Soil structure interaction for shrink-swell soils a new design procedure for foundation slabs on shrink-swell soils

Abdelmalak, Remon Melek

15 May 2009

Problems associated with shrink-swell soils are well known geotechnical problems that have been studied and researched by many geotechnical researchers for many decades. Potentially shrink-swell soils can be found almost anywhere in the world especially in the semi-arid regions of the tropical and temperate climate. Foundation slabs on grade on shrink-swell soils are one of the most efficient and inexpensive solutions for this kind of problematic soil. It is commonly used in residential foundations or any light weight structure on shrink-swell soils. Many design methods have been established for this specific problem such as Building Research Advisory Board (BRAB), Wire Reinforcement Institute (WRI), Post- Tensioning Institute (PTI), and Australian Standards (AS 2870) design methods. This research investigates most of these methods, and then, proposes a moisture diffusion soil volume change model, a soil-weather interaction model, and a soil-structure interaction model. The proposed moisture diffusion soil volume change model starts with proposing a new laboratory test to determine the coefficient of unsaturated diffusivity for intact soils. Then, it introduces the development of a cracked soil diffusion factor, provides a chart for it, and explains a large scale laboratory test that verifies the proposed moisture diffusion soil volume change model. The proposed soil-weather interaction model uses the FAO 56-PM method to simulate a weightless cover performance for six cities in the US that suffer significantly from shallow foundation problems on shrink-swell soils due to seasonal weather variations. These simulations provide more accurate weather site-specific parameters such as the range of surface suction variations. The proposed weather-site specific parameters will be input parameters to the soil structure models. The proposed soil-structure interaction model uses Mitchell (1979) equations for moisture diffusion under covered soil to develop a new closed form solution for the soil mound shape under the foundation slab. Then, it presents a parametric study by carrying out several 2D finite elements plane strain simulations for plates resting on a semiinfinite elastic continuum and resting on different soil mounds. The parametric study outcomes are then presented in design charts that end with a new design procedure for foundation slabs on shrink-swell soils. Finally, based on the developed weather-soil-structure interaction models, this research details two procedures of a proposed new design method for foundation slabs on grade on shrink-swell soils: a suction based design procedure and a water content based design procedure.

SHRINK-SWELL SOILS

SOIL STRUCTURE INTERACTION

SHALLOW FOUNDATION

BEARING CAPACITY OF SHALLOW FOUNDATION USING GEOGRID REINFORCED DOUBLE LAYERED SOIL

Tiwari, Dipak

01 December 2011

Since the last three decades, several studies have been conducted related to improvement in bearing capacity of pavements, embankments, and shallow foundations resting on geosynthetic reinforced soil. Most of the work has been carried out on single layer soil e.g., sand or clay layer only. Very few studies are available on a double layer soil system; but no study is available on the local soil of Carbondale, Illinois. The present study investigates the physical and engineering properties of a local soil and commonly available sand and improvement in the bearing capacity of a local soil for a rectangular footing by replacing top of the local soil with sand layer and placing geogrids at different depths. Seven tests on the model footing were performed to establish the load versus settlement curves of unreinforced and reinforced soil supporting a rectangular foundation. The improvement in bearing capacity is compared with the bearing capacity of the local soil and double layer unreinforced soil system. The test results focus on the improvement in bearing capacity of local soil and double layer unreinforced soil system in non-dimensional form i.e., BCR (Bearing Capacity Ratio). The results obtained from the present study show that bearing capacity increases significantly with the increasing number of geogrid layers. The bearing capacity for double layer soil increases, by placing three inch sand layer at the top of local soil, was not significant. The bearing capacity of the local soil increased at an average of 7% with three inches sand layer. The bearing capacity for the double layer soil increases with an average of 16.67% using one geogrid layer at interface of soils (i.e., local soil and sand) with u/B equal to 0.67. The bearing capacity for the double layer soil increases with an average of 33.33% while using one geogrid in middle of sand layer having u/B equal to 0.33. The improvement in bearing capacity for double layer soil maintaining u/B equal to 0.33 and h/B equal to 0.33; for two, three and four number geogrid layer were 44.44%, 61.11%, 72.22%, respectively. The results obtained from this research work may be useful for the specific condition or similar type of soil available anywhere to improve the bearing capacity of soil for foundation and pavement design.

