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UNDERSTANDING DEGRADATION AND LITHIUM DIFFUSION IN LITHIUM ION BATTERY ELECTRODESLi, Juchuan 01 January 2012 (has links)
Lithium-ion batteries with higher capacity and longer cycle life than that available today are required as secondary energy sources for a wide range of emerging applications. In particular, the cycling performance of several candidate materials for lithium-ion battery electrodes is insufficient because of the fast capacity fading and short cycle life, which is mainly a result of mechanical degradation.
This dissertation mainly focuses on the issue of mechanical degradation in advanced lithium-ion battery electrodes. Thin films of tin electrodes were studied where we observed whisker growth as a result of electrochemical cycling. These whiskers bring safety concerns because they may penetrate through the separator, and cause short-circuit of the electrochemical cells. Cracking patterns generated in amorphous silicon thin film electrodes because of electrochemical cycling were observed and analyzed. A two-dimensional spring-block model was proposed to successfully simulate the observed cracking patterns. With semi-quantitative study of the cracking pattern features, two strategies to void cracking in thin-film electrodes were proposed, namely reducing the film thickness and patterning the thin-film electrodes.
We also investigated electrodes consisting of low melting point elements and showed that cracks can be self-healed by the solid-to-liquid phase transformation upon cycling. Using gallium as an example, mechanical degradation as a failure mechanism for lithium-ion battery electrodes can be eliminated.
In order to quantitatively understand the effect of surface modification on electrodes, we analyzed diffusion equations with boundary conditions of finite interfacial reactions, and proposed a modified potentialstatic intermittent titration technique (PITT) as an electro-analytical technique to study diffusion and interfacial kinetics. The modified PITT has been extended to thin-film geometry and spherical geometry, and thus can be used to study thin-film and composite electrodes consisting of particles as active materials.
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Signature analysis of the primary components of the Koeberg nuclear power station / J.A. BezuidenhoutBezuidenhout, Jandré Albert January 2010 (has links)
In line with its commitment to safe nuclear power generation, the Koeberg Nuclear
Power Station (KNPS) replaced the outdated vibration monitoring system with a modern
on-line vibration monitoring system. This will allow plant personnel to monitor
components on a continuous basis which will provide faster response time in the
scenario of excessive vibrations of the primary components.
This study focuses on the analysis of the vibration of the primary components of the
KNPS by analysing the frequency spectra of the vibration signals of the primary
components and comparing these to reference signatures obtained during similar
operating conditions. The condition of the vibration sensors will also be evaluated.
In order to obtain a deeper understanding of the vibration behaviour and hence vibration
signatures of the KNPS primary reactor components, a simplified mathematical model
of the primary components is developed, based on the system of elasto-dynamic
equations. The equations are solved numerically and used to simulate the KNPS
vibration monitoring system. The mechanical system is modelled. Time series are
generated and Fast Fourier Transforms (FFT) are calculated to simulate the new KNPS
monitoring system. In the simulation mechanical degradation of the primary
components as well as sensor degradation is simulated.
The purpose of this study is to indicate whether mechanical degradation has occurred in
the primary components of the plant and to validate the vibration signals. At the same
time the study aims to lay a foundation for future monitoring and interpretation of
vibration signatures by simulating the vibration and the monitoring signals.
It was found that the primary components had not been affected by mechanical
degradation as no deviations in resonances were detected in the frequency signatures.
A small number of vibration sensors were found to have deteriorated; hence
replacement / maintenance was proposed.
The mechanical model and the simulation of the monitoring signals proved to be useful
to understand and interpret the vibration of the KNPS primary components. / Thesis (M.Ing. (Nuclear Engineering))--North-West University, Potchefstroom Campus, 2011.
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Signature analysis of the primary components of the Koeberg nuclear power station / J.A. BezuidenhoutBezuidenhout, Jandré Albert January 2010 (has links)
In line with its commitment to safe nuclear power generation, the Koeberg Nuclear
Power Station (KNPS) replaced the outdated vibration monitoring system with a modern
on-line vibration monitoring system. This will allow plant personnel to monitor
components on a continuous basis which will provide faster response time in the
scenario of excessive vibrations of the primary components.
