Tenpower 50XG Mission feasibility assessment - asses what missions or use cases are possible or not using a go/no-go decision using simulation. Core Technical Keywords
Explore the Tenpower 50XG cell for mission feasibility assessments in aerospace, optimising drone battery performance and reliability for various applications.
Value Propositions
Cylindrical 21700 form factor for efficient design.
Nominal capacity of 18.0 Wh and 5.0 Ah for versatile applications.
Top-quartile volumetric power density of 6,360 W/l for high-performance demands.
Gravimetric energy density of 257 Wh/kg supports lightweight designs.
Maximum continuous discharge of 45 A for robust performance.
About the Cell
The Tenpower 50XG is designed in a cylindrical 21700 form factor, providing a nominal capacity of 18.0 Wh and 5.0 Ah. With a volumetric energy density of 707 Wh/l, it ranks among the highest in the database, significantly enhancing the efficiency of drone battery designs. Its gravimetric energy density of 257 Wh/kg is also notable, allowing for lightweight drone battery packs that do not compromise on performance. The cell boasts a volumetric power density of 6,360 W/l, which is in the top-quartile compared to the median of 2,029 W/l, making it ideal for applications requiring high energy output. Furthermore, the maximum continuous discharge rate of 45 A positions it well for demanding UAV applications, ensuring reliable performance under load.
Application Challenges
In the aerospace sector, mission feasibility assessment is crucial for determining the viability of drone operations. The ability to accurately assess what missions or use cases are possible using simulation is essential. Current and energy metrics are vital in this context, as they directly influence flight time and operational reliability. For instance, the high energy density of the Tenpower 50XG cell allows for extended flight durations, which is critical for long endurance drone batteries. Additionally, understanding the thermal management of the battery is essential to prevent overheating during high discharge scenarios, ensuring safe battery packs for UAVs. The challenges of accurately predicting state of charge (SoC) and performance under varying conditions further complicate mission planning, making reliable battery selection imperative.
Why this Cell
The Tenpower 50XG cell is particularly suited for aerospace applications due to its impressive specifications. With a maximum continuous discharge of 45 A, it is positioned in the top-quartile compared to the median of 30 A, ensuring that it can handle demanding operational requirements. Its volumetric energy density of 707 Wh/l is significantly above the median of 542 Wh/l, providing the necessary energy for long endurance missions. This high performance is crucial for UAV battery optimisation, allowing operators to extend drone flight time and improve mission endurance. The lightweight design of the cell, with a gravimetric energy density of 257 Wh/kg, further enhances its appeal for custom UAV battery packs, making it an excellent choice for various drone applications.
How Model-Based Design Helps
Simulation and model-based design play a pivotal role in optimising the selection of battery cells for UAV applications. By modelling load profiles, thermal behaviour, and voltage response, engineers can predict how the Tenpower 50XG cell will perform under various conditions. This approach allows for accurate assessments of usable energy and helps to identify the best battery configurations for specific missions. For example, simulating thermal rise and internal temperature during high discharge scenarios can prevent overheating and ensure that the cell operates within safe limits. This predictive capability is essential for making informed go/no-go decisions in mission planning, ultimately enhancing the reliability and efficiency of drone operations.
