Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Sustainability perspective of marble and granite residues as concrete fillers
Highlights We tested the mechanical properties of three marble and granite residues (MGRs). MGRs are added as a sustainable replacement for cement. 5% Replacement does hardly affect the mechanical performance and rheology. Numerical analysis shows a strong correlation between amount of MGR and strength.
Abstract Huge amounts of mud and other residues are yearly being produced by various countries as a waste product by the marble and granite (MGR) industry, causing serious threats to the environment, polluting soil and water, and when dry, turning into a fine dust that is harmful to the population. At this moment, most of the MGR waste is landfilled and alternative solutions are being explored in many countries with the aim to turn MGR waste into a sustainable material. In this article, the applicability of MGR as a sustainable alternative for cement replacement is investigated, specifically for such residues created in Brazil. Compressive strength, elastic modulus and water absorption tests are conducted to examine the mechanical performance of concrete containing MGR. Chemical analysis and particle size distribution showed that MGR is a non-reactive material and may act as a filler. A numerical analysis has been performed with the objective to calculate the contact area between the expanding outer shell of the hydrating cement particles and the surface of the MGR fillers. The analysis showed a strong correlation with the contact area and also confirmed that MGR can be used as a sustainable replacement for cement.
Sustainability perspective of marble and granite residues as concrete fillers
Highlights We tested the mechanical properties of three marble and granite residues (MGRs). MGRs are added as a sustainable replacement for cement. 5% Replacement does hardly affect the mechanical performance and rheology. Numerical analysis shows a strong correlation between amount of MGR and strength.
Abstract Huge amounts of mud and other residues are yearly being produced by various countries as a waste product by the marble and granite (MGR) industry, causing serious threats to the environment, polluting soil and water, and when dry, turning into a fine dust that is harmful to the population. At this moment, most of the MGR waste is landfilled and alternative solutions are being explored in many countries with the aim to turn MGR waste into a sustainable material. In this article, the applicability of MGR as a sustainable alternative for cement replacement is investigated, specifically for such residues created in Brazil. Compressive strength, elastic modulus and water absorption tests are conducted to examine the mechanical performance of concrete containing MGR. Chemical analysis and particle size distribution showed that MGR is a non-reactive material and may act as a filler. A numerical analysis has been performed with the objective to calculate the contact area between the expanding outer shell of the hydrating cement particles and the surface of the MGR fillers. The analysis showed a strong correlation with the contact area and also confirmed that MGR can be used as a sustainable replacement for cement.
Sustainability perspective of marble and granite residues as concrete fillers
Bacarji, E. (Autor:in) / Toledo Filho, R.D. (Autor:in) / Koenders, E.A.B. (Autor:in) / Figueiredo, E.P. (Autor:in) / Lopes, J.L.M.P. (Autor:in)
Construction and Building Materials ; 45 ; 1-10
04.03.2013
10 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Granite , Marble , Residues , Concrete , Sustainability
Sustainability perspective of marble and granite residues as concrete fillers
| British Library Online Contents | 2013
Sustainability perspective of marble and granite residues as concrete fillers
| Online Contents | 2013
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