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251	Stabilization Of Expansive Soils By Using Aggregate Waste, Rock Powder And Lime Yesilbas, Gulsah 01 May 2004 (has links) (PDF) Expansive soils are a worldwide problem that poses several challenges for civil engineers. Such soils swell when given an access to water and shrink when they dry out. The most common and economical method for stabilizing these soils is using admixtures that prevent volume changes. In this study the effect of using rock powder and aggregate waste with lime in reducing the swelling potential is examined. The expansive soil used in this study is prepared in the laboratory by mixturing kaolinite and bentonite. Lime was added to the soil at 0 to 9 percent by weight. Aggregate waste and rock powder were added to the soil at 0 to 25 percent by weight. Grain size distribution, Atterberg limits and swell percent and rate of swell of the mixtures were determined. Specimens were cured for 7 and 28 days. This method of treatment caused a reduction in the swelling potential and the reduction was increased with increasing percent stabilizers.
252	Barreiras de solos estabilizados com cal e cimento para proteção ambiental / Soil barriers chemically stabilized with lime and cement to environmental protection Felipe de Campos Loch 16 December 2013 (has links) Este trabalho apresenta a avaliação dos efeitos da estabilização química com cal e cimento na condutividade hidráulica e resistência à compressão de um solo arenoso proveniente da Formação Botucatu (Estado de São Paulo, Brasil), com o objetivo de obter um material menos permeável e mais resistente. O projeto e análise de experimentos foram realizados através de um planejamento fatorial 3², com duas variáveis independentes: teor de umidade e porcentagem de estabilizante, variando em três níveis cada. Foi utilizado cal hidratada CH-III, cimento Portland CP II-Z32 e água fornecida pela concessionária local. Os ensaios de condutividade hidráulica (K) foram executados em permeâmetros de carga constante. Foram realizados ensaios de resistência a compressão simples (RC) após 7 e 28 dias de cura. As amostras de solo estabilizado e natural foram compactadas na energia Proctor Normal. Na avaliação da estrutura das amostras de solo estabilizado verificou-se a alteração da matriz de poros promovida pela adição de cal e cimento. Após a obtenção dos resultados, análises estatísticas possibilitaram avaliar os efeitos das variáveis independentes sobre o K e RC. Pelo método de superfície de respostas foi possível demonstrar o comportamento das misturas e identificar a tendência de alteração das propriedades. As amostras de solo-cimento alcançaram reduções de condutividade hidráulica de até 9,5 x 10-7 m/s e o menor valor experimental de K foi de 1,4 x 10-8 m/s. Os ensaios de RC, com 28 dias de cura, apresentaram acréscimo de resistência de até 5,1 MPa e os resultados obtidos possuem uma variação, aproximadamente, entre 0,1 e 5,1 MPa. O procedimento adotado permitiu avaliar a influência dos fatores e determinar as misturas ótimas para cada estabilizante. / A laboratory study was conducted to evaluate the effects of lime and cement stabilization over the hydraulic conductivity and unconfined compressive strength of a sandy soil from Botucatu Formation (São Paulo State, Brazil) with the intend to generate a less permeable and more resistant material. The experiment was performed using the technique of factorial design 3², with the two independent variables: moisture content and stabilizer percentage, varying on three levels each. Hydraulic conductivity (K) was measured in constant-head permeameters. Unconfined compressive strength (CS) was measured after 7 and 28 days of curing. The samples of stabilized and natural soils were compacted with the normal Proctor energy. The evaluation of the stabilized soil structure verified a pore matrix modification promoted by lime and cement addition. With the results of the characterization, statistical analysis allowed to assess the effects of the variable factors on K and CS. The response surface method was used to demonstrate the hydraulic and compressive strength behavior of the stabilized soil. The soil-cement hydraulic conductivity achieved reductions up to 9.5 x 10-7 m/s and the lowest K experimental value was 1.4 x 10-8 m/s. The compressive strength, with 28 days of curing, presented an increase in CS up to 5.1 MPa and the obtained results showed a range between 0.1 and 5.1 MPa. The adopted experimental procedure allows the assessment of the variables influence and the determination of the optimal mixtures for each stabilizer. Condutividade hidráulica Estabilização química Planejamento fatorial Resistência à compressão simples Solo-cal Solo-cimento Factorial design Hydraulic conductivity Soil stabilization Soil-cement Soil-lime Unconfined compressive strength
