Aplicação de laminado de polímero reforçado com fibras de carbono (PRFC) inserido em substrato de microconcreto com fibras de aço para reforço à flexão de vigas de concreto armado / Application of carbon fiber reinforced polymer (CFRP) strips inserted in a steel fiber reinforced concrete layer (NSM - Near Surface Mounted) for flexural strengthening of reinforced concrete beams

Arquez, Ana Paula

07 May 2010

O reforço de elementos estruturais de concreto armado com uso de polímeros reforçados com fibras de carbono (PRFC) está cada vez mais conhecido, seguro e acessível. Em todo o mundo, a aplicação do PRFC vem sendo estudada sob diversas técnicas. Características como elevada resistência à tração e à corrosão, baixo peso, facilidade e rapidez de aplicação são os principais fatores para essa disseminação. Em particular, a técnica aqui estudada é conhecida como Near Surface Mounted (NSM), que consiste na inserção de laminados de PRFC em entalhes realizados no concreto de cobrimento de elementos de concreto armado. Com dupla área de aderência, ela vem a suprir uma deficiência comum no reforço colado externamente, que é o seu destacamento prematuro. Como nas demais técnicas de reforço à flexão, o material é colado na região do concreto tracionado. Sabe-se que, na prática da intervenção, essa região frequentemente encontra-se danificada por razões diversas, como fissuração causada por ações externas, corrosão da armadura e deterioração do concreto, o que exige a sua prévia reparação. Considerando que a boa qualidade desse reparo é imprescindível à eficiência do reforço, propõe-se uma inovação técnica pela reconstituição da face tracionada da viga com um compósito cimentício de alto desempenho, que sirva como substrato para aplicação do PRFC e elemento de transferência de esforços à estrutura a ser reforçada. Produzido à base de cimento Portland, fibras e microfibras de aço, o compósito tem também potencial para retardar a abertura de fissuras e aumentar a rigidez da viga, melhorando o aproveitamento do reforço. Com apoio da mecânica do fraturamento, foi possível encontrar as taxas de fibras e microfibras de aço a serem adicionadas a uma matriz cimentícia especialmente desenvolvida. Foram realizados ensaios de aderência para estudar o processo de transferência de tensões cisalhantes do laminado para o compósito na zona de ancoragem da viga. Uma vez conhecido o comportamento do sistema, foram ensaiadas vigas de concreto armado de tamanho representativo de estruturas reais, em três diferentes versões de ancoragem do laminado, sendo duas delas com uso do compósito cimentício. Comprovou-se a eficiência da inovação proposta, constatando-se o aumento da rigidez e da capacidade de carga da viga reforçada, com excelente aproveitamento do laminado. Além disso, as fibras e microfibras diminuíram a abertura das fissuras em estágios mais avançados de carregamento, sem que se observasse fissuras horizontais próxima ao reforço, que poderiam indicar destacamento iminente do laminado de PRFC. / Strengthening of reinforced concrete elements with carbon fiber reinforced polymer (CFRP) is increasingly well known, safe and accessible. The application of CFRP has been studied worldwide using various techniques. Features like high tensile strength, corrosion resistance, lightweightness and easy and speedy application are the main factors for dissemination. In particular, the technique here analyzed is known as Near Surface Mounted (NSM), which involves inserting CFRP strips into grooves made on the concrete cover of reinforced concrete elements. With double bonding area, this technique avoids the premature peeling-off that usually takes place in externally bonded CFRP reinforcement. As in others flexural strengthening techniques, the material is bonded in the concrete tension region. It is known in strengthening practice that this region usually requires prior repair. Often it shows up damaged by several reasons such as cracking caused by external actions, reinforcement corrosion and deterioration of the concrete. Whereas the good quality of this repair is essential to strengthening efficiency, an innovative technique is proposed. A high-performance cementitious composite is used as a transition layer for insertion of CFRP strips. The composite is made of Portland cement, steel fibers and microfibers of steel. It also has the potential to delay crack opening and to increase the beam stiffness. Based on fracture mechanics, it was possible to find suitable volume fractions of steel fibers and microfibers to be added to the cementitious matrix. Bonding tests were performed to analyze the shear stress transferring from the CFRP laminate to the beam anchorage zone. Once known the system behavior, real size reinforced concrete beams were tested in three different versions of the anchorage conditions, two of them with use of cementitious composites. The efficiency of the proposed innovation was proved by confirming increased stiffness and load capacity of the strengthened beam. In addition, fibers and microfibers allowed the decrease of the crack opening in later loading steps. No horizontal cracks near to the reinforcement were noticed, which means that CFRP laminate peeling-off was not likely to occur.

