The formability of aluminum sheet depends on the temperature of the material and the strain\ud
rate. E.g. the limiting drawing ratio can be improved by increasing the temperature uniformly, but even more by\ud
heating the flange and cooling the punch. To accurately simulate the deep drawing or stretching of aluminum\ud
sheet at elevated temperatures, a material model is required that incorporates the temperature and strain-rate dependency.\ud
In this paper simulations are presented of the deep drawing of a cylindrical cup, using axi-symmetric\ud
elements. Two material models are compared. First a phenomenological material model is used, in which\ud
the parameters of a Ludwik–Nadai hardening curve are made temperature and strain-rate dependent. Then a\ud
physically-based model, according to Bergstr¨om is used. The model incorporates the influence of the temperature\ud
on the flow stress and on the hardening rate and includes dynamic recovery aspect

Bolt, P.J.

Boogaard, A.H. van den

Werkhoven, R.J.

English

The formability of aluminum sheet depends on the temperature of the material and the strain rate. E.g. the limiting drawing ratio can be improved by increasing the temperature uniformly, but even more by heating the flange and cooling the punch. To accurately simulate the deep drawing or stretching of aluminum sheet at elevated temperatures, a material model is required that incorporates the temperature and strain-rate dependency. In this paper simulations are presented of the deep drawing of a cylindrical cup, using axi-symmetric elements. Two material models are compared. First a phenomenological material model is used, in which the parameters of a Ludwik–Nadai hardening curve are made temperature and strain-rate dependent. Then a physically-based model, according to Bergstr¨om is used. The model incorporates the influence of the temperature on the flow stress and on the hardening rate and includes dynamic recovery aspect

van den Boogaard, Antonius H.

