Hcgmt® 6000W Enclosed Auto Exchange Workbench Laser Cutting Machine Sheet Metal Fabrication

Our Double-exchange worktable laser cutting machine has many advantages, including high speed, precision, high yield, low cost, and environmental protection. It can achieve high-precision cutting of various profiles, letters, patterns, etc., with a positioning accuracy of ±0.02mm and a cutting accuracy of ±0.05mm. The maximum processing size of the machine can reach 2 meters x 5 meters, and the maximum processing thickness can reach 50mm. The speed of the cutting head can reach 480m/min, and the speed of the feed table can reach 10m/min, which can achieve high-speed, high-precision processing of large-area metal plates.

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.

Double-exchange worktable laser cutting machine in cutting metal plate, the material handling system mainly functions to transport metal plate from fixed worktable to double-exchange worktable, and locate and fix it to ensure the smooth progress of cutting process.

Structure characteristics: The material handling system usually consists of fixed worktable and double-exchange worktable. Fixed worktable is the starting position of metal plate, which can accommodate a certain number of metal plates. Double-exchange worktable is composed of two worktable surfaces, which can alternate loading and unloading to improve production efficiency.

Operation principle: Before metal plate cutting, the material handling system will automatically transport the metal plate from fixed worktable to double-exchange worktable. The operation principle of material handling system is usually driven by motor, using gear, rack and other structures to achieve the movement and positioning of the worktable.

Positioning and fixation: After transporting the metal plate to the double-exchange worktable, the material handling system needs to ensure the accuracy and stability of the metal plate position.Usually, the material handling system is equipped with positioning devices and clamping devices to ensure that the metal plate will not move or tilt during the cutting process.

Automatic control: The material handling system is usually connected to the control system of laser cutting machine and can automatically control the transportation, positioning and fixation of metal plates. The control system can monitor the position and status of metal plates in real time through sensors, and adjust the operating state of the material handling system to ensure the smooth progress of the cutting process.

Safety protection: The material handling system is also equipped with safety protection devices to prevent accidents during the transportation and positioning process of metal plates. For example, when the metal plate is not placed in the correct position, the control system will automatically stop the machine and issue an alarm to ensure the safety of operators.

Numerical Control System (NCS) plays a crucial role in determining the accuracy and efficiency of laser cutting.

Function Introduction: As the "brain" of a laser cutting machine, the NCS is responsible for receiving, processing, and interpreting the instructions entered by the operator and converting them into control commands for various systems and components to achieve high-precision and high-efficiency laser cutting.

Interaction with Operator: The operator inputs instructions into the NCS through input devices such as a keyboard, mouse, or touch screen. These instructions can be parameters such as the shape, size, speed, power, etc. of the cut, and the NCS converts these parameters into comprehensible digital signals.

Control of Cutting Head and Optical System: The NCS controls the trajectory of the cutting head and the output of the laser. Under the command of the NCS, the cutting head moves along a preset path while adjusting parameters such as the power of the laser and the shape and size of the beam to ensure that the laser beam can accurately irradiate the designated position of the metal plate.

Control of Secondary Gas Supply System: The NCS also controls the secondary gas supply system. Based on factors such as the material type, thickness of the cutting metal plate, it adjusts parameters such as the type of gas, pressure, and flow rate. These gases are blown towards the cutting area, helping to blow away the molten metal and protect the cutting area from oxidation and other environmental factors.

Automated Control: The NCS also has an automated control function that can automatically detect the position and status of the metal plate, automatically adjust parameters such as the power of the laser and the focal length of the beam, to ensure the stability and accuracy of the cutting process.

Data Recording and Processing: The NCS can also record various data during the cutting process, such as cutting speed, laser power, gas pressure, etc., and save and analyze these data so that operators can understand the operating status of the equipment and cutting effectiveness, and adjust process parameters in a timely manner.
Optical system: The main function is to focus and guide the laser emitted from the laser source, forming a high-power density laser beam and irradiating it onto the surface of the metal plate.

