Numerical modeling for the rebar bond behaviour in normal and high strength concrete

Congreso celebrado en la Escuela de Arquitectura de la Universidad de Sevilla desde el 24 hasta el 26 de junio de 2015.This paper presents a finite element model for the analysis of the bond behavior between steel rebars and concrete. This behavior is defined by the bond vs. slip curve in European standards (e.g. the CEB- 90) for normal strength concrete (NSC). Pull-out tests have been performed on both NSC and high strength concrete (HSC) specimens and the resulting curves are compared to numerical models implemented in a FEM software. In these models the contact behavior has been defined according to the Model Code CEB-2010 and a position controlled loading has been performed in order to trace the load-slip curve for comparison with experiments. The FEM model has been calibrated with basic mechanical parameters from both types of concrete (compressive and tensile stress, elastic moduli). The numerical modelling has proven suitable for the NSC bond behaviour. However, the CEB standard should be improved to account for the HSC bond behaviour

FRP Confinement of Stone Samples after Real Fire Exposure

The mechanical properties of stone materials can be severely affected by exposure to high temperatures. The effect of fire on stone buildings could cause irreversible damage and make it necessary to retrofit the affected elements. Particularly, the strengthening of columns by confinement with composites has been widely improved during the last decades. Today, fiber reinforced polymer (FRP) confinement represents a very interesting alternative to traditional steel solutions. This work studied the behavior of cylindrical stone specimens subjected to real fire action and confined by means of CFRP or GFRP jackets, with the aim of assessing the effectiveness of these reinforcement systems applied to a material that has previously been seriously damaged by high temperature exposure. In general, the strengthened samples showed notable increases in strength and ductility. The response seemed to depend basically on the FRP properties and not on the degree of damage that the stone core may have suffered. Finally, the results obtained experimentally were compared with the confinement models proposed by the available design guides, in order to evaluate the accuracy that these models can offer under the different situations addressed in this research.This research was funded by the Spanish Ministry of Science, Innovation and Universities, grant number RTI2018‐101148‐B‐I00. The APC was funded by University of Alicante, grant number VIGROB 212

Experimental analysis of the loss of bond between rebars and concrete exposed to high temperatures

En el conjunto de materiales de construcción habituales en la edificación y las obras de ingeniería, el hormigón destaca entre otras razones por su excelente comportamiento frente a las altas temperaturas y la exposición al fuego. El presente estudio se centra en la adherencia residual entre el hormigón y las barras de acero corrugado soldable tras exponer probetas a altas temperaturas y enfriarlas hasta temperatura ambiente por convección natural. El estudio incluye hormigones de resistencia convencional, hormigones de alta resistencia y hormigones reforzados con fibras de polipropileno y fibras de acero. La adherencia hormigón-acero se ha medido mediante el conocido ensayo de pull-out. La campaña experimental también ha incluido la resistencia a compresión y la resistencia a tracción indirecta. Parte de las probetas se han ensayado a 28 días de edad a temperatura ambiente. A 60 días de edad se han repetido los ensayos a temperatura ambiente y se han realizado esos mismos ensayos en probetas calentadas en un horno industrial hasta tres rangos de temperatura: 450°C, 650°C y 825°C. Previo al proceso de calentamiento han sido sometidas durante 3 horas a un escalón de secado a 120°C. Mediante la metodología propuesta ha sido posible caracterizar la evolución de la pérdida de adherencia residual entre el acero y el hormigón conforme se exponen los especímenes a temperaturas más elevadas. La adición de fibras no tiene una influencia clara en la adherencia a temperatura ambiente. Sin embargo, sí se ha conseguido determinar una mejora sustancial de la adherencia residual en los hormigones, reforzados con fibras de acero sometidos a altas temperaturas.Within the context of the most usual construction materials for building and civil infrastructures, concrete stands out because of its excellent behaviour when exposed to high temperatures and fire condition. The present study focuses on the residual bond strength between concrete and steel rebars after exposure to elevated temperatures and natural cooling to room temperature. Normal strength and high strength concretes have been tested, as well as polypropylene and steel fibre reinforced concretes. The bond strength has been measured using the pull-out test. Compressive and tensile strength have also been determined. Some specimens have been tested at an age of 28 days and at room temperature. At 60 days the tests have been repeated at room temperature and after heating up to three temperature ranges: 450°C, 650°C and 825°C. Before each of the three heating phases, the specimens were pre-heated during 3 hours at 120 °C. After these experiments it has been possible to assess the loss of steel-concrete bonding for higher temperatures. The addition of fibres has no clear influence on the bonding at ambient condition. However, an improvement on the residual bonding strength has been observed for steel fibre reinforced concrete under high temperatures

