Global ETD Search

1	Nonlinear elastic analysis of concrete beams based on the Smeared Crack Approach Betancourt, N., Betancourt, N., Arias, C., Durán, F., Arana, V. 07 February 2020 (has links) In the present study, an analysis of plain and reinforced concrete beams under monotonic loading was made based on the Fixed Smeared Crack approach. The objectives of this research were to analyze the nonlinear behavior of the selected cases of analysis and to propose an alternative and simple model for the analysis of beams under service loadings, by means of Committee 435 of the American Concrete Institute. A brittle model for concrete and a linear-elastic behavior for steel reinforcement bars were considered. Results are presented through force-displacement curves and the sequence of cracking propagation. Also, a comparison of calculated instantaneous deflections of simply supported beams was made between the proposed model and other researches. It was verified that the proposed algorithm can predict adequately the cracking process and the deflections of beams subjected to service loadings, taking into account experimental results from other authors. Concrete beams Smeared Crack Monotonic loading
2	Modelagem numérica de estruturas de concreto armado utilizando o programa ATENA. / Numerical modelling of reinforcement concrete structures using the program ATENA. Lyra, Pedro Henrique Cerento de 16 December 2011 (has links) Com o avanço tecnológico dos computadores e o desenvolvimento de soluções para problemas não lineares através do método dos elementos finitos, hoje é possível fazer uma análise mais complexa e mais próxima da realidade. É de extrema importância à verificação dos resultados obtidos pelos programas com a realidade e saber em quais casos esses modelos podem ser aplicados. Assim, o objetivo deste trabalho é discutir as vantagens e desvantagens da modelagem de estruturas de concreto armado em duas e três dimensões, através dos modelos de fissuras distribuídas. Foram escolhidos três experimentos para a modelagem numérica: o primeiro trata-se de um experimento com uma viga de concreto armado (LEONHARDT; WALTHER, 1962), o segundo experimento também é realizado com uma viga de concreto armado (BRESLER; SCORDELIS, 1963) e o terceiro experimento utiliza vigas de concreto armado em escala reduzida, fabricadas com microconcreto e arame, simulando uma barra de aço lisa (ALMEIDA et al, 2006). Para a modelagem numérica, utilizando-se o modelo de fissuras distribuídas com fissura rotacional e a análise das estruturas de concreto foi escolhido o programa comercial ATENA - \"Advanced Tool Engineering Non-linear Analysis\". / The technological advancement of computers and the development of solutions for nonlinear problems by finite element method are now possible to make more complex the analysis and closer to reality. It is extremely important to verify the results obtained by programs with reality and know which cases these models can be applied. So the objective is to discuss the advantages and disadvantages of modeling reinforced concrete structures in two and three dimensions, through the smeared cracking models. Three experiments were chosen to make the numerical modeling: the first is an experiment with a reinforced concrete beam (LEONHARDT; WALTHER, 1962), the second experiment is also a reinforced concrete beam (BRESLER; SCORDELIS, 1963) and the third experiment is reinforced concrete beams with small-scale and made of wire microconcrete simulating flat steel bar (ALMEIDA et al, 2006). For numerical modeling, using the smeared crack model with rotational crack, and analysis of concrete structures was chosen the commercial program ATENA - Advanced Tool Engineering Non-linear Analysis. ATENA ATENA Concreto armado Modelagem numérica Modelo de fissuração distribuída Numerical modeling Reinforced concrete Smeared crack model
3	Modelagem numérica de estruturas de concreto armado utilizando o programa ATENA. / Numerical modelling of reinforcement concrete structures using the program ATENA. Pedro Henrique Cerento de Lyra 16 December 2011 (has links) Com o avanço tecnológico dos computadores e o desenvolvimento de soluções para problemas não lineares através do método dos elementos finitos, hoje é possível fazer uma análise mais complexa e mais próxima da realidade. É de extrema importância à verificação dos resultados obtidos pelos programas com a realidade e saber em quais casos esses modelos podem ser aplicados. Assim, o objetivo deste trabalho é discutir as vantagens e desvantagens da modelagem de estruturas de concreto armado em duas e três dimensões, através dos modelos de fissuras distribuídas. Foram escolhidos três experimentos para a modelagem numérica: o primeiro trata-se de um experimento com uma viga de concreto armado (LEONHARDT; WALTHER, 1962), o segundo experimento também é realizado com uma viga de concreto armado (BRESLER; SCORDELIS, 1963) e o terceiro experimento utiliza vigas de concreto armado em escala reduzida, fabricadas com microconcreto e arame, simulando uma barra de aço lisa (ALMEIDA et al, 2006). Para a modelagem numérica, utilizando-se o modelo de fissuras distribuídas com fissura rotacional e a análise das estruturas de concreto foi escolhido o programa comercial