论文信息 - GPR Monitoring of Artificial Debonded Pavement Structures throughout Its Life Cycle during Accelerated Pavement Testing

GPR Monitoring of Artificial Debonded Pavement Structures throughout Its Life Cycle during Accelerated Pavement Testing

The paper gives an overview of a ground penetrating radar (GPR) experiment to survey debonding areas within pavement structure during accelerated pavement tests (APT) conducted on the university Gustave Eiffel’s fatigue carrousel. Thirteen artificial defect sections composed of three types of defects (Tack-free, Geotextile, and Sand-based) were embedded during the construction phase between the top and the base layers. The data were collected in two stages covering the entire life cycle of the pavement structure using four GPR systems: An air-coupled ultra-wideband GPR (SF-GPR), two wideband 2D ground coupled GPRs (a SIR-4000 with a 1.5 GHz antenna and a 2.6 GHz-StructureScan from GSSI manufacturer), and a wideband 3D GPR (from 3D-radar manufacturer). The first stage of the experiments took place in 2012–2013 and lasted up to 300 K loadings. During this stage, the pavement structure presented no clear degradation. The second stage of experiments was conducted in 2019 and continued until the pavement surface demonstrated a strong degradation, which was observed at 800 K loadings. At the end of the GPR experiments, several trenches were cut at various sections to get the ground truth of the pavement structure. Finally, the GPR data are processed using the conventional amplitude ratio test to study the evolution of the echoes coming from the debonded areas.

[1] Cedric Le Bastard,et al. Performance assessment of SVM-based classification techniques for the detection of artificial debondings within pavement structures from stepped-frequency A-scan radar data , 2019, NDT & E International.

[2] Christina Plati,et al. Review of NDT Assessment of Road Pavements Using GPR , 2013 .

[3] Peter Annan,et al. A review of Ground Penetrating Radar application in civil engineering: A 30-year journey from Locating and Testing to Imaging and Diagnosis , 2017, NDT & E International.

[4] Christina Plati,et al. Estimation of in-situ density and moisture content in HMA pavements based on GPR trace reflection amplitude using different frequencies , 2013 .

[5] Andy Collop,et al. Effect of Bond Condition on Flexible Pavement Performance , 2005 .

[6] Higinio González-Jorge,et al. Approach to identify cracking in asphalt pavement using GPR and infrared thermographic methods: Preliminary findings , 2014 .

[7] V. Baltazart,et al. Automatic Crack Detection on Pavement Images for Monitoring Road Surface Conditions—Some Results from the Collaborative FP7 TRIMM Project , 2016 .

[8] T. Scullion,et al. Road evaluation with ground penetrating radar , 2000 .

[9] Mercedes Solla,et al. Assessing the pavement subgrade by combining different non-destructive methods , 2017 .

[10] G. Villain,et al. Gammadensimetry : A method to determine drying and carbonation profiles in concrete , 2006 .