Modèle pour la prévision de la résistance nominale des matériaux quasi-fragiles : application à la modélisation de l'endommagement et de la rupture des enrobés bitumineux sous sollicitations de fatigue par la méthode des éléments discrets / Modelling of nominal strength prediction for quasi-brittle materials : application to discrete element modelling of damage and fracture of asphalt concrete under fatigue loading

Gao, Xiaofeng

06 March 2017

L’estimation de la durée de vie et de la rupture de structures composées par des matériaux quasi-fragiles nécessite le développement de nouveaux modèles théoriques et numériques. Dans ce travail, la modélisation de l’apparition des fissures et leur propagation en chargement monotone est d'abord étudiée. Un modèle d'effet de taille pour les structures fissurées et sa forme généralisée pour les structures présentant des défauts plus complexes qu’une fissure sont développés. Les prédictions du modèle de rupture sont comparées à des résultats expérimentaux de la littérature pour divers spécimens composés de différents matériaux et de différentes tailles. Des échantillons présentant des défauts initiaux en forme de V et en forme de trou illustrent les capacités de la formulation. Ensuite, l’endommagement et la fissuration induite par des chargements cycliques en fatigue sont discutés. Un modèle local en éléments discrets est développé, qui permet de coupler les deux mécanismes (endommagement et fissuration). Les prédictions numériques sont comparées aux résultats théoriques et expérimentaux. À la fin, les applications associées au comportement du béton bitumineux renforcé par des grilles en fibres de verres sont analysées en détail. / The prediction of the fatigue life and the rupture of structures made of quasi-brittle materials requires the development of new theoretical and numerical models. In this work, the modelling of the crack initiation and propagation under monotonic loading is firstly investigated. A size effect model for cracked structures and its generalized form for structures with defects more complex than a crack are developed. The predictions of the proposed model are compared with experimental results from the literature for various specimens of different materials and sizes. Samples with initial V-shaped and hole-shaped defects exemplify the formulation's capabilities. Then, the damage and cracking induced by cyclic fatigue loads is discussed. A local model using discrete elements is developed, that allows the coupling of two mechanisms (damage and fatigue cracking). The numerical results are compared to those of experimental bending fatigue tests. Finally, applications associated with the behavior of fiber glass reinforced asphalt concrete are analyzed in detail.

Quasi-fragiles

Résistance nominale

Durée de vie en fatigue

Modélisation par éléments discrets

Quasi-brittle

Nominal strength

Fatigue life

Discrete element modeling

531.3

624.1

Caractérisation mécanique de la respiration des hydrures pour uneconception optimisée des réservoirs de stockage de l’hydrogène par voie solide / Thermo-mechanical characterization of breathing hydrides foroptimized design of tanks to store hydrogen in solids-state

