The 3D laser cutting machine is a perfect combination of six axis industrial robots and high-precision laser systems, paired with a specially designed lightweight 3D anti-collision cutting head. It can cut the spatial curve trajectory of various irregular 3D workpieces and add multiple additional axes to achieve seven axis and eight axis linkage. The overall structure is designed according to ergonomics, meeting the needs of small and medium-sized batches and diversified flexible processing in industries such as locomotive manufacturing and helmets, and strongly promoting the upgrading of industrial intelligent manufacturing.
Strong adaptability to materials, able to adapt to cutting and processing of various irregular workpieces;
High production efficiency, which can replace traditional manufacturing processes such as trimming and punching molds;
High economic efficiency, significantly reducing the research and development cycle of new products, and seizing market opportunities;
High cutting accuracy, smooth and burr free cutting surface, meeting the manufacturing accuracy requirements of the locomotive industry;
The operation is simple and fast, with a rich process database embedded, which can be called or modified with one click;
Stable and reliable performance, efficient and energy-saving, low maintenance costs, and long service life;
Strong scalability, can increase external axes for linkage or collaborative processing, and shorten cutting time;
Green and environmentally friendly processing, no production of cattle pollutants, no consumables, and high yield rate;
Main technical parameters:
|Laser cutting light source||High performance anti high reflection fiber laser|
|Repetitive positioning accuracy||± 0.03mm|
|Cutting wall thickness||0.5-10mm (depending on material)|
|Cutting speed||≤ 12m/min|
|Cutting aperture||≥ 3mm|
|Path accuracy||± 0.12mm|
|Scope of Work||2200 * 1800 * 200mm (cutting width is related to the shape and height of the workpiece)|
|Effective radius of robot||1853mm|
|Worktable load||≤ 25kg (at the center of the flange)|
|source||Three phase five wire system AC380V 50HZ|
|Protection level of main power supply||IP54|
Note: 1. The above parameters are based on FANUC-M20iB, and the configuration and parameters of each model are subject to the technical solution provided by our company; 2. This equipment is not suitable for cutting metal waste and solid cylindrical workpieces; 3. Although the processed workpiece belongs to the same specification variety, there may be differences in processing performance and quality due to differences in actual processing parts, surface conditions, material composition, or processing shapes.
Widely used for cutting edges and holes in various sheet metal stretching parts and covering parts; 3D arc cutting and hole position cutting of various hardware shaped pipe fittings. It is an aluminum alloy frame, baby bike frame, new energy electric vehicle, electric tricycle, beach bike, motorcycle industry, fitness equipment flat tube and other irregular three-dimensional metal parts, composite materials such as glass fiber, carbon fiber, Kevlar, and some plastic cutting holes, edges, and arc cutting tools.
Real shot case:
Ordering Guide :
Laser power (W)
|laser cutting||one thousand and five hundred||MA: M-20iA/20M||U formal attire||L2: L-type biaxial displacement|
|two thousand||MB: M-20iB/25||D Inversion||L1: L-type single axis displacement|
|three thousand||MD: M-20iD/25||H1: Horizontal single axis displacement|
|six thousand||MG: MOTOMAN-GP25||VT: Vertical rotation displacement|
|U1: U-shaped box displacement|
|W1: one-dimensional displacement workpiece movement|
|R1: one-dimensional displacement robot movement|
|** Other customization|
1. High precision six axis industrial robot:
Robots can be selected based on process requirements such as workpiece size and cutting accuracy requirements. The following robots can be perfectly matched with PLC systems, offline mapping software, displacement machines, and protective rooms.
2. Robot installation method:
A. Robot inversion: paired with a gantry frame to expand processing space, very suitable for flexible processing of large and ultra long workpieces; B. Robot formal attire: can be paired with a multi-station workbench, with a small footprint and flexible posture, suitable for cutting small workpieces.
3. Customized fixture:
Different types of linkage or collaborative displacement machines, sky rails or ground rails, and supporting fixtures can be developed based on the processed workpiece to achieve precise and efficient cutting of irregular workpieces of different materials, shapes, and sizes.
4. Offline programming map:
Equipped with a manual teaching device as standard, it can directly generate, edit, and transfer processing programs without programming; Alternatively, a 3D offline simulation system can be installed for direct digital and analog import, generating cutting paths with one click, shortening the preparation time before processing, and easily adjusting to the optimal cutting state.