Numerical simulations of flow and sediment transport within the Ning-Meng reach of the Yellow River, northern China

doi:10.1007/s40333-017-0059-6

摘要
参考文献
相关文章
推荐阅读
Metrics

下载:

HTML

PDF (980KB)
输出: BibTeX | EndNote (RIS)

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

Abstract:

Effective management of a river reach requires a sound understanding of flow and sediment transport generated by varying natural and artificial runoff conditions. Flow and sediment transport within the Ning-Meng reach of the Yellow River (NMRYR), northern China are controlled by a complex set of factors/processes, mainly including four sets of factors: (1) aeolian sediments from deserts bordering the main stream; (2) inflow of water and sediment from numerous tributaries; (3) impoundment of water by reservoir/hydro-junction; and (4) complex diversion and return of irrigation water. In this study, the 1-D flow & sediment transport model developed by the Yellow River Institute of Hydraulic Research was used to simulate the flow and sediment transport within the NMRYR from 2001 to 2012. All four sets of factors that primarily control the flow and sediment transport mentioned above were considered in this model. Compared to the measured data collected from the hydrological stations along the NMRYR, the simulated flow and sediment transport values were generally acceptable, with relative mean deviation between measured and simulated values of <15%. However, simulated sediment concentration and siltation values within two sub-reaches (i.e., Qingtongxia Reservoir to Bayan Gol Hydrological Station and Bayan Gol Hydrological Station to Toudaoguai Hydrological Station) for some periods exhibited relatively large errors (the relative mean deviations between measured and simulated values of 18% and 25%, respectively). These errors are presumably related to the inability to accurately determine the quantity of aeolian sediment influx to the river reach and the inflow of water from the ten ephemeral tributaries. This study may provide some valuable insights into the numerical simulations of flow and sediment transport in large watersheds and also provide a useful model for the effective management of the NMRYR.

Key words: numerical simulation flow and sediment transport 1-D flow & sediment model Yellow River

收稿日期: 2016-09-07 修回日期: 2017-01-20 接受日期: 2017-05-15 出版日期: 2017-08-10 发布日期: 2017-05-15 期的出版日期: 2017-06-21

引用本文:

. [J]. 干旱区科学, 2017, 9(4): 591-608.
Shentang DOU, Xin YU, Heqiang DU, Fangxiu ZHANG. Numerical simulations of flow and sediment transport within the Ning-Meng reach of the Yellow River, northern China. Journal of Arid Land, 2017, 9(4): 591-608.

链接本文:

http://jal.xjegi.com/CN/10.1007/s40333-017-0059-6 或 http://jal.xjegi.com/CN/Y2017/V9/I4/591

