Non-dispersive and weakly dispersive single-layer flow over an axisymmetric obstacle: the equivalent aerofoil formulation

Esler, J. G.; Rump, O. J.; Johnson, E. R.

doi:10.1017/s0022112006003910

Cited by 10 publications

(16 citation statements)

References 34 publications

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“…Fig. 9 highlights the increase of energy transferred to gravity waves around the critical regime F r = 1 or equivalently Γ = 0, as it is found in the case of a single layer flow from the consideration of the wave drag [11]. Moreover, there exists a range of Γ for which the value of the potential energy is significantly increased which can be associated with the transcritical regime.…”

Section: Wake Analysismentioning

confidence: 67%

“…A fourth parameter, Γ = (F r − 1)M −2/3 , emerges from a previous study in the case of a single layer flow [11] and is known as the transcritical similarity parameter. The range of parameters 1 As obstacles are towed upside-down, they cannot be fully immersed, so effective h 0 m is slightly smaller than the values given above and is 7.5 cm (resp.…”

Section: Experimental Set-upmentioning

confidence: 99%

“…Moreover, there exists a range of Γ for which the value of the potential energy is significantly increased which can be associated with the transcritical regime. This specific regime delimited by the subcritical regime and supercritical regime has been mostly studied in the case of single layer flows [11]. In the set of experiments considered here, it it is difficult to quantitatively delineate the different regimes.…”

Section: Wake Analysismentioning

confidence: 99%

“…1). These experiments were inspired by recent theoretical works [16,17,11] predicting the wave structure in similar flows where dispersive effects dominate over dissipative effects, as in many geophysical situations. Under certain conditions, for example when the flow speed is close to the gravity waves speed, these results lead to different predictions than previous work in the non-dispersive limit (e.g.…”

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Wave patterns generated by an axisymmetric obstacle in a two-layer flow

et al. 2013

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Section: Wake Analysismentioning

confidence: 67%

Section: Experimental Set-upmentioning

confidence: 99%

Section: Wake Analysismentioning

confidence: 99%

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Wave patterns generated by an axisymmetric obstacle in a two-layer flow

et al. 2013

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“…Swimming speed, however, is often much higher than c′, ranging from 0.75 m·s −1 for recreational up to 2 m·s −1 for competitive swimmers (Toussaint and Truijens 2005). This discrepancy in speeds makes it unlikely that the swimmer's body, seen as a displacement hull, experiences additional drag by generating interfacial waves, due to lack of coupling (Esler et al 2007). This might explain the absence of any measurable effect in a genuine swimming pool experiment, where the upper layer was less than 0.40 m (Maas and van Haren 2006), despite the fact that the swimmer's body (chest depth approximately 0.3 m (Vennell et al 2006)) was well within the 0.7-m distance over which a surface or interface might be disturbed by a moving object in its vicinity (Vennell et al 2006;Costill et al 1992).…”

Section: Introductionmentioning

confidence: 99%

Swimming obstructed by dead-water

Ganzevles

Nuland

Maas

et al. 2008

Naturwissenschaften

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In nautical literature, 'dead-water' refers to the obstructive effect encountered by ships moving in stratified water due to the ship generating waves on an interface that separates different water masses. To investigate the hypothesis that open water swimming may also be obstructed by an encounter of dead-water, possibly causing drowning, we performed two experiments that assess the impact of stratified water on swimming. In the first experiment, subjects made a single front-crawl stroke while lying on a carriage that was rolling just above the water surface. The gain in kinetic energy, as a result of the stroke, was far less in stratified than in homogeneous water. In the second experiment, four subjects swam a short distance (5 m) in homogeneous and in two different settings of stratified water. At the same stroke frequency, swimming in stratified conditions was slower by 15%, implying a loss in propulsive power by 40%. Although in nature stratification will be less strong, extrapolation of the results suggests that dead-water might indeed obstruct swimming in open water as well. This effect will be most pronounced during fair weather, when stratification of a shallow surface layer is most easily established. Our findings indicate that swimmers' anecdotal evidence on 'water behaving strangely' may have to be taken more seriously than previously thought.

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Drag associated with 3D trapped lee waves over an axisymmetric obstacle in two‐layer atmospheres

Teixeira

Miranda

2017

Quart J Royal Meteoro Soc

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Mountain‐wave drag is evaluated explicitly using linear theory and verified against numerical simulations for the flow of idealized two‐layer atmospheres with piecewise‐constant stratification over an axisymmetric mountain. Static stability is either higher in the bottom layer and lower in the top layer (Scorer's atmosphere) or neutral in the bottom layer and positive in the top layer, separated by a sharp temperature inversion (Vosper's atmosphere). The drag receives contributions from long mountain waves propagating vertically in the upper layer and from short trapped lee waves propagating downstream, either in the lower layer or at the inversion. This trapped lee‐wave drag, which is typically not represented in parametrizations, acts on the atmosphere at low levels. As in flow over a 2D ridge, this drag has several maxima as a function of the height of the interface between the two layers for Scorer's atmosphere and is maximized by a marked Scorer parameter contrast between those layers. In Vosper's atmosphere, there is a single trapped lee‐wave drag maximum for Froude numbers near one, when the wind speed matches the phase speed of the dominant interfacial waves, and this drag is maximized for relatively low interface elevations, for which waves at the inversion have higher amplitude. The 3D flow geometry allows resonant wave modes to have various horizontal orientations and a continuous spectrum, forming a dispersive ‘Kelvin ship wave’ pattern, and expanding the regions in parameter space where the drag is non‐zero relative to 2D flow, but it also decreases the drag magnitude dispersively. Nevertheless, the trapped lee‐wave drag on an axisymmetric obstacle can still equal or exceed the drag associated with vertically propagating waves and the reference hydrostatic drag valid for a uniformly stratified atmosphere.

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Non-dispersive and weakly dispersive single-layer flow over an axisymmetric obstacle: the equivalent aerofoil formulation

Cited by 10 publications

References 34 publications

Wave patterns generated by an axisymmetric obstacle in a two-layer flow

Wave patterns generated by an axisymmetric obstacle in a two-layer flow

Swimming obstructed by dead-water

Drag associated with 3D trapped lee waves over an axisymmetric obstacle in two‐layer atmospheres

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