MaxAmps MA-8000 Mission feasibility assessment - asses what missions or use cases are possible or not using a go/no-go decision using simulation.
Discover the MaxAmps MA-8000 cell for drones, optimised for mission feasibility assessments. Achieve reliable performance with high energy density.
Value Propositions
Pouch form factor with nominal capacity of 29.6 Wh and 8.0 Ah.
Volumetric energy density of 370 Wh/l, top-quartile vs median of 542 Wh/l.
Gravimetric energy density of 185 Wh/kg, around median vs database.
Maximum continuous discharge of 180 A, among the highest in database.
Volumetric power density of 8317 W/l, top-quartile vs median of 2029 W/l.
About the Cell
The MaxAmps MA-8000 cell is designed specifically for drone applications, featuring a pouch form factor that allows for efficient space utilisation. With a nominal capacity of 29.6 Wh and 8.0 Ah, this cell provides a robust energy solution for various UAV missions. The volumetric energy density of 370 Wh/l places it in the top-quartile compared to the database median of 542 Wh/l, making it an excellent choice for long endurance drone batteries. Additionally, the gravimetric energy density of 185 Wh/kg is around the median, ensuring a lightweight solution for UAV battery pack design. The cell's maximum continuous discharge rate of 180 A is among the highest in the database, allowing for high discharge rate UAV batteries that can meet demanding mission profiles. Furthermore, the volumetric power density of 8317 W/l is also in the top-quartile, providing the necessary power for rapid response scenarios.
Application Challenges
In the context of drones, mission feasibility assessment is crucial for determining what missions or use cases are possible. The MaxAmps MA-8000 cell addresses challenges such as ensuring reliable performance under various conditions, including temperature fluctuations and varying states of charge (SoC). The high energy density of this cell is vital for extending drone flight time, which is a common pain point for UAV operators. Accurate predictions of battery performance are essential for go/no-go decision-making, particularly in critical applications where reliability is paramount. The ability to simulate different mission profiles using the MA-8000 cell allows operators to assess the feasibility of missions before deployment, reducing the risk of mid-air failures and ensuring mission success.
Why this Cell
The MaxAmps MA-8000 cell is an ideal choice for mission feasibility assessments due to its impressive specifications. With a maximum continuous discharge rate of 180 A, it is among the highest in the database, ensuring that it can handle demanding power requirements during critical missions. The cell's volumetric energy density of 370 Wh/l, which is in the top-quartile compared to the median of 542 Wh/l, allows for longer flight times, making it suitable for long endurance drone batteries. Additionally, the gravimetric energy density of 185 Wh/kg is around the median, providing a lightweight solution that does not compromise on performance. These characteristics make the MA-8000 cell a strong candidate for UAV battery optimisation, enabling operators to confidently select the right cell for their specific mission needs.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising the performance of the MaxAmps MA-8000 cell for drone applications. By modelling load profiles, thermal behaviour, and voltage response, engineers can predict how the cell will perform under various conditions. This approach allows for accurate assessments of usable energy and helps identify the best operating parameters for different mission profiles. For instance, simulating thermal rise and internal temperature can prevent overheating, ensuring safe battery packs for UAVs. Additionally, these simulations enable operators to make informed go/no-go decisions based on real-time predictions of battery performance, ultimately enhancing mission reliability and efficiency.
