Global ETD Search

1	Application of Fatigue Theories to Seismic Compression Estimation and the Evaluation of Liquefaction Potential Lasley, Samuel James 21 August 2015 (has links) Earthquake-induced liquefaction of saturated soils and seismic compression of unsaturated soils are major sources of hazard to infrastructure, as attested by the wholesale condemnation of neighborhoods surrounding Christchurch, New Zealand. The hazard continues to grow as cities expand into liquefaction- and seismic compression-susceptible areas hence accurate evaluation of both hazards is essential. The liquefaction evaluation procedure presented herein is based on dissipated energy and an SPT liquefaction/no-liquefaction case history database. It is as easy to implement as existing stress-based simplified procedures. Moreover, by using the dissipated energy of the entire loading time history to represent the demand, the proposed procedure melds the existing stress-based and strain-based liquefaction procedures in to a new, robust method that is capable of evaluating liquefaction susceptibility from both earthquake and non-earthquake sources of ground motion. New relationships for stress reduction coefficient (r_d) and number of equivalent cycles ($n_{eq}$) are also presented herein. The r_d relationship has less bias and uncertainty than other common stress reduction coefficient relationships, and both the $n_{eq}$ and $r_d$ relationships are proposed for use in active tectonic and stable continental regimes. The $n_{eq}$ relationship proposed herein is based on an alternative application of the Palmgren-Miner damage hypothesis, shifting from the existing high-cycle, low-damage fatigue framework to a low-cycle framework more applicable to liquefaction analyses. Seismic compression is the accrual of volumetric strains caused by cyclic loading, and presented herein is a "non-simplified" model to estimate seismic compression. The proposed model is based on a modified version of the Richart-Newmark non-linear cumulative damage hypothesis, and was calibrated from the results of drained cyclic simple shear tests. The proposed model can estimate seismic compression from any arbitrary strain time history. It is more accurate than other "non-simplified" seismic compression estimation models over a greater range of volumetric strains and can be used to compute number-of-equivalent shear strain cycles for use in "simplified" seismic compression models, in a manner consistent with seismic compression phenomenon. / Ph. D. earthquakes dissipated energy liquefaction Fatigue seismic compression
2	Development of an Energy-based Liquefaction Evaluation Procedure Ulmer, Kristin Jane 20 January 2020 (has links) Soil liquefaction during earthquakes is a phenomenon that can cause tremendous damage to structures such as bridges, roads, buildings, and pipelines. The objective of this research is to develop an energy-based approach for evaluating the potential for liquefaction triggering. The current state-of-practice for the evaluation of liquefaction triggering is the "simplified" stressbased framework where resistance to liquefaction is correlated to an in situ test metric (e.g., normalized standard penetration test N-value, N1,60cs, normalized cone penetration tip resistance, qc1Ncs, or normalized small strain shear wave velocity, Vs1). Although rarely used in practice, the strain-based procedure is commonly cited as an attractive alternative to the stress-based framework because excess pore pressure generation (and, in turn, liquefaction triggering) is more directly related to strains than stresses. However, the method has some inherent and potentially fatal limitations in not being able to appropriately define both the amplitude and duration of the induced loading in a total stress framework. The energy-based method proposed herein builds on the merits of both the stress- and strain-based procedures, while circumventing their inherent limitations. The basis of the proposed energy-based approach is a macro-level, low cycle fatigue theory in which dissipated energy (or work) per unit volume is used as the damage metric. Because dissipated energy is defined by both stress and strain, this energy-based method brings together stress- and strain-based concepts. To develop this approach, a database of liquefaction and nonliquefaction case histories was assembled for multiple in situ test metrics. Dissipated energy per unit volume associated with each case history was estimated and a family of limit-state curves were developed using maximum likelihood regression for different in situ test metrics defining the amount of dissipated energy required to trigger liquefaction. To ensure consistency between these limit-state curves and laboratory data, a series of cyclic tests were performed on samples of sand. These laboratory-based limit-state curves were reconciled with the field-based limit-state curves using a consistent definition of liquefaction. / Doctor of Philosophy / Soil liquefaction during earthquakes is a phenomenon that can cause tremendous damage to structures such as bridges, roads, buildings, and pipelines. The objective of this research is to develop an energy-based approach for evaluating the potential for liquefaction triggering. Current procedures to evaluate liquefaction triggering include stress-based and strain-based procedures. However, these procedures have some inherent and potentially fatal limitations. The energy-based method proposed herein builds on the merits of both the stress- and strain-based procedures, while circumventing their inherent limitations. The proposed energy-based approach uses dissipated energy (or work) per unit volume to evaluate the potential for liquefaction. Because dissipated energy is defined by both stress and strain, this energy-based method brings together stress- and strain-based concepts. To develop this approach, a database of case histories in which liquefaction was either observed or not observed was assembled. Dissipated energy per unit volume associated with each case history was estimated and a family of relationships was regressed to define the amount of dissipated energy required to trigger liquefaction. Results from a series of cyclic laboratory tests performed on samples of sand were reconciled with the field-based relationships using a consistent definition of liquefaction. This research proposes a method that is based on a robust mechanistic framework that will make it easier to evaluate liquefaction for circumstances that are not well represented in current liquefaction evaluation procedures. The components of the proposed energy-based procedure are developed consistently and are presented in such a way that this procedure can be readily adopted by practitioners who are already familiar with existing liquefaction evaluation procedures. The broader impacts of this work will help to minimize losses from earthquakes by improving the way engineers evaluate liquefaction. earthquakes liquefaction dissipated energy cyclic direct simple shear
