2018
DOI: 10.1017/jfm.2018.109
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The impact of a deep-water plunging breaker on a wall with its bottom edge close to the mean water surface

Abstract: The impact of a deep-water plunging breaker on a finite height two-dimensional structure with a vertical front face is studied experimentally. The structure is located at a fixed horizontal position relative to a wave maker and the structure’s bottom surface is located at a range of vertical positions close to the undisturbed water surface. Measurements of the water surface profile history and the pressure distribution on the front surface of the structure are performed. As the vertical position, $z_{b}$ (the … Show more

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Cited by 9 publications
(12 citation statements)
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“…Throughout the breaking x f range, pressure oscillations following the second pressure maximum can be seen in figure 4. These oscillations become more pronounced from test 6 to test 20 and increase in frequency from 200 Hz to 600 Hz giving bubble radii of between 5.6 mm and 15.5 mm as calculated from (4.5) in Wang et al (2018). The three-dimensionality of these experiments allows air to escape along the sides of the boulder following bubble formation, possibly leading to faster oscillation decay than in vertical wall impact experiments (Bogaert et al 2010;Hattori et al 1994).…”
Section: Broken (Aerated) X F −06 Mmentioning
confidence: 94%
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“…Throughout the breaking x f range, pressure oscillations following the second pressure maximum can be seen in figure 4. These oscillations become more pronounced from test 6 to test 20 and increase in frequency from 200 Hz to 600 Hz giving bubble radii of between 5.6 mm and 15.5 mm as calculated from (4.5) in Wang et al (2018). The three-dimensionality of these experiments allows air to escape along the sides of the boulder following bubble formation, possibly leading to faster oscillation decay than in vertical wall impact experiments (Bogaert et al 2010;Hattori et al 1994).…”
Section: Broken (Aerated) X F −06 Mmentioning
confidence: 94%
“…Previous experiments on flip-through-type impacts have shown how maximum pressure values can be concentrated in very small areas (Lugni et al 2006;Wang et al 2018;Chan & Melville 1988;Cooker 2002). Throughout this experimental campaign, pressure on the boulder was measured at the boulder's front face via a single transducer with a 5.54 mm active area diameter.…”
Section: Pressure Measurement Limitationsmentioning
confidence: 99%
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“…Strong forces and very large accelerations can be produced as a sheet of water "flips through" the trough and generates a powerful upward jet of fluid. For discussion of the flip-through phenomenon and related experiments see [53,4,58].…”
Section: Background-scenarios For Singularitiesmentioning
confidence: 99%
“…Accuracy check. We checked the accuracy of the numerical scheme for a Dirichlet ellipse as described in section 5.2 above, with initial data for (58) given by…”
Section: Numerical Evidence For 2d Local Singularitiesmentioning
confidence: 99%