AIAA Aviation 2015-3393 22-26 June 2015, Dallas, TX 33rd AIAA Applied Aerodynamics Conference Optimization of Wind Turbine Airfoils Subject to Particle Erosion GiovanniFiore∗ andMichaelS.Selig† UniversityofIllinoisatUrbana-Champaign,DepartmentofAerospaceEngineering,Urbana,IL61801 An optimization of wind turbine airfoils subject to particle erosion is investigated. The erosive damage to the surface was represented by sand grains colliding with the blade leading edge. The optimizationwasperformedbyusingageneticalgorithmapproach(GA).Anewly-writtenGAcode wascoupledwithatwo-dimensionalinviscidflowfieldsolver(XFOIL)andwithaparticledynamics code (BugFoil). The chosen scheme of the GA was based on random tournament selection. Each geometrywasevaluatedthroughafigureofmeritthatrepresentedtheairfoilfitnesstodamageand toaerodynamicperformancewhentheairfoilisdamaged. Multipleapproachestotheoptimization weretaken. Theinitialstepofthisstudyinvolvedoptimizationthroughgeometryperturbationsof theleadingedgebymeansofBeziercurves. Itwasfoundthattheleadingedgeshapemodifications of existing airfoils increase the fitness of the airfoils subject to erosion. The second approach in- volvedacrossoverofexistingairfoilgeometriesalongwithleadingedgeshapemutations,inorder to expand the design space. The fitness of such airfoils was improved with respect to the first ap- proach. However,forboththeseapproachestheairfoilaerodynamicperformancewasdisregarded, as they were intended to give insight on the optimal airfoil shapes. The final step of the study made use of an inverse airfoil design method (PROFOIL) to widen the design space even further. In this approach the aerodynamic performance of the airfoil was evaluated, and the GA became a two-objective optimization process (maximum lift-to-drag ratio, and erosive figure of merit). It was observed that bulbous upper leading edges, and slanted, flat lower leading edges allowed for best erosion performance. Moreover, it was seen that the airfoils with a positive camber required asmallerangleofattacktooperateatthesameliftcoefficient,hencereducingtheerosivedamage experienced for sand grain impacts. The airfoils obtained from the inverse design GA algorithm werecharacterizedbyalift-to-dragratiogreaterthan310foraReynoldsnumberof5.84×106. Nomenclature AK = particlenondimensionalmass c = airfoilchordlength COE = CostofEnergy C = airfoildragcoefficient d C = particledragcoefficient D C = airfoilliftcoefficient l d = particlediameter D = particledragforce E = erosionrate FOM = figureofmerit GA = geneticalgorithm GAEP = GrossAnnualEnergyProduction K = erosionrateconstant ∗GraduateStudent(Ph.D.),DepartmentofAerospaceEngineering,104S.WrightSt.,AIAAStudentMember. †AssociateProfessor,DepartmentofAerospaceEngineering,104S.WrightSt.,AIAAAssociateFellow. http://www.ae.illinois.edu/m-selig 1of23 AmericanInstituteofAeronauticsandAstronautics Copyright © 2015 by the authors. Published by the American Institute of Aeronautics and Astronautics, Inc., with permission. LE = leadingedge m = particlemass n = erosionratevelocityexponent r/R = bladesectionradiallocation Re = freestreamReynoldsnumber t = time t/c = airfoilthickness-to-chordratio U = chordwiseflowfieldvelocitycomponent V = chord-normalflowfieldvelocitycomponent V = freestreamvelocity ∞ V = particleimpactvelocity imp V = particleslipvelocity s x = chordwisecoordinate y = chordwise-normalcoordinate α = angleofattack α = relativeanglebetweenflowfieldandparticlevelocity r θ = impactangle τ = nondimensionaltime ω = weightusedtocomputeFOM Subscriptsandsuperscripts 0 = initialstate l = lowerlimit P = particle tr = transition u = upperlimit I. Introduction Windturbinesusedforeletricalpowergenerationaresubjecttofoulinganddamagebyairborneparticlestypicalof theenvironmentwherethewindturbineoperates. Throughoutthe20-yearlifespanofawindturbine,particlessuchas rain,sand,hail,insects,andicecrystalsaremajorcontributorstoadeteriorationinturbineperformancethroughlocal airfoilsurfacealterations.1–6 Windturbinebladesaccumulatedirtespeciallyinthesurroundingsoftheleadingedge. Inaddition,temperaturejumpsandfreeze-thawcyclesmaycausesmallercoatingcrackstopropagate,promotingcoat- ing removal and eventually delamination and corrosion damage due to exposure of the internal composite structure. Theoriginallysmoothsurfaceofthebladesmaychangeconsiderably,andtheincreasedroughnesswillcauseadrop ingrossannualenergyproduction(GAEP)andanincreaseincostofenergy(COE).7–13 Moderntrendsinthewindturbinemarkethaveshownthebenefitsofoffshoremegawatt-scalewindturbineinstal- lations14,15inordertomaximizeGAEPwhilereducingCOE.However,offshorelocationsaresubjecttomoreintense sand erosion than the majority of land installations.13,16,17 Airborne sand particles collide with the blade and cause micro-cuttingandplowinginthecoatingmaterial18,19 resultinginsurfaceabrasion.20,21 Suchdamageisparticularly prominentattheoutboardsectionsofthebladewherethelocalrelativevelocityislargercomparedwithinboardsec- tions.16,22 The weather conditions of a given wind farm site may vary substantially throughout the seasons. Throughout the world, another common damage scenario is represented by water-based particles, namely raindrops and hail- stones.23–25 Whenintenseprecipitationoccurs, largeraindropsmayimpactwiththewindturbinebladesandpoten- tiallypromoteinternalpaneldelamination.23,26 Evensmallerraindropsincreasethemechanicalfatigueinthecoating plasticmaterials27,28whichtranslatesintosurfacemicro-crackingandafinalerosiveeffect.29 Thewindturbineindustryhasdevelopedseveraldevicestohelpmitigatetheeffectofairborneparticlesstriking onthebladesurface. Inparticular,chemicalcompanieshavecommercializedleadingedgetapeproductswhichallow foraconvenientsolutionthatisintegratedintotheblademaintenancecycle.11,30,31 However,fromthestandpointof 2of23 AmericanInstituteofAeronauticsandAstronautics anaerodynamicdesignersuchanapproachmayappearasalaterfix. Hence,itisvaluabletoinvestigatewhichblade sectiongeometryfeaturesallowforaminimizationofthesurfaceerosivedamage. The recent research has shown that the blade damage scenario is complex and multi faceted.22–25,32 From an aerodynamicstandpointitmustbenotedthatthereexistsacorrelationbetweenthebladeflowfieldandtheparticlein- teractionwiththebladesurface. Inparticular,smallandlightweightparticlesaremoresusceptibletotheaerodynamic flowfieldthanbiggerandheavierparticles. Therefore,abladeshapeoptimizationtominimizethedamageofanytype ofparticlemaybedifficulttoimplement. Forexample,insectsrepresentacomplexscenariowhichischallengingto undertakeduetothelargevarietyofspeciesandknowledgegapsconcerningtheiraerodynamiccharacteristics. Other heavyparticlessuchashailstonesarecharacterizedbyatrajectorythatisfairlyindependentofthebladeflowfield.23,25 Littlemaybedonefromashapeoptimizationstandpointtominimizethedamagetothepanelduetohailstonestrikes. However,thetwoparticlesthataremostsensitivetothebladeflowfieldaresandgrainsandraindrops.22,25Bothparti- clesareassociatedwithanerosionrate,henceallowingforanestimateofsurfacematerialloss. Fromanoptimization