Experimental study on acoustic emission characteristic of fatigue crack growth of self-compacting concrete

Chen, Chen; Chen, Xudong; Guo, Shu-Guang

doi:10.1002/stc.2332

Cited by 32 publications

(22 citation statements)

References 32 publications

(56 reference statements)

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“…Rubberized concrete produced by the self‐compacting technique was expected to inherit the benefits of SCC, such as high mechanical strength and low porosity, and the benefits of rubber addition, such as higher toughness. This expectation for a rubberized self‐compacting concrete (RSCC) was explored in a number of studies 11–22 . The majority of these used conventional experimental techniques, that is, standard stress and strain measurements, for determining the mechanical properties of RSCC 11–16 .…”

Section: Introductionmentioning

confidence: 99%

Investigation of tensile fracture of rubberized self‐compacting concrete by acoustic emission and digital image correlation

Chen

Jivkov

et al. 2021

Struct Control Health Monit

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Summary Damage and failure of rubberized self‐compacting concrete (RSCC) under uniaxial tension are investigated by acoustic emission (AE) and digital image correlation (DIC) techniques. Four RSCC mixtures containing fine rubber particles with 0%, 5%, 10%, and 15% volume fractions are tested. The effect of rubber content on the macroscopic mechanical behavior, the AE parameters, the strain fields, and the damage developments are analyzed. It is demonstrated that the combined use of AE parameters and DIC strain maps provides an accurate estimation of different stages of damage evolution and that the crack propagation measured by DIC correlates strongly with all AE parameters. Modes of cracking are determined by analyses of average frequency (AF) versus rise time–amplitude (RA) values to demonstrate an additional feature of AE, which can be used for explanations of different behaviors under different loading conditions. It is shown that the substitution of fine aggregates with fine rubber particles leads to a reduction of stiffness, strength, and fracture toughness when the material experiences uniaxial tension. This has to be considered in the design of structures with RSCC.

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Section: Introductionmentioning

confidence: 99%

Investigation of tensile fracture of rubberized self‐compacting concrete by acoustic emission and digital image correlation

Chen

Jivkov

et al. 2021

Struct Control Health Monit

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“…There are several applications of AE in concrete structures such as damage identification, damage monitoring, damage classification, etc 16 . Some of the recent studies such as damage detection of concrete beams by integrating AE and Weibull damage function, 17 AE characterization of fatigue crack growth, 18 determination of yielding point, 19 damage characterization of crumb rubber concrete, 20 analysis of the bond behavior of corroded reinforcement, 21 and fracture monitoring in carbon nanotube‐crumb rubber mortar highlight successful implementation of AE testing for failure characterization in concrete structures. Application of machine learning‐based algorithms 22,23 such as support vector machine and Gaussian mixture modeling are also studied by various researchers to identify local fracture mechanism, crack classification, and damage identification in reinforced concrete structures.…”

Section: Introductionmentioning

confidence: 99%

Smart monitoring of strengthened beams made of ultrahigh performance concrete using integrated and nonintegrated acoustic emission approach

Prem

Verma

Murthy

et al. 2021

Struct Control Health Monit

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Summary Ultrahigh performance concrete (UHPC) is one of the recent advancements in construction building materials and popularly used as a precast applications or strengthening material. The current paper attempts to improve understanding about fracture and failure mechanisms of UHPC application as a strengthening material using acoustic emission (AE) technique. The paper proposes an integrated and nonintegrated approach to relate the mechanical energy with AE energy for (i) undamaged reinforced concrete (RC) beams and (ii) damaged RC beams strengthened with UHPC. The integrated approach evaluates the damage mechanisms by evaluating sentry function (logarithmic ratio of mechanical and acoustic energy), while nonintegrated approach considers superimposition of flexure and AE response, load versus AE energy behavior and damage index. To validate the proposed approach, experiments are conducted on (i) control RC beams and (ii) RC beams strengthened with UHPC layers of t, 1.5t, and 2t thickness (where t = 10 mm). From the study, it is found that analysis of structures using both the approaches can overcome corresponding limitations. Hence, to completely characterize the damage, both methods are recommended.

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“…[5][6][7] Furthermore, an acoustic emission technology has been employed for measuring elastic waves in solids generated due to cracks formed inside concrete. 8,9 Ahn et al 10 summarized the principles and applications of other nondestructive techniques. The contact-type sensor is useful for crack evaluation; however, it is inefficient for monitoring cracks in full-scale civil engineering structures because the available sensing areas are limited to the proximity of the sensors.…”

Section: Introductionmentioning

confidence: 99%

Crack identification method for concrete structures considering angle of view using RGB-D camera-based sensor fusion

Kim

Lee

Ahn

et al. 2020

Structural Health Monitoring

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Cracks on concrete structures are an important indicator for assessing concrete durability and structural safety. Although such cracks are typically monitored by manual visual inspection, this method has drawbacks in terms of inspection time, safety, cost-effectiveness, and measurement accuracy. An innovative alternative is digital image processing, which can be used to obtain crack information from images captured using a digital camera. However, in image-based crack detection, the crack width may vary depending on the angle of the camera with respect to the concrete surface. A skewed angle of view is often encountered, particularly when capturing images from unmanned aerial vehicles or from higher locations. This study proposes a crack identification strategy using a combination of RGB-D and high-resolution digital cameras to accurately measure cracks regardless of the angle of view. The camera system is equipped with a tailored sensor fusion algorithm for crack identification, enabling a high measurement resolution and a robust depth estimation considering the skewed angle problem. An approximate plane corresponding to the concrete surface is introduced to effectively handle the high noise in the depth measurement data of the RGB-D camera. Subsequently, the crack image captured using the high-resolution digital camera is mapped onto the obtained plane model, allowing the crack width to be determined using the three-dimensional coordinates of each crack pixel. The measurement accuracy of the proposed approach is experimentally validated on an actual concrete structure.

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Experimental study on acoustic emission characteristic of fatigue crack growth of self-compacting concrete

Cited by 32 publications

References 32 publications

Investigation of tensile fracture of rubberized self‐compacting concrete by acoustic emission and digital image correlation

Investigation of tensile fracture of rubberized self‐compacting concrete by acoustic emission and digital image correlation

Smart monitoring of strengthened beams made of ultrahigh performance concrete using integrated and nonintegrated acoustic emission approach

Crack identification method for concrete structures considering angle of view using RGB-D camera-based sensor fusion

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