Hcgmt® 6000W Laser Beam Cutting Sheet Metal Equipment Manufacturer Cutter Machinery Supplier

Nanjing Jitermai Intelligent Equipment Co., Ltd. was established on July 7, 2023 (the head office was established on December 8, 2016). It is located in Lishui District, Nanjing City, with superior geographical location and convenient transportation. 25 km drive. We focus on the R&D, manufacturing and sales of intelligent mechanical equipment, and have a strong R&D team and a number of patented technologies.

With our professional technical team and in-depth understanding of the industry, we continue to develop products that meet market needs. Our advantageous products include flexible intelligent bending center, ultra-large-format high-power laser cutting machine, large-scale laser cutting machine, single-table laser pipe cutting machine, electro-hydraulic servo CNC bending machine, and pure electric single-axis and double-axis bending machine. These devices adopt advanced scientific research technology, high precision, fast speed, energy saving and environmental protection, which can greatly improve production efficiency and meet various large-scale production needs.

Jitermai Intelligent Equipment Co., Ltd. always adheres to market-oriented, technology-driven, quality as life, and service as guarantee. We are committed to providing the best quality equipment and services to help customers improve production efficiency, reduce costs and create greater value.

Our goal is to build Jidemei into a world-leading supplier of intelligent equipment, through technological innovation and service upgrades, to continuously meet customer needs and create greater value for customers.

Nanjing Jitemai Intelligent Equipment Co., Ltd. creates an industry benchmark for intelligent equipment with professionalism and quality.
 

The numerical control laser cutting machine adopts high-precision CNC machine tools and computer control systems, which can achieve high-precision two-dimensional cutting, while having faster cutting speed and higher cutting accuracy.

The working process of the laser cutting machine is as follows:

Input Graphic: The graphic to be cut is input into the computer in the form of CAD or CAM software. This step can be achieved by manually drawing or importing existing CAD files. When inputting graphics, it is necessary to ensure the accuracy and precision of the graphics for the subsequent cutting process to proceed smoothly.

Computer-Aided Design (CAD/CAM): Using specific software on a computer to design, layout, and optimize the input graphics. This step needs to consider the size, shape, thickness of the material, as well as the shape and size of the required cutting. CAD/CAM software helps us edit, modify, and improve graphics to meet the needs and cutting requirements of different customers.

In CAD/CAM software, operations such as graphic drawing, modification, deletion, rotation, scaling can be performed, and graphic layout and optimization can also be carried out to ensure cutting efficiency and accuracy. In addition, CAD/CAM software can provide three-dimensional modeling functions that can better showcase product appearance and structure, helping clients better understand products.

After completing the CAD/CAM design, cutting path data can be output and transmitted to the numerical control laser cutting machine for cutting operations. Therefore, the precision and accuracy of CAD/CAM software will directly affect the cutting quality and accuracy. Therefore, when using CAD/CAM software for design, carefulness and precision are necessary to ensure good cutting results.

Optical path adjustment is a crucial step that involves adjusting the path and parameters of the laser beam according to the designed graphics to ensure that the laser beam can accurately illuminate the desired cutting position. The steps include:

Adjusting the laser power: Laser power is one of the important factors affecting the cutting effect. To ensure that the laser beam can accurately cut the material, the laser power needs to be adjusted according to the graphic design and material properties. The adjustment of laser power can be achieved by changing the current or voltage of the laser.

Adjusting the spot size and shape: The spot is the light spot on the surface of the material generated by the laser beam, and its size and shape also have an important impact on the cutting effect. To enable the laser beam to accurately illuminate the desired cutting position, the spot size and shape need to be adjusted. Typically, the spot size and shape can be adjusted through optical components such as lenses and mirrors.

Adjusting the focal length and focus position of the lens: The focal length and focus position of the lens have an important impact on the focusing effect of the laser beam and the cutting accuracy. To ensure that the laser beam can accurately focus on the desired cutting position, adjustments need to be made to the focal length and focus position. Typically, the focal length and focus position can be adjusted by rotating the adjustment ring on the lens.

