Cutting Tools
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Transcript of Cutting Tools
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TECH 3113 Manufacturing Tooling
Nageswara Rao Posinasetti
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3. Cutting Tool Design
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Cutting tool Tool holding Guiding device Work piece Machine tool
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Elements of Machining
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Cutting tool harder and wear resistant than the workpiece material
Interference between the tool and workpiece designated as feed and depth of cut
Relative motion between the tool and workpiece termed as cutting speed or velocity to overcome the resistance
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Chip Formation
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The cutting speed, V, is the speed with which the cutting tool moves through the work material. This is generally expressed in feet per minute (fpm) or metres per second (ms-1).
Feed rate, f, may be defined as the small relative movement per cycle (per revolution or per stroke) of the cutting tool in a direction usually normal to the cutting speed direction.
Depth of cut, d, is the normal distance between the unmachined surface and the machined surface.
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Cutting process parameters
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The chip formation in metal cutting could be broadly categorised into three types: Continuous chip, Continuous chip with BUE, and Discontinuous chip
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Type of Chips
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Continuous chips are normally produced when machining steel or ductile metals at high cutting speeds.
The continuous chip which is like a ribbon flows along the rake face.
Continuous chip is possible because of the ductility of metal (steel at high temperature generated due to cutting) flows along the shear plane instead of rupture.
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Continuous chip
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It can be assumed that each layer of metal flows along the slip plane till it is stopped by work hardening.
Each of these layers get welded to the previous ones because of the high temperature, thus forming a continuous chip.
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Continuous chip
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Some ideal conditions that promote continuous chips in metal cutting are:
sharp cutting edge, small chip thickness (fine feed), large rake angle, high cutting speed, ductile work materials and less friction between chip tool interface through efficient lubrication.
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Continuous chip
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This is the most desirable form of chip since the surface finish obtained is good and cutting is smooth.
It also helps in having higher tool life and lower power consumption.
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Continuous chip
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However, because of the large coils of chips, the chip disposal is a problem.
To help in this direction various forms of chip breakers have been developed which are in the form of a step or groove in the tool rake face.
The chip breakers allow the chips to be broken into small pieces so that they can be easily disposed off.
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Continuous chip
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When brittle materials like cast iron are cut, the deformed material gets fractured very easily and thus the chip produced is in the form of discontinuous segments.
In this type the deformed material instead of flowing continuously gets ruptured periodically.
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Discontinuous chip
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Discontinuous chips are easier from the chip disposal view point.
However, the cutting force becomes unstable with the variation coinciding with the fracturing cycle.
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Discontinuous chip
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Also they generally provide better surface finish.
However, in case of ductile materials they cause poor surface finish and low tool life.
Higher depths of cut (large chip thickness), low cutting speeds and small rake angles are likely to produce discontinuous chips.
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Discontinuous chip
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When the friction between tool and chip is high while machining ductile materials, some particles of chip adhere to the tool rake face near the tool tip.
When such sizeable material piles up on the rake face, it acts as a cutting edge in place of the actual cutting edge.
This is termed as built up edge (BUE).
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Continuous chip with BUE
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By virtue of work hardening, BUE is harder than the parent work material.
As the size of BUE grows larger, it becomes unstable and parts of it gets removed while cutting.
The removed portions of BUE partly adheres to the chip underside and partly to the machined surface.
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Continuous chip with BUE
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This causes finished surface to be rough.
However, since the cutting is being carried by the BUE and not the actual tool tip, the life of the cutting tool increases while cutting with BUE.
That way BUE is not harmful while rough machining.
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Continuous chip with BUE
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The conditions that normally induce the formation of BUE are
low cutting speed, high feed, and low rake angle.
One of the prerequisites for the formation of BUE is the work hardenability of the workpiece material.
Higher the work hardenability, rougher is the machined surface produced.
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Continuous chip with BUE
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Chips produced with some ductile materials become very long and often become hazardous to the operator as well as the surface finish of the part produced.
Hence most of the tools needs provide a mechanism by which these long chips are broken.
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Chip Breaking
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Cutting speed Size of cut Effect of tool geometry Tool material Cutting fluid Work piece material
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Manipulating Factors
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Cutting force Radial force Axial force
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Cutting Forces
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Power requirements in Turning
000,33
43 nn dfVCHP
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Crater wear Flank wear
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Tool Wear
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Abrasive action of hard particles of work material
Plastic deformation of the cutting edge Chemical decomposition of the cutting
tool contact surfaces Diffusion between work and tool
surfaces Welding of asperities between work
and tool
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Mechanism of tool wear
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Cutting time,
minutes
Surface appearance
0 – 2 Clean, only minor traces of built-up edge
2 – 11 Dull and streaky11 – 25 Numerous large deposits of built-
up edge; unsatisfactory24 – 45 Numerous small deposits of built-
up edge; very streaky45 – 57(failure)
Partially burnished at 45 minutes to very highly burnished failureApril 22, 2023Nageswara Rao Posinasetti 27
Table 3-2 Effect of Tool Wear on Surface Quality
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Criteria for tool life Change of quality of the machined
surface Change in the magnitude of the
cutting force Change in the cutting temperature Costs
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Tool Life
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V = cutting speed, fpm T = tool life, minutes C = a constant n is a constant
HSS = 0.10 to 0.15 Carbides = 0.20 to 0.25 Ceramics = 0.6 to 1.0
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Taylor Tool Life Equation
CTV n
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V = cutting speed, feet per minute T = tool life, minutes d = depth of cut, in f = feed rate, inches per revolution K = a constant n1 = exponent for feed (0.5 to 0.8) n2 = exponent for depth of cut (0.2 to 0.4)
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Tool Life Equation
KdfTV nnn 21
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The following equation was obtained when machining AISI 2340 steel with HSS tool. A 100 minute tool life was obtained using V = 75 fpm, f = 0.0125 ipr, d = 0.10 in. Calculate the effect upon the tool life for a 20% increase in the cutting speed, feed and depth of cut, taking each separately. Calculate the effect of a 20% increase in each of the above parameters taken together.
035.237.077.013.0 dfTV
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Other tool life equations
25.121 BhndfTVK nnn
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In a metal cutting experimentation, the tool life was found to vary with cutting speed in the following manner:
Cutting speed, V, m/min Tool Life, T, min
100 120 130 50 Derive the Taylor's tool life equation
for this operation and estimate the tool life at a speed of 150 m/min. Also estimate the cutting speed for a tool life of 80 minutes.
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Taylor’s tool life equation is given by VTn = C
Taking logarithms, we get: log V + n log T = log C Applying the given data, we get log 100 + n log 120 = log C log 130 + n log 50 = log C
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Solution
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n = = 0.3
C = V Tn = 100 × 1200.3 = 420.488 Hence, Taylor’s tool life equation can
be written as V T0.3 = 421
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Solution contd..
50log120log
100log130log
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Tool life at V = 150 m/min =
= 31.1867 minutes
Cutting speed for (T = 80 minutes) =
= 113.072 m/min
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Solution contd..
3.0/1
150
421
3.080
421