ATENA - \"Advanced Tool Engineering Non-linear Analysis\". / The technological advancement of computers and the development of solutions for nonlinear problems by finite element method are now possible to make more complex the analysis and closer to reality. It is extremely important to verify the results obtained by programs with reality and know which cases these models can be applied. So the objective is to discuss the advantages and disadvantages of modeling reinforced concrete structures in two and three dimensions, through the smeared cracking models. Three experiments were chosen to make the numerical modeling: the first is an experiment with a reinforced concrete beam (LEONHARDT; WALTHER, 1962), the second experiment is also a reinforced concrete beam (BRESLER; SCORDELIS, 1963) and the third experiment is reinforced concrete beams with small-scale and made of wire microconcrete simulating flat steel bar (ALMEIDA et al, 2006). For numerical modeling, using the smeared crack model with rotational crack, and analysis of concrete structures was chosen the commercial program ATENA - Advanced Tool Engineering Non-linear Analysis. ATENA Concreto armado Modelagem numérica Modelo de fissuração distribuída ATENA Numerical modeling Reinforced concrete Smeared crack model
4	Modélisation du comportement des bétons fibrés à ultra-hautes performances par la micromécanique : effet de l'orientation des fibres à l'échelle de la structure / Micromechanics-based modelling of the UHPFRC behaviour : fibres orientation effects at the structural scale Guenet, Thomas 31 March 2016 (has links) Cette thèse s’inscrit dans le contexte d’une optimisation industrielle et économique des éléments de structure en BFUP permettant d’en garantir la ductilité au niveau structural, tout en ajustant la quantité de fibres et en optimisant le mode de fabrication. Le modèle développé décrit explicitement la participation du renfort fibré en traction au niveau local, en enchaînant une phase de comportement écrouissante suivie d'une phase adoucissante. La loi de comportement est fonction de la densité, de l'orientation des fibres vis-à-vis des directions principales de traction, de leur élancement et d'autres paramètres matériaux usuels liés aux fibres, à la matrice cimentaire et à leur interaction. L'orientation des fibres est prise en compte à partir d'une loi de probabilité normale à une ou deux variables permettant de reproduire n'importe quelle orientation obtenue à partir d’un calcul représentatif de la mise en œuvre du BFUP frais ou renseignée par analyse expérimentale sur prototype. Enfin, le modèle reproduit la fissuration des BFUP sur le principe des modèles de fissures diffuses et tournantes. La loi de comportement est intégrée au sein d'un logiciel de calcul de structure par éléments finis, permettant de l'utiliser comme un outil prédictif de la fiabilité et de la ductilité globale d’éléments en BFUP. Deux campagnes expérimentales ont été effectuées, une à l'Université Laval de Québec et l'autre à l'Ifsttar, Marne-la-Vallée. La première permet de valider la capacité du modèle à reproduire le comportement global sous des sollicitations typiques de traction et de flexion dans des éléments structurels simples pour lesquels l’orientation préférentielle des fibres a été renseignée par tomographie. La seconde campagne expérimentale démontre les capacités du modèle dans une démarche d’optimisation, pour la fabrication de plaques nervurées relativement complexes et présentant un intérêt industriel potentiel pour lesquels différentes modalités de fabrication et des BFUP plus ou moins fibrés ont été envisagés. Le contrôle de la répartition et de l’orientation des fibres a été réalisé à partir d'essais mécaniques sur prélèvements. Les prévisions du modèle ont été confrontées au comportement structurel global et à la ductilité mis en évidence expérimentalement. Le modèle a ainsi pu être qualifié vis-à-vis des méthodes analytiques usuelles de l'ingénierie, en prenant en compte la variabilité statistique. Des pistes d'amélioration et de complément de développement ont été identifiées / This Ph.D. project has been prepared within the context of an industrial and economic optimisation of UHPFRC structural elements to ensure ductility at the structural level, while adjusting the amount of fibre and optimising the manufacturing process. The model developed explicitly describes the participation of local fibre reinforcement in tension, thanks to a hardening behaviour followed by a softening one. The constitutive law is a function of the local fibre content, of the fibre orientation with respect to tensile principal directions, of the fibre slenderness and other usual material parameters related to the fibres, the cementitious matrix and their interaction. The fibre orientation is taken into account using a normal probability distribution with one or two variables to reproduce any orientation either obtained from a representative simulation of casting fresh UHPFRC or informed by experimental analysis on prototypes. Lastly, the model reproduces the cracking of UHPFRC based on the principle of smeared rotating crack models. The constitutive law is implemented in a structural finite element software as a predictive tool of