OBIGGS에서는 대기 중의 미량의 오존이 고분자 분리막의 손상을 가져오기 때문에 전단에 오존 제거장치를 설치하여 분리막에 전해지는 기체에서 오존의 농도를 감소시켜 분리막의 손상을 막고 있다. 본 연구에서는 OBIGGS용 기체 분리막을 이용하여 오존 노출시간에 따른 인장강도와 기체투과특성을 평가하여 오존 노출환경과 투과특성의 관계를 확인하였다. 폴리이미드계와 폴리설폰계 두 종류의 중공사 분리막을 이용하였고, 6.37 cm2의 유효 막 면적을 가지는 중공사 모듈을 제조하여 사용하였다. 오존 챔버를 이용하여 오존의 농도를 2-3 ppm으로 유지하였으며, 챔버 내의 기체를 펌프를 이용하여 모듈내로 지속적으로 공급하였으며, 오존 노출시간에 따라서 기체투과특성과 인장강도를 각각 평가하였다. 그 결과 폴리이미드계 중공사 분리막은 투과도에서 20%의 감소만 나타났을 뿐, 선택도와 인장강도에서 다른 큰 변화를 나타내지 않고 균일하게 유지되는 것을 확인하였다. 하지만 폴리설폰계 중공사 분리막을 사용하였을 때는 투과도가 80% 이상 감소하였고, 인장강도는 70% 이상 감소하는 결과를 나타내었다.

In this study, we prepared thin composite membranes in which a support layer and a selective layer are covalently bonded in a simple method. The graft polymerization was carried out using UV/Ozone on a commercial Poly(sulfone) ultrafiltration membrane with Poly((ethylene glycol) methyl ether methacrylate) (PEGMA) possessing CO2 affinity. As a result, nano-pores on the surface membrane were covered with PEGMA. The covalent bonding of the composite membranes has the advantage of improving stability and weatherability. In addition, due to the thin selective layer formed by the graft polymerization, highly gas permeation characteristics are exhibited, and efficient process performance can be expected. The final composite membranes were investigated in terms of their chemical structures and elements, and gas permeation properties.

In this study, we prepared thin composite membranes in which a support layer and a selective layer are covalently bonded in a simple method. The graft polymerization was carried out using UV/Ozone on a commercial Poly(sulfone) (PSf) ultrafiltration membrane with Poly((ethylene glycol) methyl ether methacrylate) (PEGMA) possessing CO2affinity. As a result, nano-pores on the surface membrane were covered with PEGMA. The covalent bonding of the composite membranes has the advantage of improving stability. In addition, due to the thin selective layer formed by the graft polymerization, highly gas permeation characteristics are exhibited, and efficient process performance can be expected. The final composite membranes were investigated in terms of their chemical structures and elements, morphology, and gas permeation properties.

A method of functionalization of multi-walled carbon nanotube (MWNT) at room temperature using dry ozone gas is described. The resulting MWNT were characterized by Fourier transform infrared, x-ray photoelectron spectroscopy, and scanning electron microscopy. Combined to these analyses and solubility in liquids, it could be concluded that the dry ozone gas exposure introduces polar functional groups such as carboxylic groups to MWNT similar to acidic modification of MWNT. Particularly, the stable dispersion of MWNT in water after ozone treatment above a critical level could be obtained, implying potential bio-application. The hydrophilic functional groups on the MWNT introduced by ozone oxidation were helpful in improving the interaction with functional groups in PA6 such as -NH2 and -CONH- resulting in improved mechanical properties.

상용 고분자막으로 많이 사용되는 Polysulfone(PSF)을 오존으로 처리하여 기체의 투과 및 분리특성을 조사하였다. 고분자막의 오존처리는 chamber 내부에 막을 설치하고 약 5vol.%의 오존을 포함한 산소를 chamber에 연속적으로 공급하면서 일정시간 동안 오전처리를 수행하였다. PSF막의 선택도는 오존처리시간에 따라 증가하였으며 적정 오존처리 시간은 1.5시간이면 충분한 것으로 조사되었다. 그리고, 오존처리에 의한 He/N2, H2/N2, O2/N2, CO2/CH4등의 선택도의 증가는 분자크기가 큰 N2나 CH4의 투과도의 감소에 기인하며 분자크기가 작은 기체의 투과도의 감소는 매우 작은 것으로 나타났다. 오존처리에 의한 선택도의 증가는 오존이 PSF 고분자를 부분적으로 산화시키고 이때 생성된 산소복합체들이 PSF의 자유부피를 감소시키기 때문으로 생각된다.

The purpose of this study was to develop a recycling system for ozone off-gas. Although the ozone transmission rate of the injector method differs slightly depending on the ozone injection rate, it reaches approximately 99%, which is very high. During the increase in water inflow to the ozone recycling system from 2 L/min to 10 L/min, the average ozone recycling rate was 99.4% at a 1 ppm ozone injection rate, 98.6% at a 2 ppm ozone injection rate, 98.1% at a 3 ppm ozone injection rate. Ozone treatment facility operating costs can be divided into the costs of pure oxygen production, ozone production, and maintenance. The annual operating costs of ozone treatment facilities in Korea are estimated to be approximately 38.9 billion won. The annual savings are estimated to be approximately 5.8 billion won when the ozone transfer rate of the diffuser method, which is mostly employed in domestic water treatment plants, is 85% and 15% of the ozone is recycled.