you would normally put water to maintain the acid levels. Do not attempt to put Epsom Salt directly into your battery because it will not dissolve into the battery acid, only water will dissolve Epsom Salt. Most batteries will be low on fluid so adding this solution will not over flow the battery. It is only recommended to add 1/2 quart of solution to an average size battery. If your battery is full of fluid already then you will need to drain some of the solution to allow for the 1/2 quart of Epsom Salt Solution. After adding the solution it is recommended to put the caps back on and shake the battery a bit to mix all the chemicals.
How to calculate UPS battery backup
When I first asked this question myself, a friend of mine kindly sent me to the manual (a joke, obviously). In the meantime, I found out that calculating ups batter back up is not such a big deal as I might have thought in the first place. In order to make everything as clear as I can, I will use a small example. Let us assume the following ideas:
Inverter efficiency of UPS battery is 90% (the norm is somewhere between 90% and 98%)
Environmental temperature 77F
Assuming that we know the following things about our UPS : one string of batteries, 30 each, UPS rating 40kW and 6 cells per unit, we can break down the calculations in three steps:
1.) Actual battery load for 40kW
40kW … 90% efficiency means an actual 44.4kW load (you can calculate this by dividing the rating of the UPS by inverter efficiency – 40/0.9 = 44.4kW)
2.) Watts per Battery
44.4kw (previously calculated) will be divided by the number of batteries we have available, and the result will lead to 1481 watts per battery. (you can calculate this using the equation: 44.4Kw/30 = 1481W)
3.) Watts per each Cell
Giving the necessary data we will deduct that each cell needs 247W. (calculate this using the equation: 1481W / 6 (the number of cells per unit) = 247 watts per each cell)
Now we can easily estimate the run-time of your UPS battery back up system. Giving the fact that we know that each batter has about 247W per each cell, and we have a battery end point voltage of 1.67V your run time should be somewhere between 45 minutes and 60 minutes.
Various Other Formulas to calculate backup time
- Battery current at full load / Battery Ah. This gives approximate backup time.
- Battery AH/Battery current at full load. Ex:160/40 amp we get three hours back up
- Battery Ah*dc cut off voltage of ups/load(VA)
- Battery Ah*nominal dc voltage of system/load in VA
- Battery capacity X No of battery X Ah X battery(0.8)/ o/p wattage. This is will give backup time for your setup
Related articles
- Letter Re: My Home Energy Backup System (survivalblog.com)
- My Home Energy Backup System, by David L. (survivalblog.com)
- Ultra 1000VA UPS Battery Backup with AVR for $90 + $17 s&h (9to5toys.com)
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