Your search keyword '"CONCRETE additives"' showing total 2,039 results

1. An investigation into the strength development of cement concrete blended with hypo sludge ash.

Author

Ingale, Sujata and Nemade, Pravin

Subjects

*CONCRETE, *WASTE paper, *LIME (Minerals), *CONCRETE mixing, *MAGNESIUM oxide, *CONCRETE additives, *CEMENT admixtures

Abstract

The study aims to produce concrete using various percentages of hypo-sludge ash (HAS) in place of cement. The waste paper sludge ash is composed of magnesium oxide and calcium oxide. Therefore, it can be tested as an innovative cement replacement, providing a solution for traditional concrete. For this study, the various proportions of ash used are 5%, 10%, and 15% by weight of cement. The mixed design carried out was as per the Indian standard code. The ingredients used for concrete making are cement, aggregates, hypo sludge ash (HSA), superplasticizer, and water. A test mix was carried out to check the behaviour of a concrete mix, and its physical and hardening properties were checked. Cube samples were cured for 3, 7, 14, and 28 days to check hardening properties. Experimental analysis shows that by replacing 5% cement with HSA, the strength results obtained are close to the reference concrete. [ABSTRACT FROM AUTHOR]

Published

2024

2. Influence of silica-containing additives on structure formation of composite cement binder for non-autoclaved aerated concrete.

Author

Tsoy, Vladimir, Abdullaeva, Djamilya, and Mukhammadiyev, Ne'matjon

Subjects

*CEMENT composites, *AIR-entrained concrete, *COMPOSITE structures, *SILICA fume, *CONCRETE additives, *CEMENT, *ADDITIVES

Abstract

The article presents the results on the effect of silica-containing fillers on the structure formation of a composite cement binder. Obtaining the results makes it possible to use, the use of active fillers in cement sources makes it possible to reduce the part of the binder without loss of density, which is the result of using the resource of energy-saving research technology in the field of building material. [ABSTRACT FROM AUTHOR]

Published

2024

3. Improve asphalt concrete's physical and mechanical characteristics.

Author

Ablakulov, A., Abdullaev, Kh., and Jamolov, S.

Subjects

*ASPHALT concrete, *ASPHALT, *ASPHALT modifiers, *CONCRETE additives

Abstract

There are several methods to raise the asphalt concrete's quality. In this article, the topic of adding surface-active additives to asphalt concrete to strengthen its physical and mechanical qualities is covered (SAA). The employed addition enhances the asphalt concrete's physical, mechanical, and serviceability characteristics. [ABSTRACT FROM AUTHOR]

Published

2024

4. Characterization of high-quality concrete using fly ash and silica fume slag materials from boiler ash.

Author

Amin, Muhammad, Jaya, Fery Hendi, Hendronursito, Yusup, Birawida, David Candra, Sumardi, Slamet, Muttaqii, Muhammad Al, Prasetyo, Erik, Dewi, Sari Utama, and Rinovian, Asnan

Subjects

*FLY ash, *SILICA fume, *CONCRETE additives, *HIGH strength concrete, *CONCRETE, *COMBUSTION products, *SLAG, *PORTLAND cement

Abstract

High strength concrete is currently a very important part in construction, namely construction that has very high strength. The strength of concrete depends on the material used and its size. The size of the concrete constituent materials affects the porosity of the resulting concrete because porosity affects the strength of the concrete. For this reason, efforts are made to use concrete constituent materials that can reduce porosity in concrete. Various materials can be used as additives to give concrete high strength. Among these materials are fly ash and silica fume. Fly ash is a product of coal combustion and functions as a substitute for pozzolanic materials in cement as much as 0, 5, 7.5, 10, 12.5, 15, and 17.5% because it has a very fine grain size < 350 mesh and silica fume ash, which functions as a substitute for fine aggregate 0, 10, 15, 20, 25, 30, and 35% which comes from the ashes of burning refined palm shells with a size < 350 mesh. Materials were prepared, namely: cement, fine aggregate, coarse aggregate, fly ash, silica fume, and weighing water. All the ingredients were stirred until homogeneous and put into a cube-shaped mold measuring 150 x 150 x 150 mm while compaction was carried out using an iron stick, then the mold was left for 24 hours, removed from the mold then soaked in water and soaked in water for 28 days. The compressive strength test and characterization of XRF and XRD and SEM were carried out. Based on the research as outlined in the graph, the maximum compressive strength of substitution of 12.5% fly ash into cement is 45.20 MPa, while the substitution of silica smoke from boiler slag into fine aggregate has a maximum compressive strength of 25% of 50.84 MPa. The results of the XRF characterization of high strength concrete showed that the dominant compounds were 54.60% CaO, and 32.50% SiO2, followed by other compounds. The results of the XRD test showed that the phases formed were calcite (Ca), quartz (SiO2), and anorthite (CaAl2Si2O8) and the distribution of C-S-H was fairly even in the concrete. Thus, fly ash and burning ash of palm shells can affect the compressive strength of concrete for the better, namely the strength increases higher than normal concrete. [ABSTRACT FROM AUTHOR]

Published

2024

5. The effect of different heat curing methods on the compressive strength of fly ash-based geopolymer concrete.

Author

Ujianto, Muhammad, Majid, Masni A., Pambudi, Rilo, Rofiq, Muhammad Ali, Nurchasanah, Yenny, and Solikin, Mochamad

Subjects

*POLYMER-impregnated concrete, *CONCRETE additives, *COMPRESSIVE strength, *CONCRETE curing, *CURING, *FLY ash, *CONCRETE

Abstract

Geopolymer concrete is produced without cement, the main material used is fly ash. The alkaline activator solutions used are sodium hydroxide (NaOH) and sodium silicate Na2SiO3. To make geopolymer concrete having a compressive strength according to the plan, one thing that needs to be done is curing. This study examines the effect of the curing method on fly ash-based geopolymer concrete. Three curing methods, namely conventional, heat curing, and steam curing, were used to determine the effect of temperature differences on the compressive strength of geopolymer concrete. Cylindrical specimens used 12 M NaOH, Na2SiO3, water, and fly ash in a ratio of 3:1:6:25. The compressive strength of the concrete was tested on the specimens after 28 days. The results showed that there was an increase in the compressive strength of concrete in heat curing and steam curing at temperatures of 50°, 60°, and 70°C by 8-21% for heat curing and 2-4% for steam curing. [ABSTRACT FROM AUTHOR]

Published

2024

6. The utilization of calcium oxide on durability performance of high-volume fly ash concrete.

Author

Solikin, Mochamad and Mahmudi, Zulhan Rasyid

Subjects

*FLY ash, *LIME (Minerals), *CHLORIDE ions, *CONCRETE durability, *CONCRETE additives, *DURABILITY, *CONCRETE

Abstract

Concrete is the most accepted material in construction as it has better durability than other materials in construction. However, some aggressive substances can reduce their durabilities, such as sulfate attack and chloride ingression. As porosity becomes the main property to improve concrete durability, the utilization of fly ash will be beneficial to reduce concrete porosity. This paper presents the experimental study on durability of high-volume fly ash concretevariationsion of 5%,10%, and 15% of calcium oxide by weight of fly ash were used as addition fly ash content. The testing program consists of compressive strength, elastic modulus test, and rapid chloride penetration test (RCPT) for durability test performance. This study reveals that adding calcium oxide to high-volume fly ash concrete can accelerate setting timebenefitstly, improving concrete compressive strength, modulus of elasticity, and resistance to chloride-ion penetration at a calcium oxide addition of 5%. [ABSTRACT FROM AUTHOR]

Published

2024

7. Experimental studies on the behavior of the fiber reinforced concrete blended with admixtures.

Author

Keerthana, T., Nirmalkumar, K., Sampathkumar, V., and Selvakumar, S.

Subjects

*FIBER-reinforced concrete, *CONCRETE additives, *CONCRETE beams, *CONCRETE industry, *SILICA fume, *GREENHOUSE gases

Abstract

The materials which are widely used for construction of the building industry are concrete. But the production of cement releases numerous amounts of greenhouse gases (CO2) that leads to increase in global warming. So, an alternative to cement has to be identified. The current research focuses on the use of mineral admixtures such as fly ash, rice husk ash, and silica fume in place of cement in concrete with the addition of coir fibre. The mechanical properties of the specimens were studied with percentage replacement of cement with various mineral admixtures. With the optimum results flexural behaviour of reinforced concrete were studied. Reinforced concrete beams with percentage replacement of silica fume offered better load carrying capacity. [ABSTRACT FROM AUTHOR]

Published

2024

8. Review on impact performance of concrete using fibers and nanomaterials.

Author

Odaa, Sief Aldeen, Al-Hadithi, Abdulkader Ismail, and Mansoor, Yousif A.

Subjects

*CALCIUM silicate hydrate, *NANOSTRUCTURED materials, *FIBERS, *CONCRETE additives, *FIBER cement, *CONCRETE, *PORTLAND cement, *PASTE

Abstract

Impact resistance was the primary goal of preparing a review; thus, it is recommended to do an extensive study to improve the concrete properties, especially from industrial waste materials such as polyethylene terephthalate (PET) fibers. It has shown that nanomaterials have already an ability to treat and strengthen the bond traction between fibers and cement paste by accelerating the hydration reactions at an early age, then consuming the calcium hydrate (CH) and increased the calcium silicate hydrate (C-S-H) which it represents the responsible about the bonding and bridging action. One of the essential qualities of concrete is its impact resistance. Furthermore, combining Nanomaterials and fibers demonstrates how to effect tangible characteristics change. The current state of Nano-materials and Fiber in Concrete is summarized in this brief review. It has been reviewed all studies from 2010-2022. [ABSTRACT FROM AUTHOR]

Published

2024

9. Technical, economic, and environmental feasibility of rice hull ash from electricity generation as a mineral additive to concrete.

