Applications of Cement-Based Smart Composites to Civil Structural Health Monitoring: A Review

Cassese, Paolino; Rainieri, Carlo; Occhiuzzi, Antonio

doi:10.3390/app11188530

Cited by 18 publications

(12 citation statements)

References 77 publications

(122 reference statements)

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“…The sampling frequency of five samples/second was chosen to record the electrical resistance data. Since the direct current (DC) measurement technique is highly influenced by the polarization effect (Azhari and Banthia, 2012; Cassese et al, 2021; Rao et al, 2021), measurement was done after stabilization. Three specimens with same MWCNT concentration were tested and the average value (considering consistent data) was taken as the electrical resistance for the corresponding specimen type.…”

Section: Development Of Embeddable Smart Composite-based Sensors (Escs)mentioning

confidence: 99%

“…Further addition of CNT in matrix (to 0.5 wt.%) leads to further reduction in the separation distance among CNTs, subsequently, the tunneling barrier is reduced and CNTs start to come into contact with each other and form a continuous conductive network. The formation of a large number of conductive networks in the cement matrix demonstrates the extremely low resistivity of composites that falls into conducting zone (C) (Azhari and Banthia 2012; Cassese et al, 2021; Ding et al, 2019; Sanati et al, 2018). However, further incorporation of CNTs did not considerably affect the electrical conductivity of cementitious composites.…”

Section: Development Of Embeddable Smart Composite-based Sensors (Escs)mentioning

confidence: 99%

“…The smart cementitious composites exhibit inherent self-sensing and damage monitoring capabilities, and are fabricated by introducing conductive functional fillers such as carbon nanofibre (CNF), carbon nanotube (CNT), steel fibre, carbon black (CB), etc. into cement matrix (Demircilioglu et al, 2020; Armoosh et al, 2022; Cassese et al, 2021; Castañeda-Saldarriaga et al, 2021; Cui et al, 2017; D’Alessandro et al, 2021; García-Macías et al, 2017; Han et al, 2015, 2017a; Khushnood et al, 2019; Majumder et al, 2008; Najafishad et al, 2020; Sanati et al, 2018; Ubertini et al, 2014a; Wen and Chung, 2001a). Their unique capability of change in electrical resistance under external disturbance or loading termed as ‘ piezoresistivity ’ offers a large scope as embeddable sensors for strain, stress, crack or damage monitoring of smart concrete structures (Cassese et al, 2021; D’Alessandro et al, 2021; García-Macías et al, 2017; Han et al, 2017a).…”

Section: Introductionmentioning

confidence: 99%

“…Their sensing efficiency was estimated by calculating a constant known as ‘gauge factor’. This gauge factor shows the linear correlation between change in electrical resistance with applied strain (Cassese et al, 2021; Castañeda-Saldarriaga et al, 2021; Cui et al, 2017; D’Alessandro et al, 2021; García-Macías et al, 2017; Han et al, 2017b). It has been found that the sensing capability of smart cementitious composite depends on several important parameters such as concentration of CNTs (Han et al, 2012; Rao et al, 2020, 2021), the surface modification of CNTs (Li et al, 2007), the process involved in the dispersion of CNTs (Azhari and Banthia, 2012; Konsta-Gdoutos et al, 2014; Tian et al, 2019), nature of applied load (Yoo et al, 2018a) and measuring techniques (Zhang et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Real-time monitoring of structures under extreme loading using smart composite-based embeddable sensors

Rao

Sindu

Sasmal

2022

Journal of Intelligent Material Systems and Structures

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Cementitious composites reinforced with conductive nanoparticles, also known as smart composite-based sensors, are emerging as novel sensors for real-time monitoring of structures. The present study deals with the development of embeddable smart composite-based sensor (called as eSCS), for monitoring the damage evolution in large-scale beam-column (B-C) sub-assemblages. Firstly, a systematic approach has been developed to fabricate the sensors through incorporation of functionalized (-COOH) multi-walled carbon nanotubes (MWCNTs). The optimum dosage of CNTs required for developing sensors with maximum conductivity and piezo-resistivity was ascertained by determining the percolation threshold limit. The best performing eSCS was then successfully embedded at the critical locations of full-scale B-C joint specimens. The embedded sensors are used, for the first time, for damage monitoring of the B-C sub-assemblages subjected to reverse cyclic loadings. From the study, it is found that eSCS with 0.50 wt.% COOH-MWCNT shows excellent piezoresistive behaviour and gauge factors are found to be approximately 730, 457 and 396 for the applied compressive stress ranges of 2–4, 2–6 and 2–8 MPa, respectively. The embedded sensors showed the excellent strain sensing capability under reverse cyclic loading. The present study demonstrates the suitability of embedded eSCS sensors for robust structural health monitoring applications.