This study focuses on the analysis of the vibration of the primary components of the
KNPS by analysing the frequency spectra of the vibration signals of the primary
components and comparing these to reference signatures obtained during similar
operating conditions. The condition of the vibration sensors will also be evaluated.
In order to obtain a deeper understanding of the vibration behaviour and hence vibration
signatures of the KNPS primary reactor components, a simplified mathematical model
of the primary components is developed, based on the system of elasto-dynamic
equations. The equations are solved numerically and used to simulate the KNPS
vibration monitoring system. The mechanical system is modelled. Time series are
generated and Fast Fourier Transforms (FFT) are calculated to simulate the new KNPS
monitoring system. In the simulation mechanical degradation of the primary
components as well as sensor degradation is simulated.
The purpose of this study is to indicate whether mechanical degradation has occurred in
the primary components of the plant and to validate the vibration signals. At the same
time the study aims to lay a foundation for future monitoring and interpretation of
vibration signatures by simulating the vibration and the monitoring signals.
It was found that the primary components had not been affected by mechanical
degradation as no deviations in resonances were detected in the frequency signatures.
A small number of vibration sensors were found to have deteriorated; hence
replacement / maintenance was proposed.
The mechanical model and the simulation of the monitoring signals proved to be useful
to understand and interpret the vibration of the KNPS primary components. / Thesis (M.Ing. (Nuclear Engineering))--North-West University, Potchefstroom Campus, 2011.
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Polyamide Carbon Fibre Filled Composite Ageing Characterization in Conventional Automotive FluidsGrimshaw, Samuel January 2016 (has links)
The use of carbon fibre-reinforced plastic technology is steadily gaining traction in the modern automotive industry as a lightweight alternative to conventional materials. The versatile chemical resistance of polyamide resins combined with the high strength properties of carbon fibre filler content aims to meet this growing need in the industry. By employing a number of accelerated and amplified ageing techniques, this work hopes to assess the resilience of carbon fibre-reinforced polyamide composites in a variety of foreseeable chemical, temperature, moisture, and stress environments.
The resins included in this characterization study include polyamide-6 (PA6) and polyamide-6,6 (PA6/6). The carbon fibre-reinforced composite specimens are subject to long term immersion in commercial automotive fluids at room and elevated temperatures. Results show that the mechanical properties of both polyamide resins are sensitive to windshield washer fluid exposure, regardless of temperature. The significant drop in glass transition temperature and greater elongation at break confirmed a plasticization effect. The Young’s modulus and tensile strength experienced a loss of approximately 40% at saturation.
Elevated temperatures resulted in increased fluid sorption rates of antifreeze and E-20 gasoline into the PA6 composite specimens. Likewise, a corresponding drop in PA6 composite mechanical properties was noted for the antifreeze and E-20 gasoline at elevated temperatures. The mechanical properties of the PA6/6 composite were largely retained in all tested automotive fluids, except windshield washer fluid, at elevated temperatures. The effect of absorbed fluid on mechanical properties tended to increase with higher fibre loadings for the PA6/6 composite and lower fibre loadings for the PA6 composite.
Finally, a single parameter acoustic emission testing technique was employed to assess internal damage of stressed PA6 composite specimens exposed to different temperature and humidity levels. However, there was no discernible correlation between environmental stress conditions and internal damage for short term exposure times. / Thesis / Master of Applied Science (MASc) / The use of carbon fibre-reinforced plastic technology is steadily gaining traction in the modern automotive industry as a lightweight alternative to conventional materials. The versatile chemical resistance of polyamide resins combined with the high strength properties of carbon fibre filler content aims to meet this growing need in the industry. By employing a number of accelerated and amplified ageing techniques, this work assessed the resilience of carbon fibre-reinforced polyamide composites in a variety of foreseeable chemical, temperature, moisture, and stress environments. The composite only showed significant sensitivity to windshield wiper fluid in the tests.
