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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
11

STUDY OF RESILIENT MODULUS AND GEOTECHNICAL PROPERTIES OF POLYMER STABILIZED HIGH PLASTICITY CLAY

Bhattarai, Sushanta 01 May 2024 (has links) (PDF)
Soil stabilization is a widely used technique in the field of geotechnical engineering for a wide range of applications. Traditional stabilizers such as cement and lime, although very efficient, are not environmentally friendly as they leave major carbon footprints, therefore the demand for sustainable stabilization methods is escalating. This research investigates the potential of two different polymers e.g., a biopolymer derived from organic source, and an inorganic commercially manufactured polymer, as viable alternatives for soil stabilization. The current study focuses on exploring the efficacy of polymers stabilized soil in improving the engineering or geotechnical properties such as plasticity, compressibility, shear strength, and stiffness behavior.The research methodology involves using locally available high plastic clay for stabilization using two different types of polymers and performing laboratory experiments to analyze the strength parameters of the stabilized soil. Xanthan Gum (XG) is a biopolymer which is being studied is used in the percentages of 0.5%, 1.0% and 1.5% by dry weight of soil mass to understand the mechanism of biopolymer-soil interactions and to conclude optimum percentage suitable for stabilization in terms of technical and economical value. Similarly, Soiltac (ST) a vinyl copolymer inorganic polymer is used in 1.5% of dry mass of soil (optimum dosage as per previous literature) to compare its effectiveness with that of Xanthan Gum. After the determination of Atterberg limits and Optimum Moisture Content (OMC) and Maximum Dry Density (MDD), the samples were subjected to tests such as Unconfined Compressive Strength (UCS), Ultrasonic Pulse Velocity (UPV), Resilient Modulus (RM) test and Consolidation test. The prepared UCS samples were cured for 0, 7, 14, and 28 days in open air condition before performing test on them. Atterberg limits test on untreated Carbondale Soil were conducted to classify the soil as CH (Clay with high compressibility) type as per USCS (Unified Soil Classification System) classification. While tests on treated sample showed significant increasement in Liquid Limit (LL), slight increment in Plastic Limit (PL), thus quite surge in the Plasticity Index (PI) with increase in XG percentage in the soil. UCS value increased with the increase in percentage addition of XG. Also, UCS results from both untreated and polymer treated samples showed increase in compressive strength with increase in curing period. UCS value increased from 417.75 psi to 490.24 psi, 504.05 psi, and 542.91 psi for 0.5%, 1.0%, and 1.5% XG addition, respectively. This increase in UCS value was 17.35%, 20.66%, and 29.96% for the corresponding XG concentrations. The treated samples had a significant increase in the UCS for all the curing period in comparison to their respectively cured untreated sample. The percentages increase in the UCS for 1.5% XG sample in comparison to untreated sample cured for the same period is 6.45%, 59.57%, and 29.96%, respectively for 7, 14 and 28 days of curing. However, for the zero-day test, the UCS of 1.5% XG stabilized sample was found to be less than the zero-day untreated sample. With the addition of ST polymer, the UCS value increased for all the curing period while comparing with the UCS of untreated soil for the same curing period. The UCS of the ST treated soil increased from 58.56 psi to 467.367 psi when cured for 0 and 28 days which is an increase of 698.1 % i.e. 7 times the strength at 0 day. When UPV (Ultrasound Pulse Velocity) tests were compared with the UCS value for the same sample, the result showed that the higher UPV value corresponded to the higher UCS value. This relationship was supported by the high degree of correlation between the two measurements. The consolidation test showed that the Compression Index (Cc) of XG stabilized soil decreased as the percentage of XG added increased. Cc decreased from 0.2795 for pure Carbondale Soil (CS) to 0.2003 for 1.5% XG addition which is a drop of 28.33%. Likewise, Cc decreased by 3.0% and 19.33% for 0.5% and 1.0% XG doses respectively. The primary aim of this study is to simplify the understanding of the Resilient Modulus (RM) test, which yields vital data for pavement design. The efficacy of inclusion of stabilizer was further substantiated by RM testing which confirmed the enhancement of soil resilient qualities compared to the untreated soil. The RM values exhibited a growing trend, indicating an enhancement in the soil's stiffness and capacity to endure repetitive loads. This attribute is extremely important for applications such as the construction of pavements and foundations that are subjected to dynamic loads. The samples containing 1.0% XG showed significant increases in their RM values. Specifically, the RM values increased by 18.5%, 40%, and 39.5% after being cured for 7, 14, and 28 days, respectively, at a confining pressure of 6 psi. Similarly, the RM for the case of ST ranges from 15227.60 psi for 0 days of curing and 2 psi of confining stress to 45375 psi for 28 days of curing and 6 psi of confining pressure. The performance of ST against XG is higher.
12