Author

Ro, Jin Wook, Cunningham, Patrick R., Miller, Sabbie A., Kendall, Alissa, and Harvey, John

Subjects

*RICE hulls, *CONCRETE additives, *ELECTRIC power production, *SUSTAINABILITY, *CIRCULAR economy, *FEEDSTOCK

Abstract

A circular economy based on symbiotic relationships among sectors, where the waste from one is resource to another, holds promise for cost-effective and sustainable production. This research explores such a model for the agriculture, energy, and construction sectors in California. Here, we develop new an understanding for the synergistic utilization mechanisms for rice hull, a byproduct from rice production, as a feedstock for electricity generation and rice hull ash (RHA) used as a supplementary cementitious material in concrete. A suite of methods including experimental analysis, techno-economic analysis (TEA), and life-cycle assessment (LCA) were applied to estimate the cost and environmental performance of the system. TEA results showed that the electricity price required for break even on expenses without selling RHA is $0.07/kWh, lower than the market price. As such, RHA may be available at little to no cost to concrete producers. Our experimental results showed the viability of RHA to be used as a supplementary cementitious material, meaning it can replace a portion of the cement used in concrete. LCA results showed that replacing 15% of cement with RHA in concrete can reduce carbon dioxide equivalent (CO2e) emissions by 15% while still meeting material performance targets. While the substitution rate of RHA for cement may be modest, RHA generated from California alone could mitigate 0.2% of total CO2e from the entire cement production sector in the United States and 1% in California. [ABSTRACT FROM AUTHOR]

Published

2024

10. Experimental study on static and impact properties of concrete incorporating different nanoparticles in single and combined forms.

Author

Al-Hagri, Mohammed Gamal and Döndüren, Mahmud Sami

Subjects

*CONCRETE additives, *FERRIC oxide, *CONCRETE, *FLEXURAL strength, *ALUMINUM oxide, *SCANNING electron microscopy

Abstract

A comparative evaluation of the single and combined effect of nanoparticles (NPs) on the static and impact properties of concrete is presented. Different NPs (silicon dioxide, aluminium oxide and ferric oxide) were used separately and in combination as partial replacements of cement at 0.5% and 1% by weight of cement. The effects of the NP additions on the unit weight, compressive strength, split tensile strength, flexural strength, toughness, fracture energy and impact performance of concrete were experimentally examined. The effects of the NPs on the microstructure of concrete was investigated using scanning electron microscopy (SEM). The cost effectiveness of the use of NPs in concrete was also assessed in order to evaluate the commercial production of NP-doped concretes. Desirability function analysis was also conducted to compare the overall performance of the concretes. The addition of NPs had a positive effect on improving the mechanical performance of the concrete, with the addition of NPs increasing the compressive strength, split tensile strength, flexural strength and energy absorption capacity. The NPs did not have any significant influence on the unit weight of the concrete. SEM analysis showed that the use of NPs improved the concrete microstructure, but the NPs did not have a good influence on the impact performance of the concrete. [ABSTRACT FROM AUTHOR]

Published

2024

11. Experimental study on the effect of cement alkali content on concrete ASR.

Author

Gao Xu and Weitong Li

Subjects

*CONCRETE additives, *ALKALIES, *CONCRETE testing, *CONCRETE, *CONFORMANCE testing, *TEST methods

Abstract

Conduct alkali silica reaction (ASR) tests on concrete by using cement with different alkali contents and according to different test standards. The influence of cement alkali content on the alkali-silica reaction of concrete was explored, and the effects of different test methods on the results of alkali-silica reaction tests were compared. The results indicate that: the type of cement and the testing method used have no significant impact on the experimental results of the alkali silica reaction. The rate of alkali silica reaction accelerates with the increase of cement alkali content. When the alkali content of cement is greater than 2.0 %, there is no potential harm of alkali silica reaction in the aggregate, which will cause harm of alkali silica reaction. The research conclusion can provide reference for the control value of alkali content in engineering cement. [ABSTRACT FROM AUTHOR]

Published

2024

12. Pull‐off capacity of FRP–concrete composite bonded with epoxy/geopolymer at elevated temperature.

Author

Rashid, Khuram, Fatima, Miral, Daud, Maheen, Ju, Minkwan, and Wang, Yi

Subjects

*HIGH temperatures, *EPOXY resins, *FAILURE mode & effects analysis, *ADHESIVES, *BOND strengths, *INORGANIC polymers, *POLYMER-impregnated concrete, *CONCRETE additives

Abstract

Externally bonded strengthening technique to the concrete has been widely used with epoxy adhesive. However, the adhesive is considerably weak against high temperatures, which has been regarded as the critical point in the loss of integrity of the strengthened system. Alternatively, geopolymer materials have shown an excellent performance at high temperatures, thus, their potential to be used as adhesive material has been investigated in this work. In experimentation, the composite specimens were developed using both types of adhesives, epoxy and geopolymer, and their performance was evaluated at three temperature levels (20, 60, and 120°C) by conducting pull‐off strength tests and classifying their failure modes. It was observed that the strength of concrete and epoxy was reduced with temperature. In contrast, the strength of geopolymer‐based adhesives strength was increased due to the reactivity of the precursor at high temperatures. Also, bond strength was reduced for both composite specimens at elevated temperatures. The highest bond strength was observed for the epoxy‐based adhesive system at 20°C, and about 70% loss in bond strength was observed when exposed to 120°C. The failure mode was also shifted from concrete to adhesive interface failure, that is, failure between the adhesive and the fiber fabric layer. The geopolymer‐based adhesive system has lower strength than its counterpart at all temperature levels, and the failure mode was adhesive interface failure. To enhance the bonding capacity at high temperatures, efforts are being made by adding different minerals has been employed. From the experimental results, it was found that there were some improvements, however, it was still less than that of epoxy‐based system. Further optimization of the geopolymer adhesive using minerals is required and then high‐thermal resistance geopolymer adhesive can be established. [ABSTRACT FROM AUTHOR]

Published

2024

13. Additive Fertigung mit Beton – Leitfaden für die Planung und die Durchführung von Projekten.

Author

Mechtcherine, Viktor, Kuhn, Alexander, Mai, Inka, Nerella, Venkatesh Naidu, Weger, Daniel, Ivaniuk, Egor, and Wiens, Udo

Subjects

*CONCRETE construction, *CONSTRUCTION laws, *CONSTRUCTION projects, *CONCRETE testing, *CONCRETE additives, *TEXTILE machinery

Abstract

Additive manufacturing with concrete – guidance for planning and implementation of projects This guideline, created by the DAfStb Working Group "Digital Concrete Construction through Additive Manufacturing," serves as a comprehensive resource to support the planning and implementation of additive manufacturing projects in concrete construction. It is intended for architects, planners, applicants, material manufacturers, construction companies, and other parties involved in construction. After a brief introduction to the classification, terminology, and methods of additive manufacturing, legal aspects and approval procedures are highlighted to ensure seamless integration of this technology into construction practice. The guide addresses the integration of additive manufacturing methods with concrete into construction law, explains the approval process, and offers assistance for coordinating responsibilities in projects. It addresses technical rules for the design and construction of structures, particularly for walls produced by additive manufacturing, and covers constructive aspects of reinforcement. An important component is concrete and component testing, including methods for sample preparation and testing procedures for fresh and hardened concrete, making the guide a useful tool for professionals in the field of digital concrete construction. [ABSTRACT FROM AUTHOR]

Published

2024

14. Implementation of Ceramic Waste as Fine Aggregate in Rigid Pavement: Performance Enhancement Through Silane Coupling Agent.

Author

Jweihan, Yazeed S.

Subjects

*SILANE coupling agents, *CONCRETE additives, *SKID resistance, *SILANE, *CERAMICS, *PAVEMENTS, *GLAZES, *SURFACE chemistry, *CONCRETE pavements

Abstract

This study investigates the feasibility and effectiveness of employing waste ceramic (WC) in rigid pavement as a replacement for fine aggregate. WC was integrated into concrete; untreated and treated with a silane compound, where 30 wt.% and 50 wt.% sand was replaced with WC. The workability, compressive strength, water absorption, skid resistance, microstructural analysis, and surface chemistry of mixtures were evaluated. The results illustrated the positive impact of using treated WC on the water absorption of mixtures, where a maximum reduction of 19% was achieved in the mixture with 50% treated WC. Moreover, concrete with 30% treated WC attained a higher compressive strength of 43 MPa than its untreated counterpart, which achieved 29 MPa, when tested at 28 days. The integration of treated and untreated WC in concrete pavement reduced its skid resistance due to the presence of glaze in the untreated mixture and silane in the treated mixture. The morphological and surface chemistry analyses confirmed the development of C–S–H, CaCO3, and SiO2 in high contents in concrete with silane-treated WC. Also, a strong bonded interfacial transition zone was noticed in concrete with silane-treated WC, unlike concrete with untreated WC, which had a poor interfacial transition zone. [ABSTRACT FROM AUTHOR]

Published

2024

15. Strength and durability properties of recycled aggregate concrete blended with hydrated lime and brick powder.

Author

Abu Bakr, Mohd and Singh, Birendra Kumar

Subjects

*RECYCLED concrete aggregates, *CONCRETE additives, *LIME (Minerals), *ULTRASONIC testing, *BRICKS, *CONSTRUCTION & demolition debris, *POWDERS

Abstract

Concrete is an important material for the construction of buildings, and highways. However, natural resources are being depleted by using natural coarse or fine aggregates for the production of concrete. The substitution of natural coarse aggregate (NCA) with recycled coarse aggregate (RCA) efficiently manages construction waste and preserves natural resources. In the present study, 50 and 100% NCA have been replaced with RCA for the preparation of recycled aggregate concrete (RAC) with blended hydrated-brick powder (RAC-HBr). Additionally, cement was replaced by 10 and 20% of blended HBr in the preparation of RAC mixes. To investigate the strength and durability properties of RCA-HBr mixtures, compressive strength, water permeability, chloride penetration test, and ultrasonic pulse velocity (UPV) tests were conducted. The outcomes indicate that the optimum percentage of blended HBr enhances the compressive strength of RCA mixes. However, blended HBr positively influenced the RCPT, water permeability, and ultrasonic pulse velocity of the RCA concrete mixes. Further, the RCPT outcomes show that the chance of corrosion was reduced by 20%, while the UPV value confirms that the density of the RAC-HBr mixes was enhanced by 28.7% at the age of 56 days. Furthermore, based on the FESEM and EDS analysis, the pozzolanic materials have densified the concrete matrix by reducing the pores and voids of RAC-HBr mixes. Thus, practically, 100% RCA with blended hydrated lime and brick powder can be used to create M35-grade concrete. The current paper investigates the effect of blended HBr on the properties of RAC. 10% HBr was an optimum percentage which has significantly enhanced the strength and durability characteristics of RAC mixes. CSH gel CH crystals densify the concrete matrix. CSH gel and CH crystals were confirmed from the microstructure analysis through FESEM and EDS analysis. [ABSTRACT FROM AUTHOR]

