Categories
2D laser cutting include high precision, fast cutting speeds, versatility in cutting a wide range of materials, minimal material wastage, and the ability to create intricate and complex designs. However, it is important to note that the maximum material thickness that can be effectively cut depends on the power and type of laser used.
3D laser cutting offers several advantages, including precise and intricate cutting of complex geometries, the ability to work on a variety of materials, minimal material wastage, and high automation potential with computer-controlled systems. 3D laser cutting depends on the size, geometry, and material properties of the object being cut.
Extreme laser cutting machines find applications in various industries, including heavy-duty manufacturing, shipbuilding, oil and gas, construction, and automotive sectors. They enable efficient cutting of thick metals, alloys, and other challenging materials, contributing to faster production times and higher productivity.
Fiber laser automation systems for loading offer numerous benefits, including increased productivity, reduced labor costs, improved material handling efficiency, and enhanced overall process reliability. These systems are commonly used in industries such as automotive, aerospace, metal fabrication, and manufacturing.
Press Brake
Nukon Press Brakes machines are used in a wide range of industries where precision bending and forming of sheet metal components are required. These machines offer efficient and reliable solutions for various bending applications, contributing to the manufacturing of high-quality metal products.
Plasma and waterjet cutting machines have their advantages and are chosen based on the specific requirements of the application. Plasma cutting is favored for its speed and cost-effectiveness. Waterjet cutting, on the other hand, offers versatility and high precision, making it suitable for a wide range of materials and applications.
Our Production Principles
Improvement of Laser Technologies
Laser Cutting Technologies: Development of more efficient, faster, and precise systems for laser cutting and welding processes. Laser Processing Efficiency: Implementation of new control systems and software enhancements to enhance the efficiency of laser processing procedures. Laser Material Interaction: Research aimed at better understanding the interaction of laser beams with materials and optimizing this interaction for improved outcomes.
Product Development and Design
Laser Machine Design: Designing laser machines that are more compact, energy-efficient, and user-friendly. Automation and Robotics Applications: Enhancing the integration of laser technologies with automation and robotic systems. Advanced Material Processing Applications: Developing specialized laser processing solutions for specific materials.
Material and Application Research
Exploration of New Materials: Researching suitable new materials for laser processing. Industrial Applications: Discovering new applications of laser technologies in industries such as automotive, metal processing, medicine, defense, and others. Environmental and Energy Efficiency: Developing solutions to reduce the environmental impact of laser processing processes and enhance energy efficiency.