• 한국결정성장학회지
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• 제10권1호
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• pp.66-72
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• 2000

재래식 및 마이크로파 가열법으로 열처리된 $Li_2O_3-SiO_2$계 글라스의 핵 생성 및 결정화 거동을 열분석법(DTA), X-선 회절(XRD), 광학 현미경(OM) 및 전기 전도도의 측정으로 비교 조사하였다. 재래식 및 마이크로피로 열처리된 시료들의 조핵 온도와 최대 핵 생성 온도는 동일하게 각각 460~$500^{\circ}C$와 $580^{\circ}C$이었다. 한편, 재래식에 비하여 마이크로파로 열처리된 시료에서는 부피 핵 생성이 일어나려는 경향이 컸다. 재래식 및 마이크로파로 열처리된 시편들에서 결정의 성장 속도는 결정화 열처리 온도에 비례하여 증가하였지만, 마이크로파 열처리의 경우는 부피 핵 생성 경향 및 물질 확산 효과의 증대에 기인하여 결정 성장을 재래식 보다 빠르게 진행되었다. 재래식 및 마이크로파로 열처리된 시편들의 전기 전도도 값은 각각 1.337~2.299와 0.281~$0.911{\times}10^{-7}\Omega {\textrm}{cm}^{-1}$이었다.

• 한국산업보건학회지
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• 제32권4호
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• pp.381-392
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• 2022

Objectives: Objective of this study is to review briefly exposure characteristics, monitoring instruments and threshold limit values for extremely low frequency-magnetic field (ELF-MF) methods. This study was undertaken through brief literature review. We performed a literature search in PubMed to identify ELF-MF studies conducted in workplaces. Initial search keywords such as 'extremely low frequency-magnetic field (ELF-MF)' and 'electromagnetic fields (EMF)' combined or singly. We limited our review to occupational rather than general nonworkplace environmental exposures. Methods: The contents we reviewed: key industry and occupations generating ELF-MF, several direct-reading instruments monitoring ELF-MF and threshold limit values (TLV) preventing health effects may be caused by the exposure to ELF-MF. Results: The industries related to the generation and supply of electricity, electrolytic installations, welding, and induction heating and more were regarded as high ELF-MF exposure industries. All jobs handling or employed performed in power cable lines, electrical wiring, and electrical equipment are found to be exposed to ELF-MF. Threshold or ceiling limit, 1,000 µT, is established to prevent acute effects of exposure to low-frequency EMFs on the nervous system: the direct stimulation of nerve and muscle tissues and the induction of retinal phosphenes. The International Agency for Research on Cancer (IARC) has classified ELF-MF as possibly carcinogenic to humans chiefly based on epidemiological studies on childhood leukemia. However, a causal relationship between magnetic fields and several types of cancer including childhood leukemia has not been established nor has any other long-term effects. Risk management using precautionary measures, has been initiated by the US and EU to prevent chronic health effects related to ELF-MF exposure in workplaces. Conclusion: This study recommends the implementation of various measures such as theestablishment of occupational exposure limit values for ELF-MF and precautionary principle to prevent potential chronic occupational health effects may be caused by ELF-MF in Korea.

• 한국해양환경ㆍ에너지학회지
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• 제16권4호
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• pp.227-238
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• 2013

