Development and in-situ application of a real-time monitoring system for the interaction between TBM and surrounding rock

•A real-time monitoring system for TBM-surrounding rock interaction is developed.•The system is capable of unattended operations, and can be controlled remotely.•Analysis methods for cutter-head vibration and shield jamming are developed.•The presented monitoring system has been performed in-situ ap...

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Bibliographic Details
Published in:Tunnelling and underground space technology 2018-11, Vol.81, p.187-208
Main Authors: Huang, Xing, Liu, Quangsheng, Liu, He, Zhang, Penglin, Pan, Shaolin, Zhang, Xiaoping, Fang, Jingnian
Format: Article
Language:English
Subjects:
Boring machines
Cutter-head vibration
Data analysis
Data transmission
Entrapment
In-situ monitoring
Interaction between TBM and surrounding rock
Jamming
Monitoring systems
Real time
Real-time monitoring
Remote sensors
Restarting
Rocks
Shield
TBM
Time domain analysis
Tunnel construction
Tunnels
Vibration analysis
Vibration measurement
Vibration monitoring
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Summary:•A real-time monitoring system for TBM-surrounding rock interaction is developed.•The system is capable of unattended operations, and can be controlled remotely.•Analysis methods for cutter-head vibration and shield jamming are developed.•The presented monitoring system has been performed in-situ application. In this study, a real-time monitoring system for the interaction between TBM (Tunnel Boring Machine) and surrounding rock is developed, in which the focus is on the cutter-head vibration, and the interaction between the surrounding rock and the shield. The monitoring system consists of sensors, data acquisition subsystem, remote data transmission-storage subsystem and data analysis subsystem. A program is developed to carry out unattended operation of the monitoring software. Further, it can transmit the data synchronously from inside the tunnel to the system outside the tunnel, as well as give feedback information of any operation error to the users automatically. The feasibility, stability, durability of the developed monitoring method has been validated. Subsequently, the time-domain and spectral frequent-domain analysis methods for the accelerated velocity of cutter-head vibration are put forward. Further, the back-calculation analyses method for the surrounding rock pressures acting on the shield and shield jamming warning approach is also developed. Then, the developed monitoring method has been implemented on the double-shield TBM in China’s Lanzhou Water Resource Project. Many evolution rules have been obtained. Firstly, the cutter-head vibration monitoring results show that: (a) the cutter-head vibration is significantly correlated with the TBM advance parameters and the geological conditions; (b) the cutter-head vibrates intensely during TBM restarting after a stoppage or entrapment; (c) the cutter-head vibration intensity increases with the increasing cutter-head rotational speed and penetration rate. Secondly, in-situ monitoring of the surrounding rock pressures acting on the shield manifests that: (a) the surrounding rock pressures acting on the shield is non-uniform, which increase with the growing distance from the tunnel face; (b) the contact scope enlarges from the front shield to the rear shield gradually with time, and the surrounding rock loads acting on the shield increases simultaneously; (c) the squeezing pressures acting on the shield decrease and then return to the relatively small pressures after the relief countermeasures we
ISSN:0886-7798
1878-4364
DOI:10.1016/j.tust.2018.07.018