1. Material Removal Process (Metal Machining Process)
1.1 Theory of Metal Cutting
overview, theory of chip formation, force &
merchant equation, power & energy, cutting
temperature
1.2 Machining Operations and Machine Tools
turning, drilling, milling, machine centers,
cutting tool technology
BDA 3052 Manufacturing Technology

2. Material Removal Processes Introduction
It is shaping operations, it remove material from a starting workpart so the remaining part has the desired geometry
Divided into three main groups:
1) Machining – material removal by a sharp cutting tool, e.g., turning, milling, drilling
2) Abrasive processes – material removal by hard, abrasive particles, e.g., grinding
3) Nontraditional processes - various energy forms other than sharp cutting tool to remove material
BDA 3052 Manufacturing Technology

3. Why Machining is Important
Variety of work materials can be machined
Most frequently used to cut metals
Variety of part shapes and special geometric features possible, such as:
Screw threads
Accurate round holes
Very straight edges and surfaces
Good dimensional accuracy and surface finish
BDA 3052 Manufacturing Technology

4. Disadvantages with Machining
Wasteful of material
Chips generated in machining are wasted material, at least in the unit operation
Time consuming
A machining operation generally takes more time to shape a given part than alternative shaping processes, such as casting, powder metallurgy, or forming
BDA 3052 Manufacturing Technology

5. Machining in Manufacturing Sequence
Generally performed after other manufacturing processes, such as casting, forging, and bar drawing
Other processes create the general shape of the starting workpart
Machining provides the final shape, dimensions, finish, and special geometric details that other processes cannot create
BDA 3052 Manufacturing Technology

6. Machining Nomenclature of single point tool
BDA 3052 Manufacturing Technology

7. Seven elements of single‑point tool geometry; and (b) the tool signature convention that defines the seven elements.
BDA 3052 Manufacturing Technology

8. Orthogonal Cutting Model
Simplified 2-D model of machining that
describes the mechanics of machining
fairly accurately
Figure Orthogonal cutting: (a) as a three‑dimensional process.
BDA 3052 Manufacturing Technology

9. Orthogonal and Oblique cutting
BDA 3052 Manufacturing Technology

10. Assumptions in orthogonal cutting (Merchant theory)
01.The tool is perfectly sharp and no contact along clearance face.
02. The shear surface is a plane extending upward from the cutting edge.
03.The cutting edge is a straight line, extending perpendicular to the direction of motion and generates a plane surface as the work moves past it.
04.The chip does not flow to either side.
05.The depth of cut is constant.
06.Width of the tool is greater than the work piece.
07.The work moves relative to the tool with uniform velocity.
08.A continuous chip is produced with no built up edge.
BDA 3052 Manufacturing Technology

11. Assumptions in orthogonal cutting (Merchant theory)
09. Chip is assume to shear continuously across plane AB on which the shear stress reaches the value of shear flow stress.
10.Width of chip is remains equal to the width of the work piece. i.e. Plane strain conditions exist.
BDA 3052 Manufacturing Technology

12. Difference between orthogonal and oblique cutting
Orthogonal cutting
Oblique cutting
01.The cutting edge of the tool is perpendicular to the direction of the tool travel.
The cutting edge is inclined at angle with the normal direction of the tool travel.
02. The cutting edge clears the width of the work piece on either ends.
The cutting edge may or may not clear the width of the workpiece.
03. The chip flows over the tool. The chip coils in tight.
The chip flows on the tool face making an angle with the normal cutting edge. The chip flows side ways in a long curl.
04. Only two components of the cutting force acting on the tool.
Three components of the forces acting on the tool.
05.Maximum chip thickness occurs at the middle.
Maximum chip thickness may not occur at middle.
06. For the given feed rate and DOC, the force which act or shears the metal acts on a smaller area and therefore, the heat developed per unit area due to friction along the tool work interface is less and the tool life is less.
It acts on larger area and thus tool life is more.

