土木工程毕业设计外文文献翻译

..外文文献翻译ReinforcedConcrete〔来自?土木工程英语?〕Concreteandreinforcedconcreteareusedasbuildingmaterialsineverycountry.Inmany,includingtheUnitedStatesandCanada,reinforcedconcreteisadominantstructuralmaterialinengineeredconstruction.Theuniversalnatureofreinforcedconcreteconstructionstemsfromthewideavailabilityofreinforcingbarsandtheconstituentsofconcrete,gravel,sand,andcement,therelativelysimpleskillsrequiredinconcreteconstruction,andtheeconomyofreinforcedconcretecomparedtootherformsofconstruction.Concreteandreinforcedconcreteareusedinbridges,buildingsofallsortsundergroundstructures,watertanks,televisiontowers,offshoreoilexplorationandproductionstructures,dams,andeveninships.Reinforcedconcretestructuresmaybecast-in-placeconcrete,constructedintheirfinallocation,ortheymaybeprecastconcreteproducedinafactoryanderectedattheconstructionsite.Concretesevereandfunctionalindesign,ortheshapeandlayoutandbewhimsicalandartistic.Fewotherbuildingmaterialsoffthearchitectandengineersuchversatilityandscope.Concreteisstrongincompressionbutweakintension.Asaresult,cracksdevelopwheneverloads,orrestrainedshrinkageoftemperaturechanges,giverisetotensilestressesinexcessofthetensilestrengthoftheconcrete.Inaplainconcretebeam,themomentsabouttheneutralaxisduetoappliedloadsareresistedbyaninternaltension-compressioncoupleinvolvingtensionintheconcrete.Suchabeamfailsverysuddenlyandcompletelywhenthefirstcrackforms.Inareinforcedconcretebeam,steelbarsareembeddedintheconcreteinsuchawaythatthetensionforcesneededformomentequilibriumaftertheconcretecrackscanbedevelopedinthebars.Theconstructionofareinforcedconcretememberinvolvesbuildingafromofmoldintheshapeofthememberbeingbuilt.Theformmustbestrongenoughtosupportboththeweightandhydrostaticpressureofthewetconcrete,andanyforcesappliedtoitbyworkers,concretebuggies,reinforcementisplacedinthisformandheldinplaceduringtheconcretingoperation.Aftertheconcretehashardened,theformsareremoved.Astheformsareremoved,propsofshoresareinstalledtosupporttheweightoftheconcreteuntilithasreachedsufficientstrengthtosupporttheloadsbyitself.Thedesignermustproportionaconcretememberforadequatestrengthtoresisttheloadsandadequatestiffnesstopreventexcessivemustbeproportionedsothatitcanbeconstructed.Forexample,thereinforcementmustbedetailedsothatitcanbeassembledinthefield,andsincetheconcreteisplacedintheformafterthereinforcementisinplace,theconcretemustbeabletoflowaround,between,andpastthereinforcementtofillallpartsoftheformcompletely.Thechoiceofwhetherastructureshouldbebuiltofconcrete,steel,dependsontheavailabilityofmaterialsandonanumberofvaluedecisions.Thechoiceofstructuralsystemismadebythearchitectofengineerearlyinthedesign,basedonthefollowingconsiderations:Economy.Frequently,theforemostconsiderationistheoverallconstofthestructure.Thisis,ofcourse,afunctionofthecostsofthematerialsandthelabornecessarytoerectthem.Frequently,however,theoverallcostisaffectedasmuchormorebytheoverallconstructiontimesincethecontractorandownermustborroworotherwiseallocatemoneytocarryouttheconstructionandwillnotreceiveareturnonthisinvestmentuntilthebuildingisreadyforoccupancy.Inatypicallargeapartmentofcommercialproject,thecostofconstructionfinancingwillbeasignificantfractionofthetotalcost.Asaresult,financialsavingsduetorapidconstructionmaymorethanoffsetincreasedmaterialcosts.Forthisreason,anymeasuresthedesignercantaketostandardizethedesignandformingwillgenerallypayoffinreducedoverallcosts.Inmanycasesthelong-termeconomyofthestructuremaybemoreimportantthanthefirstcost.Asaresult,maintenanceanddurabilityareimportantconsideration.Suitabilityofmaterialforarchitecturalandstructuralfunction.Areinforcedconcretesystemfrequentlyallowsthedesignertocombinethearchitecturalandstructuralfunctions.Concretehastheadvantagethatitisplacedinaplasticconditionandisgiventhedesiredshapeandtexturebymeansoftheformsandthefinishingtechniques.Thisallowssuchelementsadflatplatesorothertypesofslabstoserveasload-bearingelementswhileprovidingthefinishedfloorand/orceilingsurfaces. Similarly, reinforced