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Effect of Fibre Material and Fibre Roughness on the Pullout Behaviour of Metallic Micro Fibres Embedded in UHPC

dc.date.accessioned2020-09-10T13:38:54Z
dc.date.available2020-09-10T13:38:54Z
dc.date.issued2020-07-14
dc.identifierdoi:10.17170/kobra-202009091757
dc.identifier.urihttp://hdl.handle.net/123456789/11795
dc.description.sponsorshipGefördert durch den Publikationsfonds der Universität Kasselger
dc.language.isoengeng
dc.rightsNamensnennung 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/*
dc.subjecthigh-performance concreteeng
dc.subjectfibre reinforcementeng
dc.subjectshape memory alloyseng
dc.subjectpullout strengtheng
dc.subjectfibre/matrix bondeng
dc.subject.ddc500
dc.titleEffect of Fibre Material and Fibre Roughness on the Pullout Behaviour of Metallic Micro Fibres Embedded in UHPCeng
dc.typeAufsatz
dcterms.abstractThe use of micro fibres in Ultra-High-Performance Concrete (UHPC) as reinforcement increases tensile strength and especially improves the post-cracking behaviour. Without using fibres, the dense structure of the concrete matrix results in a brittle failure upon loading. To counteract this behaviour by fibre reinforcement, an optimal bond between fibre and cementitious matrix is essential. For the composite properties not only the initial surfaces of the materials are important, but also the bonding characteristics at the interfacial transition zone (ITZ), which changes upon the joining of both materials. These changes are mainly induced by the bond of cementitious phases on the fibre. In the present work, three fibre types were used: steel fibres with brass coating, stainless-steel fibres as well as nickel-titanium shape memory alloys (SMA). SMA fibres have the ability of “remembering” an imprinted shape (referred to as shape memory effect), triggered by thermal activation or stress, principally providing for superior performance of the fibre-reinforced UHPC. However, previous studies have shown that NiTi-fibres have a much lower bond strength to the concrete matrix than steel fibres, eventually leading to a deterioration of the mechanical properties of the composite. Accordingly, the bond between both materials has to be improved. A possible strategy is to roughen the fibre surfaces to varying degrees by laser treatment. As a result, it can be shown that laser treated fibres are characterised by improved bonding behaviour. In order to determine the bond strength of straight, smooth fibres of different metal alloy compositions, the present study characterized multiple fibres in series with a Compact-Tension-Shear (CTS) device. For critical evaluation, results obtained by these tests are compared with the results of conventional testing procedures, i.e., bending tests employing concrete prisms with fibre reinforcements. The bond behaviour is compared with the results of the flexural strength of prisms (4 × 4 × 16 cm3) with fibre reinforcements.eng
dcterms.accessRightsopen access
dcterms.creatorWiemer, Niels
dcterms.creatorWetzel, Alexander
dcterms.creatorSchleiting, Maximilian
dcterms.creatorKrooß, Philipp
dcterms.creatorVollmer, Malte
dcterms.creatorNiendorf, Thomas
dcterms.creatorBöhm, Stefan
dcterms.creatorMiddendorf, Bernhard
dc.relation.doidoi:10.3390/ma13143128
dc.subject.swdUltrahochfester Betonger
dc.subject.swdMikrofaserger
dc.subject.swdMemory-Legierungger
dc.subject.swdMechanische Eigenschaftger
dc.type.versionpublishedVersion
dcterms.source.identifierEISSN 1996-1944
dcterms.source.issueIssue 14
dcterms.source.journalMaterialseng
dcterms.source.pageinfo3128
dcterms.source.volumeVolume 13
kup.iskupfalse


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Except where otherwise noted, this item's license is described as Namensnennung 4.0 International