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DESCRIPTION
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the tooth passing frequency used in the milling process (and its harmonics) does not produce high FRF
values.
the wcuttingeverale mate
giloke0 m/mhulz aspeed
Deections must be controlled mainly in nishing operations,
bilityet al.more
Static tool deection (d) is calculated by Eq. (1) (considering
3 4
Contents lists available at SciVerse ScienceDirect
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International Journal of Mac
International Journal of Machine Tools & Manufacture 68 (2013) 1103pE D4E-mail address: [email protected] (A.E. Diniz).L/D ratio of 7 and 10. Their results indicated that tool deection ishigher when the angle between the machined surface and the
L /D is the tools slenderness coefcient (TSC) [9].
d 64F
L3 !
1
0890-6955/$ - see front matter & 2013 Elsevier Ltd. All rights reserved.
http://dx.doi.org/10.1016/j.ijmachtools.2013.01.002
n Corresponding author. Tel.: 55 19 35213303; fax: 55 19 32893722.since they impair surface quality and tool life [10]. Kecelj et al.[11] conducted milling experiments using ball nose mills with an
the tool a cylinder), where F is the cutting force perpendicularto the tool axis, E is the Young modulus of the tools material, anderrors in the machined workpiece [8]. These errors are particu-larly important when a high tool length/diameter ratio (L/D) isused, when the inclination of the machined surface is high andwhen tool wear is signicant [9].
which the depths of cut are small, the process is close to sta[12] and tool behavior is quasi-static [15]. According to Xu[16], under stable cutting conditions, static tool deection issignicant than dynamic deection.Flom and Komanduri [6], cutting forces decrease with increasingcutting speed up to a certain limit. Beyond this point, these forcesgradually increase.
Cutting forces cause deections in the tool/workpiece/toolxation/machine system [7], which cause signicant geometrical
surface, due to the higher radial force of the cut at 751.A well knownmodel for studying tool deection is the one that
considers the tool xed in the chuck as an overhanging cylinder[14]. This model does not include dynamic considerations, but itcan make coherent predictions, since in nish operations, in1. Introduction
Cutting forces directly inuencesurface quality, the system vibration,These forces are inuenced by sgeometry, properties of the workpieccutting strategy, etc. [2,3].
Using a mathematical model, Dathat a cutting speed of up to 120cutting forces. On the other hand, Scthat the force decreases as cutting& 2013 Elsevier Ltd. All rights reserved.
orkpiece precision andpower and tool life [1].factors, such as toolrial, cutting conditions,
et al. [4] demonstratedin does not inuencend Moriwaki [5] statedincreases. According to
horizontal is small, which is caused by the difcult conditions ofchip formation in the tools central region. This occurs particularlywhen low values of depth of cut (ap) are used. These ndingsagree with those of Lopez de Lacalle et al. [9,12], who found thehighest errors in surfaces with inclinations of less than 151. Theauthors attributed these results to the slipping effect of smallchips and to cutting distortion when the central portion of thetool is engaged in cutting. However, Oliveira [13] reported adifferent nding, claiming that the tool which cut a surface with a751 angle in relation to the horizontal line (tool in the verticalposition) presented higher deection than the tool that cut a 451Correlating surface roughness, tool weaprocess of hardened steel using long sl
Marcelo Mendes de Aguiar, Anselmo Eduardo Din
Faculdade de Engenharia Mecanica, CP 6122, Campinas, S ~ao Paulo 13083-860, Brazil
a r t i c l e i n f o
Article history:
Received 5 November 2012
Received in revised form
14 January 2013
Accepted 15 January 2013Available online 31 January 2013
Keywords:
Tool vibration
Tool wear
Surface roughness
High speed milling
a b s t r a c t
High speed milling is an o
However, when it is nece
long tools with small dia
sionals: how to minimize
surface quality and long to
hardened AISI H13 steel w
overhangs and different d
measured and these param
with the tools xed in th
surface roughness allied to
journal homepage: www.eand tool vibration in the millingder tools
, Robson Pederiva
ation frequently used in nishing and semi-nishing of dies and molds.
y to produce molds with deep cavities and/or with small corner radius,
ers are required. This represents a challenge for manufacturing profes-
vibration using a tool with such low rigidity and obtain good workpiece
ives. This paper attempts to answer this question. Milling experiments on
carried out using integral and indexable insert tools with different tool
eters. Tool wear, workpiece surface roughness and cutting forces were
rs were correlated with the frequency response function (FRF) obtained
achine tool. The main conclusion of this study is that good workpiece
g tool lives for long tools with small diameters can be achieved, provided
vier.com/locate/ijmactool
hine Tools & Manufacture
-
(RthLONG) is given by Eq. (3), where fz is the feed per tooth and
M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 1102The machine tool, cutting tool, workpiece and xation devicesform a complex system of structural elements. During cutting, alarge portion of energy is dissipated through these elements, alsoinducing vibration [17].