본 연구의 목적은 해수담수화 과정 중 황산이온과 염소이온은 제거하고 유용미네랄인 마그네슘, 칼슘은 잔존 시키는 미네랄 수질 조정 기술로 먹는물 수질기준에 맞는 고경수 제조 공정 개발에 있다. 역삼투막(RO)에 통과시켜 농축수(Concentrated deep seawater)와 탈염수(desalted deep seawater)를 제조하고, 나노여과막(NF)를 사용하여 염화나트륨이 제거되지 않은 1차 미네랄 농축수(Mineral enriched deep seawater)를 제조하여, 전기투석 이온교환막(ED)을 가동하여 염화나트륨을 제거한 탈염 미네랄농축수(Mineral enriched desalted water)를 제조하여 이를 RO 탈염수와 희석하여 고경도 먹는해양심층수를 제조하였다. 역삼투막은 해수(해양심층수) 원수에서 용존물질과 담수를 분리할 수 있으며, 2차에 걸쳐 역삼투막을 사용하면, 용존성분 중 99.9% 이상 제거되고, 경도 1이하, 염소이온의 농도 2.3 mg/L인 용존물질이 완전히 제거된 탈염수(순수)를 제조할 수 있었다. 나노여과막 (NF 막)의 간극은 $10^{-9}$ m으로 마그네슘과 칼슘은 50%정도 통과시키며, 염소이온과 나트륨 같은 일가이온은 95%이상 통과한다. 나노여과막은 마그네슘과 칼슘과 같은 경도 성분과 나트륨과 염소이온과 같은 염분성분을 분리 농축할 수 있지만, 완벽하게 분리하지는 못한다. 전기투석막(ED)은 전기전도도에 따라 경도성분의 이가이온과 염분성분인 일가이온이 분리된다. 전기전도도 20 mS/cm 이상에서 경도성분(마그네슘이온, 칼슘 이온 등)은 제거되지 않는 반면, 염분성분 (나트륨이온, 염소이온 등)은 지속적으로 제거되었다. 따라서, 나노여과막을 이용하여 마그네슘과 칼슘과 같은 경도 성분을 농축하고, 전기투석막을 이용하여 경도농축수에서 염분성분을 분리하여 경도농도 12,600 mg/L, 염소이온 농도 2,446 mg/L의 염분성분이 배제된 고경도 농축수를 제조할 수 있었다. 이러한 고경도수를 역삼투막을 이용하여 용존물질이 모두 제거된 2차 RO 생산수로 10배 희석하면 염소이온 농도 244 mg/L 로 먹는물 수질기준에 적합하면서 경도농도 1,260 mg/L 인 고경도 수 제조도 가능하였다. RO/NF/ED 또는 NF/ED 연계공정은 해수의 증발 없이 역삼투막, 나노여과막과 전기투석막만을 이용하여 염소이온과 나트륨, 칼륨, 황산이온과 같은 염분성분을 제거하면서 마그네슘과 칼슘과 같은 경도성분은 농축할 수 있어서 먹는물 수질기준에 적합한 고경도수 제조가 가능하였으며, 이 과정 중 소모되는 에너지를 줄일 수 있었다.

• 전자공학회논문지 IE
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• 제43권1호
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• pp.5-15
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• 2006

족탕기(STYX ford202)를 이용하여 발 부분의 온열수 자극을 인가하여 생체 현상의 각종 변화를 계측하였다. 생체 현상의 변화 데이터는 발 부분의 온수 열 자극을 43$^{\circ}C$, 45$^{\circ}C$의 조건으로 10명의 남여 사람을 10일 동안 1회 측정시 5분, 10분, 15분, 20분, 경과 실험을 통해 9가지 생리적 요소를 측정하여 분석하였다. 생체신호요소의 측정의 분석 결과는 이마온도는 -0.69 $\pm$ 0.01 감소하였고, 다리온도는 1.51 $\pm$ 0.22 증가되었다. 혈류($m\ell/min$)는 1.18 $\pm$ 0.50 증가되며, 혈압(mmHg)는 -1.49$\pm$ 2.81, (min) -0.06$\pm$ 0.13 감소 현상을 보였다. 맥박수의 변화는 6.97 $\pm$ 0.72 증가하며, 혈당은 ($mg/d\ell$) : -2.41 $\pm$ 1.55 감소되었고, 피부산소포화도 (%): 1.34 $\pm$ 0.28 증가하였다. 또한 체지방(%) -1.75$\pm$ 0.15 및 체중은 (kr): -0.10 $\pm$ 0.04 감소 현상으로 나타났다.

