Utilization of Co-Fired Blended Ash and Chopped Basalt Fiber in the Development of Sustainable Mortar

Shelote, Kunal; Gavali, Hindavi R.; Brás, Ana; Ralegaonkar, Rahul V.

doi:10.3390/su13031247

Cited by 11 publications

(6 citation statements)

References 38 publications

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“…As the source being the same, the material was found consistent with its properties even though acquired through various seasons. The products like bricks (Ram, Ralegaonkar and Pradhan, 2017), mortar (Shelote et al, 2021), concrete (Chippagiri et al, 2021), and alkali-activated masonry products (Gavali et al, 2019) were developed earlier. The design of modular prefabricated construction elements using CFA is aimed in the present study.…”

Section: Methodsmentioning

confidence: 99%

Development of sustainable prefabricated housing system by small-scale experimental model

Chippagiri

Brás

Ralegaonkar

2023

Proceedings of the Institution of Civil Engineers - Engineering

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Utilisation of unused industrial wastes and need for rapid volumetric construction led to the evolution of sustainable prefabricated housing elements, particularly for urban slums. An agro-industrial by-product as raw material and waste expanded polystyrene beads as the insulation material are chosen to develop a lightweight prefabricated construction element. This bio-ash is used as a partial replacement, 20% and 10% for the fine aggregates to prepare concrete and lightweight mix respectively. A small-scale model of one-third scale is conceptualised as per standards that include precast columns and beams as framed structure, and prefab panels as walling and roofing elements. These elements are developed as per the desired mix proportions of the identified raw materials. The respective laboratory specimens are evaluated for the physico-mechanical, durability, and thermal properties. The developed walling end-product is found to be 27% lighter, 8% stronger, 24% less water-absorbent, and 62% less conductive when compared with the properties of commercially available fly-ash brick. A solar photovoltaic panel is embedded into the model’s pitch roof that accommodates 71% of its generated energy to necessary electrical appliances. The material properties are found to be satisfactory for its on-site application and its final erection being 20% faster than conventional method.

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Section: Methodsmentioning

confidence: 99%

Development of sustainable prefabricated housing system by small-scale experimental model

Chippagiri

Brás

Ralegaonkar

2023

Proceedings of the Institution of Civil Engineers - Engineering

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“…The nanoparticles operate as nuclei for cement, speeding up the hydration process and densifying the microstructure as well as interfacial transition zone (ITZ), thus lowering permeability [46]. While in alkali activation process, the FA is mixed with various binder mixes such as GGBS, palm oil fuel ash, rice husk ash, and silica fume, and activated using AAM such as NaOH [24,47,48]. Best temperature endurance was witnessed in the binder mix containing 75% of GGBS and 25% of FA, and with complete replacement of natural coarse aggregate by ferro chrome slag (FCS) [25].…”

Section: Fly Ashmentioning

confidence: 99%

Agro-industrial-based wastes as supplementary cementitious or alkali-activated binder material: a comprehensive review

Blesson

Rao

2023

Innov. Infrastruct. Solut.

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An attempt to shed light on the use of agro-industrial-based wastes as supplementary cementitious material (SCM) or as alkali-activated binder (AAB) material is mainly focused in this review paper. The SCM or AAB acts as a suitable replacement for cement, as the cement manufacturing tends to contribute to 8–10% of global CO2 emissions. To gain acceptability in the construction industry, diverse agro-industrial-based wastes must demonstrate their potential as precursors in AAB or as SCM. The binder materials discussed among the agricultural wastes are rice husk ash, olive waste ash, and coconut-based waste ash, and the industrial wastes are ground granulated blast furnace slag, fly ash, and ultra-fine steel slag. The paper also analyses the effects of calcined and uncalcined agro-industrial-based wastes on pozzolanic properties of binder system. It is clear from the studies that the calcined wastes tend to provide greater reactivity compared to the uncalcined wastes, that helps in early strength development in the binder system. The review findings indicate that the agro-industrial-based wastes provide pozzolanic and hydraulic properties, thereby making them suitable as an AAB or as a SCM.

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“…Many agro-industrial and construction wastes were used as alternative raw materials in earlier mix designs. Some of these alternates are fly ash, furnace slag [17], recycled paper-mill waste [18], briquette ash [19], blended ash [20][21][22], and construction and demolition wastes [23,24]. The physicomechanical and functional test results of the novel end products were better in comparison with commercially available products.…”

Section: Introductionmentioning

confidence: 99%

Performance Evaluation of a Sustainable Prefabricated System Using Small-Scale Experimental Model Technique

et al. 2022

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The increasing urban population requires rapid housing construction. Rising global temperatures have led to more space cooling options inside buildings. There is a need to design new-age buildings with a sustainable, thermal comfort, and energy-efficiency approach. The present work integrates this approach into the design of prefabricated elements. Locally available co-fired ash, along with other sustainable alternates, are used in developing these elements. This study involves a performance evaluation and feasibility assessment of the proposed prefabricated system. A small-scale model house of one-third size is constructed using these elements for the purpose of functional evaluation. An average temperature variation of approximately 4 °C is observed upon comparison with the fly-ash brick model during the peak summer season. During energy assessment, a 12% and 52% decrease in embodied energy and peak cooling loads were observed. The time study resulted in 20% time savings over the conventional technique. The proposed system also includes a solar photo-voltaic panel, which compensates for 30% of the energy demand and reduces approximately 42% of the energy cost. Thus, the developed prefabricated system is found suitable for non-load bearing as well as functional applications. The performed studies determined the system to be sustainable, lightweight, quick, as well as energy efficient.

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Utilization of Co-Fired Blended Ash and Chopped Basalt Fiber in the Development of Sustainable Mortar

Cited by 11 publications

References 38 publications

Development of sustainable prefabricated housing system by small-scale experimental model

Development of sustainable prefabricated housing system by small-scale experimental model

Agro-industrial-based wastes as supplementary cementitious or alkali-activated binder material: a comprehensive review

Performance Evaluation of a Sustainable Prefabricated System Using Small-Scale Experimental Model Technique

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