Vibration may reach unacceptable levels, particularly whenthere is an inherent lack of rigidity in the system, as in the millingof dies and molds, which frequently requires the use of long toolsto machine deep cavities [18]. Therefore, vibration must beminimized due to its harmful inuence on the dimensionalquality and surface texture of the workpiece, on the accelerationof tool wear/damage and on the increased probability of toolbreakage [17,19].
The main types of vibration involved in die and mold millingusing high speed machining (HSM) are forced and self-excitedvibrations [13].
Forced vibrations are those caused by external forces. Theyoccur in all types of machining operations, but are especiallycritical in nishing operations, where shape errors and highvalues of surface roughness are unacceptable. They are even moreharmful when the excitation frequency is close to either thenatural system frequencies or to one of their harmonics, as theymake the cutting unstable [17].
Self-excited vibrations are not caused by external forces, butby forces generated by cutting the material [20]. These vibrationsoccur when the damping capacity of the toolworkpiecemachinesystem is insufcient to absorb the energy transmitted by thecutting [17], generating a self-exciting mechanism duringmachining which causes continuous variations in chip thickness.Initially, one of the structural elements is excited by cutting forcesand a wavy surface generated by the cut produced by one edge isremoved by the next edge, which also leaves a wavy surface dueto structural vibrations [21]. When a phase discrepancy occursbetween the vibration waves left by the cutting edges on thesurface, it produces a regenerative effect that generates evenmore vibration [21]. This phenomenon is known as chatter. Thisis the most harmful type of vibration in HSMmachining processes[17,22].
Vibration can also be controlled by the use of a more rigid tool andtool xation. Oliveira [13] studied the inuence of two grades of toolmaterial and two types of tool shank (carbide and steel) on tool wear,tool life and workpiece surface roughness life in hardened steelmilling. The carbide shank produced better results than the steelshank. This nding was attributed to the higher rigidity of the carbideshank, which decreased its tendency to vibrate.
Several authors [20,23,24] argue that to prevent chatter andachieve good workpiece surface quality, the frequency of thecutting edge entering the cut during each rotation of the tool(tooth passing frequency) must differ from the natural andharmonic frequencies. The natural frequency is inuenced, amongother factors, by the tool overhang (tool length/tool diameterratio), density and Youngs modulus of the tool and tool shankmaterials [20,25].
One of the main goals in nishing operations is to achieve avery low workpiece surface roughness [26]. However, surfaceirregularities, which are always present in all machined parts,depend on several factors. In milling operations, surface qualityimproves at higher cutting speeds. Depth of cut indirectly affectssurface quality, since the cutting force, vibration and cuttingtemperature increase with an increase in the depth of cut. Otherfactors that inuence surface roughness are feed, tool nose radius,tool wear, cutting strategy, the tools trajectory during cutting,workpiece material, cooling/lubrication system and the dynamicparameters of machining, such as cutting force, tool deection,vibration and several thermal phenomena [17,2729].
The use of high cutting speeds and small tool diameters, due to
the small radius of the tool used in cutting dies and molds makesREF is the effective radius of the tool measured at the point wherethe tool touches the workpiece. REF is related to the surfaceinclination, since the higher the angle of inclination the higherthe effective radius [13].
RthLONG f z28nREF
3
However, real roughness values usually differ from theoreticalones [28,29]. Axinte and Dewes [33] observed high values ofsurface roughness generated in a high speed milling operation,which they attributed to tool run-out at high cutting speed, alliedto the vibrational effect of high cutting forces. According toFallbohmer and Scurlock [34], cutting with a tool with a smalllevel of wear may generate lower roughness than cutting with afresh tool. Diniz et al. [35] found similar results in the milling ofH13 steel with a toroidal tool in semi-nishing conditions.A possible explanation for these results is that roughness valuesmay be associated with tool coating defects on the cutting edge,as cited by Oliveira [13], which affect roughness at the beginningof tool life. Depending on the type of wear and its evolution, thesedefects may spread along the entire length of the cutting edge incontact with the workpiece, making it more uniform and therebyimproving the surface roughness value.
