• 한국추진공학회지
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• 제26권6호
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• pp.86-100
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• 2022

핵추진 시스템의 개념 및 특징들을 소개하고 해외 핵동력 우주추진 기술개발 동향을 정리하였다. 핵추진 원료로 사용되는 우라늄은 비에너지가 매우 높아 기존 화학추진방식 대비 우수한 비추력 성능을 내고, 탑재되는 연료의 양을 줄일 수 있어 장거리 탐사 시 매우 유리한 이점을 가지고 있다. 이러한 이유로, 최근 우주개발 선도국에서 핵추진 기술 연구에 박차를 가하고 있는바, 우주개발 경쟁에서의 우위를 점하기 위해서도 핵동력을 이용한 추진기관의 개발이 반드시 필요하다고 판단된다.

• 한국추진공학회지
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• 제26권2호
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• pp.40-46
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• 2022

홀추력기는 이온을 가속하여 추력을 얻는 전기추력기의 일종으로, 높은 비추력을 보유하여 다양한 우주임무에 활용되고 있다. 특히, 최근 다양한 우주임무 내 100 kg 내외의 소형 및 초소형위성의 활용이 가파르게 증가하면서, 이를 위한 저전력 전기추력기 연구개발의 중요성 역시 크게 증가하고 있다. 본 연구에서는 양극전력 200 W 미만의 홀추력기 랩모델 두 기를 설계 및 제작하고, 운전변수에 따른 추력성능 혹은 방전특성을 분석하였다. 결과적으로, 양극전력 50-175 W에서 2.5-9.0 mN 수준의 추력과 600-1,150 s의 비추력, 15-28% 양극효율을 확보하였다.

• 기술혁신학회지
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• 제6권4호
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• pp.462-479
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• 2003

The policy trends of use and the development of nuclear power in the United States, France, United Kingdom. Germany, Russia, China, Japan and Korea are briefly investigated. Nuclear power technology has been developed as the national policy in the nuclear-advanced countries. 50 years has passed since the declaration of "Atoms for Peace" by USA President Eisenhour in December 1953. Recently, it appears to revitalize the nuclear power program in world major countries in order to recover the shortage of electric power and to curb the excess emission of carbon dioxide as well as to secure competitiveness in electricity markets. Advanced countries are making new initiatives for the development of the fourth generation nuclear power system. Furthermore, wide-ranged use and development of nuclear power technologies are expected in district heating in commercial sectors, power in the space exploration, and propulsion power of large tankers and spaceships. High temperature gas cooled nuclear power reactor will be applied for mass production of hydrogen energy in the future.

• Strategy21
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• 통권41호
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• pp.261-293
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• 2017

Nuclear power is a way of attaining an enormous amount of energy with relatively small amount of resources and after it has been introduced to the submarine since 1954, there are approximately 150 of nuclear powered submarine currently on a mission around the world. This is due to the maneuverability, mountability and covertness of nuclear submarines. However, there are other tasks, not only the high level of nuclear technology that are needed to be dealt with in order to construct nuclear powered submarine. The biggest task of all is to secure the enriched uranium. Accordingly, this research is about the way of enriching and securing the nuclear fuel that are used in the nuclear submarine with the characteristics, merits and demerits of the nuclear submarine. Due to the fact that the pressurized water reactor in South Korea is the reactor that was originally built for the development of nuclear powered submarine, many parts is designed to be suitable for the submarine propulsion. However, in order to apply this to submarine it is needed to consider additional requests such as the position of reactor, accident-coping system, radioactive covering, reactor output adjustment and ship's pitch and roll in order to apply this to submarine. Nuclear submarines have much higher speed based on the powerful propulsion in comparison with diesel-electric submarine and also have bigger loading area. Besides, there is no need to snorkel and they also have advantages in covertness with the multi-noise proof system. The nuclear technology in South Korea has seen the dramatic development since 1962 and in 1998 reached to the level that we have succeeded in the localization of nuclear plant and exported the world-class one-piece small-sized reactor (SMART) to UAE. To operate these reactors, we import the whole quantity of low-enriched uranium and having our own uranium enrich facility is not probable because of the budget and international regulations. With the ROK/US nuclear agreement revised on 2015 November, the enrichment of uranium that are available without special permission has changed up to 20%. According to the assumption that we use the 20% enrichment of Uranium on U.S. virginia class submarine, it is necessary to change the fuel after 11 years and it will cause additional cost of 1 billion dollars. But the replace period by the uranium's enrichment rate is not fixed so that it is possible to change according to the design of reactor. Therefore, I would like to make a suggestion on two types of design concepts of nuclear submarine that can be operated for 30 years without nuclear fuel change by using the 20% enriched uranium from ONNp.First of all, it is possible by increasing the size of reactor by 3 times and it results in the 1,000t increase of the weight. And secondly, it is by designing the one piece reactor to insert devices such as steam turbine, condenser into the inside of nuclear core like the Rubis class submarines of France.