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Etude du comportement d'additifs polymères épaississants dans les huiles moteur / Study of thickening bahavior of polymer additives in engine oilsDorenge, Justine 02 July 2018 (has links)
La réduction de la consommation en carburant des voitures est une préoccupation importante. L'objectif est de réduire les frottements entre pièces mobiles du moteur à travers la formulation du lubrifiant.Un lubrifiant est composé d'une huile de base et d'additifs afin d'ajuster les propriétés de l'huile moteur. En particulier, des polymères sont utilisés pour limiter la perte de viscosité avec la température afin de protéger au mieux les pièces du moteur. Le fonctionnement de ce type d'additifs, appelés améliorants de viscosité (AVI), est basé sur le gonflement avec la température des chaines polymères. Le paramètre le plus important à prendre en compte dans la formulation d'un lubrifiant est sa viscosité ainsi que sa dépendance en température. Le but de ce travail a été d'étudier l'influence de polymères AVI récemment commercialisés afin de sélectionner le plus efficace dans le cadre d'une application moteur, tout en éclaircissant les mécanismes d'action en jeu à l'échelle moléculaire dans ce type de systèmes. Les propriétés rhéologiques de poly(alkyle méthacrylates) en solution ont été étudiées à l'aide de tests standards dans le but de comprendre l'influence des lubrifiants sous pression et dans des conditions confinées. La dégradation de ce type de polymère a également été considérée à travers un test standard afin de vérifier si les performances du polymère sont conservées dans le temps. Les comportements en dégradation et en tribologie ont pu être rationalisés par des considérations de volume occupé par le polymère. / The reduction of car fuel consumption is one of the biggest concerns for oil companies. It involves the reduction of friction between moving parts through the formulation of lubricants.A lubricant is composed of base oil and several additives used to improve the properties of engine oils. Polymeric compounds are used to limit the decrease of viscosity with temperatures to efficiently protect the motor. This type of additives, called Viscosity Index Improver (VII), is based on the swelling of polymer chains with temperature. The most important parameter in the lubricant formulation is the viscosity and its dependance on temperature. The aim of the work was to study the influence of recently developed families of VII additives in different base oils in ordrer to select the most efficient type of polymer for engine lubricant uses, by understanding the molecular mechanisms responsible of the VII behavior. Various polyalkylmethacrylates were investigated to establishing the rheological properties of the solutions, namely as a function of temperature (dependence of intrinsic viscosity). For a given base oil, the efficiency of a VII varies with its chemical structure, its molecular weight and its concentration. Then, tribological properties were investigated using standard tests with the aim to obtain an overview of the lubricant's behavior under pressure. We also considered the degradation of this kind of polymers in a representative test in order to check the performance's durability. Degradation and tribological behaviors were rationalized in terms of volume occupied by polymer chains.
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UNDERSTANDING AND IMPROVING LITHIUM ION BATTERIES THROUGH MATHEMATICAL MODELING AND EXPERIMENTSDeshpande, Rutooj D. 01 January 2011 (has links)
There is an intense, worldwide effort to develop durable lithium ion batteries with high energy and power densities for a wide range of applications, including electric and hybrid electric vehicles. For improvement of battery technology understanding the capacity fading mechanism in batteries is of utmost importance. Novel electrode material and improved electrode designs are needed for high energy- high power batteries with less capacity fading. Furthermore, for applications such as automotive applications, precise cycle-life prediction of batteries is necessary.
One of the critical challenges in advancing lithium ion battery technologies is fracture and decrepitation of the electrodes as a result of lithium diffusion during charging and discharging operations. When lithium is inserted in either the positive or negative electrode, there is a volume change associated with insertion or de-insertion. Diffusion-induced stresses (DISs) can therefore cause the nucleation and growth of cracks, leading to mechanical degradation of the batteries. With different mathematical models we studied the behavior of diffusion induces stresses and effects of electrode shape, size, concentration dependent material properties, pre-existing cracks, phase transformations, operating conditions etc. on the diffusion induced stresses. Thus we develop tools to guide the design of the electrode material with better mechanical stability for durable batteries.
Along with mechanical degradation, chemical degradation of batteries also plays an important role in deciding battery cycle life. The instability of commonly employed electrolytes results in solid electrolyte interphase (SEI) formation. Although SEI formation contributes to irreversible capacity loss, the SEI layer is necessary, as it passivates the electrode-electrolyte interface from further solvent decomposition. SEI layer and diffusion induced stresses are inter-dependent and affect each-other. We study coupled chemical-mechanical degradation of electrode materials to understand the capacity fading of the battery with cycling. With the understanding of chemical and mechanical degradation, we develop a simple phenomenological model to predict battery life.
