Estudo do comportamento resiliente dos solos tropicais grossos do interior do Estado de São Paulo / Study of resilient behavior of tropical sandy soils from interior of Sao Paulo state

Helio Marcos Fernandes Viana

07 December 2007

O módulo de resiliência é uma propriedade mecânica dos solos indispensável para análise estrutural de pavimentos em termos de tensão e deformação. O principal ensaio laboratorial para estimativa do módulo de resiliência dos solos é o ensaio triaxial cíclico no qual existe um maior controle das condições da amostra, dos carregamentos aplicados e dos deslocamentos medidos. A utilização de relações para obtenção do módulo de resiliência a partir de propriedades do solo obtidas de ensaios mais simples e rotineiros é permitida pelo procedimento NCHRP 1-37A (2004) e pode ser muito útil para fase de anteprojeto de implantação de rodovias, pois permite uma avaliação rápida do módulo de resiliência dos solos de jazidas e subleitos, localizados ao longo das diversas alternativas de traçados a serem analisadas. No entanto, as relações existentes ou são restritivas, por não considerarem os solos das regiões tropicais de comportamento laterítico e não laterítico da classificação MCT (Miniatura Compactado Tropical), ou são de baixa eficiência. Considerando-se o sucesso que as redes neurais artificiais (RNAs) têm apresentado no campo da engenharia em estabelecer relações entre variáveis explicativas e variáveis resposta, neste trabalho foram desenvolvidas RNAs para relacionar o módulo de resiliência com as propriedades do solo, tanto para solos grossos compactados na energia modificada como para solos compactados na energia normal. O banco de dados utilizado no trabalho baseou-se nos resultados de ensaios de setenta e seis amostras de solos coletadas no interior do Estado de São Paulo. Finalmente, verificou-se que as RNAs podem prever, com alta eficiência, o módulo de resiliência dos solos tropicais de comportamento laterítico e não laterítico a partir de propriedades do solo tais como: composição granulométrica, LL, IP, umidade ótima e resultados do ensaio de compressão simples. / The resilient modulus is an essential mechanical property for stress-strain analysis of pavements. The main test to evaluate resilient modulus of soils is cyclic triaxial test which there is a better control not only of samples but also of loads and displacements. Nowadays, the utilization of relationships to obtain resilient modulus from soils properties, from routine simple tests, is allowed by procedure NCHRP 1-37A, and that can be useful in initial design in construction of roads, as the resilient modulus of material pits and subgrades, places along several alternative traces of design, can be evaluated very fast by relationships. However, the existing relationships are restrictive, because they do not consider tropical soils of lateritic and non-lateritic behavior from MCT (Miniatura Compactado Tropical) classification and they have low performance. Artificial neural networks (ANNs) have shown high success to establish relationships from answering variables and explicative variables, so in this work was developed ANNs to establish relationships from resilient modulus and soil properties, not only for sandy soils in Proctor\'s modified compaction energy but also for soils in Proctor\'s standard compaction energy. The data base used in this work was laboratory test results from seventy-six soils which were collected in interior of Sao Paulo state. Finally, for tropical soils of lateritic and non-lateritic behavior, it was verified that ANNs can forecast, with high performance, resilient modulus from soil properties just as: grain size composition, liquid limit (LL), plasticity index (PI), optimum moisture content and results of simple strength compressive test.

Ensaio triaxial cíclico

Módulo de resiliência

Pavimentação

Redes neurais artificiais

Resiliência

Solos tropicais

Artificial neural networks

Cyclic triaxial test

Neural networks

Pavement

Resilience

Resilient modulus

Tropical soils

Estudo da influência da variação do teor de umidade no valor do módulo de resiliência de um solo argiloso encontrado em subleito de rodovias no interior paulista / Study of the influence of moisture content in resilient modulus value of a clay found in pavement subgrade in state of São Paulo

Ricardo Freire Gonçalves

28 June 1999

O objetivo deste trabalho é avaliar a influência da variação do teor de umidade no valor do módulo de resiliência (MR) de um solo argiloso de subleito, tendo em vista que este parâmetro é muito susceptível à variações climáticas ambientais. Foram realizados ensaios triaxiais cíclicos para se estimar o módulo de resiliência de corpos de prova ensaiados em diversas condições de umidade. Verificou-se que o MR é influenciado pela tensão desvio, de forma que aquele aumenta com o acréscimo desta. Constatou-se que os corpos de prova moldados na Wot e submetidos a trajetórias de secagem e umedecimento alcançaram valores de MR superiores e inferiores, respectivamente, ao se comparar com o MR de corpos de prova ensaiados na Wot. Este fato foi também observado para os corpos de prova moldados com massa específica seca máxima, em teores de umidade abaixo e acima do teor ótimo. Determinou-se, ainda, a sucção no solo através do método do papel filtro e levantou-se a sua curva característica. Verificou-se que à medida que a umidade aumenta, a sucção diminui. Observou-se que o valor do MR aumenta com o aumento da sucção no solo. Este crescimento é tanto maior quanto maior seja a tensão desvio aplicada. Foi possível determinar a relação entre o MR, a tensão desvio e o módulo tangente inicial (Eo), proveniente dos ensaios de compressão simples. Relacionou-se, também, o Eo e a sucção no solo. / The aim of this work is to evaluate the influence of moisture content variation in resilient modulus value (MR) of a subgrade clayey soil, considering that this parameter is very susceptible to environmental climatic variations. Cyclic triaxial tests were performed to acess resilient modulus of specimens tested in several moisture conditions. lt has been verified that MR is influenced by deviator stress, so that the former increases with the latter increases. lt has been confirmed that specimens molded in Wot and submited to a drying and moistening route reached MR values higher and lower, respectively, to compare with MR of specimens tested in Wot. This fact was also observed for the specimens molded with dry density, in moisture contents below and above of optimum moisture content. lt has been also determined the soil suction using filter paper method and it has been built its characteristic curve. lt has been verified that when moisture increases, the suction decreases. lt has been observed that MR value increases with the soil suction increase. This increase is as bigger as bigger the applied deviator stress be. lt was possible to determine the relationship between MR, deviator stress and parameters from compressive strength tests. lt has been related parameters from compressive strength tests and soil suction.

