Amprius SA30 Drone Battery for Mission Feasibility Assessment - Core Technical Keywords
Explore the Amprius SA30 drone battery, optimised for mission feasibility assessments, ensuring reliable performance in critical applications.
Value Propositions
Nominal capacity of 87.72 Wh, ideal for long endurance drone batteries.
Gravimetric energy density of 324.89 Wh/kg, supporting lightweight drone battery packs.
Maximum continuous discharge of 103.2 A, top-quartile vs median 30 A.
Volumetric power density of 2796.3 W/l, +38% vs database median of 2029 W/l.
Form factor pouch, optimised for UAV battery pack design.
About the Cell
The Amprius SA30 battery features a pouch form factor with a nominal capacity of 87.72 Wh and 25.8 Ah, making it a strong contender for drone applications. With a volumetric energy density of 699 Wh/l, it ranks among the highest in the database, ensuring efficient space utilisation. The gravimetric energy density of 324 Wh/kg supports lightweight designs, crucial for UAVs. Additionally, the maximum continuous discharge rate of 103.2 A positions it in the top-quartile compared to the median of 30 A, enabling high-performance applications. The battery's volumetric power density of 2796 W/l is +38% above the median, allowing for rapid energy delivery when needed. These specifications make the SA30 an excellent choice for drone battery design, particularly in demanding missions.
Application Challenges
In the context of drones, mission feasibility assessment is critical for determining which missions can be executed successfully. The Amprius SA30 battery's high energy density and discharge capabilities are essential for ensuring that drones can operate effectively in various scenarios. For instance, in cold-weather environments, the ability to predict battery performance based on state of charge (SoC) and temperature is vital. The high nominal capacity of 87.72 Wh allows for extended flight times, which is crucial for applications such as industrial inspections and emergency response. Moreover, the lightweight design helps improve UAV mission endurance, preventing overheating and ensuring safe battery operation. Accurate predictions of battery performance can significantly enhance operational efficiency and mission success rates.
Why this Cell
The Amprius SA30 battery stands out for its impressive specifications, particularly in the context of mission feasibility assessments for drones. With a maximum continuous discharge of 103.2 A, it is in the top-quartile compared to the median of 30 A, making it suitable for high-demand applications. The volumetric energy density of 699 Wh/l is among the highest in the database, allowing for efficient energy storage in compact designs. This is particularly beneficial when designing UAV battery packs, as it maximises the available energy without adding excessive weight. The combination of high energy density and discharge rates ensures that the SA30 can meet the rigorous demands of drone operations, making it an ideal choice for custom UAV battery packs.
How Model-Based Design Helps
Simulation and model-based design play a crucial role in optimising the performance of the Amprius SA30 battery for drone applications. By simulating load profiles, engineers can predict how the battery will behave under various conditions, including thermal rise and voltage sag. This predictive capability allows for informed decision-making when selecting cells for UAVs, ensuring that the chosen battery can deliver the required performance throughout the mission. For instance, modelling the thermal behaviour of the SA30 under different discharge rates can help identify potential overheating issues, allowing for proactive measures to be taken. Additionally, simulations can assess the usable energy across the entire flight envelope, providing insights into how to maximise flight time and efficiency. This approach not only enhances the reliability of drone operations but also reduces the risk of mid-air failures, making it a vital tool in the design and optimisation of drone battery systems.
