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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 6/2018

01.03.2018 | Original Article

A mathematical model on depth-averagedβ-factor in open-channel turbulent flow

verfasst von: Punit Jain, Manotosh Kumbhakar, Koeli Ghoshal

Erschienen in: Environmental Earth Sciences | Ausgabe 6/2018

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Abstract

The well-known Rouse equation is the most widely used equation to determine the vertical distribution of suspended sediment concentration in an open-channel flow. The exponent of Rouse equation, known as Rouse number, contains the parameter β defined by the ratio of sediment diffusion coefficient to turbulent diffusion coefficient. As such to measure sediment concentration accurately, an appropriate expression for β is essentially needed. The present study, therefore, focuses on the derivation of depth-averaged β through modified expressions of sediment and turbulent diffusion coefficients. A regression analysis is done to establish the relation between β and normalized settling velocity, and the relation is used to determine suspension concentration.
Vorheriger Artikel Hydrogeochemical characterization and suitability appraisal of groundwater around stone quarries in Mahendragarh, India
Nächster Artikel Assessment of groundwater quality for drinking and irrigation purposes using hydrochemical studies in Nalbari district of Assam, India

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Literatur
Absi R (2010) Concentration profiles for fine and coarse sediments suspended by waves over ripples: an analytical study with the 1-DV gradient diffusion model. Adv Water Resour 33(4):411–418CrossRef
Absi R (2011) An ordinary differential equation for velocity distribution and dip-phenomenon in open channel flows. J Hydraul Eng 49(1):82–89CrossRef
Cellino M, Graf W (1999) Sediment-laden flow in open-channels under noncapacity and capacity conditions. J Hydraul Eng 125(5):455–462CrossRef
Cheng N-S (1997) Simplified settling velocity formula for sediment particle. J Hydraul Eng 123(2):149–152CrossRef
Cheng P, Zhu H, Zhong B, Wang D (2015) Transport mechanisms of contaminants released from fine sediment in rivers. Acta Mech Sin 31(6):791–798CrossRef
Chien N (1956) The present status of research on sediment transport. Trans Am Soc Civ Eng 121(1):833–868
Coleman NL (1970) Flume studies of the sediment transfer coefficient. Water Resour Res 6(3):801–809CrossRef
Coleman NL (1981) Velocity profiles with suspended sediment. J Hydraul Eng 19(3):211–229CrossRef
Coleman NL (1986) Effects of suspended sediment on the open-channel velocity distribution. Water Resour Res 22(10):1377–1384CrossRef
Fick A (1855) V. On liquid diffusion. Philos Mag Ser 4 10(63):30–39CrossRef
Graf WH (1984) Hydraulics of sediment transport. Water Resources Publication, Littleton
Graf W, Cellino M (2002) Suspension flows in open channels; experimental study. J Hydraul Eng 40(4):435–447CrossRef
Hongwei F (1996) The study on three-dimensional mathematical model of river bed erosion for water-sediment two-phase flow. Acta Mech Sin 12(1):85–91CrossRef
Hsu TW, Jan CD (1998) Calibration of Businger-Arya type of eddy viscosity model’s parameters. J Waterway Port Coastal Ocean Eng 124(5):281–284CrossRef
Imamoto H (1988) Measurement of secondary flow in an open channel. In: Proceedings of 6th IAHR-APD Congress, Kyoto, Japan
Kinoshita R (1967) An analysis of the movement of flood waters by aerial photography. J Jpn Soc Photogramm 6(1):1–17CrossRef
Kirkgöz MS (1989) Turbulent velocity profiles for smooth and rough open channel flow. J Hydraul Eng 115(11):1543–1561CrossRef
