• Journal of Pharmaceutical Investigation
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• 제33권2호
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• pp.145-149
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• 2003

Manufacturing facilities of the pharmaceuticals must meet certain level of the cleanness required so that foreign substances such as dust, moisture, heat, microorganism, or virus do not contaminate the product. In case of radiopharmaceuticals for medical treatment and diagnosis, not only should the operators and environment be protected from radiation but also need to be isolated from the foreign contaminant. Therefore, manufacturing facilities for radiopharmaceuticals must satisfy the design standards of both hot cell and clean room which are specified by GMP. However, standards of maintaining negative pressure for preventing spread of radioactive contaminant in isolated facilities conflict with the standards of maintaining positive pressure for keeping cleanness. To solve this problem, air pressure of hot cell was designed lower than in the adjacent area to meet standards of the radiation safety. To keep higher cleanness in certain part of the hot cell for filling, minimal relative positive pressure allows. In order to effectively maintain the cleanness that is required for production of Tc-99m generator, which takes 70% of whole demand of radiopharmaceuticals, the rooms placed in each side of production room are used as a buffer area and three lead hot cells are installed in production room. In this research, we established the appropriate engineered design concept for Tc-99m generator manufacturing facility, which satisfies both GMP cleanness standard for preventing particles, bacteria, other contaminants and the regulations of radiation safety for supervising and controlling the amount of radiation exposure and exhausted radioactivity. And the concept of multi-barrier buffer zones is introduced to apply negative air pressure for hot cell with first priority and to continue relative positive air pressure for clean room.

• 한국방사성폐기물학회:학술대회논문집
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• 한국방사성폐기물학회 2003년도 가을 학술논문집
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• pp.671-675
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• 2003

연구로 1,2호기 해체 사업이 본격적으로 착수하게 됨에 따라 2001년 8월부터 2002년 12월까지 연구로 2호기 부속시설인 동위원소 생산시설을 제염 및 해체하였다. 이 시설은 동위원소 생산용 콘크리트 핫셀, 납 핫셀 및 실험실로 구성되어 있다. 제염ㆍ해체의 대상물은 흄후드, 실험대, 씽크 및 오염된 내부 시설물이다. 안전한 해체 활동을 위해서 각종 지침서 및 절차서가 수립되었다. 해체 활동을 위해 총 20,933 man-hour의 인력이 소요되었고, 드릴링 머신 등 여러 장비가 투입되었다. 실험실에서의 최대 오염도는 유리성 오염도가 $\beta$ : 9.24 Bq/$\textrm{cm}^2$이였고, 고착성 오염도는 350,000 cpm이였다. 해체폐기물은 콘크리트류, 목재류 및 철재류 등으로 총 62.146 Ton이고, 작업자들의 피폭량은 0.33 mam-mSv로 나타났다.

• 한국원자력학회:학술대회논문집
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• 한국원자력학회 2003년도 춘계학술발표대회 요약집
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• pp.387.2-387.2
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• 2003

• Journal of Radiation Protection and Research
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• 제38권2호
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• pp.52-59
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• 2013

전베타 방사능 분석법을 이용한 내부오염 스크리닝법을 검증하였고 실제 의료용 동위원소 생산시설 종사자 내부오염을 판단하는데 적용하였다. 종사자의 작업 종료 후 첫 번째로 채취된 뇨시료(spot 시료)와 24시간 동안 취합된 뇨시료(24 h 시료)를 채취하여 측정하였다. 특정 종사자의 경우를 제외하고 대부분의 측정결과는 일반인 체내 기저준위인 100 Bq $kg^{-1}$을 기준으로 22% 이내로 변동폭이 작았다. 측정결과 작업종료 후 수 시간 이내 종사자 뇨시료의 전베타 농도가 전반적으로 35% 이상 상승하는 경향이 있었다. 또한 스크리닝 결과와 작업일지를 바탕으로 작업장내부 구조상 오염을 유발하는 요인을 추정 할 수 있었으며 추가 세부 핵종별 분석법을 바탕으로 내부피폭선량을 평가해야 할 것으로 판단되었다. 한편 사업장에서 신속히 적용 가능한 내부오염평가 절차를 수립하였다.

