Enpower Greentech XNP0094J Drones Safety and risk management - particularly around overheating and thermal runaway during flight.
Discover the Enpower Greentech XNP0094J cell for drones, designed for safety and efficiency, addressing overheating and thermal runaway challenges.
Value Propositions
Pouch form factor with nominal capacity of 32.9 Wh and 9.4 Ah.
High volumetric energy density of 607 Wh/l, top-quartile vs median.
Gravimetric energy density of 281 Wh/kg, around median performance.
Maximum continuous discharge of 47 A, top-quartile vs median.
Standard charge current of 4.7 A, efficient for UAV applications.
About the Cell
The Enpower Greentech XNP0094J cell is designed in a pouch form factor, providing a nominal capacity of 32.9 Wh and 9.4 Ah. This cell boasts a high volumetric energy density of 607 Wh/l, placing it in the top-quartile compared to the database median of 541.67 Wh/l. Its gravimetric energy density is 281 Wh/kg, which is around the median performance of 210 Wh/kg. The cell also features a maximum continuous discharge rate of 47 A, which is in the top-quartile compared to the median of 30 A. Additionally, the standard charge current of 4.7 A ensures efficient charging for UAV applications, making it a reliable choice for drone battery design.
Application Challenges
In the context of drones, safety and risk management is critical, particularly concerning overheating and thermal runaway during flight. The performance of the battery directly impacts the drone's ability to operate safely in various conditions. High energy density is essential for extending flight times, while effective thermal management is crucial to prevent overheating. The Enpower Greentech XNP0094J cell's specifications, including its high discharge rate and energy density, are tailored to meet these challenges, ensuring that drones can perform reliably without compromising safety.
Why this Cell
The Enpower Greentech XNP0094J cell is an excellent choice for drone applications due to its impressive specifications. With a maximum continuous discharge of 47 A, it is in the top-quartile compared to the median of 30 A, allowing for high-performance UAV operations. Its volumetric energy density of 607 Wh/l is also notable, being significantly higher than the median of 541.67 Wh/l, which translates to longer flight times. This cell is designed to handle the demands of drone battery design, ensuring that it can withstand the rigours of UAV battery pack design while maintaining safety and efficiency.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising the performance of the Enpower Greentech XNP0094J cell for drone applications. By simulating load profiles and thermal behaviour, engineers can predict how the cell will perform under various conditions, including high discharge rates and temperature fluctuations. This predictive capability allows for the selection of the most suitable cells for specific missions, ensuring that drones can operate safely and efficiently. For instance, modelling can help identify potential overheating issues before they occur, enabling proactive measures to be taken. This approach not only enhances battery thermal management for drones but also improves overall UAV mission endurance.
