Computational modeling for honeycomb-stator gas annular seal

G. Chochua; W. Shyy; J. Moore

doi:10.1016/S0017-9310(01)00280-0

Computational modeling for honeycomb-stator gas annular seal

G. Chochua, W. Shyy^*, J. Moore

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

39 Citations (Scopus)

Abstract

Gas annular seals are commonly adopted for leakage control in turbomachinery applications. Honeycomb seals are attractive from the viewpoints of leakage control as well as rotordynamic stability. To improve our understanding of thermo-fluid-physics in such seals, a computational capability is developed for low Mach number, compressible, turbulent flows. The emphases of the present study include (i) development of an original numerical scheme with periodic boundary conditions for flows around repeated geometries, (ii) evaluation of a low Reynolds number version of the k-ε turbulence model suitable for the operating conditions of honeycomb seals, and (iii) 3-D computations to assess the implications of the numerical predictions for practical configurations including velocity, pressure, temperature characteristics and loss mechanisms.

Original language	English
Pages (from-to)	1849-1863
Number of pages	15
Journal	International Journal of Heat and Mass Transfer
Volume	45
Issue number	9
DOIs	https://doi.org/10.1016/S0017-9310(01)00280-0
Publication status	Published - 4 Mar 2002
Externally published	Yes

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abstract = "Gas annular seals are commonly adopted for leakage control in turbomachinery applications. Honeycomb seals are attractive from the viewpoints of leakage control as well as rotordynamic stability. To improve our understanding of thermo-fluid-physics in such seals, a computational capability is developed for low Mach number, compressible, turbulent flows. The emphases of the present study include (i) development of an original numerical scheme with periodic boundary conditions for flows around repeated geometries, (ii) evaluation of a low Reynolds number version of the k-ε turbulence model suitable for the operating conditions of honeycomb seals, and (iii) 3-D computations to assess the implications of the numerical predictions for practical configurations including velocity, pressure, temperature characteristics and loss mechanisms.",

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AU - Shyy, W.

AU - Moore, J.

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N2 - Gas annular seals are commonly adopted for leakage control in turbomachinery applications. Honeycomb seals are attractive from the viewpoints of leakage control as well as rotordynamic stability. To improve our understanding of thermo-fluid-physics in such seals, a computational capability is developed for low Mach number, compressible, turbulent flows. The emphases of the present study include (i) development of an original numerical scheme with periodic boundary conditions for flows around repeated geometries, (ii) evaluation of a low Reynolds number version of the k-ε turbulence model suitable for the operating conditions of honeycomb seals, and (iii) 3-D computations to assess the implications of the numerical predictions for practical configurations including velocity, pressure, temperature characteristics and loss mechanisms.

AB - Gas annular seals are commonly adopted for leakage control in turbomachinery applications. Honeycomb seals are attractive from the viewpoints of leakage control as well as rotordynamic stability. To improve our understanding of thermo-fluid-physics in such seals, a computational capability is developed for low Mach number, compressible, turbulent flows. The emphases of the present study include (i) development of an original numerical scheme with periodic boundary conditions for flows around repeated geometries, (ii) evaluation of a low Reynolds number version of the k-ε turbulence model suitable for the operating conditions of honeycomb seals, and (iii) 3-D computations to assess the implications of the numerical predictions for practical configurations including velocity, pressure, temperature characteristics and loss mechanisms.

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UR - https://openalex.org/W2000671461

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DO - 10.1016/S0017-9310(01)00280-0

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EP - 1863

JO - International Journal of Heat and Mass Transfer

JF - International Journal of Heat and Mass Transfer

IS - 9

ER -

Computational modeling for honeycomb-stator gas annular seal

Abstract

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