T. Kageyama scite author profile

In turbulent condensation with noncondensable gas, a thin noncondensable layer accumulates and generates a diffusional resistance to condensation and sensible heat transfer. By expressing the driving potential for mass transfer as a difference in saturation temperatures and using appropriate thermodynamic relationships, here an effective “condensation” thermal conductivity is derived. With this formulation, experimental results for vertical tubes and plates demonstrate that condensation obeys the heat and mass transfer analogy, when condensation and sensible heat transfer are considered simultaneously. The sum of the condensation and sensible heat transfer coefficients becomes infinite at small gas concentrations, and approaches the sensible heat transfer coefficient at large concentrations. The “condensation” thermal conductivity is easily applied to engineering analysis, and the theory further demonstrates that condensation on large vertical surfaces is independent of the surface height.

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Experimental 3-D Simulation of the Compression Wave, Due to Train–tunnel Entry

Bellenoue

Moriniere

Kageyama

2002

Journal of Fluids and Structures

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Direct measurement of laminar flame quenching distance in a closed vessel

Bellenoue

Kageyama

Labuda

et al. 2003

Experimental Thermal and Fluid Science

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Diffusion layer modeling for condensation in vertical tubes with noncondensable gases

Kageyama

Peterson

Schrock

1993

Nuclear Engineering and Design

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Experimental study of the unsteady aerodynamic field outside a tunnel during a train entry

Auvity

Bellenoue

Kageyama

2001

Experiments in Fluids

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Blind hood effects on the compression wave generated by a train entering a tunnel

Bellenoue

Auvity

Kageyama

2001

Experimental Thermal and Fluid Science

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Train/tunnel geometry effects on the compression wave generated by a high-speed train

Bellenoue

Kageyama

2002

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Reduced scale Simulation of the Compression wave Generated by the Entry of a High-Speed Train into a Tunnel

Bellenoue

Kageyama

2002

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T. Kageyama

Diffusion Layer Theory for Turbulent Vapor Condensation With Noncondensable Gases

Experimental 3-D Simulation of the Compression Wave, Due to Train–tunnel Entry

Direct measurement of laminar flame quenching distance in a closed vessel

Diffusion layer modeling for condensation in vertical tubes with noncondensable gases

Experimental study of the unsteady aerodynamic field outside a tunnel during a train entry

Blind hood effects on the compression wave generated by a train entering a tunnel

Train/tunnel geometry effects on the compression wave generated by a high-speed train

Reduced scale Simulation of the Compression wave Generated by the Entry of a High-Speed Train into a Tunnel

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