Predicting the flexural load–deflection response of steel fibre reinforced concrete from strain, crack-width, fibre pull-out and distribution data

Jones, P. A.; Austin, Simon A.; Robins, Peter J.

doi:10.1617/s11527-007-9327-9

Cited by 40 publications

(24 citation statements)

References 12 publications

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“…In order to predict the moment capacity, the load-crack mouth opening relation for a particular FRC is used in the stressstrain profile in the flexural analysis. A similar approach is presented in [30], where a semi-analytical model is proposed to predict the flexural response of SFRC. This model also uses a stress-block approach and relates the flexural capacity of the critical section to the following parameters: the compressive stress-train relation, the tensile stress-strain relation, the fiber pullout, the number and distribution of the fibers across the cracked section (in terms of position, orientation and embedment lengths) as well as the strain/crack width relation at a given mid-span deflection.…”

Section: Direct Approachmentioning

confidence: 99%

Application of constitutive models in European codes to RC–FRC

Blanco

Pujadas

Fuente

et al. 2013

Construction and Building Materials

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The recent publication of codes for the design of FRC is a major step towards extending the use of the material. An in depth analysis indicates several differences between the constitutive models proposed in the existing codes. In this study, these models are compared and a numerical simulation is performed to evaluate their differences in terms of the structural behavior predicted and measured in an experimental program of RC-FRC elements. The predictions provided by the models fit satisfactorily the experimental results for elements with steel fibers and with plastic fibers

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Section: Direct Approachmentioning

confidence: 99%

Application of constitutive models in European codes to RC–FRC

Blanco

Pujadas

Fuente

et al. 2013

Construction and Building Materials

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“…A practical example to show the application of the proposed methodology is presented in this section, using data from Jones et al 4 . In order to characterize the pull-out versus crack opening curve, the load/deflection curves from tests undertaken on seven 75mm deep unnotched beams containing 40kg/m 3 of 30mm length and 0.5mm diameter hooked steel fibres were initially analysed ( Figure 5).…”

Section: Application Of the Proposed Modelmentioning

confidence: 99%

“…The components of bond can be classified as: the physical and/or chemical adhesion between fibre and matrix; the frictional resistance; the mechanical component (associated with a particular geometry of the fibre be it deformed, crimped, or hooked); and the fibre-to-fibre interlock 2 . To deal with this, several authors 3,4 have determined the average response of the load transmitted by the fibres through the cracked region from pull-out tests of single fibres. Some problems arise with this approach, namely: the number and position of the fibres bridging the crack is not precise, the load supported by each fibre depends on the crack opening displacement (a function of the specimen displacement), the orientation of the fibre and the embedment length.…”

Section: Introductionmentioning

confidence: 99%

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Prediction of steel fibre reinforced concrete under flexure from an inferred fibre pull-out response

et al. 2006

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“…erefore, the response of PVA and basalt fibres in concrete is different and cannot be predicted through the available model of steel fibre-reinforced concrete (SFRC) [12]. e reason of unsuitability of available models is that the post-peak stress-strain response of FRC solely depends on the fibre properties including fibre modulus of elasticity, elongation, and bond characteristics [11].…”

Section: Introductionmentioning

confidence: 99%

Flexural Modelling and Finite Element Analysis of FRC Beams Reinforced with PVA and Basalt Fibres and Their Validation

Ayub

Shafiq

2018

Advances in Civil Engineering

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A flexural capacity model for fibre-reinforced concrete (FRC) beams reinforced with PVA and basalt fibres is suggested for the rectangular beam sections. e proposed models are based on the concept of equivalent stress block parameters for both compressive and tensile stresses, similar to Eurocode and ACI code. e parameters are defined by allowing the conversion of the stress-strain models into equivalent rectangular stress blocks, similar to Eurocode 2. e flexural model is suggested to determine the loading capacity of 21 FRC beams containing up to 3% volume fraction of PVA and basalt fibres without reinforcing bars. In order to investigate the accuracy of the proposed flexure models, finite element analysis (FEA) of the same beams was carried out using the compressive and tensile stress-strain curves. Furthermore, 21 FRC beams subjected to three-point bending were tested.e results of the flexural models showed good agreement with the load-carrying capacity of the tested FRC beams, and the results of FEA of all beams showed a good correlation with the experimental results in terms of the maximum load, load versus midspan deflection patterns, and the maximum tensile strains.

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Predicting the flexural load–deflection response of steel fibre reinforced concrete from strain, crack-width, fibre pull-out and distribution data

Cited by 40 publications

References 12 publications

Application of constitutive models in European codes to RC–FRC

Application of constitutive models in European codes to RC–FRC

Prediction of steel fibre reinforced concrete under flexure from an inferred fibre pull-out response

Flexural Modelling and Finite Element Analysis of FRC Beams Reinforced with PVA and Basalt Fibres and Their Validation

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