Coherent Disturbance Structures and Bed Topography Responses in Large Depth-to-Width Ratio River Bends With Constant Curvatures

GAO Shu-xian; XU Hai-jue; BAI Yu-chuan

doi:10.21656/1000-0887.370094

Volume 37 Issue 10

Turn off MathJax

Article Contents

Article Navigation > Applied Mathematics and Mechanics > 2016 > 37(10): 1100-1117

GAO Shu-xian, XU Hai-jue, BAI Yu-chuan. Coherent Disturbance Structures and Bed Topography Responses in Large Depth-to-Width Ratio River Bends With Constant Curvatures[J]. Applied Mathematics and Mechanics, 2016, 37(10): 1100-1117. doi: 10.21656/1000-0887.370094

Citation:

PDF( 9504 KB)

Coherent Disturbance Structures and Bed Topography Responses in Large Depth-to-Width Ratio River Bends With Constant Curvatures

doi: 10.21656/1000-0887.370094

¹State Key Laboratory of Hydraulic Engineering Simulation and Safety(Tianjin University), Tianjin 300072, P.R.China;²Institute of Sediment on River and Coastal Engineering,Tianjin University, Tianjin 300072, P.R.China

Funds: The National Natural Science Foundation of China（51279124；51021004；50979066）

Received Date: 2016-04-01
Rev Recd Date: 2016-09-13
Publish Date: 2016-10-15

Abstract

Abstract

The bed topography is the result of the dynamic response of a complex meandering river system, and is an important factor influencing the further river development. Based on meandering rivers characterized by large depth-to-width ratios, the relation between the hydraulic structure and the bed topography was explored. The flow characteristics and bed topography responses were discussed through coupling of the N-S equations, the sediment transport equations as well as the bed deformation equations, and with the perturbation method. Research results show that shallows and deep grooves present regular responses under the effects of 2D flow disturbances. For a zero curvature, the bed topography shows an anti-symmetric distribution about the channel centerline; while for a non-zero curvature, the channel centerline deviates toward the concave bank. Finally, the criteria for the judgement on the stability of the bed topography influenced by the Reynolds number, the disturbance wave number and the decay ratio of the bed topography, are given.
- meandering river,
- large depth-to-width ratio river bend,
- coherent disturbance wave,
- dynamic bed topography response

FullText(HTML)

References(20)

References

[1]	Johannesson H, Parker G. Flow field and bed topography in river meanders[C]// Proceedings of Hydraulic Engineering.New York: ASCE, 1988: 684-689.
[2]	Johannesson H，Parker G. Linear Theory of River Meanders [M]//Ikeda S, Parker G, ed. River Meandering.Washington DC: American Geophysical Union, 1989: 181-214.
[3]	Seminara G. Meanders[J]. Journal of Fluid Mechanics, 2006,554: 271-297.
[4]	Pittaluga M B, Nobile G, Seminara G. A nonlinear model for river meandering[J]. Water Resource Research, 2009,45(4): 1-22.
[5]	Martin R L, Jerolmack D J. Origin of hysteresis in bed form response to unsteady flows[J]. Water Resource Research,2013,49(3): 1314-1333.
[6]	Nelson A, Dubé K. Channel response to an extreme flood and sediment pulse in a mixed bedrock and gravel-bed river[J]. Earth Surface Processes and Landforms,2016,41(2): 178-195.
[7]	Yalin M S. Mechanics of Sediment Transport [M]. Oxford: Pergamon Press, 1972: 100-114.
[8]	白玉川, 罗纪生. 明渠层流失稳与沙纹成因机理研究[J]. 应用数学和力学, 2002,23(3): 254-268.（BAI Yu-chuan, LUO Ji-sheng. The loss of stability of laminar flow in open channel and the mechanism of sand ripple formation[J]. Applied Mathematics and Mechanics,2002, 23(3): 254-268.（in Chinese））
[9]	XU Hai-jue, BAI Yu-chuan. The nonlinear theory for sediment ripple dynamic process of straight river[J]. Science China: Technological Sciences,2012,55(3): 753-771.
[10]	XU Hai-jue, BAI Yu-chuan. Theoretical analyses on hydrodynamic instability in narrow deep river with variable curvature[J]. Applied Mathematics and Mechanics (English Edition),2015，36(9): 1147-1168.
[11]	许栋, 白玉川, 谭艳. 正弦派生曲线弯道中水沙运动特性动床试验[J]. 天津大学学报（自然科学版）, 2010,43(9)：762-770.(XU Dong, BAI Yu-chuan, TAN Yan. Experiment on characteristics of flow and sediment movement in sine-generated meandering channels with movable bed[J].Journal of Tianjin University (Natural Science Edition),2010，43(9)：762-770. (in Chinese))
[12]	白玉川, 冀自清, 刘小谢, 徐海珏, 杨树青, 杨燕华. 常曲率窄深型弯曲河流水流动力稳定特征理论研究[J]. 中国科学: 物理学力学天文学, 2012,42(2): 162-171.(BAI Yu-chuan, JI Zi-qing, LIU Xiao-xie, XU Hai-jue, YANG Shu-qing, YANG Yan-hua. Instability of laminar flow in narrow and deep meander channel with constant curvature[J]. Scientic Sinica: Physica, Mechanica and Astronomica, 2012,42(2): 162-171.(in Chinese))
[13]	BAI Yu-chuan, JI Zi-qing, XU Hai-jue. Stability and self-adaption character of turbulence coherent structure in narrow-deep river bend[J]. Science China: Technological Sciences,2012,55(11): 2990-2999.
[14]	钱宁, 万兆惠. 泥沙运动力学[M]. 北京: 科学出版社, 2003: 28.（QIAN Ning, WAN Zhao-hui. Mechanics of Sediment Transport [M]. Beijing: Science Press, 2003: 28. （in Chinese））
[15]	汪维刚, 许永红, 石兰芳, 莫嘉琪. 一类双参数非线性高阶反应扩散方程的摄动解法[J]. 应用数学和力学, 2014,35(12): 1383-1391.(WANG Wei-gang, XU Yong-hong, SHI Lan-fang, MO Jia-qi. Perturbation method for a class of high-order nonlinear reaction diffusion equations with double parameters[J]. Applied Mathematics and Mechanics,2014,35(12): 1383-1391.(in Chinese))
[16]	冯依虎, 石兰芳, 汪维刚, 莫嘉琪. 一类广义非线性强阻尼扰动发展方程的行波解[J]. 应用数学和力学, 2015,36(3): 315-324.( FENG Yi-hu, SHI Lan-fang, WANG Wei-gang, MO Jia-qi. Travelling wave solution to a class of generalized nonlinear strong-damp disturbed evolution equations[J]. Applied Mathematics and Mechanics,2015,36(3): 315-324.(in Chinese))
[17]	Saghafian M, Saberian I, Rajabi R, Shirani E. A numerical study on slip flow heat transfer in micro-poiseuille flow using perturbation method[J]. Journal of Applied Fluid Mechanics, 2015,8(1): 123-132.
[18]	ZHOU Heng, LU Chang-gen, LUO Ji-sheng. Modeling of individual coherent structures in wall region of a turbulent boundary layer[J]. Science in China (Series A),1999,42(6): 366-372.
[19]	ZHANG Dong-ming, LUO Ji-sheng, ZHOU Heng. Dynamic model of coherent structure in the wall region of a turbulent boundary layer[J]. Science in China (Series G), 2003,46(3): 291-299.
[20]	BAI Yu-chuan, YANG Yan-hua. The dynamic stability of the flow in a meander channel[J]. Science China: Technological Sciences,2011,54(4): 931-940.