LSPIV Measurements of Two‐Dimensional Flow Structure in Streams Using Small Unmanned Aerial Systems: 2. Hydrodynamic Mapping at River Confluences

Lewis, Quinn W.; Rhoads, Bruce L.

doi:10.1029/2018wr022551

Cited by 54 publications

(43 citation statements)

References 53 publications

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“…As flow moves downstream, the separate high‐velocity cores of the incoming flows quickly merge into a single core. A region of flow separation develops along the left bank (right side of the cross section) downstream of a large bank protrusion on this side of the confluence (Figure 2; see also Lewis & Rhoads, 2018b). The pattern of secondary‐flow vectors reveals that pronounced counterclockwise helical motion develops over the middle part of the downstream channel in conjunction with curvature of flow from the Saline into the confluence.…”

Section: Resultsmentioning

confidence: 97%

“…More measurements of mixing rates and patterns at particular confluences over a suite of flow conditions are needed, and studies that assess mixing at numerous confluences are also recommended. Because of the difficulty in measuring detailed cross‐sectional velocities, studies that assess mixing at many confluences may benefit from remote sensing and noncontact methods to determines patterns of flow and mixing, at least at the surface (Biron et al, 2019; Lewis & Rhoads, 2018a, 2018b). However, as this study has shown mixing can be highly three‐dimensional, especially when influenced by helical motion of the flow.…”

Section: Discussionmentioning

confidence: 99%

“…As the name suggests, the mixing interface is an important hydrodynamic feature related to lateral mixing at confluences. Turbulence within this interface is generated by lateral shear associated with differences in velocity between the two flows (Babarutsi & Chu, 1998; Guillén Ludeña et al, 2017; Sukhodolov & Rhoads, 2001; Sukhodolov & Sukhodolova, 2019; van Prooijen & Uijttewaal, 2002) and by shedding of vortices from interacting shear layers that bound the stagnation zone (Lewis & Rhoads, 2018b). Large velocity differences between the incoming flows result in Kelvin‐Helmholtz (KH) instability and the generation of co‐ (co‐ rotating)rotating vertically oriented vortices within the mixing interface (KH mode) (Constantinescu, 2014; Rogers & Moser, 1992; Sukhodolov & Rhoads, 2001).…”

Section: Theoretical Background: Lateral Mixing In Rivers and At Confmentioning

confidence: 99%

See 2 more Smart Citations

Advective Lateral Transport of Streamwise Momentum Governs Mixing at Small River Confluences

Lewis

Rhoads

Sukhodolov

et al. 2020

Water Resources Research

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Confluences are important sites for mixing within river networks. Past work has shown that mixing within confluences is highly variable; in some cases flows mix rapidly and in other cases flows remain unmixed far downstream of the confluence. The fluvial processes that govern mixing within confluences remain poorly understood. This study relates patterns and amounts of mixing to three-dimensional flow structure at three small confluences. It focuses on lateral fluxes of streamwise momentum, which theoretical considerations suggest should influence lateral mixing. Patterns and amounts of mixing differ at the three sites. Considerable mixing occurs at an asymmetrical confluence with strong helical motion within flow from the lateral tributary, which produces substantial differences in advective lateral transport of streamwise momentum over depth. Minor mixing occurs at a comparatively symmetrical confluence where incoming flows have relatively equal momentum fluxes; however, helical motion within one of the flows locally increases mixing. At a symmetrical confluence where one incoming flow has much greater momentum flux than the other, mixing occurs largely through progressive lateral shifting of the mixing interface toward the minor tributary because of the strong lateral flux of streamwise momentum by the dominant tributary. At all three confluences, lateral turbulent transport of streamwise momentum is an order of magnitude less than advective lateral transport of streamwise momentum. The study indicates that generalization of mixing at confluences remains challenging but that advective lateral fluxes of streamwise momentum related to secondary currents (helical motion) or primary flow (cross currents) greatly enhance mixing at confluences.

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Section: Resultsmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Section: Theoretical Background: Lateral Mixing In Rivers and At Confmentioning

confidence: 99%

See 1 more Smart Citation

Advective Lateral Transport of Streamwise Momentum Governs Mixing at Small River Confluences

Lewis

Rhoads

Sukhodolov

et al. 2020

Water Resources Research

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“…A quantitative assessment of the LSPIV results provides insight into limiting factors of both sUAS and fixed systems, while examples and analyses of flow structure at river confluences demonstrate the utility of the method in highly complex flows. A companion study explores high‐resolution hydrodynamic mapping at river confluences, using results from this paper, to fundamentally improve understanding of these regions of complex 2‐D flow (Lewis & Rhoads, ). The results of this study help to better inform the value of LSPIV as a tool for measuring complex patterns of river flow in the field.…”

Section: Introductionmentioning

confidence: 99%

LSPIV Measurements of Two‐Dimensional Flow Structure in Streams Using Small Unmanned Aerial Systems: 1. Accuracy Assessment Based on Comparison With Stationary Camera Platforms and In‐Stream Velocity Measurements