Published

2024

16. Experimental study of the effects of adding silica nanoparticles on the durability of geopolymer concrete.

Author

Mansourghanaei, Mohammadhossein, Biklaryan, Morteza, and Mardookhpour, Alireza

Subjects

*POLYMER-impregnated concrete, *CONCRETE durability, *SILICA nanoparticles, *CONCRETE additives, *INORGANIC polymers, *TENSILE strength, *ABSORPTION coefficients, *ENVIRONMENTAL degradation

Abstract

The advantages of using geopolymer materials instead of cement in concrete are not limited to high durability properties. geopolymer concrete was introduced to mitigate the environmental damages caused by CO2 emissions and the great level of fossil fuels consumption during cement manufacturing. In the present investigation, a number of experimental studies were conducted on slag-based geopolymer concrete. Accordingly, nano-silica particles were used to improve the geopolymer concrete structure's matrix. In the current study, slag-based geopolymer concrete was used with 0–2% polyolefin fibres and 0–8% nano-silica. They were subjected to water absorption and permeability tests to assess their durability. The addition of nano-silica enhanced the whole properties of the slag-based geopolymer concrete. By using the nano-silica, the concrete paste microstructure became denser and more homogeneous, and the pores decreased. The compressive strength and tensile strength of the concrete increased by up to 22% and 14% respectively. On the other hand, in terms of durability, the nano-silica lowered the water absorption and permeability coefficients by up to 24% and 44%, respectively, by filling the pores of the concrete. In the weight loss test, geopolymer concrete achieved superior results (up to 16%) compared to ordinary concrete. [ABSTRACT FROM AUTHOR]

Published

2024

17. Mechanical properties of coal ash concrete in the presence of graphene oxide.

Author

Prasanthni, P., Priya, B., Dineshkumar, G., and Gobinath, G.N.

Subjects

*COAL ash, *CONCRETE additives, *FLY ash, *CONSTRUCTION materials, *CONCRETE, *CONCRETE mixing, *GRAPHENE oxide

Abstract

Modern concrete technology places a strong emphasis on incorporating diverse resources, particularly industrial byproducts, into the concrete production process. The utilization of fly ash, a notable industrial waste, has gained increasing importance due to its potential to enhance concrete properties and provide economic advantages. In this study, we conducted experimental investigations on concrete, varying the concentrations of graphene oxide (ranging from 0.1% to 0.5%) and coal ash (at levels of 5%, 10%, and 15%). We evaluated the mechanical characteristics of concrete, including compressive strength, tensile strength, and flexural strength, by creating a total of 45 different mix specimens across 15 distinct mix formulations. Remarkably, the combination known as 4GOCA (Graphene Oxide and Coal Ash at 5%, 10%, and 15%) exhibited the highest strength, demonstrating a remarkable 65% increase compared to the reference mix. Similarly, both 2GOCA and 3GOCA demonstrated strength gains exceeding 50%. The unique aspect of this research lies in its innovative utilization of graphene oxide and coal ash in the concrete mix, showcasing the potential for sustainable and high-performance construction materials. [ABSTRACT FROM AUTHOR]

Published

2024

18. A Review of Chloride Penetration of Recycled Concrete with Enhancement Treatment and Service Life Prediction.

Author

Wang, Yuanzhan, Liao, Jing, and Zhang, Baohua

Subjects

*SERVICE life, *CONCRETE additives, *RECYCLED concrete aggregates, *CONCRETE fatigue, *REINFORCED concrete, *CHLORIDES, *CONCRETE, *MORTAR

Abstract

The application of recycled coarse aggregate (RA) in structural concrete can save non-renewable resources and reduce land occupation. Developing comprehensive knowledge of chloride penetration and service life modeling of recycled coarse aggregate concrete (RAC) is a prerequisite for practice. However, compared with the natural aggregate concrete (NAC), the inferior durability performance, especially chloride penetration resistance, of RAC hinders its application in structural concrete. Therefore, many RAC performance enhancement methods have been proposed. This paper presents a holistic review focused on the chloride penetration of RAC with/without enhancement methods and service life prediction. The current RAC performance enhancement methods are introduced. The improvement effect of the corresponding enhancement methods on the chloride penetration resistance of RAC are discussed and analyzed in turn. Based on the reviewed data on the chloride diffusion coefficient, the modification efficiencies of assorted enhancement methods are summarized. With the hope of promoting RAC application in structural concrete, the current literature on chloride-ingress-based service life prediction for RAC is also overviewed. In addition, the typical influencing factors on chloride transport properties are also discussed, i.e., RA quality. It can be concluded that enhancement techniques can effectively improve the chloride penetration resistance of RAC. The old mortar enhancement or removal methods can improve the chloride penetration resistance by 15–30%, depending on the specific treatment measures. The modification efficiency of the modifier material depends on the specific type and content of the incorporated substance, which ranges from approximately 5% to 95%. The estimated service life of RAC structures decreases with the increasing RA replacement ratio. Finally, concluding remarks are provided concerning future research on the chloride transport behavior of RAC. [ABSTRACT FROM AUTHOR]

Published

2024

19. Mechanical and Microstructural Investigation of Geopolymer Concrete Incorporating Recycled Waste Plastic Aggregate.

Author

Adeleke, Blessing O., Kinuthia, John M., Oti, Jonathan, Pirrie, Duncan, and Power, Matthew

Subjects

*CONCRETE additives, *PLASTIC scrap recycling, *PLASTIC scrap, *PLASTIC recycling, *CALCIUM silicate hydrate, *WASTE recycling, *CONCRETE

Abstract

The effective use of waste materials is one of the key drivers in ensuring sustainability within the construction industry. This paper investigates the viability and efficacy of sustainably incorporating a polylactic acid-type plastic (WP) as a 10 mm natural coarse aggregate (NA) replacement in geopolymer concrete. Two types of concrete (ordinary Portland cement—OPC and geopolymer) were produced for completeness using a concrete formulation ratio of 1:2:3. The ordinary concrete binder control was prepared using 100% OPC at a water/binder ratio of 0.55, while the geopolymer concrete control used an optimum alkaline activator/precursor—A/P ratio (0.5) and sodium silicate to sodium hydroxide—SS/SH volume ratio (1.2/0.8). Using the same binder quantity as the control, four concrete batches were developed by replacing 10 mm NA with WP at 30 and 70 wt% for ordinary and geopolymer concrete. The mechanical performance of the developed concrete was assessed according to their appropriate standards, while a microstructural investigation was employed after 28 days of curing to identify any morphological changes and hydrated phases. The results illustrate the viability of incorporating WP in geopolymer concrete production at up to 70 wt% replacement despite some negative impacts on concrete performance. From a mechanical perspective, geopolymer concrete indicated a 46.7–58.3% strength development superiority over ordinary concrete with or without WP. The sample composition and texture quantified using automated scanning electron microscopy indicated that adding WP reduced the presence of pores within the microstructure of both concrete types. However, this was detrimental to the ordinary concrete due to the low interfacial zone (ITZ) between calcium silicate hydrate (CSH) gel and WP, resulting in the formation of cracks. [ABSTRACT FROM AUTHOR]

Published

2024

20. Under Sulfate Dry–Wet Cycling: Exploring the Symmetry of the Mechanical Performance Trend and Grey Prediction of Lightweight Aggregate Concrete with Silica Powder Content.

Author

Wang, Hailong, Chen, Yaolu, and Wang, Hongshan

Subjects

*CYCLING, *CONCRETE construction, *POWDERS, *SILICA, *MIRROR symmetry, *LIGHTWEIGHT concrete, *SILICA fume, *CONCRETE additives

Abstract

In order to improve the mechanical properties and durability of lightweight aggregate concrete in extreme environments, this study utilized Inner Mongolia pumice as the coarse aggregate to formulate pumice lightweight aggregate concrete (P-LWAC) with a silica powder content of 0%, 2%, 4%, 6%, 8%, and 10%. Under sulfate dry–wet cycling conditions, this study mainly conducted a mass loss rate test, compressive strength test, NMR test, and SEM test to investigate the improvement effect of silica powder content on the corrosion resistance performance of P-LWAC. In addition, using grey prediction theory, the relationship between pore characteristic parameters and compressive strength was elucidated, and a grey prediction model GM (1,3) was established to predict the compressive strength of P-LWAC after cycling. Research indicates that under sulfate corrosion conditions, as the cycle times and silica powder content increased, the corrosion resistance of P-LWAC showed a trend of first increasing and then decreasing. At 60 cycles, P-LWAC with a content of 6% exhibited the lowest mass loss rate and the highest relative dynamic elastic modulus, compressive strength, and corrosion resistance coefficient. From the perspective of data distribution, various durability indicators showed a clear mirror symmetry towards both sides with a silica powder content of 6% as the symmetrical center. The addition of silica fume reduced the porosity and permeability of P-LWAC, enhanced the saturation degree of bound fluid, and facilitated internal structural development from harmful pores towards less harmful and harmless pores, a feature most prominent at the 6% silica fume mixing ratio. In addition, a bound fluid saturation and pore size of 0.02~0.05 μm/% exerted the most significant influence on the compressive strength of P-LWAC subjected to 90 dry–wet cycles. Based on these two factors, grey prediction model GM (1,3) was established. This model can accurately evaluate the durability of P-LWAC, improving the efficiency of curing decision-making and construction of concrete materials. [ABSTRACT FROM AUTHOR]

Published

2024

21. Influence of chloride salt erosion on the adhesion of asphalt-aggregate interfaces considering mineral anisotropy: insights from molecular dynamics.

