Experimental study on the performance of synergistic ventilation system combining shaft with mechanical ventilation in extra-long road tunnels

•A novel mechanical board-coupled ventilation shaft was introduced.•Smoke extraction pattern would shift due to the coupling-effect between the shaft and the fan.•A model to analyze the dynamic of the synergistic smoke extraction was established.•The novel shaft can significantly improve both smoke...

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Veröffentlicht in:Tunnelling and underground space technology 2024-05, Vol.147, p.105706, Article 105706
Hauptverfasser: Zhu, Bin, Cong, Haiyong, Yu, Binshan, Shao, Zhuyu, Ye, Lili, Bi, Yubo, Zeng, Yiping
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Sprache:eng
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Zusammenfassung:•A novel mechanical board-coupled ventilation shaft was introduced.•Smoke extraction pattern would shift due to the coupling-effect between the shaft and the fan.•A model to analyze the dynamic of the synergistic smoke extraction was established.•The novel shaft can significantly improve both smoke and heat extraction performance. Ventilation shafts are widely equipped in extra-long road tunnels. Due to the plug-holing phenomenon, it may be impossible to improve smoke extraction performance solely by increasing extraction velocity in a traditional ventilation shaft. Taking reference from practices in mine ventilation shafts, a novel mechanical board-coupled ventilation shaft (MBCS) was introduced. A total of 120 experiments in a 1:20 reduced-scale tunnel model were conducted to validate the effectiveness of the novel shaft. The effects of shaft height, board location, and extraction velocity were investigated, and the interaction dynamic mechanism of synergistic smoke extraction between fan-driven and shaft-driven was revealed. The results indicate that the novel MBCS can achieve better smoke extraction performance as the extraction velocity increases. Besides, compared to the traditional MBCS in our previous study, the smoke extraction efficiency of the novel MBCS improves by 19.8 %, the heat extraction performance improves by 75.7 %. Moreover, based on theoretical and dimensional analysis, a model to analyze the dynamic mechanism of synergistic smoke extraction was established, which may provide positive insights for smoke control and extraction design both in extra-long road tunnels and mine ventilation shafts.
ISSN:0886-7798
DOI:10.1016/j.tust.2024.105706