PANG Jing-peng,LIU Chang-ming,XU Zong-xue.Streamflow and Soil Erosion Simulation Based on SWAT Model[J].Research of Soil and Water Conservation,2007,14(06):88-93.
基于SWAT模型的径流与土壤侵蚀过程模拟
- Title:
- Streamflow and Soil Erosion Simulation Based on SWAT Model
- Keywords:
- SWAT; sensitivity analysis; calibration; validation; soil erosion
- 分类号:
- S157.1
- 摘要:
- 将可表征土地利用变化对水文响应影响的分布式水文模型SWAT应用于密云水库潮河子流域,对模型的敏感性进行了分析,并采用1986-1991年下会水文站数据对其径流量和泥沙负荷进行了率定和验证,模型评估结果表明该模型对径流的模拟效果非常好,对泥沙的模拟效果较好。通过计算34个子流域内的侵蚀模数,对流域内的土壤侵蚀强度进行了分级,并分析了不同土地利用方式对产沙的影响。结果表明,流域内的土壤侵蚀主要发生在农田,为保障密云水库的水质应对其采取有效的水土保持措施。
- Abstract:
- SWAT model is a kind of distributed hydrologic model with the ability to evaluate the effects of landuse change on hydrologic response.This model was applied in Cao River catchment of Miyun reservoir basin.First, the sensitive parameters were identified through sensitive analysis.Then, the calibration and validation for flow and sediment were performed from 1986 to 1991 at Xiahui gaging station.The results of model evaluation show that the streamflow was simulated excellently, and sediment is also well simulated.Finally, the soil erosion modulus were calculated in 34 subbasins delineated by the SWAT, and the effects of different landuse types on sediment loads were analyzed.This study shows that the soil erosion mainly happened in agriculture land in the Cao River catchment, and effective measures must be taken on them to ensure the water quality in the Miyun reservoir.
参考文献/References:
[1] Pimentel D.World soil erosion and conservation[M].Cambridge:Cambridge University Press, 1993.
[2] 何萍, 王家骥.非点源 (NPS) 污染控制与管理研究的现状、困境与挑战[J].农业环境保护, 1999, 18 (5):234-237.
[3] Chu T.Modeling hydrologic and water quality response of a mixed land use watershed in Piedmont physiographic region[D] Maryland:University of Maryland, College Park, 2003.
[4] Guo H Y, Wang X R, Zhu J G.Quantification and index of non-point source pollution in Taihu Lake region with GIS[J].Environmental Geochemistry and Health, 2004, 26 (2):147-156.
[5] 杜桂森, 孟繁艳, 李学东, 等.密云水库水质现状及发展趋势[J].环境科学, 1999, (2):110-112.
[6] 杜桂森, 刘晓端, 刘霞, 等.密云水库水体营养状态分析[J].水生生物学报, 2004, 28 (2):191-195.
[7] 鲍全盛, 曹利军, 王华东.密云水库非点源污染负荷评价研究[J].水资源保护, 1997 (1):8-11.
[8] 苏保林, 王建平, 贾海峰, 等.密云水库流域非点源污染识别[J].清华大学学报:自然科学版, 2006, 46 (3):360-365.
[9] 苏保林, 王建平, 贾海峰, 等.密云水库流域非点源模型系统[J].清华大学学报:自然科学版, 2006, 46 (3):355-359.
[10] Arnold J G, Williams J R, Srinivasan R, et al.Large area hydrologic modeling and assessment part I:Model development[J].Journal of the American Water Resources Association, 1998, 34 (1):73-89.
[11] Neitsch S L, Arnold J G, Kiniry J R, et al.Soil and Water Assessment Tool User’s Manual[M].Temple:Grassland, Soil and Water Research Laboratory, Agricultural Research Service, 2002.
[12] Bera M, Borah D K.Watershed-scale hydrologic and nonpoint-source pollution models:Review of mathematical bases[J].Transactions of the American Society of Agricultural Engineers, 2003, 46 (6):1553-1566.
[13] Romanowicz A A, Vanclooster M, Rounsevell M, et al.Sensitivity of the SWAT model to the soil and land use data parametrisation:a case study in the Thyle catchment, Belgium[J].Ecological Modelling, 2005, 187 (1):27-39.
[14] U.S.Department of Agriculture, Soil Conservation Service.SCS national engineering handbook[M].Washington:Govt.Print.Off., 1972.