perspective,suchaparameterrepresentsadirectfeedbackoftheairfoilfitnesswithrespecttoparticleerosion. Largevaluesoferosionrateareresponsibleforanearliervisibledamageonthebladeovertimewhencompared with smaller values. Given the air quality characteristics of a chosen wind farm, a blade section geometry that is responsibleforhighererosionrateswilloutputlessenergythanamoredamage-resilientbladeovertime. Suchcon- siderationsmotivatetheinvestigationofoptimumsectiongeometries,underthenovelperspectiveofairborneparticle erosion. Thegoalofthisstudyistoinvestigatethebladesectiongeometryoptimizationforthecaseofsanderosion becausesandrepresentsthetypeofparticlethatismostlysusceptibletothebladeaerodynamicflowfield,andhence thebladesectiongeometry. Thispaperisdividedintofivesections: thenumericalmethodusedisexplainedinSectionII,thebladeoperating point,particleaerodynamicsanddamagemodelsareintroducedinSectionIII,whiletheresultsobtainedarediscussed inSectionIV.Finally,conclusionsareproposedinSectionV. II. MethodologyandTheoreticalDevelopment A. ParticleEquationsofMotion Inordertopredicttheerosiveeffectofsandgrainsonthebladesurface,alagrangianformulationcodewasdeveloped in-houseandnamedBugFoil.22,25BugFoilintegratesapre-existingparticletrajectorycode33andacustomizedversion ofXFOIL.34 Thelocalflowfieldvelocitycomponentsareobtainedbyqueryingthebuilt-inpotentialflowroutineof XFOILfromwhichtheparticletrajectoryandimpactlocationontheairfoilarecomputed. Insteadyflight,theforcesactingontheparticleareperfectlybalancedandperturbationstosuchforcesareassumed to be additive to the steady-state forces. For these reasons the equations of motion may be expressed by neglecting thesteady-stateforcesandmaybewrittenasfunctionsofincrementsonly.35 Inthecurrentstudy,bothraindropsand hailstonesweretreatedasaerodynamicbodieswhoseonlyassociatedforceistheaerodynamicdragD. ByapplyingNewton’ssecondlawalongtheparticletrajectoryinbothchordwisexandchord-normalydirections, thefollowingequationsareobtained18,22,36–38 d2x P m =ΣF (1) P dt2 x d2y P m =ΣF (2) P dt2 y By projecting the drag of the particle D in both chordwise x and chord-normal y directions using the relative angle betweenparticleandflowfieldvelocityα ,theequationsmayberewrittenas r d2x P m =∆D cosα (3) P dt2 r d2y P m =∆D sinα (4) P dt2 r 3of23 AmericanInstituteofAeronauticsandAstronautics GiventheparticlevelocitycomponentsU andV andgiventhevelocityflowfieldcomponentsU andV atacertain P P pointalongthetrajectory,theparticleslipvelocityV canbeexpressedas s (cid:113) V = (U−U )2+(V−V )2 (5) s P P whilethetrigonometricfunctionsinEqs.3and4mayassumetheform U−U V P rx cosα = = (6) r V V s s V−V V P ry sinα = = (7) r V V s s ByexpressingtheparticleaerodynamicdragDasafunctionofdynamicpressureandbysubstitutingforthetrigono- metricfunctions,theEqs.3and4mayberewrittenas d2x 1 V m P = ρV2A C rx (8) P dt2 2 s P D V s d2y 1 V m P = ρV2A C ry (9) P dt2 2 s P D V s Toscalethisprobleminanon-dimensionalfashion,non-dimensionaltime,space,andmassparameterscanbeintro- ducedhere tU τ = (10) c x P x = (11) P c y P y = (12) P c 2m P AK= (13) ρ A c P NondimensionalizationofEqs.8and9byareferencevelocityU yield d2x 1 P = V C V (14) dτ2 AK r D rx d2y 1 P = V C V (15) dτ2 AK r D ry whichtogetherrepresentasetofsecond-order, nonlineardifferentialequations. Oncetheparticledragcoefficientis evaluated,thetrajectorycanbecomputedbynumericallysolvingbothxandyequations. B. SandErosion Upon impact, sand grains promote a mechanism of surface abrasion. Sand erosion is responsible for an increase