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11-03-2019

The Impact of an Obstacle on Competitive Evacuation Through a Bottleneck

Authors: Peng Lin, Dong li Gao, Guo Yuan Wang, Fan Yu Wu, Jian Ma, You Liang Si, Tong Ran

Published in: Fire Technology | Issue 6/2019

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Abstract

Within the last decade, a number of crowd accidents have attracted the interest of scientists to study the movement of crowd under high levels of competition. An interesting finding in crowd dynamics is that the presence of an obstacle at an appropriate distance in front of an exit can improve flow rate. A numerical simulation based on the discrete element method (DEM) and social force model was adopted in this paper in order to study the impact of obstacles on flow rate during competitive evacuation in two typical Settings with a single 0.8 m-wide exit. Setting I is a 15 m-wide room and Setting II is a 3 m wide corridor formed by the same room with lateral constrains. Numerical simulation in Setting I showed that a 1 m-obstacle at 1-m away from the exit can reduce evacuation time by approximately 49%. However, a contrasting increase of evacuation time by approximately 64% is observed in Setting II for the obstacle at the same location. To verify the findings, a number of experiments were conducted by compelling mice to escape under high competition in two similar settings. The general limitations of such experiments were accepted and described. These results were consistent with numerical simulations. This study demonstrates that whether an obstacle can improve the flow rate passing through an exit is dependent on the surrounding geometry.

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Title: The Impact of an Obstacle on Competitive Evacuation Through a Bottleneck
Authors: Peng Lin
Dong li Gao
Guo Yuan Wang
Fan Yu Wu
Jian Ma
You Liang Si
Tong Ran
Publication date: 11-03-2019
Publisher: Springer US
Published in: Fire Technology / Issue 6/2019
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-019-00838-4

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