闽江下游河道水动力水质动态模拟
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摘要
闽江下游河道属感潮河段,受径流和潮流的双重影响,河流流态复杂;省会福州依江而立,人类活动频繁,水环境问题比较严重,开展闽江下游河道水动力、水质问题研究,具有重要的理论与现实意义。
对闽江下游河道水环境存在的主要问题及原因进行了分析。大量生活污水、畜禽养殖和工业废水直接或间接排入闽江,部分河道水体功能互相矛盾,水污染压力大;下游河道的过量采砂及水口电站的蓄水拦沙导致河床下切严重,由此引发闽江口咸潮上溯,已经并将进一步影响福州地区的饮用水安全。
根据描述河道非恒定流运动的Saint-Venant方程,以及污染物浓度变化的一维对流扩散方程,采用Preissmann四点偏心隐式差分格式,建立了闽江下游河道(竹岐——梅花)一维水动力、水质模型,运用实测资料率定了糙率、纵向离散系数和污染物降解系数,验证了模型的合理性。应用该模型,1)对枯水条件下闽江下游河道水流运动特性进行了模拟,并就河道采砂对水流动力条件的影响进行了定量评价;2)充分考虑了下边界潮汐类型和浓度变化、上边界来水量及污染负荷、河段内排污口设置和排放条件等各种边界条件,对该河段污染物运动的时空规律进行了比较系统、全面的模拟研究,对感潮河道汊道之间污染物的相互影响进行了详细分析。
The lower reaches of Minjiang River is tidal channel network. Fuzhou city, the capital of Fujian Province, stands on the side of the river. Due to the human activities, water environmental problems are serious and the research of hydrodynamic and water quality modeling for the lower reaches of Minjiang River has theoretic and practical significance.
Through investigating and appraising the current situation of hydrologic and water environment in the lower reaches of Minjiang River, the thesis makes the conclusions that a great deal of sewage drained into the river without standard disposal have bought water pollution, which is more serious in some reaches where the regionalizations of water environment function are contradictory. Excessive sand extraction and construction of Shuikou hydropower station give rise to the descending of the riverbed and even the saltwater intrusion which occurs frequently in the dry season.
Based on the Saint-Venant equations describing the movement of unsteady flow and one-dimension convection diffusion equation describing the variation of contaminant concentration, using the Preissmann weighted implicit four-point scheme, one dimensional hydrodynamic and water quality models are established and applied to the lower reaches of Minjiang River. According to the simultaneous observed data, main parameters are calibrated. The results of the computation prove that the models are rational and reliable. Applying the verified models, the characteristics of low flow are numerically simulated, and the effect of excessive sand extraction is quantificationally evaluated. Comprehensive simulation and research on the contaminant concentration in the tidal river have been conducted with representative boundary conditions, including the variation of lower boundary(Minjiang River mouth) tidal types and contaminant concentration, upper boundary(Zhuqi hydrologic station) discharges and total pollution load, sewage outfalls setting and so on.
对闽江下游河道水环境存在的主要问题及原因进行了分析。大量生活污水、畜禽养殖和工业废水直接或间接排入闽江,部分河道水体功能互相矛盾,水污染压力大;下游河道的过量采砂及水口电站的蓄水拦沙导致河床下切严重,由此引发闽江口咸潮上溯,已经并将进一步影响福州地区的饮用水安全。
根据描述河道非恒定流运动的Saint-Venant方程,以及污染物浓度变化的一维对流扩散方程,采用Preissmann四点偏心隐式差分格式,建立了闽江下游河道(竹岐——梅花)一维水动力、水质模型,运用实测资料率定了糙率、纵向离散系数和污染物降解系数,验证了模型的合理性。应用该模型,1)对枯水条件下闽江下游河道水流运动特性进行了模拟,并就河道采砂对水流动力条件的影响进行了定量评价;2)充分考虑了下边界潮汐类型和浓度变化、上边界来水量及污染负荷、河段内排污口设置和排放条件等各种边界条件,对该河段污染物运动的时空规律进行了比较系统、全面的模拟研究,对感潮河道汊道之间污染物的相互影响进行了详细分析。
The lower reaches of Minjiang River is tidal channel network. Fuzhou city, the capital of Fujian Province, stands on the side of the river. Due to the human activities, water environmental problems are serious and the research of hydrodynamic and water quality modeling for the lower reaches of Minjiang River has theoretic and practical significance.