On the experimental part we come up with a novel concept of using liquid metal alloy as a self-healing battery electrode. We develop a method to prepare thin film liquid gallium electrode on a conductive substrate. This enabled us to perform a series of electrochemical and characterization experiments which certify that liquid electrode undergo liquid-solid-liquid transition and thus self-heals the cracks formed during de-insertion. Thus the mechanical degradation can be avoided. We also perform ab-initio calculations to understand the equilibrium potential of various lithium-gallium phases.
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[pt] MONITORAMENTO DA DEGRADAÇÃO HIDROTÉRMICA DE REPAROS DE COMPÓSITO DE TUBULAÇÕES METÁLICAS OFFSHORE / [en] MONITORING OF THE HYGROTHERMAL DEGRADATION OF COMPOSITE REPAIRS FOR OFFSHORE METALLIC PIPELINESGEOVANE DE ALMEIDA SANTOS DA SILVA 08 August 2023 (has links)
[pt] Geralmente, o ambiente marinho é o ambiente natural mais agressivo para tubulações metálicas, promovendo corrosão, levando a falhas catastróficas. O método de reparo tradicional metálico soldado é um método de reparo inconveniente e custoso para a indústria. Compósitos poliméricos (FRP) são um material com potencial para reparo devido a sua alta razão resistência/peso e alta resistência à corrosão e degradação ambiental. Porém, os compósitos poliméricos também são suscetíveis a degradação severa quando expostos a condições ambientais agressivas, incluindo absorção de água, temperatura, UV e pressão. Para um melhor entendimento do mecanismo de degradação, amostras de compósito de matriz polimérica reforçado por fibras de vidro e resina epóxi pura foram fabricados e analisados em função do tempo e temperatura de envelhecimento em uma atmosfera salina. Além disso, um grupo de compósitos tiveram suas bordas cobertas com resina epóxi para similar práticas reais comuns no campo, denominado coated FRP. Uma resina epóxi DGEBA bicomponente e um tecido bidirecional de fibras de vidro foram usados como matriz e reforço, respectivamente. O tecido de fibra de vidro detém de uma razão de fibras longitudinais por transversais de 2:1. Os materiais foram sujeitos a envelhecimento de névoa salina em três câmaras à 35, 55 e 70 Celsius por aproximadamente 15171 horas. A concentração de sal na solução usada foi 5.0 por cento por massa. As amostras foram periodicamente retiradas das câmaras de envelhecimento para terem seus ganhos de massa mensurados pelo método gravitacional. Suas mudanças dimensionais também foram capturadas para avaliação do comportamento de inchamento dos materiais. Análises térmicas com DSC e DMTA foram feitas para avaliar o grau de cura dos materiais poliméricos e os efeitos da temperatura na pós-cura do material. Análises químicas com testes FTIR foram feitas para investigar a ocorrência de processos de pós-cura, hidrólise e termo-oxidação durante o envelhecimento. Amostras de compósito para testes destrutivos de flexão e resistência ao cisalhamento (ILSS) foram testados
periodicamente para terem suas degradações monitoradas com o tempo. Testes de Excitação por Impulso (IET) e Colorímetro foram realizados como testes não-destrutivos (NDT) complementares. A primeira parte deste trabalho foca na avaliação do comportamento de absorção de umidade nos compósitos e resina epóxi pura. A relação entre a capacidade de absorção de umidade dos materiais, considerando a fração volumétrica de fibras, foi investigada. Além disso, modelos de absorção não-Fickianos também foram aplicados aos dados experimentais do FRP e resina epóxi para considerar desvios do modelo Fickiano padrão. Com isso, relaxações poliméricas e interações polímero-água, assim como mudanças na rede polimérica induzidas por umidade e temperatura, foram investigados. Uma modificação ao modelo não-Fickiano de Berens-Hopfenberg (BH) foi proposta para incluir os efeitos de pós-cura na absorção de umidade; tal modificação aplicada a pós-cura não foi encontrada na literatura. Na segunda parte deste trabalho, o comportamento de inchamento da resina epóxi pura e compósitos revestidos e não-revestidos foi avaliado e correlacionado com a absorção de umidade. A ortotropia do compósito ficou evidente, visto que o material apresentou maior capacidade de inchamento na direção da espessura. Um modelo do tipo Fickiano foi implementado ao inchamento na espessura com o intuito de investigar deformação de inchamento de saturação e a frente de inchamento. A terceira parte deste trabalho foca nos testes destrutivos e na avaliação dos efeitos hidrotérmicos na degradação do material. A temperatura se mostrou um fator acelerador para degradação de propriedade. Além disso, uma metodologia para estimar a curva de serviço de sistemas de reparo e extrapolá-la para temperaturas mais baixas foi elaborada. Metodologias de extrapolação de propriedades para exposição hidrotérmica de longa duração não foram encontradas na literature. Parâmetros como platô de retenção de propriedade e taxa de degradação foram estimados para temperatura ambiente. Curvas de Arrhenius também foram plotadas para avaliar o tempo requerido para alcançar os níveis de retenção