13. Machining
Cutting action involves shear deformation of work material to form a chip
As chip is removed, new surface is exposed
(a) A cross‑sectional view of the machining process, (b) tool with negative rake angle; compare with positive rake angle in (a).
BDA 3052 Manufacturing Technology

14. Cutting Process in Turning
BDA 3052 Manufacturing Technology

15. Cutting Process in Turning
BDA 3052 Manufacturing Technology

16. Relationship between chip thickness, rake angle and shear plane angle
BDA 3052 Manufacturing Technology

17. Chip Thickness Ratio
where r = chip thickness ratio; to = thickness of the chip prior to chip formation; and tc = chip thickness after separation
Chip thickness after cut always greater than before, so chip ratio always less than 1.0
BDA 3052 Manufacturing Technology

18. Determining Shear Plane Angle
Based on the geometric parameters of the orthogonal model, the shear plane angle  can be determined as:
where r = chip ratio, and  = rake angle
BDA 3052 Manufacturing Technology

19. Example of Problem
In a machining operation that approximates orthogonal
cutting, the cutting tool has a rake angle = 10. The chip
Thickness before the cut to = 0.50 mm and the chip
thickness after the cut tc = mm. Calculate the shear
plane angle and the shear strain in the operation.
Answer :  = 25.4
 = 2.386
BDA 3052 Manufacturing Technology

20. Example of Problem 2
In an orthogonal cutting operation, the tool has a rake
angle = 15. The chip thickness before the cut = 0.30
mm and the cut yields a deformed chip thickness = 0.65
mm. Calculate (a) the shear plane angle and (b) the
shear strain for the operation.
BDA 3052 Manufacturing Technology

21. Shear Strain in Chip Formation
Shear strain during chip formation: (a) chip formation depicted as a series of parallel plates sliding relative to each other, (b) one of the plates isolated to show shear strain, and (c) shear strain triangle used to derive strain equation.
BDA 3052 Manufacturing Technology

22. Shear Strain Shear strain in machining can be computed
from the following equation, based on the
preceding parallel plate model:
 = tan( - ) + cot 
where  = shear strain,  = shear plane angle, and  =
rake angle of cutting tool
BDA 3052 Manufacturing Technology

23. Example of Problem 2
In an orthogonal cutting operation, the tool has a rake
angle = 15. The chip thickness before the cut = 0.30
mm and the cut yields a deformed chip thickness = 0.65
mm. Calculate (a) the shear plane angle and (b) the
shear strain for the operation.
BDA 3052 Manufacturing Technology

24. Chip Formation
More realistic view of chip formation, showing shear zone rather than shear plane. Also shown is the secondary shear zone resulting from tool‑chip friction.
BDA 3052 Manufacturing Technology

25. Four Basic Types of Chip in Machining
Discontinuous chip
Continuous chip
Continuous chip with Built-up Edge (BUE)
Serrated chip
BDA 3052 Manufacturing Technology

26. 1. Discontinuous Chip Low cutting speeds Large feed and depth of cut
Brittle work materials
Low cutting speeds
Large feed and
depth of cut
High tool‑chip friction
BDA 3052 Manufacturing Technology

27. 2. Continuous Chip Ductile work materials High cutting speeds
Small feeds and depths
Sharp cutting edge
Low tool‑chip friction
BDA 3052 Manufacturing Technology

28. Continuous with BUE Ductile materials Low‑to‑medium cutting speeds
Tool-chip friction causes portions of chip to adhere to rake face
BUE forms, then breaks off, cyclically
BDA 3052 Manufacturing Technology

29. Serrated Chip Semicontinuous - saw-tooth appearance
Cyclical chip forms with alternating high shear strain then low shear strain
Associated with difficult-to-machine metals at high cutting speeds
Figure 21.9 (d) serrated.
BDA 3052 Manufacturing Technology

30. Effect of Higher Shear Plane Angle
Higher shear plane angle means smaller shear plane which means lower shear force, cutting forces, power, and temperature
Effect of shear plane angle  : (a) higher  with a resulting lower shear plane area; (b) smaller  with a corresponding larger shear plane area. Note that the rake angle is larger in (a), which tends to increase shear angle according to the Merchant equation
BDA 3052 Manufacturing Technology

