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DLY-6000W-AD5-B
Laser Chiller > Fiber Laser Chiller > DLY-6000W-AD5-B
Application Range: Suitable for a 6000W fiber laser, cooling capacity of 17000W.
Features and Functions:
High-quality refrigeration components with fan speed control and electronic expansion valve energy regulation, achieving temperature control accuracy of ±0.5°C to ±1.0°C.
Equipped with RS485 communication function for remote monitoring via PC.
Includes dual protections for high/low temperature and high/low pressure, with intelligent anti-freeze protection.
Features flow display function with adjustable flow alarm values as per customer requirements.
Dual water temperature design: Automatic constant temperature function with two different set temperatures to meet varied demands. Dual signal output protection ensures one water temperature meets the cooling needs of the laser, while the other aligns with ambient temperature for laser output cooling.
Double water filter protection: Equipped with pure water and deionized water filters for enhanced equipment safety. Also includes conductivity detection device and signal output, with adjustable conductivity alarm values to effectively protect the laser.
These features highlight the capabilities of the DLY-6000W-AD5-B chiller, ensuring efficient cooling and comprehensive protection for 6000W fiber lasers in industrial applications.
A 6000W fiber laser refers to a high-power laser system used predominantly in industrial applications such as cutting, welding, marking, and engraving. Here are some key aspects and applications related to 6000W fiber lasers:
Power Output: A 6000W fiber laser emits laser beams with a power output of 6000 watts. This high power enables faster and more efficient processing of materials compared to lower-power lasers.
Applications:
Cutting: Capable of cutting through thick metal sheets (e.g., steel, aluminum) with high precision and speed, making them ideal for industries like automotive, aerospace, and manufacturing.
Welding: Used for welding various metals, offering deep penetration and high welding speeds, suitable for applications requiring strong, precise joints.
Marking and Engraving: Provides precise marking and engraving on a wide range of materials, including metals, plastics, ceramics, and composites, often used for product branding, serialization, and decorative purposes.
Advantages:
Speed and Efficiency: Processes materials faster due to higher power output, increasing production throughput.
Precision: Maintains high cutting and welding precision, achieving intricate designs and tight tolerances.
Versatility: Handles a variety of materials and thicknesses, offering flexibility across different industrial applications.
Challenges:
Heat Management: Generates significant heat during operation, requiring effective cooling systems like dedicated laser chillers to maintain optimal performance and extend the laser's lifespan.
Maintenance: Regular maintenance is crucial to ensure consistent performance and longevity, including cleaning optics and checking alignment.
Industrial Use Cases:
Automotive: Used for cutting and welding automotive components such as chassis, body panels, and exhaust systems.
Aerospace: Critical for manufacturing aircraft parts, including engine components and structural elements.
Metal Fabrication: Applied in various metalworking processes for fabrication and assembly.
Overall, 6000W fiber lasers represent a powerful tool in modern industrial manufacturing, offering superior performance in terms of speed, precision, and versatility across a wide range of applications.
A 6000W fiber laser chiller is a specialized cooling system designed to manage the heat generated by a fiber laser with a power output of 6000 watts. Here are the key aspects and considerations related to a chiller for such high-power fiber lasers:
Cooling Capacity: The chiller must have sufficient cooling capacity to dissipate the heat produced by a 6000W fiber laser effectively. Typically, the cooling capacity of the chiller should be higher than the laser's heat output to maintain stable operating temperatures.
Temperature Control: Precise temperature control is essential to ensure the fiber laser operates within optimal temperature ranges. The chiller should offer temperature control accuracy, usually specified in degrees Celsius (e.g., ±0.5°C to ±1.0°C), to prevent overheating and ensure consistent laser performance.
Refrigeration System: It includes components such as compressors, evaporators, condensers, and pumps to circulate and cool the coolant (often water or a water-glycol mixture) that absorbs heat from the laser system.
Safety Features: Chiller units for high-power fiber lasers typically incorporate safety features such as high/low-temperature alarms, high/low-pressure protections, and anti-freeze mechanisms to safeguard the laser and maintain operational reliability.
Efficiency: Energy-efficient operation is crucial to minimize operating costs. Some chillers may feature variable speed fans, energy-saving modes, and optimized refrigeration cycles to achieve efficiency while meeting cooling requirements.
Remote Monitoring and Control: Advanced models may include communication interfaces like RS485 for remote monitoring and control. This allows operators to monitor temperature levels, adjust settings, and receive alerts remotely, ensuring proactive maintenance and troubleshooting.
Water Filtration and Quality: To protect the laser optics and maintain system reliability, chillers often incorporate water filtration systems such as particle filters, carbon filters, and possibly deionization units to ensure the coolant remains clean and free of contaminants.
In summary, a 6000W fiber laser chiller plays a critical role in maintaining optimal operating conditions for high-power laser systems, ensuring performance reliability, longevity, and efficiency in industrial applications such as cutting, welding, and marking.