基于长系列水文监测数据的台风对舟山岛降雨量的影响

叶舟; 耿诚; 徐贝; 陈芳

doi:10.11988/ckyyb.20221401

PDF(15966 KB)

长江科学院院报 ›› 2023, Vol. 40 ›› Issue (6) : 35-42. DOI: 10.11988/ckyyb.20221401

水资源

基于长系列水文监测数据的台风对舟山岛降雨量的影响

叶舟, 耿诚, 徐贝, 陈芳

作者信息 +

Effect of Typhoons on Island Rainfall Based on Long-series Hydrological Monitoring Data: Case Study on Zhoushan Island in Zhejiang

YE Zhou, GENG Cheng, XU Bei, CHEN Fang

Author information +

文章历史 +

摘要

以舟山长春岭雨量站作为参考点,利用长系列监测数据进行分析计算,对1980—2019年间发生在西北太平洋的台风对长春岭站降雨量的影响进行研究。分析结果显示长春岭站平均每年台风雨占台汛期降雨的72.55%,舟山登陆、浙江登陆、其他登陆及非登录台风平均每年给长春岭站带来降雨量29.45、126.23、364.68 mm,这3类台风的单个台风给长春岭站带来降雨量分别为300.65、157.78、71.28 mm。研究揭示了长春岭站总降雨量很大程度上取决于带来影响>50 mm降雨量的台风,特别是浙江省内登录的台风。除登陆点外,浙江登陆台风影响长春岭站降雨量最大因子是路径走向,其次是强度和移动速度。研究结果对进一步认识舟山岛水资源的形成具有一定的参考意义。

Abstract

The study aimed to investigate the influence of typhoons occurring in the northwest Pacific on rainfall at the Changchunling Rainfall Station in Zhoushan. By analyzing a long-term monitoring dataset spanning from 1980 to 2019, we explored the impact of typhoons on rainfall patterns. The findings revealed that, on average, typhoon rainfall at the Changchunling Station accounted for 72.55% of the total precipitation during the typhoon season. Specifically, typhoons making landfall in Zhoushan, and those in Zhejiang, as well as typhoons making landfall in other areas and non-landfall typhoons, contributed an annual average rainfall of 29.45 mm, 126.23 mm, and 364.68 mm to the Changchunling station, respectively. Furthermore, individual typhoons of the three types brought rainfall of 300.65 mm, 157.78 mm, and 71.28 mm to the Station. The study highlights that the overall precipitation at the Station is significantly influenced by typhoons generating rainfall exceeding 50 mm. Among these, the typhoons making landfall in Zhejiang, particularly those producing rainfall amounts above 50 mm, exert the greatest impact. In addition to the landfall location, the path direction of the typhoon emerges as the primary factor influencing rainfall patterns at the Changchunling Station, followed by its intensity and moving speed. These findings provide valuable insights into comprehending the formation of water resources on Zhoushan Island, offering significant implications for further research in this area.

导出引用

叶舟, 耿诚, 徐贝, 陈芳. 基于长系列水文监测数据的台风对舟山岛降雨量的影响[J]. 长江科学院院报. 2023, 40(6): 35-42 https://doi.org/10.11988/ckyyb.20221401

YE Zhou, GENG Cheng, XU Bei, CHEN Fang. Effect of Typhoons on Island Rainfall Based on Long-series Hydrological Monitoring Data: Case Study on Zhoushan Island in Zhejiang[J]. Journal of Changjiang River Scientific Research Institute. 2023, 40(6): 35-42 https://doi.org/10.11988/ckyyb.20221401