[15] Sloan P G, Morre I D, Coltharp G B, et al.Modeling surface and subsurface stormflow on steeply-sloping forested watersheds[R].Lexington:Water Resouces Inst.Report 142, University of Kentucky, 1983.
[16] Arnold J G, Allen P M, Bernhardt G.A comprehensive surface-groundwater flow model[J].Journal of Hydrology, 1993, 142 (1-4):47-69.
[17] Overton D E.Muskingum flood routing of upland streamflow[J].Journal of Hydrology, 1966 (4):185-200.
[18] Williams J R.Flood routing with variable travel time or variable storage coefficients[J].Transactions of the American Society of Agricultural Engineers, 1969, 12 (1):100-103.
[19] Hargreaves G H, Samani Z A.Reference crop evapotranspiration from ambient air temperature[J].Applied Engineering in Agriculture, 1985, 1:96-99.
[20] Priestley C H B, Taylor R J.On the Assessment of Surface Heat Flux and Evaporation Using Large-Scale Parameters[J]. Monthly Weather Review, 1972, 100:81-92.
[21] Monteith J L.Climate and the Efficiency of Crop Production in Britain[J].Philosophical Transactions of the Royal Society of London, 1965, 281:277-329.
[22] Williams J R.Sediment routing for agricultural watersheds[J].Water Resources Bulletin, 1975, 11 (5):965-974.
[23] Bagnold R A.Bedload transport in natural rivers[J].Water Resources Research, 1977, 13 (2):303-312.
[24] Sharpley A N, Williams J R.EPIC-Erosion Productivity Impact Calculator.1.model documentation[M].Washington, D C:U.S.Dept.of Agriculture Agricultural Research Service, 1990.
[25] Neitsch S L, Arnold J G, Kiniry J R, et al.Soil and water assessment tool theoretical documentation version 2000[M].College Station:Texas Water Resources Institute, 2002.
[26] Liersch S.The programs dew1exe and dew02.exe user’s manual[EB/OL].http://www.brc.tamus1edu/swat/manualdew.pdf/200609.
[27] Saxton K E, Rawls W J, Romberger J S, et al.Estimating generalized soil-water characteristics from texture[J].Soil Science Society of America Journal, 1986, 50 (4):1031-1036.
[28] Saxton K E, Rawls W J.Soil Water Characteristic Estimates by Texture and Organic Matter for Hydrologic Solutions[EB/OL].http://users1adelphia.net/~ksaxton/SPAW%20Download.htm/200609.
[29] Van Liew M W, Garbrecht J.Hydrologic simulation of the Little Washita River experimental watershed using SWAT[J].Journal of the American Water Resources Association, 2003, 39 (2):413-426.
[30] Popov E G.Gidrologicheskie Prognozy (Hydrological Forecasts)[M].Leningrad:Gidrometeoizdat, 1979.
[31] Krause P, Boyle D P, Base F.Comparison of different efficiency criteria for hydrological model assessment[J].Advances in Geosciences, 2005 (5):89-97.
[32] Morris M D.Factorial sampling plans for preliminary computational experiments[J].Technometrics, 1991, 33 (2):161-174.
[33] McKay M D, Beckman R J, Conover W J.Comparison of three methods for selecting values of input variables in the analysis of output from a computer code[J].Technometrics, 1979, 21 (2):239-245.
[34] Holvoet K, Van Griensven A, Seuntjens P, et al.Sensitivity analysis for hydrology and pesticide supply towards the river in SWAT[J].Physics and Chemistry of the Earth, Parts A/B/C, 2005, 30 (8-10):518-526.
[35] Griensven A V, Meixner T, Grunwald S, et al.A global sensitivity analysis tool for the parameters of multi-variable catchment models[J].Journal of Hydrology, 2006, 324 (1-4):10-23.
[36] Santhi C, Arnold J G, Williams J R, et al.Validation of the SWAT model on a large river basin with point and nonpoint sources[J].Journal of the American Water Resources Association, 2001, 37 (5):1169-1188.
[37] Sloto R A, Crouse M Y.HYSEP:A computer program for steramflow hydrograph separation and analysis[R].Lemoyne:U.S.geological survey, Water-Resources Investigations Report 96-4040, 1996.
[38] White K L, Chaubey I.Sensitivity analysis, calibration, and validations for a multisite and multivariable SWAT model[J].Journal of the American Water Resources Association, 2005, 41 (5):1077-1089.
