Laser marking
Laser marking is the most important industrial application in which the scanning system converts the laser into an efficient tool. The endless variety of marking applications is due to the scanning system and the high cost-effectiveness achieved through its dynamic performance, accuracy and high speed.
Lasers can mark paper, metal, plastic, and countless other materials. These marks are waterproof, stain resistant, solvent resistant, abrasion resistant, and durable. Laser marking has excellent design flexibility because no molds or templates are required. In addition, there is no contact during processing, so there is no wear.
Micromachining
Micromachining involves highly diverse tasks such as drilling, sculpting, shaping, or cutting, and is often accompanied by challenging accuracy and speed requirements. In this field, laser scanning processing is far superior to other methods in terms of dynamics, accuracy, and processing of complex patterns or structures. The range of materials processed ranges from plastics, glass and ceramics to all kinds of metals.
Even when processing moving workpieces (dynamic), high-performance scanning
Laser welding
Laser welding offers the following advantages via scanning systems:
• Low distortion – limited local energy input to the workpiece, resulting in low thermal and mechanical loads
• Non-contact – comfortable long working distance (up to approx. 1 m) provides great flexibility, even with industrial robots
• Short processing time – fast welding speed, real-time monitoring can increase productivity
These features, combined with high quality and great freedom in designing the tool geometry, greatly enhance the position of scanner laser welding in the connection process widely used in modern industrial production. And it can weld different recyclable materials (such as plastic, metal, and glass) in various thicknesses.
Laser Cutting
As a wear-free cutting tool, lasers quickly gained their place in the field of industrial manufacturing. Combined with the scanning system, they also have absolute advantages in many aspects, such as the cutting machine is highly flexible, the installation and commissioning costs are low, and the processing speed is fast (thus the processing time is short). Unlike traditional mechanical cutting methods, laser cutting machines can also process a wide range of materials-from films and paper to glass and metal.
Paper, cardboard and wood
Cutting applications are characterized by big working area, small light spots, high throughput, and dynamic processing. With a marker cut (half-through), the contour cuts into the upper material without damaging the lower material. The key requirements for packaging production (cartons) are design flexibility and high contour accuracy (to ensure mechanical functionality), as well as rapid processing in large quantities. An important advantage of non-contact cutting in the production of abrasive discs is that the cutting tools do not wear out.
Textiles, fabrics and leather
Optimal flexibility means minimal waste, free-form cutting, and cost-effective production, even for the smallest batches.
Plastics and films
The advantages of laser cutting plastics and films include: no need for fixing materials; clean cutting without post-processing. Of course, there are other success factors such as fast, precise and cost-effective
Glass and ceramics
With the advantages of clean cutting edges, high precision and no wear, it is widely used for cutting glass and ceramics. It can quickly and repeatedly pass through a defined contour with high repetition accuracy, and has no thermal impact on the material. Micro-cutting is usually applied to hardened glass, diamond, sapphire glass (corundum), strengthened glass, and ceramics.
Metal
Similarly, for metal micro-cutting, the laser also becomes a super cutting tool when combined with a scanning system. For example, the processing distortion is small, and ultra-precision parts such as clock hands and gears can be processed.
Research Field
Currently supplies galvanometer motors and drivers to many domestic photoelectric research institutes and universities. Auxiliary role for related scientific research.
