High Discharge Charge Lithium Iron Phosphate (LiFePO4) Battery – Battery Backup Energy, Inc


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The two primary advantages of this LiFePO4 battery over sealed lead acid batteries are the significant reduction in weight and extreme (10x or more) improve in cycle life. For example, in most UPS (uninterruptible energy supply) lead acid batteries have a 200-300 cycle life and last between 3-5 years. This LiFePO4 battery has a cycle life of 2,000-3,000 and would last 10-20 years in the same state of affairs.

Flooded lead-acid deep-cycle batteries are often the least costly and have been tried and true by means of the many years that they’ve been round. These batteries do require maintenance. The water/electrolyte levels do have to be checked frequently. The battery compartment wherein these batteries are current will have to be correctly vented due the gassing from the batteries.

Lithium iron phosphate batteries are a kind of lithium-ion battery that uses lithium iron phosphate because the cathode materials to retailer lithium ions. LFP batteries typically use graphite because the anode materials. The chemical makeup of LFP batteries provides them a excessive present rating, good thermal stability, and a protracted lifecycle.

Because the photo voltaic energy business pushes the boundaries of fresh, renewable power, increasingly more households and companies are counting on the sun for fuel. But the sun solely shines for part of the day – so, like many other vitality setups, solar energy wants a storage solution to be utterly viable as a single source. Whereas adding battery storage to a Solar Controller array provides to the initial installation cost, using vitality storage increases the efficiency of photo voltaic panels, so in the long term, it decreases the per kWh value to consumers.

When connecting LiFePO4 cells in parallel, make it possible for the voltage between every cell is within 0.1V of each other before placing them into use, this can reduce the prospect of imbalance between cells. If you are charging 12V LiFePO4 cells, the charging voltage must be between 14V – 14.2V. When charging 24V cells in parallel, the charging voltage should be 28V – 28.4V. Charging 36V LiFePO4 cells in parallel requires a voltage of 42V – 42.6V. Lastly, charging a 48V LiFePO4 battery requires a voltage parameter of 56V – 56.8V. The desk under summarizes the voltage requirements for every system voltage.

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