PDF下载分享

[1]田涵元,王福增,王秋淞,等.贵州地区强对流天气防雹雷达回波特征研究[J].成都信息工程大学学报,2022,37(02):208-214.[doi:10.16836/j.cnki.jcuit.2022.02.015]
　TIAN Hanyuan,WANG Fuzeng,WANG Qiusong,et al.Difference of Radar Echo Characteristics before and after a Hail Suppression in Severe Convective Weather in Guizhou[J].Journal of Chengdu University of Information Technology,2022,37(02):208-214.[doi:10.16836/j.cnki.jcuit.2022.02.015]

点击复制

贵州地区强对流天气防雹雷达回波特征研究

成都信息工程大学学报[ISSN:1006-6977/CN:61-1281/TN] 卷: 37 期数: 2022年02期页码: 208-214 栏目: 大气科学出版日期: 2022-04-30

Title:: Difference of Radar Echo Characteristics before and after a Hail Suppression in Severe Convective Weather in Guizhou

文章编号:: 2096-1618(2022)02-0208-07

作者:: 田涵元; 王福增; 王秋淞; 段伟; (成都信息工程大学电子工程学院,四川成都 610225)

Author(s):: TIAN Hanyuan; WANG Fuzeng; WANG Qiusong; DUAN Wei; (College of Electronic Engineering, Chengdu University of Information Technology, Chengdu 610225, China)

关键词:: 强对流天气; 人工防雹; 反射率因子; 垂直累计液态水含量; 强回波区域

Keywords:: severe convective weather; hail suppression; reflectivity factor; VIL; strong echo region

分类号:: P482

DOI:: 10.16836/j.cnki.jcuit.2022.02.015

文献标志码:: A

摘要:: 冰雹是一种常见的天气灾害,所以科学检验防雹效果成为重要工作。利用贵州威宁县2019年4-8月3次典型强对流天气,实行人工防雹前后的雷达数据回波差别研究,降雹前后雷达反射率因子、强回波区域强度及垂直累计液态水含量、垂直累计液态水含量密度的变化关系。结果表明:兔街站6月14日17:40,防雹作业前雷达反射率达到峰值60.2 dBz,防雹作业20分钟,雷达反射率下降至28.1 dBz,人工防雹控制了VIL及VILD的增长,防雹效果很好。嘎基站4月27日20:53,防雹作业前雷达反射率峰值达62.4 dBz,防雹作业22分钟雷达反射率下降至38.6 dBz,防雹前期VIL达31.61 kg/m²,在防雹作业后VIL与VILD迅速减小,有效遏制对流云单体形成冰雹。炉山站8月13日14:25,防雹作业前雷达反射率峰值达61.3 dBz,防雹作业27分钟后雷达反射率下降至44.4 dBz,防雹作业前VIL达24.37 kg/m²,防雹作业后虽然控制了VIL及VILD增长,但雷达反射率在防雹作业后并未立即迅速减小,对流云单体形成冰雹,防雹作业效果不理想。通过防雹前后雷达回波参数、VIL及VILD的变化与实际情况变化检验防雹效果,为选择防雹时机、弹药量的使用等提供参考价值。

Abstract:: Hail is a common weather disaster, so scientific test of hail suppression effect has become an important work. Based on three typical severe convective weather events in Weining County of Guizhou Province from April to August in 2019, the radar data echo difference before and after hail suppression is studied, and the radar reflectivity factor and strong echo area intensity before and after hail suppression are obtained. The calculation of vertical cumulative liquid water content and vertical cumulative liquid water content density and the change relationship before and after hail suppression are realized through the algorithm. The results show that: at 17:40 on June 14, the radar reflectivity of Tujie station reaches the peak value of 60.2 dBz before hail suppression operation, and drops to 28.1 dBz after 20 minutes of hail suppression operation. The artificial hail suppression controls the growth of VIL and VILD, and the hail suppression effect is great. At 20:53 on April 27, the radar reflectivity of Gaji station reached the peak value of 62.4 dBz before hail suppression operation. After 22 minutes of hail suppression operation, the radar reflectivity dropped to 38.6 dBz, and the VIL reached31.61 kg/m² in the early stage of hail suppression. After hail suppression operation, VIL and VILD decreased rapidly, effectively curbing the formation of Hail by convective cloud cells. At 14:25 pm on August 13, Lushan station’s radar reflectivity reached a peak value of 61.3 dBz before hail suppression operation. After 27 minutes of hail suppression operation, the radar reflectivity dropped to 44.4 dBz, and VIL reached 24.37 kg/m² before hail suppression operation. Although the growth of VIL and VILD was controlled after hail suppression operation, the radar reflectivity did not decrease rapidly after hail suppression operation, and the convective cloud monomer formed hail, the hail suppression effect is not ideal. Through the changes of radar echo parameters, VIL and VILD before and after hail suppression and the actual situation, the hail suppression effect is tested, which provides reference value for the selection of hail suppression time and the use of ammunition.

