A laboratory study of wave crest statistics and the role of directional spreading

Latheef, M. A.; Swan, Chris

doi:10.1098/rspa.2012.0696

Cited by 43 publications

(65 citation statements)

References 51 publications

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“…If the water surface is steep, but not sufficiently steep, the impact will be replaced by very large run-up velocities. Although recent research [28] has shown that large incident sea states will be steeper than is commonly predicted, with a higher than expected occurrence of wave breaking, this alone is not sufficient to explain the occurrence of wave impacts on the columns of some offshore structures. Indeed, both field observation and extensive model testing have shown that columns that are large, but not so large that they lie in the linear diffractions regime, are particularly susceptible to both wave impacts and large run-up velocities.…”

Section: Wave Steepness Wave-wave Interactions and Practical Implicamentioning

confidence: 92%

The interaction between steep waves and a surface-piercing column

Swan

Sheikh

2015

Phil. Trans. R. Soc. A.

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Experimental observations are presented of a single surface-piercing column subject to a wide range of surface gravity waves. With the column diameter, D , chosen such that the flow lies within the drag-inertia regime, two types of high-frequency wave scattering are identified. The first is driven by the run-up and wash-down on the surface of the column in the vicinity of the upstream and downstream stagnation points. The second concerns the circulation of fluid around the column, leading to the scattering of a pair of non-concentric wavefronts. The phasing of the wave cycle at which this second mode evolves is dependent upon the time taken for fluid to move around the column. This introduces an additional time-scale, explaining why existing diffraction solutions, based upon a harmonic analysis of the incident waves, cannot describe this scattered component. The interaction between the scattered waves and the next (steep) incident wave can produce a large amplification of the scattered waves, particularly the second type. Evidence is provided to show that these interactions can produce highly localized free-surface effects, including vertical jetting, with important implications for the setting of deck elevations, the occurrence of wave slamming and the development of large run-up velocities.

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Section: Wave Steepness Wave-wave Interactions and Practical Implicamentioning

confidence: 92%

The interaction between steep waves and a surface-piercing column

Swan

Sheikh

2015

Phil. Trans. R. Soc. A.

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“…In this study, the appropriate weighting is based upon a normal distribution with a standard deviation of σ θ in accordance with the directional distribution outlined in equation (2.8). This method was previously adopted in [26,27] and formed the basis of the earlier laboratory study outlined in [6]. Given that this study is specifically concerned with the directionality of the sea state, the merits of these approaches need to be carefully considered.…”

Section: Directional Wave Generationmentioning

confidence: 99%

“…Indeed, this study concerns a subset of four of these sea states, the details of which are given in table 2. The original data, full details of which are given in [6], concern time-histories of the water surface elevation, η ( t ), recorded over the working area of the wave basin. This study uses η ( t ) data recorded at one representative position, located 4.75 m downstream of the wave paddles.…”

Section: Experimental Procedures and Test Casesmentioning

confidence: 99%

“…In all cases, the random wave data, incorporating η ( t ), u ( t ) and v ( t ), were based upon 20 × 3 h simulations. Once again, the 3 h duration represents the equivalent ‘full-scale’ value based upon the scaling noted below and each simulation (or seed) involves a different set of random phases, amplitudes and directions; further details of the generated data are given in [6]. …”

Section: Experimental Procedures and Test Casesmentioning

confidence: 99%

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A laboratory study of nonlinear changes in the directionality of extreme seas

2017

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This paper concerns the description of surface water waves, specifically nonlinear changes in the directionality. Supporting calculations are provided to establish the best method of directional wave generation, the preferred method of directional analysis and the inputs on which such a method should be based. These calculations show that a random directional method, in which the phasing, amplitude and direction of propagation of individual wave components are chosen randomly, has benefits in achieving the required ergodicity. In terms of analysis procedures, the extended maximum entropy principle, with inputs based upon vector quantities, produces the best description of directionality. With laboratory data describing the water surface elevation and the two horizontal velocity components at a single point, several steep sea states are considered. The results confirm that, as the steepness of a sea state increases, the overall directionality of the sea state reduces. More importantly, it is also shown that the largest waves become less spread or more unidirectional than the sea state as a whole. This provides an important link to earlier descriptions of deterministic wave groups produced by frequency focusing, helps to explain recent field observations and has important practical implications for the design of marine structures and vessels.

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“…Beforehand, it can be argued that the effect of the Benjamin-Feir instability may be very mild, because the value of k D = 1.6 of the sea is just above the critical value 1.36, and the spreading is wide which could reduce the steepness as observed in extensive laboratory experiments of Latheef and Swan (2013). The steepness, which, for unidirectional waves, would give k Hs/2 = 0.14, turns out to be much larger, up to a factor 5, in the simulations near high crests.…”

Section: Introductionmentioning

confidence: 99%

High waves in Draupner seas—Part 1: numerical simulations and characterization of the seas

Groesen

Turnip²,

Kurnia

2017

J. Ocean Eng. Mar. Energy

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Extreme waves are studied in numerical simulations of the so-called Draupner seas that resemble the wave situation near the observation area of the Draupner wave, an iconic example of a freak, rogue wave. Recent new meteorological insights describe these seas as a substantial wind-generated wave system accompanied by two low-frequency lobes. With the significant wave height H s = 12 m above a depth of 70 m and the wide directional spreading over 120 • as design information, results are presented of simulations of phase resolved waves. Quantitative data are derived from 8000 waves over an area of 15 km 2 . Very high waves with crest heights exceeding 1.5 H s occur in average in 20 min timespan over an area of 0.8 km 2 . Details will be given for an isolated freak wave and a sequence of 3 freak crest heights in a group of 2 high waves. In Part 2, van Groesen and Wijaya (J Ocean Eng Mar Energy, 2017), it will be shown that 60 s before their appearance freak waves can be predicted from radar images on board of a ship that scans the surrounding area over a distance of 2 km.

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A laboratory study of wave crest statistics and the role of directional spreading

Cited by 43 publications

References 51 publications

The interaction between steep waves and a surface-piercing column

The interaction between steep waves and a surface-piercing column

A laboratory study of nonlinear changes in the directionality of extreme seas

High waves in Draupner seas—Part 1: numerical simulations and characterization of the seas

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