Voltage & Current Accuracy: ±0.05% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤6ms
Current Response Time: ≤3ms
Minimum Pulse Width: 100ms
Feedback Efficiency (Max): 75%
Voltage & Current Accuracy: ±0.02% F.S.
High-Frequency Sampling: 200Hz
Current Conversion Time: ≤2ms
Current Response Time: ≤1ms
Minimum Pulse Width: 10ms
Feedback Efficiency (Max): 75%
Voltage Accuracy: ±0.02% F.S.
Current Accuracy: ±0.05% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤6ms
Current Response Time: ≤3ms
Minimum Pulse Width: 50ms
Current Accuracy: ±0.05% F.S.
Voltage Accuracy: ±0.02% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤6ms
Current Response Time: ≤3ms
Minimum Pulse Width: 100ms
Feedback Efficiency (Max): 90%
Voltage Accuracy: ±0.02% F.S.
Current Accuracy: ±0.05% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤10ms
Current Response Time: ≤5ms
Minimum Pulse Width: 100ms
Feedback Efficiency (Max): 94%
Voltage & Current Accuracy: ±0.02% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤20ms
Current Response Time: ≤10ms
Minimum Pulse Width: 50ms
Feedback Efficiency (Max): 96%
Voltage & Current Accuracy: ±0.02% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤20ms
Current Response Time: ≤10ms
Minimum Pulse Width: 50ms
Feedback Efficiency (Max): 96%
Voltage Accuracy: ±0.02% F.S.
Current Accuracy: ±0.05% F.S.
Recording Frequency: 100Hz
Current Conversion Time: ≤6ms
Current Response Time: ≤3ms
Minimum Pulse Width: 100ms
Current Accuracy: ±0.05% F.S.
Voltage Range: 0-1500V
Range of Adjustable: 2Ω-1MΩ
Number of Channels: 24CH
Communication Module: CAN, RS232, IIC, SMBUS, RS485
The lab focuses on solid-state battery research to overcome traditional lithium batteries' safety and energy density issues, supporting environmental sustainability. It develops innovative solid-state electrolytes, refines electrode materials, and investigates ion transfer and interface stability to revolutionize battery technology.
With the widespread use and increased frequency of cell phones, the endurance, safety, and lifespan of mobile phone batteries have become a focus of concern for both users and manufacturers. Cell phone batteries primarily use lithium-ion battery technology, but there are issues and challenges that drive the need for charge and discharge equipment to test cell phone batteries.
The electric vehicle battery industry is rapidly developing, focusing on technological innovation, market competition, and sustainability. Research hotspots include solid-state batteries, new types of electrolytes, BMS optimization, and recycling technologies. The environmental adaptability, safety, and economic viability of batteries are key research areas, and the industry is expected to undergo more innovation and transformation.
Current battery technology for laptops and tablets is moving towards higher energy density and fast charging, while focusing on improving battery safety and cycle life. Future trends point to the use of new materials such as solid-state electrolytes and the integration of smarter battery management systems to achieve longer life and better environmental resilience.
Electric Hoverboard, electric scooters, e bikes, and electric motorcycles are changing the way people travel, with the development of battery technology being at the core of this transformation. The main issues faced by electric bicycle batteries include battery cost, range, the popularity of charging infrastructure, thermal management of batteries, and safety. As battery technology continues to advance, it provides more reliable power support for these intelligent devices.
We specialize in battery preparation technology research, focusing on overcoming existing energy storage challenges by innovating in electrode materials, battery chemistry, and manufacturing processes to improve performance, enhance safety, and reduce costs. Sustainability and recycling technologies for batteries are also emphasized to mitigate environmental impacts and foster the growth of green energy.
