Enpower Greentech XNP0120J Drones Safety and risk management - particularly around overheating and thermal runaway during flight.
Discover the Enpower Greentech XNP0120J cell for drones, designed for safety and risk management against overheating and thermal runaway during flight.
Value Propositions
Pouch form factor for lightweight drone applications.
Nominal capacity of 43.2 Wh and 12.0 Ah for extended flight times.
Top-quartile volumetric energy density of 655 Wh/l for compact designs.
High gravimetric power density of 1,394 W/kg for demanding UAV operations.
Maximum continuous discharge of 60 A for high-performance needs.
About the Cell
The Enpower Greentech XNP0120J cell features a pouch form factor, providing a nominal capacity of 43.2 Wh and 12.0 Ah. With a volumetric energy density of 655 Wh/l, it ranks among the highest in the database, ensuring compact designs for drones. The gravimetric energy density of 279 Wh/kg is also impressive, allowing for lightweight drone battery packs. Additionally, the cell boasts a volumetric power density of 3,273 W/l, which is top-quartile compared to the median of 2,029 W/l, making it suitable for high energy demand applications. The maximum continuous discharge rate of 60 A positions it well for high-performance UAV operations, ensuring that it can handle demanding tasks without overheating.
Application Challenges
In the context of drones, safety and risk management are paramount, especially concerning overheating and thermal runaway during flight. The ability to manage thermal conditions is critical for maintaining operational integrity and ensuring the safety of both the drone and its payload. High energy density is essential for long endurance missions, as it allows drones to carry heavier payloads over longer distances without compromising flight time. The Enpower Greentech XNP0120J cell's specifications are tailored to meet these challenges, providing reliable performance even under extreme conditions. The risk of thermal runaway is a significant concern in UAV applications, and selecting the right battery cell is crucial to mitigate this risk and enhance mission reliability.
Why this Cell
The Enpower Greentech XNP0120J cell is specifically designed to address the challenges faced in drone applications, particularly in safety and risk management. With a maximum continuous discharge of 60 A, it is positioned in the top-quartile compared to the database median of 30 A, ensuring it can handle high discharge rates without overheating. The cell's volumetric energy density of 655 Wh/l allows for compact designs, which is vital for lightweight drone battery packs. Additionally, its gravimetric energy density of 279 Wh/kg supports extended flight times, making it an ideal choice for UAV battery pack design. The combination of these metrics ensures that the XNP0120J cell not only meets but exceeds the performance requirements for demanding drone operations.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising the performance of the Enpower Greentech XNP0120J cell for drone applications. By modelling load profiles, thermal behaviour, and voltage response, engineers can accurately predict how the cell will perform under various conditions. This approach allows for the identification of potential overheating issues and thermal runaway risks before they occur. For instance, simulating the thermal rise during high discharge scenarios enables the selection of the most suitable cell for specific mission profiles. Furthermore, understanding usable energy across different flight envelopes ensures that operators can make informed decisions about mission feasibility based on battery state of charge (SoC) and environmental conditions. This predictive capability enhances reliability and safety, ensuring that drones can complete their missions without unexpected failures.
