We use EVE's latest generation of LFP cells, they are rated for higher cycles that all other batteries similar to this. 

Most batteries use 4000 or 6000 cycle cells. 

This battery uses the 10000 cycle cells. 

Likely Technologies Implemented in the MB series of LFP cells, in many cases these technologies are licensed and patented and shared between China’s battery manufacturer’s.

1. Crystallized LFP Cathode Material:
   CATL has pioneered a fully nano-crystallized LFP cathode material based on hard carbon, not graphene, forming a highly efficient super-conductive pathyway. This sophisticated nanostructure promotes the swift extraction and movement of lithium ions, The stability and performance of the cathode are substantially improved, contributing to the extended cycle life and reliability of the battery. EVE and others like Hithium, CALB and REPT are all implementing the same technologies.
2. Granular Gradation Technology:
   This technology involves placing every nanometer particle in the optimal position within the cathode. By precisely positioning these particles, EVE has significantly improved the energy density and durability of the battery. This meticulous structuring at the nanoscale level minimizes degradation and ensures uniform performance over many cycles
3. 3D Honeycomb-Shaped Anode Material:
   The use of a 3D honeycomb-shaped material in the anode helps to increase energy density while effectively controlling the volume expansion during charge and discharge cycles. This design innovation not only boosts the battery’s capacity but also enhances its structural integrity, contributing to its extended lifespan
4. Advanced Separator Technology:
   The new LFP battery incorporates an ultra-thin, high-safety separator that improves ion transport while maintaining structural stability. This separator technology is crucial for achieving high charging speeds and ensuring safety during operation, which are critical factors for the long-term durability of the battery
5. Superconducting Electrolyte Formulation:
   The new battery employs a superconducting electrolyte formulation that enhances ion conductivity. This innovation ensures that the battery can charge and discharge at higher rates without compromising its longevity. It also contributes to the battery’s ability to maintain performance in extreme temperatures

DC Molded Case Circuit Breakers (MCCBs) are particularly suited for photovoltaic (PV) and battery applications due to their ability to handle the unique characteristics of DC power, such as high inrush currents and the continuous nature of direct current, which can be harder to interrupt than alternating current (AC). Here are a few reasons why DC MCCBs are advantageous for these applications:

1. Arc Suppression: DC circuits maintain constant current flow, making it challenging to extinguish arcs. DC MCCBs are designed with enhanced arc suppression features to break the circuit safely without sustained arcing, which is essential for battery disconnection and PV applications.

2. High Current Interrupting Capacity: Photovoltaic systems and batteries, especially in large installations, can have high fault currents. DC MCCBs are designed to interrupt these high currents effectively, preventing damage to other components and enhancing system safety.

3. Voltage Rating and Isolation: DC MCCBs are rated to handle high voltages typical in PV systems. For battery applications, these breakers meet IEC / EN 60947-2 standards, ensuring they can perform safely across various load conditions and provide effective isolation when required.

4. Compliance with AS/NZS 5139:2019: This standard is specific to battery energy storage systems in Australia and New Zealand, requiring MCCBs to act as the main battery disconnect. Compliance ensures the breakers are reliable, safe, and suitable as a main disconnect, meeting regulatory requirements for battery storage safety.

5. Reliable Overload and Short Circuit Protection: DC MCCBs provide both overload and short-circuit protection, essential for safeguarding both battery and PV system components from potential thermal and electrical damage, which could arise from system faults.

These features make DC MCCBs a robust choice for ensuring safe and reliable operation in PV and battery applications, especially when they are certified under IEC / EN 60947-2 standards and comply with AS/NZS 5139:2019.

This battery incorporates state-of-the-art cells and an advanced Battery Management System (BMS) that represent cutting-edge developments in energy storage technology. These components are so new and innovative that the necessary time to conduct extensive testing and obtain Laboratory Safety Certifications has not yet elapsed. This means the technology, despite its sophistication and potential, is still in the process of meeting all regulatory and safety requirements.

In essence, the technology is ahead of the regulatory curve, and the compliance process is ongoing to satisfy the formalities and rigorous standards required for full certification.

Right now our batteries are being shipped to the IEC for testing, this process will take a couple of months, Once we have this certification, we can then go to the CEC/SAA and apply to be a registered battery and importer and then you will be able to use this battery on the Australian Grid, with any compatible inverter, that works with the Pylontech protocol or its own compatible protocol. 

This means this battery will be able to conenct to VPP's such as Amber and others that support inverters such as the DEYE Hybrid Inverters that are currently our choice for OnGrid in Australia.