in bladesurfaceroughnessandadecreaseinstructuralstiffness. TheparametererosionrateE,definedastheremoved mass of the target material divided by the mass of the impacting particle, is a function of particle impact velocity V andangleatimpactθ,anditismeasuredinunitsof(g/g).19 ThevelocityV isrelatedtoE throughapower- imp imp law; whereas, the correlation with impact angle strongly depends on the eroded material properties. Most current materials used for wind blade coating are polyurethane derivatives30 and show a primarily plastic erosion behavior with maximum erosion rate at θ = 30 deg.39 Following the approach previously implemented by the authors,22 the erosionrateforplasticmaterialsisgivenbytheequation20,40–43 E=KVn (16) imp whereK andnareconstantsoftheerodedmaterial. ThecorrelationbetweenE andθ isimplicitintheparametersK andnfittedatvariousimpactanglesandimpactvelocities.Similartopreviousstudies,thesimulationswereperformed 4of23 AmericanInstituteofAeronauticsandAstronautics byusinglinear-fittederosionconstantsofultrahighmolecularweightpolyethylene(UHMWPE)22 becauseithasthe bestperformanceofthepolyethylene-basedcoatings,andbecausenormalimpactscausesmallerosionrates.40 Eachsimulationisperformedbyplacingaverticalarrayofsandparticlesfivechordlengthsupstreamoftheairfoil. Oncethethesimulationisinitiated,thetrajectoryoftheparticlesisevaluatedandimpingementisestimated.Giventhe angleandvelocityatimpact,E assumesdifferentvaluesintheregionaroundtheleadingedge(LE),withaminimum associatedwithnear-normalimpact. III. AerodynamicsofDamagedAirfoilsandAnalysisofSectionGeometries The design point for wind turbine airfoils is associated with the maximum aerodynamic efficiency (C/C ) . To l d max illustrate the significance of blade shape optimization it is of particular interest to predict the performance of blade sectionsinadamagedconfiguration(i.e.,whentheaerodynamicefficiencyisreduced).Inthissectiontheaerodynamic performanceofadamagedDU96-W-180arediscussed. A. ParametricStudyontheLocationofFixedTransition The erosion rate E curves due to sand on a DU 96-W-180 airfoil (α = 6.0 deg) are shown in Fig. 1. The earliest damagetoappearonthesurfacecorrespondstothelocationofmaximumerosionrate,whenthebladeisexposedto aprolongederosion(asdiscussedbytheauthorsinpreviousworks22). Infact,atsuchlocations,onecanassumethe quantityoferodedmaterialtobethelargest. Therefore,twofixedtransitionlocationsareconsideredontheupperand lowersurfaces: xu =3.13%andxl =8.39%,respectively. ThesechordwiselocationsareobtainedwithBugFoilfor tr tr abladesectionlocatedatr/R=0.75andα =6deg,sinceitrepresentsasuitabledesignpointnear(C/C ) . l d max For a more general scenario, the effects on E due to the blade angle of attack, particle diameter, and section spanwiselocation(throughlocalbladevelocity)areshowninFig.2. Itcanbeseenthatanincreaseinα [Fig.2(a)] is translated into a shift of the maximum erosion rate toward the leading edge for the upper surface and toward the trailingedgeforthelowersurface. Ontheotherhand,anincreaseinparticlediameter[Fig.2(b)]isresponsibleforan increaseinmaximumE onbothairfoilsides. Also,ashiftofthepeaksoccurstowardthetrailingedgeontheupper surfaceandtowardtheLEonthelowersurface. Lastly,anincreaseinbladevelocity[Fig.2(c)]causesanincreasein maximumE thatisroughlyproportionaltoV3. Inallcases,however,itcanbenoticedthatthehighestvaluesofE are ∞ onthebladeuppersurface. The current parametric study shows that it is relevant to investigate the effects of the chordwise position of the