• Nuclear Engineering and Technology
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• 제48권3호
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• pp.613-623
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• 2016

Molybdenum-99 ($^{99}Mo$) is the most important isotope because its daughter isotope, technetium-99m ($^{99m}Tc$), has been the most widely used medical radioisotope for more than 50 years, accounting for > 80% of total nuclear diagnostics worldwide. In this review, radiochemical routes for the production of $^{99}Mo$, and the aspects for selecting a suitable process strategy are discussed from the historical viewpoint of $^{99}Mo$ technology developments. Most of the industrial-scale $^{99}Mo$ processes have been based on the fission of $^{235}U$. Recently, important issues have been raised for the conversion of fission $^{99}Mo$ targets from highly enriched uranium to low enriched uranium (LEU). The development of new LEU targets with higher density was requested to compensate for the loss of $^{99}Mo$ yield, caused by a significant reduction of $^{235}U$ enrichment, from the conversion. As the dramatic increment of intermediate level liquid waste is also expected from the conversion, an effective strategy to reduce the waste generation from the fission $^{99}Mo$ production is required. The mitigation of radioxenon emission from medical radioisotope production facilities is discussed in relation with the monitoring of nuclear explosions and comprehensive nuclear test ban. Lastly, the $^{99}Mo$ production process paired with the Korea Atomic Energy Research Institute's own LEU target is proposed as one of the most suitable processes for the LEU target.

• 한국전기전자재료학회논문지
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• 제20권5호
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• pp.467-470
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• 2007

Application field of neutron beam is very broad including industry, medicine and science. But the research and development and use of neutron beam is restricted within in narrow limits in this country, because neutron beam facility is insufficient - a big research facility of nuclear reactor(HANARO) and some small industrial facilities which use radioisotope neutron source are available. This paper compare and investigate the results of experiment and numerical analysis of the discharge in the spherically convergent beam fusion device which were expected as a portable neutron source. The spherically convergent beam fusion device will offer stability in neutron production, possibility of movement for convenience, low construction cost and higher neutron flux than radioisotope neutron source. The star mode discharge which efficiently generate neutron, were observed at both results.

• Nuclear Engineering and Technology
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• 제50권8호
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• pp.1355-1363
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• 2018

Many radionuclides exist in normal environment and artificial radionuclides also can be detected. The radionuclides ($^{131}I$) are widely used for labeling compounds and radiation therapy. In Korea, the radionuclide ($^{131}I$) is produced at the Radioisotope Production Facility (RIPF) at the Korea Atomic Energy Research Institute in Daejeon. The residents around the RIPF assume that $^{131}I$ detected in environmental samples is produced from RIPF. To ensure the safety of the residents, the radioactive concentration of $^{131}I$ near the RIPF was investigated by monitoring environmental samples along the Gap River. The selected geographical places are near the nuclear installation, another possible location for $^{131}I$ detection, and downstream of the Gap River. The first selected places are the "front gate of KAERI", and the "Donghwa bridge". The second selected place is the sewage treatment plant. Therefore, the Wonchon bridge is selected for the upstream of the plant and the sewage treatment plant is selected for the downstream of the plant. The last selected places are the downstream where the two paths converged, which is Yongshin bridge (in front of the cogeneration plant). In these places, environmental samples, including sediment, fish, surface water, and aquatic plants, were collected. In this study, the radioactive iodine ($^{131}I$) detection along the Gap River will be investigated.

