Discharge coefficients and aerodynamic losses for cylindrical and cratered film-cooling holes with various coolant crossflow orientations

An empirical means of predicting the discharge coefficients of film cooling holes in an operating engine has been developed. The method quantifies the influence of the major dimensionless parameters, namely hole geometry, pressure ratio across the hole, coolant Reynolds number, and the freestream Mach number. The method utilizes discharge coefficient data measured on both a first-stage high-pressure nozzle guide vane from a modern aero-engine and a scale (1.4 times) replica of the vane. The vane has over 300 film cooling holes, arranged in 14 rows. Data was collected for both vanes in the absence of external flow. These noncrossflow experiments were conducted in a pressurized vessel in order to cover the wide range of pressure ratios and coolant Reynolds numbers found in the engine. Regrettably, the proprietary nature of the data collected on the engine vane prevents its publication, although its input to the derived correlation is discussed. Experiments were also conducted using the replica vanes in an annular blowdown cascade which models the external flow patterns found in the engine. The coolant system used a heavy foreign gas (SF6 /Ar mixture) at ambient temperatures which allowed the coolant-to-mainstream density ratio and blowing parameters to be matched to engine values. These experiments matched the mainstream Reynolds and Mach numbers and the coolant Mach number to engine values, but the coolant Reynolds number was not engine representative (Rowbury, D. A., Oldfield, M. L. G., and Lock, G. D., 1997, “Engine-Representative Discharge Coefficients Measured in an Annular Nozzle Guide Vane Cascade,” ASME Paper No. 97-GT-99, International Gas Turbine and Aero-Engine Congress & Exhibition, Orlando, Florida, June 1997; Rowbury, D. A., Oldfield, M. L. G., Lock, G. D., and Dancer, S. N., 1998, “Scaling of Film Cooling Discharge Coefficient Measurements to Engine Conditions,” ASME Paper No. 98-GT-79, International Gas Turbine and Aero-Engine Congress & Exhibition, Stockholm, Sweden, June 1998). A correlation for discharge coefficients in the absence of external crossflow has been derived from this data and other published data. An additive loss coefficient method is subsequently applied to the cascade data in order to assess the effect of the external crossflow. The correlation is used successfully to reconstruct the experimental data. It is further validated by successfully predicting data published by other researchers. The work presented is of considerable value to gas turbine design engineers as it provides an improved means of predicting the discharge coefficients of engine film cooling holes.

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Discharge Coefficients of Holes Angled to the Flow Direction

Journal of Turbomachinery ◽

10.1115/1.2928282 ◽

1994 ◽

Vol 116 (1) ◽

pp. 92-96 ◽

Cited By ~ 17

Author(s):

N. Hay ◽

S. E. Henshall ◽

A. Manning

Keyword(s):

Hot Spots ◽

Film Cooling ◽

Discharge Coefficient ◽

Flow Direction ◽

Turbine Blades ◽

Internal Flow ◽

Design Stage ◽

Gas Turbine Blades ◽

Discharge Coefficients ◽

Film Cooling Holes

In the cooling passages of gas turbine blades, branches are often angled to the direction of the internal flow. This is particularly the case with film cooling holes. Accurate knowledge of the discharge coefficient of such holes at the design stage is vital so that the holes are correctly sized, thus avoiding wastage of coolant and the formation of hot spots on the blade. This paper describes an experimental investigation to determine the discharge coefficient of 30 deg inclined holes with various degrees of inlet radiusing and with the axis of the hole at various orientation angles to the direction of the flow. Results are given for nominal main flow Mach numbers of 0, 0.15, and 0.3. The effects of radiusing, orientation, and crossflow Mach number are quantified in the paper, the general trends are described, and the criteria for optimum performance are identified.

