EV Charger Power Router
1. Centralized Energy Management:
The Power Router acts as the brain of the system, dynamically managing energy distribution between the solar panels, battery storage, electric vehicle (EV) chargers, transformer, and the distribution box.
Ensures that energy is routed efficiently based on availability (solar generation, battery charge, and grid power) and demand (EV charging, building load, etc.).
2. Seamless EV Charging Integration:
The EV Charger Station is directly connected to the power router, ensuring that the EVs are charged using the most cost-effective energy available (solar or stored energy).
Supports fast charging and optimizes charging times to align with solar energy production or off-peak grid hours.
3. Renewable Energy Source Integration:
The Solar System (Photovoltaic or PV) collects solar energy, which is then converted into DC electricity. The power router directs the energy from the solar system to be used directly, stored in the battery container, or fed into the grid.
Maximizes the use of renewable solar energy, reducing reliance on traditional energy sources and lowering carbon footprint.
4. Energy Storage with Battery Container:
The Battery Container stores excess solar energy or grid power for later use, ensuring a stable supply of electricity even when the sun is not shining or during peak demand.
The power router controls the charge and discharge cycles of the battery to optimize energy storage and minimize wear on the battery over time.
5. Smart Energy Distribution through Distribution Box:
The Distribution Box splits and directs energy to different loads, including the building, EV chargers, or other connected equipment.
Contains breakers, fuses, and safety controls to manage electrical faults, overloads, and short circuits.
Ensures safe, reliable power delivery to all connected devices, balancing energy usage across multiple applications.
6. Energy Optimization and Load Management:
The power router intelligently manages loads, prioritizing energy use based on real-time conditions (e.g., solar production, battery level).
It ensures that renewable energy is used first, followed by stored energy and lastly, grid power when necessary, ensuring sustainability and reducing energy costs.
7. Backup Power and Reliability:
The Battery Container acts as a backup power source in the event of a grid outage, keeping essential services running or ensuring that EVs remain charged.
Provides uninterrupted power to critical loads even during power interruptions, improving system reliability.
| Rated Power | 630kW | 1200kW |
| Number of Vehicle Charging Gun | 3~15 | 6~30 |
| Output Voltage | DC200-1500V | |
| Maximum Output Current | 250A(Forced Air Cooling) / 600A(Liquid Cooling) | |
| Vehicle Charging Gun Length | 5/6/10m | |
| Frequency Range | 50 Hz | |
| Phase Line | 3F+PE | |
| Accuracy | 0.5 level | |
| Communication Methods | RS-485, Eehernet, WiFi | |
| Power Allocation | Equal Distribution/Dual Vehicle Charging Gun | |
| BMS Auxiliary Source | DC12V/24V | |
| Installation Method | Mobile hoisting | |
| Protection Grade | IP54 | |
| Photovoltaic DC bus connection | ||
| DC bus connection of energy storage batteries | ||
| AC power supply 380V AV/50Hz optional output | ||
