A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Investigation of the compressive strength, time lags and decrement factors of AAC-lightweight concrete containing sugar sediment waste
Highlights Improved the higher compressive strength of AAC by sugar sediment waste. Confirmed the higher ratio of tobermorite phase of AAC affected the higher strength. Extended slightly the heat transfer time lag of the optimum AAC composition. Evaluated the environmental and human impacts from landfill of sugar sediment waste. Obtained an alternative application to concrete for non-structural wall.
Abstract Sugar sediment waste was incorporated into the raw material mix for the production of Autoclaved Aerated Concrete, and was demonstrated by extensive testing to provide greater compressive strength than conventional materials, and an extended time lag. In addition, the use of this otherwise waste material was demonstrated to be highly beneficial both economically and environmentally. Sugar sediment is a waste product of the sugar refining industry in Thailand, and is available in huge quantities. The optimum composition obtained had sugar sediment content of 30% by weight replacement of sand and 7.5% by weight of lime. The resultant product showed a maximum compressive strength of around 6.1N/mm2 and the highest proportion of tobermorite phase of 28.9%. The higher strength can be confirmed by a higher crystalline tobermorite phase. The surface of the Autoclaved Aerated Concrete is a finer needle-like crystalline morphology. The Autoclaved Aerated Concrete consisting of the optimum sugar sediment content also extended the time for the heat wave to propagate from the outer wall to the inner wall. This study also considered the environmental, economic and health impacts of removing a substantial quantity of the industrial waste product from landfill sites.
Investigation of the compressive strength, time lags and decrement factors of AAC-lightweight concrete containing sugar sediment waste
Highlights Improved the higher compressive strength of AAC by sugar sediment waste. Confirmed the higher ratio of tobermorite phase of AAC affected the higher strength. Extended slightly the heat transfer time lag of the optimum AAC composition. Evaluated the environmental and human impacts from landfill of sugar sediment waste. Obtained an alternative application to concrete for non-structural wall.
Abstract Sugar sediment waste was incorporated into the raw material mix for the production of Autoclaved Aerated Concrete, and was demonstrated by extensive testing to provide greater compressive strength than conventional materials, and an extended time lag. In addition, the use of this otherwise waste material was demonstrated to be highly beneficial both economically and environmentally. Sugar sediment is a waste product of the sugar refining industry in Thailand, and is available in huge quantities. The optimum composition obtained had sugar sediment content of 30% by weight replacement of sand and 7.5% by weight of lime. The resultant product showed a maximum compressive strength of around 6.1N/mm2 and the highest proportion of tobermorite phase of 28.9%. The higher strength can be confirmed by a higher crystalline tobermorite phase. The surface of the Autoclaved Aerated Concrete is a finer needle-like crystalline morphology. The Autoclaved Aerated Concrete consisting of the optimum sugar sediment content also extended the time for the heat wave to propagate from the outer wall to the inner wall. This study also considered the environmental, economic and health impacts of removing a substantial quantity of the industrial waste product from landfill sites.
Investigation of the compressive strength, time lags and decrement factors of AAC-lightweight concrete containing sugar sediment waste
Thongtha, Atthakorn (author) / Maneewan, Somchai (author) / Punlek, Chantana (author) / Ungkoon, Yothin (author)
Energy and Buildings ; 84 ; 516-525
2014-08-18
10 pages
Article (Journal)
Electronic Resource
English
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