31. Forces Acting on Chip Friction force F and Normal force to friction N
Shear force Fs and Normal force to shear Fn
Forces in metal cutting: (a) forces acting on the chip in orthogonal cutting
BDA 3052 Manufacturing Technology

32. Resultant Forces Vector addition of F and N = resultant R
Vector addition of Fs and Fn = resultant R'
Forces acting on the chip must be in balance:
R‘’ must be equal in magnitude to R
R’ must be opposite in direction to R
R’ must be collinear with R
BDA 3052 Manufacturing Technology

33. Cutting Forces
BDA 3052 Manufacturing Technology

34. Cutting Forces
BDA 3052 Manufacturing Technology

35. Cutting Forces
BDA 3052 Manufacturing Technology

36. Coefficient of Friction
Coefficient of friction between tool and chip:
-(1)
Friction angle related to coefficient of friction as follows:
-(2)
BDA 3052 Manufacturing Technology

37. Shear Stress Shear stress acting along the shear plane: -(3) -(4)
where As = area of the shear plane
-(4)
Shear stress = shear strength of work material during cutting
BDA 3052 Manufacturing Technology

38. Cutting Force and Thrust Force
F, N, Fs, and Fn cannot be directly measured
Forces acting on the tool that can be measured:
Cutting force Fc and Thrust force Ft
Forces in metal cutting: (b) forces acting on the tool that can be measured
BDA 3052 Manufacturing Technology

39. Merchant’s circle diagram
BDA 3052 Manufacturing Technology

40. Merchant’s circle diagram
BDA 3052 Manufacturing Technology

41. Forces in Metal Cutting
Equations can be derived to relate the forces that cannot be measured to the forces that can be measured:
F = Fc sin  + Ft cos  (5)
N = Fc cos  ‑ Ft sin  (6)
Fs = Fc cos  ‑ Ft sin  (7)
Fn = Fc sin  + Ft cos  (8)
Based on th ese calculated force, shear stress and coefficient of friction can be determined
BDA 3052 Manufacturing Technology

42. Example of Problem 3 Cutting force = 1559 N Thrust force = 1271 N
Width of cutting = 3 mm
Rake angle = 10
Shear plane angle = 25.4
Original Thickness = 0.5 mm
Determine the shear strength of the work
material.
shear stress, S / shear strength,  = 247 N/mm2
BDA 3052 Manufacturing Technology

43. Forces in Metal Cutting
From equation 3, the force diagram (Merchant ‘s Circle Diagram), can be used to derived the following equations:
BDA 3052 Manufacturing Technology

44. The Merchant Equation
From equation 3, 4 and 7, Merchant Equation for shear stress can be expressed as,
BDA 3052 Manufacturing Technology

45. The Merchant Equation
Of all the possible angles at which shear deformation can occur, the work material will select a shear plane angle  that minimizes energy, given by
Derived by Eugene Merchant
Based on orthogonal cutting, but validity extends to 3-D machining
BDA 3052 Manufacturing Technology

46. What the Merchant Equation Tells Us
To increase shear plane angle
Increase the rake angle
Reduce the friction angle (or coefficient of friction)
BDA 3052 Manufacturing Technology

47. Power and Energy Relationships
A machining operation requires power
The power to perform machining can be computed from:
Pc = Fc 
where Pc = cutting power (Nm/s); Fc = cutting force
(N); and  = cutting speed (m/min)
BDA 3052 Manufacturing Technology

48. Power and Energy Relationships
In U.S. customary units, power is traditional expressed as horsepower
HPc = Fc/33,000
where HPc = cutting horsepower, hp
BDA 3052 Manufacturing Technology

49. Power and Energy Relationships
Gross power to operate the machine tool Pg or HPg is given by or
where E = mechanical efficiency of machine tool
Typical E for machine tools  90%
BDA 3052 Manufacturing Technology

