Effect of Thermal Conductivity on Nozzle Guide Vane Internal Surface Temperature Distribution

Arun Kumar Pujari; B. V. S. S. S Prasad; Nekkanti Sitaram

doi:10.1515/tjj-2017-0061

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Effect of Thermal Conductivity on Nozzle Guide Vane Internal Surface Temperature Distribution

Arun Kumar Pujari , B. V. S. S. S Prasad und Nekkanti Sitaram

Veröffentlicht/Copyright: 17. Januar 2018

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Aus der Zeitschrift International Journal of Turbo & Jet-Engines Band 38 Heft 2

Abstract

Conjugate heat transfer analysis is carried out in a cascade domain for a nozzle guide vane. The nozzle guide vane is internally cooled by jet impingement cooling, and the external surface is cooled by film cooling. A computational study was carried out with three different materials, having conductivity values of 0.0048, 0.2 and 1.1 W/m.K. Distribution of local surface temperature along the leading edge, pressure and suction surface is reported. The leading edge region showed the maximum increase in internal surface temperature as the conductivity increased among the different regions of the vane internal surface. However, the pressure and suction surfaces showed relatively less increase in the surface temperature distribution. In order to validate the computational result, the obtained temperature data were compared with experimentally obtained surface temperature data. The flow phenomena like jet lift-off and self-induced cross-flow affect the local temperature distribution differently in the three materials. For a constant mainstream and coolant flow, the surface temperature gradient is higher for the lower conductivity material, and the gradient decreases as conductivity increases. Hence, a material with higher conductivity is desired in a combined impingement and film cooled nozzle guide vane, to increase the durability of the vane.

Keywords: impingement cooling; film cooling; nozzle guide vane; thermal conductivity; CFD

PACS: (Heat transfer: channel and internal, 44.15.+a)

Nomenclature

Bi: Biot number, non-dimensional [h.t/k]
C: Vane chord, m
d: Jet diameter, m
D: Coolant plenum diameter, m
h: Heat transfer coefficient, W/m²K
h_i: Heat transfer coefficient of internal surface, W/m²K
h_e: Heat transfer coefficient of external surface, W/m²K
H: Distance between jet hole and target surface, m
k: Thermal conductivity, W/m.K
l: Span length, m
M: Mass flow, kg/s
Nu: Nusselt number, non-dimensional
q″: Heat flux
Re: Reynolds number, non-dimensional
S: Distance along the vane surface from leading edge, m
S_p.max: Distance along pressure surface from leading edge to trailing edge, m
S_s.max: Distance along suction surface from leading edge to trailing edge, m
T: Temperature, K
t: Thickness of vane, m
V: Velocity
y⁺: Dimensionless wall distance
Z: Distance along the span

Greek Symbols

ρ: Density, kg/m³
κ: Turbulent kinetic energy, m²/s²
ω: Specific dissipation rate, 1/sec
μ: Coefficient of viscosity, N s/m²
φ: Overall effectiveness, (T_m-T_e)/(T_m-T_c)

Subscripts

amb: Ambient
c: Coolant
e: External
f: Fluid
i: Internal
m: Mainstream
s: Solid
w: Wall

Abbreviations

AIT: Aft Impingement Tube
DH: Hydraulic Diameter
FIT: Front Impingement Tube
HTC: Heat Transfer Coefficient
LER: Leading Edge Region
NDL: Non-Dimensional Length, (=S/S_s.max, S/S_pmax)
NDT: Non-Dimensional Temperature, θ
NGV: Nozzle Guide Vane
PSIH: Pressure Surface Impingement Hole
PSMS: Pressure Surface Mid-Span
RANS: Reynolds Averaged Navier Stokes
SSFR: Suction Surface Fillet Region
SSIH: Suction Surface Impingement Hole
SSMS: Suction Surface Mid-Span
SST: Shear Stress Transport

Acknowledgment

The authors would like to thank GATET and GTRE Bangalore for the financial support for the present investigation.

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Received: 2017-11-28

Accepted: 2017-12-28

Published Online: 2018-01-17

Published in Print: 2021-05-26

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Artikel in diesem Heft

https://doi.org/10.1515/tjj-2017-0061

Schlagwörter für diesen Artikel

impingement cooling; film cooling; nozzle guide vane; thermal conductivity; CFD