253	Contribuição ao estudo da dosagem de cal para a estabilização de um solo de comportamento laterítico e um não laterítico / Contribution to the study to estimate the lime content for stabilization of a lateritic and a non-lateritic soil Alisson Alberto de Lima Medeiros 28 November 2017 (has links) Esta pesquisa teve como objetivo estudar a dosagem de cal para a estabilização de um solo de comportamento laterítico (LG\') e outro não laterítico (NG\'). Para a estabilização foram utilizadas duas cales dolomíticas (CH-I e CH-III) e aplicados dois métodos de dosagem de solo-cal (ASTM D 6276 e o método de Thompson). Os teores de cal indicados pelos métodos foram baixos e não convergiram para o mesmo valor, por isso, para os ensaios mecânicos foram adotados os teores de 5%, 7,5% e 10% de cal. Os corpos de prova de solo-cal foram curados em uma estufa ventilada a uma temperatura controlada de 50°C por 0, 2, 7 e 14 dias. No programa experimental, foram feitas avaliações de propriedades mecânicas, de resistência à compressão simples (RCS), sem e após imersão, e do módulo de resiliência (MR); e avaliações de microestruturas, a partir de imagens de microscopia eletrônica de varredura (MEV) e espectroscopia de energia dispersiva (EDS) e de resultados de difração de raios X (DRX). Os resultados do estudo das propriedades mecânicas mostraram que: (i) com o teor de cal adequado as misturas solo-cal apresentaram importantes incrementos de resistência, sendo que após 14 dias de cura, as RCS aumentaram 3,5 a 4 vezes para as misturas NG\'+10% CH-I e LG\'+10% CH-I, respectivamente; (ii) houve manutenção de uma parcela de RCS mesmo após imersão em água (por 4h), o que foi atribuído à ocorrência das reações cimentantes; (iii) a adição de cal aumentou o MR do solo independente do tipo e do teor de cal empregado e mudou o comportamento resiliente da mistura, que passou a se comportar como material granular. Com relação à análise da microestrutura, pode-se constatar (iv) mudança de textura do solo e formação de compostos cimentantes, a partir das imagens de MEV; (v) alterações na composição química das misturas ao longo do período de cura, como notado nos resultados de EDS; e (vi) a formação de novos picos nos difratogramas dos materiais, evidenciando a formação de novos compostos minerais. As misturas estudadas nessa pesquisa, no geral, mostraram bons resultados após a estabilização e ainda que podem ser usadas como camadas de pavimentos se a dosagem for feita de maneira adequada. / This research aimed to study the lime content for stabilization of a lateritic (LG\') and a non-lateritic (NG\') soil. For the stabilization, two dolomitic limes (CH-I and CH-III) were used and two soil-lime procedures to estimate de lime content were applied (ASTM D 6276 and Thompson\'s method). The lime contents indicated by the methods were low and did not converge to the same value, therefore, for the mechanical tests were adopted the lime contents of 5%, 7.5% and 10% of lime. Soil-lime samples were cured in an air circulated oven at a controlled temperature of 50°C for 0, 2, 7 and 14 days. In the experimental program, evaluations of mechanical properties, unconfined compressive strength (UCS), without and after immersion in water, and the resilience modulus (RM) were evaluated; reviews of microstructures, images from scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) and results of X-ray diffraction (XRD) were analysed. The results of the mechanical properties showed that: (i) with the appropriate lime content, the soil-lime mixtures presented significant increases in strength, and after 14 days of cure, the UCS increased by 3.5 to 4 times for the mixtures NG\'+ 10% CH-I and LG\' + 10% CH-I, respectively; (ii) there was maintenance of a UCS portion even after immersion in water (for 4 h), which was attributed to the occurrence of cementing reactions; (iii) addition of lime increased the RM of the soil independent of the type and lime content applied and changed the resilient behavior of the mixture, which behave as a granular material. Regarding the analysis of the microstructure, we can verify (iv) change of soil texture and formation of cementing compounds, from SEM images; (v) changes in the chemical composition of the mixtures over the curing period, as noted in the EDAX results; and (vi) the formation of new peaks in the diffractograms of the materials, evidencing the formation of new mineral compounds. The mixtures studied in this research, in general, showed good results after stabilization and that can be used as layers of pavements if the properly content of lime is applied. Dosagem solo-cal Estabilização de solos Método de Thompson Método do pH Solos tropicais pH method Soil stabilization Soil-lime design Thompson's method Tropical soils