• Journal of Radiation Protection and Research
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• 제42권3호
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• pp.141-145
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• 2017

Background: The concrete walls inside the vaults of cyclotron facilities are activated by neutrons emitted by the targets during radioisotope production. Reducing the amount of radioactive waste created in such facilities is very important in case they are decommissioned. Thus, we proposed a strategy of reducing the neutron activation of the concrete walls in cyclotrons during operation. Materials and Methods: A polyethylene plate and B-doped Al sheet (30 wt% of B and 2.5 mm in thickness) were placed in front of the wall in the cyclotron room of a radioisotope production facility for pharmaceutical use. The target was Xe gas, and a Cu block was utilized for proton dumping. The irradiation time, proton energy, and beam current were 8 hours, 30 MeV, and $125{\mu}A$, respectively. To determine a suitable thickness for the polyethylene plate set in front of the B-doped Al sheet, the neutron-reducing effects achieved by inserting such sheets at several depths within polyethylene plate stacks were evaluated. The neutron fluence was monitored using an activation detector and 20-g on de Au foil samples with and without 0.5-mm-thick Cd foil. Each Au foil sample was pasted onto the center of a polyethylene plate and B-doped Al sheet, and the absolute activity of one Au foil sample was measured as a standard using a Ge detector. The resulting relative activities were obtained by calculating the ratio of the photostimulated luminescence of each foil sample to that of the standard Au foil. Results and Discussion: When the combination of a 4-cm-thick polyethylene plate and B-doped Al sheet was employed, the thermal neutron rate was reduced by 78%. Conclusion: The combination of a 4-cm-thick polyethylene plate and B-doped Al sheet effectively reduced the neutron activation of the investigated concrete wall.

• 공업화학
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• 제16권6호
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• pp.794-799
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• 2005

석유화학산업의 양적인 성장과 더불어 공정 간 연결역할을 하는 배관설비도 또한 증가하여 유지 보수를 위해 매년 많은 예산이 소요된다. 현재 국내에는 배관설비에 대한 가동 중 이상 유무를 진단할 수 있는 기술이 거의 없는데 반해, 선진국을 중심으로 하여 감마선을 이용한 배관진단 기술이 1960대 이후부터 연구되었다. 본 연구에서는 이상 현상을 보이고 있는 가동 중 증류탑 배관에 대한 원인분석 및 그 정도를 파악하기 위하여 밀봉감마선원($^{137}Cs$)과 계측기를 이용하여 현장 실험을 수행하였다. 유체이송 배관을 중심으로 한쪽에는 감마선원과 맞은편에는 계측기를 설치하고 일정간격으로 감마선 투과계측을 하였다. 계측결과로부터 배관 내부에 존재하는 유체와 다른 밀도분포 구간을 발견하였고, 추후 이것이 가스층이었음이 확인됨으로써 현장 관계자에게 유용한 정보를 제공하였다. 감마선을 이용한 배관진단 기술이 내부 유체의 분포상태에 대한 정보를 제공하는데 효율적인 진단기술임을 현장실험을 통해 확인하였다.

• Nuclear Engineering and Technology
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• 제53권4호
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• pp.1378-1389
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• 2021

TRIUMF, Canada's particle accelerator centre, is constructing a new high-power ISOL (Isotope Separation On-Line) facility called ARIEL (Advanced Rare IsotopE Laboratory). Thick porous targets will be bombarded with up to 48 kW of 480 MeV protons from TRIUMF's cyclotron, or up to 100 kW of 30 MeV electrons from a new e-linac, to produce short-lived radioisotopes for a variety of applications, including nuclear astrophysics, fundamental nuclear structure and nuclear medicine. For efficient release of radioisotopes, the targets are heated to temperatures approaching 2000 ℃, and are exposed to GSv/h level radiation fields resulting from intended fissions and spallations. Due to these conditions, the operational life for each target is only about five weeks, calling for frequent remote target exchanges to limit downtime. A few days after irradiation, the targets have a residual radiation field producing a dose rate on the order of 10 Sv/h at 1 m, requiring several years of decay prior to shipment to a national disposal facility. TRIUMF is installing new remote handling infrastructure dedicated to ARIEL, including hot cells and a remote handling crane. The system design applies learnings from multiple existing facilities, including CERN-ISOLDE, GANIL-SPIRAL II as well as TRIUMF's ISAC (Isotope Separator and ACcelerator).