Simulation and test of flexural performance of polyvinyl alcohol-steel hybrid fiber reinforced cementitious composite

Zhang, Jun; Wang, Zhenbo; Wang, Qing; Gao, Yuan

doi:10.1177/0021998316636206

Cited by 26 publications

(16 citation statements)

References 19 publications

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“…With the development of structural engineering, high‐strength concrete (HSC) or ultra‐high‐strength concrete (UHSC) characterized by a lower water‐to‐binder ratio, addition of fine and active admixtures (i.e., silica fume, fly ash and ground granulated blast furnace slag, and so on) as well as special curing technologies is proposed and designed by a large number of researchers and engineers . However, it has been widely recognized that concrete, especially HSC or UHSC, is a typical brittle material, and after its first cracking in tension, localization of deformation will occur immediately followed by decreasing load . Resultantly, the durability and life of concrete structures are deteriorated seriously.…”

Section: Introductionmentioning

confidence: 99%

“…On the one hand, a class of high‐performance fiber‐reinforced cementitious composite, called engineered cementitious composite (ECC), has been micromechanically developed to provide an ultimate strength higher than the first cracking strength . The typically extreme tensile strain capacity of ECC can be more than 2% while only a moderate amount of fibers (generally less than 2% in fraction) is required .…”

Section: Introductionmentioning

confidence: 99%

“…1,2 However, it has been widely recognized that concrete, especially HSC or UHSC, is a typical brittle material, and after its first cracking in tension, localization of deformation will occur immediately followed by decreasing load. 3,4 Resultantly, the durability and life of concrete structures are deteriorated seriously. To overcome these shortcomings and enhance mechanical performance of concrete, randomly distributed fibers have been introduced as a reinforcement material during the last few decades.…”

Section: Introductionmentioning

confidence: 99%

“…On the one hand, a class of high-performance fiberreinforced cementitious composite, called engineered cementitious composite (ECC), has been micromechanically developed to provide an ultimate strength higher than the first cracking strength. 3,4,7,8 The typically extreme tensile strain capacity of ECC can be more than 2% while only a moderate amount of fibers (generally less than 2% in fraction) is required. 7 Since 1990s, the mechanical and durability-related performances of ECC are explored and discussed at material and structural component levels, such as in the works of Alrefaei et al, 9 Li et al, 10 Bezerra et al, 11 Lepech et al, 8 Lee et al, 7 Xu et al, 12 Ahmed and Mihashi, 13 Li et al, 3 Zhang et al, 4 and Li et al 14 Moreover, ECC has been applied in some engineering practice cases.…”

Section: Introductionmentioning

confidence: 99%

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Static and dynamic mechanical properties of eco‐friendly polyvinyl alcohol fiber‐reinforced ultra‐high‐strength concrete

Zhang

Jin

YiShui

et al. 2019

Structural Concrete

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An eco‐friendly polyvinyl alcohol (PVA) fiber‐reinforced ultra‐high‐strength concrete (PFR‐UHSC) was designed and mixed to evaluate its static and dynamic mechanical properties in this study. A lower water‐to‐binder ratio of 0.22 and a superplasticizer were used to guarantee the performance of PFR‐UHSC, while several industrial by‐products were involved to reduce the negative environmental impact of concrete. Four volume fraction of PVA fibers (Vf = 0, 0.5, 1.0, and 1.5%) were included in the experiment and steel fiber‐reinforced ultra‐high‐strength concrete (SFR‐UHSC) with Vf = 1.0% was also tested as a comparison. Experiment results show that although less ductile than SFR‐UHSC, PFR‐UHSC exhibits relatively good ductility, toughness, and deformability under static loadings. Namely, splitting tensile and flexural strengths as well as flexural toughness of PFR‐UHSC are significantly improved by the incorporation of PVA fibers while no obvious variation is viewed for Young's modulus. And even, the compressive strength of PFR‐UHSC decreases slightly with the increasing PVA fiber dosage. When subjected to dynamic loadings with lower strain rates, PFR‐UHSC displays a better performance than SFR‐UHSC in terms of failure patterns, while a reverse behavior is observed for high strain rate. Affected by introduction of PVA fiber, the enhancement of strain rate for compressive strength of PFR‐UHSC is lower than that for ordinary concrete but higher than that for SFR‐UHSC. Besides, although having a slightly lower compressive toughness, the energy absorption capacity of PFR‐UHSC is similar to that of SFR‐UHSC.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Static and dynamic mechanical properties of eco‐friendly polyvinyl alcohol fiber‐reinforced ultra‐high‐strength concrete

Zhang

Jin

YiShui

et al. 2019

Structural Concrete

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“…Since the distance was smaller, the thickness of the weak link of the fiber-matrix layer was thinner which indicated that the fiber could adhere the matrix with much fastness; this meant that the mechanical strength was well developed. As assumed, the CaCO 3 whiskers were well dispersed in the three-dimensional direction in the cement paste and the equation of the average distance of the CaCO 3 whiskers was shown as follows [24][25][26]:…”

Section: Micromechanical Mechanismsmentioning

confidence: 99%

Mechanical Attributes of Uniaxial Compression for Calcium Carbonate Whisker Reinforced Oil Well Cement Pastes

Yang

Shun

2017

Advances in Materials Science and Engineering

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It is crucial for design and safety of the cementing sheath to develop better understanding of the CaCO 3 whisker reinforced oil well cement pastes. The uniaxial compression curve, mechanical constitutive relation, and reinforcing mechanism of the CaCO 3 whisker reinforced oil well cement pastes are studied in this script. The results indicate that the CaCO 3 whisker under the 10% dosage could improve the tensile strength of the cement paste significantly. The peak stress, elasticity modulus, and the energy at different stages of the stress-strain curve of the CaCO 3 whisker reinforced cement paste are reinforced with the increasing of CaCO 3 whisker. Afterward, the constitutive model of stress-strain curve, the toughness index, and capability coefficients index of the CaCO 3 whisker reinforced cement paste are established. A physical model of the interface layer is also established and the micromechanical reinforcement is related to the double film layer between the CaCO 3 whisker and cement matrix which could be bonded with much more fastness to the cement surface. The development of this script provides new ways to analyze the toughening mechanism of CaCO 3 whisker and establishes a correlation between basic material structure and the physical properties.

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Carbon Fiber Composites

Perumal

Nambiar

Sellamuthu

et al. 2020

Handbook of Nanomaterials and Nanocomposites for Energy and Environmental Applications

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Simulation and test of flexural performance of polyvinyl alcohol-steel hybrid fiber reinforced cementitious composite

Cited by 26 publications

References 19 publications

Static and dynamic mechanical properties of eco‐friendly polyvinyl alcohol fiber‐reinforced ultra‐high‐strength concrete

Static and dynamic mechanical properties of eco‐friendly polyvinyl alcohol fiber‐reinforced ultra‐high‐strength concrete

Mechanical Attributes of Uniaxial Compression for Calcium Carbonate Whisker Reinforced Oil Well Cement Pastes

Carbon Fiber Composites

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