Through investigating and appraising the current situation of hydrologic and water environment in the lower reaches of Minjiang River, the thesis makes the conclusions that a great deal of sewage drained into the river without standard disposal have bought water pollution, which is more serious in some reaches where the regionalizations of water environment function are contradictory. Excessive sand extraction and construction of Shuikou hydropower station give rise to the descending of the riverbed and even the saltwater intrusion which occurs frequently in the dry season.
Based on the Saint-Venant equations describing the movement of unsteady flow and one-dimension convection diffusion equation describing the variation of contaminant concentration, using the Preissmann weighted implicit four-point scheme, one dimensional hydrodynamic and water quality models are established and applied to the lower reaches of Minjiang River. According to the simultaneous observed data, main parameters are calibrated. The results of the computation prove that the models are rational and reliable. Applying the verified models, the characteristics of low flow are numerically simulated, and the effect of excessive sand extraction is quantificationally evaluated. Comprehensive simulation and research on the contaminant concentration in the tidal river have been conducted with representative boundary conditions, including the variation of lower boundary(Minjiang River mouth) tidal types and contaminant concentration, upper boundary(Zhuqi hydrologic station) discharges and total pollution load, sewage outfalls setting and so on.
引文
1 陈宁.河工模型试验在闽江福州段水污染防治规划中的应用[J].闽江学院学报,2004,25(5):101-105
2 江毓武,张珞平.闽江口水动力和污染扩散数值模拟[J].台湾海峡,1997,16(2):169-173
3 Newton, Sir. 'Propositions'. Book2 in Principia[M]. Royal Society, London, 1687:44-46
4 Laplace, P. S. Recherches sur Quelques Points due Systems du Monde[J]. Researches on Some Points of World System. Memoirs, Acad. Sci., Paris, 1776,9
5 Poisson, S.D. Memoir on the Theory of Waves[J]. Memoirs, Acad. Sci.,Paris, 1816,1: 71-186
6 Boussinesq, J. 'Theory of the liquid intumescence, called a solitary wave or a wave of translation, propagated in a channel of rectangular cross section'[J]. Complex Rendus Acad. Sci., Paris, 1871: 755-759
7 汪德爟.计算水力学理论与应用[M].南京:河海大学出版社,1989
8 Camara A S, Randall C W. The QUAL-2 model[J]. Proc. ASCE. J. EnvirEngrg, 110(5}: 993