Compressão simples

Ensaio triaxial cíclico

Módulo de resiliência

Pavimentação

Resiliência

Subleito

Sucção

Teor de umidade

Compressive strength test

Cyclic triaxial test

Moisture content

Pavement

Resilience

Resilient modulus

Subgrade

Suction

A influência da variação da umidade pós-compactação no comportamento mecânico de solos de rodovias do interior paulista / The influence of post-compaction moisture content variation on the mechanical behavior of soils from São Paulo state pavements

Marcelo de Castro Takeda

22 May 2006

Na construção de rodovias, as condições de umidade e densidade observadas na compactação são, geralmente, próximas daquelas correspondentes ao pico da curva de compactação obtida no ensaio Proctor. É sabido que variações ambientais no decorrer da vida do pavimento podem alterar, de maneira significativa, a umidade do subleito e dos seus componentes e assim, as suas propriedades resilientes. O objetivo principal desta pesquisa é avaliar a influência da variação da umidade pós-compactação no módulo de resiliência de solos de rodovias do interior paulista a partir de resultados de ensaios de laboratório. Foram coletados e caracterizados setenta e três solos, e, dentre estes, selecionados trinta para a etapa de estudo da variação da umidade pós-compactação, após a realização de ensaios MCT, difração de raios-x, microscopia eletrônica de varredura e azul de metileno para determinação da gênese. Os solos selecionados apresentam características distintas quanto à gênese, sendo metade laterítico e metade não-laterítico. Os corpos-de-prova foram compactados na umidade ótima e submetidos a processos de secagem e umedecimento e, posteriormente, realizados ensaios triaxiais cíclicos. Os resultados permitiram a modelagem do 'M IND.R' em função do estado de tensão para diferentes umidades e a avaliação da competência de alguns modelos matemáticos nesta representação. Estudou-se a influência da gênese e da granulometria sobre o valor do 'M IND.R' e avaliou-se a conseqüência da variação da umidade sobre este para solos lateríticos e não-lateríticos. Determinou-se uma expressão para estimar a variação do 'M IND.R' com a variação da umidade a partir do parâmetro k1, independentemente do estado de tensão. Pesquisou-se a existência de relações entre os parâmetros de regressão do modelo composto e os resultados dos ensaios de compressão simples e as propriedades físicas dos solos, de forma a permitir a estimativa do módulo de resiliência a partir do resultado de ensaios mais simples. Investigou-se a possibilidade de se utilizar as relações entre a variação do módulo tangente inicial com a variação da umidade para estimar os efeitos sobre o 'M IND.R'. / On road construction, the field compaction conditions are usually close to those determined from Proctor tests. Environmental variations may lead to changes in the pavement moisture and also changing its resilient properties. The main objective of this research is to study the influence of post-compaction moisture content variation on the resilient modulus of soils from São Paulo state pavements, using laboratory tests. To accomplish this objective, seventy three soils samples were collected and characterized. Among them, thirty samples were selected, after four different tests were carried out to determine the soils genesis, to study the post-compaction moisture content variation. Half of these selected soils are lateritic ones, and the other half are non-lateritic soils. The specimens were compacted at optimum moisture content and submitted to drying and moistening processes prior cyclic triaxial test to be carried out. The results allowed the resilient modulus modeling as a function at the stress state and the performance evaluation of five different models. The genesis and grain size distribution influence on the resilient modulus values were studied. The effects of moisture content variations on lateritic and non-lateritic soils were investigated. An expression to estimate the resilient modulus variations with the moisture variations was determined, independently of the stress state. The existence of relations of the compound model regression parameters with the results of unconfined compressive strength and soil properties were studied. The possibility of using the initial tangent modulus variations with the moisture variations to estimate the effects on the resilient modulus were also investigated.

compressão simples

ensaio triaxial cíclico

módulo de resiliência

pavimentação

resiliência

subleito

sucção

teor de umidade

compressive strength test

cyclic triaxial tests

moisture content

pavement

resilient modulus

subgrade

suction

Sledování modulů pružnosti podloží vozovek / Monitoring of the modulus of elasticity of the pavement subgrade

Hladík, Aleš

January 2013

This thesis deals with compares the procedures carried out in the cyclical load triaxial testing device according to CSN EN 13286-7, and the procedures performed in the United States of America. In the practical part elasticity moduls of mixed recycled material are experimentally compared with mixed recycled material containing binder(connective material) and with fine-grained soil in the cyclical load triaxial testing device. Further the thesis assesses the use of mixed recycled material in the construction of a third class low-load pavement.

Shear Resistance Degradation of Lime –Cement Stabilized Soil During Cyclic Loading

Gebretsadik, Alex Gezahegn

January 2014

This thesis presents the results of a series of undrained cyclic triaxial tests carried out on four lime-cement stabilized specimens and clay specimen. The shear resistance degradation rate of lime-cement column subjected to cyclic loading simulated from heavy truck was investigated based on stress-controlled test. The influence of lime and cement on the degradation rate was investigated by comparing the behavior of stabilized kaolin and unstabilized kaolin with similar initial condition. The results indicate an increase in degree of degradation as the number of loading cycles and cyclic strain increase. It is observed that the degradation index has approximately a parabolic relationship with the number of cycles. Generally adding lime and cement to the clay will increase the degradation index which means lower degree of degradation. The degradation parameter, t has a hyperbolic relationship with shear strain, but it loses its hyperbolic shape as the soil getting stronger. On the other hand, for unstabilized clay an approximate linear relationship between degradation index and number of cycles was observed and the degradation parameter has a hyperbolic shape with the increase number of cycles. It was also observed that the stronger the material was, the lesser pore pressure developed in the lime-cement stabilized clay.

undrained cyclic triaxial test

lime-cement stabilized column

shear resistance

shear strain

degradation index

degradation parameter

pore pressure

Infrastructure Engineering

Infrastrukturteknik

Efeito da adição de fibras no comportamento de uma areia sob carregamentos cíclicos / Effect of fiber addition on the behavior of sands under cyclic loadings / Efecto de la adición de fibras en el comportamiento de una arena bajo cargas cíclicas