During optical path adjustment, care and caution are required to ensure that each parameter adjustment is accurate. At the same time, necessary testing and verification need to be conducted to ensure that the laser beam can accurately illuminate the desired cutting position. Generally, optical path adjustment needs to be performed by professional technicians or experienced operators to ensure stable and accurate cutting results.

Trial cutting is an important step before formal cutting with a numerical control laser cutting machine. Its purpose is to check the accuracy and speed of the cutting to ensure that they meet the requirements. Trial cutting can reveal potential problems and areas for improvement, providing a reference and basis for the formal cutting process.

During the trial cutting process, a test piece is typically selected that is made of the same or similar material to the formal cutting material. This allows for a better evaluation of the cutting effectiveness and adaptability. During the trial cutting process, technical personnel can adjust parameters such as the cutting head position and height, laser power, and cutting speed to optimize the cutting effect.

The steps of trial cutting include the following:

Selecting a test piece: Select a test piece made of the same or similar material to the formal cutting material to conduct the test. This allows for a better evaluation of the cutting effectiveness and adaptability.

Adjusting parameters: Based on the material attributes of the test piece and the graphic design, adjust parameters such as the position and height of the cutting head, laser power, and cutting speed. These parameter adjustments can be made through the operating panel or CAD/CAM software.

Trial cutting process: Start the numerical control laser cutting machine and conduct trial cutting along preset paths. During the trial cutting process, observe the quality and effectiveness of the cutting, including the smoothness of the edges, the roughness of the cut surface, and the presence of any thermal impact areas.

Result evaluation: After the trial cutting is completed, evaluate the cutting effectiveness. Measure the size and shape of the test piece and compare it with the CAD design to evaluate the cutting accuracy and quality. Additionally, inspect the quality of the cutting edges, such as the presence of burrs or melt residue.

Parameter adjustment: Based on the results of the trial cutting, make adjustments to the parameters. If the accuracy and quality of the cutting do not meet the requirements, adjust parameters such as the optical path and other parameters to optimize the cutting effectiveness. For example, adjust the laser power, cutting speed, and position and height of the cutting head.

Repeat trial cutting: After adjusting the parameters, conduct another trial cutting to verify the adjustment results and feasibility. If the accuracy and quality of the cutting meet the requirements, proceed to the formal cutting stage.

Trial cutting is an iterative process that may require multiple trial cuts and parameter adjustments to achieve ideal cutting effectiveness. During this process, patience and professional guidance from technical personnel are required to ensure stable cutting quality and accuracy.

Formal cutting is the process of using a numerical control laser cutting machine to start the formal cutting process after trial cutting and parameter adjustment. During the formal cutting process, the numerical control system automatically controls the laser beam to move according to the pre-designed path, while tracking the movement of the material to ensure that the laser beam can accurately cut out the desired shape and size.

The process of formal cutting includes the following steps:

Preparation: Before starting the formal cutting process, it is necessary to check the cutting area to ensure that there are no obstacles or impurities. At the same time, the material needs to be placed in the correct position and the size and thickness of the material need to be confirmed to ensure that they meet the requirements.

Parameter Setting: Based on the results of the trial cutting and the material properties, set the parameters such as laser power, cutting speed, and so on. These parameter settings can be done through the operation panel or CAD/CAM software. In addition, the cutting path and program need to be set to ensure that the laser beam can move along the preset path.

Start Cutting: Start the numerical control laser cutting machine, and the laser beam automatically moves under the control of the numerical control system while tracking the movement of the material. During the cutting process, the laser beam irradiates the surface of the material, forming a molten and vaporized area to achieve cutting.

Real-time Monitoring: During the cutting process, the numerical control system monitors in real time the relative position between the laser beam and the material to ensure the accuracy and precision of the cutting. If any errors or problems are detected, the system will automatically adjust and correct them.

