scholarly journals Microstructure of concrete prepared with construction recycled aggregates

2013 ◽  
Vol 19 (S4) ◽  
pp. 147-148 ◽  
Author(s):  
L. Evangelista ◽  
M. Guedes ◽  
A.C. Ferro ◽  
J. de Brito
Keyword(s):  
Mechanical Properties ◽  
Portland Cement ◽  
Recycled Aggregates ◽  
Hydration Products ◽  
Normal Strength Concrete ◽  
Structural Concrete ◽  
Strength Concrete ◽  
Natural Aggregate ◽  
Natural Aggregates ◽  
Normal Strength

Conservation of natural resources, shortage of waste land and the high cost associated to treatment prior to disposal are driving growing interest in the recycling of construction and demolition waste materials (CDW). A challenging application for recycled CDW is the replacement of natural aggregates in the production of structural concrete. In the past few years several studies have examined the viability of this substitution. Although recycled aggregates are mostly heterogeneous, less dense and more porous than natural aggregates, satisfactory results have been attained by several authors regarding concrete workability, mechanical properties and durability. However, a systematic microstructural characterization of recycled aggregate concrete is still unaccomplished.In this context, the use of fine recycled concrete aggregates to replace natural fine aggregates in the production of structural concrete was tested, and attained microstructures are reported. The recycled aggregates were obtained from a standard concrete, produced and crushed under laboratorial conditions, thus allowing full control of concrete’s composition and setting. The used raw materials were natural aggregate (sand), recycled aggregates and Type 1 Portland cement. The substitution extent in the mixtures was 0, 10, 50 and 100 wt%; hydration was stopped at the ages of 9 h, 24 h, 96 h and 28 days. Microscopy study of the different mixtures enlightened the effect of the incorporation of recycled aggregates upon the formation and morphology of the different concrete hydration products. In this work, FEG-SEM (coupled with EDS microanalysis) was used on polished cross sections and fracture surfaces, to study the new mixtures. Focus was placed on the interfacial transition zone (ITZ) between cement matrix and aggregate.The natural aggregate-cement interfacial zone exhibits typical microstructural features of the ITZ of a normal strength concrete. After 28 days a large amount of well-crystallised C-S-H (and a small amount of poorly crystalline fibres) is present at the interface, together with CH deposits. Grains of unreacted clinker components (C2S, C3S, Ca2(Al,Fe), C3A) were also identified; ettringite crystals are barely present, even at the earlier hydration times. The ITZ is highly porous. Independently of the setting time, fracture takes place preferably along the surface between paste and aggregate, attesting the relatively loose nature of the interface. The structure of ITZ with recycled aggregates (Figure 1) is consistent with that observed in the reference natural concrete. Also, calculation based on EDS results rendered a lime to silica ratio (C/S) of 1.46 0.15, consistent with the typical 1.2-2.3 range. However, there are representative microstructural features that may contribute to variation of mechanical properties. Ettringite and plate-like CH hydrates are much more abundant, even at higher setting times. Overall porosity in the ITZ increases with the aggregate substitution extent; however maximum pore size decreases from approximately 30 µm for 0% substitution to 16 µm for 100 % substitution, as shown by image analysis results. In fresh natural concrete a water film forms around the aggregates, which is gradually replaced by the growing amount of hydration products. In recycled aggregates, active silica in residual cementitious materials reacts with the fresh cement hydration products. The secondary reaction products gradually fill the region, partially covering the recycled aggregates pore structure and creating additional interfacial bonding effects (Figure 2). In good agreement, it was observed that in substituted concretes fracture preferably takes place throughout the paste rather than throughout the contact surface.Concretes prepared with recycled aggregates exhibit typical microstructural features of the ITZ in normal strength concrete. Although porosity at the ITZ is affected by the extent of aggregate replacement, the interfacial bond is apparently stronger when recycled aggregates are used. This envisages an opportunity window for the development of increased strength Portland cement concretes.

Superplasticizer for High Strength Concrete

2015 ◽  
Vol 1768 ◽  
Author(s):  
Luis E. Rendon Diaz Miron ◽  
Maria E. Lara Magaña
Keyword(s):  
Compressive Strength ◽  
Portland Cement ◽  
High Strength Concrete ◽  
High Strength ◽  
Mineral Admixtures ◽  
Normal Strength Concrete ◽  
Strength Concrete ◽  
Normal Strength ◽  
Ready Mixed Concrete ◽  
Mixed Concrete

