Simulations of Multiphase Particle Deposition on Endwall Film-Cooling Holes in Transverse Trenches

Lawson, Seth A.; Thole, Karen A.

doi:10.1115/1.4004756

Cited by 9 publications

(6 citation statements)

References 24 publications

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“…As discussed by Barigozzi et al [22] and Chen et al [23], the upstream deposition or ramp can uplift mainstream from the wall, and cause an area of low pressure behind the deposition or ramp, which can provide a separation cavity, which leads to coolant flow residing in the cavity. Therefore, the 6 Copyright © 2016 by ASME deposition model D1.5 can improve film cooling effect. These experimental phenomena obtained from the simplified model are in accord with previous researches carried out in real environment [5].…”

Section: Effect Of Surface Deposition (Without Hole-blockage)mentioning

confidence: 98%

“…Their results indicated that the cooling effectiveness is highest in the case that deposition only in the upstream of film hole and the other deposition models deteriorate film cooling performance. Using the accelerated deposition facility, Lawson et al [6] found that the film hole in a transverse trench can defense the deposition caused by impurities in the fuel, and the trench with 0.8 diameter depth can outperform others. The phenomenon was also found by Albert et al [7]in a turbine vane experiment.…”

Section: Introductionmentioning

confidence: 98%

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Combined Influence of Surface Deposition and Hole-Blockage on Film-Cooling Performances

Wang

Yuan

et al. 2016

Volume 5C: Heat Transfer

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Commercial aero-engines may operate in dust-laden environments, such as taking off and landing on desert ground or flying through volcano dust cloud, and foreign particles frequently deposit at hot surface and film hole-exits, which results in partial blockage of film holes, clog of cooling air, reduction in cooling effect, and could induce catastrophic damage. This problem has not been well solved up to now. This paper presents an experimental investigation on two surface deposition models (deposition limited to upstream of hole with a peak height of 1.5 diameter of hole called D1.5, and downstream forming a trench with a peak height of 1.0 diameter of hole, called D1) and two blockage models (leading edge of hole LB, and trailing edge TB), as well as two combined models D1.5-LB, and D1-TB. The experiments are conducted in a low speed water tunnel using Planar Laser Induced Fluorescence (PLIF) technique. Through this experiment, the following interesting phenomena, which were not reported in previous literatures, are reveled: 1) The effect of blockage ratio at leading edge on cooling performance of combined D1.5-LB is opposite to individual LB, i.e. in the case of combined D1.5-LB, a higher blockage ratio corresponds to a lower cooling effectiveness; whereas, for individual LB, the cooling effectiveness increases with the blockage ratios in the tested range. 2) At all blowing ratios, the cooling performances of combined D1.5-LB are better than that of perfect model D0-B0 (without deposition and blockage). At all blockage ratios tested in this experiment, in the case of combined D1.5-LB, a higher blowing ratio corresponds to a higher cooling effectiveness and a lager film coverage length. 3) At lower blockage ratios of 0.1 and 0.3, the overall-averaged cooling effectiveness of combined D1-TB is higher than that of perfect model D0-B0. At large blockage ratio 0.5, the blockage effect is dominant, and the averaged cooling effectiveness of combined model D1-TB is lower than that of D0-B0. In the case of individual deposition model D1-B0, although the lateral-averaged film cooling effectiveness is augmented, the area of film cooling is reduced.

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Section: Effect Of Surface Deposition (Without Hole-blockage)mentioning

confidence: 98%

Section: Introductionmentioning

confidence: 98%

Combined Influence of Surface Deposition and Hole-Blockage on Film-Cooling Performances

Wang

Yuan

et al. 2016

Volume 5C: Heat Transfer

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“…Two particle filters were located at the outlet of the flow channel. A clearer explanation of the experimental facility was shown in [45,46]. The wax was injected by using a wax particle generator to simulate the deposition process.…”

Section: Matching Of Actual Engine and Simulated Conditionsmentioning

confidence: 99%

A review of multiphase flow and deposition effects in film-cooled gas turbines

2018

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This paper presents a review of particle deposition research in film-cooled gas turbines based on the recent open literature. Factors affecting deposition capture efficiency and film cooling effectiveness are analyzed. Experimental studies are summarized into two discussions in actual and virtual deposition environments. For investigation in virtual deposition environments, available and reasonable results are obtained by comparison of the Stokes numbers. Recent advances in particle deposition modeling for computational fluid dynamics are also reviewed. Various turbulence models for numerical simulations are investigated, and solutions for treatment of the particle sticking probability are described. In addition, analysis of injecting mist into the coolant flow is conducted to investigate gas-liquid two-phase flow in gas turbines. The conclusion remains that considerable research is yet necessary to fully understand the roles of both deposition and multiphase flow in gas turbines.

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“…They reported that maximum cooling effectiveness can be obtained when the trench depth was = 0.8 ( is the trench depth and is the diameter of the cooling hole). However, Lawson and Thole [10] found different results, suggesting that this trench depth gives negative effect on the cooling performance downstream the cooling hole. Later, Lu et al [11] and Maikell et al [12] found that the trench depth of = 0.75 gave the optimum efficiency and it was validated by CFD studies.…”

Section: Introductionmentioning

confidence: 97%

The Effect of Blowing Ratio on Film Cooling Effectiveness Using Cylindrical and Row Trenched Cooling Holes with Alignment Angle of 90 Degrees

Azwadi

Kianpour

2014

Mathematical Problems in Engineering

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This paper presents the effects of blowing ratio on film cooling performance adjacent to the combustor endwall using cylindrical and row trenched cooling holes with alignment angle of 90 degrees. A three-dimensional representation of a Pratt and Whitney gas turbine engine was simulated and analysed using a commercial finite volume package FLUENT 6.2.26. The combustor simulator was designed to combine the interaction of two rows of dilution jets, which were staggered in the streamwise direction and aligned in the spanwise direction. As a result, the combustor with row trenched holes gave almost doubled cooling performance compared to the baseline case. In addition, the film cooling layer was increased at high blowing ratio, and thus it enhanced the cooling performance.

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Simulations of Multiphase Particle Deposition on Endwall Film-Cooling Holes in Transverse Trenches

Cited by 9 publications

References 24 publications

Combined Influence of Surface Deposition and Hole-Blockage on Film-Cooling Performances

Combined Influence of Surface Deposition and Hole-Blockage on Film-Cooling Performances

A review of multiphase flow and deposition effects in film-cooled gas turbines

The Effect of Blowing Ratio on Film Cooling Effectiveness Using Cylindrical and Row Trenched Cooling Holes with Alignment Angle of 90 Degrees

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