Thrust reverser system electro-mechanical brake manual release mechanism
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02K-001/70
F02K-001/00
F02K-001/76
출원번호
US-0925700
(2004-08-24)
발명자
/ 주소
Hanlon,Casey
Christensen,Donald J.
Chakkera,Kevin K.
출원인 / 주소
Honeywell International, Inc.
대리인 / 주소
Ingrassia Fisher &
인용정보
피인용 횟수 :
7인용 특허 :
13
초록▼
A manual release mechanism for a thrust reverser actuation system electromechanical brake includes a first release plate, a second release plate, at least two balls, and a handle. The first and second release plates each have grooves formed therein that have a cam surface located at a predetermined
A manual release mechanism for a thrust reverser actuation system electromechanical brake includes a first release plate, a second release plate, at least two balls, and a handle. The first and second release plates each have grooves formed therein that have a cam surface located at a predetermined angle. The release plates face one another such that the grooves in each plate are substantially aligned, and the balls are each positioned in the aligned grooves. The first release plate is configured to rotate, and the second release plate is configured to translate. The handle is coupled to the first release plate to allow manual rotation thereof. In response to rotation of the first release plate, the second release plate will translate and disengage the electromechanical brake.
대표청구항▼
We claim: 1. A system for moving an aircraft thrust reverser, comprising: a power drive unit operable to rotate and thereby supply a rotational drive force; a thrust reverser actuator assembly coupled to receive the rotational drive force and operable, in response thereto, to selectively move the t
We claim: 1. A system for moving an aircraft thrust reverser, comprising: a power drive unit operable to rotate and thereby supply a rotational drive force; a thrust reverser actuator assembly coupled to receive the rotational drive force and operable, in response thereto, to selectively move the thrust reverser between a stowed position and a deployed position; an electromechanical brake coupled to the power drive unit, the electromechanical brake configured to receive a brake release command and operable, in response thereto, to selectively move between an engage and a disengage position, to thereby prevent and allow, respectively, rotation of the power drive unit; and a manual brake release mechanism disposed proximate the electromechanical brake and configured to selectively move the electromechanical brake between the engage and disengage position, the manual brake release mechanism including: a first release plate configured to selectively rotate in either a first or a second rotational direction in response to an input force, and a second release plate coupled to the first release plate and configured to move in either a first or a second translational direction in response to the first release plate rotating in the first or second rotational direction, respectively, to move the electromechanical brake to the disengage or engage position, respectively. 2. The system of claim 1, further comprising: a handle coupled to, and extending from, the first release plate to allow manual rotation thereof. 3. The system of claim 1, wherein the electromechanical brake comprises: a housing; a rotor plate rotationally mounted within the housing and coupled to receive the rotational drive force; an armature mounted against rotation within the housing and disposed proximate the rotor plate, the armature configured to move between (i) an engage position, in which the armature engages the rotor plate to prevent rotation thereof, and (ii) a disengage position, in which the armature does not engage the rotor plate to allow rotation thereof; one or more brake springs disposed within the housing and configured to supply a bias force that biases the armature toward the engaged position; and an armature coil disposed within the housing, the armature coil configured to be selectively energized, to thereby generate a magnetic force that moves the armature to the disengaged position. 4. The system of claim 3, wherein: the first release plate includes an exterior side, and an interior side having at least two grooves formed therein, the grooves each having a cam surface; the second release plate includes an exterior side, and an interior side opposed to the first release plate interior side and having at least two grooves formed therein that are substantially aligned with at least two of the grooves in the first release plate, the grooves in the second release plate each having a cam surface; and the manual brake further includes at least two balls, each positioned in the aligned grooves. 5. The system of claim 4, further comprising: an engagement pin coupled to the armature and extending therefrom, the engagement pin having an engagement end disposed at least proximate the second release plate, wherein the second release plate engages the armature via the engagement pin, to thereby move the electromechanical brake to the disengage position. 6. The system of claim 3, wherein the electromechanical brake further comprises: a second rotor plate rotationally mounted within the housing; a first stator plate mounted against rotation within the housing and disposed between the rotor plates; a second stator plate mounted against rotation within the housing and disposed between the second rotor plate and the second release plate exterior side; an engagement pin coupled to the armature and extending therefrom, the engagement pin having an engagement end disposed at least proximate the second release plate, wherein the second release plate engages the armature via the engagement pin, to thereby move the electromechanical brake to the disengage position. 7. The system of claim 6, wherein the engagement pin extends through at least a portion of the first and second stator plates. 8. The system of claim 6, further comprising: a plurality of spaced-apart index openings formed in the second release plate exterior side; and an index pin coupled to the second stator plate, the index pin extending at least partially into one of the index openings. 9. The system of claim 8, wherein the second release plate and second stator plate each have an outer peripheral surface, and wherein the system further comprises: a plurality of index opening notches formed on the second release plate outer peripheral surface, each index opening notch radially aligned with one of the index openings; and an index pin notch formed on the second stator plate outer peripheral surface, the index pin notch radially aligned with the index pin. 10. The system of claim 3, further comprising: a handle coupled to, and extending from, the first release plate to allow manual rotation thereof; a lock button disposed within, and extending at least partially from, the handle; and a handle detent formed in the housing and configured to receive at least a portion of the lock button therein. 