珠海市沿海风暴潮数值模拟试验研究

作者：黄宝霞1 2  李希茜1 2  罗军1 2

单位：1. 国家海洋局南海预报中心, 广东 广州 510310; 2. 自然资源部海洋环境探测技术与应用重点实验室, 广东 广州 510310

关键词：ELCIRC模型 台风“天鸽” 数值模拟 风暴增水

分类号：P731.23

出版年·卷·期（页码）：2024·41·第二期（13-23）

摘要：

基于ELCIRC模型建立了适用于珠海市海域的风暴潮模型,以1713号台风“天鸽”路径为基础,通过改变台风入射角、台风登陆点、台风移速等方式构建登陆或者影响珠海市的台风路径,并进行风暴潮数值模拟计算,分析珠海市沿海风暴潮特征。结果表明:改变台风入射角时,珠海市沿海不同岸段的风暴潮将出现较大差异性;距离台风中心约15~100 km且位于台风右半圆的沿海地区将是风暴潮的重灾区;在珠海市的香洲区和斗门区沿岸,风暴增水总体随着台风移速变慢而呈现增大的趋势,但金湾区的情况则较为复杂,当台风移速为15~30 km/h时,在沿着台风“天鸽”的移动路径上会产生较强的风暴潮过程。

Based on the ELCIRC model and Typhoon "Hato"(1713), a series of typhoon tracks landing or affecting Zhuhai have been conducted by changing incident angle, landfall location or moving speed of the typhoon. Feature of coastal storm surge in Zhuhai are studied by the ELCIRC numerical simulation. The results show that large differences in maximum storm surge exist in different coastal areas of Zhuhai when the incident angle is changed. Coastal areas are severely impacted when locate in the right half circle of the typhoon with its distance to the typhoon center being 15~100 km. The maximum storm surge increases along with the slows down of the moving speed of the typhoon in Xiangzhou district and Doumen district, however in Jinwan district,strong storm surge occurs along the typhoon track when the moving speed of the typhoon is 15~30 km/h.

