EVE Energy 40PL Drones Mission feasibility assessment - asses what missions or use cases are possible or not using a go/no-go decision using simulation.
Discover the EVE Energy 40PL cell for drones, optimised for mission feasibility assessments and high-performance applications. Learn more now.
Value Propositions
Cylindrical 21700 form factor for compact design.
Nominal capacity of 14.4 Wh and 4.0 Ah for reliable energy supply.
Top-quartile volumetric power density of 10,108 W/l for high current demands.
Gravimetric energy density of 215 Wh/kg, ideal for lightweight applications.
Maximum continuous discharge of 70 A, supporting demanding drone operations.
About the Cell
The EVE Energy 40PL cell features a cylindrical 21700 form factor, providing a nominal capacity of 14.4 Wh (4.0 Ah). With a volumetric energy density of 578 Wh/l, it stands out in the market, being around the median for volumetric energy density. The cell's gravimetric energy density of 215 Wh/kg is also competitive, ensuring lightweight solutions for drone applications. Additionally, it boasts a volumetric power density of 10,108 W/l, which is in the top-quartile compared to the database median of 2,029 W/l, making it suitable for high-performance UAVs. The maximum continuous discharge rate of 70 A allows for robust performance in demanding scenarios, while the standard charge current of 2.0 A ensures efficient recharging. Overall, the EVE Energy 40PL cell is designed to meet the rigorous demands of drone applications, providing both energy and power density that are essential for extended flight times and operational reliability.
Application Challenges
In the context of drones, mission feasibility assessment is crucial for determining which missions can be executed successfully. The EVE Energy 40PL cell's specifications play a significant role in this process. With a maximum continuous discharge of 70 A, the cell can support high-drain applications, which is vital for maintaining thrust during critical phases of flight. The nominal capacity of 14.4 Wh ensures that drones can carry out longer missions without the risk of power failure. Furthermore, the high volumetric energy density of 578 Wh/l allows for more compact battery designs, which is essential for UAVs that require lightweight solutions to enhance flight endurance. Accurate predictions of battery state-of-charge (SoC) and thermal management are also vital to prevent overheating and ensure safe operation. The EVE Energy 40PL cell's robust performance characteristics enable operators to make informed go/no-go decisions based on mission profiles, environmental conditions, and battery health, ultimately improving mission success rates.
Why this Cell
The EVE Energy 40PL cell is an excellent choice for drone applications due to its impressive specifications. With a maximum continuous discharge rate of 70 A, it is positioned in the top-quartile compared to the median of 30 A in the database, allowing for high-performance operations. Its volumetric energy density of 578 Wh/l is around the median, ensuring that drones can achieve longer flight times without compromising on payload capacity. The cell's gravimetric energy density of 215 Wh/kg is also competitive, making it suitable for lightweight drone designs. These features are critical for mission feasibility assessments, as they enable operators to evaluate the potential of various missions accurately. The EVE Energy 40PL cell's design supports the rigorous demands of UAV battery optimisation, ensuring that operators can confidently select the right battery for their specific applications.
How Model-Based Design Helps
Simulation and model-based design are invaluable tools in the selection and optimisation of battery cells for drone applications. By simulating load profiles, thermal behaviour, and voltage response, engineers can predict how the EVE Energy 40PL cell will perform under various conditions. This approach allows for accurate assessments of energy availability throughout a mission, enabling operators to make informed go/no-go decisions based on real-time data. For instance, modelling the thermal rise during high discharge scenarios helps identify potential overheating issues, ensuring that the cell operates within safe limits. Additionally, simulations can evaluate the impact of different flight profiles on battery performance, allowing for the optimisation of energy use and extending flight times. By leveraging these advanced modelling techniques, the EVE Energy 40PL cell can be effectively integrated into UAV designs, enhancing overall mission success and operational efficiency.
