Air Entrainment and Surface Fluctuations in a Turbulent Ship Hull Boundary Layer

Abstract: The air entrainment due to the turbulence in a free surface boundary layer shear flow created by a horizontally moving vertical surface-piercing wall is studied through experiments and direct numerical simulations.In the experiments, a laboratory-scale device was built that utilizes a surface-piercing stainless steel belt that travels in a loop around two vertical rollers, with one length of the belt between the rollers acting as a horizontally-moving flat wall. The belt is accelerated suddenly from rest until… Show more

“…Two distinct power-law scalings emerge in two size subranges in agreement with the measurements of Tavakolinejad (2010) and Masnadi et al. (2020), which builds further confidence in the results of this work (see also Castro, Li & Carrica 2016). The size distribution is reasonably described by a scaling at intermediate sizes, which is shallower than .…”

“…10 6 4 × 10 -3 1 × 10 -2 4 × 10 -2 1 × 10 -1 resolved sizes relative to figure 6(a) (by about 3-5 times; see also figure 15) suggests that there are more small and intermediate-sized bubbles at later times, and the break-up flux from larger sizes consistently outweighs mass loss from degassing. Two distinct power-law scalings emerge in two size subranges in agreement with the measurements of Tavakolinejad (2010) and Masnadi et al (2020), which builds further confidence in the results of this work (see also Castro, Li & Carrica 2016). The size distribution is reasonably described by a D −8/3 scaling at intermediate sizes, which is shallower than D −10/3 .…”

“…The dynamics of bubble break-up appears to be distinct in the early and late wave-breaking stages, suggesting the emergence of distinct bubble generation and evolution mechanisms. The size distribution was observed to deviate from the aforementioned D −10/3 power-law scaling by Deane & Stokes (2002), Tavakolinejad (2010) and Masnadi et al (2020) late in the wave-breaking process. Prior breaking-wave simulations either did not investigate the evolution of the ensemble-averaged size distribution as a function of time, or did not conclusively recover these alternative scalings in their ensemble-averaged size distribution in the late wave-breaking stages.…”

The turbulent bubble break-up cascade. Part 2. Numerical simulations of breaking waves

“…Two distinct power-law scalings emerge in two size subranges in agreement with the measurements of Tavakolinejad (2010) and Masnadi et al. (2020), which builds further confidence in the results of this work (see also Castro, Li & Carrica 2016). The size distribution is reasonably described by a scaling at intermediate sizes, which is shallower than .…”

“…10 6 4 × 10 -3 1 × 10 -2 4 × 10 -2 1 × 10 -1 resolved sizes relative to figure 6(a) (by about 3-5 times; see also figure 15) suggests that there are more small and intermediate-sized bubbles at later times, and the break-up flux from larger sizes consistently outweighs mass loss from degassing. Two distinct power-law scalings emerge in two size subranges in agreement with the measurements of Tavakolinejad (2010) and Masnadi et al (2020), which builds further confidence in the results of this work (see also Castro, Li & Carrica 2016). The size distribution is reasonably described by a D −8/3 scaling at intermediate sizes, which is shallower than D −10/3 .…”

“…The dynamics of bubble break-up appears to be distinct in the early and late wave-breaking stages, suggesting the emergence of distinct bubble generation and evolution mechanisms. The size distribution was observed to deviate from the aforementioned D −10/3 power-law scaling by Deane & Stokes (2002), Tavakolinejad (2010) and Masnadi et al (2020) late in the wave-breaking process. Prior breaking-wave simulations either did not investigate the evolution of the ensemble-averaged size distribution as a function of time, or did not conclusively recover these alternative scalings in their ensemble-averaged size distribution in the late wave-breaking stages.…”

The turbulent bubble break-up cascade. Part 2. Numerical simulations of breaking waves

“…As the values in table 4 represent long time averages of entrainment, turbulent breakup and buoyancy, a value β > −10/3 is expected. The slopes in table 4 are consistent with the experiments of a turbulent entraining ship hull boundary layer (β = −4.36) where multiple physical effects, including entrainment, buoyancy and turbulence, are present (Masnadi et al 2018).…”

“…The slopes in table 4 are consistent with the experiments of a turbulent entraining ship hull boundary layer ( ) where multiple physical effects, including entrainment, buoyancy and turbulence, are present (Masnadi et al. 2018).…”

Wake behind a three-dimensional dry transom stern. Part 1. Flow structure and large-scale air entrainment

The Effects of Froude Number on a Turbulent Boundary Layer with a Free-Surface