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Large-Scale Testing to Validate the Influence of External Crossflow on the Discharge Coefficients of Film Cooling Holes

Journal of Turbomachinery ◽

10.1115/1.1375171 ◽

2000 ◽

Vol 123 (3) ◽

pp. 593-600 ◽

Cited By ~ 6

Author(s):

D. A. Rowbury ◽

M. L. G. Oldfield ◽

G. D. Lock

Keyword(s):

Film Cooling ◽

Stream Flow ◽

Large Scale ◽

Discharge Coefficient ◽

Static Pressure ◽

Free Stream ◽

Discharge Coefficients ◽

Large Scale Testing ◽

Cooling Hole ◽

Film Cooling Holes

This paper discusses large-scale, low-speed experiments that explain unexpected flow-interaction phenomena witnessed during annular cascade studies into the influence of external crossflow on film cooling hole discharge coefficients. More specifically, the experiments throw light on the crossover phenomenon, where the presence of the external crossflow can, under certain circumstances, increase the discharge coefficient. This is contrary to most situations, where the external flow results in a decrease in discharge coefficient. The large-scale testing reported helps to explain this phenomenon through an increased understanding of the interaction between the emerging coolant jet and the free-stream flow. The crossover phenomenon came to light during an investigation into the influence of external crossflow on the discharge coefficients of nozzle guide vane film cooling holes. These experiments were performed in the Cold Heat Transfer Tunnel (CHTT), an annular blowdown cascade of film cooled vanes that models the three-dimensional external flow patterns found in modern aero-engines. (Rowbury et al., 1997, 1998). The variation in static pressure around the exit of film cooling holes under different flow conditions was investigated in the large-scale tests. The study centered on three holes whose geometries were based on those found in the leading edge region of the CHTT vanes, as the crossover phenomenon was witnessed for these rows during the initial testing. The experiments were carried out in a low-speed wind tunnel, with the tunnel free-stream flow velocity set to match the free-stream Reynolds number (based on the local radius of curvature) and the “coolant” flow velocity set to replicate the engine coolant-to-free-stream momentum flux ratio. It was found that the apparent enhancement of film cooling hole discharge coefficients with external crossflow was caused by a reduction in the static pressure around the hole exit, associated with the local acceleration of the free-stream around the emerging coolant jet. When these measured static pressures (rather than the free-stream static pressure) were used to calculate the discharge coefficient, the crossover effect was absent. The improved understanding of the crossover phenomenon and coolant-to-free-stream interactions that has been gained will be valuable in aiding the formulation of predictive discharge coefficient schemes.

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Discharge Coefficients of Impingement and Film Cooling Holes

Volume 3: Heat Transfer; Electric Power ◽

10.1115/85-gt-81 ◽

1985 ◽

Cited By ~ 4

Author(s):

Tay Chu ◽

A. Brown ◽

S. Garrett

Keyword(s):

Reynolds Number ◽

Film Cooling ◽

Reynolds Numbers ◽

Turbine Blade Cooling ◽

Blade Cooling ◽

Discharge Coefficients ◽

Corner Radius ◽

Flow Through ◽

Blowing Parameter ◽

Film Cooling Holes

In this article measurements of fluid flow through impingement and film cooling holes for typical turbine blade cooling systems are presented. The purpose of the measurements was to determine hole discharge coefficients over a range of Reynolds numbers from 5,000 to 30,000 and to observe in this range the dependence of discharge coefficient on Reynolds number. The effect of hole geometry, that is, sharp edged inlet or corner radius inlet, on discharge coefficients is also measured. Correlations relating discharge coefficients to Reynolds number, corner radius to hole diameter ratio, and blowing parameter are suggested.