9 G. Noseda. Mathematical Model of Unsteady Flow in Open Channels Networks[J]. Proceedings of the International Symposium on Unsteady Flow in Open Channels, 1976
10 J. J. R. Williams, T. R. E. Chidley. Nonliear Analysis of Unsteady Flow in Open Channel Networks[J]. Proceedings of the International Symposium on Unsteady Flow in Open Channels, 1976
11 李岳生.河网不恒定流隐式方程组稀疏矩阵解法[J].中山大学学报(自然科学版),1979,(1):21-26
12 J.J.Dronkers.河流近海区和外海的潮汐计算[J].水利水运科技情报,1976
13 徐正凡.明渠非恒定流[M].武汉水利电力学院,1983
14 张二骏.河网非恒定流的三级联合解法[J].华东水利学院学报,1982,10(1):1-12
15 吴寿红.河网非恒定流四级解法[J].水利学报,1985,(8):42-50
16 Jean A. Cunge. Two-dimensional modeling of flood plains[A]. K. Mahmood and V. Yevjech(edited). Unsteady flow in open channels[C],USA: Water resources publications, 1975, 2
17 金忠青.平原河网水量计算及参数率定——改进的湄公河模型[J].水动力学研究与进展(A辑),1991,6(增刊):39-45
18 韩龙喜,张学农.复杂河网非恒定流计算模型——单元划分法[J].水利学报,1994(2):52-56
19 Akan, A. O., and Yen, B. C. Diffusion wave flood routing in channel networks[J]. J. Hydr.Div., ASCE, 1981,107(7): 719-732
20 Choi, G.W., and Molinas, A. "Simultaneous solution algorithm for channel network modeling." [J] . Water Resour. Res., 1993,29(2): 321-328
21 Hillary H. Jeffcoat, and Marshall E. Jennings. "Computation of unsteady flows in the Alabama River"[J]. water resourcesbulletin, 1987,23(2): 313-315
22 韩龙喜,朱党生.河网地区水环境规划中的污染源控制方法[J].水利学报,2001(10):28-31
23 Nquyen, Q. K. and Kawano, H. "Simultaneous solution for flood routing in channel networks." [J]. J. Hydr. Engrg., ASCE, 1995,121(10): 744-750
24 傅国伟.河流水质数学模型及其模拟计算[M].北京:中国环境科学出版社,1987
25 李炜.环境水力学进展[M].武汉:武汉水利电力大学出版社,1999
26 郭天恩,孙西欢.国内外水质数学模型的研究与发展[J].西北水资源与水工程,1994,5(3):9-12
27 James Fitzpatric, Jhon Lmhoff, Edward Burgess. Water Quality Models[M]. A survey and Assessment, 2001
28 李本纲,陶澎,曹军.水环境模型与水环境模型库管理[J].水科学进展,2002,13(1):14-20
29 徐祖信,廖振良.水质数学模型研究的发展阶段和空间层次[J].上海环境科学,2003,22(2):79-85
30 Norid, S., H. Ghaemi, H..Mir Abolghasemi, and M. Abediny. Evaluation of the HEC-1 Model for Flood Forecasting and Simulation in the Hormozgan Province[J]. Iran: Journal of Environmental Hydrology, 2001, 5
31 徐贵泉、褚君达、吴祖达、陈庆江.感潮河网水环境容量影响因素研究[J].水科学进展,2000,12:376-369
32 褚君达.河网对流输移问题的求解及应用[J].水利学报,1994,10:14-35
33 徐贵泉,宋德蕃,黄士力等.感潮河网水力水质模型及其数值模拟[J].应用基础与工程学学报,1996,1:94-104
34 吴时强,丁道扬,吴碧君,马英.平面二维动态水质数学模型[J].水动力学研究与进展,1996,12:653-660
35 蒋忠锦,王继徽.天然河流一维水质模型的研究与改进[J].湖南大学学报,1997,12:90-94