254	Estudo do comportamento mecânico de dois solos lateríticos do Estado de São Paulo com adição de emulsão asfáltica / Study of the mechanical performance of two lateritics soils from the State of São Paulo when mixed with asphalt emulsion David Alex Arancibia Suárez 13 February 2009 (has links) O objetivo principal desta dissertação é determinar, a partir de ensaios de laboratório, o comportamento mecânico de misturas constituídas com solos lateríticos arenoso e argiloso e emulsão asfáltica, visando a sua utilização na construção rodoviária. Utilizou-se na compactação a energia normal do Proctor, e analisaram-se os efeitos do tipo de solo, o teor e tipo de emulsão, tipo de cura pré e pós-compactação, tempo de cura e a imersão em água na resistência e rigidez das misturas. Foram realizados ensaios para a determinação da resistência à compressão simples, resistência à compressão diametral, módulo de resiliência, índice de suporte Califórnia e variação volumétrica durante a cura e imersão dos corpos-de-prova. Os resultados mostraram que as misturas com emulsão apresentaram resistência e rigidez superiores às dos solos in natura, e ainda menores variações volumétricas decorrentes da secagem e da imersão dos corpos-de-prova em água. Finalmente, concluiu-se que o uso das emulsões asfálticas é promissora na área de pavimentação, dado que proporciona às misturas propriedades físicas e mecânicas para estas serem aplicáveis na construção rodoviária. / This work has the main objective of studying, based on laboratory tests, the mechanical behavior of sand and clay lateritics soils and the asphalt emulsion in focus mixtures, seeking their utilization in road construction. Were compacted at the normal Proctor energy, analyzing the soil type, the asphaltic emulsion rate and type, the curing pre and pos- compactation, the curing time and the effect of the immersion in water to the mixtures strength and rigidity, afterwards they were submitted to tests to the determination of unconfined compressive strength, indirect tensile strength, modulus resilient, California bearing ratio and volumetric variability of specimens when immersed in water. The results showed that the addition of asphaltic emulsion to soils improve the strength and rigidity of in natura and reduction of the volumetric variability caused by drying and immersion in water soils. Finally, it concludes that bituminous emulsion provides to soils qualities that could be qualified for use in road construction. Comportamento mecânico Emulsão asfáltica Estabilização de solos Solo-emulsão Solos lateríticos Asphalt emulsions Lateritics soils Mechanic behavior Pavements Soil stabilization Soil-emulsion
255	Improvement Of Strength Of Soils At High Water Content Using Pozzolanic Materials Narendra, B S 07 1900 (has links) (PDF) No description available. Soil Content Pozzolanic Materials Soil - Strength Soft Soils Soil - Stabilization Cement Treated Soils Stabilized Soils Fly Ash Unconfined Compressive Strength Structural Engineering
256	Analysis And Prediction Of Compaction Characteristics Of Soils - An Integrated Approach Manoj, M 03 1900 (has links) (PDF) No description available. Soil Mechanics Soils - Compressibility Soil Dynamics Soil Stabilization Soil Compaction Fine Grained Soils Field Compaction Compaction Characteristics Cohesive Soils Structural Engineering
257	Pozzolanic Additives To Control Dispersivity Of Soil Pratibha, R 12 1900 (has links) (PDF) The aim of the present investigation is to improve the geotechnical properties of dispersive soil by reducing their dispersivity after elucidating the important mechanisms controlling the dispersivity of the soils. Dispersive soils have unique properties, which under certain conditions deflocculate and are rapidly eroded and carried away by water flow. These soils are found extensively in the United States, Australia, Greece, India, Latin America, South Africa and Thailand. The mechanism of dispersivity of soils is a subject matter of great interest for geotechnical engineers. In the earlier days clays were considered to be non erosive and highly resistant to water erosion. However, recently it was found that highly erosive clay soils do exist in nature. Apart from clayey soil, dispersivity is also observed in silty soils. The tendency of the clays to disperse or deflocculate depends upon the mineralogy and soil chemistry and also on the dissolved salts in the pore water and the eroding water. Such natural dispersive soils are problematic for geotechnical engineers. They