aerodynamictransitionimposedbytheerosionontheairfoilaerodynamicperformance. Therefore,theaerodynamic performanceoftheDU96-W-180airfoilwasanalyzedwithXFOILbyparameterizingthechordwisepositionofupper (U)andlower(L)fixedtransitions. TheeffectonC/C duetothechordwisetransitionlocationcanbeseeninFig.3. l d Twocurvesareproposed,eachobtainedbymodelingonesurfacewithchordwisevariabletransitionwhileimposinga fixedtransitionpointduetosanderosionontheoppositesurface(xu =3.13%,andxl =8.39%).Itcanbeseenthatthe tr tr locationofaerodynamictransitionhasadetrimentaleffecton(C/C ) assoonasthetransitionpointmovesfromits l d max naturallocationtowardtheLE.Themostsignificanteffectontheaerodynamicefficiencyisduetothetransitiononthe Figure1.ErosionrateEcurvesonaDU96-W-180airfoil,α=6.0deg.Redsegment:uppermaximumerosionrate(Eu );cyansegment: max lowermaximumerosionrate(El );bluecircles:particleimpingementpoints. max 5of23 AmericanInstituteofAeronauticsandAstronautics (a) (b) (c) Figure2.Effectof(a)bladeangleofattackα,(b)sandgraindiameter,and(c)bladevelocityV∞onsanderosionrateEontheDU96-W-180 airfoil. Figure3.EffectonC/C ofthechordwiselocationoffixedtransitionfortheDU96-W-180. l d 6of23 AmericanInstituteofAeronauticsandAstronautics uppersurfacewhereadecreaseofC/C ≈40%isassociatedwithanearlyuppertransition. Thisfigureisrelevantin l d showingthemagnitudeoflossinGAEPofanerodedwindturbine. Similarvalueswereobtainedfortheexperimental investigationofdamagedwindturbineairfoilperformancecarriedoutinpreviousstudiesbySareenetal.44 B. PolarsofaBladeSectionSubjecttoSandErosion TheaerodynamicpolarsoftheDU96-W-180airfoil(Fig.1)arecomputedbyusingXFOILforcleansurfacecondi- tions,upperonlyfixedtransition(U)(setbyerosion),loweronlyfixedtransition(L)(setbyerosion),andbothupper andlowerfixedtransitions(U+L).AllcomputationswerecarriedoutatRe=6.88×106 asitrepresentsareasonable Reynoldsnumberforabladesectionlocatedatr/R=0.75andc=1.7m. Figure 4 shows the effects on the aerodynamic performance due to the various combinations of fixed transition. By assuming that the earliest damage in time would appear on the blade upper surface, an initial large increase in C is observed with respect to the clean configuration. Although smaller, a further increase inC is observed once d d thebladelowersurfacedamagealsoappears. Finally,adragcoefficientapproximatelydoublethecleanC forU+L d transitionsisobserved. AlargercontributiontoC oftheupperfixedtransitionmaybeexplainedbyconsideringthe d pressure gradients acting on the upper surface and the longer curvilinear path covered by the boundary layer on the bladeuppersurfacewhencomparedwiththelowersurface. Infact,athickerboundarylayerwouldbeobservedonthe uppersurfacewhencomparedwiththeboundarylayeronthelowersurface. Thiswouldcontributetotheoverallform dragofthebladesectionwhichwouldincreasemorefortheuppersurfacecontributionthanforthelowersurface. TheaerodynamicefficiencyC/C plotinFig.4showsasimilareffecttoFig.3. Itcanbeseenherethatthedrop l d inefficiencyfromcleantofixeduppertransition(U)isdrasticandbringsthebladesectiontoa≈40%penalizationin C/C atα =6deg. Oncethelowerbladetransitionisalsofixed(U+L),afurtherdecreaseinaerodynamicefficiency l d isobserved,bringingthebladesectiontoapproximatelyhalftheaerodynamicefficiencyoftheinitialcleancondition. Finally,byobservingFig.5aninitialdropinC canbeseenforuppertransition,followedbyamodestrecoverywhen l U+L-transitionsareset. Suchbehaviormaybeduetotheover-predictioninliftcoefficientofXFOILandshouldbe verifiedwithhigher-ordermethodssuchasCFD.Itshouldbenotednowthatthechronologicalhistoryofdamageon