Author

Sun, Enyong, Zhao, Yanqing, and Wang, Guozhong

Subjects

*MOLECULAR dynamics, *MINERALS, *MINERAL aggregates, *ASPHALT concrete, *ASPHALT, *ANISOTROPY, *CHLORIDES, *CONCRETE additives

Abstract

Context: Asphalt, a polymer mixture composed of various hydrocarbons, is extensively utilized due to its excellent performance. To evaluate the sensitivity of asphalt concrete to chloride salt damage at the nanoscale, considering the anisotropy of aggregate mineral crystal orientation, molecular dynamic simulations were employed to model the interface interactions between asphalt and aggregate mineral components (silica and calcite) under chloride salt exposure. The wetting processes of water droplets and chloride salt droplets on different crystal surfaces of silica and calcite were analyzed. Furthermore, the adhesive energy, decohesion energy, degradation ratio, and energy ratio of the interaction model between asphalt and aggregate mineral interfaces were analyzed to reveal the variations in the interfaces between the two components. The results demonstrated that the anisotropy of the minerals significantly affects the adhesion energy of asphalt and aggregate. Moreover, the surface hydrophilicity of calcite was larger than that of silica. The interfacial adhesion energy of asphalt-calcite was larger than that of asphalt-silica under dry condition and chloride salt attack, and the interfacial adhesion energy of both asphalt and mineral decreased with the increase of chloride salt concentration. The degradation ratio and energy ratio values of asphalt and calcite were larger than those of asphalt and silica, and the anisotropy of the mineral surface affected the degradation ratio and energy ratio values. This study provides a new method and theoretical basis for further research on the damage mechanism and strengthening measures of asphalt-aggregate under chloride salt attack. Methods: To investigate the interaction between asphalt and mineral aggregates under chloride salt erosion, models of asphalt, aggregate, and asphalt/aggregate composite systems were constructed using the Amorphous Cell module in Materials Studio 2020 software. Molecular dynamic simulations of the asphalt/aggregate composite system were then conducted using the Forcite module, employing the COMPASS II force field to describe atomic and molecular interactions. Initially, considering the crystal orientation and surface configuration of the aggregate minerals, the impact of mineral anisotropy on the asphalt-aggregate interface model was analyzed. Subsequently, by simulating the contact states of nano water droplets and chloride salt droplets with different mineral surfaces, the wetting characteristics of nano water droplets on silica and calcite surfaces were determined. Lastly, considering the corrosion effect of chloride solution at different concentrations, the adhesion energy, debonding energy, degradation ratio, and energy ratio of the asphalt-aggregate interface interaction model were analyzed. [ABSTRACT FROM AUTHOR]

Published

2024

22. Research on mechanical properties of concrete by nano-TiC-BF-fly ash.

Author

Yang, Xin, Yu, Kui, Li, Ke, Wang, Zhengjun, Ji, Fengchun, and Li, Mengyuan

Subjects

*CONCRETE, *RESPONSE surfaces (Statistics), *SCANNING electron microscopes, *FLY ash, *CONCRETE additives

Abstract

Ultra-high-rise buildings require high concrete bearing capacity. Ordinary concrete often fails to meet the project requirements. Admixture of admixtures in concrete is a means of solution. Currently, studies on the incorporation of basalt fiber (BF) and fly ash (FA) in concrete are relatively mature. However, research on incorporating nano-Titanium Carbide (nano-TiC) in concrete is still relatively scarce, which has a lot of room for development. To further improve the mechanical properties of concrete, BF, and FA synergized with nano-TiC were incorporated into concrete to produce TBF concrete in this study. And Response Surface Methodology (RSM) was used to optimize the mechanical properties of concrete. The collapse and compressive deformation damage characteristics of concrete were analyzed. The microstructure of the cement matrix was analyzed by the SEM (Scanning Electron Microscope). An optimization model of the TBF concrete craving function was developed. Optimized ratios with compressive, split tensile, and flexural strengths as response objectives were obtained, and the accuracy of the optimized ratios was investigated using the same experimental conditions. The results of the study showed that FA increased the collapse of concrete, while nano-TiC and BF decreased the collapse of concrete. Under uniaxial compression, nano-TiC, FA, and BF together incorporated into concrete can improve its compressive damage state. Moderate amounts of nano-TiC, BF, and FA could improve the mechanical properties of concrete. Their optimal mixing ratio admixtures were 0.88%, 0.24%, and 5.49%, respectively. And the measured values under the same conditions were compared with the predicted values. The maximum difference in compressive strength was 6.09%. The maximum difference in split tensile strength was 7.14%. The maximum difference in flexural strength was 8.45%. This indicated that the accuracy of the RSM optimization model was good. A moderate amount of nano-TiC, FA, and BF could improve the densification of concrete. [ABSTRACT FROM AUTHOR]

Published

2024

23. Effects of silane-functionalized nanocomposites in superabsorbent polymer and its reinforcing effects in cementitious materials.

Author

Sujitha, V. S., Ramesh, B., and Xavier, Joseph Raj

Subjects

*SUPERABSORBENT polymers, *CONCRETE additives, *MORTAR, *POLYMERIC nanocomposites, *CONCRETE curing, *CHEMICAL properties, *RHEOLOGY, *TENSILE strength

Abstract

As an internal curing substance for cementitious materials, superabsorbent polymer (SAP) is emerging as the most potential solution. Nanomaterials and their composites have wide applications in concrete mainly as crack sealants and viscosity modifiers. Silane, as a coupling agent, is utilized in cementitious materials for its effective particle dispersion and adhesion characteristics. X-ray diffraction (XRD), Fourier-transform infrared spectroscopy (FTIR), Thermogravimetry (TGA) analysis, and Scanning electron microscopy (SEM) are utilized to characterize the microstructures and phase compositions of nanoalumina, (3-aminopropyl) triethoxysilane (APTES) and polyacrylamide (PAM) SAP. The impacts of silane-functionalized nanoalumina combined polyacrylamide SAP in cementitious materials are carefully investigated in this work. Compared with plain SAP, the application of silane-functionalized SAP was found to exhibit increased compressive strength, flexural strength and split tensile strength of concrete. The chemical durability properties of cement mortar, rheological and mechanical properties of concrete under self-curing and water curing with cement replaced by the prepared composites at 0.1, 0.2, 0.3, 0.4 and 0.5% by weight of cement are studied experimentally. Results revealed that silane-functionalized nanoalumina modified SAP has good water holding capacity than those with individual SAPs contributing to the advancement of internal curing materials in concrete buildings. The weight loss measurements reveal that lower weight loss is observed for the concrete containing SAP/APTES/nanoalumina in chloride, acidic and sulphate media. This work contributes to the advancement in material technologies for the prevention of building fractures. [ABSTRACT FROM AUTHOR]

Published

2024

24. Effect of the Side-Chain Length in Polycarboxylic Superplasticizer on the Competition Adsorption in the Presence of Montmorillonite: A Density Functional Theory Study.

Author

He, Zhihao, Huang, Teng, Gao, Meiben, Kong, Desong, and Li, Meng

Subjects

*DENSITY functional theory, *CONCRETE additives, *MONTMORILLONITE, *ADSORPTION, *DEGREE of polymerization, *DENSITY of states

Abstract

Polycarboxylic superplasticizers (PCEs) exhibit numerous advantages as concrete additives, effectively improving the stability and strength of concrete. However, competitive adsorption of PCEs occurs in the presence of clay, which may affect the cement dispersion and water-reducing performance. Extensive research has been conducted on the physical and mechanical properties of PCEs; however, the effect of the diverse structures of PCEs on the competitive adsorption on clay and cement hydration products has been rarely studied. This study employs Ca-montmorillonite (CaMMT) as a clay representative, by constructing adsorption models of PCEs on CaMMT and cement hydration products. A comparison of the adsorption energies considering different side-chain lengths of PCEs is included. Typically, the adsorption energy on CaMMT is lower than that on hydration products, leading PCEs to preferentially adsorb on the clay, thereby reducing its effective dosage in the cement particles. The challenge of PCE adsorption on CaMMT increases with the polymerization degree, and methylallyl polyoxyethylene ether (HPEG) exhibits lower adsorption energies on CaMMT. The density of states (DOS) analysis indicated the highest peak values of allyl polyethylene ether (APEG) as well as the peak area at n (polymerization degree) = 1. The total number of transferred electrons for APEG was 0.648, surpassing those of other PCEs. The interaction mechanism of PCEs with clay and hydration products is further elucidated through electronic gain/loss analysis, also providing a basis for the theoretical analysis on how to reduce the adsorption of PCEs on clay and the structural design of mud-resistant PCEs. [ABSTRACT FROM AUTHOR]

Published

2024

25. Effect of mixed basalt fibers and nano-silica on mechanical properties and microstructure of recycled aggregate concrete.

Author

Chen, Wei and Chen, Yueshun

Subjects

*RECYCLED concrete aggregates, *CONCRETE additives, *BASALT, *MICROSTRUCTURE, *SCANNING electron microscopes, *FIBERS

Abstract

In this study, basalt fibers (BFs) and nano-silica (NS) were innovatively combined to reinforce recycled aggregate concrete (RAC) to prepare recycled aggregate concrete (named NBRAC) with better mechanical and microstructural properties as an alternative to ordinary concrete. Different NBRAC specimens were prepared by adjusting the contents of NS and BF; the damage mechanism and mechanical properties of NBRAC were investigated; and the compressive, split tensile, and flexural strengths of NBRAC were evaluated. The microstructure of NBRAC was analyzed by scanning electron microscopy observation. The results showed that the densification of NBRAC was improved under the condition of 50% RA substitution rate and that its compressive, split tensile, and flexural strengths were increased by 6.8%, 16.3%, and 32.7%, respectively, compared with that of natural concrete, which proved that the method was feasible for the preparation of high-performance RAC. Scanning electron microscope image analysis confirmed the improvement effects of NS and BF on RAC, and combined with the experimental data, a composite explanation for the improvement effects of NS and BF on RAC was proposed for the first time. [ABSTRACT FROM AUTHOR]

Published

2024

26. Investigation of the effect of polyvinyle alcohol fibers on mechanical properties of the high-strength concrete containing microsilica.