参考文献：

[1] 张海燕.南海区台风风暴潮时空分布特征[J].海洋预报, 2019, 36(6):1-8.ZHANG H Y. Spatio-temporal distribution of typhoon storm surge along the South China Sea coast[J]. Marine Forecasts, 2019, 36(6):1-8. [2] 贾宁,刘强,石先武,等.基于现场调查的台风"天鸽"(1713)和台风"山竹"(1822)风暴潮灾害影响和致灾对比分析[J].海洋预报,2022, 39(5):94-99.JIA N, LIU Q, SHI X W, et al. Comparative analysis of the impact of typhoon storm surge disaster and the disaster-causing difference between typhoon "Hato" (1713) and "Mangkhut" (1822) based on field survey[J]. Marine Forecasts, 2022, 39(5):94-99. [3] 傅赐福,董剑希,刘秋兴,等. 1409号和1415号台风风暴潮预报的数值研究[J].海洋预报, 2016, 33(4):26-33.FU C F, DONG J X, LIU Q X, et al. Numerical simulation study on typhoon "Rammasun" (1409) and typhoon "Kalmaegi" (1415) storm surge forecast[J]. Marine Forecasts, 2016, 33(4):26-33. [4] DU M, HOU Y J, QI P, et al. The impact of different historical typhoon tracks on storm surge:A case study of Zhejiang, China[J].Journal of Marine Systems, 2020, 206:103318. [5] LIU W C, HUANG W C. Investigating typhoon-induced storm surge and waves in the coast of Taiwan using an integrally-coupled tide-surge-wave model[J]. Ocean Engineering, 2020, 212:107571. [6] 梁连松,张钊,顾冬明,等.典型路径下台风移速调整对鳌江站增水的数值分析[J].海洋预报, 2020, 37(5):59-66.LIANG L S, ZHANG Z, GU D M, et al. Numerical analysis of typhoon's moving speed adjustment influence on storm surge of Aojiang station under typical route[J]. Marine Forecasts, 2020, 37(5):59-66. [7] LI A L, GUAN S D, MO D X, et al. Modeling wave effects on storm surge from different typhoon intensities and sizes in the South China Sea[J]. Estuarine, Coastal and Shelf Science, 2019,235:106551. [8] MURTY P L N, RAO A D, SRINIVAS K S, et al. Effect of wave radiation stress in storm surge-induced inundation:a case study for the east coast of India[J]. Pure and Applied Geophysics, 2020, 177(6):2993-3012. [9] 庞古乾,黄玉明,何健,等.珠海市台风及其次生风暴潮特征分析与评估[J].热带气象学报, 2020, 36(1):42-50.PANG G Q, HUANG Y M, HE J, et al. Analysis and assessment of the characteristics of typhoon induced storm surge in Zhuhai[J].Journal of Tropical Meteorology, 2020, 36(1):42-50. [10] 韩晶.台风山竹和天鸽对珠海沿海风暴潮增水影响[J].吉林水利, 2019(8):47-49.HAN J. Effect of typhoon "Hato" and "Mangkhut" on rainfall of storm surge in Zhuhai Coastal area-taking Sanzao hydrological station as an example[J]. Jilin Water Resources, 2019(8):47-49. [11] 殷成团,张金善,熊梦婕,等.我国南海沿海台风及暴潮灾害趋势分析[J].热带海洋学报, 2019, 38(1):35-42.YIN C T, ZHANG J S, XIONG M J, et al. Trend analysis of typhoon and storm surge disaster on the South China Sea coast of China[J]. Journal of Tropical Oceanography, 2019, 38(1):35-42. [12] 杨飞,杨文俊,杨森. ELCIRC源程序代码分析[J].长江科学院院报, 2013, 30(5):97-102.YANG F, YANG W J, YANG S. Algorithm of ELCIRC source code[J]. Journal of Yangtze River Scientific Research Institute,2013, 30(5):97-102. [13] 王培涛,董剑希,赵联大,等.黄渤海精细化温带风暴潮数值预报模式研究及应用[J].海洋预报, 2010, 27(4):1-8.WANG P T, DONG J X, ZHAO L D, et al. Studies and applications of refined numerical extratropical storm surge forecast model for Bohai and Yellow Sea[J]. Marine Forecasts,2010, 27(4):1-8. [14] 王喜年,尹庆江,张保明.中国海台风风暴潮预报模式的研究与应用[J].水科学进展, 1991, 2(1):1-10.WANG X N, YIN Q J, ZHANG B M. Research and applications of a forecasting model of typhoon surges in China Seas[J].Advances in Water Science, 1991, 2(1):1-10. [15] FUJITA T. Pressure distribution in typhoon[J]. Geophysical Magazine, 1952, 23:437-452. [16] 陈洁,汤立群,申锦瑜,等.台风气压场与风场研究进展[J].海洋工程, 2009, 27(3):136-142.CHEN J, TANG L Q, SHEN J Y, et al. Advances in typhoon wind field and pressure field[J]. The Ocean Engineering, 2009, 27(3):136-142. [17] JELESNIANSKI C P. A numerical calculation of storm tides induced by a tropical storm impinging on a continental shelf[J].Monthly Weather Review, 1965, 93(6):343-358. [18] CHU D D, ZHANG J C, WU Y S, et al. Sensitivities of modelling storm surge to bottom friction, wind drag coefficient, and meteorological product in the East China Sea[J]. Estuarine,Coastal and Shelf Science, 2019, 231:106460. [19] ISLAM M R, TAKAGI H. Typhoon parameter sensitivity of storm surge in the semi-enclosed Tokyo Bay[J]. Frontiers of Earth Science, 2020, 14(3):553-567. [20] ZHANG H, CHENG W C, QIU X X, et al. Tide-surge interaction along the east coast of the Leizhou Peninsula, South China Sea[J].Continental Shelf Research, 2017, 142:32-49. [21] WANG Y X, GAO T, JIA N, et al. Numerical study of the impacts of typhoon parameters on the storm surge based on Hato storm over the Pearl River Mouth, China[J]. Regional Studies in Marine Science, 2020, 34:101061. [22] 刘睿哲,朱庆勇,倪培桐.珠江河口地区风暴潮增水过程数值模拟[J].广东水利水电, 2018(4):6-10.LIU R Z, ZHU Q Y, NI P T. Numerical simulation of storm surge process in Pearl River Estuary[J]. Guangdong Water Resources and Hydropower, 2018(4):6-10. [23] KWON Y Y, CHOI J W, KWON J I. Simulation of storm surge due to the changes of typhoon moving speed in the south coast of Korean peninsula[J]. Journal of Coastal Research, 2020, 95(sp1):1467-1472. [24] REGO J L, LI C Y. On the importance of the forward speed of hurricanes in storm surge forecasting:A numerical study[J].Geophysical Research Letters, 2009, 36(7):L07609. [25] PARK Y H, YOUN D. Characteristics of storm surge based on the forward speed of the storm[J]. Journal of Coastal Research, 2021,114(S1):71-75.

服务与反馈：

【文章下载】【发表评论】【查看评论】【加入收藏】