concrete walls can providearchitecturallyattractivesurfacesinadditiontohavingtheabilitytoresistgravity,wind,orseismicloads.Finally,thechoiceofsizeofshapeisgovernedbythedesignerandnotbytheavailabilityofstandardmanufacturedmembers.Fireresistance.ThestructureinabuildingmustwithstandtheeffectsofafireandremainstandingwhilethebuildingisevacuatedandAconcretebuildinginherentlyhasa1-to3-hourfireratingwithoutspecialfireproofingorotherdetails.Structuralsteelortimberbuildingsmustbefireproofedtoattainsimilarfireratings.Lowmaintenance.Concretemembersinherentlyrequirelessmaintenancethandostructuralsteelortimbermembers.Thisisparticularlytrueifdense,air-entrainedconcretehasbeenusedforsurfacesexposedtotheatmosphere,andifcarehasbeentakeninthedesigntoprovideadequatedrainageoffandawayfromthestructure.Specialprecautionsmustbetakenforconcreteexposedtosaltssuchasdeicingchemicals.Availabilityofmaterials.Sand,gravel,cement,andconcretemixingfacilitiesareverywidelyavailable,andreinforcingsteelcanbetransportedtomostjobsitesmoreeasilythancanstructuralsteel.Asaresult,reinforcedconcreteisfrequentlyusedinremoteareas.Ontheotherhand,thereareanumberoffactorsthatmaycauseonetoselectamaterialotherthanreinforcedconcrete.Theseinclude:Lowtensilestrength.Thetensilestrengthconcreteismuchlowerthanitscompressivestrength(about1/10),andhenceconcreteissubjecttocracking.Instructuralusesthisisovercomebyusingreinforcementtocarrytensileforcesandlimitcrackwidthstowithinacceptablevalues.Unlesscareistakenindesignandconstruction,however,thesecracksmaybeunsightlyormayallowpenetrationofwater.Whenthisoccurs,waterorchemicalssuchasroaddeicingsaltsmaycausedeteriorationorstainingoftheconcrete.Specialdesigndetailsarerequiredinsuchcases.Inthecaseofwater-retainingstructures,specialdetailsand/ofprestressingarerequiredtopreventleakage.Formsandshoring.Theconstructionofacast-in-placestructureinvolvesthreestepsnotencounteredintheconstructionofsteelortimberstructures.Theseare(a)theconstructionoftheforms,(b)theremovaloftheseforms,and(c)proppingorshoringthenewconcretetosupportitsweightuntilitsstrengthisadequate.Eachofthesestepsinvolveslaborand/ormaterials,whicharenotnecessarywithotherformsofconstruction.Relativelylowstrengthperunitofweightforvolume.Thecompressivestrengthofconcreteisroughly5to10%thatofsteel,whileitsunitdensityisroughly30%thatofsteel.Asaresult,aconcretestructurerequiresalargervolumeandagreaterweightofmaterialthandoesacomparablesteelstructure.Asaresult,long-spanstructuresareoftenbuiltfromsteel.Time-dependentvolumechanges.Bothconcreteandsteelundergo-approximatelythesameamountofthermalexpansionandcontraction.Becausethereislessmassofsteeltobeheatedorcooled,andbecausesteelisabetterconcrete,asteelstructureisgenerallyaffectedbytemperaturechangestoagreaterextentthanisaconcretestructure.Ontheotherhand,concreteundergoesfryingshrinkage,which,ifrestrained,maycausedeflectionsorcracking.Furthermore,deflectionswilltendtoincreasewithtime,possiblydoubling,duetocreepoftheconcreteundersustainedloads.Inalmosteverybranchofcivilengineeringandarchitectureextensiveuseismadeofreinforcedconcreteforstructuresandfoundations.Engineersandarchitectsrequiresbasicknowledgeofreinforcedconcretedesignthroughouttheirprofessionalcareers.Muchofthistextisdirectlyconcernedwiththebehaviorandproportioningofcomponentsthatmakeuptypicalreinforcedconcretestructures-beams,columns,andslabs.Oncethebehavioroftheseindividualelementsisunderstood,thedesignerwillhavethebackgroundtoanalyzeanddesignawiderangeofcomplexstructures,suchasfoundations,buildings,andbridges,composedoftheseelements.Sincereinforcedconcreteisanohomogeneousmaterialthatcreeps,shrinks,andcracks,itsstressescannotbeaccuratelypredictedbythetraditionalequationsderivedinacourseinstrengthofmaterialsforhomogeneous