中图分类号： P332.1

参考文献

[1] 陈淑琴, 黄辉. 台风“麦莎”在舟山引起的特大暴雨的成因分析[J]. 海洋预报, 2011, 28(2): 23-27.
[2] 赵玉春, 王叶红, 陈健康, 等. “莫兰蒂”台风(2016)登陆前后精细结构及其引发福建特大暴雨的模拟研究[J]. 暴雨灾害, 2018, 37(2): 135-148.
[3] 陈涛, 董林, 罗玲, 等. 台风利奇马登陆期间的对流结构特征及对强降雨影响[J]. 气象, 2021, 47(12): 1433-1443.
[4] 端义宏.登陆台风精细结构的观测、预报与影响评估[J]. 地球科学进展, 2015, 30(8): 847-854.
[5] 陈联寿, 许映龙. 中国台风特大暴雨综述[J]. 气象与环境科学, 2017, 40(1): 3-10.
[6] 陈镭, 徐海明, 余晖, 等. 台风“桑美”(0608)登陆前后降水结构的时空演变特征[J]. 大气科学, 2010, 34(1): 105-119.
[7] 王毅, 钱燕珍, 段晶晶, 等. “温比亚”台风登陆前后大暴雨特征及成因分析[J]. 海洋预报, 2020, 37(3): 62-71.
[8] 何会中, 程明虎, 周凤仙. 0302号(鲸鱼)台风降水和水粒子空间分布的三维结构特征[J]. 大气科学, 2006, 30(3): 491-503.
[9] LONFAT M, MARKS F D JR, CHEN S S. Precipitation Distribution in Tropical Cyclones Using the Tropical Rainfall Measuring Mission (TRMM) Microwave Imager: A Global Perspective[J]. Monthly Weather Review, 2004, 132(7): 1645-1660.
[10]BURPEE R W, BLACK M L. Temporal and Spatial Variations of Rainfall near the Centers of Two Tropical Cyclones[J]. Monthly Weather Review, 1989, 117(10): 2204-2218.
[11]梁玉春, 梁毅进, 王盛繁, 等. “莫拉菲”和“杜鹃”台风降雨对比分析[J]. 气象研究与应用, 2012, 33(增刊1): 6-8.
[12]谢韶,苏小山,吕卫华,等.比较分析路径相似两强台风的降雨特征[J].海洋预报,2009,26(4):44-52.
[13]朱红芳,杨祖祥,王东勇,等.进入内陆的两个台风降水特征对比分析[J].气象学报,2019,77(2):268-281.
[14]钱燕珍, 潘灵杰, 段晶晶, 等. 三个登陆台风间接造成宁波大暴雨特征分析[J]. 气象与环境学报, 2019, 35(5): 37-45.
[15]王盛繁,何林宴.1311号超强台风“尤特”强降雨过程综合分析[J].气象研究与应用,2016,37(增刊1):20-21.
[16]黄敏辉, 陈嘉玲, 吴晓芳. 登陆广东台风的路径、强度和移速特征与广州降水关系分析[J]. 广东气象, 2000, 22(3): 5-8.
[17]陈宏, 杨晓君, 易笑园, 等. 北上台风“安比”后期两个阶段暴雨落区分布的差异性分析[J]. 高原气象, 2021, 40(5): 1087-1100.
[18]叶舟. 基于浙江海堤安全的海洋环境因子变化研究[J]. 海洋工程, 2021, 39(3): 127-134.
[19]叶舟, 周旦娜, 陈芳. 基于网络流模型利用台风雨资源的舟山岛地下水库调度研究[J]. 水利水电技术(中英文), 2022, 53(2): 18-30.
[20]叶舟, 徐贝. 基于大数据的影响浙江海堤安全的台风相关特征分析[J]. 浙江海洋大学学报(自然科学版), 2021, 40(2): 139-147.
[21]陈惠芬.台风登陆路径与青田降水分布特征分析[C]∥浙江省丽水市科学技术协会、浙江省衢州市科学技术协会、浙江省金华市科学技术协会.第二届浙江中西部科技论坛论文集第二卷(气象分卷).青田县气象局:浙江省科学技术协会,2005:2.
[22]赵放,冀春晓,高守亭,等.浙江沿海登陆台风结构特性的多普勒雷达资料分析[J].气象学报,2012,70(1):15-29.
[23]施春红. 9806号台风异常移动特征的初步分析[J]. 海洋预报, 2000, 17(1): 50-61.
[24]董加斌, 黄新晴. 登陆浙江的台风路径分类和暴雨落区分析[J]. 浙江气象, 2019, 40(3): 13-19.
[25]曹美兰, 俞燎霓. 舟山台风灾害及东部海岛台风降雨量分布特征[J]. 浙江海洋学院学报(自然科学版), 2010, 29(6): 579-582.
[26]台风路径:https:∥typhoon.slt.zj.gov.cn/.
[27]朱法君, 邬扬明. 浙江省各地市水资源压力指数评价[J]. 长江科学院院报, 2010, 27(9): 14-16, 28.