Author

FAGHIHMALEKI, Hadi and RASTKAR, Hamidreza

Subjects

*CONCRETE additives, *HIGH strength concrete, *FIBERS, *MODULUS of elasticity, *CONCRETE, *TENSILE strength, *POLYVINYL alcohol, *SELF-consolidating concrete

Abstract

Today, the use of fibers in concrete is one of the best methods to improve weaknesses such as low tensile strength and brittleness. Polyvinyl alcohol fibers are one of the best fibers to improve the mechanical properties of fiber concrete. These fibers improve the mechanical strength and performance of concrete by the connection between the micro-cracks, which is due to its excellent adhesion, tensile strength and high modulus of elasticity. The main purpose of this research is to analyze and evaluate the effect of polyvinyl alcohol fibers with a diameter of 0.014 mm and lengths of 6 and 12 mm in combination in high strength concrete containing microsilica. Accordingly, four mixtures with different amounts of polyvinyl alcohol fibers (0, 0.15, 0.3 and 0.6% of the total volume of concrete) were evaluated due to their effect on the fresh and hardened properties of high strength concrete. 10% microsilica was used as a substitute for Portland cement in all mixtures. A series of experiments (compressive strength, indirect tensile strength) showed that the low volume of polyvinyl alcohol fibers significantly increases the mechanical properties of concrete. The results of this research show that the use of volume ratio of 0.15% of polyvinyl alcohol fibers increases the compressive strength by 10.29% and tensile strength by 10.43%. [ABSTRACT FROM AUTHOR]

Published

2024

27. Effect of Various Methods of Curing on Concrete Using Crusher Dust as Replacement to Natural Sand.

Author

Kumar, Amit, Saxena, Shekhar, and Rawat, Vijendra Singh

Subjects

*CONCRETE additives, *SOLUBLE glass, *CONCRETE durability, *DUST, *WATER supply, *SAND, *HYDROTHERAPY, *CONCRETE curing

Abstract

The present paper highlight upon research work is that curing is one of most important aspect of construction. The life of concrete and its serviceability depends heavily on curing. The method of curing applied on concrete will affect its final strength and durability. Owing to this fact this paper contains the research done on concrete under various curing methods. The standard method of curing concrete is done by water and results wastage of a lot of water. With the increase in the deficiency of availability of water, curing becomes a problem. Hence this research aims at providing better methods of curing which will not only improve the strength and durability of concrete but will also save water. The various methods that have been researched upon are plastic covered curing, addition of sodium silicate to curing water, and addition of curing compounds to curing water. The tests are carried on concrete with desirable strengths of M15 and M20. In this research the fine aggregate used in making of M15 and M20 concrete consists of a mixture of sand and crusher dust. Two mixes of ratio 50:50 and 60:40, sand to crusher dust have been taken and the effects of curing on these mixes are considered. Plastic curing is done by covering the concrete with plastic soon after demolding. Hence minimum water is required. The curing done by sodium silicate is done by adding 2% by weight of sodium silicate to curing water. Concrete is submerged in water containing sodium silicate. Once the concrete is cured, this water mix can be reused to cure freshly cast concrete, thereby saving more water. Curing by curing compounds is done in a similar way as that of curing with sodium silicate, only that instead of sodium silicate, curing compounds are used. The effect of these three methods on concrete is studied and discussions are made. [ABSTRACT FROM AUTHOR]

Published

2024

28. Synergistic use of nano-silica to enhance the characterization of ambient-cured geopolymer concrete.

Author

Swathi, B. and Vidjeapriya, R.

Subjects

*CONCRETE additives, *INORGANIC polymers, *ENERGY dispersive X-ray spectroscopy, *CONCRETE durability, *BINDING agents, *CONCRETE, *MODULUS of elasticity

Abstract

As global urbanization flourishes, the adverse effects on the environment also incredibly increase. This urbanization leads to the evolution of construction and building materials. To meet the requirements of eco-balanced construction materials without compromising their original properties, many evolutions of concrete are in practice nowadays. One such evolution of concrete is geopolymer concrete. The objective of the current study is to produce high-strength geopolymer concrete using ground granulated blast furnace slag (GGBS), metakaolin (MK), and nano-silica (NS) in ambient-cured conditions. The influence of nano-silica in the geopolymer concrete is evaluated by workability, setting time, mechanical strength, durability properties, and microstructural analyses, which include scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDX), X-ray diffraction (XRD), and correlation analysis. In this research, the effect of nano-silica on formulating the equation for modulus of elasticity was determined. Nano-silica was replaced at a percentage of 1, 2, and 3% of the binder material. It is summarized that the molar ratios and properties of the precursor materials are the defining factors in altering the systems of geopolymer concrete. The highest strength of 89.4 MPa at 28 days of ambient-cured concrete with outstanding durability performance was achieved. [ABSTRACT FROM AUTHOR]

Published

2024

29. GGBFS-Based Self-Compacting Geopolymer Concrete with Optimized Mix Parameters Established on Fresh, Mechanical, and Durability Characteristics.

Author

Pradhan, Jharana, Panda, Soumyaranjan, Parhi, Suraj Kumar, Pradhan, Priyanka, and Panigrahi, Saubhagya Kumar

Subjects

*SELF-consolidating concrete, *CONCRETE mixing, *CONCRETE additives, *SOLUBLE glass, *MOLARITY, *DURABILITY, *SODIUM hydroxide, *ACID throwing

Abstract

The current study presents an investigation into the optimal content determination of the mix parameters in their acceptable ranges through fresh, mechanical, and durability characteristics in ground granulated blast furnace slag (GGBFS) based self-compacting geopolymer concrete (SCGC) cured under ambient temperature. Ordinary portland cement (OPC) based self-compacting concrete (SCC) was prepared as a control concrete. Both the M25 SCGC and SCC were characterized through fresh property tests satisfying the flowability, passing ability, and segregation resistance; mechanical tests by both nondestructive and destructive tests; and durability tests through water absorption, sorptivity, acid attack, sulfate attack; and rapid chloride permeability test (RCPT). The prime mix parameters considered in SCGC with their variation ranges were molar concentration of sodium hydroxide (10M, 12M, 14M, 16M), sodium silicate to hydroxide ratio (1.5, 2.0, 2.5, 3.0), superplasticizer (SP) dosage (5%, 6%, 7%, 8%), and percentage of extra water (EW) (15%, 18%, 21%, 24%). The results of SCGC were compared with the control SCC and discussed. The mix parameter optimal values derived from all the fresh and hardened concrete properties were a 12M concentration of sodium hydroxide, sodium silicate to hydroxide ratio of 2.5, SP dose of 7%, and EW percentage of 21%. SCGC thus prepared is stable, workable, and exhibits superior properties to OPC-based concrete to promote sustainable development. The current study estimates the optimal quantity of mix parameters, i.e., 12M NaOH, AAS ratio of 2.5, 7% SP, and 21% EW to produce ground granulated blast furnace slag (GGBFS)-based self-compacting geopolymer concrete (SCGC) cured under ambient temperature. The SCGC-optimized mix-parametric values are evaluated based on the mix materials whose physical and chemical properties are declared in the manuscript. The cementless concrete thus prepared is GGBFS based, which is an industrial byproduct, yielding sustainable concrete. Under ambient temperature, the SCGC can be cured, which is practically beneficial for the in situ construction work. The self-compacting capability of SCGC involves minimal energy in producing a dense, smooth concrete surface, reducing both the construction period and cost involvement. Being a stable workable concrete, its nonsegregation nature makes it homogeneous with minimal entrapped air. The reduced permeability nature renders it a larger insulating potential. Concerning OPC-based concrete, SCGC has larger mechanical and durability characteristics, making it a better choice. Thus, the SCGC has a huge potential in the global construction sector and is practically applicable. [ABSTRACT FROM AUTHOR]

Published

2024

30. Relation between destructive and non-destructive tests of lightweight geopolymer concrete.

Author

Kamel, Mustafa Haitham, Ibrahim, Yasir K., and Abdulrehman, Mohammed Ali

Subjects

*LIGHTWEIGHT concrete, *NONDESTRUCTIVE testing, *ULTRASONIC testing, *CONCRETE additives, *PUMICE, *COMPRESSIVE strength, *CRUSHED stone

Abstract

In this study, lightweight geopolymer concrete was produced based on slag as a binder and using two types of lightweight aggregates (the first type is pumice aggregate resulting from pumice stone crushing, and the second type is bentonite aggregate resulting from converting bentonite clay into aggregate through several stages). This concrete can be considered more environmentally friendly because of its use of slag as a binder and slag as it is known to all that slag is an industrial waste. After pouring the samples and completing the curing period, the compressive strength test was performed and two non-destructive tests (the ultrasonic pulse velocity test and the rebound number test), and then a relationship was found between the compressive strength on the one hand and the non-destructive tests on the other hand, and this relationship is considered very important to estimate the compressive strength of a structure or wall forming of the same type of concrete that has been subjected to certain conditions or dilapidated building through non-destructive tests. As for the best lightweight concrete mix, it is LBB, which contains fine aggregates of bentonite and coarse aggregates of bentonite with a grade (5-25), as it gave a compressive strength of 26.4 MPa. [ABSTRACT FROM AUTHOR]

Published

2023

31. The use of inorganic pigments in the production of colored geopolymer concrete.

Author

Ghadban, Rusul Abdul Rahim and Abdulrehman, Mohammed Ali

Subjects

*INORGANIC polymers, *CONCRETE additives, *FOURIER transform infrared spectroscopy, *CONCRETE, *PIGMENTS, *FLEXURAL strength

Abstract

The feasibility of coloring geopolymer concrete that uses slag as a binder was investigated in this work by employing inorganic pigments and examining the influence of the pigment on certain geopolymer concrete parameters. In geopolymer concrete, tests were carried out with the addition of two pigment types (cobalt blue and iron oxide red), at percent of 0, 2, 4, 6 and 0, 1, 2, 3 %, respectively, of the slag's weight. Values of slump, compressive strength, flexural strength, indirect tensile (splitting) test, permeability test and Fourier transform infrared spectroscopy (FTIR) test were obtained. It was found through the above tests that the optimum percentage of adding pigments is 1% for the red pigment and 2% for the blue pigment. It was concluded through the FTIR test that both pigments that were used in this research did not interact with the other components of the mixtures and did not affect the interaction of the components among themselves. [ABSTRACT FROM AUTHOR]

