962 resultados para Mortar and concrete
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El objetivo de este trabajo es conocer las posibles modificaciones que puede producir en el comportamiento de las estructuras de hormigón armado (EHA) el hecho de que sean utilizadas como estructuras termoactivas, ya sea como intercambiadores en contacto con el terreno, o como sistema de distribución de calor utilizando la inercia térmica de los elementos de hormigón del edificio, basándose en el uso de energías renovables. Las EHA termoactivas se caracterizan por la incorporación en su interior de tubos de polietileno por los que circulan fluidos a temperaturas medias, que pueden incidir en el comportamiento mecánico de los elementos estructurales debido a dos efectos fundamentales: el incremento de temperatura que se produce en el interior de la EHA y la perturbación provocada por la incorporación de los tubos de polietileno. Con este fin, se ha realizado una campaña experimental de probetas de hormigón, estudiando los dos efectos por separado, por un lado se ha evaluado el comportamiento de probetas de hormigón tipo H-25 y tipo H-30 sometidas a cuatro temperaturas diferentes: 20ºC, 40ºC, 70ºC y 100ºC, ensayando la resistencia a compresión y la resistencia a anclaje/adherencia mediante ensayo “pull-out”; y, por otro lado, se ha evaluado el comportamiento de probetas de hormigón tipo H-25 y tipo H-30, elaboradas con dos tipos de molde (cilíndrico y cúbico), en las que se ha colocado tubos de polietileno en su interior en distintas posiciones, ensayando su resistencia a compresión. Los resultados de los ensayos han puesto de manifiesto que aunque se produce una disminución en la resistencia a compresión, y a arrancamiento, del hormigón, al ser sometido a aumentos de temperatura, esta disminución de la propiedades mecánicas es inferior al 20% al no superar esta tecnología los 70ºC; y respecto a la variación de la resistencia a compresión de probetas cilíndricas y cúbicas, debidas a la incorporación de los tubos de polietileno, se observa que si la posición de los mismos es paralela a la dirección de la carga tampoco se ven comprometidas las propiedad mecánicas del hormigón en valores superiores al 20%. ABSTRACT The aim of this project is to study the effects of using concrete structures as thermo-active constructions, either as energy foundations or other kind of thermo-active ground structures, or as a thermally activated building structure utilizing its own thermal mass conductivity and storage capacity to heat and cool buildings, based on renewable or “free” energy sources. The pipes, filled with a heat carrier fluid, that are embedded into the building´s concrete elements may bring on two different adverse effects on concrete structures. In one hand, the consequence of thermal variations and, on the other hand, because of the fact that the pipes are inside of the concrete mortar and in direct contact with the reinforcing steel bars. For this reason, different types of specimens and testing procedures have been proposed to discuss the effects of temperature (20º, 40ºC, 70ºC y 100ºC) on the performance of two different hardened concrete: H-25 and H-30, and the effects of having the pipes embedded in different positions inside of specimens made of two types of concrete, H-25 and H-30, and with two kind of cast, cylindrical and cubical. The experimental program includes the use of compressive strength test and also pull-out test, in order to investigate the interfacial adhesion quality and interfacial properties between steel bar and concrete. The results of the mechanical test showed that the increase of temperature in hardened concrete specimens lower than 70ºC, and the introduction of embedded pipes placed in parallel to the load, in cylindrical or cubic specimens, does not jeopardize the mechanical properties of concrete with strength decreases higher than 20%.
Effect of nano-Si2O and nano-Al2O3 on cement mortars for use in agriculture and livestock production
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The effect of nano-silica, nano-alumina and binary combinations on surface hardness, resistance to abrasion and freeze-thaw cycle resistance in cement mortars was investigated. The Vickers hardness, the Los Angeles coefficient (LA) and the loss of mass in each of the freeze–thaw cycles to which the samples were subjected were measured. Four cement mortars CEM I 52.5R were prepared, one as control, and the other three with the additions: 5% nano-Si, 5% nano-Al and mix 2.5% n-Si and 2.5% n-Al. Mortars were tested at 7, 28 and 90 d of curing to determine compression strength, total porosity and pore distribution by mercury intrusion porosimetry (MIP) and the relationship between the CSH gel and Portlandite total by thermal gravimetric analysis (TGA). The capillary suction coefficient and an analysis by a scanning electron microscope (SEM) was made. There was a large increase in Vickers surface hardness for 5% n-Si mortar and a slight increase in resistance to abrasion. No significant difference was found between the mortars with nano-particles, whose LA was about 10.8, classifying them as materials with good resistance to abrasion. The microstructure shows that the addition of n-Si in mortars refines their porous matrix, increases the amount of hydrated gels and generates significant changes in both Portlandite and Ettringite. This produced a significant improvement in freeze–thaw cycle resistance. The effect of n-Al on mortar was null or negative with respect to freeze–thaw cycle resistance.