are clayey soils which are highly susceptible to erosion in nature and contain a high percentage of exchangeable sodium ions, (Na+). It is considered that the soil dispersivity is mainly due to the presence of exchangeable sodium present in the structure. When dispersive clay soil is immersed in water, the clay fraction behaves like single-grained particles; that is, the clay particles have a minimum of electrochemical attraction and fail to closely adhere to, or bond with, other soil particles. This implies that the attractive forces are less than the repulsive forces thus leading to deflocculation (in saturated condition).This weakens the aggregates in the soil causing structural collapse. Such erosion may start in a drying crack, settlement crack, hydraulic fracture crack, or other channel of high permeability in a soil mass. Total failure of slopes in natural deposits is initiated by dispersion of clay particles along cracks, fissures and root holes, accelerated by seepage water. For dispersive clay soils to erode, a concentrated leakage channel such as a crack (even a very small crack) must exist through an earth embankment. Erosion of the walls of the channel then occurs along the entire length at the same time. Many slope and earth dam failures have occurred due to the presence of dispersive soils. Unlike erosion in cohesionless soils, erosion in dispersive clay is not a result of seepage through the pores of clay mass. However, the role of type of clay and its Cation exchange capacity in the dispersion of soil is not well understood. Data on the presence, properties, and tests for identification of dispersive clays is scarce. Hence, an attempt is made, in this thesis, to develop reliable methods to identify these soils and understand the extent of their dispersivity as well as to develop methods to control their dispersivity. The present study deals with the characterization of a local dispersive soil collected from southern part of Karnataka State. This study has focused on comprehensive tests to assess the dispersivity of the soils by different methods and to methods to improve geotechnical properties by reducing the dispersivity of the soil. An attempt is made to reduce the dispersivity of soil by using calcium based stabilizers such as lime, cement and fly ash. The mechanism of improvement in reducing the dispersivity of the soil with calcium based stabilizers has been studied. One of the important mechanism by which the dispersivity of the soil is reduced is by inducing cementation of soil particles. The differences in effectiveness of different additives are due to their differences in abilities to produce cementitious compounds. Although all the additives increased the strength of the soil and reduced the dispersivity of the soil, cement was found to significantly reduce the dispersivity of the soil, compared to the other two additives lime and fly ash. Cement is more effective as sufficient cementitious compounds are produced on hydration without depending on their formation. A detailed review of literature on all aspects connected with the present study is given in Chapter 2. A comprehensive description of dispersive soils present worldwide has been brought out in this section. Based on this survey, the scope of the present investigation has been elaborated at the end of the chapter. To understand the reasons for dispersivity of the soil and to estimate its degree of dispersivity, it is essential to assess standard methods to characterize the soil. Chapter 3 presents a summary of material properties and testing programs. The results of geotechnical characterization of the soil, the index properties of the soilspecific gravity, sieve analysis, Atterberg’s limits are discussed in Chapter 4. The physico chemical characteristics play an important role in determining the amount of dispersivity of the soil. Dispersive soils have two main characteristics which define its dispersivity chemically. These are Sodium Adsorption Ratio (S.A.R) and Exchangeable Sodium Percentage (E.S.P). The two characteristics are determined from the Cation exchange capacity of the soil. Exchangeable Sodium Percentage is defined as the concentration of sodium ions present in the soil with respect to the Cat ion exchange capacity of the soil. And Sodium Adsorption Ratio is used to quantify the free salts present in the pore water. Since Atterberg’s limits and grain size analysis do not help in identifying dispersive soils or in quantifying its dispersivity, two other tests- Emerson Crumb test and double hydrometer test were carried out on the soil. Emerson crumb test is a simple way for identification of dispersive soils. In this test, a crumb of soil measuring about 1mm