Simulation of Progressive Shear Failure in Railway Foundation

Li, Xu Dong

24 November 2020

Railways are one of the largest transportation networks in the world that play an important role in the mass transportation of both the passengers and freight. The speed of trains and as well as the axial load carrying capacity have been increasing significantly during the past few decades to keep in pace with the population and economy growth and to compete with other modes of transportation such as the road, air and water transportation system. Billions of dollars are spent annually for maintenance of rail tracks in the world. The efficient and optimum use of these funds is a challenging task that demands innovative and cutting edge technologies in railway engineering. The railway subgrade is an important part of railway foundation and should be capable of providing a suitable base supporting the ballast and subballast to accommodate the stresses due to traffic loads without failure or excessive deformation. The progressive shear failure is a well-known and age old challenging problem for railways over the world for centuries. The subgrade of railway track which typically constitutes of fine-grained material tends to fail through the accumulation of soil movements up- and sideward developing a path for the least resistance along which progressive shear failure occurs under repeated train-induced loads and due to the effects of climate factors. To-date, limited number of studies have addressed failure mechanism associated with the progressive shear failure, especially using the mechanics of unsaturated soils. In this thesis, a novel and first of its kind, Visual Basic program developed in AutoCAD environment based on Mohr-Coulomb failure criteria and unsaturated soil mechanics theory. This program is capable of taking account of the influence of matric suction and simulate progressive shear failure in the subgrade under moving train. Simulation results suggest several parameters that include stress distribution, matric suction, cohesion, coefficient of lateral earth pressure at rest, and coefficient of residual friction as well as the angle of internal friction have a significant effect on the progressive shear failure and the shape of failure planes in the subgrade. The progressive shear failure in subgrade can be reduced by increasing matric suction, cohesion, coefficient of lateral earth pressure at rest, and coefficient of residual friction as well as the angle of internal friction, and optimizing combination of these parameters. The simulation results suggest the progressive shear failure can be well simulated with the Mohr-Coulomb failure criteria. Several suggestions are made for railway subgrade construction and maintenance based on the results of this study.

Railway Subgrade

Mohr-Coulomb Failure Criteria

Visual Basic for AutoCAD (VBA)

Progressive Shear Failure

Matric Suction

STRENGTH-STIFFNESS CORRELATIONS FOR CHEMICALLY TREATED SOILS

Pranavkumar Shivakumar (12535903)

01 June 2022

<p> The central theme of the study is to identify strength-stiffness correlations for chemically treated subgrade soils in Indiana. This was done by conducting Unconfined Compression (UC) tests and resilient modulus tests for soils collected at three different sites, namely : US 31, SR 37 and I-65. At each site, soil samples were obtained from 11 locations at 30 ft spacing. The soils were treated in the laboratory with cement, using the same proportions used for construction, and cured for 7 and 28 days before testing. Results from the UC tests were compared with the resilient modulus results that were available. No direct correlation was found between resilient modulus and UCS parameters for the soils investigated in this study. A brief statistical analysis of the results was conducted, and a simple linear regression model involving the soil characteristics (plasticity index, optimum moisture content and maximum dry density) along with UCS and resilient modulus parameters was proposed.  </p>

Civil geotechnical engineering

resilient modulus

Unconfined Compressive strength

Subgrade soils.

treated soils

Remediation Methods for Subgrade Settlements of Existing Roadways: Lifetime Cost-Benefit Analysis

Arens, Kevin C.

January 2019

No description available.

Civil Engineering

Geotechnology

Transportation

Roadway settlement

ground improvement

roadway cost-benefit

geotechnical

subgrade

Analysis of Vertical Column Support Systems for Stabilization of Roadway Subgrade Settlements

Salveter, Mark

January 2019

No description available.

Civil Engineering

vertical column support systems

roadway stabilization

subgrade settlement

ground improvement

deep foundations

Early performance of concrete pavement containing ground granulated blast furnace slag

Boltz, Daniel Edward

January 1998

No description available.