50. Unit Power in Machining
Useful to convert power into power per unit volume rate of metal cut
Called unit power, Pu or unit horsepower, HPu or
where MRR = material removal rate (mm3/s)
BDA 3052 Manufacturing Technology

51. Specific Energy in Machining
Unit power is also known as the specific energy U
Units for specific energy are typically N‑m/mm3 or J/mm3
BDA 3052 Manufacturing Technology

52. Cutting Temperature
Approximately 98% of the energy in machining is converted into heat
This can cause temperatures to be very high at the tool‑chip
The remaining energy (about 2%) is retained as elastic energy in the chip
BDA 3052 Manufacturing Technology

53. Cutting Temperature is Important
High cutting temperatures
Reduce tool life
Produce hot chips that pose safety hazards to the machine operator
Can cause inaccuracies in part dimensions due to thermal expansion of work material
BDA 3052 Manufacturing Technology

54. Cutting Temperature
Analytical method derived by Nathan Cook from dimensional analysis using experimental data for various work materials
where T = temperature rise at tool‑chip interface; U = specific energy; v = cutting speed; to = chip thickness before cut; C = volumetric specific heat of work material; K = thermal diffusivity of work material
BDA 3052 Manufacturing Technology

55. Example Problem 6 Cutting speed = 100 m/min
Chip original thickness = 0.5 mm
Thermal diffusivity = 50 mm2/s
Specific Energy = 1.038
Volumetric specific heat work material = 3 x10-3 J/mm3
Find the mean temperature rise at the tool-chip
Interface.
BDA 3052 Manufacturing Technology

56. Cutting Temperature
Experimental methods can be used to measure temperatures in machining
Most frequently used technique is the tool‑chip thermocouple
Using this method, Ken Trigger determined the speed‑temperature relationship to be of the form:
T = K vm
where T = measured tool‑chip interface temperature, and v = cutting speed
K and m depend on the cutting conditions and work material
BDA 3052 Manufacturing Technology

57. Machining
A material removal process in which a sharp cutting tool is used to mechanically cut away material so that the desired part geometry remains
Most common application: to shape metal parts
Most versatile of all manufacturing processes in its capability to produce a diversity of part geometries and geometric features with high precision and accuracy
Casting can also produce a variety of shapes, but it lacks the precision and accuracy of machining

58. Classification of Machined Parts
Rotational - cylindrical or disk‑like shape
Nonrotational (also called prismatic) - block‑like or plate‑like
Machined parts are classified as: (a) rotational, or (b) nonrotational, shown here by block and flat parts.

59. Machining Operations and Part Geometry
Each machining operation produces a characteristic part geometry due to two factors:
Relative motions between tool and workpart
Generating – part geometry determined by feed trajectory of cutting tool
Shape of the cutting tool
Forming – part geometry is created by the shape of the cutting tool

60. Generating Shape
Figure Generating shape: (a) straight turning, (b) taper turning, (c) contour turning, (d) plain milling, (e) profile milling.

61. Forming to Create Shape
Forming to create shape: (a) form turning, (b) drilling, and (c) broaching.

62. Forming and Generating
Combination of forming and generating to create shape: (a) thread cutting on a lathe, and (b) slot milling.

63. Turning
Single point cutting tool removes material from a rotating workpiece to generate a cylinder
Performed on a machine tool called a lathe
Variations of turning performed on a lathe:
Facing
Contour turning
Chamfering
Cutoff
Threading

64. Turning
Turning operation.

65. Turning Operation
Close-up view of a turning operation on steel using a titanium nitride coated carbide cutting insert (photo courtesy of Kennametal Inc.)