3	Impact des défauts géométriques sur l'amortissement dans les assemblages / Impact of geometrical defects on damping in assemblies Bouchaala, Noussa 17 January 2014 (has links) Cette thèse porte sur la quantification de l’énergie dissipée ainsi que l’amortissement induit par les micro-glissements dans les interfaces constituant les assemblages mécaniques en présence du défaut géométrique. Le mémoire est composé de quatre chapitres traitant la problématique tant du point de vue analytique qu’expérimental. Un modèle rhéologique de contact basé sur les hypothèses de Greenwood et Williamson est développé afin de prendre en compte les défauts géométriques à l’interface du contact. L’énergie dissipée ainsi que l’amortissement induit par les micro-glissements entre deux surfaces rugueuses soumises à un effort normal constant et un déplacement tangentiel allant du glissement partiel jusqu’au glissement total sont déterminés. Afin de valider et discuter le modèle développé on a considéré un montage expérimental composé d’un tribomètre installé sur la machine MTS 830. Afin de révéler le phénomène de dissipation d’énergie entre deux surfaces nominalement planes soumises à un effort normal statique et une rotation alternée, un second banc d’essai est dimensionné et réalisé. Le montage est constitué de deux poutres assemblées par un boulon et excitées par un pot vibrant. Le modèle rhéologique de contact développé dans le premier partie est étudiée dans le cas où les deux surfaces en contact soumises à une charge normal statique et une rotation alternée dynamique. / This thesis focuses on the quantification of energy dissipation and damping induced by microslipping in interfaces constituent assemblies in the presence of geometric defect. The thesis contains four chapters examining this problem from both analytical and experimental viewpoints. A rheological contact model based on the assumptions of Greenwood and Williamson is developed to take into account the geometrical defects at the interface of contact. The energy dissipated and damping induced by micro-slipping between two rough surfaces subjected to a constant normal force and tangential displacement ranging from partial slip to total slip are determined. To validate and discussed the developed model we considered an experimental setup consisting of a tribometer installed on the MTS 830 machine. To reveal the phenomenon of energy dissipation between two nominally flat surfaces subjected to a static axial force and an alternating rotation, a second test bench is designed andrealized. The experimental setup consists of two beams assembled by bolt and excited by a shaker. The rheological contact model developed in the first part is studied in the case where the two contact surfaces subjected to a normal static and dynamic load alternating rotation. Energie dissipée Amortissement Modèle rhéologique de contact Dissipated energy Damping Rheological contact model
4	Comprehensive Evaluation of Permanent Deformation Behavior for Asphalt Mixtures under High Stresses Saqer, Hamzeh 23 September 2019 (has links) No description available. Civil Engineering Geotechnology Transportation Rutting airport mix dissipated energy polymer-modified asphalt GTR
5	Simulation expérimentale de l'usure du contact aube-disque de compresseur sous sollicitations de fretting Mary, Caroline 25 September 2009 (has links) Lors du fonctionnement d'un turboréacteur, la rotation de l'axe du moteur induit une force centrifuge qui plaque les aubes contre les alvéoles du disque, le long de surfaces appelées « portées ». Au cours de la vie du moteur, des micro-glissements (« fretting ») sont générés au niveau des portées. Ce travail de thèse s'intéresse aux endommagements de type oligocyclique des portées aube/ disque du compresseur Haute Pression (HP) d'un turboréacteur civil. Afin de réduire le frottement et de protéger les pièces, les portées des aubes sont revêtues d'un dépôt épais de CuNiln sur lequel est appliqué un lubrifiant solide. Le système est soumis à des pressions fortes (600MPa) et à des températures élevées (500°C). Des expertises sur pièces ont permis d'identifier des usures importantes et des phénomènes de transfert. Pour simuler expérimentalement le contact, un moyen d'essai de fretting usure en température a été développé dans le cadre de cette thèse. A partir d'une géométrie de contact échelle 1 simplifiée, choisie pour représenter les champs de chargement moteur, le domaine des sollicitations a été balayé et les comportements tribologiques identifiés et caractérisés. L'étude tribologique a permis de mettre en évidence l'influence forte de la force normale sur les mécanismes d'endommagements, dont les scénarios de mise en place ont pu être explicités pour les deux domaines majeurs de sollicitations. Dans un deuxième temps, les endommagements ont été étudiés d'un point de vue physicochimique et le rôle tribochimique joué par les éléments environnementaux (0, N ... ) a été mis en évidence. Pour finir, la comparaison directe des mécanismes identifiés sur banc expérimental et sur le système industriel a permis d'aborder, d'un point de vue critique, l'importance des paramètres choisis pour les équivalences expérience / système industriel ; et de la dynamique de chargement pour garantir la représentativité d'un essai à l'échelle laboratoire. / In the blade/ disk contact of aero-engines, movements induced by the engine regime changes may lead to critical wear. In order to limit friction and protect components, motorists usually use a thick and soft CuNiin layer (150 !