Use of Recycled Asphalt

Ayanda Thembeka Ncube (10783554) 12 May 2021 (has links)
<p>The term Reclaimed Asphalt Pavement (RAP) is used to designate a material obtained from the removal of pavement materials. RAP is used across the US in multiple applications, largely on asphalt pavement layers. RAP can be described as a uniform granular non-plastic material, with a very low percentage of fines. It is formed by aggregate coated with a thin layer of asphalt. It is often used mixed with other granular materials. The addition of RAP to aggregates decreases the maximum dry unit weight of the mixture and decreases the optimum water content. It also increases the Resilient Modulus of the blend, but decreases permeability. RAP can be used safely, as it does not pose any environmental concerns. The most important disadvantage of RAP is that it displays significant creep. It seems that this is caused by the presence of the asphaltic layer coating the aggregate. Creep increases with pressure and with temperature, and decreases with the degree of compaction. Creep can be mitigated by either blending RAP with aggregate or by stabilization with chemical compounds. Fly ash and cement have shown to decrease, albeit not eliminate, the amount of creep. Mechanical stabilizing agents such as geotextiles may also be used.</p><p><br></p><p><br></p>
13

Performance based characterization of virgin and recycled aggregate base materials

Ahmeduzzaman, Mohammad 12 September 2016 (has links)
Characterization of the effect of physical properties on the performance such as stiffness and drainage of unbound granular materials is necessary in order to incorporate them in pavement design. The stiffness, deformation and permeability behaviour of unbound granular materials are the essential design inputs for Mechanistic-Empirical Pavement Design Guide as well as empirical design methods. The performance based specifications are aimed to design, and construct a durable and cost effective material throughout the design life of a pavement. However, the specification varies among jurisdiction depending on the historical or current practice, locally available materials, landform, climate and drainage. A literature review on the current unbound granular materials virgin and recycled concrete aggregate base construction specification has been carried out in this study. Resilient modulus, permanent deformation and permeability tests have been carried out on seven gradations of materials from locally available sources. Resilient modulus stiffness of unbound granular material at two different conditioning stress level have been compared in the study. The long term deformation behaviour has also been characterized from results of the permanent deformation test using shakedown approach, dissipated energy approach and a simplified approach. The results show improvement in resilient modulus and permanent deformation for the proposed specification compared to the currently used materials as a results of reduced fines content, increased crush count and inclusion of larger maximum aggregate size into the gradation. A significant effect of particle packing on permeability of granular materials have also been found, in addition to the effect of fines. / October 2016
14

