V. Velidandla scite author profile

V. Velidandla

5Publications

51Citation Statements Received

0Citation Statements Given

How they've been cited

186

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Affiliations

KLA (United States), Arizona State University, Global Engineering and Materials (United States)

Publications

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Local Measurements in the Two-Phase Region of Turbulent Subcooled Boiling Flow

Roy

Velidandla

Kalra

et al. 1994

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Local measurements of vapor phase residence time fraction, vapor bubble size distribution, bubble axial velocity, and vapor and liquid temperatures were performed in turbulent boiling flow of Refrigerant-113. The dissolved air content of the experimental fluid was minimized. Data are reported for three wall heat fluxes, two fluid mass velocities, and three subcoolings at test section inlet. Local time-averaged interfacial area concentrations were estimated. The measuring devices, viz., dual-sensor fiber-optic probe for the vapor bubble measurements and phase-compensated chromel-alumel microthermocouple for the fluid temperature measurement, provided more complete and accurate data compared with our earlier work. The data should be helpful in the development and validation of multidimensional turbulent boiling flow models. Further work is needed, however, before the local interfacial area concentration can be determined with confidence.

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Velocity Field in Turbulent Subcooled Boiling Flow

Roy

Velidandla

Kalra

1997

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The velocity field was measured in turbulent subcooled boiling flow of Refrigerant-113 through a vertical annular channel whose inner wall was heated. A two-component laser Doppler velocimeter was used. Measurements are reported in the boiling layer adjacent to the inner wall as well as in the outer all-liquid layer for two fluid mass velocities and four wall heat fluxes. The turbulence was found to be inhomogeneous and anisotropic and the turbulent kinetic energy significantly higher than in single-phase liquid flow at the same mass velocity. A marked shift toward the inner wall was observed of the zero location of the axial Reynolds shear stress in the liquid phase, and the magnitude of the shear stress increased sharply close to the inner wall. The near-wall liquid velocity field was quite different from that in single-phase liquid flow at a similar Reynolds number. Comparison of the measurements with the predictions of a three-dimensional two-fluid model of turbulent subcooled boiling flow show reasonably good agreement for some quantities and a need for further development of certain aspects of the model.

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Untitled

Pit

Marchon

Meeks³

et al. 2001

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Texture process monitoring in solar cell manufacturing using optical metrology

Velidandla¹,

Xu²,

Hou³

et al. 2011

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Turbulent velocity field in isothermal and heated liquid flow through a vertical annular channel

Velidandla

Putta

Roy

1996

International Journal of Heat and Mass Transfer

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V. Velidandla

Local Measurements in the Two-Phase Region of Turbulent Subcooled Boiling Flow

Velocity Field in Turbulent Subcooled Boiling Flow

Untitled

Texture process monitoring in solar cell manufacturing using optical metrology

Turbulent velocity field in isothermal and heated liquid flow through a vertical annular channel

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