Performance optimization for rotors in hover and axial flight

Performance optimization for rotors in hover and axial flight is a topic of continuing importance to rotorcraft designers. The aim of this Phase 1 effort has been to demonstrate that a linear optimization algorithm could be coupled to an existing influence coefficient hover performance code. This code, dubbed EHPIC (Evaluation of Hover Performance using Influence Coefficients), uses a quasi-linear wake relaxation to solve for the rotor performance. The coupling was accomplished by expanding of the matrix of linearized influence coefficients in EHPIC to accommodate design variables and deriving new coefficients for linearized equations governing perturbations in power and thrust. These coefficients formed the input to a linear optimization analysis, which used the flow tangency conditions on the blade and in the wake to impose equality constraints on the expanded system of equations; user-specified inequality contraints were also employed to bound the changes in the design. It was found that this locally linearized analysis could be invoked to predict a design change that would produce a reduction in the power required by the rotor at constant thrust. Thus, an efficient search for improved versions of the baseline design can be carried out while retaining the accuracy inherent in a free wake/lifting surface performance analysis.

[1]  Peretz P. Friedmann,et al.  Application of modern structural optimization to vibration reduction in rotorcraft , 1984 .

[2]  Todd R. Quackenbush,et al.  A new methodology for free wake analysis using curved vortex elements , 1987 .

[3]  Mark W. Davis,et al.  Application of Design Optimization Techniques to Rotor Dynamics Problems , 1986 .

[4]  A. J. Landgrebe,et al.  Helicopter rotor wake geometry and its influence in forward flight. Volume 2: Wake geometry charts , 1983 .

[5]  Joanne L. Walsh,et al.  Optimization Methods Applied to the Aerodynamic Design of Helicopter Rotor Blades , 1987 .

[6]  Todd R. Quackenbush,et al.  Free wake analysis of hover performance using a new influence coefficient method , 1990 .

[7]  Holt Ashley,et al.  On Making Things the Best-Aeronautical Uses of Optimization , 1982 .

[8]  W. Z. Stepniewski,et al.  Multivariate Search and Its Application to Aircraft Design Optimisation , 1970, The Aeronautical Journal (1968).

[9]  Continuum Dynamics,et al.  Free Wake Calculation of Rotor Flow Fields for Interactional Aerodynamics , 1988 .

[10]  M. Scully,et al.  Computation of helicopter rotor wake geometry and its influence on rotor harmonic airloads , 1975 .

[11]  Leonard Spunt,et al.  Optimum structural design , 1971 .

[12]  Anton J. Landgrebe,et al.  An Analytical and Experimental Investigation of Helicopter Rotor Hover Performance and Wake Geometry Characteristics , 1971 .

[13]  Hirokazu Miura,et al.  Applications of numerical optimization methods to helicopter design problems: A survey , 1984 .

[14]  Sikorsky Aircraft Div.,et al.  Theory and Application of Optimum Airloads to Rotors in Hover and Forward Flight , 1982 .

[15]  Daniel A. Wachspress,et al.  A new approach to the free wake problem for hovering rotors , 1985 .