Hydraulic jumps and breaking bores: modelling and analysis

Wang, Hang; Leng, Xinqian; Chanson, Hubert

doi:10.1680/jencm.16.00025

Cited by 9 publications

(10 citation statements)

References 35 publications

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“…mass flux direction (STOKER 1957, TRICKER 1965. Herein the air-water flow structures tended to be similar to gas-liquid structures observed in breaking hydraulic jumps (CHANSON 2011b, CHACHEREAU and CHANSON 2011, WANG et al 2017) and in the upper region of high-speed self-aerated flows (CAIN andWOOD 1981, CHANSON 1997a,b).…”

Section: Air-water Flow Patternsmentioning

confidence: 58%

“…It was shown that the entrapped air can be compressed, and resulting pressure shock waves can contribute to some substantial impact on structures (BREDMOSE et al 2009). The air entrainment in breaking bores has not been investigated to date, except for a few preliminary works (CHANSON 2009a,2016b, LENG and CHANSON 2015a, and a limited analogy with stationary hydraulic jumps (CHANSON 2009b, WANG et al 2017. CHANSON (2009aCHANSON ( ,2016b studied the atmospheric noise of breaking tidal bores, linking the low pitch sound of the advancing bore to a dominant frequency of collective oscillations of bubble clouds in the bore roller.…”

Section: Introductionmentioning

confidence: 99%

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Air-water interaction and characteristics in breaking bores

Leng

Chanson

2019

International Journal of Multiphase Flow

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A tidal bore is an unsteady rapidly-varied open channel flow characterised by a rise in water surface elevation in estuarine zones, under spring tidal conditions. After formation, the bore is traditionally analysed as a hydraulic jump in translation and its leading edge is characterised by a breaking roller for Froude number Fr1 > 1.3-1.5. The roller is a key flow feature characterised by intense turbulence and air bubble entrainment. Detailed unsteady air-water flow measurements were conducted in a breaking bore propagating in a large-size channel, using an array of three dual-tip phase detection probes and photographic camera. The data showed a relatively steep roller, with a short and dynamic bubbly flow region. Air entrainment took place in the form of air entrapment at the roller toe, air-water exchange across the roller 'free-surface', spray and splashing with dynamic water drop ejection and re-attachment, roll up and roll down of water 'tongues' engulfing air pockets. The roller free-surface profile and characteristics were comparable to observations in stationary hydraulic jumps and steady breaker, for similar flow conditions. Within the roller, the amount of entrained air was quantitatively small for Froude number Fr1 = 2.2. The number of air bubbles was limited, with between 5 to 20 bubbles per phase-detection probe sensor detected at each vertical elevation.The entrained air bubble chord lengths spanned over several orders of magnitude, with a large proportion of clustered bubbles. Overall, the study highlighted the three-dimensional nature of the air-water roller motion and strong evidence of the in-homogeneity of the turbulent air-water mixture.

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Section: Air-water Flow Patternsmentioning

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Air-water interaction and characteristics in breaking bores

Leng

Chanson

2019

International Journal of Multiphase Flow

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“…The fluctuations in bore celerity are large in both transverse and longitudinal directions, with ratio of standard deviation to mean value greater than unity. The bore roller toe perimeter constantly fluctuates with time and space, so it is not a straight line (CHANSON, 2016;WANG et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

CFD modeling of tidal bores: development and validation challenges

Leng

Simon

Khezri

et al. 2018

Coastal Engineering Journal

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A tidal bore is a natural estuarine phenomenon forming a positive surge in a funnel shaped river mouth during the early flood tide under spring tide conditions and low freshwater levels. The bore propagates upstream into the lower estuarine zone and its passage may induce some enhanced turbulent mixing, with upstream advection of suspended material. Herein the flow field and turbulence characteristics of tidal bores were measured using both numerical (CFD) and physical modelling. This joint modelling approach, combined with some theoretical knowledge, led to some new understanding of turbulent velocity field, turbulent mixing process, Reynolds stress tensor, and tidal bore hydrodynamics. The numerical CFD tool Thétis was used herein. Thétis is a CFD model using the volume of fluid technique (VOF) to model the free-surface and Large Eddy Simulation technique (LES) for the turbulence modelling. Physical data sets were used to map the velocity and pressure field and resolve some unusual feature of the unsteady flow motion. A discussion will be provided to explain why a detailed validation process is crucial, involving a physical knowledge of the flow. Comparison of the numerical model results and experimental data over broad ranges of conditions for the same flow is mandatory. The validation process from 2D to 3D will be commented and difficulties will be highlighted.

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“…The second full-length paper (Wang et al, 2017) is devoted to bores and hydraulic jumps. Sketched by Leonardo da Vinci (Clark and Pedretti, 1968), observed in nature and utilised by engineers for a century, it might be thought that the hydraulic jump had yielded all its secrets some time ago.…”

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confidence: 99%

“…://dx.doi.org/10.1680/jencm.2017.170.1.1 ICE Publishing: All rights reserved most complete investigations of the average jump profile and length, Mossa andTolve (1998), Mossa (1999)), the research on this transition flow and its related flow motions, such as tidal bore or surge, is still relevant, as shown by Wang et al (2017) in their interesting paper. In fact, the authors show that the flow structure in the roller remains a great research challenge due to large quantities of entrained air, bubble turbulence interactions and the coupling between turbulent properties and free surface deformations.…”

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confidence: 99%

Editorial

Mossa¹

2017

Proceedings of the Institution of Civil Engineers - Engineering

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Hydraulic jumps and breaking bores: modelling and analysis

Cited by 9 publications

References 35 publications

Air-water interaction and characteristics in breaking bores

Air-water interaction and characteristics in breaking bores

CFD modeling of tidal bores: development and validation challenges

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