Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material

Geopolymers have been considered a promising replacement for ordinary Portland cement (OPC) as a binding material. As geopolymers can be produced from alumina- and silica- rich industrial and agro-industrial waste materials and by-products such as blast furnace slags, mine tailings, coal ashes, etc....

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Main Author: Kalaw, Martin Ernesto L.
Format: text
Language:English
Published: Animo Repository 2021
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Online Access:https://animorepository.dlsu.edu.ph/etd_doctoral/1411
https://animorepository.dlsu.edu.ph/cgi/viewcontent.cgi?article=2402&context=etd_doctoral
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Institution: De La Salle University
Language: English
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spelling oai:animorepository.dlsu.edu.ph:etd_doctoral-24022022-04-12T02:11:34Z Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material Kalaw, Martin Ernesto L. Geopolymers have been considered a promising replacement for ordinary Portland cement (OPC) as a binding material. As geopolymers can be produced from alumina- and silica- rich industrial and agro-industrial waste materials and by-products such as blast furnace slags, mine tailings, coal ashes, etc., geopolymer technology has a great potential for environmental management of these types of wastes towards closing the loop in a circular economy. Further, the geopolymerization process has characteristic lower emissions and lower energy consumption vis- à-vis OPC which translates to positive environmental initiatives. In this study, the ternary mixture of the alumina- silica- rich materials coal fly ash, coal bottom ash and rice husk ash was evaluated for developing low heat transmission and fire resistant materials. Conventional geopolymer formulations use mainly coal fly ash with the coal bottom ash usually relegated to the ash ponds/ landfills. But in this study, coal bottom ash has been shown as a significant combining element in the geopolymer mixture. The rice husk ash being light and having very low thermal conductivity was able to pull lower both the heat transmissibility and volumetric weight of the resulting geopolymer. Via optimization using response surface methodology (RSM) with desirability functions, an optimum ternary mixture of 85% coal fly ash - 10% coal bottom ash - 5% rice husk ash met the performance requirements of OPC concrete according to ASTM standards for lightweight, low heat transmission, medium load masonry applications. Fire resistance tests based on ASTM E119 show better performance than similar samples of OPC specimens. Also, environmental impact analysis via embodied energy and CO2 estimation obtained 63% reduction in embodied energy and 84% reduction in embodied CO2 vis-à-vis OPC. The study has thus presented two main elements: (1) the development of a lightweight, low heat transmission, and fire-resistant material and (2) a waste management option for coal ashes and rice husk waste. 2021-01-01T08:00:00Z text application/pdf https://animorepository.dlsu.edu.ph/etd_doctoral/1411 https://animorepository.dlsu.edu.ph/cgi/viewcontent.cgi?article=2402&context=etd_doctoral Dissertations English Animo Repository Waste products as building materials Fire resistant materials Coal ash Rice hulls Mechanical Engineering
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
language English
topic Waste products as building materials
Fire resistant materials
Coal ash
Rice hulls
Mechanical Engineering
spellingShingle Waste products as building materials
Fire resistant materials
Coal ash
Rice hulls
Mechanical Engineering
Kalaw, Martin Ernesto L.
Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
description Geopolymers have been considered a promising replacement for ordinary Portland cement (OPC) as a binding material. As geopolymers can be produced from alumina- and silica- rich industrial and agro-industrial waste materials and by-products such as blast furnace slags, mine tailings, coal ashes, etc., geopolymer technology has a great potential for environmental management of these types of wastes towards closing the loop in a circular economy. Further, the geopolymerization process has characteristic lower emissions and lower energy consumption vis- à-vis OPC which translates to positive environmental initiatives. In this study, the ternary mixture of the alumina- silica- rich materials coal fly ash, coal bottom ash and rice husk ash was evaluated for developing low heat transmission and fire resistant materials. Conventional geopolymer formulations use mainly coal fly ash with the coal bottom ash usually relegated to the ash ponds/ landfills. But in this study, coal bottom ash has been shown as a significant combining element in the geopolymer mixture. The rice husk ash being light and having very low thermal conductivity was able to pull lower both the heat transmissibility and volumetric weight of the resulting geopolymer. Via optimization using response surface methodology (RSM) with desirability functions, an optimum ternary mixture of 85% coal fly ash - 10% coal bottom ash - 5% rice husk ash met the performance requirements of OPC concrete according to ASTM standards for lightweight, low heat transmission, medium load masonry applications. Fire resistance tests based on ASTM E119 show better performance than similar samples of OPC specimens. Also, environmental impact analysis via embodied energy and CO2 estimation obtained 63% reduction in embodied energy and 84% reduction in embodied CO2 vis-à-vis OPC. The study has thus presented two main elements: (1) the development of a lightweight, low heat transmission, and fire-resistant material and (2) a waste management option for coal ashes and rice husk waste.
format text
author Kalaw, Martin Ernesto L.
author_facet Kalaw, Martin Ernesto L.
author_sort Kalaw, Martin Ernesto L.
title Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
title_short Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
title_full Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
title_fullStr Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
title_full_unstemmed Development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
title_sort development of a ternary blend geopolymer from coal fly ash, coal bottom ash and rice husk for low heat transmission and fire resistant material
publisher Animo Repository
publishDate 2021
url https://animorepository.dlsu.edu.ph/etd_doctoral/1411
https://animorepository.dlsu.edu.ph/cgi/viewcontent.cgi?article=2402&context=etd_doctoral
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