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International Journal of Machine Tools & Manufacture 48 (2008) 195–208
Mechanics of high speed cutting with curvilinear edge tools
Yigit Karpat1, Tugrul Ozel�
Department of Industrial and Systems Engineering, Rutgers University, Piscataway, NJ 08854, USA
Received 26 April 2007; received in revised form 8 August 2007; accepted 16 August 2007
Available online 25 August 2007
Abstract
High speed cutting is advantageous due to the reduced forces and power, increased energy savings, and overall improved productivity
for discrete-part metal manufacturing. However, tool edge geometry and combined cutting conditions highly affects the performance of
high speed cutting. In this study, mechanics of cutting with curvilinear (round and oval-like) edge preparation tools in the presence of
dead metal zone has been presented to investigate the effects of edge geometry and cutting conditions on the friction and resultant tool
temperatures. An analytical slip-line field model is utilized to study the cutting mechanics and friction at the tool-chip and
tool–workpiece interfaces in the presence of the dead metal zone in machining with negative rake curvilinear PCBN tools. Inserts with six
different edge designs, including a chamfered edge, are tested with a set of orthogonal cutting experiments on AISI 4340 steel. Friction
conditions in each different edge design are identified by utilizing the forces and chip geometries measured. Finite-element simulations
are conducted using the friction conditions identified and process predictions are compared with experiments. Analyses of temperature,
strain, and stress fields are utilized in understanding the mechanics of machining with curvilinear tools.
r 2007 Elsevier Ltd. All rights reserved.
Keywords: Round edge tools; Friction factor; Dead metal zone; Cutting; Slip line field analysis
1. Introduction
The design of cutting edge geometry and its influence onmachining performance have been a research topic in metalcutting for a long time. Emerging machining techniquessuch as hard turning, hard milling, and micromechanicalmachining where the uncut chip thickness and the tool edgedimension are in the same order of magnitude requirecutting edges which can withstand high mechanical andthermal stresses, hence wear, for a prolonged machiningtime. It is known that sharp tools are not suitable for suchmachining operations, therefore, tool manufacturers in-troduced different types of tool edge preparations such aschamfered, double chamfered, chamfer+hone, honed, andwaterfall hone (oval-like) edge designs. Chamfered toolsare usually used in roughing and interrupted turning. Thestable trapped material (dead metal zone—DMZ or cap) in
front of the chamfered cutting edge increases the strengthof the tool tip; however, it also increases cutting forces.Honed tools are employed in finish turning operationssince the application of hone to the tool tip increases theimpact resistance. Waterfall hone edge geometry combinesthe appropriate characteristics of chamfered and honedtools such as increased tool tip strength and increased rakeangle. Its oval-like geometry eases the flow of workmaterial in front of the tool.The proper selection of edge preparation (edge radius,
chamfer angle, and height) can be possible once thebehavior of material flow around the cutting edge is wellunderstood. The effect of edge preparation on themechanics of cutting has been investigated by manyresearchers by using various methods such as analytical[1–7], computational [8–12], and experimental [13–16]methods. The initial motivation of studying the effects ofedge preparation was to understand the ploughingphenomena [1,13,17]. A tertiary shear zone at thetool–workpiece interface was believed to be responsiblefor additional cutting forces. In an early study, Mayer andStauffer [18] compared the performance of the honed and
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0890-6955/$ - see front matter r 2007 Elsevier Ltd. All rights reserved.
doi:10.1016/j.ijmachtools.2007.08.015
�Corresponding author. Tel.: +1732 445 1099; fax: +1 732 445 5467.
E-mail addresses: ykarpat@bilkent.edu.tr (Y. Karpat),
ozel@rci.rutgers.edu (T. Ozel).1Present address: Industrial Engineering, Bilkent University, Turkey.
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chamfer tool inserts with sharp tools during non-inter-rupted machining of AISI 1045 steel. They found that theincreasing hone radius and chamfer width and angle resultsin increased forces and decreased tool life.