参考文献/References:

[1] 李大山.人工影响天气现状与展望[M].北京:气象出版社,2002.
[2] 李红梅,尹丽云,金文杰,等.昭通一次强对流天气过程及人工防雹效果分析[C].北京:大气水资源开发利用与气象防灾减灾,2014.
[3] 王志新,王飞.阿克苏地区东部三县近十年防雹效果检验分析[J].农业气象,2018,38(2):57.
[4] 李淑玲,臧传花.一次弓形回波的多普勒雷达资料分析[J].山东气象,2007,27(3):14-16.
[5] 高帆,胡鹏,李瑞,等.一次弓形回波演变特征分析[J].山东气象,2012,32(4):14-16.
[6] 王雨曾,郁青.多物理参量检验防雹效果的研究[J].气象,1995,21(10):3-8.
[7] 章澄昌.当前国外人工增雨防雹作业的效果评估[J].气象1998,24(10):3-8.
[8] 曾勇,李丽丽,李迪,等.贵州一次典型冰雹云单体回波多阶跃增特征分析[J].防灾科技学院学报,2019,21(3):56-65.
[9] 刁秀广,朱君鉴,黄秀韶,等.VIL和VIL密度在冰雹云判据中的应用[J].高原气象,2008(5):1131-1139.
[10] V S Inyukhin,V S Makitov,S A Kushchev.Radar Studies of Formation and Development of Hail Cores in Severe Convective Clouds[J].Russian Meteorology and Hydrology.2017(42):471-476.
[11] 曹巧莲.临汾CINRAD/CC雷达冰雹预警VIL指标研究[A].雷达气象学委员会、中国气象局气象探测中心第31届中国气象学会年会S1气象雷达探测技术研究与应用[C].雷达气象学委员会、中国气象局气象探测中心:中国气象学会,2014.
[12] 曹水,邹书平,曾勇,等.一次冰雹云天气过程不同波段雷达回波对比分析[J].中低纬山地气象,2020,44(2):66-70.

相似文献/References:

[1]郑博华,李斌.一种与作业效率相关的人工防雹物理检验方法的探究[J].成都信息工程大学学报,2019,(02):198.[doi:10.16836/j.cnki.jcuit.2019.02.015]
　ZHENG Bohua,LI Bin.A Study on the Method of Artificial Anti-hail Physical Testing Related to Operating Efficiency[J].Journal of Chengdu University of Information Technology,2019,(02):198.[doi:10.16836/j.cnki.jcuit.2019.02.015]
[2]鹿原,周筠珺,邹书平,等.威宁一次单体雹暴防雹作业的宏微观物理响应特征分析[J].成都信息工程大学学报,2024,39(04):442.[doi:10.16836/j.cnki.jcuit.2024.04.008]
　LU Yuan,ZHOU Yunjun,ZOU Shuping,et al.Analysis of Macro and Micro Physical Response Characteristics of a Hail-suppression Operation Against an Unicellular Hailstorm in Weining[J].Journal of Chengdu University of Information Technology,2024,39(02):442.[doi:10.16836/j.cnki.jcuit.2024.04.008]

备注/Memo

收稿日期:2021-08-08
基金项目:国家重点研发资助项目(2018YFC1507201)

更新日期/Last Update: 2022-04-30