ABSTRACTIn the early 1970s, experts predicted that the practical limit of ready-mixed concrete would be unlikely to exceed a compressive strength greater than 90 MPa [1]. Over the past two decades, the development of high-strength concrete has enabled builders to easily meet and surpass this estimate. The primary difference between high-strength concrete and normal-strength concrete relates to the compressive strength that refers to the maximum resistance of a concrete sample to applied pressure. Although there is no precise point of separation between high-strength concrete and normal-strength concrete, the American Concrete Institute defines high-strength concrete as concrete with a compressive strength greater than 45 MPa. Manufacture of high-strength concrete involves making optimal use of the basic ingredients that constitute normal-strength concrete. When selecting aggregates to obtain high-strength concrete, we consider strength, optimum size distribution, surface characteristics and a good bonding with the cement paste that affect compressive strength. Selecting a high-quality Portland cement and optimizing the combination of materials by varying the proportions of cement, water, aggregates, and admixtures is also necessary. Any of these properties could limit the ultimate strength of high-strength concrete. Pozzolans, such as fly ash and silica fume along with silicic acid, are the most commonly used mineral admixtures in high-strength concrete. These materials impart additional strength to the concrete by reacting with Portland cement hydration products to create additional Calcium Silicate Hydrate (CSH) gel, the part of the paste responsible for concrete strength; finally the most important admixture is polycarboxylate ether as super plasticizer. It would be difficult to produce high-strength ready-mixed concrete without using chemical admixtures. In this paper we study the use of high performance concrete (HPC) to obtain very narrow strong pre-fabricated elements for water conducting channels.

scholarly journals Recycled Concrete Aggregates and Their Influences on Performances of Low and Normal Strength Concretes

Buildings ◽  
2020 ◽  
Vol 10 (9) ◽  
pp. 167
Author(s):  
Mohammed Seddik Meddah ◽  
Ali Al-Harthy ◽  
Mohamed A. Ismail
Keyword(s):  
Mechanical Properties ◽  
Compressive Strength ◽  
Portland Cement ◽  
Recycled Concrete ◽  
Construction And Demolition Waste ◽  
Recycled Materials ◽  
Concrete Aggregates ◽  
Recycled Concrete Aggregates ◽  
Natural Aggregates ◽  
Normal Strength

Recycled materials are now widely used in various industrial sectors to enhance sustainability and reduce environmental charges. Using recycled aggregates in concrete production significantly lowers demand for natural aggregates and the amount of solid waste sent to landfills. This paper summarizes the main results of a study undertaken to design low and normal strength concrete with various replacement ratios of coarse recycled concrete aggregates (RCA). To persuade the concrete industry to use recycled materials as one of the main components of concrete produced, the overall mechanical and durability performances of the RCA-concrete should be close or even similar to the concrete made with natural ingredients. The present research adopted an approach that consists of designing a series of low and normal strength with RCA having an equal target 28-day design strength to the corresponding natural aggregates concrete but while varying the water–cement ratios (w/c). Coarse recycled concrete aggregates, obtained by crushing waste concrete debris collected from different construction and demolition waste sources, were used in three different proportions of 30%, 50% and 100% (by weight) to produce new concrete with various w/c ratios and different compressive strength grades. Concrete mixes produced with general use Portland cement and various RCA contents were investigated in terms of their key mechanical and durability performances. The mechanical properties (crushing value) of the used RCA were visibly lower than the natural coarse aggregates (NCA). Thus, RCA-concrete showed lower performance than the NCA-concrete. It was found that by using up to 30% coarse RCA, the mechanical properties of concrete were not significantly affected. Beyond 30% of partial replacement of NCA by the coarse RCA, a continuing decrease in the mechanical performance with an increase in RCA amount was found. However, reducing the w/c ratio of concrete designed with the coarse RCA resulted in a compressive strength improvement, a better resistance to sulphate attack, carbonation, and chloride ion penetrations. Additionally, a proper design of Portland cement concrete produced with various proportions of RCA could also contribute to promoting sustainability in the construction industry and lowering its environmental impact.

Mechanical Properties and Durability of Bonded-Concrete Overlays and Ultrathin Whitetopping Concrete

2003 ◽  
Vol 1834 (1) ◽  
pp. 16-23 ◽  
Author(s):  
Norbert Delatte ◽  
Anshuman Sehdev
Keyword(s):  
Mechanical Properties ◽  
High Strength Concrete ◽  
High Strength ◽  
Fiber Reinforced Concrete ◽  
Normal Strength Concrete ◽  
Traffic Loading ◽  
Strength Concrete ◽  
Concrete Overlays ◽  
Normal Strength ◽  
Strength And Stiffness

