THE LATERAL DISTRIBUTION OF DEPTH-AVERAGED VELOCITY IN CONSECUTIVE BENDS WITH POOL-POINT BAR

Liu Yujiao; Yu Minghui; Tian Haoyong

doi:10.6052/0459-1879-20-208

Volume 53 Issue 2

Feb. 2021

Turn off MathJax

Article Contents

Abstract

References

Chinese Journal of Theoretical and Applied Mechanics > 2021 > 53(2): 580-588. > DOI: 10.6052/0459-1879-20-208 CSTR: 32045.14.0459-1879-20-208

Liu Yujiao, Yu Minghui, Tian Haoyong. THE LATERAL DISTRIBUTION OF DEPTH-AVERAGED VELOCITY IN CONSECUTIVE BENDS WITH POOL-POINT BAR[J]. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(2): 580-588. DOI: 10.6052/0459-1879-20-208

Citation:

PDF (771 KB)

THE LATERAL DISTRIBUTION OF DEPTH-AVERAGED VELOCITY IN CONSECUTIVE BENDS WITH POOL-POINT BAR

State Key Laboratory of Water Resources and Hydropower Engineering Science, Wuhan University, Wuhan 430072, China

Received Date: June 15, 2020

Graphical Abstract

Abstract

Abstract

This paper proposes an analytical approach to modeling the lateral distribution of depth-averaged streamwise velocity for flow in consecutive bends with pool-point bar based on the depth-integrated Navier-Stokes equations. The additional secondary flow and yet fully developed flow are assumed to be a linear function of the lateral distance. Then, the model for calculating the average vertical velocity distribution along the cross section of the pool region and the point bar regions is presented, and it is applied to consecutive bends with pool-point bar. By calibrating the calculated parameters from the measured data, the model can calculate the average longitudinal velocity distribution of vertical cross-section under different outlet water depth. The modeled results agree well with experimental data. The value rules of the parameters have analyzed for different water depth and along the cross-sections. Sensitivity analysis is performed on the parameters which showed that the region division of the coefficient of the first degree term in the linear hypothesis has great influence on the size and position of the peak flow velocity. The region division of the constant term value is according to the traverse gradient. The region edge between the flat bed and the sloping bed of the constant term has a significant influence on the results. According to the sensitivity of parameters, the mean value of parameters along the flume is presented as a reference value. The transverse distribution of the secondary flow term and the additional stress term in the depth-integrated Navier--Stokes equations along the experimental channel is discussed to further understand the applicability of the linear hypothesis. The results show that the linear hypothesis is suitable for the curve path in the flume. The research results are helpful to understand the longitudinal velocity distribution characteristics and the formation mechanism of the consecutive bends with pool-point bar.
- consecutive bends,
- streamwise velocity,
- pool-point bar,
- open channel flow,
- analytic solutions

FullText(HTML)

References (30)