Engineering, Civil

Strain Measurement

Temperature Measurement

Subgrade Moisture Measurement

Slab Shape

Development of a constitutive model for resilient modulus of cohesive soils

Kim, Dong-Gyou

04 March 2004

No description available.

Engineering, Civil

resilient modulus

constitutive model

subgrade

cohesive

soil

moisture content

Evaluation of Laboratory Durability Tests for Stabilized Subgrade Soils

Parker, John Wesley

17 May 2008

The Portland Cement Association commissioned a research project at Brigham Young University to compare selected laboratory durability tests available for assessing stabilized subgrade materials. Improved understanding of these tests is needed to enable more objective selection of durability tests by design engineers and to facilitate more meaningful comparisons of data obtained for different stabilizer treatments using different evaluation procedures. The laboratory research associated with this project involved two subgrade materials, four stabilizers at three concentrations each, and three durability tests in a full-factorial experimental design. The two subgrade soils used were a silty sand and a lean clay, while the four stabilizer types included Class C fly ash, lime-fly ash, lime, and Type I/II portland cement. The three tests used in this comparative study were the freeze-thaw test, the vacuum saturation test, and the tube suction test. On average, to achieve the same 7-day unconfined compressive strength (UCS) values, the sand required 4.4 times more Class C fly ash than cement, 3.6 times more lime-fly ash than cement, and 6.0 times more lime than cement. Likewise, the clay required 10 times more Class C fly ash than cement, 7.5 times more lime-fly ash than cement, and 1.8 times more lime than cement. Analyses of the test results indicated that the UCS and retained UCS were higher for specimens tested by vacuum saturation than the corresponding values associated with freeze-thaw cycling. This observation suggests that the freeze-thaw test is more severe than the vacuum saturation test for these particular fine-grained materials. Testing also suggested that specimens with 7-day UCS values below 200 psi will generally not survive freeze-thaw cycling. After both freeze-thaw and vacuum saturation testing, the sand specimens treated with lime-fly ash had significantly higher UCS and retained UCS than specimens treated with Class C fly ash, lime, or cement. Similarly, the clay specimens treated with Class C fly ash or lime-fly ash had significantly higher UCS values than specimens treated with cement or lime; however, clay specimens treated with Class C fly ash and lime-fly ash were not significantly different. None of the four stabilizer types were significantly different from each other with respect to retained UCS after vacuum saturation testing. Dielectric values measured in tube suction testing were lowest for specimens treated with lime-fly ash and cement with respect to the sand and for specimens treated with Class C fly ash and cement with respect to the clay. The lime-fly ash and cement successfully reduced the dielectric value of sand specimens to a "marginal" rating, while no stabilizer reduced the moisture susceptibility of the clay to a satisfactory level. A strong correlation was identified between UCS after the freeze-thaw test and UCS after the vacuum saturation test, while very weak correlations were observed between the final dielectric value after tube suction testing and all other response variables. Differences in variability between test results were determined to be statistically insignificant in an analysis of the CVs associated with data collected in this research. Although the freeze-thaw test utilized in this research was determined to be more severe than the vacuum saturation test for materials similar to those tested in this study, the vacuum saturation test is recommended over both the freeze-thaw and tube suction tests because of the shorter test duration, usability for specimens with 7-day UCS values even below 200 psi, and lack of a need for daily specimen monitoring.

freeze-thaw

vacuum saturation

tube suction

subgrade

silt

clay

fly ash

lime-fly ash

lime

cement

stabilization

stabilizer

durability

cold regions engineering

road subgrade

frost heave

Civil and Environmental Engineering

Incorporating Chemical Stabilization of the Subgrade in Pavement Design andConstruction Practices

Al-Jhayyish, Anwer K.

22 September 2014

No description available.