diameter is immersed in a beaker containing distilled water and the subsequent reaction is observed for 5 minutes. It is solely based on direct qualitative observations. Depending on the degree of turbidity of the cloud formed in the beaker, the soil is classified in one of the four levels of dispersion in accordance with ASTM-D6572. Since this test is mainly a qualitative test and does not help in quantifying the dispersivity, it cannot be depended upon completely in identifying a dispersive soil. Another test double hydrometer test, which helps in quantifying the dispersivity of the soil, was also conducted on the soil. This test involves in conducting the particle size distribution using the standard hydrometer test in which the soil specimen was dispersed in distilled water with a chemical dispersant. A parallel hydrometer test was conducted on another soil specimen, but without a chemical dispersant. The dispersing agent used for the experiment was sodium hexametaphosphate. The percent dispersion is the ratio of the dry mass of particles smaller than 0.005 mm diameter of the test without dispersing agent to the test with dispersing agent expressed as a percentage. The double hydrometer test was carried out according to Double Hydrometer Test (ASTM D4221). Apart from the conventional tests, attempts are made to consider shrinkage limit test and unconfined compression test to determine the dispersivity of the soil. For this purpose, the shrinkage limit of the soil was determined with and without dispersing agent. The initial shrinkage limit of the untreated soil reduced on treating it with dispersing agent, thus indicating that the soil had further dispersed on addition of dispersing agent. In order to carry out the unconfined compression strength, the maximum dry density and optimum moisture content was determined through the compaction test. The soil was then treated with dispersing agent and compacted at the optimum moisture content. The soil exhibited high degree of dispersion through the strength test. Hence it is necessary to stabilize the soil with additives. Detailed experimental program has been drawn to find methods to improve the geotechnical properties and to reduce the dispersivity of the soil. Chapter 5 presents the investigations carried out on the dispersive soil with lime. The importance of lime stabilization and the mechanism of lime stabilization have been discussed initially. Commercially obtained hydrated lime was used in the present study. The soil was treated with three different percentages of lime 3, 5 and 8. The curing period was varied from one day to twenty eight days. The effect of addition of lime on various properties of the soil such as pH, Atterberg’s limits, compaction test and unconfined compression test is elaborated in chapter 5. The pH of the soil was maximum on addition of 3% lime. On further addition, the pH decreased and remained constant. The liquid limit of the soil increased on adding 3% lime and decreased with further lime content. The compaction test conducted on the soil showed an increase in maximum dry density of the soil and reduction in optimum moisture content with 3% lime content. On further increase in the lime content, the soil showed a decrease in the maximum dry density and increase in optimum moisture content. The unconfined compressive strength of the soil also increased on increasing lime content upto 5%. The variation in strength of the soil with respect to curing period was also compared. Optimum lime content arrived at based on the above conducted tests was 3%. The effect of lime in reducing the dispersivity of the soil through shrinkage limit test and unconfined compression test is also presented in this chapter. Details of the efforts made on the soil with fly ash are presented in Chapter 6.The fly ash used for stabilization of Suddha soil was of Class F type. This type of fly ash contains low reactive silica and lime. The effect of varying fly ash content on the properties of Suddha soil by varying the percentage of fly ash from 3 to 10 percentages is discussed in this chapter. The tests conducted on fly ash treated Suddha soil were pH test, compaction test, Atterberg’s limits and unconfined compression test with varying curing period. The fly ash treated Suddha soil was cured from one day to twenty eight days for the unconfined compressive strength analysis. The pH of the soil system increased with increasing percentage of fly ash. The increase in liquid limit was marginal on addition of fly ash. The maximum dry density of fly ash treated Suddha soil decreased continuously and the optimum moisture content of the treated soil increased with increasing fly ash content. The unconfined compressive