• Title of article

    Experimental investigation of the effects of blowing conditions and Mach number on the unsteady behavior of coolant ejection through a trailing edge cutback

  • Author/Authors

    Barigozzi، نويسنده , , Giovanna and Armellini، نويسنده , , Alessandro and Mucignat، نويسنده , , Claudio and Casarsa، نويسنده , , Luca، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2012
  • Pages
    14
  • From page
    37
  • To page
    50
  • Abstract
    The present paper shows the results of an experimental investigation into the unsteadiness of coolant ejection at the trailing edge of a highly loaded nozzle vane cascade. The trailing edge cooling scheme features a pressure side cutback with film cooling slots, stiffened by evenly spaced ribs in an inline configuration. Cooling air is also ejected through two rows of cylindrical holes placed upstream of the cutback. Tests were performed with a low inlet turbulence intensity level (Tu1 = 1.6%), changing the cascade operating conditions from low speed (M2is = 0.2) up to high subsonic regime (M2is = 0.6), and with coolant to main stream mass flow ratio varied within the 0.5–2.0% range. Particle Image Velocimetry (PIV) and flow visualizations were used to investigate the unsteady mixing process taking place between coolant and main flow downstream of the cutback, up to the trailing edge. For all the tested conditions, the results show the presence of large coherent structures, which presence is still evident up to the trailing edge. Their shape and direction of rotation change with injection conditions, as a function of coolant to mainstream velocity ratio, strongly influencing the thermal protection capability of the injected coolant flow. The Mach number increase is only responsible for a positioning of such vortical structures closer to the wall, while the Strouhal number almost remains unchanged.
  • Keywords
    Film cooling , Cutback trailing edge , Coherent structures , Unsteadiness , PIV
  • Journal title
    International Journal of Heat and Fluid Flow
  • Serial Year
    2012
  • Journal title
    International Journal of Heat and Fluid Flow
  • Record number

    2382098