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751	Estudo numérico do comportamento de emendas de barras por meio de laço em juntas de estruturas de concreto armado / Numerical study of bars overlappings behaviour by loop in joints of reinforced concrete structures Vasconcelos, Thiago Delfino Lima 09 March 2017 (has links) O surgimento de juntas é inevitável em certas construções em concreto armado e para garantir que a estrutura trabalhe de forma monolítica, deve-se proporcionar uma adequada transferência de esforços entre os elementos, para isso, faz-se necessário dispor de uma emenda adequada entre os elementos. Emendas com barras retas ocupam muito espaço devido ao comprimento de traspasse necessário, dessa forma, em situações em que há uma limitação de espaço para a emenda, uma armação que constitui uma boa solução é a emenda por meio de laço, que, apesar de ter poucos estudos relacionados, vem sendo bastante difundida na construção civil. O objetivo desse trabalho é estudar o comportamento de emendas em laço em juntas de estruturas de concreto armado submetidas à tração. Para isso, realizam-se simulações numéricas no software DIANA® em modelos numéricos 3D. Inicialmente, fez-se a calibração do modelo numérico com base em ensaios experimentais da literatura, depois foi realizada uma análise paramétrica variando parâmetros geométricos das peças e da armação em laço. Os resultados mostraram que traspasses menores que o diâmetro de dobra dos laços e espaçamentos maiores que 100 mm se mostram insuficientes para a formação de bielas de compressão entre laços. Dessa forma, ao se utilizar emendas em laço em juntas de concreto armado, recomenda-se dispor as barras o mais próximo possível até um espaçamento máximo de 60 mm entre eixos, como também um traspasse mínimo igual ao diâmetro de dobra dos laços. / The appearance of joints is inevitable in certain constructions of reinforced concrete and aiming to guarantee that the structure works monolithically, it is important to provide an appropriate transfer of stresses between elements, for that, it is necessary using a proper overlapping between them. Straight bars overlappings take up too much space due to the required overlapping length, therefore, in limited space situations, a reinforcement that represents a good solution is the loop joint, which has spread a lot in civil construction, although there are very few studies about it. The aim of the present work is to study the loop joint behaviour in reinforced concrete structures under tension. In order to do so, numerical simulations with numerical 3D models are made using the software DIANA®. Initially, it was made the calibration of the numerical model based on experimental tests of the literature, after that, parametric analyses were performed, varying geometric parameters of the elements and of the loop reinforcement. The results showed that overlapping lengths smaller than the loop diameter and distances between loops axes greater than 100 mm are not sufficient for the development of compression struts between loops. Thus, when the loop joint in reinforced concrete structures is used, it is recommended that the bars are placed as near as possible until a distance between the loops axes of 60 mm and a minimum overlapping length equal to the loop diameter of the reinforcement. Anchorage Ancoragem Concreto armado Emenda Junta Laço Loop joint Numerical simulation Overlapping Reinforced concrete Simulação numérica
752	Modified Indirect Tension Testing of Synthetic Fiber Reinforced Concrete Samples Exposed to Different Environmental Conditions Unknown Date (has links) Laboratory experiments were conducted to observe, document and evaluate the mechanical behavior of Fiber Reinforced Concrete after being submitted to five different environments for 8 months. The specimens were molded and reinforced with synthetic fibers with a composition similar to that used for dry-cast concrete. Four different types of fibers with different composition were used. The fibers were mixed with the concrete to create the samples and the samples were exposed to different environmental conditions. Some of these environments were meant to increase degradation of the interface fiber-concrete to simulate longevity and imitate harsh environments or marine conditions. The environments consisted of: a high humidity locker (laboratory conditions), submerged in the Intracoastal Waterway in a barge (SeaTech), a wet/dry cycle in seawater immersion simulating a splash/tidal zone, low pH wet/dry seawater immersion cycle and samples submerged in calcium hydroxide solution. The latter three were in an elevated temperature tank (87-95°F) to increase degradation process. The specimens were monitored weekly and the environments were controlled. Then, specimens were evaluated using different mechanical testing as the Indirect Tensile (IDT) test method, compressive strength according to ASTM standards. Results of testing were documented and observed in this study for further understanding of mechanical properties of Fiber Reinforced concrete. Forensic observation of fiber distribution after the IDT tests were also performed. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2019. / FAU Electronic Theses and Dissertations Collection Concrete--Environmental testing Fiber-reinforced concrete--Testing Tensile Strength Materials--Compression testing
