cutting tool geometry for determiniung surface finish

Department of Collegiate and Technical Education
TOOL GEOMETRY (Week 3)
Session-III
MACHINE TOOL TECHNOLOGY
( IIIrd Semester)
Mechanical Engineering
Mechanical Engineering – 20ME32P

• Tool Geometry
• Tool Materials – High carbon steel, HSS, Cemented carbides,
Medium alloy, Abrasives, Diamonds, Stellite ceramics
• Tool Designation (Tool Signature)
• Tool Life - Definition, Taylors Tool life equation
•Tool Wear – Mechanical wear, Thermo Chemical wear,
Chemical wear, Galvanic wear
• Cutting Speed, Feed, Depth of Cut & Machining Time
Contents

TOOL GEOMETRY
The typical right hand single point cutting tool terminology is as
shown in fig

Shank: The shank is that portion of the tool bit which is not ground
to form cutting edges and is rectangular in cross section.
Face: The face of cutting tool is that surface which faces the w/p.
Heel: The heel is the lowest portion of the side cutting and end
cutting edge.
Nose: The nose is the conjunction of the side and end cutting edges.
Base: The base is the underside of the shank.
Contd.,

Rake: The rake is the slope of the top away from the cutting edge.
Each tool has a side and back rake. Back rake indicates that the plane
which forms the face or top of a tool has been ground back at an
angle sloping from the nose. Side rake indicates that the place that
forms the face or top of a tool has been ground back at an angle
sloping from the side cutting edge.
Contd.,

Side clearance or side relief angle:
The side clearance or side relief indicates that the plane that forms the
flank or side of a tool has been ground back at an angle sloping down
from the side cutting edge.
End cutting edge angle: The end cutting edge angle indicates that
the plane which forms the end of a tool has been ground back at an
angle sloping from the nose to the side of the shank. Chips are
removed by its cutting edge.
Contd.,

Lip or cutting angle: The lip or cutting angle is the included angle
when the tool has been ground wedge shaped.
Rake angle: It is the angle made by the face of tool and the plane
parallel to the base of cutting tool. If the rake angle is measured in the
direction of tool shank, it is called back rake angle and if measured in a
direction at right angle to it, then it is called side rake angle.
Side cutting edge angle: It also known as lead angle. It is the angle
between the side cutting edge and the side of the tool shank.
Contd.,

1. High Carbon Steel:
• It is one of the earliest cutting materials used in machining. It is
however now virtually superseded by other materials used in
engineering because it starts to temper at about 2200
C. This softening
process continues as the temperature rises. As a result cutting using this
material for tools is limited to speeds up to 0.15 m/s for machining mild
steel with lots of coolant.
Cutting Tool Materials

• High carbon steels are oil- or water-hardened plain carbon steels with
0.9 to 1.4 percent carbon content. They are used for hand tools such as
files and chisels, and only to a limited extent for drilling & turning
tools.
•These tools, however, tend to soften at machining speeds above 50
feet per minute (fpm) in mild steels.
Contd.,

2. High Speed Steel (HSS):
• This range of metal contains about 7% C, 4% Cr plus additions of
tungsten, vanadium, molybdenum and cobalt. These metals maintain
their hardness at temperature up to about 600, but soften rapidly at
higher temperatures. These materials are suitable for cutting mild steel at
speeds up maximum rates of 0.8 m/s to 1.8 m/s
• HSS may be used at higher cutting speeds It is sometimes used for
lathe tools when special tool shapes are needed, especially for boring
tools. However, HSS is extensively used for milling cutters.
• These cutters usually have a longer working life

3. Cast Alloys: - These cutting tools are made of various nonferrous
metals in a cobalt base. They can withstand cutting temperatures of up to
7600C and are capable of cutting speeds about 60% higher than HSS.
4. Stellite: - This is a cast alloy of Co (40 to 50%), Cr (27 to 32%),
W (14 to 19%) and C (2%). Stellite is quite tough and more heat and
wear resistive than the basic HSS (18–4–1) but such stellite as cutting
tool material became obsolete for its poor grindability and especially
after the arrival of cemented carbides.

5. Cemented Carbides (Cermets or Sintered Carbide): -
• This material usually consists of tungsten carbide or a mixture of
tungsten carbide, titanium, or tantalum carbide in powder form, sintered
in a matrix of cobalt or nickel. The term Carbide is commonly used to re-
present to cemented carbides, the cutting tools composed of tungsten
carbide, titanium carbide, or tantalum carbide & cobalt in various
combinations.
• A typical composition of cemented carbide is 85 to 95 percent of
tungsten & the remainder a cobalt binder for the tungsten carbide powder

Contd.,
• Cemented carbides are extremely hard tool materials (above RA 90),
have a high compressive strength & resist wear & rupture. Coated
carbide inserts are often used to cut hard or difficult-to-machine work
pieces.
• These are the most widely used in the machining industry, particularly
useful for cutting tough alloy steels, which quickly break down HSS. As
this material is expensive and has low rupture strength it is normally
made in the form of tips which are brazed or clamped on a steel shank

6. Coated Carbides
• The cutting system is based on providing a thin layer of high wear-
resistant titanium carbide fused to a conventional tough grade carbide
insert, thus achieving a tool combining the wear resistance of one
material with the wear resistance of another. These systems provide a
longer wear resistance and a higher cutting speed compared to
conventional carbides

