철도 방음벽의 형상에 따른 태양복사에너지 흡수 특성 연구Effect of Railway Noise Barrier Shape on Solar Radiation Energy Absorption
- Authors
- 정찬호; 이진운; 장용준; 김주헌; 유홍선; 이성혁
- Issue Date
- Dec-2013
- Publisher
- 한국액체미립화학회
- Keywords
- 방음벽; 태양에너지; 전산유체해석; 방위각; 건물일체형 태양광발전시스템; Noise barrier; Solar energy; CFD; Azimuth angle; BIPV(Building Integrated Photovoltaic System)
- Citation
- 한국액체미립화 학회지, v.18, no.4, pp 209 - 214
- Pages
- 6
- Journal Title
- 한국액체미립화 학회지
- Volume
- 18
- Number
- 4
- Start Page
- 209
- End Page
- 214
- URI
- https://scholarworks.bwise.kr/cau/handle/2019.sw.cau/19152
- DOI
- 10.15435/JILASSKR.2013.18.4.209
- ISSN
- 1226-2277
- Abstract
- The present study aims to determine the optimized shape for the maximum electric energy production of building integrated photovoltaic system (BIPV) noise barrier through numerical analysis. The shape of BIPV noise barrier is one of the important factors in determining angle difference between direction vector of the sun and normal vector of the sound barrier surface. This study simulated numerically the flow and thermal fields for different angles in the range from 90° to 180°, and from the results, the amount of isolation onto noise barrier surface was estimated along the angle between ground and top side of noise barrier. The commercial CFD code (Fluent V. 13.0) was used for calculation. It was found that the maximum amount of insolation per unit area was 19.6 MJ for 105º case during a day in summer and was estimated 12.4 MJ in 150º case during a day in winter. The results of the summer and winter cases showed the different tendency and this result would be useful in determining the appropriate shape of noise barrier which can be mounted under various circumstances.
The present study aims to determine the optimized shape for the maximum electric energy production of building integrated photovoltaic system (BIPV) noise barrier through numerical analysis. The shape of BIPV noise barrier is one of the important factors in determining angle difference between direction vector of the sun and normal vector of the sound barrier surface. This study simulated numerically the flow and thermal fields for different angles in the range from 90° to 180°, and from the results, the amount of isolation onto noise barrier surface was estimated along the angle between ground and top side of noise barrier. The commercial CFD code (Fluent V. 13.0) was used for calculation. It was found that the maximum amount of insolation per unit area was 19.6 MJ for 105º case during a day in summer and was estimated 12.4 MJ in 150º case during a day in winter. The results of the summer and winter cases showed the different tendency and this result would be useful in determining the appropriate shape of noise barrier which can be mounted under various circumstances.
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