Civil Engineering

Transportation

Soil Stabilization

Incorporate

Subgrade Stabilization

Pavement Design

Construction Practices

MEPDG

AASHTO 1993

Finite Element Model

Dynamic Cone Pentrometer

DCP

Falling Weight Deflectometer

FWD

Backcalculation

Subgrade Modulus

Contribuições ao estudo do comportamento mecânico de solos de subleito para fins de projeto de pavimentos asfálticos. / Contributions to the study of the mechanical behavior of subase soils for the design of asphalt pavement structures.

Ferri, Santi

20 March 2018

O comportamento mecânico do subleito tem influência determinante no desempenho das estruturas de pavimento. Porém, muitas vezes, os estudos realizados para elaboração de projetos são simplistas e não levam em conta as variações de comportamento mecânico que podem ocorrer, seja por fatores construtivos, seja ambientais, como umidade, durante o período de operação. Neste sentido, métodos de dimensionamento mecanicistas-empíricos de estruturas de pavimentos empregam modelos de comportamento das diversas camadas da estrutura e do subleito, sendo alvos de constantes revisões para recalibração destes modelos, de modo que se aproximem mais da realidade do comportamento em serviço. As calibrações dos modelos são necessárias para aumentar a confiabilidade do dimensionamento de modo a garantir pavimentos mais duráveis, e para otimizar custos de execução e de manutenção ao longo da vida útil das estruturas. Neste contexto o presente trabalho propõe uma metodologia para compreender as propriedades dos solos do subleito e de suas variações, estabelecendo um programa de ensaios de campo e de laboratório, cadastramento, processamento e combinação de resultados de propriedades físicas e mecânicas de solos de subleitos de pavimentos de rodovias existentes. O objetivo final é estabelecer parâmetros de deformabilidade elástica de solos do subleito e sua variabilidade para auxiliar no dimensionamento de novas estruturas de pavimentos e reabilitação das antigas. O trabalho utiliza estudos de casos de pavimentos rodoviários em operação. O primeiro caso foi base para o estabelecimento metodológico de estudo desejável do subleito de um pavimento existente, concebendo modelos de previsão de comportamento resiliente do subleito para uso em futuros projetos de restauração deste pavimento ou para novos projetos em locais com similaridade de ocorrência de solos. Empregando a metodologia estabelecida no primeiro caso, fez-se uma busca minuciosa de dados em vários documentos existentes sobre pavimentos rodoviários de concessionárias do Estado de São Paulo, concebendo-se um banco de dados para análise do subleito destes pavimentos, de modo a ampliar a gama de solos pesquisados. Com resultados de caracterização de solos em laboratório e de deflectometria em campo, além de dados de localização dos pontos estudados em mapas geológicos e pedológicos, dados de precipitação, de terraplenagem, entre outros, pôde-se analisar os dados e identificar a influência de cada elemento na variação do módulo de resiliência dos solos de fundação de pavimentos em serviço. O banco de dados de ensaios laboratoriais de solos de subleito contou com um total de 3.894 registros e de ensaios não destrutivos deflectométricos de campo com um total de 169.525 registros (dados históricos de nove rodovias estaduais diferentes). Dentre as principais conclusões, verificou-se que grande parte dos modelos de correlações existentes na literatura entre parâmetros de propriedades físicas e de resistência (como CBR) de solos com o módulo de resiliência possui aplicação muito restrita, inviabilizando sua aplicação de forma indiscriminada em locais distintos daqueles onde foram obtidas as correlações. Além disso, verificou-se que o módulo de resiliência do subleito em campo apresenta variações de grande magnitude e, portanto, é de difícil previsão, requerendo acumulação de dados históricos, bem como de um cadastro adicional de maior gama de informações. Recomenda-se que maiores quantidades de ensaios sejam realizadas e que permitam verificação, ou dupla checagem, para validação, bem como para futuramente ser possível o estabelecimento de modelos matemáticos mais confiáveis. Nos estudos, foi possível estabelecer parâmetros estatísticos que podem ser utilizados tanto em métodos de dimensionamento vigentes ou novos, como naquelas que consideram as variações do módulo de resiliência do subleito para determinação do risco de falha, ou da confiabilidade das estruturas. / Subgrade mechanical behavior has a determining influence on the performance of pavement structures. However, often, the studies carried out for project designs are simplistic and do not take into account the variations that can occur in the mechanical behavior, whether by constructive factors or environmental ones, such as the moisture content during the operation period. Thus, mechanical-empirical design methods of pavement structures employ performance models of the many layers of the structure and of the subgrade, being targets of constant revisions for adjustment of these models so that they come closer to reality in operation behavior. Model adjustments are necessary to increase design reliability to ensure more durable pavements and to optimize execution and maintenance costs during the structure life. In this context, the present work proposes a methodology to understand the subgrade soil properties and their variations, establishing a program of field and laboratory tests, registration, processing and combination of results of physical and mechanical properties of subgrade soils of existing highway pavements. The final objective is to establish parameters of the subgrade soil elastic deformability and their variability to assist in the design of new pavement structures and in the rehabilitation of old ones. This work uses case studies of road pavements in operation. The first case was the basis for the methodological establishment of a desirable study of the subgrade of an existing pavement, designing predictive models of the subgrade resilient behavior for use in future rehabilitation projects of this pavement or for new projects in places with a similar occurrence of soils. By using the methodology established in the first case, a thorough data search was carried out in several existing documents on road pavements of concessionaires in the State of São Paulo, and a database was prepared to analyze the subgrade of such pavements in order to expand the range of soils studied. With the results of soil characterization in the laboratory and by field deflections, in addition to location data of the points studied in geological and pedological maps, precipitation and earthwork data, among others, it was possible to analyze the data and identify the influences of each element on the variation of the subgrade resilient modulus of the pavements in operation. The database from laboratory tests of subgrade soils covered a total of 3,894 registers and of non-destructive deflectometric field tests - a total of 169,525 registers (historical data on nine different state highways). Among the main conclusions, it was verified that most of the correlation models existing in the literature between parameters of physical and mechanical strength properties (like the CBR) of soils with the resilient moduli have very restricted application, making it impossible to apply them indiscriminately in places other than those where the correlations were obtained. In addition, it was verified that the resilient modulus of the subbase in situ presents variations of great magnitude and, therefore, it is difficult to make predictions. Lots of historical data are required, as well as additional registers of a greater range of information. Therefore, it is recommended that a larger number of tests be performed in order to allow for checking and double-checking for validation as well as the possibility of a future establishment of more reliable mathematical models. In the studies, it was possible to establish statistical parameters that can be used both in current and in new design methods, like in those that consider variations of the subgrade resilient moduli to determine the risk of failure or of the reliability of structures.