11. The system of claim 10, further comprising: a handle spring coupled between the handle and the housing and configured to bias the first release plate to rotate in the second rotational direction. 12. The system of claim 11, wherein the handle spring has a first end and a second end, the handle spring first end coupled to the handle, and wherein the system further comprises: a release mechanism mount disposed within the housing and extending at least partially through the first and second release plates; and a plurality of slots formed on the release mechanism mount, wherein the handle spring second end is disposed at least partially within one of the slots. 13. A thrust reverser system electromagnetic brake assembly, comprising: a housing; a rotor plate rotationally mounted within the housing; an armature mounted against rotation within the housing and disposed proximate the rotor plate, the armature configured to move between (i) an engage position, in which the armature engages the rotor plate to prevent rotation thereof, and (ii) a disengage position, in which the armature does not engage the rotor plate to allow rotation thereof; one or more springs disposed within the housing and configured to supply a bias force that biases the armature toward the engaged position; an armature coil disposed within the housing, the armature coil configured to be selectively energized, to thereby generate a magnetic force that moves the armature to the disengaged position; and a manual brake release mechanism disposed proximate the electromechanical brake and configured to selectively move the armature between the engage and disengage position, the manual brake release mechanism including: a first release plate configured to selectively rotate in either a first or a second rotational direction in response to an input force, and a second release plate coupled to the first release plate and configured to move in either a first or a second translational direction in response to the first release plate rotating in the first or second rotational direction, respectively, to thereby move the armature to the disengage or engage position, respectively. 14. The brake assembly of claim 13, wherein: the first release plate includes an exterior side, and an interior side having at least two grooves formed therein, the grooves each having a cam surface; the second release plate includes an exterior side, and an interior side opposed to the first release plate interior side and having at least two grooves formed therein that are substantially aligned with at least two of the grooves in the first release plate, the grooves in the second release plate each having a cam surface; and the manual brake further includes at least two balls, each positioned in the aligned grooves. 15. The system of claim 14, further comprising: an engagement pin coupled to the armature and extending therefrom, the engagement pin having an engagement end disposed at least proximate the second release plate, wherein the second release plate engages the armature via the engagement pin, to thereby move the electromechanical brake to the disengage position. 16. The system of claim 13, wherein the electromechanical brake further comprises: a second rotor plate rotationally mounted within the housing; a first stator plate mounted against rotation within the housing and disposed between the rotor plates; a second stator plate mounted against rotation within the housing and disposed between the second rotor plate and the second release plate exterior side; an engagement pin coupled to the armature and extending therefrom, the engagement pin having an engagement end disposed at least proximate the second release plate, wherein the second release plate engages the armature via the engagement pin, to thereby move the electromechanical brake to the disengage position. 17. The system of claim 16, wherein the engagement pin extends through at least a portion of the first and second stator plates. 18. The system of claim 16, further comprising: a plurality of spaced-apart index openings formed in the second release plate exterior side; and an index pin coupled to the second stator plate, the index pin extending at least partially into one of the index openings. 19. The system of claim 18, wherein the second release plate and second stator plate each have an outer peripheral surface, and wherein the system further comprises: a plurality of index opening notches formed on the second release plate outer peripheral surface, each index opening notch radially aligned with one of the index openings; and an index pin notch formed on the second stator plate outer peripheral surface, the index pin notch radially aligned with the index pin. 20. The system of claim 13, further comprising: a handle coupled to, and extending from, the first release plate to allow manual rotation thereof; a lock button disposed within, and extending at least partially from, the handle; and a handle detent formed in the housing and configured to receive at least a portion of the lock button therein. 21. The system of claim 20, further comprising: a handle spring coupled between the handle and the housing and configured to bias the first release plate to rotate in the second rotational direction. 22. The system of claim 21, wherein the handle spring has a first end and a second end, the handle spring first end coupled to the handle, and wherein the system further comprises: a release mechanism mount disposed within the housing and extending at least partially through the first and second release plates; and a plurality of slots formed on the release mechanism mount, wherein the handle spring second end is disposed at least partially within one of the slots. 23. A thrust reverser system manual brake release mechanism, comprising: a first release plate including an exterior side and an interior side; at least two grooves formed in the first release plate interior side, the grooves each having a cam surface located at a predetermined angle; a second release plate including an exterior side and an interior side, the second release plate interior side positioned opposed to the first release plate interior side; at least two grooves formed in the second release plate interior side and substantially aligned with at least two of the grooves in the first release plate, the grooves in the second release plate each having a cam surface located at a predetermined angle; at least two balls, each positioned in the aligned grooves; a handle coupled to, and extending from, the first release plate to allow manual rotation thereof; an alignment mechanism extending at least partially through the first and second release plates; a plurality of slots formed on the manual brake alignment mechanism; and a spring having a first end and a second end, the spring first end coupled to the handle, the spring second end disposed within one of the manual brake alignment mechanism slots.
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