Salque, Bruno

26 June 2017

L’hydrogène est une solution chimique de stockage d’énergie électrique intéressante. En effet, l’hydrogèneproduit devient un vecteur d’énergie utilisable de différentes façons. Pour développer l’industrie hydrogène,sa production, son stockage et sa consommation doivent être étudiés et optimisés.Cette thèse traite du stockage solide d’hydrogène dans des hydrures métalliques. Dans cette technologie,l’hydrogène est piégé à l’intérieur d’un matériau métallique selon une réaction chimique réversibleexothermique. L’hydrogène peut être libéré selon la réaction inverse, endothermique. Les performances dece stockage sont liées au choix du matériau, à la gestion des transferts thermiques et au système utilisé. Sesgrands avantages sont sa compacité énergétique et la sécurité d’un tel stockage. L’inconvénient majeur vientdu poids du système. Lors de l’absorption de l’hydrogène dans le matériau, ce dernier augmente de volume.Pour pouvoir dimensionner les réservoirs à hydrures métalliques, il est nécessaire de connaître les contraintesgénérées pas ce gonflement. Le confinement du matériau dans une enceinte étanche doit être garanti. Lecyclage entre les étapes de gonflement dégonflement dûs aux stockage/dé-stockage de l’hydrogène dans unhydrure métallique est appelé la respiration de l’hydrure.Ce travail de recherche commence par rappeler l’état de l’art sur l’hydrogène et les hydrures métalliques.Dans le second chapitre, le matériau sélectionné, LmNiCoMnAl , est caractérisé. Les deux chapitres suivantsprésentent l’étude expérimentale de la respiration en conditions oedométriques à contrainte imposée et dansun volume fixe. Le chapitre cinq présente les travaux de simulation numérique par éléments discrets. Lesgrains, modélisés sous forme de clusters, sont placés dans différentes conditions aux limites avec différentscoefficients de frottement.Les résultats des expériences complètent les travaux précédents sur d’autres matériaux. Contrairementau Ti-Cr-V, le LaNiCoMnAl voit sa densité diminuer au cours de la respiration pour les contraintes deconfinement utilisées. Le taux de décroissance de la densité diminue quand la contrainte de confinementaugmente. Quand l’échantillon est placé dans un volume fixe, les contraintes développées par le matériauaugmentent avec la quantité de matériau introduite dans le volume. La simulation numérique a permis demontrer qu’une dédensification est observée pour des niveaux de contrainte intermédiaires quand le coefficientde frottement augmente, confirmant l’hypothèse que les paramètres matériaux ont une importance dans lecomportement macroscopique des hydrures métalliques pendant la respiration. / Hydrogen can be used as a storage for electric energy. Hydrogen may become an energy vector, whichcould be used and transported easily. For the hydrogen sector to develop and mature, production, storageand consumption should be researched and optimized.This PhD is dedicated to hydrogen solid storage in metal hydride. This technology consists in usinga reversible and exothermic chemical reaction between an alloy and hydrogen. The hydrogen is capturedinside the metal lattice and can be released with the endothermic opposite reaction. The main factors whichimpact the performance of this technology are the choice of material, the heat flow management and thesystem used. Its main advantages lay on safety and energy compactness. Its main drawbacks come from theweight of the system. When the material absorb hydrogen, its volume increases. To contain this materialin an airtight environment, it is mandatory to know how stress develop on the container that contains thematerial. The cycles of dilatation and contraction of the material, when it is loading or unloading hydrogen,is called breathing.This research begins with a large spectrum presentation of hydrogen. Then comes a chemical and structuralcharacterization of the material : LaNiCoMnAl. Its Composition-Temperature-Pressure characteristicsare given. The material exhibits granular properties and is structurally characterize using laser grain sizing,shape measurement and X-Ray tomography. The typical length scale of LaNiCoMnAl particles is 20 micrometers.The third and fourth chapters are concerned with the experimental behavior. A sample is placed ina stress controlled environment where its density is measured during cycling. The other experiment places asample in a fixed volume. In that case, the stress exerted on the material is recorded and measured duringcycling. In the last chapter, numerical simulations using the Discrete Element Method are used. The materialis modeled by X shaped clusters and studied with different friction parameters and boundary conditions.Following other works done on other materials, these experiment showed a different behavior of LaNi-CoMnAl compared to Ti-Cr-V. During breathing, LaNiCoMnAl exhibits a decrease in density even whensubmitted to a relatively large stress. The rate at which the density decreases is lowered when the confinementpressure increases. When the material is placed in a fixed volume, the stress increases with increasingpoured mass. Numerical simulations show a decrease in density when the friction parameter is high enough.It validates the hypothesis that material parameters play a major role in the macroscopic behavior of metalhydride during breathing.

Hydrogène

Hydrure métallique

Milieux granulaires

Stockage solide

Simulation par éléments discrets

Hydrogen

Metal hydride

Granular matter

Solid storage

Discrete Element Method

620

Análise teórico-experimental do comportamento de concretos reforçados com fibras de aço quando submetidos a cargas de impacto / A numerical and experimental analysis of steel fiber reinforced concretes subjected to impact loads

