拖拉機半軸殼銑床夾具設(shè)計【銑削φ36端面】【說明書+CAD+PROE】
拖拉機半軸殼銑床夾具設(shè)計【銑削φ36端面】【說明書+CAD+PROE】,銑削φ36端面,說明書+CAD+PROE,拖拉機半軸殼銑床夾具設(shè)計【銑削φ36端面】【說明書+CAD+PROE】,拖拉機,半軸殼,銑床,夾具,設(shè)計,銑削,36,端面,說明書,CAD,PROE
Proceedingsofthe2006IEEE/RSJInternationalConferenceonIntelligentRobotsandSystemsOctober9-15,2006,Beijing,ChinaANovelModularFixtureDesignandAssemblySystemBasedonVRPengGaoliang,LiuWenjianSchool ofMechatronicsEngineeringHarbinInstituteofTechnologyHarbin,150001,CAbstract-Modularfixturesareoneoftheimportantaspectsofmanufacturing.ThispaperpresentsadesktopVRsystemformodularfixturedesign.Thevirtualenvironmentisdesignedandthedesignprocedureisproposed.Itassiststhedesignertomakethefeasibledesigndecisionseffectivelyandefficiently.Ahierarchicaldatamodelisproposedtorepresentthemodularfixtureassembly.Basedonthisstructure,theusercanmanipulatethevirtualmodelspreciselyinVEduringthedesignandassemblyprocesses.Moreover,themachiningsimulationformanufacturinginteractioncheckingisdiscussedandimplemented.Finally,thecasestudyhasdemonstratedthefunctionalityoftheproposedsystem.ComparedwiththeimmersiveVRsystem,theproposedsystemhasofferedanaffordableandportablesolutionformodularfixturesdesign.IndexTerms-Modularfixture,desktopVR,assemblydesign,machiningsimlulation.I.INTRODUCTIONModularfixturesareoneoftheimportantaspectsofmanufacturing.Properfixturedesigniscrucialtoproductqualityintermsofprecision,accuracy,andfinishofthemachinedpart.Modularfixtureisasystemofinterchange-eableandhighlystandardizedcomponentsdesignedtosecurelyandaccuratelyposition,hold,andsupporttheworkpiecethroughoutthemachiningprocess1.Tradition-ally,fixturedesignersrelyonexperienceorusetrial-and-errormethodstodetermineanappropriatefixturingscheme.Withtheadventofcomputertechnology,computeraideddesignhasbeenprevalentintheareaofmodularfixturedesign.Ingeneral,theassociatedfixturedesignactivities,namelysetupplanning,fixtureelementdesign,andfixturelayoutdesignareoftendealtwithatthedownstreamendofthemachinetooldevelopmentlife-cycle.Thesepracticesdonotlendthemselveswelltothebridgingofdesignandmanufacturingactivities.Forexample,veryfewsystemshaveincorporatedthefunctionalityofdetectingmachininginterference.Thisleadstoagapbetweenthefixturedesignandmanufacturingoperationswheretheaspectofcutterpathsisnotconsideredduringthedesignstage2.Asaresult,re-designcannotbeavoidedwhenthecutterisfoundtointerferewiththefixturecomponentsinthemanufactu-ringset-up.Therefore,inordertobringmachiningfixturedesignintothearenaofflexiblemanufacturing,amoresystematicandnaturaldesignenvironmentisrequired.Asasynthetic,3D,interactiveenvironmenttypicallygeneratedbyacomputer,VRhasbeenrecognizedasaverypowerfulhuman-computerinterfacefordecades4.VRholdsgreatpotentialinmanufacturingapplicationstosolveproblemsbeforebeingemployedinpracticalmanufacturingtherebypreventingcostlymistakes.TheadvancesinVRtechnologyinthelastdecadehaveprovidedtheimpetusforapplyingVRtodifferentengineeringapplicationssuchasproductdesign5,assembly6,machiningsimulation7,andtraining8.ThegoalofthispaperistodevelopaVR-basedmodularfixturesdesignsystem(VMJFDS).Thisisthefirststeptodevelopanintegratedandimmersiveenvironmentformodularfixturedesign.Thisapplicationhastheadvantagesofmakingthefixturedesigninanaturalandinstructivemanner,providingbettermatchtotheworkingconditions,reducinglead-time,andgenerallyprovidingasignificantenhancementoffixtureproductivityandeconomy.II.OVERVIEWOFTHEPROPOSEDSYSTEMThesystemarchitectureoftheproposeddesktopVRsystemismodularisedbasedonthefunctionalrequirementsofthesystem,whichisshowninFig.1.Atthesystemlevel,threemodulesofproposedsystem,namely,Graphicinterface(GUI),Virtualenvironment(VE)andDatabasemodulesaredesigned.Foreachofthemodules,asetofobjectshasbeenidentifiedtorealizeitsfunctionalrequirements.Thedetailedobjectdesignandimplementationareomittedfromthispaper.Instead,thebriefdescriptionofthesethreemodulesisgivenbelow.1)GraphicInterface(GUI):TheGUIisbasicallyafriendlygraphicinterfacethatisusedtointegratethevirtualenvironmentandmodularfixturedesignactions.2)Virtualenvironment(VE):TheVEprovidestheuserswitha3Ddisplayfornavigatingandmanipulatingthemodelsofmodularfixturesystemanditscomponentsinthevirtualenvironment.AsshowninFig.1,thevirtualenvironmentmodulecomprisestwoparts,namelyassemblydesignenvironmentandmachiningsimulationenvironment.Theuserselectsappropriateelementsandputsdowntheseelementsonthedeskintheassemblydesignarea.Thenheassemblestheselectedelementsonebyonetobuildupthefinalfixturesystemwiththeguidanceofthesystem.1-4244-0259-X/06/$20.00C)2006IEEE2650Authorized licensed use limited to: Nanchang University. 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Fig.1.OverviewofthedesktopVRbasedmodularfixturedesignsystem.3)Database:Thedatabasedepositallofthemodelsofenvironmentandmodularfixtureelements,aswellasthedomainknowledgeandusefulcases.Thereare 5databasesshowninFig.1.Amongthem,knowledge&rulebasegoverningallfixtureplanningprinciplesformsthebrainsofthesystem.III.PROCEDUREOFMODULARFIXTUREDESIGNInthissection,aninstructivemodularfixturedesignprocedurewithinVEispresented.Besidesthe3Ddepththattheusersfeelandthereal-worldlikeoperationprocess,thisprocedurefeaturesintelligenceandintroduction.Duringthedesignprocess,someusefulcasesandsuggestionwillbepresentedtotheuserforreferencebasedonintelligentinferencemethodsuchasCasebasedreasoning(CBR)andRulebasedreasoning(RBR).Furthermore,relativeknowledgeandrulesarepresentedashelppagesthattheusercaneasilybrowsedduringthedesignprocess.OverviewofmodularfixturedesignprocessissummarizedinFig.2.AftertheVEenvironmentisinitialedandtheworkpieceisloaded,thefirststepisfixtureplanning.Inthisstep,theuserfirstdecidesthefixturingscheme,thatisspecifiesthefixturingfacesoftheworkpieceinteractively.Forhelptheusersdecision-making,someusefulcasesaswellastheirfixturingschemewillbepresentedviatheautomaticCBRretrievalmethod.Oncethefixturingfacesareselected,theusermaybeprompttospecifythefixturingpoints.Inthistask,somesuggestionsandrulesaregiven.Afterthefixturingplanning,thenextstepisfixtureFUsdesignstage.Inthisstage,theusermaybetoselectsuitablefixtureelementsandassembletheseindividualpartsintoFUs.Accordingtothespatialinformationofthefixturingpointsinrelationtothefixturebaseandtheworkpiece,sometypicalFUsandsuggestionsmaybepresentedautomatically.Thesewillbehelpfulfortheuser.AftertheplanningandFUsdesignstage,thenextstageisinteractivelyassemblingthedesignedfixtureFUstoconnecttheworkpiecetothebaseplate.Whenthefixtureconfigurationiscompleted,theresultwillbecheckedandevaluatedwithinthemachiningenvironment.Thetasksexecutedinthisenvironmentincludingassemblyplanning,machiningsimulation,andfixtureevaluation.Assemblyplanningisusedtogainoptimalassemblysequenceandassemblypathofeachcomponent.Machiningsimulationisresponsibleformanufacturinginteractiondetection.Fixtureevaluationwillcheckandevaluatethedesignresult.Inconclusion,thewholedesignprocessisinanaturemannerforthebenefitofVE.Moreover,thepresentedinformationofsuggestionandknowledgecanadvisetheuseronhowtomakedecisionsofthebestdesignselection.IV.ASSEMBLY