Bearing capacity

Biaxial geogrid

Double layered soil

Shallow Foundation

Shallow foundation systems response to blast loading

Gamber, Nathan K.

January 2004

No description available.

Engineering, Civil

Shallow Foundation Systems

System Response

Blast Loading

Návrh založení dálničního mostu / The Design of Highway Bridge Foundations

Králík, Michal

January 2019

Topic of this master`s thesis is founding of the hightway bridge, which is located between Lipník and Bělotín. Thesis is aimed for creating shallow foundation and foundation on piles and choosing which option is better. All evaluations have been made without specialized software and than compared with GEO5 results. Better solution will be completed with procedure for construction and drawing documentation.

Scale Model Shake Table Testing of Shallow Embedded Foundations in Soft Clay

Kuo, Steven

01 August 2012

This research involves shake table testing of 1g scale models that mimic the coupled seismic response of a structure on a shallow mat foundation and foundation soil (known as soil-foundation-structural-interaction or SFSI). In previous research, SFSI effects have been quantified through analytical models, numerical analyses, and limited field data. This research works towards increasing the amount of empirical data through scale model shake table testing. A suite of earthquake time histories is considered in evaluating a nominal 10th scale soil-structure model using a flexible wall barrel on a 1-D shake table. San Francisco Young Bay Mud (YBM) is used as the prototype soil and long period narrow building as the prototype structure. Foundation embedment depth, fundamental mode of the structure, and seismic loading function are varied to generate a large database of SFSI results under controlled conditions. The foundation level response is compared to free-field responses to determine the magnitude of the SFSI. The results confirm the effects of foundation embedment on the peak ground motion and the spectral acceleration at the predominant period of the structure. The foundation level accelerations are deamplified compared to free-field results. Results also confirm the legitimacy of the testing platform and program by comparing the data to previous experimental study.

Shake Table

Soil-structure-interaction

shallow foundation

seismic

earthquake

clay

embedment

Geotechnical Engineering

Building a framework for predicting the settlements of shallow foundations on granular soils using dynamically measured soil properties

Kacar, Onur

27 June 2014

In this dissertation, the framework is being developed for a new method to predict the settlements of shallow foundations on granular soil based on field seismic and laboratory dynamic tests. The new method combines small-strain seismic measurements in the field with nonlinear measurements in the field and/or in the laboratory. The small-strain shear modulus (Gmax ) of granular soil and the stress dependency of Gmax is determined from the shear wave velocity measurements in the field. Normalized shear modulus (G/Gmax ) versus log shear strain(log [gamma]) curves are determined from field or laboratory measurements or from empirical relationships. The G/Gmax -- log [gamma] curves and Gmax values are combined to determine the shear stress-shear strain response of granular soil starting from strains of 0.0001% up to 0.2-0.5%. The shear stress-shear strain responses at strains beyond 1.0-2.0 % are evaluated by adjusting the normalized shear modulus curves to larger-strain triaxial test data. A user defined soil model (MoDaMP) combines these relationships and incorporates the effect of increasing confining pressure during foundation loading. The MoDaMP is implemented in a finite element program, PLAXIS, via a subroutine. Measured settlements from load-settlement tests at three different sites where field seismic and laboratory dynamic measurements are available, are compared with the predicted settlements using MoDaMP. Predictions with MoDaMP are also compared with predictions with two commonly used methods based on Standard Penetration and Cone Penetration tests. The comparison of the predicted settlements with the measured settlements show that the new method developed in this research works well in working stress ranges. The capability of the new method has significant benefits in hard-to-sample soils such as in large-grained soils with cobbles and cemented soils where conventional penetration test methods fail to capture the behavior of the soil. The new method is an effective-stress analysis which has applicability to slower-draining soils such as plastic silts and clays. / text