36 丁训静,姚琪.水质模型在运河水网区应用的研究[J].河海大学学报,1991,19(3)
37 褚君达,徐惠慈.河网水质模型及其数值模拟[J].河海大学学报,1992,20(1)
38 曾凡棠,许振成.潮汐河网水环境实时数学模型研究与应用[J].重庆环境科学,1989,11(6):36-43
39 徐贵泉,吴祖扬.潮汐河网水环境容量数值计算[J].环境科学学报,2000,20(3):263-268
40 徐祖信,卢士强.平原感潮河网水质模型研究[J].水动力学研究与进展,2003,18(2):182-186
41 张永良,刘陪哲.水环境容量综合手册[M].北京:清华大学出版社,1991
42 李重荣.流域污染负荷与水质变化预测研究[T].武汉大学博士学位论文,2003.4:14-15
43 程永隆.闽江下游河床下切对水资源利用的影响[J].水利科技,2005(1):12-14
44 王峰.闽江下游河道保护与整治的一些看法[J].城市道桥与防洪,1999(3):39-40
45 罗进洲.基于SMS及RS的闽江福州段水污染控制研究[T].福州大学环境工程硕士论文,2004.1:22-23
46 陈兴伟,周长春,刘梅冰.福州内河水环境综合治理研究[J].福建师范大学学报,2004,20(3):76-79
47 陈守真.水口水电站蓄水运行对下游河道及河口区海潮上溯的影响分析[J].水力发电,1997(11):20-21
48 陈兴伟,罗肇森.感潮河网水沙运行计算[J].水利水运科学研究,1988(1):33—41
49 陈兴伟.开展闽江下游河道水质模型研究的几个问题[J].水利科技,1992(3):14—17
50 陈锡林.新沂河沐东段水漫滩河道糙率计算探讨[J].水文,2000,20(1):41-46
51 徐祖信.河流污染治理规划理论与实践[M].北京:中国环境科学出版社,2003.2:332-335
52 倪立.闽江福州段水环境容量合理利用探讨[J].福建建筑,2004(5):113-114
2 江毓武,张珞平.闽江口水动力和污染扩散数值模拟[J].台湾海峡,1997,16(2):169-173
3 Newton, Sir. 'Propositions'. Book2 in Principia[M]. Royal Society, London, 1687:44-46
4 Laplace, P. S. Recherches sur Quelques Points due Systems du Monde[J]. Researches on Some Points of World System. Memoirs, Acad. Sci., Paris, 1776,9
5 Poisson, S.D. Memoir on the Theory of Waves[J]. Memoirs, Acad. Sci.,Paris, 1816,1: 71-186
6 Boussinesq, J. 'Theory of the liquid intumescence, called a solitary wave or a wave of translation, propagated in a channel of rectangular cross section'[J]. Complex Rendus Acad. Sci., Paris, 1871: 755-759
7 汪德爟.计算水力学理论与应用[M].南京:河海大学出版社,1989
8 Camara A S, Randall C W. The QUAL-2 model[J]. Proc. ASCE. J. EnvirEngrg, 110(5}: 993
9 G. Noseda. Mathematical Model of Unsteady Flow in Open Channels Networks[J]. Proceedings of the International Symposium on Unsteady Flow in Open Channels, 1976
10 J. J. R. Williams, T. R. E. Chidley. Nonliear Analysis of Unsteady Flow in Open Channel Networks[J]. Proceedings of the International Symposium on Unsteady Flow in Open Channels, 1976
11 李岳生.河网不恒定流隐式方程组稀疏矩阵解法[J].中山大学学报(自然科学版),1979,(1):21-26
12 J.J.Dronkers.河流近海区和外海的潮汐计算[J].水利水运科技情报,1976
13 徐正凡.明渠非恒定流[M].武汉水利电力学院,1983
14 张二骏.河网非恒定流的三级联合解法[J].华东水利学院学报,1982,10(1):1-12
15 吴寿红.河网非恒定流四级解法[J].水利学报,1985,(8):42-50
16 Jean A. Cunge. Two-dimensional modeling of flood plains[A]. K. Mahmood and V. Yevjech(edited). Unsteady flow in open channels[C],USA: Water resources publications, 1975, 2
17 金忠青.平原河网水量计算及参数率定——改进的湄公河模型[J].水动力学研究与进展(A辑),1991,6(增刊):39-45