University of Twente Research Information

Aluminum sheetformingat elevatedtemperaturesA.H. van  denBoogaardUniversityof Twente, Departmentof MechanicalEngineering, Enschede, theNetherlandsandNetherlandsInstitutefor MetalsResearchP.J.Bolt & R.J.WerkhovenTNOIndustrialTechnology, Eindhoven,theNetherlandsABSTRACT: The formability of aluminumsheetdependson the temperatureof the materialandthe strainrate.E.g. thelimiting drawing ratiocanbeimprovedby increasingthetemperatureuniformly, but evenmorebyheatingtheflangeandcooling thepunch.To accuratelysimulatethedeepdrawing or stretchingof aluminumsheetatelevatedtemperatures,amaterialmodelis requiredthatincorporatesthetemperatureandstrain-ratede-pendency. In thispapersimulationsarepresentedof thedeepdrawing of acylindrical cup,usingaxi-symmetricelements. Two materialmodelsare compared. First a phenomenologicalmaterialmodel is used,in whichthe parametersof a Ludwik–Nadaihardeningcurve aremadetemperatureandstrain-ratedependent.Thenaphysically-basedmodel,accordingto Bergstr̈om is used.Themodelincorporatestheinfluenceof thetempera-tureon theflow stressandon thehardeningrateandincludesdynamicrecoveryaspects.1 INTRODUCTIONIn deepdrawing of a cylindrical cup, the limitingdrawing ratio canbe increasedconsiderablyby con-trolling the temperatureof differentpartsof the alu-minum sheet(Wilson 1988; Bolt et al. 1999; Boltet al. 2000).By heatingthe flangeup to 250C andcoolingthepunchthelimiting drawing ratiocouldbeincreasedfrom 2.1 to 2.6 for a 5754-Oalloy in anexperimentperformedby the authors(seefig. 1). ItFigure1: Limiting drawing resultsat 20C (left) andwith theflangeat 250C (right).canbe expectedthat the optimal temperaturedistri-bution dependson thetypeof aluminumandthetoolgeometry. In this paperexperimentswith the5754-Oalloy are analyzed,to determinewhethera numeri-cal analysiscanpredictthepunchforce-displacementcurvesandthethicknessdistributionof thefinal prod-uct. Uniaxial tensile testswere performedat 4 dif-ferent temperaturesand2 strainrates.With the datafrom theseexperiments,theparametersfor two mate-rial modelswerefitted. This is describedin the nextsection.With thesemodels,somedeepdrawing ex-perimentsweresimulated.In theexperimentsthedieand blank-holderwere heatedat different tempera-turesand the punchwas kept at room temperature.Theresultsarepresentedin Section3.2 MATERIAL MODEL2.1 ExperimentsTwo differentmaterialmodelswereusedfor theanal-yses.First a phenomenologicalmodelwasusedandsecondlya so-calledphysically basedmodel. Thephysicallybasedmodelstill hasanumberof parame-tersthataredifficult to measureandhenceareusedasfitting parameters.Thechoiceof parametersandstatevariableshowever is basedonphysicalquantitieslikethe dislocationdensities,in contrastwith the purelyphenomenologicalmodels.Both modelsgive a flow stressas a function ofthedeformationpath,temperatureandstrainrate.Thetranslationof this (equivalent) stressto the generalstressspaceis performedby an isotropicVon Misesyield surface.Uniaxialtensiletestexperimentswereperformedattemperaturesof 25C, 100C, 175C and250C atstrainratesof 0.002and0.02s 1. Theresultingengi-neeringstress-straincurvesarepresentedin Figures2and3.0501001502002500 0.1 0.2 0.3 0.4 0.5 0.620 C100 C175 C250 CFigure2: Measuredengineeringstress–straincurvesat ε̇  0  002.0501001502002500 0.1 0.2 0.3 0.4 0.5 0.620 C100 C175 C250 CFigure3: Measuredengineeringstress–straincurvesat ε̇  0  02.2.2 TheextendedNadaimodelThe phenomenologicalmodel is basedon the Nadaihardeninglaw andpower law strainratedependency:σ  C  ε  ε0  n  ε̇ε̇0 	 m (1)Thetemperaturedependenceis includedby lettingC,n andmbefunctionsof thetemperatureT (in Kelvin).Startingof with simpleexponentialrelations,we fi-nally arrivedat thefollowing functionsfor theparam-eters,in orderto fit thetensiletests.CT   C0  a1  1  exp  a2T  273Tm 	 (2a)nT   n0  b1  1  exp  b2T  273Tm 	 (2b)mT   m0exp  cT  273Tm 	 (2c)Theparameterswerefittedto theuniaxialtensiletestsasdescribedin Section2.1. The resultingvaluesarepresentedin Table1.Table1: Parametersfor theextendedNadaimodelTm 800K n0 0.36ε0 0.009 b1 0.07C0 475MPa b2 4a1 110 m0 0.02a2 4 c 3ε̇0 0.0001s 12.3 TheBergströmmodelThe physically basedmodel used in this paper isa model describedby Bergstr̈om and later adaptedby Van Liempt (Bergstr̈om 1969; Bergstr̈om 1983;Van Liempt 1994). The model incorporatesthe in-fluenceof the temperatureon theyield stressandonthehardeningrateandincludesrecoveryaspects.Thismodelwasinitially usedfor thesimulationof hot de-formationof steel(Rietman1999).Basically the model determinesthe (equivalent)stressas:σ  g  T   σ0  αGrefb  ρ  σ   ε̇  T  (3)wherethefunctiongT  wasoriginally definedby theratiobetweentheelasticshearmodulusattemperatureT and at the referencetemperatureTref: GT  Gref.Thesecondparton theright-hand-sideis thefamiliarTaylor equationseee.g.