• 분석과학
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• 제28권5호
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• pp.353-360
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• 2015

지하수 중 라돈은 끓임으로서 쉽게 제거할 수 있다. 다양한 라돈 농도를 가진 13 개 지하수 시료를 이용하여 가열 시간과 온도를 변경시키며 라돈의 제거효율을 평가하였다. 지하수 시료는 Bladder 펌프를 이용하여 채수하였고 용존산소, 수소이온농도 등의 현장수질은 Flow cell을 이용하여 측정 하였다. 경과시간 및 수온 별로 분취한 시료의 라돈 농도는 액체섬광계수기(LSC)로 분석하였다. 실험결과, 온도가 높을수록 경과시간에 따른 지하수 중 라돈의 제거율도 높아지며 지하수 중 라돈의 초기농도가 높을수록 경과시간에 따른 지하수 중 라돈의 제거율은 낮아진다. 즉, 지하수 중 라돈의 농도가 높을수록 가열에 의한 라돈 제거 시 더 많은 시간과 에너지를 필요로 한다. 따라서 지하수 중 라돈 제거율은 주로 라돈초기농도, 가열온도, 그리고 가열시간에 의해 결정된다.

• 한국산업보건학회지
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• 제27권1호
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• pp.38-45
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• 2017

Objectives: Radon may be second only to smoking as a cause of lung cancer. Radon is a colorless, tasteless radioactive gas that is formed via the radioactive decay of radium. Therefore, radon levels can build up based on the amount of radium contained in construction materials such as phospho-gypsum board or when ventilation rates are low. This study provides our findings from evaluation of radon gas at facilities and offices in an industrial complex. Methods: We evaluated the office rooms and processes of 12 manufacturing factories from May 14, 2014 to September 23, 2014. Short-term data were measured by using real-time monitoring detectors(Model 1030, Sun Nuclear Co., USA) indoors in the office buildings. The radon measurements were recorded at 30-minute intervals over approximately 48 hours. The limit of detection of this instrument is $3.7Bq/m^3$. Also, long-term data were measured by using ${\alpha}-track$ radon detectors(${\alpha}-track$, Rn-tech Co., Korea) in the office and factory buildings. Our detectors were exposed for over 90 days, resulting in a minimum detectable concentration of $7.4Bq/m^3$. Detectors were placed 150-220 cm above the floor. Results: Radon concentrations averaged $20.6{\pm}17.0Bq/m^3$($3.7-115.8Bq/m^3$) in the overall area. The monthly mean concentration of radon by building materials were in the order of gypsum>concrete>cement. Radon concentrations were measured using ${\alpha}-track$ in parallel with direct-reading radon detectors and the two metric methods for radon monitoring were compared. A t-test for the two sampling methods showed that there is no difference between the average radon concentrations(p<0.05). Most of the office buildings did not have central air-conditioning, but several rooms had window- or ceiling-mounted units. Employees could also open windows. The first, second and third floors were used mainly for office work. Conclusions: Radon levels measured during this assessment in the office rooms of buildings and processes in factories were well below the ICRP reference level of $1,000Bq/m^3$ for workplaces and also below the lower USEPA residential guideline of $148Bq/m^3$. The range of indoor annual effective dose due to radon exposure for workers working in the office and factory buildings was 0.01 to 1.45 mSv/yr. Construction materials such as phospho-gypsum board, concrete and cement were the main emission sources for workers' exposure.

• 한국입자에어로졸학회지
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• 제13권2호
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• pp.87-95
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• 2017

Radon ($Rn^{222}$) is a radioactive gas and is found at high concentrations underground. Investigations were done in many years specifically on public transportations such as in the subway stations, concourses and platforms for these are located underground areas. This study correlates the $Rn^{222}$ concentrations with the Particulate Matter (PM) concentration for the gas could be attached or trapped inside these particles. It was done on the opening subway tunnel of Miasageori Station going to Mia Station (Line 4) last August 2016. Based on the result, the $Rn^{222}$ were more influenced on the mass ratio (%) of PM present in the air instead of its mass concentration (${\mu}g/m^3$). As the $PM_{10}$ mass ratio increases ($42.32{\pm}1.03%$) during morning rush-hours, radon starts to increase up to $0.97{\pm}0.03pCi/L$. But during the afternoon $Rn^{222}$ concentrations decreased while the composition were stable at $22.96{\pm}3.0%$, $39.04{\pm}0.6%$ and $38.01{\pm}0.3%$ in $PM_1$, $PM_{2.5}$ and $PM_{10}$ respectively. It was then assumed that it could be the composition of the morning hours of the station were influencing the concentration of the radon.

