使用反渗透、纳滤和超滤膜去除有毒离子（铬酸盐、砷酸盐和高氯酸盐）。

Removal of toxic ions (chromate, arsenate, and perchlorate) using reverse osmosis, nanofiltration, and ultrafiltration membranes.

作者信息

Yoon Jaekyung, Amy Gary, Chung Jinwook, Sohn Jinsik, Yoon Yeomin

机构信息

Korea Institute of Energy Research, Jang-Dong, Yuseong-Gu, Daejeon, South Korea.

出版信息

Chemosphere. 2009 Sep;77(2):228-35. doi: 10.1016/j.chemosphere.2009.07.028. Epub 2009 Aug 12.

DOI:10.1016/j.chemosphere.2009.07.028

PMID:19679331

Abstract

Rejection characteristics of chromate, arsenate, and perchlorate were examined for one reverse osmosis (RO, LFC-1), two nanofiltration (NF, ESNA, and MX07), and one ultrafiltration (UF and GM) membranes that are commercially available. A bench-scale cross-flow flat-sheet filtration system was employed to determine the toxic ion rejection and the membrane flux. Both model and natural waters were used to prepare chromate, arsenate, and perchlorate solutions (approximately 100microgL(-1) for each anion) in mixtures in the presence of other salts (KCl, K(2)SO(4), and CaCl(2)); and at varying pH conditions (4, 6, 8, and 10) and solution conductivities (30, 60, and 115mSm(-1)). The rejection of target ions by the membranes increases with increasing solution pH due to the increasingly negative membrane charge with synthetic model waters. Cr(VI), As(V), and ClO(4)(-) rejection follows the order LFC-1 (>90%) > MX07 (25-95%) congruent withESNA (30-90%)>GM (3-47%) at all pH conditions. In contrast, the rejection of target ions by the membranes decreases with increasing solution conductivity due to the decreasingly negative membrane charge. Cr(VI), As(V), and ClO(4)(-) rejection follows the order CaCl(2)<KCl congruent withK(2)SO(4) at constant pH and conductivity conditions for the NF and UF membranes tested. For natural waters the LFC-1 RO membrane with a small pore size (0.34nm) had a significantly greater rejection for those target anions (>90%) excluding NO(3)(-) (71-74%) than the ESNA NF membrane (11-56%) with a relatively large pore size (0.44nm), indicating that size exclusion is at least partially responsible for the rejection. The ratio of solute radius (r(i,s)) to effective membrane pore radius (r(p)) was employed to compare ion rejection. For all of the ions, the rejection is higher than 70% when the r(i,s)/r(p) ratio is greater than 0.4 for the LFC-1 membrane, while for di-valent ions (CrO(4)(2-), SO(4)(2-), and HAsSO(4)(2-)) the rejection (38-56%) is fairly proportional to the r(i,s)/r(p) ratio (0.32-0.62) for the ESNA membrane.

摘要

对市售的1种反渗透（RO，LFC - 1）膜、2种纳滤（NF，ESNA和MX07）膜以及1种超滤（UF，GM）膜的铬酸盐、砷酸盐和高氯酸盐截留特性进行了研究。采用实验室规模的错流平板过滤系统来测定有毒离子截留率和膜通量。在存在其他盐（KCl、K₂SO₄和CaCl₂）的情况下，使用模拟水和天然水制备铬酸盐、砷酸盐和高氯酸盐溶液（每种阴离子浓度约为100μg L⁻¹）；并在不同pH条件（4、6、8和10）以及溶液电导率（30、60和115 mS m⁻¹）下进行实验。由于合成模拟水使膜表面电荷越来越负，随着溶液pH升高，膜对目标离子的截留率增加。在所有pH条件下，Cr(VI)、As(V)和ClO₄⁻的截留率顺序为LFC - 1（>90%）> MX07（25 - 95%）≈ESNA（30 - 90%）> GM（3 - 47%）。相反，由于膜表面电荷减少，随着溶液电导率升高，膜对目标离子的截留率降低。在测试的NF和UF膜的恒定pH和电导率条件下，Cr(VI)、As(V)和ClO₄⁻的截留率顺序为CaCl₂ < KCl≈K₂SO₄。对于天然水，孔径较小（0.34nm）的LFC - 1 RO膜对除NO₃⁻（71 - 74%）外的那些目标阴离子（>90%）的截留率明显高于孔径相对较大（0.44nm）的ESNA NF膜（11 - 56%），这表明尺寸排阻至少部分地导致了截留。采用溶质半径（r(i,s)）与有效膜孔径半径（r(p)）的比值来比较离子截留情况。对于所有离子，当LFC - 1膜的r(i,s)/r(p)比值大于0.4时，截留率高于70%；而对于二价离子（CrO₄²⁻、SO₄²⁻和HAsSO₄²⁻），ESNA膜的截留率（38 - 56%）与r(i,s)/r(p)比值（0.32 - 0.62）大致成比例。