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Section: Development Of Embeddable Smart Composite-based Sensors (Escs)mentioning

confidence: 99%

Section: Development Of Embeddable Smart Composite-based Sensors (Escs)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Real-time monitoring of structures under extreme loading using smart composite-based embeddable sensors

Rao

Sindu

Sasmal

2022

Journal of Intelligent Material Systems and Structures

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“…The hydration product and the conductive material only trigger adhesion through the conjugated hydrogen bond of the hydroxyl groups. [ 12 ] Therefore, the toughening of cement‐based sensors has the potential for optimization.…”

Section: Introductionmentioning

confidence: 99%

Ultraductile Cementitious Structural Health Monitoring Coating: Waterborne Polymer Biomimetic Muscle and Polyhedral Oligomeric Silsesquioxane‐Assisted C‐S‐H Dispersion

Pang

Jin

Zhang

et al. 2022

Adv Funct Materials

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Cement‐based sensors (CBSs) have demonstrated potential in structural health monitoring (SHM) despite rare applications due to their poor flexibility and sensing accuracy/protection with robustness. Herein, a promising strategy is reported to design a waterborne epoxy resin (WEP)‐modified cement‐based composite coating sensorcapable of simultaneous stable SHM and durable protection. The interpenetrating network (IPN) formed by WEP within cement paste is bionic to the toughness and crack resistance of biological muscle tissue and balances the ion permeation performance and polarization of hydration products. The polymerization‐redispersion progress and mechanism of calcium silicate hydrate (C‐S‐H) gel modified with [3‐(2‐aminoethylamino)‐propyl]trimethoxysilane silsesquioxane (C‐POSS) are characterized and revealed. The results show that the muscle‐like IPN increases the cement‐based coatings’ maximum deflection angle to 30° and improves the monitoring accuracy of compressive, tensile, and fatigue microchanges of concrete structures to more than 95%. The POSS···Ca2+···C‐S‐H interaction in C‐POSS partially transferred the intra‐adhesive hydrogen bonds surrounding the nanoconducer into electrostatic bridging ones to maintain an excellent electromechanical conductive dispersion.

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Triboelectric Nanogenerator‐Enabled Digital Twins in Civil Engineering Infrastructure 4.0: A Comprehensive Review

Pang,

He,

Liu

et al. 2024

Advanced Science

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The emergence of digital twins has ushered in a new era in civil engineering with a focus on achieving sustainable energy supply, real‐time sensing, and rapid warning systems. These key development goals mean the arrival of Civil Engineering 4.0.The advent of triboelectric nanogenerators (TENGs) demonstrates the feasibility of energy harvesting and self‐powered sensing. This review aims to provide a comprehensive analysis of the fundamental elements comprising civil infrastructure, encompassing various structures such as buildings, pavements, rail tracks, bridges, tunnels, and ports. First, an elaboration is provided on smart engineering structures with digital twins. Following that, the paper examines the impact of using TENG‐enabled strategies on smart civil infrastructure through the integration of materials and structures. The various infrastructures provided by TENGs have been analyzed to identify the key research interest. These areas encompass a wide range of civil infrastructure characteristics, including safety, efficiency, energy conservation, and other related themes. The challenges and future perspectives of TENG‐enabled smart civil infrastructure are briefly discussed in the final section. In conclusion, it is conceivable that in the near future, there will be a proliferation of smart civil infrastructure accompanied by sustainable and comprehensive smart services.

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Applications of Cement-Based Smart Composites to Civil Structural Health Monitoring: A Review

Cited by 18 publications

References 77 publications

Real-time monitoring of structures under extreme loading using smart composite-based embeddable sensors

Real-time monitoring of structures under extreme loading using smart composite-based embeddable sensors

Ultraductile Cementitious Structural Health Monitoring Coating: Waterborne Polymer Biomimetic Muscle and Polyhedral Oligomeric Silsesquioxane‐Assisted C‐S‐H Dispersion

Triboelectric Nanogenerator‐Enabled Digital Twins in Civil Engineering Infrastructure 4.0: A Comprehensive Review

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