1	Beasley D B, Huggins L F, Monke E J.1980. ANSWERS: a model for watershed planning. Transactions of the ASAE, 23(4): 938-944.
2	Burkow M, Griebel M.2016. A full three dimensional numerical simulation of the sediment transport and the scouring at a rectangular obstacle. Computers & Fluids, 125: 1-10.
3	Chang H H.1984. Modeling of river channel changes. Journal of Hydraulic Engineering, 110(2): 157-172.
4	Chen Q H, Fang H W, Wang G Q.2004. 1-D numerical simulation of unsteady flow and non-uniform sediment transport at the Sanmenxia reservoir in the Yellow River. Advances in Water Science, 15(2): 160-164. (in Chinese)
5	Chen W B, Liu W C, Wu C Y.2013. Coupling of one-dimentsional reiver routing model and a three-dimensional ocean model to predict overbank flows in a complex river-ocean system. Applied Mathematical Modelling, 37(9): 6163-6176.
6	Dai M, Xiong G, Zeng M.2008. Key technologies of regulation of water and sediment of the reservoirs along the main stream of Yellow River and reservoir operations adjustment of Longyangxia and Liujiaxia reservoirs. Special Report of Yellow River Conservancy Commission. Zhengzhou: Yellow River Conservancy Commission. (in Chinese)
7	Dou S T, Wang D W, Yu M H, et al.2014. Numerical modeling of the lateral widening of levee breach by overtopping in a flume with 180° bend. Natural Hazards and Earth System Sciences, 14(1): 11-20.
8	Du H Q, Xue X, Wang T.2014. Estimation of the quantity of aeolian saltation sediments blown into the Yellow River from the Ulanbuh Desert, China. Journal of Arid Land, 6(2): 205-218.
9	Du H Q, Xue X, Wang T, et al.2015. Assessment of wind-erosion risk in the watershed of the Ningxia-Inner Mongolia reach of the Yellow River, northern China. Aeolian Research, 17: 193-204.
10	Fan S S.1988. Twelve selected computer stream sedimentation models developed in the United States. Washington, DC: Federal Energy Regulatory Commission.
11	Fang H W, Wang G Q.2000. 1-D numerical simulation for total sediment transport and its application. Jounal of Basic Science and Engineering, 8(2): 154-164. (in Chinese)
12	Fryrear D W, Saleh A, Bilbro J D, et al.1998. Revised wind erosion equation (RWEQ). Technical Bulletin No. 1. USDA-ARS, Lubbock, TX.
13	Han Q J, Qu J J, Zhang K C, et al.2009. Wind tunnel investigation of the influence of surface moisture content on the entrainment and erosion of beach sand by wind using sands from tropical humid coastal southern China. Geomorphology, 104(3-4): 230-237.
14	Hanley N, Faichney R, Munro A, et al.1998. Economic and environmental modelling for pollution control in an estuary. Journal of Environmental Management, 52(3): 211-225.
15	Holly Jr F M, Rahuel J L.1990. New numerical/physical framework for mobile-bed modelling. Part 1: numerical and physical principles. Journal of Hydraulic Research, 28(4): 401-416.
16	Holly Jr F M, Yang J C, Schovarz P, et al.1990. CHARIMA: numerical simulation of unsteady water and sediment movements in multiply connected networks of mobile-bed channels. Report No. 343. Iowa City, Iowa: Iowa Institute of Hydraulic Research, University of Iowa.
17	Hou S Z.1996. Fluvial process of the Inner Mongolia Reach of the Yellow River in 1987-1993. Yellow River, (9): 43-44. (in Chinese)
18	Jia X P, Wang H B.2011. Mineral compositions and sources of the riverbed sediment in the desert channel of Yellow River. Environmental Monitoring and Assessment, 173(3-4): 969-983.
19	Jia X P, Wang H B, Xiao J H.2011. Geochemical elements characteristics and sources of the riverbed sediment in the yellow river's desert channel. Environmental Earth Sciences, 64(8): 2159-2173.
20	Karim M F, Kennedy J F.1982. IALLUVIAL: a commuter based discharge and sediment routing for alluvial streams and its application to the Missouri River. Report No. 250. Iowa City, Iowa: Iowa Institute of Hydraulic Research, University of Iowa.
21	Krishnappan B G.1981. Users manual: unsteady, non-uniform, mobile boundary flow model-MOBED. Burlington, Ontario: Hydraulic Division, National Water Research Institute.
22	Laflen J M, Lane L J, Foster G R.1991. WEPP: a new generation of erosion prediction technology. Journal of Soil and Water Conservation, 46(1): 34-38.
23	Li Y T, Shang Q M.1998. Modeling of sediment transport in unsteady flow. Journal of Sediment Research, (1): 81-87. (in Chinese)
24	Liang G T, Gao Y T, Liang Y P, et al.1999. Principles and application for mathmatical model for one-dimension unsteady sediment flow. Jounal of Sediment Research, (4): 44-48. (in Chinese)
25	Luan Z Y, Jin Q.2016. Research on water-sediment numerical simulation of middle and lower reaches of the Yangtze River and estuary. Procedia Engineering, 154: 582-588.
26	Martins R.1989. Recent Advances in Hydraulic Physical Modelling. Netherlands: Kluwer Academic Publisher, 1-2.
27	Merritt W S, Letcher R A, Jakeman A J.2003. A review of erosion and sediment transport models. Environmental Modelling & Software, 18(8-9): 761-799.
28	Molinas A M, Yang C T.1986. Computer program user’s manual for GSTARS. Denver, Colorado: U.S. Bureau of Reclamation Engineering and Research Center.
29	Nakato T.1990. Tests of selected sediment-transport formulas. Journal of Hydraulic Engineering, 116(3): 362-379.
30	Ong C. Knight D.1987. Hybrid MacCormack and implicit beam-warming algorithms for a supersonic compression corner. AIAA Journal, 25(3): 401-407.