-lm) covered with a lubricant. This system is subjected to high contact pressure (upto 600 MPa) and high temperatures (up to 500 °C). In service observations of engine parts revealed significant wear and transfer phenomena. An experimental layout was designed to perform fretting wear tests in temperature on a punch/plane contact, representative of engine solicitation. Based on the tribological study performed, specified gradation mechanisms were identified and the evidence of a pressure threshold was demonstrated. Physicochemical analyses performed confirmed the role played by environment (0, N ... ) in fretting wear mechanisms and suggest that the tribochemical effects should be considered in the fretting wear models. Direct comparisons between degradation mechanisms identified on the experimental system, and on industrial parts, allow a critical review of parameters chosen to simulate the contact. Finally, the impact of loading dynamics was investigated in order to improve tests representativity at la bora tory scale. Fretting Usure Cinétique Energie dissipée CuNiln TTS Ti17 Ti6242 Tribochimie Fretting Wear Kinetic Dissipated energy CuNiln TTS Ti17 Ti6242 Tribochemistry
6	Modelling of the resilient and permanent deformation behaviour of subgrade soils and unbound granular materials Soliman, Haithem 03 October 2015 (has links) Laboratory characterization of subgrade soils and unbound granular materials is an essential component of the Mechanistic-Empirical Pavement Design Guide (Pavement ME). The design thickness and performance of a pavement structure are highly dependent on the deformation behaviour of subgrade and granular material. Specifications for granular materials vary among transportation agencies based on the availability of materials, climatic conditions, and function. Specifications aim to provide durable materials that meet design requirements and achieve the target design life with cost effective materials. The objectives of the research are to: • evaluate resilient modulus of typical fine-grained soils under traffic loading. • evaluate resilient modulus, permanent deformation, and permeability of typical unbound granular materials. • evaluate the effect of moisture and fines fraction on the performance of unbound granular materials and subgrade soil. • develop prediction models for resilient modulus to improve reliability of Level 2 inputs in the Pavement ME. • provide test data in support of updating Manitoba Infrastructure and Transportation specifications for unbound granular materials to improve the performance of pavement structures. Resilient modulus tests were conducted on three types of subgrade soil (high plastic clay, sandy clay, and silty sand/sandy silt) at four levels of moisture content. Resilient modulus, permanent deformation and permeability tests were conducted on six gradations representing two types of granular material (100% crushed limestone and gravel) at two levels of moisture content. Prediction models were developed for resilient modulus and compared to the models developed under the Long Term Pavement Performance program. The proposed models provided more reliable predictions with lower root mean square error. The deformation behaviour of the granular materials was classified according to the shakedown and dissipated energy approaches. Among the tested fines contents, limestone and gravel materials with optimum fines contents of 4.5% and 9%, respectively, had better resistance to plastic deformation and higher resilient modulus. The dissipated energy approach can be used to determine the stress ratio for the boundary between post compaction and stable zones from multistage triaxial testing. Result of permeability tests showed that the hydraulic conductivity of unbound granular material increased as the fines content decreased. / February 2016
7	Fatigue models for life prediction of structures under multiaxial loading with variation in time and space. / Tenue des structures en fatigue multiaxiale : prise en compte des variations de chargement en temps et en espace Ma, Zepeng 18 December 2017 (has links) L'objet de ce travail est de proposer une approche multi-échelle de la fatigue fondée sur l'énergie, et susceptible d'estimer les durées de vie associées à des chargements multidimensionnels variables. Le fondement de la démarche consiste à supposer que l'énergie dissipée à petite échelle régit le comportement à la fatigue. À chaque point matériel, est associée une distribution stochastique de points faibles qui sont susceptibles de plastifier et de contribuer à la dissipation d'énergie sans affecter des contraintes macroscopiques globales. Ceci revient à adopter le paradigme de Dang Van en fatigue polycyclique. La structure est supposée élastique (ou adaptée) à l'échelle macroscopique. De plus, on adopte à l'échelle mésoscopique un comportement élastoplastique avec une dépendance de la fonction de charge plastique non seulement de la partie déviatorique des contraintes, mais aussi de la partie hydrostatique. On considère également un écrouissage cinématique linéaire sous l'hypothèse d'une plasticité associée. Au lieu d'utiliser le nombre de cycles comme variable incrémentale, le concept d'évolution temporelle du chargement est adopté pour un suivi précis de l'historique du chargement réel. L'effet de la contrainte moyenne est pris en compte dans la fonction de charge mésoscopique ; une loi de cumul non linéaire de dommage est également considérée dans le modèle. La durée de vie à la fatigue est ensuite déterminée à l'aide d'une loi de phénoménologique fondée sur la dissipation d'énergie mésoscopique issue du cycle d'accommodation plastique. La première partie du travail a porté sur une proposition d'un modèle de fatigie à gradient de mise en oeuvre plus simple que les précédents modèles. / The aim of this work is to propose a multi-scale approach to energy-based fatigue, which can estimate lifetimes associated with variable multidimensional loading. The foundation of the approach is to assume that the energy dissipated on a small scale governs the fatigue behavior. Each material point is associated to a stochastic distribution of weak points that are likely to plasticize and contribute to the dissipation of energy without affecting global macroscopic stresses. This amounts to adopting Dang Van's paradigm of high cycle fatigue. The structure is supposed to be elastic (or adapted) on a macroscopic scale. In addition, we adopt on the mesoscopic scale an elastoplastic behavior with a dependence of the plastic load function not only of the deviatoric part of the stresses, but also of the hydrostatic part. Linear kinematic hardening is also considered under the assumption of an associated plasticity. Instead of using the number of cycles as an incremental variable, the concept of temporal evolution of the load is adopted for a precise follow-up of the history of the actual loading. The effect of mean stress is taken into account in the mesoscopic yield function; a law of nonlinear accumulation of damage is also considered in the model. Fatigue life is then determined using a phenomenological law based on mesoscopic energy dissipation from the plastic accommodative cycle. The first part of the work focused on a proposal for a fatigue model with a simpler implementation gradient than the previous models. Fatigue à grand nombre de cycles Énergie dissipée Approche multi-Échelle Plasticité Fatigue à gradient High cycle fatigue Dissipated energy Multiscale approach Plasticity Fatigue gradient
8	Reciclagem de pavimentos flexíveis com adição de cimento Portland : estudo de fadiga através do ensaio de flexão em viga quatro pontos / Full-depth reclamation of semi-rigid pavements with cement : contribution for the development of a mix design method / Reciclaje de pavimentos flexibles con adición de cemento Portland : estudio de fatiga a través del ensayo de flexión en viga cuatro puntos Castañeda López, Mario Alexander January 2016 (has links) A reciclagem de pavimentos com adição de cimento Portland é uma técnica que permite reutilizar estruturas degradadas de pavimentos flexíveis na conformação de uma nova camada estabilizada. Seu dimensionamento, no Brasil, tem sido abordado de forma empírica. Entretanto, os métodos racionais desenvolvidos para pavimentos semirrígidos estão baseados principalmente na previsão da vida de fadiga das camadas cimentadas, associada ao nível de deformação atuante na sua fibra inferior. Com o intuito de contribuir no desenvolvimento de um método de dimensionamento de pavimentos com camadas recicladas com adição de cimento, a pesquisa relatada nesta dissertação teve como objetivo principal o estudo laboratorial do comportamento a fadiga de misturas constituídas por fresado asfáltico (20%, 50% e 70%), brita graduada e cimento Portland (teores de 2% e 4%). O programa experimental foi baseado no protocolo para caraterização de materiais cimentados da Austroads (2008; 2012), para ensaios estáticos e de fadiga, além de recomendações para caracterização flexural da JCI (1984), procurando-se avaliar a sua aplicabilidade. Os ensaios de fadiga foram realizados em vigotas com dimensões 10 cm x 10 cm x 40 cm, curadas por pelo menos 28 dias. O modo dos ensaios foi o de tensão controlada como função da resistência à tração na flexão, previamente determinada. O sistema de carregamento é conhecido como fadiga a 4 pontos. Foram obtidos modelos de fadiga em função da tensão de tração atuante, da deformação inicial e da energia dissipada inicial. Os resultados dos ensaios estáticos indicam a predominante influência do teor cimento na resistência a tração na flexão das misturas (valores entre 0,21 MPa e 1,53 MPa), enquanto a porcentagem de fresado tem efeito significativo na deformação de ruptura, tornando as misturas mais dúcteis, e no Módulo de Elasticidade Flexural (que variou entre 1483 MPa e 12800 MPa). No caso dos ensaios de fadiga, os Módulos de Resiliência Flexural iniciais (valores entre 2913 MPa e 7725 MPa) mostraram-se mais dependentes do teor de cimento e independentes do nível de tensão. Nos modelos de fadiga obtidos, os valores dos exponentes de dano por deformação variaram entre 7 e 15, sendo próximos aos relatados pela Austroads para materiais cimentados. Esses modelos foram empregados na modelagem de estruturas de pavimento com camadas de base reciclada, de espessura de 18 cm a 40 cm, visando quantificar o efeito do teor de cimento e da porcentagem de fresado na vida de fadiga, bem como das espessuras da camada reciclada e da nova camada asfáltica sobrejacente. Observou-se que espessuras de camada reciclada inferiores a 30 cm terão curta vida de fadiga. Por outro lado, também ficou evidenciado que a vida de fadiga dessa camada depende significativamente da espessura da nova camada asfáltica sobrejacente, recomendando-se espessuras de no mínimo 10 cm. Finalmente, destaca-se que o volume de dados gerado durante os ensaios de fadiga, e seu processamento por meio de algoritmos desenvolvidos na pesquisa, permitiram abordar conceitos de energia dissipada, como aproximação à definição de critérios de micro e macrofissuração, o que mostrou a utilidade deste tipo de abordagem para futuras pesquisas. / Full-depth reclamation with Portland cement (FDR-C), is a technique allowing the reuse of flexible pavements damaged structures, in order to build a new stabilized layer. In Brazil, pavement design with FDR-C has been determined by empirical approaches. However, mechanistic approach developed for semi-rigid pavements mainly use fatigue relationships based on deformations occurring at the bottom of the cemented layer. In order to develop a pavement design method with FDR-C materials, this research work aimed to study, in laboratory, the fatigue behavior of FDR-C mixtures, for three cement grades (2 %, 4 % e 6 %) and three RAP (Reclaimed Asphalt Pavement) percentages (20 %, 50 % e 70 %).The experimental program was based on the protocol for the characterization of cemented materials of the Austroads (2008; 2012), for static and dynamic tests, and on the recommendations for flexural characterization of concrete reinforced with steel fibers, of the JCI (1984), evaluating the availability of these procedures. Fatigue tests were executed using beams (10 cm x 10 cm x 40 cm), static compacted and