6533b82efe1ef96bd1293183
RESEARCH PRODUCT
Physical and mechanical properties of sustainable hydraulic mortar based on marble slurry with waste glass
Carmelo SanfilippoD. BadagliaccoAntonino ValenzaBartolomeo Megnasubject
Glass recyclingMaterials sciencePozzolanic aggregates0211 other engineering and technologies02 engineering and technologyManagement Monitoring Policy and LawRaw materialengineering.material021105 building & constructionGE1-350General Materials Science021108 energyWaste Management and DisposalLimeMetallurgyHydraulic limeRecycled glassPozzolanEnvironmental sciencesCompressive strengthHydraulic mortarsengineeringSlurryMarble slurryWaste materialsMortardescription
This paper aims to propose and characterize a sustainable hydraulic mortar entirely obtained by the reuse of waste materials, with marble slurry coming from quarries in the north-western Sicily and glass powder coming from a waste collection plant in Marsala (Province of Trapani). The first was used as raw material to produce the mortar binder by a kilning and slaking process, while the second was used as a pozzolanic additive. The chemical and morphological characterization of the marble slurry was done by XRD, FTIR, STA and SEM analyses. Glass powder was analyzed through particle size distribution measurements, XRD and standard pozzolanic tests. Hydraulic mortars constituted by slaked lime from kilned marble slurry and waste glass powder (LGS) were prepared beside commercial Natural Hydraulic Lime (NHL) based mortars (NGS) and air-hardening lime (LSS)-based mortars. Mechanical and absorption properties of the mortars were investigated as a function of the grain size of the glass powder by means of three-point bending and compressive strength tests, capillary uptake, helium pycnometry and simultaneous thermal analysis. The results demonstrated that the formulation LGS exhibits significantly improved mechanical and absorption properties compared to air-hardening mortars (LSS). It confirms the possibility of producing a more sustainable hydraulic mortar exclusively from waste materials for civil engineering.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-06-09 |