Flórez Gálvez, Jorge Hernán

January 2018

O avanço das técnicas de melhoramento de solos vem permitindo o aproveitamento de locais nos quais, até pouco tempo atrás, era considerada a construção de muitas estruturas como inviáveis, seja técnica, financeira ou ambientalmente. Uma das técnicas que tem conseguido demostrar bons resultados é o reforço com fibras de diferentes origens, com ou sem presença de algum agente cimentante. A maioria dos estudos conduzidos sobre este tipo de materiais se têm centrado na caracterização dos materiais sob cargas estáticas, e outros estudos se limitam a avaliar o comportamento sob cargas cíclicas destes materiais para densidades relativas baixas, nas quais o fenômeno de liquefação governa o mecanismo de ruptura. O presente estudo tenta aprofundar no conhecimento sobre materiais compactos quando submetidos a carregamentos cíclicos, de maneira a fornecer insumos para o estudo deste campo. O estudo, de caráter experimental, foi feito através da caracterização de corpos de prova de areia e areia com 0,5% de fibras, além da consideração de dois índices de vazios: o primeiro de 0,63 (correspondente a uma densidade relativa de 90%), e o segundo com um índice de vazios igual a 0,75 (correspondente a uma densidade relativa de 50%) Foram executados 29 ensaios triaxiais, além da adoção dos valores de outros 15 feitos por outro autor, totalizando 44 ensaios. A totalidade dos ensaios divide-se assim: 12 ensaios monotônicos CID, 12 ensaios monotônicos CIU, e 20 ensaios cíclicos CIU sob tensão controlada. Nos ensaios monotônicos obtiveram-se incrementos no ângulo de atrito do material composto, sendo mais evidente para as amostras compactas. Em relação aos ensaios cíclicos, obteve-se incrementos nas resistência do material até atingir sua condição de ruptura, seja por liquefação em amostras pouco compactas (Dr= 50%), ou por mobilidade cíclica no caso de amostras compactas (Dr= 90%). A normalização dos resultados permitiu observar que, embora as fibras melhorem o desempenho das misturas quando submetidas a carregamentos cíclicos, não alteraram a estrutura do material em sua resposta em termos de módulo de elasticidade, pelo menos no que respeita a níveis de deformações medianos a grandes. Para pequenas deformações, evidenciou-se uma diminuição na rigidez das amostras, ocasionando assim maiores acréscimos de poropressão nos estágios iniciais dos ensaios, mais nas em areias com fibras do que sem elas. / The development of ground improvement techniques has allowed the use of certain places, which was in the past considered as non-viable for the construction of many types of structures. Fiber reinforced soils have shown good results, with or without presence of any cementitious agent. The focus of most studies performed on this type of materials, is the characterization under static loading, and other studies are limited to evaluating its behavior on cyclic loading at low level of relative density, in which cases the liquefaction phenomenon governs the mechanism of rupture. This study aims to improve the knowledge of cyclic loading effects in dense materials. Was carried out an experimental program by characterizing specimens of sand with 0% and 0.5% of randomly distributed fiber, considering two void ratios: 0.63 (dense sand, Dr = 90%) and 0.75 (moderately loose sand, Dr = 50%). In total, were performed 29 triaxial tests, in addition of another 15 executed by another author, totaling 44 The test were divided as follows: 12 monotonic CIU test, 12 monotonic CID test, and 20 CIU loading controlled cyclic test. In monotonic conditions, fibers addition increases the friction angle, mostly on dense samples (Dr = 90%) than on loose specimens (Dr = 50%). For cyclic tests, in both materials, fiber additions causes improvement on cyclic behavior, but with different failure mechanism, liquefaction for loose, and cyclic mobility for dense sands, regardless of the presence of fibers. The transformation of the number of cycles axis, or normalization of another cyclic results allowed observing that, despite the fiber addition can cause improvement of materials subjected to cyclic loading, the structure of the material did not change in elasticity modulus response, at least for medium to large strains levels. For small strains, occur a decrease in the stiffness of samples, causing greater increases of pore pressure in the initial stages of tests, more in reinforced sand than for none reinforced condition. / El avance de las técnicas para mejoramiento de suelos ha permitido el aprovechamiento de sitios en los cuales, hasta hace poco tiempo, se consideraba como no viable la construcción de muchas estructuras, sea por cuestiones técnicas, financieras o ambientales. Una técnica que ha demostrado buenos resultados es la incorporación de refuerzos con fibras de diferente origen, considerando o no la presencia de algún agente cementante. La mayoría de los estudios realizados a este tipo de materiales se han centrado en la caracterización bajo la acción de cargas estáticas, e otros se han limitado a evaluar el comportamiento bajo la acción de cargas cíclicas considerando únicamente densidades relativas bajas, para las cuales la ruptura está controlada por el fenómeno de licuación. El presente estudio busca ahondar en el conocimiento sobre el comportamiento bajo acción de cargas cíclicas de materiales compactos, buscando con ello ampliar la base experimental sobre este campo. El estudio, de carácter experimental, fue realizado a partir de la caracterización de especímenes de arena sin fibras y con 0,5% de fibras, además de la consideración de dos relaciones de vacíos: 0.63 (correspondiente a una densidad relativa de 90%), y 0,75 (correspondiente a una densidad relativa de 50%) Fueron realizados 29 ensayos triaxiales, además de haber adoptado los resultados de otros 15 realizados por otro autor, totalizando 44 ensayos. Los ensayos fueron divididos así: 12 ensayos monotónicos CID, 12 ensayos monotónicos CIU, y 20 ensayos triaxiales cíclicos CID con control de esfuerzos. En los ensayos monotónicos fueron obtenidos incrementos en el ángulo de fricción del material compuesto, siendo esta situación más evidente en muestras compactas. Con relación a los ensayos cíclicos, se obtuvo incremento en la resistencia de las muestras hasta alcanzar su condición de ruptura, bien sea por licuación (materiales relativamente sueltos, Dr = 50%), o por movilidad cíclica (materiales compactos, Dr = 90%). La normalización de los resultados permitió observar que, aunque las fibras mejoran el desempeño bajo cargas cíclicas de los materiales, no alteraron la estructura del material en términos de módulo de elasticidad, por lo menos para niveles medios y altos de deformación. Para pequeñas deformaciones, se evidenció una disminución en la rigidez de las muestras, lo que produjo mayores incrementos en las presiones de poros durante las fases iniciales de los ensayos, con mayor visibilidad en las arenas con fibras que cuando no hubo adición.

Solo reforçado

Solo : Melhoramento

Ensaios triaxiais

Fibras

Rock falls

Cyclic triaxial test

Cyclic loadings

Ground improvement

Fiber reinforced sands

Sand fiber

Arena fibra

Ensayo triaxial cíclico

Cargas cíclicas

Mejoramiento de suelos

Arenas reforzadas con fibras

Efeito da adição de fibras no comportamento de uma areia sob carregamentos cíclicos / Effect of fiber addition on the behavior of sands under cyclic loadings / Efecto de la adición de fibras en el comportamiento de una arena bajo cargas cíclicas

