2020
DOI: 10.1016/j.conbuildmat.2019.117486
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Gainful utilization of waste glass for production of sulphuric acid resistance concrete

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Cited by 30 publications
(19 citation statements)
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“…Such Si and Al-rich gel might act as a barrio to stop further corrosion. Furthermore, Bisht [75] found that the reaction between waste glass and sulfuric acid could form sodium sulfate, which prevented the decomposition of cementitious materials. Meanwhile, 21 % of sand replaced with waste glass Journal of Asian Concrete Federation, Vol.…”
Section: Siliceous or Aluminosilicates Materials And Crumb Rubbermentioning
confidence: 99%
“…Such Si and Al-rich gel might act as a barrio to stop further corrosion. Furthermore, Bisht [75] found that the reaction between waste glass and sulfuric acid could form sodium sulfate, which prevented the decomposition of cementitious materials. Meanwhile, 21 % of sand replaced with waste glass Journal of Asian Concrete Federation, Vol.…”
Section: Siliceous or Aluminosilicates Materials And Crumb Rubbermentioning
confidence: 99%
“…This paper was cited in publications on the preparation of glass-containing foams from geopolymers [122] and vitrified MSWI bottom ash [123] in which the formation of wollastonite and the freezing of the microstructural evolution were mentioned. Other papers cited this publication with respect to the recycling of glass waste into foam glass [124][125][126][127][128][129], porous waste glass for lead removal in wastewater treatment [130], lead stabilization through alkali activation and sintering of Pb-bearing sludge [131], utilization of waste glass for the production of sulphuric acid resistant concrete [132], mechanical and alkali activation of MSWI fly and bottom ashes for the production of low-range alkaline cement [133] and foam glass-ceramics [134], inorganic gel casting for manufacturing of boro-alumino-silicate glass foams [135], porous glass-ceramics derived from MgO-CuO-TiO 2 -P 2 O 5 glasses [136], alkali activation of coal and biomass fly ashes [137], nickel-based catalysts for steam reforming of naphthalene utilizing MSW gasification slag as support [138], production of porous glass ceramics from titanium mine tailings and waste glass [139], porous bioactive glass microspheres [140], Al-SiO 2 composites [141], glass-ceramic foams from alkali-activated vitrified MSWI bottom ash and waste glasses [142]. Another study used vitrified MSWI bottom ash as input material to obtain similar porous glass ceramics [143] and was cited by some of the publications that also cited the first study.…”
Section: Sintering Of Glass-ceramicsmentioning
confidence: 99%
“…They found, according to the analysis of the mechanical properties, degree of reaction and microstructure of alkali-activated fly ash, that the dissolved waste glass silicate by the NaOH solution had a substantial impact on the composition of the geopolymerisation reaction. Other studies demonstrated that usage of waste glass in concrete enhances its acid resistance as well as its physical and mechanical properties [29,30]. In contrast the addition of waste glass reduces the plasticity of the fresh paste, thereby reduce its workability, thus a super-plasticizer is needed [31].…”
Section: Geopolymersmentioning
confidence: 99%
“…Several studies demonstrated that usage of glass waste in concrete enhances its acid resistance as well as its physical and mechanical properties. Bisht et al [29] have used waste of glassy materials made of soda lime to produce acid resistance concrete. They have shown that the best optimized performance in terms of compressive strength and acid resistance can be obtained by substituting up to 21% of sand by glass waste.…”
Section: Wall Coating Materials With Anti-corrosion and Anti-leakage Propertiesmentioning
confidence: 99%