Garcez, Estela Oliari

January 2005

Quando o concreto é submetido a ações especiais, como cargas cíclicas ou ação de cargas de impacto, modificações em sua composição são necessárias, já que o concreto não apresenta desempenho satisfatório à tração, o que compromete o seu comportamento frente à ação de cargas dinâmicas. Uma alternativa para amenizar esta deficiência consiste em adicionar fibras ao concreto. Estas atuam como reforços à tração, transformando a matriz cimentícia, tipicamente frágil, em um material que apresenta boa resistência residual após a fissuração. Buscando colaborar na avaliação da eficiência de diferentes tipos de fibras, o presente trabalho analisa o comportamento de concretos com fibras de aço, submetidos ao impacto, avaliando a influência do fator de forma, do comprimento e do teor de fibras, assim como do tamanho do agregado. São ainda analisados os efeitos da incorporação de fibras na resistência à compressão, na resistência à tração por compressão diametral, no módulo de elasticidade e na tenacidade dos compósitos. Adicionalmente, é executada uma comparação entre os resultados experimentais e os derivados de um esquema de modelagem da situação de impacto através do uso do método de elementos discretos. Buscou-se, através da modelagem teórica, executar um mapeamento dos danos, provocados por cargas de impacto incrementais, ao longo do tempo, bem como determinar as energias necessárias para levar as placas até a ruptura. Os resultados indicam que a incorporação de fibras de aço não consegue retardar o aparecimento da primeira fissura, mas aumenta significativamente a tenacidade dos compósitos. Fibras mais longas e com maior fator de forma tendem a ser mais eficientes, desde que se supere um teor de fibras mínimo, que neste trabalho ficou em torno de 100.000 fibras/m3, para fibras longas (50-60 mm) e de 400.000 fibras/m3, para fibras curtas, cuja ancoragem é menos eficiente. O método de teste de impacto por queda de esfera se mostrou adequado e sensível, porém o esquema de modelagem numérica testado necessita ser refinado para permitir uma adequada simulação do comportamento de concretos com fibras. / When submitted to special loading patterns, derived from dynamical actions such as cyclic or impact loads, concrete elements need to be reinforced, in order to resist the tensile stresses. A feasible alternative, in such cases, is to incorporate fibers in the concrete matrix. The fibers act as a tensile reinforcement, transforming the fragile cement matrix into a composite with significant post-cracking residual strength. In order to contribute with the data collection about the efficiency of different fiber types, the present research work presents an analysis of the behavior of steel fiber reinforced concretes subjected to impact loads. The work investigates the influences of changes in the shape factor, length and amount of fibers. The effects of these combinations on other basic properties of the composites, such as compression strength, split cylinder tensile strength, Young’s modulus and tenacity is also measured. Additionally, a comparison is made between the experimental results from the impact tests and the estimates obtained from a theoretical model that uses the discrete element method (DEM). This theoretical approach aimed to determine if the model was able to simulate the damage evolution over time generated by the increasing impacts loads, as well as to determine the total energy necessary to crack and break the specimens. The results obtained pointed out that the introduction of steel fibers does not affect the energy for the first crack but increases significantly the tenacity of the composite. Longer fibers, with greater shape factors, tend to be more efficient, provided that the fiber content is sufficiently high. The minimum recommended fiber content, according to the data from this research, may be around 100.000 fibers/m3, for longer fibers (50-60 mm). Or around 400.000 fibers/m3, for shorter fibers, which are not so efficient in terms of anchorage. The impact test method developed was considered adequate, being sensitive to the phenomenon and providing reliable data. The DEM model, however, needs to be refined to be able to deal with fiber concrete composites.

Estruturas (Engenharia)

Método dos elementos discretos

Fibras de aço

Concreto reforçado com fibras

Steel fiber reinforced concrete

Composite materials

Impact loads

Discrete element method

Aplicação do método dos elementos discretos na análise estática e dinâmica de estruturas de concreto reforçado com fibras de aço / Application of the Discrete Element Method in static and dynamic analysis of steel fiber reinforced concrete structures

Figueiredo, Marcelo Porto de

January 2006

Quando o concreto é submetido a carregamentos especiais, como cargas cíclicas ou ação de cargas de impacto, modificações em sua composição são necessárias. Uma vez que o material não apresenta desempenho satisfatório à tração, seu comportamento frente a este tipo de carregamento acaba seriamente comprometido. Uma alternativa para amenizar esta deficiência consiste em adicionar fibras de aço ao concreto. Ao adicionar estes elementos à matriz cimentícia, promove-se meios de transferência de tensões através das fissuras, aumentando a tenacidade do material, proporcionando mecanismos de absorção, relacionados com o desligamento e o arrancamento de fibras. Um número significativo de trabalhos experimentais envolvendo os mais diversos tipos de elementos estruturais reforçados com fibras de aço está disponível, havendo, no entanto, uma forte carência sob o ponto de vista de simulações numéricas. Buscando colaborar no desenvolvimento do material, o presente trabalho propõe a aplicação do Método dos Elementos Discretos para simulação do compósito submetido a carregamentos estáticos e dinâmicos. São realizadas alterações no algoritmo do método a fim de realizar a dispersão de fibras de aço na matriz de concreto. A análise das condições de contorno utilizadas em trabalho anterior revela a necessidade de aplicação de apoios elásticos sob pena de superestimar a rigidez do modelo. Os diagramas carga versus deslocamento que resultaram dos ensaios estáticos demonstram que o modelo criado é sensível à adição de fibras: maiores teores conduzem a modelos com maior tenacidade. O ensaio de impacto também se mostrou sensível e o padrão de fissuração encontrado nas simulações revelou uma boa aproximação com ensaios experimentais anteriores. / When submitted to special loading patterns, derived from dynamical actions such as cyclic or impact loads, some alterations in the concrete constitution need to be done, since the material don’t have an adequate behavior under tensile stress. A feasible alternative, in such cases, is to incorporate steel fibers in the concrete matrix. Adding these elements, stress transference mechanisms along the cracks are promoted, increasing the material tenacity. An expressive number of experimental works involving all the kinds of steel fiber reinforced concrete structural elements are available. However, few researches based on numerical methods are found in the literature. In order to contribute with the data collection and the development of the material, the present research work proposes the application of the Discrete Element Method to simulate the composite subjected to static and dynamic loads. Some modifications are made on the method algorithm trying to create the dispersion of fibers in the concrete matrix. The analysis of the boundary conditions used on previous work reveal the importance of using elastic support to don’t overestimate the stiffness of the model. The diagram load versus displacement that came from the static simulations shows that the model is sensible to the addition of fibers: higher proportions of fiber leads to models with higher tenacity. The impact tests also demonstrate sensibility and the crack pattern found on the simulations presented a very good approximation to previous experimental work.