18 韩龙喜,张学农.复杂河网非恒定流计算模型——单元划分法[J].水利学报,1994(2):52-56
19 Akan, A. O., and Yen, B. C. Diffusion wave flood routing in channel networks[J]. J. Hydr.Div., ASCE, 1981,107(7): 719-732
20 Choi, G.W., and Molinas, A. "Simultaneous solution algorithm for channel network modeling." [J] . Water Resour. Res., 1993,29(2): 321-328
21 Hillary H. Jeffcoat, and Marshall E. Jennings. "Computation of unsteady flows in the Alabama River"[J]. water resourcesbulletin, 1987,23(2): 313-315
22 韩龙喜,朱党生.河网地区水环境规划中的污染源控制方法[J].水利学报,2001(10):28-31
23 Nquyen, Q. K. and Kawano, H. "Simultaneous solution for flood routing in channel networks." [J]. J. Hydr. Engrg., ASCE, 1995,121(10): 744-750
24 傅国伟.河流水质数学模型及其模拟计算[M].北京:中国环境科学出版社,1987
25 李炜.环境水力学进展[M].武汉:武汉水利电力大学出版社,1999
26 郭天恩,孙西欢.国内外水质数学模型的研究与发展[J].西北水资源与水工程,1994,5(3):9-12
27 James Fitzpatric, Jhon Lmhoff, Edward Burgess. Water Quality Models[M]. A survey and Assessment, 2001
28 李本纲,陶澎,曹军.水环境模型与水环境模型库管理[J].水科学进展,2002,13(1):14-20
29 徐祖信,廖振良.水质数学模型研究的发展阶段和空间层次[J].上海环境科学,2003,22(2):79-85
30 Norid, S., H. Ghaemi, H..Mir Abolghasemi, and M. Abediny. Evaluation of the HEC-1 Model for Flood Forecasting and Simulation in the Hormozgan Province[J]. Iran: Journal of Environmental Hydrology, 2001, 5
31 徐贵泉、褚君达、吴祖达、陈庆江.感潮河网水环境容量影响因素研究[J].水科学进展,2000,12:376-369
32 褚君达.河网对流输移问题的求解及应用[J].水利学报,1994,10:14-35
33 徐贵泉,宋德蕃,黄士力等.感潮河网水力水质模型及其数值模拟[J].应用基础与工程学学报,1996,1:94-104
34 吴时强,丁道扬,吴碧君,马英.平面二维动态水质数学模型[J].水动力学研究与进展,1996,12:653-660
35 蒋忠锦,王继徽.天然河流一维水质模型的研究与改进[J].湖南大学学报,1997,12:90-94
36 丁训静,姚琪.水质模型在运河水网区应用的研究[J].河海大学学报,1991,19(3)
37 褚君达,徐惠慈.河网水质模型及其数值模拟[J].河海大学学报,1992,20(1)
38 曾凡棠,许振成.潮汐河网水环境实时数学模型研究与应用[J].重庆环境科学,1989,11(6):36-43
39 徐贵泉,吴祖扬.潮汐河网水环境容量数值计算[J].环境科学学报,2000,20(3):263-268
40 徐祖信,卢士强.平原感潮河网水质模型研究[J].水动力学研究与进展,2003,18(2):182-186
41 张永良,刘陪哲.水环境容量综合手册[M].北京:清华大学出版社,1991
42 李重荣.流域污染负荷与水质变化预测研究[T].武汉大学博士学位论文,2003.4:14-15
43 程永隆.闽江下游河床下切对水资源利用的影响[J].水利科技,2005(1):12-14
44 王峰.闽江下游河道保护与整治的一些看法[J].城市道桥与防洪,1999(3):39-40
45 罗进洲.基于SMS及RS的闽江福州段水污染控制研究[T].福州大学环境工程硕士论文,2004.1:22-23
46 陈兴伟,周长春,刘梅冰.福州内河水环境综合治理研究[J].福建师范大学学报,2004,20(3):76-79
47 陈守真.水口水电站蓄水运行对下游河道及河口区海潮上溯的影响分析[J].水力发电,1997(11):20-21
48 陈兴伟,罗肇森.感潮河网水沙运行计算[J].水利水运科学研究,1988(1):33—41
49 陈兴伟.开展闽江下游河道水质模型研究的几个问题[J].水利科技,1992(3):14—17
50 陈锡林.新沂河沐东段水漫滩河道糙率计算探讨[J].水文,2000,20(1):41-46
51 徐祖信.河流污染治理规划理论与实践[M].北京:中国环境科学出版社,2003.2:332-335
52 倪立.闽江福州段水环境容量合理利用探讨[J].福建建筑,2004(5):113-114