7. Ceramics
• Ceramic or “cemented oxide” tools are made primarily from
aluminum oxide. Ceramics are made by powder metallurgy from
aluminium oxide with additions of titanium oxide and magnesium
oxide to improve cutting properties.
• These have a very high hot resistance and wear resistance and can
cut at very high speed. However they are brittle, little resistance to
shock. Their use is therefore limited to tips used for continuous high
speed cutting on vibration-free machines

8. Diamond Tools
• Diamonds have limited application due to the high cost and the
small size of the stones. They are used on very hard materials to
produce a fine finish and on soft materials especially those inclined
to clog other cutting materials. They are generally used at very high
cutting speed with low feed and light cuts and vibration free.
• The tools last for 10 times longer than carbide based tools.
Industrial diamonds are sometimes used to machine extremely hard
work pieces.

Contd.,
• Only relatively small removal rates are possible with diamond tools,
but high speeds are used and good finishes are obtained.
• Diamond tools are particularly effective for cutting abrasive
materials that quickly wear out other tool materials. Nonferrous
metals, plastics, and some nonmetallic materials are often cut with
diamond tools.

Tool Designation (Tool Signature)
αb – αs – ϕe – ϕs – Ce – Cs – r
Where,
αb = Back rake angle, αs = Side rake angle, ϕe = End relief angle,
ϕs = Side relief angle, Ce = End cutting edge angle, Cs = Side cutting
edge angle, r = Tool radius

Tool Life
Tool life generally indicates the amount of satisfactory
performance or service rendered by a fresh tool or a cutting
point till it is declared failed. Tool life is defined in two ways
(a) In R & D: Actual machining time (period) by which a
fresh cutting tool (or point) satisfactorily works after which it
needs replacement or reconditioning.
(b) In industries or shop floor: The length of time of
satisfactory service or amount of acceptable output provided
by a fresh tool prior to it is required to replace or recondition

Taylor’s Tool Life Equation
Wear and hence tool life of any tool for any work
material is governed mainly by the level of the
machining parameters i.e., cutting velocity (VC), feed
(f) and depth of cut (t). Cutting velocity affects
maximum and depth of cut minimum. The usual pattern
of growth of cutting tool wear (mainly Flank wear VB),
principle of assessing tool life and its dependence on
cutting velocity are schematically shown in Fig

• The tool life obviously decreases with the increase in
cutting velocity keeping other conditions unaltered as
indicated in above Fig. If the tool lives, T1, T2, T3, T4
etc are plotted against the corresponding cutting
velocities, V1, V2, V3, V4 etc as shown in above Fig.
Contd.,

• A smooth curve like a rectangular hyperbola is found to appear.
When F. W. Taylor plotted the same figure taking both V and T in
log-scale, a more distinct linear relationship appeared as
schematically shown in previous Fig
• With the slope, n and intercept, c, Taylor derived the simple
equation as, VCTn
= C
Where, n = Taylor’s tool life exponent. The values of both ‘n’ and
‘C’ depend mainly upon the tool-work materials and the cutting
Contd.,

The common mechanisms of cutting tool wear are:
(a) Mechanical wear
•Thermally insensitive type; like abrasion, chipping and de-lamination.
•Thermally sensitive type; like adhesion, fracturing, flaking etc.
(b) Thermo chemical wear
•Macro-diffusion by mass dissolution.
•Micro-diffusion by atomic migration.
Tool Wear

(c) Chemical wear: Chemical wear, leading to damages like grooving
wear may occur if the tool material is not enough chemically stable
against the work material and/or the atmospheric gases.
(d) Galvanic wear: Galvanic wear, based on electrochemical
dissolution, seldom occurs when the work and tool materials are
electrically conductive, cutting zone temperature is high and the cutting
fluid acts as an electrolyte.
Contd.,

CUTTING SPEED:
Cutting speed for lathe work may be defined as the rate in meters per
minute at which the surface of the job moves past the cutting tool.
Cutting speed is given by the equation
V = m/min
Where, D – Mean diameter of the work piece (mm).
N – Rotational speed of the work piece (rpm).
Cutting speed, Feed, Depth of Cut, Machining
Time

FEED:
In a lathe, the feed of a cutting tool is the distance the tool advances for
each revolution of the work piece, it is expressed in ‘mm/rev’.
DEPTH OF CUT: It is the perpendicular distance measured from the
machined surface to the uncut surface of the work piece.
Depth of cut = (D-d)/2
Where D = Dia of the work piece before machining.
d = Dia of the machined work piece.
Contd.,

MACHINING TIME: The machining time in lathe work can be
calculated for a portion operation, if the speed of the work piece and
feed length of the work piece is known.
Let f = Feed of the work piece in mm/rev
L= length of the work piece in mm.
N = Speed of the work piece in rpm.
T = Machining time in minutes.
Machining time is given by: T = L/(f x N) minutes.
Contd.,

REFERENCES
•Elements of Workshop Technology (Vols. 1 and II) by Hajra Chaudhary.
•Production Technology By R.K. Jain
•Foundry Technology By O.P.Khanna
•Engineering Drawing Vol-2 By K.R.Gopala Krishna
•Engineering Drawing By N.D.Bhat

cutting tool geometry for determiniung surface finish

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