Development of High-Strength Geopolymer Concrete Incorporating High-Volume Copper Slag and Micro Silica

Arunachelam, N.; Maheswaran, Jeyaprakash; Chellapandian, M.; Murali, G.; Vatin, Nikolai

doi:10.3390/su14137601

Cited by 22 publications

(7 citation statements)

References 69 publications

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“…A water absorption test for thin brick and stone veneer was carried out following the ASTM standard C67 [38]. This test aims to determine the durability of produced samples in changing weather conditions [42]. The thin brick samples for the water absorption test have length (L) 95 × breadth (B) 90, with two different thicknesses (T) of 13 mm and 27 mm.…”

Section: Test Methodsmentioning

confidence: 99%

New Coal Char-Based Building Products: Manufacturing, Engineering Performance, and Techno-Economic Analysis for the USA Market

Pandey,

Yu,

Lau

et al. 2024

Sustainability

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Common building products, i.e., thin brick and stone veneer, add the look of brick walls or the enduring charm of natural stones into buildings and houses without imposing a substantial increase in structural load. This study investigates the mechanical strength, durability, and economic feasibility of producing innovative char-based thin bricks and stone veneers. The char-based thin brick vacuum treated with hydrophobic liquid exhibits water absorption rates within the 4–7% range, displays durability against 50 freeze–thaw (F-T) cycles, and maintains a saturation coefficient below 0.6. In contrast, commercial thin bricks have water absorption of 9–12%. Treated char-based stone veneer has water absorption of 5.3% and an average compressive strength of 19.2 MPa, maintains its structural integrity throughout 50 F-T cycles, and exhibits a negligible linear shrinkage of approximately 0.01%. In contrast, commercial stone veneers have water absorption of 10–16%. These engineering properties meet the criteria as per ASTM standards C1088 and C1670 for thin brick and stone veneer, respectively. A techno-economic study was preliminarily conducted to examine the potential cost efficiency and cash flow in manufacturing these char-based building products. The manufacturing cost of USD 25.83 is lower than the average market price of 64.65 USD/sq. m. for thin bricks. The manufacturing cost of USD 32.65 is lower than the average market price of 129.17 USD/sq. m. for stone veneers. These comparisons present a compelling economic advantage for their commercialization. This comprehensive study has demonstrated the advantages of sustainable char-based stone veneers and thin bricks regarding engineering performance and economic benefits.

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Section: Test Methodsmentioning

confidence: 99%

New Coal Char-Based Building Products: Manufacturing, Engineering Performance, and Techno-Economic Analysis for the USA Market

Pandey,

Yu,

Lau

et al. 2024

Sustainability

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“…Also, in addition to the above types of aluminosilicate components, metakaolin, microsilica and ground waste from concrete and brick waste are used for the production of geopolymer composites [18][19][20]. The combination of these types of aluminosilicate components with each other in optimal quantities makes it possible to obtain durable composites with high mechanical characteristics [21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

Structure and Properties Improvement by Recipe Factors of Geopolymer Basalt Fiber Reinforced Concrete for Building Enclosing Structures

Zubarev,

Shcherban’,

Stel’makh

et al. 2024

Buildings

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The application of geopolymer concrete in buildings and structures is becoming widespread because of its low cost and high strength characteristics. At the same time, the capabilities of geopolymer concrete are not fully used, especially to strengthen flexural properties. The article examines the problems of developing an effective composition of geopolymer concrete based on ground granulated blast furnace slag (GGBS) by selecting the optimal composition of the alkaline activator and the amount of basalt fiber (BF). To determine the degree of effectiveness of the proposed formulation solutions, the characteristics of geopolymer fiber-reinforced concrete (FRC) were determined. It has been investigated the most effective composition of an alkaline activator is an activator containing a NaOH solution with a molarity of 12 M. The most optimal dosage of BF is 1.5% by weight of GGBS. The increase in compressive and flexural strength for the most effective composition of geopolymer FRC 12 M/BF1.5, which combines the most effective parameters of formulation solutions, compared to the least effective composition 8 M/BF0 was 40.54% and 93.75%, respectively, and the decrease of water absorption was 45.75%. The obtained scientific result represents a significant empirical basis for future research in the field of geopolymer FRC. The developed effective composition of geopolymer FRC is ready for use in practical construction.

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“…Arunachelam et al [8] reported that the geopolymer concrete made with 10 molarity raised the concrete's strength by approximately 35% when the molarity of the NaOH solution was increased to 16 M. Additionally, the compressive strength was increased by 53.8% when river sand was replaced with 100% copper slag compared to the control geopolymer concrete made with no copper slag. Te use of high-volume copper slag instead of river sand in the production of high-strength geopolymer concrete was studied by Arunachelam et al [9]. According to the fndings, the optimized geopolymer concrete mix achieved a maximum compressive strength of 79.0 MPa when 2% microsilica was added.…”

Section: Introductionmentioning

confidence: 99%

Research on Pure Modes I and II and Mixed-Mode (I/II) Fracture Toughness of Geopolymer Fiber-Reinforced Concrete

Karthik

Mohan

Murali

et al. 2023

Advances in Civil Engineering

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The unsustainable use of resources and the rising demand for traditional concrete have disrupted ecological equilibrium, necessitating the adoption of a more appropriate and long-lasting alternative. One such substitute for cement in concrete production is geopolymer concrete, although this material is prone to cracking and fracturing due to its low tensile strength, leading to costly repairs or even structural collapse. Fiber-reinforced concrete has recently been widely adopted as a construction material to counteract these issues. This research examined the crack proliferation and fracture toughness of geopolymer concrete comprising different fibers using a cracked Brazilian disc. Four different fibers were used, such as polypropylene and steel fiber (short and long), at a dosage of 1.5% by volume. Fracture toughness was computed for various modes (I, II, and I/II) of fractures, and crack propagation from cracked specimens was studied. A different angle of inclination (0, 15, 28, 83, 60, 75, and 90 degrees) was used to conduct the Brazilian disc test on the specimens with respect to the preexisting crack direction. The findings indicate that the increasing loading angle increased the load-carrying capacity. The fracture toughness values of specimens under all three modes ranged from 0.26 to 1.75 MPa.m1/2. Additionally, long polypropylene and steel fibers exhibit higher fracture toughness than short fibers.

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Development of High-Strength Geopolymer Concrete Incorporating High-Volume Copper Slag and Micro Silica

Cited by 22 publications

References 69 publications

New Coal Char-Based Building Products: Manufacturing, Engineering Performance, and Techno-Economic Analysis for the USA Market

New Coal Char-Based Building Products: Manufacturing, Engineering Performance, and Techno-Economic Analysis for the USA Market

Structure and Properties Improvement by Recipe Factors of Geopolymer Basalt Fiber Reinforced Concrete for Building Enclosing Structures

Research on Pure Modes I and II and Mixed-Mode (I/II) Fracture Toughness of Geopolymer Fiber-Reinforced Concrete

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