Effect of fiber dosage on water permeability using a newly designed apparatus and crack monitoring of steel fiber–reinforced concrete under direct tensile loading

Hussain, Zahoor; Zhang, Pu; Hussain, Abasal; Ahmed, S.; Shah, Ajmal; Ali, Aitzaz; Azhar, A.B.M.

doi:10.1177/14759217211052855

Cited by 22 publications

(8 citation statements)

References 65 publications

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“…The appearance of crack and the crack region are localized by observing the drop in voltage using the six‐electrode method without conductive materials 209 . Nevertheless, only the smart cement composites with conductive filler could exhibit excellent self‐sensing property to monitor the crack damage under compression, 46 propagation of multiple cracks, 210 water permeability of the cracked concrete, 211 and provide forewarning of concrete degradation 212 . Among the several parameters, sensitivity and repeatability seem to be the significantly explored sensing properties investigated by the researchers.…”

Section: Mechanism Of Sensing Characteristicsmentioning

confidence: 99%

Smart cement‐sensor composite: The evolution of nanomaterial in developing sensor for structural integrity

Kanagasundaram

Elavenil

2023

Structural Concrete

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The integration of self‐sensing ability and different functional properties of nanomaterials into construction materials leads to smart and multifunctional cementitious sensor composites. Significant evolution of the Structural Health Monitoring (SHM) has helped to elevate the life span and mitigate damages of the structure. Developing smart cementitious sensor composite with electrical properties as a parent element and embedding it in the structural components have proved to be advantageous in terms of evaluating the damages, monitoring the periodic health and life assessment of the structures. In this review, the copious development processes and various methods of designing smart‐sensing cementitious composites have been scrutinized. This work recapitulates the principle of self‐sensing technique, typical functional fillers, trends of percolation threshold, dispersing material, dispersion technology, and also describes the required sensing ability of the sensors using the conduction theory. Subsequently application of smart cement‐sensors in structural components for SHM is discussed. In addition, this review article provides comprehensive information on the effects of nano materials and their dispersion in the development for smart and multifaceted cementitious sensor composites with enhanced sensitivity parameters and economic benefits that are suitable for future prospects.

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Section: Mechanism Of Sensing Characteristicsmentioning

confidence: 99%

Smart cement‐sensor composite: The evolution of nanomaterial in developing sensor for structural integrity

Kanagasundaram

Elavenil

2023

Structural Concrete

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“…Based on the fiber constitutive response, fiber dimensions, fiber functions and fiber performances hooked end steel fiber, polypropylene fiber and basalt fiber are selected for this research. Silica fume, fly ash are the essential constituents for making high strength concrete and to prevent depletion of fine aggregate, other waste material such as copper slag is used in this research to make the environment ecological sustainable [25][26][27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Effect of fiber synergy on strength & durability of high-performance concrete

Gupta

Raj

Sahu

et al. 2023

Mater. Res. Express

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The distinct fiber addition to concrete can improve weak performance in tension. Due to its higher performance, fiber hybridization is becoming more and more competitive. In this study, the hardened and durability characteristics of performance-based concrete reinforced with polypropylene, basalt and hooked end steel fibers are investigated. Total 12 mixes are prepared to evaluate the different characteristics of performance-based concrete. The influence of basalt fibers (BFs 0.2, 0.25, 0.5, 0.75 & 1 %), polypropylene fibers (PFs 0.025, 0.03, 0.035, 0.05 & 1%), hooked end steel fibers (SF 0.225, 0.475, 0.65, 0.75, 0.80 & 1%) to explore the impact of fiber synergy, various hybrid fibers with maximum volume fraction of 1% were used out of total concrete volume with and without copper slag (20% & 40%) replacement with fine aggregate are investigated on the hardened characteristics including; compressive strength, flexural strength, splitting tensile strength. Moreover, durability properties including; water absorption, electrical Resistivity, for performance-based concrete are also conducted. Out of the 12 mixes considered for this study, PP0.05B0.2S0.75CS40 performs better and exhibit excellent performance in terms of strength and durability.

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“…Various mono and hybrid functional fillers (e.g. carbon black (CB) [14][15][16], carbon fibers [17][18][19][20], carbon nanotubes (CNTs) [21][22][23], and steel fibers (SFs) [24,25] have been investigated [25][26][27]. In addition, the incorporation of some functional fillers can also improve the compressive strength, tensile strength, or flexural strength of concrete [10].…”

Section: Introductionmentioning

confidence: 99%

Self-sensing ultra-high performance concrete: a review

Guo,

Wang,

Ashour

et al. 2023

Meas. Sci. Technol.

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Ultra-high performance concrete (UHPC) is an innovative cementitious composite, that has been widely applied in numerous structural projects because of its superior mechanical properties and durability. However, ensuring the safety of UHPC structures necessitates an urgent need for technology to continuously monitor and evaluate their condition during their extended periods of service. Self-sensing ultra-high performance concrete (SSUHPC) extends the functionality of UHPC system by integrating conductive fillers into the UHPC matrix, allowing it to address above demands with great potential and superiority. By measuring and analyzing the relationship between fraction change in resistivity (FCR) and external stimulates (force, stress, strain), SSUHPC can effectively monitor the crack initiation and propagation as well as damage events in UHPC structures, thus offering a promising pathway for structural health monitoring (SHM). Research on SSUHPC has attracted substantial interests from both academic and engineering practitioners in recent years, this paper aims to provide a comprehensive review on the state of the art of SSUHPC. It offers a detailed overview of material composition, mechanical properties and self-sensing capabilities, and the underlying mechanisms involved of SSUHPC with various functional fillers. Furthermore, based on the recent advancements in SSUHPC technology, the paper concludes that SSUHPC has superior self-sensing performance under tensile load but poor self-sensing performance under compressive load. The mechanical and self-sensing properties of UHPC are substantially dependent on the type and dosage of functional fillers. In addition, the practical engineering SHM application of SSUHPC, particularly in the context of large-scale structure, is met with certain challenges, such as environment effects on the response of SSUHPC. Therefore, it still requires further extensive investigation and empirical validation to bridge the gap between laboratory research and real engineering application of SSUHPC.

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Effect of fiber dosage on water permeability using a newly designed apparatus and crack monitoring of steel fiber–reinforced concrete under direct tensile loading

Cited by 22 publications

References 65 publications

Smart cement‐sensor composite: The evolution of nanomaterial in developing sensor for structural integrity

Smart cement‐sensor composite: The evolution of nanomaterial in developing sensor for structural integrity

Effect of fiber synergy on strength & durability of high-performance concrete

Self-sensing ultra-high performance concrete: a review

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