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 sports stadiums?: Yes, solar energy systems can definitely be used for powering sports stadiums. With their large open spaces and high electricity needs, sports stadiums are ideal candidates for solar installations. Solar panels can be installed on the stadium roof or in nearby open areas to capture sunlight and convert it into electricity. This renewable energy source can help stadiums reduce their reliance on traditional power grids, lower their carbon footprint, and potentially even generate excess energy that can be fed back into the grid.

Q: What is the role of solar-powered water heaters in solar energy systems?: The role of solar-powered water heaters in solar energy systems is to utilize the sun's energy to heat water for various purposes, such as domestic use or in industrial settings. By harnessing the heat from the sun, solar water heaters reduce the dependence on traditional energy sources and contribute to the overall energy efficiency of solar energy systems.

Q: Can solar energy systems be used in powering disaster relief centers or emergency shelters?: Yes, solar energy systems can definitely be used in powering disaster relief centers or emergency shelters. In fact, solar power is increasingly being utilized in such situations due to its numerous benefits. One of the key advantages of solar energy systems is their ability to function independently of the grid. During natural disasters or emergencies, the conventional power grid may be disrupted or completely unavailable. In such situations, solar panels can generate electricity from sunlight, providing a reliable and sustainable source of power for essential operations in relief centers or shelters. Solar energy systems are also highly portable and modular, making them ideal for temporary installations. They can be quickly deployed and set up in disaster-stricken areas, providing immediate power for lighting, communication devices, medical equipment, and other critical needs. Additionally, solar energy systems can be easily expanded or modified to meet the increasing energy demands of relief centers or shelters as the situation evolves. Furthermore, solar power systems have minimal environmental impact compared to traditional fuel-based generators. They produce clean energy without releasing harmful pollutants or greenhouse gases, which is particularly important in disaster-stricken areas where air quality may already be compromised. Lastly, solar energy systems offer long-term cost savings. Once installed, solar panels require minimal maintenance and have a lifespan of 25-30 years. This reduces the reliance on expensive and often scarce fuel supplies, allowing relief centers and emergency shelters to allocate their resources more efficiently. In conclusion, solar energy systems are a reliable, sustainable, and cost-effective solution for powering disaster relief centers or emergency shelters. Their ability to function independently, portability, minimal environmental impact, and long-term cost savings make them an excellent choice for powering critical operations during times of crisis.

Q: What is the difference between a monofacial and bifacial solar panel?: A monofacial solar panel is a conventional type of solar panel that only uses one side of the panel to capture sunlight and convert it into electricity. Photovoltaic (PV) cells on the single side of the panel absorb sunlight and produce electrical current. Monofacial panels are the most commonly used type of solar panels. On the other hand, a bifacial solar panel is designed to capture sunlight from both sides of the panel. It has PV cells on both the front and back sides, allowing it to generate electricity from sunlight that is reflected or scattered onto the back side. This design has an advantage over monofacial panels as it can generate more energy by harnessing light that would otherwise be wasted. The main difference between monofacial and bifacial solar panels lies in their efficiency and energy output. Bifacial panels can produce more electricity per unit area than monofacial panels because they can capture light from both sides. This makes bifacial panels a suitable choice for situations where space is limited and maximizing energy production is crucial. Additionally, bifacial panels can benefit from certain installation configurations that allow light to bounce off the ground or other nearby surfaces onto the backside of the panel, further increasing their energy output. This makes them particularly effective in environments with high levels of ground reflectance, such as snow-covered areas or locations with white rooftops. However, it is important to note that the increased efficiency and energy output of bifacial panels come at a higher cost compared to monofacial panels. Bifacial panels require more complex design and manufacturing processes, which contribute to their higher price. Additionally, the installation of bifacial panels may require specialized mounting systems to ensure proper exposure to both sides of the panel. To summarize, the main difference between monofacial and bifacial solar panels is their ability to capture sunlight. Monofacial panels use only one side of the panel to generate electricity, while bifacial panels utilize both sides, resulting in higher efficiency and energy output. However, the higher cost and specific installation requirements make bifacial panels a more specialized choice compared to the widely used monofacial panels.

