이온교환막은 수용액중의 양이온 및 음이온을 선택적으로 분리할 수 있는 이온선택성 막으로서 기본적 개념, 실직적 응용 분야, 기술적 적절성 등에 있어서 다양한 공정들에 폭넓게 사용되어지고 있다. 이온교환막을 응용한 공정은 최근 저가·고효율 이온교환막의 개발로 경제적이며 친환경적인 분리 공정으로 주목받고 있다. 이온교환막을 이용한 분리 공정은 초순수 제조, 이온성 물질의 분리·정제, 산·염기 제조와 같은 다양한 산업 분야에 적용이 가능하다. 본 발표에서는 이온교환막의 상업적 공정 적용 사례를 소개하고 향후 이온교환막의 개선방향에 대한 제안을 통해 보다 실용적인 국내 이온교환막의 개발에 도움이 되고자 한다.

The effect of electron beam (EB) irradiation on the electrical properties of Zn-Sn-O (ZTO) thin films fabricated using a sol-gel process was investigated. As the EB dose increased, the saturation mobility of ZTO thin film transistors (TFTs) was found to slightly decrease, and the subthreshold swing and on/off ratio degenerated. X-ray photoelectron spectroscopy analysis of the O 1s core level showed that the relative area of oxygen vacancies (VO) increased from 10.35 to 12.56 % as the EB dose increased from 0 to 7.5 × 1016 electrons/cm2. Also, spectroscopic ellipsometry analysis showed that the optical band gap varied from 3.53 to 3.96 eV with increasing EB dose. From the results of the electrical property and XPS analyses of the ZTO TFTs, it was found that the electrical characteristic of the ZTO thin films changed from semiconductor to conductor with increasing EB dose. It is thought that the electrical property change is due to the formation of defect sites like oxygen vacancies.

최근 도심지에서 지중매설관의 구조적 결함에 의한 토사 유실로 인해 지하 공동이 빈번하게 발생하고 있다. 본 연구에서는 이러한 지하 공동을 파악하는데 있어 현장 실험 수행 결과 전기비저항 탐사와 공압콘관입시험이 지반 조건의 이상 징후를 탐지하는데 효율적임을 확인하였다. 또한, 이미지 분석을 통한 전기비저항 실험 측정값을 정량화 하여 평균 비저항 값을 산정하는 방법을 제안하였다. 실대형 실험 결과, 평균 비저항 값이 감소할수록 위험도가 증가하였고, 공압콘관입시험 결과, N치가 작을수록 위험도가 높다는 것을 확인하였으며, 제한적인 측정 데이터 수를 토대로 평균 비저항 값과 공압콘관입시험의 결과를 토대로 상관관계를 나타내었을 때, 지반의 지하공동 발생과 관련된 위험 수준을 제한적으로 평가할 수 있을 것으로 판단된다.

This study investigates how the spatial recognition structure is emerging through the case of rectangular plan combined with a combination of Dang-Sil(堂室) and Gong(工) shape roof, and identifies a type of architecture in the early Joseon Dynasty that has never been revealed. The conclusion of this study is as follows. First, the Dang and the Sil are connected to each other, but the architectural elements such as pillars, frame, and windows are distinguished and appear as separate buildings. Second, the distinction between Dang and Sil is evident by the difference in the number of ridges and the shape of the roof. In addition, the roof and roof framework of the independent rooms and the rooms were common in the right angled architecture where the direction and the expandability of each structure were maintained. Third, the construction of the Dang-Sil combined structure, in which two or more structure frameworks were combined with the rectangular combined flat roof structure, gradually changed into a single structure with a single ridge. Fourth, this change means that people of the early Joseon Dynasty recognized the Dang and Sil as separate architecture, but the strict sense of spatial separation has disappeared over time.

Doped-LaCrO3 perovskites, because of their good electrical conductivity and thermal stability in oxidizing and/or reducing environments, are used in high temperature solid oxide fuel cells as a gas-tight and electrically conductive interconnection layer. In this study, perovskite (La0.8Ca0.2)(Cr0.9Co0.1)O3 (LCCC) coatings manufactured by atmospheric plasma spraying followed by heat treatment at 1200 oC have been investigated in terms of microstructural defects, gas tightness and electrical conductivity. The plasma-sprayed LCCC coating formed an inhomogeneous layered structure after the successive deposition of fully-melted liquid droplets and/or partially-melted droplets. Micro-sized defects including unfilled pores, intersplat pores and micro-cracks in the plasma-sprayed LCCC coating were connected together and allowed substantial amounts gas to pass through the coating. Subsequent heat treatment at 1200 oC formed a homogeneous granule microstructure with a small number of isolated pores, providing a substantial improvement in the gas-tightness of the LCCC coating. The electrical conductivity of the LCCC coating was consequently enhanced due to the complete elimination of inter-splat pores and microcracks, and reached 53 S/cm at 900 oC.