The objective of the experiments shown in this work is to ndhow to minimize tool vibration using long slender tools andobtain good workpiece surface quality and long tool lives. There-fore, milling experiments using integral carbide and indexablecarbide end mill with high tool overhang are described below.
2. Methods, equipments and materials
Several experiments involving nishing operations using thehigh speed milling technique were performed to determine theinuence of tool diameter, tool slenderness coefcient (L3/D4,where L is tool overhang and D is tool diameter) and type of tool(integral carbide end mill and indexable carbide tool with a carbidetool shank) on tool wear and workpiece surface roughness.
The machine tool used in the experiments was a 5-axismachining center with 15 kW of power in the main motor, toolrotation between 35 and 25,000 rpm and HSK 63 A system fortool xation.
The workpieces used in the experiments were made of AISIH13 steel, quenched and tempered to reach 50 HRC of hardness.
Four ball nose end mill tools were used, two integral and twoindexable carbide inserts with carbide tool shanks. The cementedcarbide inserts had a 3 to 4 mm thick PVD coating of TiAlN.it mandatory to apply very high tool rotation speeds in high speedmilling nishing operations. Therefore, the feed velocity is high,even when low feed rates are used, which allows for a highnumber of tool passes (with low radial and axial increments)without increasing the cutting time. As a result, good levels ofsurface nish are usual in these processes [9,3032].
In the milling of inclined at surfaces with either toroidal orball nose tools, the theoretical surface roughness can be deter-mined in both the transverse and longitudinal directions inrelation to the feed direction. The theoretical roughness perpen-dicular to the feed direction (RthTRANS) is determined by thecombination of tool radius (R), axial increment (ap) and inclina-tion angle of the surface (a), according to Eq. (2) [13,30].
RthTRANS R
2R2 apsena
24
s2
In the feed direction, the maximum theoretical roughnessThe rst was an 8 mm tool with insert code KDMB08M0ERGN
-
grade KC515M, which, according to the manufacturers catalog, isemployed in machining steel (class P) and hardened steel (class H)with hardness up to 54 HRc with geometry suitable for nishingoperations, xed in a tool shank code KDMB08R150A08HN. Thesecond tool was a 12 mm tool with insert code KDMB12M0ERGN,with the same characteristics as the 8 mm diameter inserts, xed ina tool shank code KDMB12R160A12HNC. Both tools were xed inthe chuck by cold deformation. The integral carbide end mills had8 and 12 mm diameters, both PVD coated with TiAlN. The two typesof tools (insert and integral) had similar cemented carbide gradesand their tool radial run-out in all the experiments was lower than10 mm.
Due to the tools high wear resistance, it was impossible to
were xed at the same value, 0.2 mm. Using these Equations, and
M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 110 3reach tool wear values that would congure the end of tool life,even after a long cutting time and using a very high cutting speed.Therefore, the experiments ended upon reaching 400 min ofcutting time. Even after such a lengthy cutting time, tool ankwear was less than 0.10 mm. The tool ank wear was measuredusing an optical microscope with 50 magnication.
The cutting speed (vc) and the angle between the milledsurface and the machine tools XY plane (a) were kept constantduring all experiments (vc500 m/min and a751).
The input variables of the experiments were tool diameter (D),tool slenderness coefcient (called TSC in this paper) and type oftool (integral and indexable inserts and ball nose end mills), all ofthem with two levels, which would result in a 23 factorialexperimental design. In preliminary experiments, the conditionwith the indexable insert carbide tool with D8 mm andTSC45 mm1 presented very high roughness values from thebeginning of the experiments (Rz9.11 and 3.96 mm measuredtransverse and longitudinal to the feed directions, respectively).Therefore, the use of TSC45 for the indexable insert tools wasdiscarded, resulting in a nal incomplete 23 factorial experimen-tal design. The experimental conditions employed here aredescribed in Table 1. Each experiment was performed twice.
All the tools used in the experiments were extremely sharpand had a very small cutting edge radius, but larger than the chipthicknesses. The integral carbide end mills presented a morepositive rake angle than the indexable carbide insert tools.