MODELINGOFMODULARFIXTUREA.ModularfixturestructureanalysisAfunctionalunit(FU)isacombinationoffixtureelementstoprovideconnectionbetweenthebaseplateandaworkpiece11.Generally,modularfixturestructuremaybedividedintothreefunctionalunitsaccordingtoitsbasicstructurecharacteristics,namelylocatingunit,clampingunit,andsupportingunit.ThenumberoffixtureelementsinaFUmayconsistofoneormoreelements,inwhichonlyoneelementservesasalocator,supportorclamp.Themajortaskofthemodularfixtureassemblyistoselectthesupporting,locating,clampingandaccessoryelementstogeneratethefixtureFUstoconnecttheworkpiecetothebaseplate.Byanalyzingthepracticalapplicationofmodularfixtures,itisfoundthattheassemblyofmodularfixturesbeginsbyselectingthesuitablefixtureelementstoconstructFUs,thensubsequentlymountingtheseFUsonthebaseplate.Therefore,theFUscanberegardedassubassembliesofmodularfixturesystem.Further,thestructureofmodularfixturesystemcanberepresentedasahierarchalstructureasshowninFig.3.2651Authorized licensed use limited to: Nanchang University. 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UsefTa6*T-siikg&Suggelr,lFixtuieElemenetsrUetrievali0ToolsrKetrieval4Fig.2ModularfixturedesignprocedureinproposedsystemB.HierarchicallystructureddatamodelformodularfixturerepresentationinVEItiscommonthatthecorrespondingvirtualenvironmentmaycontainmillionsofgeometricpolygonprimitives.Overthepastyears,anumberofmodelsub-divisionschemes,suchasBSP-tree10andOctrees,havebeenproposedtoorganizelargepolygonalmodels.However,formodularBa1I_1HsreplalteBansepla1nteElements*LocatngElementsL,catingUnitsAccessoryEllementsClamnpingElemnents!ClampingUnitsSupportingElemntsSupportingUfnitsAccessoryElementsFig.3Hierarchicalstructureofmodularfixturesystemdesignapplications,thesceneisalsodynamicallychanging,duetointeractions.Forexample,indesignprocess,thepartobjectmaychangeitsspatialposition,orientationandassemblyrelations.Thisindicatesthatastaticrepresentation,suchasBSP-tree,isnotsufficient.Furthermore,theabovemodelscanonlyrepresentthetopologystructureoffixturesysteminthecomponentlevel.However,totheassemblyrelationshipamongfixturecomponents,whichreferstothematingrelationshipbetweenassemblyfeaturesthatisnotconcerned.Inthissection,wepresentahierarchicallystructuredandconstraint-baseddatamodelformodularfixturesystemrepresentation,real-timevisualizationandprecise3DmanipulationinVE.AsshowninFig.4,thehigh-levelcomponentbasedmodelisusedforinteractiveoperationsinvolvingassembliesordisassembles.Itprovidesbothtopologicalstructureandlinkrelationsbetweencomponents.Theinformationrepresent-edinthehigh-levelmodelcanbedividedintotwotypes,ponentobjectsandassemblyrelationships.Componentobjectscanbeasubassemblyorapart.Asubassemblyconsistsofindividualpartsandassemblyrelationshipsbetweentheparts.ComponentLevel(PtPartSSubassemblyAssemblyrelationshipFeatureLevelFt3FeatureFeaturematingrelationshipt-tPolygonLevelFZ-ll.PolygonFig.4ThehierarchicalstructuredatamodelinVEThemiddle-levelfeaturebasedmodelisbuiltuponfeaturesandfeatureconstraints.Ingeneral,theassemblyrelationshipoftentreatedasthematingrelationshipsbetweenassemblyfeatures.Thusthefeaturebasedmodelisusedtodescribetheassemblyrelationshipandprovidesnecessaryinformationforspatialrelationshipcalculatingduringassemblyoperation.Inthismodel,onlythefeaturerelationshipsbetweentwodifferentcomponentsareconsidered.Therelationshipbetweenfeaturesofoneelementwillbediscussedinfeaturebasedmodularfixtureelementmodelingbelow.Thelow-levelpolygonbasedmodelcorrespondstotheabovetwolevelmodelsforreal-timevisualizationandinteraction.Itdescribestheentiresurfaceasaninter-connectedtriangularsurfacemesh.Moreabouthowthepolygonsorganizedofasingleelementwillbediscussedisthenextsection.C.ModularfixtureelementsmodelingAsweknow,inVE,thepartisonlyrepresentedasanumberofpolygonprimitives.Thisresultinthetopological2652Authorized licensed use limited to: Nanchang University. 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Restrictions apply. relations-hipsandparametricinformationarelostduringthetranslationprocessofmodelsfromCADsystemstoVRsystems.However,thisimportantinformationisnecessaryindesignandassemblyprocess.Inordertofulfilltherequirements,wepresentamodelingschemeforfixtureelementsrepresentationinthissection.Themodularfixtureelementsarepre-manufacturedpartswithstandarddimensions.Afterthefixturingschemedesigned,theleftjobistoselectsuitablestandardelementsandassembletheseelementstoformafixturesysteminafeasibleandeffectivemanner.Therefore,intheproposedsystem,onlytheassemblyfeaturesofthefixtureelementsneedtobeconsidered.Inthispaperanassemblyfeatureisdefinedasapropertyofafixtureelement,whichprovidesrelatedinformationrelevanttomodularfixturedesignandassembly/disassembly.Thefollowingeightfunctionfacesaredefinedasassemblyfeaturesoffixtureelements:supportingfaces,supportedfaces,locatingholes,counterboreholes,screwholes,fixingslots,andscrewbolts.Besidestheinformationaboutthefeatureliketypeanddimension,otherparameters,i.e.therelativepositionandorientationofthefeatureintheelementslocalcoordinatesystemarerecordedwiththegeometricmodelinthefixtureelementdatabase.Whenoneelementassembleswithanother,theinformationaboutthematedfeaturesisretrievedandusedtodecidethespatialrelationshipofthetwoelements.MoreinformationabouttheassemblyfeaturesandtheirmatingrelationshiparediscusseddetailedinRef1.D.ConstraintbasedfixtureassemblyinVE1)AssemblyrelationshipbetweenfixtureelementsMatingrelationshipshavebeenusedtodefineassemblyrelationshipsbetweenpartcomponentsinthefieldofassembly.Accordingtotheassemblyfeaturessummarizedintheabovesection,therearefivetypesofmatingrelationshipsbetweenfixtureelements.Namelyagainst,fit,screwfit,across,andT-slotfit,whichareillustratedinFig.5.Basedonthesematingrelationships,wecanreasonthepossibleassemblyrelationshipofanytwoassembledfixtureelements.2)AssemblyrelationshipreasoningIngeneral,theassemblyrelationshipoftwoassembledpartisrepresentedasthematedassemblyfeaturepairsofthem.Intheabovesection,wedefinedfivebasicmatingrelationshipsbetweenfixtureelements.Therefore,itisenabledtodecidethepossibleassemblyrelationshipsthroughfindingthepossiblematingassemblyfeaturepairs.Thesepossibleassemblyrelationshipsaresavedinassemblyrelationshipsdatabase(ARDB)forfixtureassemblyinnextstage.However,whenthefixtureiscomplicatedandthenumbersofcompositefixtureelementsislarge,thepossibleassemblyrelationshipsaretoomuchtotakemuchtimeforreasoningandtreating.Toavoidthissituation,wefirstdecidethepossibleassembledelementspairs.Thatistoavoidreasoningtheassemblyrelationshipbetweenaclampandthebaseplate,fortheyneverwereassembledtogether.Inthisstage,somerulesareutilizedtofindthepossibleassembledelementspairs.ThealgorithmofassemblyrelationshipsreasoningissimilartowhatdiscussedinRef12.Thusthedetaileddescriptionofthealgorithmisomittedfromthispaper.