Articles

Determination of river cross section for 1-D water quality model in area without observation data

  • LU Min ,
  • JIN Tiantian ,
  • YIN Jing ,
  • SU Huidong
Expand
  • 1. College of Earth Environmental Science, Lanzhou University, Lanzhou 730000, China;
    2. State Key Laboratory of Simulation and Regulation of Water Cycle in River Basin, China Institute of Water Resources and Hydropower Research, Beijing 100038, China

Received date: 2017-03-03

  Revised date: 2017-07-28

  Online published: 2017-08-26

Abstract

The hydrodynamic and water quality model is widely used in the water environmental capacity calculation. However, the establishing of the model depends very much on the cross section data, which are sometimes not available, especially in medium and small river areas of West China. In this paper, the Google Earth remote sensing images, the maximum river water depth obtained from the field measurement and a piecewise mathematical model are combined to acquire the generalized cross section data. The MIKE, the hydrodynamic and water quality model worldwidely used, is adopted to test the generalized cross section data. The 1-D hydrodynamic and water quality models are established with the generalized cross section data and the cross section data obtained from field measurement, respectively. The method is tested through a comparison of the outputs (including the water level, the flow velocity, and the pollutant density) of the two models with different cross section inputs. According to the result, no significant differences are found between the two models in the water level, the flow velocity, and the pollutant density at the upper, middle and lower sections of the simulated river segment. It is emphasized that identical parameters, except the cross section data, are used for the models. The consistency of two model outputs can be improved further through the input of the field water level, the flow velocity, and the pollutant density. This research provides a simple and convenient way to establish the cross section file for building the 1-D Hydrodynamic and quality model under the MIKE11 in the areas where the measured cross section data are not available.

Cite this article

LU Min , JIN Tiantian , YIN Jing , SU Huidong . Determination of river cross section for 1-D water quality model in area without observation data[J]. Science & Technology Review, 2017 , 35(16) : 74 -83 . DOI: 10.3981/j.issn.1000-7857.2017.16.010

