Enhancement of Membrane Performance through Surface Hydrophilization of Hydrophobic Porous Flat-sheet Membranes
Kim B, Lee H, Lee B, Kim S, Cheong SI, Rhim JW
소수성 다공성 평막의 표면 친수화를 통한 막성능 향상
김백암, 이학민, 이보성, 김성표, 정성일, 임지원
Abstract
In order to enhance water permeability through the improvement of fouling phenomena and
wettability of hydrophobic porous membranes, various adsorption materials, i.e., pol (vinyl amine), poly (styrene sulfonic acid), poly(vinyl sulfonic acid), and poly(acrylamide-co-acrylic acid) were adsorbed onto the surface of polyethylene (PE) porous membrane. The concentration of adsorption solutions, adsorption time, the sort of salts and their ionic strength were varied, and the pure water permeability of their resulting adsorbed membranes was measured. In general, water permeability increased with an initial increase in the concentration of adsorption solution, adsorption time, and ionic strength and then decreased with a further increase. The pure water permeability of 375 L/m2h(LMH), 35% enhancement, was obtained at a condition of poly(vinyl sulfonic acid) 1000 ppm, Mg(NO3)2 ionic strength(IS) 0.1, and adsorption time 150 sec, while the 50% (411 LMH) and 35% (374 LMH) enhancements were obtained at conditions of poly(styrene sulfonic acid) 1000 ppm, adsorption time 60 sec, and NaCl IS 0.1 and 0.2, respectively.
소수성 막의 파울링 현상 개선, 젖음성 향상을 통한 투과도 증가 등을 위하여 poly(vinyl amine), poly(styrene sulfonic acid), poly(vinyl sulfonic acid), 그리고 poly(acrylamide-co-acrylic acid) 등의 다양한 흡착소재를 polyethylene (PE) 다공성막 표면에 흡착용액 농도, 흡착시간, 염의 종류, 이온세기 등을 변화시키면서 순수 투과도를 측정하였다. 일반적으로 흡착용액의 농도, 흡착시간, 그리고 이온세기가 증가하면 투과도는 초기에 증가하다가 감소하는 경향을 보였다. Poly(vinyl sulfonic acid) 1000 ppm, Mg(NO3)2의 이온세기 0.1, 그리고 흡착시간 150초 조건에서 순수 투과도가 35% 향상된 375 L/m2h(LMH)를 얻었으며, poly(styrene sulfonic acid) 1000 ppm, NaCl의 이온세기 0.1과 0.2, 그리고 흡착시간 60초에서 각각 50%(411 LMH), 35%(374 LMH)의 순수 투과도 증가율을 보였다.
11. Li N, Liu ZZ, Xu SG, J. Membr. Sci., 169(1), 17 (2000)
12. Kang GD, Liu M, Lin B, Cao YM, Yuan Q, Polymer, 48(5), 1165 (2007)
13. Ward WJ, McCarthy TJ, in Encyclopedia of Polymer Science and Engineering, 2nd ed., Mark HF, Bikales NM, Overberger CG, Menges G, Kroschwitz JI, Editors,John Wiley and Sons, New York, Suppl. Vol., p 674 (1989)
14. Kozlov M, Quarmyne M, Chen W, McCarthy TJ, Macromolecules, 36(16), 6054 (2003)
15. Serizawa T, Kamimura S, Kawanishi N, Akashi M, Langmuir, 18(22), 8381 (2002)