Liquefaction Triggering in Low-Plasticity Silts and Effects of Liquefaction-Induced Lateral Spreading on a Reinforced-Concrete Pile PDF Download

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Category : Geotechnical engineering
Languages : en
Pages : 0

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Liquefaction triggering and post-liquefaction effects on lateral loading of deep foundations is an emerging area of study. This project presents: the results of cyclic direct simple shear (CDSS) testing on a low-plasticity alluvial silt collected in Portland, Oregon; and analysis of the combined effects of liquefaction-induced lateral spreading on a reinforced-concrete pile using data collected from a shake table test. The former research determines the liquefaction susceptibility and post-liquefaction characteristics of a local transitional soil using stress-controlled CDSS testing, the latter explores the complex lateral loading a reinforced-concrete pile undergoes during seismic loading with liquefaction-induced lateral spreading of the ground surface. This project presents the research performed to comment on liquefaction susceptibility and its effects on deep foundations

Author: Liangcai He
Publisher:
ISBN:
Category :
Languages : en
Pages : 886

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Author: Wolfgang Daniel Meyersohn
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Category : Lateral loads
Languages : en
Pages : 322

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Author: John Charles Horne
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Category : Piling (Civil engineering)
Languages : en
Pages : 742

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Author:
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ISBN:
Category :
Languages : en
Pages : 283

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A review of liquefaction-induced lateral spreading and its effects on pile foundations has been presented. A review of currently available methods of analysis for prediction of bending moments and deflections of a single pile subjected to lateral spreading has also been conducted. The methods included in this study are: (a) Deformation method, (b) Japanese Road Association (JRA) method, (c) Limit Equilibrium method, (d) Hybrid force-deformation imposed method, and (e) Finite element method. Numerical analyses were conducted on single piles subjected to lateral spreading, using ABAQUS, based on the first four methods indicated above. The numerical analyses involved three different soil-pile configurations: (a) a two-layer soil profile without a non-liquefiable soil crust, (b) a three-layer soil profile with a non-liquefiable soil crust underlain by liquefiable soil over a dense sand, and (c) a three-layer soil profile like that of case (b) with a lateral deformation constraint at the pile head. The results were compared with a limited number of centrifuge data on single piles. The purpose was to calibrate these methods and assess their ability to capture the measured moment and deflection responses of single piles. The limit equilibrium method and the deformation-imposed method predicted the centrifuge data very well. The JRA method overpredicted both moments and pile deflections by as much as four times. Based on deformation imposed method, parametric analyses were also conducted to study the influence of: (i) the crust thickness, (ii) the liquefied layer thickness, (iii) the non-liquefied bottom layer thickness, (iv) the pile diameter, and (v) the lateral pile head deflection constraint, on pile response subjected to lateral displacements induced by soil liquefaction. The effects of these parameters on single pile response are presented.

Author: Siang Huat Goh
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ISBN:
Category : Piling (Civil engineering)
Languages : en
Pages : 702

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Author: Ahmed Amr Ebeido
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ISBN:
Category :
Languages : en
Pages : 485

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Book Description
Current techniques for assessing the effects of liquefaction-induced lateral spreading on pile foundations are based on simplified analytical methods that potentially lead to estimates that vary within a wide range. This might lead to potential excessive design demands, with high expenses for pre-event mitigation. Conversely, underestimated design demands might lead to costly post-event damage remediation. The conducted study is directed towards enhancements to the assessment of liquefaction induced lateral spreading effects on bridge foundation systems. Current simplified analysis techniques have been only been developed recently in preliminary form. In addition, quantitative data sets from large-scale experimentation are needed concerning the response of such ground-foundation scenarios. An effort was undertaken to address the simplified method areas of applicability and potential for enhancements. Challenges in implementing the methodology are presented within a comparative scope contrasting results of a California bridge site from different studies. On this basis, insights are derived for improvement of the currently employed simplified analysis guidelines. Furthermore, large scale shake table testing was performed on pile foundation-ground systems, under conditions of liquefaction-induced lateral spreading. A total of 7 different experiments were conducted with varying heights, ground inclination, soil profiles, pile material and cross-section. The tested models were densely instrumented, including strain gauges, total pressure and excess pore-pressure sensors, accelerometers and displacement pots. In addition, data from 4 different experiments conducted in the NIED Japan shake table facility, including single piles and pile groups and varying soil profiles were utilized to provide additional insights and characteristics. In these tests, the laminar soil container was placed in a mildly-inclined configuration to allow for accumulation of the liquefaction-induced lateral deformations. Detailed instrumentation and data interpretation procedures enable measurement of the fundamental soil-pile interaction behavior. The loading mechanisms have large cyclic components that may act in-phase or out-of-phase along the pile embedded length. The conducted heavily instrumented tests resulted in a wealth of quantitative response data sets, to be used for: i) drawing insights and recommendations of practical significance based directly on the observed response, ii) calibration of simplified and more elaborate computational analysis tools, and iii) enhancement of our design guidelines and practical assessment procedures. Monotonic pushover analysis based on newly derived p-y curves in this study is found to provide useful design estimates in good agreement with the observed experimental results.

Author: Jose Manuel Ramirez
Publisher:
ISBN: 9781109679922
Category :
Languages : en
Pages : 73

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Pile foundations have been significantly damaged by liquefaction-induced lateral spreading during earthquakes. There are large uncertainties regarding the effects of various soil properties on this pattern of soil-structure interaction. The main concern of this study is to numerically investigate the role of soil permeability in such lateral spreading scenarios. Through extensive calibration, finite element analysis models were developed in which the response reasonably matched experimental data from shake-table testing and centrifuge testing. The overall impact of permeability on the soil stratum and the pile response was similar for both situations. In most cases, soil displacement increased with increasing permeability, while pile load decreased.

Author: John C. Horne
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Category : Bridges
Languages : en
Pages : 146

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Author: Ryan A. Rasanen
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ISBN:
Category : Earthquakes
Languages : en
Pages : 454

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Book Description
Earthquake induced soil liquefaction has been one of the most studied topics in geotechnical engineering over the past 60 years due to its severe impacts on natural and man-made structures. Improving the prediction of liquefaction triggering has already been undertaken for many years, however, in ways that can produce inconsistent, and inaccurate, results in different seismic environments. The first focal point of this thesis is the introduction of a liquefaction-targeted intensity measure that would allow practicing engineers to obtain the benefits of a full probabilistic liquefaction hazard analysis with the same, or less, effort than required by current conventional liquefaction hazard analyses. Lateral spreading is one of the most common, and most severe, effects of liquefaction. Up to three mechanisms are believed to drive lateral spreading. Each of these potential deformation mechanisms is influenced by static shear stresses yet both empirical and semi-empirical procedures for prediction of lateral spreading displacements currently characterize static shear stresses in a crude and incomplete manner. The second focal point of this research was directed toward developing an improved framework for characterizing the initial static shear stresses over a continuous range of site conditions commonly encountered at lateral spreading sites. This framework is intended to lay the foundation for an improved lateral spreading displacement procedure. To accomplish this, numerical analyses were performed to develop a function that can predict the initial static shear stress at depths of lateral spreading interest.