Evaluation of quantitative performance of the membrane filtration-differential mobility analyzer (MF-DMA) counting technique to determine suspended particles and dissolved solids in water

Abstract

Suspended particles and dissolved solids in seawater during desalination process have been known to cause colloidal fouling in membranes. The membrane filtration-differential mobility analyzer (MF-DMA) counting technique has been developed to quantify suspended nanoparticles and dissolved solids in water in real time. Various types of suspended particles (PSL, CaCO(3), and MgCO(3)) and dissolved solids (artificial seawater, NaCl, KCl, MgCl(2), and CaCl(2)) were used to evaluate the MF-DMA method. By using PSL particles of known sizes and numbers in water, a linear relationship between particle number concentrations in air (particles/cm(3)) and in water (particles/ml) was established, which was valid independent of particle size. This relationship was used to determine number concentrations of CaCO(3) and MgCO(3) particles in water, showing good agreements with the calculated values within similar to 19%. By using artificial seawater, a linear relationship between mass concentration of dissolved solids in air (mu g/m(3)) and in water (ppm) was also found. Mass concentrations of dissolved solids (NaCl, KCl, CaCl(2), and MgCl(2)) in water estimated by the MF-DMA method were in good agreements with those measured with the TDS meter within similar to 15%. The current real time technique can be applied to monitor both suspended particles and dissolved solids in pretreated seawater during RO membrane desalination process.