AC160-2
CY TECH
Product Description
Cytech's Energy Storage Thermal Management aloso called energy storage cooling system is actively cooling with compressor, and it will remove the heat inside the cabinet to outside. It also can keep the dust and heat outside the cabinet, avoiding problems from using fan. The inside cabinet can be maintained at an ideal temperature for electrical components which effectively guarantees the stability of the electronic equipment and improves the reliability of the whole system.
◆This series of products can be widely used for outdoor telecom cabinets, battery cabinets,electric cabinets and industry control cabinets etc.
◆The protective level of internal and external circulation is IP55, which can protect cabinet to avoid moisture, dust, water. The air conditioner can also be indoor or outdoor installed.
◆This system is suitable for high/low temperature working conditions of 55 ℃/-40 ℃.
◆Digital temperature controller and high precision of temperature control.
Cooling: the high-pressure refrigerant liquid in the system enters the evaporator and evaporates to absorb heat of the air in the cabinet, so the air is cooled, and the refrigerant that evaporates into gas in the evaporator is inhaled by the compressor and compressed into the high-pressure and high-temperature refrigerant gas, which enters the condenser and cooled to refrigerant liquid, and then re-enters the evaporator to cool the indoor air, and circulates accordingly
Name | Energy Storage Thermal Management |
Model | AC160-2 |
Mounting Method | Semi-embedded Mounting |
Power Supply | 3 phase 380VAC±15% 50Hz |
Cooling capacity | 6000W@L35/35 |
Power capacity | 2220W@L35/35 |
Cooling capacity | 3300W@L35/55 |
Power capacity | 2760W@L35/55 |
Max Noise Level | 65dB(A) |
IP Grade | IP55 |
Heater | 2000W(Optional) |
Net Weight | 80kg |
Refrigerant | R410a |
Dimensions | 1640*672*298(mm) |
Note:@L35/L35 is Internal temperature 35℃, ambient temperature 35℃
Please design and install the product according to the installation holes drawings below
Equipped with a display LED in internal side of product, can display running, alarm information and parameter
No. | Symbol | Definition | No. | Symbol | Definition |
1 | * | 6 | ALR-NC | Alarm output-NC | |
2 | * | 7 | ALR-COM | Alarm output-COM | |
3 | * | 8 | ALR-NO | Alarm output-NO | |
4 | RS485- | Communication port B- | |||
5 | RS485+ | Communication port A+ |
▶It is strictly prohibited to turn the air conditioner upside down or lie flat during transportation or handling.
▶Install vertically and make sure the polarity of wiring is correct and firm.
▶To avoid objects blocking the air circulation at the inlet and outlet of internal and external circulation.
▶If the protective cover is added, the vent area of the cover shall not be less than that of the air conditioner.
Options
Model | Voltage | Cooling capacity (rated)(W) | Power consumption(W) | Heater (W) (option) | Weight(KG) | Noise (dbA) |
1~230V±15%/50Hz | 3000 - 3500 | 1300 | 2000 | 45 | 69dB(A) | |
1~230V±15%/50Hz | 5000 | 1900 | 3000 | 50 | 69dB(A) | |
1~230V±15%/50Hz | 7500 | 2700 | 3000 | 75 | 69dB(A) | |
1~230V±15%/50Hz | 10000 | 3850 | 6000 | 100 | 69dB(A) | |
3~380V±15%/50Hz | 12500 | 4800 | 6000 | 120 | 69dB(A) | |
3~380V±15%/50Hz | 15000 | 5800 | 9000 | 130 | 69dB(A) | |
3~380V±15%/50Hz | 20000 | 7600 | 9000 | 150 | 69dB(A) |
Application
Energy storage systems are a cornerstone of modern energy infrastructure, and effective thermal management for energy storage is essential to ensure performance, safety, and longevity. Advanced thermal management solutions for energy storage system market are being developed to address the unique challenges of various applications, ranging from electric vehicles to grid-scale installations.
In the realm of energy storage, thermal management is about more than just keeping systems cool—it’s about maintaining optimal operating temperatures to enhance energy efficiency and prolong system life. Whether you are deploying an energy storage cooling system for battery packs, supercapacitors, or other storage technologies, precise temperature regulation can prevent degradation and mitigate risks such as thermal runaway.
Battery Pack Efficiency: An effective thermal management for energy storage approach in EVs ensures that lithium-ion batteries maintain their ideal operating temperatures. This not only maximizes performance but also extends battery longevity.
Active Cooling Techniques: The integration of advanced energy storage cooling systems, such as liquid cooling loops, helps prevent overheating during high-power discharge, ensuring both safety and efficiency.
Load Balancing: At grid-scale, thermal management systems are critical. They help maintain stable performance during charge/discharge cycles, which is essential for grid reliability and sustainability.
Adaptive Solutions: The deployment of hybrid active-passive thermal management solutions for energy storage system market enables systems to adapt to fluctuating environmental conditions, ensuring efficiency across diverse climates.
Miniaturized Cooling Solutions: In consumer electronics like smartphones and laptops, micro-scale energy storage cooling systems are integrated using advanced conductive materials and phase change materials (PCMs) to maintain optimal performance and safety.
