Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates
Quartz sandstone (QS) is a mine waste; therefore, its use in construction allows for both reducing the cost of the concrete and contributing to the utilization of waste. The scientific originality of this study is the identification of models of the effect of QS aggregate on the physicomechanical, d...
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doaj-771b4997b60144a48977d401fdb02bef2020-12-08T00:04:52ZengMDPI AGMaterials1996-19442020-12-01135575557510.3390/ma13235575Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste AggregatesAleksandr Tolstoy0Valery Lesovik1Roman Fediuk2Mugahed Amran3Murali Gunasekaran4Nikolai Vatin5Yuriy Vasilev6Department of Building Materials Science, Products and Structures, Belgorod State Technological University named after V.G.Shoukhov, 46 Kostiukova Str., 308012 Belgorod, RussiaDepartment of Building Materials Science, Products and Structures, Belgorod State Technological University named after V.G.Shoukhov, 46 Kostiukova Str., 308012 Belgorod, RussiaPolytechnic Institute, Far Eastern Federal University, 690922 Vladivostok, RussiaDepartment of Civil Engineering, College of Engineering, Prince Sattam Bin Abdulaziz University, Alkharj 11942, Saudi ArabiaSchool of Civil Engineering, SASTRA Deemed to be University, Thanjavur 613404, IndiaHigher School of Industrial, Civil and Road Construction, Peter the Great St. Petersburg Polytechnic University, 195251 St. Petersburg, RussiaDepartment of Road-Building Materials, Moscow Automobile and Road Construction University, 125319 Moscow, RussiaQuartz sandstone (QS) is a mine waste; therefore, its use in construction allows for both reducing the cost of the concrete and contributing to the utilization of waste. The scientific originality of this study is the identification of models of the effect of QS aggregate on the physicomechanical, durability characteristics, and eco-safety of greener high-strength concrete. The study used an energy-efficient method of non-thermal effects of electromagnetic pulses on the destruction mechanisms of quartz-containing raw materials. The characteristics of quartzite sandstone aggregates, including the natural activity of radionuclides, were comprehensively studied. The features of concrete hardening, including the formation of an interfacial transition zone between the aggregate and the cement matrix, were studied, taking into account the chemical and morphological features of quartzite sandstone. In addition, the microstructural and morphological properties of concrete were determined after a 28 day curing. In this study, the behaviors of the concrete with QS aggregate were investigated, bearing in mind the provisions of geomimetics science on the affinity of structures. The results obtained showed that the QS aggregate had the activity of natural radionuclides 3–4 times lower compared to traditional aggregates. Efficient greener concrete with a 46.3 MPa compressive strength, water permeability grade W14, and freeze–thaw resistance of 300 cycles were also obtained, demonstrating that the performance of this greener concrete was comparable to that of traditional concrete with more expensive granite or gabbro diabase aggregates.https://www.mdpi.com/1996-1944/13/23/5575greener high-strength concretequartz sandstonemine wasteaggregatecompressive strengthfreeze–thaw resistance |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Aleksandr Tolstoy Valery Lesovik Roman Fediuk Mugahed Amran Murali Gunasekaran Nikolai Vatin Yuriy Vasilev |
spellingShingle |
Aleksandr Tolstoy Valery Lesovik Roman Fediuk Mugahed Amran Murali Gunasekaran Nikolai Vatin Yuriy Vasilev Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates Materials greener high-strength concrete quartz sandstone mine waste aggregate compressive strength freeze–thaw resistance |
author_facet |
Aleksandr Tolstoy Valery Lesovik Roman Fediuk Mugahed Amran Murali Gunasekaran Nikolai Vatin Yuriy Vasilev |
author_sort |
Aleksandr Tolstoy |
title |
Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates |
title_short |
Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates |
title_full |
Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates |
title_fullStr |
Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates |
title_full_unstemmed |
Production of Greener High-Strength Concrete Using Russian Quartz Sandstone Mine Waste Aggregates |
title_sort |
production of greener high-strength concrete using russian quartz sandstone mine waste aggregates |
publisher |
MDPI AG |
series |
Materials |
issn |
1996-1944 |
publishDate |
2020-12-01 |
description |
Quartz sandstone (QS) is a mine waste; therefore, its use in construction allows for both reducing the cost of the concrete and contributing to the utilization of waste. The scientific originality of this study is the identification of models of the effect of QS aggregate on the physicomechanical, durability characteristics, and eco-safety of greener high-strength concrete. The study used an energy-efficient method of non-thermal effects of electromagnetic pulses on the destruction mechanisms of quartz-containing raw materials. The characteristics of quartzite sandstone aggregates, including the natural activity of radionuclides, were comprehensively studied. The features of concrete hardening, including the formation of an interfacial transition zone between the aggregate and the cement matrix, were studied, taking into account the chemical and morphological features of quartzite sandstone. In addition, the microstructural and morphological properties of concrete were determined after a 28 day curing. In this study, the behaviors of the concrete with QS aggregate were investigated, bearing in mind the provisions of geomimetics science on the affinity of structures. The results obtained showed that the QS aggregate had the activity of natural radionuclides 3–4 times lower compared to traditional aggregates. Efficient greener concrete with a 46.3 MPa compressive strength, water permeability grade W14, and freeze–thaw resistance of 300 cycles were also obtained, demonstrating that the performance of this greener concrete was comparable to that of traditional concrete with more expensive granite or gabbro diabase aggregates. |
topic |
greener high-strength concrete quartz sandstone mine waste aggregate compressive strength freeze–thaw resistance |
url |
https://www.mdpi.com/1996-1944/13/23/5575 |
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