Liquefaction of Silty Soils
Author : Desmond Charles Arthur Andrews
Publisher :
Page : 406 pages
File Size : 50,14 MB
Release : 1997
Category : Clay soils
ISBN :
State of the Art and Practice in the Assessment of Earthquake-Induced Soil Liquefaction and Its Consequences
Author : National Academies of Sciences, Engineering, and Medicine
Publisher :
Page : 350 pages
File Size : 44,86 MB
Release : 2019-01-30
Category :
ISBN : 9780309440271
Book Description
Earthquake-induced soil liquefaction (liquefaction) is a leading cause of earthquake damage worldwide. Liquefaction is often described in the literature as the phenomena of seismic generation of excess porewater pressures and consequent softening of granular soils. Many regions in the United States have been witness to liquefaction and its consequences, not just those in the west that people associate with earthquake hazards. Past damage and destruction caused by liquefaction underline the importance of accurate assessments of where liquefaction is likely and of what the consequences of liquefaction may be. Such assessments are needed to protect life and safety and to mitigate economic, environmental, and societal impacts of liquefaction in a cost-effective manner. Assessment methods exist, but methods to assess the potential for liquefaction triggering are more mature than are those to predict liquefaction consequences, and the earthquake engineering community wrestles with the differences among the various assessment methods for both liquefaction triggering and consequences. State of the Art and Practice in the Assessment of Earthquake-Induced Soil Liquefaction and Its Consequences evaluates these various methods, focusing on those developed within the past 20 years, and recommends strategies to minimize uncertainties in the short term and to develop improved methods to assess liquefaction and its consequences in the long term. This report represents a first attempt within the geotechnical earthquake engineering community to consider, in such a manner, the various methods to assess liquefaction consequences.
Liquefaction Mitigation of Silty Soils Using Dynamic Compaction
Author :
Publisher :
Page : 319 pages
File Size : 36,26 MB
Release : 2006
Category :
ISBN :
Book Description
Liquefaction of saturated loose granular sand and non-plastic silty sand deposits during seismic loading has caused significant damage to structures and highway systems in almost all major earthquakes. Sand deposits densified by dynamic compaction (DC) are more resistant to liquefaction, and have performed well during earthquakes. Silty sand deposits appear to densify and perform well when improved by DC supplemented with wick drains. current practice for evaluating feasibility and choosing the operational parameters of the DC technique at a site depends mainly on field trials, past experience at similar sites, and empirical equations based on reported records. Rational analytical methods are needed to improve the state of practice. This dissertation presents an analytical simulation model for the densification process of saturated sand deposits without wick drains, and silty deposits supplemented with wick drains during DC. Pore pressure generated during DC processes is simulated based on an energy based liquefaction model. The densification during dissipation is modeled using consolidation theory. Based on the model effects of silt content, hydraulic conductivity, initial soil density and techniques' operational parameters such as energy per impact, number of impacts per location, impact grid pattern, impact grid spacing, wick drains spacing, and time cycle between impacts on the densification of soils improved by DC have been studied. The model performance has also been verified through documented case histories and found to compare reasonably well. A rational design procedure has been developed for liquefaction mitigation of loose sand and non-plastic silty soils. The design model has been used to determine the densification achievable using DC in silty deposits supplemented with wick drains. A design procedure and design examples are presented. The computational methodology presented herein is a powerful tool for design analyses of DC taking into account the site conditions for different deposits and operational parameters. The model is expected to advance the use of DC in sands and silty soils, and reduce the reliance on expensive field trials as a design tool.
Liquefaction Criteria for Silty Soils
Author : Sukhmander Singh
Publisher :
Page : 8 pages
File Size : 47,65 MB
Release : 1983
Category : Soil liquefaction
ISBN :
Book Description
Geotechnics for Sustainable Infrastructure Development
Author : Phung Duc Long
Publisher : Springer Nature
Page : 1417 pages
File Size : 11,99 MB
Release : 2019-11-28
Category : Science
ISBN : 9811521840
Book Description
This book presents 09 keynote and invited lectures and 177 technical papers from the 4th International Conference on Geotechnics for Sustainable Infrastructure Development, held on 28-29 Nov 2019 in Hanoi, Vietnam. The papers come from 35 countries of the five different continents, and are grouped in six conference themes: 1) Deep Foundations; 2) Tunnelling and Underground Spaces; 3) Ground Improvement; 4) Landslide and Erosion; 5) Geotechnical Modelling and Monitoring; and 6) Coastal Foundation Engineering. The keynote lectures are devoted by Prof. Harry Poulos (Australia), Prof. Adam Bezuijen (Belgium), Prof. Delwyn Fredlund (Canada), Prof. Lidija Zdravkovic (UK), Prof. Masaki Kitazume (Japan), and Prof. Mark Randolph (Australia). Four invited lectures are given by Prof. Charles Ng, ISSMGE President, Prof.Eun Chul Shin, ISSMGE Vice-President for Asia, Prof. Norikazu Shimizu (Japan), and Dr.Kenji Mori (Japan).
