|
Troubleshooting
for Cutting Tools
There is one simple fact about carbide cutting tools —
they eventually fail during use, no matter how high their
quality. The extreme cutting forces and high temperatures
generated by a machining operation take a tremendous toll
on the cutting tool.
The key is to recognize the type of failure so preventive
measures can be taken to maximize productivity and minimize
tooling costs. Oftentimes, more than one type of failure
is the culprit, making it difficult to accurately diagnosis
the cause of the failure. Therefore, a good understanding
of the different types of cutting tool failure is essential.
An incorrect diagnosis may lead to control actions that worsen
the problem instead of improve it.
The eight most common types of cutting tool failure are discussed
below. They are abrasive
flank wear, cratering,
built-up edge, chipping,
thermal cracking, plastic
deformation, notching,
and fracture.
|
|
|
|
Abrasive
Flank Wear
Of all cutting tool failures, abrasive flank wear is the
most desirable and predictable, because it means the insert
simply wore out over a period of time. Abrasive flank
wear is caused by the abrading action of the workpiece against
the cutting edge of the insert. Although this abrasive
action is a normal part of the machining process, it causes
a "wear land" to appear on the flank of the cutting
tool, as shown in the figure above. The degree to which
a wear land develops is directly related to the time of the
cut. As shown in the chart below, there are basically
three "zones" of wear land development.
Zone "A" is referred to as the "break-in"
period and is characterized by rapid flank wear. Zone
"B" makes up the largest part of the cutting tool's
life. In this zone, wear is constant and very predictable.
In Zone "C," the cutting forces and high temperatures
begin to exceed what the cutting tool can withstand. These
extreme conditions accelerate flank wear and ultimately cause
the cutting tool to fail. Therefore, cutting tools should
be indexed at the beginning of Zone "C," before unpredictable
flank wear causes problems with the finish of the workpiece.
|
|
|
 |
|
|
Top
|
|
|
Cratering
The type of failure known as "cratering" is characterized
by a concave wear pattern on the rake surface of an insert,
as shown in the figure. This wear pattern occurs when
small particles of the cutting tool are worn away by the chip
as it passes over the rake surface. If not corrected,
this erosion process will continue until the crater breaks through
to the cutting edge causing complete failure of the insert.
Although elimination of the crater is not always possible, the
growth of the crater can often be controlled so that normal
flank wear preempts a failure caused by the crater.
Suggested Control Actions
- Use TiC or Al 2O3
coated grades. These types of grades have high
hardness values and exhibit excellent crater wear resistance.
- Use TiC-bearing grades. Uncoated grades that
have TiC in their composition also exhibit the same crater
wear resistance as coated grades containing TiC or Al 2O3.
- Use coolant. If coolant is not being used
but is an option, it can sometimes help in the control of
crater failure. The lubricating and heat-reducing
effect of the coolant may suppress the conditions necessary
for crater formation.
- Reduce operating conditions. If the above
suggestions do not control the cratering problem, the operating
conditions may need to be reduced. This will result
in lower productivity and is the least desirable of the
suggested control actions, but reducing the operating conditions
may be the best solution to the cratering problem.
Top
|
|
|
 |
|
|
Built-Up
Edge
The failure mode known as "built-up edge" occurs
when the extreme forces at the point of contact between the
cutting tool and the workpiece weld small particles of the workpiece
to the cutting tool, as illustrated in the figure. This
type of failure is common when machining a soft, malleable workpiece
at slower than recommended cutting speeds. The built-up
edge reduces the efficiency of the cutting tool, which increases
the cutting forces on the insert and often leads to chipping
of the cutting tool.
Suggested Control Actions
- Increase feed rate. If the conditions that
cause the built-up edge condition can be reduced, the built-up
edge can be controlled or eliminated. Increasing the
feed rate (surface feet per minute) reduces the cutting
time and, consequently, reduces the opportunity for any
welding action to form a built-up edge. This solution
may also increase productivity and improve the surface finish
of the workpiece.
