Effect of Fiber Orientation on the Fatigue Behavior of Steel Fiber-Reinforced Concrete Specimens by Performing Wedge Splitting Tests and Computed Tomography Scanning
暂无分享,去创建一个
[1] Lihua Xu,et al. Mechanical performance of steel-polypropylene hybrid fiber reinforced concrete subject to uniaxial constant-amplitude cyclic compression: Fatigue behavior and unified fatigue equation , 2023, Composite Structures.
[2] O. Ozturk,et al. Sustainability and cost-effectiveness of steel and polypropylene fiber reinforced concrete pavement mixtures , 2022, Journal of Cleaner Production.
[3] Zhiguang Zhou,et al. Mechanical Properties of Natural as well as Synthetic Fiber Reinforced Concrete: A Review , 2022, Construction and Building Materials.
[4] D. Shen,et al. Early-age autogenous Shrinkage and tensile creep of hooked-end steel fiber reinforced concrete with different thermal treatment temperatures , 2022, Cement and Concrete Composites.
[5] J. J. Ortega,et al. Size effect on the compressive fatigue of fibre-reinforced concrete , 2022, Construction and Building Materials.
[6] M. Cao,et al. Effectiveness of hybrid steel-basalt fiber reinforced concrete under compression , 2022, Case Studies in Construction Materials.
[7] R. Masmoudi,et al. Valorization of recycled FRP materials from wind turbine blades in concrete , 2021 .
[8] Chenglin Wu,et al. Effects of fiber clustering on fatigue behavior of steel fiber reinforced concrete beams , 2021 .
[9] D. González,et al. Use of Computed Tomography Scan Technology to Explore the Porosity of Concrete: Scientific Possibilities and Technological Limitations , 2021, Applied Sciences.
[10] Le Huang,et al. Fatigue life analysis of polypropylene fiber reinforced concrete under axial constant-amplitude cyclic compression , 2021 .
[11] Le Huang,et al. Constitutive behavior of hybrid fiber reinforced concrete subject to uniaxial cyclic tension: Experimental study and analytical modeling , 2021 .
[12] G. Plizzari,et al. Influence of fiber orientation on the behavior of fiber reinforced concrete slabs , 2021, Structural Concrete.
[13] Yanmin Jia,et al. Mechanical properties and microstructure of glass fiber and polypropylene fiber reinforced concrete: An experimental study , 2021 .
[14] R. Kurda,et al. Environmental and economic benefits of steel, glass, and polypropylene fiber reinforced cement composite application in jointed plain concrete pavement , 2020, Composites Communications.
[15] L. Qureshi,et al. Flexural behavior of glass fiber-reinforced recycled aggregate concrete and its impact on the cost and carbon footprint of concrete pavement , 2020 .
[16] H. Cifuentes,et al. Microstructural analyses of the addition of PP fibres on the fracture properties of high-strength self-compacting concrete by X-ray computed tomography , 2020 .
[17] J. Xia,et al. Fibre Distribution Characterization of Ultra-High Performance Fibre-Reinforced Concrete (UHPFRC) Plates Using Magnetic Probes , 2020, Materials.
[18] Álvaro Mena Alonso,et al. La tomografía computerizada más allá de la medicina: Aplicaciones al estudio microestructural del hormigón y otros materiales de la ingeniería , 2020 .
[19] D. González,et al. Influence of Fibers and Curing Conditions on the Pore Morphology in Plain and Fiber-Reinforced High-Performance Concrete through the Use of Computed Tomography Scan Technology , 2020, Applied Sciences.
[20] Majid Ali,et al. Efficiency of silica-fume content in plain and natural fiber reinforced concrete for concrete road , 2020 .
[21] S. Mirjavadi,et al. Investigation of the Effect of Larestan’s Pipeline Water on the Mechanical Properties of Concretes Containing Granite Aggregates , 2019, Advances in Civil Engineering.
[22] G. Ruiz,et al. Effects of fiber orientation and content on the static and fatigue behavior of SFRC by using CT-Scan technology , 2019, International Journal of Fatigue.
[23] S. Cavalaro,et al. Fatigue of cracked high performance fiber reinforced concrete subjected to bending , 2019, Construction and Building Materials.
[24] Miguel A. Vicente,et al. Plain and Fiber-Reinforced Concrete Subjected to Cyclic Compressive Loading: Study of the Mechanical Response and Correlations with Microstructure Using CT Scanning , 2019, Applied Sciences.
