Enpower Greentech XNP0120J 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 XNP0120J cell for drones, optimising mission feasibility with high energy density and performance for reliable operations.
Value Propositions
Nominal capacity of 43.2 Wh and 12.0 Ah for effective energy storage.
Top-quartile volumetric energy density of 655 Wh/l, enhancing drone endurance.
Maximum continuous discharge of 60 A, supporting high power demands.
Gravimetric energy density of 279 Wh/kg, ideal for lightweight drone applications.
Form factor pouch design, optimising space and weight for UAVs.
About the Cell
The Enpower Greentech XNP0120J cell is designed specifically for drone applications, featuring a nominal capacity of 43.2 Wh and 12.0 Ah. Its pouch form factor allows for efficient use of space, making it suitable for various UAV designs. With a volumetric energy density of 655 Wh/l, this cell is among the highest in the database, significantly enhancing the endurance of drones. The gravimetric energy density of 279 Wh/kg ensures that the battery remains lightweight, which is crucial for maintaining optimal flight performance. Additionally, the cell boasts a maximum continuous discharge rate of 60 A, enabling it to handle demanding power requirements during flight. This combination of high energy and power densities positions the XNP0120J as an excellent choice for drone battery applications.
Application Challenges
In the context of drones, mission feasibility assessment is critical. The ability to determine whether a drone can successfully complete its mission based on battery performance is essential. Factors such as energy capacity, discharge rates, and environmental conditions play a significant role in this assessment. For instance, high energy density is vital for extending flight times, while reliable discharge rates ensure that drones can perform under varying loads. The Enpower Greentech XNP0120J cell addresses these challenges effectively, providing the necessary specifications to support a range of UAV missions, from industrial inspections to emergency response scenarios.
Why this Cell
The Enpower Greentech XNP0120J cell is particularly suited for mission feasibility assessments due to its impressive specifications. With a maximum continuous discharge of 60 A, it is positioned in the top-quartile compared to the database median of 30 A, ensuring that it can meet high power demands during critical operations. Additionally, its volumetric energy density of 655 Wh/l is significantly above the median, allowing for longer flight times without increasing weight. This makes it an ideal choice for applications requiring reliable performance in challenging environments, such as cold weather or high payload scenarios. The lightweight design, combined with high energy density, directly contributes to improved UAV mission endurance, making the XNP0120J a preferred option for drone manufacturers.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising the selection of battery cells for drones. By simulating various mission profiles, engineers can assess how the Enpower Greentech XNP0120J cell performs under different conditions, including thermal behaviour and voltage response. This allows for accurate predictions of usable energy and helps in understanding the impact of battery weight on flight time. For example, modelling the thermal rise during high discharge scenarios can prevent overheating and ensure safe operation. Furthermore, simulations enable the evaluation of energy consumption across different flight speeds, aiding in the selection of the optimal cruise velocity for maximum efficiency. This data-driven approach ensures that the right cell is chosen for specific missions, reducing the risk of failure and enhancing overall operational reliability.
