What are the advantages of Multi-line cutting fluid in adapting to complex tool geometries?
Publish Time: 2024-11-18
In the field of modern metalworking, complex tool geometries are increasingly widely used, and Multi-line cutting fluid plays a vital role in this, showing many unique adaptability advantages.
Multi-line cutting fluid has excellent lubrication performance. For tools with complex geometries, such as tools with spiral grooves, multiple cutting edges or special curved surfaces, the friction conditions at various parts during the cutting process are complex. Multi-line cutting fluid can form a stable and effective lubricating film at the contact point between the tool and the workpiece. In key areas such as the cutting edge and corners of complex tools, this lubricating film can significantly reduce friction and reduce tool wear. For example, when cutting with a spiral groove tool, the cutting fluid can be evenly distributed along the groove, so that the tool can still maintain a good lubrication state during high-speed rotation cutting, thereby ensuring smooth cutting.
Its good cooling performance is also a major advantage. When cutting complex tools, due to the special geometry, heat tends to accumulate in certain local areas. Multi-line cutting fluid can quickly take away this heat to prevent problems such as reduced hardness and deformation of the tool due to overheating. Especially for tools with fine geometric structures, such as micro-complex tools, accurate temperature control is essential. Multi-line cutting fluid can effectively cool all parts of the tool, maintain the geometric accuracy of the tool, and ensure processing quality.
In addition, Multi-line cutting fluid also has excellent chip removal capabilities. The chip shape and discharge path generated by complex tools during cutting vary depending on the tool geometry. Multi-line cutting fluid can smoothly remove chips from the tool surface and processing area. For tools with complex chip removal channels, it can help disperse and carry chips, avoid chips from accumulating in the special geometry of the tool, thereby reducing secondary damage to the tool cutting edge by chips, extending the tool life, and also improving processing efficiency and quality.