Vires Energy
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| DC Parameters | |||
|---|---|---|---|
| Battery Type | LFP | Operating Voltage Range | 600V ~ 876V |
| Combination Mode | 1P240S | Cooling Mode | Liquid cooling |
| Rated Capacity | 314Ah | Coolant | Ethylene glycol solution (50% V) |
| Rated Energy | 241kWh | Cycle Number | 6000 |
| Rated Voltage | 768V | Fire Protection System | Perfluorohexanone + Aerosol + Water fire suppression |
| Rated Power | 105kW | Detector Type | Temperature, smoke, CO |
| Rated Charge/Discharge C-rate | 0.5P | ||
| AC Parameters | |||
|---|---|---|---|
| Rated Output Power | 241kW | ||
| AC Overload Capability | 115.5kW (System capacity details: 46.592kWh) | ||
| Wiring Method | Three-phase, four-wire | ||
| Allowed Grid Voltage | 380V (-20% ~ +15%) | ||
| Allowed Grid Frequency | 50Hz/60Hz ± 2.5Hz | ||
| Total Harmonic Distortion (THD) | ≤ 3% (at full load) | ||
| Power Factor | -0.99 / -1 ~ 1 | ||
| DC Component in Current | ≤ 0.5% | ||
| Charge/Discharge Conversion Time | < 100ms | ||
| Maximum Conversion Efficiency | ≥ 98% | ||
| System Parameters | |||
|---|---|---|---|
| Operating Environment | -20°C to 50°C (de-rated operation above 45°C) | ||
| Noise Level | ≤ 75dB | ||
| Dimensions | 1000 * 1300 * 2500mm | ||
| Weight | ~2.6 tons | ||
| Water Resistance Rating | Battery compartment: IP65, Electrical compartment: IP54 | ||
| Allowed Relative Humidity | 0-95% (non-condensing) | ||
| Maximum Altitude | ≤ 2000m (de-rating above 2000m) | ||
| Communication Interface | CAN, Ethernet | ||
| Communication Protocol | Modbus TCP/RTU | ||
| System Operation Mode | Peak shaving, demand control, reactive power adjustment, grid scheduling interface, remote dispatch, local data storage, anti-backflow feature | ||
| Certification Standard | GB/T36276-2018, IEC62619 (Product layout fit dimensions: 790*1145*245mm) | ||
Our energy storage modules are continuously developed and optimized:
Cloud Remote Operation and Maintenance: The management system monitors local device data and evaluates operation status to dynamically allocate output power to each energy storage device. It coordinates power flow between multiple units, optimizes operating modes, and ensures maximum system efficiency and output benefits.
7x24 hours cloud-based real-time monitoring. Analyzes battery pack consistency, uses predictive algorithms to flag potential risks, and sends warnings to guarantee overall safety.
Provides real-time visibility into peak/valley power, load patterns, and returns. Enables optimized strategies like peak load shifting, load tracking, demand control, and emergency dispatch.
Features dynamic 3D scenarios, mapping of multiple project sites, and streamlined graphical controls for straightforward parameter monitoring and operational tracking.
System capacity & performance optimizations based on verified core technologies.
Advanced Battery Management System (BMS) testing, validation, and layout research.
Tailored system designs customized to align with distinct operational scenarios.
Pre-installed containerized platforms (combining battery modules and PV inputs) minimize onsite deployment time and lower installation and commissioning expenses.
Features intelligent temperature cooling to run efficiently at ambient environments up to 45°C (IP54 rated). Average round-trip efficiency (RTE) shows a 3% performance improvement over standard models. Relies on stable LiFePO4 cells.
Modular cabinet designs support adaptable project sizing ranging from 100kWh up to 5MWh. Integrates smoothly with off-grid and on-grid setups, supporting parallel configuration of up to 4 units.
Reduces utility bills by 30% to 70% utilizing valley-peak shaving, solar self-consumption, and microgrid setups. Lowers maintenance via automated remote error alerts.
Multi-layered security protocols featuring active fire protection, pack-level immersion fire containment, strict thermal isolation, and certification standards (UN38.3, IEC).
Equipped with fully automated production lines for air and liquid-cooled systems. Backed by cloud intelligence optimization algorithms and adaptive load dispatch rules.
Energy Storage Capacity: 300kW / 600kWh
Application Purpose: Peak shaving, valley filling, and off-grid emergency backup power support.
Energy Storage Capacity: 1.05MW / 2.15MWh
Application Purpose: Utility bill management via peak shifting and high-reliability local backup power.
Energy Storage Capacity: 300kW / 600kWh
Application Purpose: Peak load shifting, electric bill savings, and off-grid operational backup.
Energy Storage: 630kW / 1.29MWh
Purpose: Peak-valley balancing and off-grid utility backup.
Energy Storage: 300kW / 600kWh
Purpose: Demand charge management, peak-shaving, and backup capability.
Founded in 2015, we are a national high-tech enterprise specializing in the design, development, manufacturing, and sales of new energy storage products. We have built an experienced R&D and technical team focused on energy storage integration.
Our manufacturing factory operates automated air-cooled battery pack assembly lines alongside liquid-cooled battery pack production lines to deliver standard and customized GWh-scale products for utility-scale setups, microgrids, and factory energy storage cabinets.
We run dedicated automated production tracks optimized to meet customizable engineering specifications for air-cooled and liquid-cooled cabinet models.
Our lines utilize automated handling systems and high-precision welding systems. This workflow is built to fulfill robust specifications for industrial integrations, commercial cabinets, and heavy-duty grid energy containers.
Highly efficient and stable capacity is our core foundation. The factory is equipped with automated packing setups capable of supporting GWh-level energy storage projects.
Strict inspection rules and testing systems monitor every phase. We utilize advanced assembly methods to ensure overall module stability and long-term lifespan.
By using automated production loops and managing a flexible raw material supply chain, we respond dynamically to demand fluctuations and ensure timely product delivery.