[25] Jesús Mínguez,et al. Computed tomography scanning of the internal microstructure, crack mechanisms, and structural behavior of fiber-reinforced concrete under static and cyclic bending tests , 2019, International Journal of Fatigue.
[26] Jesús Mínguez,et al. Recent advances in the use of computed tomography in concrete technology and other engineering fields. , 2019, Micron.
[27] M. Karaaslan,et al. A Nondestructive Method for Determining Fiber Content and Fiber Ratio in Concretes Using a Metamaterial Sensor Based on a V-Shaped Resonator , 2019, Journal of Electronic Materials.
[28] D. González,et al. Study of the effect of the fibers’ orientation on the post-cracking behavior of steel fiber reinforced concrete from wedge-splitting tests and computed tomography scanning , 2018, Construction and Building Materials.
[29] Giovanni Plizzari,et al. The effect of fiber orientation on the post-cracking behavior of steel fiber reinforced concrete under bending and uniaxial tensile tests , 2018, Cement and Concrete Composites.
[30] G. Ruiz,et al. CT-Scan study of crack patterns of fiber-reinforced concrete loaded monotonically and under low-cycle fatigue , 2018, International Journal of Fatigue.
[31] E. Landis,et al. A methodology for quantifying the impact of casting procedure on anisotropy in fiber-reinforced concrete using X-ray CT , 2018 .
[32] D. González,et al. Fiber geometrical parameters of fiber-reinforced high strength concrete and their influence on the residual post-peak flexural tensile strength , 2018 .
[33] D. González,et al. Postcracking residual strengths of fiber‐reinforced high‐performance concrete after cyclic loading , 2018 .
[34] E. Mohseni,et al. Restrained Shrinkage Cracking of Fiber-Reinforced High-Strength Concrete , 2018 .
[35] L. Vandewalle,et al. Uniaxial tensile creep of a cracked polypropylene fiber reinforced concrete , 2018 .
[36] M. Shoukath Ali,et al. Behavior of fiber reinforced concrete for controlling the rate of cracking in canal-lining , 2017 .
[37] Y. Uchida,et al. Relationship between fiber orientation/distribution and post-cracking behaviour in ultra-high-performance fiber-reinforced concrete (UHPFRC) , 2017 .
[38] Lennart Elfgren,et al. Experimental evaluation of tensile behaviour of single cast-in-place anchor bolts in plain and steel fibre-reinforced normal- and high-strength concrete , 2017 .
[39] G. Balázs,et al. Observation of steel fibres in concrete with Computed Tomography , 2017 .
[40] Jong-Han Lee. Influence of concrete strength combined with fiber content in the residual flexural strengths of fiber reinforced concrete , 2017 .
[41] Aki Kallonen,et al. Methods for fibre orientation analysis of X-ray tomography images of steel fibre reinforced concrete (SFRC) , 2016, Journal of Materials Science.
[42] Young Soo Yoon,et al. Structural performance of ultra-high-performance concrete beams with different steel fibers , 2015 .
[43] J. Katzer,et al. X-ray computed tomography of fibre reinforced self-compacting concrete as a tool of assessing its flexural behaviour , 2015, Materials and Structures.
[44] H. Al-Mattarneh. Electromagnetic quality control of steel fiber concrete , 2014 .
[45] B. Mobasher,et al. Backcalculation of residual tensile strength of regular and high performance fiber reinforced concrete from flexural tests , 2014 .
[46] D. González,et al. Determination of dominant fibre orientations in fibre-reinforced high-strength concrete elements based on computed tomography scans , 2014 .
[47] C. Blom,et al. Characterization of the orientation profile of steel fiber reinforced concrete , 2011 .
[48] P. R. Sparks,et al. The effect of rate of loading upon the static and fatigue strengths of plain concrete in compression , 1973 .
[49] Yubo Zhang,et al. Experimental Investigation on the Mechanical Properties of Natural Fiber Reinforced Concrete , 2022, Journal of Renewable Materials.
[50] L. Bank,et al. Concrete with discrete slender elements from mechanically recycled wind turbine blades , 2018 .
[51] H. Herrmann,et al. Time-efficient automated analysis for fibre orientations in steel fibre reinforced concrete , 2016 .
[52] G. Ruiz,et al. Effect of the loading frequency on the compressive fatigue behavior of plain and fiber reinforced concrete , 2015 .