Abstract
The traditional Solvay process and other modifications that are based on different types of alkaline material and waste promise to be effective in the reduction of reject brine salinity and the capture of CO2. These processes, however, require low temperatures (10–20 °C) to increase the solubility of CO2 and enhance the precipitation of metallic salts, while reject brine is usually discharged from desalination plants at relatively high temperatures (40–55 °C). A modified Solvay process based on potassium hydroxide (KOH) has emerged as a promising technique for simultaneously capturing carbon dioxide (CO2) and reducing ions from reject brine in a combined reaction. In this study, the ability of the KOH-based Solvay process to reduce brine salinity at relatively high temperatures was investigated. The impact of different operating conditions, including pressure, KOH concentration, temperature, and CO2 gas flowrate, on CO2 uptake and ion removal was investigated and optimized. The optimization was performed using the response surface methodology based on a central composite design. A CO2 uptake of 0.50 g CO2/g KOH and maximum removal rates of sodium (Na+), chloride (Cl−), calcium (Ca2+), and magnesium (Mg2+) of 45.6%, 29.8%, 100%, and 91.2%, respectively, were obtained at a gauge pressure, gas flowrate, and KOH concentration of 2 bar, 776 mL/min, and 30 g/L, respectively, and at high temperature of 50 °C. These results confirm the effectiveness of the process in salinity reduction at a relatively high temperature that is near the actual reject brine temperature without prior cooling. The structural and chemical characteristics of the produced solids were investigated, confirming the presence of valuable products such as sodium bicarbonate (NaHCO3), potassium bicarbonate (KHCO3) and potassium chloride (KCl).
Highlights
The 3D plot shown in Figure 2b reveals that the maximum CO2 uptake was obtained at a maximum gas flowrate of 1600 mL/min and a low temperature of 10 ◦ C, owing to the high solubility of CO2 gas at low temperatures [1,4,8]
CO2 uptake still reached a value of up to 0.53 g CO2 /g KOH at a temperature of 30 ◦ C and a low gas flowrate of nearly 400 mL/min. This observation confirms the effect of gas flowrate on CO2 uptake, where a low gas flowrate resulted in a high residence time and high CO2 capture [4,8]
This result reflects the novelty of the inert-particle spouted bed reactor (IPSBR) [18,19,20], which can still operate under high feed-gas flowrate and achieve high
Summary
Many factors affect the performance of the combined process, such as the reaction temperature, alkaline type, and solution pH. Among these variables, temperature has the greatest impact on the process because it controls the solubility of CO2 and metal ions in the brine [1]. High temperatures have a negative effect on the solubility of CO2 and decrease the precipitation of metal ions such as sodium (Na+ ) ions, which are present in the brine at high concentrations compared with other ions such as calcium (Ca2+ ), magnesium (Mg2+ ), and chloride (Cl− ).
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