Short-term analysis on the combined use of sugarcane bagasse ash and rice husk ash as supplementary cementitious material in concrete production

Channa, Shahid Hussain; Mangi, Sajjad Ali; Bheel, Naraindas; Soomro, Faheem Ahmed; Khahro, Shabir Hussain

doi:10.1007/s11356-021-15877-0

Cited by 38 publications

(10 citation statements)

References 22 publications

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“…This in-depth analysis of sugar cane bagasse ash and blast furnace slag was done with the goal of finding the ideal ratio in terms of mechanical qualities and cost, reducing environmental stress, and pursuing sustainable growth. In the numerous studies in the literature, experimental works have been used to predict the behavior of sugar cane bagasse ash (Channa et al, 2022). However, there has been no experimental work to evaluate the effect of using sugar cane bagasse ash (SA) and blast furnace slag (BF) reinforced by glass fiber (GF) on the mechanical properties of mortar, which is crucial to calibrate under different loadings (compressive and flexural) and can be used as an indication for future studies based on sugar cane bagasse ash.…”

Section: Figurementioning

confidence: 99%

“…PVA-reinforced concrete offers higher pull-out loads and flexural strength than concrete reinforced with metallic fibers. The inclusion of fiber also highly contributes to enhancing the fracture (Xu et al, 2018) and fire resistance (Yashwanth et al, 2017) and seismic load (Channa et al, 2022). According to the findings (Zhang et al, 2022b), the geopolymer mortar had considerable mass loss when exposed to temperatures between 25 °C and 250 °C, however, only a little amount of mass loss was observed between 250 °C and 700 °C and none at all between 700 °C and 800 °C.…”

Section: Introductionmentioning

confidence: 99%

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Behavior of geomaterial composite using sugar cane bagasse ash under compressive and flexural loading

Nikhade

Birali²,

Ansari

et al. 2023

Front. Mater.

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The sugar industry produces a huge quantity of sugar cane bagasse ash in India. Dumping massive quantities of waste in a non-eco-friendly manner is a key concern for developing nations. The main focus of this study is the development of a sustainable geomaterial composite with higher strength capabilities (compressive and flexural). To develop this composite, sugarcane bagasse ash (SA), glass fiber (GF), and blast furnace slag (BF) are used. Ash generated from burning sugar cane in the sugar industry is known as sugar cane bagasse. To check the suitability of this secondary waste for use in civil engineering and to minimize risk to the environment in the development of sustainable growth, a sequence of compressive and flexural strength tests was performed on materials prepared using sugar cane bagasse ash (SA) reinforced by glass fiber (GF) in combination with blast furnace slag (BF) and cement (CEM). The effects of the mix ratios of glass fiber to bagasse ash (0.2%–1.2%), blast furnace slag to the weight of bagasse ash (10%), cement binding to bagasse ash (10%–20%), and water to sugar cane bagasse ash (55%) regarding the flexural strength, compressive strength, density, tangent modulus, stress–strain pattern, and load–deflection curve of the prepared materials were studied. According to the findings, compressive strength achieved a maximum strength of 1055.5 kPa and ranged from 120 to 1055.5 kPa, and the flexural strength achieved a maximum strength of 217 kPa and ranged from 80.1 to 217 kPa at different mix ratio percentages. The value of the initial tangent modulus for the cube specimens ranged between 96 and 636 MPa. For compression specimens with 20% cement, the density decreased from 1320.1 to 1265 kg/m3, and the flexural strength decreased from 1318 to 1259.6 kg/m3. With limitation in lower percentages of C/SA, the specimen cannot sustain its shape even after curing period. In comparing the previous research with the present experimental work, it was observed that the material proposed here is lightweight and can be utilised as a filler substance in weak compressible soils to improve their load-bearing capacity.

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Section: Figurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Behavior of geomaterial composite using sugar cane bagasse ash under compressive and flexural loading

Nikhade

Birali²,

Ansari

et al. 2023

Front. Mater.

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“…The key properties of SCMs are their compatibility with aggregates (similar to OPC) and their better pozzolanic nature [ 62 , 63 ]. The application of RHA in concrete has sparked tremendous interest in the usage of sustainable and environmentally friendly SCM [ 64 , 65 , 66 , 67 ]. RHA has amorphous nature, high surface area, and compatibility with OPC-concrete, which results in outstanding pozzolanic capabilities [ 55 , 68 , 69 , 70 ].…”

Section: Introductionmentioning

confidence: 99%

Mapping Research Knowledge on Rice Husk Ash Application in Concrete: A Scientometric Review

2022

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This study aimed to carry out a scientometric review of rice husk ash (RHA) concrete to assess the various aspects of the literature. Conventional review studies have limitations in terms of their capacity to connect disparate portions of the literature in a comprehensive and accurate manner. Science mapping, co-occurrence, and co-citation are a few of the most difficult phases of advanced research. The sources with the most articles, co-occurrences of keywords, the most prolific authors in terms of publications and citations, and areas actively involved in RHA concrete research are identified during the analysis. The Scopus database was used to extract bibliometric data for 917 publications that were then analyzed using the VOSviewer (version: 1.6.17) application. This study will benefit academics in establishing joint ventures and sharing innovative ideas and strategies because of the statistical and graphical representation of contributing authors and countries.

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“…Concrete is currently the second most consumed substance after water with an annual per capita production of more than 1 m 3 worldwide (Channa et al 2021). Its popularity in civil infrastructure and large construction projects such as bridges and nuclear reactors exposed to seawater has been because of availability, strength, exibility, and durability over other construction and building materials (Memon et al 2021).…”

Section: Introductionmentioning

confidence: 99%

“…As a result, alternative supplementary cementitious materials (SCMs) like y ash, ground granulated blast furnace slag, metakaolin etc. are explored (Channa et al 2021). Concrete made from OPC and SCMs is the most practical and cost-effective option (Owaid et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Long-term Performance of Nanoparticle Incorporated Eco-friendly Concrete in Natural Seawater Environment

Philip

Harilal

Anandkumar³

et al. 2021

Preprint

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The use of blended concrete has widely gained industrial importance owing to the CO2 gas emissions and carbon footprint resulting from the production of ordinary Portland cement (OPC). Despite the advancements, the deterioration of concrete structures raises a significant threat to their long term durability and service life in aggressive conditions. In this work, the long-term antifouling, strength and durability properties of a blended eco-friendly concrete with OPC, fly ash, nanoparticles, and corrosion inhibitor is evaluated in natural seawater for one year. The biofouling attachment, total viability count (TVC), mechanical strength, alkalinity and free chloride contents were measured and the results were compared with OPC concrete. A four-order reduction in the total biomass and total bacterial density is observed on the surface of the blended concrete. Further, a significantly lower chloride and water penetration depth, free chloride content, compact and smooth surface morphology devoid of cracks and high C-S-H content are observed in blended concrete, compared to the OPC concrete, after exposure in seawater for one year. From the results, it is seen that the blended concrete mix is promising for applications in seawater environments because of its superior biofouling resistance, mechanical properties and durability.

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Short-term analysis on the combined use of sugarcane bagasse ash and rice husk ash as supplementary cementitious material in concrete production

Cited by 38 publications

References 22 publications

Behavior of geomaterial composite using sugar cane bagasse ash under compressive and flexural loading

Behavior of geomaterial composite using sugar cane bagasse ash under compressive and flexural loading

Mapping Research Knowledge on Rice Husk Ash Application in Concrete: A Scientometric Review

Long-term Performance of Nanoparticle Incorporated Eco-friendly Concrete in Natural Seawater Environment

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