References

[1]	Abril JB, Knight DW. Stage-discharge prediction for rivers in flood applying a depth-averaged model. Journal of Hydraulic Research, 2004,42(6):616-629
[2]	Sharifi S, Sterling M. Using the Shiono and Knight model to predict sediment transport//European IAHR Congress. HeriotWatt University, Edinburgh: Scotland, 2010
[3]	王虹, 王连接, 邵学军等. 连续弯道水流紊动特性试验研究. 力学学报, 2013,45(4):525-533 (Wang Hong, Wang Lianjie, Shao Xuejun, et al. Turbulence characteristics in consecutive bends. Chinese Journal of Theoretical and Applied Mechanics, 2013,45(4):525-533 (in Chinese))
[4]	Farhadi A, Sindelar C, Tritthart M, et al. An investigation on the outer bank cell of secondary flow in channel bends. Journal of Hydro-Environment Research, 2018,18:1-11
[5]	王千, 刘桦, 房詠柳等. 孤立波与淹没平板相互作用的三维波面和水动力实验研究. 力学学报, 2019,51(6):1605-1613 (Wang Qian, Liu Hua, Fang Yongliu, et al. An experimental study of 3-d wave surface and hydrodynamic loads for interaction between solitary wave and submerged horizontal plate. Chinese Journal of Theoretical and Applied Mechanics, 2019,51(6):1605-1613 (in Chinese))
[6]	杨燕华, 白玉川. 连续弯道水流运动的三维数值模拟. 泥沙研究, 2011 ( 6):46-49 (Yang Yanhua, Bai Yuchuan. Three-dimensional numerical simulation of flow in successive bends. Journal of Sediment Research, 2011,6:46-49 (in Chinese))
[7]	Gholami A, Bonakdari H, Zaji AH, et al. Simulation of open channel bend characteristics using computational fluid dynamics and artificial neural networks. Engineering Applications of Computational Fluid Mechanics, 2015,9(1):355-369
[8]	吴霆, 时北极, 王士召等. 大涡模拟的壁模型及其应用. 力学学报, 2018,50(3):453-466 (Wu Ting, Shi Beiji, Wang Shizhao, et al. Wall-model for large-eddy simulation and its applications. Chinese Journal of Theoretical and Applied Mechanics, 2018,50(3):453-466 (in Chinese))
[9]	张嫚嫚, 孙姣, 陈文义. 一种基于几何重构的Youngs-VOF耦合水平集追踪方法. 力学学报, 2019,51(3):775-786 (Zhang Manman, Sun Jiao, Chen Wenyi. An interface tracking method of coupled youngs-vof and level set based on geometric reconstruction. Chinese Journal of Theoretical and Applied Mechanics, 2019,51(3):775-786 (in Chinese))
[10]	王韦, 蔡金德. 弯曲河道内水深和流速平面分布的计算. 泥沙研究, 1989(2):46-54 (Wang Wei, Cai Jinde. Computation for distribution of d and velocity in curved open channels. Journal of Sediment Research, 1989(2):46-54 (in Chinese))
[11]	许唯临. 复式河道漫滩水流计算方法研究. 水利学报, 2002,33(6):0021-0027 (Xu Weilin. Study on computational method of overbank flow in channels with compound cross section. Journal of Hydraulic Engineering, 2001,6:21-26 (in Chinese))
[12]	Tang XN, Knight DW. A general model of lateral depth-averaged velocity distributions for open channel flows. Advances in Water Resources, 2008,31(5):846-857
[13]	Yang KJ, Nie RH, Liu XN, et al. Modeling depth-averaged velocity and boundary shear stress in rectangular compound channels with secondary flows. Journal of Hydraulic Engineering, 2013,139(1):76-83
[14]	孙东坡, 朱岐武, 张耀先等. 弯道环流流速与泥沙横向输移研究. 水科学进展, 2006,17(1):61-66 (Sun Dongpo, Zhu Qiwu, Zhang Yaoxian, et al. Study of circulating velocity profile and lateral sediment transport in curved channels. Advances in Water Science, 2006,17(1):61-66 (in Chinese))
[15]	Shiono K, Knight DW. Turbulent open-channel flows with variable depth across the channel. Journal of Fluid Mechanics, 1991,222:617-646
[16]	Devi K, Khatua KK, Das BS. A numerical solution for depth-averaged velocity distribution in an open channel flow. ISH Journal of Hydraulic Engineering, 2016,22(3):262-271
[17]	Ervine DA, Babaeyan-Koopaei K, Sellin RHJ. Two-dimensional solution for straight and meandering overbank flows. Journal of Hydraulic Engineering, 2000,126(9):653-669
[18]	Knight DW, Omran M, Tang XN. et al. Modeling depth-averaged velocity and boundary shear in trapezoidal channels with secondary flows. Journal of Hydraulic Engineering, 2007,133(1):39-47
[19]	Liu C, Luo X, Liu XN. et al. Modeling depth-averaged velocity and bed shear stress in compound channels with emergent and submerged vegetation. Advances in Water Resources, 2013,60:148-159
[20]	Huai WX, Gao M, Zeng YH. et al. Two-dimensional analytical solution for compound channel flows with vegetated floodplains. Applied Mathematics & Mechanics, 2009,30(9):1121-1130
[21]	Zhong Y, Huai WX, Chen G. Analytical model for lateral depth-averaged velocity distributions in rectangular ice-covered channels. Journal of Hydraulic Engineering, 2019,145(1):04018080
[22]	杨中华, 高伟. 考虑滩槽相互作用的漫滩水流二维解析解. 四川大学学报 (工程科学版), 2009,41(5):42-46 (Yang Zhonghua, Gao Wei. Two dimensional analytical solution for overbank flows with interaction between the main channel and floodplain. Journal of Sichuan University (Engineering Science Edition), 2009,41(5):42-46 (in Chinese))
[23]	哈岸英, 吴腾, 陈刚. 冲积河流滩槽定量划分方法及应用. 水利学报, 2012,43(1):10-14 (Ha Anying, Wu Teng, Chen Gang. Quantitative division method for floodplain and main channel of alluvial river and its application. Journal of Hydraulic Engineering, 2012,43(1):10-14 (in Chinese))
[24]	Rezaei B, Knight DW. Application of the Shiono and Knight method in compound channels with non-prismatic floodplains. Journal of Hydraulic Research, 2009,47(6):716-726
[25]	Rozovskii IL. Flow of Water in Bends of Open Channels. London: Acad. of Sci. of the Ukrainian SSR, Kiev, 1957
[26]	Tang XN, Knight DW. The lateral distribution of depth-averaged velocity in a channel flow bend. Journal of Hydro-environment Research, 2015,9(4):532-541
[27]	Tubino M, Repetto R, Zolezzi G. Free bars in rivers. Journal of Hydraulic Research, 1999,37(6):759-775
[28]	Chow VT. . Open-Channel Hydraulics. London: McGraw-Hill, 1959
[29]	Van Balen W, Uijttewaal WSJ, Blanckaert K. Large-eddy simulation of a mildly curved open-channel flow. Journal of Fluid Mechanics, 2009,630:413-442
[30]	Hu CW, Yu MH, Wei HY. et al. The mechanisms of energy transformation in sharp open-channel bends: Analysis based on experiments in a laboratory flume. Journal of Hydrology, 2019,571:723-739