Small-strain

Seismic measurements

Dynamic laboratory test

Shallow foundation

Settlement

Granular soil

Finite element

Dynamic soil properties

Numerical Methods in Offshore Geotechnics: Applications to Submarine Landslides and Anchor Plates

Nouri, Hamid Reza

03 October 2013

The emphasis of this dissertation is on using numerical and plasticity based methods to study two main areas of offshore geotechnics. The first part of this dissertation focuses on the undrained behavior of deeply embedded anchor plates under combined shear and torsion. Plate anchors are increasingly being used instead of typical foundation systems to anchor offshore floating platforms to sustain uplift operating forces. However extreme loading cases would create general loading conditions involving six degrees of freedom. The focus of my research was to evaluate the bearing capacity of plate anchors under two-way horizontal and torsional loading and to study the decreasing effect of torsional moment on the horizontal bearing capacity of these foundations. The study takes advantage of several approaches: Numerical simulation (two and three dimensional finite element analysis) Evaluating and modification of the available plasticity solutions Developing equations for three degree-of-freedom yield locus surfaces The same methodology is applied to evaluate the response of shallow foundations for subsea infrastructure subjected to significant eccentric horizontal loads. The second part of this study focuses on offshore geohazards. Coastal communities and the offshore industry can be impacted directly by geohazards, such as submarine slope failures, or by tsunamis generated by the failed mass movements. This study aims at evaluating the triggering mechanisms of submarine landslide under cyclic wave and earthquake loading. A simple effective stress elasto-plastic model with a minimal number of parameters accounting for monotonic and cyclic response of fine-grained material is developed. The new constitutive soil model could be used to simulate case histories and conduct parametric study to evaluate the effect of slope inclination angle, the earthquake loading with different PGA, frequency content, and duration, as well as various deposition rates to simulate different over pressure levels. This study will generate more insight on the static and cyclic behavior of submarine slopes and influencing factors on their triggering mechanisms using more comprehensive and realistic modeling tools. Several objectives are defined: Developing an appropriate constitutive formulation, Evaluating the constitutive model and material parameters for available databases.

offshore geotechnics

plate anchors

shallow foundation

bearing capacity

offshore geohazards

submarine landslide

constitutive modelling

cyclic and monotonic loading

clays

[es] CONFIABILIDAD Y PROBABILIDAD EN GEOTECNIA DE FUNDACIONES SUPERFICIALES / [pt] CONFIABILIDADE E PROBABILIDADE EM GEOTECNIA DE FUNDAÇÕES SUPERFICIAIS / [en] CONFIABILITY AND PROBABILITY IN GEOTECHNICS OF SHALLOW FOUNDATION