(a)AIlai.ns.2l.I.FLIiI7Fd)Asicmie1f-isxktElmnFig.5Fivebasicmatingrelationshipsbetweenfixtureelements3)Constraint-basedfixtureassemblyAftercarryingouttheassemblyrelationshipsreasoning,allpossibleassemblyrelationshipsoftheselectedelementsareestablishedandsavedinARDB.Basedontheserelationships,thetraineecanassembletheseindividualpartstoafixturesystem.ThissectionisaboutthediscussionofinteractiveassemblyoperationinVE.TheprocessofasingleassemblyoperationispresentedinFig.5andillustratedbytwosimplepartsassemblyasshowninFig.6.Ingeneral,theassemblyoperationprocessisdividedintothreesteps,namelyassemblyrelationshiprecognizing,constraintanalysisandapplying,constraint-basedmotion.Firstly,thetraineeselectsanelementandmovesittotheassembledcomponent.Onceaninferencebetweentheassemblingandassembledcomponentisdetectedduringthemoving,theinferredfeaturesischecked.IfthetwofeaturesisoneoftheassemblyrelationshipsinARDB,theywillbehighlightedandwillawaittheusersconfirmation.Onceitisconfirmed,therecognizedassemblyrelationshipwillbeappliedbyconstraintanalyzingandsolving,thatisadjustthetranslationandorientationoftheassemblingelementtosatisfythepositionrelationshipofthesetwocomponents,aswellasapplythenewconstrainttotheassemblingelement.Whenthenewconstraintisapplied,themotionoftheassemblingelementwillbemappedintoaconstraintspace.Thisisdonebytransferring3Dmotiondatafromtheinputdevicesintotheallowablemotionsoftheobject.Theconstraint-basedmotionnotonlyensuresthattheprecisepositionsofacomponentcanbeobtained,butalsoguaranteethattheexistingconstraintswillnotbeviolatedduringthefutureoperations.Theassemblingelementwillreachtothefinalpositionthroughsuccessionassemblyrelationshiprecognizingandconstraintapplying.2653Ii1-114-(b)F.tAuthorized licensed use limited to: Nanchang University. 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NOAssemblyrelationshipIispossiblecheckingelatioohship?Fig.6ProcessofassemblyconstraintestablishmentNoV.MACHININGSIMULATIONA.ManufacturinginteractionsDuringthemachiningprocess,therearemanytypesofmanufacturinginteractionsassociatedwiththefixturemayoccur.Theseinteractionscanbedividedintotwobroadcategoriesillustratedbelow,namelystaticinteractionsanddynamicinteractions.1)Staticinteractionsrefertotheinterferencebetweenfixturecomponents,theinterferencebetweenfixturecomponentsandmachinetool,andtheinterferencebetweenfixturecomponentsandmachingfeatureofworkpieceduringtheworkpiecesetup.2)Dynamicinteractionsrefertothetool-fixtureinteractions,whichoccurwithinasingleoperationwhenthetoolandthefixtureusedinthatoperationmaycollideduringcutting.Generally,theaspectsofmachiningprocessandcutterpathsarenotconsideredduringthefixturedesignstage.Asaresult,theseinteractionsmayoftenoccurduringthepracticalmanufacturing.Thusthehumanmachinistshavetospendmuchoftheirtimeidentifyingtheseinteractionsandresolvingthem.Itisoftenresultsinmodificationorre-designoffixturesystem.Thatistediousandtimecostly.B.InterferencedetectionAlthoughthecurrentlycommercialsoftware,likeVERICUT,cansimulatesNCmachiningtodetecttoolpatherrorsandinefficientmotionpriortomachininganactualworkpiece.Itisavailabletoeliminateerrorsthatcouldruinthepart,damagethefixture,breakthecuttingtool,orcrashthemachineduringthepartprogrammingstage.However,thesesoftwareareexpensiveandorientedtoNCprogram-mertherebynotsuitableforfixturedesigners.Duringthefixturedesignstage,itshouldbeensuredthattheassociatedfixtureinteractionscanbeavoided.Inthissystem,afterthefixtureconfigurationiscomplete,themachiningsimulationmoduleispresentedtotheusertoidentifytheinteractionsandresolvethem.Withinthemachiningsimulationenvironment,the3Ddigitalmodelofmachinetoolispresented.Thecanassemblethefixturecomponentsontheworkbenchandsetuptheworkpiece,justaswhatthemachiningengineersdointheactualsite.Duringthesetup,thefixturecomponentsandtheworkpiecearemovetotheirassemblypositionundermanipulation.Theinterferencecheckingmoduleiscarriedout.Ifinterferenceoccurs,theinferredobjectwillbehighlight.Itispossibletoadjusttheassemblysequenceorassemblypathsothattheinterferencecanbeavoided.However,ifitcannot,thentheusermustchangetheelementorfixtureunit.Aftertheworkpiecesetup,themovementofthecutterissimulatedaccordingtothegeneratedcuttingtoolpathfromCAMsystem.ForthebenefitofVR,thesolid,dynamic,3Dgraphicalrepresentationallowsforsuperioron-screenvisualisationofthemotionofthecutter.Therefore,toolpathsimulationallowstheusercloseinspectionandprovidesinformationofinterferenceifoccur.VI.IMPLEMENTATIONOFPROPOSEDSYSTEMANDACASESTUDYA.DesktopVRsysteminterfaceInordertoprovidetheend,thefixturedesignengineer,withanaturalinterfaceformoreefficientdesignpurposes.TheGUIisdesignedwiththereferencetotheimmersiveVRsoftwarebyhidingmostofthewindowscomponents.TheGUI(Fig.7)consistsofamainVRdisplaywindow,aright-handtoolbarandabottomoutputstatusbar.Theinteractionbetweenthesystemandtheusersisimplementedviamouseandkeyboardinput.Thetoolbarprovidestheoverallfunctionsofdevelopedsystem.Fig.7GUIoftheproposedmodularfixturedesignsystemB.AcasestudyThedevelopeddesktopVRbasedmodularfixturedesignsystemisexplainedwithacasestudy.AworkpiecetobemachinedisshowninFig.6.Facemillingistobeperformedonthetopface,thenfollowedbyfinishingthetwocounter-boreholes.Theuserdesignsamodularfixturesystemforthisworkpiecestepbystepwiththeguidanceofthesystem.Thefixtureplanningmodulehasbeenappliedtoreachafeasibledesignsolutionefficiently.Inthismodule,thelocating,clampingandsupportingfaces,aswellasthelocating,supporting,andclampingpointswillbedetermined2654Authorized licensed use limited to: Nanchang University. Downloaded on December 20, 2009 at 22:44 from IEEE Xplore. Restrictions apply. accordinglybasedonthesknowledgeandthefixturingheuristicrules.Afterthat,theuserexploresintheelementsdepositingareaandselectstheappropriatefixtureelementstofulfillthefixturingspatialrequirementatvariouspoints.Whenfinished,theusermovestotheassemblydesignareaandputsdowntheselectedelementsonthedesk,asshowninFig.8(a).Thenexttaskisassemblytheselectedelementstocompletethefixtureconfiguration.Inthevirtualenvironment,theusercanassemblethefixtureelementsinanaturalmanner.AsshowninFig.8(b),thefinalconfigurationofmodularfixturesystemfortheexampleworkpieceisformed.Whenthefixtureconfigurationiscompleted,thenextphaseismachiningsimulationforinferencedetection.AsshowninFig.9(a)andFig.9(b),theconstructedfixturesystemismountedonthetableofaCNCmachineandthesimulati
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