Abstract
Introduction A RECENT review 1 of wing rock of advanced aircraft, such as X-29A, X-31, and F-18 HARV, showed that wing rock occurs rst at moderate angles of attack through dynamic stall of outer wing panels with moderately swept leading edges. This is illustrated by the experimental results for the X-29A aircraft (Fig. 1). When this type of wing rock was suppressed by the use of the aperons, forebody-induced wing rock occurred at higher angles of attack, a > 35 deg (Fig. 1b). The driving ow mechanism for the wing rock at these high angles of attack is the moving wall effect on the forebody cross ow separation at a > uA, where uA is the forebody apex half-angle. The wing rock reaches its maximum amplitude at an angle of attack just below that for which static asymmetric cross ow separation occurs, i.e., at a 2uA, the moving wall effect has to overcome the static cross ow asymmetry. This is the reason for the rapid decrease of the limit cycle amplitude for a > 55 deg in Fig. 1b. In the analysis in Ref. 1 of the experimentally observed wing rock of a generic aircraft model (Fig. 2), a certain roll-damping value had to be assumed to obtain a limit-cycle oscillation. In the wind-tunnel test bearing friction could have supplied the needed roll damping. However, in free ight, the roll damping has to be generated by other means to obtain an oscillation of the limit-cycle type. As discussed in Ref. 1, the only source of this roll damping at high angles of attack is the deep-stall damping-in-plunge of the outboard wing sections. The wing on the generic aircraft model (Fig. 2) has a atplate airfoil section. It and the inverted 7.4% Clark Y airfoil have very similar deep-stall cl(a) characteristics 9 (Fig. 3). Judging by the deep-stall characteristics for the NACA 0012 and NACA 0015 airfoil sections (Fig. 4), the mean cl(a) slope at a > 8 deg in Fig. 3 should give a conservative estimate for the at-plate airfoil section, i.e., cla ’ 0.95. As the tangential force is negligibly small, cna ’ 0.95/cos a. For the plunging wing section during wing rock, the sectional normal force at the spanwise location y = hb/2, where b is the wing span, is
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