[1]	Zhou Yongfeng, Li Jie. ANALYTICAL SOLUTIONS OF THE GENERALIZED PROBABILITY DENSITY EVOLUTION EQUATION WITH MULTIDIMENSIONAL RANDOM VARIABLES: THE CASE OF EULER-BERNOULLI BEAM[J]. Chinese Journal of Theoretical and Applied Mechanics, 2024, 56(9): 2659-2668. DOI: 10.6052/0459-1879-24-001
[2]	Wang Zhechao, Jia Wenjie, Feng Xiating, Wang Jingkui. ANALYTICAL SOLUTION OF LIMIT STORAGE PRESSURES FOR TUNNEL TYPE LINED GAS STORAGE CAVERNS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2023, 55(3): 710-718. DOI: 10.6052/0459-1879-22-474
[3]	Shi Hemu, Zeng Xiaohui, Wu Han. ANALYTICAL SOLUTION OF THE HUNTING MOTION OF A WHEELSET NONLINEAR DYNAMICAL SYSTEM[J]. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(7): 1807-1819. DOI: 10.6052/0459-1879-22-003
[4]	Li Yansong, Chen Shougen. ANALYTICAL SOLUTION OF FROST HEAVING FORCE IN NON-CIRCULAR COLD REGION TUNNELS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2020, 52(1): 196-207. DOI: 10.6052/0459-1879-19-226
[5]	Jiang Zhongming, Li Jie. ANALYTICAL SOLUTIONS OF THE GENERALIZED PROBABILITY DENSITY EVOLUTION EQUATION OF THREE CLASSES STOCHASTIC SYSTEMS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2016, 48(2): 413-421. DOI: 10.6052/0459-1879-15-221
[6]	Kou Haijiang, Yuan Huiqun, Zhao Tianyu. ANALYTICAL SOLUTION FOR ROTATIONAL RUBBING PLATE UNDER THERMAL SHOCK[J]. Chinese Journal of Theoretical and Applied Mechanics, 2014, 46(6): 946-956. DOI: 10.6052/0459-1879-14-075
[7]	Yaochen Li, Feng Qi, Zheng Zhong. Simplified theory and analytical solutions for functionally graded piezoelectric circular plate[J]. Chinese Journal of Theoretical and Applied Mechanics, 2008, 40(5): 636-645. DOI: 10.6052/0459-1879-2008-5-2007-145
[8]	ANALYTICAL SOLUTION OF POINT ELASTIC IMPACT BETWEEN STRVCTURES[J]. Chinese Journal of Theoretical and Applied Mechanics, 1996, 28(1): 99-103. DOI: 10.6052/0459-1879-1996-1-1995-307
[9]	THE ANALYTICAL SOLUTION OF DIFFERENTIAL EQUATION OF ELASTIC CURVED SURFACE OF STEPPED THIN RECTANGULAR PLATE ON WINKLER'S FOUNDATION[J]. Chinese Journal of Theoretical and Applied Mechanics, 1992, 24(6): 754-762. DOI: 10.6052/0459-1879-1992-6-1995-800

Cited By

Cited by

Periodical cited type(1)

王永强，胡春宏，张鹏，杨胜发，胡江，李文杰. 三峡库区黄花城河段环流结构与涡尺度特征初探. 水科学进展. 2022(02): 253-263 .

Other cited types(6)

Get Citation

PDF

XML

Article Metrics

Article views (977) PDF downloads (93) Cited by(7)

THE LATERAL DISTRIBUTION OF DEPTH-AVERAGED VELOCITY IN CONSECUTIVE BENDS WITH POOL-POINT BAR

Abstract

References

Related Articles

Cited by

Periodical cited type(1)

Other cited types(6)

Catalog

Article Metrics

Related

Download Center

Author Center

THE LATERAL DISTRIBUTION OF DEPTH-AVERAGED VELOCITY IN CONSECUTIVE BENDS WITH POOL-POINT BAR

Abstract

References

Related Articles

Cited by

Periodical cited type(1)

Other cited types(6)

Catalog

Article Metrics

Related

Download Center

Author Center

Export File

Citation

Format

Content