Reduction of Secondary Flow Losses in Turbine Cascades by Leading Edge Modifications at the Endwall

Sauer, H.; Mu¨ller, Ralf; Vogeler, Konrad

doi:10.1115/1.1354142

Cited by 58 publications

(25 citation statements)

References 2 publications

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“…SL2F produces larger losses than SL2P from about 12% to 35% span, and the midspan losses increase by about 10% for both cases. The pitch-averaged loss trends in the current data sets are similar to the results of Sauer et al (2001), who investigated the effects of endwall leading edge bulbs on secondary flows; in their study, the secondary loss reduction was mainly attributed to the intensification of the suction-side leg of the horseshoe vortex, resulting in a weaker passage vortex.…”

Section: Downstream Flow Field Measurements At 14c Xsupporting

confidence: 83%

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Endwall Flows in Transonic Turbine Cascades

Taremi¹

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The results of an investigation of the midspan and endwall flows in transonic linear turbine cascades are documented here. A family of five turbine cascades with different levels of flow turning and aerodynamic loading were used for this study to quantify the effects of these parameters on loss generation in compressible flows. Experimental data on these flows are scarce in the open literature. In addition, the application of two different passive flow control techniques for reducing the endwall losses is examined here: these are referred to as endwall contouring, and airfoil pressure-side modification. The experimental investigations were conducted in the Pratt and Whitney Canada (PWC) High-Speed Wind Tunnel Laboratory at Carleton University. The measurements were made using a seven-hole pressure probe downstream of the cascades at both design and off-design Mach numbers. In addition to the measurements, surface flow visualization was conducted to assist in the interpretation of the flow physics. The results from complementary numerical investigations are also presented, and compared with the experimental data. Overall, the examined secondary flow structures are in agreement with previous lowspeed findings. However, in contrast to low-speed results, the downstream mixing losses are mainly attributed to the dissipation of primary kinetic energy in the present study. Raising the exit Mach number results in weaker secondary flow structures and smaller secondary losses.The experimental results demonstrate that endwall contouring is a viable option for mitigating the secondary flows, particularly for the more highly-loaded cascade. The modification of the airfoil pressure surface is also found to provide a significant benefit in terms of endwall loss reduction. The differences between the measurements and the computational results highlight the need for detailed experimental investigations.ii Acknowledgments I would like to express my gratitude to my thesis supervisor, Professor Steen Sjolander, for giving me the opportunity to work on this research project. I would also like to thank him for his invaluable advice regarding the interpretation of the results, and for reviewing the text.

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Section: Downstream Flow Field Measurements At 14c Xsupporting

confidence: 83%

“…The application of leading edge bulbs to the T106 airfoil ( Figure 2.4) was examined by Sauer et al (2001). The resulting configurations are labelled T106/1 and T106/2 in As mentioned, the modification of the airfoil pressure-surface profile in the present study is mainly aimed at reducing the secondary losses.…”

Section: Airfoil Pressure Surface Modificationmentioning

confidence: 96%

Endwall Flows in Transonic Turbine Cascades

Taremi¹

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“…Some authors have modified the leading edge region of the endwall to influence the formation of the horseshoe vortex. Sauer et al (2001) tested four leading edge bulb designs applied to the T106 airfoil in a linear cascade. They found that the bulb increased the strength of the suction-side leg of the horseshoe vortex (V s h), which counter-rotates relative to the passage vortex.…”

Section: Leading Edge Modificationsmentioning

confidence: 99%

Controlling secondary flows in very highly-loaded low-pressure turbine cascades

Knezevici¹

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“…Han and Goldstein [24] used fillet geometry around the blade leading edge, which removes the horseshoe vortex and reduces the heat transfer near the leading edge. Sauer and Wolf [25] employed a bulb geometry onto an inlet guide vane. The bulb design strengthens counter vortex, which counter-acts the passage vortex.…”

Section: Introductionmentioning

confidence: 99%

Improving Purge Air Cooling Effectiveness by Engineered End-Wall Surface Structures—Part II: Turbine Cascade

Miao

Zhang

Atkin

et al. 2018

Journal of Turbomachinery

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Motivated by the recent advances in additive manufacturing, a novel turbine end-wall aerothermal management method is presented in this two-part paper. The feasibility of enhancing purge air cooling effectiveness through engineered surface structure was experimentally and numerically investigated. The fundamental working mechanism and improved cooling performance for a 90 deg turning duct are presented in Part I. The second part of this paper demonstrates this novel concept in a low-speed linear cascade environment. The performance in three purge air blowing ratios is presented and enhanced cooling effectiveness and net heat flux reduction (NHFR) were observed from experimental data, especially for higher blow ratios. The Computational fluid dynamics (CFD) analysis indicates that the additional surface features are effective in reducing the passage vortex and providing a larger area of coolant coverage without introducing additional aerodynamic loss.

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Reduction of Secondary Flow Losses in Turbine Cascades by Leading Edge Modifications at the Endwall

Cited by 58 publications

References 2 publications

Endwall Flows in Transonic Turbine Cascades

Endwall Flows in Transonic Turbine Cascades

Controlling secondary flows in very highly-loaded low-pressure turbine cascades

Improving Purge Air Cooling Effectiveness by Engineered End-Wall Surface Structures—Part II: Turbine Cascade

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