Does the structural design of the alloy milling cutter T-type knife enhance the anti-vibration performance during high-speed cutting?
Publish Time: 2025-02-17
The structural design of the alloy milling cutter T-type knife does enhance the anti-vibration performance during high-speed cutting.
1. Optimization of the cutter body structure design
The alloy milling cutter T-type knife has made many optimizations in the cutter body structure design to enhance its anti-vibration performance. For example, the blade installation method of welding-clamping or machine clamping without regrinding makes the connection between the blade and the cutter body more stable, thereby improving the overall rigidity of the cutter. During high-speed cutting, this more rigid tool can better resist the vibration caused by cutting force.
2. Selection of blade shape and material
The blade shape and material selection of the alloy milling cutter T-type knife also have an important impact on the anti-vibration performance. Generally speaking, the blade with a wave-edge design can reduce the cutting force, prevent cutting vibration, and significantly improve the cutting efficiency. In addition, the use of high-performance materials such as cemented carbide also makes the blade have higher hardness and wear resistance, thereby further enhancing the anti-vibration performance of the tool.
3. Optimization of cutting parameters and processes
In the process of high-speed cutting, reasonable cutting parameters and process selection are also key factors in improving the vibration resistance of the tool. For example, selecting appropriate parameters such as cutting speed, feed rate and cutting depth, as well as adopting appropriate cooling and lubrication methods, can effectively reduce vibration and heat accumulation during the cutting process, thereby extending the service life of the tool and improving the processing quality.
4. Design of anti-vibration tool bar
In response to the vibration problem in high-speed cutting, some professional alloy milling cutters T-type knife also adopt the design of anti-vibration tool bar. This tool bar can more effectively absorb and disperse the vibration energy generated during the cutting process by optimizing its structural shape and material selection, thereby further improving the anti-vibration performance of the tool.
In summary, the structural design of the alloy milling cutter T-type knife does enhance the vibration resistance during high-speed cutting. This is mainly reflected in the optimization of the cutter body structure, the selection of blade shape and material, the optimization of cutting parameters and processes, and the design of anti-vibration tool bar. Under the joint action of these optimization measures, the alloy milling cutter T-type knife can better resist vibration during high-speed cutting, improve processing accuracy and surface quality.