In modeling the mechanics of cutting in the stagnantmetal zone by using analytical techniques, two majorapproaches have been proposed. The first approach isbased on the existence of a stagnation point on the toolround edge where the material flow is diverted upwardsand downwards [5,7]. The second approach considers astable build up of material in front of the tool edge like aDMZ which diverts material flow [4]. Waldorf [19]compared these two approaches for AL 6061-T6 aluminumand AISI 4340 steel, and concluded that the model withstable build up describes experimental results better. Stabletrapped work material zone formation was observed byKountanya et al. [20] for honed tools. As for stagnationpoint based approaches, Manjunathaiah et al. [5] utilizedequivalent chamfer geometry for the honed tool byidentifying the stagnation point on the tool. Fang [7]presented a detailed slip-line field analysis for rounded-edge tools based on stagnation point assumption. LaterFang and Wu [21] compared honed and chamfered edgesduring machining of aluminum alloys. All the workmentioned above, especially the ones based on stagnationpoint assumption, considered cutting tools with a positiverake angle. Recently, Ranganath et al. [22] investigated theeffects of edge radius for machining of cast iron. Honedcutting tools with various edge radii and rake angles weretested. Proposed mechanistic model based on stagnationpoint assumption successfully captured the effect of honeradius on cutting forces during cutting with positive rakeangle tools, however high prediction errors were obtainedat zero and negative rake angle cutting conditions. In thisstudy, DMZ assumption is adopted due to the fact thatnegative rake tools are used.
Complex material flow around honed tools, especially infinish machining conditions, can be modeled and simulatedwith finite element modeling (FEM) techniques. In FEM
models, workpiece material properties and the edgegeometry of the cutting tool can be defined and processvariables such as forces, temperature distributions, stresses,etc. can be obtained. Kim et al. [8] studied the effects ofhoned edge preparation on the forces and temperatures inorthogonal cutting by using finite element analysis andshowed that tool edge radius influences field variables suchas temperature distributions and strain rate. They observedincreasing cutting forces and temperatures, decreasingmaximum effective strain rate with increasing edge radius.In another finite-element simulation based study, Yen et al.[11] observed the effect of various tool edge geometries onthe field variables. They also observed increasing averagerake face temperature in the tool, increasing effective straindistribution in the chip and workpiece with increasing edgeradius. Recently Chen et al. [12] investigated the perfor-mance of honed and chamfered PCBN cutting tools forhard turning of AISI 52100 steel. They concluded that theoptimum selection of edge preparation depends onmachining parameters.It must also be noted that the correct definition of
friction conditions are crucial in order to obtain mean-ingful results from the finite-element models. Sartkulvanichet al. [23] performed a sensitivity analysis and showed theeffect of friction and flow stress models on the outputs of2D cutting finite element simulations. Ozel [24] investigatedthe tool–chip interfacial frictional models by using FEMand concluded that when frictional properties and work-piece material behavior are properly modeled, FEMmodels can offer accurate and viable predictions.The goal of this work is to understand the mechanics of
high speed machining and complex material flow aroundthe curvilinear (rounded) cutting edge tools. Orthogonalcutting tests and slip-line modeling is performed to identifyfriction factors and DMZ angles. A cutting speed range of125–175m/min is selected for the cutting tests that isconsidered transition to the high speed machining rangefor AISI 4340 steel [32]. Recommended cutting speeds bythe cutting tool suppliers are much more conservative.
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Nomenclature
A plastic equivalent strain in Johnson–Cookconstitutive model (MPa)
B strain related constant in Johnson–Cook con-stitutive model (MPa)
C strain-rate sensitivity constant in Johnson–Cook constitutive model
Fc , Ft cutting and thrust force components (N)k shear flow stress (N/mm2)m thermal softening exponent in Johnson-Cook
constitutive modelm1, m2, m3 friction factorsn strain-hardening parameter in Johnson–Cook
constitutive model
re edge radius of the tool (mm)Tm melting temperature of the work material (1C)tu , tc uncut and cut chip thickness (mm)
V, Vs, Vch cutting velocity, shear velocity, and chipvelocity (m/s)
w width of cut (mm)a dead metal zone angle (degree)f shear angle (degree)t frictional shear stress (N/mm2)g1, g2 rake and chamfer angle (degree)z1, z2, z3 slip-line angles (degree)r prow angle (degree)d, y slip-line central fan angles (degree)
Y. Karpat, T. Ozel / International Journal of Machine Tools & Manufacture 48 (2008) 195–208196
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These two cutting speeds represent two values towardhigher end of the recommended cutting speeds. Further-more, selecting very high cutting speeds (anything above200m/min) is avoided in order to be able to use plasticitybased slip-line field analysis and Johnson–Cook materialmodel for FEA. The performances of honed and waterfallhone type of edges is compared in terms of cutting forces,temperature, and stress distributions. The basic geome-trical comparison of round hone (re) and waterfall hone(re/2: re) is given in Fig. 1. In the waterfall hone edge design,the ratio of the side of the edge to its top is usually taken as1:2. Current edge preparation technology can provideabout 0.005mm (0.000200) repeatability for the curvilinearedges (hone and waterfall hone) for CBN tools [33]. That ispossible because the high resistance to wear presented bythe CBN. On this superhard material the edge erosion isslow enough that edge preparation process be controlledmuch closer than if it were ceramic or carbide cutting toolmaterial [33].
