Your search keyword '"Propagation distance"' showing total 7 results

1. Size Effect on the Acoustic Emission Behavior of Textile-Reinforced Cement Composites.

Author

Ospitia, Nicolas, Hardy, Aymeric, Si Larbi, Amir, Aggelis, Dimitrios G., and Tsangouri, Eleni

Subjects

ACOUSTIC emission, ELASTIC waves, CEMENT composites, PIEZOELECTRIC detectors, THEORY of wave motion, CEMENT

Abstract

Acoustic emission (AE) is applied for the structural health evaluation of materials. It commonly uses piezoelectric sensors to detect elastic waves coming from energy releases within the material. Concerning cementitious composites as well as polymers, AE parameters have proven their potential to not only detect the existence of a defect, its location and the fracture mode, but also the developing strain field even before visible damage evolves. However, the wave propagation distance, wave dispersion due to plate geometry, heterogeneity and reflections result in attenuation and distortion of the AE waveforms. These factors render the interpretation more complex, especially for large samples. In this study, the effect of wave propagation on plain glass textile-reinforced cement (TRC) plates is investigated. Then, curved plates with different widths are mechanically loaded for bending with concurrent AE monitoring. The aim is to evaluate to what extent the plate dimensions and propagation distance influence the original AE characteristics corresponding to a certain fracture mechanism. [ABSTRACT FROM AUTHOR]

Published

2021

2. Size Effect on the Acoustic Emission Behavior of Textile-Reinforced Cement Composites

Author

Nicolas Ospitia, Aymeric Hardy, Amir Si Larbi, Dimitrios G. Aggelis, and Eleni Tsangouri

Subjects

waveform, bending, textile-reinforced cement, frequency, rise time, propagation distance, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Acoustic emission (AE) is applied for the structural health evaluation of materials. It commonly uses piezoelectric sensors to detect elastic waves coming from energy releases within the material. Concerning cementitious composites as well as polymers, AE parameters have proven their potential to not only detect the existence of a defect, its location and the fracture mode, but also the developing strain field even before visible damage evolves. However, the wave propagation distance, wave dispersion due to plate geometry, heterogeneity and reflections result in attenuation and distortion of the AE waveforms. These factors render the interpretation more complex, especially for large samples. In this study, the effect of wave propagation on plain glass textile-reinforced cement (TRC) plates is investigated. Then, curved plates with different widths are mechanically loaded for bending with concurrent AE monitoring. The aim is to evaluate to what extent the plate dimensions and propagation distance influence the original AE characteristics corresponding to a certain fracture mechanism.

Published

2021

3. Size Effect on the Acoustic Emission Behavior of Textile-Reinforced Cement Composites

Author

Amir Si Larbi, Aymeric Hardy, Dimitrios G. Aggelis, Eleni Tsangouri, Nicolas Ospitia, Laboratorium for Micro- and Photonelectronics, Mechanics of Materials and Constructions, Faculty of Engineering, and Applied Mechanics

Subjects

Technology, Materials science, Piezoelectric sensor, Wave propagation, QH301-705.5, QC1-999, 0211 other engineering and technologies, 02 engineering and technology, Bending, matrix crack, textile-reinforced cement, Distortion, 021105 building & construction, Waveform, General Materials Science, Composite material, Biology (General), rise time, Instrumentation, QD1-999, Fluid Flow and Transfer Processes, Process Chemistry and Technology, Attenuation, Physics, General Engineering, bending, 021001 nanoscience & nanotechnology, Engineering (General). Civil engineering (General), Computer Science Applications, Chemistry, waveform, Acoustic emission, frequency, Fracture (geology), propagation distance, TA1-2040, 0210 nano-technology

Abstract

Acoustic emission (AE) is applied for the structural health evaluation of materials. It commonly uses piezoelectric sensors to detect elastic waves coming from energy releases within the material. Concerning cementitious composites as well as polymers, AE parameters have proven their potential to not only detect the existence of a defect, its location and the fracture mode, but also the developing strain field even before visible damage evolves. However, the wave propagation distance, wave dispersion due to plate geometry, heterogeneity and reflections result in attenuation and distortion of the AE waveforms. These factors render the interpretation more complex, especially for large samples. In this study, the effect of wave propagation on plain glass textile-reinforced cement (TRC) plates is investigated. Then, curved plates with different widths are mechanically loaded for bending with concurrent AE monitoring. The aim is to evaluate to what extent the plate dimensions and propagation distance influence the original AE characteristics corresponding to a certain fracture mechanism.