66. Facing
Tool is fed
radially inward

67. Contour Turning
Instead of feeding tool parallel to axis of rotation, tool follows a contour that is other than straight, thus creating a contoured shape

68. Chamfering
Cutting edge cuts an angle on the corner of the cylinder, forming a "chamfer"

69. Cutoff
Tool is fed radially into rotating work at some location to cut off end of part

70. Cutoff
Tool is fed radially into rotating work at some location to cut off end of part

71. Threading
Pointed form tool is fed linearly across surface of rotating workpart parallel to axis of rotation at a large feed rate, thus creating threads

72. Cutting Conditions in Turning - 1
The rotational speed in turning related to the desired cutting
speed at the surface of the cylindrical workpiece by the
equation:
N = rotational speed, rev/min;  = cutting speed, m/min,
And Do = original diameter of the part, m. 72

73. Cutting Conditions in Turning - 2
The change in diameter is determined by the depth of cut, d:
Do – Df = 2d
Do = original diameter, mm; Df = final diameter, mm
d = depth of cut 73

74. Cutting Conditions in Turning - 3
The feed in turning is generally expressed in mm/rev. This
feed can be converted to linear travel rate in mm/min by the
formula:
fr = Nf
fr = feed rate, mm/min; f = feed mm/rev 74

75. Cutting Conditions in Turning - 4
The time to machine from one end of a cylindrical workpart
to the other is given by:
Tm = L/fr
Tm = time of actual machining, minutes; and L = length of
the cylindrical workpart, mm 75

76. Cutting Conditions in Turning - 5
The volumetric rate of material removal rate can be most
conveniently determined by the following equation:
MRR = vfd
MRR = material removal rate, mm3/min, f = feed, mm 76

77. Cutting Conditions in Turning
Problem 1
A cylindrical workpart 200 mm in diameter
and 700 mm long is to be turned in an
engine lathe. Cutting conditions are as
follows: cutting speed is 2.30 m/s, feed is
0.32 mm/rev, and depth of cut is 1.80
mm.
Determine (a) cutting time, and (b)
metal removal rate. 77

78. Cutting Conditions in Turning
Problem 1
A cylindrical workpart 200 mm in diameter
and 700 mm long is to be turned in an
engine lathe. Cutting conditions are as
follows: cutting speed is 2.30 m/s, feed is
0.32 mm/rev, and depth of cut is 1.80
mm.
Determine (a) cutting time, and (b)
metal removal rate. 78

79. Cutting Conditions in Turning
Problem 2
A work materials are to be turned to final size of
175 mm length having diameter of 60 mm.
Total length of the work material is 300 mm. A
single point tool having a certain degree of rake
angle is used. The work material rotates at 1400
RPM. The feed is 0.35 mm / revolution.
Final size of the work material is 51 mm.
Calculate:
1. Cutting velocity,
2. Time taken to machine to the length of 55 mm,
3. Total Material removal rate to get 51 mm diameter. 79

80. Milling
Machining operation in which work is fed past a rotating tool with multiple cutting edges
Axis of tool rotation is perpendicular to feed
Creates a planar surface
Other geometries possible either by cutter path or shape
Other factors and terms:
Interrupted cutting operation
Cutting tool called a milling cutter, cutting edges called "teeth"
Machine tool called a milling machine 80

81. Peripheral Milling vs. Face Milling
Cutter axis parallel to surface being machined
Cutting edges on outside periphery of cutter
Face milling
Cutter axis perpendicular to surface being milled
Cutting edges on both the end and outside periphery of the cutter 81

82. METHODS OF MILLING-1
1) Up milling is also referred to as conventional milling. The direction of the cutter rotation opposes the feed motion. For example, if the cutter rotates clockwise , the workpiece is fed to the right in up milling. 82

83. METHODS OF MILLING-2
2) Down milling is also referred to as climb milling. The direction of cutter rotation is same as the feed motion. For example, if the cutter rotates counterclockwise , the workpiece is fed to the right in down milling 83

84. Slab Milling
Basic form of peripheral milling in which the cutter width extends beyond the workpiece on both sides 84

85. Slotting
Width of cutter is less than workpiece width, creating a slot in the work 85

86. Conventional Face Milling
Cutter overhangs work on both sides 86

87. Profile Milling
Form of end milling in which the outside periphery of a flat part is cut 87

88. Pocket Milling
Another form of end milling used to mill shallow pockets into flat parts 88

89. Surface Contouring
Ball‑nose cutter fed back and forth across work along a curvilinear path at close intervals to create a three dimensional surface form 89

