Influence of Surface Roughness on the Aerodynamic Losses of a Turbine Vane

Abstract: The effects of surface roughness on the aerodynamic performance of a turbine vane are investigated for three Mach number distributions, one of which results in transonic flow. Four turbine vanes, each with the same shape and exterior dimensions, are employed with different rough surfaces. The nonuniform, irregular, three-dimensional roughness on the tested vanes is employed to match the roughness which exists on operating turbine vanes subject to extended operating times with significant particulate deposition… Show more

“…The data of Zhang and Ligrani [8] show that magnitudes of Integrated Aerodynamic Losses change by much larger amounts as either the freestream Mach number or turbulence intensity are altered, when the airfoil is roughened (compared to smooth airfoil results). Other recent investigations are described by Zhang et al [37,38] and by Zhang and Ligrani [39,40].…”

“…With this approach, the local stagnation pressure loss is normalized by a quantity which does not vary with cascade exit location. Zhang et al [5,37,38], Jackson et al [54], Chappell et al [55], and Zhang and Ligrani [8,27,39,40] employ integrated aerodynamic loss IAL to quantify aerodynamic losses in turbine components. Dimensional magnitudes of Integrated Aerodynamic Loss, IAL, are determined by integrating profiles of (P oi − P oe ) with respect to y in the transverse flow direction across the wake for one single vane spacing, from −p/2 to p/2 [54].…”

“…section. Additional details on experimental apparatus and procedure details are provided by Zhang et al [37,38], and Zhang and Ligrani [27,39,40]. Wake profile data are presented for two different locations downstream the vane trailing edge, which illustrate the influences of varying freestream turbulence intensity level, surface roughness, and vane Mach number on local aerodynamic losses, Integrated…”

Aerodynamic Losses in Turbines with and without Film Cooling, as Influenced by Mainstream Turbulence, Surface Roughness, Airfoil Shape, and Mach Number

“…The data of Zhang and Ligrani [8] show that magnitudes of Integrated Aerodynamic Losses change by much larger amounts as either the freestream Mach number or turbulence intensity are altered, when the airfoil is roughened (compared to smooth airfoil results). Other recent investigations are described by Zhang et al [37,38] and by Zhang and Ligrani [39,40].…”

“…With this approach, the local stagnation pressure loss is normalized by a quantity which does not vary with cascade exit location. Zhang et al [5,37,38], Jackson et al [54], Chappell et al [55], and Zhang and Ligrani [8,27,39,40] employ integrated aerodynamic loss IAL to quantify aerodynamic losses in turbine components. Dimensional magnitudes of Integrated Aerodynamic Loss, IAL, are determined by integrating profiles of (P oi − P oe ) with respect to y in the transverse flow direction across the wake for one single vane spacing, from −p/2 to p/2 [54].…”

“…section. Additional details on experimental apparatus and procedure details are provided by Zhang et al [37,38], and Zhang and Ligrani [27,39,40]. Wake profile data are presented for two different locations downstream the vane trailing edge, which illustrate the influences of varying freestream turbulence intensity level, surface roughness, and vane Mach number on local aerodynamic losses, Integrated…”

Aerodynamic Losses in Turbines with and without Film Cooling, as Influenced by Mainstream Turbulence, Surface Roughness, Airfoil Shape, and Mach Number

“…For example, Roberts and Yaras [15] present experimental results documenting the combined effects of surface roughness and mainstream turbulence level on boundary-layer transition. Zhang et al [16] investigate the influences of surface roughness effect on aerodynamic losses produced by a cambered turbine vane. A technique to determine the skin friction coefficients from wake data measured downstream of symmetric turbine airfoils with rough surfaces is described by Zhang et al [17].…”

Numerical Predictions of Stanton Numbers, Skin Friction Coefficients, Aerodynamic Losses, and Reynolds Analogy Behavior for a Transsonic Turbine Vane

“…Performance tests were conducted in a low-speed, single-stage, axial flow turbine with roughened blades. Afterwards, Zhang et al [5] studied the influence of surface roughness on the aerodynamic losses of a turbine vane. They employed the nonuniform, irregular and three-dimensional roughness on the tested vanes.…”

Effects of surface roughness on deviation angle and performance losses in wet steam turbines