Asphalt pavements

Módulo de resiliência

Pavement design

Pavement performance

Pavimentos asfálticos

Resilient modulus

Subgrade

Simple Models for Estimating the Rotational Stiffness of Steel Column-to-Footing Connections

Tryon, Joshua Edwin

01 March 2016

Despite the crucial role they play in transferring loads from the superstructure to the foundation, steel column-to-footing connections have received little attention in research. Though shallow embedded connections are typically characterized as pinned, studies have shown that they exhibit significant rotational stiffness. The objective of this thesis is to quantify the rotational stiffness of such connections. A method named the continuum model is developed by which the rotational stiffness of embedded connections may be calculated. Outputs from this model are compared with experimental data on steel connections embedded in concrete. The continuum model is shown to be capable of reasonably predicting the rotational stiffness of such connections. Results from the model were consistent with those of previous experimental studies that showed that embedment lengths greater than twice the column depth fail to significantly increase stiffness. Plots of rotational stiffness vs. embedment length developed from the continuum model are provided such that rotational stiffness may be calculated for any wide flange shape at any embedment length. Simplified equations provide a simpler way for engineers to estimate the same information.

steel column-to-footing connections

stiffness

embedment

beam on elastic foundation

modeling

foundations

modulus of subgrade reaction

Civil and Environmental Engineering