• Title/Summary/Keyword: 메탄발산량

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Estimation of Methane Emission Flux Using a Laser Methane Detector at a Solid Waste Landfill (레이저메탄검지기를 활용한 폐기물매립지 표면발생량 산정에 관한 연구)

  • Kang, Jong-Yun;Park, Jin-Kyu;Lee, Nam-Hoon
    • Journal of the Korea Organic Resources Recycling Association
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    • v.23 no.3
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    • pp.78-84
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    • 2015
  • The aim of this study was to evaluate methane emission flux based on spatial methane concentration using laser methane detector, and geospatial methodology (Inverse distance weighting) at a landfill. The obtained results showed that the spatial methane concentrations were in good agreement with the methane emission fluxes. Thus, it was concluded that the methane emission flux could be derived from spatial methane concentrations. In addition, the results of the geospatial calculations showed that 12.85% of the total area contributed more than 42.21% of total flux. This suggested that the geospatial methodology might be essential in chamber method to determine accurate methane emission fluxes from landfills.

Analysis of surface emission and oxidation rate of landfill gas by major discharge path of landfill (매립장 주요 배출경로별 매립가스 표면발산량 및 산화율 분석)

  • Seung-Kyu Chun;Jong-Keun Park;Myoung-Gwan Kim
    • Journal of the Korean Applied Science and Technology
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    • v.40 no.3
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    • pp.425-434
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    • 2023
  • An analysis was conducted on landfill gas generation and surface emission by major routes for three landfill sites of S Landfill in the metropolitan area. LS1, which had a total landfill gas generation ratio of 10.9%, accounted for 49.4% of the total surface emissions. The total surface emission of methane alone was 13.6 Nm3/min in the three landfill sites. Among them, the surface emission of methane at LS1, LS2, and LS3 was 8.4(61.7%), 4.0(29.4%), and 1.2 Nm3/min(8.9%), respectively. By emission path in the upper, slope, and dike, it was 7.3(53.2%), 6.4(46.7%), and 0.02 Nm3/min(0.1%). The dike section of the major surface emission areas showed the largest oxidation rate at 87.5%, followed by the upper at 72.3%, and the slope at 71.8%. Based on methane generation, LS1 had the largest surface emission contribution rate, with 61.7% of the total by S Landfill. By major emission path, the slope section of LS1 accounted for 41.7% of the total, the upper section of LS2 24.4%, and the upper section of LS1 20.0%, which accounted for 86.1% of the total methane surface emission of S Landfill. Therefore, it is concluded that intensive management will be necessary.

Improvement Method for the Post-Management End System of a Landfill by Applying Total Pollutant Load Concept (오염총량 개념을 적용한 매립장 사후관리종료제도 개선 방안)

  • Chun, Seung-Kyu;Sim, Nak-Jong;Jeon, Eun-Jeong;Ryu, Don-Sik
    • Journal of the Korean GEO-environmental Society
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    • v.22 no.2
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    • pp.15-23
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    • 2021
  • A method of improving the post-management end system of a landfill that reflected total pollutant load was applied to the SUDOKWON 1st Landfill Site. Modeling results showed that the ratio of remaining methane, when compared to the total maximum potential of 2,521 × 106 Nm3, was estimated to be 8.8% in 2020, 7.0% in 2030, and 6.5% in 2040. If the average oxidation rate of 89.1% in 2005-2019 was applied, the ratio decreased by 1.01% in 2020, 0.76% in 2030, and 0.70% in 2040. This suggests that if the amount of methane generated is all emitted from the surface of the landfill after 2025, the real amount emitted to the atmosphere is less than that in 2019; therefore, the post-management end is possible. According to the results of trend analysis of the quality of leachate water, effluent criteria for Biochemical Oxygen Demand (BOD) can be satisfied in 2024, while those for Chemical Oxygen Demand (COD) and Total Nitrogen (T-N) can be satisfied in 2047 and 2117, respectively. If the post-management end system changed based on total pollutant load, the post-management can be terminated BOD today and COD within a few years; however, the fact that T-N could be terminated only after 2041 shows the need to fundamentally change management methods.

Comparison and Optimization of Flux Chamber Methods of Methane Emissions from Landfill Surface Area (매립지 표면의 메탄 발산량 실측을 위한 플럭스 챔버의 방법론적 비교와 최적화)

  • Jeong, Jin Hee;Kang, Su Ji;Lim, Jong Myoung;Lee, Jin-Hong
    • Journal of Korean Society of Environmental Engineers
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    • v.38 no.10
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    • pp.535-542
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    • 2016
  • As one of the most cost-effective methods for surface emission measurements, flux chamber method has been used worldwide. It can be classified into two types: SFC (with slope method) and DFC (with steady-state method). SFC (static flux chamber) type needs only simple equipment and is easy to handle. However, the value of flux might vary with SFC method, because it assumes that the change of concentration in chamber is linear with time. Although more specific equipments are required for DFC (dynamic flux chamber) method, it can lead to a constant result without any ambiguity. We made a self-designed DFC using a small and compact kit, which recorded good sample homogeneity (RSD < 5%) and recovery ( > 90%). Relative expanded measurement uncertainty of this improved DFC method was 7.37%, which mainly came from uncontrolled sweep air. The study shows that the improved DFC method can be used to collect highly reliable emission data from large landfill area.