The liquid cooling energy storage system is an advanced power storage solution designed for stable energy regulation in high-demand environments. It utilizes a circulating coolant mechanism to manage heat generated during charging and discharging processes, helping maintain consistent internal operating conditions. The system is built with modular battery units that allow flexible configuration for different capacity requirements. It supports integration with renewable energy sources, grid networks, and industrial power systems. A smart control unit coordinates energy flow, system monitoring, and protective functions to ensure reliable operation. This solution is suitable for applications requiring continuous power delivery and efficient thermal stability management.
DC Side Specification:
| Project / Parameter | Main Parameter / Specification |
|---|---|
| Rated Voltage | LFP 3.2V / 280Ah |
| Voltage Range | 672–864 V |
| Battery PACK Configuration | 43.008 kWh / 1P48S |
| Battery System Configuration (Rack) | 215.04 kWh / 1P240S |
| DC Protection | Breaker + Fuse |
AC Side Specification:
| Project / Parameter | Main Parameter / Specification |
|---|---|
| Rated AC Power | 100 kW |
| Maximum AC Power | 120 kW |
| Rated AC Voltage | 400 V |
| Rated Frequency | 50 Hz |
| Harmonic Distortion | <3% (At Rated Power) |
| Power Factor | >0.99 (At Rated Power, >20% Load) |
| Reactive Power Adjustment Range | -105% – 105% |
System Specification:
| Project / Parameter | Main Parameter / Specification |
|---|---|
| System Efficiency | ≥89% (Without internal consumption) |
| Charge/Discharge Ratio | ≤0.5C |
| Discharge Depth | 0–99% DOD |
| Cycle Life | > 8000 cycles&70% |
| Protection Degree | IP54 |
| Cooling Method | Liquid Cooling |
| Coolant | Ethylene Glycol : Water Solution = 50% : 50% |
| Corrosion Resistance Level | C4 |
| Fire Protection System | Active Alarm + Aerosol + PACK Immersion |
| Operating Temperature Range | -30℃ ~ 50℃ (Derating above 45℃) |
| Operating Altitude | ≤4000 m (Derating above 2000 m) |
| Operating Humidity | 0–95%, Non-Condensing |
| Communication Interface | RS485, CAN, Ethernet |
If you would like to explore the full capabilities of our Liquid Cooling Energy Storage System, understand how it can improve your energy performance, or discuss a customized configuration tailored to your project requirements, please feel free to contact our team for detailed information and professional support.
Selecting a reliable energy storage solution is essential for achieving long-term operational stability, cost efficiency, and high-performance energy management. Our liquid cooling energy storage system is designed to meet the demands of modern industrial, commercial, and utility-scale applications where continuous power output and precise thermal control are critical.
One of the core strengths of this system is its advanced liquid-based thermal regulation technology. Compared with traditional air-cooled methods, liquid circulation enables more efficient heat transfer and more uniform temperature control across battery modules. This significantly reduces thermal imbalance, minimizes cell degradation, and enhances overall system consistency during high-load operation. As a result, the system maintains stable performance even under extreme working conditions.
Built with high-quality LiFePO4 battery cells, the system offers exceptional safety characteristics, long cycle life, and strong resistance to thermal stress. This chemistry is widely recognized for its durability and stability, making it ideal for demanding environments where reliability is non-negotiable. With a cycle life exceeding 6000 cycles, it helps reduce long-term replacement costs and improves return on investment.
Another key advantage is its scalable modular architecture. The system can be configured for different capacity requirements, from medium-scale commercial applications to large grid-level energy storage projects. Its flexible design allows parallel expansion, enabling users to increase energy capacity without redesigning the entire infrastructure. This makes it a future-ready solution that can evolve alongside growing energy demands.
The integrated intelligent Energy Management System (EMS) and advanced Battery Management System (BMS) work together to provide real-time monitoring, predictive protection, and optimized energy distribution. These systems continuously track voltage, current, temperature, and system health, ensuring safe and efficient operation. Multi-layer protection mechanisms help prevent overcharging, deep discharging, short circuits, and thermal anomalies.
In addition, the system is engineered for high compatibility and seamless integration with solar PV systems, industrial grids, UPS systems, and hybrid energy platforms. It supports multiple communication protocols, enabling smooth integration into existing energy infrastructure while improving overall grid efficiency and stability.
Finally, our liquid cooling energy storage system is built to meet global standards such as CE, UL, IEC, and UN certifications, ensuring compliance with strict safety and performance requirements. With its combination of advanced thermal control, robust design, and intelligent energy management, it delivers a dependable and future-oriented solution for modern energy storage challenges.
This solution is developed for demanding energy environments that require high power stability, long cycle performance, and continuous operational reliability.
It can be seamlessly integrated with photovoltaic systems, industrial power networks, UPS backup systems, and hybrid energy platforms. The embedded energy management system (EMS) enables coordinated control of charging, discharging, and power distribution, ensuring optimized energy utilization across different operating scenarios.
The liquid cooling energy storage system is suitable for high-energy-demand applications such as industrial plants, commercial complexes, and grid-side energy storage stations.
The system uses high-grade LiFePO4 battery cells with strong thermal stability and long service life. The enclosure is constructed using reinforced industrial metal materials combined with corrosion-resistant coatings to ensure durability in harsh environments.
Precision-engineered liquid channels and heat exchange modules enhance thermal balance across battery modules, reducing internal stress and improving overall system efficiency. High-performance busbar design minimizes resistance and ensures stable current transmission.
Each liquid cooling energy storage system undergoes strict production processes including cell screening, module assembly, thermal system integration, and full system validation testing.
The integrated BMS continuously monitors voltage, current, temperature, and insulation status, providing multi-level protection against overcharge, over-discharge, overheating, and short-circuit conditions. Every system is verified through performance cycling tests, thermal simulation, and safety certification checks before delivery.
The liquid cooling energy storage system is widely applied in utility-scale energy storage stations, industrial power systems, large commercial complexes, renewable energy farms, and grid support infrastructure.
It is especially suitable for high-load environments requiring continuous power output, peak shaving, frequency regulation, and renewable energy stabilization.
The system is designed to comply with international standards including CE, UL, IEC, UN38.3, and MSDS certifications.
It meets strict industrial-grade requirements for safety, thermal management, and electrical performance, ensuring reliable operation in complex and high-demand energy environments.
Q1: What is a liquid cooling energy storage system?
A: It is an advanced battery storage solution that uses circulating coolant to regulate temperature and maintain stable performance during operation.
Q2: What are the main advantages of liquid cooling compared to air cooling?
A: Liquid cooling provides more precise thermal control, better heat dissipation efficiency, and improved consistency under high-load conditions.
Q3: Can this system work with solar and wind energy?
A: Yes, it can be integrated with renewable energy systems such as solar PV and wind power for energy storage and distribution.
Q4: Is the system suitable for large-scale industrial use?
A: Yes, it is designed for utility-scale and industrial applications requiring continuous power support and high energy capacity.
Q5: Does it support remote monitoring and control?
A: Yes, the system includes intelligent monitoring features that allow real-time status tracking and remote management.
A sealed coolant circulation pathway enables controlled heat transfer without reliance on external airflow conditions.
Temperature differences across battery modules are minimized through evenly distributed liquid circulation channels.
The system maintains stable electrical performance during prolonged heavy-duty discharge scenarios.
Real-time tracking of coolant condition ensures stable thermal operation and early anomaly detection.
The cooling components are structurally optimized to reduce space usage while maintaining efficiency.
Performance remains consistent even in high ambient temperature or confined installation environments.
The Liquid Cooling Energy Storage System is suitable for a variety of emerging power application environments, including high-power-density energy dispatch nodes, long-duration energy storage regulation centers, industrial-grade thermal load stabilization platforms, and multi-energy coordination and conversion hubs. It can be applied in system architectures that require continuous high-energy output and precise thermal management, while also adapting to complex grid optimization and regional energy balancing scenarios, delivering stable energy support and operational reliability under high-intensity operating conditions.
Commonly deployed in large grid-side energy storage projects to balance supply and demand, stabilize frequency, and improve overall grid reliability.
Widely used in factories and heavy industry plants to support continuous production, manage power fluctuations, and reduce peak electricity costs.
Applied in solar and wind farms to store excess generated energy and release it during low production periods, improving energy utilization efficiency.
Used in shopping malls, office towers, and business parks to optimize electricity consumption and provide backup power during outages.
Installed in high-reliability environments to ensure uninterrupted power supply for servers, communication systems, and mission-critical operations.
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