2. Slip line modeling for machining with curvilinear edge
tools
Slip line filed analysis based on plasticity theory has beenused to model orthogonal metal cutting as reviewed inChilds et al. [25] and Fang et al. [26]. Abebe and Appl [27]proposed a slip-line field model for machining with largenegative rake angle tools by considering stagnant metalzone in front of the cutting tool. Waldorf et al. [4] proposeda slip-line model to study ploughing and tool wearmechanisms in round edge cutting tools. Fang et al. [26]presented a universal slip-line field model in the case ofcurled chip formation for machining with restricted contacttools. Later Fang [7] presented slip-line models formachining with round edge tools. The slip-line model forhone and waterfall hone and associated hodograph areillustrated in Fig. 2. The chip is assumed to be straight inorder to simplify the model. The slip-line angles z1, z2, andz3 denote the friction conditions on the surfaces AD, DFand FC where the tool rake face is in contact with the chipalong FC.
The geometry of DMZ will be calculated according tohoned (re) or waterfall hone (re/2:re) radii. The shear angleis represented with f, the angle formed by the bottomboundary of the DMZ with the cutting direction is DMZangle a, cut chip thickness tc, tool–chip contact length onthe rake face FC, tool–chip friction at the rake facem3 ¼ tFC/k, and friction factor on the front boundary ofDMZ m2 ¼ tDF/k are calculated according to given uncutchip thickness tu, friction factor under DMZ m1 ¼ tAD/k,hydrostatic pressure at point E pE, and tool geometry,i.e. hone radius re or waterfall re/2:re, and rake angle g2.It is assumed that the work material above point D flows
upward into the chip, and the work material under point Dflows downward into the workpiece. The inclination of theworkpiece material ahead of the tool is also considered as
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Fig. 1. Waterfall hone (re/2:re) and round hone (re) type of edge
preparations.
Fig. 2. Slip-line model for machining with: (a) round hone, (b) waterfall
hone type of edge preparations, and (c) their hodograph.
Y. Karpat, T. Ozel / International Journal of Machine Tools & Manufacture 48 (2008) 195–208 197
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represented by prow angle r which is given as [28]
r ¼ sin�1sin að Þffiffiffi2p
sin ðz1Þ
� �(1)
In this slip-line model, cut chip thickness tc and cuttingforces Fc and Ft can be calculated according to uncut chipthickness tu, tool–chip friction factor under DMZ m1
¼ tAD/k, shear angle f, DMZ angle a, and tool geometry(hone radius re or waterfall re/2:re, negative rake angle g2).The variable t denotes frictional shear stress and k is thematerial shear flow stress. The value of friction factor t/k
varies between 0 and 1 where a value of zero means nofriction occurs and a value of one means stickingconditions occur. The following expressions can be writtenfrom slip-line theory:
z1 ¼1
2cos�1
tAD
k
� �, (2)
z2 ¼1
2cos�1
tDF
k
� �, (3)
z3 ¼1
2cos�1
tFCk
� �, (4)
pE ¼ k 1þ 2p4� f� r
� �� �. (5)
where the expression in the parenthesis in Eq. (5) is equal toslip line field angle y;
y ¼p4� f� r, (6)
and central fan angle d, the angle ADF (D) can becalculated as
d ¼ fþ z1 � a, (7)
D ¼p2þ
y2þ z1 þ z2 � d. (8)
In order to simplify the problem, the DMZ is assumed tobe extending from the rake face which enables us to relateslip line angle z1 to slip line angles z2 and z3 as
z2 ¼ z1 þ g2 þf2þ
r2�
p8, (9)
z3 ¼ f� yþ g2. (10)
The cut chip thickness tc can be calculated as
tc ¼ DE sin p=2� f� g2� �
, (11)
where
DE ¼tu
sin fð Þ. (12)
For honed edge preparation, the distances AD and DFcan be expressed as
AD ¼re cos að Þ � sin g2
� �cos að Þ � sin að Þ cos g2
� �cos aþ g2� � ,
DF ¼re 1� sin g2� �cos aþ g2� � . ð13Þ
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Fig. 4. SEM images of: (a) waterfall hone and (b) round hone type of edge
preparations at 50� magnification.
CBN insert
Dynamometer
Workpiece with thin webs
Fig. 3. Experimental setup for orthogonal turning.
