铁路水害及预警模型

干旱区研究 ›› 2011, Vol. 28 ›› Issue (1): 181-186.

• 气候与气候灾害 • 上一篇

铁路水害及预警模型

李晓霞¹, 王勇¹, 关向宁², 王有生¹, 全建瑞¹

1. 兰州中心气象台, 甘肃兰州 730020;
2. 兰州铁路局防洪指挥部, 甘肃兰州 730000

收稿日期:2009-06-02 修回日期:2009-09-08 出版日期:2011-02-25 发布日期:2011-09-06
作者简介:李晓霞(1970－),女,河南巩县人,硕士,高工,主要从事气象预报业务工作.E-mail:lxxhappy@tom.com
基金资助:
甘肃省气象局科研项目"兰州铁路防洪指挥气象预警服务系统"资助

Flood Disasters and the Development of Early Warning Model for Railway

LI Xiao-xia¹, WANG Yong¹, GUAN Xiang-ning², WANG You-sheng¹, QUAN Jian-rui¹

1. Lanzhou Central Meteorological Obseratory, Lanzhou 730020, China;
2. Flood Control Headquarters, Lanzhou Railway Bureau, Lanzhou 730020, China

Received:2009-06-02 Revised:2009-09-08 Online:2011-02-25 Published:2011-09-06

摘要/Abstract

摘要： 利用兰州铁路局2002-2007年辖区内的水害资料及同期的气象资料,统计分析兰州铁路局铁路水害时空分布特征及与气象条件的关系。分析发现:兰州铁路局水害发生具有明显的地域性,不同路段、不同类型、不同量级的降水引发的铁路水害是不同的。同时,还分段建立了铁路水害预警模型,以期为铁路防洪预报服务。

关键词: 铁路水害, 降水类型, 降水量级, 预警等级, 时空分布, 气象条件, 兰州

Abstract: Lanzhou Railway Bureau is a main personnel and material transportation artery in northwest China, and manages 5 main railways in the popedom of the bureau: the western section of the Longhai Railway, southern section of the Baotou-Lanzhou Railway, eastern section of Lanzhou-Xinjiang Railway, northern section of the Baozhong Railway and Gantangzi-Wuwei Railway and 10 branch lines. The railways in the popedom of the bureau pass through Gansu Province and Ningxia Hui Autonomous Region. In this area, weather and climate is diversity, rainfall is quite different from different regions, the geographical environment is complicated, there are the Gobi deserts, deserts, mountains, plateaus and other landforms, and flood disasters occur frequently along the railways. In this paper, the data of disrupted times and their durations of the railways as well as rainfall are used to discuss flood disasters along the railways within the popedom of Lanzhou Railway Bureau during the period from 2002 to 2007. The temporal variation of flood disasters along the railways and their relationship with precipitation are analyzed. Results show that the flood disasters along the railways varied with rainfall type and intensity for different railway sections. Flood disasters occurred mainly during the period from May to October, especially from July to August, and the proportions of disrupted times and their durations of the railways were 62% and 77% of the total flood disasters. The water-damaged railway sections were mainly distributed along 5 railways and increased from northwest to southeast, the regional feature of water-damaged railway sections was obvious, and flood disasters were the most serious along the railway sections from Lanzhou to Dingxi and then to Tianshui. In this 2 sections, the average annual disrupted times of the railways were 15 and 12, and the average annual disrupted durations of the railways were 40.8 and 20.8 hours, respectively. Flood disaster along the railways was closely related to precipitation. The correlation between the disrupted times of the railways and precipitation was 0.78, and the correlation between the disrupted duration of the railways and precipitation was 0.41. Regional heavy rainfall, severe convective weather and continuous rainfall were the main factors resulting in water damage of the railways. There were 85 flood disasters along the railways during the period from 2002 to 2007, in which 50.5% were caused by the severe convective weather, 42% by regional heavy rainfall, and 9.5% by autumn continuous rainfall.

Key words: railway, flood disaster, precipitation type, precipitation level, warning level, spatiotemporal distribution, meteorological condition, Lanzhou

中图分类号:

P426.616

李晓霞, 王勇, 关向宁, 王有生, 全建瑞. 铁路水害及预警模型[J]. 干旱区研究, 2011, 28(1): 181-186.

LI Xiao-xia, WANG Yong, GUAN Xiang-ning, WANG You-sheng, QUAN Jian-rui. Flood Disasters and the Development of Early Warning Model for Railway[J]. , 2011, 28(1): 181-186.

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铁路水害及预警模型

Flood Disasters and the Development of Early Warning Model for Railway

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