1. Voltage Consistency:
This 3.2V LiFePO4 prismatic battery is engineered for exceptional voltage stability, ensuring consistent output during operation. Thanks to its voltage consistency, our battery maintains reliable performance across the system, minimizing fluctuations that can affect sensitive electronics or power-intensive applications.
2. Long Cycle Life:
Designed for durability, our battery supports over 1,000 charge and discharge cycles under standard usage. Some advanced versions exceed 2,000 cycles, providing a long-lasting power solution that reduces replacement frequency and long-term operational costs.
3. High Voltage Platform:
With a nominal voltage of 3.2V, this battery offers a higher operating platform than conventional 1.2V nickel-cadmium or nickel-metal hydride batteries. As a result, it delivers more energy per cell and enhances system efficiency.
4. No Memory Effect:
Unlike traditional nickel-based batteries, our lithium iron phosphate battery has no memory effect. It can be recharged at any state of charge without reducing its total capacity, making charging more flexible and user-friendly.
5. Fast Charging Capability:
This 3.2V LiFePO4 prismatic battery supports fast charging, enabling rapid energy intake with minimal heat generation - ideal for users needing quick turnaround times without sacrificing safety or performance.
6. Enhanced Safety:
Our battery features multiple built-in safety features, including overcharge, overdischarge, short circuit, and overheating protection, ensuring safe and stable operation even under demanding conditions.
7. Low Temperature Performance:
Our battery performs reliably in cold climates, making it suitable for outdoor or refrigerated applications where low-temperature tolerance is critical.
8. Standard Size:
With dimensions of 160mm × 50mm × 115mm (L×W×H), the prismatic design is ideal for integration into applications like e-bikes, energy storage systems, UPS backups, and industrial tools.
9. Customizability:
These batteries can be connected in series or parallel to meet specific voltage or capacity needs, offering flexibility for small-scale and large-scale power systems.
10. Environmental Protection:
This environmentally friendly battery is free from toxic elements like lead or cadmium. Its high energy density reduces battery consumption and promotes a greener, more sustainable energy solution.
PRODUCT DETAILS
SAFETY TESTING
Jawepower is a high-tech company integrating research and development, manufacturing, and sales of rechargeable battery products.
Since its inception, we have adhered to the "integrity-based, service-oriented, sincere communication, equality and attentiveness" as the core business philosophy, adhering to the "responsibility, innovation, resilience" corporate culture, relying on high-quality requirements for the backing of the spirit of openness and innovation in the lithium new energy industry.
FACTORY & WAREHOUSE
CERTIFICATES
JW_N21700CM_1.2m
JW_N21700CM_MSDS
JW_N21700CM_UN38.3
JW_N21700CM_STACKING
JW_N21700CM_SEABRONE
JW_N21700CM_AIRLIFT
Faq
Q:
Will high temperature lithium batteries explode?
A:
High temperature lithium batteries have a certain risk of explosion, but not all high temperature lithium batteries will explode.
The safe use temperature of lithium batteries is between 20 degrees Celsius and 60 degrees Celsius. Using lithium batteries
in a high temperature environment may trigger a chemical reaction inside the battery, resulting in the release of chemicals
inside the battery, thus increasing the risk of battery explosion.
However, most lithium batteries can still be used safely even at high temperatures. In order to ensure the safe use
of lithium batteries, you need to pay attention to the following points during use:
Avoid exposing lithium batteries to high temperatures for long periods of time, such as prolonged exposure to the hot sun or use in airtight electronic product cases.
2. Avoid mixing lithium batteries of different brands, specifications and capacities, as this may lead to short-circuiting
of the battery management chip, thus triggering an explosion.
3. Avoid overcharging or over-discharging during use, which may damage the battery management chip and increase
the risk of battery explosion.
4. In the process of using the battery should be kept well ventilated and heat dissipation, to avoid overheating of the battery.
In short, high-temperature lithium batteries have a certain risk of explosion, but as long as they are used correctly and cared for, this risk can be reduced.
Q:
What is the auto repair function of low temperature lithium battery?
A:
The automatic repair function of low temperature lithium battery means that the battery can still work normally in
low temperature environment and can be repaired automatically when failure occurs. This function is very important
for electronic products used in extreme environments, such as outdoor equipment in cold regions, automotive
electronics, spacecraft and so on.
The main principle of the low-temperature lithium battery auto-repair function is to add a special chemical substance
inside the battery in order to increase the conductivity of the battery in a low-temperature environment so as to
improve the efficiency of the battery. At the same time, this chemical substance can also be in the battery failure,
automatically repair the battery damage, to ensure the service life of the battery.
In conclusion, the low temperature resistant lithium battery auto-repair function is a technology that improves
the efficiency and lifespan of batteries in low temperature environments through special chemicals. This technology
plays an important role in improving the performance and reliability of electronic products and is widely used in various fields.
Q:
There are several welding methods for lithium batteries?
A:
Lithium battery welding methods are mainly the following:
Laser welding: laser welding uses a high-energy laser beam to irradiate on the battery cell, causing it to melt to form a welded joint. This welding method can realize efficient and precise welding, and will not cause thermal damage to the battery.
2. ultrasonic welding: ultrasonic welding uses high-frequency vibration energy to weld the battery cells together.
This welding method can realize efficient and precise welding, and will not cause thermal damage to the battery.
3. Resistance Welding: Resistance welding utilizes high voltage, low current electrical energy to generate heat through
the welding electrodes, melting the battery cells to form a welded joint. This welding method can realize efficient and
precise welding, but may cause thermal damage to the battery.
4. Laser spot welding: Laser spot welding utilizes a high-energy laser beam to irradiate the battery cells, causing them
to melt and form a welded joint. This welding method can realize efficient and precise welding, and will not cause thermal
damage to the battery.
In short, the welding method of lithium battery needs to be selected according to different product requirements and
material properties. When selecting the welding method, it is necessary to take into account the welding quality, production
efficiency, cost control and other factors.
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