Workpiece roundness profile in the frequency domain an application in cylindrical plunge grinding.docx
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Workpiece roundness profile in the frequency domain an application in cylindrical plunge grinding.docx
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Workpieceroundnessprofileinthefrequencydomainanapplicationincylindricalplungegrinding
DOI10.1007/s00170-014-5664-3
Workpieceroundnessprofileinthefrequencydomain:
anapplicationincylindricalplungegrinding
AndreD.L.Batako&SiewY.Goh
Received:
21August2013/Accepted:
21January2014/Publishedonline:
14February2014
#Springer-VerlagLondon2014
AbstractIngrinding,mostcontrolstrategiesarebasedonthespindlepowermeasurement,butrecently,acousticemissionhasbeenwidelyusedforwheelwearandgapelimination.Thispaperexploresapotentialuseofacousticemission(AE)todetectworkpiecelobes.ThiswasachievedbysectioningandanalysingtheAEsignalinthefrequencydomain.Forthefirsttime,theprofileofthegroundworkpiecewaspredictedmathematicallyusingkeyfrequenciesextractedfromtheAEsignals.Theresultswerevalidatedagainstactualworkpieceprofilemeasurements.Therelativeshiftofthewaveformedonthesurfaceofthepartwasexpressedusingthewheel-workpiecefrequencyratio.AcomparativestudyshowedthattheworkpieceroundnessprofilecouldbemonitoredinthefrequencydomainusingtheAEsignalduringgrinding.
KeywordsPlungegrinding.Roundness.Waviness.Frequency.Acousticemission
1Introduction
Grindingismostlyusedasthelaststageofamanufacturingprocessforfinefinishing.However,recently,highefficiencydeepgrinding(HEDG)wasintroducedasaprocessthatachieveshighmaterialremovalratesexceeding1,100mm3/mm/s[1–5].Grindingismainlyusedtoachievehighdimen-sionalandgeometricalaccuracy.However,incylindricalplungegrinding,vibrationisakeyprobleminkeepingtighttolerancesandformaccuracy(roundness)ofgroundparts.
Machinetoolsaredesignedandinstalledtohaveminimumvibration(withanti-vibrationpadwhenrequired).Neverthe-less,ingrinding,theinteractionbetweenthewheelandtheworkpiecegeneratespersistentvibration.Thisleadstovaria-tionoftheforcesactinginthecontactzone,whichinturncausesavariationinthedepthofcutonthegroundworkpiece.Consequently,thiscreateswavinessonthecircumferenceoftheworkpiece.Theengenderedunevenprofileonthework-piecesurfaceleadstoamodulationofthegrindingconditionsofthefollowingsuccessiverotations;thisiscalledworkpieceregenerativeeffect.Thebuildingupofthiseffectcantakeplaceingrindingcycleswithlongerduration.Similareffectsoccuronthegrindingwheelsurface;however,theprocessofthebuildupisslow[6–9].
Itisgenerallydifficulttogetagrindingwheelperfectlybalancedmanually,whichisacceptableforgeneralpurposegrinding.Forprecisiongrinding,automaticdynamicwheelbalancingdevicesareused.Thoughcurrentgrindingma-chineshaveautomaticbalancingsystemstoreducetheout-of-balanceofgrindingwheels,inactualgrinding,forcedvi-brationisstillcausedbythedynamicallyunbalancedgrindingwheels[10].Thisisbecauseanyeccentricityintherotatinggrindingwheelgeneratesavibratorymotion.
Thestiffnessofthewheelspindleandthetailstockalsoaffectsthewheel-workpiece-tailstocksubsystem,whichoscil-latesduetotheinteractionofthewheelwiththeworkpiece.Inpractice,thegeneratedforcevibrationishardtoeliminatecompletely.Thistypeofvibrationhasgreaterinfluenceontheformationoftheworkpieceprofile.Duringthegrindingprocess,theout-of-balanceofthewheelbehavesasasinusoi-dalwaveformthatisimprintedontheworkpiecesurface.This,
asinapreviouscase,leadstothevariationofdepthofcutand
A.D.L.Batako(*):
S.Y.Goh
AMTReL,TheGeneralEngineeringResearchInstitute,LiverpoolJohnMooresUniversity(LJMU),ByromStreet,LiverpoolL33AF,UK
e-mail:
******************.uk
createslow-frequencylobesaroundtheworkpiece,andthisisthekeytargetofthestudypresentedhere.
Otherfactorssuchasgrindingparametershavetobetakenintoconsiderationinthestudyofgrindingvibrationbecause
theseaspectsaffectthestabilityoftheprocess.Thisisbecausetheresultingworkpieceprofileisthecombinedeffectofdifferenttypeofvibrationingrinding[7,11].ThestudiescarriedoutbyInasaki,TonouandYonetsushowedthatthegrindingparametershaveastronginfluenceontheamplitudeandgrowthrateoftheworkpieceandwheelregenerativevibration[12].