thebladesectionisnotcrucialtothepresentanalysis.Infact,identicalconsiderationsmaybedrawnwhenconsidering anearlylowerdamageandalaterupperdamage. C. TheEffectofBladeShapeonSandErosion The scenario depicted in Sections III. A and III. B does not include the relationship of the blade section shape to sand erosion rate E. In the current section, the role of different geometry features with respect to sand erosion is investigated.Anefficientwaytocomparetheresultsistofixtheparticlesize,thefreestreamconditions,andtheairfoil operating point while varying the airfoil geometry. At this point, it is significant to choose a design lift coefficient C rather than an angle of attack, since it gives a better indication of the blade operating conditions once the airfoil l geometryisincludedinthebladedesign. The analysis that has been carried out in previous studies22,25 involved the Delft University wind turbine airfoil familyappliedtothedamageproblem.12,45,46Eventhoughthischoiceofairfoilsiscurrentlyrepresentativeofstate-of- the-artwindturbines,itissomewhatlimitedwhentryingtoinvestigatethegeometricfeaturesthatpotentiallyminimize damagetobladesections. Infact,theNRELairfoilfamilyoffersawidervarietyofupperandlowersurfacetopology andcurvaturewhencomparedwiththeDUfamily.47–49 Forsuchreasons,theNRELSfamilyofairfoilsisincluded here. Finally, because the most prominent effects of particle damage are seen when moving toward the blade tip, interestisaimedatoptimizingoutboardbladesectiongeometries. Aliftcoefficientof1.0ischosenandtheresultsare presentedasacomparisonbetweentwopairsofairfoilsasshowninFigs.6,and7. Theerosionpeaksontheairfoil uppersidearedenotedbyredmarks; whereas,thecyanlinesdenotepeaksofthelowerside. Itshouldbenotedthat moreairfoilswereanalyzedbytheauthors,butonlyfourareshowninthissectionforbrevity. A DU96-W-180 and aDU 96-W-212 arecompared in Fig.6 since theyare characterized byvery similar upper geometries,whereasthemaximumthicknessisduetothedifferentcurvatureofthelowersurface. TheupperE peaks arevirtuallyidenticalinvalue,shape,andchordwisemaximumlocation. Ontheotherhand,themorebulbousfront part of the DU 96-W-212 promotes an erosion peak on the lower side that is noticeably farther downstream, when comparedwiththethinnerDU96-W-180airfoil. Inotherwords,thefullershapeoftheairfoillowersideallowsfor the erosion peak to move downstream while also becoming flatter. No appreciable effect is detected as far as the maximumvalueofE onthebladelowerside. 7of23 AmericanInstituteofAeronauticsandAstronautics Figure4.C,C ,andC/C curvesoftheDU96-W-180forcleananddamagedconditions. l d l d Figure5.DragpolaroftheDU96-W-180forcleananddamagedconditions. 8of23 AmericanInstituteofAeronauticsandAstronautics Figure6.ErosionratecomparisonforaDU96-W-180andaDU96-W-212atCl=1.0,effectofthelowersidegeometry.Uppersideerosion ratepeaksinred;lowersideerosionratepeaksincyan. Figure7. ErosionratecomparisonforaNRELS817andaNRELS831atCl=1.0,effectoftheuppersidegeometry. Uppersideerosion ratepeaksinred;lowersideerosionratepeaksincyan. 