Global ETD Search

191	Avaliação experimental da interação solo coesivo-fita polimérica sob condições de teor de umidade variáveis. / Experimental evaluation of the effect of soil moisture content on cohesive soil-geosynthetic strap interaction. Orlando, Patrícia Del Gaudio 20 March 2015 (has links) Em geral, as recomendações normativas sugerem a utilização de materiais granulares para a construção de estruturas em solo reforçado, principalmente devido à sua elevada resistência ao cisalhamento e boa capacidade de drenagem. No entanto, nem sempre há disponibilidade deste tipo de material no entorno das obras, tornando o uso dos solos finos imperativo para a viabilização desta solução. No Brasil, solos residuais finos são encontrados em abundância e, muitas vezes, apresentam excelentes parâmetros de resistência ao cisalhamento e baixa compressibilidade. Contudo, o seu uso pode induzir poro-pressões indesejáveis durante a construção ou cisalhamento do aterro reforçado. Por outro lado, as elevadas sucções matriciais que podem persistir em seu interior geram um aumento na estabilidade dos maciços reforçados. Neste contexto, este trabalho apresenta os resultados experimentais e discute o efeito da variação climática (umedecimento e secagem) na resistência de interface solo coesivo-fita polimérica de uma estrutura de contenção em solo reforçado. Os ensaios foram realizados com amostras compactadas de um solo residual de gnaisse típico da cidade de São Paulo e uma fita polimérica de alta aderência. Os corpos de prova foram submetidos a ensaios de cisalhamento direto e de arrancamento sob três diferentes níveis de tensão normal e de sucção, além da condição inundada. Ensaios triaxiais saturados (CU) e não saturados (CW) foram realizados para a determinação da envoltória de resistência tridimensional do solo, avaliação da eficiência da interação solo-reforço e para a verificação do comportamento da água intersticial durante o cisalhamento. Os resultados indicam que o solo coesivo em questão apresenta excelentes parâmetros de resistência ao cisalhamento, elevada capacidade de se manter sob pressões negativas da água intersticial e uma eficiente interação com as fitas poliméricas, o que possibilitaria a execução de estruturas estáveis quanto ao arrancamento dos reforços. Além disso, sugerem um crescimento não linear da máxima resistência de interface com o aumento da sucção matricial do solo e uma tendência de redução dos coeficientes de atrito aparente solo-reforço (f) com o umedecimento das amostras. Porém, mostraram que a sucção matricial exerce pouca influência na resistência residual da interface solo reforço. / Current specifications for reinforced soil structures generally require the use of granular backfill due to their high strength, well drainage capacity and low volume change potential. However, in cases where granular fills are not easily and readily available, poorly draining soils should be used to enable the implementation of a mechanically stabilized earth wall (MSEW). In Brazil, the fine-grained residual soils that cover large areas of its territory frequently present high shear strengths and low compressibility. However, the use of cohesive soils can cause unwanted effects in structure stability due to the water content variations of the backfill soil, and the potential development of pore-water pressures or loss of strength. On the other hand, matric suctions may increase the soil-geosynthetic interface shear strength. In this context, this study presents the experimental results and discusses the effects of seasonal climatic variations (wetting and drying) on shear strength of soil-geosynthetic straps interfaces under unsaturated conditions. For the laboratory investigation, a compacted residual soil of gneiss composed of 80% silty sand passed through a 0.075mm sieve, sourced from São Paulo city, and a high-tenacity polyester strap were used. Direct shear and pullout tests were conducted with three different net normal stresses and levels of matric suction, besides the inundated condition. Triaxial tests under saturated (CU) and unsaturated (CW) conditions with suction measurement using a high capacity tensiometer were performed in order to evaluate the shear strength parameters of the unsaturated soil, the interface efficiency of the soil-geosynthetic strap and the pore water pressure variations during shear. The results indicate that the cohesive soil used in this study has excellent shear strength parameters, a high capacity to maintain negative pore water pressures and presents an efficient interaction with the geosynthetics straps, which would allow the implementation of a stable MSEW for failure by pullout. Furthermore they reveal that the peak shear strength of the soil-geosynthetic strap interface increases nonlinearly with the soil suction, while the apparent friction factor (f) decreases with the increase in molding moisture contents. On the other hand, the effect of suction on the post-peak shear strength of the interface was negligible. Cohesive soil Condição não saturada Geossintéticos Geosynthetic strap Interface shear strength Reinforced soil structures Resistência de interface Solo reforçado Solos coesivos Unsaturated conditions
