Backmixing in a cylindrical confined jet.

Moeller, Wolf Gunter.

January 1968

No description available.

Jets -- Fluid dynamics

Engineering, General.

Electrical dispersion of liquids.

Wynn, Nyunt.

January 1969

No description available.

Jets -- Fluid dynamics

Suspensions (Chemistry)

Prediction of flow and heat transfer under a laminar swirling impinging jet

Huang, Bing

January 1977

Note:

Jets -- Fluid dynamics.

Heat -- Transmission.

An experimental and theoretical study of the interaction of an electrostatic field with a two-dimensional jet flow.

Kaveh, Farrokh

January 1981

No description available.

Engineering

Electrostatics

Jets--Fluid dynamics

Visual studies of jets injected into a turbulent boundary layer

Lee, Hoi-yuen, Louis, 李海源

January 1977

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Jets - Fluid dynamics.

Turbulent boundary layer.

An experimental and numerical investigation of a turbulent round jet issuing into an unsteady crossflow

夏麗萍, Xia, Liping.

January 1998

published_or_final_version / Civil Engineering / Doctoral / Doctor of Philosophy

Unsteady flow (Aerodynamics)

Jets - Fluid dynamics.

Flow development in the initial region of a submerged round jet in a moving environment

Or, Chun-ming., 柯雋銘.

January 2009

published_or_final_version / Civil Engineering / Master / Master of Philosophy

Jets - Fluid dynamics.

Fluid dynamic measurements.

Three-dimensional turbulent axisymmetric, wall and surface jets originating from circular orifices.

Tjio, Hok-kie.

January 1971

No description available.

Jets -- Fluid dynamics.

Turbulence.

Anemometer.

Hydrodynamics.

Under-expanding sonic jet discharging from a cylindrical concave wall

Elabdin, Mohamed Nabil Mohamed Zein.

January 1975

No description available.

Jet nozzles.

Engineering, General.

Jets -- Fluid dynamics.

Effects of orifice geometry and surface boundary condition on heat transfer of impinging jet array

Kanokjaruvijit, Koonlaya.

16 February 2000

The effects of the orifice geometry and the surface boundary condition on the heat transfer distribution to a flat surface of an impinging jet array were investigated. The jet array impinged normally onto the surface which was either isothermal or had a uniform heat flux. The experiments were performed for the flow rate range from 0.0039 to 0.0070 m��/s corresponding to jet Reynolds numbers of 5000 to 11000. The jet-to-surface spacings varied from 1 to 4 jet diameters. After impinging, the air jet was constraine4 to exit in one direction creating a "crossflow". condition. The isothermal surface results are presented in terms of the average heat transfer coefficient. For the uniform heat flux surface, both average and local values are presented. The average and local heat transfer distributions were mapped using thermochromic liquid crystals. Results are presented for two jet geometries: circular and cusped ellipse. The cusped ellipse jets show better heat transfer performance compared to the circular jets for both surface boundary conditions. This is thought to be a result of increased turbulence and the axis-switching phenomenon. Results for the uniform heat flux surface boundary higher than for the isothermal surface boundary condition. This result can be explained by the difference between the surface temperature and the jet temperature for both surface boundary conditions. Correlations of Nusselt versus Reynolds numbers are presented for both jet geometries and surface boundary conditions. / Graduation date: 2000

Jets -- Fluid dynamics

Heat -- Transmission

Gas-turbines