Análisis por elementos finitos de losas de edificación sometidas a punzonamiento

Comunicación presentada en el VII Congreso Trienal de la Asociación Científico-Técnica del Hormigón Estructural (ACHE), A Coruña, 20-22 junio 2017.Uno de los principales problemas en las estructuras de edificación es el debido al punzonamiento en el encuentro losa-pilar. En el presente trabajo se expone un modelo numérico no lineal basado en método de los elementos finitos, y desarrollado en ABAQUS, para el análisis de la rotura por punzonamiento en losas de hormigón armado. El objeto es disponer de una herramienta de simulación que permita el estudio de forjados existentes, para la evaluación de su capacidad a punzonamiento y de un posible refuerzo. También el estudio de forjados de nueva construcción, donde se pueda optimizar la geometría y las cuantías.One of the main building structure problems is the phenomenon of punching in the slab-column connection. In this paper a nonlinear numerical model based on finite element method is exposed, and developed in ABAQUS, for the analysis of punching failure of reinforced concrete slabs. The goal is to achieve simulation tool that allows the study of existing slabs, to assess their ability to punching and a possible reinforcement. The study also concerns new constructions, where geometry and ratios can be optimized

Textile Reinforced Mortars (TRM) tensile behavior after high temperature exposure

Although one of the main advantages of Textile Reinforced Mortars (TRM) is their non-combustible character, their behavior against fire or high temperatures has not been sufficiently studied at present. This work analyzes the behavior of different commercial systems containing inorganic mortars and fabric reinforcements based on glass, carbon and basalt fibers, subjected to different temperature levels. To characterize the mechanical response of the different systems, non-destructive tests have been carried out to determine the dynamic modulus of elasticity of the different materials, and subsequent destructive tests to determine their strength and stress-strain relationship. For this purpose, the TRM coupons have been subjected to uniaxial tensile tests and the deformations have been monitored using LVDT (Linear Variable Displacement Transducer) sensors and DIC (Digital Image Correlation), in order to evaluate cracking patterns and failure modes. The results show, in general terms, that the mechanical capacity of these materials is seriously compromised at temperatures in the order of 400 to 600 °C, which can easily be reached during a fire inside a building. Therefore, it can be concluded that although these systems are erroneously perceived as fire resistant in many cases, they may require additional protection depending on the specific use for which they are intended.The authors would like to acknowledge Mapei Spain S.A. for the materials supplied in this work. This research has been funded by the Spanish Ministry of Science, Innovation and Universities, grant number RTI2018-101148-B-100

Masonry walls strengthened with Textile Reinforced Mortars (TRM) and subjected to in-plane cyclic loads after real fire exposure

A key feature that determines the seismic performance of masonry buildings is the ability of the walls to withstand in-plane cyclic loads. In this context, Textile Reinforced Mortars (TRM) have proven to be a very suitable strengthening solution, although their effectiveness after high temperature exposure is currently practically unexplored. This paper proposes an experimental campaign with full-scale brick walls and carbon fiber TRM, tested to failure under horizontal cyclic in-plane loads, after being exposed to temperatures of about 1000 °C by exposure to real fire. TRM is applied on one or both sides of the walls, and after or before exposure to fire, to simulate different scenarios that a real building could be exposed to. The results show that high temperatures can seriously compromise the integrity of the walls, while TRM can provide effective protection and prevent cracking of masonry from fire. Even after previous fire damage, the reinforcements can double the shear strength of unreinforced damaged walls, and provide high ductility and energy dissipation capacity. However, it is important to note that TRM, even undamaged, may not be able to properly retrofit a severely fire-damaged wall.This research has been funded by the Spanish Ministry of Science, Innovation and Universities, grant number RTI2018-101148-B-I00

Shear strengthening of masonry walls with Textile Reinforced Mortars (TRM) under high temperature exposure

