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

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

Finite element modelling of cracking in concrete gravity dams

Cai, Qingbo

30 January 2008

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