753	Finite Element Modeling of Bond-Zone Behavior in Reinforced Concrete Seungwook Seok (6313136) 17 October 2019 (has links) In reinforced concrete (RC) structures, adequate bond between the reinforcement and concrete is required to achieve a true composite system, in which reinforcing steel carries tensile stress, once concrete cracks, and concrete and reinforcing steel carry compression. Determining bond strength and required development length for shear transfer between concrete and reinforcement is an ongoing research subject in the field of reinforced concrete with advances in the concrete and reinforcement materials requiring continuous experimental efforts. Finite element analysis (FEA) provides opportunities to explore structural behavior of RC structures beyond the limitations of experimental testing. However, there is a paucity of research studies employing FEA to investigate the reinforcement-concrete bond-zone behavior and related failure mechanism. Instead, most FEA-based research associated with RC bond has centered on developing a bond (or interface) constitutive model for use in FEA that, by itself, can characterize bond-zone behavior, typically represented by the bond stress-slip displacement relationship. This class of bond models is useful for simulating the global behavior of RC structures but is limited in its ability to simulate local bond resistance for geometries and material properties that differ substantially from those used to calibrate the model. To fill this gap in research, this study proposes a finite element (FE) modeling approach that can simulate local bond-zone behavior in reinforced concrete. The proposed FE model is developed in a physics-based way such that it represents the detailed geometry of the bond-zone, including ribs on the deformed reinforcement, and force transfer mechanisms at the concrete-reinforcement interface. The explicit representation of the bond-zone enables simulation of the local concrete compression due to bearing of ribs against concrete and subsequent hoop tension in the concrete. This causes bond failure either due to local concrete crushing (leading to reinforcement pullout) or global concrete splitting. Accordingly, special attention is given to the selection and calibration of a concrete model to reproduce robust nonlinear response. The power of the proposed modeling approach is its ability to predict bond failure and damage patterns, based only on the physical and material properties of the bond area. Thus, the successful implementation and application of this approach enables the use of FEA simulation to support the development of new design specifications for bond zones that include new and improved materials. Structural Engineering Reinforced Concrete Finite Element Analysis Bond Behavior Rib-Scale Concrete Damage-Plasticity Model
754	[en] ANALYTICAL MODEL FOR FLEXURAL DESIGN OF REINFORCED CONCRETE BEAMS STRENGTHENED WITH CARBON FIBERS COMPOSITES / [pt] MODELO ANALÍTICO PARA DIMENSIONAMENTO DE REFORÇO À FLEXÃO DE VIGAS EM CONCRETO ARMADO UTILIZANDO COMPÓSITOS DE FIBRAS DE CARBONO MELISSA COSTA JOAQUIM 08 June 2004 (has links) [pt] O reforço de estruturas de concreto armado torna-se necessário por uma série de fatores, tais como: erros de projeto ou de execução que levam a sistemas estruturais inseguros; deterioração do concreto e do aço causada por envelhecimento natural; agentes agressivos ou acidentes como incêndio e choques; mudança no tipo de utilização original da estrutura através do aumento do carregamento e/ou modificações na sua geometria. A aplicação de compósitos de fibra de carbono para reforço de estruturas de concreto armado representa o que há de mais moderno em engenharia estrutural. O uso deste material é bastante interessante devido à sua leveza, alta resistência mecânica, resistência à corrosão, neutralidade eletromagnética, fácil aplicação e manutenção das dimensões originais do elemento estrutural. A escolha deste tipo de reforço, em vez de sistemas tradicionais que utilizam chapas de aço, depende da viabilidade econômica e de restrições específicas feitas no projeto. O objetivo deste trabalho é desenvolver um modelo analítico para o dimensionamento à flexão de vigas de concreto armado reforçadas com compósitos de fibras de carbono. Foi realizada uma revisão da literatura disponível de modo a se obter evidências experimentais acerca do assunto. Com o propósito de avaliar a eficiência do modelo analítico desenvolvido, os resultados numéricos calculados com este modelo são discutidos e comparados com os resultados experimentais e teóricos obtidos da literatura. / [en] The strengthening of reinforced concrete structures turns to be necessary due to a number of factors, such as: mistakes in the design or in the construction leading to unsafe structural systems; deterioration of concrete and steel caused by natural aging, aggressive agents or accidents like fire and shocks; the changing of the original use of the structure with the increase of loading and/or modifications in the geometry. The application of carbon fiber composites for strengthening of reinforced concrete structures is a very new and modern issue in structural engineering. The use of this material is very interesting due to its lightness, high mechanical strength, resistance to