Evaluation of Steel Fiber Reinforced Geopolymer Concrete Made of Recycled Materials

Goaiz, Hussam A; Shamsaldeen, Hassan A.; Abdulrehman, Mohammed Ali; Al-Gasham, Thaar S.

doi:10.5829/ije.2022.35.10a.19

Cited by 6 publications

(6 citation statements)

References 20 publications

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“…The beams were subjected to a successive cycle of loading and unloading (repeated loading) (7). Through this type of loading, as shown in Figure 3.…”

Section: Experimental Workmentioning

confidence: 99%

“…Both ordinary concrete and geopolymer concrete are weak under tensile stresses and for this reason; the concrete in tension is neglected in many international codes and depends in totally on the strength of steel reinforcement to resist the tensile strength in structural members. While plain concrete tensile strength enhanced significantly by adding steel fibers to the concrete mix (7). The use of geopolymer cement can reduce carbon dioxide emissions by 44-64% compared to Portland cement (8).…”

Section: Introductionmentioning

confidence: 99%

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Behavior of Reinforced Geopolymer Concrete Beams under Repeated Load

Raad Shaker,

AlSaraj,

AL-Jaberi

2024

IJE

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Finding an alternative material for building constructions is an essential topic nowadays after the weather pollution which caused by cement protection factories, at the same time, the engineers thinking to find such material from environments wastes to minimize the earth pollutions. Geopolymer is very important material which satisfy such purpose, because it is minimizes the need to concrete production and overcome the environment from many slags. Geopolymer beams were casted and tested under repeated load to study the possibility of using them as structural members exposing to repeated loads. The beams also strengthen by steel fibers and glass fiber reinforced polymer (GFRP) to investigate their effect on such new structural member. It was concluded that, it has been observed that the structural behavior of geo-polymer concrete beams tends to be more flexible when compared to that of ordinary concrete beams. Also, the geopolymer members showed an improvement in strength when using the steel fibers and GFRP, which what was observed on conventional concrete.

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“…The beams were subjected to a successive cycle of loading and unloading (repeated loading) (7). Through this type of loading, as shown in Figure 3.…”

Section: Experimental Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Behavior of Reinforced Geopolymer Concrete Beams under Repeated Load

Raad Shaker,

AlSaraj,

AL-Jaberi

2024

IJE

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“…Mohammadi and Bagheripour [7] studied the engineering properties of self-compressing lightweight concrete (SCLWC) after adding fibers to it and found that the compressive strength was improved by adding 1% fine steel fibers. Goaiz et al [8], Mohammed and Kadhim [9] showed that adding fiber increased compressive strength. A study by Varghese et al [10] showed that carbon fiber-reinforced concrete samples had better residual shear strength than others.…”

Section: Introductionmentioning

confidence: 99%

The Post-fire Behavior of Lightweight Structural Concrete is Improved by Nano-SiO2 and Steel Fibers

Altalib,

Tavakoli,

Hashemi

2023

IJE

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The primary goal of the engineering design of building is to reduce the weight of the structure and its resistance to fires and earthquakes because fires are inevitable. Hence, the direction of this study was to use lightweight concrete because of its unique advantages in weight loss and fire resistance due to its thermal insulation property. It was also intended to enhance the strength and behavior of this concrete at high temperatures. For this purpose, four mixing designs samples without fibers and nano-SiO2, samples with different proportions of nano-SiO2, samples with different proportions of fibers, and samples with both fibers and nano-SiO2 together were prepared. The results showed damage to samples free of nano-SiO2 and fibers, changing their color, reducing their resistance and reducing their weight. But adding nano-SiO2 fibers or using them together leads to improving the properties of concrete at all temperatures. Due to nano-SiO2, its pozzolanic interactions improve the microstructure, and the fibers prevent cracks in concrete. This study also dealt with the effect of changing the size of the samples on the compressive strength, and the results showed an increase in the resistance of the samples with small sizes, and resulted factors for converting the resistance of non-standard samples into a standard.

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“…The concrete industry, heavily reliant on non-renewable resources and CO2-intensive processes, presents a significant opportunity for sustainability through the exploration of alternative materials (1). Concrete, a primary construction material, typically contains 10-15% Portland cement (OPC), with the remainder being aggregates, water, and other additives.…”

Section: Introductionmentioning

confidence: 99%

Effect of Varying Glass Powder Size on Performance of Cement Mortar: Microstructural and Compressive Strength Assessment at High Temperatures

Patil,

Patil

2024

IJE

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This study employs fine glass powder as a partial replacement for ordinary Portland cement in order to better understand the complex effects of high temperature on the microstructure and compressive strength of cement mortar. The study aims to identify the optimal mix that maximizes the benefits of glass powder incorporation by experimenting with different glass powder sizes (38 µm, 53 µm, and 75 µm) and replacement rates (10%, 20%, and 30%). At 25 o C, 200 o C, 400 o C, 600 o C, and 800 o C, mortars containing glass powder were subjected to compressive strength tests. Mortar samples were examined using X-ray diffraction (XRD), scanning electron microscopy (SEM), and Thermo Gravimetric analysis (TGA) to gain insight into their behavior at high temperatures. Mortar mixes containing 10% glass powder (38 µm size) performed best at temperatures below 400 o C, with an average residual strength index value of 90.7% compared to 87.8% in the reference sample. The glass powder mortars with 10% and 20% replacement rates functioned better at higher temperatures of 800 o C, losing just 52-57% of their strength as opposed to 72% in the control sample. The increased pozzolanic activity attributable to the addition of glass powder is shown by XRD and SEM analyses to account for the increased strength of mortar by consuming more portlandite (Ca(OH)2). TGA study has shown that at temperatures exceeding 400 o C, to bermorite and other hydrated products become dehydrated, which may account for the strength reduction.

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Evaluation of Steel Fiber Reinforced Geopolymer Concrete Made of Recycled Materials

Cited by 6 publications

References 20 publications

Behavior of Reinforced Geopolymer Concrete Beams under Repeated Load

Behavior of Reinforced Geopolymer Concrete Beams under Repeated Load

The Post-fire Behavior of Lightweight Structural Concrete is Improved by Nano-SiO2 and Steel Fibers

Effect of Varying Glass Powder Size on Performance of Cement Mortar: Microstructural and Compressive Strength Assessment at High Temperatures

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