Flórez Gálvez, Jorge Hernán

January 2018

O avanço das técnicas de melhoramento de solos vem permitindo o aproveitamento de locais nos quais, até pouco tempo atrás, era considerada a construção de muitas estruturas como inviáveis, seja técnica, financeira ou ambientalmente. Uma das técnicas que tem conseguido demostrar bons resultados é o reforço com fibras de diferentes origens, com ou sem presença de algum agente cimentante. A maioria dos estudos conduzidos sobre este tipo de materiais se têm centrado na caracterização dos materiais sob cargas estáticas, e outros estudos se limitam a avaliar o comportamento sob cargas cíclicas destes materiais para densidades relativas baixas, nas quais o fenômeno de liquefação governa o mecanismo de ruptura. O presente estudo tenta aprofundar no conhecimento sobre materiais compactos quando submetidos a carregamentos cíclicos, de maneira a fornecer insumos para o estudo deste campo. O estudo, de caráter experimental, foi feito através da caracterização de corpos de prova de areia e areia com 0,5% de fibras, além da consideração de dois índices de vazios: o primeiro de 0,63 (correspondente a uma densidade relativa de 90%), e o segundo com um índice de vazios igual a 0,75 (correspondente a uma densidade relativa de 50%) Foram executados 29 ensaios triaxiais, além da adoção dos valores de outros 15 feitos por outro autor, totalizando 44 ensaios. A totalidade dos ensaios divide-se assim: 12 ensaios monotônicos CID, 12 ensaios monotônicos CIU, e 20 ensaios cíclicos CIU sob tensão controlada. Nos ensaios monotônicos obtiveram-se incrementos no ângulo de atrito do material composto, sendo mais evidente para as amostras compactas. Em relação aos ensaios cíclicos, obteve-se incrementos nas resistência do material até atingir sua condição de ruptura, seja por liquefação em amostras pouco compactas (Dr= 50%), ou por mobilidade cíclica no caso de amostras compactas (Dr= 90%). A normalização dos resultados permitiu observar que, embora as fibras melhorem o desempenho das misturas quando submetidas a carregamentos cíclicos, não alteraram a estrutura do material em sua resposta em termos de módulo de elasticidade, pelo menos no que respeita a níveis de deformações medianos a grandes. Para pequenas deformações, evidenciou-se uma diminuição na rigidez das amostras, ocasionando assim maiores acréscimos de poropressão nos estágios iniciais dos ensaios, mais nas em areias com fibras do que sem elas. / The development of ground improvement techniques has allowed the use of certain places, which was in the past considered as non-viable for the construction of many types of structures. Fiber reinforced soils have shown good results, with or without presence of any cementitious agent. The focus of most studies performed on this type of materials, is the characterization under static loading, and other studies are limited to evaluating its behavior on cyclic loading at low level of relative density, in which cases the liquefaction phenomenon governs the mechanism of rupture. This study aims to improve the knowledge of cyclic loading effects in dense materials. Was carried out an experimental program by characterizing specimens of sand with 0% and 0.5% of randomly distributed fiber, considering two void ratios: 0.63 (dense sand, Dr = 90%) and 0.75 (moderately loose sand, Dr = 50%). In total, were performed 29 triaxial tests, in addition of another 15 executed by another author, totaling 44 The test were divided as follows: 12 monotonic CIU test, 12 monotonic CID test, and 20 CIU loading controlled cyclic test. In monotonic conditions, fibers addition increases the friction angle, mostly on dense samples (Dr = 90%) than on loose specimens (Dr = 50%). For cyclic tests, in both materials, fiber additions causes improvement on cyclic behavior, but with different failure mechanism, liquefaction for loose, and cyclic mobility for dense sands, regardless of the presence of fibers. The transformation of the number of cycles axis, or normalization of another cyclic results allowed observing that, despite the fiber addition can cause improvement of materials subjected to cyclic loading, the structure of the material did not change in elasticity modulus response, at least for medium to large strains levels. For small strains, occur a decrease in the stiffness of samples, causing greater increases of pore pressure in the initial stages of tests, more in reinforced sand than for none reinforced condition. / El avance de las técnicas para mejoramiento de suelos ha permitido el aprovechamiento de sitios en los cuales, hasta hace poco tiempo, se consideraba como no viable la construcción de muchas estructuras, sea por cuestiones técnicas, financieras o ambientales. Una técnica que ha demostrado buenos resultados es la incorporación de refuerzos con fibras de diferente origen, considerando o no la presencia de algún agente cementante. La mayoría de los estudios realizados a este tipo de materiales se han centrado en la caracterización bajo la acción de cargas estáticas, e otros se han limitado a evaluar el comportamiento bajo la acción de cargas cíclicas considerando únicamente densidades relativas bajas, para las cuales la ruptura está controlada por el fenómeno de licuación. El presente estudio busca ahondar en el conocimiento sobre el comportamiento bajo acción de cargas cíclicas de materiales compactos, buscando con ello ampliar la base experimental sobre este campo. El estudio, de carácter experimental, fue realizado a partir de la caracterización de especímenes de arena sin fibras y con 0,5% de fibras, además de la consideración de dos relaciones de vacíos: 0.63 (correspondiente a una densidad relativa de 90%), y 0,75 (correspondiente a una densidad relativa de 50%) Fueron realizados 29 ensayos triaxiales, además de haber adoptado los resultados de otros 15 realizados por otro autor, totalizando 44 ensayos. Los ensayos fueron divididos así: 12 ensayos monotónicos CID, 12 ensayos monotónicos CIU, y 20 ensayos triaxiales cíclicos CID con control de esfuerzos. En los ensayos monotónicos fueron obtenidos incrementos en el ángulo de fricción del material compuesto, siendo esta situación más evidente en muestras compactas. Con relación a los ensayos cíclicos, se obtuvo incremento en la resistencia de las muestras hasta alcanzar su condición de ruptura, bien sea por licuación (materiales relativamente sueltos, Dr = 50%), o por movilidad cíclica (materiales compactos, Dr = 90%). La normalización de los resultados permitió observar que, aunque las fibras mejoran el desempeño bajo cargas cíclicas de los materiales, no alteraron la estructura del material en términos de módulo de elasticidad, por lo menos para niveles medios y altos de deformación. Para pequeñas deformaciones, se evidenció una disminución en la rigidez de las muestras, lo que produjo mayores incrementos en las presiones de poros durante las fases iniciales de los ensayos, con mayor visibilidad en las arenas con fibras que cuando no hubo adición.