90. End Milling
Cutter diameter is less than work width, so a slot is cut into part 90

91. Machining Centers
Highly automated machine tool can perform multiple machining operations under CNC control in one setup with minimal human attention
Typical operations are milling and drilling
Three, four, or five axes
Other features:
Automatic tool‑changing
Pallet shuttles
Automatic workpart positioning 91

92. Milling Operation
High speed face milling using indexable inserts (photo courtesy of Kennametal Inc.). 92

93. Cutting Conditions in Milling - 1
The cutting speed is determined at the
outside diameter of a milling cutter.
N = rotational speed, rev/min;  = cutting speed, m/min,
And Do = outside diameter of a milling cutter,mm. 93

94. Cutting Conditions in Milling - 2
The feed, f in milling is usually given as a feed per cutter
tooth; called the chip load, it represents the size of the chip
formed by each cutting edge.
fr = Nnt f
fr = feed rate, mm/min; N = spindle speed, rev/min; nt =
number of teeth on the cutter; f = chip load in mm/tooth 94

95. Cutting Conditions in Milling - 2
The feed, f in milling is usually given as a feed per cutter
tooth; called the chip load, it represents the size of the chip
formed by each cutting edge.
fr = Nnt f
fr = feed rate, mm/min; N = spindle speed, rev/min; nt =
number of teeth on the cutter; f = chip load in mm/tooth 95

96. Cutting Conditions in Milling - 3
The material removal rate,
MRR = wdfr
w = width; d = depth of cut; fr = feed rate, mm/min; 96

97. Peripheral Milling 97

98. Cutting Conditions in Milling - 4
Approach distance A, to reach full cutter depth given by:
d = depth of cut, mm, and D = diameter of the milling cutter, mm 98

99. Cutting Conditions in Milling - 5
The time to mill the workiece Tm is
therefore; 99

100. Face Milling – cutter is centered
100

101. Cutting Conditions in Milling - 6
Where A and O are each to half the cutter
diameter;
A = O = D/2
D= cutter diameter, mm
101

102. Face Milling – cutter is offset
102

103. Cutting Conditions in Milling - 7
Where A and O are each to half the cutter
diameter;
w= width of the cut, mm
103

104. Cutting Conditions in Milling - 8
The time to mill the workiece in face
milling,Tm is therefore;
104

105. Cutting Conditions in Milling
Problem 1
A peripheral milling operation is performed
on the top surface of a rectangular
workpart which is 400 mm long by 60 mm
wide. The milling cutter, which is 80 mm in
diameter and has five teeth, overhangs the
width of the part on both sides. The cutting
speed is 70 m/min, the chip load is 0.25
mm/tooth, and the depth of cut is 5.0 mm.
Determine (a) the time to make one pass
across the surface, and (b) the maximum
material removal rate during the cut.
105

106. Cutting Conditions in Milling
Problem 2
A face milling operation is performed to finish
the top surface of a steel rectangular work
piece 350 mm long by 55 mm wide. The milling
cutter has four teeth (cemented carbide inserts)
and a 85 mm diameter. Cutting conditions are:
v = 600 m/min, f = 0.35 mm / tooth, and d =
3.5 mm.
Determine:
a) the time to make one pass across the surface.
b) the metal removal rate during the cut.
106

107. Drilling Creates a round hole in a workpart
Compare to boring which can only enlarge an existing hole
Cutting tool called a drill or drill bit
Machine tool: drill press

108. Through Holes vs. Blind Holes
Through‑holes - drill exits opposite side of work
Blind‑holes – does not exit work opposite side
Two hole types: (a) through‑hole, and (b) blind hole.