Lewis

Rhoads

2018

Water Resources Research

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Measuring two‐dimensional (2‐D) patterns of flow in rivers at high resolution over large areas is challenging using traditional velocity‐measurement methods, which provide data at specific locations or cross sections. Large‐scale particle image velocimetry (LSPIV) based on imagery obtained from fixed camera platforms can measure flow velocity on the surface of rivers and is generally accurate compared to near‐surface velocity measurements obtained by traditional methods. The proliferation of inexpensive small unmanned aerial systems (sUAS) equipped with high‐resolution cameras and onboard GPS has the potential to facilitate measurements of flow patterns in rivers using LSPIV, but few studies have assessed the accuracy of sUAS‐derived LSPIV compared to fixed‐platform LSPIV and in‐stream velocity measurements. This study assesses the accuracy of sUAS‐based LSPIV for measuring 2‐D mean surface velocities as well as quasi‐instantaneous 2‐D velocities obtained from successive image frames. For persistent 2‐D flow, mean velocities derived from sUAS‐based LSPIV match those obtained by stationary camera platforms, and velocities measured by both LSPIV methods agree with near‐surface velocities measured by an acoustic Doppler velocimeter. Quasi‐instantaneous velocities are degraded by camera movement and low pixel resolution, but capturing the evolution of 2‐D flow structures is possible in certain circumstances. The results confirm that sUAS‐derived LSPIV provides accurate, high‐resolution measurements of mean surface velocities over large spatial areas of persistent 2‐D flow and can characterize evolving 2‐D flow structures under favorable conditions. sUAS‐based LSPIV is a valuable new method for mapping of 2‐D patterns of surface flow in rivers—an issue explored in a companion paper.

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“…The height of the flume walls was 40 cm. Different widths were employed for the upstream and downstream channels to mimic the channel expansion in recent confluence field studies (Biron et al, 2002; Boyer et al, 2006; Imhoff & Wilcox, 2016; Rhoads et al, 2009; Rhoads & Sukhodolov, 2001; Rhoads & Sukhodolov, 2008; Riley et al, 2015; Riley & Rhoads, 2012; Lewis & Rhoads, 2018; Sukhodolov et al, 2017; Sukhodolov & Sukhodolova, 2019). Two stacked tube grids were set behind the outlets of the upstream tanks in order to minimize the turbulence at the outlets.…”

Section: Methodsmentioning

confidence: 99%

Experiments on the Morphodynamics of Open Channel Confluences: Implications for the Accumulation of Contaminated Sediments

Yuan

Rennie

2020

JGR Earth Surface

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Contaminated sediments are common in river networks. The flow convergence and particular flow structures in confluences, such as the flow separation zone, may result in greater accumulation of contaminated sediments than in other river locations, but this issue is rarely studied. In addition, the contaminated sediment transport is driven by the particular morphodynamics occurring at confluences. This article describes a novel confluence flume experiment on both morphodynamics and deposition patterns of contaminated sediments as a function of geometric and flow conditions. The initial equilibrium bed geometry was developed from a mobile bed and then fixed, allowing for subsequent flow velocimetry and sediment feeding. Colored sediments of fine gradation, which mimic contaminated sediments, were then fed to the tributary channel. The results suggest that the junction angle primarily determines the confluence bed morphology and sediment transport pattern while the discharge ratio is a secondary factor. It was also observed that most introduced sediments tended to deposit immediately after the cessation of feeding at the stoss of the bar in the flow separation zone. The time history of the transport of the contaminated sediments was also investigated. Sediment that initially deposited at the stoss of the bar eventually moved to the lee of the bar and deposited around the bar downstream of the confluence, demonstrating that the sedimentation pattern evolved to a state similar to the equilibrium bed morphology. Plain Language Summary This article describes a novel confluence flume experiment on the bed form and contaminated sediment transport patterns. The initial bed state was developed from a flat mobile bed until stable and was then fixed for flow field measurements and sediment feeding. Dyed sediments of fine sizes, representing contaminated sediments, were fed to the tributary channel. Variables including confluence junction angle, flow discharge ratio between tributary and mean channel, and sediment feeding location were all considered and investigated. It was observed that the confluence junction angle primarily determines the bed form and sediment transport pattern, while the discharge ratio is a secondary factor. The contaminated sediment deposition pattern tended to evolve to a state that is similar to the initial bed state. This study improves understanding of confluence bed form evolution and water quality maintenance in confluences. Confluences are characterized by complex hydrodynamics associated with particular morphological structures. Based on those defined by Best (1987) and Best and Rhoads (2008), the general hydrodynamic and morphological components in confluences can be summarized as follows, with numbers indicating labels in Figure 1: ① Flow stagnation zone, where the local velocity of the fluid is close to zero (Best, 1988).

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LSPIV Measurements of Two‐Dimensional Flow Structure in Streams Using Small Unmanned Aerial Systems: 2. Hydrodynamic Mapping at River Confluences

Cited by 54 publications

References 53 publications

Advective Lateral Transport of Streamwise Momentum Governs Mixing at Small River Confluences

Advective Lateral Transport of Streamwise Momentum Governs Mixing at Small River Confluences

LSPIV Measurements of Two‐Dimensional Flow Structure in Streams Using Small Unmanned Aerial Systems: 1. Accuracy Assessment Based on Comparison With Stationary Camera Platforms and In‐Stream Velocity Measurements

Experiments on the Morphodynamics of Open Channel Confluences: Implications for the Accumulation of Contaminated Sediments

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