Abstract:The spatial and temporal distribution of rainfall in the Pearl River is uneven, with obvious differences in annual and interannual, and drought in successive seasons and years occurs from time to time. In addition, the Pearl River Estuary is affected by the saltwater intrusion, so the situation of water supply in the urban agglomeration of Guangdong-Hong KongMacao Greater Bay Area is critical. At present, the lack of drought drilling ability and the low efficiency of emergency scheme preparation are barriers of drought defense in the Pearl River Basin. In order to further enhance the basin drought defense ability, according to the relevant technical requirements of digital twins construction and combined with the characteristics of the Pearl River Basin, this study improved the database plate of basinal monitoring data and river channel topography, and developed the technology for management of water model and efficient generation of emergency scheme preparation. A“FEDE(forecasting, early-warning, drilling and emergency plan)”platform for the drought prevention have diverse functions. There are multi-source drought dynamic perception, multi-model interactive forecasting, multi-element precision early warning, multi-scheme simulation drilling and intelligent generation of multi-scheme emergency plan. These diverse functions successfully support the drought defense and water supply of the Pearl River during drought period of 2021 to 2022, effectively improves the drought response capacity of the Pearl River Basin. Moreover, it provides a reference for the construction of digital twins in the Pearl River Basin.
王珊琳, 王井腾, 杨跃, 范光伟, 田茂春. 珠江抗旱“四预”平台建设与实践[J]. 中国防汛抗旱, 2023, 33(6): 25-29.
WANG Shanlin, WANG Jingteng, YANG Yue, FAN Guangwei, TIAN Maochun. Construction and practice of the“FEDE”platform for drought defense in the Pearl River. journal1, 2023, 33(6): 25-29.
[1] Mishra A K, Singh V P. A review of drought concepts[J].Journal of Hydrology, 2010, 391:202-216. [2] White D A.Drought as a natural hazard:Concepts and define-tions in drought:A global assessment[M].UK:Routledge, 2000, 2-18. [3] Yuan Wenping, Zhou Guangsheng.Theoratical study and re-search prospect on drought indices[J].Advances in Earth Sci-ence, 2004, 19(6):982-991. [4] Zhang Qiang, Zhang Liang, Cui Xiancheng, et al.Progressesand challenges in drought assessment and monitoring[J].Advances in Earth Science, 2011, 26(7):763-778. [5] Guan Xiaodan, Ma Jieru, Huang Jianping, et al.Impact of oceans on climate change in drylands[J].Science in China (Se-ries D), 2019, 62(6):891-908. [6] 李国英在2023年全国水利工作会议上的讲话[EB/OL].(2023-01-16)[2023-06-10]. http://www.mwr.gov.cn/xw/slyw/202301/t20230116_1643021.html. [7] 杨旭颖.阜新市防汛抗旱指挥系统研究与应用分析[J].水利科学与寒区工程, 2022, 5(11):168-170. [8] 杨帆,邓丽仙,付奔,等.基于"两台一库"的云南省抗旱业务应用系统设计与实现[J].水利信息化, 2022, 170(5):88-92. [9] 马冬冬,沈炜皓,周文彬,等.新形势下防汛抗旱及水旱灾害防御信息化建设探讨[J].江苏水利, 2022, 310(S1):37-39, 49. [10] 范光伟,王高丹,杨跃,等.珠江流域抗旱抑咸"四预"系统研发与应用[J].中国水利, 2022, 931(1):12-13, 18. [11] 水利部珠江水利委员会.迎战珠江流域罕见水旱灾害纪实——下册·抗旱篇[M].北京:中国水利水电出版社, 2022.
2023, Vol. 33 