strength of Suddha soil increased with increase in fly ash content upto 8% and then decreased for fly ash content of 10%. For all the percentages of fly ash added, the strength of the soil increased with increase in the curing period. The effect of fly ash in reducing the dispersivity of the soil was carried out using shrinkage limit and unconfined compression test. It was seen that on increasing the fly ash content, the soil treated with dispersing agent showed an increase in the shrinkage limit. Also, the same trend was observed for the unconfined compression strength to determine dispersivity. Optimum fly ash was determined as 8% with the help of all the tests conducted on the soil. Since the improvement in the properties of the soil with lime and fly ash was not very high, Cement was also considered as another additive used for stabilization of Suddha soil. It is known that soil with lesser amount of clay content will respond well with cement. The effect of cement addition on various properties of Suddha soil has been brought out in Chapter 7. It was found that addition of cement had positive effects on all the properties of Suddha soil. The pH of the soil increased for all the percentages of cement addition. The liquid limit of the soil increased on increasing the cement content. The shrinkage limit also showed a similar trend. The optimum moisture content of the soil decreased on increasing the cement content for Suddha soil and the maximum dry density increased for cement treated Suddha soil. The soil showed the maximum dry density at 8% cement content. The unconfined compression strength conducted on cement treated Suddha soil increased significantly for higher cement contents and also with curing period. Suddha soil when treated with 8% cement content exhibited maximum strength in comparison to other percentages. Also, the effect of cement in reducing the dispersivity of the soil was carried out using shrinkage limit and unconfined compression test. The shrinkage limit of the soil increased for all percentages of cement content, even in the presence of dispersing agent. Through the unconfined compression strength for dispersivity, it could be seen that 8% cement treated Suddha soil had the least dispersion. Optimum cement content was derived as 8% with the help of the tests conducted on the soil. A comparison of effect of all the additives on the strength of the soil as well as effect of the additives in reducing the dispersivity of the soil is discussed in Chapter 8. The effect of additives on the shrinkage limit of the soil with and without dispersing agent has been compared. The variation in shrinkage limit of the soil when treated with the additives was due to the different mechanisms involved in reducing the dispersivity by each additive. The effect on the unconfined compression strength of the soil treated with the additives with and without dispersing agent is also brought out in this chapter. It was noted that the dispersion exhibited through shrinkage limit test was lesser as compared to the percentage dispersivity exhibited through unconfined compression test. Hence it could be said that dispersion of the soil is due to loss of cohesion than volume change behavior. Also, the unconfined compression strength of the soils with respect to curing period is compared. The percentage dispersivity calculated through these tests is summarized and compared. With the help of this it could be said that to control the dispersivity of the soil, it is necessary to enhance the strength of the soil. The general summary and major conclusions drawn from the thesis are presented in Chapter 9. Dispersive Soils Suddha Soil Soil Stabilization Soil Dispersivity Lime Stabilization Fly Ash Stabilization Cement Stabilization Pozzolanic Additives Soil Mechanics Dispersive Soil Structural Engineering
258	Estudo do comportamento mecânico de dois solos lateríticos do Estado de São Paulo com adição de emulsão asfáltica / Study of the mechanical performance of two lateritics soils from the State of São Paulo when mixed with asphalt emulsion Arancibia Suárez, David Alex 13 February 2009 (has links) O objetivo principal desta dissertação é determinar, a partir de ensaios de laboratório, o comportamento mecânico de misturas constituídas com solos lateríticos arenoso e argiloso e emulsão asfáltica, visando a sua utilização na construção rodoviária. Utilizou-se na compactação a energia normal do Proctor, e analisaram-se os efeitos do tipo de solo, o teor e tipo de emulsão, tipo de cura pré e pós-compactação, tempo de cura e a imersão em água na resistência e rigidez das misturas. Foram realizados ensaios para a determinação da resistência à compressão simples, resistência à compressão