A modeling system for drinking water sources and its application to Jiangdong Reservoir in Xiamen city

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• 作者：Pengfei Du (1)
  Zhiyi Li (1)
  Jinliang Huang (2)
  
• 关键词：water source ; integrated modeling system ; prediction ; Jiulong River
• 刊名：Frontiers of Environmental Science & Engineering
• 出版年：2013
• 出版时间：October 2013
• 年：2013
• 卷：7
• 期：5
• 页码：735-745
• 全文大小：399KB
• 参考文献：1. Qu J H, Yin C Q, Yang M, Liu H J. Development and application of innovative technologies for drinking water quality assurance in China. Frontiers of Environmental Science & Engineering in China, 2007, 1(3): 257鈥?69 CrossRef
  2. Jia H F, Wang S, Wei M J, Zhang Y S. Scenario analysis of water pollution control in the typical peri-urban river using a coupled hydrodynamic-water quality model. Frontiers of Environmental Science & Engineering in China, 2011, 5(2): 255鈥?65 CrossRef
  3. Liu L, Ma X M. Integrated river basin management in rapidly urbanizing areas: a case of Shenzhen, China. Frontiers of Environmental Science & Engineering in China, 2011, 5(2): 243鈥?54 CrossRef
  4. Jia H F, Dong N, Ma H T. Evaluation of aquatic rehabilitation technologies for polluted urban rivers and the case study of the Foshan Channel. Frontiers of Environmental Science & Engineering in China, 2010, 4(2): 213鈥?20 CrossRef
  5. Jia H F, Cheng S T. Spatial and dynamic simulation for Miyun Reservoirwaters in Beijing. Water Science and Technology, 2002, 46(11鈥?2): 473鈥?79
  6. Wang J P, Su B L, Jia H F, Cheng S T, Yang Z S, Wu D W, Sun F. Integrated model of nutrients for the Miyun Reservoir and its watershed. Environmental Sciences, 2006, 27(7): 1286鈥?291 (in Chinese)
  7. Wang J P, Su B L, Jia H F, Cheng S T, Yang Z S, Wu D W, Sun F. Scenario analysis of integrated model of nutrients in the Miyun Reservoir and its watershed. Environmental Sciences, 2006, 27(8): 1544鈥?548 (in Chinese)
  8. Jia H F, Kong M M, Guo Y, Zhao Q F.Water quality models for the Miyun reservoir in the EDSS framework. Journal of Tsinghua University Science and Technology, 2010, 50(9): 1383鈥?386
  9. Hao T, Du P F, Gao Y.Water environment security indicator system for urban water management. Frontiers of Environmental Science & Engineering in China, 2012, 6(5): 678鈥?91
  10. Gao H S, Zhang Y Z. Water quality assessment and change analysis for main control sections of Jiulong River. Journal of Subtropical Resources and Environment, 2011, 6(2): 42鈥?8 (in Chinese)
  11. Chen N W, Hong H S, Zhang L P. Preliminary results concerning the spatiotem poralpattern and mechanism of nitrogen sources and exports in the Jiulong River watershed. Acta Scientiae Circumstantiae, 2009, 29(4): 830鈥?39 (in Chinese)
  12. Cao W, Hong H, Yue S. Modelling agricultural nitrogen contributions to the Jiulong River estuary and coastal water. Global and Planetary Change, 2005, 47(2): 111鈥?21 CrossRef
  13. Schuol J, Abbaspour K C. Using monthly weather statistics to generate daily data in a SWAT model application to West Africa. Ecological Modelling, 2007, 201(3): 301鈥?11 CrossRef
  14. Olivera F, Valenzuela M, Srinivasan R, Choi J, Cho H, Koka S, Agrawal A. ARCGIS-SWAT: A geodata model and GIS interface for SWAT1. JAWRA Journal of the American Water Resources Association, 2006, 42(2): 295鈥?09 CrossRef
  15. Shen Z, Liao Q, Hong Q, Gong Y. An overview of research on agricultural non-point source pollution modelling in China. Separation and Purification Technology, 2012, 84(SI): 104鈥?11 CrossRef
  16. Grizzetti B, Bouraoui F, Granlund K, Rekolainen S, Bidoglio G. Modelling diffuse emission and retention of nutrients in the Vantaanjoki watershed (Finland) using the SWAT model. Ecological Modelling, 2003, 169(1): 25鈥?8 CrossRef
  17. Huang Z, Xue B, Pang Y. Simulation on stream flow and nutrient loadings in Gucheng Lake, Low Yangtze River Basin, based on SWAT model. Quaternary International, 2009, 208(1): 109鈥?15 CrossRef
  18. Bouraoui F, Benabdallah S, Jrad A, Bidoglio G. Application of the SWAT model on the Medjerda river basin (Tunisia). Physics and Chemistry of the Earth, Parts A/B/C, 2005, 30(8-10): 497鈥?07 CrossRef
