glass fibre reinforced polyetherimide on polymer and steel counterface materials.docx
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glass fibre reinforced polyetherimide on polymer and steel counterface materials.docx
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glassfibrereinforcedpolyetherimideonpolymerandsteelcounterfacematerials
Optimizationofinfraredradiationcureprocessparametersforglassfiberreinforcedpolymercomposites OriginalResearchArticle
Materials&Design,Volume32,Issue3,March2011,Pages1129-1137
P.KiranKumar,N.V.Raghavendra,B.K.Sridhara
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AbstractAbstract|Figures/TablesFigures/Tables|ReferencesReferences
Abstract
Elevatedtemperaturepostcuringisoneofthemostcriticalstepintheprocessingofpolymercomposites.Itensuresthatthecompletecross-linkingtakesplacetoproducethetargetedpropertiesofcomposites.Inthisworkinfraredradiation(IR)postcuringprocessforglassfiberreinforcedpolymercompositelaminatesisstudiedasanalternativetoconventionalthermalcure.DistancefromtheIRsource,curingscheduleandvolumeofthecompositewereselectedastheIRcureparametersforoptimization.Designofexperiments(DOE)approachwasadoptedforconductingtheexperiments.Tensilestrengthandflexuralstrengthofthecompositelaminateweretheresponsesmeasuredtoselectthefinalcureparameters.Analysisofvariance(ANOVA),surfaceplotsandcontourplotsclearlydemonstratethatthedistancefromtheIRsourceandvolumeofthecompositecontributenearly70%totheresponsefunctions.ThisestablishesthatpolymercompositescuredusingIRtechniquecanachievethesamepropertiesusingonly25%ofthetotaltimecomparedtothatofconventionalthermalcuring.
ArticleOutline
1.Introduction
2.Materials
3.Experiments
4.Resultsanddiscussion
5.Conclusions
Acknowledgements
References
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Graphicalabstract
Conventionalthermalpostcuringprocessofpolymercompositeshasthedisadvantagesoflongercureschedule,presenceofthermalgradientbetweenthecoreandouterlayersanduncuredresinpatcheswithinthecompositelaminate.Infraredradiation(IR)whichisapartofelectromagneticspectrum,likeotherradiationcuringmethods,itisutilizedforprocessingoffoodproducts,heatingmetalsandotherapplications.Thesametechnologyisextendedforcuringofpolymercompositelaminatesinthiswork.IRcuringresultsinvolumetricheating,henceitisfasterandbettercomparedtothermalcuring.Considerableamountoftimeissavedasunderstoodfromthegraph.
Researchhighlights
►IRcuringutilizesonly25%oftotaltimeascomparedtoconventionalthermalcuringmethod.►TheoptimizedprocessparametershavebeendevelopedforInfraredradiationcuringprocess.►Infraredradiationcuringcanbeeffectivelyemployedforcuringofpolymercompositelaminates.
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Amethodforoptimaldesignofsteelfiberreinforcedconcretecomposition OriginalResearchArticle
Materials&Design,InPress,CorrectedProof,Availableonline19February2011
L.Dvorkin,O.Dvorkin,V.Zhitkovsky,Y.Ribakov
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Abstract
Existingdesignapproachesforsteelfiberreinforcedconcretecompositionpracticallydonotconsidertheinteractionbetweentheconcretecomponents.Itdecreasesthedesignefficiencyandaccuracy.Thepaperdealswithmethodologyfordesignofoptimalsteelfiberedfine-grainedconcretecompositionbasedonstiffmixtures.Suchconcreteisusedforproductionofthinwalledpreciseelements.Thecurrentinvestigationenablestofindtheinfluenceofthemainfactors(water–cementratio,fibercontent,finenessandquantityofsand)ontheconcretemixturestiffness,compressiveandflexuralstrengthofconcrete.Thestudyhasalsoenabledtoobtaincorrespondingmathematicalmodelsofconcreteproperties.Basedonthemodelsamethodologyfordesignofsteelfiberedconcretewasdevelopedandappropriatenomogramswereprepared.Theproposedmethodologyallowsobtainingofoptimalsteelfiberedfine-grainedconcretecomposition,takingintoaccounttherequiredflexuralstrengthofconcrete,sandfinenessandconcretemixtureworkability.
ArticleOutline
1.Introduction
2.AvailablemethodsfordesignofSFCmixtures
3.Researchsignificance,aimandscope
4.Experimentsplanning
5.Modeldescription
6.Experimentalprogram
6.1.Materialsproperties
6.2.Descriptionofspecimens,storageconditionsandtestsetup
7.Resultsanddiscussion
8.Numericalexample
9.Conclusions
References
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Highlights
►Mathematicalmodelsforexperimentsplanningareused.►Nomogramsfordesignofsteelfiberedconcretearedeveloped.►Designofconcretecompositionaccordingtodesiredpropertiesisproposed.