(Estrin1996;Meyers1999).The essentialpart is the evolution of dislocationdensityρ. Thiswill givea temperatureandstrainrateinfluenceon thehardening,while σ  yieldsaninstan-taneoustemperatureandstrain rate influenceon theflow stress.The dynamicstressσ  is commonlyde-finedasσ   ε̇  T   σ 0  1  kT∆G0 ln  ε̇ε̇0 	 (4)for ε̇0exp  ∆G0  kT  ε̇  ε̇0 andwith k theBoltz-mannnumber. Fromthis equation,it canbeseenthattheinfluenceof σ  decreaseswith increasingtemper-ature.If Figures2 and3 arecompared,it canbeseenthat thereis hardlyany influenceof thestrainrateontheinitial yield stressandthatthesmallinfluencethatis presentat low temperaturesdoesnot decreaseathightemperatures.Thereforethecontributionof σ  isneglectedaltogetherin this paper. This meansthatallthe influenceof the temperatureon theflow stressisintroducedindirectly by the influenceon theharden-ing rate.For fcc alloys, this behavior is alsonotedinthe literaturee.g. (Yao & Zajac 2000).Note that inthepresentextendedNadaimodelthestrain-rateandtemperatureinfluenceactsdirectlyon theflow stress.The evolution of dislocationdensityis formulatedasadifferentialequation:dρdε U  ρ   Ω  ε̇  T  ρ (5a)withU  U0  ρ (5b)Ω  Ω0  Cexp   Qv3RT 	 ε̇  13 (5c)ThefunctionU represents torageof mobiledisloca-tions (making them immobile) andΩ representsre-mobilizationor dynamicrecovery. The functionsU ,and especiallythe function Ω determinethe shapeof the hardeningcurve at differenttemperaturesandstrainrates.The parameterswere fitted to the uniaxial tensiletestsasdescribedin Section2.1.Theresultingvaluesarepresentedin Table2. ThefunctiongT  wasfittedTable2: Parametersfor theBergstr̈ommodelσ0 100MPa σ  0 MPaα 1.0 U0 5  5  108 m  1b 2  857  10 10 m Ω0 17.5C 3070 Qv 87000J/moleasapolynomialwith theinitial yield stressat a strainrate of 0.02 becausethe original scalingwith GT yieldeda too strongdecreaseof theyield stress.In Figures4 and5 thesimulatedengineeringstress-straincurvesareplotted,togetherwith theexperimen-tal data.It canbe seenthat both modelsaremoreorlesscapableof describingtheexperiments.It shouldbenotedthatthecomparisonis only valid for uniformstrain,soup to themaximumengineeringstress.0 10 20 30 40 50010020030025 C slow rate0 10 20 30 40 500100200300100 C0 10 20 30 40 500100200300175 C0 10 20 30 40 500100200300250 CFigure 4: Stress–straincurves at different tempera-turesfor ε̇  0  002,experiments(dashed),Bergstr̈ommodel(solid)andNadaimodel(dotted).0 10 20 30 40 50010020030025 C medium rate0 10 20 30 40 500100200300100 C0 10 20 30 40 500100200300175 C0 10 20 30 40 500100200300250 CFigure 5: Stress–straincurves at different tempera-turesfor ε̇  0  02, experiments(dashed),Bergstr̈ommodel(solid)andNadaimodel(dotted).3 EXPERIMENTSAND SIMULATIONSA numberof cylindrical cupshavebeendeepdrawnatdifferenttemperaturesandwith differentpunchveloc-ities.Theseexperimentshavebeensimulatedwith thetwo materialmodels,describedin the previous sec-tion. Examplesof testproductsaregivenin Figure1.Figure6: Elementmeshat differentpunchdisplace-ments.The simulation of the deepdrawing experimentswas performed with axi-symmetric elements.Thesheetsof 1.2mm thicknessweremodeledwith 2 ele-mentsin thicknessdirection and an elementsizeof1 mm in radial direction. The extendedNadai ma-terial model was implementedas a user routine inMSC.MARC. In this modelalsoa partof thepunch,die and blank holder were modeled,including heatrods and cooling channels.From theseanalyses,itappearedthat the sheetin contactwith the punchor the die/blankholder takesthe temperatureof that0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementdiameter 230 mm, velocity 120 mm/min20 C175 C250 CFigure7: Experimentaload-displacementcurvesforthepunchat