Abstract:To accurately predict the vibration response of large-span floor under crowd walking, the random crowd load model was established according to the relationship among variable step size, variable step frequency and variable step speed during pedestrian walking. Based on the thin plate vibration theory, the crowd-large-span floor coupling dynamic equation considering human-structure interaction was deduced, and the variation rule of dynamic characteristic parameters and acceleration response of large-span floor under random crowd action was calculated and analyzed. The results show that under the random crowd walking, the instantaneous frequency of the large-span floor is decreased with latter increasing, and the instantaneous damping ratio is increased with latter decreasing. With the increasing of the number of people walking, the minimum instantaneous frequency of the structure is decreased significantly, and the maximum instantaneous damping ratio is increased significantly, while the instantaneous acceleration and root mean square acceleration of the large-span floor show the trend of increasing with latter decreasing. Under the different number of people walking, the acceleration response of the structure with and without pedestrian randomness is significantly different. The maximum difference rate of instantaneous acceleration can reach 53.90%, and the maximum difference rate of root mean square acceleration can reach 61.57%.
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2024, Vol. 45 