Módulo de resiliência e vida de fadiga de areia artificialmente cimentada

Venson, Guilherme Irineu January 2015 (has links)
Com o crescimento dos grandes centros urbanos e expansão da ação do homem sobre a natureza, muitos projetos de engenharia se tornam inviáveis devido a inexistência de solos que atendam as solicitações necessárias no local, elevados custos de transporte e excessivos danos ambientais. Uma das alternativas existentes é a melhoria das condições destes solos e entre as múltiplas técnicas para melhoramento encontram-se os solos artificialmente cimentados, os quais têm como uma de suas mais corriqueiras utilizações em campo a resistência a solicitações cíclicas, principalmente na construção de pavimentos, o reforço de áreas suscetíveis a sismos e a fundação de estruturas costeiras. Assim esta pesquisa estuda o comportamento cíclico de uma determinada areia artificialmente cimentada, aferindo sua resistência a compressão simples, módulo cisalhante, sucção e focando nos parâmetros módulo de resiliência e vida de fadiga e busca correlacioná-los com a razão porosidade/teor volumétrico de cimento. Para tanto, foi projetado e construído um equipamento para realização dos ensaios de fadiga e calibrado outro equipamento já existente para execução de ensaios de módulo de resiliência conforme a norma vigente. Em conjunto com os resultados dos ensaios, são apresentadas uma relação de previsão do módulo com base no modelo composto de estado de tensões e correlações satisfatórias dos parâmetros cíclicos obtidos com a razão porosidade/teor volumétrico de cimento, comprovando a possibilidade de seu uso na previsão do comportamento e dosagem deste solo-cimento. / With the growth of large urban centers and expansion of human activities, many engineering projects become infeasible due to the absence of soils that meet the necessary requests on site, high transportation costs and excessive environmental damage. One of the alternatives is to improve the conditions of these soils and, among multiple improvement techniques, the artificially cemented soil is highlighted. This practice has one of its most usual applications on the field to improve materials strength to cyclic loads, especially in pavement designs, reinforcement of areas susceptible to earthquakes and foundations of coastal structures. This research studies the cyclic behavior of a artificially cemented sand, checking its compressive strength, shear modulus, suction and focusing on the resilient modulus and fatigue life parameters. Additionally it seeks to correlate them with the porosity/volumetric cement content ratio. To this end it was designed and built a device for carrying out the fatigue tests and calibrated another existing equipment to run resilient modulus tests according to current standards. Along with the tests results, a modulus prediction relationship is shown based on the composite model of stress state and good correlations of cyclic parameters obtained with the porosity/volumetric content of cement ratio are observed proving the possibility of its use for predicting behavior and dosage of this soil-cement.
15

Effect of Climatic Changes on Subgrade Stiffness

Andrea Ardila Quiroga (7332803) 16 October 2019 (has links)
<p>There is consistent research evidence that shows improvement of the engineering properties of subgrade soils treated with lime or cement. However, limited information is available on the effect of climatic changes on the subgrade stiffness. The thesis studies the effects of changes in soil moisture content and temperature on the resilient modulus of treated and untreated subgrades in Indiana. Two types of soils were tested: A-6 and A-7-6, from two locations in Indiana: Hartford City and Bloomington, respectively. When existing standards ASTM D559/559-15 and ASTM D560/560-16 for wetting/drying (WD) and freezing/thawing (FT) processes, respectively, were followed, the treated and untreated samples failed through the process of preparation due to the stringent procedures in the standards. Appropriate test conditions were investigated, as part of the research, to develop new protocols more appropriate to the field conditions in Indiana. Two new test protocols were developed and successfully applied to the treated soils. A total of 26 resilient modulus, M<sub>R</sub>, tests were conducted following the standard AASHTO T307-99. The M<sub>R</sub> results showed that the repeated action of WD and FT cycles reduced the stiffness of the chemically-treated soils down to values similar to or lower than those of the untreated soils. However, when the amount of chemical was doubled, with respect to the optimum, the M<sub>R</sub> of the treated soils improved over that of the untreated soils, even after the wetting-drying cycles.</p>
16

Evaluation Of Resilient Modulus Estimation Methods For Asphalt Mixtures Based On Laboratory Measurements

Demirci, Canser 01 May 2010 (has links) (PDF)
Resilient modulus is a property for bound and unbound pavement materials characterizing the elastic behavior of materials under dynamic repeated loading. Resilient modulus is an important design parameter for pavement structures because it represents the structural strength of pavement layers through which the thickness design is based on. In Turkey, the layer thickness design is performed using resilient modulus determined empirically from various published sources. Determining a layer modulus using empirical methods causes inaccurate design solutions, which directly affects the structural performance and the overall cost of pavement construction. In this study, the resilient moduli of bituminous mixtures are measured in the laboratory by the indirect tensile test procedure for eight asphalt concrete samples according to NCHRP and ASTM procedures. The measured moduli of samples based on the two procedures are compared with the predicted values calculated from various empirical methods using aggregate and binder properties. An evaluation of each estimation method is presented on the basis of its accuracy level. The results show that the Witczak predictive equation produces the closest estimation to the modulus of samples for both laboratory measurement methods.
17