- Use coolant. Many types of coolant interfere
with any welding action by "contaminating" the
surfaces of the workpiece and the cutting tool. Since
welding requires a clean surface, the residue of the used
coolant on the workpiece and the cutting tool helps prevent
the formation of a weld.
- Remove coolant. If coolant is being used
in the operation, it may be cooling the cutting edge to
a temperature suitable for the welding action can take place.
Removing the coolant will increase the temperature of the
cutting edge, reducing the likelihood that workpiece materials
can weld to the cutting edge.
- Use an insert with a positive rake angle.
Cutting tools with positive rake angles help reduce the
cutting forces necessary for the built-up edge to form.
- Use TiC or Al2O3
coated grades. These types of grades have anti-welding
characteristics and higher hardness values that help to
impede the formation of a built-up edge.
Top
|
|
|
 |
|
|
Chipping
The failure mechanism called "chipping" occurs
when small pieces of the carbide insert are chipped away from
the cutting edge during the machining process, as shown in the
figure. Eventually, increased cutting forces at the chipped
cutting edge cause the cutting edge to become inefficient, leading
quickly to catastrophic failure. Chipping may not always
be obvious. Some chipping occurs microscopically, the
appearance of which may be confused with normal flank wear unless
examined closely. Chipping can result from a variety of
conditions poor rigidity in the tooling set-up, weak cutting
edge, deflecting workpiece, inadequate machine tool, varying
cutting loads.
Suggested Control Actions
- Minimize deflections. Deflection can originate
in the tooling set-up, the workpiece, chucking or fixturing
of the machine tool, or in the tool blocks, tail stock,
live centers, carriages, cross slides, and rests.
Any such deflection causes varying cutting loads on the
insert that can lead to chipping. To minimize deflections,
check the machine tool for excessive clearance in the spindle
bearings and the gibs, check the toolholder or boring bar
for excessive overhang and secure clamping, and use large
boring bars with low length-to-diameter ratios.
- Increase edge preparation on inserts. The
cutting edge of an insert is honed to increase its strength.
Honing helps evenly distribute the cutting forces along
the cutting edge, thereby making it stronger. The
amount of hone required depends on the cutting forces to
be encountered during the machining process. Greater
shock loads require heavier hones. Although most cutting
tools are purchased with honed cutting edges, a heavier
hone or a "T"-land may be required in extreme
applications.
- Use an insert with a stronger geometry. Negative
rake inserts are stronger than positive rake inserts and
are capable of handling greater shock loads. If negative
rake inserts aren't available, use positive rake inserts
with smaller relief angles. Also, inserts with large
nose radii are stronger than inserts with small nose radii.
- Use a tougher carbide grade. If deflections
have been minimized and cutting edges have been honed and
chipping still occurs, it may be necessary to change to
a more shock-resistant carbide grade with a higher cobalt
content. However, the feed rate will probably have
to be reduced to avoid other types of failure, which will
decrease productivity. This solution should be the
last alternative chosen.
Top
|
|
|
 |
|
|
Thermal/Mechanical
Failure
Thermal/mechanical failure appears on the cutting tool as
cracks that are generally perpendicular to the cutting edge,
as seen in the figure. This type of failure is usually
caused by the inability of the cutting tool to withstand the
extreme temperature variations of interrupted cutting operations.
The heat produced in such machining operations tends to remain
at the cutting edge instead of being transferred to the rest
of the insert, because carbide is a poor conductor of heat.
This causes extreme thermal stress on the overheated cutting
edge causing it to crack.
Suggested Control Actions
- Use coolant correctly or don't use it at all.
If coolant is applied intermittently or in insufficient
volume, the thermal cracking problem will be worsened.
If coolants cannot be applied correctly, the operation should
be performed without coolant at reduced speed, feed, and
depth of cut.
- Use a stronger carbide grade. Stronger grades
of carbide with higher cobalt content have greater tolerance
to extreme temperature changes. Grades with TaC also
possess heat-resistant characteristics.
Top
|
|
|
 |
|
|
Plastic
Deformation
The type of failure known as "plastic deformation"
occurs when the carbide at the cutting edge is softened by the
high temperatures produced during machining operations.
