Due to the frequent occurrence of extreme rainstorm waterlogging events in recent years, the safety and resilience of underground engineering have been greatly challenged. Therefore, a resilience evaluation method was proposed for urban underground engineering under rainstorm and waterlogging conditions. Firstly, the law of the water intake process in underground engineering was studied through rainstorm scenario simulation. Secondly, the underground engineering performance function under the condition of rainstorms and waterlogging was established from the perspective of personnel safe passage rate, and the passable performance variation rule of underground engineering under different influent conditions was revealed. The quantitative calculation method of underground engineering toughness index from the perspective of safe passage was proposed. Finally, the method was applied through a typical case, and the change law of resilience of typical underground engineering under rainstorm waterlogging conditions was revealed by considering factors such as rainstorm recurrence period and retaining facilities. The results show that the resilience of underground engineering decreases with the increase of rainstorm intensity and increases with the increase of retaining facilities' height.
Zhang Dongmei
,
Wei Chuanyao
,
Huang Zhongkai
,
Zhang Wuyu
,
Chen Haixia
. Resilience Evaluation of Urban Waterlogging Underground Engineering from the Perspective of Personnel Passage[J]. Chinese Journal of Underground Space and Engineering, 2024
, 20(S1)
: 358
-368
.
DOI: 10.20174/j.JUSE.2024.S1.43
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