  19. Green C H, Van Griensven A. Auto calibration in hydrologic modeling: using SWAT2005 in small-scale watersheds. Environmental Modelling & Software, 2008, 23(4): 422鈥?34 CrossRef
  20. Singh J, Knapp H V, Arnorld J G, Demissie M. Hydrological modeling of the Iroquois River Watershed using HSPF and SWAT. Water Resource Association, 2005, 41(2): 343鈥?60 CrossRef
  21. Kim N W, Chung I M, Won Y S, Arnold J G. Development and application of the integrated SWAT-MODFLOW model. Journal of Hydrology (Amsterdam), 2008, 356(1): 1鈥?6 CrossRef
  22. Hamrick JM. A Three-Dimensional Environmental Fluid Dynamics Computer Code: Theoretical and Computational Aspects. Gloucester, Massachusetts: Virginia Institute of Marine Science, the College of William and Mary, 1992, 1鈥?3
  23. Hamrick J M, Wu T S. Computational design and optimization of the EFDC /HEM3D surface water hydrodynamic and eutrophication models. In: Delic G, Wheller M F, eds. Next Generation Environmental Models and Computational Methods. hiladelphia: Society for Industrial and Applied Mathematics (SIAM), 1997, 143鈥?56
  24. Jin K R, Hamrick J H, Tisdale T. Application of three-dimensional hydrodynamic model for Lake Okeechobee. Journal of Hydraulic Engineering, 2000, 126(10): 758鈥?71 CrossRef
  25. Johnson B H, Kim K W, Heath R E, Hsieh B B, Butler H L. Validation of three dimensional hydrodynamic model of Chesapeake Bay. Journal of Hydraulic Engineering, 1993, 119(1): 2鈥?0 CrossRef
  26. Ambrose R B, Wool T A, Martin J L, Connolly J P, Schanz R W. WASP5.x, A Hydrodynamic and Water Quality Model Model Theory, User鈥檚 Manual, and Programmer鈥檚 Guide. Draft: Environmental Research Laboratory, US Environmental Protection Agency, 1993
  27. Bierman V J, DePinto J V, Young T C, Rodgers P W, Martin S C, Raghunathan R, Hinz S C. Development and Validation of An Integrated Exposure Model for Toxic Chemicals in Green Bay, Lake Michigan. Michigan: the US Environmental Protection Agency, 1992
  28. Huang J L, Zhou P, Zhou Z R, Huang Y L. Assessing the influence of land use and land cover datasets with different points in time and levels of detail on watershed modeling in the North River Watershed, China. International Journal of Environmental Research and Public Health, 2013, 10(1): 144鈥?57 CrossRef
  29. Li Z Y, Du P F, Huang J L. Integrated Ecological-hydrodynamic Model for the Jiangdong Reservoir in Jiulong River. In: Biomedical Engineering and Biotechnology (iCBEB), 2012, Macao. Piscataway: IEEE Computer Society, 2012, 1534鈥?537
  
• 作者单位：Pengfei Du (1)
  Zhiyi Li (1)
  Jinliang Huang (2)
  
  1. State Key Joint Laboratory of Environment Simulation and Pollution Control, School of Environment, Tsinghua University, Beijing, 100084, China
  2. Coastal & Ocean Management Institute, Xiamen University, Xiamen, 361005, China
  
• ISSN：2095-221X

文摘

Drinking water sources are highly valued by authorities for safeguarding the life of a city. Models are widely applied as important and effective tools in the management of water sources. However, it is difficult to apply models in water source management because water managers are often not equipped with the professional knowledge and operational skills necessary for making use of the models. This paper introduces a drinking water source simulation and prediction system that consists of a watershed model, a hydrological model and a water quality model. This system provides methods and technical guidance for the conventional management of water sources and emergency water event response. In this study, the sub-models of the system were developed based on the data of the Jiangdong Reservoir in Xiamen, and the model validation was based on local monitoring data. The hydrological model and water quality model were integrated by computer programming, and the watershed model was indirectly integrated into the system through a network platform. Furthermore, three applications for Jiangdong Reservoir water protection utilizing the system were introduced in this paper, including a conventional simulation, an emergency simulation, and an emergency measures evaluation.