The Gerchamp lead-acid battery monitoring system features advanced intelligent algorithm analysis for thermal runaway early warning and high-precision state-of-health monitoring, providing reliable safeguards for the backup power systems in data centers. ### Lead Acid Battery Monitoring System ## 600 cells ### Maximum Management Scale ### As low as 3mA ### Operating Current ±5% ### SOC Accuracy ### Get a Quote ### Features of the Lead Acid Battery Monitoring System ### Lead Acid Battery Monitoring System ### Preventing Thermal Runaway Risks The system analyzes float charging current and temperature changes to predict and prevent thermal runaway in advance. This inherently avoids the risk of fire or explosion, ensuring the reliable operation of key area equipment and backup power supplies. ### Lead Acid Battery Monitoring System 24h Ultra-Low Power Operation The G-TH module adopts an advanced low-power circuit design, which at its lowest can maintain a consistent operating current of 3mA during 24h real-time monitoring. This minimizes the additional load on the battery under test, thereby extending its service life. ### Lead Acid Battery Monitoring System ### High-Precision Condition Monitoring The system delivers exceptionally accurate remaining capacity and health state analysis, with SOC/SOH accuracy of ±5%. This precision enables facility managers to implement targeted maintenance and predictive component replacement. ### Lead Acid Battery Monitoring System ### Outstanding Compatibility The product comes standard with multiple wired network and dry-contact interfaces, supporting MODBUS/RTU, TCP, and SNMP. It can be seamlessly integrated into third-party data center centralized monitoring platforms, reducing deployment costs. ### Lead Acid Battery Monitoring System ### Industrial-Grade High Reliability The core components boast a mean time between failures (MTBF) of 100,000 hours. The product has successfully passed multiple international certifications (CE, REACH, UL), enabling it to operate reliably in harsh environments with strong electromagnetic interference. ### Lead Acid Battery Monitoring System ### High-Density Array Management A single system can manage up to six independent string circuits, with a total of 600 lead-acid battery cells connected. This design features a high energy density that significantly saves cabinet deployment space compared to traditional monitoring solutions. Detailed technical specifications of Gerchamp lead-acid battery monitoring system | Project | Parameter Name | Parameter Value | | :--- | :--- | :--- | | Operating environment | Operating temperature | -20 to +60°C; Altitude: 0 to 2000m | | Operating environment | Relative humidity | 5% to 95% (non-condensing) | | Reliability indicators | Automatic restart trigger | Built-in WDT (Watchdog Timer) | | Reliability indicators | MTBF | 100,000 hours | | Industry Certification | Standards | CE, REACH, UL, EN61010 | | System performance | Max management scale | 6 strings, total 600 cells | | Communication interface | Support Protocol | MODBUS/RTU, TCP, SNMP protocols | | Measurement accuracy | Individual voltage | Compatible with 1.2V, 2V, 6V, 12V; Error ±0.1% | | Measurement accuracy | Internal resistance | 50 to 65535 μΩ; Repeatability error ±2% | | Measurement accuracy | Pole temperature | -5 to +99.9°C; Error ±1°C | | Power consumption | G-TH series modules | Fixed 3mA operating current (24h monitoring) | ### Lead Acid Battery Monitoring System Comparison Point ### Lead Acid Battery Monitoring System Comparison Point ### Lead Acid Battery Monitoring System ### Predictive vs. Passive Monitoring Unlike basic acquisition devices, the Gerchamp system integrates intelligent algorithms that can predict battery degradation trends. This allows operations teams to proactively prevent issues rather than passively responding to alarms. ### Lead Acid Battery Monitoring System ### Hardware Efficiency & Space Saving This product uses an ultra-low power architecture where the G-TH module maintains an operating current as low as 3mA. Furthermore, the physical volume of the hardware is significantly reduced than lead acid battery conventional sensors, saving cabinet space and reducing load-bearing pressure. ### Lead Acid Battery Monitoring System ### Thermal Runaway Prevention To solve the pain point of fire hazards, Gerchamp eliminates potential safety risks through floating charge flow linkage temperature early warning technology, protecting key area equipment. ### Lead Acid Battery Monitoring System Applicable Scenarios ### High-End Data Center Backup Power Data centers require zero-tolerance protection against power outages. In this scenario, the system provides 24h real-time health tracking, ensuring that core servers receive safe DC power backup even when the mains power is abnormal. ### Lead Acid Battery Monitoring System Applicable Scenarios ### Rail Transit Signal and Control Systems Signal and control equipment in rail transit is highly dependent on stable DC power. With high-standard anti-electromagnetic interference certification, the system is ideal for monitoring battery status in complex electromagnetic environments like trains and stations. ### Lead Acid Battery Monitoring System Applicable Scenarios ### Petrochemical Critical Infrastructure The production environment in the petrochemical industry demands extreme fire safety. The system’s thermal runaway warning mechanism identifies aging batteries with fire risks in advance, ensuring the safety of key area equipment and preventing production shutdowns. ### Lead Acid Battery Monitoring System Applicable Scenarios ### Financial and Banking Server Rooms For infrastructure requiring high continuity, the system’s high-precision (±0.1% voltage error) data helps managers accurately locate degraded cells, ensuring the absolute reliability of the backup power array.