본 논문에서는 전기화학발광 소재로 널리 이용되는 Ruthenium 착화합물을 함유한 전기화학발광 소자의 활 성층 제작시, 인쇄성 및 공정성을 향상시키기 위해 Poly(methyl methacrylate) (PMMA)를 첨가하였을 때, PMMA의 함유량이 전기화학발광소자의 발광층 내 이온들의 이동 현상에 미치는 영향에 대하여 살펴보았다. 이를 위해, Ruthenium 착화합물과 이온성 액체가 9:1 비율로 섞인 용질이 Acetonitrile에 20 mg/ml 농도로 녹여진 용액과 Dichloromethane에 PMMA가 25 mg/ml의 농도로 용해된 용액을 세 가지 (10:0.14, 10:1 그리고, 10:3) 중량비로 섞어 서 준비한 용액으로부터 발광층을 형성하여 전기화학발광소자를 제작하고, 소자의 전기적 특성을 평가하였다. 그 결 과, 발광층 내의 PMMA 함유량이 증가할수록 Ruthenium 착화합물 기반 전기화학발광소자의 구동 전압은 점차 증가 하였고, PMMA의 양이 줄어들면 순방향 전압하의 전류와 역방향 전압하의 전류 차에 따라 나타나는 이력곡선 (hysteresis)이 점차 사라지는 것을 확인할 수 있었다.

본 연구는 융복합기술을 사용하여 국내 자동차 산업의 배터리 및 전기시스템과 수상레저기구 중 접근이 용이한 수상오토바이를 결합하여 전기 동력 추진식 수상오토바이 개발과 전기 동력 추진식 수상오토바이 실용화를 위한 등록 및 제작을 위해 전기 동력 추진식 수상오토바이의 안전검사 기준(안)과 형식승인 기준(안)을 개발하였다. 전기 동력 추진식 수상 오토바이 인증기준은 기존 내연기관 동력 수상오토바이의 인증기준과 선박 전기 시스템과 관련된 인증기준을 기본으로 구조 및 시스템 설치 안과 전기시스템 안의 두 분류로 구분을 하였고, 최종적으로 안전검사 기준(안)과 형식승인 기준(안)으로 개발하였다. 안전검사 기준(안)의 내용은 총 7개의 범주로 구분되어 수상오토바이의 안전한 운행을 위한 설비의 확인을 목적으로 작성되었고, 형식승인 기준(안)은 총 7개의 범주로 구분되어 수상오토바이의 안전한 제작을 위한 목적으로 작성되었다. 본 연구를 통해 국내 친환경 수상오토바이 제작의 환경 조성과 전기동력 추진 선박의 인증기준에 대한 정책 수립 기초 자료로 활용이 가능하다.

Silicon alloys are considered promising anode active materials to replace Li-ion batteries by graphite powder, because they have a relatively high capacity of up to 4200 mAh/g, and are environmentally friendly and inexpensive ECO-materials. However, its poor charge/discharge properties, induced by cracking during cycles, constitute their most serious problem as anode electrode. In order to solve these problems, Si-Ge-Al alloys with porous structure are designed as anode alloy powders, to improve cycling stability. The alloys are melt-spun to obtain the rapidly solidified ribbons, and then ball-milled to make fine powders. The powders are etched using 1 M HCl solution, which gives the powders a porous structure by removing the element Al. Subsequently, in this study, the microstructures and the characteristics of the etched powders are evaluated for application as anode materials. As a result, the etched porous powder shows better electrochemical properties than as-milled Si-Ge-Al powder.

This study describes the effects of polyurethane/loess powder (PU/LP) nanofiber thin films composite produced from electrospun for absorption volatile organic compounds (VOCs) from air. Environmental issue has become a focus with improving people's living quality. The VOCs are one of the factors that affect the environmental safety. So, in order to improve the environment and safety for people, many air cleaning techniques have been investigated. One of the methods is nanofiber filtration technology. In this study, the PU nanofiber thin film has been studied that it has the adsorption of VOCs capacity, and LP nanoparticles (NPs) can be used as an additive to load into PU nanofiber thin film by electrospinning. For studying PU/LP nanofiber thin films's absorption of VOCs capacity, 4 samples (0, 10, 30, and 50 wt% LP with respect to PU) were manufactured, respectively. The results show that PU composite mats containing 30 wt% LP NPs has the highest VOCs absorption capacity, and the adsorption capacity for toluene was the highest compared to benzene and chloroform.