Estruturas (Engenharia)

Método dos elementos discretos

Concreto reforçado com fibras

Fibras de aço

Steel Fiber Reinforced Concrete

Discrete Element Method

Numerical Smulation

Análise do processo de dano em material quase-frágil através da simulação de um modelo de barras

Birck, Gabriel

January 2016

Diversos materiais de interesse tecnológico podem ser considerados como materiais heterogêneos, onde sua natureza aleatória deve ser considerada para representar corretamente o comportamento não-linear. A avaliação quantitativa do dano em materiais sujeitos a estados de tensão ou deformação tem grande importância devido ao caráter crítico desse fenômeno, que pode crescer de forma abrupta e resultar em uma falha catastrófica da estrutura. Em estudos anteriores, Carpinteri e seus colaboradores apresentaram diferentes aspectos relacionados à caracterização do dano em materiais heterogêneos. Três desses aspectos são discutidos neste trabalho: (i) a proposta do número de fragilidade como medida da fragilidade da estrutura em análise; (ii) a evolução da dimensão fractal em que o processo de dano é desenvolvido; (iii) e os índices globais obtidos pela análise de Emissão Acústica (EA). Neste trabalho, uma versão do método dos elementos discretos formado por barras é utilizada para explorar esses aspectos. Espécimes de material quase-frágil são simulados e, quando possível, os resultados numéricos são comparados com resultados experimentais. Além disso, a discussão dos resultados obtidos é realizada visando compreender o comportamento desse tipo de material, como por exemplo, o fato de que estruturas com diferentes dimensões, porém com o mesmo número de fragilidade, têm comportamentos similares. Ademais, o método numérico empregado é apresentado como uma ferramenta viável para complementar a informação obtida em ensaios experimentais na avaliação do processo de dano. Pelo sinal de EA obtido através do método numérico empregado, obtiveram-se parâmetros para a classificação do tipo de falha e para o cálculo do tensor momento, onde comparando os resultados obtidos pelo modelo numérico e pela EA se observam comportamentos coerentes. / Several materials with technological interest can be considered as heterogeneous materials, where their random nature must be accounted to correctly represent the nonlinear behavior. The quantitative evaluation of damage in materials subjected to stress or strain states have great importance due to the critical nature of this phenomenon, which abruptly can rise to catastrophic failure. In previous studies, Carpinteri and his coworkers have presented different aspects of the damage process characterization in heterogeneous materials. Three of these aspects are discussed in this work: (i) the brittleness number proposal to measure the brittleness level of the analyzed structure, (ii) the relationship of the fractal dimension in which the damage process is developed, (iii) and the global indexes obtained by the Acoustic Emission (AE) analysis. In the present work, a version of discrete element method formed by bars is used to explore these concepts. A set of quasi-brittle material specimen is simulated and, when possible, the numerical results are compared with experimental ones. Moreover, a discussion of the obtained results is carried out aiming to understand the behavior of this kind of material, for instance, the fact that structures with different dimensions, but with the same brittleness number, have similar behavior. In addition, the numerical method is presented as a viable tool to complement information from experimental test on the damage process. From the AE signal obtained by the numerical method, parameters to classify the type of crack and for calculating the moment tensor were obtained, where consistent behaviors are observed by comparing the results of the numerical model and the AE.

