• 제목/요약/키워드: TAPM

검색결과 4건 처리시간 0.023초

Numerical Study on the Impact of Power Plants on Primary PM10 Concentrations in South Korea

  • Park, Il-Soo;Song, Chang-Keun;Park, Moon-Soo;Kim, Byung-Gon;Jang, Yu-Woon;Ha, Sang-Sub;Jang, Su-Hwan;Chung, Kyung-Won;Lee, Hyo-Jung;Lee, Uh-Jeong;Kim, Sang-Kyun;Kim, Cheol-Hee
    • Asian Journal of Atmospheric Environment
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    • 제12권3호
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    • pp.255-273
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    • 2018
  • To develop effective emission abatement strategies for eighteen coal-fired power plants located throughout Korea, power plant emission data and TAPM (The Air Pollution Model) were used to quantify the impact of emission reductions on primary $PM_{10}$ concentrations. TAPM was validated for two separate time periods: a high $PM_{10}$ concentration period from April 7 to 12, 2016, and a low $PM_{10}$ concentration period from June 1 to June 6 2016. The validated model was then used to analyze the impacts of five applicable power plant shut-down scenarios. The results showed that shut-down of four power plants located within the Seoul metropolitan area (SMA) would result in up to 18.9% reduction in maximum $PM_{10}$ concentrations, depending on synoptic conditions. A scenario for the shutdown of a single low stack height with highest-emission power plant located nearest to Seoul showed a small impact on averaged $PM_{10}$ concentrations (~1%) and 4.4% ($0.54{\mu}g/m^3$) decrease in maximum concentration. The scenario for four shutdowns for power plants aged more than 30 years within SMA also showed a highest improvement of 6.4% ($0.26{\mu}g/m^3$ in April) in averaged $PM_{10}$ concentrations, and of 18.9% ($2.33{\mu}g/m^3$ in June) in maximum concentration, showing almost linear relationship in and around SMA. Reducing gaseous air pollutant emissions was also found to be significant in controlling high $PM_{10}$ concentrations, indicating the effectiveness of coreduction of power plant emissions together with diesel vehicle emissions in the SMA. In addition, this study is implying that secondary production process generating $PM_{10}$ pollution may be a significant process throughout most regions in Korea, and therefore concurrent abatement of both gas and particle emissions will result in more pronounced improvements in air quality over the urban cities in South Korea.

수도권지역에서의 권역간 대기오염물질 상호영향 연구 (A Regional Source-Receptor Analysis for Air Pollutants in Seoul Metropolitan Area)

  • 이용미;홍성철;유철;김정수;홍지형;박일수
    • 한국환경과학회지
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    • 제19권5호
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    • pp.591-605
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    • 2010
  • This study were to simulate major criteria air pollutants and estimate regional source-receptor relationship using air quality prediction model (TAPM ; The Air Pollution Model) in the Seoul Metropolitan area. Source-receptor relationship was estimated by contribution of each region to other regions and region itself through dividing the Seoul metropolitan area into five regions. According to administrative boundary, region I and region II were Seoul and Incheon in order. Gyeonggi was divided into three regions by directions like southern(region III), northern(IV) and eastern(V) area. Gridded emissions ($1km{\times}1km$) by Clean Air Pollicy Support System (CAPSS) of National Institute of Environmental Research (NIER) was prepared for TAPM simulation. The operational weather prediction system, Regional Data Assimilation and Prediction System (RDAPS) operated by the Korean Meteorology Administration (KMA) was used for the regional weather forecasting with 30km grid resolution. Modeling period was 5 continuous days for each season with non-precipitation. The results showed that region I was the most air-polluted area and it was 3~4 times more polluted region than other regions for $NO_2$, $SO_2$ and PM10. Contributions of $SO_2$ $NO_2$ and PM10 to region I, II and III were more than 50 percent for their own sources. However region IV and V were mostly affected by sources of region I, II and III. When emissions of all regions were assumed to reduce 10 and 20 percent separately, air pollution of each region was reduced linearly and the contributions of reduction scenario were similar to those of base case. As input emissions were reduced according to different ratio - region I 40 percent, region II and III 20 percent, region IV and V 10 percent, air pollutions of region I and III were decreased remarkably. The contributions to region I, II, III were also reduced for their own sources. However, region I, II and III affected more regions IV and V. Shortly, graded reduction of emission could be more effective to control air pollution in emission imbalanced area.

수도권 지역에서 AWS자료 동화에 의해 개선되는 바람장 및 농도장의 통계적 분석 (Statistical Performance for wind and pollution fields simulated by AWS assimilation processes in Seoul metropolitan area)

  • 박일수;김철희;김정수;유철;김록호;이석조
    • 한국대기환경학회:학술대회논문집
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    • 한국대기환경학회 2002년도 추계학술대회 논문집
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    • pp.161-161
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    • 2002
  • 수도권 지역에서 3차원 바람장 및 농도장의 공간 특징을 모의하기 위해 AWS 자료동화 기법을 호주 CSIRO에서 개발된 비정역학 TAPM(The Air Pollution Model, V.2) 에 적용하여 2002년 7월 2일부터 7월 11일까지 10일 동안 1km$\times$1km격자에서 바람장 및 농도장을 도출하였다. (중략)

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수도권지역에서 오염원별 대기오염농도 기여도 평가 (Estimation of Source Contribution by Air Pollutant Type (Point, Area, Line) over Seoul Metropolitan Area)

  • 박일수;이석조;김종춘;김상균;이동원;유철;이재범;송형도;이정영;김지현
    • 한국대기환경학회지
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    • 제21권5호
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    • pp.495-505
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    • 2005
  • This study is to estimate source contribution by air pollutantion types (point, area, line) over Seoul metropolitan area. The Air Pollution Model (TAPM) and the highly resolved anthropogenic and biogenic gridded emissions ($1km{\times}1km$) were applied to simulate $SO_2,\;NO_2,\;O_3\;and\;PM_{10}$ concentrations by seasons and contribution was estimated by their source types (point, area, line). The results showed that the simulated concentrations of secondary pollutant agreed well with observed values with an index of agreement (IOA) over 0.4, whereas IOAs over 0.3 were observed for most primary pollutants. The contributions of each source types by seasons were similar. The point source contribution was the highest for $SO_2$ at medium level ranged from $55.1\%\;to\;61.5\%$. But the contribution from area source during for the spring and summer increased as the concentration level increased. The line source contribution was the highest for $NO_2$ at all levels ranged from $68.3\%\;to\;93.1\%$. The results indicate that $SO_2$ emissions should be mainly controlled from point source, as well as area source at higher level concentration. Also, $NO_2\;and\;PM_{10}$ to from line source should be controlled.