Lm 05

Module
2
Mechanics of
Machining

Version 2 ME IIT, Kharagpur

Lesson
5
Mechanism of chip
formation


Instructional Objectives

At the end of this lesson, the student would be able to

(i) describe with illustration the mechanism of chip formation in
machining
• ductile materials and
• brittle materials
(ii) illustrate and assess geometrical characteristics of ductile chips :
• chip reduction coefficient & cutting ratio
• shear angle and cutting strain
(iii) Identify and state the causes, characteristics and effects of
built – up – edge (BUE) formation.
(iv) Classify chips and identify the condition for different chip forms.

(i) Mechanism of chip formation in machining
Machining is a semi-finishing or finishing process essentially done to impart
required or stipulated dimensional and form accuracy and surface finish to
enable the product to
• fulfill its basic functional requirements
• provide better or improved performance
• render long service life.

Machining is a process of gradual removal of excess material from the
preformed blanks in the form of chips.

The form of the chips is an important index of machining because it directly or
indirectly indicates :
• Nature and behaviour of the work material under machining condition
• Specific energy requirement (amount of energy required to remove unit
volume of work material) in machining work
• Nature and degree of interaction at the chip-tool interfaces.

The form of machined chips depend mainly upon :
• Work material
• Material and geometry of the cutting tool
• Levels of cutting velocity and feed and also to some extent on depth of
cut
• Machining environment or cutting fluid that affects temperature and
friction at the chip-tool and work-tool interfaces.


Knowledge of basic mechanism(s) of chip formation helps to understand the
characteristics of chips and to attain favourable chip forms.

• Mechanism of chip formation in machining ductile materials

During continuous machining the uncut layer of the work material just ahead
of the cutting tool (edge) is subjected to almost all sided compression as
indicated in Fig. 5.1.

a1: chip thickness (before cut)
a2: chip thickness (after cut)

Work Vf

F
Tool N
R
πo
VC

Fig. 5.1 Compression of work material (layer) ahead of the tool tip

The force exerted by the tool on the chip arises out of the normal force, N and
frictional force, F as indicated in Fig. 5.1.
Due to such compression, shear stress develops, within that compressed
region, in different magnitude, in different directions and rapidly increases in
magnitude. Whenever and wherever the value of the shear stress reaches or
exceeds the shear strength of that work material in the deformation region,
yielding or slip takes place resulting shear deformation in that region and the
plane of maximum shear stress. But the forces causing the shear stresses in
the region of the chip quickly diminishes and finally disappears while that
region moves along the tool rake surface towards and then goes beyond the
point of chip-tool engagement. As a result the slip or shear stops propagating
long before total separation takes place. In the mean time the succeeding
portion of the chip starts undergoing compression followed by yielding and
shear. This phenomenon repeats rapidly resulting in formation and removal of
chips in thin layer by layer. This phenomenon has been explained in a simple
way by Piispannen [1] using a card analogy as shown in Fig. 5.2.

In actual machining chips also, such serrations are visible at their upper
surface as indicated in Fig. 5.2. The lower surface becomes smooth due to
further plastic deformation due to intensive rubbing with the tool at high
pressure and temperature. The pattern of shear deformation by lamellar
sliding, indicated in the model, can also be seen in actual chips by proper
mounting, etching and polishing the side surface of the machining chip and
observing under microscope.


The pattern and extent of total deformation of the chips due to the primary and
the secondary shear deformations of the chips ahead and along the tool face,

as indicated in Fig. 5.3, depend upon
[1] Piispannen V., “Theory of formation of metal chips”, J. Applied Physics, Vol. 19, No. 10, 1948, pp. 876.
• work material
• tool; material and geometry
• the machining speed (VC) and feed (so)
• cutting fluid application

chip

VC Tool

(a) Shifting of the postcards by partial (b) Chip formation by shear in
sliding against each other lamella.

Fig. 5.2 Piispanen model of card analogy to explain chip formation in
machining ductile materials

primary deformation (shear)
zone

WORK
CHIP
secondary deformation zone

VC

Fig. 5.3 Primary and secondary deformation zones in the chip.

The overall deformation process causing chip formation is quite complex and
hence needs thorough experimental studies for clear understanding the
phenomena and its dependence on the affecting parameters. The feasible
and popular experimental methods [2] for this purpose are:
• Study of deformation of rectangular or circular grids marked on the side
surface as shown in Fig. 5.4


[2] Bhattacharya, A.., “Metal cutting – Theory and Practice”, Book, New Central Book Agency, Kolkata.

• Microscopic study of chips frozen by drop tool or quick stop apparatus
• Study of running chips by high speed camera fitted with low
magnification microscope.