elasticmaterials.Muchofreinforcedconcretedesigninthereforeempirical,i.e.,designequationsanddesignmethodsarebasedonexperimentalandtime-provedresultsinsteadofbeingderivedexclusivelyfromtheoreticalformulations.Athoroughunderstandingofthebehaviorofreinforcedconcretewillallowthedesignertoconvertanotherwisebrittlematerialintotoughductilestructuralelementsandtherebytakeadvantageofconcrete’sdesirablecharacteristics,itshighcompressivestrength,itsfireresistance,anditsdurability.likematerial,ismadebymixingcement,water,fineaggregate(oftensand),coarseaggregate,andfrequentlyotheradditives(thatmodifyproperties)intoaworkablemixture.Initsunhardenedorplasticstate,concretecanbeplacedinformstoproducealargevarietyofstructuralelements.Althoughthehardenedconcretebyitself,i.e.,withoutanyreinforcement,isstrongincompression,itlackstensilestrengthandthereforecrackseasily.Becauseunreinforcedconcreteisbrittle,itcannotundergolargedeformationsunderloadandfailssuddenly-withoutwarning.Theadditionfosteelreinforcementtotheconcretereducesthenegativeeffectsofitstwoprincipalinherentweaknesses,itssusceptibilitytocrackinganditsbrittleness.Whenthereinforcementisstronglybondedtotheconcrete,astrong,stiff,andductileconstructionmaterialisproduced.Thismaterial,calledreinforcedconcrete,isusedextensivelytoconstructfoundations,structuralframes,storagetakes,shellroofs,highways,walls,dams,canals,andinnumerableotherstructuresandbuildingproducts.Twoothercharacteristicsofconcretethatarepresentevenwhenconcreteisreinforcedareshrinkageandcreep,butthenegativeeffectsofthesepropertiescanbemitigatedbycarefuldesign.Acodeisasettechnicalspecificationsandstandardsthatcontrolimportantdetailsofdesignandconstruction.Thepurposeofcodesitproducestructuressothatthepublicwillbeprotectedfrompoorofinadequateandconstruction.Twotypesfcoedsexist.Onetype,calledastructuralcode,isoriginatedandcontrolledbyspecialistswhoareconcernedwiththeproperuseofaspecificmaterialorwhoareinvolvedwiththesafedesignofaparticularclassofstructures.Thesecondtypeofcode,calledabuildingcode,isestablishedtocoverconstructioninagivenregion,oftenacityorastate.Theobjectiveofabuildingcodeisalsotoprotectthepublicbyaccountingfortheinfluenceofthelocalenvironmentalconditionsonconstruction.Forexample,localauthoritiesmayspecifyadditionalprovisionstoaccountforsuchregionalconditionsasearthquake,heavysnow,orstructuralcodesgenrallyareincorporatedintolocalbuildingcodes.TheAmericanConcreteInstitute(ACI)BuildingCodecoveringthedesignofreinforcedconcretebuildings.Itcontainsprovisionscoveringallaspectsofreinforcedconcretemanufacture,design,andconstruction.Itincludesspecificationsonqualityofmaterials,detailsonmixingandplacingconcrete,designassumptionsfortheanalysisofcontinuousstructures,andequationsforproportioningmembersfordesignforces.Allstructuresmustbeproportionedsotheywillnotfailordeformexcessivelyunderanypossibleconditionofservice.Thereforeitisengineerusegreatcareinanticipatingalltheprobableloadstowhichastructurewillbesubjectedduringitslifetime.Althoughthedesignofmostmembersiscontrolledtypicallybydeadandliveloadactingsimultaneously,considerationmustalsobegiventotheforcesproducedbywind,impact,shrinkage,temperaturechange,creepandsupportsettlements,earthquake,andsoforth.Theloadassociatedwiththeweightofthestructureitselfanditspermanentcomponentsiscalledthedeadload.Thedeadloadofconcretemembers,whichissubstantial,shouldneverbeneglectedindesigncomputations.Theexactmagnitudeofthedeadloadisnotknownaccuratelyuntilmembershavebeensized.Sincesomefigureforthedeadloadmustbeusedincomputationstosizethemembers,itsmagnitudemustbeestimatedatfirst.Afterastructurehasbeenanalyzed,thememberssized,andarchitecturaldetailscompleted,thedeadloadcanbecomputedmoreaccurately.Ifthecomputeddeadloadisapproximatelyequaltotheinitialestimateofitsvalue(orslightlyless),thedesigniscomplete,butifasignificantdifferenceexistsbetweenthecomputedandestimatedvaluesofdeadweight,thecomputationsshouldberevisedusinganimprovedvalueofdeadload.Anaccurateestimateofdeadloadisparticularlyimportantwhenspansarelong,sayover75ft(22.9m),becausedeadloadconstitutesamajorportionofthedesignload.Liveloadsassociatedwithbuildingusearespecificitemsofequipmentandoccupantsinacertainareaofabuilding,buildingcodesspecifyvaluesofuniformliveforwhichmembersaretobede