期刊
STRUCTURAL HEALTH MONITORING-AN INTERNATIONAL JOURNAL
卷 22, 期 4, 页码 2325-2345出版社
SAGE PUBLICATIONS LTD
DOI: 10.1177/14759217221122337
关键词
Structural health monitoring; bridge responses; predictive model; back propagation neural network; long short-term memory
Bridges are critical components of transportation infrastructure, and regular inspections are necessary to ensure their long-term performance and public safety. This study presents an in-site structural health monitoring system deployed on the Caohekou Bridge in China, providing continuous real-time data for 4 years. Various structural parameters are monitored and assessed to understand the effects of time and temperature on structural deterioration. Additionally, methods are proposed to predict bridge responses under changing environmental and operational conditions, enabling early warning and effective maintenance decisions.
Bridges are critical components of transportation infrastructure. To ensure the long-term performance of bridges and the safety of the public, regular inspections are required during their service. Structural performance assessments are subject to various conditions. Structural deterioration is caused by complex environmental and operational conditions (EOCs) including temperature changes, truckloads, chemical corrosion, etc. In this study, an in-site structural health monitoring (SHM) system is designed and deployed on the Caohekou Bridge in China with a series of sensors installed, providing continuous real-time data for 4 years. Crack width, vertical deformation, concrete strains, temperature, longitudinal displacement and acceleration are monitored and assessed. Time-history monitoring data are comprehensively analysed to advance our understanding of structural deterioration caused by time and temperature. It is very common to lose data during the monitoring process, especially in the long-term run. To overcome the challenge of missing data package and to realize early warning, methods including an SHM systems face, a back propagation neural network and a long short-term memory are proposed to predict the bridge responses under the change of EOCs. It has been proved that the performance of predicted crack widths is close to that of the measured value, and the trend of change is consistent. Such results indicate that approaches proposed that quantitatively assess in-service structure are promising. Therefore, effective and efficient maintenance decisions can be made to ensure an immediate response, long-term safety and serviceability of bridge structures.
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