화학공학소재연구정보센터
Desalination, Vol.351, 27-36, 2014
Exploration of the fundamental equilibrium behaviour of calcium exchange with weak acid cation resins
This study evaluated the complexity of calcium ion exchange with sodium exchanged weak acid cation resin (DOW MAC-3). Exchange equilibria recorded for a range of different solution normalities revealed profiles which were represented by conventional "L" or "H" type isotherms at low values of equilibrium concentration (C-e) of calcium ions, plus a superimposed region of increasing calcium uptake was observed at high C-e values. The loading of calcium ions was determined to be ca. 53.5 to 58.7 g/kg of resin when modelling only the sorption curve created at low C-e values, which exhibited a well-defined plateau. The calculated calcium ion loading capacity for DOW MAC-3 resin appeared to correlate with the manufacturer's recommendation. The phenomenon of super equivalent ion exchange (SEIX) was observed when the "driving force" for the exchange process was increased in excess of 2.25 mmol calcium ions per gram of resin in the starting solution. This latter event was explained in terms of displacement of sodium ions from sodium hydroxide solution which remained in the resin bead following the initial conversion of the as supplied "H+" exchanged resin sites to the "Na+" version required for softening studies. Evidence for hydrolysis of a small fraction of the sites on the sodium exchanged resin surface was noted. The importance of carefully choosing experimental parameters was discussed especially in relation to application of the Langmuir-Vageler expression. This latter model which compared the ratio of the initial calcium ion concentration in solution to resin mass, versus final equilibrium loading of the calcium ions on the resin; was discovered to be an excellent means of identifying the progress of the calcium-sodium ion exchange process. Moreover, the Langmuir-Vageler model facilitated standardization of various calcium-sodium ion exchange experiments which allowed systematic experimental design. (C) 2014 Elsevier B.V. All rights reserved.