Materiais

Simulação numérica

Emissão acústica

Estruturas (Engenharia)

Método dos elementos discretos

Heterogeneous materials

Lattice discrete element method

Acoustic emission

Damage process

Size effect

Estudo da ruptura em materiais heterogêneos quase frágeis aplicando o Método dos Elementos Discretos formado por barras juntamente com a técnica de emissão acústica

Puglia, Vicente Bergamini

January 2013

A ruptura de materiais heterogêneos quase frágeis, como o concreto, as cerâmicas e diferentes tipos de rochas, tem um comportamento mecânico complexo, foco de estudo de pesquisadores já há muito tempo. Uma ferramenta para simular o comportamento até ruptura destes tipos de materiais são os métodos de elementos discretos formados por barras (Discrete Element Method - DEM). Neste método as massas são concentradas em pontos nodais que estão ligados por meio de elementos unidimensionais caracterizados por relações constitutivas uniaxiais simples. Neste contexto, realizam-se novas implementações na versão do DEM com o intuito de estudar diversos aspectos dos materiais quase frágeis. Os principais focos da tese estão na desvinculação do nível de discretização do modelo do comprimento de correlação dos campos aleatórios que caracterizam as propriedades mecânicas. Através da interpretação dos resultados na simulação de emissão acústica é possível conhecer melhor o processo de dano neste tipo de material. Testes experimentais preliminares também são apresentados. Também são realizadas simulações em DEM utilizando carregamento biaxial, onde é explorado nessas simulações o comportamento dos modelos sob a ótica da técnica de emissão acústica. / The rupture of heterogeneous materials quasi-fragile, like concrete, ceramics and different types of rocks have a complex mechanical behavior, which has been the focus of study by researchers for a long time. The truss-like Discrete Element Method (DEM) was used to perform numerical simulations of the testing processes. The test results and the results of the numerical analyses, in terms of load vs. time diagram and AE data, as determined through b-value. In this context, new implementations in the version of DEM were realized with the objective to study the aspects of quasi-fragile materials. The main focuses of the thesis are in untying the level of discretization of the model of the correlation length from random fields which characterize the mechanical properties. And, through the interpretation of the results in the simulation of the acoustic emission, it is possible to better understand the process of damage in this type of material. Are also performed in DEM the biaxial loading, where is explored in this simulations the behavior of models from the point of view of the acoustic emission technique.

Mecânica da fratura

Estruturas (Engenharia)

Método dos elementos discretos

Emissão acústica

Discrete element

Random fields

Acoustic emission

Fracture mechanics

Quasi-fragile materials

Correlation length

Modélisation explicite de l’initiation et la propagation de fractures / Explicit modeling of initiation and propagation of fractures

