Your search keyword '"Tero Luukkonen"' showing total 2 results

1. Sustainable batching water options for one-part alkali-activated slag mortar: Sea water and reverse osmosis reject water.

Author

Tero Luukkonen, Juho Yliniemi, Paivo Kinnunen, and Mirja Illikainen

Subjects

Medicine, Science

Abstract

Concrete production is globally a major water consumer, and in general, drinking-quality water is mixed in the binder. In the present study, simulated sea water and reverse osmosis reject water were used as batching water for one-part (dry-mix) alkali-activated blast furnace slag mortar. Alkali-activated materials are low-CO2 alternative binders gaining world-wide acceptance in construction. However, their production requires approximately similar amount of water as regular Portland cement concrete. The results of the present study revealed that the use of saline water did not hinder strength development, increased setting time, and did not affect workability. The salts incorporated in the binder decreased the total porosity of mortar, but they did not form separate phases detectable with X-ray diffraction or scanning electron microscopy. Leaching tests for monolithic materials revealed only minimal leaching. Furthermore, results for crushed mortars (by a standard two-stage leaching test) were within the limits of non-hazardous waste. Thus, the results indicated that high-salinity waters can be used safely in one-part alkali-activated slag to prepare high-strength mortars. Moreover, alkali-activation technology could be used as a novel stabilization/solidification method for reverse osmosis reject waters, which frequently pose disposal problems.

Published

2020

2. Sustainable batching water options for one-part alkali-activated slag mortar: Sea water and reverse osmosis reject water

Author

Juho Yliniemi, Mirja Illikainen, Tero Luukkonen, and Paivo Kinnunen

Subjects

Osmosis, Salinity, Compressive Strength, 0211 other engineering and technologies, Marine and Aquatic Sciences, 02 engineering and technology, Alkalies, Wastewater, Physical Chemistry, law.invention, X-Ray Diffraction, law, Materials Physics, 021105 building & construction, Leaching (agriculture), Materials, Microstructure, Multidisciplinary, Waste management, Sulfates, Physics, Slag, 021001 nanoscience & nanotechnology, 6. Clean water, Chemistry, visual_art, Physical Sciences, Cements, visual_art.visual_art_medium, Medicine, 0210 nano-technology, Porosity, Research Article, Science, Materials Science, Material Properties, Industrial Waste, Coal Ash, Chlorides, Sea Water, Binders, Seawater, Reverse osmosis, Construction Materials, Ecology and Environmental Sciences, Chemical Compounds, Water, Aquatic Environments, Saline water, Marine Environments, Portland cement, Chemical Properties, Ground granulated blast-furnace slag, Microscopy, Electron, Scanning, Earth Sciences, Environmental science, Composite Materials, Salts, Mortar, Filtration, Concrete

Abstract

Concrete production is globally a major water consumer, and in general, drinking-quality water is mixed in the binder. In the present study, simulated sea water and reverse osmosis reject water were used as batching water for one-part (dry-mix) alkali-activated blast furnace slag mortar. Alkali-activated materials are low-CO2 alternative binders gaining world-wide acceptance in construction. However, their production requires approximately similar amount of water as regular Portland cement concrete. The results of the present study revealed that the use of saline water did not hinder strength development, increased setting time, and did not affect workability. The salts incorporated in the binder decreased the total porosity of mortar, but they did not form separate phases detectable with X-ray diffraction or scanning electron microscopy. Leaching tests for monolithic materials revealed only minimal leaching. Furthermore, results for crushed mortars (by a standard two-stage leaching test) were within the limits of non-hazardous waste. Thus, the results indicated that high-salinity waters can be used safely in one-part alkali-activated slag to prepare high-strength mortars. Moreover, alkali-activation technology could be used as a novel stabilization/solidification method for reverse osmosis reject waters, which frequently pose disposal problems.

Published

2020