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Classical Inflow Models

Classical Inflow Models. Background. In Part II and Part III of our lecture notes, we used Glauert’s inflow model to compute the induced velocity in forward flight. This model gives acceptable results for performance, but does not give good results for blade dynamics or vibratory loads.

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Classical Inflow Models

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  1. Classical Inflow Models

  2. Background • In Part II and Part III of our lecture notes, we used Glauert’s inflow model to compute the induced velocity in forward flight. • This model gives acceptable results for performance, but does not give good results for blade dynamics or vibratory loads. • It fails miserably for Blade-Vortex-Interactions.

  3. Why does the model fail in forward flight?Because most of the wake is the first and second quadrants.We can not expect the induced velocities to be uniform! Freestream Tip Vortices Rotor Disk

  4. Experiment by Harris • Because most of the tip vortices are in the first and fourth quadrants, the induced velocity associated with these vorticies (i.e. the inflow) is very high in the first and fourth quadrants. • The resultant reduced angle of attack leads to smaller lift forces in the aft region, compared to uniform inflow model. • The blade responds to this reduced loads 90 degrees later. • It flaps down (leading to a more negative b1s) more than expected. • Harris experimentally observed this, in a paper published in 1972 in the Journal of the American Helicopter Society (See Wayne Johnson, page 274, figure 5-39).

  5. Effects of Non-Uniform Inflow on Lateral Flapping

  6. Effects of Non-Uniform Inflow on Blade-Vortex-Interaction Loads • During descent the tip vortices are pushed up against the rotor disk by the freestream, leading to a very close spacing between the blades and the vortices. • According to Biot-Savart law, this leads to very high, and very rapidly varying, induced velocity. • This affects the airloads dramatically. • Ignoring this rapid variation in the inflow and using a Glauert inflow model will lead to a severe underprediction of vibratory loads, and associated aerodynamically generated noise.

  7. Blade Vortex Interaction The velocity field experienced by the blade changes dramatically in a matter of mili-seconds!

  8. Efforts to Improve Inflow Models • Engineers and researchers recognized very quickly that there is need for improvements in the inflow model. • Until the mid 1960s, the work was analytical or semi-empirical. This approach is called classical vortex theory. See pages 134-141 of text, and our web site. • Starting 1960s, numerical approaches based on Biot-Savart law became popular.

  9. Coleman’s Model Coleman divided the Continuous helical vortex into a Series of circular rings. He assumed that the vortex strength is constant. Real Tip Vortex is helical, and distorted. Its strength varies along its length.

  10. Side View Coleman used Biot-Savart law, and numerical integration to compute the Induced velocity at a few points on the rotor disk. Induced velocity v + Normal component of freestream = l WR Rotor Disk Edgewise component of Freestream Velocity = m WR Successive Rings of Vortices G=constant in Coleman’s Model

  11. Castles’ et al’s Model • This model is discussed in NACA report 1184. A pdf file may be found at the web site: http://www.ae.gatech.edu/~lsankar/AE6070.Fall2002/castles.pdf • Castles replaced the numerical integration in Coleman’s model with analytical integration. • These authors also replaced the individual rings by a continuous sheet of vorticity.

  12. Castles’ Model The individual rings were replaced by a skewed cylindrical surface. Vorticity strength was uniform on the cylinder surface. Biot-Savart Law was used. Results are supplied as charts and graphs.

  13. Heyson et al’s Model • This model is discussed in the NACA Report 1319. An electronic version may be found at: http://www.ae.gatech.edu/~lsankar/AE6070.Fall2002/heyson.pdf • This model rectifies one of the assumptions in Castles’ and Coleman’s models, namely that the rotor only sheds tip vortices.

  14. Radial Variation of Loads causes a continuous shedding of vorticity Heyson assumed that the Circulation G varies linearly With radius. G r/R Heyson modeled each of the trailing vortices as a vortex sheet whose shape is in the form of a skewed cylinder. The effects of each of the cylinders may be superposed, using the analytical formulas developed by Castles’ et al.

  15. Heyson’s Model At each radial location A vortex sheet of shape Similar to a circular Cylinder is shed. The strength is constant, Both along the axis of the Cylinder and around the azimuth.

  16. Advanced Inflow Models

  17. Background • Around 1965, more powerful digital computers became readily available. • Engineers began to model the tip vortex as a skewed, distorted, helix. • The strength of the tip vortex was allowed to vary with azimuth, acknowledging the fact that the blade loading changes with the azimuthal position of the blade.

  18. Background (Continued) • Sadler at Bell Helicopter, and Scully at MIT developed some of the earliest techniques. • Sadler used a rigid helical wake, while Scully allowed for the wake to deform due to self-induced velocities. • The induced velocity at the “strips” on the blade were computed using Biot-Savart Law. • Modern methods (e.g. CAMRAD-II) not only model the tip vortex, but also the inboard vortices, and shed vortices. • See our web site for several publications related to CAMRAD-II.

  19. Shed Wake When the lift (or bound circulation) around an airfoil changes with time, Circulation that is equal in magnitude to the bound circulation but opposite In strength is shed into the wake.

  20. Trailing and Shed Wake Representation The blade is divided into a number of strips, as in HW#1 and 2 Hub Strip j Tip The end points of vortex segments are Called markers. Shed Vortex Tip Vortex Inboard Trailing Vortex

  21. Trialing Vortex Strength Bound Circulation On next strip G+dG Bound Circulation On this strip G dG Right hand screw rule is applied to assign the orientation of the vortex. The strength of the most recently shed trailing vortex segment may be thought of as the change in the bound vortex strength between adjacent “strips.”

  22. Shed Vortex Strength Strip j Blade position at next time step n+1 Gjn+1 Trailing vortices Tip vortex Blade position At time step n Strength of shed Vortex segment = Gjn+1-Gjn The strength of the shed vortex segments Will vary from one strip to the next.

  23. Induced Velocity Calculation • The calculations are done in a time marching mode. • The strength of the shed and trailing vortices are known from the previous time steps. • The geometry of the wake is assumed to be a helix (rigid), prescribed (deformed wake, curve fitted from experiments) or free wake. • Free wake geometry is computed by allowing the wake to move at the freestream velocity plus the induced velocity computed at the junction points (markers).

  24. Rigid Wake Model where the  is the azimuthal angle of the reference blade, and f is the vortex wake age. mx, mx and mz are advance ratio Components along x-, y-, and z- directions. The Glauert uniform inflow model is used to estimate the inflow components x, y and z , the three components of l.

  25. Wake Age f Tip Vortex x

  26. Prescribed Wake Model In this model, the x and y coordinates of the tip vortex are prescribed from a rigid wake model. The vertical displacements of the tip vortices are given as: where E is an envelop function given by: Here, A0, A1, M, B, Cn and Dn are all empirical constants listed in “Egolf, A. and Landgrebe, A. J., “Helicopter Rotor Wake Geometry and Its Influence in Forward Flight, Vol. I, NASA CR-3726.”

  27. Free Wake Geometry

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