reliability and overall ductility of UHPFRC elements. Two experimental campaigns were carried out, one at Laval University in Quebec and one at Ifsttar, Marne-la-Vallée. The first one is used to confirm the model ability to reproduce the overall behaviour under typical tensile and bending loads in simple structural elements for which the preferential fibre orientation was measured by microtomography. The second experimental campaign demonstrates the capabilities of the model, in an optimisation process, to help manufacture relatively complex ribbed triangular plates of industrial interest in which different manufacturing process and fibre volume have been considered. The identification of fibre distribution and orientation has been performed using mechanical tests on sawn samples. The model predictions have been compared to the global structural behaviour, and to the ductility demonstrated experimentally. The model could be qualified through comparison with conventional analytical engineering methods, taking into account the statistical variability. Improvement and additional developments have been identified Bfup Modèle de fissures diffuses Micromécanique Orientation des fibres Structures Uhpfrc Smeared crack model Micromechanics Fibres orientation Structures
5	[en] REACTIVATION OF GEOLOGICAL FAULTS WITH DISCRETE AND DISTRIBUTED NUMERICAL MODELS / [pt] REATIVAÇÃO DE FALHAS GEOLÓGICAS COM MODELOS NUMÉRICOS DISCRETOS E DISTRIBUÍDO JULIO ALBERTO RUEDA CORDERO 03 September 2015 (has links) [pt] Em reservatórios complexos com descontinuidades geológicas como falhas, os riscos na produção de petróleo e gás pelos métodos de injeção frequentemente utilizados são maiores. Um dos fenômenos que pode acarretar graves problemas de perda de produção e acidentes ambientais é a reativação de falhas geológicas. Isto ocorre devido às variações de tensões induzidas na formação, as quais podem ser suficientemente altas para reativar as falhas e modificar significativamente o comportamento do reservatório, gerando uma das situações mais críticas na indústria de petróleo. Nessa dissertação investiga-se através do método dos elementos finitos o fenômeno de reativação de falhas com base em modelos de representação explícita da falha através de elementos de interface. Adota-se ainda para efeitos de comparação uma modelagem da falha por meio de uma zona de falha através do conceito de contínuo equivalente. Uma metodologia com base em uma análise poro-elastoplástica desacoplada que permite estimar as pressões limite para a reativação durante a produção em reservatórios de petróleo de uma maneira versátil e eficiente foi empregada nas situações investigadas através do simulador Abaqus. Para tal, foram implementadas uma série de rotinas para incorporar ao programa Abaqus novos elementos de interface, governados pelo modelo constitutivo de Mohr-Coulomb. A metodologia apresentada foi avaliada e verificada através da simulação de um modelo sintético com falha normal comparando os resultados com uma solução analítica simplificada e com os resultados obtidos com o simulador de elementos finitos AEEPECD (Costa, 1984). São apresentados alguns exemplos de aplicação representando a falha com elementos de interface e como um contínuo equivalente. Os resultados obtidos nas análises demonstram a aplicabilidade da metodologia a problemas de campos reais. / [en] In complex reservoirs with geological discontinuities, such as faults, the risk in the production of oil and gas are increase by the injection methods frequently used. The injection and depletion processes induce stress variations in the formation. These can be high enough to reactivate faults and significantly modify the behavior of the reservoir, bringing on one of the most critical situations in the oil industry. In this context, this dissertation investigates the phenomenon of fault reactivation by employing the finite element method based on an explicit representation of the fault with interface elements. In addition, a fault zone model based on an equivalent continuum approach is adopted for comparison. The pressure limits during production of oil reservoirs considering fault reactivation are determined from pore-elastoplastic uncoupled analyses with the software Abaqus. With this purpouse, interfaces elements with Mohr-Coulomb constitutive model were implemented through user subroutine in Abaqus to represent, in an approximate way, the fault behavior. In addition, other tools were developed to facilitate the generation of the models to be analyzed. The presented methodology was evaluated and verified through the simulation of a synthetic model with a normal fault. The results were compared with a simplified analytical approach and the results obtained by finite element simulator AEEPECD (Costa, 1984). Some examples of applications are presented, in which faults are represented using interface elements and alternatively, through an equivalent continuum approach. The analysis results demonstrate the applicability of the methodology to real fields. [pt] MECANICA COMPUTACIONAL [en] COMPUTATIONAL MECHANICS [pt] REATIVACAO DE FALHAS [en] FAULT REACTIVATION [pt] ELEMENTO DE INTERFACE [en] INTERFACE ELEMENT [pt] FRATURA DISTRIBUIDA [en] SMEARED CRACK
