Non-Equilibrium Phenomena near Vapor-Liquid Interfaces
Kryukov, Alexei.
Non-Equilibrium Phenomena near Vapor-Liquid Interfaces [electronic resource] / by Alexei Kryukov, Vladimir Levashov, Yulia Puzina. - X, 54 p. 24 illus., 9 illus. in color. online resource. - SpringerBriefs in Applied Sciences and Technology, 2191-530X . - SpringerBriefs in Applied Sciences and Technology, .
Introduction -- Background for pure (one component) substance -- Evaporation and condensation of vapor-gas mixtures -- Motion of vapor-liquid interfaces -- Liquid - vapor interface form determination.
This book presents information on the development of a non-equilibrium approach to the study of heat and mass transfer problems using vapor-liquid interfaces, and demonstrates its application to a broad range of problems. In the process, the following peculiarities become apparent: 1. At vapor condensation on the interface from gas-vapor mixture, non-condensable components can lock up the interface surface and condensation stops completely. 2. At the evolution of vapor film on the heater in superfluid helium (He-II), the boiling mass flux density from the vapor-liquid interface is effectively zero at the macroscopic scale. 3. In problems concerning the motion of He-II bridges inside capillaries filled by vapor, in the presence of axial heat flux the He-II bridge cannot move from the heater as would a traditional liquid, but in the opposite direction instead. Thus the heater attracts the superfluid helium bridge. 4. The shape of liquid-vapor interface at film boiling on the axis-symmetric heaters immersed in liquid greatly depends on heat flux in the interface. Thus a new type of hydrostatic problems appears when in contrast to traditional statements the shape of the liquid-vapor interface has a complex profile with a point of inflection and a smooth exit on a free liquid surface.
9783319000831
10.1007/978-3-319-00083-1 doi
Engineering.
Hydraulic engineering.
Nuclear engineering.
Engineering.
Engineering Thermodynamics, Heat and Mass Transfer.
Nuclear Engineering.
Engineering Fluid Dynamics.
TJ265 QC319.8-338.5
621.4021
Non-Equilibrium Phenomena near Vapor-Liquid Interfaces [electronic resource] / by Alexei Kryukov, Vladimir Levashov, Yulia Puzina. - X, 54 p. 24 illus., 9 illus. in color. online resource. - SpringerBriefs in Applied Sciences and Technology, 2191-530X . - SpringerBriefs in Applied Sciences and Technology, .
Introduction -- Background for pure (one component) substance -- Evaporation and condensation of vapor-gas mixtures -- Motion of vapor-liquid interfaces -- Liquid - vapor interface form determination.
This book presents information on the development of a non-equilibrium approach to the study of heat and mass transfer problems using vapor-liquid interfaces, and demonstrates its application to a broad range of problems. In the process, the following peculiarities become apparent: 1. At vapor condensation on the interface from gas-vapor mixture, non-condensable components can lock up the interface surface and condensation stops completely. 2. At the evolution of vapor film on the heater in superfluid helium (He-II), the boiling mass flux density from the vapor-liquid interface is effectively zero at the macroscopic scale. 3. In problems concerning the motion of He-II bridges inside capillaries filled by vapor, in the presence of axial heat flux the He-II bridge cannot move from the heater as would a traditional liquid, but in the opposite direction instead. Thus the heater attracts the superfluid helium bridge. 4. The shape of liquid-vapor interface at film boiling on the axis-symmetric heaters immersed in liquid greatly depends on heat flux in the interface. Thus a new type of hydrostatic problems appears when in contrast to traditional statements the shape of the liquid-vapor interface has a complex profile with a point of inflection and a smooth exit on a free liquid surface.
9783319000831
10.1007/978-3-319-00083-1 doi
Engineering.
Hydraulic engineering.
Nuclear engineering.
Engineering.
Engineering Thermodynamics, Heat and Mass Transfer.
Nuclear Engineering.
Engineering Fluid Dynamics.
TJ265 QC319.8-338.5
621.4021