High Capacity 3.2V LiFePO4 Battery 280AH For EV And Solar Energy Storage System
Product Details:
Place of Origin: | GUANGZHOU |
Brand Name: | ODM OR OEM |
Certification: | MSDS REACH ROHS UN38.3 |
Model Number: | 71173204F |
Payment & Shipping Terms:
Minimum Order Quantity: | 100PCS |
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Price: | USD87 |
Packaging Details: | 4pcs/carton |
Delivery Time: | 14 days |
Supply Ability: | 100000PCS/month |
Detail Information |
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Type: | LiFePO4 Battery | Capacity: | 280AH |
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Voltage: | 3.2V | Dimension: | 71mm*173mm*204mm |
Weight: | 5.4KG | Case Material: | Aluminum |
High Light: | High Capacity 3.2V LiFePO4 Battery,280AH 3.2V LiFePO4 Battery,Solar Energy Storage 3.2V LiFePO4 Battery |
Product Description
High Capacity 3.2V LiFePO4 Battery 280AH for EV And Solar Energy Storage System
Feature:
1.Long cycle life ≥6000Cycles
2. Safe
3. Good high temperature performance
4. M8 Stud or non-stud.
High Capacity 3.2V LiFePO4 Battery 280AH for EV And Solar Energy Storage System
Parameter:
No. | Parameter | Specification | Condition |
2.1.1 |
Nominal capacity |
280Ah |
Refer to 2.2&2.3 standard charge and discharge procedure |
2. 1.2 |
Nominal energy |
896Wh | |
2. 1.3 |
Operation voltage |
2.5~3.65V 2.0~3.65V |
Cell temperature T>0℃ Cell temperature T≤0℃ |
2. 1.4 |
Impedance(1KHz) |
0. 12~0.22m Ω |
Fresh cell (25%SOC) |
2. 1.5 |
Shipping capacity |
70± 1.5Ah | 25%SOC |
2. 1.6 |
Shipping voltage |
3.260~3.290V | 25%SOC |
2. 1.7 |
Residual capacity loss |
≤3.5%/月 Per month ≤3.5% |
Fresh cell after 3 month, 40%SOC, 25±2°C storage |
2. 1.8 |
Operating temperature (charging) |
0~60℃ | Reference to paragraph 2.2 |
2. 1.9 |
Operating temperature (discharging) |
-20~60℃ | Reference to paragraph 2.2 |
2. 1. 10 |
Cell weight |
5.40±0.30kg | N.A. |
2. 1. 11 | Storage temperature | -20~60℃ |
Storage ambient humidity < 85% ROH, no condensation |
2. 1. 12 |
Typical dimension (W*H*T) |
(Width): 173.9±0.5mm (Height): 207 .3±0.5mm (Thickness):71.7±0.8mm |
Thickness with compression force (300±20Kgf), Height with Terminal, BOL (Reference to item 3) |
2. 1. 13 |
Rest SOC |
≥5% |
interval without load or charging |
No. | Parameter | Specification | Condition |
2. 1. 14 |
Altitude |
≤2000m | N.A. |
2. 1. 15 |
Cycle performance |
≥6000Cycles |
25±2°C, cycle test by the standard charge and discharge method under 300±20Kgf preload, 80% nominal capacity |
2. 1. 16 |
Cycle fading |
≤5% |
25±2°C, cycle test by the standard charge and discharge method under 300±20Kgf preload for 200 cycles |
2. 1. 17 |
Storage fading |
≤5% |
25±2°C, standard charging to 100% SOC storage under 300±20Kgf preload for 6 month |
Picture:
High Capacity 3.2V LiFePO4 Battery 280AH for EV And Solar Energy Storage System
High Capacity 3.2V LiFePO4 Battery 280AH for EV And Solar Energy Storage System
Charging/Parameter
No | Parameter | Specification | Condition |
2.2. 1 | Standard charge Current | 0.5C | 25±2℃ |
2.2.2 | Standard charge voltage | max voltage 3.65V | N.A. |
2.2.3 | Standard charge method |
0.5C CC-CV charge to 3.65 V ,cut off 0.05C |
|
2.2.4 | charge temperature | 25±2°C |
Cell Temperature |
2.2.5 |
Absolute charging temperature (Cell Temperature) |
0~60°C |
No matter what charge mode the battery is in, stop charging once the cell temperature exceeds absolute charge temperature range |
2.2.6 |
charging voltage |
Max 3.65V |
No matter what charge mode the battery is in, stop charging once the cell voltage exceeds absolute charge voltage |
Discharging/Parameter
No. | Parameter | Specification | Condition |
2.3. 1 | Standard discharge current | 0.5C | 25±2℃ |
2.3.2 |
Maximum discharge current (continuous) |
1.0C | N.A. |
2.3.3 | Discharge cut-off voltage |
2.5V 2 0V |
(Temp.) T>0℃ (Temp ) T≤0℃ |
2.3.4 | Standard discharge temperature | 25±2℃ |
Cell temperature |
2.3.5 |
Absolute discharge temperature |
-20~60°C |
Stop discharging once cell temperature is outside this range regardless of whether continuous or pulse current is adopted . |
Cell temperature rise
The temperature rise refers to the surface temperature of the cell after discharge minus the surface temperature of the cell before discharge. The measurement of the temperature rise of the cell should be carried out in a room where the ambient temperature is relatively stable and the space is large enough. For each cell temperature measurement, a calibrated temperature sensor that records time data should be selected.