Insulating TaNx films were grown by plasma enhanced atomic layer deposition using butylimido tris dimethylamido tantalum and N2+H2 mixed gas as metalorganic source and reactance gas, respectively. Crossbar devices having a Pt/TaNx/Pt stack were fabricated and their electrical properties were examined. The crossbar devices exhibited temperature-dependent nonlinear I (current) - V (voltage) characteristics in the temperature range of 90-300 K. Various electrical conduction mechanisms were adopted to understand the governing electrical conduction mechanism in the device. Among them, the Poole- Frenkel emission model, which uses a bulk-limited conduction mechanism, may successfully fit with the I - V characteristics of the devices with 5- and 18-nm-thick TaNx films. Values of ~0.4 eV of trap energy and ~20 of dielectric constant were extracted from the fitting. These results can be well explained by the amorphous micro-structure and point defects, such as oxygen substitution (ON) and interstitial nitrogen (Ni) in the TaNx films, which were revealed by transmission electron microscopy and UV-Visible spectroscopy. The nonlinear conduction characteristics of TaNx film can make this film useful as a selector device for a crossbar array of a resistive switching random access memory or a synaptic device.

Recently, as demand for Electric Car has been increasing, it has been a main factor that maximizing performance and ensuring the stability of the Electric Car battery to increase the reliability of Electric Car. Above all the study on thermal control in a big influence on the performance and battery life is growing in parallel. This study has compared cooling effect of an Electric Car battery between battery with Heat Sink and without Heat Sink for optimum design of Electric Car battery. Battery is simply modeled into four cells, divided into two cases of battery with Heat Sink that attached on the cell's side and without Heat Sink. And this research was conducted on forced convection. The battery which is designed by this way was numerically analyzed by CFX 14.5. Numerical results, revealed that the battery with Heat Sink was superior in terms of cooling effect. According to the numerical analysis by battery cell's temperature variations, the battery with Heat Sink turned out to be superior in cooling effect to the battery without Heat Sink.

In this study, electric propulsion leisure boat with 9 meters length is designed and the performances are investigated by CFD analysis and model test. Maximum speed of the developed boat is 15knots(7.7 m/s) using 80Kw electric motor. Catamanan type hull form with slender body is adopted considering high Froude number and large deck area. Two kinds of hull forms are designed and the performances are compared in resistance point of view. Wave patterns are observed to make clear the relationship between resistance performance and wave characteristics. The results show that not only wave interaction due to shoulder waves but also stern waves have a strong influence on resistance performance and CFD analysis including free surface can give useful informations at initial ship design stage for high Froude number catamaran boat.

We performed this study to understand the effect of a single-crystalline anode on the mechanical properties of asdeposited films during electrochemical deposition. We used a (111) single- crystalline Cu plate as an anode, and Si substrates with Cr/Au conductive seed layers were prepared for the cathode. Electrodeposition was performed with a standard 3-electrode system in copper sulfate electrolyte. Interestingly, the grain boundaries of the as-deposited Cu thin films using single-crystalline Cu anode were not distinct; this is in contrast to the easily recognizable grain boundaries of the Cu thin films that were formed using a poly-crystalline Cu anode. Tensile testing was performed to obtain the mechanical properties of the Cu thin films. Ultimate tensile strength and elongation to failure of the Cu thin films fabricated using the (111) single-crystalline Cu anode were found to have increased by approximately 52 % and 37%, respectively, compared with those values of the Cu thin films fabricated using apoly-crystalline Cu anode. We applied ultrasonic irradiation during electrodeposition to disturb the uniform stream; we then observed no single-crystalline anode effect. Consequently, it is presumed that the single-crystalline Cu anode can induce a directional/uniform stream of ions in the electrolyte that can create films with smeared grain boundaries, which boundaries strongly affect the mechanical properties of the electrodeposited Cu films.

In this study, we intensively investigated the effect of conductive additive amount on electrochemical performance of organic supercapacitors. For this purpose, we assembled coin-type organic supercapacitor cells with a variation of conductive additive(carbon black) amount; carbon aerogel and polyvinylidene fluoride were employed as active material and binder, respectively. Carbon aerogel, which is a highly mesoporous and ultralight material, was prepared via pyrolysis of resorcinolformaldehyde gels synthesized from polycondensation of two starting materials using sodium carbonate as the base catalyst. Successful formation of carbon aerogel was well confirmed by Fourier-transform infrared spectroscopy and N2 adsorptiondesorption analysis. Electrochemical performances of the assembled organic supercapacitor cells were evaluated by cyclic voltammetry, galvanostatic charge/discharge, and electrochemical impedance spectroscopy measurements. Amount of conductive additive was found to strongly affect the charge transfer resistance of the supercapacitor electrodes, leading to a different optimal amount of conductive additive in organic supercapacitor electrodes depending on the applied charge-discharge rate. A high-rate charge-discharge process required a relatively high amount of conductive additive. Through this work, we came to conclude that determining the optimal amount of conductive additive in developing an efficient organic supercapacitor should include a significant consideration of supercapacitor end use, especially the rate employed for the charge-discharge process.

