Our battery system is designed with seamless scalability, allowing it to adapt to diverse power requirements. It consists of two core modules:
a cell module containing four cells , which can be configured in 4s1p or 2s2p to enable flexible voltage and current outputs, and a control
module that integrates all the necessary electronics, ensuring a plug-and-play solution for fast, convenient, and efficient deployment

Our battery system is designed with a smart and efficient architecture, ensuring optimal performance, safety, and reliability. It consists of
three key components: CMU, BMU, and PDU, each playing a crucial role in system stability. With a safety-by-design approach, the system
includes redundancy mechanisms to prevent failures and ensure uninterrupted operation. The CMU continuously monitors and controls the battery system in real-time. The BMU manages battery health, charge, and discharge cycles, preventing overcharging and deep discharging to extend lifespan. The PDU efficiently distributes power, optimizing energy flow for various applications. To maximize performance, the system features
internal electrical balancing, ensuring all cells operate at peak efficiency. This enhances longevity, prevents degradation, and allows the
battery to consistently p Our battery system has proudly reached TRL9, erform at full capacity.

Our battery system is designed with seamless scalability, allowing it to adapt to diverse power requirements. It consists of two core modules:
a cell module containing four cells , which can be configured in 4s1p or 2s2p to enable flexible voltage and current outputs, and a control
module that integrates all the necessary electronics, ensuring a plug-and-play solution for fast, convenient, and efficient deployment

Space X- OSSIE OTV LEO mission. Cubesat deployment platform. 

 Our battery system has proudly reached TRL9, erform at full capacity. demonstrating its maturity and readiness
for operational use in the most demanding environments. The battery has undergone a comprehensive qualification process, following
the strict ECSS standards to ensure both performance and reliability in extreme conditions.

Extensive testing has been conducted to validate the battery’s robustness and functionality. These include thermal vacuum cycling, where the battery
undergoes full thermal cycling, being charged and discharged in both cold and hot conditions to ensure reliable performance across a wide range
of temperatures in vacuum. Random vibration and shock tests replicate the environment the system might experience during launch and flight,
verifying the structural integrity and stability of the battery. Additionally, thermal cycling tests simulate extreme temperature fluctuations to
ensure the battery remains operational across a broad range of temperatures, maintaining optimal performance. Furthermore, specialized safety
tests have been carried out on the electronic systems to ensure they meet the highest safety standards. These tests focus on fault detection, protection mechanisms, and overall system stablity under different conditions.
system stability under different conditions.

no restriction

global distribution

UARX