ROMULO CASTELLO HENRIQUES RIBEIRO

30 July 2001

[pt] O interesse por análises de confiabilidade em geotecnia tem aumentado muito nos últimos anos. Métodos probabilísticos tem sido utilizados com o objetivo de racionalizar a quantificação das incertezas existentes na geotecnia. Neste âmbito, o presente trabalho apresenta um resumo com os conceitos básicos de probabilidade necessários para a compreensão do assunto. Desenvolve-se o Método do Segundo Momento de Primeira Ordem para quantificação da confiabilidade inerente ao desempenho de fundações. Metodologias são propostas para racionalizar a adoção de fatores de segurança quanto à ruptura de fundações superficiais e quantificar o risco associado à probabilidade do recalque estimado ser superior ao recalque admissível. Os exemplos de cálculo são apresentados com base no desempenho de fundações protótipo submetidas a provas de carga superficiais executadas no campo experimental 1 da PUC-Rio. / [en] The interest for reliability analysis in geotechnical engineering has been growing up in the last two decades. Probabilistic methods are generally used as a way of rationalizing the analysis of the uncertainties presents in the geotechnical properties. The First Order Second Moment method (FOSM) was applied in order to quantify the reliability of foundations. A methodology is proposed for quantifying the probability of faylure of shallow foundations and also the probability of settlements larger than the allowable design value. Example calculations are presented with basis on the results of prototype footings tested in the experimental research site at PUC-Rio. / [es] EL interés por análisis de confiabilidad en geotecnia ha aumentado mucho en los últimos años. Métodos probabilísticos han sido utilizados con el objetivo de racionalizar la cuantificación de las incertezas que existen en la geotecnia. En este ámbito, el presente trabajo presenta un resumen de los conceptos básicos de las probabilidades, necesarios para la comprensión del asunto. Se desarrolla el Método del Segundo Momento de Primer Orden para cuantificar la confiabilidad inherente al desempeño de fundaciones. Se proponen metodologías para racionalizar la adopción de factores de seguridad y cuantificar el riesgo asociado a la probabilidad de que el recalco estimado sea superior al recalco admisible. Los ejemplos de cálculo presentados tienen como base el desempeño de fundaciones prototipos, sometidas a pruebas de carga superficiales, ejecutadas en el campo experimental 1 de la PUC-Rio.

[pt] RECALQUE

[pt] CAPACIDADE DE SUPORTE

[pt] METODOS PROBABILISTICOS

[pt] FUNDACAO SUPERFICIAL

[en] SETTLEMENT

[en] BEARING CAPACITY

[en] PROBABILISTIC METHODS

[en] SHALLOW FOUNDATION

[es] RECALQUES

Three-dimensional physical and numerical modelling of jack-up structures on sand

Bienen, Britta

January 2007

Mobile offshore jack-up drilling rigs are not custom-designed for a particular location but rated for typical operating characteristics, like water depths. They may be deployed at a number of different sites during their design life. Under the current guidelines, the jack-up is required to be assessed for its suitability for each new proposed location, assuming environmental loading conditions due to wind, waves and current corresponding to a 50-year return period storm applicable to the site. Traditionally, these assessments have been performed in two dimensions, simplifying the jack-up to a plane frame and the loading conditions to be in-plane with the rig's 'axis of symmetry'. This thesis introduces a computer program, named SOS_3D, for the fluid-structure-soil interaction analysis of jack-up response in three dimensions. Extensive experimental series have been performed to provide evidence for the generalisation of the foundationsoil interaction model to general six degree-of-freedom loading conditions and its applicability to load paths and stress levels relevant to jack-up spudcans. These experiments included (1) 1g single footing tests, (2) centrifuge single footing tests and (3) centrifuge model jack-up tests. The latter tests highlighted differences in response and mode of failure depending on the loading direction of the jack-up and re-iterated the importance of three-dimensional modelling. The numerical program SOS_3D introduced early in this thesis was shown to represent a useful tool for the prediction of jack-up behaviour under general combined loading in three dimensions. It provided reasonably good, conservative predictions of the experimentally measured jack-up behaviour.

Jackup rigs -- Computer simulation

Engineering geology

Soil mechanics -- Mathematical models

Sand -- Testing -- Mathematical models

Shallow foundation

Fluid-structure-soil interaction

Numerical modelling and analysis

Combined loading

Physical modelling

Založení nové a sanované podpěry "Starého mostu" přes Dunaj v Bratislavě / Foundation of new and redeveloped supports "Old Bridge" over the Danube in Bratislava

Korec, Michael

January 2015

The thesis is focused on the reconnstruction of the "Old Bridge“ in Bratislava. Part of the reconstruction is the foundations of a new pier and redevelopment of an existing pier. The introduction provides an overview of methods used for the foundations within the river and from there onwards, the most suitable method haas been selected. The piers foundation is designed in several variants, coupled with the drawings. In conclusion, the variants were compared and the most suitable one was selected.