109. Reaming
Used to slightly enlarge a hole, provide better tolerance on diameter, and improve surface finish

110. Tapping Used to provide internal screw threads on an existing hole
Tool called a tap

111. Counterboring
Provides a stepped hole, in which a larger diameter follows smaller diameter partially into the hole

112. Cutting Conditions in Drilling - 1
Letting N represent the spindle rev/min,
 = cutting speed, m/min; D = the drill diameter,mm.
112

113. Cutting Conditions in Drilling - 2
Feed can be converted to feed rate using the the same
equation as for turning:
fr = Nf
fr = feed rate, mm/min; N = spindle speed, rev/min; f = feed
in drilling, mm/rev
113

114. Cutting Conditions in Drilling - 3
The time to drill through holes;
Tm= machining time, min; t = work thickness,
mm; fr = feed rate, mm/min
114

115. Cutting Conditions in Drilling - 4
The allowance is given by;
A = approach allowance, mm;  = drill point angle
115

116. Cutting Conditions in Drilling - 5
The time to drill blind holes;
Tm= machining time, min; d = hole depth,
mm; fr = feed rate, mm/min
116

117. Cutting Conditions in Drilling
Problem 1
A drilling operation is to be performed with a
12.7 mm diameter twist drill in a steel
workpart. The hole is a blind hole at a depth of
60 mm and the point angle is 118. The cutting
speed is 25 m/min and the feed is 0.30
mm/rev.
Determine
(a) the cutting time to complete the drilling
operation, and
(b) metal removal rate during the operation, after the drill bit reaches full diameter.
117

118. CUTTING TOOL TECHNOLOGY
Tool Life
Tool Materials
Tool Geometry
Cutting Fluids

119. Cutting Tool Technology
Two principal aspects:
Tool material
Tool geometry

120. Three Modes of Tool Failure
Fracture failure
Cutting force becomes excessive and/or dynamic, leading to brittle fracture
Temperature failure
Cutting temperature is too high for the tool material
Gradual wear
Gradual wearing of the cutting tool

121. Preferred Mode: Gradual Wear
Fracture and temperature failures are premature failures
Gradual wear is preferred because it leads to the longest possible use of the tool
Gradual wear occurs at two locations on a tool:
Crater wear – occurs on top rake face
Flank wear – occurs on flank (side of tool)

122. Tool Wear
Figure Diagram of worn cutting tool, showing the principal locations and types of wear that occur.

123. Figure Crater wear, (above), and flank wear (right) on a cemented carbide tool, as seen through a toolmaker's microscope (photos by K. C. Keefe, Manufacturing Technology Lab, Lehigh University).

124. FLANK WEAR and BUE

125. CRATER WEAR

126. BUILT UP EDE

127. Taylor Tool Life Equation
Relationship is credited to F. W. Taylor
where v = cutting speed; T = tool life; and n and C are parameters that depend on feed, depth of cut, work material, tooling material, and the tool life criterion used
n is the slope of the plot
C is the intercept on the speed axis at one minute tool life

128. Tool Life Criteria in Production
Complete failure of cutting edge
Visual inspection of flank wear (or crater wear) by the machine operator
Fingernail test across cutting edge
Changes in sound emitted from operation
Chips become ribbon-like, stringy, and difficult to dispose of
Degradation of surface finish
Increased power
Workpiece count
Cumulative cutting time

129. Tool Materials
Tool failure modes identify the important properties that a tool material should possess:
Toughness ‑ to avoid fracture failure
Hot hardness ‑ ability to retain hardness at high temperatures
Wear resistance ‑ hardness is the most important property to resist abrasive wear

130. Quiz
In a machining operation that approximates orthogonal cutting, the
cutting tool has a rake angle = 20. The chip thickness before the cut
to = 0.80 mm and the chip thickness after the cut tc = 1.35 mm.
Calculate the shear plane angle and the shear strain in the operation.
 = tan( - ) + cot 
BDA 3052 Manufacturing Technology

131. Kuiz 3) Determine time processing for face milling
1) Determine time processing to drill through hole
2) Determine approach distance A in peripheral milling process
3) Determine time processing for face milling
BDA 3052 Manufacturing Technology