Journal of Environmental Science International (한국환경과학회지)

The Korean Environmental Sciences Society (한국환경과학회)
권호 표지

Application of Thermal Discharge Dispersion Model on Cheonsu Bay

천수만 해역에서 온배수 확산모델의 적용

  • 박영기 (군산대학교 환경공학과)
  • Published : 1995.06.01
Download PDF
⟨ Previous Next ⟩

Abstract

This Daper presents effective simulation of the dispersion of thermal discharge which can be relesed at Boryong power plant. Applied numerical models are finite difference method for hydrodynamic analysis and Masch-model comprised of conditions for ambient current velocity. Application of these models is done in Cheonsu Bay Summing up the results of this study are as follows; 1. It is found that the result for measurements of temperature appears high at southwardly Songdo on flood. The reason is that tidal currents which flowed north direction were accompanied with southwardly dispersed thermal discharge. A minute Particle of thermal Plume has a tendency to dispels inward Deacheon Bay. 2. According to the results of numerical experiment, maximum distance for thermal discharge dispersion appeared 10.8 km at lower part and 8.6 km at upper part with power plant outlet as starting point. 3. Comparative the numerical simulation and Airbone Multispectral Scanner indicated that thermal discharge should be verified separative phenomena. The simulated results were compared with field data set showing good agreement. It is concluded that these model can be simulated well.

Keywords

References

  1. 한국해양학회지 v.11 한국연안의 표면해수와 대기간의 열교환 봉종헌
  2. 보령화력 온배수확산분포조사 서울대학교 자연과학대학 부설 해양연구소
  3. 연안해역에서 온배수확산예측수법의 적합성에 관한 연구 일본전력중앙연구소
  4. 한국해안 · 해양공학회지 v.23 no.3 표면온배수 난류모형 최홍식;이길성
  5. Ocenaographic studies for Kori nuclear power plants KORDI
  6. 보령 T/P 냉각수가 연안양식 수산물에 미치는 영향 조사 한국전력공사 기술연구원
  7. MIT-EL 87-008 Prediciting Circulation and Dispersion Near Coastal Power Plants : Applications Using Models ELA Adams,E.E.;Cosler,D.J.
  8. Cneter for Environmental Studies Surface thermal plumes: Evaluation of Mathematical Models for the Near and Complete Field Dunn,W.E.;A.J.Policastro;R.A.Paddock
  9. J. royal Astronom. Sco. v.42 Tidal computations for Morecambe Bay. Geophys Flather,R.A.;N.S.Heaps
  10. Final Report to U.S. Atomic Energy Commission. R.M. Parsons Lab. for Water Resources and Hydro. no.203 An Assessment of Techniques for Hydrothermal Impact Prediction Jirka,G.;H.Abraham;D.R.F.Harleman
  11. Tech. rept. HYD 12-7104 A short-term conservative transport model for shallow estuaries Masch,F.D.
  12. J. Fluid Mech. v.95 no.4 Mathermatical Modelling of Three-Dimensional Heated Surface Jets McGuirk,J.J.;Rodi,W.
  13. Physical oceanography of estuaries Offic,C.B.
  14. J. Hyd. Res. v.15 An Experimental Study of Bluff Buoyant Turbulent Surface Jets Pande,B.B.L.;Rajaratnam,N.
  15. J. of Hyd. Eng. v.114 no.7 Prediction of Three-Dimensional Thermal Discharge Flows Raithby,G.D.;Elliot,R.V.;Hutchinson,B.R.
  16. Civil Eng. Lab. Development of Predictive Method for Thermal Diffusion in the sea Near the Cooling Water Outlet Wada,W.;Araki,H.
  17. 한국해안 · 해양공학회지 v.3 no.3 표층밀도분류의 3차원 수치해석 허재영