The goal of tool engagement controlled milling is to achieve the highest possible productivity. This requires gaining complete control of the cutting environment in order to cut optimally everywhere along the toolpath. To cut optimally means to create chips with the optimal geometry for the particular tool being used and the particular material being cut. This requires controlling the feedrate, spindle speed, depth-of-cut and the tool’s engagement with the material.

That is, the highest material removal rate (MRR) can only be achieved when the feedrate is held at its optimal value, the spindle speed is held at its optimal value, the depth-of-cut is held at its optimal value and the tool’s engagement with the material is held at its optimal value (creating the optimal chip).

  With tool engagement controlled milling, a machinist only has to know how to optimally perform a side cut with constant stepover, constant feedrate, constant spindle speed and constant depth-of-cut. With this information, a tool engagement controlled CAM system can then create a toolpath, for any part geometry, that cuts everywhere as if it were cutting a simple side cut. This allows for extremely high MRR everywhere along the toolpath, greatly reducing machining time. Cutting chips optimally also greatly increases tool life, greatly reduces the amount of heat created, reduces part warpage, maintains a constant load on the tool, increases dimensional accuracy and entirely eliminates chattering.

 Depth-of-Cut
Whereas HSM might use a depth-of-cut of about 0.2 times the diameter of the tool, tool engagement controlled milling can use a depth of cut of 1.5 to 2.0 (or more) times the diameter of the tool. This increase in depth-of-cut allows for far fewer passes to get to the total depth-of-cut, greatly decreasing the time it takes to machine a part. With HSM, only the tip of the tool is cutting. This causes the tip to overheat and wear out rapidly. With tool engagement controlled milling, much more of the flute is used. This allows the load, heat and wear to be spread out evenly over a much larger area of the tool—resulting in much longer tool life.

 Chip Geometry Control
Some might have you believe that controlling the material removal rate (sometimes called constant volume milling) achieves the highest possible productivity. This is not true. Controlling the chip geometry, especially the chip thickness, is required to achieve the highest productivity. This can only be accomplished by controlling the tool’s engagement with the material. A toolpath that controls the tool’s engagement with the material and uses a constant feedrate, constant spindle speed and constant depth-of-cut, will by definition have a constant material removal rate. More importantly, it will have a constant chip geometry (including constant chip thickness). This is the key to optimal cutting and high productivity.

 Toolpath
In a constant volume scheme without controlled tool engagement, the feedrate must be reduced when the tool encounters a corner, which creates too thin a chip and too much heat. This is especially true for harder materials such as P20 and titanium. This extra heat causes rapid tool wear, which must be overcome by reducing the material removal rate. This problem does not occur with tool engagement controlled milling.
A toolpath that controls the tool engagement will look very different from a contour parallel or direction parallel toolpath. Taking advantage of today’s readily available computing power, it is possible to create a toolpath for which most of the toolpath does not resemble the final shape that is ultimately cut. The entire toolpath is planned in advance such that at no place in the toolpath will the tool engagement exceed the user’s specified value.
A high-end CNC machine is not required to take advantage of tool engagement controlled milling. By reducing the load on the tool, the load on the CNC machine also is reduced and older machines immediately show an increase in productivity.
A tool engagement controlled toolpath allows for consistent cutting everywhere. There are no high pitched squeals as the tool enters a corner. There is no need to attempt to continuously adjust the feedrate or the depth-of-cut. There is no need to have an operator standing by to hit the stop button should something go wrong. There is just smooth, continuous cutting with long tool life. This is ideal for lights-out operation.

  Benefits
The productivity benefit from controlling the tool engagement, and thereby controlling the entire chip geometry, is remarkable. Hard-to-machine materials can only be cut well under a narrow range of chip producing conditions. When the entire chip geometry is controlled, a hard-to-machine material becomes easy to machine. With materials such as P20 and titanium, productivity results in excess of two times have been reported by many customers with a simultaneous doubling of the tool life. With soft materials there also is a significant increase in productivity due to the increased depth-of-cut in conjunction with a large controlled tool engagement angle.                           

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