Highlights
– 650+ Cycles without loss of capacity, which proven exceptional material stability and a long operational lifespan compared to conventional batteries
– Nearly 100% coulombic efficiency, attaching minimal additional reactions and strong intrinsic safety of sodium nickel chloridechemia
-High energy efficiency of up to 92%, which exceeds typical 70-80% levels of competing battery technologies
– proven safety under extreme conditions – Cells remained stable during overload, deep discharge and thermal cycles up to 300 degrees without gasification, leakage or breakage
– Robust and reliable chemistry – Sodium nickel chloride avoids flammable electrolytes and runaway risks, so that the suitability is confirmed for safe, large -scale grid and storage of renewable energy
-ABS60 prototype validated under Real-WORLD Conditions tested over different loading profiles, high current pulses and thermal variations
– Stable, efficient performance – achieve ~ 88% return efficiency without observable capacity fade over 110+ cycles
Cell performance
The prototype cells of the Cer energy (R) have successfully completed more than 650 load discharge cycles without any detectable loss of capacity. Cycle Life is a critical measure of the durability of the battery, because most conventional batteries experience gradual demolition with each cycle. Achieving such performance emphasizes the excellent stability of the materials and points to the potential for a long operational lifespan.
For stationary energy storage systems (ESS) this translates into fewer battery replacements, lower lifespan costs and greater reliability for end users.
The cells also delivered almost 100% coulombic efficiency in addition to an energy efficiency of up to 92% over 650 cycles. Coulombic efficiency reflects the share of the load that was recovered during dismissal compared to what was delivered during charging. A value that is 100% approaching indicates minimal secondary reactions or parasitic losses, which confirms the intrinsic stability and safety of sodium nickel chloride chemistry. This high efficiency shows that the cells do not spend energy on unwanted processes such as breakdown of electrode. Such performance is vital for scalability and ensures reliable, long -term operation in commercial energy storage applications.
Energie -Efficiency represents the share of the energy supplied compared to the energy supplied. Competing technologies, including conventional batteries at high temperature and many flow batteries, usually only reach around 70-80%. By reaching 92%, Cerenergy (R) positions itself in a very competitive class, which offers more cost -effective energy storage, stronger economy for grid operators and seamless compatibility with the requirements for integration of renewable energy.
The cells reached a nominal capacity of 100 AH and 250 Wh, with reliable performance, even at higher discharge speeds. An important feature is their ability to support multiple daily load discharge cycles within the 20-80% State of Charge (SOC) range on 25 A. These capacity positions Cerenergy (R) as a very flexible solution for schedule operators and energy storage providers, making it possible for cost-efficiency in applications in applications in applications in application. Frequent frequent frequent frequent frequent cycling, such as renewed, peak power, and backup force.
Cer energy (r) prototype cells underwent rigorous abuse tests, including overload of up to 4 V, deep discharge to 0.2 V and thermal cycles between room temperature and 300 degrees. In all cases, the cells remained stable without gasification, leakage or fracture -clear evidence of their excellent safety. These results emphasize the intrinsic stability of sodium nickel chloride chemistry, which prevents the flammable electrolytes and runaway risks that are common in lithium ion batteries. The possibility to resist extreme electrical and thermal stress shows the robustness of Cer energy (R) and confirms the suitability for safe, larger deployment in grid, renewable and industrial energy storage applications. This was achieved of 3 cycles with 1.8 full load equivalent (FCE) in 22 hours.
Battery ABS60 (60 kWh) Prototype
The first ABS60 battery package prototype is successfully validated under Real-World operating conditions, so that an important step forward in product willingness is marked. Testing includes different loading profiles,
Continuous discharges at 25 A (equivalent to C speed of C/4 (discharging in 4 hours), or a quarter of the nominal capacity of the package per hour) at 80% discharge depth (DOD), short-term pulses with a short duration and carefully controlled thermal variations.
The package showed consistently stable performance, so that ~ 88% return efficiency was achieved while retaining reliable thermal management. Efficiency refers to the share input energy that can be collected during the operation-a critical measure of economic viability for large-scale storage. In more than 110 cycles, the results showed no blurring of capacity and only a slight increase in internal resistance. Capacity blur refers to the gradual decrease in usable energy compared to repeated cycles, while internal resistance influences the power output and the generation of heat.
The absence of meaningful breakdown confirms the durability and electroclocation stability of the ABS60 design. These results are very important because they demonstrate that the package is resistant to Real-World duty cycles while retaining performance and efficiency, translating into a longer lifespan, fewer replacements and lower total property costs.
For grid operators and renewable integration projects, this combination of robust bicycle capacity, efficiency and thermal stability underlines the commercial readiness of ABS60 and the competitive advantage in the stationary energy storage market.
These results are a strong confirmation of the technological leadership of Cerenergy (R) and a clear signal of competitiveness and the robustness of technology for future applications in energy storage and industrial markets.
Group Managing Director, Iggy Tan, said: “These results confirm the robustness and willingness of Cerenergy (R) for market adoptation. Long cycle -lifference, high efficiency and unparalleled safety, we are now strongly positioned to offer a competitive and sustainable alternative for grid and industrial energy storage.”
*To view photos, tables and numbers, visit:
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About Altech Batteries Ltd:
Altech Battery’s Limited (ASX: ATC, OTC: ALTHF) (FRA: A3Y) is a special battery technology company that has a joint venture agreement with the world leading German battery institute Fraunhofer Ikts (“Fraunhofer”) to the revolutionary Cerergary (Sodergekalumy Cerergyalumy) (SAS) battery (SAS) battery (SAS) battery to commercialize. Cerenergy (r) batteries are the game-changing alternative to lithium ion batteries. Cerenergy (r) batteries are fire and explosion resistant; Have a lifespan of more than 15 years and operate in extreme cold and desert climates. The battery technology uses table salt and is lithium -free; Cobalt -free; Graphite -free; And copper -free, eliminating exposure to critical metal price increases and ensuring supply chain.
The joint venture commercializes its battery from Cerenergy (R), with plans to build a 100mWH production facility at Altech’s Land in Saxony, Germany. The facility is intended to produce battery modules of the Cer energy (R) to offer solutions for schedule storage on the market.
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