Y. Karpat, T. Ozel / International Journal of Machine Tools & Manufacture 48 (2008) 195–208198
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For waterfall hone edge preparation, the distances ADand DF can be expressed as
AD ¼ðre=2Þ
cos aþ g2� � ,
DF ¼ re 2� tan aþ g2� �
. ð14Þ
The cutting force and thrust force are written as
Fc ¼ kw DE cos fð Þ þ 1þ 2yð Þ sin fð Þ½ ��þAD cos að Þ cos 2z1ð Þ þ 1þ 2yþ 2dþ sin 2z1ð Þð Þ½
� sin að Þ��,
F t ¼ kw DE 1þ 2yð Þ cos fð Þ � sin fð Þ½ ��
,
þAD 1þ 2yþ 2dþ sin 2z1ð Þð Þ½
�cos að Þ � sin að Þ cos 2z1ð Þ��, ð15Þ
where w is the width of cut. The ratio of cutting force tothrust force Fc/Ft can be calculated from Eq. (15) withoutnecessarily knowing shear flow stress k at the primary shearzone. In Eq. (15), the first term on the right hand side
represents shearing and the second term representsploughing forces due to DMZ.Identification of the unknown slip line angle y, DMZ
angle a, and friction factors are performed by utilizingorthogonal cutting tests where cutting forces and chipthicknesses are measured for various cutting conditionsand matching those with slip line field calculations by usinga Matlab code. The unknown slip-line angle pair (y, a) aresolved as a set of possible solutions depending on thetolerance value allowed between measured and calculatedforce (Fc/Ft) and chip ratios (tc/tu) for a known frictionfactor m1 as follows:
DE ¼
ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiF c
F t
� �ex
�F c
F t
� �calc
�2þ
tc
tu
� �ex
�tc
tu
� �calc
�2spTol.
(16)
Hence, by using a computational procedure, frictionfactors on tool–chip interface, slip-line angle y, friction
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Table 1
Cutting conditions used in experiments and simulations (marked by X)
Uncut chipthickness tu(mm)
Tool type
Honed re ¼ 40 mm Honed re ¼ 50mm Waterfall 20:40mm Waterfall 25:50mm
0.075
0.1 X X X X
0.125 X
0.15 X X X X
0.18
0
100
200
300
400
500
600
700
800
900
0.075 0.1 0.125 0.15 0.18
Cu
ttin
g F
orc
e F
c, (N
/mm
)
Chamfer
Waterfall 30-60
Hone 50
Waterfall 25-50
Hone 40
WF 20-40
0
100
200
300
400
500
600
700
800
0.075 0.1 0.125 0.15 0.18
Cu
ttin
g F
orc
e, F
c, (N
/mm
)
Chamfer
Waterfall 30-60
Hone 50
Waterfall 25-50
Hone 40
WF20-40
0
100
200
300
400
500
600
700
0.075 0.1 0.125 0.15 0.18
Th
rust
Fo
rce F
t, (
N/m
m)
ChamferWaterfall 30-60Hone 50Waterfall 25-50Hone 40WF 20-40
0
100
200
300
400
500
600
700
0.075 0.1 0.125 0.15 0.18
Th
rust
Fo
rce (
Ft)
, (N
/mm
)
Chamfer
Waterfall 30-60
Hone 50
Waterfall 25-50
Hone 40
WF20-40
Uncut Chip Thickness (mm) Uncut Chip Thickness (mm)
Uncut Chip Thickness (mm) Uncut Chip Thickness (mm)
V=175 m/minV=175 m/min
V=125 m/minV=125 m/min
Fig. 5. Measured cutting forces Fc: (a) V ¼ 125m/min and (b) V ¼ 175m/min. Measured thrust forces Ft: (c) V ¼ 125m/min and (d) V ¼ 175m/min.
Y. Karpat, T. Ozel / International Journal of Machine Tools & Manufacture 48 (2008) 195–208 199
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factor on the rake face m1, and DMZ angle a wereidentified.
