Heat Pipe Reliability In HighPower ApplicationsWord文件下载.docx
《Heat Pipe Reliability In HighPower ApplicationsWord文件下载.docx》由会员分享,可在线阅读,更多相关《Heat Pipe Reliability In HighPower ApplicationsWord文件下载.docx(11页珍藏版)》请在冰豆网上搜索。
Useofheatpipesinhigh-power(>
150W)coolingapplicationshasbeenlimitedtocustomapplicationsrequiringeitherlowthermalresistanceorhavingaseverelyrestrictedenclosurearea.Thecostoftheselargerdiameterheatpipeswashighduetoalimitednumberofmanufacturersandhandmadeassemblytimes.
Fig.1.Theextremeheatloadsandfluxdensitiesexperiencedbythelatestgenerationofsemiconductorpowermodulesdemandtheuseofheatpipestoenhancebase-plateheatspreading.WhenheatpipesaremountedintheZ-axisofthe,perpendiculartothebase-mountingsurface(asshownabove),theycanboorstfinefficienciesbynearly100%.
EnternowthelatestgenerationofIGBTandothersemiconductorpowermodules.Thesemodulesofferhighpoweroutputsandevenmorechallengingpowerdensities-coolingofthemodulesatfullratedoutputpowerisvirtuallyimpossible.Asinmodernmicroprocessors,theremovalofwasteenergyintheformofheathasarguablybecomethemostchallengingengineeringtaskofthemechanicaldesigneffort.
Theseheatloadsandfluxdensitiesaresohighthatinmanycasesconventionalair-cooledaluminumextrusionandevenbondedfinheatsinkswillnotprovidesufficientcooling.Usingforcedair-cooling,theycannotremoveheatfastenoughtokeepthemodulefromexceedingitsmaximumrecommendedjunctiontemperatures.Theintroductionofasolidcopperheatspreader(copperhas2Xtheconductivityofextrudedaluminum)intothebaseofanextrusionalsowillnotsuffice.
Historically,somehigh-powersystemshaveusedheatpipestoenhancebase-plateheatspreadingindifferentmodesasthesolutiontokeepsystemsusingair-coolingandkeepthemawayfromliquidcooling(Fig.1).Aheatpipehasanapparentconductivitymanytimesgreaterthancopperandreliesonthelatentheatofvaporizationofaworkingliquidinsideaheatpipetooperate.
Reliabilityandlongevityoftheseclosed-loopcoolersandthesystemtheyareusedinnowbecomealargeissue.Whatwillhappeniftheheatpipestopsworking?
WhatMTBFcanbeexpectedfromtheselargediameterheatmovers?
Isthereanywaytoensuretheykeepworkinguptoandbeyondtheexpectedlifeofthesystem?
HeatPipeOperation
Basicallyaheatpipeisapartiallyevacuated,closedvesselthatrecirculatesasmallamountofworkingfluid,whichthroughtheadditionofheat,changesfromliquidtogas.Condensingthatgasbacktoaliquidandreleasingtheabsorbedheatrequiresadditionalcoolingsurfaceorothermeansofheatremoval.
Inoperation,aheatpipeabsorbssignificantamountsofheatintheevaporatorsectionasitreachesasettemperature.Theworkingfluidandthepartialpressureinsidethepipesetthistemperature.Heatofvaporizationofliquidallowsforhighquantitiesofheattobeabsorbedatgiventemperature.Thisissimilartoliquidwaterat100℃vs.steamat100℃.Theadditionalheatabsorptionisrequiredtochangephase.
Heatedgasmovestothecoldendoftheheatpipeatnearlythespeedofsoundandundernearlyisothermalconditions.Atthecondensersectionthegascoolsslightly,releasingtheheatgain,revertingwithlessthana5℃differentialfromoneendofthepipetoanother.
Operationtakesplaceatvirtuallythesametemperatureanddoesnotdependonwheretheheatentersorleavestheheatpipe.Dependingonpipediameter,thisprocesscanmovehundredsofwattsadistanceofmanyinches,offeringanapparentthermalconductivityofthousandsofW/mK(Fig.2).
Heatpipesoffermanyadvantagesintheiruseandoperation.First,aheatpipebyitselfdoesnotremoveordissipateheat.Itisonlyaconduitthroughwhichheatcanbemovedfromonepointtoanotherwithalowthermalresistance.Tomakeitoperational,aheatpipemusthaveasmuchcoolingsurfaceareainformoffinsadtheequivalent-sizeair-coolingheatsinkwithoutaheatpipe.Itmustalsohaveahighconductivitythermalcontacttotheheatsourcetobringheatintotheheatpipe.
Heatpipesareorientation-sensitiveinrelationshiptogravity.Heatpipeswillcarrylargeamountsofheatwhentheyoperateinaheat-down,cooling-upattitude.Thisorientationallowsfortherapidreturnofcooledliquidtoevaporator.Heatpipesalsowilloperatewuthlittlelossofconductivityinahorizontalattitude.However,operationinaheat-up/cooling-downorientationmustbecarefullyengineered.Dependingonthestyleofwickorliquidreturncapillary,mostheatpipeswilllosesomeefficiency.