6	Análisis no lineal elástico en vigas de concreto a través del Modelo Fijo de Grietas Dispersas / Nonlinear Elastic Analysis of concrete beams by the Fixed Smeared Crack Approach Arias Palomino, Christopher, Betancourt Irusta, Karl Nils 24 January 2020 (has links) El presente estudio trata sobre el análisis del agrietamiento en vigas de concreto sujetas a cargas monotónicas a través de un cálculo pseudo-estático. El fundamento teórico se basa en el Método de Grietas Dispersas (Smeared Crack Approach) de la Mecánica de Fractura, el cual será evaluado dentro de un algoritmo de análisis considerando el Método de Elementos Finitos. El objetivo principal es proponer un modelo computacional para el cálculo de deflexiones instantaneas y la modelación del agrietamiento en vigas de concreto armado sometidas a cargas de servicio. Con este propósito, se evaluaron las vigas analizadas por diversos autores. Los resultados del estudio se presentan mediante curvas fuerza-desplazaminto, la secuencia de propagación del agrietamiento y la evaluación de la resistencia última. Se consideró un modelo frágil de esfuerzo y deformación en la grieta. De esta manera, para los elementos analizados, se demostró que el modelo utilizado es capaz de predecir adecuadamente el proceso de agrietamiento y de calcular las deflexiones instantáneas en vigas de concreto, teniendo en cuenta resultados experimentales existentes. / The present study deals with cracking analysis of concrete beams under monotonic loadings by means of a quasi-static evaluation. The theoretical basis herein used is lies on the Fixed Smeared Crack Approach taking into account Fracture Mechanics within a Finite Element algorithm for the numerical solution of the problem. The main objective is to propose a computational model for the calculus of instantaneous deflection and the simulation of cracking in concrete beams under service loadings. On this purpose, diverse beams evaluated by may authors where analyzed. The results of this study cases are presented through and force-displacement curves, cracking propagation and the evaluation of the ultimate resistance of the beam. Within the computational algorithm, a fragile crack stress-strain relation was implemented. On this way, for the analyzed elements it was demonstrated that the model herein used can predict adequately cracking processes and instantaneous deflections of concrete beams considering existing experimental results. / Tesis Agrietamiento Concreto Método de Grietas Dispersas Método de Elementos Finitos Cracking Concrete Fixed Smeared Crack Approach Finite Element Method
7	Consolidation theories for saturated-unsaturated soils and numerical simulation of residential buildings on expansive soils Zhang, Xiong 01 November 2005 (has links) The coupled and uncoupled consolidation theories for saturated-unsaturated soils have been discussed. A new method for constructing the constitutive surfaces for saturated-unsaturated soils has been proposed. The consolidation processes for saturated-unsaturated soils have been explained by thermodynamic analogue. One dimensional consolidation theory for saturated-unsaturated soils is presented and a new method is proposed to calculate the immediate settlement, total settlement and the time history of the consolidation settlement manually in the same way as what we have done for saturated soils with a higher accuracy. It makes the consolidation theory of unsaturated soils as applicable as that of saturated soils. This method can also be used to perform uncoupled two or three dimensional consolidation calculation for both expansive soils and collapsible soils. From the analysis, the equivalent effective stress and excessive pore water pressure can be easily calculated. At the same time, the physical meanings for the parameters in the constitutive laws for saturated-unsaturated are illustrated. A new set of the differential equations for the coupled two or three dimensional consolidation of saturated-unsaturated soils are proposed, together with the corresponding method to solve the differential equations. It is also proved numerically and analytically that during the consolidation process the Mandel-Cryer effect exists for unsaturated expansive soils and there is a ??reverse?? Mandel-Cryer effect for unsaturated collapsible soils. A new method is proposed to estimate the volume change of expansive soils. A complete system is proposed for the numerical simulation of residential buildings on expansive soils. The strength of this method lies in its use of simple and readily available historic weather data such as daily temperature, solar radiation, relative humidity, wind speed and rainfall as input. Accurate three dimensional predictions are obtained by integrating a number of different analytical and numerical techniques: different simulation methods for different boundary conditions such as tree, grass, and bare soils, coupled hydro-mechanical stress analysis to describe deformation of saturated-unsaturated soils, jointed elements simulation of soil-structure interaction, analysis of structure stress moment by general shell elements, and to assess structural damage by the smeared cracking model. The real-time and dynamic simulation results are consistent with filed measurements.
