CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System

CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System System 1

CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System System 2

CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System System 3

CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System System 4

CATL Cell Industry Commercial 372kWh LiFePO4 Battery Liquid Cooling Energy Storage System

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Loading Port:: Stock in Panama

Payment Terms:: TT OR LC

Min Order Qty:: 50 set

Supply Capability:: 10000 set/month

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Specification

Application:

Industrial

Output Voltage (V):

51.2v

Work Time (h):

100 hours and longer

Liquid cooled high voltage LFP BATTERY ENERGY STORAGE SYSTEM

SDC-ESS-R1228V2752kWh It is a LFP battery container designed for high-capacity energy storage systems, mainly used in large-scale renewable energy generation consumption, power grid peak regulation and frequency regulation, emergency backup, delayed distribution network upgrade, distributed generation and microgrid systems. Modular design, strong scalability, can meet the power and energy needs of different user scenarios. The battery module has a rated voltage of 1228V and a rated capacity of 280Ah。

Product features

High Security：The use of LFP material system, with high safety, long life, stable and reliable characteristics; The protection level of the battery module is IP65 or above, which can effectively prevent condensation and salt spray erosion.

High Performance Liquid-cooling Technology：Adopt intelligent temperature control and balanced design, single PACK temperature difference ≤ 3 °C.

Multi-dimensional Fire Protection Design：Equipped with cell level, PACK level, cabin class three-level fire protection design, equipped with temperature sensitivity, combustible gas detection and other detection sensors, water fire, cabin gas fire and PACK level gas fire compatible design, flexible selection.

uStandardized Modules：The standardized module design is adopted, which is highly extensible and can meet the power and energy requirements of different scenarios. All components are pre-installed in the factory, saving onsite installation and commissioning workload and meeting the overall marine transportation

Q: Can solar energy systems be used for powering research laboratories or scientific facilities?: Yes, solar energy systems can definitely be used for powering research laboratories or scientific facilities. Solar power can provide a reliable and sustainable source of electricity to meet the energy needs of these facilities. It can help reduce their carbon footprint, lower energy costs, and provide a more secure and independent energy source. Additionally, advancements in solar technology and energy storage systems have made it possible to generate and store enough power to meet the high energy demands of research laboratories and scientific facilities.

Q: Can a solar energy system store excess energy for later use?: Yes, a solar energy system can store excess energy for later use. This is achieved through the use of batteries or other storage technologies. When a solar energy system generates more electricity than is needed in real-time, the excess energy can be stored in batteries. These batteries can then be used to power the system during periods of low solar generation, such as at night or during cloudy days. By storing excess energy, solar energy systems can provide a more reliable and continuous power supply, reducing the dependence on the grid and increasing self-consumption of renewable energy.

Q: Can solar energy systems be used for powering remote sensing or surveillance equipment?: Yes, solar energy systems can be used for powering remote sensing or surveillance equipment. Solar panels can be installed to capture sunlight and convert it into electricity, which can then be used to power the equipment. This allows for a reliable and sustainable source of energy in remote locations where traditional power sources may be limited or unavailable. Additionally, solar energy systems are often low maintenance and can be easily deployed, making them an ideal choice for powering remote sensing or surveillance equipment.

Q: Can solar energy systems be used to heat water?: Yes, solar energy systems can be used to heat water. Solar thermal systems, also known as solar water heaters, utilize the sun's energy to heat water for various purposes such as domestic use, swimming pools, or industrial applications. These systems absorb sunlight through solar collectors and transfer the heat to water, providing an efficient and sustainable way to heat water using solar power.

Q: What is the warranty period for solar energy systems?: The warranty period for solar energy systems typically varies depending on the manufacturer, but it is commonly between 10 to 25 years.

Q: Are there any disadvantages to installing a solar energy system?: Yes, there are a few disadvantages to installing a solar energy system. Some of the main drawbacks include the high upfront cost of installation, the need for sufficient sunlight to generate optimal power, and the requirement for ample space to accommodate the solar panels. Additionally, solar energy systems can be less efficient during cloudy or rainy periods, and their production may not align with peak energy demands. Finally, the maintenance and occasional replacement of components can be costly and time-consuming. Despite these disadvantages, the long-term benefits and environmental advantages of solar energy make it an increasingly popular and viable option for many households and businesses.

Q: Can a solar energy system be used in areas with high levels of air pollution?: Yes, a solar energy system can still be used in areas with high levels of air pollution. While air pollution may affect the efficiency of the solar panels to some extent, they can still generate electricity. However, it is important to regularly clean and maintain the panels to ensure optimal performance. Additionally, investing in advanced air filtration systems can help mitigate the impact of air pollution on the solar energy system.

Q: Can solar energy be used in cloudy climates?: Yes, solar energy can still be used in cloudy climates, although the efficiency may be reduced. Solar panels can still generate electricity even with limited sunlight, although the output will be lower compared to sunny conditions. Additionally, advancements in solar technology and the use of tracking systems can help optimize energy production in cloudy environments.

Q: Can solar energy systems be used for powering food processing or packaging plants?: Food processing or packaging plants can utilize solar energy systems to power their operations. These systems, like photovoltaic panels, generate electricity from sunlight. This electricity can then be used to operate machinery and processes in these plants. To function effectively, food processing and packaging plants require a significant amount of energy for various purposes, such as lighting, refrigeration, and machinery. By adopting solar energy, these plants can reduce their reliance on fossil fuels and decrease their carbon footprint. Installing solar energy systems on rooftops or nearby open spaces is possible for food processing or packaging plants. The energy produced by these systems can be used immediately or stored in batteries for later use. Additionally, surplus energy can be sold back to the power grid, creating an extra source of income. Although the initial cost of setting up solar energy systems can be high, the long-term advantages outweigh the expenses. Solar energy is a renewable and clean power source that decreases dependence on non-renewable resources and minimizes greenhouse gas emissions. Moreover, solar energy systems can be combined with energy-efficient technologies like LED lighting, energy management systems, and heat recovery systems to further enhance the overall efficiency of food processing or packaging plants. In conclusion, solar energy systems are a viable and sustainable option for powering food processing or packaging plants. They offer numerous benefits, including reduced operational costs, lower environmental impact, and increased energy independence.

Q: How does solar energy storage work?: Solar energy storage works by capturing and storing the energy produced by solar panels during periods of sunlight. This stored energy can then be used during times when sunlight is not available, such as during the night or on cloudy days. Typically, solar energy storage systems use batteries to store the excess energy generated by the solar panels. These batteries store the energy in the form of chemical potential, which can be converted back into electricity when needed. This allows for a continuous and reliable supply of solar energy, even when the sun is not shining.

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