• Journal of the Korean Wood Science and Technology
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• 제36권3호
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• pp.70-84
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• 2008

국산재의 여러 가지 응용물성을 매년 3수종씩, 3년에 걸쳐 조사하였다. 첫 수종으로 우리나라의 대표 수종인 소나무를 사용하였다. 매년 동일한 장치와 실험조건으로 실험하였기 때문에 모든 수종에 대한 결과를 상호 비교할 수 있다. 수분흡착성 실험은 목분을 이용하였으며, 가열처리조건에 따른 평형함수율과 흡착등온곡선을 구하였다. 열전도율과 열확산률은 열선열전도장치를, 전기의 부피저항률과 저항은 고전기저항계를 이용하여 측정하였다. 정목재와 판목재의 열적 전기적 특성차이가 관찰되었는데 이는 해부학적 차이에 의한 것으로 보인다. 음향측정시스템을 사용하여 동적탄성률, 내부마찰을 측정하였다. 본 논문의 결과들은 목재구조물 설계, 휴대용 목재수분계 보정, 비파괴검사 등에 필요한 기본 자료를 제공한다.

• Nuclear Engineering and Technology
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• 제25권1호
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• pp.91-101
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• 1993

가압경수로형 원자로의 정상 비정상 운전시의 열수력학적 거동을 예측하기 위해서는 원자로내기포계수의 분포를 정확히 계산하는 것이 필수적이다. 이러한 기포계수의 정확한 예측을 위하여 많은 모델들이 제시되었다. 이중 drift-flux모델은 그 계산의 정확성과 간결성에 의하여 널리 사용되고 있다. 이러한 drift-flux 모델을 사용하여 보다 더 정확한 기포계수를 예측하기 위해서는 각 상간의 슬립률과 flow regime 에 따른 기포의 운동의 변화가 정확히 고려되어야 한다. Drift-flux 모델에서는 이러한 두 가지 요소가 drift-flux parameter인 $C_{o}$ 와 (equation omitted), 에서 고려된다. 본 연구에서는 이러한 $C_{o}$ 의 실험적 결정을 위하여 원자로 노심을 모사한 4개의 전열봉이 있는 비등이 발생하는 수직사각 유로를 구성하였으며, 완성된 유로내에서 기포계수의 분포 및 기포속도의 분포를 측정하였다. 국부적 기포계수 및 기포속도 분포의 측정에 사용된 방법은 이중탐침법이며 측정이 이루어진 유로내의 유동 상태는 유속이 비교적 느린 low flow rate condition이며 유로내 압력은 3기압 이하이다. 본 실험에서는 액상의 속도는 측정되지 않았으며, 따라서 $C_{o}$ 의 계산을 위하여 (equation omitted)의 실험 상관관계식을 사용하여 유로내 평균 기포계수의 함수로 나타내었다.

• International Journal of Ocean System Engineering
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• 제2권3호
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• pp.185-194
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• 2012

A Macroscopic combination of two or more distinct materials is commonly referred to as a "Composite Material", having been designed mechanically and chemically superior in function and characteristic than its individual constituent materials. Composite materials are used not only for aerospace and military, but also heavily used in boat/ship building and general composite industries which we are seeing increasingly more. Regardless of the various applications for composite materials, the industry is still limited and requires better fabrication technology and methodology in order to expand and grow. An example of this is that the majority of fabrication facilities nearby still use an antiquated wet lay-up process where fabrication still requires manual hand labor in a 3D environment impeding productivity of composite product design advancement. As an expert in the advanced composites field, I have developed fabrication skills with the use of machinery based on my past composite experience. In autumn 2011, the Korea government confirmed to fund my project. It is the development of a composite sanding machine. I began development of this semi-robotic prototype beginning in 2009. It has possibilities of replacing or augmenting the exhaustive and difficult jobs performed by human hands, such as sanding, grinding, blasting, and polishing in most often, very awkward conditions, and is also will boost productivity, improve surface quality, cut abrasive costs, eliminate vibration injuries, and protect workers from exposure to dust and airborne contamination. Ease of control and operation of the equipment in or outside of the sanding room is a key benefit to end-users. It will prove to be much more economical than normal robotics and minimize errors that commonly occur in factories. The key components and their technologies are a 360 degree rotational shoulder and a wrist that is controlled under PLC controller and joystick manual mode. Development on both of the key modules is complete and are now operational. The Korean government fund boosted my development and I expect to complete full scale development no later than 3rd quarter 2012. Even with the advantages of composite materials, there is still the need to repair or to maintain composite products with a higher level of technology. I have learned many composite repair skills on composite airframe since many composite fabrication skills including repair, requires training for non aerospace applications. The wind energy market is now requiring much larger blades in order to generate more electrical energy for wind farms. One single blade is commonly 50 meters or longer now. When a wind blade becomes damaged from external forces, on-site repair is required on the columns even under strong wind and freezing temperature conditions. In order to correctly obtain polymerization, the repair must be performed on the damaged area within a very limited time. The use of pre-impregnated glass fabric and heating silicone pad and a hot bonder acting precise heating control are surely required.

