Critical liquefied soil thickness for response patterns of piles in inclined liquefied ground overlain by nonliquefied crust

IF 4.3 2区 工程技术 Q1 ENGINEERING, CIVIL Earthquake Engineering & Structural Dynamics Pub Date : 2024-07-01 DOI:10.1002/eqe.4190
Jiunn-Shyang Chiou, Yuan-Man Hsu, Cheng-En Ho
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Abstract

Lateral spreading has historically caused extensive pile failure in liquefaction-prone areas during strong earthquakes. A critical design scenario involves piles embedded in lateral spreading ground composed of a nonliquefied soil crust overlying a liquefied layer; it is critical because both layers can exert loads on the piles. Different thicknesses of the liquefied soil and the upper nonliquefied crust may engender different pile response patterns. Accordingly, to investigate factors influencing the lateral responses of a single pile embedded in liquefied ground with a nonliquefied crust, we conduct parametric analyses. The effects of liquefied and nonliquefied soil thicknesses are analyzed first, followed by those of pile-head rotational restraint, pile diameter, and lateral spreading displacement. We observe two main pile response patterns for various liquefied soil thicknesses. The ground can be categorized into thin or thick liquefied ground depending on whether its liquefied soil thickness is less or greater than a critical value, namely, critical liquefied soil thickness; this critical thickness is dependent on the pile-head rotational restraint, pile diameter, and lateral spreading displacement. The difference in the patterns stems from the varying roles of the upper nonliquefied soil layer during lateral spreading. For the thin liquefied ground, the nonliquefied layer contributes to adding lateral spreading force; therefore, the displacement, moment, and shear force responses of the pile increase with the nonliquefied soil thickness. However, for the thick liquefied ground, the nonliquefied layer provides resistance to lateral spreading; therefore, the maximum displacement, moment, and shear force of the pile initially decreases and then gradually increases with the nonliquefied soil thickness.

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非液化地壳覆盖的倾斜液化地层中桩响应模式的临界液化土厚度
历史上,在强地震期间,侧向扩展曾导致易发生液化地区的大量桩基坍塌。一个关键的设计方案是将桩嵌入横向扩展地层中,该地层由覆盖在液化层上的非液化土壳组成;之所以关键,是因为这两层土壳都会对桩施加荷载。不同厚度的液化土层和上层非液化地壳可能会产生不同的桩基响应模式。因此,为了研究影响嵌入液化地层和非液化地壳中的单桩横向响应的因素,我们进行了参数分析。首先分析了液化土和非液化土厚度的影响,然后分析了桩头旋转约束、桩直径和横向扩展位移的影响。对于不同的液化土厚度,我们观察到两种主要的桩基响应模式。根据液化土厚度小于或大于临界值(即临界液化土厚度),地面可分为薄液化地面和厚液化地面;临界厚度取决于桩头旋转约束、桩直径和侧向扩展位移。模式的差异源于上部非液化土层在横向扩展过程中的不同作用。对于较薄的液化地层,非液化层会增加侧向扩展力;因此,桩的位移、力矩和剪力响应会随着非液化土厚度的增加而增加。然而,对于厚液化地层,非液化层提供了横向扩展阻力,因此桩的最大位移、力矩和剪力最初会减小,然后随着非液化土厚度的增加而逐渐增大。
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来源期刊
Earthquake Engineering & Structural Dynamics
Earthquake Engineering & Structural Dynamics 工程技术-工程:地质
CiteScore
7.20
自引率
13.30%
发文量
180
审稿时长
4.8 months
期刊介绍: Earthquake Engineering and Structural Dynamics provides a forum for the publication of papers on several aspects of engineering related to earthquakes. The problems in this field, and their solutions, are international in character and require knowledge of several traditional disciplines; the Journal will reflect this. Papers that may be relevant but do not emphasize earthquake engineering and related structural dynamics are not suitable for the Journal. Relevant topics include the following: ground motions for analysis and design geotechnical earthquake engineering probabilistic and deterministic methods of dynamic analysis experimental behaviour of structures seismic protective systems system identification risk assessment seismic code requirements methods for earthquake-resistant design and retrofit of structures.
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