8	Finite element modelling of cracking in concrete gravity dams Cai, Qingbo 30 January 2008 (has links) Evaluating the safety of unreinforced concrete structures, such as concrete dams, requires an accurate prediction of cracking. Developing a suitable constitutive material model and a reliable computational procedure for analysing cracking processes in concrete has been a challenging and demanding task. Although many analytical methods based on fracture mechanics have been proposed for concrete dams in the last few decades, they have not yet become part of standard design procedures. Few of the current research findings are being implemented by practising engineers when evaluating dam safety. This research is focused on the development of a suitable crack modelling and analysis method for the prediction and study of fracturing in concrete gravity dams, and consequently, for the evaluation of dam safety against cracking. The research aims to contribute to the continuing research efforts into mastering the mechanics of cracking in concrete dams. An analytical method for the purpose of establishing a crack constitutive model and implementing the model for the fracture analysis of concrete structures, in particular massive concrete gravity dams under static loading conditions, has been developed, verified and applied in the safety evaluation of a concrete gravity dam. The constitutive material model is based on non-linear fracture mechanics and assumes a bilinear softening response. The crack model has various improved features: (1) an enhanced mode I bilinear strain-softening approach has been put forward; (2) a new formula for bilinear softening parameters has been developed and their relation with linear softening has been outlined; (3) the influence of bilinear softening parameters on the cracking response has been studied; and (4) an enhanced modification to the shear retention factor which depends on the crack normal strain is included. The material model has been incorporated into a finite element analysis using a smeared crack approach. A sub-program was specially coded for this research. The validity of the proposed cracking model and the computational procedure developed for the purpose of analyzing the tensile fracture behaviour of concrete structures has been confirmed by verification on various concrete structures, including beams, a dam model and actual gravity dams. The crack modelling technique developed was successfully used in evaluating the safety of an existing concrete gravity dam in South Africa and adequately predicted the cracking response of the dam structure under static loadings. The main conclusions drawn are as follows: <ul><li>Both mode I and mode II fracture have been modelled successfully.</li> <li>The proposed bilinear softening model remains relatively simple to implement but significantly improves on predicting the softening response of “small-scale” concrete structures.</li> <li>Both plane stress and plane strain crack analyses have been considered and can be confidently adopted in two-dimensional applications.</li> <li>The proposed method is mesh objective.</li> <li>The crack modelling method developed can correctly predict the crack propagation trajectory and the structural behaviour with regard to fracturing in concrete structures.</li> <li>If not considering shear stress concentration near the tip of a crack, constitutive crack analysis normally indicates a higher safety factor and a higher Imminent Failure Flood (IFF) than the classical methods in the analysis of concrete gravity dams for safety evaluation.</li></ul> / Thesis (PhD(Civil Engineering))--University of Pretoria, 2007. / Civil Engineering / PhD / unrestricted Crack modeling Bilinear softening Crack propagation Dam safety Computational procedure Constitutive crack model Non-linear fracture mechanics Concrete gravity dams Smeared crack approach UCTD
9	Development of Novel Computational Simulation Tools to Capture the Hysteretic Response and Failure of Reinforced Concrete Structures under Seismic Loads Moharrami Gargari, Mohammadreza 26 July 2016 (has links) Reinforced concrete (RC) structures constitute a significant portion of the building inventory in earthquake-prone regions of the United States. Accurate analysis tools are necessary to allow the quantitative assessment of the performance and safety offered by RC structures. Currently available analytical approaches are not deemed adequate, because they either rely on overly simplified models or are restricted to monotonic loading. The present study is aimed to establish analytical tools for the accurate simulation of RC structures under earthquake loads. The tools are also applicable to the simulation of reinforced masonry (RM) structures. A new material model is formulated for concrete under multiaxial, cyclic loading conditions. An elastoplastic formulation, with a non-associative flow rule to capture compression-dominated response, is combined with a rotating smeared-crack model to capture the damage associated with tensile cracking. The proposed model resolves issues which characterize existing concrete material laws. Specifically, the newly proposed formulation accurately describes the crack opening/closing behavior and the effect of confinement on the strength and ductility under compressive