Tenpower 50XG Drones Mission feasibility assessment - asses what missions or use cases are possible or not using a go/no-go decision using simulation.
Explore the Tenpower 50XG cell for drones, designed for mission feasibility assessments, ensuring optimal performance and reliability in various conditions.
Value Propositions
Cylindrical 21700 form factor for compact design.
Nominal capacity of 18.0 Wh and 5.0 Ah for reliable energy supply.
Top-quartile volumetric energy density of 707 Wh/l for efficient space usage.
Maximum continuous discharge of 45.0 A, ideal for high-demand applications.
Gravimetric power density of 2314 W/kg, supporting robust performance.
About the Cell
The Tenpower 50XG cell features 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 stands out in its class, offering top-quartile performance compared to the database median of 542 Wh/l. The gravimetric energy density is 257 Wh/kg, which is around the median, ensuring a lightweight solution for drone applications. Additionally, the cell boasts a maximum continuous discharge of 45.0 A, which is significantly above the median of 30 A, making it suitable for high-demand scenarios. Its volumetric power density of 6360 W/l is among the highest in the database, providing exceptional power output for various drone missions. This combination of features makes the 50XG an excellent choice for UAV battery pack design, particularly in applications requiring high energy density and lightweight solutions.
Application Challenges
In the context of drones, mission feasibility assessment is crucial for determining which missions can be executed successfully. The ability to accurately predict performance under various conditions is essential. The Tenpower 50XG cell, with its high energy density and robust discharge capabilities, addresses the challenge of ensuring reliable operation during critical missions. For instance, when assessing drone capabilities for long endurance flights, the cell's nominal capacity and discharge rates play a vital role in decision-making. Simulation tools can model various scenarios, allowing operators to make informed go/no-go decisions based on the cell's performance metrics. This is particularly important in extreme environments where temperature fluctuations can impact battery performance. The 50XG's design helps mitigate risks associated with battery overheating and ensures that drones can complete their missions without unexpected failures.
Why this Cell
The Tenpower 50XG cell is specifically designed for drone applications, making it an ideal choice for mission feasibility assessments. Its maximum continuous discharge of 45.0 A positions it in the top-quartile compared to the median of 30 A, ensuring that it can handle demanding power requirements during flight. Furthermore, its volumetric energy density of 707 Wh/l is significantly higher than the median, allowing for longer flight times and improved mission endurance. This cell's lightweight design, with a gravimetric energy density of 257 Wh/kg, supports the need for efficient UAV battery pack design, where weight is a critical factor. By selecting the 50XG, operators can enhance their UAV's performance, ensuring that they can undertake a wider range of missions with confidence.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising drone battery performance. By modelling load profiles, thermal behaviour, and voltage responses, engineers can accurately predict how the Tenpower 50XG cell will perform under various conditions. This approach allows for the assessment of energy consumption across different flight scenarios, enabling the identification of optimal flight speeds and power management strategies. For example, simulations can reveal how the cell's maximum continuous discharge of 45.0 A impacts overall flight time and efficiency. Additionally, thermal modelling helps prevent overheating, ensuring that the cell operates within safe limits during extended missions. By leveraging these advanced simulation techniques, operators can make informed decisions regarding mission feasibility, ultimately enhancing the reliability and effectiveness of their drone operations.
