Dynamic analysis of precast ultra-high performance concrete tunnel under internal explosion

IF 2.1 Q2 ENGINEERING, CIVIL
Viet-Chinh Mai, Ngoc Quang Vu, Van Tu Nguyen, Xuan Dai Nguyen
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引用次数: 0

Abstract

Underground structures hold great significance in the infrastructure of modern society. With the rapid construction of such facilities, the possibility of explosions occurring inside these structures due to unforeseen accidents or deliberate acts cannot be ignored. Past catastrophic events have demonstrated the necessity of implementing anti-blast design for underground structures, particularly in vulnerable locations. This promotes investigations into the behavior of underground structures subjected to internal explosions. For the first time, a thorough simulation model is developed using the multi-material Coupled Eulerian–Lagrangian approach to examine a full-scale precast ultra-high performance concrete (UHPC) tunnel under internal explosion. The precast tunnel structure closely resembles real construction configurations. The simulation model takes into account the simultaneous interaction between the tunnel and the surrounding soil. The accuracy of the suggested simulation model is validated against experimental results. For various explosive charge weights, tunnel lining thicknesses, materials, and tunnel shapes, extensive parametric simulations are conducted. Results obtained highlighted UHPC's superiority as a substitute for conventional concrete due to its strong blast-resistant capacity. The findings from this research also shed light on the precast UHPC tunnel's structural response to an interior explosion, that can assist designers and managers choose the best design for blast protection.
预制超高性能混凝土隧道内爆动力分析
地下建筑在现代社会的基础设施中占有重要地位。随着这些设施的快速建设,由于不可预见的事故或故意行为,这些建筑物内发生爆炸的可能性不容忽视。过去的灾难性事件已经证明了对地下结构进行抗爆设计的必要性,特别是在脆弱的位置。这促进了对地下结构在内部爆炸作用下的行为的研究。首次采用多材料耦合欧拉-拉格朗日方法建立了全尺寸预制超高性能混凝土(UHPC)隧道内爆过程的模拟模型。预制隧道结构与实际施工结构非常相似。该模拟模型考虑了隧道与周围土体的同时相互作用。通过实验结果验证了所建仿真模型的准确性。对于各种炸药装药量、隧道衬砌厚度、材料和隧道形状,进行了广泛的参数模拟。结果表明,超高性能混凝土具有较强的抗爆能力,可替代传统混凝土。本研究结果还揭示了预制超高强度混凝土隧道对内部爆炸的结构响应,可以帮助设计师和管理者选择最佳的防爆设计。
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
CiteScore
4.30
自引率
25.00%
发文量
48
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