This paper analyzes concrete fine aggregate (sand) modification by scrap tire rubber particles-fine crumb rubber (FCR) and coarse crumb rubber (CCR) of fraction 0/1mm. Such rubberized concrete to get better bonding properties were modified by car-boxylated styrene butadiene rubber (SBR) latex and to gain the strength were modified by glass waste. The following tests—slump test, fresh concrete density, fresh concrete air content, compressive strength, flexural strength, fracture energy, freezing-thawing, porosity parameter, and scanning electron microscope—were conducted for rubberized concretes. From experiments, we can see that fresh concrete properties decreased when crumb rubber content has increased. Mostly it is related to crumb rubber (CR) lower specific gravity nature and higher fineness compared with changed fine aggregate-sand. In this research, we obtained a slight loss of compressive strength when CR was used in concrete However, these rubberized concretes with a small amount of rubber provided sufficient compressive strength results (greater than 50 MPa). Due to the pozzolanic reaction, we see that compressive strength results after 56 days in glass powder modified samples increased by 11–13% than 28 days com-pressive strengths, while at the same period control samples increased its compressive strength about 2.5%. Experiments have shown that the flexural strength of rubberized concrete with small amounts of CR increased by 3.4–15.8% compared to control mix, due the fact that rubber is an elastic material and it will absorb high energy and perform positive bending toughness. The test results indicated that CR can intercept the tensile stress in concrete and make the deformation more plastic. Fracturing of such conglomerate concrete is not brittle, there is no abrupt post-peak load drop and gradually continues after the maximum load is exceeded. Such concrete requires much higher fracture energy. It was obtained that FCR particles (lower than A300) will entrap more micropores content than coarse rubbers because due to their high specific area. Freezing-thawing results have confirmed that Kf values can be conveniently used to predict freeze-thaw resistance and durability of concrete. The test has shown that modification of concrete with 10 kg fine rubber waste will lead to similar mechanical and durability properties of concrete as was obtained in control concrete with 2 kg of prefabricated air bubbles.
Every year, colossal amounts of used and non-biodegradable rubber tyres are accumulated in the world. Experience shows that the most efficient way to increase the concrete fracture energy G F (N/m) is to use metal or polypropylene fibres. The optimal content of fibre increases concrete resistance to stress (especially tensile stress under bending force). Concrete fracture is not brittle; concrete continues deforming after maximum stresses and is able to resist certain stresses, there is no abrupt decrease in loading. The research has proved that crumb rubber can be used in concretes as an alternative to metal and polypropylene fibres. The investigation has found that rubber waste additives, through their specific properties can partly take up tensile stresses in concrete and make the concrete fracture more plastic; besides, such concrete requires a significantly higher fracture energy and concrete samples can withstand much higher residual strength at 500 mm crack mouth opening displacement (CMOD) and deflection.
This work presents a study on the influence of thermal-electrical fly ash on the cement paste hydration processes, investigation into cement stone, mortar, ordinary and self-compacting concrete, when cement was replaced by fly ash (533 %). It was estimated that cement stone and cement paste prepared from fly ash and cement properties were better when polycarboxylic superplasticiser Visco Crete-3 was used. It was established that admixture of fly ash influences the processes of cement hydration: the amount of free Ca(OH) 2 in cement stone was decreased and amount of stable calcium hydro silicates was increased. It allows to state, that cement stone becomes more corrosion-resistant and more durable. When fly ash admixture is applied in ordinary concrete production, it is possibility to reduce cement expenditures up to 33 % and in self-compacting concrete production, segregation and separation of water decreases. Data of investigations on hardened concrete showed that fly ash increases compressive strength (up to 15 %), decreases shrinkage strains (up to 31,6 %), increases plastic deformations (up to 38 %), modulus of elasticity (up to 15 %) and modifies other concrete properties.