Moreover, all the tools used in the tests were subjected tovibrational analysis in order to identify the frequency responsefunction (FRF) of each set, and thus, to determine the naturalfrequency of each system. This procedure was performed on thetools mounted on the spindle using an instrumented impacthammer. The curves of the natural frequency of each set areshown in the graphs in Fig. 1. It can be seen in this gure thestrong inuence of both, the tool diameter and the TSC, on thenatural frequencies of the several tool sets tested. For a constanttool diameter, when TSC increased, the natural frequencydecreased. The same occurred for the tool diameter when TSCwas kept constant. The reason for these occurrences was the
Table 1Conditions employed in the experiments.
Experiment vc[m/min]
a[degree]
Rth[lm]
ana
[mm]Tool D
[mm]TSC[mm1]
1 500 75 0.20 0.10 Integral 8.0 20
2 12.0 20
3 8.0 45
4 12.0 45
5 Indexable
insert
8.0 20
6 12.0 20
a an is the thickness of the material removed perpendicular to the machinedsurface.in order to obtain Rth0.20 mm in both directions, the values ofap and fz used here were 0.077 and 0.079 mm, respectively, for thetools with D8 mm, and 0.095 and 0.096 mm for the tools withD12 mm. These values are close to those recommended by thetool supplier, which suggests depth of cut values of around 0.01Dfor nishing operations [37] and also close to the value used byKlocke et al. [38].
The cutting forces (XZ directions) were measured at thebeginning of the experiments (fresh tool) and after the tool hadbeen cutting for 400 min. These measurements were taken with aKistler 9257B dynamometer connected to a Kistler 5019B signalconditioner and an A/D board to sample the signals entering thecomputer. For a tilt angle of 751, Lopez et al. [39] proposed the useof a sampling frequency of 44 kHz for a tool rotation of10,000 rpm, and 110 kHz for 25,000 rpm. Therefore, in this work,a sampling frequency of 75 kHz was used to acquire signals in allthe experiments, since TPF were 684.7 and 456.7 Hz (or toolrotations of 20,542 and 13,701 rpm) for 8 and 12 mm tools,respectively.
Surface roughness values were measured using a portable rough-ness meter connected to a computer, so as not to have only theroughness values, but also their proles. They were measured at thebeginning of the experiments, and after 25 and 50min of cutting.After, roughness measurements were taken at 50-min intervalsduring cutting. At these precise moments, three surface roughnessmeasurements were taken in the directions parallel and perpendi-cular to the feed direction. The values shown in the gures of the nextitem represent the average of three measurements.
3. Results and discussion
Fig. 2 shows the average roughness values over the 400 min ofmachining, obtained from two replicates of the experiments; thedispersion lines represent a standard deviation of 71 (in eachreplicate, roughness was measured three times in each direction).
The values of transverse surface roughness (perpendicular tothe feed direction) were more sensitive to differences in the inputparameters than the longitudinal roughness proles. This is dueto the greater differences among the roughness curves in each ofthe experiments. Except for the curve of experiment 3, the curvesof longitudinal roughness are very similar to each other. Theresults also show that, over the 400 min evaluated, the transversesurface roughness tended to be higher than in the directionlongitudinal to the feed direction.
The mean roughness produced by using 12 mm diameter endmills showed no signicant variations, regardless of the TSC valuecorrelation among these parameters and the rigidity and mass ofthe vibratory system formed by the tool and its xation in themachine tool. It can be also seen that when the kind of tool(integral or insert) was changed, the variations in the character-istic frequencies of the system were not high. The vertical lines inthe gure, which represent the tooth passing frequencies (TPF)(calculated from the cutting speed, tool diameter and number ofteeth) and their harmonics, indicate the fundamental excitationfrequencies and show how distant they are from the naturalfrequency of the tool and tool xation system.
The surface roughness produced in the experiments, whichwas measured in the feed direction and perpendicularly to thefeed direction using Rz parameters, was associated with thetheoretical roughness values (RthEqs. (2) and (3)) because thisroughness parameter is sensitive to the presence of high peaksand valleys on the surface [17,36]. The ap was dened usingEq. (2) and fz using Eq. 3. RthTRANS (Eq. (2)) and RthLONG (Eq. (3))used in the experiments. The lengths in balance (Lt) were 78.25
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M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 1104050
100150200250300350400450500
Hertz
INTEGRAL D=8,00 TSC=20
XYTPF and harmonicsand 101.40 mm for TSC20 and 45 mm1, respectively. This factdemonstrates the possibility of using end mills of this diameterwith lengths in balance for machining deep areas withoutimpairing the surface quality either at the beginning of tool lifeor after 400 min of milling.