differenttemperatures.0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementdiameter 230 mm, velocity 120 mm/min20 C175 C250 CFigure 8: Punchload-displacementcurves with theextendedNadaimodelat differenttemperatures.0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementdiameter 230 mm, velocity 120 mm/min20 C175 C250 CFigure 9: Punchload-displacementcurves with theBergstr̈om modelat differenttemperatures.tool, within somemargin. The simulation with theBergstr̈om model was performedwith the in-housecodeDIEKA. Here the tools were modeledas rigidcontourswith a prescribedtemperature.The unde-formedand4 deformedmeshesof this simulationarepresentedin figure6.The friction betweentool andworkpieceis oneofthe leastknown factorsin thesimulation.In thesim--0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, velocity 120 mm/minT=20 CT=175 CT=250 CFigure10:Experimentalthicknessdistributionsatdif-ferenttemperatures.-0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, velocity 120 mm/minT=20 CT=175 CT=250 CFigure 11: Thickness distribution with extendedNadaimodelat differenttemperatures.-0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, velocity 120 mm/minT=20 CT=175 CT=250 CFigure 12: Thicknessdistributions with Bergstr̈ommodelat differenttemperatures.ulationsa Coulombfriction coefficient of 0.06 is as-sumedbetweentool andworkpiece.This valuewasmeasuredexperimentally. It canbeexpectedhoweverthat at high temperatures,the friction coefficient ishigherthanat low temperatures.All experimentsandsimulationswereperformedwith blanksof 230 mmdiameterand a punchstroke of 80 mm. The blankholder force wasequivalent to an initial pressureof0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementtemperature 175 C, diameter 230 mmv=12 mm/minv=120 mm/minv=480 mm/minFigure13:Experimentaload-displacementcurvesforthepunchat differentpunchvelocities.0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementtemperature 175 C, diameter 230 mmv=12 mm/minv=120 mm/minv=480 mm/minFigure14: Punchload-displacementcurveswith theextendedNadaimodelat differentpunchvelocities.0200004000060000800001000000 10 20 30 40 50 60 70 80 90punch forcepunch displacementtemperature 175 C, diameter 230 mmv=12 mm/minv=120 mm/minv=480 mm/minFigure15: Punchload-displacementcurveswith theBergstr̈om modelat differentpunchvelocities.1.0MPa.All mentionedtemperaturesarethetemper-aturesof thedie andblankholder. Thepunchis keptat 20  C.3.1 Temperature influenceThreeexperimentswereperformedwith a punchve-locity of 120 mm/min. The respective temperatureswere 20 C, 175 C and 250 C. In Figures7-9, the-0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, temperature 175 Cv=12 mm/minv=120 mm/minv=480 mm/minFigure16:Experimentalthicknessdistributionsatdif-ferentpunchvelocities.-0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, temperature 175 Cv=12 mm/minv=120 mm/minv=480 mm/minFigure 17: Thickness distribution with extendedNadaimodelat differentpunchvelocities.-0.2-0.15-0.1-0.0500.050.10.150.20.250 20 40 60 80 100 120 140logarithmic thickness strainlength from centerthickness strains: diameter 230 mm, temperature 175 Cv=12 mm/minv=120 mm/minv=480 mm/minFigure 18: Thicknessdistributions with Bergstr̈ommodelat differentpunchvelocities.force-displacementdiagramsof thepunchareplottedfor theexperimentsandthesimulationwith extendedNadaiandBergstr̈om modelrespectively.In Figures10-12,thethicknessdistributionsof thecup at a depthof 80 mm areplotted for the experi-mentsandthesimulations.3.2 Punch velocityinfluenceThreeexperimentswere performedwith a die tem-perature of 175 C and punchvelocitiesof 12, 120and 480 mm/min. In Figures13-15 the experimen-tal and simulatedforce-displacementcurves for thepunchareplotted.In Figures16-18 the experimentaland simulatedthicknessdistributionsareplotted.4 DISCUSSIONIn the extendedNadaimodelthe flow stressdirectlydependson theequivalentstrain,strain-rateandtem-perature.In theBergstr̈om modelan evolution equa-tion for thedislocationdensityis solved.As a result,theNadaimodelwill show adifferentflow stressuponstrainratechangedirectly, while theBergstr̈ommodelwill reachanew flow stressonly aftersomeadditionalstrain. It wasexpectedthat this differencewould beclearly visible in the simulationof the