Enpower Greentech XNP0094J Drones Mission feasibility assessment - asses what missions or use cases are possible or not using a go/no-go decision using simulation.
Explore the Enpower Greentech XNP0094J cell for drones, designed for mission feasibility assessments with high energy density and optimal performance.
Value Propositions
Nominal capacity of 32.9 Wh and 9.4 Ah, ideal for drone applications.
Volumetric energy density of 607 Wh/l, top-quartile vs median (+16% vs 522 Wh/l).
Gravimetric energy density of 281 Wh/kg, around median vs database (±34%).
Maximum continuous discharge of 47.0 A, top-quartile vs median (+55% vs 30 A).
Form factor is pouch, providing lightweight and compact design for UAVs.
About the Cell
The Enpower Greentech XNP0094J cell is a pouch-type lithium-ion battery designed specifically for drone applications. With a nominal capacity of 32.9 Wh and 9.4 Ah, it offers a robust solution for UAV battery pack design. Its volumetric energy density of 607 Wh/l places it in the top-quartile compared to the median of 522 Wh/l, making it an excellent choice for long endurance drone batteries. The gravimetric energy density of 281 Wh/kg is around the median, providing a balanced performance for various missions. The maximum continuous discharge rate of 47.0 A is particularly noteworthy, as it is significantly higher than the median of 30 A, ensuring that the cell can handle demanding power requirements during flight. This cell is engineered for optimal performance in challenging environments, making it suitable for a wide range of drone applications.
Application Challenges
In the context of drones, mission feasibility assessment is critical for determining what missions or use cases are possible. The ability to accurately assess battery performance under various conditions is essential for ensuring mission success. The Enpower Greentech XNP0094J cell's high energy density and robust discharge capabilities allow for extended flight times, which is vital for applications such as industrial inspections, surveying, and emergency response. The challenge lies in ensuring that the battery can perform reliably under different environmental conditions, including temperature variations and varying states of charge (SoC). Accurate predictions of battery performance are necessary to prevent mid-air failures and to optimise mission planning.
Why this Cell
The Enpower Greentech XNP0094J cell is particularly suited for mission feasibility assessments due to its impressive specifications. With a volumetric energy density of 607 Wh/l, it allows for lightweight drone battery packs that do not compromise on performance. The maximum continuous discharge rate of 47.0 A positions it in the top-quartile compared to the median of 30 A, ensuring that it can meet the high discharge rate demands of UAVs. This capability is crucial for applications requiring rapid power delivery, such as heavy lift operations or high-speed manoeuvres. Additionally, the cell's gravimetric energy density of 281 Wh/kg supports the design of lightweight drone battery packs, which is essential for improving UAV mission endurance and extending flight times.
How Model-Based Design Helps
Simulation and model-based design play a pivotal role in optimising the performance of the Enpower Greentech XNP0094J cell for drone applications. By modelling load profiles, thermal behaviour, and voltage responses, engineers can accurately predict how the battery will perform under various conditions. This approach allows for the assessment of energy consumption across different flight speeds and mission profiles, ensuring that the selected cell meets the specific requirements of the mission. For instance, simulating the thermal rise during high discharge scenarios helps in selecting cells that can withstand demanding operational conditions without overheating. This predictive capability is essential for making informed go/no-go decisions, ultimately enhancing the reliability and efficiency of drone operations.