Laser: The laser is the source of the optical system, which generates the laser beam. Depending on the type and technical parameters of the laser cutting machine, commonly used lasers include carbon dioxide lasers, fiber lasers, etc. The laser converts electrical energy into optical energy through an excitation system to generate a high-energy laser beam.

Focusing system: The focusing system consists of a series of optical elements, including reflectors and focusing lenses. The laser beam is reflected by the reflector and focused by the focusing lens, increasing the energy density of the beam to a higher level so that it can produce melting and cutting effects on the metal plate.

Optical elements: Optical elements include reflectors, focusing lenses, beam splitters, collimators, etc. These elements are combined and arranged to achieve functions such as shaping, focusing, and reflecting the laser beam. The accuracy and cleanliness of these optical elements have a significant impact on the quality of laser cutting.

Laser beam guidance system: The laser beam guidance system is an important component of the optical system. It consists of a series of reflecting mirrors and optical elements that guide the laser beam from the laser source, through focusing and reflection, and ultimately irradiate it onto the surface of the metal plate. The design and precision of the beam guidance system directly affect the trajectory of the laser beam and the cutting quality.

Cutting head: The cutting head is the terminal part of the optical system, which typically contains optical elements such as reflecting mirrors and focusing lenses, as well as auxiliary devices such as gas nozzles. The laser beam is focused and reflected by the cutting head, irradiated onto the surface of the metal plate, and simultaneously high-speed airflow blows away the molten metal to achieve the cutting effect.
Cutting head system: The main responsibility of the cutting head system is to focus the laser beam onto the metal plate and blow away the molten metal with high-speed airflow to achieve high-quality metal plate cutting.

Structural Features: The cutting head system typically consists of a cutting head housing, optical elements, a focusing lens, and a gas nozzle. The cutting head housing serves as the supporting structure for the cutting head and protects the core components such as the optical elements and focusing lens. The optical elements include reflecting mirrors and focusing lenses for focusing and reflecting the laser beam. The focusing lens focuses the laser beam into a narrower beam spot to improve cutting accuracy. The gas nozzle blows high-speed airflow onto the cutting area when the laser beam irradiates onto the metal plate, blowing away the molten metal to prevent the metal melt in the cutting region from adhering.

Working Principle: During laser cutting, the laser beam emitted from the laser source first passes through the optical elements in the cutting head housing, which focuses and reflects the beam. Then, the beam irradiates onto the surface of the metal plate. When the laser beam irradiates onto the metal plate, the metal plate is locally heated and melted, gradually forming a molten pool. At this time, high-speed airflow is blown out from the gas nozzle, blowing away the molten metal and preventing the metal melt in the cutting region from adhering.

Influencing factors: The performance of the cutting head system has a significant impact on laser cutting. On one hand, the accuracy and cleanliness of optical elements and focusing lens directly affect the focusing effect and cutting accuracy of the laser beam. On the other hand, the quality of high-speed airflow also affects the effect of blowing away molten metal and thereby affects cutting quality and efficiency.

Maintenance: To maintain the stability and reliability of the cutting head system, regular maintenance is necessary. For example, regular checks should be conducted on the accuracy and cleanliness of optical elements and focusing lenses, and cleaning or replacement should be carried out promptly; regular checks should be conducted on the unobstructedness and pressure stability of gas nozzles to ensure the quality of high-speed airflow.

Auxiliary gas supply system: The auxiliary gas supply system is mainly responsible for providing gases such as nitrogen or oxygen to the cutting area to assist in the cutting process and improve cutting quality. For example, when cutting stainless steel and other materials, using nitrogen can prevent oxidation reactions and improve cutting quality.

Function introduction: The auxiliary gas supply system provides specific types and flows of gases to the cutting area to improve the laser cutting process. During laser cutting, high-speed airflow can blow away the molten metal and prevent the metal melt from sticking to the cutting area, thereby improving cutting quality and efficiency. At the same time, according to different metal materials and cutting requirements, selecting appropriate types and flows of gases can prevent unfavorable factors such as oxidation reactions and improve cutting quality.