Earthquake Geotechnical Engineering
Author : Kyriazis D. Pitilakis
Publisher : Springer Science & Business Media
Page : 497 pages
File Size : 44,97 MB
Release : 2007-06-14
Category : Technology & Engineering
ISBN : 1402058926
Book Description
This book contains the full papers on which the invited lectures of the 4th International Conference on Geotechnical Earthquake Engineering (4ICEGE) were based. The conference was held in Thessaloniki, Greece, from 25 to 28 June, 2007. The papers offer a comprehensive overview of the progress achieved in soil dynamics and geotechnical earthquake engineering, examine ongoing and unresolved issues, and discuss ideas for the future.
Liquefaction Remediation in Silty Soils Using Dynamic Compaction and Stone Columns
Author : S. Thevanayagam
Publisher :
Page : 122 pages
File Size : 18,60 MB
Release : 2006
Category : Soil liquefaction
ISBN :
Book Description
Soil Liquefaction
Author : Michael Jefferies
Publisher : CRC Press
Page : 625 pages
File Size : 36,72 MB
Release : 2006-09-04
Category : Science
ISBN : 020330196X
Book Description
Soil liquefaction is a major concern in areas of the world subject to seismic activity or other repeated vibration loads. This book brings together a large body of information on the topic, and presents it within a unified and simple framework. The result is a book which will provide the practising civil engineer with a very sound understanding of
Advances in Soil Liquefaction Engineering
Author : Yoshimichi Tsukamoto
Publisher : Springer Nature
Page : 195 pages
File Size : 39,4 MB
Release : 2022-01-20
Category : Science
ISBN : 981155479X
Book Description
This book describes recent developments in soil liquefaction engineering and introduces more appropriate procedures than the current ones to evaluate triggering and consequences of soil liquefaction during earthquakes. The topics therefore cover all aspects of soil behaviour following liquefaction during earthquakes. The contents start with new approaches and new findings on characterisation of liquefaction resistance and undrained shear strength of fully saturated, partially saturated, and unsaturated sand, which are fully based on laboratory tests. New approaches and findings are then described on the use of in situ sounding tests for characterising triggering and consequences of soil liquefaction, including post-liquefaction settlement, lateral spreading, and stability against flow slide. All the topics are accompanied by illustrative case history data from recent major earthquakes in Japan.
Liquefaction Mitigation in Silty Soils Using Stone Columns Supplemented with Wick Drains
Author :
Publisher :
Page : 365 pages
File Size : 29,61 MB
Release : 2006
Category :
ISBN :
Book Description
Vibro replacement stone columns are in use to mitigate liquefaction hazards in sandy soils for almost three decades. There are three mechanisms that help reduce liquefaction potential of a sandy soil improved using stone columns. During stone column installation sandy soils densify due to installation vibration. Further, the stiffness of the composite improved soil increases leading to a reduction in cyclic shear stress induced on the soil surrounding the stone columns during earthquakes. In addition, pore pressures generated in the soil during earthquakes are quickly dissipated through the highly permeable stone columns. These combined mechanisms reduce the liquefaction potential of the improved soil. Sandy soil sites improved using stone columns have performed well during earthquakes. However, its effectiveness in silty soils is limited. Recent case histories show stone columns supplemented with wick drains work well in such soils. This study focuses on three aspects: (i) examining the reasons for the sub-performance of stone columns in silty soils, identifying key soil parameters that hinder the effectiveness of stone columns, and developing means to improve the effectiveness of this method in silty soils including provision of supplementary wick drains, (ii) developing a numerical model to simulate stone column installation with and without wick drains, and qualitatively evaluate the degree of ground improvement, and (iii) verifying the numerical simulation results using case histories and field experimental studies, and developing modified design charts and guidelines for designing stone columns with and without wick drains to improve sands and silty soils. Pore pressure generation, post-liquefaction dissipation, and densification characteristics of an artificial silty soil and three natural silty soils were experimentally studied and compared with sand. A careful analysis of such data indicates that liquefaction characteristics of silty soils and sands are not very different when compared using grain contact density indices as the basis for comparison. However, post-liquefaction dissipation characteristics are very much dependent on grain size characteristics. Low coefficient of consolidation associated with silty soils precludes faster pore pressure dissipation during stone column installation and therefore hinders densification around the stone columns during installation. It also hinders drainage during earthquakes. This appears to be the primary reason for the lack of effectiveness of stone columns in silty soils. Numerical studies of pore pressure behavior of silty and sandy soils support this view. Based on the experimental results, a numerical model was developed to simulate the stone column installation process. During installation, pore pressure generated due to the vibratory energy imparted into the surrounding ground was estimated, and the ground densification associated with pore pressure dissipation was calculated. Several simulations were done for sands and silty soils with varying initial conditions improved using stone columns with and without wick drains. The model was fine tuned and tested using case studies and field measurements. Design charts and design guidelines that were developed based on the extensive experimental and numerical study are presented. Recommendations for improving the stone column design methodology, and for further research in this subject are presented as well.