Cutting Completion: When the cutting is completed, the equipment will automatically stop running and give a prompt sound or signal. At this time, the operator can inspect and measure the cut parts to confirm whether the cutting quality and accuracy meet the requirements.

Formal cutting is a high-precision and high-efficiency process that requires ensuring that each parameter setting and adjustment is accurate and correct. At the same time, operators need to have rich experience and skills to handle unexpected situations and meet the requirements of different material attributes.

Cooling system is usually equipped with numerical control laser cutting machine to ensure that the laser can maintain stable performance during the cutting process. The cooling system is to effectively reduce the temperature of the laser, thereby avoiding cutting errors caused by temperature fluctuations.

Working principle of cooling system: Cooling system usually adopts water cooling or air cooling way to cool. Water-cooled cooling system uses circulating water to carry away the heat generated by the laser and release it to the outside through a radiator. Air-cooled cooling system uses a fan to blow cold air onto the laser and release the heat to the outside through a heat sink.

System composition: The cooling system usually consists of a radiator, a water pump or fan, a water tank or filter, and a temperature sensor.

Radiator and water pump or fan: The radiator and water pump or fan are the core components of the water-cooled cooling system. The water pump withdraws water from the water tank and flows through the laser, carrying away the heat generated by the laser. The radiator releases the heat to the outside and keeps the water temperature within a certain range. In an air-cooled cooling system, a fan is used to blow cold air onto the laser and release the heat through a heat sink.

Water tank and filter: In a water-cooled cooling system, the water tank is used to store circulating water, and the filter is used to filter impurities in the water to keep the water clean and prevent blockage of the radiator.

Temperature sensor: The temperature sensor is used to monitor the temperature of the laser, and feedback the temperature signal to the control system. The control system adjusts the power of the laser or the operating state of the cooling system according to the temperature signal, thereby maintaining the temperature stability of the laser.

The cooling system plays a crucial role in a numerical control laser cutting machine. It can effectively reduce the temperature of the laser, avoid cutting errors caused by temperature fluctuations, and thereby ensure the stability and accuracy of the cutting process.

To meet the needs of different customers, numerical control laser cutting machines typically have a variety of different cutting modes and functions, such as rotation cutting, sway cutting, multi-axis linkage, etc. These functions can be personalized and customized according to customer needs to meet various cutting requirements of different shapes and structures.

Rotation cutting is a common cutting mode that can create circular or elliptical cutting areas on the material. By controlling the rotation speed of the laser beam and the movement speed of the material, circular or elliptical cutting areas of different sizes and shapes can be formed on the material. This cutting mode is suitable for cutting circular or elliptical parts, such as gears, bearings, etc.

Sway cutting is also a common cutting mode. By controlling the angle and amplitude of the laser beam's oscillation on the material surface, different shapes can be cut. For example, by controlling the left-right oscillation angle and amplitude of the laser beam on the material surface, rectangular, trapezoidal, triangular, etc. different shapes can be cut. This cutting mode is suitable for parts that require cutting into different shapes, such as brackets, guides, etc.

Multi-axis linkage is an advanced cutting mode. By controlling the movement of the laser beam on multiple axes on the material surface, complex graphics and structures can be cut. For example, by controlling the movement of the laser beam on the X, Y, and Z axes, three-dimensional structures can be cut. This cutting mode is suitable for parts that require cutting into complex graphics and structures, such as automotive components, aerospace components, etc.

In terms of efficient production with automation production lines, numerical control laser cutting machines can be integrated with other equipment such as robots and conveyor belts to achieve automated and efficient cutting production. Through the cooperation of automation production lines, production efficiency can be greatly improved, labor costs can be reduced, and product quality and consistency can be guaranteed. For example, robots can automatically place materials in the cutting area, and conveyor belts can automatically transport cut parts to the next process, achieving continuous automated production and improving production efficiency and quality.