Enpower Greentech XNP0094J Drones Maximise flight time - optimise the cell selection, duty cycle and flight speed to maximise flight time.
Discover the Enpower Greentech XNP0094J cell for drones, designed to maximise flight time with high energy density and optimal performance.
Value Propositions
Pouch form factor with a nominal capacity of 32.9 Wh and 9.4 Ah.
Volumetric energy density of 607 Wh/l, top-quartile vs median of 541 Wh/l.
Gravimetric energy density of 281 Wh/kg, around median of 210 Wh/kg.
Maximum continuous discharge of 47 A, top-quartile vs median of 30 A.
Standard charge current of 4.7 A, around median of 2 A.
About the Cell
The Enpower Greentech XNP0094J cell is designed specifically for drone applications, featuring a pouch form factor that allows for lightweight and compact designs. With a nominal capacity of 32.9 Wh and 9.4 Ah, it provides a robust solution for UAV battery pack design. The cell boasts a volumetric energy density of 607 Wh/l, placing it in the top-quartile compared to the median of 541 Wh/l in the market. Its gravimetric energy density of 281 Wh/kg is around the median of 210 Wh/kg, ensuring a lightweight solution for high energy density drone batteries. The maximum continuous discharge rate of 47 A positions it in the top-quartile against the median of 30 A, making it suitable for high discharge rate UAV batteries. Furthermore, the standard charge current of 4.7 A is around the median of 2 A, facilitating efficient charging for drone applications. This combination of features makes the XNP0094J an ideal choice for custom UAV battery packs aimed at maximising flight time.
Application Challenges
In the realm of drones, maximising flight time is critical. The challenge lies in optimising cell selection, duty cycle, and flight speed to achieve this goal. Current battery technologies often struggle with energy density and thermal management, which can lead to overheating and reduced mission endurance. The Enpower Greentech XNP0094J cell addresses these challenges with its high energy density and robust discharge capabilities. By selecting the right cell, operators can extend drone flight time, improve UAV mission endurance, and prevent battery overheating. Accurate state of charge (SoC) prediction is also essential for ensuring reliable performance during missions, especially in extreme environments. The XNP0094J's specifications make it a strong candidate for long endurance drone batteries, enabling operators to confidently plan missions without the risk of mid-air failures.
Why this Cell
The Enpower Greentech XNP0094J cell is particularly suited for drone applications due to its impressive specifications. With a volumetric energy density of 607 Wh/l, it is in the top-quartile compared to the median of 541 Wh/l, allowing for lightweight drone battery packs that do not compromise on performance. The gravimetric energy density of 281 Wh/kg is around the median of 210 Wh/kg, ensuring that the cell remains lightweight while providing substantial energy. Additionally, the maximum continuous discharge rate of 47 A places it in the top-quartile against the median of 30 A, making it ideal for high discharge rate UAV batteries. This combination of high energy density and robust discharge capabilities directly contributes to maximising flight time, making the XNP0094J an excellent choice for UAV battery optimisation.
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 modelling load profiles, engineers can predict how the cell will perform under various conditions, including different duty cycles and flight speeds. This allows for accurate predictions of thermal rise and voltage sag, which are critical for ensuring safe operation and preventing overheating. Furthermore, simulations can help determine the usable energy across the entire flight envelope, enabling operators to make informed decisions about mission feasibility. By using cell-specific data, engineers can benchmark the XNP0094J against other high-energy cells, ensuring that the best performing cell is selected for each specific application. This approach not only enhances battery thermal management for drones but also improves overall UAV powertrain efficiency, leading to longer and more reliable missions.
