The CDI (Capacitive deionization) is one of the desalination technologies that use a carbon material electrode with large surface area and excellent electrical conductivity. Recently, research on a MCDI (Membrane Capacitive deionization) process, which is a combination of an ion-exchange membrane, has been actively conducted. In this study, we tried to find out the water quality of treated water and the concentration characteristics of concentrated water through TDS analysis by MCDI conventional and circulation process. In producing treated water, there was no significant difference in adsorption efficiency between MCDI conventional and circulation process. It was confirmed that both processes adsobed more than 96 %. However, the MCDI conventional process showed a low yield of 50 %, whereas the MCDI circulation process showed a high yield of 97.6 %. It's because, the wasted water was reused at desorption. In the case of the TDS concentration using MCDI circulation process, as the cycle progressed, the TDS concentration was concentrated up to 1,300 mg/L, but the rate gradually decreased. It is believed that this is because the volume of the concentrated water tank is limited, and the amount of soluble ions gradually decreases. As a result of analyzing the wasted water at MCDI circulation process through Ion Chromatography, it was confirmed that the concentration of all ions were concentrated. However, there was no significant difference in the types and proportions of analyzed ions. It is judged that the types and concentration of ions do not have a significant effect on adsorption and desorption in the MCDI circulation process.

Recently, various researches have been studied, such as water treatment, water reuse, and seawater desalination using CDI (Capacitive deionization) technology. Also, applications like MCDI (Membrane capacitive deionization), FCDI (Flow-capacitive deionization), and hybrid CDI have been actively studied. This study tried to investigate various factors by an experiment on the TDS (Total dissolved solids) removal characteristics using MCDI module in aqueous solution. As a result of the TDS concentration of feed water from 500 to 2,000 mg/L, the MCDI cell broke through faster when the higher TDS concentration. In the case of TDS concentration according to the various flow rate, 100 mL/min was stable. In addition, there was no significant difference in the desorption efficiency according to the TDS concentration and method of backwash water used for desorption. As a result of using concentrated water for desorption, stable adsorption efficiency was shown. In the case of the MCDI module, the ions of the bulk solution which is escaped from the MCDI cell to the spacer during the desorption process are more important than the concentration of ions during desorption. Therefore, the MCDI process can get a larger amount of treated water than the CDI process. Also, prepare a plan that can be operated insensitive to the TDS concentration of backwash water for desorption.

본 연구에서는 다공성 탄소 전극의 음극과 양극 표면에 각각 양이온교환고분자(Nafion)와 음이온교환고분자 (aminated polyphenylene oxide, APPO)를 코팅하여 막 결합형 축전식 탈염(membrane capacitive deionization, MCDI) 공정에 적용하였다. 또한 위 공정의 성능을 탄소 전극만으로 구성한 축전식 탈염(capacitive deionization, CDI) 공정과 비교 평가해 보고 염 제거 효율이 최대로 나타나는 MCDI 공정의 최적 운전 조건을 탐색하고자 하였다. 염 제거 효율은 MCDI 공정이 CDI 공정에 비해 높게 나타났으며 Nafion과 APPO를 적용한 MCDI 공정에서 흡착 조건이 1.2 V, 3 min이고 탈착 조건이 -1.0 V, 1 min 일 때의 염 제거 효율이 82.1%로 최댓값을 보임을 확인했다.

막 결합형 축전식 탈염공정에서 이온교환막의 이온교환용량이 염 제거 효율에 미치는 영향을 알아보기 위해 poly(vinyl alcohol)(PVA) 수용성 고분자에 sulfosuccinic acid (SSA) 가교제를 첨가하고 poly(4-styrene sulfonic acid-co-maleic acid)(PSSA_MA)를 PVA 질량대비 10, 50, 90 wt%로 달리 첨가하여 제조하였다. PSSA_MA의 함량이 증가함에 따라 함수율과 이온교환용량이 증가하는 경향을 나타내었으며 막 결합형 축전식 탈염공정에서 염 제거 효율도 상승되었다. PSSA_MA 90 wt%, 100 mg/L NaCl의 공급액과 유속 15 mL/min에서 흡착 1.4 V/5분의 조건에서 가장 높은 65.5%의 염 제거 효율을 나타내었다.