Lithium Iron Phosphate Battery 24V 100AH Lithium Battery Pack Lifepo4 Battery
|
Nominal voltage |
24V |
|
Nominal capacity |
100AH |
|
Energy |
2.4KWh |
|
Internal resistance |
≤10mΩ |
|
Discharging end voltage |
29.2V |
|
Charging voltage |
29.2V±0.2V |
|
Max discharging current |
100A |
|
Max charging current |
50A |
|
Over-charging protection voltage |
29.2V |
|
Over-discharging protection voltage |
20V |
|
Charging temperature |
0 ℃ to 45 ℃ (32F to 113F) |
|
Discharging temperature |
-20 ℃ to 60 ℃ (-4F to 140F) |
|
BMS |
Customized |
|
LED display |
Optional |
Lithium Iron Phosphate Battery 24V 100AH Lithium Battery Pack Lifepo4 Battery
Their first challenge was to develop a novel electrolyte. A lithium-CO2 battery consists of two electrodes — an anode made of lithium and a cathode made of carbon — and an electrolyte, a solution that helps carry charged particles back and forth between the electrodes as the battery is charged and discharged. For their system, they needed an electrolyte made of amine plus captured CO2 dissolved in a solvent — and it needed to promote chemical reactions on the carbon cathode as the battery discharged.
They started by testing possible solvents. They mixed their CO2-absorbing amine with a series of solvents frequently used in batteries and then bubbled CO2 through the resulting solution to see if CO2 could be dissolved at high concentrations in this unconventional chemical environment. None of the amine-solvent solutions exhibited observable changes when the CO2 was introduced, suggesting that they might all be viable solvent candidates.