192	Fabricação e controle de espessura de juntas coladas single lap joint: caracterização mecânica dos aderentes e do adesivo / Manufacture and thickness control of single lap joints: mechanical properties characterization of adherents and adhesive Madureira, Fernando 28 September 2018 (has links) Devido a suas vantagens comparadas aos métodos tradicionais de união mecânica, a utilização de juntas coladas estruturais só tende a crescer, entretanto, devido suas propriedades e modos de falha dependerem de diversos parâmetros (tratamento superficial, geometria, material, condições de tralho, etc.) uma utilização mais ampla desta técnica ainda é restrita pela ausência de modelos de falhas confiáveis. O presente trabalho consiste na apresentação de métodos para fabricação de juntas coladas em material compósito e verificação da influência da espessura da camada adesiva na resistência de juntas simples coladas (single lap joints) submetidas à tração. São também apresentados métodos para fabricação dos aderentes, corpos de prova de adesivo puro para ensaios de caracterização e realização de ensaios mecânicos para obtenção das propriedades mecânicas tanto dos aderentes quanto do adesivo. As propriedades mecânicas dos aderentes e do adesivo foram obtidas através de ensaios realizados em uma máquina de tração universal com o auxílio da técnica de correlação digital de imagem, e a obtenção das energias críticas de resistência à fratura (GIc,GIIc) da camada adesiva foram calculadas através de ensaios Double Cantilever Beam (DCB) e End Notched Flexure (ENF). Foram estudados métodos para gerar falha coesiva nas juntas adesivas, sendo que o melhor método encontrado foi o de tratamento superficial dos aderentes com jateamento abrasivo seguido pela limpeza superficial com acetona. O controle preciso da espessura da camada adesiva foi alcançado através do desenvolvimento de um dispositivo de fácil construção, compostos por suportes de madeira, hastes e linhas de nylon. Nos ensaios em juntas coladas foi constatado uma relação inversamente proporcional entre a espessura da camada adesiva e a resistência máxima suportada pela junta, ou seja, quanto maior a espessura do adesivo menor sua resistência. Os métodos aqui apresentados foram os resultados de vários meses de estudo e compreensão das normas e técnicas disponíveis na literatura, o aprimoramento das técnicas foram frutos de um ciclo compostos por fabricação, testes e análise de resultados. / Amongst the joining techniques, adhesively bonding joints are one of the most commonly applied nowadays. However, a lack of reliable failure criteria still exists, limiting in this way a more widespread application of adhesively bonded joints in principal load-bearing structural applications. An accurate strength prediction of the adhesively bonded joints is essential to decrease the amount of expensive testing at the design stage. This work consists to show methods for manufacturing single lap joints and to verify the adhesive thickness influence on the joint resistance. The manufacturing process of the composite adherends and adhesives for bulk tests was also covered. The mechanical properties of the adherends and bulk adhesive were performed on a universal testing machine with assistance of a digital image correlation (DIC) technique. The fracture toughness energy release rates (GIc,GIIc) of the adhesive layer were obtained respectively through Double Cantilever Beam (DCB) and End Notched Flexure (ENF) tests. Cohesive failure was achieved by grit blasting the adherents followed by cleaning with acetone. A constant adhesive thickness was guaranteed by placing nylon fishing lines between the adherents. Single lap joints tests showed that the joint resistance decrease with increasing adhesive thickness. Adesivos Bonded joints Cohesive failure Composite structures Compósitos laminados Controle de espessura Correlação de imagem Digital image correlation Falha coesiva Juntas coladas Thickness control