Resilient modulus and permanent deformation testing of unbound granular materials

Kancherla, Anuroopa 01 November 2005 (has links)
Numerous research efforts have been devoted to characterizing the behavior of granular materials, which is one of the main concerns of pavement engineers. For better understanding of this behavior, laboratory tests where in-situ stress conditions and traffic loads are adequately simulated are needed. This study makes use of an expanded test protocol called a performance test that includes resilient modulus as well as permanent deformation testing. This test protocol determines three nonlinear resilient modulus parameters (k1, k2, k3) and two permanent deformation parameters (?,??). The resilient modulus test results are required inputs in the Level 1 analysis of the proposed American Association of State Highway and Transportation Officials (AASHTO) Pavement Design Guide. In addition, both resilient modulus and permanent deformation test results provide material property inputs to pavement performance prediction models. This study also evaluated the within laboratory repeatability of the performance test and developed a within laboratory precision statement. Further, a statistical analysis was conducted on the test results to estimate the number of test specimens required for testing for specific reliability levels. Two test specimens are required for a reliability level of 15%. A within laboratory study was also conducted to investigate the influence of specimen size on test results. The specimen height was reduced from 12 in. (304 mm) to 8 in. (203 mm), and there was no difference in test results at a confidence level of 95%. The performance test was further used successfully in subsequent studies to evaluate the behavior of granular materials and the influence of various factors on their behavior. As fines content increased, the resilient modulus values decreased and permanent deformation increased. As the moisture content increased, the resilient modulus value decreased and the resistance to permanent deformation decreased. A simplified laboratory measurement tool that is repeatable, relatively cheap and easy to perform might prompt the use of laboratory measured values of resilient modulus in pavement design and facilitate correlation of these values to field measured values on a large scale. Use of measured data for the base properties rather than estimates would insure improved pavement designs and, in many cases, would save money in construction costs.
18

Characterising the Deformation Behaviour of Unbound Granular Materials in Pavement Structures

Rahman, Mohammad Shafiqur January 2015 (has links)
Unbound granular materials (UGMs) used in the base and sub-base layers of flexible pavements play a significant role in the overall performance of the structure. Proper understanding and characterization of the deformation behaviour of UGMs in pavement structures are, therefore, vital for the design and maintenance of flexible pavements. In this study, the resilient deformation (RD) and the permanent deformation (PD) behaviour of UGMs were investigated for the better understanding and improved modelling of these deformation characteristics. The study is based on a series of repeated-load triaxial (RLT) tests carried out on several UGMs commonly used in pavement structures. Here, the influences of stress level and moisture content - two of the most significant factors affecting the deformation behaviour of UGMs - were analysed. The effects of the grain size distribution and the degree of compaction were also considered. The study on the RD behaviour indicated that the resilient stiffness (MR)of UGMs increases with the increased bulk stress level, which can be satisfactorily described by the k-θ model. Moisture was found to negatively impact the MR as long as the deformation was mostly resilient with a negligible amount of accumulated PD. Analysis of the influence of moisture on the parameters k1 and k2 of the k-θ model showed that k1 decreases with increased moisture and k2 is relatively insensitive to moisture. Based on these observations, a simple model was developed for the impact of moisture on MR. The performance of this model was comparable to an existing moisture dependent MR model. In contrast, it was further observed that at the later stages of the RLT tests, after a relatively large number of load applications, the MR increased with increased moisture up to the optimum moisture content. This occurred when the RD was accompanied by a significant amount of PD. Further investigation suggested that moisture aided the post-compaction (PC) and possible particle rearrangement that resulted in the increased PD and increased MR. In this case k1 decreased, whereas k2 increased, with increased moisture. The existing MR-moisture model did not work for this behaviour. This suggests that the effect of PC on MRshould be considered in modelling. However, although not explored in this study, it may be possible to simulate this effect of increase in MR with increased moisture due to PC using the proposed model if k2 is expressed as a function of moisture. The PD characteristics of UGMs were investigated based on the multistage (MS) RLT test. In contrast with the single stage (SS) RLT test, the MS RLT test accounts for the effect of stress history and enables a comprehensive study of the material behaviour under cyclic stresses of various magnitudes. Since the existing PD models cannot be directly applied for the MS loading procedure, a general formulation based on the time hardening concept was derived that can be used to extend the models for the MS loading conditions. Based on this formulation, some of the current models were calibrated and their performance in predicting the PD behaviour in MS RLT tests was compared. The investigation regarding the impact of moisture on PD showed that moisture significantly increases the accumulation of PD. Generally, materials with finer grading showed more sensitivity to moisture with regards to both PD and RD. To characterize the impact of moisture, moisture sensitivity of different grain size distributions and the impact of the degree of compaction on PD with reduced effort, a simple model was proposed. Unlike some of the well-performing existing models, this model can be calibrated using a single MS RLT test without requiring any separate static failure triaxial tests. This model was validated using the MS RLT test data with satisfactory results. The sensitivity of the parameters of this model was studied with respect to moisture content, degree of compaction and grain size distribution. Some reasonable trends for the sensitivity of the parameters to these influential factors were obtained, which suggests that these may be further developed to incorporate into the model. / <p>QC 20150325</p>
19

