Flexural Strength of Thin Slabs Made of UHPFRC

Milan Holy; David Čítek; Petr Tej; Lukáš Vrablik

doi:10.4028/www.scientific.net/SSP.292.224

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Nonlinear Analysis and Comparison of Design Methods for Slender Concrete Columns with their Impact on Economy and Reliability
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Serviceability Limit State Evaluation in Discontinuity Regions
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B4 Model Adaptation for Prediction of UHPC Strains from Creep and Shrinkage
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Influence of Test Configuration on Bond Strength of GFRP Bars
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Flexural Strength of Thin Slabs Made of UHPFRC
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Cracking and Failure Mode of the Self-Stressed Members with FRP Bars
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Utilization of Vacuum-Formed Plastic Membranes for the Production of Lightened HPC Panels
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New Composite Construction Method with STEEL/UHPFRC Constructing Railway Bridges
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Limits and Potential of 3D Printing Technologies for Construction of Concrete Shells
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HomeSolid State PhenomenaSolid State Phenomena Vol. 292Flexural Strength of Thin Slabs Made of UHPFRC

Flexural Strength of Thin Slabs Made of UHPFRC

Abstract:

This paper focuses on the determination of the flexural strength of thin slabs made of the Ultra High Performance Fiber Reinforced Concrete (UHPFRC). The load-bearing capacity in bending of elements reinforced only with steel fibers (used as a scattered reinforcement) is primarily influenced by the orientation and distribution of the fibers. A size-effect occurs by these elements. Some special bending tests were executed within the development of precast bridge deck segments for an innovative timber-concrete composite bridge system. The bending tests were executed on the slab strips under similar boundary conditions as by the bridge deck segments. The slab strips of various thickness of 40, 50, 60, 70 and 80 mm were tested in 4-point bending tests with span 1900 mm and in 3-point bending tests with span 600 mm. Half of the test specimens was tested in casting position, the other half was tested upside down. The obtained values of the flexural strength were compared to values from reference bending tests of the beams 150 x 150 x 700 mm, 100 x 100 x 400 mm and 40 x 40 x 160 mm. An influence of the different size of the tested specimen, of the slab thickness, of the span size and of the positioning of the slab with respect to the direction of casting on the flexural strength are evaluated. The experiments are further supported by numerical simulation.

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Periodical:

Solid State Phenomena (Volume 292)

Pages:

224-229

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.292.224

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Online since:

June 2019

Authors:

Milan Holy*, David Čítek, Petr Tej, Lukáš Vrablik

Keywords:

Bending Test, Flexural Strength, UHPFRC

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