Experimental investigation of liquid film cooling in hypersonic flow

Abstract: ARTICLES YOU MAY BE INTERESTED INHigh-enthalpy models for boundary-layer stability and transition Physics of Fluids 31, 044101 (2019); https://doi.org/10.1063/1.5084235Numerical study of the shear-thinning effect on the interaction between a normal shock wave and a cylindrical liquid column Physics of Fluids 31, 043101 (2019); https://doi. ABSTRACTFilm cooling is generally considered as a promising active cooling technology for developing thermal protection systems of hypersonic vehicles; however, most of expe… Show more

“…Since the cusp is the origin of a ligament producing droplets downstream, the cusp volume approximately coincides with total droplet volume detaching from the cusp. We derive < as discussed later, thus, the cross-sectional area of the conical cusp corresponds to 2…”

“…of a thin liquid film extending on a wall exposed to a fast gas flow is a general thermo-fluid issue in many practical situations, such as film-cooling technology [1][2][3], icing on aircraft wings [4][5][6], and drying of paints and cleaning solutions [7]. Past and recent studies including quantitative measurements [5,[8][9][10][11][12][13][14][15] provide a scenario that the turbulent gas flows over the initially smooth film, soon drives the film with complex wavy structures by Kelvin-Helmholtz (KH) instability as a roll wave, accelerates the wave crests producing transverse wave by Rayleigh-Taylor (RT) instability as a ripple wave, stretches ligaments, and eventually entrains droplets disintegrated by Plateau-Rayleigh instability, all in a sequential fashion.…”

“…For a liquid rocket engine combustion chamber employing the film cooling technique [1,2,7,19,20], minimizing the coolant flow rate is desired to improve the performance of characteristic velocity and specific impulse [3,19,21] with achieving the sufficient heat resistance. Liquid fuel jets are often ejected on the inner surface of the combustion chamber in a bipropellant thruster below the critical pressure of propellants, followed by the propagating liquid film covering the wall.…”

Evaporation of Three-Dimensional Wavy Liquid Film Entrained by Turbulent Gas Flow

“…Since the cusp is the origin of a ligament producing droplets downstream, the cusp volume approximately coincides with total droplet volume detaching from the cusp. We derive < as discussed later, thus, the cross-sectional area of the conical cusp corresponds to 2…”

“…of a thin liquid film extending on a wall exposed to a fast gas flow is a general thermo-fluid issue in many practical situations, such as film-cooling technology [1][2][3], icing on aircraft wings [4][5][6], and drying of paints and cleaning solutions [7]. Past and recent studies including quantitative measurements [5,[8][9][10][11][12][13][14][15] provide a scenario that the turbulent gas flows over the initially smooth film, soon drives the film with complex wavy structures by Kelvin-Helmholtz (KH) instability as a roll wave, accelerates the wave crests producing transverse wave by Rayleigh-Taylor (RT) instability as a ripple wave, stretches ligaments, and eventually entrains droplets disintegrated by Plateau-Rayleigh instability, all in a sequential fashion.…”

“…For a liquid rocket engine combustion chamber employing the film cooling technique [1,2,7,19,20], minimizing the coolant flow rate is desired to improve the performance of characteristic velocity and specific impulse [3,19,21] with achieving the sufficient heat resistance. Liquid fuel jets are often ejected on the inner surface of the combustion chamber in a bipropellant thruster below the critical pressure of propellants, followed by the propagating liquid film covering the wall.…”

Evaporation of Three-Dimensional Wavy Liquid Film Entrained by Turbulent Gas Flow

Thermal performance of MMH/NTO rocket thrust chamber based on pintle injector by using liquid film cooling

Experimental and numerical study on liquid film cooling performance under heated wall condition