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Home > products > 24V Lithium Iron Phosphate Battery > Factory Manufacture Li-Fepo4 24V 30AH Battery Pack For Pipeline Drain Inspection Robot

Factory Manufacture Li-Fepo4 24V 30AH Battery Pack For Pipeline Drain Inspection Robot

Product Details

Place of Origin: China

Brand Name: EWT

Certification: MSDS

Model Number: LFP 24V30AH

Payment & Shipping Terms

Minimum Order Quantity: 10

Price: 135USD/pc for 10-100pcs

Packaging Details: carton box+paper box

Delivery Time: 7-12 delivery days

Payment Terms: T/T

Supply Ability: 100pcs for 25-30 days

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Factory Manufacture Li-Fepo4 24V 30AH Battery Pack For Pipeline Drain Inspection Robot

Factory Manufacture Li-Fepo4 24V 30AH Battery Pack For Pipeline Drain Inspection Robot

 

 

species

 

Lithium Iron Phosphate

 

Voltage

32700-24V

 

capacity

30AH

 

Batteries

IFR32700 3.2V 6Ah

 

size

195*131*185mm

 

weight

7KG

 

Maximum charging current

20A

 

Maximum discharge current

50A

 

Display screen

No

 

Communication support

Bluetooth

 

 

What is the essence of the average voltage of lithium batteries? How to improve?

 

Generally speaking, the higher the specific capacity of the electrode, or the higher the average battery voltage, it is undoubtedly beneficial to the improvement of battery energy density. where the average cell voltage is determined by the free enthalpy of the lithium-ion exchange reaction, which includes the intercalation and disengagement of the lithium ions on the active electrode material. For ordinary cathode materials, the electrode reaction appears to be a redox reaction at first glance, however, this view does not take into account the interaction of electrons and ions in the material. It is because of these interactions that the electronic state of the transition metal ions involved in the reaction depends on the degree of lithium ion intercalation.

 

In view of the lack of understanding of the average voltage of batteries in traditional methods, in this paper, Professor Wolfram Jaegermann of the Technical University of Darmstadt, Germany, proposes a new method to analyze the average electrode potential of batteries. As shown in the figure above, the schematic diagram of the Fermi level and the density of states (DOS) of the electrode can be seen that under normal conditions, the Fermi level of the cathode material is located in the TM-3d derivative band and moves with the change of the charge state, and its displacement is related to the corresponding displacement of the electrochemical potential. However, the information obtained from this diagram alone is also incomplete, as it does not take into account the difference between the lithium-ion chemical potential in lithium metal and other anodes.