stress states. The model formulation is validated with analyses both at the material level and at the component level. Parametric analyses on RC columns subjected to quasi-static cyclic loading are presented to demonstrate the need to regularize the softening laws due to the spurious mesh size effect and the importance of accounting for the increased ductility in confined concrete. The impact of the shape of the yield surface on the results is also investigated. Subsequently, a three-dimensional analysis framework, based on the explicit finite element method, is presented for the simulation of RC and RM components under cyclic static and dynamic loading. The triaxial constitutive model for concrete is combined with a material model for reinforcing steel which can account for the material hysteretic response and for rupture due to low-cycle fatigue. The reinforcing steel bars are represented with geometrically nonlinear beam elements to explicitly account for buckling of the reinforcement. The strain penetration effect is also accounted for in the models. The modeling scheme is validated with the results of experimental static and dynamic tests on RC columns and RC/RM walls. The analyses are supplemented with a sensitivity study and with calibration guidelines for the proposed modeling scheme. Given the computational cost and complexity of three-dimensional finite element models in the simulation of shear-dominated structures, the development of a conceptually simpler and computationally more efficient method is also pursued. Specifically, the nonlinear truss analogy is employed to capture the response of shear-dominated RC columns and RM walls subjected to cyclic loading. A step-by-step procedure to establish the truss geometry is described. The uniaxial material laws for the concrete and masonry are calibrated to account for the contribution of aggregate interlock resistance across inclined shear cracks. Validation analyses are presented, for quasi-static and dynamic tests on RC columns and RM walls. / Ph. D. Nonlinear analysis RC structures Flexure-dominated Shear-dominated Triaxial constitutive model Elastoplastic model Smeared cracking Confinement effect Collapse Nonlinear truss model Aggregate interlock Cyclic loading Seismic loading
10	Nonlinear finite element analysis of reinforced concrete exterior beam-column joints with nonseismic detailing Deaton, James B. 11 January 2013 (has links) This research investigated the behavior of nonseismically detailed reinforced concrete exterior beam-column joints subjected to bidirectional lateral cyclic loading using nonlinear finite element analysis (NLFEA). Beam-column joints constitute a critical component in the load path of reinforced concrete buildings due to their fundamental role in integrating the overall structural system. Earthquake reconnaissance reports reveal that failure of joints has contributed to partial or complete collapse of reinforced concrete buildings designed without consideration for large lateral loads, resulting in significant economic impact and loss of life. Such infrastructure exists throughout seismically active regions worldwide, and the large-scale risk associated with such deficiencies is not fully known. Computational strategies provide a useful complement to the existing experimental literature on joint behavior and are needed to more fully characterize the failure processes in seismically deficient beam-column joints subjected to realistic failure conditions. Prior to this study, vulnerable reinforced concrete corner beam-column joints including the slab had not been analyzed using nonlinear finite element analysis and compared with experimental results. The first part of this research focused on identification and validation of a constitutive modeling strategy capable of simulating the behaviors known to dominate failure of beam-column joints under cyclic lateral load using NLFEA. This prototype model was formulated by combining a rotating smeared crack concrete constitutive model with a reinforcing bar plasticity model and nonlinear bond-slip formulation. This model was systematically validated against experimental data, and parametric studies were conducted to determine the sensitivity of the response to various material properties. The prototype model was then used to simulate the cyclic response of four seismically deficient beam-column joints which had been previously evaluated experimentally. The simulated joints included: a one-way exterior joint, a two-way beam-column exterior corner joint, and a series of two-way beam-column-slab exterior corner joints with varying degrees of seismic vulnerability. The two-way corner joint specimens were evaluated under simultaneous cyclic bidirectional lateral and cyclic column axial loading. For each specimen, the ability of the prototype model to capture the strength, stiffness degradation, energy dissipation, joint shear strength, and progressive failure mechanisms (e.g. cracking) was demonstrated. Smeared crack model Shear failure Beam-column joint NLFEA Earthquake engineering Seismic design Finite element method (FEM) Reinforced concrete Earthquake engineering Research Structural analysis (Engineering) Numerical analysis Joints (Engineering) Concrete construction Joints

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