3. Experimental setup and results
Orthogonal turning of thin webs (2.5–2.8mm) wereperformed on annealed AISI 4340 steel using CBN cuttingtool inserts (TNG-423) with five different hone andwaterfall hone and a chamfered edge design (201 chamferangle and 0.1mm chamfer height) in a rigid CNC turningcenter as illustrated in Fig. 3. The tool holder provided anegative 71 rake angle; hence a negative 271 angle is formedat the chamfer face. The images of the round and waterfall
(oval-like) edge preparation of the CBN insert taken byfield emission scanning electron microscopy (FESEM) isgiven in Fig. 4. In the experiments straight edges oftriangular inserts were used (see Fig. 4). Forces weremeasured with a Kistlers turret type force dynamometer, aPC-based DAQ system and Kistlers DynoWare software,and cut chip thicknesses were measured by using atoolmaker’s microscope.In cutting tests, two different cutting speeds are selected
as 125 and 175m/min. Experiments are replicated twotimes. The cutting conditions are summarized in Table 1.Same cutting conditions used for waterfall hone 30:60 mmare used for chamfered inserts. Uncut chip thickness valuesused in the experiments are selected in accordance withedge radius of the cutting tool. The thrust and cutting forcemeasurements are shown in Fig. 5. Orthogonal cutting
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Table 2
Comparison of identified slip-line angles of honed and waterfall hone edge
preparations for V ¼ 125m/min
tu (mm) a y m1 m2 m3 tc
V ¼ 125m/min
Hone 40 0.075 5.73 13.51 0.525 0.68 0.836 0.165
0.1 5.4 13.49 0.573 0.68 0.834 0.22
0.125 5.17 13.11 0.581 0.66 0.813 0.265
Hone 50 0.1 6.07 13.83 0.423 0.688 0.84 0.22
0.125 5.68 13.51 0.49 0.675 0.829 0.27
0.15 5.84 13.7 0.397 0.671 0.827 0.32
WF 2040 0.075 4.65 16.11 0.32 0.71 0.88 0.165
0.1 4.68 15.54 0.448 0.7 0.87 0.22
0.125 4.43 15.36 0.4 0.69 0.85 0.265
WF 2550 0.1 4.316 15.21 0.57 0.7 0.86 0.22
0.125 3.85 15.2 0.6 0.69 0.85 0.26
0.15 3.52 14.73 0.7 0.68 0.84 0.305
WF 3060 0.1 4.674 15.51 0.455 0.7 0.87 0.22
0.15 3.55 14.71 0.635 0.668 0.835 0.31
0.18 2.92 14.22 0.745 0.654 0.82 0.365
0.9
0.95
1
1.05
1.1
1.15
1.2
1.25
Fo
rce R
ati
o (
Fc/F
t)
WF 25-50
WF 30-60
Hone 50
1
1.05
1.1
1.15
1.2
1.25
1.87 2 2.5 3 3.12
Fo
rce R
ati
o
V=125 m/min V=175 m/min
0.1 0.15
Uncut Chip Thickness (mm)
Ratio of Uncut Chip Thickness to Edge Radius
Fig. 6. (a) Comparison of force ratio Fc/Ft for waterfall and honed edge
preparations. (b) Force ratio Fc/Ft versus ratio of uncut chip thickness to
edge radius.
0.78
0.79
0.8
0.81
0.82
0.83
0.84
0.85
2 3
Ra
ke
Fa
ce
Fri
cti
on
Fa
cto
r
V=125 m/min V=175 m/min
1.87
Ratio of Uncut Chip Thickness to Edge Radius
2.5 3.12
Fig. 7. Variation of rake face friction factors with respect to ratio of uncut
chip thickness to edge radius.
Table 3
Comparison of identified slip-line angles of honed and waterfall hone edge
preparations for V ¼ 175m/min
tu (mm) a y m1 m2 m3 tc
V ¼ 175m/min
Hone 40 0.075 5.14 13.09 0.6 0.66 0.815 0.16
0.1 5.05 13.03 0.589 0.654 0.808 0.21
0.125 4.88 12.91 0.6 0.647 0.8 0.26
Hone 50 0.1 5.1 13.06 0.577 0.655 0.808 0.21
0.125 5.27 13.19 0.51 0.65 0.807 0.26
0.15 4.61 12.76 0.652 0.642 0.795 0.31
WF 2040 0.075 3.85 15 0.3 0.64 0.82 0.15
0.1 4.27 15.22 0.438 0.68 0.85 0.21
0.125 3.95 14.97 0.457 0.66 0.83 0.255
WF 2550 0.1 4.06 15.03 0.523 0.68 0.847 0.2
0.125 3.72 14.81 0.544 0.66 0.832 0.25
0.15 3.53 14.664 0.55 0.649 0.82 0.3
WF 3060 0.1 4.13 15.083 0.557 0.69 0.855 0.21
0.15 3.25 14.547 0.635 0.648 0.81 0.31
0.18 2.25 14.227 0.845 0.644 0.81 0.36
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forces obtained from chamfered tools are also included inthe figures.
The results have revealed the relationship between edgeradius and cutting forces. The effect of edge preparation oncutting forces, especially on thrust forces, becomes morenoticeable when uncut chip thickness is increased. In termsof measured cutting forces, waterfall hone tools yieldedlower forces than honed and chamfered tools. Waterfallhone with 20:40 mm edge dimension yielded the lowestthrust forces. It is clear from the experimental results thatas edge radius increases, thrust forces increase.
