Analysis of interaction between ship bottom air cavity and boundary layer

Butuzov, 1990, Ship drag reduction by artificial gas cavities, Sudostroenie, n#11, 3

Amromin, 2011, Synergy of resistance reduction effects for a ship with bottom air cavity, ASME J Fluids Eng, 133, 021302, 10.1115/1.4003422

Gorbachev, 2015, Ships with air cavity: real method to enhance energy efficiency and ecological safety, Sea Fleet, n#1, 26

Sverchkov, 2010, Application of air cavities on high-speed ships in Russia

Amromin, 2015, Technologies of ship resistance reduction

Foeth, 2008, Decreasing of frictional resistance by air lubrication

Kopriva, 2008, Improvement of hydrofoil performance by partial ventilated cavitation in steady flow and periodic gusts, ASME J Fluids Eng, 130, 031301, 10.1115/1.2842147

Lay, 2010, Partial cavity drag reduction at high Reynolds numbers, J Ship Res, 54, 109, 10.5957/jsr.2010.54.2.109

Mäkiharju, 2013, On the scaling of air entrainment from a ventilated partial cavity, J Fluid Mech, 732, 47, 10.1017/jfm.2013.387

Zverkhovskyi, 2014, Experimental study on drag reduction by air cavities on a ship model

Butusov, 1966, Extreme parameters of vented cavity on the top surface of horizontal wall, Fluids Dyn, 1, 167

Choi, 2010, Numerical study on the behavior of air layers used for drag reduction

Arndt, 2009, Creation and maintenance of cavities under horizontal surfaces in steady and gust flows, ASME J Fluids Eng, 131, 111301, 10.1115/1.4000241

Kawakami, 2011, Investigation of the behavior of ventilated supercavities, ASME J Fluids Eng, 133, 091305, 10.1115/1.4004911

Kinzel, 2007, Computational investigation of air entrainment, hysteresis and loading for large-scale, buoyant cavities

Brewer, 1997, Experiment and viscous flow analysis on a partially cavitating hydrofoil, J Ship Res, 41, 161, 10.5957/jsr.1997.41.3.161

Amromin, 2002, Scale effect of cavitation inception on a 2D Eppler hydrofoil, ASME J Fluids Eng, 124, 186, 10.1115/1.1427689

Kubota, 1992, A new modeling of cavitating flows: a numerical study of unsteady cavitation of a hydrofoil section, J Fluid Mech, 240, 59, 10.1017/S002211209200003X

Reichardt, 1946, The law of cavitation bubbles at axially symmetric bodies in a flow, vol. 766

Amromin, 2007, Design of bodies with drag reduction by partial cavitation as an inverse ill-posed problem for velocity potential

Shiri, 2012, Hydrodynamics of a displacement air cavity ship

Knapp, 1970

Amromin, 2015, Ships with ventilated cavitation in seaways and active flow control, Appl Ocean Res, 50, 163, 10.1016/j.apor.2015.01.017

Faltisen, 2008, The effect of gravity and cavitation on a hydrofoil near the free surface, J Fluid Mech, 597, 371, 10.1017/S0022112007009822

Cebeci, 1984

Kieffer, 1977, Sound speed in liquid–gas mixtures, water–air and water–steam, J Geophys Res, 82, 2895, 10.1029/JB082i020p02895

Amromin, 2010, Microbubble drag reduction downstream of ventilated partial cavity, ASME J Fluids Eng, 132, 051302, 10.1115/1.4001489

Bourgoyne, 2005, Vortex shedding from a hydrofoil at high Reynolds number, J Fluid Mech, 531, 293, 10.1017/S0022112005004076

Kunz, 2006, Validation of two-fluid Eulerian CFD modeling for microbubble drag reduction across a wide range of Reynolds numbers, ASME J Fluids Eng, 129, 66, 10.1115/1.2375124

Elbing, 2013, On the scaling of air layer drag reduction, J Fluid Mech, 717, 484, 10.1017/jfm.2012.588

Kline, 1983, Correlation of the detachment of two-dimensional boundary layers, AIAA J, 21, 68, 10.2514/3.8029

Briley, 1976, Numerical prediction of incompressible separation bubbles, J Fluid Mech, 69, 631, 10.1017/S0022112075001607

Cebeci, 1986, Airfoils with separation and the resulting wakes, J Fluid Mech, 163, 323, 10.1017/S0022112086002318

Sanders, 2006, Bubble friction drag reduction in a high Reynolds number flat plate turbulent boundary layer, J Fluid Mech, 552, 353, 10.1017/S0022112006008688

Sato, 1997, Experimental study on friction reduction of a model ship by air lubrication, J Soc Naval Archit Jpn, 182, 121, 10.2534/jjasnaoe1968.1997.182_121

Gorbachev, 2015, Propulsion of displacement ships with the single bottom cavities, Sudostroenie, n#1, 17