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Nanoclay-based pigments are promising colorants. They enhance the colorimetric properties of the dye giving more intense and saturated colours. In addition, they act as reinforce additive when they are dispersed into polymers. They can be applied in a wide variety of substrates: printing inks, textiles, acrylic paints and concrete; and more applications are being developed. One important advantage of the nanoclay-based pigments is the fact that they can be considered an ecological alternative to contaminant colorants, in contrast to some traditional inorganic pigments that contend heavy metal in their structure.
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This Working Paper offers detailed analysis of EU-UNICEF cooperation on the rights of the child in the European Union's external relations, in particular as regards linkages between the EU policy priorities and concrete actions to advance the protection and promotion of child rights in third countries. It addresses a number of crucial questions: how has the EU’s external policy on the rights of the child developed over the past decade, what were these developments influenced by and what role did UNICEF play in these processes; what is the legal and policy framework for EU-UNICEF cooperation in foreign policy and what added-value it brings; what mechanisms are used by the EU and UNICEF to improve child rights protection in third countries and what are the motivations behind their field cooperation. The study starts by examining the development of the EU’s foreign policy on the rights of the child and covers the legal basis enshrined in EU treaties, the policy framework, and the implementation instruments and then investigates the evolution of the EU’s relations with the United Nations. The paper focuses on the EU’s cooperation with UNICEF by looking into the legal and political framework for EU-UNICEF relations, the policy-oriented cooperation and joint implementation of projects on the ground in third countries. This section outlines the rationale behind the practical cooperation as well as the factors for success and obstacles hindering the delivery of sustainable results. Finally, the Working Paper concludes with suggestions on how EU-UNICEF cooperation could be further enhanced following recent developments, namely the 2012 EU Strategic Framework and the Action Plan on Human Rights as well as human rights country strategies.
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"HRDI-11/10-05(2M)E"--P. [4] of cover.
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Analytical solutions are presented for linear finite-strain one-dimensional consolidation of initially unconsolidated soil layers with surcharge loading for both one- and two-way drainage. These solutions complement earlier solutions for initially unconsolidated soil layers without surcharge and initially normally consolidated soil layers with surcharge. Small-strain solutions for the consolidation of initially unconsolidated soil layers with surcharge loading are also presented, and the relationship between the earlier solutions for initially unconsolidated soil without surcharge and the corresponding small-strain solutions, which was not addressed in the earlier work, is clarified. The new solutions for initially unconsolidated soil with surcharge loading can be applied to the analysis of low stress consolidation tests and to the partial validation of numerical solutions of non-linear finite-strain consolidation. They also clarify a formerly perplexing aspect of finite-strain solution charts first noted in numerical solutions. Copyright (C) 2004 John Wiley Sons, Ltd.
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The depths of cracks in desiccating plastic concrete are estimated by considering the effects of the suction (negative pore pressure) associated with desiccation and applying five failure models derived from fracture, theories combined with theories drawn from geotechnical engineering under the assumption that plastic concrete is a frictional particulate material. The estimated crack depths vary with the depth of desiccation, the suction profile, and a small number of material parameters that depend on the model adopted and are comparatively easy to estimate accurately. Four of the models predict excessively large crack depths. The fifth, however, predicts shallower crack depths that increase with the age of the concrete and are consistent with those of analogous desiccation cracks in coal mine tailings. It thus offers a relatively robust method of estimating the depth of desiccation cracks. Confirmation of this with data for plastic concrete is clearly desirable but not possible at present.
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Software development methodologies are becoming increasingly abstract, progressing from low level assembly and implementation languages such as C and Ada, to component based approaches that can be used to assemble applications using technologies such as JavaBeans and the .NET framework. Meanwhile, model driven approaches emphasise the role of higher level models and notations, and embody a process of automatically deriving lower level representations and concrete software implementations. The relationship between data and software is also evolving. Modern data formats are becoming increasingly standardised, open and empowered in order to support a growing need to share data in both academia and industry. Many contemporary data formats, most notably those based on XML, are self-describing, able to specify valid data structure and content, and can also describe data manipulations and transformations. Furthermore, while applications of the past have made extensive use of data, the runtime behaviour of future applications may be driven by data, as demonstrated by the field of dynamic data driven application systems. The combination of empowered data formats and high level software development methodologies forms the basis of modern game development technologies, which drive software capabilities and runtime behaviour using empowered data formats describing game content. While low level libraries provide optimised runtime execution, content data is used to drive a wide variety of interactive and immersive experiences. This thesis describes the Fluid project, which combines component based software development and game development technologies in order to define novel component technologies for the description of data driven component based applications. The thesis makes explicit contributions to the fields of component based software development and visualisation of spatiotemporal scenes, and also describes potential implications for game development technologies. The thesis also proposes a number of developments in dynamic data driven application systems in order to further empower the role of data in this field.
