Your search keyword '"Augonis, Algirdas"' showing total 10 results

1. Mechanical properties and durability of rubberized and SBR latex modified rubberized concrete

Author

Grinys, Audrius, Augonis, Algirdas, Daukšys, Mindaugas, and Pupeikis, Darius

Published

2020

2. The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste

Author

Manhanga Fallon Clare, Rudžionis Žymantas, Ivanauskas Ernestas, and Augonis Algirdas

Subjects

concrete, self-healing, crystalline, admixture, crack, Engineering (General). Civil engineering (General), TA1-2040

Abstract

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.

Published

2022

3. Influence of carbonated bottom slag granules in 3D concrete printing

Author

Butkute, Karolina, Vaitkevicius, Vitoldas, Sinka, Maris, Augonis, Algirdas, Korjakins, Aleksandrs, and MDPI AG (Basel, Switzerland)

Subjects

burnt fly ash, CO2 reduction, bottom slag, 3D printing, artificial aggregate

Abstract

This study investigates the possibility of utilising bottom slag (BS) waste from landfills, and a carbonation process advantageous for the use of artificial aggregates (AAs) in printed three-dimensional (3D) concrete composites. In general, the main idea of granulated aggregates is to reduce the amount of CO2 emissions of printed 3D concrete objects (wall). AAs are made from construction materials, both granulated and carbonated. Granules are made from a combination of binder (ordinary Portland cement (OPC), hydrated lime, burnt shale ash (BSA)) and waste material (BS). BS is a waste material left over after the municipal waste burning process in cogeneration power plants. Whole printed 3D concrete composite manufacturing consists of: granulating artificial aggregate, aggregate hardening and sieving (adaptive granulometer), carbonation of AA, mixing 3D concrete, and 3D printing. The granulating and printing processes were analysed for hardening processes, strength results, workability parameters, and physical and mechanical properties. Printings with no granules (reference 3D printed concrete) were compared to 3D printed concretes with 25% and 50% of their natural aggregate replaced with carbonated AA. The results showed that, theoretically, the carbonation process could help to react approximately 126 kg/m3 CO2 from 1 m3 of granules.

Published

2023

4. The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste

Author

Manhanga, Fallon Clare, Rudžionis, Žymantas, Ivanauskas, Ernestas, and Augonis, Algirdas

Subjects

crack, concrete, self-healing, admixture, crystalline, General Medicine

Abstract

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.

Published

2022

5. The investigations on properties of self-healing concrete with crystalline admixture and recycled concrete waste.

Author

Alexander, M.G., Beushausen, H., Dehn, F., Ndawula, J., Moyo, P., Manhanga, Fallon Clare, Rudžionis, Žymantas, Ivanauskas, Ernestas, and Augonis, Algirdas

Published

2022

6. Effect of milled electrical cable waste on mechanical properties of concrete.

Author

Grinys, Audrius, Vaičiukynienė, Danutė, Augonis, Algirdas, Sivilevičius, Henrikas, and Bistrickaitė, Rėda

Subjects

ELECTRIC cables, MILLING (Metalwork), CONCRETE, MECHANICAL behavior of materials, FRACTURE mechanics, MICROSTRUCTURE, COMPRESSIVE strength

Abstract

The article focuses on investigation of mechanical and fracture properties of concrete containing electrical cable waste as well as some microstructural features of such concrete. Added to concrete, electrical cable waste reduces the overall concrete bulk density. Compressive, flexural, tensile splitting strengths and elastic modulus decreased when electrical cable waste was admixed to conventional and polymer modified concretes. The best mechanical properties of concrete samples containing electrical cable waste were identified in polymer modified concrete containing 5% of electrical cable waste. Electrical cable waste particles increase the deformability of polymer modified concretes and have almost no influence on normal concrete. Consequently, the optimal amount of electrical cable waste particles can provide concrete with desirable strength that is required for different applications. [ABSTRACT FROM AUTHOR]

Published

2015

7. The Influence of Expanded Glass and Expanded Clay on Lightweight Aggregate Shotcrete Properties.

Author

Augonis, Algirdas, Ivanauskas, Ernestas, Bocullo, Vytautas, Kantautas, Aras, and Vaičiukynienė, Danutė

Subjects

*LIGHTWEIGHT concrete, *SHOTCRETE, *THERMAL conductivity measurement, *FLEXURAL strength testing, *THERMAL conductivity, *GLASS waste

Abstract

In the construction industry, the selection of sustainable materials leads to a movement towards more sustainable construction. In this study, lightweight aggregate shotcrete based on expanded glass (EG) and expanded clay (EC) is investigated. The goal of the study is to determine the influence of EG and EC inclusion on the properties of shotcrete. Ordinary Portland cement (OPC) powder with supplementary cementitious materials, such as silica fume and ground glass waste, are used as binders. The mechanical, physical and morphological properties, as well as the mineral and oxygen compositions, are obtained through compressive and flexural strength tests, thermal conductivity measurements, scanning electron microscopy with energy dispersive X-ray spectrometry (SEM–EDX), X-ray diffraction (XRD) and X-ray fluorescence (XRF) analysis. In this study, the mechanical, physical and thermal properties and waste utilization as cement supplementary materials are balanced. The shotcrete samples show that a density of 790 kg/m3 had a good thermal performance (thermal conductivity coefficient of 0.174 W/(m·K)) with the sufficient compressive strength of 6.26 MPa. [ABSTRACT FROM AUTHOR]

Published

2022

8. Mechanical Properties and Durability of Rubberized and Glass Powder Modified Rubberized Concrete for Whitetopping Structures.