Increasing cutting speed resulted in slightly decreasingcutting forces. Fig. 6(a) represents the variation of forceratio with respect to uncut chip thickness for honed andwaterfall hone edge preparations with 50, 25:50 and30:60 mm edge radius. Due to lower thrust force measure-ments, waterfall hone tools have greater force ratios underthe same cutting conditions. Increasing cutting speedincreased the force ratio because of further decreasingthrust forces. In order to investigate the relationshipbetween the uncut chip thickness and the edge radius, theforce ratio Fc/Ft is plotted against the ratio of uncut chipthickness to edge radius in Fig. 6(b) for two differentcutting speeds. According to these results, as the ratio of
uncut chip thickness to edge radius decreases, force ratioFc/Ft becomes closer to unity.
4. Identification of slip-line and DMZ angles and friction
factors
By using the friction factor identification procedure, rakeface friction factor m3, DMZ angle a, DMZ friction factorm1, and slip-line angle y can be determined. Fig. 7 showsthe relationship between the ratios of uncut chip thicknessto edge radius to the rake face friction factors for differentcutting speeds. According to these results, as the ratio ofuncut chip thickness to edge radius increases, frictionfactor on the rake face decreases. As cutting speedincreases, rake face friction factor decreases.Tables 2 and 3 shows the identified slip-line angles for all
cutting conditions. These results reveal that, waterfall honetools exhibited higher rake face friction factors m3 than
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0
0.02
0.04
0.06
0.08
0.1
0.12
Len
gth
of
DF
(m
m)
Hone 40 WF 20-40WF 25-50 WF 30-60
0
0.05
0.1
0.15
0.2
0.25
0.3
0.1 0.125 0.15
To
ol C
hip
Co
nta
ct
Len
gth
(m
m)
Hone 40WF 20-40WF 25-50WF 30-60
Uncut Chip Thickness (mm)
0.075 0.1 0.125 0.15
Uncut Chip Thickness (mm)
0.075
Fig. 8. Length of front surface of the DMZ and tool chip contact length
for various uncut chip thickness values at V ¼ 125m/min.
0 5000
0.2
0.4
0.6
0.8
1
Fri
cti
on
Facto
r
tu=0.075 mmtu=0.1 mmtu=0.125 mm
Tool Chip
Contact Length
Friction Factor
m=1
FC
DF
Normal Pressure (N/mm2)
30002500200015001000
Fig. 9. Friction definition used in finite-element simulations.
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honed tools. Similar friction factors on the front boundaryof the DMZ m2 were obtained.
DMZ angle a is found to be lower in waterfall honetools. Slip-line angle y in waterfall hone tools are identifiedas greater than honed tools, which indicate a greater tool-chip contact length in waterfall hone tools. Fig. 8 shows thevariation of the tool-chip contact length and the length offront surface of the DMZ (DF in Fig. 3(b)) with respect touncut chip thickness at cutting speed V ¼ 125m/min.These results show that waterfall hone tools have longertool-chip contact length both on the rake face and on theDMZ. Tool-chip contact length is a little less than 2 timesof the uncut chip thickness.
The above given results suggest that oval-like design ofwaterfall hone edge preparation helps transferring theloads acting on the tip of the tool towards the rake face ofthe tool. DMZ covers a greater range of the tool tip whichprotects the cutting tip. According to the identified slip-lineangles given in Tables 2 and 3, honed tool with 40 mm edgeradius and waterfall hone with 20:40 mm edge dimensionsyielded different results. This implies that waterfall honeequivalent of honed tools must have greater edge dimen-sions. Investigation of the influence of various edgepreparations on field variables such as temperatures,effective stresses, and strains, is performed by finite-element simulations.
5. Finite-element analysis
In order to compare field variables such as temperaturedistributions, strains, and maximum effective stresses in thetool, finite-element simulations were performed by usingcommercial software DEFORM-2Ds. Johnson-Cook [29]work material constitutive constants for AISI-4340 steelA ¼ 1504MPa, B ¼ 569MPa, n ¼ 0.22, C ¼ 0.003, andm ¼ 1.17 was adapted from Gray et al. [30] and used insimulations under rigid–plastic material deformation con-ditions. As mentioned before, friction definition is crucialin order to obtain reasonable simulations in finite-elementanalysis [24]. Fig. 9(a) shows how the friction factors aredefined as a function of normal pressure at the tool–chipinterface for various uncut chip thickness values in thisstudy. In Fig. 9(b), DF represents the region where thefriction factor will be equal to one (sticking zone) and FCdenotes the tool chip contact length where the frictionfactor will decrease with decreasing normal pressure on thetool rake face (Fig. 9(a)). It must be noted that normalstress distribution on the rake face is a function of tooledge geometry and cutting conditions.In order to simulate serrated chips which were observed
during large uncut chip thickness experiments, a damagemodel proposed by Cockcroft and Latham [31] isemployed. The critical damage coefficient is determined
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Fig. 11. Tool temperature distributions for V ¼ 175m/min, tu ¼ 0.15mm.
