湘江湖南段洪水灾害综合风险区划

长江流域资源与环境 >> 2011, Vol. 20 >> Issue (11): 1405-.

•　区域可持续发展　• 上一篇

湘江湖南段洪水灾害综合风险区划

莫宏伟 | 李少青 | 陶建军 | 刘晗 | 肖志坤

(1.湖南科技大学建筑与城乡规划学院|湖南湘潭 411201； 
2.湖南科技大学煤炭资源清洁利用与矿山环境保护湖南省重点实验室|湖南湘潭 411201)

出版日期:2011-11-22

RISK ZONING OF FLOOD DISASTER ALONG XIANGJIANG RIVER IN HUNAN PROVINCE

MO Hongwei1,2, LI Shaoqing1, TAO Jianjun1, LIU Han1, XIAO Zhikun1

(1.School of Architecture &|Urban Planning,Hunan University of Science and Technology,Xiangtan 411201,China;2.Hunan Province Key Laboratory of Clean Coal Resources Utilization and Mine Environment Protection,Xiangtan 411201,China

Online:2011-11-22

摘要/Abstract

摘要：

以湘江湖南段河流沿线地区为例，基于自然灾害风险评价的基本原理构建了洪水灾害综合风险值计算模型，即综合危险度和综合社会经济易损度的叠加。利用研究区全球数字高程模型(GDEM)数据、1971~2007年地面气象站观测数据和2008年社会经济统计数据等，借助地理信息系统(GIS)技术和地学方法，得到包含高风险区、较高风险区、中等风险区和较低风险区4个风险等级的洪水灾害综合风险区划图。结果表明：洪水灾害危险度最高的地区集中分布在湘江下游沿岸的湘阴县和长株潭地区；综合社会经济易损度最高的地区为人口密集的市区；湘阴县、长株潭三市和衡阳市市区危险度和易损度均较高，为洪水灾害高风险区。研究结果可为风险管理者和决策者提供量化的理论参考

Abstract:

Risk zoning of flood disaster is the base of flood risk management.The advance in resolution of data can guide flood control，and flood insurance in a macroscopic view is available.Taking the catchment area along Xiangjiang River in Hunan Province as an example,and on the basis of elementary principles of natural disasters risk assessment,calculative model was established to obtain comprehensive flood disaster risk value which was computed by the integrated dangerous degree and comprehensive socioeconomic vulnerability.Based on 30 m ASTER Global Digital Elevation Model (GDEM) data,climate data from 37 meteorological stations during 1971 to 2006,and 2008 socioeconomic statistic data,with the support of ArcGIS and quantitative geoscience methods,the regionalization map of comprehensive risk of flood disaster in study area was drawn by calculating proportion of risk areas.The regionalization map divided general risk assessed results mainly into four grades,that is,the lower risk region,moderate risk region,higher risk region and the highest risk regions.The results show that the highest integrated dangerous degree of flood disaster areas are mainly distributed in Xiangyin and ChangZhuTan region which along the lower reaches of Xiangjiang River.The highest comprehensive socioeconomic vulnerability areas is distributed in urban that in high population density.Xiangyin,ChangshaZhuzhouXiangtan and Hengyang belong to the highest comprehensive flood disaster risk areas.The results can provide quantitatively theoretic basis for environmental management and ecological risk decisionmaking

莫宏伟 | 李少青 | 陶建军 | 刘晗 | 肖志坤. 湘江湖南段洪水灾害综合风险区划[J]. 长江流域资源与环境, 2011, 20(11): 1405-.

MO Hongwei1,2, LI Shaoqing1, TAO Jianjun1, LIU Han1, XIAO Zhikun1. RISK ZONING OF FLOOD DISASTER ALONG XIANGJIANG RIVER IN HUNAN PROVINCE[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2011, 20(11): 1405-.

参考文献

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

推荐阅读 10

[1]	李娜,许有鹏, 陈爽. 苏州城市化进程对降雨特征影响分析[J]. 长江流域资源与环境, 2006, 15(3): 335 -339 .
[2]	张政, 付融冰\| 杨海真, 顾国维. 水量衡算条件下人工湿地对有机物的去除[J]. 长江流域资源与环境, 2007, 16(3): 363 .
[3]	孙维侠, 赵永存, 黄标, 廖菁菁, 王志刚, 王洪杰. 长三角典型地区土壤环境中Se的空间变异特征及其与人类健康的关系[J]. 长江流域资源与环境, 2008, 17(1): 113 .
[4]	许素芳,周寅康. 开发区土地利用的可持续性评价及实践研究——以芜湖经济技术开发区为例[J]. 长江流域资源与环境, 2006, 15(4): 453 -457 .
[5]	郝汉舟, 靳孟贵, 曹李靖, 谢先军. 模糊数学在水质综合评价中的应用[J]. 长江流域资源与环境, 2006, 15(Sup1): 83 -87 .
[6]	刘耀彬, 李仁东. 现阶段湖北省经济发展的地域差异分析[J]. 长江流域资源与环境, 2004, 13(1): 12 -17 .
[7]	陈永柏,. 三峡工程对长江流域可持续发展的影响[J]. 长江流域资源与环境, 2004, 13(2): 109 -113 .
[8]	时连强,李九发,应铭,左书华,徐海根. 长江口没冒沙演变过程及其对水库工程的响应[J]. 长江流域资源与环境, 2006, 15(4): 458 -464 .
[9]	翁君山,段宁\| 张颖. 嘉兴双桥农场大气颗粒物的物理化学特征[J]. 长江流域资源与环境, 2008, 17(1): 129 .
[10]	王书国,段学军,姚士谋. 长江三角洲地区人口空间演变特征及动力机制[J]. 长江流域资源与环境, 2007, 16(4): 405 .