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2 results

  • 7 - Aerodynamic Loading

  • Michael Casey, Chris Robinson
  • Book:
    Radial Flow Turbocompressors
    Published online:
    08 July 2021
    Print publication:
    29 April 2021, pp 210-246

  • Summary

    The important fluid dynamic principles of the flows around aerofoils, cascades of blades and the diffusing flow in radial compressor flow channels are described. The nature of decelerating flows in two-dimensional channel diffusers is explained together with their interesting flow regimes, which limit the amount of diffusion that is possible. The different nondimensional parameters used to define the fluid dynamic loading limits in compressors blade rows related to diffusion and blade loading are summarised. The primary meaning of aerodynamic loading is that there is a difference in pressure between the surfaces of a blade profile. This pressure difference leads to the forces and the torque needed to drive an impeller and to change the direction of the flow. The pressure difference between the adjacent blades may be high even if the work coefficient or pressure rise of the stage is moderate, simply by dint of having few blades. The second meaning is that the stage is designed for a particularly high work coefficient. The third meaning is related to the amount of diffusion in the flow between the inlet and the outlet of a cascade or a diffuser vane.

  • Drag optimisation of a wing equipped with a morphing upper surface

  • Part of
  • A. Koreanschi, O. Sugar-Gabor, R. M. Botez
  • Journal:
    The Aeronautical Journal / Volume 120 / Issue 1225 / March 2016
    Published online by Cambridge University Press:
    23 March 2016, pp. 473-493

  • The drag coefficient and the laminar-to-turbulent transition for the aerofoil component of a wing model are optimised using an adaptive upper surface with two actuation points. The effects of the new shaped aerofoils on the global drag coefficient of the wing model are also studied. The aerofoil was optimised with an ‘in-house’ genetic algorithm program coupled with a cubic spline aerofoil shape reconstruction and XFoil 6.96 open-source aerodynamic solver. The wing model analysis was performed with the open-source solver XFLR5 and the 3D Panel Method was used for the aerodynamic calculation. The results of the aerofoil optimisation indicate improvements of both the drag coefficient and transition delay of 2% to 4%. These improvements in the aerofoil characteristics affect the global drag of the wing model, reducing it by up to 2%. The analyses were conducted for a single Reynolds number and speed over a range of angles of attack. The same cases will also be used in the experimental testing of the manufactured morphing wing model.