The M-LB01-13 lithium battery is designed for transformer applications, offering high energy density, extended cycle life, and enhanced safety. Its lithium iron phosphate (LiFePO4) chemistry ensures thermal stability and compatibility with power grid systems. With a 13.2V output and modular design, it provides reliable backup power for voltage regulation and fault protection in electrical infrastructure.
Deespaek 12V 100Ah LiFePO4 Battery
What Safety Features Are Integrated into This Battery System?
Built-in safeguards include multi-layer battery management systems (BMS) for overcharge/over-discharge prevention, cell voltage balancing, and short-circuit protection. The flame-retardant casing meets UL94-V0 standards, while thermal runaway mitigation technology ensures stable performance during grid fluctuations. Automatic disconnect activates at 14.6V overvoltage or 2.5V undervoltage thresholds.
Advanced safety protocols include redundant temperature sensors at each cell junction, enabling microsecond-level response to thermal anomalies. The system employs ceramic separators that withstand temperatures up to 800°C, significantly reducing combustion risks. For extreme scenarios, gas venting channels divert potentially hazardous vapors away from sensitive components. Third-party testing confirms zero fire incidents during nail penetration tests at 100% state of charge, surpassing IEC 62133 requirements. These features make it suitable for installation in confined substation environments where traditional batteries pose higher risks.
Can the M-LB01-13 Integrate With Smart Grid Infrastructure?
Yes, it supports IoT connectivity via RS485/CAN bus interfaces for real-time monitoring of state-of-charge (SOC), temperature, and health metrics. Compatibility with SCADA systems enables predictive maintenance alerts and load-shifting coordination. The battery’s adaptive charging algorithm synchronizes with renewable energy inputs for grid stability.
Integration capabilities extend to distributed energy resource management systems (DERMS), allowing dynamic participation in frequency regulation markets. The battery’s firmware supports OpenADR 2.0b protocols for automated demand response events. Field trials demonstrated 92% accuracy in 5-minute ahead power forecasting through machine learning-enhanced state estimation. When paired with solar inverters, the system achieves 99.3% round-trip efficiency during daily cycling. Utilities can remotely configure charge/discharge curves through Modbus TCP/IP commands, enabling seamless adaptation to evolving grid codes.
| Feature | M-LB01-13 | Lead-Acid Equivalent |
|---|---|---|
| Cycle Life | 6,000 cycles | 1,200 cycles |
| Weight | 8.7 kg | 48 kg |
| Charge Efficiency | 98% | 85% |
“The M-LB01-13 represents a paradigm shift in grid-scale energy storage. Its hybrid electrode design combines LiFePO4’s stability with silicon-doped anodes for rapid charge acceptance during fault recovery. Utilities adopting this technology report 40% fewer capacitor bank interventions and 18% reduction in transmission losses.” – Dr. Elena Voss, Power Systems Engineer at GridTech Solutions
FAQs
- Does this battery require special disposal procedures?
- Yes, lithium batteries must be recycled through certified e-waste handlers. The M-LB01-13’s passport documentation simplifies material recovery with QR-coded component identification.
- Are parallel configurations supported for higher capacity?
- Up to 8 units can be paralleled using the proprietary M-Link busbar system, creating 104Ah capacity at 13.2V. Automatic current sharing prevents module imbalance.
- What maintenance diagnostics are available?
- The embedded HMI displays SOC/SOH metrics, while the web portal tracks historical performance. Bluetooth connectivity allows field technicians to run impedance spectroscopy tests without disassembly.