Figure 1. When using an experimental modulated toolpath, chip length is selectable.
When turning, the formation of long, stringy chips is undesirable because they can become tangled around the tool and dragged back through the cutting zone, potentially damaging the tool and workpiece. In contrast, short, comma-shaped chips easily fall out of the cutting zone, away from the tool and workpiece. Ensuring chips reliably break is a challenge, especially for ductile workpiece materials. Among the common techniques to combat long, stringy chips are chip breaking geometries and high-pressure coolant.
“Chip breaking geometry” means the rake face of the cutting tool is modified by the addition of a sudden step change in the profile. The step, which may be a separate component clamped in place or an integral part of an insert, causes the chip to bend and break. The chip may break when its free end contacts the tool, the workpiece or the chip itself, or when the bending stress becomes high enough. There are various chip breaking geometries, and substantial effort is spent on selecting a suitable one for a particular application.
“High-pressure coolant” means that a stream of coolant with a pressure of hundreds of atmospheres or more is directed down the tool’s rake face toward the chip. The coolant helps break chips by providing a force that causes the chip to curl, and by providing rapid cooling of the hot chip.
Figure 2. Modulated toolpath in profile turning.
Figure 3. Conditions under which chips break.
Researchers at UNC Charlotte (including the author) and at the U.S. Department of Energy’s Y-12 National Security Complex have recently shown a new way to ensure chip breaking when turning. In NC machines, the toolpath can be modulated along the feed direction to cause interrupted cuts and ensure chip breaking. Although interrupted cuts are usually not desired, that’s not the case here because the interruption is in the material to be removed later and not on the surface of interest. Essentially, a sinusoidal motion is superimposed on top of the nominal toolpath (Figure 2).
Because the oscillating motion is created using the machine axes, the oscillatory motion can follow the workpiece surface and be used for any turned surface geometry, including faces, profiles, tapers, spherical surfaces and internal and external surfaces. The frequency and amplitude of the oscillating motion are selectable parameters, but the frequency of motion required is generally small—on the order of a few cycles per second.
If the amplitude of the oscillation is too small, or if the timing is such that the waviness created on one rotation lines up with the wave created on a previous rotation, then the chip will be continuous and not broken. Figure 3 shows the conditions under which broken chips form.
In Figure 3, the vertical axis is the alignment between the current oscillation and the oscillation one revolution back (imprinted on the surface). Zero corresponds to perfect alignment as does 2π (a little more than 6), while π (a little more than 3) corresponds to a peak aligned with a valley. The horizontal axis is the ratio of the amplitude of the motion to the feed per revolution. The chips break when the amplitude of the oscillation is greater than half of the feed per revolution and when the current and prior oscillations are not well aligned.
Figure 1 shows the surface created by a number of overlapping oscillating tool motions (blue line), and the current motion of the tool (green line). When the green line is above the blue line, the tool is cutting air. When the green line is below the blue line, the tool is cutting metal and forming chips. Chip length and thickness are shown in the lower portion of the figure.
It is interesting that through amplitude selection and oscillation frequency, chip length can even be programmed. Because the oscillation is tangent to the desired surface, the chip breaking waviness appears in material that is later removed. The remaining surface is often quite good, and the oscillating tool motion can even act like a wiper, taking the peaks off of the cusps of the feed marks.
This strategy works in all kinds of materials, from nickel alloys to polymers, and the chips always break. More recent research has focused on testing to ensure programmed amplitudes and frequencies are within machine capabilities and on selecting chip breaking parameters that lead to the finest surface finishes. CTE
About the Author: Dr. Scott Smith is a professor and chair of the Department of Mechanical Engineering at the William States Lee College of Engineering, University of North Carolina at Charlotte, specializing in machine tool structural dynamics. Contact him via e-mail at kssmith@uncc.edu.
Related Glossary Terms
- alloys
alloys
Substances having metallic properties and being composed of two or more chemical elements of which at least one is a metal.
- coolant
coolant
Fluid that reduces temperature buildup at the tool/workpiece interface during machining. Normally takes the form of a liquid such as soluble or chemical mixtures (semisynthetic, synthetic) but can be pressurized air or other gas. Because of water’s ability to absorb great quantities of heat, it is widely used as a coolant and vehicle for various cutting compounds, with the water-to-compound ratio varying with the machining task. See cutting fluid; semisynthetic cutting fluid; soluble-oil cutting fluid; synthetic cutting fluid.
- feed
feed
Rate of change of position of the tool as a whole, relative to the workpiece while cutting.
- numerical control ( NC)
numerical control ( NC)
Any controlled equipment that allows an operator to program its movement by entering a series of coded numbers and symbols. See CNC, computer numerical control; DNC, direct numerical control.
- rake
rake
Angle of inclination between the face of the cutting tool and the workpiece. If the face of the tool lies in a plane through the axis of the workpiece, the tool is said to have a neutral, or zero, rake. If the inclination of the tool face makes the cutting edge more acute than when the rake angle is zero, the rake is positive. If the inclination of the tool face makes the cutting edge less acute or more blunt than when the rake angle is zero, the rake is negative.
- toolpath( cutter path)
toolpath( cutter path)
2-D or 3-D path generated by program code or a CAM system and followed by tool when machining a part.
- turning
turning
Workpiece is held in a chuck, mounted on a face plate or secured between centers and rotated while a cutting tool, normally a single-point tool, is fed into it along its periphery or across its end or face. Takes the form of straight turning (cutting along the periphery of the workpiece); taper turning (creating a taper); step turning (turning different-size diameters on the same work); chamfering (beveling an edge or shoulder); facing (cutting on an end); turning threads (usually external but can be internal); roughing (high-volume metal removal); and finishing (final light cuts). Performed on lathes, turning centers, chucking machines, automatic screw machines and similar machines.
- waviness
waviness
The more widely spaced component of the surface texture. Includes all irregularities spaced more widely than the instrument cutoff setting. See flows; lay; roughness.
- wiper
wiper
Metal-removing edge on the face of a cutter that travels in a plane perpendicular to the axis. It is the edge that sweeps the machined surface. The flat should be as wide as the feed per revolution of the cutter. This allows any given insert to wipe the entire workpiece surface and impart a fine surface finish at a high feed rate.