Pore Water Pressure Response of a Soil Subjected to Traffic Loading under Saturated and Unsaturated Conditions

January 2011 (has links)
abstract: This study presents the results of one of the first attempts to characterize the pore water pressure response of soils subjected to traffic loading under saturated and unsaturated conditions. It is widely known that pore water pressure develops within the soil pores as a response to external stimulus. Also, it has been recognized that the development of pores water pressure contributes to the degradation of the resilient modulus of unbound materials. In the last decades several efforts have been directed to model the effect of air and water pore pressures upon resilient modulus. However, none of them consider dynamic variations in pressures but rather are based on equilibrium values corresponding to initial conditions. The measurement of this response is challenging especially in soils under unsaturated conditions. Models are needed not only to overcome testing limitations but also to understand the dynamic behavior of internal pore pressures that under critical conditions may even lead to failure. A testing program was conducted to characterize the pore water pressure response of a low plasticity fine clayey sand subjected to dynamic loading. The bulk stress, initial matric suction and dwelling time parameters were controlled and their effects were analyzed. The results were used to attempt models capable of predicting the accumulated excess pore pressure at any given time during the traffic loading and unloading phases. Important findings regarding the influence of the controlled variables challenge common beliefs. The accumulated excess pore water pressure was found to be higher for unsaturated soil specimens than for saturated soil specimens. The maximum pore water pressure always increased when the high bulk stress level was applied. Higher dwelling time was found to decelerate the accumulation of pore water pressure. In addition, it was found that the higher the dwelling time, the lower the maximum pore water pressure. It was concluded that upon further research, the proposed models may become a powerful tool not only to overcome testing limitations but also to enhance current design practices and to prevent soil failure due to excessive development of pore water pressure. / Dissertation/Thesis / Ph.D. Civil and Environmental Engineering 2011
20

Desenvolvimento de um equipamento triaxial de grande porte para avaliação de agregados utilizados como camada de pavimentos / Development of triaxial equipment for testing large specimens of unbound aggregates for paving purposes

