Numerical investigation of wall curvature effects on heat transfer and film cooling effectiveness

A. Shalchi-Tabrizi; M. Taiebi-Rahni; Gongnan Xie; Masoud Asadi

doi:10.1615/HeatTransRes.2016010264

Numerical investigation of wall curvature effects on heat transfer and film cooling effectiveness

A. Shalchi-Tabrizi, M. Taiebi-Rahni, Gongnan Xie, Masoud Asadi

School of Marine Science and Technology

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

Abstract

In this research, the problems of adiabatic film-cooling the flat, convex, and concave surfaces are investigated numerically. Two different radii of curvature and one row of vertical injection holes are considered. The Navier-Stokes equations are solved using a fine nonuniform multiblock staggered curvilinear grid and the SIMPLE-based finite volume method. The blowing rates are 0.5 and 1.0 and the mainstream Reynolds number is 10,000. The obtained results indicated that at a low blowing ratio, the cooling effectiveness enhances over the convex surface and reduces over the concave surface compared to the flat surface case. In comparison with the low blowing ratio, the curvature effects at a high blowing ratio seem to be less pronounced. At the high blowing ratio, the effectiveness is not greatly influenced by the surface curvature.

Original language	English
Pages (from-to)	559-574
Number of pages	16
Journal	Heat Transfer Research
Volume	47
Issue number	6
DOIs	https://doi.org/10.1615/HeatTransRes.2016010264
State	Published - 2016

Keywords

Concave surface
Convex surface
Cooling effectiveness
Flat plate
Numerical simulation
Wall curvature

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title = "Numerical investigation of wall curvature effects on heat transfer and film cooling effectiveness",

abstract = "In this research, the problems of adiabatic film-cooling the flat, convex, and concave surfaces are investigated numerically. Two different radii of curvature and one row of vertical injection holes are considered. The Navier-Stokes equations are solved using a fine nonuniform multiblock staggered curvilinear grid and the SIMPLE-based finite volume method. The blowing rates are 0.5 and 1.0 and the mainstream Reynolds number is 10,000. The obtained results indicated that at a low blowing ratio, the cooling effectiveness enhances over the convex surface and reduces over the concave surface compared to the flat surface case. In comparison with the low blowing ratio, the curvature effects at a high blowing ratio seem to be less pronounced. At the high blowing ratio, the effectiveness is not greatly influenced by the surface curvature.",

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AU - Shalchi-Tabrizi, A.

AU - Taiebi-Rahni, M.

AU - Xie, Gongnan

AU - Asadi, Masoud

PY - 2016

Y1 - 2016

N2 - In this research, the problems of adiabatic film-cooling the flat, convex, and concave surfaces are investigated numerically. Two different radii of curvature and one row of vertical injection holes are considered. The Navier-Stokes equations are solved using a fine nonuniform multiblock staggered curvilinear grid and the SIMPLE-based finite volume method. The blowing rates are 0.5 and 1.0 and the mainstream Reynolds number is 10,000. The obtained results indicated that at a low blowing ratio, the cooling effectiveness enhances over the convex surface and reduces over the concave surface compared to the flat surface case. In comparison with the low blowing ratio, the curvature effects at a high blowing ratio seem to be less pronounced. At the high blowing ratio, the effectiveness is not greatly influenced by the surface curvature.

AB - In this research, the problems of adiabatic film-cooling the flat, convex, and concave surfaces are investigated numerically. Two different radii of curvature and one row of vertical injection holes are considered. The Navier-Stokes equations are solved using a fine nonuniform multiblock staggered curvilinear grid and the SIMPLE-based finite volume method. The blowing rates are 0.5 and 1.0 and the mainstream Reynolds number is 10,000. The obtained results indicated that at a low blowing ratio, the cooling effectiveness enhances over the convex surface and reduces over the concave surface compared to the flat surface case. In comparison with the low blowing ratio, the curvature effects at a high blowing ratio seem to be less pronounced. At the high blowing ratio, the effectiveness is not greatly influenced by the surface curvature.

KW - Concave surface

KW - Convex surface

KW - Cooling effectiveness

KW - Flat plate

KW - Numerical simulation

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Numerical investigation of wall curvature effects on heat transfer and film cooling effectiveness

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