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贵州省农业净灌溉需水量与灌溉需求指数时空分布
引用本文:雷宏军,乔姗姗,潘红卫,商崇菊.贵州省农业净灌溉需水量与灌溉需求指数时空分布[J].农业工程学报,2016,32(12):115-121.
作者姓名:雷宏军  乔姗姗  潘红卫  商崇菊
作者单位:1. 华北水利水电大学水利学院,郑州,450045;2. 贵州省水利科学研究院防灾减灾所,贵阳,550002
基金项目:NSFC-河南联合基金项目(U1504512);水利部公益性行业科研专项(201301039)
摘    要:农业用水需求时空分布规律可为区域抗旱减灾管理和灌溉水资源优化配置提供科学依据。基于贵州省及其周边国家气象站点长系列资料和1953-2012年贵州省9个市(州)水稻、玉米、冬小麦、油菜和烤烟的种植面积,计算贵州省9市(州)近60 a净灌溉需水量及灌溉需求指数,分析其时空分布特征。结果表明:1)贵州省的净灌溉需水量和灌溉需求指数分别在314.48~742.57 mm和0.34~0.68之间,60 a间农业净灌溉需水量的和灌溉需求指数呈波动变化,多峰值分布的特征,总体上峰值有所减小但波动周期延长;2)1993—2000年是净灌溉需水量和灌溉需求指数总体变化的转折时期,之前为下降期,之后为上升期;3)净灌溉需水量和灌溉需求指数的季节特征明显,分别为夏季和冬季最高;4)净灌溉需水量(IR)呈现东高西低的规律,灌溉需求指数(IRI)呈现东部、西北部高,西南部低的规律,全省9市(州)可分为3个风险区,东部、西北部的缺水高风险区是抗旱管理的重点区域;5)气候变化是贵州省净灌溉需水量和灌溉需求指数升高的主导因素,它主要通过降水减少来实现的。研究可为贵州省农业季节性缺水问题识别、农业水利工程布局和种植结构调整提供支撑。

关 键 词:灌溉  降水  蒸发  需水量  需求指数  贵州省  时空分布规律
收稿时间:2015/10/26 0:00:00
修稿时间:2016/4/21 0:00:00

Temporal and spatial distribution of agricultural irrigation water requirement and irrigation requirement index in Guizhou Province
Lei Hongjun,Qiao Shanshan,Pan Hongwei and Shang Chongju.Temporal and spatial distribution of agricultural irrigation water requirement and irrigation requirement index in Guizhou Province[J].Transactions of the Chinese Society of Agricultural Engineering,2016,32(12):115-121.
Authors:Lei Hongjun  Qiao Shanshan  Pan Hongwei and Shang Chongju
Institution:1. School of Water Conservancy, North China University of Water Conservancy and Electric Power, Zhengzhou 450045, China,1. School of Water Conservancy, North China University of Water Conservancy and Electric Power, Zhengzhou 450045, China,1. School of Water Conservancy, North China University of Water Conservancy and Electric Power, Zhengzhou 450045, China and 2. Center for Disaster Prevention and Mitigation, Water Resources Research Institute of Guizhou Province, Guiyang 550002, China
Abstract:Abstract: Temporal and spatial distribution characteristics of agricultural water requirement are of great significance to the management of regional drought prevention, mitigation and optimal allocation of irrigation water. Guizhou is a typical region suffering from droughts all around the year and seasonal water shortage of agriculture limits the sustainable agricultural development. In order to investigate the temporal and spatial distribution of agricultural irrigation water requirement and irrigation requirement index in Guizhou Province, in this study, the effective precipitation (Pe), the crop evapo-transpiration (ETc) of rice, maize, winter wheat, oilseed rape and tobacco in different growth stages were estimated by using effective precipitation coefficient, FAO Penman-Monteith equation and crop coefficient method based on the meteorological and statistical data of planting crops area between 1953 and 2012 in Guizhou Province. The annual net agricultural irrigation water requirement (IR) and irrigation requirement index (IRI) were statistically analyzed. Results showed that IR and IRI in the 9 cities of Guizhou province were in the range of 314.48-742.57 mm and 0.34-0.68, respectively. During the last 6 decades, IR and IRI had shown fluctuation characteristics with multi peaks distribution. The peak value demonstrated a decrease trend with the prolonged fluctuation period. The temporal turning stage of IR and IRI was between 1993 and 2000. Before that stage, IR and IRI declined. IR and IRI showed seasonal characteristics of the highest IR in summer and highest IRI in winter. IR showed high value in the East and low value in the West district, while the high value of IRI was in the East and Northwest district, but the low value was in the Southwest district of Guizhou Province. 9 cities could be divided into three risk regions, and the high risk in water shortage lied in the East and Northwest district, which was the focus of regional drought management. The construction of water pond project and the drought resistance plans should be made and carried out to alleviate the problem of engineering water shortage in these regions. The increments of IR and IRI were mainly attributed to the climate change, especially to the change of precipitation. The results of crop evapotranspiration (ETc) showed that the mean ETc of rice, maize, oilseed, winter wheat rape, and tobacco were 738.1, 482.4, 367.4, 347.9, and 450.4 mm, respectively. And the IR showed that the mean IR of rice, maize, oilseed, winter wheat rape, and tobacco were 362.2, 142.4, 208.4, 213.1, and 102.6 mm, respectively. Regional water resources transferred from the southern area to the northern side could be carried out to improve the basic conditions of regional agriculture production. This study can provide support for the identification of seasonal water shortage in Guizhou Province, the layout of agricultural water conservancy project, and the adjustment of planting structure and cropping pattern.
Keywords:irrigation  precipitation  evaporation  water requirement  requirement index  Guizhou Province  spatial and temporal distribution characteristics
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