SKD11 Industrial Cutting Blade Long Thin Slitting For Cutting Metal Plate
Description:
Industrial cutting blades have a wide range of primary applications across various industries and sectors, including:
1,Electronics and Electrical Industry:
- Used to cut PCB circuit boards, flexible circuits, thin-film electronic components, etc.
- Applicable for manufacturing and repair of electronic products such as smartphones, computers, and home appliances.
2,Optical and Photonics Industry:
- Used to cut optical glass, optical films, and thin-film coatings.
- Widely used in the production of display panels, optical lenses, optical fibers, and other optical products.
3,Packaging Industry:
- Used to cut various flexible packaging materials, such as plastic films, aluminum foils, and paper.
- Applied in the production of packaging for food, medical, and consumer goods.
4,Textile and Apparel Industry:
- Used to cut textile fabrics, leather, and other fibrous materials.
- Meets the cutting requirements for garments, home textiles, and automotive upholstery.
5,Automotive Manufacturing:
- Used to cut automotive interior and exterior trim materials, seat fabrics, carpets, etc.
- Satisfies the cutting needs in the automotive manufacturing and assembly processes.
6,General Industrial Manufacturing:
- Used to cut a variety of industrial raw materials, such as metal sheets, rubber, and plastics.
- Widely applied in various stages of industrial processing and fabrication.
Industrial Blade Specifications:
| Product name | Industrial Cutting Blade Long Thin Slitting |
| Material | SKD11 |
| Hardness | HRC56-92 |
| Precision | ±30 Micron |
| Length | 1490mm |
| Width | 50mm |
| Thickness | 2mm |
| Applicable Industries | Manufacturing Plant |
The manufacturing process of industrial cutting blades exhibits the following key characteristics:
1,Material Selection:
- Tungsten carbide (cemented carbide) is the primary material choice, offering excellent hardness, wear resistance, and toughness.
- Specialty applications may also utilize high-speed steel, ceramic, and other hard material compositions.
2,Shaping Techniques:
- Powder metallurgy is a common manufacturing method, where carbide and metal powders are pressed and sintered to shape.
- Additional mechanical processing, such as hot forging and cold rolling, may be employed to further enhance the blade properties.
3,Surface Treatment:
- The blades are often coated with wear-resistant thin films through chemical or physical vapor deposition techniques, such as TiN or AlTiN.
- The coatings significantly improve the wear resistance and service life of the cutting blades.
4,Geometric Design:
- The blade shape is optimized for specific applications, with parameters like taper angle and edge geometry carefully designed.
- Precise geometric features contribute to improved cutting efficiency and precision.
5,Finishing Processes:
- Final steps include precise grinding and polishing to ensure a smooth and sharp cutting edge.
- Stress-relief heat treatment may also be performed to enhance the impact resistance of the blades.
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