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2022 Vol.15, Issue 2 Preview Page

Original Article

30 June 2022. pp. 37-44
Abstract
References
1
Choi, J. R. (2018). An Analysis of Debris-Flow Propagation Characteristics and Assessment of Building Hazard Mapping Using FLO-2D. Crisisonomy. 14(2): 91-99.
2
Christen, M., Kowalski, J., and Bartelt, P. (2010). RAMMS: Numerical Simulation of Dense Snow Avalanches in Three-dimensional Terrain. Cold Regions Science and Technology. 63(1-2): 1-14. 10.1016/j.coldregions.2010.04.005
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FLO-2D (2009). FLO-2D Reference Manual. http://www.flo-2d.com.
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Kang, B. D. (2022). Analysis on Characteristics of Debris Flow of Hyper KANAKO Model Considering Buildings. Master Dissertation. Kangwon National University.
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Kim, G. J. (2021). A Study on the Analysis of Debris Flow Disaster Area Using Hyper Kanako Model. M. S. Dissertation. Kangwon National University.
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Kim, N. G. (2011). A Study on Transport and Diffusion of Debris Flow with FLO-2D. M. S. Dissertation. Kangwon National University.
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Kim, S. E., Paik, J. C., and Kim, K. S. (2013). Run-out Modeling of Debris Flows in MT. UMyeon using FLO-2D. Journal of the Korean Society of Civil Engineers. 33(3): 965-974.
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Kim, Y. H. (2017). Sediment Discharge Analysis according to Location Change of Check Dam Using Debris Flow Numerical Model. M. S. Dissertation. Kangwon National University.
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O’Brien, J. S. Julien, P. Y., and Fullerton, W. T. (1993). Two-dimensional Water Flood and Mudflow Simulation. Journal of Hydraulic Engineering. 119(2): 244-261.
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Oh, C.Y. and Jun, K. W. (2019). Terrain Data Construction and FLO-2D Modeling of the Debris-Flow Occurrences Area Journal Korean Society of Disaster & Security. 12(4): 53-61.
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Peng, S. H. and Lu, S. C. (2013). FLO-2D Simulation of Mudflow Caused by Large Landslide due to Extremely Heavy Rainfall In Southeastern Taiwan during Typhoon Morakot. Journal of Mountain Science. 10(2): 207-218. 10.1007/s11629-013-2510-2
12
Tak, W. J. (2015). A Study on Transport and Diffusion Range Estimate of Debris Flow using RAMMS. M. S. Dissertation. Kangwon National University.

Korean References Translated from the English

13
강배동 (2022). 건물을 고려한 Hyper KANAKO 모형의 토석류 유동특성 분석. 국내석사학위논문. 강원대학교.
14
김기중 (2021). Hyper Kanako 모형을 이용한 토석류 피해지역 해석에 관한 연구. 석사학위논문. 강원대학교.
15
김남균 (2011). FLO-2D 모형을 이용한 토석류의 이동과 확산에 관한 연구. 석사학위논문. 강원대학교.
16
김승은, 백중철, 김경식 (2013). Flo-2D 모형을 이용한 우면산 토석류 유동 수치모의. 대한토목학회논문집. 33(3): 965-974. 10.12652/Ksce.2013.33.3.965
17
김영환 (2017). 토석류 수치모형을 이용한 사방댐 위치 변화에 따른 토사유출해석. 석사학위논문. 강원대학교.
18
오채연, 전계원 (2019). “토석류 발생지역 지형자료 구축 및 FLO-2D 모델링.” 한국방재안전학회 논문집. 12(4): 53-61.
19
최정렬 (2018). FLO-2D 수치해석 모델을 이용한 토석류 거동 분석 및 건물 위험도 평가. 위기관리논집. 14(2): 91-99.
20
탁원준 (2015). RAMMS를 이용한 토석류 이동과 확산범위 산정에 관한 연구. 석사학위논문. 강원대학교.
Information
  • Publisher :Korean Society of Disaster and Security
  • Publisher(Ko) :한국방재안전학회
  • Journal Title :Journal of Korean Society of Disaster and Security
  • Journal Title(Ko) :한국방재안전학회 논문집
  • Volume : 15
  • No :2
  • Pages :37-44
  • Received Date :2022. 06. 20
  • Revised Date :2022. 06. 24
  • Accepted Date : 2022. 06. 29