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引用次数: 18
摘要
在目前的隧道工程实践中,有限元模拟是机械化隧道工程规划和设计阶段不可或缺的组成部分。生成足够的计算模型通常是耗时的,并且需要来自许多不同来源的数据,特别是当使用2D - CAD图纸手动生成时。结合建筑信息模型(BIM)概念,通过使用几何BIM子模型作为结构分析的基础,为简化这一过程提供了机会。本文提出了一个隧道信息模型(TIM),作为一个专门为满足机械化隧道工程需求而量身定制的BIM和“BIM - to - FEM”技术,该技术可以自动从BIM子模型中提取有限元模拟所需的相关信息(地质、路线、衬砌、材料和工艺参数),并随后对隧道驱动进行有限元分析。分析结果集中存储在用户可以连续访问的数据服务器上。本文以德国d塞尔多夫Wehrhahn - Metro线路项目为例,展示了BIM - to - FEM工作流程的有效性和适用性。
Integrated BIM‐to‐FEM approach in mechanised tunnelling
In current tunnelling practice, Finite Element (FE) simulations form an integral element in the planning and the design phase of mechanised tunnelling projects. The generation of adequate computational models is often time consuming and requires data from many different sources, in particular, when manually generated using 2D‐CAD drawings. Incorporating Building Information Modelling (BIM) concepts offers opportunities to simplify this process by using geometrical BIM sub‐models as a basis for structural analyses. This paper presents a Tunnel Information Model (TIM) as a BIM specifically tailored to fit the needs of mechanised tunnelling projects and a ”BIM‐to‐FEM“ technology, that automatically extracts relevant information (geology, alignment, lining, material and process parameters) needed for FE simulations from BIM sub‐models and subsequently performs FE analysis of the tunnel drive. The results of the analysis are stored centrally on a data server to which the user has continuous access. A case study from the Wehrhahn‐Metro line project in Düsseldorf, Germany, is presented and discussed to demonstrate the efficiency and the applicability of the proposed BIM‐to‐FEM workflow.
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