deepdrawingexperiments,sincetherestrain-rateand temperaturearenotconstant.Comparingthedifferentpunchforce-displacementcurves,it canbeseenthatbothnumericalmodelsun-derestimatethe experimentalcurves.The wiggles inthe numericalcurvesaredue to not fully convergedincrements.SincetheextendedNadaimodelwasusedin ananalysismodelthat includedthethermalanaly-sis of the die, blank holder and punch,the wigglesaremorepronouncedthanwith theBergstr̈ommodel.Thishasnothingto dowith thematerialmodelsthem-selves.Thetrendswith changingtemperatureor punchve-locity arepredictedwell, but the differencebetween20C and175C andbetween120mm/minand480mm/minareoverestimated.Thechangein thicknessafter80 mm punchstrokeis most pronouncedin the bottom of the cup. Bothnumericalmodelspredictthis,but theextendedNadaimodeloverestimatesthis considerably.In thesimulationsof thedeepdrawing experimentsthefriction betweentool andworkpieceis oneof thefundamentalunknowns.Values,basedon room tem-peratureexperiencewereused,but it is clearthatthesevaluesare likely to changeas the temperaturein-creases.Howeverhigh temperaturexperimentaldataare lacking. It is mainly attributed to the unknownfriction conditionsthat the differencesbetweensim-ulationandexperimentareratherlarge.Anotherrea-sonmay be the useof an isotropicVon Misesyieldsurface,while a non-isotropicandlesssmoothyieldsurfacewould be moreappropriate.For the momenthowever, theactualshapeof theyield surfaceat ele-vatedtemperaturescanonly beguessed.With thedeviationsbetweensimulationandexperi-ment,thedifferencesbetweentheextendedNadaiandtheBergstr̈ommodelcannotbedecisively interpretedasanadvantageof oneover theother.REFERENCESBergstr̈om, Y. (1969). Dislocation model for the stress-strain behaviour of polycrystalline α-Fe with specialemphasison thevariationof thedensitiesof mobileandimmobiledislocations.Mater. Sci.Eng. 5, 193–200.Bergstr̈om, Y. (1983).The plastic deformationof metals- a dislocationmodeland its applicability. Reviews onPowderMetalurgy andPhysicalCeramics2, 105–115.Bolt, P., Lamboo,N. A. P. M., & Rozier, P. J.C.M. (1999).Feasibilityof warmdrawing of aluminiumproducts.InM. Geiger, H. J. J. Kals, B. Shirvani, & U. P. Singh(Eds.),SheetMetal1999, Erlangen,pp.575–580.Bolt, P., Lamboo,N. A. P. M., Van Leeuwen,J. F. C., &Werkhoven,R. J. (2000).Warmdrawing of aluminiumcomponents.In Proceedingsof the 7th SaxonConfer-enceon FormingTechnology, LightweightConstructionbyFormingTechnology, Chemnitz,pp.101–118.Estrin,Y. (1996).Dislocation-density–related constitutivemodeling.In A. S. Krausz& K. Krausz(Eds.),UnifiedConstitutiveLawsof Plastic Deformation, pp. 69–104.SanDiego:AcademicPress.Meyers,M. A. (1999).Dynamicdeformationandfailure.In M. A. Meyers,R.W. Armstrong,& H. O.K. Kirchner(Eds.), Mechanics and Materials; FundamentalsandLinkages, pp. 489–594.New York etc.: JohnWiley &Sons,Inc.Rietman,A. D. (1999).NumericalAnalysisof Inhomoge-neousDeformationin PlaneStrain Compression. Ph.D.thesis,Universityof Twente.Van Liempt, P. (1994).Workhardeningand substructuralgeometryof metals.J. Mater. Process.Technol.45, 459–464.Wilson,D. V. (1988).Aluminium versussteelin thefamilycar - the formability factor. J. of Mech. Working Tech-nol. 16, 257–277.Yao,X. & Zajac,S. (2000).Thestrain-ratedependenceofflow stressandwork-hardeningratein threeAl-Mg al-loys.ScandinavianJournalof Metallurgy 29, 101–107.

Aluminium sheet forming at elevated temperatures

NARCIS 

Aluminium versus steel in the family car - the formability factor.

Dislocation model for the stressstrain behaviour of polycrystalline a-Fe with special emphasis on the variation of the densities of mobile and immobile dislocations.

Dislocation-density–related constitutive modeling. In

Dynamic deformation and failure.

Feasibility of warm drawing of aluminium products. In

Numerical Analysis of Inhomogeneous Deformation in Plane Strain Compression.

The plastic deformation of metals - a dislocation model and its applicability.

The strain-rate dependence of ﬂow stress and work-hardening rate in three Al-Mg alloys.

Warm drawing of aluminium components.

Workhardening and substructural geometryof metals.

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Aluminium sheet forming at elevated temperatures

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