Author

Grinys, Audrius, Balamurugan, Muthaiah, Augonis, Algirdas, Ivanauskas, Ernestas, and Stöckelhuber, Klaus Werner

Subjects

POWDERED glass, CRUMB rubber, RUBBER waste, CONCRETE durability, GLASS waste, WASTE tires

Abstract

This paper analyzes concrete fine aggregate (sand) modification by scrap tire rubber particles-fine crumb rubber (FCR) and coarse crumb rubber (CCR) of fraction 0/1 mm. 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. [ABSTRACT FROM AUTHOR]

Published

2021

9. Evaluation of Methodologies for Assessing Self-Healing Performance of Concrete with Mineral Expansive Agents: An Interlaboratory Study.

Author

Litina, Chrysoula, Bumanis, Girts, Anglani, Giovanni, Dudek, Marta, Maddalena, Riccardo, Amenta, Maria, Papaioannou, Stamatoula, Pérez, Gloria, García Calvo, José Luis, Asensio, Eloy, Beltrán Cobos, Rubén, Tavares Pinto, Fabiano, Augonis, Algirdas, Davies, Robert, Guerrero, Ana, Sánchez Moreno, Mercedes, Stryszewska, Teresa, Karatasios, Ioannis, Tulliani, Jean-Marc, and Antonaci, Paola

Subjects

SELF-healing materials, EVALUATION methodology, CONCRETE, MINERALS, POTENTIAL flow, HEALING, WATER testing

Abstract

Self-healing concrete has the potential to optimise traditional design approaches; however, commercial uptake requires the ability to harmonize against standardized frameworks. Within EU SARCOS COST Action, different interlaboratory tests were executed on different self-healing techniques. This paper reports on the evaluation of the effectiveness of proposed experimental methodologies suited for self-healing concrete with expansive mineral additions. Concrete prisms and discs with MgO-based healing agents were produced and precracked. Water absorption and water flow tests were executed over a healing period spanning 6 months to assess the sealing efficiency, and the crack width reduction with time was monitored. High variability was reported for both reference (REF) and healing-addition (ADD) series affecting the reproducibility of cracking. However, within each lab, the crack width creation was repeatable. ADD reported larger crack widths. The latter influenced the observed healing making direct comparisons across labs prone to errors. Water absorption tests highlighted were susceptible to application errors. Concurrently, the potential of water flow tests as a facile method for assessment of healing performance was shown across all labs. Overall, the importance of repeatability and reproducibility of testing methods is highlighted in providing a sound basis for incorporation of self-healing concepts in practical applications. [ABSTRACT FROM AUTHOR]

Published

2021

10. Physical and mechanical investigations of self-healing concrete after healed cracks

Author

Saleh, Monzer and Augonis, Algirdas

Subjects

savaiminis betono atsinaujinimas, kristaliniai priedai, flexural strength, crystalline additives, self-healing, bakterijos, bacteria, compressive strength, lenkimo stipris, gniuždymo stipris

Abstract

Concrete is a vital building material that is an absolutely essential component of public infrastructure and most buildings. Macro and micro cracks form a serious threat on concrete strength therefore on construction lifetime. Due water penetration and humidity that seek through this crack to steel reinforcement and cause its corrosion. To handle this threat a major important is given nowadays to improve resistance of concrete for this micro and macro crack by adding crystalline additives or bacteria to concrete mixture that can self-heal these concrete cracks. In our work are studying the influent of crystalline additives on physical and mechanical properties of concrete, also the effect of healing using pipe method, strength recovery, limit of healing process and the dimension of crack that could be healed in the presence of this additives., Betonas yra labai svarbi statybinė medžiaga, kuri yra esminė viešosios infrastruktūros ir daugumos pastatų dalis. Vis dėl to, mikro ir makro įtrūkimai betone kelia rimtą grėsmę jo stiprumui ir ilgaamžiškumui. Taip atsitinka dėl vandens ir drėgmės prasiskverbimo per plyšius, kas gali sukelti armatūros koroziją. Siekiant preventyviai kovoti su šitomis betono problemomis, šiais laikais galima padidinti betono atsparumą dėl mikro ir makro pleišėjimo, į jo mišinio sudėtį pridedant kristalinių priedų arba bakterijų, kas leidžia savaime užtaisyti betono plyšius. Šiame darbe yra tyrinėjama kristalinių priedų įtaka betono fizikinėms ir mechaninėms savybėms, taip pat betono savaiminio atsinaujinimo efektas naudojant vamzdžių metodą, stiprumo atsinaujinimas, savaiminio užsitaisymo galimybių ribos ir plyšių dydžiai, kurie gali užsitaisyti dėl šių priedų.

Published

2019