31	Onishi Y.1994. Sediment transport models and their testing. In: Chaudhry M H, Mays L W. Computer Modeling of Free-surface and Pressurized Flows. Netherlands: Springer, 281-312.
32	Papanicolaou A N, Bdour A, Wicklein E.2004. One-dimensional hydrodynamic/sediment transport model applicable to steep mountain streams. Journal of Hydraulic Research, 42(4): 357-375.
33	Papanicolaou A N, Elhakeem M, Krallis G, et al.2008. Sediment transport modeling review-current and future developments. Journal of Hydrualic Engineering, 134(1): 1-14.
34	Peng Y, Zhang H W.2006. 1-D numerical simulation of unsteady flow and sedimentation transport at the Three Gorges Reservoir (TGR). Journal of Hydrodynamics, 21(3): 285-292. (in Chinese)
35	Przedwojski B, B?az?ejewski R, Pilarczyk K W. 1995.River Training Techniques: Fundamentals, Design and Applications. Balkema, the Netherlands: CRC Press, 1.
36	Qin Y.2009. Mechanics of river course response to river environment change and control strategy-for the Ning-Mong Section of the Yellow River. PhD Dissertation. Xi’an: Xi’an University of Technology. (in Chinese)
37	Ren R X, Tong G Q, Li J, et al.2004. Application of one-dimensional non-steady flow model to water regulation of the Yellow River. Yellow River, 26(12): 19-21. (in Chinese)
38	Rodi W.2006. DNS and LES of some engineering flows. Fluid Dynamics Research, 38(2-3): 145-173.
39	Runkel R L, Broshears R E.1991. OTIS: one-dimensional transport with indischarge and storage (OTIS): a solute transport model for small streams. CADWES Technical Report 91-01. Boulder, Colorado: University of Colorado.
40	Shao Y P.2001. A model for mineral dust emission. Journal of Geophysical Research, 106(D17): 20239-20254.
41	Spasojevic M, Holly Jr F M. 2000. Field data and 3D mobile-bed modeling: help or hindrance. In: Proceedings of the 4th International Conference on Hydroinformatics. Cedar Rapids: International Association of Hydraulic Engineering and Research.
42	Su T, Wang SJ, Mei Y G, et al.2015. Comparison of channel geometry changes in Inner Mongolian reach of the Yellow River before and after joint operation of large upstream reservoirs. Journal of Geographical Sciences, 25(8): 930-942.
43	Ta W Q, Yang G S, Qu J J, et al.2003. The effect of the coarse aeolian sand on siltation of the Inner Mongolian Reach of the Yellow River. Environmental Geology, 43(5): 493-502.
44	Ta W Q, Jia X P, Wang H B.2013. Channel deposition induced by bank erosion in response to decreased flows in the sand-banked reach of the upstream Yellow River. CATENA, 105: 62-68.
45	Ta W Q, Wang H B, Jia X P.2014. Aeolian process-induced hyper-concentrated flow in a desert watershed. Journal of Hydrology, 511: 220-228.
46	Termini D.2011. 1-D numerical simulation of sediment transport in alluvial channel beds. European Journal of Environmental and Civil Engineering, 15(2): 269-292.
47	Thomann R V.1982. Verification of water quality models. Journal of the Environmental Engineering Division, 108(5): 923-940.
48	Viney N R, Sivapalan M, Deeley D.2000. A conceptual model of nutrient mobilisation and transport applicable at large catchment scales. Journal of Hydrology, 240(1-2): 23-44.
49	Wang S Q.1996. Mathematical model for predicting the fluvial processes in the Yellow River. Advances in Water Science, 7(3): 193-199. (in Chinese)
50	Wu W M, Vierira D A, Wang S Y.2004. One-dimensional numerical model for nonuniform sediment transport under unsteady flows in channel networks. Jounral of Hydraulic Engineering, 130(9): 914-923.
51	Wu W M, Marsooli R, He Z G.2012. Depth-averaged two-dimensional model of unsteady flow and sediment transport due to noncohesive embankment break/breaching. Jounral of Hydraulic Engineering, 138(6): 503-516.
52	Xu J X.2013. Erosion and sediment yield of 10 small tributaries joining Inner Mengolia reach of upper Yellow River in relation with coupled wind-water processes and hyperconcentrated flows. Journal of Sediment Research, (6): 28-37. (in Chinese)
53	Yang G S, Liu Y Y, Shi P J.1987. Estimation of the aeolian sand entering the Yellow River. Chinese Science Bulletin, 13(13): 1017-1021. (in Chinese)
54	Yao H F, Shi C X, Shao W W, et al.2016. Changes and influencing factors of the sediment load in the Xiliugou Basin of the upper Yellow River, China. CATENA, 142: 1-10.
55	Yao Z Y, Ta W Q, Jia X P, et al.2011. Bank erosion and accretion along the Ningxia-Inner Mongolia reaches of the Yellow River from 1958 to 2008. Geomorphology, 127(1-2): 99-106.
56	Yen B C.1993. Criteria for evaluation of watershed models. Journal of Irrigation and Drainage Engineering, 119(3): 429-442.
57	Yu M H, Shen K, Wu S B, et al.2013. An experimental study of interaction between bank collapse and river bed evolution. Advances in Water Science, 24(5): 675-682. (in Chinese)
58	Zhang H W, Zhao L J, Wang G Q, et al.2003. Quasi-2D mathematical model for morphology of the Lower Yellow River. Journal of Hydrolic Engineering, (4): 1-7.
59	Zhao W, Chen X, Hou, S.1999. Variations of the alluvial process of the Yellow River in Ningxia Province and Inner Mongolia Province. Yellow River, 21(6): 11-14. (in Chinese)
60	Zhou L Y, Cui Z H, Luo Q S.2012. Water and sediment variation and characteristics of scouring and deposition of Ningxia-Inner Mongolia Reach of the Yellow River. Yellow River, 34(1): 25-26. (in Chinese)

No related articles found!

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed