关于二级液压节流锥阀的低汽蚀研究论文外文翻译中英文文献对照翻译Word格式.docx
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关于二级液压节流锥阀的低汽蚀研究论文外文翻译中英文文献对照翻译Word格式.docx
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第一部位外文原文
标题:
关于二级液压节流锥阀的低汽蚀研究
Researchonlowcavitationinwaterhydraulictwo-stagethrottlepoppetvalve
Abstract:
Cavitationhasimportanteffectsontheperformancesandlifespanofwaterhydrauliccontrolvalve,suchasdegradingefficiency,intensenoise,andseverevibration.Two-stagethrottlevalveisapracticableconfigurationtomitigatecavitation,whichisextensivelyusedinwaterhydraulicpressurereliefvalvesandthrottlevalves.Thepressuredistributioninsideamediumchamberlocatedbetweentwothrottlesofatwo-stagethrottlevalveisinvestigatedthroughnumericalsimulations.Theeffectsofthepassagearearatioofthetwothrottlesandtheinletandoutletpressuresonthepressureinsidethemediumchamberareexamined.Thesimulationresultsindicatethat(a)thepressureinsidethemediumchamberisnotconstant,(b)thelocationsofmaximumandminimumpressuresinsidethemediumchamberarebothfixed,whichwillnotvarywiththepassagearearatioortheinletandoutletpressures,and(c)theratioofthepressuredropacrossthefrontthrottletothetotalpressuredropacrossthetwo-stagethrottlevalveisnearlyconstant.Thecriticalcavitationindexofthetwo-stagethrottlevalveisthenestablished.Asemiempiricaldesigncriterionisobtainedforthewaterhydraulictwo-stagethrottlevalve.Thecorrelationbetweenthecriticalcavitationindexandthepassagearearatioofthetwothrottlesisinvestigated.Relevantvalidationexperimentsareconductedatacustom-manufacturedtestingapparatus.Theexperimentalresultsareconsistentwiththesimulatedones.Furtheranalysesindicatethat(a)thelargebackpressurecanimprovenotonlytheanti-cavitationcapabilitybutalsothetotalloadrigidityofthewaterhydraulictwo-stagethrottlevalve,(b)anappropriatepassagearearatiowillbebeneficialforimprovingtheanti-cavitationcapabilityofthewaterhydraulictwo-stagethrottlevalve,and(c)thewaterhydraulictwo-stagethrottlevalvewithapassagearearatioof0.6wouldhavethebestanti-cavitationperformancewiththelowestriskofcavitation.Keywords:
computationalfluiddynamicssimulationcavitationloadrigiditypassagearearatiotwo-stagethrottlevalvewaterhydraulics
1INTRODUCTION
Waterhydraulicsystemsareoperatedwithrawwater(puretapwater)substitutingformineraloil.Theyhaveadvantagesintermsofdurability,reliability,safety,andcleanness.Suchsystemsarebecomingmoreandmorepopular,especiallyinfieldsofsteelandglassproduction,coalandgoldmining,foodandmedicineprocessing,nuclearpowergeneration,oceanexploration,andunderwaterrobotics[1–5].
Becausetheopeningofawaterhydrauliccontrolvalveisverysmallcomparedwiththatofoilvalve,thewaterflowvelocitythroughthewaterhydrauliccontrolvalveislargerunderthesamepressurecondition;
thuscavitationerosionmayoccurduetothehighvapourpressureofwater.Cavitationhasanimportanteffectontheperformanceandlifespanofwaterhydrauliccontrolvalve,suchasdegradingefficiency,intensenoise,andseverevibration.Previously,anumberofstudiesontherelationshipsbetweencavitationanddischargecoefficient,thrustforceandpressuredistributionsinthevalves,andmitigationofcavitationdamagewerecarriedoutthroughincreasingoutletpressureofvalves,modifyingshapesofthrottles,addingstagesofvalves,selectinganti-corrosionmaterialsforparts,andcontrollingmaximumfluidtemperatureandflowvelocity.Tsukijietal.[6]investigatedcavitationbyflowvisualizationinhydraulicpoppet-typeholdingvalvestoreducecavitation.Somemeasureswereemployedtodiminishnoiseandcavitationthroughcontrollingflowrate,upstreampressure,downstreampressure,andvalveliftincaseofconvergingflow.
Aoyamaetal.[7]studiedexperimentallytheunsteadycavitationperformanceinanoilhydraulicpoppetvalve.Itwasfoundthat,asabsolutevaluesofthevariationratesofinletandoutletpressureincreased,theincipientcavitationindexexhibitedatendencytodecrease,whereasthefinalcavitationindexatendencytoincreaseunderallgeometricalparameters.Astheabsolutevaluesofthevariationratesofinletandoutletpressurefurtherincreased,thehysteresisbetweentheincipientandfinalcavitationindiceswouldbecomelargerthaneverforeachcombinationofthevalveandvalveseat.
Ishiharaetal.[8]studiedoilflowunsteadinesseffectoncavitationphenomenaatsharp-edgedorifices.Therateofpressuredropacrosstheorificewaskeptconstant,andcavitationincipienceandfinalewererecordedbyusingscatteredlaserbeamsshowingthat(a)thereexistedtwotypesofcavitation,namely,gaseouscavitationandvapourouscavitation,and(b)cavitationincipienceandfinalevariedwiththeinitialcondition,thetemperatureofhydraulicoil,andtherateofpressuredrop.
