A probabilistic approach for damage identification and crack mode classification in reinforced concrete structures

Farhidzadeh, Alireza; Salamone, Salvatore; Singla, Puneet

doi:10.1177/1045389x13484101

Cited by 117 publications

(63 citation statements)

References 40 publications

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“…As already mentioned, the design at hand may suffer from several different fracture mechanisms: tensile cracking of the GFR.IPC box, debonding between the GFR.IPC box and concrete, cracking or crushing of concrete and -in case a carbon strip is attached-debonding between the strip and In several materials, and concrete in particular, signals with high frequency indicators (average frequency, AF) and short rise time (RT, see Fig. 10), indicate fracture events of tensile character while when signals become longer this usually implies a shift to a more shear character including delaminations and fibre pull-out [24,28,29]. This is also expressed by an increase of "RA" which is the ratio of RT over amplitude and it measures the inverse of the initial rising angle of the waveform (see again Fig.…”

Section: Acoustic Emission Testsmentioning

confidence: 99%

Experimental Structural Analysis of Hybrid Composite-Concrete Beams by Digital Image Correlation (DIC) and Acoustic Emission (AE)

et al. 2015

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The use of composites such as textile reinforced cements (TRCs) and fibre reinforced polymers (FRPs) enables the development of lightweight structures. Such a lightweight solution for floor renovation consists of a hybrid composite-concrete cross section: prefabricated beams (TRC-CFRP reinforced hollow boxes with concrete on top) support sandwich panels together with a finishing concrete compression layer creating a monolithic hybrid floor. As the hybrid beams are the main structural element of this floor system, their load-bearing and failure behaviour should be fully understood. In order to examine the optimal design of these structures in terms of load bearing capacity, the beams are separately tested in four point bending while the amount of CFRP reinforcement and the concrete thickness are varied. The digital image correlation (DIC) and acoustic emission (AE) measuring techniques are applied in a complimentary way to monitor the bending and failure behaviour of the full scale hybrid beams. DIC visualises the development of surface strain fields together with the exact cracking patterns in relation to the applied load. AE contributes in defining the load at the onset of serious cracking activity. Furthermore, AE characterizes the contribution of the different fracture modes that may vary from concrete cracking, delamination between the successive layers of the TRC or debonding at the interphase between the TRC hollow box and the concrete on the one hand and the CFRP on the other hand. B S. Verbruggen svetlana.verbruggen@vub.ac.be

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Section: Acoustic Emission Testsmentioning

confidence: 99%

Experimental Structural Analysis of Hybrid Composite-Concrete Beams by Digital Image Correlation (DIC) and Acoustic Emission (AE)

et al. 2015

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“…1. The important parameters include the amplitude, A, the rise time, RT, the RA-value which is RT over A. RT and RA are well related to the cracking mode, and specifically obtain low values for tensile phenomena and higher for shear either in the form of delaminations [7] or cracking due to shear stresses [8][9][10]. Frequency content is measured by the average frequency, AF, which is roughly the number of cycles over the duration or the peak frequency, PF, which is the frequency component with the highest magnitude after FFT of the waveform.…”

Section: Introductionmentioning

confidence: 99%

Influence of geometry on the fracturing behavior of textile reinforced cement monitored by acoustic emission

et al. 2014

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In this work the flexural behavior of textile reinforced cement (TRC) laminate is examined using acoustic emission (AE). The TRC composite is a combination of inorganic phosphate cement (IPC) with randomly distributed glass fibres. IPC has been developed at the "Vrije Universiteit Brussel" and shows a neutral pH meaning that glass fibers are hardly attacked. During bending, stresses lead to the activation of damage mechanisms like matrix cracking, delaminations and fiber pull-out being in succession or overlapping in time. AE records the responses of the damage propagation events and allows the monitoring of the fracture behavior from the onset to the final stage. The effect of the span in three-point bending tests, which is varied to create different stress fields, is targeted. Parameters like duration and frequency reveal information about the mode of the damage sources in relation to the span. Results show that as the span decreases, the dominant damage mode shifts away from bending and acquires more shear characteristics by increasing the interlaminar shearing events.

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“…In general, the frequency and the gravity of the waveforms (energy distributed between the early or later part) are well correlated to the corresponding fracture modes in bulk media like concrete or composite plates [7][8][9]. Since damage characterization is based on the received waveforms, the performance of the sensors is of utmost importance.…”

Section: Introductionmentioning

confidence: 99%

The Influence of Sensor Size on Acoustic Emission Waveforms—A Numerical Study

Tsangouri

2018

Applied Sciences

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Abstract:The performance of Acoustic Emission technique is governed by the measuring efficiency of the piezoelectric sensors usually mounted on the structure surface. In the case of damage of bulk materials or plates, the sensors receive the acoustic waveforms of which the frequency and shape are correlated to the damage mode. This numerical study measures the waveforms received by point, medium and large size sensors and evaluates the effect of sensor size on the acoustic emission signals. Simulations are the only way to quantify the effect of sensor size ensuring that the frequency response of the different sensors is uniform. The cases of horizontal (on the same surface), vertical and diagonal excitation are numerically simulated, and the corresponding elastic wave displacement is measured for different sizes of sensors. It is shown that large size sensors significantly affect the wave magnitude and content in both time and frequency domains and especially in the case of surface wave excitation. The coherence between the original and received waveform is quantified and the numerical findings are experimentally supported. It is concluded that sensors with a size larger than half the size of the excitation wavelength start to seriously influence the accuracy of the AE waveform.

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A probabilistic approach for damage identification and crack mode classification in reinforced concrete structures

Cited by 117 publications

References 40 publications

Experimental Structural Analysis of Hybrid Composite-Concrete Beams by Digital Image Correlation (DIC) and Acoustic Emission (AE)

Experimental Structural Analysis of Hybrid Composite-Concrete Beams by Digital Image Correlation (DIC) and Acoustic Emission (AE)

Influence of geometry on the fracturing behavior of textile reinforced cement monitored by acoustic emission

The Influence of Sensor Size on Acoustic Emission Waveforms—A Numerical Study

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