em cada temperatura testada. Por fim, duas técnicas não-destrutivas foram utilizadas no FRP e resina epóxi pura como testes complementares como forma de validar os resultados encontrados em outras técnicas. A Técnica de Excitação por Impulso (IET) foi realizada para obter o módulo de Young e boa correlação foi obtida entre o teste IET e o ensaio destrutivo de flexão. Através dos testes colorimétricos, os efeitos de umidade e temperatura foram visíveis, já que a mudança de cor da resina foi mais forte para tempos longos e temperaturas mais altas. / [en] Generally, the marine environment is the most aggressive natural environment for metallic pipelines, promoting corrosion, leading to catastrophic failures. The traditional welded metallic repairs are high-cost and inconvenient repair methods for the industry. Polymeric composites (FRP) are a potential repair material due to their high resistance/weight ratio and high resistance to corrosion and environmental degradation. However, polymeric composites are also susceptible to severe degradation when exposed to harsh environment conditions, including water absorption, temperature, UV and pressure. To better understand the degradation mechanism, glass-fiber reinforced polymer matrix composite (GFRP) and neat epoxy samples were fabricated and analyzed as a function of aging time and temperature in a saline atmosphere. In addition, a group of composites had their exposed edges coated with epoxy resin to simulate common real-life practices in the field, namely coated FRP. A two-component DGEBA epoxy resin and a bidirectional glass-fiber woven fabric were used as matrix and reinforcement, respectively. The fiberglass fabric had a longitudinal to transverse fiber ratio of 2:1. The materials were subjected to salt spray aging in three chambers at 35, 55 and 70 Celsius for approximately 15171 hours. The salt concentration in the solution used was 5.0 per cent by weight. Samples were periodically removed from the chambers to have their mass gain measured by the gravitational method. Their dimensional changes were also measured to evaluate the swelling behavior of the materials. Thermal analyses with DSC and DMTA were performed to evaluate the curing degree of the polymeric materials tested and the effects of temperature on the material’s post-curing. Chemical analyses with FTIR tests were performed to investigate the occurrence of post-curing, hydrolysis and thermo-oxidation processes during aging. Composite samples for bending and interlaminar shear strength (ILSS) destructive tests were periodically tested to have their degradation monitored over time. Impulse Excitation Technique and colorimetry tests were also performed as complementary non-destructive tests (NDT). The first part of this work focuses on the assessment of the moisture absorption behavior of both composite and neat epoxy resin. The relationship between the moisture gain capacity of the materials, considering the fiber volume fraction, was investigated. Besides, non-Fickian absorption models were also applied to the experimental data of FRP and neat epoxy resin to account for deviations from the standard Fickian model. Then, polymeric relaxations and polymer-water interactions, as well as network changes induced by moisture and temperature, were investigated. A modification to the Berens-Hopfenberg (BH) non-Fickian model was proposed to account for post-curing effects on the moisture absorption; such modification applied for post-curing was not found in literature. In the second part of this work, the swelling behavior of neat epoxy resin, uncoated and coated composites was evaluated and correlated with moisture absorption. The orthotropy of the composite was evident, since this material showed greater swelling capacity in the thickness direction. A Fickian-like model was implemented to the thickness swelling to investigate swelling strain saturation and swelling front. The third part of this work focuses on the destructive tests and evaluation of the hygrothermal effects on the material degradation. Temperature proved to be an accelerating factor for property degradation. In addition, a methodology to estimate the service-life curve of the repair systems and extrapolate it to lower temperatures was elaborated. The methodology of property extrapolation for long-term hygrothermal exposure in salt spray environments could not be found in literature. Parameters like property retention plateau and degradation rate were estimated for room temperature (25°C). Arrhenius curves were also plotted to evaluate the time required to reach the properties’ retention levels for each temperature. Finally, two non-destructive techniques were performed on the uncoated FRP and on neat epoxy resin as complementary tests in order to validate the results found in other techniques. The Impulse Excitation Technique (IET) was performed to evaluate the Young modulus and good correlation was found between IET and destructive bending tests. From the colorimetry tests, the effects of moisture and temperature were visible, as the resin s color change was stronger at longer aging time and higher temperatures.