The behavior of masonry walls strengthened with Textile Reinforced Mortars (TRM) is a topic that has received considerable attention from researchers in recent years. However, the response of such elements after exposure to high temperature is an issue that remains to be explored extensively. This study analyzes the behavior of TRM-strengthened brick masonry panels with glass and carbon fiber meshes subjected to temperatures up to 600 °C, and subsequently tested under diagonal compression. The reinforcements were applied before or after temperature exposure, to analyze the effectiveness of damaged or undamaged TRMs, thus simulating different scenarios that might occur in a real building under a fire event. In general terms, the results showed that TRMs with carbon fibers exhibited a better response in these conditions, restoring the walls to their original capacity and providing additional ductility, whilst reinforcements with glass fibers seemed to be more affected by temperature. Finally, the experimental results are here compared to predictions from available design guides, in order to assess the accuracy that these codes would provide in these circumstances.This research has been funded by the Spanish Ministry of Science, Innovation and Universities, grant number RTI2018-101148-B-100

Coordinación vertical de la formación en Cálculo de Estructuras dentro del Grado en Ingeniería Civil: Desarrollo de aplicaciones interactivas para la docencia

Las nuevas tecnologías aplicadas a la enseñanza permiten la visualización de fenómenos físicos y su relación con la base matemática utilizada en la modelización de los mismos. En este trabajo se ha utilizado el programa Mathematica para realizar aplicaciones ilustrativas de distintos conceptos básicos para el cálculo de estructuras de ingeniería civil y edificación. Se han tratado temas como la reología, la plastificación de los materiales, la relación entre tensiones y deformaciones de los sólidos elásticos o la dinámica estructural, siempre desde un punto de vista teórico-práctico y tratando de mantener en todo momento un carácter interactivo que permita la participación activa de los estudiantes. Cada aplicación compagina los fundamentos teóricos y la influencia de los parámetros implicados, con la visualización en forma de gráfico animado de la función resultante

Residual Compressive Strength of Recycled Aggregate Concretes after High Temperature Exposure

Sustainability requirements are gaining importance in the construction industry, which needs to take specific measures in the design and construction of concrete structures. The use of recycled aggregates in concrete may be of special interest. Recycling a construction waste will close the life cycle of the original materials (e.g., concrete). Thus, environmental benefits would come from the lower waste generation, and from a lower necessity of raw materials for new structures. The current Spanish code for structural concrete considers the use of recycled aggregates in replacement rates up to 20% by aggregate mass, assimilating their properties with those of concretes without aggregate replacement. Higher substitution percentages would require further testing. In this work, substitution of coarse aggregate for recycled aggregates (with replacement percentages of 25%, 50% and 100%) has been studied, and the concrete’s residual properties after exposure to high temperatures (between 350 °C and 850 °C) have been assessed. Compressive strength and capillary water absorption tests were made after heating, and the experiments showed higher residual strength in concretes with the greatest content of recycled aggregates. However, a statistical analysis made with additional data available in the literature seemed to predict otherwise, and the recycled aggregate replacement would have a negative effect on the residual strength.This research was funded by Generalitat Valenciana, grant number GV/2018/015

Application of an Evolutionary Algorithm to Reduce the Cost of Strengthening of Timber Beams

The present paper describes the application of an evolutionary algorithm to the optimum design of the reinforcement of timber beams using FRP laminates and sheets. The objective function is the material cost of the strengthening and is subjected to ten constraints derived from the ultimate limit states for flexural and shear behaviour as well as the serviceability limit states. A genetic algorithm is used and the optimization problem is transformed into an unconstrained one by means of an adaptive penalty function. The design variables are the CFRP and GFRP mechanical properties and dimensions and they are encoded in a binary chromosome: type of composite material (CFRP or GFRP), reinforcement mechanical properties and geometric configuration. The search space for the minimum cost consists of 65 billion possible solutions. The crossover operator switches randomly between a fenotype crossover and flat crossover. An adaptive mutation scheme has been as well as an elitism criterion. The algorithm has been used for obtaining optimum designs in several specific load and geometry cases of glued laminated timber beams. The objective is finding whether there are specific reinforcement configurations more feasible for a certain loading situations: short or long beams and lower or higher loading increments. Five cases have been analysed. In the first three cases the length of the beams has constant values of 2, 2.5 and 3 m, whereas the value of loading was variable. In the latter case, the value of the load was fixed and the length of the beam was variable. The analysis of the results shows that the GFRP reinforcement is more efficient than CFRP for designs governed by shear failure, whereas CFRP is more effective in the case of flexural failure and deflection controlled strengthening of timber beams.This work was partially financed by the University of Alicante by means of the GRE12-04 Research Project and Generalitat Valenciana, grant GV/2014/079