Composition: The auxiliary gas supply system usually consists of gas cylinders, gas control valves, gas pipelines, nozzles, etc. The gas cylinder is a container for storing gases and can provide stable gas pressure. Gas control valves are used to control the flow and pressure of gases and can be adjusted according to cutting requirements. Gas pipelines connect the gas cylinder to the cutting head, enabling gases to be delivered smoothly to the cutting area. Nozzles are terminal components for gas ejection and can spray gases evenly onto the cutting area.

Working principle: During laser cutting, the auxiliary gas supply system delivers specific types and flows of gases from the gas cylinder to the cutting head according to cutting requirements and adjustments made by the gas control valve. Then, the gases are ejected out through the nozzle as high-speed airflow, blowing away the molten metal and preventing the metal melt from sticking to the cutting area. Additionally, the auxiliary gas supply system can also provide protective gases to the cutting area to prevent metal materials from oxidizing and polluting.

Influencing factors: The performance of the auxiliary gas supply system has a significant impact on laser cutting. On one hand, the type and flow of gases directly affect the effectiveness of blowing away the molten metal and preventing oxidation reactions. On the other hand, the unobstructedness and sealing properties of gas pipelines and nozzles also affect the flow and ejection effects of gases.

Maintenance: To maintain the stability and reliability of the auxiliary gas supply system, regular maintenance is necessary. For example, regular checks should be conducted on the gas pressure and sealing properties of gas cylinders, and replacements should be made promptly when needed; regular checks should be conducted on the unobstructedness and sealing properties of gas pipelines and nozzles to ensure the flow and ejection effects of gases.

Control system: Responsible for monitoring and regulating the entire cutting process to ensure accurate and efficient cutting of metal plates.

Function introduction: The control system is mainly responsible for monitoring the position and status of metal plates in real time, as well as parameters such as the power and speed of the laser beam. The control system can collect these parameters through sensors and other equipment, and analyze and process them according to preset programs and algorithms. Then, based on the analysis results, the control system adjusts parameters such as the power of the laser, the focal distance of the beam, and the pressure of the gas to ensure the stability and accuracy of the cutting process.

Composition: The control system usually consists of sensors, controllers, actuators, etc. Sensors are used to monitor the position, status of metal plates, as well as parameters of the laser beam, and convert these parameters into electrical or digital signals to be transmitted to the controller. The controller is the core part of the control system, which analyzes and processes the received signals according to preset programs and algorithms, and outputs control instructions to the actuator. The actuator is the end part of the control system, which adjusts parameters of devices such as the laser, optical path system, and gas supply system according to control instructions.

Working principle: During laser cutting, the control system first monitors the position and status of metal plates through sensors, as well as parameters such as the power and speed of the laser beam. Then, the control system compares the collected parameters with preset standard values, and adjusts parameters such as the power of the laser, the focal distance of the beam, and the pressure of the gas according to the comparison results. For example, if the position of the metal plate is offset, the control system will adjust the power of the laser and the focal distance of the beam to ensure that the laser beam accurately irradiates onto the metal plate. If the metal plate melts too fast, the control system will adjust the pressure and flow rate of the gas to blow away more melted metal.

Influencing factors: The performance of the control system has a significant impact on laser cutting. On one hand, the accuracy and stability of sensors, controllers, and actuators in the control system directly affect the accuracy and stability of regulation. On the other hand, programs and algorithms in the control system are important factors affecting adjustment results. Therefore, for different metal materials and cutting requirements, it is necessary to design appropriate control systems and program algorithms to ensure optimal cutting effects and production efficiency.

Maintenance: To maintain the stability and reliability of the control system, regular maintenance is necessary. For example, regular checks are conducted on sensor accuracy and sensitivity, cleaned and replaced in a timely manner; regular checks are conducted on actuator operation status and accuracy to ensure the accuracy of regulation results.