Correlation of Plastic Strain Energy and Acoustic Emission Energy in Reinforced Concrete Structures

Sagasta, Francisco; Benavent‐Climent, Amadeo; Roldán, A.; Gallego, Antolino

doi:10.3390/app6030084

Cited by 34 publications

(22 citation statements)

References 27 publications

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“…It is shown that as the corrosion level becomes higher (from Control to LC and HC beam specimens), there is a collective increase in AF and a decrease in RA value of the beam specimens. On the other hand, it also indicates the transition of the beam specimen dominating fracture behaviour, which shifts from tensile to shear as the damage stage increases (from damage Stage I to IV) in accordance to the classification method suggested previously[10,27,35]. RA value versus AF for (a) Control, (b) LC and (c) HC beam specimens4.2.2.…”

supporting

confidence: 84%

Monitoring fracture of steel corroded reinforced concrete members under flexure by acoustic emission technique

Zaki

Chai

Behnia

et al. 2017

Construction and Building Materials

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Acoustic emission (AE) technique is used for monitoring and evaluating the influence of corrosion on the structural behaviour of steel reinforced concrete (RC) beams under three-point flexure test. In this study, steel corrosion was accelerated by electro-chemical method utilising a direct current (DC) power supply and 5% sodium chloride (NaCl) solution. The steel corrosion that was induced into beam specimens casting were estimated at 0%, 4.55% and 32.37%, respectively, according to mass loss of steel reinforcement. Based on observations during static load test, the damage developed in the specimens could be classified into four different stages, namely, micro-cracking, first visible cracks, cracks distribution, as well as damage localization and yielding. Analysis of the AE data reveals distinguishable trends for RA value and average frequency (AF) registered for different corrosion levels, respectively. Moreover, the index of damage (ID) derived from the AE energy parameters obtained during the first stage of damage was found to be useful as an indicator for evaluating the extent of corrosion damage of RC beam specimens at initial loadings. In addition, to provide a practical application of AE toward life span estimation of corroded beam specimen, a Weibull damage function was introduced to estimate the remaining flexural capacity of the beam specimens. Based on analysis as well, it is noted that tensile fracture became more dominant with an increase in corrosion level.

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supporting

confidence: 84%

Monitoring fracture of steel corroded reinforced concrete members under flexure by acoustic emission technique

Zaki

Chai

Behnia

et al. 2017

Construction and Building Materials

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“…With the recent advances in structural health monitoring (SHM) [2][3][4][5][6][7][8] and nondestructive evaluation (NDE) [9,10], many monitoring and evaluation methods, such as modal characteristics-based methods [11][12][13], active sensing [14][15][16][17][18][19][20], electromechanical impedance [21][22][23][24][25], ultrasonic guided wave [26], active thermography [26][27][28] and vibrothermography [29,30], among others, are available. Among them, acoustic emission technique [31][32][33][34][35][36][37] is an effective nondestructive technique that can characterize the wear process [38,39], and it has been widely used in civil engineering [40][41][42][43], mechanical engineering [44][45][46][47]<...>…”

Section: Introductionmentioning

confidence: 99%

“…Compared with other non-destructive testing approaches, using a highly sensitive piezoceramic probe, the AE technique is more sensitive to material damage, and it is suitable for continuous health monitoring in real time [17]. For example, researchers have extensively applied AE techniques to monitor concrete structures [43,[64][65][66][67][68]. Aldahdooh et al [41] and Prem et al [69] demonstrated that AE technique was an effective technique to monitor the damage process of reinforced concrete.…”

Section: Introductionmentioning

confidence: 99%

Feasibility Study of Real-Time Monitoring of Pin Connection Wear Using Acoustic Emission

et al. 2018

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Pin connections are one of the most important connecting forms and they have been widely used in engineering fields. In its service, pin connections are subject to wear, and it will be beneficial if the health condition of pin connections can be monitored in real time. In this paper, an acoustic emission (AE)-based method was developed to monitor wear degree of low rotational speed pin connections in real time in a nondestructive way. Most pin connections are operated at low rotational speed. To facilitate the research, an experimental apparatus to accelerate the wear test of low rotational speed pin connections was designed and fabricated. The piezoceramic AE sensor was mounted on the test apparatus in a nondestructive way, and it was capable of real-time monitoring. Accelerated wear tests of low rotational speed pin connections were conducted. To verify the results of the AE technique, a VHX-600E digital (from Keyence, Osaka, Japan) microscope was applied to observe the micrographs of the tested pins. The experimental results show that AE activity existed throughout the entire wear process, and it was the most prominent in the serious wear phase. The wear degree of the pin connections can be reflected qualitatively by the signal strength and the accumulative signal strength of the AE signals. In addition, two different wear forms can be distinguished by comparing the signal strength values of all specimens. Micrographs of all specimens confirm these results, and determine that the two wear forms include adhesive wear and abrasive wear. Furthermore, AE results demonstrated that adhesive wear is the main mode of wear for the low rotational speed pin connections, and the signal strength of the adhesive wear is around 190 times larger than that of abrasive wear. This feasibility study demonstrated that the developed acoustic emission technique can be utilized in the wear monitoring of pin connections in real time in a nondestructive way.

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“…Crack detection, hydration monitoring and energy harvesting using similar embedded piezoelectric transducers were reported in [6][7][8]. Recently, good correlation between acoustic emission energy at low frequency (25-100 kHz) and plastic strain energy of reinforced concrete specimens was established in [9,10]. An active acoustic method at a lower frequency of around 6 kHz was also employed [11] to monitor setting and hardening in concrete at early ages, wherein the P-wave velocity and attenuation coefficient were used to characterize the development of calcium silicate hydrate (C-S-H) gel inside the concrete and, hence, predict strength growth during early ages.…”

Section: Introductionmentioning

confidence: 96%

Strength Correlation and Prediction of Engineered Cementitious Composites with Microwave Properties

et al. 2016

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This paper presents the results of microwave and mechanical measurements of engineered cementitious composites (ECCs) using a nondestructive microwave near-field detecting technique. The objective of this research is to investigate the correlations between effective conductance and compressive strength of ECCs at various curing ages under the influence of different initial water contents. Parallel measurements and regression analysis on compressive strength and microwave conductance were undertaken. It is shown that the strength evolution of ECCs can be accurately modeled and predicted by using microwave conductance at the early ages using bi-exponential functions. Compressive strength grows as a function of decreasing effective conductance, whereas the regression coefficients of the correlation models have a linear variation with water-to-binder ratios. These findings have highlighted the effectiveness of the microwave technique in detecting the variation of liquid phase morphology and pore structure.

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Correlation of Plastic Strain Energy and Acoustic Emission Energy in Reinforced Concrete Structures

Cited by 34 publications

References 27 publications

Monitoring fracture of steel corroded reinforced concrete members under flexure by acoustic emission technique

Monitoring fracture of steel corroded reinforced concrete members under flexure by acoustic emission technique

Feasibility Study of Real-Time Monitoring of Pin Connection Wear Using Acoustic Emission

Strength Correlation and Prediction of Engineered Cementitious Composites with Microwave Properties

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