Compact Integration: Innovations in thermal interface materials facilitate efficient heat dissipation without compromising the compact designs that modern consumer electronics demand.
High-Capacity Systems: Industrial applications, which often involve large-scale battery arrays for backup power or load leveling, require robust thermal management strategies to preserve system performance.
Durability Enhancement: Implementing effective thermal management for energy storage extends the service life of batteries by reducing thermal cycling stress and minimizing maintenance costs.
Phase Change Materials (PCMs): These materials naturally absorb and release heat during phase transitions, providing an efficient buffer against temperature spikes without the need for external energy.
Thermal Insulation: Utilizing high-conductivity materials helps distribute heat evenly, reducing the formation of hotspots and ensuring the longevity of the storage system.
Liquid Cooling Systems: A leading energy storage cooling system, liquid cooling employs circulating coolants to remove excess heat rapidly, especially in dense battery configurations.
Air Cooling Systems: In applications with moderate thermal loads, forced-air cooling provides a cost-effective method for managing system temperatures.
Combining Passive and Active Approaches: Integrating passive methods such as PCMs with active cooling techniques creates a robust thermal management solution for energy storage system market. This synergy is particularly beneficial in environments with variable thermal loads.
The development of cutting-edge thermal management for energy storage is vital for modern applications. Whether enhancing the performance of electric vehicles, ensuring grid reliability, or supporting high-performance consumer electronics, a well-designed energy storage cooling system is key. With ongoing innovations and the integration of intelligent monitoring systems, thermal management solutions for energy storage system market will continue to evolve, pushing the boundaries of efficiency, safety, and durability in energy storage technology.
How to order
Choosing the right embedded energy storage air conditioner (EESAC) involves considering several factors to ensure it meets your specific needs and maximizes efficiency and cost savings. Here’s a comprehensive guide to help you make an informed decision:
◆ Size of the Area:
Determine the size of the area you need to cool. Air conditioners are rated by their cooling capacity, measured in BTUs (British Thermal Units). Ensure the EESAC is appropriately sized for your space.
◆ Cooling Load:
Consider the cooling load, which includes factors like insulation, number of windows, occupancy, and heat-generating appliances. This will help you determine the capacity required for efficient cooling.
◆ Battery Type:
· Lithium-ion: Offers higher energy density and longer cycle life but is more expensive.
· Lead-acid: More affordable but has a shorter lifespan and lower energy density.
· Other Technologies: Explore advanced options like flow batteries or solid-state batteries if they meet your needs.
◆ Storage Capacity:
Assess your energy usage patterns to determine the required storage capacity. Consider the duration of potential power outages and your peak energy consumption periods.
◆ Energy Efficiency Ratio (EER) and Seasonal Energy Efficiency Ratio (SEER)
Higher EER and SEER ratings indicate more efficient air conditioning systems. Look for units with high ratings to reduce energy consumption and costs.
◆ Inverter Technology
Inverter air conditioners adjust the compressor speed to maintain the desired temperature, resulting in significant energy savings compared to traditional fixed-speed units.
◆ Smart Controls
Look for units with smart thermostats and remote control capabilities. These features allow you to monitor and control the system via smartphone apps, optimizing energy usage.
◆ Integration with Home Automation:
Ensure the EESAC can integrate with existing home automation systems for seamless operation and improved energy management.
◆ Power Electronics:
Ensure the EESAC has high-quality inverters, converters, and transformers to manage electricity flow efficiently.
◆ Communication Modules:
Look for advanced communication modules that facilitate real-time data exchange and synchronization between the energy storage system, air conditioner, and the grid.
◆ Professional Installation:
Choose a unit that can be professionally installed by certified technicians to ensure optimal performance and safety.
◆ Maintenance Requirements:
Consider the ease of maintenance and availability of replacement parts. Regular maintenance is crucial for the longevity and efficiency of the system.
◆ Upfront and Operating Costs:
Compare the upfront costs of different units, keeping in mind that higher efficiency models may have higher initial costs but lower operating expenses.
◆ Incentives and Rebates:
Research available incentives and rebates for energy-efficient systems in your region. These can significantly offset the initial investment.
◆ Brand Reliability:
Choose reputable manufacturers known for producing high-quality, reliable air conditioning systems with embedded energy storage.
◆ Warranty and Support:
Ensure the unit comes with a comprehensive warranty and reliable customer support.
◆ Refrigerant Type:
Opt for units using eco-friendly refrigerants with low Global Warming Potential (GWP).
◆ Sustainability:
Consider the overall environmental impact, including the manufacturing process and recyclability of components.
Choosing the right embedded energy storage air conditioner involves balancing your cooling needs, energy storage requirements, efficiency, smart features, and budget. By carefully evaluating these factors and considering the manufacturer's reputation, installation, maintenance, and environmental impact, you can select an EESAC that provides reliable, efficient, and sustainable cooling for your space.
Fault state | Analysis of the reasons | Solutions |
Power on the switch, the energy storage container temperature is too high but the air conditioner is not working. |
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The air conditioner is running but the cooling effect is not good. |
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The machine is stopping suddenly, and the electric system is normal. |
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