Solo reforçado

Solo : Melhoramento

Ensaios triaxiais

Fibras

Rock falls

Cyclic triaxial test

Cyclic loadings

Ground improvement

Fiber reinforced sands

Sand fiber

Arena fibra

Ensayo triaxial cíclico

Cargas cíclicas

Mejoramiento de suelos

Arenas reforzadas con fibras

Response of Geosynthetic Reinforced Granular Bases Under Repeated Loading

Suku, Lekshmi

January 2016

Key factors that influence the design of paved and unpaved roads are the strength and stiffness of the pavement layers. Among other factors, the strength of pavements depends on the thickness and quality of the aggregates used in the pavement base layer. In India and many other countries, there is a high demand for good quality aggregates and the availability of aggregate resources is limited. There is a need for the development of sustainable construction methods which can handle aggregate requirements with least available resources and provide good performance. Hence it is imperative to strive for alternatives to achieve improved quality of pavements using supplementary potential materials and methods. The strength of pavement increases with increase in the thickness of the base which has a direct implication on construction cost whereas decreasing the thickness of the base makes it weak which results in low load bearing capacity especially for unpaved roads. The use of different types of geosynthetics like geocell and geogrid are a potential and reliable solution for the lack of availability of aggregates and studies are conducted in this direction. To better understand the performance of any geosynthetically reinforced base layers, it is essential to characterize the pavement material by studying the behavior of these materials under static as well as repeated loading. For unpaved roads, the base layer, made of granular aggregates plays a crucial role in the reduction of permanent deformation of the pavements. The resilient modulus (Mr) of these materials is a key parameter for predicting the structural response of pavements and for characterizing materials in pavement design and evaluation. Usually, during the design of flexible pavements, pavement materials are treated as homogeneous and isotropic. The use of rollers in the field during pavement construction leads to a higher compaction of material in the vertical direction which introduces stress-induced anisotropy in the base material. The effect of stress-induced anisotropy on the properties of the granular material is studied and discussed in the first part of the research by conducting repeated load triaxial tests. Isotropic consolidated and anisotropically consolidated samples were prepared to investigate the behavior of base materials under stress induced anisotropic conditions. An additional axial load was applied on the isotropically consolidated sample to create anisotropically consolidated sample. The axial loading was provided such that the stress ratio (σ1/σ3), during anisotropic consolidation was kept constant for all the tests at different confining pressures. The effect of repeated loading on the permanent deformation and the resilient modulus for both isotropically and anisotropically consolidated samples, at different confining pressure and loading conditions, are discussed. The behavior of both anisotropically and isotropically consolidated samples has been explained using the record of the excess pore pressures generated during the experiments. The experimental studies show that the permanent strains measured in the vertical direction of the anisotropically consolidated samples are less compared to the results obtained for isotropically consolidated samples. The resilient moduli of the anisotropically consolidated samples were also observed to be higher than that of the isotropically consolidated sample. The study conducted on the pore pressure of both the samples explains better performance of the anisotropically consolidated samples. The studies showed that the isotropically consolidated samples showed higher pore pressures compared to the anisotropically consolidated specimens. Another factor which influences the resilient modulus of the pavement materials is the geosynthetic reinforcement. Geocell and geogrid reinforced triaxial samples were prepared to study the effect of reinforcement in the resilient modulus of the base materials. From the literature, it can be seen that most of the research in the triaxial testing equipment were carried out in the non-destructive range of confining pressure and deviatoric stress. Several studies have been conducted by the researchers to visualize the pavement response in the elastic range. However, the studies in the plastic creep range and incremental collapse range were highly limited. In the current study, testing is carried out on the triaxial samples for two different stress ranges. In the first sections, loading was applied in the elastic and elastic shakedown range as per AASTHO T-307. For various loading sequences, a comparative analysis has been done for the resilient modulus of the geogrid and geocell. In the next section, the loading was applied on the sample in the plastic shakedown range and incremental collapse range. The results of the permanent strains and resilient modulus of the sections are compared with the corresponding results of the unreinforced section. In the plastic shakedown and incremental collapse range also the permanent strains of reinforced samples were less than those observed in the unreinforced section. The performance of geosynthetically reinforced pavement layers can be better understood by studying the samples prepared under realistic field conditions. In the case of triaxial experiments the sample size is very less compared to the field conditions and the effect of other pavement layers on the performance of the base layers cannot be studied on triaxial samples. Samples were prepared in the laboratory by modeling the pavement sections in a cuboidal tank, in which different pavement layers are laid one over the other, and a static loading or repeated loading is applied to overcome the bottleneck of small sample size in the triaxial setup. The experiments were conducted on the unreinforced section; geocell reinforced section and geogrid reinforced section placed above strong and weak subgrade. The results of the study are examined regarding the resilient deformation, permanent deformation, pressure distribution and strain measurements for different thicknesses of base layers under repeated loading. The initial parts of the study present the results of experiments and analysis of the results to understand the behavior of geocell reinforced granular base during repeated loading. In this study, an attempt is made to understand the various factors which influence the behavior of geocell reinforced granular base under repeated loading by conducting plate load tests. The loads applied on the pavements are much higher than the standard axle loading used for the design of pavements. High pressure was applied on all the test sections to simulate these higher loading conditions in the field. The optimum width and height of the geocell to be provided, to get maximum reduction in permanent deformation is studied in detail. The effect of resilient deformation of reinforced and unreinforced base layers is quantified by calculating the resilient modulus of these layers. The studies showed that the geocell reinforcement was effective in reducing the permanent and resilient deformations of base layer when compared to the unreinforced samples. The resilient modulus calculated was higher for the reinforced sample with half of the thickness of the unreinforced sample. The effect of reinforcement in the stress distribution within the base layer is also studied by measuring the pressures at different depths of the base layer. The results showed that the pressure getting transferred to the subgrade level was much lower in the case of geocell reinforced base layer. The ultimate aim of any pavement design method is to reduce the distress in the subgrade level and thus leading to increased life of pavements. Pressures at the subgrade level for reinforced and unreinforced sections are studied in detail, the main parameter under study being the stress distribution angle, to investigate the distress in the subgrade level. It was observed that the geocell reinforced sample showed higher stress distribution angle when compared to its unreinforced counterpart. Another important factor that has to be studied is the strains at the subgrade level since it is the governing factor of causing rutting in the pavements. From the experiments conducted in the study, it was shown that the reinforcement is very effective in reducing the strains at the top of subgrades. The implications of the current study are brought out in terms of improved pavement performance as the carbon emission reductions. It is important to analyze the performance of reinforced section under realistic field conditions. To do that experiment were conducted on reinforced and unreinforced base layers placed on top of weak subgrade material. The study showed that the reinforcements are effective in reducing the deformations under weak subgrade conditions also but not as effective as it was under strong subgrade case. The experimental results were then validated with the two-dimensional mechanistic-empirical model for geocell reinforced unpaved roads for predicting the performance of pavements under a significant number of cycles. The modified permanent deformation model which incorporates the triaxial test results and strains measured directly from the base sections were used to model and validate. Plate load experiments were also conducted on base layers reinforced with geogrid to understand the behavior of these reinforced samples under repeated loading. Several factors like the width of the geogrid to be provided and the depth of placing the geogrid in the base layer were studied in detail to achieve maximum reduction in deformations. Permanent and resilient deformation studies were carried out for both reinforced and unreinforced sections of varying thicknesses, and a comparison was made to understand the effect of reinforcement. The geogrid reinforcement could effectively reduce the permanent and resilient deformations when compared to the unreinforced sections. A study was also carried out on the resilient modulus, which explained the better performance of the geogrid reinforced samples by showing higher resilient modulus for reinforced samples than the unreinforced specimens. The performance of the geogrid reinforced base layers was further verified by studying the pressure distribution at the subgrade level and by calculating the stress distribution angle corresponding to the reinforced and unreinforced samples. The strains at the subgrade level were also studied and compared with the unreinforced sample which showed a better performance of geogrid reinforced samples. The results from the strain gauges fixed in the geogrid were further used to model and validate the permanent deformation model. Experiments were conducted on geogrid-reinforced base layer placed above weak subgrade conditions. The results showed that the reinforcement was effective in reducing the deformations under weak subgrade conditions also. Apart from conducting the laboratory studies, experimental results were numerically modeled to accurately back-calculate the resilient moduli of the layers used in the study. 3D numerical modeling of the unreinforced and honeycomb shaped geocell reinforced layers were carried out using finite element package of ANSYS. The subgrade layer, geocell material, and infill material were modeled with different material models to match the real case scenario. The modeling was done for both static and repeated load conditions. The material properties were changed in a systematic fashion until the vertical deformations of the loading plate matched with the corresponding values measured during the experiment. The experimental study indicates that the geocell reinforcement distributes the load in the lateral direction to a relatively shallow depth when compared to the unreinforced section. Numerical modeling further strengthened the results of the experimental studies since the modeling results were in sync with the experimental data.

