Ứng dụng mô hình nền hardening soil và mohr coulomb trong plaxis 3D mô phỏng tính toán chuyển vị tường vây

Vietnam Institute for Building Science and Technology Pub Date : 2023-06-01 DOI:10.59382/j-ibst.2023.vi.vol2-6

Ngọc Thắng Nguyễn, Văn Thịnh

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Abstract

Diaphragm wall deflection is considered one of the reasons for soil instability around excavation, causing serious consequences for neighboring constructions. Therefore, in the design and calculation of deep excavation, analyzing and simulating the diaphragm wall deflection between phases of excavation construction becomes very important. However, selecting an appropriate mathematical model and determining its input parameters affect the accuracy of the calculation results and their deviation from reality. In this article, the Hardening Soil (HS) model and the Mohr Coulomb (MC) model were used to simulate deflection calculations of diaphragm wall using Plaxis 3D and compared with data obtained from a real project in Ho Chi Minh City. The results showed that the stiffness parameter Eref50 was taken according to the formula Eref50 = 1000N for sandy soil (N: number of SPT blows), Eref50 = 500Su for cohesive soil (Su: undrained soil resistance) in the HS model, resulting in analysis of deflection that was quite compatible with actual data. In addition, the deflection of diaphragm wall varied inversely with its thickness, but this change was relatively small.

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plaxis 3D模拟墙体位移的mohr库伦模型的应用

地下连续墙挠曲被认为是引起基坑周围土体失稳的原因之一，对邻近建筑造成严重后果。因此，在深基坑的设计计算中，分析和模拟连续墙开挖施工各阶段之间的挠度就显得十分重要。然而，选择合适的数学模型和确定其输入参数会影响计算结果的准确性和与实际的偏差。本文采用硬化土(HS)模型和莫尔库仑(MC)模型，利用Plaxis 3D软件对连续墙的挠度进行了模拟计算，并与胡志明市某实际工程数据进行了比较。结果表明，HS模型中刚度参数Eref50的取值公式为:砂土Eref50 = 1000N (N: SPT吹风次数)，粘性土Eref50 = 500Su (Su:不排水土阻力)，挠度分析与实际数据吻合较好。此外，连续墙的挠度随厚度呈反比变化，但这种变化相对较小。

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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Vietnam Institute for Building Science and Technology

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