Multi-layer imaging method for void defects in ballastless track using forward ray tracing with SAFT

•SAFT with forward ray tracing is proposed to locate void defects in ballastless track.•This method is validated with finite-element analysis and lab experiment.•The method outperforms RR-SAFT and RMS-SAFT.•The research promotes more efficient and precise ultrasonic imaging of ballastless track. Rap...

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Veröffentlicht in:	Measurement : journal of the International Measurement Confederation 2021-03, Vol.173, p.108532, Article 108532
Hauptverfasser:	Li, Zai-Wei, Zhu, Wen-Fa, Meng, Xiang-Zhen, Fan, Guo-Peng, He, Yue-Lei
Format:	Artikel
Sprache:	eng
Schlagworte:	Concrete structures Efficiency and precision Finite element analysis Finite element method High speed rail Maintenance Mathematical analysis Medical imaging Multi-layer concrete ballastless track Multilayers Photography Railway tracks Ray forward tracing with SAFT Ray tracing Refracted waves Repair Sensors Synthetic apertures Travel time Ultrasonic imaging Ultrasonic testing Void detection
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container_title	Measurement : journal of the International Measurement Confederation
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creator	Li, Zai-Wei Zhu, Wen-Fa Meng, Xiang-Zhen Fan, Guo-Peng He, Yue-Lei
description	•SAFT with forward ray tracing is proposed to locate void defects in ballastless track.•This method is validated with finite-element analysis and lab experiment.•The method outperforms RR-SAFT and RMS-SAFT.•The research promotes more efficient and precise ultrasonic imaging of ballastless track. Rapid and precise detection of void disease in ballastless track is fundamental to the repair and maintenance of high-speed rail. Under the difference in material attributes of ballastless track in each layer and the resultant refraction, the calculation of sonic wave travel time can be complex. To this end, ultrasonic imaging is developed for the precise and rapid imaging of void diseases in ballastless track with multi-layer concrete structure. Combining forward ray tracing and synthetic aperture focusing technique (RF-SAFT), the ultrasonic imaging mechanism is developed based on the forward mapping of the refracted ray trajectory to establish the relationship between the refracted ray and multi-layer boundary, so as to identify the void locations. This method is calibrated and validated with finite-element analysis and experiment, which is demonstrated to contribute to efficient high-resolution photography of void diseases in multi-layer concrete ballastless track, with the calculation time reduced by 70% in comparison to the conventional backward ray tracing with SAFT, and higher precision than that by root mean square SAFT. This research can promote responsive and precise detection of void disease in ballastless track to support effective repair and maintenance of high-speed rail.
doi_str_mv	10.1016/j.measurement.2020.108532
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Rapid and precise detection of void disease in ballastless track is fundamental to the repair and maintenance of high-speed rail. Under the difference in material attributes of ballastless track in each layer and the resultant refraction, the calculation of sonic wave travel time can be complex. To this end, ultrasonic imaging is developed for the precise and rapid imaging of void diseases in ballastless track with multi-layer concrete structure. Combining forward ray tracing and synthetic aperture focusing technique (RF-SAFT), the ultrasonic imaging mechanism is developed based on the forward mapping of the refracted ray trajectory to establish the relationship between the refracted ray and multi-layer boundary, so as to identify the void locations. This method is calibrated and validated with finite-element analysis and experiment, which is demonstrated to contribute to efficient high-resolution photography of void diseases in multi-layer concrete ballastless track, with the calculation time reduced by 70% in comparison to the conventional backward ray tracing with SAFT, and higher precision than that by root mean square SAFT. 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Rapid and precise detection of void disease in ballastless track is fundamental to the repair and maintenance of high-speed rail. Under the difference in material attributes of ballastless track in each layer and the resultant refraction, the calculation of sonic wave travel time can be complex. To this end, ultrasonic imaging is developed for the precise and rapid imaging of void diseases in ballastless track with multi-layer concrete structure. Combining forward ray tracing and synthetic aperture focusing technique (RF-SAFT), the ultrasonic imaging mechanism is developed based on the forward mapping of the refracted ray trajectory to establish the relationship between the refracted ray and multi-layer boundary, so as to identify the void locations. This method is calibrated and validated with finite-element analysis and experiment, which is demonstrated to contribute to efficient high-resolution photography of void diseases in multi-layer concrete ballastless track, with the calculation time reduced by 70% in comparison to the conventional backward ray tracing with SAFT, and higher precision than that by root mean square SAFT. 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Rapid and precise detection of void disease in ballastless track is fundamental to the repair and maintenance of high-speed rail. Under the difference in material attributes of ballastless track in each layer and the resultant refraction, the calculation of sonic wave travel time can be complex. To this end, ultrasonic imaging is developed for the precise and rapid imaging of void diseases in ballastless track with multi-layer concrete structure. Combining forward ray tracing and synthetic aperture focusing technique (RF-SAFT), the ultrasonic imaging mechanism is developed based on the forward mapping of the refracted ray trajectory to establish the relationship between the refracted ray and multi-layer boundary, so as to identify the void locations. This method is calibrated and validated with finite-element analysis and experiment, which is demonstrated to contribute to efficient high-resolution photography of void diseases in multi-layer concrete ballastless track, with the calculation time reduced by 70% in comparison to the conventional backward ray tracing with SAFT, and higher precision than that by root mean square SAFT. This research can promote responsive and precise detection of void disease in ballastless track to support effective repair and maintenance of high-speed rail.</abstract><cop>London</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.measurement.2020.108532</doi></addata></record>
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subjects	Concrete structures Efficiency and precision Finite element analysis Finite element method High speed rail Maintenance Mathematical analysis Medical imaging Multi-layer concrete ballastless track Multilayers Photography Railway tracks Ray forward tracing with SAFT Ray tracing Refracted waves Repair Sensors Synthetic apertures Travel time Ultrasonic imaging Ultrasonic testing Void detection
title	Multi-layer imaging method for void defects in ballastless track using forward ray tracing with SAFT
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