Affiliation:
1. Faculty of Civil Engineering, Cracow University of Technology, 31-155 Cracow, Poland
2. Department of Structural and Geotechnical Engineering, Sapienza University of Rome, 00184 Rome, Italy
Abstract
Developing new structural materials, such as composite materials, has provided many opportunities in bridge engineering. Among these materials, glass-fiber-reinforced polymers (GFRPs), in particular, have found applications in footbridges. However, some of the commonly recognized advantages of GFRPs, such as the high values of the strength/weight ratio, can also be considered disadvantageous for certain realizations, particularly when the composite material used in a footbridge is, for example, subjected to dynamic actions such as those that are induced by wind and walking and/or running users. The induced accelerations can reach high values in comparison to recommended thresholds. Further, the natural frequency decays during the service life, reducing the capacity of the frequencies to move toward the frequency content of the pedestrian step. In this framework, the presented research is devoted to the dynamic comfort assessment of a pioneering cable-stayed GFRP pedestrian bridge, Aberfeldy, which was assembled in 1992 in the eponymous small town, which is located in Scotland (UK). The assessment was numerically performed through a finite element (FE) model, which was tuned based on the literature data concerning geometry, structural details, and in situ-acquired frequencies. The analyses carried out in this study include the evaluation of the accelerations’ time histories, which were induced when simulating a set of pedestrian path scenarios, and the dynamic actions that occur during pedestrian traveling. Specifically, different values of velocity and step frequency were considered as well as the inclusion of walking and running movements. Then, based on the acceleration values, the assessments of comfort criteria for the current standards were elaborated while also recognizing that the peak accelerations—usually attained for short periods—cannot be the only parameters considered in evaluating the pedestrian bridge capacity. This investigation allowed a dynamic comfort rating to be established for the Aberfeldy footbridge.
Subject
General Materials Science
Reference49 articles.
1. Delamination buckling of GFRP-strips in strengthened RC beams;Capozucca;Compos. Struct.,2022
2. Strengthening of non-engineered building beam-column joint to increase seismic performance with variation of steel plate width;Purwanto;Lecture Notes in Civil Engineering, Proceedings of the 5th International Conference on Rehabilitation and Maintenance in Civil Engineering: ICRMCE 2021, Surakarta, Indonesia, 8–9 July 2021,2022
3. Gatesco, N. (2011). New Materials for the Rehabilitation of Cultural Heritage, České Vysoké Učení Technické v Praze.
4. Bank, L.C. Application of FRP composites to bridges in the USA. Proceedings of the International Colloquium on Application of FRP to Bridges.
5. A review of the present and the future utilization of FRP composites in the civil infrastructure with reference to their important in-service properties;Hollaway;Constr. Build Mater.,2010