Geocell Reinforcement,

Granular Material Characterization

Geogrid Reinforced Pavements

Geocell

Geogrid

Granular Bases

Geogrid-Reinforcement

Geocell Reinforced Granular Base

Pavement Design

Cyclic Loading

Geosynthetic Reinforced Layers

Repeated Load Triaxial Tests

Cyclic Triaxial Tests

Civil Engineering

Efeito da adição de fibras no comportamento de uma areia sob carregamentos cíclicos / Effect of fiber addition on the behavior of sands under cyclic loadings / Efecto de la adición de fibras en el comportamiento de una arena bajo cargas cíclicas

Flórez Gálvez, Jorge Hernán

January 2018

O avanço das técnicas de melhoramento de solos vem permitindo o aproveitamento de locais nos quais, até pouco tempo atrás, era considerada a construção de muitas estruturas como inviáveis, seja técnica, financeira ou ambientalmente. Uma das técnicas que tem conseguido demostrar bons resultados é o reforço com fibras de diferentes origens, com ou sem presença de algum agente cimentante. A maioria dos estudos conduzidos sobre este tipo de materiais se têm centrado na caracterização dos materiais sob cargas estáticas, e outros estudos se limitam a avaliar o comportamento sob cargas cíclicas destes materiais para densidades relativas baixas, nas quais o fenômeno de liquefação governa o mecanismo de ruptura. O presente estudo tenta aprofundar no conhecimento sobre materiais compactos quando submetidos a carregamentos cíclicos, de maneira a fornecer insumos para o estudo deste campo. O estudo, de caráter experimental, foi feito através da caracterização de corpos de prova de areia e areia com 0,5% de fibras, além da consideração de dois índices de vazios: o primeiro de 0,63 (correspondente a uma densidade relativa de 90%), e o segundo com um índice de vazios igual a 0,75 (correspondente a uma densidade relativa de 50%) Foram executados 29 ensaios triaxiais, além da adoção dos valores de outros 15 feitos por outro autor, totalizando 44 ensaios. A totalidade dos ensaios divide-se assim: 12 ensaios monotônicos CID, 12 ensaios monotônicos CIU, e 20 ensaios cíclicos CIU sob tensão controlada. Nos ensaios monotônicos obtiveram-se incrementos no ângulo de atrito do material composto, sendo mais evidente para as amostras compactas. Em relação aos ensaios cíclicos, obteve-se incrementos nas resistência do material até atingir sua condição de ruptura, seja por liquefação em amostras pouco compactas (Dr= 50%), ou por mobilidade cíclica no caso de amostras compactas (Dr= 90%). A normalização dos resultados permitiu observar que, embora as fibras melhorem o desempenho das misturas quando submetidas a carregamentos cíclicos, não alteraram a estrutura do material em sua resposta em termos de módulo de elasticidade, pelo menos no que respeita a níveis de deformações medianos a grandes. Para pequenas deformações, evidenciou-se uma diminuição na rigidez das amostras, ocasionando assim maiores acréscimos de poropressão nos estágios iniciais dos ensaios, mais nas em areias com fibras do que sem elas. / The development of ground improvement techniques has allowed the use of certain places, which was in the past considered as non-viable for the construction of many types of structures. Fiber reinforced soils have shown good results, with or without presence of any cementitious agent. The focus of most studies performed on this type of materials, is the characterization under static loading, and other studies are limited to evaluating its behavior on cyclic loading at low level of relative density, in which cases the liquefaction phenomenon governs the mechanism of rupture. This study aims to improve the knowledge of cyclic loading effects in dense materials. Was carried out an experimental program by characterizing specimens of sand with 0% and 0.5% of randomly distributed fiber, considering two void ratios: 0.63 (dense sand, Dr = 90%) and 0.75 (moderately loose sand, Dr = 50%). In total, were performed 29 triaxial tests, in addition of another 15 executed by another author, totaling 44 The test were divided as follows: 12 monotonic CIU test, 12 monotonic CID test, and 20 CIU loading controlled cyclic test. In monotonic conditions, fibers addition increases the friction angle, mostly on dense samples (Dr = 90%) than on loose specimens (Dr = 50%). For cyclic tests, in both materials, fiber additions causes improvement on cyclic behavior, but with different failure mechanism, liquefaction for loose, and cyclic mobility for dense sands, regardless of the presence of fibers. The transformation of the number of cycles axis, or normalization of another cyclic results allowed observing that, despite the fiber addition can cause improvement of materials subjected to cyclic loading, the structure of the material did not change in elasticity modulus response, at least for medium to large strains levels. For small strains, occur a decrease in the stiffness of samples, causing greater increases of pore pressure in the initial stages of tests, more in reinforced sand than for none reinforced condition. / El avance de las técnicas para mejoramiento de suelos ha permitido el aprovechamiento de sitios en los cuales, hasta hace poco tiempo, se consideraba como no viable la construcción de muchas estructuras, sea por cuestiones técnicas, financieras o ambientales. Una técnica que ha demostrado buenos resultados es la incorporación de refuerzos con fibras de diferente origen, considerando o no la presencia de algún agente cementante. La mayoría de los estudios realizados a este tipo de materiales se han centrado en la caracterización bajo la acción de cargas estáticas, e otros se han limitado a evaluar el comportamiento bajo la acción de cargas cíclicas considerando únicamente densidades relativas bajas, para las cuales la ruptura está controlada por el fenómeno de licuación. El presente estudio busca ahondar en el conocimiento sobre el comportamiento bajo acción de cargas cíclicas de materiales compactos, buscando con ello ampliar la base experimental sobre este campo. El estudio, de carácter experimental, fue realizado a partir de la caracterización de especímenes de arena sin fibras y con 0,5% de fibras, además de la consideración de dos relaciones de vacíos: 0.63 (correspondiente a una densidad relativa de 90%), y 0,75 (correspondiente a una densidad relativa de 50%) Fueron realizados 29 ensayos triaxiales, además de haber adoptado los resultados de otros 15 realizados por otro autor, totalizando 44 ensayos. Los ensayos fueron divididos así: 12 ensayos monotónicos CID, 12 ensayos monotónicos CIU, y 20 ensayos triaxiales cíclicos CID con control de esfuerzos. En los ensayos monotónicos fueron obtenidos incrementos en el ángulo de fricción del material compuesto, siendo esta situación más evidente en muestras compactas. Con relación a los ensayos cíclicos, se obtuvo incremento en la resistencia de las muestras hasta alcanzar su condición de ruptura, bien sea por licuación (materiales relativamente sueltos, Dr = 50%), o por movilidad cíclica (materiales compactos, Dr = 90%). La normalización de los resultados permitió observar que, aunque las fibras mejoran el desempeño bajo cargas cíclicas de los materiales, no alteraron la estructura del material en términos de módulo de elasticidad, por lo menos para niveles medios y altos de deformación. Para pequeñas deformaciones, se evidenció una disminución en la rigidez de las muestras, lo que produjo mayores incrementos en las presiones de poros durante las fases iniciales de los ensayos, con mayor visibilidad en las arenas con fibras que cuando no hubo adición.