diametral, módulo de resiliência, índice de suporte Califórnia e variação volumétrica durante a cura e imersão dos corpos-de-prova. Os resultados mostraram que as misturas com emulsão apresentaram resistência e rigidez superiores às dos solos in natura, e ainda menores variações volumétricas decorrentes da secagem e da imersão dos corpos-de-prova em água. Finalmente, concluiu-se que o uso das emulsões asfálticas é promissora na área de pavimentação, dado que proporciona às misturas propriedades físicas e mecânicas para estas serem aplicáveis na construção rodoviária. / This work has the main objective of studying, based on laboratory tests, the mechanical behavior of sand and clay lateritics soils and the asphalt emulsion in focus mixtures, seeking their utilization in road construction. Were compacted at the normal Proctor energy, analyzing the soil type, the asphaltic emulsion rate and type, the curing pre and pos- compactation, the curing time and the effect of the immersion in water to the mixtures strength and rigidity, afterwards they were submitted to tests to the determination of unconfined compressive strength, indirect tensile strength, modulus resilient, California bearing ratio and volumetric variability of specimens when immersed in water. The results showed that the addition of asphaltic emulsion to soils improve the strength and rigidity of in natura and reduction of the volumetric variability caused by drying and immersion in water soils. Finally, it concludes that bituminous emulsion provides to soils qualities that could be qualified for use in road construction. Asphalt emulsions Comportamento mecânico Emulsão asfáltica Estabilização de solos Lateritics soils Mechanic behavior Pavements Soil stabilization Soil-emulsion Solo-emulsão Solos lateríticos
259	Water Vapor Movement in Freezing Aggregate Base Materials Rogers, Maile Anne 18 December 2013 (has links) The objectives of this research were to 1) measure the extent to which water vapor movement results in water accumulation in freezing base materials; 2) evaluate the effect of soil stabilization on water vapor movement in freezing base materials; 3) determine if the corresponding changes in water content are sufficient to cause frost heave during winter; 4) determine if the corresponding changes in water content are sufficient to cause reductions in stiffness during spring; 5) evaluate relationships between selected material properties, freezing conditions, and the occurrence and impact of water vapor movement; and 6) numerically simulate heat and water movement in selected pavement design scenarios. The research involved extensive laboratory and field testing, statistical analyses, and numerical modeling. The results of the laboratory testing, which included gradations, Atterberg limits, soil classifications, specific gravity and absorption values, electrical conductivity values, moisture-density relationships, soil-water characteristic curves, moisture-stiffness curves, hydraulic conductivity values, and frost susceptibility assessments, were used to characterize each material and enable subsequent statistical analyses. Testing of both treated and untreated materials enabled investigation of a wide variety of material properties. The results of the field testing, which included temperature, moisture content, water potential, elevation, and stiffness data over time, provided the basis for comparing pavement sections with and without capillary barriers and established the framework for numerical modeling. In a pavement section with a capillary barrier underlying the base layer, water vapor movement from the subgrade through the capillary barrier may be expected to increase the water content of the base layer by 1 to 3 percent during a typical winter season in northern Utah for base materials similar to those studied in this research. During winter, cold temperatures create an ideal environment for water vapor to travel upward from the warm subgrade soil below the frost line, through the capillary barrier, and into the base material. Soil stabilization can lead to increased or decreased amounts of water vapor movement in freezing base materials depending on the properties of the stabilized soil, which may be affected by gradation, mineralogy, and stabilizer type and concentration. Accumulation of water from long-term water vapor movement into frost-susceptible base materials underlain by a capillary barrier can lead to frost heave of the base layer as it approaches saturation, as water available in the layer can be redistributed upwards to create ice lenses upon freezing. However, the incremental increase in total water content that may occur exclusively from water vapor movement during