Large-scale geo-mechanical model tests for stability assessment of super-large cross-section tunnel

•Large-scale model tests of a double-hole tunnel with lining were conducted.•Failure behaviors under different burial depths were elucidated.•Failure areas of super-large cross-section tunnels were identified.•Safety factors were proposed for super-large cross-section tunnel. For ensuring safety dur...

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Veröffentlicht in:	Tunnelling and underground space technology 2021-03, Vol.109, p.103756, Article 103756
Hauptverfasser:	Li, Liping, Shang, Chengshun, Chu, Kaiwei, Zhou, Zongqing, Song, Shuguang, Liu, Zhenhua, Chen, Yanhao
Format:	Artikel
Sprache:	eng
Schlagworte:	Construction Cross-sections High burial depth Large cross-section tunnel Mathematical analysis Mathematical models Model testing Model tests Numerical simulation Occupational safety Overloading Rock masses Rocks Safety factors Safety management Stability analysis Tunnel stability Tunnels Underground construction
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container_title	Tunnelling and underground space technology
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creator	Li, Liping Shang, Chengshun Chu, Kaiwei Zhou, Zongqing Song, Shuguang Liu, Zhenhua Chen, Yanhao
description	•Large-scale model tests of a double-hole tunnel with lining were conducted.•Failure behaviors under different burial depths were elucidated.•Failure areas of super-large cross-section tunnels were identified.•Safety factors were proposed for super-large cross-section tunnel. For ensuring safety during the construction and use of a super-large cross-section tunnel, it is essential to understand the lining structure failure pattern and the instability of the surrounding rock mass under a high burial depth. With the Letuan Tunnel of China as an engineering background, we conducted large-scale geo-mechanical model tests and numerical simulations in this study. The results reveal the failure behaviour of the lining structure of a super-large cross-section tunnel and demonstrate the stress variation of the surrounding rock under overload conditions. Based on an analysis of the key protected areas as per the experimental results, the lining structure near the tunnel foot, vault, and entrance should be strengthened, and the stress of the surrounding rock near the middle rock wall, especially the tunnel sidewall and foot, should be focused on. Overloading safety factors were also determined through the overloading test. This study can provide a reliable reference for the design of support structures and safety control during the construction of a double-hole super-large cross-section tunnel in the deeply buried area.
doi_str_mv	10.1016/j.tust.2020.103756
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For ensuring safety during the construction and use of a super-large cross-section tunnel, it is essential to understand the lining structure failure pattern and the instability of the surrounding rock mass under a high burial depth. With the Letuan Tunnel of China as an engineering background, we conducted large-scale geo-mechanical model tests and numerical simulations in this study. The results reveal the failure behaviour of the lining structure of a super-large cross-section tunnel and demonstrate the stress variation of the surrounding rock under overload conditions. Based on an analysis of the key protected areas as per the experimental results, the lining structure near the tunnel foot, vault, and entrance should be strengthened, and the stress of the surrounding rock near the middle rock wall, especially the tunnel sidewall and foot, should be focused on. Overloading safety factors were also determined through the overloading test. 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For ensuring safety during the construction and use of a super-large cross-section tunnel, it is essential to understand the lining structure failure pattern and the instability of the surrounding rock mass under a high burial depth. With the Letuan Tunnel of China as an engineering background, we conducted large-scale geo-mechanical model tests and numerical simulations in this study. The results reveal the failure behaviour of the lining structure of a super-large cross-section tunnel and demonstrate the stress variation of the surrounding rock under overload conditions. Based on an analysis of the key protected areas as per the experimental results, the lining structure near the tunnel foot, vault, and entrance should be strengthened, and the stress of the surrounding rock near the middle rock wall, especially the tunnel sidewall and foot, should be focused on. Overloading safety factors were also determined through the overloading test. 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For ensuring safety during the construction and use of a super-large cross-section tunnel, it is essential to understand the lining structure failure pattern and the instability of the surrounding rock mass under a high burial depth. With the Letuan Tunnel of China as an engineering background, we conducted large-scale geo-mechanical model tests and numerical simulations in this study. The results reveal the failure behaviour of the lining structure of a super-large cross-section tunnel and demonstrate the stress variation of the surrounding rock under overload conditions. Based on an analysis of the key protected areas as per the experimental results, the lining structure near the tunnel foot, vault, and entrance should be strengthened, and the stress of the surrounding rock near the middle rock wall, especially the tunnel sidewall and foot, should be focused on. Overloading safety factors were also determined through the overloading test. This study can provide a reliable reference for the design of support structures and safety control during the construction of a double-hole super-large cross-section tunnel in the deeply buried area.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.tust.2020.103756</doi></addata></record>
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subjects	Construction Cross-sections High burial depth Large cross-section tunnel Mathematical analysis Mathematical models Model testing Model tests Numerical simulation Occupational safety Overloading Rock masses Rocks Safety factors Safety management Stability analysis Tunnel stability Tunnels Underground construction
title	Large-scale geo-mechanical model tests for stability assessment of super-large cross-section tunnel
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