193	Failure Prediction for Composite Materials with Generalized Standard Models Zhenyuan Gao (7481801) 17 October 2019 (has links) <div>Despite the advances of analytical and numerical methods for composite materials, it is still challenging to predict the onset and evolution of their different failure mechanisms. Because most failure mechanisms are irreversible processes in thermodynamics, it is beneficial to model them within a unified thermodynamic framework. Noting the advantages of so-called generalized standard models (GSMs) in this regard, the objective of this work is to formulate constitutive models for several main failure mechanisms: brittle fracture, interlaminar delamination, and fatigue behavior for both continuum damage and delamination, in a generalized standard manner.</div><div><br></div><div>For brittle fracture, the numerical difficulties caused by damage and strain localization in traditional finite element analysis will be addressed and overcome. A nonlocal damage model utilizing an integral-type regularization technique will be derived based on a recently developed ``local'' continuum damage model. The objective is to make this model not only rigorously handle brittle fracture, but also incorporate common damage behavior such as damage anisotropy, distinct tensile and compressive damage behavior, and damage deactivation. A fully explicit integration scheme for the present model will be developed and implemented.</div><div><br></div><div>For fatigue continuum damage, a viscodamage model, which can handle frequently observed brittle damage phenomena, is developed to produce stress-dependent fatigue damage evolution. The governing equation for damage evolution is derived using an incremental method. A class of closed-form incremental constitutive relations is derived. </div><div><br></div><div>For interlaminar delamination, a cohesive zone model (CZM) will be proposed. Focus is placed on making the associated cohesive elements capable of displaying experimental critical energy release rate--mode mixture ratio relationships. To achieve this goal, each cohesive element is idealized as a deformable string exhibiting path dependent damage behavior. A damage model having a path dependence function will be developed, which will be constructed such that each cohesive element can exhibit designated, possibly sophisticated mixed-mode behavior. The rate form of the cohesive law will be subsequently derived.</div><div><br></div><div>Finally, a CZM for interlaminar fatigue, capable of handling brittle damage behavior, is developed to produce realistic interlaminar crack propagation under high-cycle fatigue. An implicit integration scheme, which can handle complex separation paths and mixed-mode delamination, is developed. Many numerical examples will be utilized to clearly demonstrate the capabilities of the proposed nonlocal damage model, continuum fatigue damage model, and CZMs for quasi-static and fatigue delamination.</div> Composite and Hybrid Materials Theory and Design of Materials Numerical Computation Generalized standard materials Composite materials cohesive zone models Continuum damage mechanics fatigue damage
194	Modélisation du comportement mécanique des composites a matrice céramique : développement du réseau de fissures / Damage model for the mechanical behaviour of ceramic matrix composite materials : crack networks development Coradi, Audrey 18 November 2014 (has links) Les matériaux composites à matrice céramique (CMC) sont élaborés à partir de constituants fragiles. Le comportement mécanique et le développement de la fissuration dépendent des propriétés des constituants élémentaires des CMC. La connaissance de l’influence de ces propriétés sur l’évolution de la fissuration et du comportement mécanique fournit une aide au concepteur de matériaux composites.L’objectif de ce travail est de modéliser l’évolution du réseau de fissures au sein du CMC sollicité en traction, à l’échelle du fil et à l’échelle du composite tissé. L’approche proposée est une alternative aux principaux modèles de comportement des CMC.A l’échelle du fil, l’endommagement intervient d’abord sous forme de fissures matricielles accompagnées de décohésions à l’interface fibre/matrice. Les analyses de ces deux mécanismes ont permis d’exprimer leur évolution au sein du fil en traction. Le comportement en traction résultant de l’endommagement et l’ouverture de la fissure matricielle sont aussi exprimés semi-analytiquement.Les comparaisons avec un modèle numérique de zones cohésives et avec les essais expérimentaux montrent une bonne corrélation des résultats.Enfin ces expressions à l’échelle du fil sont utilisées pour modéliser l’endommagement du fil longitudinal au sein du composite tissé en traction. De plus, un outil numérique est développé pour modéliser la fissuration matricielle