a single winter season in northern Utah would not be expected to cause measurable increases in thaw weakening of the base layer during spring. Because water in a base layer overlying a capillary barrier cannot drain until nearly reaching positive pore pressures, the base layer will remain indefinitely saturated or nearly saturated as demonstrated in this research. For materials similar to those studied in this research, potentially important material properties related to the occurrence of water vapor movement during freezing include dry density, percent of material finer than the No. 200 sieve, percent of material finer than 0.02 mm, apparent specific gravity, absorption, initial water content, porosity, degree of saturation, hydraulic conductivity, and electrical conductivity. The rate at which water vapor movement occurs is also dependent on the thermal gradient within the given material, where higher thermal gradients are associated with higher amounts of water vapor movement. The numerical modeling supported the field observations that the capillary barrier effectively trapped moisture in the overlying base material, causing it to remain saturated or nearly saturated throughout the monitoring period. Only non-frost-susceptible aggregate base materials should be specified for use in cold climates in conjunction with capillary barriers, and the base material in this case should be assumed to remain in a saturated or nearly saturated condition during the entire service life of the pavement. Further study is recommended on water vapor movement in freezing aggregate base materials. aggregate base material capillary barrier cement treatment water vapor freezing frost heave pavement SHAW model soil stabilization soil-water characteristic curve Civil and Environmental Engineering
260	Análisis experimental de las características mecánicas de la subrasante arcillosa del camino vecinal N° SM-707 Tarapoto – San Francisco de Río Mayo estabilizada con 3% de cal tras la adición de Cenizas de Cáscara de Arroz (CCA) Vizcarra Arapa, Santiago, Lujan Cabrera, Ismael Lorenzo 20 May 2021 (has links) Existen estudios sobre las mejoras mecánicas que le brinda la adición de cal y Ceniza de Cáscara de Arroz (CCA) a los suelos arcillosos -naturalmente plásticos- con más de 70% de material fino en su composición. Sin embargo, para el comportamiento de arcillas arenosas, cuyo porcentaje de granos gruesos en su estructura superan el 40%, hacen falta más referencias. En la investigación se evalúa la influencia de la adición de CCA a esta clase de suelo, estabilizado con 3% de cal. El suelo estabilizado (sin CCA) incrementó 11.2 veces su valor de CBR natural; al agregarle la adición, el CBR incrementó solo en 1.56%. Al adicionarle 28% de CCA se observó un decrecimiento en su resistencia. Por otro lado, según la clasificación AASHTO, la trabajabilidad del suelo estabilizado fue mejorando a medida que se incrementó la adición de CCA, llegando a valores de IG=0. La mejor performance del suelo estabilizado se obtuvo con 16% de CCA, alcanzando 51.3% de CBR, 1.65g/cm3 de MDS y 15.8% de OCH. El CBR de este suelo estabilizado con cal y con la adición de CCA no proyecta mejoras mecánicas sustanciales, por más que demuestre una mejor trabajabilidad, la estabilización con cal de este tipo de suelos resulta suficiente para una buena performance. / There are many studies about how the addition of lime and Rice Husk Ash (RHA) gives the soil a better mechanical behavior, particularly on clayey soils, where usually fine particles reach more than 75%. However, the soils with a small presence of fine particles (59-60%) do not have much research. This investigation evaluates the influence that RHA has on this kind of soil previously stabilized with 3% of lime. After the initial mix of soil-lime, the CBR increased 11.2 times its initial value; within the addition of the ash, the CBR maxed out its value increasing just 1.56%. When 28% of RHA was added, a decay in the value of CBR was noticed. Otherwise, soil workability improved and following the AASHTO standards, the specimens with more ash resulted in a more granular material, with a group index value of 0. The greatest CBR record was obtained when the stabilized soil was added a 16% RHA, reaching a 51.3% CBR, 1.58g/cm3 of MDD and 16.5% of OMC. The CBR of the soil stabilized with lime and the addition of RHA, does not shows substantial improvement, and beyond that the workability seems better, the addition of lime by itself should be enough for an adequate performance for silica-rich clayey soils. / Tesis Estabilización de suelos Arcilla Ceniza de cáscara de arroz Soil stabilization Clay Rice husk ash

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