The tool diameter does not affect the results when TSC20 isused, since low values of surface roughness were obtained withboth tool diameters, particularly in the direction longitudinal tothe feed, with values less than 1.00 mm (Rz).
Most of the tested conditions resulted in low roughness values.An analysis of Fig. 2 indicates that minor variations in roughness,as well as slight standard deviations occurred during the 400 minof the experiments. Therefore, it can be stated that the low toolwear (the tool wear behavior will be analyzed later in this paper)did not affect surface roughness. Moreover, an analysis of theevolution of the roughness curves in experiments 1 and 4 reveals
050
100150200250300350400450500
m/s
2 /New
ton
m/s
2 /New
ton
Hertz
INTEGRAL D=8,00 TSC=45
XYTPF and harmonics
050
100150200250300350400450500
Hertz
INTEGRAL D=12,00 TSC=20
XYTPF and harmonics
Fig. 1. FRF curves of tool/tool-shank/machinem/s
2 /New
ton
050
100150200250300350400450500
Hertz
INTEGRAL D=12,00 TSC=45
XYTPF and harmonicsthat the values were lower in both directions when the tool hadalready been in operation for 400 min. In experiment 1, thesurface roughness transverse and longitudinal to the feed direc-tion began with 1.49 and 0.89 mm Rz, respectively, and after400 min showed values of 1.45 and 0.69 mm Rz. In experiment 4,the surface roughness started at 2.14 and 0.73 mm Rz and endedafter 400 min of cutting with values of 1.96 and 0.63 mm Rz. Thesedecreases, albeit slight, demonstrate that, especially under theseconditions, the tools could be used for much longer periods andstill maintain the quality of the machined surfaces.
In contrast to a majority of the experiments, in experiment 3,the use of the integral end mill with 8 mm diameter and TSC45resulted in high roughness values with the fresh tool, showing anaverage Rz of 3.14 mm transverse to the feed direction and of1.94 mm in the longitudinal direction, obtained at the beginningof the experiment. During machining, the surface roughness
m/s
2 /New
ton
m/s
2 /New
ton
050
100150200250300350400450500
Hertz
INSERT D=8,00 TSC=20XYTPF and harmonics
050
100150200250300350400450500
Hertz
INSERT D=12,00 TSC=20
XYTPF and harmonics
system in each experimental condition.
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M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 110 50.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
9.00
10.00
0 25 50 100 150 200 250 300 350 400
Rz
Tran
sver
sal [
m]
Machining time [min]
INTEGRAL D=8,00 TSC=20INTEGRAL D=12,00 TSC=20INTEGRAL D=8,00 TSC=45INTEGRAL D=12,00 TSC=45INSERT D=8,00 TSC=20INSERT D12,00 TSC=20
10.00INTEGRAL D=8,00 TSC=20values increased further and visible vibration marks appeared onthe machined surface. The low surface quality generated bymachining in this experiment is evident when observing thecurve of increasing surface roughness and also the high standarddeviations, which indicate signicant variations in surface rough-ness. Thus, the conditions used in experiment 3 would not complywith the quality requirements for surface machining of dies andmolds, and several analyses were conducted to investigate thecauses of this substantial increase in roughness in this experi-ment, which will be discussed later.
Tool wear may strongly affect the quality of machined sur-faces. Thus, the wear (VBB max) of the tools used in the experimentwas measured at two cutting edges of each of the tools used intwo replicates after 400 min of cutting, and the results are shownin Fig. 3. These values represent the average wear of the fouredges (two edges of each tool, in two replicates of each experi-ment). The dispersion lines represent a standard deviation of 71.
Based on Fig. 3, it can be stated that all the tools showed lowerank wear, including the tool used in experiment 3, than thatobtained in other experiments.