22.2
2.42.62.8
33.23.4
3.63.8
Str
ain
600
620
640
660
680
700
720
740T
em
pe
ratu
re(C
)Strain Temperature
560
580
600
620
640
660
680
700
To
ol T
ip T
em
pera
ture
(C
)
2400
2450
2500
2550
2600
2650
2700
2750
2800
Max. E
ffecti
ve S
tress (
MP
a)
Tool Tip Temperature
Max Effective Stress (MPa)
Edge Micro-Geometry
Hone 50 Hone 40 WF 2040 WF2550 WF3060
Edge Micro Geometry
Hone 50 Hone 40 WF 2040 WF2550 WF3060
Fig. 10. (a) Strains and temperatures on the machined workpiece surface.
(b) Tool tip temperatures and maximum effective stresses at the cutting
condition V ¼ 175m/min, tu ¼ 0.15mm.
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by trial and error and kept constant in all simulations.Fig. 10(a) illustrates the variation of the strains andtemperatures on the machined workpiece surface forvarious edge preparations at the cutting conditionV ¼ 175m/min and tu ¼ 0.15mm. Fig. 10(b) demonstratesthe variation of maximum effective stresses on the tool andtool tip temperatures at the same cutting condition. Itcan be seen from these results that as edge radius increases,
strains and temperatures on the machined surfaceincreases. Surface integrity of workpiece, i.e. residualstresses and surface roughness, is directly related to strainsand temperature distributions on the machined workpiecesurface. There are certain advantages of using small honeradius in terms of obtaining good surface roughness;however, using relatively larger edge radius may producecompressive residual stresses on the workpiece. Tool tip
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Fig. 12. Effective stress (in MPa) distributions in honed and waterfall hone tools for V ¼ 175m/min, tu ¼ 0.15mm.
Fig. 14. Tool temperature (in 1C) distributions for V ¼ 125m/min, tu ¼ 0.1mm.
Fig. 13. Strain distributions in honed and waterfall hone tools for V ¼ 175m/min, tu ¼ 0.15mm.
Y. Karpat, T. Ozel / International Journal of Machine Tools & Manufacture 48 (2008) 195–208 203
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temperatures tend to decrease with increasing edge radius.The reason for decreasing tool tip temperatures may beexplained with increased surface area for heat transfer asedge radius increases. However, when edge radius is notselected according to uncut chip thickness, i.e. machining asmall uncut chip thickness with a large hone; temperaturesare localized at the tip of the tool which leads to rapid toolwear. According to the results given in Figs. 10(a) and (b),waterfall hone with 20:40 mm edge dimension seems like themost suitable edge preparation among other edge prepara-tions when only workpiece is considered. Waterfall honewith 30:60 mm edge dimensions can be selected when only
cutting tool is considered. For all edge preparations, rakeface temperatures were found to be around 800 1C. Fig. 11shows the finite element simulation results of temperaturedistributions in the cutting tool.In Fig. 11, it can be seen that rake face temperature
distributions are distributed more evenly in waterfall honetools than honed tools because of longer tool–chip contact.The lowest tool tip temperature is obtained in waterfallhone 30:60 mm edge dimension tool. Larger tool tipsurface area helps distribution of heat energy around thetool tip. Fig. 12 represents the distribution of effectivestresses on the tool. The effect of the edge shape on
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Fig. 15. Effective stress (in MPa) distributions in honed and waterfall hone tools for V ¼ 125m/min, tu ¼ 0.1mm.
Fig. 16. Strain distributions in honed and waterfall hone tools for V ¼ 125m/min, tu ¼ 0.1mm.
Fig. 17. Effective stress (in MPa) distributions in round hone tools.
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effective stress distributions can be clearly seen in thisfigure. The locations of maximum stresses are found to becloser to the tool tip for waterfall hone tools. Fig. 13 showsthe chip shape and strain distributions for all edgepreparations. As mentioned before, serrated chips wereobserved at high uncut chip thicknesses. The simulatedchip shapes are in good agreement with the FESEM imagesobtained from chips collected during machining tests (Figs.19–22). It is obvious from these images that as edge radiusincreases the degree of serration also increases under thesame cutting condition. Increasing edge radius works like
increasing negative rake angle which causes further plasticdeformations on the chip and yields more serration.Because of its cyclic nature, serrated chips producefluctuations in forces depending on the degree of serration.Fluctuating forces are known to cause vibrations and mayyield poor surface finish. In order to investigate the effectof decreasing cutting speed and decreasing uncut chipthickness, finite-element simulations were performedat the cutting condition of V ¼ 125m/min andtu ¼ 0.1mm. Fig. 14 shows that waterfall hone with20:40 mm edge dimensions yielded favorable tempe-
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Fig. 18. Dead metal zone formation for honed and waterfall edge preparations.