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MECHANICS AND DYNAMICS OF PARTICLE NETWORK IN COMPOSITE ELECTRODESNikhil Sharma (16648830) 04 August 2023 (has links)
<p>Energy storage devices have become an integral part of the digital infrastructure of the 21st century. Li-ion batteries are a widely used chemical form of energy storage devices comprising components with varied chemical, mechanical and electrochemical properties. Over long-term usage, the anode and cathode experience spatially heterogeneous Li reaction, mechanical degradation, and reversible capacity loss. The small particle size and environmental sensitivity of materials used in Li-ion battery materials make investigating electrodes' electrochemical and mechanical properties an arduous task. Nevertheless, understanding the effect of electrochemical fatigue load (during the battery's charging and discharging process) on composite electrodes' mechanical stability is imperative to design and manufacture long-lasting energy storage devices.</p><p>Due to the low-symmetry lattice, Lithium Nickel Manganese Cobalt Oxide (NMC) cathode materials exhibit direction-dependent (anisotropic) mechanical properties. In this Dissertation, we first measure the anisotropic elastic stiffness of NMC cathode material using nano-indentation. We also determine the effect of Ni stoichiometry on the indentation modulus, hardness, and fracture toughness of NMC materials. The complete information on the mechanical properties of cathode materials will enable accurate computational results and the design of robust cathodes.</p><p>Further, using operando optical experiments, we report that NMC porous composite cathode experiences asynchronous reactions only during the 1st charging process. Non-uniform carbon binder network coverage across the cathode and Li concentration-dependent material properties of NMC results in the initial asynchronous phenomenon. The information on the degree of electrochemical conditioning of Li-ion battery cathode obtained from optical microscopy can test the consistency of product quality in the industrial manufacturing process. We also investigate the effects of non-uniform reactions on active material’s local morphology change and study the evolution of particle network over long-term cycling. Reported data from experiments depicts that in the early cycles, individual particles’ characteristics significantly influence the degree of damage across the cathode.</p><p>However, the interaction with neighboring particles becomes more influential in later cycles. Computational modeling uses a multiphysics-based theoretical framework to explain the interplay between electrochemical activity and mechanical damage. The methodology, theoretical framework, and experimental procedure detailed here will enable the design of efficient composite electrodes for long-lasting batteries.</p>
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[pt] COMPORTAMENTO MECÂNICO E ANÁLISE DA EVOLUÇÃO DO DANO EM CONCRETO REFORÇADO COM FIBRAS SOB FADIGA À FLEXÃO PARA APLICAÇÕES ESTRUTURAIS / [en] MECHANICAL BEHAVIOR AND DAMAGE EVOLUTION OF FIBER REINFORCED CONCRETE UNDER FLEXURAL FATIGUE LOADING FOR STRUCTURAL APPLICATIONSVITOR MOREIRA DE ALENCAR MONTEIRO 11 April 2024 (has links)
[pt] A presente tese de doutorado tem como origem o projeto de pesquisa Aneel
PD-0394-1905/2019, realizado a partir de uma colaboração entre Furnas e PUC-Rio. A principal meta desse grande projeto de pesquisa está no desenvolvimento do
concreto reforçado com fibras visando sua aplicação em elementos estruturais que
estão submetidos à fadiga na flexão ao longo de toda sua vida útil, como torres
eólicas, pavimentos e elementos de pontes. Dessa maneira, ao longo de todo essa
tese doutorado, a degradação mecânica do concreto reforçado com fibras sob fadiga
é analisada em detalhe desde a escala da fibra em ensaios de arrancamento até a
escala estrutural através de testes mecânicos de fadiga em larga escala. A primeira
etapa desse estudo traz uma análise do comportamento à fadiga do concreto
reforçado com fibras. A vida à fadiga desse material é estudada através de diferentes
modelos estatísticos, que garantem avaliar a falha do material baseada em uma
probabilidade falha. Já os ensaios de fadiga no arrancamento ajudam a explicar na
escala interface fibra-matriz como ocorre a ruptura dos prismas sob carregamentos