[39] Winter T C.Uncertainties in estimating the water balances of lakes[J].Water Resources Bulletin, 1981, 17 (1):82-115.
[40] Walling D E, Webb B W.The reliability of rating curve estimates of suspended sediment yield:some further comments[C]//Bordas M P, Walling D E, eds.Sediment budgets.Wallingford:IAHS publication, 174.
[41] SL190-96, 土壤侵蚀分类分级标准[S].北京:中国水利水电出版社出版, 1997.
相似文献/References:
[1]李佳,张小咏,杨艳昭.基于SWAT模型的长江源土地利用/土地覆被情景变化对径流影响研究[J].水土保持研究,2012,19(03):119.
LI Jia,ZHANG Xiao-yong,YANG Yan-zhao.SWAT Model of Runoff Study under Different Land Use Land Cover Scenarios in Source Region of the Yangtze River[J].Research of Soil and Water Conservation,2012,19(06):119.
[2]杨巍,汤洁,李昭阳,等.基于SWAT模型的大伙房水库汇水区径流与泥沙模拟[J].水土保持研究,2012,19(02):77.
YANG Wei,TANG Jie,LI Zhao-yang,et al.Streamflow and Sediment Simulation Based on SWAT Model in Dahuofang Reservoir Catchment[J].Research of Soil and Water Conservation,2012,19(06):77.
[3]丁晋利,郑粉莉.SWAT模型及其应用[J].水土保持研究,2004,11(04):128.
DING Jin-li,ZHENG Fen-li.SWAT Model and Its Application[J].Research of Soil and Water Conservation,2004,11(06):128.
[4]庞靖鹏,徐宗学,刘昌明.SWAT模型研究应用进展[J].水土保持研究,2007,14(03):31.
PANG Jing-peng,XU Zong-xue,LIU Chang-ming.SWAT Model Application:State-of-the-Art Review[J].Research of Soil and Water Conservation,2007,14(06):31.
[5]王亚军,周陈超,贾绍凤,等.基于SWAT模型的湟水流域径流模拟与评价[J].水土保持研究,2007,14(06):394.
WANG Ya-jun,ZHOU Chen-chao,JIA Shao-feng,et al.Simulation and Assessment of Natural Runoff in Huangshui River Basin Based on SWAT[J].Research of Soil and Water Conservation,2007,14(06):394.
[6]梁小军,江洪,朱求安,等.岷江上游流域不同土地利用与气候变化的径流响应研究[J].水土保持研究,2008,15(05):30.
LIANG Xiao-jun,JIANG Hong,ZHU Qiu-an,et al.Modelling Hydrological Response to Different Land-use and Climate Change Scenarios in the Upper Reach of Minjiang River[J].Research of Soil and Water Conservation,2008,15(06):30.
[7]杨菁荟,张万昌.SWAT模型及其在水环境非点源污染中的应用研究进展[J].水土保持研究,2009,16(05):260.
YANG Jing-hui,ZHANG Wan-chang.Research Progress on SWAT Model and Its Application on Water Environmental Nonpoint Source Pollution[J].Research of Soil and Water Conservation,2009,16(06):260.
[8]李进鹏,王飞,穆兴民,等.延河流域土地利用变化对其生态服务价值的影响[J].水土保持研究,2010,17(03):110.
LI Jin-peng,WANG Fei,MU Xing-min,et al.Impacts of Landuse Change on Ecosystem Services Value in the Yanhe River Basin[J].Research of Soil and Water Conservation,2010,17(06):110.
[9]侯统昭,李锦育.SWAT模型之初步探讨[J].水土保持研究,2009,16(06):282.
HOU Tung-chao,LEE Chin-yu.Primarily Study for Soil and Water Assessment Tool (SWAT)[J].Research of Soil and Water Conservation,2009,16(06):282.
[10]张雪松,郝芳华,杨志峰,等.基于SWAT模型的中尺度流域产流产沙模拟研究[J].水土保持研究,2003,10(04):38.
ZHANG Xue-song,HAO Fang-hua,YANG Zhi-feng,et al.Runoff and Sediment Yield Modeling in Meso-scale Watershed Based on SWAT Model[J].Research of Soil and Water Conservation,2003,10(06):38.
备注/Memo
收稿日期:2006-11-30。
基金项目:北京市科技计划项目(D0704004040191)
作者简介:庞靖鹏(1976- ),男,山东青岛人,博士研究生,主要从事水资源与水环境等研究。