Kironoto B, Yulistiyanto B (2009) The validity of rouse equation for predicting suspended sediment concentration profiles in transversal direction of uniform open channel flow. In: International conference on sustainable development for water and waste water treatment, Yogyakarta
Kundu S, Ghoshal K (2012) An analytical model for velocity distribution and dip-phenomenon in uniform open channel flows. Int J Fluid Mech Res 39(5):13CrossRef
Lyn D (1988) A similarity approach to turbulent sediment-laden flows in open channels. J Fluid Mech 193:1–26CrossRef
Majumdar H, Carstens MR (1967) Diffusion of particles by turbulence: Effect of particle size. Water Resources Center, Georgia Inst Technol Rep WRC-0967, Dec 1967. 102 p, 12 fig, 12 tab, 19 ref. FWPCA Grant 5 R 01 WP 00912-02 ESE
Mazumder B, Ghoshal K, Dalal D (2005) Influence of bed roughness on sediment suspension: experimental and theoretical studies. J Hydraul Eng 43(3):245–257CrossRef
Montes V (1973) Interaction of two dimensional turbulent flow with suspended particles. Ph.D. thesis, Massachusetts Institute of Technology, Cambridge
Nezu I (2002) Open-channel turbulence and its research prospect in the new century. In: Proc. 13th IAHRAPD Cong., pp 8
Nezu I, Rodi W (1986) Open-channel flow measurements with a laser doppler anemometer. J Hydraul Eng 112(5):335–355CrossRef
Nielsen P, Teakle IA (2004) Turbulent diffusion of momentum and suspended particles: a finite-mixing-length theory. Phys Fluids 16(7):2342–2348CrossRef
Pal D, Ghoshal K (2014) Effect of bed roughness on grain-size distribution in an open channel flow. J Hydro Environ Res 8(4):441–451CrossRef
Pal D, Ghoshal K (2016) Effect of particle concentration on sediment and turbulent diffusion coefficients in open-channel turbulent flow. Environ Earth Sci 18(75):1–11
Prandtl L (1932) Recent results of turbulence research. Technical Memorandum 720, National Advisory Committee for Aeronautics
Rouse H (1937) Modern conceptions of the mechanics of turbulence. Trans ASCE 102:463–543
Tsai CT, Tsai CH, Weng CH, Bair JJ, Chen CN (2010) Calculation of bed load based on the measured data of suspended load. Paddy Water Environ 8(4):371–384CrossRef
Van Rijn L (1984) Sediment transport, part II: suspend load transport. J Hydraul Eng ASCE 1104(11):16131641
Vanoni VA (1946) Transportation of suspended sediment by water. Trans ASCE 111:67–102
Wren D, Bennett S, Barkdoll B, Kuhnle R (2005) Distributions of velocity, turbulence, and suspended sediment over low-relief antidunes. J Hydraul Eng 43(1):3–11CrossRef
Wu P, Jin Y (2010) Parameters used in modeling sediment-laden flow in open channels. In: Environmental Hydraulics, Two Volume Set: Proceedings of the 6th International Symposium on Environmental Hydraulics, Athens, Greece, 23–25 June 2010. CRC Press, London, p 265
Xinyu L, Changzhi C, Zengnan D (1995) Turbulent flows in smooth-wall open channels with different slope. J Hydraul Eng 33(3):333–347CrossRef
Yang SQ (2005) Interactions of boundary shear stress, secondary currents and velocity. Fluid Dyn Res 36(3):121–136CrossRef
Yang SQ, Tan SK, Lim SY (2004) Velocity distribution and dip-phenomenon in smooth uniform open channel flows. J Hydraul Eng 130(12):1179–1186CrossRef
Zhu HW, Cheng PD, Li W, Chen JH, Pang Y, Wang DZ (2017) Empirical model for estimating vertical concentration profiles of re-suspended, sediment-associated contaminants. Acta Mech Sin 33(5):846–854CrossRef
Metadaten
Titel
A mathematical model on depth-averagedβ-factor in open-channel turbulent flow
verfasst von
Punit Jain
Manotosh Kumbhakar
Koeli Ghoshal
Publikationsdatum
01.03.2018
Verlag
Springer Berlin Heidelberg
Erschienen in
Environmental Earth Sciences / Ausgabe 6/2018
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-018-7428-0

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