Journal ArticleDOI
Flow Physics and Profiling of Recessed Blade Tips: Impact on Performance and Heat Load
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TLDR
In this article, an improved design of a recessed blade tip for a highly loaded axial turbine rotor blade with application in high pressure axial turbines in aero engine or power generation is presented.Abstract:
In axial turbine the tip clearance flow occurring in rotor blade rows is responsible for about one third of the aerodynamic losses in the blade row and in many cases is the limiting factor for the blade lifetime. The tip leakage vortex forms when the leaking fluid crosses the gap between the rotor blade tip and the casing from pressure to suction side and rolls up into a vortex on the blade suction side. The flow through the tip gap is both of high velocity and high temperature, with the heat transfer to the blade from the hot fluid being very high in the blade tip area. In order to avoid blade tip burnout and a failure of the machine, blade tip cooling is commonly used. This paper presents the physical study and an improved design of a recessed blade tip for a highly loaded axial turbine rotor blade with application in high pressure axial turbines in aero engine or power generation. With use of three-dimensional Computational Fluid Dynamics (CFD), the flow field near the tip of the blade for different shapes of the recess cavities is investigated. Through better understanding and control of cavity vortical structures, an improved design is presented and the differences to the generic flat tip blade are highlighted. It is observed that by an appropriate profiling of the recess shape, the total tip heat transfer Nusselt Number was significantly reduced, being 15% lower than the flat tip and 7% lower than the baseline recess shape. Experimental results also showed an overall improvement of 0.2% in the one-and-1/2-stage turbine total efficiency with the improved recess design compared to the flat tip case. The CFD analysis conducted on single rotor row configurations predicted a 0.38% total efficiency increase for the rotor equipped with the new recess design compared to the flat tip rotor.Copyright © 2006 by ASMEread more
Citations
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Journal ArticleDOI
Gas Turbine Blade Tip Heat Transfer and Cooling: A Literature Survey
Bengt Sundén,Gongnan Xie +1 more
TL;DR: In this article, a literature survey of blade tip leakage flow and heat transfer, as well as research of external and internal cooling technologies, is presented, where the tip clearance gap is defined as the point where the complex tip leakage flows and local high heat loads prevail.
Journal ArticleDOI
Dominant flow structure in the squealer tip gap and its impact on turbine aerodynamic performance
TL;DR: In this article, the authors investigated the physical mechanism of flow structures inside the cavity that control leakage loss, which is obtained by analyzing the evolution of the flow structures and its influence on the leakage flow rate and momentum at the gap outlet.
Journal ArticleDOI
Aero-Thermal Performance of a Winglet at Engine Representative Mach and Reynolds Numbers
D. O. O’Dowd,Qiang Zhang,Li He,M. L. G. Oldfield,P. M. Ligrani,Brian C. Y. Cheong,Ian Tibbott +6 more
TL;DR: In this paper, an experimental investigation of the aero-thermal performance of a cooled winglet tip, under transonic conditions (exit Mach number 1.0, and an exit Reynolds number of 1.27×106, based on axial chord), is presented.
Patent
Fluted tip turbine blade
TL;DR: In this paper, a turbine blade includes an airfoil (12) having pressure and suction sidewalls (24,26) extending between leading and trailing edges (38,30) and root (32,34) and tip (34).
Journal ArticleDOI
Effects of turbine blade tip shape on total pressure loss and secondary flow of a linear turbine cascade
TL;DR: In this paper, the effects of tip shape on the secondary flow and total pressure loss in a turbine cascade have been investigated experimentally and a total of 11 tip shapes including plane, single or double squealer, dimpled, chamfered, and grooved tips were tested.
References
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Proceedings ArticleDOI
Thin-layer approximation and algebraic model for separated turbulent flows
B. Baldwin,H. Lomax +1 more
TL;DR: In this article, an algebraic turbulence model for two-and three-dimensional separated flows is specified that avoids the necessity for finding the edge of the boundary layer, and compared with experiment for an incident shock on a flat plate, separated flow over a compression corner, and transonic flow over an airfoil.
Journal ArticleDOI
The measurement and formation of tip clearance loss
TL;DR: In this article, the tip clearance loss from the leading to trailing edge of a linear turbine cascade was measured and the contributions made by mixing, internal gap shear flow, and endwall/secondary flow were identified, separated, and quantified for the first time.
Proceedings ArticleDOI
Multigrid solution of the Euler equations for aircraft configurations
Antony Jameson,Timothy J. Baker +1 more
TL;DR: In this article, a multigrid scheme for solving the Euler equations is presented, which has been successfully applied to two-dimensional airfoil calculations on both O-type and C-type meshes.
Journal ArticleDOI
The Effect of Blade Tip Geometry on the Tip Leakage Flow in Axial Turbine Cascades
TL;DR: In this paper, the effects of using plain tips, suction side squealers, and pressure side swealers were investigated in two linear cascades of turbine blades, and a method of calculating the tip discharge coefficients for squealer geometries was put forward.