with a minimum curing time of 28 days. Stress controlled mode was used, based on flexural strength, previously determined. Loading system was a four-point bending test. Were developed fatigue strain, stress and dissipated energy relationships. Static tests results show that cement is the principal influence on the flexural strength of the mixtures (0.21 MPa up to 1.53 MPa), while the RAP have a major effect in the increasing of the tensile strains making it more ductile (flexural elastic modulus were 1483 MPa up to 12800 MPa). In the case of fatigue tests, flexural modulus were more dependent on the degree of cementation (2913 MPa up to 7725 MPa), and not on the applied stress level. About the fatigue models of FDR-C mixtures, strain damage exponents (7 up to 15) were similar to those reported by Austroads. Laboratory models based on strain were used in modeling of pavement structures, with a FDR-C base layer. Results showed benefits of thickness in FDR-C mixtures and asphalt layers (18 cm up to 40 cm), in order to evaluate the effect of the cement and RAP content on fatigue life, and FDR-C new asphalt thickness as well. This model highlights that FDR-C with a thickness inferior than 30 cm will have a shorter fatigue life. On the other side, was showed that the fatigue life of this layer mainly depends on new hot mix asphalt thickness layer (thickness recommended up to 10 cm). Finally, the volume of data generated during the fatigue tests and his processing through algorithms developed in research allowed using dissipated energy criteria as an approximation of the definition of micro and macro-cracking limits which indicate the utility of this methodology for future research. / El reciclaje de pavimentos con adición de cemento Portland es una técnica que permite la reutilización de estructuras degradadas de pavimentos flexibles para la conformación de una nueva capa estabilizada. Su diseño, en Brasil, ha sido abordado de forma empírica. Sin embargo, métodos racionales desarrollados para pavimentos semirrígidos están basados en la vida de fatiga de las capas cementadas, asociada al estado de deformaciones actuante en su base. Con el objetivo de contribuir al desarrollo de un método de dimensionamiento de pavimentos con capas recicladas con adición de cemento, la investigación relatada en esta disertación tuvo como objetivo principal el estudio laboratorial del comportamiento de fatiga de mezclas constituidas por fresado asfáltico (20%, 50% y 70%), base granular y cemento Portland (2%, 4 % y 6 %). El programa experimental fue basado en protocolos de caracterización de materiales cementados de la Austroads (2008, 2012), para ensayos estáticos y de fatiga, además de recomendaciones para caracterización flexural de concreto reforzado con fibras de acero de la JCI (1984), procurando evaluar su aplicabilidad. Los ensayos de fatiga fueron realizados en vigotas con dimensiones de 10 cm x 10 x cm x 40 cm, moldadas estáticamente y curadas por lo menos 28 días. El modo de carga fue de esfuerzo controlado en función de la resistencia de tracción en la flexión, previamente determinada. El sistema de carga es conocido como fatiga 4 puntos. Los resultados de los ensayos estáticos mostraron una influencia predominante del contenido de cemento respecto a la resistencia flexural de las mezclas (valores entre 0,21 MPa y 1,53 MPa), mientras que el material fresado tiene un efecto significativo en la deformación de tracción al tonar más dúctiles las mezclas, afectando módulo de elasticidad flexural (valores entre 1483 MPa y 12800 MPa). En el caso de los ensayos de fatiga, los Módulos de Resiliencia Flexural iniciales (valores entre2913 MPa y 7725 MPa) mostraron ser más dependientes del grado de cementación e independientes del nivel de esfuerzo aplicado. Los valores de los exponentes de daño por deformación en los modelos de fatiga, que variaron entre 7 y 15, fueron próximos a los relatados por la Austroads. Estos modelos fueron usados en la modelación de estructuras de pavimento con capas de base reciclada, de espesor entre 18 cm y 40 cm, buscando cuantificar el efecto del contenido de cemento y de fresado en la vida de fatiga. Se observó que espesores de la capa reciclada inferiores a 30 cm tendrán corta vida de fatiga. Por otro lado, fue evidenciado que la vida de fatiga de esta capa depende significativamente del espesor del nuevo revestimiento asfáltico, recomendándose espesores superiores a 10 cm. Finamente, se destaca que el volumen de datos generados durante los ensayos de fatiga y su procesamiento por medio de algoritmos desarrollados en la investigación permitieron abordar conceptos de energía disipada, como aproximación a la definición de criterios de micro y macro fractura que mostraron la utilidad de este tipo de metodologías para estudios futuros. Pavimentos Comportamento mecânico Ensaios de flexão Reciclagem Cimento Pavement design Four point bending test FDR with cement Flexural strength Dissipated energy Diseño de pavimentos Fatiga en cuatro puntos Reciclaje de pavimentos con cemento Resistencia de tracción a la flexión Energía disipada
9	Reciclagem de pavimentos flexíveis com adição de cimento Portland : estudo de fadiga através do ensaio de flexão em viga quatro pontos / Full-depth reclamation of semi-rigid pavements with cement : contribution for the development of a mix design method / Reciclaje de pavimentos flexibles con adición de cemento Portland : estudio de fatiga a través del ensayo de flexión en viga cuatro puntos Castañeda López, Mario Alexander January 2016 (has links) A reciclagem de pavimentos com adição de cimento Portland é uma técnica que permite reutilizar estruturas degradadas de pavimentos flexíveis na conformação de uma nova camada estabilizada. Seu dimensionamento, no Brasil, tem sido abordado de forma empírica. Entretanto, os métodos racionais desenvolvidos para pavimentos semirrígidos estão baseados principalmente na previsão da vida de fadiga das camadas cimentadas, associada ao nível de deformação atuante na sua fibra inferior. Com o intuito de contribuir no desenvolvimento de um método de dimensionamento de pavimentos com camadas recicladas com adição de cimento, a pesquisa relatada nesta dissertação teve como objetivo