inter-fil dans le composite tissé. / Ceramic matrix composite materials (CMC) are elaborated from fragile constituents. Their mechanical behaviour and crack growing depend on the properties of the CMC elementary constituent. Knowing the influence of these properties on crack development and mechanical behaviour provides support to the composite material designer.This work aims at modelling the crack networks development within the CMC under axial tension, at the yarn scale as well as at the woven composite scale. The proposed approach is an alternative to the main CMC behaviour models.At the yarn scale, matrix cracking with interfacial debonding between fiber and matrix first happen. Both mechanisms are analysed and their development are expressed. The mechanical behaviour resulting from damage and the crack opening displacement are also described using semi-analytical equations. Comparisons with numerical cohesive zone model and also with experimental testing shows good correlation between results.These semi-analytical expressions are then used for modelling damage within each yarns at the woven composite scale. In addition, a numerical tool is developed for matrix cracking and interfacial debonding between yarns of the woven composite. Composites à matrice céramique Fissures Mécanique de la rupture Modèles d’endommagement Comportement mécanique Modèles de zones cohésives Ceramic matrix compositeMaterials Crack development Damage models Mechanical behaviour Cohesive zone models
195	Micromechanical modeling of cleavage fracture in polycrystalline materials Stec, Mateusz January 2008 (has links) Cleavage fracture in ferritic steels can be defined as a sequence of few critical steps. At first nucleation of a microcrack takes place, often in a hard inclusion. This microcrack then propagates into the surrounding matrix material. The last obstacle before failure is the encounter of grain boundaries. If a microcrack is not arrested during any of those steps, cleavage takes place. Temperature plays an important role since it changes the failure mode from ductile to brittle in a narrow temperature interval. In papers A and B micromechanical models of the last critical phase are developed (cleavage over a grain boundary) in order to examine the mechanics of this phase. An extensive parameter study is performed in Paper A, where cleavage planes of two grains are allowed to tilt relative each other. It is there shown that triaxiality has a significant effect on the largest grain size that can arrest a rapidly propagating microcrack. This effect is explained by the development of the plastic zone prior to crack growth. The effect of temperature, addressed through a change in the visco-plastic response of the ferrite, shows that the critical grain size increases with the temperature. This implies that with an increasing temperature more cracks can be arrested, that is to say that less can become critical and thus that the resistance to fracture increases. Paper B shows simulations of microcrack propagation when the cleavage planes of two neighboring grains are tilted and twisted relatively each other. It is shown that when a microcrack enters a new grain, it first does it along primary cleavage planes. During further growth the crack front is protruded along the primary planes and lags behind along the secondary ones. The effect of tilt and twist on the critical grain size is decoupled with twist misorientation offering a greater resistance to propagation. Simulations of cracking of a particle and microcrack growth across an inclusion-matrix interface are made in Paper C. It is shown that the particle stress can be expressed by an Eshelby type expression modified for plasticity. The analysis of dynamic growth, results in a modified Griffith expression. Both findings are implemented into a micromechanics-based probabilistic model for cleavage that is of a weakest link type and incorporates all critical phases of cleavage: crack nucleation, propagation over particle-matrix interface and into consecutive grains. The proposed model depends on six parameters, which are obtained for three temperatures in Paper D using experimental data from SE(B) tests. At the lowest temperature, -30° , the model gives an excellent prediction of the cumulative failure probability by cleavage fracture and captures the threshold toughness and the experimental scatter. At 25º and 55º the model slightly overestimates the fracture probability. In Paper E a serie of fracture experiments is performed on half-elliptical surface cracks at 25º in order to further verify the model. Experiments show a significant scatter in the fracture toughness. The model significantly overestimates the fracture probability for this crack geometry. / QC 20100910 cleavage fracture probabilistic modeling brittle to ductile transition cohesive zone visco-plastic material Engineering mechanics Teknisk mekanik Other technology Övriga teknikvetenskaper