Solo reforçado

Solo : Melhoramento

Ensaios triaxiais

Fibras

Rock falls

Cyclic triaxial test

Cyclic loadings

Ground improvement

Fiber reinforced sands

Sand fiber

Arena fibra

Ensayo triaxial cíclico

Cargas cíclicas

Mejoramiento de suelos

Arenas reforzadas con fibras

Assessment of Leachate Characteristics and Geotechnical Properties of Municipal Solid Waste Landfill

Naveen, B P

January 2016

Solid Waste Management is one of the essential services provided by local bodies to keep the urban areas clean. Often it is poorly rendered as it is unscientific, out-dated and inefficient. With the rapid increase in population, livening standards, the generation rates of solid waste are increasing drastically. The landfill waste includes both organic and inorganic wastes as it is not often effectively segregated before disposal. The problem is acute in developing countries such as India. Bangalore city, with a population of about 10.18 million and more than 2000 industries, generates about 4,500 TPD of municipal solid waste. Of this Presently, various municipal solid waste processing units in Bangalore can handle only about 2100 TPD of waste. Mavallipura landfill developed and operated by M/s. Ramky Environmental Engineers, located 40 km away from Bangalore, is being used for disposing of about 1000 TPD, the installed capacity being only 600 TPD of waste. There are also a few dumps in around Bangalore due to historical reasons and insufficient capacity of various designated landfills. To reclaim the old dump sites/closed landfill sites for infrastructural development, it is necessary to know their geotechnical characteristics. Within the Landfill, the characteristics of the waste may change with depth due to degraded wastes as it has been dumped over a period of time. The physical parameters, chemical properties as well as the geotechnical behaviour of the waste change with depth. MSW is known to be a heterogeneous material of varying constituent types and dimensions, containing elements that degrade with time. To consider MSW as a geo-material to support the foundation of structures such as buildings and pavement, an analysis of the bearing capacity of the foundation and further long-term settlement of MSW is essential. The MSW samples are retrieved from a Mavallipura landfill site, Bangalore and analysed for important geotechnical properties such as compaction characteristics, shear strength, permeability, compressibility behaviour and dynamic properties of MSW using ultrasonic and cyclic triaxial tests. This research thus aims to provide valuable information about landfill sites for reclamation, closure and infrastructural development after the closure of landfills. Scanty data are available on the geotechnical properties of waste from landfill sites with varying degrees of degradation. This landfill site is selected as there is a huge environmental concern regarding the soil and groundwater contamination in the area and also can represent a typical landfill scenario in tropical regions. Quantification, quality assessment, consequent treatment and management of leachate have become a monstrous problem world over. In this context, the present study envisages to study the physicochemical and biological characterization of representative urban municipal landfill leachate and nearby water bodies and attempts to figure out relationships between the various parameters together with understanding the various processes for chemical transformations. The analysis shows intermediate leachate age (5-10 years) with higher nutrient levels i.e. 10,000 - 12,000 mg/l and ~2,000 - 3,000 mg/l of carbon (COD) and nitrogen (TKN) respectively. Elemental analysis and underlying mechanisms reveal chemical precipitation and co-precipitation as the vital processes in leachate pond systems resulting in accumulation of trace metals in these systems. The microbial analysis also correlated with specific factors relevant to redox environments that show a gradient in nature and the abundance of biotic diversity with a change in leachate environment. Finally, the quality and the contamination potential of the sampled leachate were performed with the help of potential leachate index (LPI) analysis and water quality index (WQI) analysis for surrounding water bodies (namely surface pond and open well) of Mavallipura landfill site. A geotechnical testing program has been drawn to evaluate the engineering properties of municipal solid waste samples retrieved from a landfill at Mavallipura at various depths through augur within the landfill dumped area. Laboratory studies included are composition, moisture content, particle size analysis, compaction, permeability, direct shear test, consolidation, triaxial compression test. For the laboratory tests, we had considered maximum particle sizes of less than 4.75 mm only. Standard Proctor Compaction tests yielded a maximum dry density of 7.0kN/m3 at 50% optimum moisture content. The permeability of MSW results shows in the range of 4x10-4 cm/sec. Compression index of MSW is 0.46980 and recompression index of MSW is 0.09454. Results obtained from the rectangular hyperbola method are compared with Casagrande and Taylor methods to prove that this method is reliable equally, and results are reasonably accurate. Based on direct shear tests, the MSW sample exhibited continuous strength gain with an increase in shear strain (16%) to define strength. The cohesion of MSW was 10kPa and friction angle is 34°. Based on the elastic constants results obtained from the direct shear test found to be very soft material. In the triaxial test, the MSW sample exhibited continuous strength gain with an increase in axial strain. The frictional component is increased due to sliding and rolling of fibrous particles over one another resulting in the development of apparent cohesion due to antiparticle bonds within the MSW material. Landfills are an integral part of waste management, and disastrous consequences can happen if seismic vulnerability of these landfills is not considered. Dynamic properties of MSW are required to perform seismic response analysis of MSW landfills, but there is no good understanding of the dynamic shear strength of MSW in literature. A comprehensive laboratory cyclic triaxial testing program has been taken up to determine the properties at different densities, confining pressures and shear strains. MSW degrades with time, and its shear modulus and damping are expected to vary with time and degradation. For the density of 6 kN/m3 the dynamic shear modulus values for MSW varied from 0.68 MPa to 5.38 MPa and damping ratio varied from 20% to 40% for MSW. For the density of 7 kN/m3 the dynamic shear modulus values for MSW varied from 1.8 MPa to 7.5 MPa and Damping ratio varied from 23% to 40% for MSW. For the density of 8kN/m3 dynamic shear modulus values for MSW varied from 2.46 MPa to 8.00MPa and damping ratio varied from 16% to 33% for MSW. Also, the ultrasonic testing method was used for determining the dynamic properties at low strains. The Ultrasonic test results indicated that with an increase in density of the sample and with decreased void ratio, the pulse propagation velocity (Vp) increases. With an increase in the density, the shear wave velocity and elastic constants (elastic modulus and shear modulus) increase. The elastic constant values obtained from the ultrasonic test are higher compared to values obtained from