principal o estudo laboratorial do comportamento a fadiga de misturas constituídas por fresado asfáltico (20%, 50% e 70%), brita graduada e cimento Portland (teores de 2% e 4%). O programa experimental foi baseado no protocolo para caraterização de materiais cimentados da Austroads (2008; 2012), para ensaios estáticos e de fadiga, além de recomendações para caracterização flexural da JCI (1984), procurando-se avaliar a sua aplicabilidade. Os ensaios de fadiga foram realizados em vigotas com dimensões 10 cm x 10 cm x 40 cm, curadas por pelo menos 28 dias. O modo dos ensaios foi o de tensão controlada como função da resistência à tração na flexão, previamente determinada. O sistema de carregamento é conhecido como fadiga a 4 pontos. Foram obtidos modelos de fadiga em função da tensão de tração atuante, da deformação inicial e da energia dissipada inicial. Os resultados dos ensaios estáticos indicam a predominante influência do teor cimento na resistência a tração na flexão das misturas (valores entre 0,21 MPa e 1,53 MPa), enquanto a porcentagem de fresado tem efeito significativo na deformação de ruptura, tornando as misturas mais dúcteis, e no Módulo de Elasticidade Flexural (que variou entre 1483 MPa e 12800 MPa). No caso dos ensaios de fadiga, os Módulos de Resiliência Flexural iniciais (valores entre 2913 MPa e 7725 MPa) mostraram-se mais dependentes do teor de cimento e independentes do nível de tensão. Nos modelos de fadiga obtidos, os valores dos exponentes de dano por deformação variaram entre 7 e 15, sendo próximos aos relatados pela Austroads para materiais cimentados. Esses modelos foram empregados na modelagem de estruturas de pavimento com camadas de base reciclada, de espessura de 18 cm a 40 cm, visando quantificar o efeito do teor de cimento e da porcentagem de fresado na vida de fadiga, bem como das espessuras da camada reciclada e da nova camada asfáltica sobrejacente. Observou-se que espessuras de camada reciclada inferiores a 30 cm terão curta vida de fadiga. Por outro lado, também ficou evidenciado que a vida de fadiga dessa camada depende significativamente da espessura da nova camada asfáltica sobrejacente, recomendando-se espessuras de no mínimo 10 cm. Finalmente, destaca-se que o volume de dados gerado durante os ensaios de fadiga, e seu processamento por meio de algoritmos desenvolvidos na pesquisa, permitiram abordar conceitos de energia dissipada, como aproximação à definição de critérios de micro e macrofissuração, o que mostrou a utilidade deste tipo de abordagem para futuras pesquisas. / Full-depth reclamation with Portland cement (FDR-C), is a technique allowing the reuse of flexible pavements damaged structures, in order to build a new stabilized layer. In Brazil, pavement design with FDR-C has been determined by empirical approaches. However, mechanistic approach developed for semi-rigid pavements mainly use fatigue relationships based on deformations occurring at the bottom of the cemented layer. In order to develop a pavement design method with FDR-C materials, this research work aimed to study, in laboratory, the fatigue behavior of FDR-C mixtures, for three cement grades (2 %, 4 % e 6 %) and three RAP (Reclaimed Asphalt Pavement) percentages (20 %, 50 % e 70 %).The experimental program was based on the protocol for the characterization of cemented materials of the Austroads (2008; 2012), for static and dynamic tests, and on the recommendations for flexural characterization of concrete reinforced with steel fibers, of the JCI (1984), evaluating the availability of these procedures. Fatigue tests were executed using beams (10 cm x 10 cm x 40 cm), static compacted and with a minimum curing time of 28 days. Stress controlled mode was used, based on flexural strength, previously determined. Loading system was a four-point bending test. Were developed fatigue strain, stress and dissipated energy relationships. Static tests results show that cement is the principal influence on the flexural strength of the mixtures (0.21 MPa up to 1.53 MPa), while the RAP have a major effect in the increasing of the tensile strains making it more ductile (flexural elastic modulus were 1483 MPa up to 12800 MPa). In the case of fatigue tests, flexural modulus were more dependent on the degree of cementation (2913 MPa up to 7725 MPa), and not on the applied stress level. About the fatigue models of FDR-C mixtures, strain damage exponents (7 up to 15) were similar to those reported by Austroads. Laboratory models based on strain were used in modeling of pavement structures, with a FDR-C base layer. Results showed benefits of thickness in FDR-C mixtures and asphalt layers (18 cm up to 40 cm), in order to evaluate the effect of the cement and RAP content on fatigue life, and FDR-C new asphalt thickness as well. This model highlights that FDR-C with a thickness inferior than 30 cm will have a shorter fatigue life. On the other side, was showed that the fatigue life of this layer mainly depends on new hot mix asphalt thickness layer (thickness recommended up to 10 cm). Finally, the volume of data generated during the fatigue tests and his processing through algorithms developed in research allowed using dissipated energy criteria as an approximation of the definition of micro and macro-cracking limits which indicate the utility of this methodology for future research. / El reciclaje de pavimentos con adición de cemento Portland es una técnica que permite la reutilización de estructuras degradadas de pavimentos flexibles para la conformación de una nueva capa estabilizada. Su diseño, en Brasil, ha sido abordado de forma empírica. Sin embargo, métodos racionales desarrollados para pavimentos semirrígidos están basados en la vida de fatiga de las capas cementadas, asociada al estado de deformaciones actuante en su base. Con el objetivo de contribuir al desarrollo de un método de dimensionamiento de pavimentos con capas recicladas con adición de cemento, la investigación relatada en esta disertación tuvo como objetivo principal el estudio laboratorial del comportamiento de fatiga de mezclas constituidas por fresado asfáltico (20%, 50% y 70%), base granular y cemento Portland (2%, 4 % y 6 %). El programa experimental fue basado en protocolos