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A 130kWh liquid-cooled sodium-ion energy storage cabinet with 12,000-cycle life, intrinsically safe chemistry with no fire or explosion risk, discharge capability down to −40°C, and earth-abundant sodium for long-term cost advantage — available as OEM/ODM for C&I and utility applications.
No Fire · No Explosion
Sodium-ion chemistry offers a fundamentally different safety profile from lithium-ion. The thermal runaway temperature of sodium-ion cells is significantly higher than NCM lithium cells, and the intrinsic design eliminates the fire and explosion risk associated with conventional lithium-ion chemistries. Even under internal or external damage, the cell will not burn or explode. This intrinsic safety advantage reduces the fire suppression system requirements and insurance costs for BESS installations, and makes the AU130L-60K suitable for deployment in locations where lithium-ion fire risk is a regulatory or insurance barrier — including urban buildings, car parks, and indoor installations.
Discharge to −40°C
The AU130L-60K supports discharge from −40°C to +70°C — a temperature range that no lithium-ion chemistry can match. This makes sodium-ion the technology of choice for energy storage in extreme cold climates: northern Canada, Scandinavia, Russia, Central Asia, and high-altitude regions where winter temperatures regularly fall below −30°C. Conventional LFP cells lose 30–50% of their capacity at −20°C and cannot discharge below −30°C; sodium-ion cells maintain reliable performance throughout this range. The wide geographical deployment capability opens markets that are effectively inaccessible to lithium-ion BESS products.
12,000 Cycles @ 70% SOH
The AU130L-60K is rated for 12,000 cycles at 0.5P charge/discharge, 25°C, to 70% state of health — more than double the cycle life of standard LFP cells (typically 6,000 cycles) and over four times that of NMC cells. At one cycle per day, this translates to over 32 years of operational life, making the system economically viable for long-duration grid support and C&I peak shaving applications where the battery is cycled daily. The liquid cooling system maintains cell temperature uniformity to further extend cycle life beyond the rated specification under real-world operating conditions.
Earth-Abundant · Lower Cost
Sodium is the sixth most abundant element in the Earth's crust, available in virtually unlimited quantities at negligible extraction cost — compared to lithium, cobalt, and nickel, which are subject to supply chain concentration risk, geopolitical constraints, and price volatility. The AU130L-60K contains no lithium, no cobalt, and no nickel, eliminating exposure to the critical mineral supply chains that drive cost uncertainty for lithium-ion BESS. This structural cost advantage is expected to grow as sodium-ion manufacturing scales, making the AU130L-60K an attractive long-term cost position for large-scale energy storage procurement.
Sodium-ion · 130kWh · 170Ah · Liquid cooling · OEM/ODM available | Aurea Energy
| Parameter | Value |
|---|---|
| System | |
| Model | AU130L-60K |
| Nominal Capacity | 130 kWh |
| Cell | |
| Nominal Capacity | 170 Ah |
| Storage Capacity | 175 Ah |
| Operating Voltage | 1.5V – 3.5V |
| Platform Voltage | 2.85V |
| Rated Energy | 484.5 Wh |
| Impedance (1kHz) | ≤ 0.3 mΩ |
| Shipping Status | 38% SOC |
| Weight | 4.75 ± 0.20 kg |
| Temperature Rise | ≤ 10°C |
| Charging | |
| Standard Charge Current | 0.5P |
| Standard Charge Voltage | Cell max. 3.5V |
| Max. Charge Current (continuous) | 1P |
| Standard Charge Mode | 0.5P charge to 3.5V |
| Standard Charge Temperature | 25 ± 2°C |
| Absolute Charge Temperature (cell) | 0°C to +55°C |
| Absolute Charge Voltage | Max. 3.5V |
| Discharging | |
| Standard Discharge Current | 0.5P |
| Max. Discharge Current (continuous) | 1.5P |
| Discharge Cut-off Voltage | 1.5V |
| Standard Discharge Temperature | 25 ± 2°C |
| Absolute Discharge Temperature (cell) | −40°C to +70°C |
| General | |
| Cycle Life | 12,000 cycles (0.5P, 25±2°C, @70% SOH) |
| Environment Humidity | ≤ 95% RH (non-condensing) |
| Cooling Method | Liquid cooling |
| Fire Safety | Aerosol |
| Communication Interface | Ethernet / CAN / RS485 |
| Max. Working Altitude (m) | 2000 |
| Compliant Standards | GB/T34120, GB/T36276, IEC62477, IEC62619, IEC61000, UN38.3 |
| OEM/ODM available · Intrinsically safe — no fire/explosion risk · Earth-abundant sodium — no critical material bottlenecks | |
Intrinsically safe sodium-ion chemistry. Even under internal or external damage, the cell will not burn or explode — enabling deployment where lithium-ion fire risk is a barrier.
Absolute discharge temperature −40°C to +70°C — reliable performance in extreme cold climates where LFP cells lose capacity or cannot operate at all.
Over 32 years at one cycle per day — more than double standard LFP cycle life. Liquid cooling maintains temperature uniformity to further extend real-world lifespan.
No lithium, no cobalt, no nickel. Sodium is the 6th most abundant element — eliminating critical mineral supply chain risk and long-term cost uncertainty.
Integrated liquid cooling for thermal management and aerosol fire suppression. IEC62619, IEC62477, UN38.3, and GB/T36276 certified.
Available as OEM or ODM for system integrators and project developers. Ethernet / CAN / RS485 communication interfaces for integration with any EMS or SCADA platform.
Our engineering team is available Mon – Fri 8:00am – 6:00pm CST. Emergency support 24/7.
