Abstract
Vertical deflection has been emphasized as an important safety indicator in the management of railway bridges. Therefore, various standards and studies have suggested physics-based models for predicting the time-dependent deflection of railway bridges. However, these approaches may be limited by model errors caused by uncertainties in various factors, such as material properties, creep coefficient, and temperature. This study proposes a new Bayesian method that employs both a finite element model and actual measurement data. To overcome the limitations of an imperfect finite element model and a shortage of data, Gaussian process regression is introduced and modified to consider both, the finite element analysis results and actual measurement data. In addition, the probabilistic prediction model can be updated whenever additional measurement data is available. In this manner, a probabilistic prediction model, that is customized to a target bridge, can be obtained. The proposed method is applied to a pre-stressed concrete railway bridge in the construction stage in the Republic of Korea, as an example of a bridge for which accurate time-dependent deflection is difficult to predict, and measurement data are insufficient. Probabilistic prediction models are successfully derived by applying the proposed method, and the corresponding prediction results agree with the actual measurements, even though the bridge experienced large downward deflections during the construction stage. In addition, the practical uses of the prediction models are discussed.
Highlights
The vertical deflection of railway bridges is an important safety indicator that is used in the safety management of structures and trains [1,2]
The monitoring and management of the vertical deflection of railway bridges have been emphasized in several standards, such as the Design Guide for Steel Railway Bridges of the UK (2004), UIC CODE 518 OR (2009), and the Guideline of Track Maintenance of Korea Rail Network Authority (2016), which suggest monitoring for the acceptable vertical deflection at mid-span [3,4,5]
Pre-stressed concrete (PSC) girders have been widely adopted as superstructures for high-speed railway bridges; the long-term deflection of bridges with PSC girders is known to be dependent on Sensors 2019, 19, 4956; doi:10.3390/s19224956
Summary
The vertical deflection of railway bridges is an important safety indicator that is used in the safety management of structures and trains [1,2]. This study aims to overcome the limitations of the structural model error and data shortage and provide a probabilistic prediction of bridge deflection To this end, a new Bayesian method is proposed, utilizing an FE model constructed with physics-based knowledge and actual measurement data. The prediction model, based on physics-based knowledge, is updated by measurement data utilizing Gaussian process regression (GPR), which is a nonparametric Bayesian method In this manner, the probabilistic interval (e.g., 95% prediction interval) of the expected vertical deflection can be obtained, which can be used for bridge deflection management in the construction stage
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