9of23 AmericanInstituteofAeronauticsandAstronautics ThesituationisreversedwhenconsideringtheairfoilsNRELS817andS831inFig.7. Suchairfoilshavesimilar lowersidegeometriesintheforwardsection,whereastheuppersideismorebulbousfortheNRELS831. Thelower erosionpeaksarevirtuallylocatedatthesamechordwiselocation,althoughtheshapeofE appearstobeflatterforthe NREL S817 airfoil. An important difference appears when considering the upper erosion peaks. Again, the bulkier geometrypromotesanerosionpeakfartherdownstreamoftheLE,whencomparedwiththethinnersection. Also,a slightdropinthemaximumvalueofE isseenwhenconsideringtheNRELS831. D. LessonsLearned Theanalysisoftheprevioussectionshighlightstheroleofthebladegeometrywithrespecttoerosion. Itcanbecon- cludedthatthechordwiselocationofmaximumE istranslatedintoappreciableeffectsontheaerodynamicbehavior ofthebladesectiononceerosionisinitiated. Ontheotherhand,themaximumvalueofE isalsodrivenbytheblade sectionshape. Inotherwords,theshapeofthecleanbladecandictatewhenandwheretheearliestdamagewouldap- pearonthesurface;thebladeshapealsodictatestheperformanceinroughconditionsduetothechordwisetransition locationontheupperandlowersurfaces. Suchanobservationisanimportantfeedbackonbladegeometrysubjectto sanderosionwithrespecttominimizingthelossofaerodynamicperformanceoncetheairfoilisdamaged. Ingeneral, thebladedesignerwouldfavorgeometriesthatpromotethelowesterosionpeakslocatedasdownstreamaspossible fromtheLEtherebyallowingforbetteraerodynamicperformanceinroughconditions. Fromthecomparisonofthe airfoilsitcanbeconcludedthat: • An important geometric feature that pushes the maximum-E location downstream is the LE slope. In partic- ular, it appears that a more bulbous upper side allows for the maximum E to appear more downstream, when comparedwiththinnerLEgeometries. • Asimilarobservationcouldbemadeforthebladelowerside. However, itwasobservedthatthecurvatureof theblademayplayanimportantroleonboththeshapeoftheerosionratecurveandthemaximumlocationof E (seeFig.6). • The sensitivity of maximum E to variations in geometry is smaller when compared with the sensitivity of the chordwise location of maximum E. However, even small changes in maximum E translate into longer blade life, extending the clean, smooth conditions in which the turbine operate, yielding relatively higher values of GAEPovertime. E. FigureofMerit The considerations of Section III. D pose a new problem that is quantifying the fitness of an airfoil subject to sand erosion. Generally,itwouldbesignificanttocombineboththemaximumvalueofE andthecorrespondingchordwise location to obtain a numerical insight on the airfoil erosion performance. In particular, a designer would want to penalizehighvaluesoferosionrate,whileobtainingtransitionlocationstobeasdownstreamaspossibleontheblade surface. Forthesereasons,ifsuchadesignerwouldwanttocreatethebesterosion-resilientairfoilofthosepreviously considered, he or she would need to combine the upper airfoil geometry of the NREL S831 [Fig. 7] with the lower geometryoftheDU96-W-212[Fig.6]. The proposed mathematical expression to obtain the fitness of an airfoil subject to sand erosion is the following figureofmerit(FOM),thatis FOM= 1 (1.1+xu)ωu+ 1 (cid:16)1+xl (cid:17)ωl (17) Eu tr El tr max max whereω andω aretheweightsassignedtotheupperandlowersurface,respectively,inordertopenalizelargevalues u l of the chordwise location of transition x . Such aspect is tied with the analysis of Section III. A and represents a tr powerfulwaytofavoronesideoftheairfoilgeometrywithrespecttotheother. Becausetheuppersidehasshowna moreimportanteffectontheairfoilperformanceindamagedconditionscomparedwiththelowerside,thetwochosen weightsareω =5andω =1.5. u l ToshowthevalueofusingFOM,acomparisonofairfoilsisproposed,withfixedC =1.0. Theairfoilsdiscussed l in Section III. C, along with NREL S804, S832, S813, and S810, are ranked based on the erosion performance 10of23 AmericanInstituteofAeronauticsandAstronautics
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