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基于原位虚实交互的盾构机空推过站仿真方法OA

Simulation method of shield-machine empty push through station based on in situ virtual-real interaction

中文摘要英文摘要

在地铁隧道建设中,由于盾构机体积和质量较大,在狭窄的地下空间进行空推过站时,极易与隧道主体结构或周边临时设施发生碰撞,构成重大安全风险.高成本、高风险的实物演练难以重复,因此传统盾构机空推过站风险管控通常依赖有限的传感器和人工测量的方法,存在实时感知能力弱、精度不足的问题.而纯虚拟仿真难以精确反映复杂多变的真实施工环境细节.针对盾构机空推过站过程中,地下空间高度受限、碰撞风险点具有隐蔽性与动态演变性的问题,该文提出一种基于原位虚实交互的盾构机空推过站仿真方法.首先,融合盾构机及施工场景多源数据,构建高保真虚拟模型;其次,通过混合现实技术及数据处理算法,将盾构机虚拟模型高精度配准并同步至真实施工现场,实现虚拟模型与真实环境的实时耦合模拟及碰撞检测反馈.经北京平谷地铁站盾构机空推过站原位仿真验证,该方法实现了虚实同步精度为±4.5mm、核心计算延迟小于6ms的高性能表现,并且能实时触发碰撞部件高亮预警,有效解决了传统方法实时性与精度不足的问题,显著提高经济效益,提升了复杂地下空间盾构机空推过站过程碰撞风险的超前识别与预警能力,为现场人员决策提供即时、可靠的依据.

[Objective]In the complex domain of metro tunnel construction,shield-machine station traversal represents a critical operational phase.Within these confined subterranean spaces,the sheer volume and mass of the shield machine pose substantial safety risks,particularly the risk of collisions with the main tunnel structure or peripheral temporary facilities.The clearance between the machinery and the tunnel walls is often minimal,rendering the operation extremely hazardous.As physical rehearsals for such large-scale operations are cost-prohibitive,logistically complex,and difficult to replicate under varying conditions,conventional risk management strategies have typically relied on limited sensor data and manual measurements.However,these methods are inherently labor-intensive and lack adequate real-time perception capabilities,providing only discrete data points rather than a continuous,holistic view of spatial relationships within the tunnel.Furthermore,purely virtual simulations often fail to accurately capture the complex,dynamic,and unscripted characteristics of the actual construction environment.To address these significant limitations,this paper reports a novel simulation method based on in situ virtual-real interaction,designed to provide real-time,high-precision risk early warning and decision support specifically during shield-machine station traversal.[Method]First,multisource design data of the shield machine were fused with on-site sensing information to construct high-fidelity,drivable virtual models of the shield machine and the construction environment using lightweight processing techniques and multilevel-of-detail modeling.These models were subsequently optimized for real-time rendering.Second,a robust markerless three-dimensional registration algorithm based on mixed reality technology was applied.This enabled high-precision spatial alignment of the virtual models with the physical environment without requiring intrusive physical markers,thereby ensuring dynamic synchronization of virtual and real scenes.To further enhance accuracy,the system integrated multisource data,including inertial measurements,inclination sensing,and guidance system inputs.By incorporating these inputs into an extended Kalman filter,the system obtained a stable,real-time solution for the six-degrees-of-freedom pose and motion simulation of the shield machine,effectively mitigating sensor drift.Simultaneously,a comprehensive collision-detection mechanism was established using the Unity physics engine.By implementing a mixed configuration of rigid bodies and triggers,the system achieved real-time interference identification for static and dynamic obstacles,facilitating multimodal warning feedback and forming a closed-loop system encompassing perception,simulation,and early warning.[Result]The proposed system was subjected to rigorous field validation in an actual engineering project at the Beijing Pinggu metro station.The results demonstrated that the system achieved a virtual-real spatial registration accuracy of±4.5 mm within a 30 m test section.The core collision-detection latency was<6 ms,and the rendering frame rate remained stable at 45 fps,ensuring a smooth visual experience for operators and excellent real-time stability.In diverse complex scenarios,including static obstacles,unpredictable dynamic personnel intrusions,and cluttered temporary facilities,the system consistently triggered real-time highlighting warnings for collision zones.[Conclusion]Compared with conventional manual measurement methods,this approach significantly improved inspection efficiency,effectively enhancing risk-identification accuracy and real-time responsiveness.Furthermore,it substantially mitigated personnel safety risks and potential economic losses associated with equipment collisions and project delays.The simulation method based on in situ virtual-real interaction proposed in this paper overcomes the real-time and precision limitations of conventional techniques.By enabling proactive identification and immediate warning of potential collision risks,it transforms risk management from a lagging,passive mode into a proactive one characterized by risk anticipation and intervention.Ultimately,this approach significantly enhances construction safety and economic efficiency while providing a reliable technical pathway and decision-making basis for advancing intelligent risk management and digital twin applications in complex underground engineering projects.

赵雪锋;张睿;樊雄涛;郭飞;晏文凯

北京工业大学智能建造与工程管理研究所,北京 100124北京工业大学智能建造与工程管理研究所,北京 100124北京工业大学智能建造与工程管理研究所,北京 100124北京市政建设集团有限责任公司,北京 100089北京工业大学智能建造与工程管理研究所,北京 100124

建筑与水利

混合现实空推过站原位仿真方法盾构施工

mixed realitycrossing stationin situsimulation methodshield construction

《清华大学学报(自然科学版)》 2026 (5)

898-910,13

教育部人文社科规划基金项目(23YJA630145)北京市政建设集团有限责任公司技术中心科技创新项目(2023-24)

10.16511/j.cnki.qhdxxb.2026.21.001

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