References

[1] 王刚, 吴楠, 齐珺, 等. 我国水环境容量研究现状及问题分析[C]//2014中国环境科学学会学术年会论文集. 北京:中国环境科学学会, 2014:4656-4661. Wang Gang, Wu Nan, Qi Jun, et al. Our country current situation and problems of water environmental capacity research analysis[C]//Pro-ceedings of 2014 Academic Annual Meeting of China Environmental Science Society. Beijing:China Environmental Science Society, 2014:4656-4661.
[2] Kim E, Kim Y, Rhew D, et al. A study on the water quality changes of tmdl unit watershed in guem river basin using a nonparametric trend analysis[J]. Journal of Korean Society on Water Environment, 2014, 30(2):148-158.
[3] 杨桐, 杨常亮, 毛永杨. 水环境容量研究进展[C]//2011中国环境科学学会学术年会论文集:第1卷. 北京:中国环境科学学会, 2011:467-471. Yang Jong, Yang Changliang, MaoYongyang. Research progress of water environmental capacity[C]//Proceedings of 2011 Annual Meeting of Chi-na Environmental Science Society, Academic:vol 1. Beijing:China En-vironmental Science Society, 2011:467-471.
[4] 陈丁江, 吕军, 金树权, 等. 河流水环境容量的估算和分配研究[J]. 水土保持学报, 2007, 21(3):123-127. Chen Dingjiang, Lv Jun, Jin Shuquan, et al. The estimation of river wa-ter environmental capacity and distribution of research[J]. Journal of Soil and Water Conservation, 2007, 21(3):123-127.
[5] Kim M, Kim J, Baek J, et al. Development of water quality forecasting models based on the SOM-ANN on TMDL unit watershed in Nakdong river[C]//American Geophysical Union Fall Meeting. Washington:Amer-ican Geophysical Union, 2013.
[6] 张明亮. 河流水动力及水质模型研究[D]. 大连:大连理工大学, 2007. Zhang Mingliang. River hydrodynamic and water quality modeling study[D]. Dalian:Dalian University of Technology, 2007.
[7] 马蔚纯, 陈立民, 李建忠, 等. 水环境非点源污染数学模型研究进展[J]. 地球科学进展, 2003, 18(3):358-366. Ma Weichun, Chen Liming, Li Jianzhong, et al. Research progress of mathematical model of agricultural non-point source pollution of water environment[J].J ournal of Earth Science, 2003, 18(3):358-366.
[8] 左海凤, 李凯. 一维水动力模型在城市水系规划设计中的应用[J]. 水利建设与管理, 2016, 36(8):36-40. Zuo Haifeng, Li Kai. A one-dimensional hydrodynamic model in the application of urban water system planning and design[J]. Water Con-servancy Construction and Management, 2016, 36(8):36-40.
[9] 侯海红, 黄渝桂, 章鹏. 基于MIKE软件在防洪保护区洪水演进的研究[J]. 治淮, 2016(10):18-20. Hou Haihong, Huang Yugui, Zhang Peng. MIKE software based on the flood control protected area flood routing study[J]. Journal of Harness-ing The Huaihe River, 2016, 30(10):18-20.
[10] 姜俊厚. 基于MIKE和GIS洪水风险计算的应用研究[D]. 大连:大连理工大学, 2010. Jiang Junhou. MIKE and GIS flood risk calculation based application research[D]. Dalian:Dalian University of Technology, 2010.
[11] 毛磊, 张燕, 寇冰煜, 等. 稳态双极黏滞量子流体力学模型的正解的存在性[J]. 科学技术与工程, 2012, 12(24):5961-5965. Mao Lei, Zhang Yan, Kou Bingyu, et al. The existence of positive solu-tion of the steady-state bipolar viscous quantum hydrodynamic model[J]. Science Technology & Engineering, 2012. 12(24):5961-5965.
[12] 梁彬锐. MIKE11模型在沙井河片区防洪排涝工程中的应用[J]. 中国农村水利水电, 2008(7):81-83. Liang Binrui. MIKE11 model in the application of shajing river area flood and draining waterlogging[J]. China's Rural Water Conservancy and Hydropower,2008, 15(7):81-83.
[13] 张硕. 基于MIKE软件建立辽河流域水质模型的研究[D]. 沈阳:东北大学, 2013. Zhang Shuo. Liao river water quality model is established based on MIKE software research[D]. Shenyang:Northeastern University, 2013.
[14] 陈胖胖, 吴其彰.水质模型参数计算方法研究[J]. 水利科技与经济, 2009, 15(5):403-404. Chen Pangpang, Wu Qizhang. Water quality model parameters calcula-tion method research[J]. Water Science and Technology and Economy, 2009, 15(5):403-404.
[15] 郑红星, 李丽娟. 水质模型参数的非数值随机优化[J]. 地理研究, 2001, 20(1):97-102. Zheng Hongxing, Li Lijuan. Water quality model parameters of the nu-merical random optimization[J]. Journal of Geographical Research, 2001, 20(1):97-102.
