Abstract
As human occupancy has an enormous effect on the dynamics of light, flexible, large-span, low-damping structures, which are sensitive to human-induced vibrations, it is essential to investigate the effects of pedestrian–structure interaction. The single-degree-of-freedom (SDOF) mass–spring–damping (MSD) model, the simplest dynamical model that considers how pedestrian mass, stiffness and damping impact the dynamic properties of structures, is widely used in civil engineering. With field testing methods and the SDOF MSD model, this study obtained pedestrian dynamics parameters from measured data of the properties of both empty structures and structures with pedestrian occupancy. The parameters identification procedure involved individuals at four walking frequencies. Body frequency is positively correlated to the walking frequency, while a negative correlation is observed between the body damping ratio and the walking frequency. The test results further show a negative correlation between the pedestrian’s frequency and his/her weight, but no significant correlation exists between one’s damping ratio and weight. The findings provide a reference for structural vibration serviceability assessments that would consider pedestrian–structure interaction effects.
Highlights
With the application of increasingly advanced structural design methods, highstrength, lightweight materials and construction techniques, building structures are evolving towards being lightweight, flexible, large spans and low damping
The problem of human discomfort caused by structural vibrations is of increasing concern [2,3,4,5,6,7,8,9,10,11,12,13,14], and current design codes may underestimate the impacts of vibrations induced by pedestrians [15]
The interaction between pedestrians and structure can be expressed in two aspects: (1) the influence of structural dynamic properties and vibration levels on humaninduced loads; and (2) the influence of the residual crowd on structural dynamic properties and dynamic response
Summary
With the application of increasingly advanced structural design methods, highstrength, lightweight materials and construction techniques, building structures are evolving towards being lightweight, flexible, large spans and low damping. The covers of largespan and light structures such as footbridges, shelters, exhibition halls and stadium stands have a low vertical natural frequency and a large vibration response due to their lightness, large span and low damping. When the vertical or horizontal frequency of the structure is close to the excitation frequency of the crowd activity, the crowd excitation will cause resonation of the structure, whose response may even exceed the tolerance limit of human comfort, which results in psychological panic among pedestrians [1]. The problem of human discomfort caused by structural vibrations is of increasing concern [2,3,4,5,6,7,8,9,10,11,12,13,14], and current design codes may underestimate the impacts of vibrations induced by pedestrians [15]. The interaction between pedestrians and structure can be expressed in two aspects: (1) the influence of structural dynamic properties and vibration levels on humaninduced loads; and (2) the influence of the residual crowd on structural dynamic properties and dynamic response
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