In CNC milling center, vibration may occur due to the limitations of cutting tools, tool holders, machine tools, workpieces, or fixtures. To reduce vibration, some strategies need to be considered.
1. Cutting tool
For face milling, the direction of the cutting force must be considered:
- When using a 90° milling cutter, the cutting force is mainly concentrated in the radial direction. In long overhang conditions, this can cause the milling cutter to sway; however, when milling thin-walled/vibration-sensitive parts, low axial forces are advantageous.
- 45° milling cutter can generate evenly distributed axial force and radial force.
- Round blade milling cutters direct most of the force upwards along the spindle, especially when the depth of cut is small. In addition, the 10° milling cutter transmits the main cutting force to the spindle, thereby reducing vibration caused by long tool overhangs.
Choose the smallest possible diameter for the process.
DC should be 20-50% greater than ae.
Choose sparse tooth and/or unequal pitch milling cutter.
Lightweight milling cutter bits are advantageous, such as carbide end mills with aluminum alloy body.
For unstable thin-walled workpieces, use large entering angle = small axial cutting force; for long tool overhang conditions, use small entering angle = high axial cutting force.
The modular tool holder system can be used to assemble tools of the required length while maintaining high stability and minimum runout.
1)Keep the tool assembly as high as possible rigidity and as short as possible.
2)Choose the largest possible post diameter/size.
3) Use adaptors that are suitable for oversized milling cutters and avoid reducing diameter adaptors.
4) For small size end mill, if possible, use tapered adaptors.
5) In the process where the last pass is in the deep part of the part, use the extended tool at the predetermined position. Adjust cutting parameters according to each tool length.
6) If the spindle speed exceeds 20000 rpm, use a dynamically balanced cutting tool and an oversize milling cutter with a tool holder, and be sure to use the shortest possible tool length and gradually increase the length.
3. Damping milling cutter
If the overhang is greater than 4 times the tool diameter, the milling vibration trend may become more obvious, and the damping milling cutter can significantly increase productivity.
4. Cutting edge
To reduce cutting force:
1) Choose light-load geometry-L with sharp cutting edge and thin coating material
2) Use a blade with a small arc radius and a small parallel cutting edge
Sometimes, the vibration tendency can be reduced by adding more damping to the system. Use a cutting edge geometry with a larger negative rake angle and a slightly worn cutting edge.
5. Cutting parameters and tool path programming
1) Be sure to position the milling cutter off-center relative to the milling surface.
2) For KAPR 90° long edge milling cutters or end mills, use small radial depth of cut (maximum ae = 25%×DC) and large axial depth of cut (maximum ap = 100%×De).
3) When face milling, use small depth of cut ap and high feed fz and round inserts or high feed milling cutters with small entering angle.
4) Avoid vibration in the corners by programming a large arc pass, see inner corner milling.
5) If the chip thickness becomes too thin, the cutting edge will scratch instead of cutting, resulting in vibration. In this case, the feed per tooth should be increased.
6. Machine tools
The condition of the machine tool may have a greater impact on the milling vibration trend. Excessive wear of the spindle bearing or feed mechanism will result in poor machining performance. Carefully choose the machining strategy and cutting force direction to take full advantage of the stability of the machine tool.
Every machine tool spindle has unstable areas that are prone to vibration. The stable cutting area is described by the stability graph and increases with the increase of speed. Even a speed increase as low as 50 rpm can change the cutting process from an unstable state of vibration to a stable state.
7. Workpiece and its fixture
When milling thin-walled/base parts and/or when the fixture rigidity is poor, consider the following points:
1) The fixture should be close to the machine table.
2) Optimize the tool path and feed direction towards the position with the highest machine tool/fixture strength to obtain the most stable cutting conditions.
3) Avoid machining along the direction where the workpiece is not fully supported.
4) When the rigidity of the fixture and/or workpiece in a particular direction is poor, up-milling can reduce the tendency of vibration.