Hamdi, Jabrane Khalil

18 December 2017

L’étude du comportement des roches nécessite de comprendre leur réponse sous diverses sollicitations. L’étude énergétique de l’endommagement des roches est indispensable pour prédire les phénomènes dynamiques. Ces phénomènes sont dus au développement de fissures dans les roches soumises à des fortes contraintes initiales et induites. La fissuration est une forme de dissipation d’énergie qui permet de rétablir l'équilibre du milieu. L’objectif de la thèse est de modéliser la fissuration dans les milieux rocheux dans la perspective d’étudier le comportement des ouvrages souterrains à grande profondeur. Le développement des modèles capables de représenter la fissuration, la coalescence des fissures et leur interaction avec des fractures préexistantes est indispensable. De la littérature, il ressort deux principales approches théoriques et numériques de modélisation de la fissuration : continue et discrète. Une synthèse critique de ces approches nous a conduit à retenir l’approche discrète et plus particulièrement le code Yade dans le cadre de cette thèse. Ce code permet de simuler explicitement la fissuration avec ou sans fractures pré-existantes. Des développements ont été effectués afin de tenir compte des différentes formes d’énergie intervenant dans le comportement des roches soumises à des sollicitations. En particulier une corrélation entre l’énergie de fissuration numérique et l’activité microsismique observée sur des échantillons en laboratoire en compression. Les différentes composantes énergétiques explicitées puis implémentées dans Yade sont : le travail externe, l’énergie potentielle, l'énergie élastique, l’énergie de frottement, l’énergie de fissuration, l'énergie cinétique et l’énergie dissipée en amortissement. La validation de l’approche énergétique a été réalisée grâce à la simulation des essais de laboratoire. L’évolution des différentes composantes énergétiques a permis de vérifier que le bilan des énergies est correctement évalué. Le bilan énergétique a également été vérifié à échelle de structures en simulant l’excavation souterraine d’un Mine-by Experiment (URL Manitoba). L’extension de la zone endommagée induite par l’excavation prédite numériquement a été comparée à celle observée in-situ autour du Mine-by Experiment. Il a été constaté que l’endommagement prédit est similaire à celui observé dans les directions des contraintes initiales mineure et majeure. Par ailleurs la formulation énergétique permet d’étudier numériquement les processus de fissuration des roches. Wassermann (2006) a réalisé des essais de compression uniaxiale et triaxiale sur des échantillons de minerai de fer lorrain. Nous avons modélisé ces essais. La comparaison qualitative des événements acoustiques et des énergies de fissuration issues respectivement des essais et des simulations numériques a montré des tendances similaires. Par contre, la comparaison d’un point de vue quantitatif a montré que le nombre des événements acoustiques numériques est plus important que celui déterminé expérimentalement. L’énergie dissipée par fissuration numérique est également plus importante que celle obtenue sur les essais. Cette différence est expliquée par le fait que les capteurs du dispositif expérimental ne détectent pas tous les événements acoustiques. Les résultats obtenus pourront permettre de mieux comprendre les cinétiques des phénomènes dynamiques dans les ouvrages souterrains profonds. Une autre application a consisté à modéliser un pilier de mine de fer de Joeuf (Lorraine). Le modèle numérique montre deux modes de fissuration dans le pilier : (a) écaillage en peau de pilier, (b) deux bandes de rupture s’initiant du mur et toit du pilier pour se propager vers le cœur du pilier. Ce travail offre de bonnes perspectives pour mieux comprendre la propagation de la fissuration à plus grande échelle mais aussi de progresser dans la recherche de corrélation entre la géomécanique et la géophysique / The study of rock mass behavior requires the understanding of their response under various loadings. The study of rock damage from an energetic point of view is essential in order to predict dynamic phenomena. These phenomena are due to the development of cracks in rocks subjected to strong initial and induced stresses. Fracturing is a form of energy dissipation that restores the balance of the involved medium. The aim of the thesis is to model rock cracks and study the behavior of underground structures at great depths. The development of models able to simulate the fracturing, the coalescence of cracks and their interaction with pre-existing fractures is essential. In the literature, there are two main theoretical and numerical approaches for crack modeling: continuous and discrete. A detailed analysis of these approaches has led us to choose the discrete approach and more particularly the code Yade. This code enables to simulate explicitly cracks propagation with or without pre-existing fractures. Developments have been made to evaluate the different forms of energy involved in rock behavior. In particular, a correlation between the cracks energy determined numerically and the microseismic activity observed in laboratory samples has been performed. The various energy components developed and then implemented in Yade are: external work, potential energy, elastic energy, friction energy, cracks energy, kinetic energy and damping energy. Validation of the energy approach was carried out by simulating laboratory tests. The evolution of the various energy components permits to verify that the energy balance is correctly evaluated. The energy balance was also verified at a structure scale by simulating the underground excavation of a Mine-by Experiment (URL Manitoba). The extension of the damaged zone induced by excavation and predicted by numerical simulations was compared with that observed in-situ around the Mine-by Experiment. It has been found that the predicted and the observed damage are similar in the directions of initial minor and major initial stresses. In addition, the energy formulation enables to study numerically the fracturing process of rocks. Wassermann (2006) performed uniaxial and triaxial compression tests on samples of iron ore from Lorraine. We have modeled these tests. The qualitative comparison of acoustic events and cracks energies determined from tests and numerical simulations showed similar trends. On the other hand, the quantitative comparison showed that the number of numerical acoustic events is greater than the number of experimental acoustic events. Also, the energy dissipated by cracks determined numerically is greater than the energy measured in the tests. This difference is explained by sensors accuracy of the experimental device, which are not able to detect all the generated acoustic events. The results obtained will allow us to better understand the dynamic phenomena in the deep underground structures. Another application consisted in modeling an iron ore pillar of Joeuf (Lorraine). The numerical model shows two modes of cracking in the pillar: (a) flaking of pillar wall, (b) two breaking bands initiating from the wall and the roof of the pillar to propagate towards his core. This provides good perspectives for better understanding cracks propagation at a larger scale, also to progress in the understanding of the correlation between geomechanics and geophysics

