CY-A50NE
CY TECH
Product Description
Name | Energy Storage Container Air Conditioner |
Model | AC150-2 |
Mounting Method | Semi-embedded Mounting |
Power Supply | 220VAC±15% 50Hz/60Hz |
Cooling capacity | 5000W@L35/35 |
Power capacity | 1850W@L35/35 |
Cooling capacity | 3000W@L35/55 |
Power capacity | 2400W@L35/55 |
Max Noise Level | 65dB(A) |
IP Grade | IP55 |
Heater | 2000W(Optional) |
Net Weight | 53kg |
Refrigerant | R410a |
Dimensions | 1401*562*350(mm) |
Note:@L35/L35 is Internal temperature 35℃, ambient temperature 35℃
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.
Dimension
Installation
Please design and install the product according to the installation holes drawings below
Wiring
No. | Symbol | Definition | No. | Symbol | Definition |
1 | L | AC power-L line | 1 | RS485- | Communication port B- |
2 | N | AC power- N line | 2 | RS485+ | Communication port A+ |
3 | PE | Protective earthing wire | 3 | * | |
4 | * | 4 | ALR-NC | Alarm output-NC | |
5 | * | 5 | ALR-COM | Alarm output-COM | |
6 | ALR-NO | Alarm output-NO |
▶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) | |
CY-A50NA | 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
As the global demand for energy efficiency and sustainability increases, embedded energy storage systems (EESS) are gaining traction. An embedded energy storage air conditioner (EESAC) integrates energy storage directly within the air conditioning system, enhancing its overall functionality and performance. This innovative approach can dramatically reduce energy consumption, lower utility costs, and ensure a more stable and reliable power supply, contributing to both economic and environmental sustainability. The integration of HVAC for energy storage systems and energy storage cooling systems offers a new frontier in energy management.
Battery Types: Common options include lithium-ion, lead-acid, and advanced battery technologies.
Capacity: Ranges from several kilowatt-hours (kWh) to hundreds of kWh, depending on the system size and application.
Types: Options include split systems, central air systems, and portable units.
Efficiency: The units are equipped with high-efficiency compressors, fans, and advanced refrigerants, contributing to overall energy savings.
Smart Controls: Provides real-time monitoring and adjustment of energy use.
Integration: Seamlessly connects with building management systems and smart home technologies for optimized performance.
Power Electronics: Includes inverters, converters, and transformers to manage and convert electricity flow.
Communication: Ensures synchronization between the air conditioning unit and the energy storage system for efficient operation.
Energy Savings: Stores excess energy during off-peak hours for use during peak demand, reducing overall energy consumption.
Backup Power: Provides uninterrupted power during outages, ensuring the air conditioning system remains operational.
Demand Response: Participates in demand response programs to reduce energy consumption during peak periods, earning financial incentives.
Operational Efficiency: Improves HVAC efficiency, ensuring reliable and consistent operation of cooling systems in commercial buildings.
Process Cooling: Offers reliable cooling for industrial processes, ensuring consistent production and quality.
Energy Management: Optimizes energy use in large industrial facilities, reducing operational costs and improving efficiency.
Reduced Consumption: By optimizing stored energy use, EESAC systems or Energy Storage Container Air Conditioning help lower overall energy consumption.
Peak Shaving: Reduces demand during peak hours, leading to lower energy costs and minimizing the strain on the grid.
Lower Utility Bills: EESAC systems os Energy Storage Container Air Conditionings help decrease utility bills through efficient energy use and reduced peak demand charges.
Incentives: These systems may qualify for energy efficiency incentives and rebates from various organizations.
Backup Power: EESAC systems or Energy Storage Container Air Conditionings provide backup power during grid outages, ensuring continuous operation of cooling systems.
Stable Operation: These systems help maintain the stability and reliability of critical HVAC operations, even under fluctuating energy conditions.
Reduced Emissions: By lowering reliance on fossil fuels during peak demand, EESAC systems contribute to reduced greenhouse gas emissions.
Sustainability: Supports the use of renewable energy sources and promotes sustainable energy practices, helping to reduce the overall carbon footprint.
Transmission terminals are critical to the efficient operation of an energy storage cooling system. These include:
Inverters: Convert DC power from batteries to AC power for use in air conditioning units.
Converters: Adjust voltage and current levels to ensure compatibility with the air conditioning system’s requirements.
Transformers: Safely manage the transfer of electricity between different system components.
Communication Modules: Enable real-time data exchange between the energy storage system, air conditioner, and building’s energy management system.
Efficient transportation and installation are key to the successful deployment of EESAC systems (Energy Storage Container Air Conditioning). This process involves:
Logistics Planning: Ensuring timely, cost-effective delivery of components.
Packaging: Protecting sensitive equipment during transit.
Installation: Skilled technicians handle the setup, integrating the system with existing infrastructure for smooth operation.