• 한국추진공학회지
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• 제25권5호
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• pp.65-72
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• 2021

소형위성의 궤도조정 및 궤도유지에 활용될 수 있는 700 W급 홀추력기 랩모델을 개발하였다. 스케일링 방정식을 사용하여 방전채널의 크기를 선정하였으며, 자기장이 방전채널 중심선을 기준으로 대칭성을 가지면서 방전채널 바깥에서 최대가 되도록 설계하였다. 개발된 홀추력기의 방전시험은 2.0×10^-5 Torr 이하의 배경압력을 갖는 진공 환경에서 수행되었으며 추력 스탠드를 이용하여 추력을 측정하였다. 양극전압을 300 V로 고정하고 양극유량과 코일전류를 변수로 하여 추력을 측정하였으며, 양극유량 2.36 mg/s, 코일전류 2.4 A 조건에서 양극전력 620 W에서 추력 38 mN, 통합비추력 1,540 s, 양극효율 50 %로 가장 높은 성능을 보였다.

• Journal of Radiation Protection and Research
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• 제21권4호
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• pp.313-327
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• 1996

원전부지내(AR) 사용후핵연료 건식저장방식으로 횡형콘크리트 모듈방식, 금속 저장용기 방식, 콘크리트 저장용기 방식, 수송저장 겸용용기 방식 및 다목적용기 방식 등이 있다. 이중다목적용기 방식을 제외한 다른 방식들은 각각 운영인허가를 받아 이미 세계 각 국에서 사용후핵연료 AR 건식저장에 사용되고 있으며 다목적용기 방식도 최근 개발을 활발히 진행하고 있는 상태이다. AR 건식저장 시설을 운영하고 있거나 추진중인 나라는 미국, 일본, 독일, 캐나다, 스페인, 체코, 스위스 등으로 AR 건식저장을 거쳐 중간저장이나 재처리시설로 수송하는 방식을 채택하고 있다. 우리나라의 경우 월성에서 콘크리트 Silo 건식저장을 이미 사용하고 있으며 일부 다른 원자로도 사용후핵연료 저장능력이 한계에 도달하고 있는 현실을 감안할 때 AR 임시 저장은 불가피한 것으로 여겨진다. 본 보고서에서는 고리를 비롯한 국내원전에 적용 가능한 외국의 AR 저장 시스템 각각에 대하여 설계특성, 설계요건, 기술기준 및 현황 등을 논의하였다. 대부분의 경우 저장용기 인허가 기간은 20년으로 제한하고 있으며 전 수명기간동안 재질의 건전성, 밀봉유지 등이 중요하게 요구되고 있다.

• 한국윤활학회:학술대회논문집
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• 한국윤활학회 1998년도 제28회 추계학술대회
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• pp.3-8
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• 1998

The industrial revolution in England was based on the manufacturing systems by the power of water mill and rapidly progressed by the innovation of steam engine. It is no exaggeration to say that today's civilization is realized by the development of various types of power machinery, namely fluid machinery and heat engine. The electric energy is converted mainly from thermal energy (mainly steam) of mineral oil, coal and nuclear fuel through generator connected with steam turbine which is a kind of power machinery. There are various types of power machinery as shown in Tables 1a and 1b. They are classified into two types by use. One is absorption type of fluid and/or thermal energy, for examples, windmill and heat engine. The other is provision type of the energies for examples, pump, compressor and propulsion. By flow type, they are also classified by two types, turbo type and positive-displacement type. The turbo type began from water mill and windmill and evolve to steam turbine and finally to gas turbine. The positive-displacement type started from reciprocating water pump and developed into steam engine and changed to reciprocating combustion engine. The pumps and motors used in oil hydraulic system for power control are also positive-displacement type.