Fissuration

Initiation

Propagation

Bilan énergétique

Éléments discrets

Énergie de fissuration

Cracking

Initiation

Propagation

Energy balance

Discrete element

Cracks energy

551.875

624.151 32

Ecoulement confiné d'un matériau granulaire en interaction avec un gaz : application à la relocalisation du combustible nucléaire / Confined dense particle-gas flow : application to nuclear fuel relocation

Martin, Alexandre

25 February 2010

Ce travail de thèse est consacré à l'étude des écoulements biphasiques grains-gaz dans un régime de blocage (jamming). Ce régime caractérisé par un écoulement interrompu en temps fini et fréquemment rencontré dans la nature ou les applications industrielles présente un caractère stochastique. Sa compréhension nécessite la mesure de son débit, de ses fluctuations et de la probabilité d'arrêt liée à la géométrie de confinement, à la microstructure granulaire et au gaz interstitiel. Une approche numérique discrète couplant la méthode de la dynamique des contacts non-régulière (Non Smooth Contact Dynamics) pour la dynamique des particules et une méthode mésoscopique de type homogène équivalente pour le gaz est développée. La statistique d'écoulement obtenue est en bon accord avec des résultats expérimentaux de la littérature : le débit vérifie une loi de puissance croissante en fonction de l'ouverture avec un débit moyen affecté par la présence du gaz. Ces résultats statistiques quantitatifs sont appliqués à l'estimation du taux de relocalisation du combustible nucléaire fragmenté et confiné dans son tube-gaine présentant un ballonnement local suite à une situation accidentelle de type Perte de Réfrigérant Primaire. / In this work, we investigate particle-gas two-phase flows in the jamming regime where the flow stops in finite time. In this regime, which occurs quite often in nature and industrial applications, the flow is stochastic and needs therefore to be characterized by the jamming probability as well as the flow rate and its fluctuations that depend on the confining geometry, granular microstructure and gas properties. We developped a numerical approach based on the coupling of the Non Smooth Contact Dynamics for the solid phase and a mesoscopic method for the gas phase. We find that the flow rate as a function of the opening is well fit by a power law in agreement with reported experimental data. The presence of a gas affects only the mean flow rate, the flow statistics being sensibly the same as in the absence of the gas. We apply our quantitative statistical results in order to estimate the relocation rate of fragmented nuclear fuel inside its cladding tube as a result of a local balloon caused by an accident (loss-of-refrigerent accident).

Matériaux granulaires

Blocage

Éléments discrets

Couplage fluide-grains

Éléments finis

Relocalisation

Granular materials

Jamming

Discrete element method

Simulation of particulate flows

Finite element method

Relocation

Apport de la méthode des éléments discrets à la modélisation des maçonneries en contexte sismique : vers une nouvelle approche numérique de la vulnérabilité sismique. / On the Use of the Discrete Element Methods DEM in the Modeling of Masonry Structures Subjected to Seismic Loads : Towards a New Numerical Approach of the Evaluation of the Seismic Vulnerability.

Taforel, Paul

21 December 2012

L'évaluation des risques naturels et du risque sismique en particulier a pris une importance croissante pour les autorités publiques ces dernières années, entraînant une adaptation importante des outils utilisés jusqu'à présent dans l'étude de la vulnérabilité du bâti. Il est nécessaire de mieux évaluer ces risques afin de mieux y faire face. De nouvelles approches doivent être proposées pour répondre à ces objectifs dont les approches numériques font partie. Parmi les méthodes numériques développées pour tenir compte de la spécificité du bâti maçonné figurent les approches par éléments discrets comme la méthode NSCD (« Non Smooth Contact Dynamics »). Les travaux présentés dans cette thèse visent à mieux appréhender le comportement mécanique et dynamique des ouvrages maçonnés en utilisant ce type de méthode implémenté dans le code calcul LMGC90, afin d'affiner la compréhension et la caractérisation de la vulnérabilité sismique des édifices en maçonnerie. La méthodologie que nous cherchons à mettre en place vise à traiter la vulnérabilité sismique de bâtiments spécifiques ou au contraire d'ensembles de bâtiments de même typologie. / The perception and the evaluation of natural risks and more particularly of the seismic hazard have never been so important and highlighted by the authorities. This phenomenon leads to a deep adjustment of tools used up to now in the assessment of the vulnerability of buildings. New approaches as numerical approaches have to be proposed so as to best estimate the risk. Among all the numeriacl methods developed to take into account specificities of masonry buildings, approaches by discrete elements methods as the NSCD method (“Non Smooth Contact Dynamics”) seem to be particularly well adapted. This PhD thesis aims to best understand the mechanical behaviour of masonry structures by using this discrete method implemented in the software LMGC90 so as to give an accurate estmation of the seismic vulnerability of buildings. The very purpose of this work is to develop a calculation tool able to deal with the vulnerabilityof both specific and common masonry buildings.

