Abstract : A methodology is developed to perform minimum-weight structural design for composite or metallic main rotor blades subject to aerodynamic performance, material strength, autorotation, and frequency constraints. The constraints and load cases are developed such that the final preliminary rotor design will satisfy U.S. Army military specifications. In addition, the methodology uses design variables which can take advantage of the versatility of composite materials. A minimum-weight design is first developed subject to satisfying the aerodynamic performance, strength, and autorotation constraints for all static load cases. The minimum-weight design is then dynamically tuned to avoid resonant frequencies occurring at the design rotor speed. With this design methodology, three rotor blade designs were developed based on the geometry of the UH-60A Black Hawk titanium-spar rotor blade. The first design is of a single titanium-spar cross section, which is compared with the UH-60A Black Hawk rotor blade. The second and third designs use single and multiple graphite/epoxy-spar cross sections. These are compared with the titanium-spar design to demonstrate weight savings from use of this design methodology in conjunction with advanced composite materials.
[1]
J. E. Griffith,et al.
Mechanics of Composite Materials.
,
1971
.
[2]
R. H. Blackwell,et al.
Blade Design for Reduced Helicopter Vibration
,
1983
.
[3]
R. Bielawa,et al.
Techniques for stability analysis and design optimization with dynamic constraints of nonconservative linear systems
,
1971
.
[4]
O. K. McCaskill.
Composite Applications at Bell Helicopter
,
1979
.
[5]
David A. Peters,et al.
Design of helicopter rotor blades for desired placement of natural frequencies
,
1984
.
[6]
P. Shanthakumaran,et al.
Aeroelastic tailoring of rotor blades for vibration reduction in forward flight
,
1983
.