Published

2023

32. The effect of NaOH molarity on the performance of geopolymer concrete using fly ash from North Sumatera and Aceh.

Author

Pahlawan, Trio, Tarigan, Johannes, Ekaputri, Januarti Jaya, and Nasution, Amrinsyah

Subjects

*POLYMER-impregnated concrete, *FLY ash, *TENSILE tests, *CONCRETE additives, *FLEXURAL strength testing, *MOLARITY, *COAL-fired power plants

Abstract

Geopolymer concrete is green concrete that uses fly ash and alkali activator substituting Portland cement. The use of Fly Ash from different sources produces different concrete characteristics. This study used three different fly ashes obtained from three different coal-fired power plants in Aceh and North Sumatera: Nagan Raya, Labuhan Angin, and Pangkalan Susu, as geopolymer concrete material. The 10 Molar and 12 Molar Sodium Hydroxide (NaOH) solutions were used as a variable in this study. Then, the concrete was tested with a compressive strength test, splitting tensile strength test, flexural tensile strength test, and elasticity modulus test. The specimen for the compressive strength test was 100×100×100 mm cube which was tested at 7, 14, and 28 days. The splitting tensile strength test and modulus elasticity test specimen was 150×300 mm cylinder tested at 28 days. The specimen for the flexure test was 100×100×500 mm beam tested at 28 days. Based on the result, it was found that geopolymer concrete using Pangkalan Susu fly ash and 12 M of NaOH had higher performance than geopolymer concrete using Nagan Raya and mixed fly ashes. Geopolymer concrete made from fly ash is promising to be applied as a construction material for both structural and non-structural elements. [ABSTRACT FROM AUTHOR]

Published

2023

33. Analysis of concrete mixture with marble waste material as a sand filler and bagasse ash as cement filler.

Author

Zulkarnain, Fahrizal, Frapanti, Sri, and Munthe, A. P.

Subjects

*BAGASSE, *FILLER materials, *CONCRETE analysis, *MARBLE, *LIME (Minerals), *CONCRETE additives

Abstract

Recent studies show sugarcane bagasse ash and marble waste are used as fillers in concrete mixtures to produce more environmentally friendly construction material. The characteristics of these inputs become the basis for their utilization. Marbles are known to contain silicon-dioxide/silica (SiO2), calcium oxide (CaO), and magnesium oxide (MgO) as the primary chemical components. Meanwhile, the bagasse possesses similar content as the main constituents of Portland cement, including silica (SiO2) and ferrite (Fe2O3) believed to increase the compressive strength of concrete. The aim of this study, therefore, was to determine the effects of the quality of marble waste and bagasse ash on the compressive strength of concrete. This paper applied SNI 03-2834-2000 standard with compressive strength of 30 MPa, cube specimen with 15cm side measurement, and test age of 14 and 28 days. Also, the composition of the mixture was varied at 12% marble waste, 6% bagasse ash, and 12% marble waste mixture+6% bagasse ash. The results showed the 12% marble waste mixture expressed the highest compressive strength of 39.93 MPa or an increase of 25.37% against normal concrete, while the 6% bagasse ash decreased to 26.68 MPa or an estimated -13.25%. This decline is due to corrosion observed in the bagasse and therefore tends to alter the quality of the concrete mixture. Furthermore, 12% of marble waste demonstrated useful workability and is suitable for enhancing compressive strength. [ABSTRACT FROM AUTHOR]

Published

2023

34. Influence of styrene butadiene rubber latex and fly-ashon pervious concrete incorporating natural and recycled aggregate.

Author

Modh, Utsav, Joshi, Tejas, and Dave, Urmil

Subjects

*LIGHTWEIGHT concrete, *POLYBUTADIENE, *RUBBER, *CONCRETE additives, *STYRENE-butadiene rubber, *CONSTRUCTION & demolition debris, *LATEX, *STYRENE

Abstract

Pervious concrete (PC) is a term refers to a concrete that has a near zero slope and is open-graded. It is normally composed of Portland cement, coarse aggregate (C.A.), less quantity of fine aggregate (F.A.), additives and water. When these components are integrated, a hardened material is formed with interconnected pores that permits easy passage of water. With the growth of construction industry demand of aggregate has also increased and also the construction demolition of structures waste gets deposited more and more per day. As we have a limited source of natural aggregate (N.A.), use of Recycled aggregate (R.A.) would be the easy and sustainable solution. In this work an attempt was made to developing PC with R.A. replacing N.A. with specific proportions. W/c ratio 0.4 and a/c ratio were kept constant for the mix design of PC. Additives such as Fly-ash(F-ash) and styrene butadiene rubber latex were (SBR) were to improve the properties such as compressive strength(c.s.), void ratio(v.r.) and density. A noticeable increment was found in c.s. using SBR up to10% of usage. [ABSTRACT FROM AUTHOR]

Published

2023

35. Evaluation of the compressive strength of concrete under combined force and chloride load.

Author

Lehner, Petr, Koubová, Lenka, and Bujdoš, David

Subjects

*CONCRETE additives, *COMPRESSIVE strength, *CHLORIDE ions, *REINFORCED concrete, *SOLUTION (Chemistry), *CONCRETE, *ULTIMATE strength, *REINFORCED concrete corrosion

Abstract

The degradation of reinforced concrete (RC) in aggressive environments is caused by a combination of factors ranging from force loading to weathering, to various chemical agents. Reinforcement corrosion in RC structures caused by excessive chloride ion diffusion is then one of the highly critical factors related to the potential destruction of this construction. Considering these facts, it is highly desirable to investigate the behaviour of concretes under a combination of force and chemical loading. The present study thus provides the basic results of an experiment in which laboratory concrete specimens were first subjected to partial loading in a press machine, then immersed in a fully saturated salt solution, and in the last step the compressive strength was determined. The loaded specimens were compared with specimens without the first loading and also with specimens immersed in normal water. This makes it possible to evaluate the combined effect. The results were evaluated also with respect to the strength increase under maturation of concrete in time. The results showed that concrete immersed in water after initial partial loading has a lower ultimate strength. Then, concrete without preloading force but immersed in chloride solution showed lower values and concrete preloaded and immersed in chloride for 90 days had the worst residual strength result. [ABSTRACT FROM AUTHOR]

Published

2023

36. Thermodynamic calculation of alkali-silica reaction.

Author

Korkh, Oleksandra, Sopov, Viktor, Butska, Larisa, Makarenko, Olga, and Pershina, Lidia

Subjects

*CONSTRUCTION materials, *BUILDING materials industry, *CONCRETE additives, *CLIMATE change

Abstract

Concerning about the problem of climate change has motivated many scientists to look for ways to solve it. A lot of research work is devoted to the creation of "green" building materials due to the large contribution of building materials industry to the acceleration of warming processes. Glass concrete is an excellent example of a decorative material that uses recycled resources. But its long-term life can be threatened by the development of an alkali-silica reaction. The paper uses a theoretical method to study the possibility of the appearance of this reaction in concrete. Thermodynamic calculations showed that there is an exothermic process at the temperatures of 243K, 283K, 295K, and at 353 an endothermic one. [ABSTRACT FROM AUTHOR]

Published

2023

37. The effect of PET (polyethylene therephthalate) fiber and mineral admixture on self-compacting concrete.

Author

Goud, K. Anand, Balakrishna, Ch., and Allamraju, K. Viswanath

Subjects

*SELF-consolidating concrete, *PLASTIC scrap, *POLYETHYLENE, *FLY ash, *MINERALS, *FIBERS, *CEMENT admixtures, *CONCRETE additives

Abstract

The objective of this research is to examine the impact of plastic waste (PW) as a replacement for sand on the fresh properties of self-compacting concrete (SCC). To achieve this, various SCC mixes were prepared with a constant water-to-powder ratio of 0.46 and a powder content of 530 kg/m3. As a supplementary cementitious material, Class C fly ash (FA) was used (30 percent by weight of cement). The shredded plastic waste is used at 0, 2.5, 5, 7.5, and 10% in this experiment. The fresh properties of SCC can be found by slump flow, T50 slump flow (SF) time, V-funnel, J-ring height, L-box height ratio and U-box height tests. The obtained results are compared statically with each other. From these results it is stated that addition of 5% of PW in SCC, there is an ideal value in every test conducted. The criteria of self-compacting concrete is accepted up to 5% of plastic waste in it but if the addition of PW exceeds 5% then there is either an increase or decrease in the values which are not accepted by the criteria of SCC. Hence the plastic waste can be partially replaced with fine aggregate up to 5%. [ABSTRACT FROM AUTHOR]

Published

2023

38. Characteristic Study of Polycarboxylate Ether Sand as a Potential Substitute for Natural River Sand in the Construction Industry.

Author

Khupsare, Abhishek, Parmar, Ajay, Agarwal, Ajay K., and Wanjari, Swapnil P.

Subjects

*SAND & gravel industry, *X-ray spectroscopy, *CONCRETE additives, *FLY ash, *SPECIFIC gravity, *CONSTRUCTION industry, *SAND

Abstract

The extreme demand for aggregate leads to the exploitation of riverbeds for fine aggregates, affecting the environment adversely. Therefore, a suitable alternative to natural river sand is essentially required. This study focuses on preventing environmental impact by developing polycarboxylate ether (PCE) sand to replace natural river sand (NRS). Development of polycarboxylate ether (PCE) sand by mixing high-volume fly ash, bottom ash, cement, natural river sand, and locally purchased high-solid-content polycarboxylate ether–based superplasticizer (HSPCE). All the physical and chemical properties of PCE sand were observed and satisfied the requirement of current standards. PCE sand yields a good specific gravity of 2.31 and is classified as Zone I sand with a satisfactory friction angle (37°) compared with NRS and geopolymer fly ash sand (GFS). Although the water absorption (6.83%) and pH (12.18) are slightly more than those of GFS and NRS, the alkali silica reaction and soundness are well within the permissible limit as per Indian standards. The chemical analysis by X-ray fluorescence showed the presence of high amounts of SiO2 and Al2O3 with magnitudes of 58.879%, and 26.77%, respectively. Finally, the compressive strength of M25 grade concrete using PCE sand and GFS was observed to be 87.51% and 83.82% with respect to NRS after 28 days, respectively. The results of this study indicate that PCE sand can be a good alternative to NRS for construction work because it not only reduces the environmental effect due to sand mining but also focuses on utilizing fly ash and bottom ash. [ABSTRACT FROM AUTHOR]

Published

2024

39. Effect of Internal Curing with Superabsorbent Polymers on the Compressive Strength and Shrinkage of Concrete with Natural Volcanic Ash.

