Mahlaba J.S., Kearsley E.P., Kruger R.A., Pretorius P.C.
University of Pretoria, Civil Engineering, Pretoria 0002, South Africa; SASOL Technology Pty (Ltd.), RandD Environmental Sciences and Engineering, P/Bag 1034, Secunda, South Africa; Richonne Consulting, Somerset Mall, P.O. Box 742, Cape Town 7137, South Africa
Mahlaba, J.S., University of Pretoria, Civil Engineering, Pretoria 0002, South Africa, SASOL Technology Pty (Ltd.), RandD Environmental Sciences and Engineering, P/Bag 1034, Secunda, South Africa; Kearsley, E.P., University of Pretoria, Civil Engineering, Pretoria 0002, South Africa; Kruger, R.A., Richonne Consulting, Somerset Mall, P.O. Box 742, Cape Town 7137, South Africa; Pretorius, P.C., SASOL Technology Pty (Ltd.), RandD Environmental Sciences and Engineering, P/Bag 1034, Secunda, South Africa
Anthropogenic pollution is an unavoidable consequence of both producing energy from coal and desalination of water. Coal ash and brines are partially utilised due to vast volumes and stringent legal environmental requirements. Therefore innovative management for these wastes is essential. This manuscript presents the initial results of research showing that brine chemistry dominates the behaviour of fly ash pastes. The outcome could expand the utilisation of brines in mortars and mass concrete to conserve potable water. The tests involved varying paste consistency and brine characteristics. The results demonstrated that chemical composition of brine plays a more important role than salinity in determining both paste rheology and strength development. An optimum brine salinity range for pastes was obtained with a specific fly ash. The results suggest that an opportunity exists for utilising industrial brines rich in Cl- and SO4= as mixing waters in the co-disposal or mine backfilling with fly ash pastes. This would reduce operational costs and liability of energy generation from coal. © 2011 Elsevier Ltd. All rights reserved.
Anthropogenic pollution; Chemical compositions; Co-disposal; Coal fly ash; Energy generations; Environmental requirement; Mass concrete; Operational costs; Paste backfill; Strength development; Water salinity; Chlorine; Coal; Coal ash; Desalination; Environmental regulations; Fly ash; Potable water; Salinity measurement; Solid wastes; Waste management; Water filtration; Brines