The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste
The concept of self-healing concrete is becoming more necessary as sustainability in construction is more desirable. Amongst the current solutions in this technology are autogenous, chemical, and bacterial self-healing. It is paramount that secondary raw materials be used in the production of selfhealing concrete as a form of a sustainable solution. Therefore, in this paper, the admixture “Betocrete-CP-360-WP”, which is a crystallizing waterproofing admixture with hydrophobic effect and is 100% recyclable, has been used and its effect on the physical, chemical, and mechanical properties of concrete, as well as selfhealing capabilities of concrete, have been determined. According to the obtained results, the crystalline additive “Betocrete-CP-360-WP” has no effect on density and slightly increases the amount of entrained air in the concrete mix. However, it does decrease the workability of the concrete mixture which could prove problematic in transportation to the construction site or in concreting in general. Also, with the crystalline admixture in the concrete mix, a 60% reduction in concrete compressive strength after one day of hardening has been estimated, but after 7 and 28 days, the strength attained is within the ranges of the control samples. In addition, concrete containing Betocrete-CP360-WP was 30% less water permeable as compared to control samples. The self-healing efficiency of the concrete was determined by a water flow test through a formed crack (approximately 0.35 mm wide). This was done by gluing a plastic pipe to the top of the cracked concrete specimens and maintaining a constant pressure of the water in the pipe. The experiment was continued for 28 days, and the crack self-healing efficiency of the concrete was calculated from the differences in the amount of water passed through the crack before healing and after 7, 14, 21 and 28 days of the healing process. After 28 days of the water flow test, the cracks in the concrete with the crystalline admixture and recycled concrete dust were completely healed, while the control specimens were not.
The objective of these experimental studies is to evaluate (verify) the possibility of applying by-products (0/2 mm fraction dolomite screenings or dolomite powder) obtained in the process of producing crushed dolomite from Petrašiūnai dolomite quarry rocks in concrete technology. A rational application of this material expands the range of concrete mix aggregates and provides an integrated use of dolomite rock by consuming less attractive by-products of dolomite processing. The article discusses the possibilities of using the above introduced dolomite by-products in concrete applications and gives a preliminary assessment of physical, mechanical and technological characteristics of commercial and technological concrete with dolomite screenings. 0/2 mm fraction dolomite screenings from Petrašiūnai dolomite quarry with an average density of 2600 kg/m3, a bulk density of 1690 kg/m3, a bulk porosity of 39.1%, fine particle content (contamination with dust and clay particles) of < 4,9%, a specific surface of 1085 cm2/g determined by Blaine tester were used for experimental study. The physicalcharacteristics of dolomite powder and dolomite screenings additionally crushed in a lab ball mill were similar: an average density of 2600 kg/m3, a bulk density of 1210 kg/m3, a bulk porosity of 53,5% and a specific surface after additional milling of 3030 cm2/g and 4070…4200 cm2/g respectively. Dolomite particles have a rough, conchoidal and porous surface, however, their form is close to cubic or even oval while their edges are less sharp (mechanically grated) compared to granite or other crushed stone screenings. Therefore, dolomite particles bond very well with cement stone and almost do not increase water demand for producing a paste of normal consistency and do not weaken the rheological properties of the mixes. Dolomite screenings or dolomite powder from Petrašiūnai quarry have stable mineral composition, but the XRD patterns of rock provide little information: although dolomite peaks are prevailing, quartz and feldspar peaks can also be noticeable. Moreover, ferrous minerals (pyrite, limonite) are present in dolomite, nevertheless, so few particles of these impurities are so small (< 0.2 mm in diameter) that they pose no risk of the potential destruction of concrete. Energy consumption of crushing dolomite screenings to reach the fineness of cement particles is much lower compared to crushing granite screenings. The crushed granite screenings are 1.5–2 times finer compared to the fineness of dolomite screenings crushed for the same time. Besides, the fineness of carbonate rock powder can be easily adjusted by changing crushing time. Therefore, dolomite screenings is a very perspective raw material for producing concrete micro-aggregates. No pozzolanic behaviour of dolomite screenings and dolomite powder during the short-term curing of cement stone or concrete under normal (room) temperature conditions were observed, and therefore a rational application of these mineral admixtures in conventional concretes would be only as substitutes for fine aggregate (sand) and only partly for cement. Most probably, dolomite powder can behave as a weak pozzolanic admixture at higher temperatures (above 50 oC); however more detailed studies are required to prove this supposition. The powdered dolomite admixture does not increase water demand for obtaining the paste of normal consistency but improves the structure of cement stone pores and frost resistance. The crushed dolomite screenings reduce the compressive and bending strength of concrete cured under ordinary temperature conditions; however, a small content of these admixtures (up to 15 ÷ 20 per cent of cement mass) can be recommended for self-compacting concrete and other fine-grained concrete mixes because the deterioration of the mechanical characteristics of cement stone is insignificant, i.e. about 10 ÷ 12 per cent. Dolomite screenings substituting for sand (or a part of sand) in conventional Portland cement concrete improve the granular composition of the mix, increase the content of fine (0.063 ÷ 0.25 mm) fractions and grow in the compressive strength of such concrete by 12 per cent. Such concrete has a better structure dominated by closed pores. Therefore, fine aggregate from dolomite screenings (or with them) is recommended for Portland cement mixes or cement grouts.
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