Torsionalstrengtheningofrectangularandflangedbeamsusingcarbonfibre-reinforced-polymers–Experimentalstudy OriginalResearchArticle
ConstructionandBuildingMaterials,Volume22,Issue1,January2008,Pages21-29
ConstantinE.Chalioris
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Abstract
Thepresentexperimentalinvestigationdealswiththetorsionalstrengtheningofconcretebeamswithoutstirrupsusingepoxy-bondedcarbonfibre-reinforced-polymer(FRP)sheetsandstripsasexternaltransversereinforcement.Theexperimentalprogramcomprises14rectangularandT-shapedbeamstestedunderpuretorsion.Basedonthemeasuredvaluesofthetorsionalmomentatcrackingandatultimate,thecorrespondingtwists,thebehaviouralcurvesandthefailuremodesofthebeams,usefulconcludingremarksareindicated.ThestrengthenedrectangularbeamsusingfullwrappingwithcontinuousFRPsheetsperformedenhancedtorsionalbehaviourandhighercapacitythanthestrengthenedbeamswithFRPstrips.U-jacketedflangedbeamsexhibitedprematuredebondingfailureandsubstantialreductionsofthepotentialtorsionalcapabilitiesarereported.Ingeneral,FRPfabricscouldeffectivelybeusedasexternaltorsionalreinforcementinunder-reinforcedconcreteelementswithoutsteeltransversereinforcement.
ArticleOutline
1.Introduction
2.Experimentalprogram
2.1.Specimencharacteristics
2.2.Testsetup
3.Testresultsanddiscussions
3.1.Torsionalstrengthvaluesandbehaviouralcurves
3.2.Crackpatternsandfailuremodes
3.3.ContributionofFRPsheetstothetorsionalcapacity
4.Concludingremarks
Acknowledgements
References
Vitae
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29
CombinedloadingofabridgedeckreinforcedwithastructuralFRPstay-in-placeform OriginalResearchArticle
ConstructionandBuildingMaterials,Volume23,Issue4,April2009,Pages1605-1619
JosephP.Hanus,LawrenceC.Bank,MichaelG.Oliva
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Abstract
Theinvestigationofastructuralfiber-reinforced-polymer(FRP)stay-in-place(SIP)formusedtoconstructandreinforceadeckforaprototypemilitarybridgesystemisdiscussedinthispaper.Forthisapplicationthedeckissubjectedtocombinedbendingandcompressivelongitudinalaxialloadbecauseitalsoservesasthetopchordofthetrussforthebridgesystem.Inanexperimentalprogram,deckspecimensweretestedinseveralconfigurations.TheresultsarecomparedtoACI440designguideequations,andcapacitypredictiontechniquesareproposedforlimitstatesassociatedwithflexuralandflexural-shearunderthecombinedloading.ItwasfoundthattheACI440equationsaccuratelypredictedtheflexuralandflexural-shearcapacitiesundercombinedloadsprovidedthateccentricityduetothecombinedloadingwasaccountedforinthecalculations.
ArticleOutline
1.Introduction
2.Deckcomponentdesign
3.Experimentalprogram
3.1.Constructionofspecimens
3.1.1.Singlespanspecimens
3.1.2.Doublespanspecimens
3.2.Specimendetails
3.3.Testsetup,instrumentation,andloading
3.3.1.Singlespantestconfigurationwithoutaxialload
3.3.2.Singlespantestconfigurationwithaxialload
3.3.3.Doublespantestconfigurationwithaxialload
3.3.4.Instrumentation
3.3.5.Loading
3.4.Testresults
3.4.1.Singlespantestresultswithoutaxialload
3.4.2.Singlespantestresultswithaxialload
3.4.3.Doublespantestresultswithaxialload
3.4.4.Moment–deflectioncurves,allspecimens
4.Analysis
4.1.Neutralaxisdepth
4.2.Flexuralfailureinspecimenswithbendingloadonly(SS1–SS4)
4.3.Flexuralfailureincombinedbendingandaxiallyloadedspecimens(SS5–SS8)
4.4.Flexural-shearfailureincombinedbendingandaxiallyloadedspecimens(DSA1–DSA2)
5.Conclusions
Acknowledgements
References
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Delaminationofpultrudedglassfiber-reinforcedpolymercompositessubjectedtoaxialcompression OriginalResearchArticle
CompositeStructures,Volume91,Issue1,November2009,Pages66-73
YuBai,TillVallée,ThomasKeller
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Abstract
AxialcompressionexperimentswereconductedonpultrudedE-glassfiber-reinforcedpolymerlaminatesofdifferentslenderness.Second-orderdeformationsgreatlyincreasedthebendingmomentsandshearforcesofslenderspecimens.Delaminationfailureoccurredinallspecimens,independentofslenderness.Basedonmeasurementsoflateraldeformationsatdelaminationinitiation,thedistributionofshearforceswasdeterminedandthestressstateatfailurewasobtainedandcomparedtoanadoptedfailurecriterion.Ultimateloadswerefurtherpredictedba
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