Journal of Korean Society of Coastal and Ocean Engineers (한국해안·해양공학회논문집)

Korean Society of Coastal and Ocean Engineers (한국해안·해양공학회)
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Reproduction of Shallow Tides and Tidal Asymmetry by Using Finely Resolved Grid on the West Coast of Korea

서해연안 상세해상을 통한 천해조석 및 조석비대칭 재현

  • Suh, Seung-Won (Department of Coastal Construction Engineering, Kunsan National University)
  • 서승원 (군산대학교 해양건설공학과)
  • Received : 2011.06.29
  • Accepted : 2011.07.23
  • Published : 2011.08.29
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Abstract

Finite element grid system using h-refinement on the Yellow Sea was constructed based on previous study (Suh, 1999b) from 14 K to 210 K and special attention was concentrated on refining the coastal zone. In grid generation, depth change between adjacent points and non-dimensional tidal wave length ratio were considered. As a result approximately a quarter of the total nodes are located nearby 5 m of shallow area. Accurate bathymetry data using 30's and ETOPO1 with open boundary conditions of 8 major tidal constituents extracted automatically from FES2004 have been applied. In tidal simulation a 3-dimensional nonlinear harmonic model was setup and tidal amplification due to changes in vertical turbulent and bottom friction were simulated. In this study not only 8 major tidal constituents but also nonlinear shallow tides $M_4,$, $MS_4$ and long period $M_f,$, $M_{sf}$ were reproduced. It is found that implication of spatial variation of friction coefficient plays a very important role in reproduction of astronomical and shallow tides which are computed by iterative computation of nonlinear terms. Also it should be considered differently with respect to tidal periods. To understand the distribution of tidal asymmetry, amplitude ratio of $M_4/M_2$ and phase differences $2g(M_2)-g(M_4)$ were calculated. Tidal distortion ratio marks up to 0.2 on the west coast showing shallow coastal characteristics and somewhat wide range of ebb-dominances in front of Mokpo area are reproduced.

황해 조석모의를 위한 유한요소 격자체계가 h-상세화에 의해 구축되어 이전연구(서, 1999b) 14 K 절점에 비해 210 K로 연안지역 해상이 특별하게 고려되었다. 격자생성시 인접절점간 수심변화, 무차원 조석파장비가 고려되어 전체절점의 약 1/4이 수심 5 m 내외 연안역에 집중적으로 분포되었다. 수심에 ETOPO1 및 30초 정밀자료가 적용되었고 개방경계에 FES2004로부터 자동추출된 8대분조가 정의되었다. 조석모의에는 비선형 3차원 조화모형이 수립되었으며, 연직난류와 바닥마찰계수의 변화에 따른 서해연안의 조석확폭이 모의되었고, 8대분조 및 $M_4,$ $MS_4$ 등 비선형 천해조석과 $M_f$$M_{sf}$의 장주기 등이 재현되었다. 천문조뿐만 아니라 비선형 항의 반복에 의해 계산되는 천해조 해석결과에 마찰계수의 공간적변화가 미치는 영향이 지대하여, 조석 주기별로 다른 값을 적용하는 것이 제시되었다. 조석 비대칭성 분포를 파악하고자 진폭비 $M_4/M_2$와 위상차 $2g(M_2)-g(M_4)$를 계산하였는데, 우리나라 서해연안에 조석왜곡 비율이 0.2에 다다르는 등 천해역 특성이 뚜렷하며 목포해역 전면에 폭넓은 낙조우세가 재현되었다.

Keywords

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