cíclicos. Uma segunda fase desse trabalho mostra a degradação mecânica de vigas
armadas sob fadiga e o impacto da adição de fibras nos principais parâmetros de
interesse. A adição do reforço fibroso é responsável por causar uma redistribuição
de tensões na zona tracionada do elemento estrutural, diminuindo as deformações
da armadura longitudinal e amenizando a degradação mecânica do concreto armado
em termos de curvatura, deslocamento e rigidez. Além disso, a adição de fibras
também é responsável por incrementar significativamente a aderência da barra de
aço ao redor da matriz de concreto. Fator chave para explicar a melhora da resposta
mecânica da estrutura sob fadiga e estudada nessa tese de doutorado através dos
ensaios de arrancamento da barra aço. Por fim, uma nova solução analítica foi
desenvolvida para avaliar a degradação mecânica dos prismas de concreto
reforçado com fibras sob fadiga. As curvas analíticas propostas se adequaram de
forma bem sucedida os resultados experimentais analisados nesse trabalho. A
adição de fibras apresentou grande potencial visando uma diminuição da
degradação mecânica das estruturas de concreto armado submetidas a
carregamentos cíclicos. A redistribuição de tensões na zona tracionada devido às
fibras promove uma maior rigidez da estrutura sob fadiga, uma melhora da
aderência da armadura e uma maior capacidade de resistir aos ciclos de fadiga ao
longo do tempo. Esse ganho mecânico com o reforço fibroso, portanto, pode
garantir maior vida útil das estruturas em concreto armado. / [en] This doctoral thesis originates from the research project Aneel PD-0394-
1905/2019, carried out through a collaboration between Furnas and PUC-Rio. The
main objective of this extensive research project is the development of fiber
reinforced concrete for distinct structural application which are subjected to
continuous flexural fatigue loading along their useful life, such wind tower
endeavors, concrete pavements and bridge elements. The addition of fibers in the
concrete mix has the potential to mitigate the mechanical deterioration along the
continuous load cycles, enhancing, as a consequence, the durability and the fatigue
life of the cited concrete structural elements. Throughout this doctoral thesis, the
mechanical degradation of fiber reinforced concrete under fatigue is carefully
analyzed, starting from the fiber scale with pull-out tests and going up to the
structural scale through large-scale fatigue mechanical tests. The first stage of this
study involves an analysis of the mechanical behavior of fiber reinforced concrete
under fatigue loading. The material fatigue life is examined using different
statistical models, which allow evaluating material failure based on a failure
probability. Fatigue pull-out tests help explain, at the fiber-matrix interface scale,
how the prisms rupture under cyclic loading. A second phase of this work
demonstrates the mechanical degradation of reinforced structural beams under
fatigue and the impact of fiber addition on key concerned parameters. The addition
of fiber reinforcement causes a redistribution of stresses in the tension zone of the
structural element, reducing the deformations of the longitudinal rebar and
mitigating the mechanical degradation of reinforced concrete in terms of curvature,
displacement and stiffness. Furthermore, fiber addition significantly improves the
bond between the steel bar and the surrounding concrete matrix, a key factor in
explaining the enhanced mechanical response of the structure under fatigue, as
studied in this doctoral thesis through rebar pull-out tests. Finally, a new analytical
solution was developed to assess the mechanical degradation of fiber reinforced
concrete prisms under fatigue loads. The proposed analytical curves successfully fit
the experimental results analyzed in this work. The addition of fibers showed great
potential in reducing the mechanical degradation of reinforced concrete structures
subjected to cyclic loading. The stress redistribution in the tension zone, caused by
the fibers, promotes greater stiffness of the structure under fatigue, improves the
bond with the reinforcement and enhances the ability to withstand fatigue cycles
over time. Therefore, the observed enhancement of mechanical properties through
fiber reinforcement can ensure a longer service life for reinforced concrete
structures.