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A Method for Correlating the Influence of External Crossflow on the Discharge Coefficients of Film Cooling Holes

Volume 3: Heat Transfer; Electric Power; Industrial and Cogeneration ◽

10.1115/2000-gt-0294 ◽

2000 ◽

Author(s):

D. A. Rowbury ◽

M. L. G. Oldfield ◽

G. D. Lock

Keyword(s):

Reynolds Number ◽

Mach Number ◽

Film Cooling ◽

Guide Vane ◽

Density Ratio ◽

External Flow ◽

Published Data ◽

Discharge Coefficients ◽

Wide Range ◽

Film Cooling Holes

An empirical means of predicting the discharge coefficients of film cooling holes in an operating engine has been developed. The method quantifies the influence of the major dimensionless parameters, namely hole geometry, pressure ratio across the hole, coolant Reynolds number, and the freestream Mach number. The method utilises discharge coefficient data measured on both a first-stage high-pressure nozzle guide vane from a modern aero-engine and a scale (1.4 times) replica of the vane. The vane has over 300 film cooling holes, arranged in 14 rows. Data was collected for both vanes in the absence of external flow. These non-crossflow experiments were conducted in a pressurised vessel in order to cover the wide range of pressure ratios and coolant Reynolds numbers found in the engine. Regrettably, the proprietary nature of the data collected on the engine vane prevents its publication, although its input to the derived correlation is discussed. Experiments were also conducted using the replica vanes in an annular blowdown cascade which models the external flow patterns found in the engine. The coolant system used a heavy foreign gas (SF6/Ar mixture) at ambient temperatures which allowed the coolant-to-mainstream density ratio and blowing parameters to be matched to engine values. These experiments matched the mainstream Reynolds and Mach numbers and the coolant Mach number to engine values, but the coolant Reynolds number was not engine representative (Rowbury et al., 1997 and 1998). A correlation for discharge coefficients in the absence of external crossflow has been derived from this data and other published data. An additive loss coefficient method is subsequently applied to the cascade data in order to assess the effect of the external crossflow. The correlation is used successfully to reconstruct the experimental data. It is further validated by successfully predicting data published by other researchers. The work presented is of considerable value to gas turbine design engineers as it provides an improved means of predicting the discharge coefficients of engine film cooling holes.

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Method for correlating discharge coefficients of film-cooling holes

AIAA Journal ◽

10.2514/3.13921 ◽

1998 ◽

Vol 36 ◽

pp. 976-980 ◽

Cited By ~ 2

Author(s):

Michael Gritsch ◽

Achmed Schulz ◽

Sigmar Wittig

Keyword(s):

Film Cooling ◽

Discharge Coefficients ◽

Film Cooling Holes

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Discharge Coefficient Measurements of Film-Cooling Holes With Expanded Exits

Volume 3: Heat Transfer; Electric Power; Industrial and Cogeneration ◽

10.1115/97-gt-165 ◽

1997 ◽

Cited By ~ 14

Author(s):

M. Gritsch ◽

A. Schulz ◽

S. Wittig

Keyword(s):

Mach Number ◽

Film Cooling ◽

Discharge Coefficient ◽

Pressure Ratio ◽

Cylindrical Hole ◽

Flow Conditions ◽

Discharge Coefficients ◽

Wide Range ◽

Cooling Hole ◽

Film Cooling Holes

This paper presents the discharge coefficients of three film-cooling hole geometries tested over a wide range of flow conditions. The hole geometries include a cylindrical hole and two holes with a diffuser shaped exit portion (i.e. a fanshaped and a laidback fanshaped hole). The flow conditions considered were the crossflow Mach number at the hole entrance side (up to 0.6), the crossflow Mach number at the hole exit side (up to 1.2), and the pressure ratio across the hole (up to 2). The results show that the discharge coefficient for all geometries tested strongly depends on the flow conditions (crossflows at hole inlet and exit, and pressure ratio). The discharge coefficient of both expanded holes was found to be higher than of the cylindrical hole, particularly at low pressure ratios and with a hole entrance side crossflow applied. The effect of the additional layback on the discharge coefficient is negligible.