• Journal of Radiation Protection and Research
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• 제16권1호
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• pp.1-13
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• 1991

국내 12개 지역의 340여 실내에서 측정한 라돈농도로부터 단순한 수학적 폐선량 평가모형을 이용하여 주민의 실효선량당량을 평가하였다. 수동적 시간적분형 CR-39 라돈컵으로 1990년 4월부터 10월까지 $3{\sim}4$개월 동안 측정 한 실내의 라돈농도는 지역별로 $33.82{\sim}61.42 Bq/m^3$(평균 : $48.90 Bq/m^3$)의 분포를 보였으며, 이로 인한 라돈자핵종의 평형등가라 돈농도$(EEC_{Rn})$는 라돈과 자핵종간의 평형인자의 값 0.4를 적용했을 때 $13.53{\sim}24.57Bq/m^3$(평균 : $19.55 Bq/m^3$)으로 예상되었다. 국제방사선방어위원회의 폐모형에 근거한 본 연구의 폐선량 평가모형에서 유도된 단위 평형등가라돈농도의 피폭당 실효선량당량환산 인자는 $1.07{\times}10^{-5}\;mSv/Bq\;h\;m^{-3}$으로 국제방사선방어위원회나 국제연합 방사선영향평가 과학위원회(UNSCEAR)에서 권고한 값과 잘 일치하였다. 동 선량환산인자와 CR-39 라돈 컵으로 측정 한 실내 의 평균 평형등가라돈농도를 년간 $0.75 m^3/h$의 호흡율로 호흡한 것으로 가정했을 때, 주민이 받는 년평균 폐선량당량 및 실효선량당량은 갹각 20.90 mSv 및 1.25 mSv인 것으로 평가되었다. 동 피폭선량은 국제연합(UNSCEAR)에서 1988년에 발표한 일반인의 년평균 자연방사선피폭 실효선량당량인 2.40mSv의 거의 50%에 상당하였다.

• 한국농촌건축학회논문집
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• 제22권2호
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• pp.9-17
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• 2020

The ratio of the deterioration housing in rural area was 29.6%, but it was 18.3% in urban area based on a 2018 survey. In consideration of the point, this study aims to analyze the actual condition of indoor air quality in rural houses to provide basic data for improving the indoor air environment. It was investigated 15housings of Hongseong-gun, Chungchengnam-do. To investigate the correlation between indoor air quality and housing type, both the field survey of housing type and precision diagnosis of concentration of indoor air pollutants such as HCHO, TVOC, Fine dust(PM-10, PM-2.5), CO₂, Radon. The results of this study are as follows. First, according to the average value of each element of rural old housing, the construction year was distributed in 1939~2004, and 12households(80%) living in houses older than 30years have passed for about 46years. As for the housing area, more than 12houses(80%) of 60㎡ or more and 3 houses (20%) of less than 60㎡ were often living in relatively small-scale housing. Second, as a result of measuring indoor air pollutants in rural houses, substances exceeding the standard values were found in HCHO, TVOC, CO₂. Third, in the case of Fine dust and Radon, none of such factors were exceeded the standard. Fourth, there was no significant difference in indoor air quality depending on housing type in rural houses. This paper is expected to contribute to the regional development projects and effective implementation of rural policies.

• 한국대기환경학회지
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• 제24권5호
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• pp.538-550
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• 2008

Radon is an invisible, odorless, and radioactive gas. It is formed by the disintegration of radium, which is a decay product of uranium. Some amounts of radon gas and its products are present ubiquitously in the soil, water, and air. Particularly high radon levels occur in regions of high uranium content. Although radon is permeable into indoor environment not only through geological features (bed rock and permeability) but also through the construction materials and underground water, the radiation from the geological features is generally main exposure factor. So there can be a problem in a certain space such as the underground and/or relatively poor ventilation condition. In this study, a GIS technique was used in order to investigate spatial distribution of radon measured from sub- way stations of 1 thru 8 in Seoul, Korea in 1991, 1998, 2001, and 2006. Spatial analysis was applied to reproduce the radon distribution. We utilized spatial analysis techniques such as inverse distance weighted averaging (IDW) and kriging techniques which are widely used to relate between different spatial points. To validate the results from the analyses, the jackknife technique for an uncertainty test was performed. When the number of measuring sites was less than 100 and also when the number of omitted sites increased, the kriging technique was better than IDW. On the other hand, when the number of sites was over 100, IDW technique was better than kriging technique. Thus the selection of analytical tool was affected sensitives by the analysis based on the number of measuring sites.