The shape of the edge wear can inuence surface roughnesssince this shape is transferred to the machined surface duringthe cutting process. This inuence is greater perpendicularly to
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
9.00
0 25 50 100 150 200 250 300 350 400
Rz
Long
itudi
nal [
m]
Machining time [min]
INTEGRAL D=12,00 TSC=20INTEGRAL D=8,00 TSC=45INTEGRAL D=12,00 TSC=45INSERT D=8,00 TSC=20INSERT D12,00 TSC=20
Fig. 2. Roughness, Rz, values obtained in the experiments.the feed direction since, in the longitudinal direction, the direc-tion of measurement of the roughness prole and the toolsrotation attenuate this effect. Fig. 4 shows the edge radius ofthe tools used in the experiments, enabling the identication ofthe shape of the worn edge after 400 min of use. Here, each tool isrepresented by the edge showing the highest wear in eachreplicate.
The images indicate that only the edge of the tool used inreplicate 1 of experiment 1 was slightly altered from its originalprole. This may have inuenced the formation of the surfaceprole, especially in the direction transverse to the feed. More-over, the two tools used in this experiment showed delaminationof the coating, exposing the substrate. This occurred at one of thetwo edges of each tool. The tool used in replicate 1 of experiment4 showed a slight change from its original shape and minorsuccessive chipping across the rake surface, which could have anegative effect on roughness. However, this was not conrmed bythe roughness curve in Fig. 2.
The other tools exhibited essentially uniform ank wear,including the tools used in experiment 3, particularly whencompared with the wear obtained in other experiments. There-fore, the wear shape analysis also does not explain the signicantincrease in roughness occurred in experiment 3 during the
7488
71 6748
62
0
20
40
60
80
100
120
D=8,00 D=12,00 D=8,00 D=12,00 D=8,00 D=12,00
TSC=20 TSC=45 TSC=20
INTEGRAL INDEXABLE INSERT
Flan
k w
ear
[m
]
Fig. 3. Flank wear presented by ball nose end mills after 400 min of cutting.400 min of milling shown in Fig. 2.Another analysis to explain this high surface rough-
ness obtained in experiment 3 was to verify the cutting forces,since they may also inuence the quality of machined surfaces.The three orthogonal components (XZ) of the cutting forces weremeasured in all the evaluated conditions. Toh [2] states that thecomponent transverse to the feed direction (Fy in this work) ismore sensitive to the detection of regenerative vibration, due tothe reduced damping ratio, other than the other two axes. There-fore, the average peak values of the Fy component were consideredin this analysis, as indicated in Fig. 5
According to this gure, in each case, the Fy values were higherafter 400 min than at the beginning of the experiments. Only inexperiment 5, after the tool had already been cutting for 400 min,was the value very similar to that obtained when machining withthe fresh tool. It is not clear whether the Fy value in experiment3 differed from the values recorded in other experiments.A comparison of the raw signal of Fy from all the experimentsrevealed that the behavior of the curve obtained in experiment3 was different, as depicted in Fig. 6, which indicates a typicalsample of Fy for the other experiments (Fig. 6a) and a typicalsample of Fy for experiment 3 (Fig. 6b).
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M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 1106Kin
dTS
CD
iam
eter
Exp
erim
ents
Replica 1
8 1During stable cutting, the signal is periodic with two peaks ofdifferent amplitudes at each rotation of the tool, which demon-strate radial run-out between the two edges of the tool. In otherwords, Fig. 6a shows that, due to the radial run-out of the tool,one cutting edge cuts more material than the other. However,a comparison of the forces obtained in different tool rotationsshows stability. Due to the small chip cross section area, a smalltool radial run-out caused by imperfections either of the tool orof the tool xation and also caused by the tool deectiongenerated by cutting forces, made the actual chip cross section
Inte
gral
2012 2
458 3
12 4
Inse
rt20
8 512 6
Fig. 4. Microscopic images of wear on the bal
71.7 75.1 74.1 70.3 78.1 68.584.5 85.8
98.0 88.4 79.7 88.2
0
20
40
60
80
100
120
140
Experiment 1 Experiment 2 Experiment 3 Experiment 4 Experiment 5 Experiment 6
D=8,00 D=12,00 D=8,00 D=12,00 D=8,00 D=12,00
TSC=20 TSC=45 TSC=20
INTEGRAL INDEXABLE INSERT
Fy [N
]
New
400 minutes
Fig. 5. Fy in the experiments.Replica 2
100 m 100 m
100 m 100 m
100 m100 m
100 m 100 m
100 mand, consequently, the cutting force to vary in each tool revolu-tion, as it is seen in Fig. 6a. However, this tool run-out, as can beseen in Figs. 2 and 3, was neither able to damage surfaceroughness, nor stimulate ank wear. On the other hand, inexperiment 3, the signal of the Y component of the cutting forces(Fig. 6b) shows different amplitudes not only in a single toolrotation but also when different rotations are compared. Thevibration that caused this cutting force behavior also caused thehighest roughness values obtained in experiment 3, which areillustrated in Fig. 2.