Aderência

Bond

Carbon fibers (CFRP)

Cementitious composite

Compósito cimentício

Concreto com fibras de aço

Fibras de carbono (PRFC)

RC beams

Reabilitação - estruturas

Reforço de vigas

Steel fiber reinforced concrete

Strengthening

Structural rehabilitation

Réparation ou renforcement des poutres en béton armé corrodées ou non par l'insertion de joncs de carbone dans la surface du béton (NSM technique) : étude expérimentale et modélisation par éléments finis. / Strengthening of corroded reinforced concrete (RC) beams with near surface mounted (NSM) technique using carbon fiber polymer (CFRP) rods : an experimental and finite element (FE) modelling study

Almassri, Belal

04 June 2015

Cette thèse s’intéresse à l’efficacité des renforcements par matériaux composites à base de fibres carbone (CFRP : Carbon Fiber Reinforced Polymer) par la technique NSM (Near Surface Mounted ; réalisation d’engravures sur la surface du béton) pour requalifier les structures corrodées. Elle est composée d’une partie expérimentale et d’une partie modélisation par la méthode des Eléments Finis (EF). La technique NSM consiste à réaliser des engravures sur la surface du béton où sont insérés les joncs de carbone rendus adhérents par remplissage d’une résine époxy. Les éléments étudiés dans cette thèse sont des poutres en béton armé naturellement corrodées pendant 28 années d’exposition à un environnement salin. Dans cette thèse, nous nous intéressons aux modes de rupture et à la capacité portante à la fois : en flexion et à l’effort tranchant. Le degré de corrosion a été mesuré par la méthode de perte de masses locales après la fin des essais mécaniques sur les barres longitudinales ainsi que sur les cadres d’effort tranchant. La première partie présente les résultats expérimentaux obtenus sur une poutre corrodée et une poutre témoin réparée ou renforcée en flexion par un jonc de carbone de 6 mm de diamètre inséré dans la surface tendue par la technique NSM. Les essais ont pour objectif d’étudier la capacité portante, la flèche à la ruine, la rigidité en flexion et le mode de ruine des deux poutres afin de vérifier l’efficacité du renforcement ou de la réparation... La seconde partie présente les résultats expérimentaux obtenus sur des poutres courtes permettant de mettre en avant la résistance vis à vis de l’effort tranchant. A partir des poutres longues testées dans la première partie, deux poutres courtes corrodées et deux poutres courtes témoins sont extraites. Une poutre courte corrodée et une poutre témoin sont réparées ou renforcées en flexion et une poutre corrodée et une poutre témoin sont en plus réparées ou renforcées vis-à-vis à l’effort tranchant par des joncs de carbone de 6 mm de diamètre par la technique NSM. L’éventuel glissement des armatures longitudinales sur les appuis a été mesuré durant les essais de flexion 3 points. Les résultats expérimentaux montrent que la corrosion des armatures longitudinales et la corrosion des cadres d’effort tranchant n’affectent pas le mode de ruine et modifient très peu les capacités portantes. La réparation vis-à-vis de l’effort tranchant avec la technique NSM change le mode de ruine de la formation d’une fissure diagonale due au glissement des barres d’acier tendues, à la formation d’une large fissure de flexion à mi-travée suivie de l’écrasement du béton comprimé... La troisième partie s’intéresse à la modélisation par la méthode de modélisation par EF du comportement global en flexion. Une première approche 2D est élaborée avec le code FEMIX développé à l’Université de Minho par le professeur Barros. Cinq poutres sont modélisées : 3 corrodées dont une réparée par la technique NSM et 2 témoins dont une renforcée par la technique NSM. La modélisation par EF donne de bons résultats sauf dans le cas de la poutre corrodée réparée dont le mode de ruine est non conventionnel (séparation du béton d’enrobage)... La quatrième et dernière partie est consacrée à l’étude numérique des poutres courtes. Quatre poutres sont modélisées : 2 corrodées réparées dont une réparée vis-à-vis de l’effort tranchant et 2 témoins renforcées dont une renforcée vis-à-vis de l’effort tranchant. La modélisation par EF est faite en 3D en utilisant le code FEMIX. Les résultats numériques reproduisent correctement les aspects importants du comportement force-flèche ainsi que les modes de fissuration à la ruine pour les poutres réparées vis-à-vis de l’effort tranchant ou non. / The thesis is composed of an experimental and Finite Element Modeling (FEM) study, investigating the effectiveness of the (Near Surface Mounted CFRP rods technique (NSM)) on the corroded RC beams. In the NSM technique, the CFRP rods are placed inside pre-cut grooves and are bonded to the concrete with epoxy adhesive. The thesis studies the failure modes and the mechanical performance of the corroded RC beams due to steel corrosion and finally, the prediction of the mechanical behaviour of the repaired corroded RC beams using nonlinear models based on FE numerical modelling. The corroded RC beams studied here in this study were exposed to natural corrosion for more than 28 years. The first part includes experimental results which were obtained on two beams: (one corroded and one control beams, both are 3 metres long) repaired or strengthened in bending with one 6-mm-diameter NSM CFRP rod. The beams were tested in a three-point bending test up to failure. Overall stiffness was studied. Ultimate capacity, ductility and failure modes were also reviewed. Finally some comparisons were made between repaired and non-repaired beams in order to assess the effectiveness of the NSM technique... The second part discusses the experimental results of two short corroded beams, which were tested under three-point bending until failure, along with two short control beams of the same characteristics (age, length and cross-section). One RC corroded deep beam was repaired in bending and the other one was repaired in both bending and shear with NSM CFRP rods. After the beams had been tested up to failure, the main steel bars and the stirrups were extracted from the beams and the loss of mass was measured and plotted for both the longitudinal and transverse reinforcement. The slip of tensile reinforcement at the end of the beams was also measured during the tests. The effect of corrosion and the effect of repairing with CFRP NSM rods in bending and shear on the behaviour of deep beams are discussed. Experimental results showed that both corroded and control deep beams repaired only in bending failed due to shear failure mode(diagonal tension failure), while corroded and control beams repaired in both bending and shear failed due to concrete crushing. The test results also showed that the corrosion of both longitudinal and transversal reinforcement hardly modified the mechanical response of deep beams... The third part shows experimental results and numerical modelling results of 2D finite element model using the FEMIX computer code were obtained on five, 3-metre-long beams: three corroded RC beams and two control beams. Two beams, one corroded and one control were repaired or strengthened in bending with NSM CFRP rod and were then tested in three-point bending up to failure. The FE numerical modelling results from FEMIX were compatible with the experimental ones except for the repaired corroded beam, for which a three-dimensional model using the commercial software ABAQUS was required... Finally, the last part presents 3D numerical modelling results in terms of load-deflection curves, and failure modes for 4 short corroded beams: two corroded beams and two control beams, half of the beams were let repaired or strengthened in bending only with NSM CFRP rods while the others were repaired or strengthened in both bending and shear with NSM technique. Results showed that the FE model was able to capture the main aspects of the experimental load-deflection curves of the RC beams, moreover it has presented the experimental failure modes and FE numerical modelling crack patterns and both gave similar results for both shear-repaired and non-shear repaired beams, three dimensional crack patterns were produced for shear-repaired beams in order to investigate the splitting cracks occurred at the middle of the beams and near the support.

Poutres

Ductilité

Flexion

Effort tranchant

Flèche

Rigidité Eléments Finis

FEMIX

ABAQUS

Fibres de carbone

Renforcement

Réparation

Corrosion

Béton armé

RC beams

Corrosion

Repair

Strengthening

NSM CFRP rods

Ductility

Bending

Shear

Deflection

Stiffness

Finite element

FEMIX

ABAQUS

624

Aplicação de laminado de polímero reforçado com fibras de carbono (PRFC) inserido em substrato de microconcreto com fibras de aço para reforço à flexão de vigas de concreto armado / Application of carbon fiber reinforced polymer (CFRP) strips inserted in a steel fiber reinforced concrete layer (NSM - Near Surface Mounted) for flexural strengthening of reinforced concrete beams

Ana Paula Arquez

07 May 2010

O reforço de elementos estruturais de concreto armado com uso de polímeros reforçados com fibras de carbono (PRFC) está cada vez mais conhecido, seguro e acessível. Em todo o mundo, a aplicação do PRFC vem sendo estudada sob diversas técnicas. Características como elevada resistência à tração e à corrosão, baixo peso, facilidade e rapidez de aplicação são os principais fatores para essa disseminação. Em particular, a técnica aqui estudada é conhecida como Near Surface Mounted (NSM), que consiste na inserção de laminados de PRFC em entalhes realizados no concreto de cobrimento de elementos de concreto armado. Com dupla área de aderência, ela vem a suprir uma deficiência comum no reforço colado externamente, que é o seu destacamento prematuro. Como nas demais técnicas de reforço à flexão, o material é colado na região do concreto tracionado. Sabe-se que, na prática da intervenção, essa região frequentemente encontra-se danificada por razões diversas, como fissuração causada por ações externas, corrosão da armadura e deterioração do concreto, o que exige a sua prévia reparação. Considerando que a boa qualidade desse reparo é imprescindível à eficiência do reforço, propõe-se uma inovação técnica pela reconstituição da face tracionada da viga com um compósito cimentício de alto desempenho, que sirva como substrato para aplicação do PRFC e elemento de transferência de esforços à estrutura a ser reforçada. Produzido à base de cimento Portland, fibras e microfibras de aço, o compósito tem também potencial para retardar a abertura de fissuras e aumentar a rigidez da viga, melhorando o aproveitamento do reforço. Com apoio da mecânica do fraturamento, foi possível encontrar as taxas de fibras e microfibras de aço a serem adicionadas a uma matriz cimentícia especialmente desenvolvida. Foram realizados ensaios de aderência para estudar o processo de transferência de tensões cisalhantes do laminado para o compósito na zona de ancoragem da viga. Uma vez conhecido o comportamento do sistema, foram ensaiadas vigas de concreto armado de tamanho representativo de estruturas reais, em três diferentes versões de ancoragem do laminado, sendo duas delas com uso do compósito cimentício. Comprovou-se a eficiência da inovação proposta, constatando-se o aumento da rigidez e da capacidade de carga da viga reforçada, com excelente aproveitamento do laminado. Além disso, as fibras e microfibras diminuíram a abertura das fissuras em estágios mais avançados de carregamento, sem que se observasse fissuras horizontais próxima ao reforço, que poderiam indicar destacamento iminente do laminado de PRFC. / Strengthening of reinforced concrete elements with carbon fiber reinforced polymer (CFRP) is increasingly well known, safe and accessible. The application of CFRP has been studied worldwide using various techniques. Features like high tensile strength, corrosion resistance, lightweightness and easy and speedy application are the main factors for dissemination. In particular, the technique here analyzed is known as Near Surface Mounted (NSM), which involves inserting CFRP strips into grooves made on the concrete cover of reinforced concrete elements. With double bonding area, this technique avoids the premature peeling-off that usually takes place in externally bonded CFRP reinforcement. As in others flexural strengthening techniques, the material is bonded in the concrete tension region. It is known in strengthening practice that this region usually requires prior repair. Often it shows up damaged by several reasons such as cracking caused by external actions, reinforcement corrosion and deterioration of the concrete. Whereas the good quality of this repair is essential to strengthening efficiency, an innovative technique is proposed. A high-performance cementitious composite is used as a transition layer for insertion of CFRP strips. The composite is made of Portland cement, steel fibers and microfibers of steel. It also has the potential to delay crack opening and to increase the beam stiffness. Based on fracture mechanics, it was possible to find suitable volume fractions of steel fibers and microfibers to be added to the cementitious matrix. Bonding tests were performed to analyze the shear stress transferring from the CFRP laminate to the beam anchorage zone. Once known the system behavior, real size reinforced concrete beams were tested in three different versions of the anchorage conditions, two of them with use of cementitious composites. The efficiency of the proposed innovation was proved by confirming increased stiffness and load capacity of the strengthened beam. In addition, fibers and microfibers allowed the decrease of the crack opening in later loading steps. No horizontal cracks near to the reinforcement were noticed, which means that CFRP laminate peeling-off was not likely to occur.

Aderência

Compósito cimentício

Concreto com fibras de aço

Fibras de carbono (PRFC)

Reabilitação - estruturas

Reforço de vigas

Bond

Carbon fibers (CFRP)

Cementitious composite

RC beams

Steel fiber reinforced concrete

Strengthening

Structural rehabilitation

Modélisation d'éléments de structure en béton armé renforcés par collage de PRF : application à la rupture de type peeling-off / Modeling of reinforced concrete structural members strengthened with FRP plates : study of the peeling-off failure mode

Radfar, Sahar

13 December 2013

Le renforcement de structures ou d'éléments de structure par collage de plats PRF (polymères renforcés de fibres) est une technique actuellement reconnue et utilisée dans le monde entier. Il permet d'augmenter la durée de vie des structures existantes ce qui est très intéressant du point de vue développement durable et est souvent plus intéressant d'un point de vue économique. La première partie de ce travail s'intéresse au renforcement de poutres béton armé par des plats PRF. En effet, ce type de renforcement peut engendrer une rupture prématurée de type peeling-off. Ce mode de ruine très fragile résulte du décollement du béton d'enrobage qui reste collé au matériau de renforcement. Pour une conception optimale d'un renforcement en flexion par collage, il est important d'être en mesure de prévoir ce type de rupture et d'en tenir compte dans le dimensionnement. Pour cela, un modèle numérique fiable de type élasto-plastique est dans un premier temps présenté qui permet de prévoir la rupture de type peeling-off. Ce modèle est validé à l'aide de résultats d'essais expérimentaux. Les paramètres principaux affectant l'efficacité du renforcement sont ensuite mis en évidence dans le cadre d'une étude paramétrique. Les résultats de cette étude sont mis en parallèle avec des résultats d'essais de la littérature prouvant ainsi l'efficacité du modèle proposé. Enfin, plusieurs mesures sont proposées pour améliorer la performance du renforcement et éviter la rupture prématurée de peeling-off. La deuxième partie de ce travail s'attache quant à elle à l'étude de renforcement de tabliers de ponts soumis aux efforts éventuels d'impact d'un véhicule sur une barrière de sécurité. Une campagne expérimentale composée de différentes configurations de dalles est d'abord réalisée. Un modèle numérique s'inspirant du modèle proposé précédemment est ensuite présenté. La confrontation des résultats expérimentaux et numériques montre une concordance encourageante avant la fissuration majeure de la dalle. Enfin, les résultats mettent en relief l'efficacité du renforcement par des plats PRF dans le cas de glissières de sécurité / Strengthening of structures by bonding FRP plates (fiber reinforced polymer) is a technique currently recognized and used worldwide. This method is a viable solution to costly replacement of deteriorating structures and increases the life of reinforced structures. The first part of this doctoral work focuses on the strengthening of reinforced concrete beams with FRP plates and more precisely on a premature failure caused by this type of reinforcement called peeling-off or concrete cover separation. This brittle failure mode which prevents the strengthened RC beams from attaining their ultimate flexural capacity involves the tearing-off of the concrete cover along the level of tension steel reinforcement starting from a plate end. The first step for a successful, safe and economic design of flexural strengthening using FRP composite at the bottom of the beam is then to predict such failure and to take it into account in design. A reliable numerical model analysis which is validated by test results is first presented to predict ultimate loading capacity and the failure mode of RC beams in a four-point bending setup. The main parameters affecting the efficiency of the reinforcement are then highlighted in a parametric study. The results of this study are compared with test results in the literature demonstrating the efficiency of the proposed model. Finally, several measures are proposed to improve the performance of the strengthening and in order to avoid the premature rupture of peeling-off. The second part of this work is concerned with the strengthening study of a bridge deck subject to eventual loads generated by a car crash into a safety barrier. A series of equivalent impact tests is first performed on deck slabs. A numerical model inspired by the previously proposed model for RC beams is then presented. Comparisons between the predictions of the numerical model and test results show a good agreement before the major cracking of the slab. Finally, the results highlight the efficiency of FRP plates in the case of safety guardrails

Renforcement par collage de PRF

Poutres béton armé

Modélisation de rupture par peeling-off

Barrières de sécurité

Etude expérimentale

Analyse éléments finis

Strengthening with FRP plates

RC beams

Concrete cover separation; peeling-off

Safety barriers

Experimental investigations

Finite element analysis