• 한국건축시공학회지
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• 제18권1호
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• pp.59-65
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• 2018

라돈가스는 암석이나 토양 등에 존재하는 자연 방사성 물질인 우라늄이 붕괴할 때 발생하는 무색, 무취, 무미의 가스이다. 인체가 연간 노출되는 방사선의 85%는 자연 방사선에 의한 것이고, 그 중 50%가 라돈가스이다. 미국 환경보호청(EPA)의 조사결과에 의하면, 라돈가스에 장시간 노출될 경우 흡연자는 1,000명 중 62명, 비흡연자는 1,000명 중 7명이 폐암 발병률에 노출된다. 이러한 라돈가스의 위해성을 저감하고자 활성탄소를 사용하여 경화체를 제작하여 그에 대한 공극 특성과 라돈가스 저감 특성에 대한 실험을 진행하였다. 활성탄소를 활용하였을 경우, 측정기간이 길어질수록 라돈가스 농도는 급격한 저감과 그래프 상의 변화를 확인할 수 있었다. 또한 활성탄소의 재료적 특성 중 하나인 공극 분포와 미세공 특성을 파악할 수 있다.

• 한국대기환경학회:학술대회논문집
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• 한국대기환경학회 1999년도 추계학술대회 논문집
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• pp.297-298
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• 1999

라돈과 라돈 낭핵종은 예전부터 생활환경 중에 존재해 왔던 것으로 최근 산업화등으로 인해 급격히 증가하는 다른 오염물질과는 그 발생원이 다소 차이가 있지만 폐암, 위암등의 암을 유발시키는 중요한 요인이라는 것이 미국, 캐나다, 체코의 우라늄 광산 및 스웨덴, 영국의 비우라늄 광산에서 확인된 바 있어 그 관리의 중요성이 나날이 대두되고 있다(Guimond 등, 1979; UN, 1977).(중략)

• 한국컴퓨터정보학회논문지
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• 제25권1호
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• pp.117-124
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• 2020

본 연구는 실내공기질의 실시간 농도변화 분석을 통하여 일시적으로 기준값을 초과하는 항목에 대하여 원인 분석을 통하여 요양원의 쾌적한 실내공기질을 유지하기 위한 방안을 제안하고자 실시하였다. 요양원에서 미세먼지(PM10), 이산화탄소(CO2), 일산화탄소(CO), 휘발성유기화합물(VOC), 라돈(Radon) 등 5개 항목에 대하여 다목적 홀에서 봄(4월), 가을(9월)에 각1회 측정을 실시한 결과 측정 항목 모두 실내공기질 관리법에서 정한 기준을 만족하는 것으로 분석되었다. 실시간 농도 변화에 대한 분석 결과 병실의 경우 이산화탄소의 농도가 재실자 수에 의하여 기준치에 근접하는 수준을 보였으며 다목적 홀의 경우 이산화탄소 및 미세먼지는 주간보호 대상 어르신 및 근무자의 프로그램 활동과 휘발성유기화합물의 경우 식탁을 소독하기 위하여 사용하는 소독제(알코올) 및 만들기, 색칠하기 등의 프로그램 운용시 사용되는 보조도구(접착제)로 인하여 일시적으로 기준치를 초과하는 것으로 분석되었다. 결국 측정 대상 요양원에서는 온열환경을 고려하여 주기적인 환기, 천연소독제 사용 및 친환경 접착제 사용 등을 실시한다면 쾌적한 실내공기질 제공이 가능하고 요양원의 경쟁력 확보에도 기여할 것으로 판단된다.

• 자원환경지질
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• 제31권3호
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• pp.215-222
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• 1998

The radon (Rn-222) potential of metropolitan subway stations and soils in Seoul city were delineated using alpha-track filter and EDA-200 radon detectors, respectively. The uranium (U) and thorium (Th) contents were also determined using a Multi Channel Analyzer to identify the sources of radon gas. The average U concentrations in Seoul varies according to basement rock types. For example, there is $9.40{\pm}10.11ppm$ in the Precambrian metasedimentary rock (PM), $9.08{\pm}2.85ppm$ in the Jurassic Kwanaksan granite (JK) and $4.94{\pm}1.43ppm$ in the Jurassic Seoul granite (JS). Uranium contents in soil samples are $10.30{\pm}4.74ppm$ in JK, $10.10{\pm}7.43ppm$ in PM and $6.69{\pm}3.95ppm$ in JS and these closely reflect the content of uraniferous minerals. The levels of soil radon are $604{\pm}273pCi/L$ in JK, $502{\pm}275$ in JS and $262{\pm}211pCi/L$ in PM. The soil radon concentrations are shown to reflect soil permeability and porosity rather than their U contents. The mean indoor radon contents in subway stations are $1.50{\pm}0.62pCi/L$ on the 4th line, $1.41{\pm}0.95pCi/L$ on the 3rd line, $0.84{\pm}0.13pCi/L$ on the 1st line and $0.80{\pm}0.25pCi/L$ on the 2nd line. The subway stations located in the JK have the highest average radon concentration with $2.04{\pm}0.65pCi/L$, where levels of $1.57{\pm}0.81pCi/L$ occur in the JS and $0.80{\pm}0.23pCi/L$ in the PM. The highest radon levels of 4.1 pCi/L occur mainly in Keongbokkung station on the 3rd line and these exceed 4 pCi/L of the US EPA action level.