Malysz, Rodrigo January 2009 (has links)
Camadas granulares desempenham um importante papel no comportamento global de pavimentos, especialmente daqueles com revestimentos delgados ou sem revestimento. Para conhecer as características de resistência e deformabilidade de materiais componentes dessas camadas são realizados ensaios triaxiais. No caso de ensaios em materiais granulares, o corpo de prova deve ter diâmetro de pelo menos cinco vezes o tamanho máximo de partícula e altura igual a duas vezes o seu diâmetro. Como as especificações do DNIT permitem o emprego de agregados de até 5 cm em camadas de brita graduada ou solo-agregado, os corpos-de-prova devem ter diâmetro de 25 cm e altura de 50 cm. Equipamentos capazes de ensaiar corpos-deprova com estas dimensões são raros no mundo e inexistiam no Brasil até 2008. Com o intuito de superar esta carência e avançar no conhecimento do comportamento mecânico de agregados graúdos, a pesquisa relatada nesta tese teve como objetivos desenvolver um equipamento triaxial de grande porte capaz de aplicar carregamentos estáticos, monotônicos e cíclicos em corpos-de-prova de grandes dimensões (25 cm x 50 cm); bem como realizar e interpretar os primeiros ensaios. A concepção e a montagem do equipamento são descritas considerando as partes principais. Também é detalhada a instrumentação utilizada composta por: duas células de carga, três transdutores de deslocamento e dois transmissores de pressão. Para os primeiros ensaios foi escolhida uma brita graduada de basalto, anteriormente utilizada em pistas experimentais solicitadas por simulador de tráfego. Ensaios em corpos-de-prova de 10 cm de diâmetro e 20 cm de altura foram realizados para comparação com resultados de ensaios em corpos-de-prova maiores, realizados no novo equipamento. Os ensaios de módulo de resiliência foram conduzidos segundo o método de ensaio do DNIT, com algumas modificações para adequá-lo ao padrão internacional. Os ensaios triaxiais monotônicos e os cíclicos de deformações permanentes foram conduzidos tanto em multiestágios, quanto em estágio único de tensões. Os resultados obtidos foram interpretados segundo diversas teorias e modelos, obtendo-se parâmetros de resistência e de deformabilidade. Uma análise mecanística utilizando os parâmetros obtidos nos ensaios permitiu analisar o comportamento do material estudado como camada de pavimento. Conclui-se que o equipamento triaxial de grande porte atende as necessidades para as quais foi projetado, permitindo obter parâmetros para caracterização do comportamento de agregados graúdos e prever desempenho de pavimentos, quanto a deformações permanentes e ruptura por cisalhamento de camadas granulares. / Unbound aggregates layers play an important role in the performance of thinly surfaced or unsurfaced pavements. In order to assess the strength-strain characteristics of soils and aggregates used in those layers, triaxial tests must be carried out on cylindrical specimens with diameter not smaller than 5 times the particle maximum size and height twice the diameter. Since Brazil National Roads Department allows using 2” aggregates in granular bases, specimens for triaxial tests should be at least 25 cm in diameter and 50 cm in height. All over the world there are only a few equipments for testing such specimens; and up to 2008 none of them in Brazil. Aiming at overcoming this deficiency and enhance the knowledge on the mechanical behavior of coarse aggregates, the objectives of research reported in this thesis were to develop a triaxial equipment capable of applying static, monotonic and repeated loadings on large specimens (25 cm x 50 cm) and perform and analyze the first tests. The design and assemblage of the equipment are describe, detailing its main components and the instrumentation, that included two load cells, three displacement transducers and two pressure transmitters. The first tests were carried out on specimens made of dense crushed aggregates, formerly used in APT test sections. Tests were also carried out on specimens with 10.0 cm diameter and 20.0 cm height, in order to compare their results to those of tests carried out in larger specimens tested in the new triaxial equipment. Resilient modulus tests were carried out according to the Brazilian standard, but some modifications were introduced to follow international patterns. Triaxial monotonic and repeated loading permanent deformation tests were carried out both in multiple stages and unique stage of stresses. The results were interpreted were calculated taking into account several theories and models, strength and strain parameters being obtained. A mechanistic analysis using parameters obtained in tests allowed analyzing the behavior of the studied aggregates making part of pavement layers. It is concluded the new triaxial equipment for large specimens fulfills the requirements that motivated its design and construction, making possible to obtain parameters for characterizing the behavior of coarse aggregates and estimating pavements performance regarding permanent deformation and shear failure of granular layers.

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