Effects of Inlet Turbulence Conditions and Near-wall Treatment Methods on Heat Transfer Prediction over Gas Turbine Vanes

Bak, Jeong-Gyu; Lee, Seawook; Kang, Young Seok

doi:10.5139/ijass.2016.17.1.8

Cited by 6 publications

(2 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Some thermodynamic and fluid properties of the air are given as follows: (i) specific heat capacity at constant pressure = 1006.43 J/kgK, (ii) thermal conductivity = 0.0242 W/mK, and (iii) dynamic viscosity = 1.7894×10 -5 kg/ms. Since the flow over the vane surface is turbulent, the SST k- turbulence model [9] from the FLUENT solver is selected as this turbulence model can predict reasonable results for the flow field [10][11][12]. The maximum Y+ is lower than 4.5, which is acceptable for using the SST k- model.…”

Section: Computational Approachmentioning

confidence: 99%

Numerical Study on Flow Physics of Damaged Vane Trailing Edge

Thammachote,

Premyothin,

Khumhaeng

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

According to practical applications in gas turbines, the turbine’s nozzle guide vane (NGV) is the first downstream component of the combustor that experiences high thermal loads from burned gases. This situation can severely damage the vane material, particularly the trailing edge (TE). This is because of the limitation of TE thickness and the difficulty of effective cooling in that region. Moreover, the deterioration of the TE surface leads to vane fatalities and has a negative impact on turbine performance because the flow field is unfavorably changed during the operation. This paper aims to numerically study the flow physics of a damaged vane TE using a 3D steady-flow CFD simulation with the SST k-turbulence model. Under the assumptions of ideal gas and compressible flow, air is used as the burned gas. To simplify the vane damage shape, the broken pattern at the TE is given in a long cutback geometry in the simulation. Numerical results in terms of turbulent kinetic energy (TKE), vorticity magnitude, turbulent viscosity, and streamlines are compared and discussed. The interesting findings show that with the inclusion of the damaged TE, the TKE and turbulent viscosity in the broken region increase dramatically on both the midspan and vertical planes. Furthermore, an increment in the vortex size is observed on the midspan plane. However, the vortex centers along the broken region disappear and are replaced by smooth streamlines.

show abstract

Section: Computational Approachmentioning

confidence: 99%

Numerical Study on Flow Physics of Damaged Vane Trailing Edge

Thammachote,

Premyothin,

Khumhaeng

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

show abstract

“…It has been proved that the location, cross-section and mass flow rate of the cooling arrangements are highly influential on the temperature distribution in the vane [18]. Other studies have included thermal barrier coating, the effects of turbulence intensity and material selection [19,20]. Recent developments have suggested replacing compressed air with steam because of its superior heat transfer capabilities.…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation of a Radially Cooled Turbine Guide Vane Using Air and Steam as a Cooling Medium

Norheim

Amzin

2021

Computation

View full text Add to dashboard Cite

Gas turbine performance is closely linked to the turbine inlet temperature, which is limited by the turbine guide vanes ability to withstand the massive thermal loads. Thus, steam cooling has been introduced as an advanced cooling technology to improve the efficiency of modern high-temperature gas turbines. This study compares the cooling performance of compressed air and steam in the renowned radially cooled NASA C3X turbine guide vane, using a numerical model. The conjugate heat transfer (CHT) model is based on the RANS-method, where the shear stress transport (SST) k−ω model is selected to predict the effects of turbulence. The numerical model is validated against experimental pressure and temperature distributions at the external surface of the vane. The results are in good agreement with the experimental data, with an average error of 1.39% and 3.78%, respectively. By comparing the two coolants, steam is confirmed as the superior cooling medium. The disparity between the coolants increases along the axial direction of the vane, and the total volume average temperature difference is 30 K. Further investigations are recommended to deal with the local hot-spots located near the leading- and trailing edge of the vane.

show abstract