corrosion, electromagnetic neutrality, easy application and maintenance of the original shape of the structural element. The choice of this type of reinforcement, instead of more traditional systems using steel plates, depends on the economical viability and specific restrictions made in the project. The objective of this work is to develop analytical model for flexural design of reinforced concrete beams strengthened with carbon fiber composites. A literature review was carried out in order to obtain the experimental evidences on this subject. In order to evaluate the efficiency of the analytical model, the numerical results obtained with this model are discussed and compared with the experimental and numerical results obtained from literature. [pt] CONCRETO ARMADO [en] REINFORCED CONCRETE [pt] REFORCO ESTRUTURAL [en] STRUCTURAL STRENGTHENING [pt] FIBRAS DE CARBONO [en] CARBON FIBER
755	Flange effectiveness in the resistance of shear on RC T-beams subjected to point loads Giaccio, Craig, 1974- January 2003 (has links) Abstract not available Reinforced concrete Concrete beams Shear (Mechanics) Concrete beams -- Fatigue Concrete -- Cracking
756	Shear strength of reinforced concrete T-beams strengthened using carbon fibre reinforced polymer (CFRP) laminates Lee, Tuan Kuan, 1976- January 2003 (has links) Abstract not available Concrete beams -- Testing Reinforced concrete -- Testing Fibrous composites Carbon fibers Plates (Engineeriang) Strains and stresses Shear (Mechanics)
757	Crack Spacing, Crack Width and Tension Stiffening Effect in Reinforced Concrete Beams and One-Way Slabs Piyasena, Ratnamudigedara, n/a January 2003 (has links) An analytical method for determining the crack spacing and crack width in reinforced concrete beams and one-way slabs is presented in this thesis. The locations and the distribution of cracks developed in a loaded member are predicted using the calculated concrete stress distributions near flexural cracks. To determine the stresses, a concrete block bounded by top and bottom faces and two transverse sections of the beam is isolated and analysed by the finite element method. Two types of blocks are analysed. They are: (i) block adjacent to the first flexural crack, and (ii) block in between successive cracks. The calculated concrete stress distribution adjacent to the first flexural crack is used to predict the locations of primary cracks (cracks formed at sections where the stresses have not been influenced by nearby cracks). The concrete stress distributions in between successive cracks, calculated for various crack spacings and load levels, are used to predict the formation of secondary cracks in between existing cracks. The maximum, minimum and the average crack spacing at a given load level are determined using the particular crack spacing that would produce a concrete tensile stress equal to the flexural strength of concrete. The resulting crack width at reinforcement level is determined as the relative difference in elastic extensions of steel and surrounding concrete. The accuracy of the present method is verified by comparing the predicted spacing and width of cracks with those measured by others. The analytical method presented in this thesis is subsequently used to investigate the effects of various variables on the spacing and width of cracks, and the results are presented. These results are used to select the set of parameters that has the most significant effect. A parametric study is then carried out by re-calculating the spacing and width of cracks for the selected parameters. Based on the results of this parametric study, new formulas are developed for the prediction of spacing and width of cracks. The accuracy of these formulas is ascertained by comparing the predicted values and those measured by other investigators on various types of beams under different load levels. The calculated stress distributions between successive cracks are also used to develop a new method of incorporating the tension stiffening effect in deflection calculation. First, curvature values at sections between adjacent cracks are determined under different load levels, using the concrete and steel stresses. These results are used to develop an empirical formula to determine the curvature at any section between adjacent cracks. To verify the accuracy of the new method, short-term deflections are calculated using the curvature values evaluated by the proposed formula for a number of beams, and the results are compared with those measured by others. reinforced concrete beams crack cracks cracking one-way slabs tension tensioning deflection
