Modal Analysis of Flax Fiber Reinforced Composite Bridge Using FEA to Support the Design of the Target Bridge Made of Innovative Material

Ali Shahmirzaloo; Faas Moonen

doi:10.4028/p-MhC8E7

Paper Titles

Trial Production of Disk Caster for Thin Bar
p.37

Design and Properties Analysis of Coating Removal Actuator by Abrasive Water Jet
p.49

Exhaust Emission Analysis of Spark Ignition Engine with Modification of Exhaust Gas Recirculation (EGR), Air Intake Tank, and Swirl Generator
p.57

Turbulent Flow Analysis in an Annular Diffuser Having a Rectangular Twisted Hub
p.67

Dynamic Response of a Tube of Heat Exchanger with an Axial Load
p.73

Numerical Considerations on Design Parameters of Diffuser Vane Slit
p.79

Investigation of Stress and Delamination Behaviors of a Bonded Beam Having Orthotropic Inclusion in Adhesive Layer under Tensile Loading
p.85

Modal Analysis of Flax Fiber Reinforced Composite Bridge Using FEA to Support the Design of the Target Bridge Made of Innovative Material
p.91

HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 169Modal Analysis of Flax Fiber Reinforced Composite...

Modal Analysis of Flax Fiber Reinforced Composite Bridge Using FEA to Support the Design of the Target Bridge Made of Innovative Material

Abstract:

This paper presents a comprehensive modal analysis of a 15-meter span footbridge constructed using fiber-reinforced polymer structures (FRPs) integrated with natural resource fibers and a partial bio-based resin. The bridge was erected at the Floriade Expo 2022 located in Almere, the Netherlands. The lightweight nature of FRPs, coupled with their sensitivity to vibrations, necessitates the satisfaction of specific design requirements to ensure the safety and comfort of pedestrians. The initial phase of this study entails determining the natural frequencies of the bridge via Finite Element Analysis (FEA). Comparative assessment between the footbridge's natural frequency and excitation frequencies evaluates the risk of resonance induced by pedestrian loading. The FEA employs a composite layup technique to replicate the same ply configuration as the actual bridge model. Following the initial assessment, a comprehensive analysis is undertaken to meticulously examine the dynamic response of the footbridge. This analysis prioritizes the evaluation of critical acceleration parameters under diverse conditions, encompassing scenarios such as walking, jogging, and crowded pedestrian traffic. Bridge peak acceleration is assessed and juxtaposed against design values based on site usage, route redundancy, and structural height, and for the target bridge is 0.77 m/s². The results indicate that the footbridge successfully fulfills the specified design criteria for ensuring pedestrian comfort under various dynamic loading conditions. This finding underscores the significance of including the footbridge in the building application process. This study underscores the successful application of FRPs, augmented with natural fibers and bio-based resin, in ensuring the structural integrity and comfort of footbridges subjected to real-world dynamic conditions.