Abstract
Coal mine waters often have high salinity, hardness and alkalinity. The treatment of coal mine water requires careful management of multi-stage reverse osmosis (RO) systems to achieve effective recovery of water for domestic reuse, as well as zero liquid discharge to minimise the impact to the local environment. Design of RO systems for coal mine water treatment has been limited to the use of commercial design packages provided by membrane manufacturers, which do not provide insights into the impact of operating parameters such as feedwater salinity, concentrations of sparingly soluble salts, feed pressure and their interactions with different RO modules on the fouling/scaling potential of RO membranes. This also restricts the use of novel RO products and the delivery of an optimum design based on real needs. In this work, a mathematical model was developed to simulate a standard brackish water RO pressure vessel consisting six full-size RO membrane elements, using computational fluid dynamics (CFD). The model can be used to predict the permeate flowrate, water recovery levels, as well as the spatial information of the accumulation and scaling potential of sparingly soluble salts on the membrane surface. The results obtained from the model showed good agreement with the results obtained from the commercial RO design software WAVE. The CFD model was then used to predict the scaling threshold on various positions of a full-scale RO element, at different operating conditions, using parametric simulations based on Central Composite Designs. Outputs from this work not only provide insights into the microscopic flow characteristics of multiple full-scale elements in the RO pressure vessel, but also predicts the position where scaling would occur, at different feed conditions, for any RO products.
Highlights
Reverse osmosis (RO) is a process of separating solutes from liquid streams by applying external pressure to overcome the osmotic pressure of the solutes on the membrane, and has been widely used in desalination, pure water production, industrial wastewater treatment and water reclamation [1,2]
The concentration of calcium increased from 31.1 mg/L at the feed inlet to 49.9 mg/L
−0.96, indicating that calcium sulphate will not form a scale in the first stage of brackish water reverse osmosis (BWRO)
Summary
Reverse osmosis (RO) is a process of separating solutes from liquid streams by applying external pressure to overcome the osmotic pressure of the solutes on the membrane, and has been widely used in desalination, pure water production, industrial wastewater treatment and water reclamation [1,2]. The water recovery level from brackish water desalination using RO processes can be up to 60%–95%, which is a critical operating parameter determining the cost effectiveness of the process. The higher the recovery, the higher the concentrations of inorganic salts that could potentially accumulate on the feed side of the membranes, leading to a more severe concentration polarization (CP) phenomenon and membrane scaling [3,4]. Coal mine waters usually contain complex inorganic salts with high total dissolved solids (TDS) and high hardness [5,6]. Most coal mine water shows an alkaline pH [7]
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