758	Intermediate crack debonding of plated reinforced concrete beams Liu, Irene S. T. January 2006 (has links) With increasing number of structures reaching their designed life or capacities everyday, retrofitting has become an important area in civil engineering. A popular method of strengthening and stiffening reinforced concrete ( RC ) beams is by adhesively bonding steel or FRP plates to the external surfaces. This technique has been proven to be efficient, inexpensive, unobtrusive and can be applied while the structure is in use. However, it has been found that adhesively bonded plates are prone to premature debonding prior to reaching their designed capacities, which restricts the use of existing design rules and guidelines for retrofitting RC beams using this relatively new form of structure. There are various forms of debonding including : plate end ( PE ) debonding ; critical diagonal crack ( CDC ) debonding ; and intermediate crack ( IC ) debonding. IC debonding is an especially important mechanism as it will occur at plated hinges of continuous members, and unlike other premature debonding mechanisms, IC debonding is very difficult to prevent. This debonding mechanism is associated with the formation of flexural or flexural - shear cracks in the vicinity of the plates, which causes slip to occur at the plate / concrete as well as the bar / concrete interfaces. Most research to date has been focusing on the bond - slip relationship at the plate / concrete interface, while little attention has been given to the IC debonding behaviour of flexural members. To allow safe and effective use of plated structures, it is necessary to model the debonding behaviours at the plate / concrete interface as premature debonding will affect both the strength and ductility of the members, and hence the ability of continuous structures to redistribute moment. Despite the importance of moment redistribution, very limited research has been carried out on the moment redistribution of continuous plated members. Since IC debonding is likely to occur at plated hinges of continuous members hence affecting the ductility of the hinges, the existing approaches for determining moment redistribution of reinforced concrete beams cannot be applied to plated members. In this research a numerical model based on discrete cracking and partial interaction theory has been developed which models the IC debonding of plated beams, taking into account the slips at all interfaces. This model will allow a better understanding of the IC debonding behaviour of plated members, and also from the model, the rotation capacity of both plated and unplated hinges in continuous reinforced concrete beams can be determined. Mathematical models and design rules have been developed for analysing critical diagonal crack debonding, which is dependent on the IC debonding behaviour of the plated members. Moment redistribution of beams with externally bonded and near surface mounted plates is studied through a series of tests and a mathematical model based on variation in flexural rigidity is proposed. Through the tests carried out on continuous plated beams, much moment redistribution is evident as oppose to that suggested by the existing design guidelines for plated members, where no moment redistribution is allowed for members plated with FRP. From the models proposed for IC and CDC debonding in this research, together with the existing PE debonding models available, all debonding mechanisms can now be modelled. Furthermore from the research on continuous plated beams, moment redistribution of plated beams can be analysed, allowing safe, effective and economic use of this retrofitting technique. This thesis is presented in the form of a collection of journal papers published or submitted for publication as a result of the research performed by the author. A selection of ten publications have been included in the following context, together with literature reviews performed on the related areas of studies, as well as further discussions on the papers, which consist of any additional information or work that was carried out in this research but not presented in the papers. / Thesis (Ph.D.)--School of Civil and Environmental Engineering, 2006. Concrete beams Strains and stresses. Reinforced concrete Testing. Concrete Cracking
759	Behavior of Full-Scale Reinforced Concrete Members with External Confinement or Internal Composite Reinforcement under Pure Axial Load De Luca, Antonio 21 December 2009 (has links) The need to satisfy aerospace industry's demand not met by traditional materials motivated researchers and scientists to look for new solutions. The answer was found in developing new material systems by combining together two or more constituents. Composites, also known as fiber reinforced polymers (FRP) consisting of a reinforcing phase (fibers) embedded into a matrix (polymer), offered several advantages with respect to conventional materials. High specific modulus and strength together with other beneficial properties, corrosion resistance and transparency to electrical and magnetic fields above all, made FRP also suitable for use as construction materials in structural engineering. In the early years of the twenty-first century, the publication by the American Concrete Institute (ACI) of design guidelines for the use of FRP as internal reinforcement and for external strengthening of concrete members accelerated their implementation for structural engineering applications. To date, FRP have gained full acceptance as advanced materials for construction and their use is poised to become as routine as the use of conventional structural materials such as masonry, wood, steel, and concrete. However, new concrete columns internally reinforced with FRP bars and FRP confinement for existing prismatic reinforced concrete (RC) columns have currently important unsolved issues, some of which are addressed in this dissertation defense. The dissertation is articulated on three studies. The first study (Study 1) focuses on RC columns internally reinforced