Abstract
The detection of acoustic emissions with multiple channels and different kinds of sensors (external ultrasound electronic sensors and internal optical fiber sensors) for monitoring power transformers is presented. The source localization based on the times of arrival was previously studied, comparing different strategies for solving the location equations and the most efficient strategy in terms of computational and complexity costs versus performance was selected for analyzing the error propagation. The errors of the acoustic emission source location (localization process) are evaluated from the errors of the times of arrival (detection process). A hybrid programming architecture is proposed to optimize both stages of detection and location. It is formed by a virtual instrumentation system for the acquisition, detection and noise reduction of multiple acoustic channels and an algorithms-oriented programming system for the implementation of the localization techniques (back-propagation and multiple-source separation algorithms could also be implemented in this system). The communication between both systems is performed by a packet transfer protocol that allows continuous operation (e.g., on-line monitoring) and remote operation (e.g., a local monitoring and a remote analysis and diagnosis). For the first time, delay errors are modeled and error propagation is applied with this error source and localization algorithms. The 1% mean delay error propagation gives an accuracy of 9.5 mm (dispersion) and a maximum offset of 4 mm (<1% in both cases) in the AE source localization process. This increases proportionally for more severe errors (up to 5% reported). In the case of a multi-channel internal fiber-optic detection system, the resulting location error with a delay error of 2% is negligible when selecting the most repeated calculated position. These aim at determining the PD area of activity with a precision of better than 1% (<10 mm in 110 cm).
Highlights
Acoustic Emission (AE) is the study and practical use of elastic waves generated by a material subjected to external stress
Mean error, up to 10% maximum error). The origin of these errors in real conditions are of a different nature: (I) the PD source is a small region of the solid isolator and not a systematic point; (II) the conditions of propagation can change even for consecutive detections of the same acoustic source; (III) amplitude noise affects the effectiveness of the amplitude threshold that triggers the detection and this has a higher impact with a lower signal to noise ratio in the detector; and (IV) the amplitude of each single AE
The detection of acoustic emissions with multiple channels and different kinds of sensors has been implemented in a modular configuration, it is adapted to different applications
Summary
Acoustic Emission (AE) is the study and practical use of elastic waves generated by a material subjected to external stress. Acoustic refers to the pressure waves detected by ear. The elastic waves in solids are not limited to pressure waves, since all types of vibration modes are generated by acoustic emission sources (AES). AE has become almost universally used for the phenomena of elastic waves generated by an internal event in a medium. In this case, acoustic refers to any elastic wave generated by an AES. AE is the generation of an elastic wave by rapid change in the stress state of a region in the material.
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