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This thesis is concerned with the experimental and theoretical investigation into the compression bond of column longitudinal reinforcement in the transference of axial load from a reinforced concrete column to a base. Experimental work includes twelve tests with square twisted bars and twenty four tests with ribbed bars. The effects of bar size, anchorage length in the base, plan area of the base, provision of bae tensile reinforcement, links around the column bars in the base, plan area of column and concrete compressive strength were investigated in the tests. The tests indicated that the strength of the compression anchorage of deformed reinforcing steel in the concrete was primarily dependent on the concrete strength and the resistance to bursting, which may be available within the anchorage . It was shown in the tests without concreted columns that due to a large containment over the bars in the foundation, failure occurred due to the breakdown of bond followed by the slip of the column bars along the anchorage length. The experimental work showed that the bar size , the stress in the bar, the anchorage length, provision of the transverse steel and the concrete compressive strength significantly affect the bond stress at failure. The ultimate bond stress decreases as the anchorage length is increased, while the ultimate bond stress increases with increasing each of the remainder parameters. Tests with concreted columns also indicated that a section of the column contributed to the bond length in the foundation by acting as an extra anchorage length. The theoretical work is based on the Mindlin equation( 3), an analytical method used in conjunction with finite difference calculus. The theory is used to plot the distribution of bond stress in the elastic and the elastic-plastic stage of behaviour. The theory is also used to plot the load-vertical displacement relationship of the column bars in the anchorage length, and also to determine the theoretical failure load of foundation. The theoretical solutions are in good agreement with the experimental results and the distribution of bond stress is shown to be significantly influenced by the bar stiffness factor K. A comparison of the experimental results with the current codes shows that the bond stresses currently used are low and in particular, CPIlO(56) specifies very conservative design bond stresses .
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Three types of crushed rock aggregate were appraised, these being Carboniferous Sandstone, Magnesian Limestone and Jurassic Limestone. A comprehensive aggregate testing programme assessed the properties of these materials. Two series of specimen slabs were cast and power finished using recognised site procedures to assess firstly the influence of these aggregates as the coarse fraction, and secondly as the fine fraction. Each specimen slab was tested at 28 days under three regimes to simulate 2-body abrasion, 3-body abrasion and the effect of water on the abrasion of concrete. The abrasion resistance was measured using a recognised accelerated abrasion testing apparatus employing rotating steel wheels. Relationships between the aggregate and concrete properties and the abrasion resistance have been developed with the following properties being particularly important - Los Angeles Abrasion and grading of the coarse aggregate, hardness of the fine aggregate and water-cement ratio of the concrete. The sole use of cube strength as a measure of abrasion resistance has been shown to be unreliable by this work. A graphical method for predicting the potential abrasion resistance of concrete using various aggregate and concrete properties has been proposed. The effect of varying the proportion of low-grade aggregate in the mix has also been investigated. Possible mechanisms involved during abrasion have been discussed, including localised crushing and failure of the aggregate/paste bond. Aggregates from each of the groups were found to satisfy current specifications for direct finished concrete floors. This work strengthens the case for the increased use of low-grade aggregates in the future.
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Polymer modified cements and mortars have become popular for use as patch repair materials. General evidence suggests that these materials offer considerable improvements compared to traditional mortars although the mechanisms for this are not fully understood. This work elucidates the factors which govern some properties and performance of different polymer systems. In view of the wide range of commercial systems available, investigations concentrated on the use of three of the most commonly available groups of polymers. These were: (1) Styrene Butadiene Rubber (SBR), (2) Acrylics and, (3) Ethylene Vinyl Acetates (EVA). The later two were in the form of both emulsions and redispersible powders. Experiments concentrated on: (1) Rheological behaviour of polymer modified cement pastes; (2) Workability of polymer modified mortars; (3) Influence of curing conditions on the pore size distribution and diffusion of chloride ions; (4) Bond strength of polymer modified cement and mortar patches; and (5) Microscopic examination and semi-quantitative analyses of the bulk and interfacial microstructures. The following main conclusions were reached: (1) The addition of polymer emulsions have a considerable influence on the workability of fresh cement pastes, the extent of this depending on the type of system used. (2) The rheological parameters of fresh polymer modified mortars can be established using a two-point workability test which may be used when comparing the properties of different systems at constant workability. (3) Curing conditions affect the properties of polymer modified systems and a wet/dry curing regime was essential for good adhesion of these materials to mortar substrates. (4) In contrast, the wet/dry curing regime resulted in a curing affected zone at the surface of patch materials. This can result in a much coarser pore structure and enhanced diffusion of e.g. chloride ions. (5) The microstructure of polymer modified systems was very different compared with the unmodified cement/mortar and varied depending on curing conditions.