• 대한치과보철학회지
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• 제39권6호
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• pp.709-734
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• 2001

The aims of this experiment were to investigate the strain and temperature changes simultaneously within autopolymerzing acrylic resin specimens. A computerized data acquisition system with an electrical resistance strain gauge and a thermocouple was used over time periods up to 180 minutes. The overall strain kinetics, the effects of stress relaxation and additional heat supply during the polymerization were evaluated. Stone mold replicas with an inner butt-joint rectangular cavity ($40.0{\times}25.0mm$, 5.0mm in depth) were duplicated from a brass master mold. A strain gauge (AE-11-S50N-120-EC, CAS Inc., Korea) and a thermocouple were installed within the cavity, which had been connected to a personal computer and a precision signal conditioning amplifier (DA1600 Dynamic Strain Amplifier, CAS Inc., Korea) so that real-time recordings of both polymerization-induced strain and temperature changes were performed. After each of fresh resin mixture was poured into the mold replica, data recording was done up to 180 minutes with three-second interval. Each of two poly(methyl methacrylate) products (Duralay, Vertex) and a vinyl ethyl methacrylate product (Snap) was examined repeatedly ten times. Additionally, removal procedures were done after 15, 30 and 60 minutes from the start of mixing to evaluate the effect of stress relaxation after deflasking. Six specimens for each of nine conditions were examined. After removal from the mold, the specimen continued bench-curing up to 180 minutes. Using a waterbath (Hanau Junior Curing Unit, Model No.76-0, Teledyne Hanau, New York, U.S.A.) with its temperature control maintained at $50^{\circ}C$, heat-soaking procedures with two different durations (15 and 45 minutes) were done to evaluate the effect of additional heat supply on the strain and temperature changes within the specimen during the polymerization. Five specimens for each of six conditions were examined. Within the parameters of this study the following results were drawn: 1. The mean shrinkage strains reached $-3095{\mu}{\epsilon},\;-1796{\mu}{\epsilon}$ and $-2959{\mu}{\epsilon}$ for Duralay, Snap and Vertex, respectively. The mean maximum temperature rise reached $56.7^{\circ}C,\;41.3^{\circ}C$ and $56.1^{\circ}C$ for Duralay, Snap, and Vertex, respectively. A vinyl ethyl methacrylate product (Snap) showed significantly less polymerization shrinkage strain (p<0.01) and significantly lower maximum temperature rise (p<0.01) than the other two poly(methyl methacrylate) products (Duralay, Vertex). 2. Mean maximum shrinkage rate for each resin was calculated to $-31.8{\mu}{\epsilon}/sec,\;-15.9{\mu}{\epsilon}/sec$ and $-31.8{\mu}{\epsilon}/sec$ for Duralay, Snap and Vertex, respectively. Snap showed significantly lower maximum shrinkage rate than Duralay and Vertex (p<0.01). 3. From the second experiment, some expansion was observed immediately after removal of specimen from the mold, and the amount of expansion increased as the removal time was delayed. For each removal time, Snap showed significantly less strain changes than the other two poly(methyl methacrylate) products (p<0.05). 4. During the external heat supply for the resins, higher maximum temperature rises were found. Meanwhile, the maximum shrinkage rates were not different from those of room temperature polymerizations. 5. From the third experiment, the external heat supply for the resins during polymerization could temporarily decrease or even reverse shrinkage strains of each material. But, shrinkage re-occurred in the linear nature after completion of heat supply. 6. Linear thermal expansion coefficients obtained from the end of heat supply continuing for an additional 5 minutes, showed that Snap exhibited significantly lower values than the other two poly(methyl methacrylate) products (p<0.01). Moreover, little difference was found between the mean linear thermal expansion coefficients obtained from two different heating durations (p>0.05).