(a) rectangular grids (b) circular grids

Fig. 5.4 Pattern of grid deformation during chip formation.

It has been established by several analytical and experimental methods
including circular grid deformation that though the chips are initially
compressed ahead of the tool tip, the final deformation is accomplished
mostly by shear in machining ductile materials.
However, machining of ductile materials generally produces flat, curved or
coiled continuous chips.

• Mechanism of chip formation in machining brittle materials

The basic two mechanisms involved in chip formation are
• Yielding – generally for ductile materials
• Brittle fracture – generally for brittle materials
During machining, first a small crack develops at the tool tip as shown in Fig.
5.5 due to wedging action of the cutting edge. At the sharp crack-tip stress
concentration takes place. In case of ductile materials immediately yielding
takes place at the crack-tip and reduces the effect of stress concentration and
prevents its propagation as crack. But in case of brittle materials the initiated
crack quickly propagates, under stressing action, and total separation takes
place from the parent workpiece through the minimum resistance path as
indicated in Fig. 5.5.
Machining of brittle material produces discontinuous chips and mostly of
irregular size and shape. The process of forming such chips is schematically
shown in Fig. 5.6.


crack propagation in case of
brittle materials
Initial minute crack

VC

Fig. 5.5 Development and propagation of crack causing chip separation.

(a) separation (b) swelling (c) further swelling (d) separation (e) swelling again

Fig. 5.6 Schematic view of chip formation in machining brittle materials.

(ii) Geometry and characteristics of chip forms
The geometry of the chips being formed at the cutting zone follow a particular
pattern especially in machining ductile materials. The major section of the
engineering materials being machined are ductile in nature, even some semi-
ductile or semi-brittle materials behave ductile under the compressive forces
at the cutting zone during machining.
The pattern and degree of deformation during chip formation are quantitatively
assessed and expressed by some factors, the values of which indicate about
the forces and energy required for a particular machining work.


• Chip reduction coefficient or cutting ratio

The usual geometrical features of formation of continuous chips are
schematically shown in Fig. 5.7.
The chip thickness (a2) usually becomes larger than the uncut chip thickness
(a1). The reason can be attributed to
• compression of the chip ahead of the tool
• frictional resistance to chip flow
• lamellar sliding according to Piispannen

so

(a) (b)

Fig. 5.7 Geometrical features of continuous chips’ formation.

The significant geometrical parameters involved in chip formation are shown
in Fig. 5.7 and those parameters are defined (in respect of straight turning) as:
t = depth of cut (mm) – perpendicular penetration of the cutting tool tip
in work surface
so = feed (mm/rev) – axial travel of the tool per revolution of the job
b1 = width (mm) of chip before cut
b2 = width (mm) of chip after cut
a1 = thickness (mm) of uncut layer (or chip before cut)
a2 = chip thickness (mm) – thickness of chip after cut
A1 = cross section (area, mm2) of chip before cut
The degree of thickening of the chip is expressed by
a
ζ = 2 > 1.00 (since a2 > a1) (5.1)
a1
where, ζ = chip reduction coefficient


a1= sosinφ (5.2)
where φ = principal cutting edge angle
Larger value of ζ means more thickening i.e., more effort in terms of forces or
energy required to accomplish the machining work. Therefore it is always
desirable to reduce a2 or ζ without sacrificing productivity, i.e. metal removal
rate (MRR).

Chip thickening is also often expressed by the reciprocal of ζ as,
1 a
=r= 1 (5.3)
ζ a2
where, r = cutting ratio
The value of chip reduction coefficient, ζ (and hence cutting ratio) depends
mainly upon
• tool rake angle, γ
• chip-tool interaction, mainly friction,μ
Roughly in the following way [3]
π
μ ( −γ o )
ζ =e 2
[for orthogonal cutting] (5.4)
π/2 and γo are in radians
The simple but very significant expression (5.4) clearly depicts that the value
of ζ can be desirably reduced by
• Using tool having larger positive rake
• Reducing friction by using lubricant
The role of rake angle and friction at the chip-tool interface on chip reduction
coefficient are also schematically shown in Fig. 5.8.
Chip reduction coefficient, ζ

μ (friction coefficient)

Rake angle, γ

Fig. 5.8 Role of rake angle and friction on chip reduction coefficient

Chip reduction coefficient, ζ is generally assessed and expressed by the ratio
of the chip thickness, after (a2) and before cut (a1) as in equation 5.1.
But ζ can also be expressed or assessed by the ratio of


[3] Kronenberg, M., “A new approach to some relationships in the Theory of Metal Cutting”, J. Applied
Physics, Vol.6, No. 6, 1945.

