Coupling process controlling data and numerical simulation in mechanised tunnelling

Q4 Earth and Planetary Sciences

Geomechanik und Tunnelbau Pub Date : 2024-06-11 DOI:10.1002/geot.202400011

M.Sc. Yaman Zendaki, Dr.-Ing. Ba-Trung Cao, Dr.-Ing. Janosch Stascheit, Dr.-Ing. Abdullah Alsahly, Prof. Dr.-Ing. Steffen Freitag, Dr.-Ing. Ulrich Maidl, Prof. Dr. techn. Günther Meschke

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Abstract

Nowadays, both process data management and numerical analysis are necessary for decision-making in a tunnel project from its early design stage to the construction phase. Traditional generation of simulation models largely depends on tunnel design and reports, which are error prone due to the involvement of manual intervention. This article presents the application of a digital workflow to efficiently transfer automatically acquired data from tunnel projects to computational simulations. The application workflow is developed and executed through a web-based environment. Project data from the Victory Boogie Woogie tunnel is retrieved from the process controlling software PROCON via web services to generate numerical simulations for settlement predictions at different tunnel sections. The simulated results are validated using real measured settlements in the project to prove the quality of the simulation model. Different scenarios of applying operational steering parameters are then investigated, utilising the simulation model, which can be used to support the on-site engineers as an assistance system to drive the tunnel boring machines. The work has been carried out within the framework of the transfer project T2 of the Collaborative Research Center “Interaction Modeling in Mechanized Tunneling” (SFB 837), which aims to implement and test a digital twin for process control under practical conditions in the tunnelling industry.

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将机械化隧道施工中的过程控制数据与数值模拟结合起来

如今，隧道项目从早期设计阶段到施工阶段的决策都需要过程数据管理和数值分析。传统的模拟模型生成主要依赖于隧道设计和报告，由于涉及人工干预，容易出错。本文介绍了数字化工作流程的应用，可将隧道项目自动获取的数据有效地传输到计算模拟中。应用工作流程是通过网络环境开发和执行的。胜利布吉隧道的项目数据通过网络服务从过程控制软件 PROCON 中获取，以生成不同隧道断面的沉降预测数值模拟。模拟结果通过项目中的实际测量沉降进行验证，以证明模拟模型的质量。然后，利用仿真模型对应用操作转向参数的不同方案进行了研究，仿真模型可作为隧道掘进机的辅助系统，为现场工程师提供支持。这项工作是在合作研究中心 "机械化隧道施工中的交互建模"（SFB 837）的转让项目 T2 框架内进行的，其目的是在隧道施工行业的实际条件下实施和测试用于过程控制的数字孪生系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Geomechanik und Tunnelbau Earth and Planetary Sciences-Geotechnical Engineering and Engineering Geology

CiteScore

1.20

自引率

0.00%

发文量

111

期刊介绍： The contributions published in Geomechanics and Tunnelling deal with practical aspects of applied engineering geology, rock mechanics and rock engineering, soil mechanics and foundation engineering, and primarily tunnelling. Each issue focuses on a current topic or specific project. Brief news, reports from construction sites and news on conferences round off the content. From the start of 2009 Geomechanics and Tunnelling has been published as a bilingual English/German journal.