Z-axisHeatRemoval
Mosthigh-powerheatpipeapplicationshaveusedheatpipesorvaporchambers(aflatheatpipe)tohelpheatspreadingunderthebaseofapowermodule.Manytimesaseriesofroundheatpipesareembeddedinaheatsinkbasetohelpaveragethetemperatureofthealuminummountingplate.
Althoughthisisapositivestep,itstillleavesconventionalair-cooledfinsorextendedcoolingsurfacesoperatingatfinefficienciesoftenaslowas50%to60%.HeatpipesusedintheZ-axis,perpendiculartothebasemountingsurface,canofferfinefficienciesapproaching100%.
Fig.3.Acomparisonofefficiencyforahighratioextrusionheatsick(a),abonded-finheatsink(b),andaheatsinkwithheatpipeassemblyembeddedintheZ-axis(c).Overallthermalperformancevariesfrom100%fortheextrusionto150&
forthebonded-finheatsinktogreaterthan200%fortheheatsinkwithheatpipeassembly.
Fig.3showsacomparisonoffinefficienciesandoverallthermalperformanceforthreetypesofheatsinks-ahighratioextrusion,abonded-finheatsink,andaheatsinkwithaheat-pipeassemblymountedintheZ-axis.
Foranextrusionwithafinareaof1X,thefinefficiencyis70%to90%,andtheoverallthermalperformanceoftheheatsinkofthesamesize,afinareaof1.5Xisachieved,whichproducesafinefficiencyof60%to80%andanoverallthermalperformanceof150%.Inthecaseoftheheatsinkwithheatpipeassembly,afinefficiencyof3Xispossible.Thisheatsinkachievesafinefficiencyashighas90%to95%andanoverallthermalperformancegreaterthan200%.
Heatpipeswiththeabilitytomoveheatwithnear-zerotemperatureriseareemployedasconduitstoeliminatethisfinefficiencyproblem.Z-axiscoolerdesignuseslargediameterheatpipesmountedthroughabaseplateheatspreader,perpendiculartotheheatsinkmountingsurface.Heatspreadersintegraltotheheatpipesarepositionedinthebaseplatetomakemaximumcontacttothehighheatfluxsites(diepositions)underthepowermodule.
Theheatpipesmoveheatawayfromthebaseplateanduseaseriesofthin,copperfinsattachedtothepipestodissipatethisheatintoaforcedairstream.Duetotheeffectsoftheheatpipe,thecopperfinfurthestfromthebaseplatewillhavevirtuallythesamefinefficiencyastheclosestfin.Thisallowssignificantincreasesinfincountandcoolingsurfaceoveranextrusiontypeheatsink.InmanycasesZ-axiscoolerscanincreasecoolingofapowermodule(IGBTorsimilardevice)byupto100%
HeatPipeReliability
Overthepast40yearsofheatpipedesignandmanufacture,reliabilityandconsistencyofperformancehavealwaysbeenissues.Doheatpipesleakoverlongperiodsoftime?
Cantheycontinuetooperateattheirlimitsforyears?
Whataretheirlimits?
Tounderstandheatpipelongevityandpotentialfailure,itisnecessarytounderstandthemanufacturingstepsanddesignforreliability.Virtually100%ofprematurelyfailedheatpipescomefrom:
●Impropercleaning/oxidationoftheinterior.
●Improperfillingorcharging.
●Poorsealingorpotentialleakageovertime.
●Incompatiblematerials.
●Overtemperatureduringassembly.
Failuresalsocanbeseenastheresultofdesignersnotunderstandingthelimitationsofheatpipesinapplicationandlong-termuse.Intermsoflongevity,howaheatpipeisappliedisjustasimportantashowitisassembled.Inshortthesefailuremodesare:
●Dry-out(highheatloads/heatfluxes).
●Improperorientationtogravity.
●Sealing/crimpproblems.
●Flexfailureduetoshaping.
●Catastrophicfailureduetotoohightemperatureatassemblyorinoperation(Fig.4)
PredictingOperationalLife
Heatpipesaresimilartosemiconductorelectronicsinthattheydemonstratehigherfailureratesatstartup,duetoinitialinfantmortality,andattheendoflife,duetowear-out.Afterpassingthefirstfewhoursofoperation,aheatpipewillnormallyoperateformanytensofthousandsofhoursbeforefailureoccurs.
Inmanyreal-life,highduty-cycleapplications,largediameterheatpipeshavebeeninoperationformorethan20yearswithoutfailure.Theseapplicationsincludesteel-wheellocomotiveandtractiondrive,electricallypoweredpeoplemovers,aswellaswindpowergenerators,high-horsepoweracmotordrivesandregionbuses.
Onepredictorofpotentialheatpipelifeistheuseofshort-term,high-temperaturetestingtoinducefailureandmathematicallypredictwear-out.Theuseofcontrolledtemperaturechamberstoa
升级会员 