unconsolidated-undrained triaxial tests. Also, the carbon stored in the buried organic matter in Mavallipura landfill is estimated. Total organic carbon increases steeply with an increase in depth and is significantly high at a depth of 6 m. Subsurface properties cannot be specified but must be analysed through in-situ tests. The in-situ testing that are carried out in a landfill are boring, sampling, standard penetration test (SPT), dynamic cone penetration test (DCPT) and plate load tests (under static and cyclic condition). A correlation between corrected SPT ‘N’ values and measured using shear wave velocities has been developed for Mavallipura landfill site. Results show that the corrected SPT- N values increase with depth. Corrected N-values are used in the landfill design, so they are consistent with the design method, and correlations are useful. The results obtained from the dynamic cone penetration tests shows lower value when to compare with standard penetration test. The unit weight profile with depth ranged from a low unit weight of 2.48 kN/m3 near the surface to a highest value of approximately 9.02 kN/m3 at a depth of 6 m. The highest temperatures for landfills were reported at mid-waste elevations with temperatures decreasing near the top. The bearing pressure-settlement curves for plate size 75cm and 60cm presented similar behaviour while the plate size of 60cm curve presents a lesser settlement of 70mm, compared to with plate size of the 75cm curve with the settlement of 80mm and failure mode could be classified as punching shear. The cyclic plate load test with plate size of 60cm and 75cm were carried out on the soil cover. The elastic constants were found to be 73.87 and 96.84 kPa/mm and for 60 and 75cm plates respectively. Geophysical testing may not be as precise but has the benefit of covering large areas at small costs and sometimes can locate features that might be missing by conventional borings. Multichannel analysis of surface waves (MASW) is an indirect geophysical method used in the landfill for the characterization of the municipal solid waste site. The Mavallipura landfill was surveyed up to the length of about 35m at the top level. A series of one-dimensional and two-dimensional MASW surveys used active seismic sources such as sledgehammer (5kg) and propelled energy generator (PEG-40) was used. This hammer was instrumented with geophones to trigger record time. All the testing has been carried out with geophone spacing of 1m and recorded surface wave arrivals using the source to first receiver distance as 5m with recording length of 1000 millisecond and the recording sampling interval of 0.5 milliseconds (ms) were applied. Results shows that the PEG-40 hammer can generate the longest wavelength with a maximum depth of penetration. The shear wave velocity varies from 75 to 155 m/s with an increase in depth of about 27.5m. Based on the site characterization at the landfill site, it was found that the Mavallipura landfill site can be categorized as very loose, and it is still in a continued stage of degradation. Shear wave and P-wave velocity profile for eight major locations in the study area were determined and variation of waste material stiffness corresponding to the in-situ state with depth, was also evaluated. Also, MASW survey has been carried out to develop dispersion curve on another landfill site at Bhandewadi, Nagpur. MASW system consisting of 24 channels geode seismograph with 24 geophones of 4.5Hz capacity is used in this investigation. The seismic waves were created by sledgehammer with 30cmx 30cmx2cm size hammer plate with ten shots. These waves were captured by the geophones/receivers and further analyzed by inversion. The results indicated that near surface soils(less than 3m depth) approximately the to 5mm, and with 85% of dry weight basis of waste particles with sizes less than 10mm, the shear wave velocity varies from 75 to 140 m/s (frequency ranges from 30 to 23Hz). With the increase in 6.5m depth, the shear wave velocity ranged from 140 to 225m/s (frequency ranges 23 to 13Hz). Overall, the results of the study showed that seismic surveys have the potential to capture the changes in dynamic properties like shear wave velocity and Poisson’s ratio of the depth of MSW landfill to infer the extent of degradation and provide dynamic properties needed for seismic stability evaluations. Based on the in situ and laboratory results of this study and a review of the literature, the unit weight, shear wave velocity, strain-dependent normalized shear modulus reduction and material damping ratio relationships for Mavallipura landfill are developed and also validated using semi-empirical methods. Finally, seismic response analysis of Mavallipura landfill has been carried out using the computer programs like SHAKE 2000 and DEEPSOIL. Results show that the unit weight is increased with depth in response to the increase in overburden stress. The proposed material damping ratio and normalized shear modulus reduction curve lie close to the profile given in the literature for landfills composed of waste materials with 100% particles sized less than 20mm. Peak spectral acceleration at 5% damping value is 0.7g for 0.07 sec in SHAKE 2000 and peak spectral acceleration at 5% damping value is 0.63g for 0.04 sec in DEEPSOIL. Amplification ratio is 6.11 at 1.1l Hz in SHAKE2000 and 4.65 at 2.67Hz in DEEPSOIL. Peak ground acceleration (PGA) for the landfill site, it is observed PGA has decreased from 0.3g to 0.15g in DEEPSOIL and PGA has decreased from 0.33g to 0.15g in SHAKE2000. The studies presented in the thesis brought out the importance of characterization of municipal solid waste leachate regarding metabolism and treatment/degradation of Mavallipura landfill leachate. For municipal solid waste of with sizes ranging from 0.08 coefficient of permeability being about 10-4 cm/sec, the compression index was about 0.47. A more reliable method of calculating the coefficient of consolidation has been recommended. Correlations between shear wave velocity and SPT-N values has been developed for the Mavallipura landfill site. The results showed that the dynamic cone penetration tests values are lower than indicated by standard penetration tests. The cyclic plate load tests carried out with plate sizes of 75cm and 60cm showed that elastic constants of 96.84 kPa/mm and 73.87kPa/mm respectively. MSW properties evaluated in this thesis are compared with those of soft clays. The MSW properties showed higher values (strength and SBC) and lower values of compressibility, compared with those of soft clays. Thus foundation improvement on MSW is less challenging than foundations on soft soils. Also stabilization of MSW with other solid wastes such as fly ash can be considered as an economical option. Based on detailed studies the importance of unit weight, shear wave velocity, strain-dependent normalized shear modulus reduction and material damping ratio relationships for landfill waste have been developed. Based on the site characterization, the waste landfill has been categorized as very loose material, which is still in a degradation process. SHAKE2000 software shows higher PGA value comparing with DEEPSOIL.

Municipal Solid Waste Landfills

Solid Waste Management

Leachate

Municipal Solid Waste

Cyclic Triaxial Test

Land Fills

Fills (Earthwork)

Mavallipura Landfill

MSW Landfill

Municipal Solid Waste Leachate

Fly Ash

Civil Engineering