In order to have a better visualization of the differencesbetween stable and unstable conditions, Fig. 7 was built. It showsFy peak values at the beginning and end of the experiments, usingpolar coordinates during 30 tool rotations. As the instability of theprocess increases, the difference between the shape of its polarcoordinate graphic and a perfect circle also increases. Because thisgraphic shows the force against tool rotation and not againstcutting time like in Fig. 6, it makes easier for the reader tounderstand the force variation along the rotations. The differencebetween two successive points depicts the tools radial run-out.
The curves obtained in most of the experiments are symme-trical to a circle passing through the average values of the peaks.Moreover, the peak forces obtained with the fresh tool showlower values than the same tool after 400 min of cutting. Inexperiment 5, this difference is practically nonexistent.
Tool wear not was responsible for increasing the roughnessvalues in the experiments since the ank wear values (Fig. 3)were very low and the tool nose shapes (Fig. 4) were close to the
100 m
100 m 100 m
l nose end mills used in the experiments.
-
0 ro
20
xper
M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 110 730
50
70
90
110
130
150
0 1000 2000
Fy [N
]
30
50
70
90
110
130
150
0 1000 2000
Fy [N
]
1 rotation
2
1 rotation
Fig. 6. Acquisition signals: (a) Stable condition (eoriginal ones after 400 min of cutting. However, even low wearvalues led to higher tool run-out values, as can be seen in Fig. 7.This gure shows that the difference between cutting forces ateach rotation of the tool (Fy at a given point minus Fy at the nextpoint) were higher when tool had already cut during 400 min.
In experiment 3, instability of the cutting process is clear, sincethere is a signicant dispersion of the peak forces in bothmoments, at the beginning (fresh tool) and mainly at the end ofthe experiment. The points form a polygon very distant from acircle, and this distance is even greater in the curve obtained fromthe tool after 400 min of cutting. This indicates that instabilityoccurred in this process from the beginning of the experiments(fresh tool) and was enhanced by the low tool ank wear after400 min of cutting.
All the auxiliary data for this analysis leads to the conclusionthat only the vibration of the cutting process in experiment3 affected the roughness results, since the other analyzed factors Fy and tool wear were at levels similar to those obtained inother experiments. Polli [20] stated that high amplitude vibra-tions occur when the harmonics of the TPF approach the systemsnatural frequency. This fact may also explain this result since thehighest peak in the FRF curve of the tool used in experiment 3 was1369 Hz, which is the second harmonic of TPF (see Fig. 1).
Fig. 8 shows the FRF values of each tool obtained at a frequencyequal to twice the TPF (FRF in the second harmonic of the toolsnatural frequency). These values were obtained from Fig. 1 and arerelated to the value shown on the curves where the second verticalgreen line (twice the TPF) crosses the FRF curve.
The energy values were low in most of the experiments. Again,the exception was experiment 3, in which a FRF of 456.2 m/s2/Nwas obtained at the frequency of 1370 Hz (very close to the secondharmonic1369.4 Hz), in the Y direction. Moreover, experiment4 showed a higher FRF than experiment 3 in the X direction, but the3000 4000 5000
3000 4000 5000
tations
rotations
iment 1), (b) Unstable condition (experiment 3).total vibration energy of experiment 4 in the second harmonic ofTPF was much lower than that obtained in experiment 3. This iswhat probably caused the instability in the cutting process,resulting in the high roughness of the machined surface.
These results thus demonstrate that the main reason for thehigher roughness values in experiment 3 was the tool instability,as evidenced in Figs. 68. However, the toughness of the tool usedin this process sufced to prevent its early damage or catastrophicfailure, enabling it to cut for at least 400 min.
It is interesting to compare the results of experiment 3 withexperiment 1. Both were performed with the same tool andcutting speed (same tool revolution) and same TPF. Therefore,both had the same excitation frequency. However, as the toolused in experiment 1 had a shorter length (L) and, consequently,lower values of FRF at the second harmonic of TPF, it was able towithstand the excitation caused by the cutting forces withoutinstability in the process.
