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50.68kWh/230.4V
Product Description
Some Parameters
Battery Type: Lithium Iron Phosphate (LFP)
Standard charging/discharging current:110A
Operating temperature:-10~50°C
Component Parts
This product mainly consists of three battery packs, a battery housing, four main communication lines, positive and negative connection harnesses and a power distribution unit. The three batteries are connected by the main communication line and the positive and negative connection harnesses, which together store the transmission current.
Application Scenarios
①Separately configured energy storage: saving electricity costs for enterprises through peak-shaving and valley-filling or as a backup power source, mainly used in factories and shopping malls, etc.
②Integration of light storage and charging: Building integrated light storage and charging power station on limited land, using roof and parking lot canopy photovoltaic, configuring energy storage system to achieve "self-generation and self-consumption, surplus storage", effectively alleviating the impact of charging pile load on the grid.
③Microgrid + energy storage: Microgrid is regarded as a controllable unit in the grid, which reacts in seconds to meet the demand of external transmission and distribution network, and can meet the energy needs of a piece of electric load gathering area, such as: islands, distant residential areas and industrial parks, etc. If a microgrid is established in a load concentration area and the energy storage system is used to store power, the storage system can supply power to the load smoothly when there is a short-time power outage. For off-grid microgrids, energy storage can smooth new energy generation and be used as backup power; for grid-connected microgrids, the main role of energy storage is to achieve energy optimization and energy saving.
Precautions
Safety: Ensure proper safety measures are in place during installation, operation, and maintenance to prevent any electrical hazards or risks to personnel.
Voltage Compatibility: Verify that the electrical infrastructure and equipment are compatible with the system's voltage level of 230.4V to prevent damage or malfunction.
Capacity Planning: Plan energy usage and storage needs carefully to optimize the system's 50.68kWh capacity for maximum efficiency and cost savings.
Cooling and Ventilation: Adequate cooling and ventilation are essential to prevent overheating and maintain optimal performance and lifespan of the storage system.
Maintenance Schedule: Establish a regular maintenance schedule to ensure the system's components, including batteries and electronics, are functioning properly and to extend the system's operational life.
Load Management: Implement effective load management strategies to balance energy demand and supply, avoiding excessive discharge or charge cycles that could impact battery lifespan.
Monitoring and Control: Utilize advanced monitoring and control systems to track system performance, detect anomalies, and optimize energy usage based on real-time data.
Emergency Preparedness: Develop contingency plans for power outages or system failures, including backup power sources or alternative energy solutions to maintain critical operations.
Environmental Considerations: Dispose of old batteries and components in an environmentally responsible manner and explore options for recycling or repurposing components.
Regulations and Codes: Adhere to relevant local regulations, codes, and standards pertaining to energy storage systems, electrical safety, and environmental impact.
Lifecycle Costs: Factor in maintenance, replacement, and disposal costs over the system's lifecycle to ensure long-term economic viability.
Integration: Ensure seamless integration with existing energy infrastructure, renewable energy sources, and grid connections to maximize the benefits of the energy storage system.
User Training: Provide training to personnel responsible for operating and maintaining the system to ensure its optimal and safe use.
Performance Monitoring: Regularly analyze system performance data to identify trends, make necessary adjustments, and continuously improve system efficiency.
By considering these points, you can effectively deploy and manage the described energy storage system in a safe, efficient, and sustainable manner.