Theactualmeasurementoftheworkpieceprofileisanintegralpartofthemanufacturingprocessduetotheuncertain-tyinwheelwearandthecomplexityofthegrindingprocess.Contactlessmeasurementandcontactstylussystemsweredevelopedtorecordthevariationsoftheworkpiecesizeandroundness.However,thesetechniquescanbeusedaspost-processcheckingasitislimitedtoaparticularset-upandmustbeusedwithoutthedisturbanceofthecuttingfluidinacleanair-conditionedenvironmentwithstabletemperature[13–16].Intheindustry,randomsamplesfrombatchesareusuallyinspectedafterthegrindingprocess.Anyrejectionofpartsorsometimesbatchesincreasesthemanufacturingtimeandcost.Therefore,itbecomesimportanttodeveloponlinemonitoringsystemstocutdowninspectiontimeandtominimiserejectedpartsingrinding.Someoftheexistingmonitoringsystemsingrindingarebasedonthewheelspindlepower.However,sen-sorssuchasacousticemissionandaccelerometersarealsousedtogatherinformationofthegrindingprocessfordifferentappli-cation.Dornfeldhasgivenacomprehensiveviewoftheappli-cationofacousticemission(AE)sensorsinmanufacturing[17].MostreportedapplicationsofAEingrindingareforgapelim-
ination,touchdressingandthermalburndetection[18–21].
Incylindricalgrindingprocesses,thegeneratedchattervibrationcausesthelossofformanddimensionalaccuracyofgroundworkpieces.Theeffectofvibrationinducestheformationoflobesontheworkpiecesurface,whichareusu-allydetectedusingroundnessmeasurementequipment.High-precisionpartswithtighttoleranceareincreasinglyindemandandshortcycletimesputpressureonmanufacturingprocess-es.Thisleadstotheneedfordevelopingin-processroundnessmonitoringsystemsforcylindricalgrindingprocesses.
Thepotentialofusingacousticemissiontodetecttheformationoflobesonaworkpieceduringacylindricalplungegrindingprocessisinvestigatedinthiswork.Theaimistoextracttheworkpieceroundnessprofilefromtheacousticemissionsignalinthefrequencydomain.Theextractedfre-quenciesarecomparedwithactualmeasurementinfrequencydomain,i.e.harmoniccomponents.Thekeyfrequenciesoftheharmoniccontentareusedtopredicttheexpectedprofileonthegroundpart.
2Thestudyofacousticemissionplungegrinding
AEisanelasticwavethatisgeneratedwhentheworkpieceisundertheloadingactionofthecuttinggritsduetothe
interfacialandinternalfrictionalandstructuralmodification.Thewavegeneratedistransmittedfromthecontactzonethroughthecomponentsofthemachinestructure[22,23].Ingrindingprocesses,themainsourceoftheAEsignalisthemechanicalstressappliedbythewheelontheworkpieceinthegrindingzone[24].Thechippingactionoftheabrasivegritsontheworkpiecesurfacegeneratesamultitudeofacous-ticwaves,whicharetransmittedtothesensorthroughthecentresandthetailstockofmachine.Themachiningconditionisreflectedinthesignalthroughthemagnitudeoftheacousticemission,whichvarieswiththeintensityofthecutting,e.g.rough,mediumorfinegrinding.ThekeyinformationofthemachiningprocessanditsconditionisburiedintheAEsignal.ToextractanyinformationofinterestfromtheAEsignals,itisimportanttoidentifythefrequencybandwidthandstudythesignalindetails.
SusicandGrabecshowedthatintensivechangesofAEsignalrelatetothegrindingcondition,thusthegroundsurfaceroughnesscouldbeestimatedbasedonthemeasuredsignalwithaprofilecorrelationfunction[25].AstrongchattervibrationingrindingisalsoreflectedintherecordedRMSAEsignal.Asvibrationcouldgeneratethewavinessontheworkpiece,hence,theAEsignalwasalsousedtostudytheroundnessprofile[26].Acomprehensivestudyofthechattervibration,wheelsurfaceandworkpiecequalityincylindricalplungegrindingbasedontheAEsignalwascarriedoutrecently[27].
Inroundnessmeasurementsystems,theroundnessofthepartisalsogivenasharmoniccomponents.Generally,thefrequencyspangivenbythemeasurementmachineisoflowfrequency—500Hzandbelow.Thisisbecausetheroundnessprofiledealswiththewavinessbutnotwiththesurfaceroughnessthatisalwaysofhigherfrequency.Fricker[8]andLiandShin[28]alsoindicatedpartsprofileoffrequencybelow300Hz.Partroundnessprofileisexpressedinundula-tionperrevolution.Therefore,lowerfrequencycomponentsaremainlytargetedbythemeasurementequipment,buthigherfrequencycomponentstendstorideontopoflowercarriers.Inmostcases,theprovidedfrequencyprofileisintherangeof300Hz[8,28].Therefore,thisworkstudiestheAEsignalalongthegrindingprocessusingthefastFouriertransform(FFT)withaparticularfocusonfrequenciesbelow300Hz.Thisallowedforadirectcomparisonbetweentheresultsfromthisinvestigationandtheactualroundnessmeasurements.
Figure1illustratestheequipmentusedinthisstudy,where
(a)istheconfigurationofthegrindingmachinewiththelocationofthesensorsand(b)istheroundnessmeasurementmachine.Toimprovesignaltransmission,thecoatingofthetailstockwasremovedfromthelocationofthesensorsasshowninthisfigure.
Duringthisstudy,observationsoftheshapeoftherec
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