The integration of embedded energy storage within air conditioning systems represents a major leap in energy efficiency and sustainability. With advanced technologies like industrial precision backpack type air conditioning (AC) units, HVAC for energy storage systems, and energy storage cooling systems, EESAC solutions offer a powerful tool for reducing energy consumption, lowering costs, and improving system reliability. As energy storage technology advances, the role of these systems will continue to grow, playing an essential part in the future of sustainable energy management.
How to order
Choosing the right embedded energy storage air conditioner (EESAC) is a critical decision that impacts energy efficiency, cost savings, and the long-term performance of your HVAC system. To ensure the system meets your needs, it's essential to consider several key factors. Here's a comprehensive guide to help you make an informed decision when selecting the right unit.
The first step is to determine the size of the area that needs cooling. Air conditioners are rated by their cooling capacity, measured in BTUs (British Thermal Units). Ensure that the energy storage cooling system you choose is properly sized for your space to avoid inefficient cooling or overworking the system.
Consider the cooling load, which takes into account factors like insulation, the number of windows, occupancy, and heat-generating appliances. By evaluating these factors, you can determine the capacity required for efficient cooling, ensuring that the HVAC for energy storage systems works optimally.
Lithium-ion: Offers higher energy density, longer cycle life, and better overall efficiency, though it is more expensive.
Lead-acid: A more affordable option but with a shorter lifespan and lower energy density.
Other Technologies: Look into advanced options like flow batteries or solid-state batteries if they align with your specific needs.
Evaluate your energy consumption patterns and peak demand periods. The required storage capacity will depend on factors such as the duration of potential power outages and how much energy you typically use during peak times. Ensure the energy storage cooling system can handle these needs.
The EER and SEER ratings indicate the efficiency of the air conditioner. Higher ratings mean more efficient systems, which can reduce energy consumption and lower operating costs. When evaluating a system, choose one with the best EER and SEER to maximize energy savings.
Air conditioners with inverter technology adjust the compressor speed to maintain the desired temperature. This results in significant energy savings compared to traditional fixed-speed units. An HVAC for energy storage system with inverter technology is essential for improving overall performance and reducing energy waste.
Look for EESAC units equipped with smart thermostats and remote control capabilities. These features allow you to monitor and optimize energy usage through smartphone apps, giving you more control over your cooling needs.
Ensure the system integrates with your existing home automation setup for seamless operation and better energy management. This is particularly useful for managing the cooling needs of a HVAC for energy storage system alongside other smart home systems.
Make sure the system has high-quality inverters, converters, and transformers that efficiently manage electricity flow. These components are vital for ensuring the reliability of the energy storage cooling system.
Advanced communication modules are essential for real-time data exchange and synchronization between the energy storage cooling system, the air conditioner, and the power grid. This allows for more efficient energy management and optimal performance.
Opt for a system that can be professionally installed by certified technicians. Proper installation is key to ensuring optimal performance, safety, and system longevity.
Consider the ease of maintenance and availability of replacement parts. Regular maintenance is crucial for keeping the energy storage cooling system running efficiently and prolonging its lifespan.
Compare the upfront costs of different models. Keep in mind that while higher-efficiency models may come with a higher initial price tag, they can provide significant savings in operating costs over time.
Research available energy efficiency incentives and rebates in your region. These can significantly offset the initial investment, making an energy-efficient HVAC for energy storage system more affordable.
Choose a reputable manufacturer known for producing high-quality, reliable air conditioning systems with integrated energy storage. This ensures your energy storage cooling system will perform optimally and stand the test of time.
Ensure the system comes with a comprehensive warranty and reliable customer support to assist you with any issues that may arise after installation.
Look for units that use eco-friendly refrigerants with low Global Warming Potential (GWP). This is especially important for reducing the environmental impact of your cooling system.
Consider the overall environmental footprint of the system, including the manufacturing process and recyclability of components. Choosing a sustainable system reduces its long-term environmental impact.
Selecting the right embedded energy storage air conditioner (EESAC) involves balancing several key factors, including cooling needs, energy storage requirements, efficiency, smart features, and environmental impact. By carefully evaluating these aspects, you can choose a system that provides reliable, energy-efficient, and sustainable cooling for your space while offering cost savings and reducing your carbon footprint.
Analysis of Reasons:
Power failure or no power.
The cooling set temperature is higher than the container temperature.
System fault.
Solutions:
Check the power supply and electric circuit.
Set the cooling temperature according to the needs.
Contact professional maintenance.
Analysis of Reasons:
The cooling capacity is not matched with the load.
Ambient temperature is too high.
Other system fault.
Solutions:
Add or choose another air conditioner according to the load.
Ensure the machine is used within the correct temperature range.
Contact professional maintenance.
Analysis of Reasons:
The energy storage container temperature is greater than or equal to the cooling set temperature.
Other system fault.
Solutions:
Set the cooling temperature according to needs.
Contact professional maintenance.
