US 11,884,385 B2
Active vibration control system with non-concentric revolving masses
David E. Heverly, II, Arlington, TX (US); Jeremy DeWaters, Hummelstown, PA (US); and Frank B. Stamps, Colleyville, TX (US)
Assigned to Textron Innovations Inc., Providence, RI (US)
Filed by Bell Textron Inc., Fort Worth, TX (US)
Filed on Sep. 21, 2020, as Appl. No. 17/026,394.
Application 17/026,394 is a continuation of application No. 16/054,606, filed on Aug. 3, 2018, granted, now 10,814,963.
Application 16/054,606 is a continuation of application No. 14/600,180, filed on Jan. 20, 2015, granted, now 10,065,730, issued on Sep. 4, 2018.
Claims priority of provisional application 61/930,004, filed on Jan. 22, 2014.
Prior Publication US 2021/0001976 A1, Jan. 7, 2021
Int. Cl. B64C 27/00 (2006.01); B64C 29/00 (2006.01)
CPC B64C 27/001 (2013.01) [B64C 29/0033 (2013.01); B64C 2027/003 (2013.01)] 3 Claims
OG exemplary drawing
 
1. An active vibration control system comprising:
a rotor hub of a tiltrotor aircraft, the rotor hub being configured to be driven in rotation by a mast about a mast axis of rotation, the rotor hub comprising:
a standpipe including a mast portion disposed in the mast and a narrowed portion disposed beyond the mast, the standpipe being stationary; and
bearings disposed between the standpipe and the mast, the bearings configured to allow for rotation of the mast relative to the standpipe;
a force generator attached to the narrowed portion of the standpipe, the force generator comprising:
(a) a first motor;
(b) a second motor;
(c) a first weight configured to be independently driven about a first axis of rotation by the first motor;
(d) a second weight configured to be independently driven about a second axis of rotation by the second motor;
(e) a third weight independently driven about a third axis of rotation by a third motor and being diametrically opposed to the first weight; and
(f) a fourth weight independently driven about a fourth axis of rotation by a fourth motor and being diametrically opposed to the second weight;
wherein the first weight and the third weight form a first set, and the second weight and the fourth weight form a second set and wherein the first axis of rotation and the second axis of rotation are non-concentric to the mast axis of rotation and normal to the mast axis of rotation;
a controller attached to the narrowed portion of the standpipe;
the controller for receiving input signals and outputting command signals independently to the first motor, the second motor, the third motor, and the fourth motor to control a generated oscillatory shear force of the force generator; and
a sensor for measuring vibration and providing input to the controller;
wherein during operation the first set is rotated about the mast axis of rotation at a different rotational speed than the second set, allowing the generated oscillatory shear force of the force generator to attenuate vibrations at multiple frequencies;
wherein during operation the first set is rotated about the mast axis of rotation in an opposite rotational direction than the second set;
wherein the axis of rotation for each of the first weight, the second weight, the third weight, and the fourth weight are offset from the mast axis a same radial distance;
wherein a first relative position of the first weight and the third weight in the first set and a second relative position of the second weight and the fourth weight of the second set have zero additional positional relationship constraints other than being the same radial distance from the mast axis and being diametrically opposed from one another; and
wherein during operation the force generator produces oscillatory shear forces on the standpipe that are transferred into the mast through the bearings.