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[en] INFLUENCE OF POLYMER DEGRADATION AND NANOPARTICLE ADDITION ON THE RHEOLOGY AND FLOW OF POLYMER SOLUTIONS AND DISPERSIONS IN POROUS MEDIA / [pt] INFLUÊNCIA DA DEGRADAÇÃO DE POLÍMEROS E DA ADIÇÃO DE NANOPARTÍCULAS NA REOLOGIA E NO FLUXO DE SOLUÇÕES E DISPERSÕES DE POLÍMEROS EM MEIOS POROSOSANDREA VANESSA VACA MORA 19 August 2024 (has links)
[pt] A poliacrilamida parcialmente hidrolisada (HPAM) é amplamente empregada no processo de recuperação avançada de petróleo (EOR). No entanto, sua eficácia é prejudicada pela degradação das moléculas do polímero durante o fluxo através das linhas de injeção, válvulas e reservatório. Essa degradação leva a uma diminuição do peso molecular médio e, consequentemente, reduza viscosidade e as propriedades viscoelásticas da solução, afetando sua eficácia no deslocamento do petróleo. Para abordar essas questões, nossa pesquisa caracterizou o grau de degradação mecânica das soluções de HPAM usando reologia de cisalhamento e extensional. Induzimos a degradação fazendo as soluções fluírem por uma válvula com constrição e diferentes vazões através deum modelo microfluídico de um médio poroso. Os resultados revelam que aadição de nanopartículas de sílica (SiO2) tem um efeito insignificante sobreas viscosidades de cisalhamento e extensional de soluções frescas e minimiza a degradação mecânica das soluções de HPAM. As propriedades reológicas das soluções de HPAM com nanopartículas de SiO2 não são significativamente afetadas pela degradação mecânica, o que sugere que a incorporação de nanopartículas poderia aumentar a eficiência da injeção de polímeros em processosde EOR por meio da estabilização das soluções de HPAM. Além disso, nosso estudo explorou escoamento de deslocamento de óleo usando soluções de polímero HPAM frescas e degradadas em dispositivos microfluídicos usados como modelos de meios porosos. Os resultados sugerem que o HPAM fresco é mais eficiente na produção de óleo do que o HPAM degradado. Além disso, a adição de nanopartículas de sílica em soluções degradadas de NPs-HPAM resultou em um aumento de 9-13 por cento na recuperação de petróleo, destacando o enorme potencial das nanopartículas no aprimoramento dos processos de EOR. / [en] Partially hydrolyzed polyacrylamide (HPAM) is widely employed in enhanced oil recovery (EOR) process. However, its effectiveness is hindered by
degradation of polymer molecules during flow through injection lines, valves
and reservoir. This degradation leads to a decrease in average molecular weight
and subsequently reduces the solution’s viscosity and viscoelastic properties,
impacting its effectiveness on displacing oil. Our research characterized the degree of mechanical degradation of HPAM solutions using shear and extensional
rheology. We induced degradation by flowing the solutions through a valve with
varying constriction and flow rates and through a microfluidic porous medium
model. Our findings reveal that the addition of silica (SiO2) nanoparticles has
a negligible effect on the shear and extensional viscosities of fresh solutions
and minimizes the mechanical degradation of HPAM solutions. The rheological properties of HPAM solutions with SiO2 nanoparticles are not significantly
affected by mechanical degradation, suggesting that incorporating nanoparticles could enhance the efficiency of polymer injection in EOR processes by
stabilizing HPAM solutions. In addition, our study explored oil displacement
flow using both fresh and degraded HPAM polymer solutions in microfluidic
devices used as models of porous media. The findings suggest that fresh HPAM
is more efficient in displacing oil than degraded HPAM. Furthermore, the addition of silica nanoparticles into degraded NPs-HPAM solutions resulted in a
9-13 percent increase in oil recovery, highlighting the enormous potential of nanoparticles in enhancing EOR processes.
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