196	Comportamiento en fatiga de poliamidas reforzadas con fibra de vidrio corta Casado del Prado, José Antonio 20 July 2001 (has links) El estudio muestra la existencia de tres estados en el comportamiento en fatiga de la poliamida reforzada con fibra de vidrio corta su rotura.En el estado I se genera deformación por fluencia transitoria, lo que conlleva disipación de energía en el material que aumenta su temperatura. Si el incremento térmico se estabiliza el materialsoporta un número ilimitado de ciclos. Si aumenta la temperatura, la deformación del material alcanza un valor para el que se produce la transición al estado II.En el estado II el material se deforma a velocidad constante. Se inician fenómenos de crazing o pseudo-fisuración en el material, con cierta capacidad portante de carga. El proceso conduce a una inestabilidad final cuando la deformación del material alcanza el valor para el que sucede la transición al estado III.En el estado III se produce la inestabilidad local en el material que antecede a su rotura. Se debe a que el desarrollo de los crazes produce un crecimiento acelerado de la deformación del material y se obtiene su rotura tras un número de ciclos bajo. / The work shows the existence of three states in the fatigue behaviour of short fibre-glass reinforced polyamide up to the moment of failure. In the state I creep transient deformation processes are produced. If temperature, associated to the dynamic process, stabilises, the material is able to withstand an unlimited number of cycles. On the other hand, if temperature grows continuously the material takes a critical strain for which a transition to the state II is reached. This new state shows a constant material´s deformation rate and a homogeneous nucleation of crazing phenomena. The hysteresis energy per cycle grows in a constant way and the material´s temperature increases. These conditions lead to the final instability that starts when the material´s deformation reaches a new critical value for which a second transition to the state III takes place. Under these circumstances local instabilities precede material´s final fracture. This is due to the quantity of crazes and their sizes, which are important enough to origin high concentration of mechanical effects to produce a material´s accelerated growth deformation to obtain its fracture. Crazing (cohesive cracks) Short fibber glass reinforced polyamide Fatigue Pseudo-fisuración (fisuras cohesivas) Poliamida reforzada con fibra de vidrio Fatiga 62 620
197	Numerical methods for dynamic contact and fracture problems Doyen, David 02 December 2010 (has links) (PDF) The present work deals with the numerical solution of dynamic contact and fracture problems. The contact problem is a Signorini problem with or without Coulomb friction. The fracture problem uses a cohesive zone model with a prescribed crack path. These problems are characterized by a non-regular boundary condition and can be formulated with evolutionary variational inequations or differential inclusions. For the numerical solution, we combine, as usual in solid dynamics, a finite element discretization in space and time-integration schemes. For the contact problem, we begin by comparing the main methods proposed in the literature. We then focus on the so-called modified mass method recently introduced by H. Khenous, P. Laborde et Y. Renard, for which we propose a semi-explicit variant. In addition, we prove a convergence result of the space semi-discrete solutions to a continuous solution in the frictionless viscoelastic case. We also analyze the space semi-discrete and fully discrete problems in the friction Coulomb case. For the dynamic fracture problem, using a fully explicit scheme is impossible or not robust enough. Therefore, we propose time-integration schemes where the boundary condition is treated in an implicit way. Finally, we present and analyze augmented Lagrangian methods for static fracture problems [MATH] Mathematics [MATH] Mathématiques [SPI] Engineering Sciences [SPI] Sciences de l'ingénieur Solid dynamics Unilateral contact Coulomb friction Cohesive zone models Finite elements Time-integration schemes