Vulnérabilité sismique

Aléa sismique

Simulation numérique

Modélisation des maçonneries

Méthode des Eléments Discrets (DEM)

Seismic vulnerability

Seismic hazard

Numerical simulation

Masonry structures modeling

Discrete Element Method (DEM)

Análise teórico-experimental do comportamento de concretos reforçados com fibras de aço quando submetidos a cargas de impacto / A numerical and experimental analysis of steel fiber reinforced concretes subjected to impact loads

Garcez, Estela Oliari

January 2005

Quando o concreto é submetido a ações especiais, como cargas cíclicas ou ação de cargas de impacto, modificações em sua composição são necessárias, já que o concreto não apresenta desempenho satisfatório à tração, o que compromete o seu comportamento frente à ação de cargas dinâmicas. Uma alternativa para amenizar esta deficiência consiste em adicionar fibras ao concreto. Estas atuam como reforços à tração, transformando a matriz cimentícia, tipicamente frágil, em um material que apresenta boa resistência residual após a fissuração. Buscando colaborar na avaliação da eficiência de diferentes tipos de fibras, o presente trabalho analisa o comportamento de concretos com fibras de aço, submetidos ao impacto, avaliando a influência do fator de forma, do comprimento e do teor de fibras, assim como do tamanho do agregado. São ainda analisados os efeitos da incorporação de fibras na resistência à compressão, na resistência à tração por compressão diametral, no módulo de elasticidade e na tenacidade dos compósitos. Adicionalmente, é executada uma comparação entre os resultados experimentais e os derivados de um esquema de modelagem da situação de impacto através do uso do método de elementos discretos. Buscou-se, através da modelagem teórica, executar um mapeamento dos danos, provocados por cargas de impacto incrementais, ao longo do tempo, bem como determinar as energias necessárias para levar as placas até a ruptura. Os resultados indicam que a incorporação de fibras de aço não consegue retardar o aparecimento da primeira fissura, mas aumenta significativamente a tenacidade dos compósitos. Fibras mais longas e com maior fator de forma tendem a ser mais eficientes, desde que se supere um teor de fibras mínimo, que neste trabalho ficou em torno de 100.000 fibras/m3, para fibras longas (50-60 mm) e de 400.000 fibras/m3, para fibras curtas, cuja ancoragem é menos eficiente. O método de teste de impacto por queda de esfera se mostrou adequado e sensível, porém o esquema de modelagem numérica testado necessita ser refinado para permitir uma adequada simulação do comportamento de concretos com fibras. / When submitted to special loading patterns, derived from dynamical actions such as cyclic or impact loads, concrete elements need to be reinforced, in order to resist the tensile stresses. A feasible alternative, in such cases, is to incorporate fibers in the concrete matrix. The fibers act as a tensile reinforcement, transforming the fragile cement matrix into a composite with significant post-cracking residual strength. In order to contribute with the data collection about the efficiency of different fiber types, the present research work presents an analysis of the behavior of steel fiber reinforced concretes subjected to impact loads. The work investigates the influences of changes in the shape factor, length and amount of fibers. The effects of these combinations on other basic properties of the composites, such as compression strength, split cylinder tensile strength, Young’s modulus and tenacity is also measured. Additionally, a comparison is made between the experimental results from the impact tests and the estimates obtained from a theoretical model that uses the discrete element method (DEM). This theoretical approach aimed to determine if the model was able to simulate the damage evolution over time generated by the increasing impacts loads, as well as to determine the total energy necessary to crack and break the specimens. The results obtained pointed out that the introduction of steel fibers does not affect the energy for the first crack but increases significantly the tenacity of the composite. Longer fibers, with greater shape factors, tend to be more efficient, provided that the fiber content is sufficiently high. The minimum recommended fiber content, according to the data from this research, may be around 100.000 fibers/m3, for longer fibers (50-60 mm). Or around 400.000 fibers/m3, for shorter fibers, which are not so efficient in terms of anchorage. The impact test method developed was considered adequate, being sensitive to the phenomenon and providing reliable data. The DEM model, however, needs to be refined to be able to deal with fiber concrete composites.

Estruturas (Engenharia)

Método dos elementos discretos

Fibras de aço

Concreto reforçado com fibras

Steel fiber reinforced concrete

Composite materials

Impact loads

Discrete element method