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Effect of Crossflows on the Discharge Coefficient of Film Cooling Holes With Varying Angles of Inclination and Orientation

Volume 3: Heat Transfer; Electric Power; Industrial and Cogeneration ◽

10.1115/2001-gt-0134 ◽

2001 ◽

Cited By ~ 7

Author(s):

Michael Gritsch ◽

Achmed Schulz ◽

Sigmar Wittig

Keyword(s):

Inclination Angle ◽

Film Cooling ◽

Discharge Coefficient ◽

Orientation Angle ◽

Discharge Coefficients ◽

Wide Range ◽

Cooling Hole ◽

Discharge Behavior ◽

Hole Geometry ◽

Film Cooling Holes

Measurements of discharge coefficients for five configurations of cylindrical film cooling hole geometries are presented. These comprise holes of varying angles of inclination (α= 30, 45, and 90deg) and orientation (γ= 0, 45, and 90deg) which are tested over a wide range of engine like conditions in terms of internal and external crossflow Mach numbers (Mam=0…1.2, Mac=0…0.6) as well as pressure ratios (ptc/pm=1…2.25). Results show that discharge coefficients do not solely depend on hole geometry but are also profoundly affected by the internal and external crossflow conditions. The effect of increasing the orientation angle on the discharge behavior is very similar to the effect of increasing the inclination angle. Both result in higher losses particularly at the cooling hole inlet while the losses at the hole exit are only slightly affected.

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Discharge Coefficient and Effectiveness Measurement for Conical Shaped Film Cooling Holes

Heat Transfer, Part A ◽

10.1115/imece2005-81713 ◽

2005 ◽

Cited By ~ 1

Author(s):

H. A. Zuniga ◽

Vaidyanathan Krishnan ◽

A. K. Sleiti ◽

J. S. Kapat ◽

Sanjeev Bharani

Keyword(s):

Film Cooling ◽

Discharge Coefficient ◽

Density Ratio ◽

Diameter Ratio ◽

Constant Density ◽

Base Line ◽

Blowing Ratio ◽

Discharge Coefficients ◽

Effectiveness Measurement ◽

Film Cooling Holes

Experimental measurements of discharge coefficient and effectiveness of conical shaped film cooling holes with 1°, 2° and 3° uniform diffusion angle are presented. All film holes are inclined at 35° with hole length to diameter ratio, L/D = 3.5, pitch to diameter ratio, PI/D = 3 with a constant density ratio of 1.26 and with nitrogen as the coolant. Results show that conical film holes have higher discharge coefficients than their cylindrical counterparts. For conical holes, the local distribution and laterally averaged effectiveness values decrease with increasing blowing ratio from 0.45 to 1. The configuration with 3° uniform diffusion angle has the highest effectiveness values and outperforms the conical holes with 1°, 2° diffusion angles by 40% in the proximity of the holes (X/D ≪ 5) at a blowing ratio of 0.45. Results are compared to base line cylindrical as well as to fan shape film holes available in open literature. The average effectiveness of the conical holes can reach values comparable to those achieved by fan shaped film holes at the same blowing ratio.

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Discharge Coefficient of Turbine Cooling Holes: A Review

Journal of Turbomachinery ◽

10.1115/1.2841408 ◽

1998 ◽

Vol 120 (2) ◽

pp. 314-319 ◽

Cited By ~ 30

Author(s):

N. Hay ◽

D. Lampard

Keyword(s):

Film Cooling ◽

Discharge Coefficient ◽

Correlated Data ◽

Published Data ◽

Flow Conditions ◽

Turbine Cooling ◽

Acceptable Accuracy ◽

Discharge Coefficients ◽

Method Of Evaluation ◽

Film Cooling Holes

Published information on the discharge coefficient of film cooling holes is classified in terms of the hole geometry, the external flow conditions at inlet and outlet, and the method of evaluation. This may be either theoretical or experimental. The information is reviewed primarily in the context of its use for evaluating discharge coefficients for conditions not directly covered by published data. It is shown that potential flow analyses can give acceptable accuracy for simple geometries with crossflows, while more complex cases require the use of correlated data, which may be incorporated in a range of predictive schemes. Deficiencies and inconsistencies in the published information are highlighted, and future developments are discussed.

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