As mentioned in the Methods, equipments and materialssection, a complete experiment was not performed in the condi-tion using the indexable insert tool with D8 mm andTSC45 mm1, because it resulted in higher roughness valuesthan those obtained in experiment 3, even using a fresh tool.However, Fig. 9a shows the FRF curve of the tool, and Fig. 9bcompares the energy values in the second harmonic of the toolused in this condition with those of the integral ball nose end millof D8 mm and TSC45 mm1 (experiment 3).
In this case, the FRF value on the Y axis at the second harmonicof the TPF is lower than that obtained in experiment 3, but ismuch higher than those obtained in the other experiments (seeFig. 8). However, what might explain the higher roughness valuesthan in experiment 3 is the high FRF in the X direction (thehighest amongst all the experiments). Therefore, in terms of totaltool vibration in the second harmonic of the TPF, this preliminary
-
EI
D
M.M. de Aguiar et al. / International Journal of Machine Tools & Manufacture 68 (2013) 1108EXPERIMENT 1
Integral
D=8,00
Fresh tool400 minutes170
[N]experiment produced the highest value, causing considerable toolinstability, and hence, high surface roughness, precluding the useof this set of conditions.
Again, it is evident that high amplitude vibrations occur whenthe harmonics of TPF are close to the systems natural frequency,
TSC=20 85
0Fy
T
EXPERIMENT 3
Integral
D=8,00
TSC=45
Fresh tool400 minutes170
85
0
Fy [N
]
E
I
D
T
EXPERIMENT 5
Insert
D=8,00
TSC=20
Fresh tool400 minutes170
85
0
Fy [N
]
E
I
D
T
Fig. 7. Polar coordinXPERIMENT 2
ntegral
=12,00
Fresh tool400 minutes170
[N]as stated by Polli [20]. In experiment 3, the roughness valuesobtained in cutting with the fresh tool were Rz3.14 and 1.94 mmmeasured, respectively, in the directions transverse and long-itudinal to the feed, and in the preliminary experiment, thesevalues were Rz9.11 and 3.96 mm.
SC=20 85
0
Fy
XPERIMENT 4
ntegral
=12,00
SC=45
Fresh tool400 minutes170
85
0Fy
[N]
XPERIMENT 6
nsert
=12,00
SC=20
Fresh tool400 minutes170
85
0
Fy [N
]
ates of Fy peaks.
-
workpiece surface roughness when compared with thatobtained in the other experiments.
Re
[1
[3
[5
[6
[7] G.M. Kim, B.H. Kim, C.N. Chu, Estimation of cutter deection and form error in
Experiment 1 Experiment 2 Experiment 3 Experiment 4 Experiment 5 Experiment 6
D=8,00 D=12,00 D=8,00 D=12,00 D=8,00 D=12,00
TSC=20 TSC=45 TSC=20
INTEGRAL INDEXABLE INSERTEnergyX 44.6 20.2 125.3 203.6 32.2 15.9EnergyY 34.1 18.1 456.2 160.1 2.4 15.3
0.050.0
100.0150.0200.0250.0300.0350.0400.0450.0500.0
m/s2
/New
ton
Fig. 8. Energy values in the second harmonic of the natural frequency of the tool/tool-shank/machine system.
050
100150200250300350400450500
m/s2
/New
ton
Hertz
INSERT D=8,00 TSC=45XYTPF and harmonics
Experiment 3 Preliminary Experiment
D=8,00 D=8,00
TSC=45 TSC=45
INTEGRAL INDEXABLE INSERT
Energy X 125.3 291.6
Energy Y 456.2 305.4
0
50
100
150
200
250
300
350
400
450
500
m/s2
/New
ton
Fig. 9. FRF of the tool/tool-shank/machine system of the preliminary experiment(a), and energy values in the second harmonic of experiment 3 and preliminary
experiment (b).
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Wear was not a problem for the tools since, even after a longcutting time (400 min), ank wear was very slight and the toolnose shape was not unduly damaged. Surface roughness didnot increase signicantly with cutting time in most of theconditions tested in this work.
Albeit slight, wear was responsible for the increase in tool run-out as the cutting time proceeded. However, the higher toolrun-out did not increase the surface roughness in most of theexperiments.
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Correlating surface roughness, tool wear and tool vibration in the milling process of hardened steel using long slender...IntroductionMethods, equipments and materialsResults and discussionConclusionsReferences