de caracterización de materiales cementados de la Austroads (2008, 2012), para ensayos estáticos y de fatiga, además de recomendaciones para caracterización flexural de concreto reforzado con fibras de acero de la JCI (1984), procurando evaluar su aplicabilidad. Los ensayos de fatiga fueron realizados en vigotas con dimensiones de 10 cm x 10 x cm x 40 cm, moldadas estáticamente y curadas por lo menos 28 días. El modo de carga fue de esfuerzo controlado en función de la resistencia de tracción en la flexión, previamente determinada. El sistema de carga es conocido como fatiga 4 puntos. Los resultados de los ensayos estáticos mostraron una influencia predominante del contenido de cemento respecto a la resistencia flexural de las mezclas (valores entre 0,21 MPa y 1,53 MPa), mientras que el material fresado tiene un efecto significativo en la deformación de tracción al tonar más dúctiles las mezclas, afectando módulo de elasticidad flexural (valores entre 1483 MPa y 12800 MPa). En el caso de los ensayos de fatiga, los Módulos de Resiliencia Flexural iniciales (valores entre2913 MPa y 7725 MPa) mostraron ser más dependientes del grado de cementación e independientes del nivel de esfuerzo aplicado. Los valores de los exponentes de daño por deformación en los modelos de fatiga, que variaron entre 7 y 15, fueron próximos a los relatados por la Austroads. Estos modelos fueron usados en la modelación de estructuras de pavimento con capas de base reciclada, de espesor entre 18 cm y 40 cm, buscando cuantificar el efecto del contenido de cemento y de fresado en la vida de fatiga. Se observó que espesores de la capa reciclada inferiores a 30 cm tendrán corta vida de fatiga. Por otro lado, fue evidenciado que la vida de fatiga de esta capa depende significativamente del espesor del nuevo revestimiento asfáltico, recomendándose espesores superiores a 10 cm. Finamente, se destaca que el volumen de datos generados durante los ensayos de fatiga y su procesamiento por medio de algoritmos desarrollados en la investigación permitieron abordar conceptos de energía disipada, como aproximación a la definición de criterios de micro y macro fractura que mostraron la utilidad de este tipo de metodologías para estudios futuros. Pavimentos Comportamento mecânico Ensaios de flexão Reciclagem Cimento Pavement design Four point bending test FDR with cement Flexural strength Dissipated energy Diseño de pavimentos Fatiga en cuatro puntos Reciclaje de pavimentos con cemento Resistencia de tracción a la flexión Energía disipada
10	Reciclagem de pavimentos flexíveis com adição de cimento Portland : estudo de fadiga através do ensaio de flexão em viga quatro pontos / Full-depth reclamation of semi-rigid pavements with cement : contribution for the development of a mix design method / Reciclaje de pavimentos flexibles con adición de cemento Portland : estudio de fatiga a través del ensayo de flexión en viga cuatro puntos Castañeda López, Mario Alexander January 2016 (has links) A reciclagem de pavimentos com adição de cimento Portland é uma técnica que permite reutilizar estruturas degradadas de pavimentos flexíveis na conformação de uma nova camada estabilizada. Seu dimensionamento, no Brasil, tem sido abordado de forma empírica. Entretanto, os métodos racionais desenvolvidos para pavimentos semirrígidos estão baseados principalmente na previsão da vida de fadiga das camadas cimentadas, associada ao nível de deformação atuante na sua fibra inferior. Com o intuito de contribuir no desenvolvimento de um método de dimensionamento de pavimentos com camadas recicladas com adição de cimento, a pesquisa relatada nesta dissertação teve como objetivo principal o estudo laboratorial do comportamento a fadiga de misturas constituídas por fresado asfáltico (20%, 50% e 70%), brita graduada e cimento Portland (teores de 2% e 4%). O programa experimental foi baseado no protocolo para caraterização de materiais cimentados da Austroads (2008; 2012), para ensaios estáticos e de fadiga, além de recomendações para caracterização flexural da JCI (1984), procurando-se avaliar a sua aplicabilidade. Os ensaios de fadiga foram realizados em vigotas com dimensões 10 cm x 10 cm x 40 cm, curadas por pelo menos 28 dias. O modo dos ensaios foi o de tensão controlada como função da resistência à tração na flexão, previamente determinada. O sistema de carregamento é conhecido como fadiga a 4 pontos. Foram obtidos modelos de fadiga em função da tensão de tração atuante, da deformação inicial e da energia dissipada inicial. Os resultados dos ensaios estáticos indicam a predominante influência do teor cimento na resistência a tração na flexão das misturas (valores entre 0,21 MPa e 1,53 MPa), enquanto a porcentagem de fresado tem efeito significativo na deformação de ruptura, tornando as misturas mais dúcteis, e no Módulo de Elasticidade Flexural (que variou entre 1483 MPa e 12800 MPa). No caso dos ensaios de fadiga, os Módulos de Resiliência Flexural iniciais (valores entre 2913 MPa e 7725 MPa) mostraram-se mais dependentes do teor de cimento e independentes do nível de tensão. Nos modelos de fadiga obtidos, os valores dos exponentes de dano por deformação variaram entre 7 e 15, sendo próximos aos relatados pela Austroads para materiais cimentados. Esses modelos foram empregados na modelagem de estruturas de pavimento com camadas de base reciclada, de espessura de 18 cm a 40 cm, visando quantificar o efeito do teor de cimento e da porcentagem de fresado na vida de fadiga, bem como das espessuras da camada reciclada e da nova camada asfáltica sobrejacente. Observou-se que espessuras de camada reciclada inferiores a 30 cm terão curta vida de fadiga. Por outro lado, também ficou evidenciado que a vida de fadiga dessa camada depende significativamente da espessura da nova camada asfáltica sobrejacente, recomendando-se espessuras de no mínimo 10 cm. Finalmente, destaca-se que o volume de dados gerado durante os ensaios de fadiga, e seu processamento por meio de algoritmos desenvolvidos na pesquisa, permitiram abordar conceitos de energia dissipada, como aproximação à definição de critérios de micro e macrofissuração, o que mostrou a utilidade deste tipo de abordagem para futuras pesquisas. / Full-depth reclamation with