초록 ▼

Disclosed is a cone brake no-back for use with an actuation system. The actuation system may be an aircraft actuation system, for example. The no-back may include cone brakes capable of preventing undesired displacement of an aircraft surface (such as a flap, a leading edge, or a trailing edge of a

Disclosed is a cone brake no-back for use with an actuation system. The actuation system may be an aircraft actuation system, for example. The no-back may include cone brakes capable of preventing undesired displacement of an aircraft surface (such as a flap, a leading edge, or a trailing edge of a wing) in the event that an actuator input becomes disconnected or is otherwise insufficient to oppose the load created by the aircraft surface.

대표청구항 ▼

1. A no-back assembly comprising: a first disc coupled to a first shaft and arranged radially outward of the first shaft;a first brake arranged radially outward of the first disc, the first brake being configured to prevent the first disc from rotating when in a no-back condition; anda spring adjace

1. A no-back assembly comprising: a first disc coupled to a first shaft and arranged radially outward of the first shaft;a first brake arranged radially outward of the first disc, the first brake being configured to prevent the first disc from rotating when in a no-back condition; anda spring adjacent the first brake, the spring configured to urge the first brake toward the first disc to prevent the first disc from rotating when in the no-back condition. 2. The no-back assembly of claim 1 further including: a second disc coupled to a second shaft and arranged radially outward of the second shaft; anda second brake arranged radially outward of the second disc, the second brake being configured to prevent the second disc from rotating when in the no-back condition. 3. The no-back assembly of claim 2 further including that the first disc is an output disc, the first shaft is an output shaft, the second disc is an input disc, and the second shaft is an input shaft; and wherein the first disc is arranged radially outward of the first and second shafts. 4. The no-back assembly of claim 2 wherein, when in the no-back condition, the first and second brakes contact a respective one of the first and second discs such that the first and second shafts are substantially prevented from rotating. 5. The no-back assembly of claim 4 wherein the first shaft is urged in forward rotational direction by a forward input and is urged in a reverse rotational direction by a load, the reverse rotational direction opposite the forward rotational direction, the first shaft being operatively coupled to the second shaft. 6. The no-back assembly of claim 5 wherein, when in the no-back condition, there is no input. 7. The no-back assembly of claim 6 wherein each of the first and second brakes are rotatably fixed relative to the first and second discs and include a sloped surface on an inner periphery thereof, the sloped surfaces of the first and second brakes being inclined relative to an axis of the first and second shafts, each of the first and second discs including a sloped surface about the outer periphery thereof, the sloped surfaces of the first and second discs inclined to be substantially parallel to the sloped surfaces of respective first and second brakes. 8. The no-back assembly of claim 7 wherein, when in the no-back condition, the sloped surfaces of the first and second brakes contact respective sloped surfaces of the first and second discs such that a resistance torque is generated that is larger than a torque created by the load urging the first shaft in the reverse rotational direction. 9. The no-back assembly of claim 8 further including that each of the first and second discs include a ballramp formed therein, respective ballramps of the first and second discs being generally aligned with and facing one another. 10. The no-back assembly of claim 9 further including that a ball is positioned between the first and second discs such that the ball is supported partially by the ballramp of the first disc and partially by the ballramp of the second disc. 11. The no-back assembly of claim 10 wherein each of the ballramps are formed with a varying depth, the ballramps being deepest at a center portion, ends of the ballramps including sloped portions such that the ballramps taper downwardly from the ends to the center portion. 12. The no-back assembly of claim 11 wherein the first brake is axially slidable and rotatably fixed relative to a housing, the first brake is in contact with the spring on a first side of the first brake and is in contact with the first disc on a second side of the first brake, the second side of the first brake being generally opposite the first side of the first brake. 13. The no-back assembly of claim 12 wherein, when in the no-back condition, the ball is positioned such that it contacts the sloped portion of the ballramp of the first disc and the sloped portion of the ballramp of the second disc, and thereby the first disc is displaced in a first axial direction and causes the first brake to slide axially in the first axial direction toward the spring, the spring urges the first brake in a second axial direction opposite the first axial direction such that the sloped surfaces of the first and second brakes contact the sloped surfaces of respective first and second discs, thereby substantially preventing the first and second discs and the first and second shafts from rotating. 14. The no-back assembly of claim 1 wherein at least one of the first brake and the first disc includes a sloped surface on a periphery thereof, the sloped surface being inclined relative to an axis of the first shaft. 15. The no-back assembly of claim 14 including a sloped surface on an outer periphery of the first disc, and a sloped surface on an inner periphery of the first brake. 16. The no-back assembly of claim 1 wherein the first brake is disposed about the outer periphery of the first disc. 17. The no-back assembly of claim 1 wherein, when in the no-back condition, the first disc is urged in a first axial direction and the first brake is urged by the spring in a second axial direction opposite the first axial direction such that the brake is wedged into the disc, thereby preventing the disc from rotating. 18. A system comprising: an actuator including a shaft receiving an input and coupled to a load;a disc in communication with the shaft;a brake disposed about the outer periphery of the disc;a spring adjacent the brake; andwhen in a no-back condition, the brake is urged, by way of the spring, to contact the disc such that the disc and the shaft are substantially prevented from rotating. 19. The system of claim 18 wherein at least one of the disc and the brake includes a sloped surface on a periphery thereof, the sloped surface included relative to an axis of the shaft. 20. The system of claim 19 wherein the disc includes a sloped surface on an outer periphery thereof, and the brake includes a sloped surface on an inner periphery thereof. 21. The system of claim 20 wherein, when in the no-back condition, the disc is urged in a first axial direction and the brake is urged by the spring in a second axial direction opposite the first axial direction such that the brake is wedged into the disc, thereby preventing the disc from rotating. 22. A method comprising the steps of: a) rotating a disc in a first rotational direction when in a first operational state;b) moving the disc in a first axial direction when in a second operational state; andc) when in the second operational state, urging a brake in a second axial direction opposite the first axial direction such that the brake is wedged into the disc and thus prevents the disc from rotating. 23. The method of claim 22 wherein at least one of the disc and the brake includes a sloped surface on a periphery thereof, the sloped surface included relative to the first axial direction. 24. The method of claim 22 wherein the brake is urged in the second axial direction by way of a spring.