Numerical Study of on Cooling Performance for Multi-holes Steam Jet in the Internal Channel of a Hollow Turbine Blade

Abstract To investigate the application of ribbed cross-flow coolant channels with film hole effusion and the effects of the internal cooling configuration on film cooling, experimental and numerical studies are conducted on the effect of the relative position of the film holes and different orientation ribs on the film cooling performance. Three cases of the relative position of the film holes and different orientation ribs (post-rib, centered, and pre-rib) in two ribbed cross-flow channels (135° and 45° orientation ribs) are investigated. The film cooling performances are measured under three blowing ratios by the transient liquid crystal measurement technique. A RANS simulation with the realizable k-ε turbulence model and enhanced wall treatment is performed. The results show that the cooling effectiveness and the downstream heat transfer coefficient for the 135° rib are basically the same in the three position cases, and the differences between the local effectiveness average values for the three are no more than 0.04. The differences between the heat transfer coefficients are no more than 0.1. The “pre-rib” and “centered” cases are studied for the 45° rib, and the position of the structures has little effect on the film cooling performance. In the different position cases, the outlet velocity distribution of the film holes, the jet pattern and the discharge coefficient are consistent with the variation in the cross flow. The related research previously published by the authors showed that the inclination of the ribs with respect to the holes affects the film cooling performance. This study reveals that the relative positions of the ribs and holes have little effect on the film cooling performance. This paper expands and improves the study of the effect of the internal cooling configuration on film cooling and makes a significant contribution to the design and industrial application of the internal cooling channel of a turbine blade.

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Investigation of a Rotor Blade With Tip Cooling Subject to a Nonuniform Temperature Profile

Journal of Turbomachinery ◽

10.1115/1.4050332 ◽

2021 ◽

Vol 143 (7) ◽

Author(s):

Harika S. Kahveci

Keyword(s):

Temperature Profile ◽

Turbine Blade ◽

Numerical Study ◽

Turbine Rotor ◽

Inlet Temperature ◽

Pressure Side ◽

Engine Operation ◽

Pressure Losses ◽

Blade Tip ◽

Temperature Levels

Abstract One of the challenges in the design of a high-pressure turbine blade is that a considerable amount of cooling is required so that the blade can survive high temperature levels during engine operation. Another challenge is that the addition of cooling should not adversely affect blade aerodynamic performance. The typical flat tips used in designs have evolved into squealer form that implements rims on the tip, which has been reported in several studies to achieve better heat transfer characteristics as well as to decrease pressure losses at the tip. This paper demonstrates a numerical study focusing on a squealer turbine blade tip that is operating in a turbine environment matching the typical design ratios of pressure, temperature, and coolant blowing. The blades rotate at a realistic rpm and are subjected to a turbine rotor inlet temperature profile that has a nonuniform shape. For comparison, a uniform profile is also considered as it is typically used in computational studies for simplicity. The effect of tip cooling is investigated by implementing seven holes on the tip near the blade pressure side. Results confirm that the temperature profile nonuniformity and the addition of cooling are the drivers for loss generation, and they further increase losses when combined. Temperature profile migration is not pronounced with a uniform profile but shows distinct features with a nonuniform profile for which hot gas migration toward the blade pressure side is observed. The blade tip also receives higher coolant coverage when subject to the nonuniform profile.

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A CFD-Based Parametric Study on Modification of Discrete Sister Holes Location for the Film Cooling Flow

Volume 5B: Heat Transfer ◽

10.1115/gt2014-25970 ◽

2014 ◽

Author(s):

Siavash Khajehhasani ◽

Bassam Jubran

Keyword(s):

Film Cooling ◽

Numerical Study ◽

Three Dimensional ◽

Navier Stokes ◽

Base Case ◽

Spanwise Direction ◽

Cooling Performance ◽

Cooling Flow ◽

Lift Off ◽

The Individual

A numerical study on the effects of sister holes locations on film cooling performance is presented. This includes the change of the location of the individual discrete sister holes in the streamwise and spanwise directions, where each one of these directions includes 9 different locations, The simulations are performed using three-dimensional Reynolds-Averaged Navier Stokes analysis with the realizable k–ε model combined with the standard wall function. The variation of the sister holes in the streamwise direction provides similar film cooling performance as the base case for both blowing ratios of 0.5 and 1. On the other hand, the spanwise variation of the sister holes’ location has a more prominent effect on the effectiveness. In some cases, as a result of the anti-vortices generated from the sister holes and the repositioning of the sister holes in the spanwise direction, the jet lift-off effect notably decreases and more volume of coolant is distributed in the spanwise direction.

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Experimental Study of the Effects of an Oscillating Approach Flow on Overall Cooling Performance of a Simulated Turbine Blade Leading Edge

Volume 3: Heat Transfer, Parts A and B ◽

10.1115/gt2009-60290 ◽

2009 ◽

Cited By ~ 6

Author(s):

Ross Johnson ◽

Jonathan Maikell ◽

David Bogard ◽

Justin Piggush ◽

Atul Kohli ◽

...

Keyword(s):

Turbine Blade ◽

Film Cooling ◽

Density Ratio ◽

Leading Edge ◽

Stagnation Line ◽

Cooling Performance ◽

Blowing Ratio ◽

Oscillation Frequencies ◽

Overall Effectiveness ◽

Blade Leading Edge

When a turbine blade passes through wakes from upstream vanes it is subjected to an oscillation of the direction of the approach flow resulting in the oscillation of the position of the stagnation line on the leading edge of the blade. In this study an experimental facility was developed that induced a similar oscillation of the stagnation line position on a simulated turbine blade leading edge. The overall effectiveness was evaluated at various blowing ratios and stagnation line oscillation frequencies. The location of the stagnation line on the leading edge was oscillated to simulate a change in angle of attack between α = ± 5° at a range of frequencies from 2 to 20 Hz. These frequencies were chosen based on matching a range of Strouhal numbers typically seen in an engine due to oscillations caused by passing wakes. The blowing ratio was varied between M = 1, M = 2, and M = 3. These experiments were carried out at a density ratio of DR = 1.5 and mainstream turbulence levels of Tu ≈ 6%. The leading edge model was made of high conductivity epoxy in order to match the Biot number of an actual engine airfoil. Results of these tests showed that the film cooling performance with an oscillating stagnation line was degraded by as much as 25% compared to the performance of a steady flow with the stagnation line aligned with the row of holes at the leading edge.

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A numerical study of the effect of wake passing on turbine blade film cooling

10.2514/6.1995-3044 ◽

1995 ◽

Cited By ~ 1

Author(s):

James Heidmann

Keyword(s):

Turbine Blade ◽

Film Cooling ◽

Numerical Study ◽

Wake Passing

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