• Total length of the chip before (L1) and after cut (L2)
• Cutting velocity, VC and chip velocity, Vf
Considering total volume of chip produced in a given time,
a1b1L1 = a2b2L2 (5.5)

The width of chip, b generally does not change significantly during machining
unless there is side flow for some adverse situation.
Therefore assuming, b1=b2 in equation (5.5), ζ comes up to be,
⎛ a ⎞ L
ζ ⎜= 2 ⎟ = 1
⎜ a ⎟ L (5.6)
⎝ 1 ⎠ 2

Again considering unchanged material flow (volume) ratio, Q
Q = (a1b1)VC = (a2b2)Vf (5.7)
Taking b1=b2,
⎛ a ⎞ V
ζ ⎜= 2 ⎟ = C
⎜ a ⎟ V (5.8)
⎝ 1 ⎠ f

Equation (5.8) reveals that the chip velocity, Vf will be lesser than the cutting
⎛ 1⎞
velocity, VC and the ratio is equal to the cutting ratio, r ⎜ = ⎟
⎜ ζ⎟
⎝ ⎠
• Shear angle
It has been observed that during machining, particularly ductile materials, the
chip sharply changes its direction of flow (relative to the tool) from the
direction of the cutting velocity, VC to that along the tool rake surface after
thickening by shear deformation or slip or lamellar sliding along a plane. This
plane is called shear plane and is schematically shown in Fig. 5.9.

Shear plane: Shear plane is the plane of separation of work material layer in
the form of chip from the parent body due to shear along that plane.
Shear angle: Angle of inclination of the shear plane from the direction of
cutting velocity [as shown in Fig. 5.9].
VC'
Shear plane
a1
A
B
βo a2
(βo - γo)
O C γo
VC
πo

Fig. 5.9 Shear plane and shear angle in chip formation


The value of shear angle, denoted by βo (taken in orthogonal plane) depends
upon
• Chip thickness before and after cut i.e. ζ
• Rake angle, γo (in orthogonal plane)
From Fig. 5.9,
AC = a2 = OAcos(βo-γo)
And AB = a1 = OAsinβo
Dividing a2 by a1
a2 cos( β o − γ o )
=ζ = (5.9)
a1 sin β o
cos γ o
or, tan β o = (5.10)
ζ − sin γ o
Replacing chip reduction coefficient, ζ by cutting ratio, r, the equation (5.10)
changes to
r cos γ o
tan β o = (5.11)
1 − r sin γ o
Equation 5.10 depicts that with the increase in ζ, shear angle decreases and
vice-versa. It is also evident from equation (5.10) as well as equation (5.4)
that shear angle increases both directly and indirectly with the increase in tool
rake angle. Increase in shear angle means more favourable machining
condition requiring lesser specific energy.

• Cutting strain

The magnitude of strain, that develops along the shear plane due to
machining action, is called cutting strain (shear). The relationship of this
cutting strain, ε with the governing parameters can be derived from Fig. 5.10.

Due to presence of the tool as an obstruction the layer 1 has been shifted to
position 2 by sliding along the shear plane.
From Fig. 5.10,
Δs PM
Cutting strain (average), ε = =
Y ON
PN + NM PN NM
or, ε = = +
ON ON ON
or, ε = cot β o + tan( β o−γ o ) (5.12)

(iii) Built-up-Edge (BUE) formation
• Causes of formation
In machining ductile metals like steels with long chip-tool contact length, lot of
stress and temperature develops in the secondary deformation zone at the
chip-tool interface. Under such high stress and temperature in between two
clean surfaces of metals, strong bonding may locally take place due to
adhesion similar to welding. Such bonding will be encouraged and


accelerated if the chip tool materials have mutual affinity or solubility. The
weldment starts forming as an embryo at the most favourable location and
thus gradually grows as schematically shown in Fig. 5.11.

βo
Δs
τs

Y
O
M
γo
N
P
Δs shear strain
Y
πo

Fig. 5.10 Cutting strain in machining

Built-up-edge

F

VC

Fig. 5.11 Scheme of built-up-edge formation


With the growth of the BUE, the force, F (shown in Fig. 5.11) also gradually
increases due to wedging action of the tool tip along with the BUE formed on
it. Whenever the force, F exceeds the bonding force of the BUE, the BUE is
broken or sheared off and taken away by the flowing chip. Then again BUE
starts forming and growing. This goes on repeatedly.

• Characteristics of BUE
Built-up-edges are characterized by its shape, size and bond strength, which
depend upon:
• work tool materials
• stress and temperature, i.e., cutting velocity and feed
• cutting fluid application governing cooling and lubrication.
BUE may develop basically in three different shapes as schematically shown
in Fig. 5.12.

