Jet impingement onto a conical cavity with elevated wall temperature

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

doi:10.1108/09615530410557423

Jet impingement onto a conical cavity with elevated wall temperature

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

^*Corresponding author for this work

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

12 Scopus citations

Abstract

Gas jet assisting process finds wide application in industry due to its ability to alter the heat transfer characteristics of the region subjected to jet assisted processing. In the present study, jet impingement onto a cavity with elevated wall temperature is considered. The flow and heat transfer equations are solved numerically using a control volume approach. Reynolds Stress Turbulence Model is employed to account for the turbulence. The simulations are repeated for four cavity depths and two gas jet velocities. It is found that the stagnation zone moves slightly further into the cavity with increasing cavity depth. The flow generated behind the stagnation zone in the cavity influences the heat transfer characteristics in this region, particularly for the cavities with relatively large depth.

Original language	English
Pages (from-to)	1011-1028
Number of pages	18
Journal	International Journal of Numerical Methods for Heat and Fluid Flow
Volume	14
Issue number	8
DOIs	https://doi.org/10.1108/09615530410557423
State	Published - 2004

Keywords

Flow
Heat transfer
Jets
Turbulence

ASJC Scopus subject areas

Computational Mechanics
Aerospace Engineering
Engineering (miscellaneous)
Mechanical Engineering

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10.1108/09615530410557423

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title = "Jet impingement onto a conical cavity with elevated wall temperature",

abstract = "Gas jet assisting process finds wide application in industry due to its ability to alter the heat transfer characteristics of the region subjected to jet assisted processing. In the present study, jet impingement onto a cavity with elevated wall temperature is considered. The flow and heat transfer equations are solved numerically using a control volume approach. Reynolds Stress Turbulence Model is employed to account for the turbulence. The simulations are repeated for four cavity depths and two gas jet velocities. It is found that the stagnation zone moves slightly further into the cavity with increasing cavity depth. The flow generated behind the stagnation zone in the cavity influences the heat transfer characteristics in this region, particularly for the cavities with relatively large depth.",

keywords = "Flow, Heat transfer, Jets, Turbulence",

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

year = "2004",

doi = "10.1108/09615530410557423",

language = "English",

volume = "14",

pages = "1011--1028",

journal = "International Journal of Numerical Methods for Heat and Fluid Flow",

issn = "0961-5539",

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TY - JOUR

T1 - Jet impingement onto a conical cavity with elevated wall temperature

AU - Yilbas, B. S.

AU - Shuja, S. Z.

AU - Budair, M. O.

PY - 2004

Y1 - 2004

N2 - Gas jet assisting process finds wide application in industry due to its ability to alter the heat transfer characteristics of the region subjected to jet assisted processing. In the present study, jet impingement onto a cavity with elevated wall temperature is considered. The flow and heat transfer equations are solved numerically using a control volume approach. Reynolds Stress Turbulence Model is employed to account for the turbulence. The simulations are repeated for four cavity depths and two gas jet velocities. It is found that the stagnation zone moves slightly further into the cavity with increasing cavity depth. The flow generated behind the stagnation zone in the cavity influences the heat transfer characteristics in this region, particularly for the cavities with relatively large depth.

AB - Gas jet assisting process finds wide application in industry due to its ability to alter the heat transfer characteristics of the region subjected to jet assisted processing. In the present study, jet impingement onto a cavity with elevated wall temperature is considered. The flow and heat transfer equations are solved numerically using a control volume approach. Reynolds Stress Turbulence Model is employed to account for the turbulence. The simulations are repeated for four cavity depths and two gas jet velocities. It is found that the stagnation zone moves slightly further into the cavity with increasing cavity depth. The flow generated behind the stagnation zone in the cavity influences the heat transfer characteristics in this region, particularly for the cavities with relatively large depth.

KW - Flow

KW - Heat transfer

KW - Jets

KW - Turbulence

UR - https://www.scopus.com/pages/publications/10444220170

U2 - 10.1108/09615530410557423

DO - 10.1108/09615530410557423

M3 - Article

AN - SCOPUS:10444220170

SN - 0961-5539

VL - 14

SP - 1011

EP - 1028

JO - International Journal of Numerical Methods for Heat and Fluid Flow

JF - International Journal of Numerical Methods for Heat and Fluid Flow

IS - 8

ER -

Jet impingement onto a conical cavity with elevated wall temperature

Abstract

Keywords

ASJC Scopus subject areas

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