The softened carbide is deformed from its original shape by
the cutting forces, as shown in the figure. When a cutting
edge appears to have developed a large wear land after a very
short time, plastic deformation should be suspected.
Suggested Control Actions
- Use coolant. The use of coolant to reduce
the temperature of the insert at the cutting edge will prevent
plastic deformation by allowing the cutting tool to maintain
its hardness and better withstand the cutting forces.
- Reduce operating conditions. The reduction
in feed, speed, or depth of cut will reduce the heat and
cutting forces generated at the cutting edge. This
will result in lower productivity and is the least desirable
of the suggested control actions, but reducing the operating
conditions will correct the problem.
- Use a more wear-resistant grade. Carbide
grades that are wear-resistant also resist plastic deformation.
These grades generally have lower cobalt content and higher
hardness values and may contain TiC or TaC.
Top
|
|
|
 |
|
|
Notching
The failure mechanism called "notching" appears
as a severe "notch-shaped" abrasive wear pattern that
is localized at the depth-of-cut line, as illustrated in the
figure. Notching generally occurs during the machining
of high temperature alloys and work-hardened materials, where
"scale" material on the surface of the workpiece is
very hard and causes accelerated abrasive wear on the insert
at the depth-of-cut line.
Suggested Control Actions
- Use tooling that provides a large cutting edge angle
to the workpiece. The large cutting edge angle
distributes the cut over a larger section of the insert,
which weakens the chip and reduces the abrasive effect on
the insert's cutting edge.
- Increase the hone at the depth-of-cut line area of
the cutting edge. A stronger edge at the depth-of-cut
line achieved by additional honing will improve the insert's
resistance to the abrasive action of the scale on the workpiece.
- Reduce the feed rate. If the application
of a larger cutting edge angle does not solve the problem,
a reduction in feed rate may be necessary to eliminate notching.
However, this will decrease productivity and should only
be used if other attempted solutions fail.
Top
|
|
|
 |
|
|
Fracturing
"Fracturing" occurs when the cutting forces exceed
the strength of the insert's cutting edge causing catastrophic
removal of a large piece of the cutting tool, as shown in the
figure. Several circumstances can cause fracturing, including
excessive flank wear land, shock loading during interrupted
cutting operations, improper carbide grade selection, and improper
insert size selection. Fracturing may result in injury
to the operator, the inability to use the remaining unused cutting
edges of the insert, and damage to the workpiece, toolholder,
or machine tool.
Suggested Control Actions
- Index the insert before the wear land reaches its end-point.
Fracturing will occur when the wear land reaches its end-point,
or the point at which it can wear no more. Therefore,
the insert should be indexed before this occurs.
- Use a tougher carbide grade. Carbide grades
with higher cobalt content are generally tougher and more
resistant to the shock loads that can cause fracturing.
- Use an insert of appropriate size. If fracturing
occurs, the insert is not able to withstand the cutting
forces of the machining operation. A larger or thicker
insert will absorb more shock forces.
- Use an insert with a stronger geometry. Negative
rake inserts are stronger than positive rake inserts and
are capable of handling greater shock loads. Also,
inserts with large nose radii are stronger than inserts
with small nose radii.
- Use honed inserts. The cutting edge of an
insert is honed to increase its strength. Honing helps
evenly distribute the cutting forces along the cutting edge,
thereby making it stronger. The amount of hone required
depends on the cutting forces to be encountered during the
machining process. Greater shock loads require heavier
hones. Although most cutting tools are purchased with
honed cutting edges, a heavier hone may be required in extreme
applications.
- Reduce operating conditions. The reduction
in feed, speed, or depth of cut will reduce the cutting
forces generated at the cutting edge. This will result
in lower productivity and is the least desirable of the
suggested control actions, but reducing the operating conditions
may be the only solution..
- Use a toolholder with better support. If
an insert does not have sufficient support in the toolholder,
it may fracture. A toolholder with proper support
must be used or even the best inserts will fracture.
Top
|
|
|
 |
|
|