Q: Can solar energy systems be integrated into building materials?: Yes, solar energy systems can be integrated into building materials. This is known as building-integrated photovoltaics (BIPV), where solar panels are seamlessly integrated into the design and structure of buildings, such as solar roof tiles or solar windows. BIPV offers the dual benefit of generating renewable energy while fulfilling the aesthetic and functional requirements of the building.

Q: Can solar energy systems be used for powering off-grid communities?: Yes, solar energy systems can definitely be used for powering off-grid communities. They provide a reliable and sustainable source of electricity in remote areas where grid connection is not feasible or economically viable. Solar panels capture sunlight and convert it into electricity, which can be stored in batteries for use during nighttime or cloudy days. This makes solar energy an ideal solution for off-grid communities, as it reduces their dependence on fossil fuels and helps in achieving energy independence.

Q: Are there any financing options available for purchasing solar energy systems?: Yes, there are several financing options available for purchasing solar energy systems. One common option is to take out a solar loan, which allows homeowners to borrow money specifically for the purchase and installation of a solar energy system. These loans typically have low interest rates and flexible repayment terms, making them an affordable option for many homeowners. Another financing option is to lease a solar energy system. With a solar lease, homeowners can have a solar energy system installed on their property without having to pay for the equipment upfront. Instead, they make monthly lease payments to the solar company in exchange for using the solar energy generated by the system. This option is especially popular for homeowners who don't want the responsibility of maintaining and repairing the equipment themselves. Additionally, some states and municipalities offer solar incentives and tax credits to help offset the cost of installing solar energy systems. These incentives can include grants, rebates, or tax credits that reduce the upfront costs of purchasing and installing solar panels. It's important to research what incentives are available in your area, as they can significantly reduce the overall cost of going solar. Finally, some solar companies offer power purchase agreements (PPAs), where homeowners pay for the solar electricity they use at a predetermined rate. This option allows homeowners to benefit from solar energy without any upfront costs, as the solar company owns and maintains the equipment. While PPAs can be a good option for some homeowners, it's crucial to carefully review the terms and conditions before entering into a contract. Overall, there are various financing options available for purchasing solar energy systems, making it more accessible and affordable for homeowners to transition to clean and renewable energy sources.

Q: Can solar energy systems be used for powering outdoor surveillance cameras?: Yes, solar energy systems can definitely be used for powering outdoor surveillance cameras. Solar energy systems consist of solar panels that convert sunlight into electricity, and this electricity can be used to power various devices, including outdoor surveillance cameras. By installing solar panels near the cameras, the captured sunlight can be converted into electrical energy, which can then be stored in batteries or used directly to power the cameras. This eliminates the need for traditional power sources or running electrical wires to remote locations, making it a cost-effective and eco-friendly solution. Additionally, solar energy systems can provide a reliable and continuous power source, even in areas with limited access to electricity, ensuring uninterrupted surveillance capabilities.

Q: Can solar energy systems be used in areas with limited land availability?: Yes, solar energy systems can be used in areas with limited land availability through various innovative solutions. For instance, rooftop solar panels can be installed on buildings, maximizing the use of vertical space. Additionally, solar panels can be integrated into infrastructure like parking lots or highways, making use of unused areas. Moreover, advancements in technology have led to the development of compact and flexible solar panels that can be installed in unconventional spaces. Therefore, even in areas with limited land availability, solar energy systems can still be effectively utilized.

Q: Can a solar energy system be installed on a building with multiple levels?: Yes, a solar energy system can be installed on a building with multiple levels. The installation process may vary depending on the specific layout and structure of the building, but with proper planning and design, solar panels can be successfully installed on roofs, walls, or even as shading structures on multiple levels of a building to generate renewable energy from the sun.

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