It is environmentally friendly. Unlike some traditional battery technologies that contain harmful substances like lead and mercury, it is free from such pollutants. This not only reduces the environmental pollution associated with its production but also minimizes the negative impact during its use and disposal. It aligns with the growing global trend towards sustainable and clean energy solutions, making it a more responsible choice for both consumers and industries. In the context of the global push for a greener future, it plays a significant role in reducing the carbon footprint of various applications. From powering electric bicycles that offer an eco-friendly alternative to gas-powered vehicles for short commutes, to being used in off-grid renewable energy systems in remote areas, it helps to create a more sustainable and environmentally conscious energy landscape.
It offers a wide operating temperature range. It can function effectively not only in normal ambient temperatures but also in relatively extreme heat or cold conditions. This versatility makes it suitable for a broad spectrum of applications, from indoor electronics to outdoor industrial equipment that may be exposed to varying weather and temperature conditions. In desert solar farms, where temperatures can soar during the day, it can withstand the heat and continue to store and supply energy efficiently. In Antarctic research facilities, it operates reliably in the frigid cold, powering scientific experiments and essential equipment.
In the production of it, thermal management technology is incorporated to control the temperature of it during operation. This may include the use of heat sinks, cooling fins, or liquid cooling systems. The heat generated during charging and discharging needs to be dissipated efficiently to prevent overheating, which could damage it and reduce it's lifespan. The thermal management system is designed to maintain it within an optimal temperature range. For example, in a liquid cooling system, a coolant is circulated through channels in the battery pack to absorb and carry away the heat. The flow rate and temperature of the coolant are carefully regulated based on it's operating conditions.
The manufacturing process also involves the calibration of it's performance parameters. This is done to ensure accurate measurement and reporting of it's state of charge, voltage, and capacity. Specialized calibration equipment and software are used to adjust the BMS settings and sensors. The calibration process is carried out at different stages of production and may involve charging and discharging it under specific conditions while measuring and adjusting the relevant parameters. Accurate calibration is essential for the proper functioning of it and for providing reliable information to the user.
|
Model |
48100 |
48200 |
|
Specification |
48V100Ah |
51.2V200Ah |
|
Combination |
15S1P |
16S1P |
|
Capacity |
4.8KWh |
10.24KWh |
|
Standard discharge current |
50A |
50A |
|
Max. discharge current |
100A |
100A |
|
Working voltage range |
40.5-54VDC |
40.5-54VDC |
|
Standard Voltage |
48VDC |
51.2VDC |
|
Max. charging current |
50A |
100A |
|
Max. charging voltage |
54V |
54V |
|
Cycle |
3000~6000cycles @DOD 80%/25℃/0 . 5C |
|
|
Operating temperature |
-10~+50℃ |
|
|
Working altitude |
≤2500m |
|
|
Installation |
Wall mount/Stacked |
|
|
Warranty |
5~ 10 Years |
|
|
Communication |
Default: RS485/RS232/CAN Optional :WiFi/4G/Bluetooth |
|
|
Certified |
CE ROHS FCC UN38 .3 MSDS |
|
Power wall 48V 100AH
Stacked 48V 100AH
Vertical 48V 200AH