Published

2021

4. Effect of wave distortion on acoustic emission characterization of cementitious materials

Author

Aggelis, D.G., Mpalaskas, A.C., Ntalakas, D., and Matikas, T.E.

Subjects

*ACOUSTIC emission, *FRACTURE mechanics, *CEMENT, *NONDESTRUCTIVE testing, *DETECTORS, *ELASTIC waves, *CRACK propagation (Fracture mechanics)

Abstract

Abstract: The fracturing behavior of materials can be nondestructively monitored by the acoustic emission (AE) technique, using sensors that detect the transient elastic waves after any crack propagation event. In addition to the information relatively to the total activity and the location of the cracks, certain waveform features supply detailed information on the type of cracking. The waveform of the emitted AE signal depends on the relative motion of the crack sides and therefore, it carries information on the mode of cracks. Therefore, AE is used for classification of the active cracking mode. This enables characterization of the current fracturing condition within the material and warning before final failure. Tension-related cracks, which in most materials and loading conditions are nucleated first, emit signals with higher frequency content and shorter rising time than shear cracks. However, in most cases wave propagation from the crack to the sensor is attenuative and dispersive. This results in signal distortion which is enhanced by geometry restrictions and material or damage-induced inhomogeneity. This results in strong change of the waveform shape and the calculated AE parameters. This effect is stronger as the propagation distance increases rendering crack classification troublesome for structures where the separation distance between sensors is long. In the present study, fracture experiments were conducted in cementitious specimens in order to investigate the influence of distance on the AE parameters as measured by sensors at different distances from the source. Numerical simulations based on the finite difference method are also used to enlighten the problem and expand to different material conditions. This is one of the first studies of wave dispersion examined not from the classical ultrasonics point of view of phase velocity dependence on frequency but from the AE view, where specific waveform parameters are of interest. Experimental and numerical results show that the influence of the propagation path is crucial and should be taken into consideration for AE characterization of large structures, while it should not be neglected even in small-scale laboratory studies in order to improve crack characterization. [Copyright &y& Elsevier]

Published

2012

5. High energy, low frequency, ultrasonic transducer

Author

Brown, Albert [Hayward, CA]

Published

2000

6. Effect of wave distortion on acoustic emission characterization of cementitious materials

Author

A. C. Mpalaskas, D. Ntalakas, Theodore E. Matikas, D. G. Aggelis, and Mechanics of Materials and Constructions

Subjects

Materials science, Wave propagation, Acoustics, Signal, matrix cracking, Distortion, propagation, Waveform, General Materials Science, Dispersion (water waves), rise time, attenuation, Civil and Structural Engineering, business.industry, ultrasound, scattering, media, fracture mode, Fracture mechanics, Building and Construction, Structural engineering, damage evaluation, fracture process, Acoustic emission, classification, frequency, propagation distance, dispersion, reinforced-concrete, Phase velocity, business

Abstract

The fracturing behavior of materials can be nondestructively monitored by the acoustic emission (AE) technique, using sensors that detect the transient elastic waves after any crack propagation event. In addition to the information relatively to the total activity and the location of the cracks, certain waveform features supply detailed information on the type of cracking. The waveform of the emitted AE signal depends on the relative motion of the crack sides and therefore, it carries information on the mode of cracks. Therefore, AE is used for classification of the active cracking mode. This enables characterization of the current fracturing condition within the material and warning before final failure. Tension-related cracks, which in most materials and loading conditions are nucleated first, emit signals with higher frequency content and shorter rising time than shear cracks. However, in most cases wave propagation from the crack to the sensor is attenuative and dispersive. This results in signal distortion which is enhanced by geometry restrictions and material or damage-induced inhomogeneity. This results in strong change of the waveform shape and the calculated AE parameters. This effect is stronger as the propagation distance increases rendering crack classification troublesome for structures where the separation distance between sensors is long. In the present study, fracture experiments were conducted in cementitious specimens in order to investigate the influence of distance on the AE parameters as measured by sensors at different distances from the source. Numerical simulations based on the finite difference method are also used to enlighten the problem and expand to different material conditions. This is one of the first studies of wave dispersion examined not from the classical ultrasonics point of view of phase velocity dependence on frequency but from the AE view, where specific waveform parameters are of interest. Experimental and numerical results show that the influence of the propagation path is crucial and should be taken into consideration for AE characterization of large structures, while it should not be neglected even in small-scale laboratory studies in order to improve crack characterization. (C) 2012 Elsevier Ltd. All rights reserved. Construction and Building Materials

Published

2012

7. Time delay spectrum conditioner

Author

Greiner, Norman [Los Alamos, NM]

Published

1980