198	Simulation of delamination in composites under quasi-static and fatigue loading using cohesive zone models Turon Travesa, Albert 18 December 2006 (has links) Es desenvolupa una eina de disseny per l'anàlisi de la tolerància al dany en composites. L'eina pot predir el inici i la propagació de fisures interlaminars. També pot ser utilitzada per avaluar i planificar la necessitat de reparar o reemplaçar components durant la seva vida útil. El model desenvolupat pot ser utilitzat tan per simular càrregues estàtiques com de fatiga.El model proposat és un model de dany termodinàmicament consistent que permet simular la delaminació en composites sota càrregues variables. El model es formula dins el context de la Mecànica del Dany, fent ús dels models de zona cohesiva. Es presenta un metodologia per determinar els paràmetres del model constitutiu que permet utilitzar malles d'elements finits més bastes de les que es poden usar típicament. Finalment, el model és també capaç de simular la delaminació produïda per càrregues de fatiga. / A design tool for the analysis of delamination in laminated composites was developed. The design tool is developed using the damage-tolerance concept to predict both delamination initiation and growth. Therefore, the model developed can be used to perform either strength or damage-tolerance verification of new components, and can be used to assess the necessity to repair or replace in-service components. The model developed can be used either to simulate quasi-static or fatigue loading.A thermodinamically consistent damage model is proposed for the simulation of delamination in composite materials under variable-mode loading. The model is formulated in the context of Damage Mechanics by means of the Cohesive Zone Model concept. Moreover, a methodology to determine the parameters of the constitutive model is proposed. The methodology presented allows the use of coarser meshes that is usually admissible. Finally, the model has been enhanced to simulate high cycle fatigue. Cohesive zone model Modelo de zona cohesiva Model de zona cohesiva Fatiga de materials Fatiga de materiales Fatigue of materials Deterioration of materials Deterioramiento de materiales Deteriorament de materials Composites Compuestos Compostos 620
199	Influência de substâncias irrigadoras endodônticas nas propriedades mecânicas da dentina radicular Queiroz, Ellyne Cavalcanti 13 March 2007 (has links) The aim of this study was to evaluate the influence of different endodontic irrigants on the cohesive and flexural strength of the root dentin. One hundred of bovine incisor roots were selected, instrumented and randomly divided into 10 experimental groups (n = 10), according to the irrigation solution used: Control - physiological solution; N1 - sodium hypochlorite 1.0%; N5 - sodium hypochlorite 5.25%; N1EDTA - sodium hypochlorite 1.0% associate to EDTA 17%; N5EDTA - sodium hypochlorite 5.25% associate to EDTA 17%; Sclx chlorhexidine gluconate solution 2.0%; Gclx - chlorhexidine gluconate gel 2.0%; SclxEDTA - chlorhexidine gluconate solution 2.0% associate to EDTA 17%; GclxEDTA - chlorhexidine gluconate gel 2.0% associate to EDTA 17% and EDTA - EDTA 17%. The roots were axially sectioned in two halves. Half of them were used for the microtensile cohesive strength test: six 1.0mm thick slices were trimmed to produce hourglass shaped samples with a test area of 1mm2. The other halves were used in a 3-point bend flexural strength by means of dentine bars with 1X1X12 mm. Each sample remained two hours in contact with the irrigant solutions, except for EDTA, which remained for five minutes. After irrigants treatment, samples were rinsed with distilled water, and tested. Specific devices for each test were used, in a universal testing machine with a load cell of 20Kgf, and a crosshead speed of 0.5 mm/minute. Date were recorded and statistically analyzed with one-way ANOVA and Tukey test. Significant reduction in the ultimate cohesive strength and flexural strength was verified only for the groups that used sodium hypochlorite irrespective of the concentration and additional solution, differing significant from the group control. The use of chlorhexidine and EDTA separately did not cause alteration in the mechanical properties of root dentine. / O objetivo desse estudo foi avaliar a influência de diferentes irrigantes endodônticos na resistência coesiva e flexural da dentina radicular. Cem raízes de incisivos bovinos foram selecionadas, instrumentadas e divididas aleatoriamente em 10 grupos experimentais (n= 10), de acordo com a substância irrigadora utilizada: Controle - solução fisiológica; N1 - hipoclorito de sódio a 1,0%; N5 - hipoclorito de sódio a 5,25% ; N1EDTA - hipoclorito de sódio a 1,0% associado à EDTA a 17%; N5EDTA - hipoclorito de sódio a 5,25% associado à EDTA a 17%; Sclx - solução de gluconato de clorexidina a 2,0%; Gclx - gel de gluconato clorexidina a 2,0%; SclxEDTA - solução de gluconato clorexidina 2,0% associado à EDTA a 17%; GclxEDTA - gel de gluconato clorexidina a 2,0% associado à EDTA a 17% e EDTA - EDTA a 17%. As raízes foram axialmente seccionadas em duas metades. Uma metade foi utilizada para ensaio de microtração, da qual foram obtidas seis fatias de 1,0mm de espessura que receberam constrições na face externa, determinando área de teste de 1mm2. A outra metade foi utilizada no ensaio de flexão de 3-pontos, da qual foi extraída uma barra de dentina com dimensões de 1X1X12 mm. Cada amostra permaneceu duas horas em contato com a substância irrigante endodôntica com exceção do EDTA, que atuou por cinco minutos. Após o tratamento com os irrigantes, procedeu-se a lavagem com água destilada, e em seguida executados os ensaios mecânicos. Foram utilizados dispositivos específicos para cada ensaio, acoplados à máquina de ensaio mecânico, utilizando célula de carga de 20Kgf, com velocidade de 0,5 mm/minuto até a fratura da amostra. Os dados obtidos foram submetidos à análise de variância e teste Tukey. Verificou-se redução significativa na resistência máxima coesiva e flexural apenas para os grupos que empregaram o hipoclorito de sódio independe da concentração e associação com outra substância, diferindo estatisticamente do grupo controle. O uso de clorexidina e EDTA isoladamente não alterou as propriedades mecânicas da dentina radicular. / Mestre em Odontologia Irrigação endodôntica Hipoclorito de sódio Gluconato de clorexidina EDTA Resistência máxima coesiva Resistência flexural Endodontia Endodontic irrigants Sodium hypochlorite Chlorhexidine gluconate Cohesive strength Flexural strength. CNPQ::CIENCIAS DA SAUDE::ODONTOLOGIA
200	In-situ X-ray computed tomography tests and numerical modelling of ultra high performance fibre reinforced concrete Qsymah, Ansam January 2016 (has links) Ultra high performance fibre reinforced concrete (UHPFRC) is a relatively new fibre reinforced cementitious composite and has become very popular in construction applications. Extensive experimental studies have been conducted, demonstrating its superior properties such as much higher strength, ductility and durability than conventional fibre reinforced concrete (FRC) and high performance concrete. However, the material's damage and fracture mechanisms at meso/micro scales are not well understood, limiting its wider applications considerably. This study aims at an in-depth understanding of the damage and fracture mechanisms of UHPFRC, combining microscale in-situ X-ray computed tomography (µXCT) experiments and mesoscale image-based numerical modelling. Firstly, in-situ µXCT tests of small-sized UHPFRC specimens under wedge splitting loading were carried out, probably for the first time in the world, using an in-house designed loading rig. With a voxel resolution of 16.9µm, the complicated fracture mechanisms are clearly visualised and characterised using both 2D images and 3D volumes at progressive loading stages, such as initiating of micro-cracks, arresting of cracks by fibres, bending and pulling out of fibres and spalling of mortar at the exit points of inclined fibres. Secondly, based on the statistics of pores in the µXCT images obtained for a 20mm cube specimen, an efficient two-scale analytical-numerical homogenisation method was developed to predict the effective elastic properties of the UHPFRC. The large number of small pores were first homogenised at microscale with sand and cement paste, using elastic moduli from micro-indentation tests. 3D mesoscale finite element models were built at the second scale by direct conversion of the µXCT images, with fibres and large pores were faithfully represented. The effects of the volume fraction and the orientation of steel fibres on the elastic modulus were investigated, indicating that this method can be used to optimise the material micro-structure. Thirdly, 3D mesoscale finite element models were built for the specimen used in the in-situ µXCT wedge splitting test, with embedded fibre elements directly converted from the µXCT images. The fracture behaviour in the mortar was simulated by the damage plasticity model available in ABAQUS. Finally, 2D mesoscale finite element models were developed to simulate the fracture behaviour of UHPFRC using cohesive interface elements to simulate cracks in the mortar, and randomly distributed two-noded 1D fibres and connector elements to simulate the pull-out behaviour of fibres. This approach offers a link between the fibres pull-out behaviour and the response of the whole composite at the macroscale, thus it can be used to conduct parametric studies to optimise the material properties.

Search results