Author

Xia, Jingliang, Ren, Longfang, Ren, Qiang, Zhang, Rui, Gao, Chao, and Jiang, Zhengwu

Subjects

*EXPANSION & contraction of concrete, *VOLCANIC ash, tuff, etc., *COMPRESSIVE strength, *CONCRETE additives, *SUPERABSORBENT polymers, *CURING, *CONCRETE curing, *HUMIDITY

Abstract

The abundant natural volcanic ash (NVA) in East Africa is a prospective supplementary cementitious material that may be used to produce green and economical railway concrete. To mitigate the shrinkage of concrete with NVA, internal curing using a superabsorbent polymer (SAP) is employed in this study. The compressive strength, autogenous shrinkage, and drying shrinkage of internally cured concrete with NVA were measured. In addition, the water loss and internal relative humidity of internally cured concrete with NVA were analyzed. The results indicate that the compressive strength of concrete with NVA shows a linear decreasing trend with SAP. In addition, SAP significantly reduces the autogenous shrinkage but slightly increases the drying shrinkage of concrete with NVA. The internal curing using SAP increases the water loss of concrete, whereas the water released from SAP still significantly improves the internal relative humidity (IRH) of concrete. The positive influence of internal curing on the autogenous shrinkage overwhelms the unexpected influence on the drying shrinkage, resulting in the mitigated shrinkage of concrete with NVA. [ABSTRACT FROM AUTHOR]

Published

2024

40. Transport Properties and Deicing Salt Resistance of Blended Ultrahigh-Performance Concrete.

Author

Hasnat, Ariful and Ghafoori, Nader

Subjects

*ICE prevention & control, *SILICA fume, *CONCRETE additives, *FLY ash, *SALT, *CONCRETE, *PORTLAND cement

Abstract

Premature degradation of concrete, caused by frost damage, has been associated with inadequate transport properties and poor resistance to deicing salt. In this study, transport properties and deicing salt resistance of various kinds of ultrahigh-performance concrete (UHPC) containing Type V portland cement, fly ash, and microsilica were investigated. Seven combinations of cementitious materials (one reference, three binary, and three ternary) were used to batch UHPCs using a water-to-cementitious material ratio (w/cm) of 0.21. The aggregate-to-cementitious material ratio (Va/Vcm) of 1.20 was kept constant for all mixtures. The investigated transport properties included water absorption, volume of permeable voids, water penetration, rapid chloride penetration, and surface resistivity. The transport properties of the plain UHPCs were also compared to those of the corresponding steel fiber–reinforced UHPCs. The test results showed that the transport properties and deicing salt resistance of the studied binary and ternary UHPCs improved with the inclusion and increases in microsilica, replacing a portion of cement. The addition of steel fiber had a minor effect on strength and transport properties and a moderate increase in deicing salt resistance of the studied UHPCs. While rapid chloride penetration and surface resistivity tests were found appropriate to assess chloride transport through the studied plain UHPCs, both tests were deemed unsuitable for the companion steel fiber–reinforced UHPCs. [ABSTRACT FROM AUTHOR]

Published

2024

41. Unlocking cementitious performance: nano‐lubrication via polycarboxylate superplasticizers.

Author

Wang, Muhan, Ji, Xiang, Manzano, Hegoi, Hou, Dongshuai, and Li, Zongjin

Subjects

*INTERFACIAL friction, *CEMENT slurry, *MOLECULAR dynamics, *CONCRETE additives, *DISPERSING agents

Abstract

Polycarboxylate (PCE) superplasticizers are the most important additive in concrete, which can effectively improve the workability of cement slurry. Different from the traditional regarding of PCEs as dispersants, here, we understand the PCEs as nano‐lubricants. By employing the molecular dynamics simulation, a sophisticated model was used to evaluate the interfacial friction between the C–S–H particles. The results reveal that the PCEs can reduce the interfacial friction between the C–S–H particles, and thus increase the fluidity of cement slurry. Further analyses infer the role of PCE segments in lubrication. The carboxylates on PCEs ensure the anchoring and hinder the separation of Ca ions. The side chains are used to lubricate the C–S–H surface, due to the weak adsorption between the side chains and the C–S–H surface. Predictably, this study not only provides a method to directly evaluate the performance of PCEs but also suggests new insights into the colloid dispersion of the low‐water content system. [ABSTRACT FROM AUTHOR]

Published

2024

42. The Influence of Manganese Slag on the Properties of Ultra-High-Performance Concrete.

Author

Xu, Wenyu, Yu, Jia, and Wang, Hui

Subjects

*HIGH strength concrete, *CALCIUM silicate hydrate, *CONCRETE additives, *CALCIUM silicates, *SLAG, *MANGANESE, *YIELD stress, *SELF-consolidating concrete, *FLEXURAL strength

Abstract

Manganese slag (MS) is a kind of chemical waste, which may pollute the environment if conventional handling methods (stacking and landfill) are applied. Ultra-high-performance concrete (UHPC)—with considerably high compactness and strength—can be used not only as a special concrete material, but also to solidify the toxic substances in solid waste. This study proposes the addition of MS to UHPC, where the mass ratio of MS varies from 0% to 40% in the total mass of MS and silica fume. The effects of MS on the fluidity, plastic viscosity, and yield shear stress are investigated, and the flexural strength, compressive strength, and dry shrinkage rate of UHPC with MS are measured. X-ray diffraction (XRD) spectrum and energy spectrum analysis (EDS) diagrams are obtained to analyze the performance mechanism of the UHPC. A rheological study confirms that the slump flow increases with the increasing rate of 0–14.3%, while the yield shear stress and plastic viscosity decrease with the rates of 0–29.6% and 0–22.2%, respectively. The initial setting time increases with the mass ratio of MS by 0–14.3%, and MS has a positive effect on the flexural and compressive strengths of UHPC. In the early curing stage (less than 14 days), the increasing rate in the specimens increases with the curing age; meanwhile, when the curing age reaches 14 days or higher, the increasing rate decreases with increasing curing age. The compactness of UHPC is increased by adding MS. Furthermore, MS can increase the elements of Al and decrease crystals of Ca(OH)2 and calcium silicate hydrate in UHPC. [ABSTRACT FROM AUTHOR]

Published

2024

43. Characterisation and standardisation of different-origin end-of-life building materials for assessment of circularity.

Author

Ozcelikci, Emircan, Yildirim, Gurkan, Siad, Hocine, Lachemi, Mohamed, and Sahmaran, Mustafa

Subjects

*CONSTRUCTION & demolition debris, *CONSTRUCTION materials, *MORTAR, *CIRCULAR economy, *RECYCLING management, *CONCRETE waste, *PORTLAND cement, *CONCRETE additives

Abstract

Construction and demolition waste (CDW) management and recycling practices are crucial for transitioning to a circular economy. The focus of this study was on the detailed characterisation of different CDWs (hollow brick (HB), red clay brick (RCB), roof tile (RT), concrete and glass) collected from seven different demolition sites in Turkey. The CDWs were characterised based on particle size distribution, chemical composition and crystalline nature. Pozzolanic activity was evaluated through compressive strength measurements of cement mortars made with 20% cement replacement by CDWs at 7, 28 and 90 days. The results showed that the clayey CDWs exhibited similar physical/chemical properties and crystalline structures. The compositions of the waste concretes varied significantly based on their original materials. All the CDWs satisfied the minimum strength activity index (SAI) for supplementary cementitious materials, with pozzolanic activity influenced by the fineness and silica + alumina contents. The average SAIs for the HB, RCB, RT, concrete and glass were, respectively, 84.5%, 86.3%, 83.4%, 80.7% and 75.8%. Clayey CDWs contributed to mechanical strength development, while the contribution of concretes was related to the hydration of unreacted cementitious particles. Glass exhibited the weakest pozzolanic activity due to its coarser particle size. Overall, the CDWs demonstrated suitable properties for use as supplementary cementitious materials in Portland cement based systems. [ABSTRACT FROM AUTHOR]

Published

2024

44. Utilization of discarded face masks in combination with recycled concrete aggregate and silica fume for sustainable civil construction projects.

Author

Amin, Fahad, Javed, Muhammad Faisal, Ahmad, Imtiaz, Asad, Osama, Khan, Nangyal, Khan, Abdul Basit, Ali, Shahid, Abdullaev, Sherzod, Awwad, Fuad A., and Ismail, Emad A. A.

Subjects

*RECYCLED concrete aggregates, *CONCRETE additives, *SILICA fume, *MEDICAL masks, *CONSTRUCTION projects, *SUSTAINABLE construction

Abstract

The coronavirus (COVID-19) pandemic has not only had a severe impact on global health but also poses a threat to the environment. This research aims to explore an innovative approach to address the issue of increased waste generated by the pandemic. Specifically, the study investigates the utilization of discarded face masks in combination with recycled concrete aggregate (RCA) and Silica Fume (SFM) in civil construction projects. The disposable face masks were processed by removing the ear loops and nose strips, and then cutting them into small fibers measuring 20 mm in length, 5 mm in width, and 0.46 mm in thickness, resulting in an aspect ratio of 24. Various proportions of SFM and RCA were incorporated into the concrete mix, with a focus on evaluating the compressive strength, split tensile strength, and durability of the resulting material. The findings indicate that the addition of SFM led to improvements in both compressive and split tensile strength, while no significant impact on durability was observed. [ABSTRACT FROM AUTHOR]

Published

2024

45. Investigating the influence of nano-silica incorporation on mechanical characteristics of steel fiber-reinforced concrete to mitigate solid waste and environmental contamination.