[16] 张质明, 王晓燕, 潘润泽. 一种改进的不确定性水质模型参数率定方法[J]. 中国环境科学, 2017, 37(3):956-962. Zhang Zhiming, Wang Xiaoyan,PanRunze. An improved method of water quality model parameter uncertainty rate[J]. China Environmen-tal Science, 2017, 37(3):956-962.
[17] 刘佳, 王利民, 滕飞, 等. Google Earth影像辅助的农作物面积地面样方调查[J]. 农业工程学报, 2015, 31(24):149-154. Liu Jia,Wang Limin, Teng Fei, et al. Google Earth image aided crop area ground quadrat survey[J]. Journal of Agricultural Engineering, 2015, 31(24):149-154.
[18] 许有鹏, 陈钦峦. 遥感信息在水文动态模拟中的应用[J]. 水科学进展, 1995, 6(2):156-161. Xu Youpeng, Chen Qinluan.The application of remote sensing infor-mation in hydrological dynamic simulation[J]. Advances in Water Sci-ence, 1995, 6(2):156-161.
[19] 安洁玉, 程朋根, 丁斌芬. 基于Google Earth二维影像获取建筑物高度的方法[J]. 地理与地理信息科学, 2010, 26(6):31-33. An Jieyu, Cheng Pegngen, Ding Binfen. 2 d images based on Google Earth for building height method[J]. Journal of Geography and Geo-graphic Information Science, 2010, 26(6):31-33.
[20] Tang Z, Li Y, Gu Y, et al. Assessing Nebraska playa wetland inunda-tion status during 1985-2015 using Landsat data and Google Earth Engine[J]. Environmental Monitoring & Assessment, 2016, 188(12):654.
[21] 赵少华, 邱国玉, 杨永辉, 等. 遥感水文耦合模型的研究进展[J]. 生态环境学报, 2006, 15(6):1391-1396. Zhao Shaohua, Qiu Guoyu,Yang Yonghui, et al. The research progress of remote sensing hydrology coupling model[J]. Journal of Ecological Environment, 2006, 15(6):1391-1396.
[22] Dong J, Xiao X, Menarguez M A, et al. Mapping paddy rice planting area in northeastern Asia with Landsat 8 images, phenology-based al-gorithm and Google Earth Engine[J]. Remote Sensing of Environment, 2016, 185:142.
[23] 雪克来提·巴斯托夫, 龙爱华, 邓铭江, 等. 基于Google Earth的巴尔喀什湖流域中下游水资源开发利用研究[J]. 干旱区地理(汉文版), 2012, 35(3):388-398. Xuekelaiti Basituofu, Long Aihua, Deng Mingjiang, et al. Based on the Google Earth in the middle and lower reaches of the balkhash lake basin water resources development and utilization of research[J]. Journal of Arid Zone (Chinese version), 2012, 35(3):388-398.
[24] 许有鹏. 遥感信息在水文模型参数确定中的应用研究[J]. 遥感技术与应用, 1992, 7(4):16-22. Xu Youpeng. The application of remote sensing information in hydro-logical model parameters study[J].Journal of Remote Sensing Technolo-gy and Applications, 1992, 7(4):16-22.
[25] 谢欢. 基于遥感的水质监测与时空分析[D]. 上海:同济大学, 2006. Xie Huan. Water quality monitoring based on remote sensing and space-time analysis[D]. Shanghai:Tongji University, 2006.
[26] 汪权方, 许纪承, 陈媛媛, 等. 遥感影像空间分辨率对居民地信息提取的影响[J]. 资源科学, 2012, 34(1):159-165. Wang Quanfang, Xu Jicheng, Chen Yuanyuan, et al. Spatial resolution remote sensing image of residents in the influence of the information extraction[J]. Journal of Resources Science, 2012, 34(1):159-165.
[27] 周丹, 黄川友. 拉萨河流域水环境现状及污染防治对策[J]. 四川水利, 2007, 28(2):48-51. Zhou Dan, Huang Cuanyou. Lhasa river basin water environment sta-tus quo and pollution control countermeasures[J]. Journal of Water Re-sources in Sichuan, 2007, 28(2):48-51.
[28] 赵毓民. 关于河道断面形状的探讨[J]. 人民黄河, 1981(3):41-44. Zhao Yumin. On the river cross-section shape discussion[J]. The Peo-ple of The Yellow River, 1981(3):41-44.
[29] 蔺学东, 张镱锂, 姚治君, 等. 拉萨河流域近50年来径流变化趋势分析[J]. 地理科学进展, 2007, 26(3):58-67. Yan Xuedong, Zhang Yili, Yao Zhijun, et al. Lhasa river basin runoff in recent 50 years change trend analysis[J]. Journal of Geographical Science, 2007, 26(3):58-67.
[30] 丁海容. 拉萨市城区段水环境污染总量控制研究[D]. 成都:四川大学, 2005. Ding Hairong. Lhasa urban water environment pollution total amount control research[D]. Chengdu:Sichuan University, 2005.
[31] 沈大军, 陈传友, 苏人琼. 拉萨河水资源合理利用研究[J]. 自然资源学报, 1996(4):373-376. Shen Dajun, Chen Chuanyou, Su Renqiong. Lhasa river water resourc-es reasonable use research[J]. Journal of Natural Resources, 1996(4):373-376.
[32] 朱国宇. 拉萨市区地表水环境功能区划分及达标控制方案研究[D]. 成都:四川大学, 2003. Zhu Guoyu. Lhasa urban surface water environmental function divi-sion and standard control scheme research[D]. Chengdu:Sichuan Uni-versity, 2003.
Outlines

/