Optimization of Trailing Edge Ejection Mixing Losses: A Theoretical and Experimental Study

Pappu, K.; Schobeiri, Meinhard T.

doi:10.1115/97-gt-523

Volume 1: Aircraft Engine; Marine; Turbomachinery; Microturbines and Small Turbomachinery 1997

DOI: 10.1115/97-gt-523

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Optimization of Trailing Edge Ejection Mixing Losses: A Theoretical and Experimental Study

K. Pappu

Meinhard T. Schobeiri

Abstract: The aerodynamic effects of trailing edge ejection on mixing losses downstream of cooled gas turbine blades were experimentally investigated and compared with an already existing one-dimensional theory by Schobeiri (1989). The significant parameters determining the mixing losses and therefore the efficiency of cooled blades are the ejection velocity ratio, the cooling mass flow ratio, the temperature ratio, the slot thickness ratio and the ejection flow angle. To cover a broad range of representative turbine bl… Show more

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Cited by 6 publications

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“…6 When the ejection velocity and angle were tuned, an overall optimization could be achieved. 7 Although the method clearly works, it is still important to understand the underlying ow mechanism. On this point, experimentalists have made some progress, and the mechanism of drag reduction is believed to involve a change in the wake dynamics.…”

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confidence: 99%

Direct numerical simulation of turbulent trailing-edge flow with base flow control

Yao¹,

Sandham²

2002

AIAA Journal

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Direct numerical simulation has been carried out for turbulent ow over a rectangular trailing edge at a Reynolds number of 1 £ £ 10 3 (based on the freestream quantities and the trailing-edge thickness) and ratio of boundarylayer displacement thickness to trailing-edge thickness close to unity. Two types of ow control were studied: base transpiration and secondary splitter plate. Simulation of base transpiration was performed using different slit heights and volume ow rates. It was found that even small ow rates could produce signi cant changes in overall aerodynamic performance, measured, for example, by the base pressure coef cient. It was also found that for the same volume ow rate, a greater increase in base pressure (drag reduction) was obtained by blowing slowly through a wide slit rather than quickly through a narrow slit. The effectiveness of a secondary splitter plate located on the trailing-edge centerline was investigated by varying the plate length from one to ve times the trailing-edge thickness. A signi cant increase in the base pressure coef cient (about 25%) was achieved, even with the shortest splitter plate equal to the trailing-edge thickness. The base pressure coef cient increased monotonically with the splitter plate length, and no intermediate maximum value was found.

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confidence: 99%

Direct numerical simulation of turbulent trailing-edge flow with base flow control

Yao¹,

Sandham²

2002

AIAA Journal

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Aerodynamic Loss Characteristics of a Turbine Blade With Trailing Edge Coolant Ejection: Part 2—External Aerodynamics, Total Pressure Losses, and Predictions

Uzol

Camcı

2000

Journal of Turbomachinery

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Investigation of the internal fluid mechanic losses for a turbine blade with trailing edge coolant ejection was present in Uzol et al. (2001). The current study is a detailed experimental investigation of the external subsonic flowfield near the trailing edge and the investigation of the external aerodynamic loss characteristics of the turbine blade with trailing edge coolant ejection system. Particle Image Velocimetry experiments and total pressure surveys in the near wake of the blade are conducted for two different Reynolds numbers and four different ejection rates. Two different trailing edge configurations with different cut-back lengths are also investigated. Numerical simulations of the flowfield are also performed for qualitative flow visualization purposes. Two-dimensional, incompressible, and steady solutions of Reynolds-averaged Navier–Stokes equations are obtained. A two-equation standard k-ε turbulence model coupled with an Algebraic Reynolds Stress Model is used for the simulation of the turbulent flowfield. The results show that the aerodynamic penalty levels in the wake region near the trailing edge are increased due to the mixing of the coolant and mainstream flows for 0–3 percent ejection rates. However, after a threshold level (5 percent ejection rate), the ejected coolant flow has enough momentum to fill the wake of the blade, which in turn results in a decrease in the aerodynamic penalty levels.

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Convective Heat Transfer and Aerodynamics in Axial Flow Turbines

Dunn

2001

Journal of Turbomachinery

112

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The primary focus of this paper is convective heat transfer in axial flow turbines. Research activity involving heat transfer generally separates into two related areas: predictions and measurements. The problems associated with predicting heat transfer are coupled with turbine aerodynamics because proper prediction of vane and blade surface-pressure distribution is essential for predicting the corresponding heat transfer distribution. The experimental community has advanced to the point where time-averaged and time-resolved three-dimensional heat transfer data for the vanes and blades are obtained routinely by those operating full-stage rotating turbines. However, there are relatively few CFD codes capable of generating three-dimensional predictions of the heat transfer distribution, and where these codes have been applied the results suggest that additional work is required. This paper outlines the progression of work done by the heat transfer community over the last several decades as both the measurements and the predictions have improved to current levels. To frame the problem properly, the paper reviews the influence of turbine aerodynamics on heat transfer predictions. This includes a discussion of time-resolved surface-pressure measurements with predictions and the data involved in forcing function measurements. The ability of existing two-dimensional and three-dimensional Navier–Stokes codes to predict the proper trends of the time-averaged and unsteady pressure field for full-stage rotating turbines is demonstrated. Most of the codes do a reasonably good job of predicting the surface-pressure data at vane and blade midspan, but not as well near the hub or the tip region for the blade. In addition, the ability of the codes to predict surface-pressure distribution is significantly better than the corresponding heat transfer distributions. Heat transfer codes are validated against measurements of one type or another. Sometimes the measurements are performed using full rotating rigs, and other times a much simpler geometry is used. In either case, it is important to review the measurement techniques currently used. Heat transfer predictions for engine turbines are very difficult because the boundary conditions are not well known. The conditions at the exit of the combustor are generally not well known and a section of this paper discusses that problem. The majority of the discussion is devoted to external heat transfer with and without cooling, turbulence effects, and internal cooling. As the design community increases the thrust-to-weight ratio and the turbine inlet temperature, there remain many turbine-related heat transfer issues. Included are film cooling modeling, definition of combustor exit conditions, understanding of blade tip distress, definition of hot streak migration, component fatigue, loss mechanisms in the low turbine, and many others. Several suggestions are given herein for research and development areas for which there is potentially high payoff to the industry with relatively small risk.

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Optimization of Trailing Edge Ejection Mixing Losses: A Theoretical and Experimental Study

Cited by 6 publications

References 5 publications

Direct numerical simulation of turbulent trailing-edge flow with base flow control

Direct numerical simulation of turbulent trailing-edge flow with base flow control

Aerodynamic Loss Characteristics of a Turbine Blade With Trailing Edge Coolant Ejection: Part 2—External Aerodynamics, Total Pressure Losses, and Predictions

Convective Heat Transfer and Aerodynamics in Axial Flow Turbines

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