Author

Ashokan, Anbuchezian, Dhairiyasamy, Ratchagaraja, and Rajendaran, Silambarasan

Subjects

*SOLID waste, *STEEL, *FLEXURAL strength, *CONCRETE additives, *TENSILE strength, *MICROFIBERS, *FIBER-reinforced concrete, *SILICA fibers

Abstract

Using nano-silica and steel micro-fibers in high-strength concrete has gained attention due to their potential to reduce solid waste and environmental pollution. In this study, the impact of nano-silica inclusions on the mechanical properties of steel fiber-reinforced concrete, referred to as “Micro-Concrete Reinforced with Steel Fibers Embedding Nano-Silica” (MRSFEN), was assessed. MRSFEN mixtures were prepared with 0%, 1%, and 2% nano-silica content and 0.5%, 1%, 2%, and 3% steel micro-fiber content. Tests showed a 17%-32% increase in compressive strength and a 12%-29% increase in tensile strength by adding 1%-2% nano-silica across all fiber contents. Incorporating 1%-3% steel micro-fibers resulted in 18–25 MPa higher compressive strength, 6–12 MPa higher tensile strength, and 10%-35% higher flexural strength relative to non-fiber concrete. However, workability reduced by 15%-30% with 3% fiber content. The combined use of nano-silica and steel micro-fibers enhanced strength and ductility, with the optimum composition identified as 1% nano-silica with 2% steel micro-fibers based on the mechanical performance. The results indicate the potential of tailored MRSFEN mixtures to improve the mechanical properties of steel fiber-reinforced concrete, with benefits in reducing solid waste and mitigating environmental contamination. [ABSTRACT FROM AUTHOR]

Published

2024

46. Carbonation-Induced Corrosion on Concrete with Waste Brick Powder and Hydrated Lime Additive.

Author

Mohan, Mani and Singh, Birendra Kumar

Subjects

*CONCRETE corrosion, *LIME (Minerals), *CONCRETE waste, *CONCRETE additives, *CONCRETE construction, *POWDERS, *PORTLAND cement

Abstract

This study explores the possibility of partially replacing cement with crushed brick powder (CBP) and 6% hydrated lime (HL) in concrete. The results showed an increase in compressive strength compared with the control at the intermediate age of 56 days. Adding HL to the cement and CBP paste samples resulted in a 22% reduction in capillary pores and a 23% increase in gel pores. Although the control samples had less carbonation penetration, the corrosion rate was higher than that of blended cement concrete with HL. The half-cell potential measurement on carbonated samples indicated that, unlike chloride-induced corrosion, the depassivation of steel could not be identified by a stable demarcating half-cell potential value. Moreover, blended cement concrete with HL exhibited higher resistivity. Visual inspection of corroded bars revealed that the assumption of uniform corrosion by carbonation might not be entirely accurate. The use of HL with a cement-CBP binder improved the concrete's characteristics and reduced the risk of carbonation-induced corrosion. The study provides supplementary information on the feasibility of using a blend of crushed brick powder and hydrated lime as sustainable alternatives in the field of concrete construction with environmental considerations. [ABSTRACT FROM AUTHOR]

Published

2024

47. Investigation on Physical and Chemical Protecting Mechanism of SME-PS as a Concrete Surface Protectant.

Author

Houshmand Khaneghahi, Mohammad, He, Jialuo, and Farnam, Yaghoob

Subjects

*DETERIORATION of concrete, *LIGHTWEIGHT concrete, *CONCRETE, *PETROLEUM waste, *CHEMICAL reactions, *GYPSUM, *CONCRETE additives

Abstract

Soy methyl ester-polystyrene (SME-PS) is a biodegradable and nontoxic blend of soybean oil and waste polystyrene that can be used as a surface treatment to improve concrete deterioration and rebar corrosion caused by freeze–thaw cycles and chloride salt exposures. Although SME-PS has shown promising results for concrete protection, the mechanism by which it protects concrete is relatively unknown. The current study utilizes thermal analysis techniques to explore the physical and chemical protecting mechanism of SME-PS. The potential chemical reaction, reaction rate, and reaction products among SME-PS, hydrated cement paste, and cement hydration products are investigated using isothermal calorimetry and thermogravimetric analysis. Dynamic vapor sorption analysis is conducted to physically evaluate the effect of SME-PS on the pore structure of concrete. The results indicated that the SME-PS can occupy the pores with sizes smaller than 50 nm, physically preventing the ingress of detrimental ions and water into the concrete porous structure. It was also found that SME-PS can chemically interact with cement paste products rapidly occurring at the first 12 min of blending of cement paste powder with SME-PS. The thermogravimetric results indicated the SME-PS reaction mainly occurs among calcium hydroxide, pore solution, and gypsum. Additionally, the hydrophobic nature of SME-PS is beneficial in terms of protecting the cementitious material surface from aggressive chemicals. [ABSTRACT FROM AUTHOR]

Published

2024

48. Recycled plastics as synthetic coarse and fine asphalt aggregate.

Author

Xuan Lu, Dai and Giustozzi, Filippo

Subjects

*FATIGUE limit, *CONCRETE additives, *ASPHALT concrete, *ASPHALT, *PLASTICS, *BIODEGRADABLE plastics, *POLYETHYLENE terephthalate, *BEND testing

Abstract

This study investigates the performance of asphalt concrete containing recycled plastics as synthetic aggregates in the dry mixing process. Two types of recycled plastics were used, namely, acrylonitrile butadiene styrene (RABS) and Polyethylene Terephthalate (RPET), based on the high-temperature properties of the plastics that make them suitable to be treated as synthetic aggregates (i.e. do not melt during the asphalt mixing phase). The proportions of recycled plastics were chosen at 0.5%, 1%, 2% and 4% of the mix mass. The laboratory testing programme includes the evaluation of compactability properties, moisture resistance, cracking resistance via IDEAL-CT test, fatigue resistance via four-point bending beam test and rutting resistance via Hamburg wheel tracking (wet) test. It was found that the inclusion of recycled plastics did affect the compactability of the mixes depending on their relative size and shape. On the other hand, the inclusion of recycled plastics did not significantly vary the moisture resistance of asphalt mixes. The cracking and rutting behaviour of asphalt mixes that incorporated recycled plastics were also modified and some benefits were observed depending on the plastic content and size. [ABSTRACT FROM AUTHOR]

Published

2023

49. Preparation and Performance Investigation of Epoxy Resin-Based Permeable Concrete Containing Ceramsite.

Author

Li, Shengjia, Cui, Honghai, Wang, Haihua, Wang, Wensheng, Sui, Yi, Dong, Liangyu, and Wang, Jiaxing

Subjects

*CONCRETE additives, *FREEZE-thaw cycles, *LIGHTWEIGHT concrete, *CONCRETE durability, *DISCRETE element method, *EPOXY resins, *CONCRETE, *COMPRESSIVE strength

Abstract

Permeable concrete is an innovative type of concrete that provides a sustainable solution for stormwater management by allowing water to seep through and be filtered naturally. This study focuses on the preparation and performance investigation of an epoxy resin-based permeable concrete containing ceramsite. In this study, ceramsite, a lightweight aggregate, is used as a substitute for conventional aggregates in the concrete mixture. The epoxy resin is then added to improve the strength and durability of the concrete. A series of tests, including compressive strength, water permeability, and freeze-thaw resistance tests, are conducted to evaluate the performance of the epoxy resin-based permeable concrete. The results show that with an increasing epoxy resin binder–aggregate ratio, the compressive strength of the epoxy resin-based permeable concrete significantly increases while the permeability coefficient decreases. Different types of aggregates have varying effects on the compressive strength and permeability coefficient of epoxy resin-based permeable concrete, with high-strength clay ceramsite providing the highest compressive strength and lightweight ceramsite having the highest permeability coefficient. In addition, the discrete element simulation method effectively and feasibly determines the ultimate load and accurately simulates the compressive strength of the permeable cement-based mixture, consistent with the measured compressive strength. A quadratic polynomial regression analysis yielded an R2 value of around 0.93, showing a strong relationship between durability and freeze-thaw cycles. The findings contribute to the development of sustainable construction materials for stormwater management and offer potential applications in various infrastructure projects. [ABSTRACT FROM AUTHOR]

Published

2023

50. Surface application of multifunctional compound to prevent and control combined chloride and carbonation corrosion in concrete.

Author

Kumar Tiwari, Ashish, Purnima, Goyal, Shweta, and Luxami, Vijay

Subjects

*CONCRETE corrosion, *CARBONATION (Chemistry), *CONCRETE additives, *CHLORIDE ions, *CHLORIDES, *GRAVIMETRIC analysis, *CONCRETE analysis, *PORTLAND cement

Abstract

This paper presents the performance of a multifunctional generic compound, 4-Aminobenzoic acid (4ABA) as migratory inhibitor applied on hardened concrete surface to curb corrosion due to combined chloride and carbonated environment. Electrochemical techniques (LPR and EIS), gravimetric analysis were applied to evaluate the corrosion performance and the inhibition mechanism of 4ABA. Chloride and carbonation profiles were developed to investigate the dominant cause of corrosion during the exposure. Visual and microscopic analysis of concrete surface and rebar surface was also done. Compressive strength test was performed to study the effect of corrosion inhibitor on strength property of hardened concrete. Results confirm that 4ABA prolonged the passive state of rebar when used as preventive measure and restrained the on-going corrosion process when employed as repair strategy. Combined exposure by chlorides and CO2 leads to redistribution of chloride ions in concrete matrix. The results also conclude that during the combined exposure, chloride ions initiate the corrosion process and carbonation aggravates this process. Application of 4ABA does not influence the strength properties of concrete. ABA has performed the inhibition by protective layer development and shield formation against the negatively charged corrosive ions. Blended cement concrete system which was observed to be more vulnerable to corrosion was seen to attain similar corrosion resistance as OPC concrete after inhibitor application. [ABSTRACT FROM AUTHOR]

Published

2023