Jet impingement onto a cylindrical cavity: Consideration of annular nozzle cone angles, and cavity diameter

S. Z. Shuja; B. S. Yilbas; M. O. Budair

doi:10.1080/10618560500532631

Jet impingement onto a cylindrical cavity: Consideration of annular nozzle cone angles, and cavity diameter

S. Z. Shuja
, B. S. Yilbas^*
, M. O. Budair

^*Corresponding author for this work

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

7 Scopus citations

Abstract

In the present study, gas jet emerging from an annular nozzle and impinging onto a cylindrical cavity is considered. The geometric configuration of the nozzle is varied in the simulations. Air is used as impinging gas while stainless steel is considered as workpiece material. Reynolds turbulence model is accommodated to account for the turbulence. A numerical scheme employing a control volume approach is used to simulate the flow field. Heat transfer characteristic and shear stress distribution around the cavity are computed. It is found that outer cone angle of the annular nozzle influences the heat transfer rates from the cavity wall. The flow structure around the cavity changes significantly with increasing cavity diameter. Moreover, increasing cavity depth results in stagnation zone moving into the cavity.

Original language	English
Pages (from-to)	483-492
Number of pages	10
Journal	International Journal of Computational Fluid Dynamics
Volume	19
Issue number	7
DOIs	https://doi.org/10.1080/10618560500532631
State	Published - Oct 2005

Keywords

Annular nozzle
Cavity
Heat transfer
Jet impingement

ASJC Scopus subject areas

Computational Mechanics
Aerospace Engineering
Condensed Matter Physics
Energy Engineering and Power Technology
Mechanics of Materials
Mechanical Engineering

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10.1080/10618560500532631

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title = "Jet impingement onto a cylindrical cavity: Consideration of annular nozzle cone angles, and cavity diameter",

abstract = "In the present study, gas jet emerging from an annular nozzle and impinging onto a cylindrical cavity is considered. The geometric configuration of the nozzle is varied in the simulations. Air is used as impinging gas while stainless steel is considered as workpiece material. Reynolds turbulence model is accommodated to account for the turbulence. A numerical scheme employing a control volume approach is used to simulate the flow field. Heat transfer characteristic and shear stress distribution around the cavity are computed. It is found that outer cone angle of the annular nozzle influences the heat transfer rates from the cavity wall. The flow structure around the cavity changes significantly with increasing cavity diameter. Moreover, increasing cavity depth results in stagnation zone moving into the cavity.",

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author = "Shuja, \{S. Z.\} and Yilbas, \{B. S.\} and Budair, \{M. O.\}",

year = "2005",

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language = "English",

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pages = "483--492",

journal = "International Journal of Computational Fluid Dynamics",

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T2 - Consideration of annular nozzle cone angles, and cavity diameter

AU - Shuja, S. Z.

AU - Yilbas, B. S.

AU - Budair, M. O.

PY - 2005/10

Y1 - 2005/10

N2 - In the present study, gas jet emerging from an annular nozzle and impinging onto a cylindrical cavity is considered. The geometric configuration of the nozzle is varied in the simulations. Air is used as impinging gas while stainless steel is considered as workpiece material. Reynolds turbulence model is accommodated to account for the turbulence. A numerical scheme employing a control volume approach is used to simulate the flow field. Heat transfer characteristic and shear stress distribution around the cavity are computed. It is found that outer cone angle of the annular nozzle influences the heat transfer rates from the cavity wall. The flow structure around the cavity changes significantly with increasing cavity diameter. Moreover, increasing cavity depth results in stagnation zone moving into the cavity.

AB - In the present study, gas jet emerging from an annular nozzle and impinging onto a cylindrical cavity is considered. The geometric configuration of the nozzle is varied in the simulations. Air is used as impinging gas while stainless steel is considered as workpiece material. Reynolds turbulence model is accommodated to account for the turbulence. A numerical scheme employing a control volume approach is used to simulate the flow field. Heat transfer characteristic and shear stress distribution around the cavity are computed. It is found that outer cone angle of the annular nozzle influences the heat transfer rates from the cavity wall. The flow structure around the cavity changes significantly with increasing cavity diameter. Moreover, increasing cavity depth results in stagnation zone moving into the cavity.

KW - Annular nozzle

KW - Cavity

KW - Heat transfer

KW - Jet impingement

UR - https://www.scopus.com/pages/publications/33645158072

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DO - 10.1080/10618560500532631

M3 - Article

AN - SCOPUS:33645158072

SN - 1061-8562

VL - 19

SP - 483

EP - 492

JO - International Journal of Computational Fluid Dynamics

JF - International Journal of Computational Fluid Dynamics

IS - 7

ER -

Jet impingement onto a cylindrical cavity: Consideration of annular nozzle cone angles, and cavity diameter

Abstract

Keywords

ASJC Scopus subject areas

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