A Review on Concrete Structural Properties and Damage Evolution Monitoring Techniques

Zhang, Jinghua; Peng, Lisha; Wen, Shuzhi; Huang, Songling

doi:10.3390/s24020620

Cited by 4 publications

(1 citation statement)

References 155 publications

(201 reference statements)

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“…Various technologies such as strain gauges (SGs), electromechanical impedance (EMI), fiber Bragg grating (FBG), etc., which are based on different working principles and scopes, have been developed and widely used in SHM. For instance, traditional sensors such as SGs and thermocouples are technically mature and inexpensive, and can measure the localized state of a concrete structure; the optical properties of light in the fibers of FBG sensors show high sensitivity to multiple parameter changes in the structural state [1]; EMI monitors the state of the structure through the structural response under electromagnetic excitation [2]; and magnetic testing (MT) [3], radar wave detection (RWD) [4], radiation detection (RD) [5], and infrared thermography monitoring (IRT) [6] can achieve a wide range of detection in concrete structures. In the sonic technique, acoustic parameters of sound waves correlate with the state of the propagation medium; among them, acoustic emission (AE) is a passively received acoustic wave method tested during damage development [5][6][7], while ultrasonic pulse velocity (UPV) detects the medium's state by calculating the wave speed of a direct wave [5,8].…”

Section: Introductionmentioning

confidence: 99%

Combinatorial Quantification of Multi-Features of Coda Waves in Temperature-Affected Concrete Beams

Zheng,

Song,

Xue

et al. 2024

Materials

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Coda waves are highly sensitive to changes in medium properties and can serve as a tool for structural health monitoring (SHM). However, high sensitivity also makes them susceptible to noise, leading to excessive dispersion of monitoring results. In this paper, a coda wave multi-feature extraction method is proposed, in which three parameters, the time shift, the time stretch, and the amplitude variation of the wave trains within the time window, are totally derived. These three parameters are each mapped to the temperature variation of concrete beams, and then combined together with their optimal weight coefficients to give a best-fitted temperature–multi-parameter relationship that has the smallest errors. Coda wave signals were collected from an ultrasonic experiment on concrete beams within an environmental temperature range of 14 °C~21 °C to verify the effectiveness of the proposed method. The results indicate that the combination of multi-features derived from coda wave signals to quantify the medium temperature is feasible. Compared to the relationship established by a single parameter, the goodness-of-fit is improved. During identification, the method effectively reduces the dispersion of identification errors and mitigates the impact of noise interference on structural state assessment. Both the identification accuracy and stability are improved by more than 50%, and the order of magnitude of the identification accuracy is improved from 1 °C to 0.1 °C.

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Section: Introductionmentioning

confidence: 99%

Combinatorial Quantification of Multi-Features of Coda Waves in Temperature-Affected Concrete Beams

Zheng,

Song,

Xue

et al. 2024

Materials

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Prediction of axial compressive stresses in ultra-high-performance concrete blocks using non-destructive ultrasonic techniques

Wu,

Li,

Elghazouli

et al. 2024

Journal of Building Engineering

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Study on Mechanical and Acoustic Emission Characteristics of Backfill–Rock Instability under Different Stress Conditions

Dong,

Yan,

Chen

et al. 2024

Sensors

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Unveiling the mechanical properties and damage mechanism of the complex composite structure, comprising backfill and surrounding rock, is crucial for ensuring the safe development of the downward-approach backfill mining method. This work conducts biaxial compression tests on backfill–rock under various loading conditions. The damage process is analyzed using DIC and acoustic emission (AE) techniques, while the distribution of AE events at different loading stages is explored. Additionally, the dominant failure forms of specimens are studied through multifractal analysis. The damage evolution law of backfill–rock combinations is elucidated. The results indicate that DIC and AE provide consistent descriptions of specimen damage, and the damage evolution of backfill–rock composite specimens varies notably under different loading conditions, offering valuable insights for engineering site safety protection.

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A Review on Concrete Structural Properties and Damage Evolution Monitoring Techniques

Cited by 4 publications

References 155 publications

Combinatorial Quantification of Multi-Features of Coda Waves in Temperature-Affected Concrete Beams

Combinatorial Quantification of Multi-Features of Coda Waves in Temperature-Affected Concrete Beams

Prediction of axial compressive stresses in ultra-high-performance concrete blocks using non-destructive ultrasonic techniques

Study on Mechanical and Acoustic Emission Characteristics of Backfill–Rock Instability under Different Stress Conditions

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