(a) positive wedge (b) negative wedge (c) flat type

Fig. 5.12 Different forms of built-up-edge.

In machining too soft and ductile metals by tools like high speed steel or
uncoated carbide the BUE may grow larger and overflow towards the finished
surface through the flank as shown in Fig. 5.13
.

chip

VC

Fig. 5.13 Overgrowing and overflowing of BUE causing surface roughness


While the major part of the detached BUE goes away along the flowing chip, a
small part of the BUE may remain stuck on the machined surface and spoils
the surface finish. BUE formation needs certain level of temperature at the
interface depending upon the mutual affinity of the work-tool materials. With
the increase in VC and so the cutting temperature rises and favours BUE
formation. But if VC is raised too high beyond certain limit, BUE will be
squashed out by the flowing chip before the BUE grows. Fig. 5.14 shows
schematically the role of increasing VC and so on BUE formation (size). But
sometime the BUE may adhere so strongly that it remains strongly bonded at
the tool tip and does not break or shear off even after reasonably long time of
machining. Such detrimental situation occurs in case of certain tool-work
materials and at speed-feed conditions which strongly favour adhesion and
welding.

S03 > S02
S02 > S01
S01
Size of BUE

Cutting velocity, VC

Fig. 5.14 Role of cutting velocity and feed on BUE formation.

• Effects of BUE formation
Formation of BUE causes several harmful effects, such as:
• It unfavourably changes the rake angle at the tool tip causing increase
in cutting forces and power consumption
• Repeated formation and dislodgement of the BUE causes fluctuation in
cutting forces and thus induces vibration which is harmful for the tool,
job and the machine tool.
• Surface finish gets deteriorated
• May reduce tool life by accelerating tool-wear at its rake surface by
adhesion and flaking
Occasionally, formation of thin flat type stable BUE may reduce tool wear
at the rake face.


(iv) Types of chips and conditions for formation of
those chips
Different types of chips of various shape, size, colour etc. are produced by
machining depending upon
• type of cut, i.e., continuous (turning, boring etc.) or intermittent cut
(milling)
• work material (brittle or ductile etc.)
• cutting tool geometry (rake, cutting angles etc.)
• levels of the cutting velocity and feed (low, medium or high)
• cutting fluid (type of fluid and method of application)
The basic major types of chips and the conditions generally under which such
types of chips form are given below:
o Discontinuous type
• of irregular size and shape : - work material – brittle like grey
cast iron
• of regular size and shape : - work material ductile but hard
and work hardenable
- feed – large
- tool rake – negative
- cutting fluid – absent or inadequate
o Continuous type
• Without BUE : work material – ductile
Cutting velocity – high
Feed – low
Rake angle – positive and large
Cutting fluid – both cooling and lubricating

• With BUE : - work material – ductile
- cutting velocity – medium
- feed – medium or large
- cutting fluid – inadequate or absent.

o Jointed or segmented type
- work material – semi-ductile
- cutting velocity – low to medium
- feed – medium to large
- tool rake – negative
- cutting fluid – absent

Often in machining ductile metals at high speed, the chips are deliberately
broken into small segments of regular size and shape by using chip breakers
mainly for convenience and reduction of chip-tool contact length.


Exercise - 5
A. Quiz Test

Identify the correct one out of the four given answers

1.In turning mild steel the value of ζ will be
(a) > 1.0
(b) < 1.0
(c) = 1.0
(d) none of the above

2.The value of shear angle, βo depends upon

(a) tool rake angle
(b) friction at chip-tool interface
(c) built – up – edge formation
(d) all of the above

3.Shaping grey cast iron block will produce
(a) continuous chip with BUE
(b) continuous chip without BUE
(c) discontinuous chip of irregular size & shape
(d) discontinuous chip of regular size & shape

4.The value of chip reduction coefficient, ζ does
not depend upon
(a) cutting velocity
(b) depth of cut
(c) cutting tool material
(d) tool rake angle

B. Numerical Problem

1.During plain turning mild steel by a tool of geometry, 0o, 0o, 8o, 7o,
15o, 90o, 0 (mm) at so= 0.2 mm/rev, the chip thickness was found to
be 0.5 mm. Determine the values of ζ and βo in the above case.


Answers
A. Quiz Test
1 – (a)
2 – (d)
3 – (c)
4 – (b)

B. Numerical Problem
a2 a2 0 .5
ζ = = = = 2 .5
a1 so sin φ 0.2 x sin 90o

cos γ o cos 0o
tan β o = = [∵ γ o = 0o ]
ζ − sin γ o 2.5 − sin 0o

1 1
= = = 0 .4
ζ 2 .5
∴ β o = tan−1(0.4) = 21.8o


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