Concrete overlays have been used for pavement and bridge-deck rehabilitation for many years. The mechanical properties and durability of several plain and fiber-reinforced concrete-overlay mixes were analyzed. Eight different concrete-overlay mix designs were investigated. The materials properties investigated were compressive and splitting tensile strength, modulus of elasticity, bond to concrete (with three different surface roughness characteristics), and durability. Freeze-thaw tests were performed to determine the durability of the concrete mixtures used. Strength and stiffness were investigated from 1, 3, 7, and 14 days. Laboratory tests on the strength and stiffness development of eight candidate concrete-overlay designs showed that high-strength concrete was appropriate for opening overlays to traffic in 24 h or less, but normal-strength concrete may be used if traffic loading may be delayed for 48 or 72 h. For larger projects, where paving continues over several days, normal-strength mixtures may be used when 48 to 72 h or more of curing can be achieved before traffic loading begins, with high-strength mixtures used for the last day's construction. All the high-strength concrete overlay-mixture designs tested appear to have satisfactory strength, stiffness, bond properties, and durability for use in bonded overlay construction. The normal-strength concrete is more economical than the high-strength concrete but develops its design properties more slowly.

scholarly journals INFLUÊNCIA DE AGREGADOS RECICLADOS DE RESÍDUOS DE CONSTRUÇÃO EM PROPRIEDADES MECÂNICAS DO CONCRETO (doi:10.5216/reec.V11i1.35467)

2016 ◽  
Vol 11 (1) ◽  
Author(s):  
Daniel Lima Araújo ◽  
Ludmylla Pires Felix ◽  
Leonardo Costa Silva ◽  
Thiago Martins Santos
Keyword(s):  
Mechanical Properties ◽  
Compressive Strength ◽  
Modulus Of Elasticity ◽  
Recycled Aggregates ◽  
Environmental Standards ◽  
Material Loss ◽  
Construction Waste ◽  
Final Destination ◽  
Natural Aggregate ◽  
Natural Aggregates

RESUMO: É notório o desperdício de materiais na construção civil, o que resulta na geração de resíduos de construção. Com a normalização ambiental recente, não se pode mais descartar esses resíduos de forma indiscriminada, porém deve-se dar aos mesmos uma destinação final adequada ou, sempre que possível, buscar a sua reutilização. Em grande parte, o resíduo gerado na indústria da construção civil é formado por concreto e argamassa, denominados de resíduos “cinzas”. Assim, este trabalho tem como objetivo analisar a substituição dos agregados graúdos naturais por agregados graúdos oriundos da reciclagem de resíduos “cinzas” da construção. Para isso, foram analisados traços de concreto contendo vários níveis de substituição (0%, 19%, 43%, 75%, 100%) do agregado natural pelo agregado reciclado. Foi verificada a influência dos agregados reciclados em algumas propriedades do concreto nos estados fresco e endurecido, com destaque para a resistência à compressão e o módulo de elasticidade. Os resultados mostraram ser possível a substituição de até 100% do agregado natural pelo agregado reciclado sem prejuízo da resistência mecânica do concreto e com redução de apenas 12% no módulo de elasticidade, o que indica a possibilidade do mesmo ser utilizado na produção de concretos com fins estruturais. ABSTRACT: The material loss in civil construction is large, which results in a great amount of construction waste. The latest environmental standards in Brazil do not allow that wastes are indiscriminately disposed of, and it is necessary to ensure their adequate final destination or, whenever possible, their reuse. The greater amount of construction waste is made up of concrete and mortar, called “grey waste”. The aim of this paper is analyze the replacement of natural aggregates with coarse recycled aggregates from grey construction waste. Several concrete mixes were produced with various substitution percentages (0%, 19%, 43%, 75%, 100%) of natural aggregates with coarse recycled aggregates to evaluate the influence of this substitution on the fresh and mechanical properties of the concrete. The most important mechanical properties analyzed are the compressive strength and modulus of elasticity. The results show that it is possible to replace up to 100% of the natural aggregate with recycled aggregates without reducing the compressive strength. In this case, the modulus of elasticity is reduced by only 12%. This suggests that recycled aggregates can be used in the production of structural concretes.

Behavior of Densified Normal Strength Concrete under Elevated Temperature

2009 ◽  
Vol 405-406 ◽  
pp. 405-408 ◽  
Author(s):  
Bo Ming Zhao ◽  
Gai Fei Peng ◽  
Ting Yu Hao
Keyword(s):  
Mechanical Properties ◽  
High Temperature ◽  
Fire Resistance ◽  
High Strength Concrete ◽  
High Strength ◽  
Polymer Fiber ◽  
Normal Strength Concrete ◽  
Strength Concrete ◽  
Normal Strength ◽  
Spalling Test

This paper presents an experimental investigation on fire resistance of densified normal strength concrete (DNSC), at water/binder (W/B) ratios of 0.45, 0.36, and 0.32, of which compressive strength of 28-days ranged from 42.5 MPa to 56.3 MPa. The results of the spalling test reveal that DNSC encountered explosive under high temperature. Polymer fiber can be used to improve fire resistance of DNSC. DNSC subjected to high temperature lost its mechanical properties in a similar manner to that of high-strength concrete.

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