with glass FRP (GFRP) bars; the second (Study 2) on RC prismatic columns externally confined by means of FRP laminates using glass and glass/basalt fibers; and the third (Study 3) is a theoretical attempt to interpret and capture the mechanics of the external FRP confinement of square RC columns. Study 1 describes an experimental campaign on full-scale GFRP RC columns under pure axial load undertaken using specimens with a 24 by 24 in. (0.61 by 0.61 m) square cross section. The study was conducted to investigate whether the compressive behavior of longitudinal GFRP bars impacts the column performance, and to understand the contribution of GFRP ties to the confinement of the concrete core, and to prevent instability of the longitudinal reinforcement. The results showed that the GFRP RC specimens behaved similarly to the steel RC counterpart, while the spacing of the ties strongly influenced the failure mode. Study 2 presents a pilot research that includes laboratory testing of full-scale square and rectangular RC columns externally confined with glass and basalt-glass FRP laminates and subjected to pure axial load. Specimens that are representative of full-scale building columns were designed according to a dated ACI 318 code (i.e., prior to 1970) for gravity loads only. The study was conducted to investigate how the external confinement affects ultimate axial strength and deformation of a prismatic RC column. The results showed that the FRP confinement increases concrete axial strength, but it is more effective in enhancing concrete strain capacity. The discussion of the results includes a comparison with the values obtained using existing constitutive models. Study 3 proposes a new theoretical framework to interpret and capture the physics of the FRP confinement of square RC columns subjected to pure compressive loads. The geometrical, physical and mechanical parameters governing the problem are analyzed and discussed. A single-parameter methodology for predicting the axial stress - axial strain curve for FRP-confined square RC columns is described. Fundamentals, basic assumptions and limitations are discussed. A simple design example is also presented. VERTICAL LOADS EXTERNAL CONFINEMENT INTERNAL REINFORCEMENT FULL-SCALE REINFORCED CONCRETE COLUMNS COMPOSITE MATERIALS
760	A Framework for Stochastic Finite Element Analysis of Reinforced Concrete Beams Affected by Reinforcement Corrosion Baingo, Darek 16 July 2012 (has links) Corrosion of reinforcing bars is the major cause of deterioration of reinforced concrete (RC) structures in North America, Europe, the Middle East, and many coastal regions around the world. This deterioration leads to a loss of serviceability and functionality and ultimately affects the structural safety. The objective of this research is to formulate and implement a general stochastic finite element analysis (SFEA) framework for the time-dependent reliability analysis of RC beams with corroding flexural reinforcement. The framework is based on the integration of nonlinear finite element and reliability analyses through an iterative response surface methodology (RSM). Corrosion-induced damage is modelled through the combined effects of gradual loss of the cross-sectional area of the steel reinforcement and the reduction bond between steel and concrete for increasing levels of corrosion. Uncertainties in corrosion rate, material properties, and imposed actions are modelled as random variables. Effective implementation of the framework is achieved by the coupling of commercial finite element and reliability software. Application of the software is demonstrated through a case study of a simply-supported RC girder with tension reinforcement subjected to the effects of uniform (general) corrosion, in which two limit states are considered: (i) a deflection serviceability limit state and (ii) flexural strength ultimate limit state. The results of the case study show that general corrosion leads to a very significant decrease in the reliability of the RC beam both in terms of flexural strength and maximum deflections. The loss of strength and serviceability was shown to be predominantly caused by the loss of bond strength, whereas the gradual reduction of the cross-sectional area of tension reinforcement was found to be insignificant. The load-deflection response is also significantly affected by the deterioration of bond strength (flexural strength and stiffness). The probability of failure at the end of service life, due to the effects of uniform corrosion-induced degradation, is observed to be approximately an order of magnitude higher than in the absence of corrosion. Furthermore, the results suggest that flexural resistance of corroded RC beams is controlled by the anchorage (bond) of the bars and not by the yielding of fully bonded tensile reinforcement at failure. This is significant since the end regions can be severely corroded due to chloride, moisture, and oxygen access at connections and expansion joints. The research strongly suggests that bond damage must be considered in the assessment of the time-dependent reliability of RC beams subjected to general corrosion. structural reliability time-dependent reliability reinforced concrete corrosion damage bond deterioration computational framework

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