Johnstonetal.[9]carriedoutanexperimentalinvestigationofflowandforcecharacteristicsofhydraulicpoppetanddiscvalvesusingwaterastheworkingfluid.Theaxisymmetricvalvehousingwasconstructedfromclearperspextofacilitateflowvisualization;
testswereperformedonarangeofdifferentpoppetanddiscvalvesoperatingundersteadyandnon-cavitatingconditions,forReynoldsnumbersgreaterthan2500.Measuredflowcoefficientsandforcecharacteristicsshowedobviousdifferencesdependingonvalvegeometryandopening.
Vaughanetal.[10]conductedcomputationalfluiddynamics(CFD)analysisonflowthroughpoppetvalves.Simulationswerecomparedwithexperimentalmeasurementsandvisualizedflowpatterns.Aqualitativeagreementbetweensimulatedandvisualizedflowpatternswasidentified.However,errorsinthepredictionofjetseparationandreattachmentresultedinquantitativeinaccuracies.Theseerrorswereduetothelimitationsoftheupwinddifferencingschemeemployedandtherepresentationofturbulencebythek–1model,whichwasknowntobeinaccuratewhenappliedtorecirculatingflow.
Uenoetal.[11]investigatedexperimentallyandnumericallytheoilflowinapressurecontrolvalveunderanassumptionofnon-cavitatingconditionsforvariousconfigurationsofthevalvesonthebasicsofafinitedifferencemethod.Theyconcludedthatthemainnoiseofthetestingvalveswasgeneratedfromcavitation,andthenoisewasaffectedbythevalveconfiguration.Pressuremeasurementsandflowvisualizationattwolocationsinavalvechamberwerealsoperformedonthebasisoftwo-dimensionalmodels.Throughcomparisonsofthemeasuredandcalculatedresults,severaldesigncriteriaweresetupforlow-noisevalves.
Martinetal.[12]investigatedcavitationinspoolvalvesinordertoidentifydamagemechanismsoftherelatedcomponents.Testswereconductedinarepresentativemetalspoolvalveaswellasamodelbeingthreetimeslarger.Datatakenundernon-cavitatingconditionswithbothofthesevalvesshowedthattheorientationofhigh-velocityangularjetswouldbeshiftedduetovariationsinvalveopeningandReynoldsnumber.Bymeansofhigh-frequencyresponsepressuretransducersstrategicallyplacedinthevalvechamber,thecavitationcouldbesensedthroughthecorrelationofnoisewithacavitationindex.Theonsetofcavitationcouldbedetectedbycomparingenergyspectraforafixedvalveopeningwithaconstantdischarge.Theincipientcavitationindex,asdefinedinthisinvestigation,wascorrelatedwiththeReynoldsnumberforbothvalves.
Gaoetal.[13]performedasimulationofcavitatingflowsinhydraulicpoppetvalvesbymeansofanrenormalizationgroup(RNG)k–1turbulencemodel,whichwasderivedfromthenstantaneousNavier–StokesequationsbasedontheRNGtheory.Experimentswereconductedtocatchcavitationimagesaroundtheseatofapoppetvalvefromperpendiculardirections,usingapairofindustrialfibrescopesandahigh-speedvisualizationsystem.Thebinarycavitatingflowfielddistributionsobtainedthroughdigitalprocessingoftheoriginalcavitationimageshowedsatisfactoryagreementwithnumericalresults;
thevibrationsofvalvebodyandpoppetinducedbythecavitatingflowweredetectedusingavortexdisplacementtransducer,alaserdisplacementmetreandadigitalstraindevice.Itwasconcludedthattheopeningandconeofaconicalvalvehadsignificanteffectsontheintensityofcavitation.However,inthisstudy,onlydownstreamcavitationinceptionvolumewasanalysedinestimatingtheanti-cavitationcapability,whereastheeffectsofoutletpressurewerenotconsidered.
Oshimaetal.[14]experimentallyinvestigatedtheinfluencesof(a)chamferlengthinthevalveseat,(b)thepoppetangle,and(c)theoiltemperatureontheflowcharacteristicsandthecavitationphenomena,usingwaterinsteadofoilastheworkingmediuminwaterpoppetthrottles.Thecavitationphenomenaweredirectlyobservedandthepressuredistributionbetweenthevalveseatandpoppetsurfacewasmeasuredinwaterpoppetthrottles.Comparisonanalysesontheconditionofcriticalcavitationwereconductedbetweenoilandwater.Itwasfoundthatthedischargecoefficientandthecriticalcavitationnumberforwaterpoppetthrottleswereconsiderablydifferentfromthoseofoilones,duetothehighdensityandlowviscosityofwater.Recently,Liuetal.[15,16]investigatedexperimentallytheflowandcavitationcharacteristicsofatwo-stagethrottleinwaterhydraulicsystem;
theyconcludedthatthetwo-stagethrottlehadstrongeranti-cavitationcapabilitythanthesingle-stageone,andthattheshapeofseatsalsoaffectedtheanti-cavitationcapabilityofthethrottles.Thecavitationchokingappearedonlywhencavitationindexwaslessthan0.4.Theyalsoconductedsevera
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