The Fe-Cr-Al alloy system shows an excellent heat resistance because of the formation of an Al2O3 film on the metal surface in an oxidizing atmosphere at high temperatures up to 1400oC. The Fecralloy needs an additive that can act as a binder because of its bad compactability. In this study, the green compacts of STS434L and Al powder added to Fecralloy are oxidized at 950oC for up to 210 h. Fecralloy and Al is mixed by two types of ball milling. One is vented to air and the other was performed in a sealed jar. In the case of Al addition, there are no significant changes in the electrical resistance. Before the oxidation test, Al oxides are present in the Fecralloy surface, as determined from the energy dispersive spectroscopy results. The addition of Al improves the compactability because of an increased density, and the addition of STS434L increases the electrical resistivity by forming a composite oxide.

당뇨병 환자들은 말초신경 손상의 합병증으로서 이상감각과 통증을 느낄 수 있는데 이는 날카로운 느낌, 차갑고 시린 느낌, 무딘 느낌, 살갗이 벗겨진 듯한 예민한 느낌, 화끈거리는 느낌, 따끔하고 가려운 느낌 등 다양하게 나타날 수 있다. 이를 진단하기 위해서 여러 선별검사와 전기생리학적 검사를 활용할 수 있다. 본 연구에서는 신경병통증척도와 미시간 신경병증 선별도구 및 신경전도검사를 통해 이상감감/통증을 호소하는 당뇨병 환자 11명과 호소하지 않는 당뇨병 환자 10명 간에 차이점 및 특징을 분석하였고, 세부 감각양상과 신경전도검사 지표간 상관성을 분석하였다. 그 결과 이상감각/통 증을 호소하는 환자군에서 신경병통증척도와 미시간 신경병증 선별검사의 점수가 통계적으로 유의하게 높았고 신경전도검 사에서는 주로 정중신경 운동신경과 비골신경이 의미 있는 기능 변화를 보였다. 세부 감각양상에 따른 신경전도검사 지표는 주로 정중신경 운동신경, 후경골신경, 장딴지신경에서 유의한 변화를 보였다. 이러한 결과들은 감각이상과 통증이 실제 말초신경 이상과 관련이 있음을 시사한다. 향후 많은 수의 대상자를 포함한 추가적인 연구가 필요하다.

연구에서는, 전기방사법을 이용하여 산화철-산화그래핀(Fe3O4/GO, metallic graphene oxide; MGO)이 도입된 PVdF/MGO 복합나노섬유(PMG)를 제조하였으며, 이를 활용하여 비소제거에 대한 특성 평가를 진행하였다. MGO의 경우 In-situ-wet chemical 방법으로 제조하였으며, FT-IR, XRD분석을 진행하여, 형태와 구조를 확인하였다. 나노섬유 분리막의 기 계적 강도 개선을 위하여 열처리과정을 진행하였으며, 제조된 분리막의 우수한 기계적 강도 개선 효과를 확인할 수 있었다. 그러나, PMG 막의 경우, 도입된 MGO의 함량이 증가할수록 기계적 강도가 감소되는 경향성을 보여주었으며, 기공크기 분석 결과로부터, 0.3~0.45 μm의 기공크기를 가진 다공성 분리막이 제조되었음을 확인할 수 있었다. 수처리용 분리막으로의 활용 가능성 조사를 위해, 수투과도 분석을 실시하였다. 특히, PMG2.0 샘플의 경우 0.3 bar 조건에서, PVdF 나노섬유막(91 kg/m2h)에 비해 약 70% 향상된 결과값(153 kg/m2h)을 나타내었다. 또한, 비소 흡착실험 결과로부터, PMG 막의 경우, 비소3 가와 5가에 최대 81%, 68%의 높은 제거율을 보여주었으며, 흡착등온선 분석으로부터, 제조된 PMG 막의 경우 비소3가, 5가 모두 Freundlich 흡착거동을 따른다는 것을 확인하였다. 위 모든 결과로부터, PVdF/MGO 복합 나노섬유 분리막은 비소제거 및 수처리용 분리막으로 충분히 활용할 수 있을 것으로 판단된다.