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MODERN TUNNELLING TECHNOLOGY 2025, Vol. 62 Issue (2) :71-78    DOI:
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Theoretical Innovation, Method Implementation, and Engineering Verification of Shield Machine with Thrust Vector Intelligent Control
(1. Shanghai Tunnel Engineering Co. Ltd., Shanghai 200232; 2. Shanghai Urban Construction Tunnel Equipment Co. Ltd.,Shanghai 200137; 3. School of Civil and Hydraulic Engineering, Huazhong University of Science and Technology, Wuhan 430074;4. Department of Geotechnical Engineering College of Civil Engineering, Tongji University, Shanghai 200092
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Abstract In order to address the practical issue of unstable tunnel axis quality caused by manual control of the shield machine, the motion mechanism of the shield machine under the dual vector effects of load and thrust is analyzed.A method for autonomous control of the shield machine's posture based on thrust vector technology is proposed, and schemes for autonomous planning of shield motion path and intelligent control of thrust vector are presented. This method is applied to large-diameter shield tunnelling. The practice demonstrates that the target thrust of the shield machine maintains a fixed deviation from the actual value, and the shield machine's excavation speed remains stable. The effective execution of the target thrust torque enables accurate steering control in both the horizontal and elevation directions, and the shield machine's actual posture gradually approaches the set target.
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KeywordsShield tunnel   Shield posture   Thrust vector   Autonomous control   Engineering verification     
Abstract: In order to address the practical issue of unstable tunnel axis quality caused by manual control of the shield machine, the motion mechanism of the shield machine under the dual vector effects of load and thrust is analyzed.A method for autonomous control of the shield machine's posture based on thrust vector technology is proposed, and schemes for autonomous planning of shield motion path and intelligent control of thrust vector are presented. This method is applied to large-diameter shield tunnelling. The practice demonstrates that the target thrust of the shield machine maintains a fixed deviation from the actual value, and the shield machine's excavation speed remains stable. The effective execution of the target thrust torque enables accurate steering control in both the horizontal and elevation directions, and the shield machine's actual posture gradually approaches the set target.
KeywordsShield tunnel,   Shield posture,   Thrust vector,   Autonomous control,   Engineering verification     
Cite this article:   
.Theoretical Innovation, Method Implementation, and Engineering Verification of Shield Machine with Thrust Vector Intelligent Control[J]  MODERN TUNNELLING TECHNOLOGY, 2025,V62(2): 71-78
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