Portland cement (FDR-C), is a technique allowing the reuse of flexible pavements damaged structures, in order to build a new stabilized layer. In Brazil, pavement design with FDR-C has been determined by empirical approaches. However, mechanistic approach developed for semi-rigid pavements mainly use fatigue relationships based on deformations occurring at the bottom of the cemented layer. In order to develop a pavement design method with FDR-C materials, this research work aimed to study, in laboratory, the fatigue behavior of FDR-C mixtures, for three cement grades (2 %, 4 % e 6 %) and three RAP (Reclaimed Asphalt Pavement) percentages (20 %, 50 % e 70 %).The experimental program was based on the protocol for the characterization of cemented materials of the Austroads (2008; 2012), for static and dynamic tests, and on the recommendations for flexural characterization of concrete reinforced with steel fibers, of the JCI (1984), evaluating the availability of these procedures. Fatigue tests were executed using beams (10 cm x 10 cm x 40 cm), static compacted and with a minimum curing time of 28 days. Stress controlled mode was used, based on flexural strength, previously determined. Loading system was a four-point bending test. Were developed fatigue strain, stress and dissipated energy relationships. Static tests results show that cement is the principal influence on the flexural strength of the mixtures (0.21 MPa up to 1.53 MPa), while the RAP have a major effect in the increasing of the tensile strains making it more ductile (flexural elastic modulus were 1483 MPa up to 12800 MPa). In the case of fatigue tests, flexural modulus were more dependent on the degree of cementation (2913 MPa up to 7725 MPa), and not on the applied stress level. About the fatigue models of FDR-C mixtures, strain damage exponents (7 up to 15) were similar to those reported by Austroads. Laboratory models based on strain were used in modeling of pavement structures, with a FDR-C base layer. Results showed benefits of thickness in FDR-C mixtures and asphalt layers (18 cm up to 40 cm), in order to evaluate the effect of the cement and RAP content on fatigue life, and FDR-C new asphalt thickness as well. This model highlights that FDR-C with a thickness inferior than 30 cm will have a shorter fatigue life. On the other side, was showed that the fatigue life of this layer mainly depends on new hot mix asphalt thickness layer (thickness recommended up to 10 cm). Finally, the volume of data generated during the fatigue tests and his processing through algorithms developed in research allowed using dissipated energy criteria as an approximation of the definition of micro and macro-cracking limits which indicate the utility of this methodology for future research. / El reciclaje de pavimentos con adición de cemento Portland es una técnica que permite la reutilización de estructuras degradadas de pavimentos flexibles para la conformación de una nueva capa estabilizada. Su diseño, en Brasil, ha sido abordado de forma empírica. Sin embargo, métodos racionales desarrollados para pavimentos semirrígidos están basados en la vida de fatiga de las capas cementadas, asociada al estado de deformaciones actuante en su base. Con el objetivo de contribuir al desarrollo de un método de dimensionamiento de pavimentos con capas recicladas con adición de cemento, la investigación relatada en esta disertación tuvo como objetivo principal el estudio laboratorial del comportamiento de fatiga de mezclas constituidas por fresado asfáltico (20%, 50% y 70%), base granular y cemento Portland (2%, 4 % y 6 %). El programa experimental fue basado en protocolos de caracterización de materiales cementados de la Austroads (2008, 2012), para ensayos estáticos y de fatiga, además de recomendaciones para caracterización flexural de concreto reforzado con fibras de acero de la JCI (1984), procurando evaluar su aplicabilidad. Los ensayos de fatiga fueron realizados en vigotas con dimensiones de 10 cm x 10 x cm x 40 cm, moldadas estáticamente y curadas por lo menos 28 días. El modo de carga fue de esfuerzo controlado en función de la resistencia de tracción en la flexión, previamente determinada. El sistema de carga es conocido como fatiga 4 puntos. Los resultados de los ensayos estáticos mostraron una influencia predominante del contenido de cemento respecto a la resistencia flexural de las mezclas (valores entre 0,21 MPa y 1,53 MPa), mientras que el material fresado tiene un efecto significativo en la deformación de tracción al tonar más dúctiles las mezclas, afectando módulo de elasticidad flexural (valores entre 1483 MPa y 12800 MPa). En el caso de los ensayos de fatiga, los Módulos de Resiliencia Flexural iniciales (valores entre2913 MPa y 7725 MPa) mostraron ser más dependientes del grado de cementación e independientes del nivel de esfuerzo aplicado. Los valores de los exponentes de daño por deformación en los modelos de fatiga, que variaron entre 7 y 15, fueron próximos a los relatados por la Austroads. Estos modelos fueron usados en la modelación de estructuras de pavimento con capas de base reciclada, de espesor entre 18 cm y 40 cm, buscando cuantificar el efecto del contenido de cemento y de fresado en la vida de fatiga. Se observó que espesores de la capa reciclada inferiores a 30 cm tendrán corta vida de fatiga. Por otro lado, fue evidenciado que la vida de fatiga de esta capa depende significativamente del espesor del nuevo revestimiento asfáltico, recomendándose espesores superiores a 10 cm. Finamente, se destaca que el volumen de datos generados durante los ensayos de fatiga y su procesamiento por medio de algoritmos desarrollados en la investigación permitieron abordar conceptos de energía disipada, como aproximación a la definición de criterios de micro y macro fractura que mostraron la utilidad de este tipo de metodologías para estudios futuros. Pavimentos Comportamento mecânico Ensaios de flexão Reciclagem Cimento Pavement design Four point bending test FDR with cement Flexural strength Dissipated energy Diseño de pavimentos Fatiga en cuatro puntos Reciclaje de pavimentos con cemento Resistencia de tracción a la flexión Energía disipada

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