Table 4
Predicted and measured cutting forces and chip thicknesses
Insert type V (m/min) tu (mm) Meas. Fc
(N/mm)
Meas. Ft
(N/mm)
Pred. Fc
(N/mm)
Pred. Ft
(N/mm)
Error %
Fc
Error % Ft Meas. tc(mm)
Pred. tc(mm)
Hone 40 125 0.1 493 444 512 370 3.8 16.6 0.22 0.22
Hone 50 125 0.1 489 478 485 355 0.8 25.7 0.22 0.23
WF 20-40 125 0.1 484 435 491 330 1.4 24 0.225 0.23
WF 25-50 125 0.1 484 423 480 340 0.8 19 0.23 0.23
WF 30-60 125 0.1 487 457 486 325 0.2 28 0.235 0.23
Hone 50 175 0.15 666 543 660 430 0.9 20 0.31 0.3
WF 25-50 175 0.15 624 481 632 400 1.28 16 0.295 0.3
WF 30-60 175 0.15 653 515 641 405 1.8 21 0.3 0.3
Fig. 19. Chip formation for honed edge preparations for V ¼ 125m/min, tu ¼ 0.1mm.
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Fig. 20. Chip formation for waterfall hone edge preparations for V ¼ 125m/min, tu ¼ 0.1mm.
Fig. 21. Chip formation for waterfall hone edge preparation for V ¼ 125m/min, tu ¼ 0.1mm with two magnification levels.
Fig. 22. Chip formation for honed and waterfall edge preparations for V ¼ 175m/min, tu ¼ 0.15mm.
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rature distributions compared to others. Fig. 15 representsthe stress distributions at the cutting condition ofV ¼ 125m/min and tu ¼ 0.1mm. The stress distributionsare similar to those obtained for V ¼ 175m/min andtu ¼ 0.15mm with lower stress values. In a more detailedanalysis, the stress distributions in the honed tool forvarious uncut chip thicknesses are shown in Fig. 16. Asexpected, the effective stresses increase with increasinguncut chip thickness. Fig. 16 illustrates the simulated chipshapes for low uncut chip thickness cutting conditionwhere the degree of serration is lesser than for large uncutchip thickness machining case. Stagnant metal zone isillustrated by plotting velocity profiles of finite-elementsimulations for different cutting conditions in Figs. 17and 18. Stagnant metal zone covers the tool tip in allcutting cases.
Finally, the comparison of measured and predictedcutting forces and chip thicknesses are given in Table 4and Figs. 19–22. Finite element simulations yielded verygood predictions in terms of cutting forces Fc and cut chipthickness tc values, however thrust forces Ft were underpredicted by the finite element software.
6. Conclusions
In this paper, the tool–chip friction characteristics ofcurvilinear edge tools are investigated by utilizing ortho-gonal cutting tests, slip-line field analysis, and finite-element simulations. Orthogonal cutting tests were usedto identify slip-line angles which yielded tool–chip frictioncharacteristics of curvilinear edge cutting tools. Finite-element simulations, which make use of the friction factorfindings of the slip-line field analysis, are used to studytemperature, strain, and stress distributions in the cuttingtools. Proposed methodology introduces a scientific app-roach to model friction in finite-element simulations andyielded good results in terms of simulated cutting forcesand chip shapes. It has been shown that:
� Size of edge radius is an important factor and it affectsthe mechanics of cutting.� Edge radius must be selected according to cutting
conditions. Large edge radius is not suitable formachining low uncut chip thickness,� The ratio of uncut chip thickness to edge radius around
3 seems to be an appropriate ratio for edge preparationsused in the cutting tests. There must be an upper limit onthis value which considers the rupture strength of theedge preparation. However, due to experimental limita-tions this upper limit was not studied.� There is always a trade-off when it comes to edge radius
selection. The purpose of using cutting tools withcurvilinear edges is to protect the cutting edge fromchipping, to improve its impact resistance, and toincrease surface area for heat transfer from the cuttingzone. However, if the edge radius is not selectedcarefully, that may result in increased cutting forces,
poor surface workpiece quality and short tool lives.When selecting edge radius for a given cutting condition,both machined workpiece surface and cutting tool mustbe considered.� The observation of collected chip shapes revealed that
edge preparation affects chip formation mechanism dueto increased cyclical plastic deformations along the faceof the curvilinear edge.
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