An electromechanical actuator incorporates a drive housing connected to a motor for rotational motion. A screw is employed with an actuating nut having protruding engagement bosses and a drive coupling is concentrically received within the drive housing having segments equal to the number of engagem
An electromechanical actuator incorporates a drive housing connected to a motor for rotational motion. A screw is employed with an actuating nut having protruding engagement bosses and a drive coupling is concentrically received within the drive housing having segments equal to the number of engagement bosses. Each segment has a cavity to receive a respective one of the engagement bosses and the segments are cooperatively positionable from an active position radially compressed to engage the bosses within the cavities to a released position radially expanded to disengage the bosses from the cavities.
대표청구항▼
1. An electromechanical actuator comprising: a drive housing connected to a motor for rotational motion;a screw and actuating nut, the actuating nut having a plurality of engagement bosses;a drive coupling concentrically received within the drive housing and having a plurality of segments equal to t
1. An electromechanical actuator comprising: a drive housing connected to a motor for rotational motion;a screw and actuating nut, the actuating nut having a plurality of engagement bosses;a drive coupling concentrically received within the drive housing and having a plurality of segments equal to the plurality of engagement bosses, each segment having a cavity to receive a respective one of the engagement bosses, the segments cooperatively positionable from an active position radially compressed to engage the bosses within the cavities to a released position radially expanded to disengage the bosses from the cavities;wherein each segment in the drive coupling has first and second opposing grooves in circumferential alignment; and,a plurality of push plates, each push plate received for sliding motion in the first groove and second groove, respectively, of adjacent segments of the plurality of segments, said push plates having a first position retaining the segments in the active position and a second position releasing the segments into the released position. 2. The electromechanical actuator of claim 1 wherein each push plate has at least one release hole and further comprising a plurality of release pins extending radially inward from an inner surface of the drive housing wherein said release pins engage each push plate in the first position and, upon sliding of the push plates in the grooves to the second position, align with the at least one release hole allowing radial expansion to the released position for the drive coupling. 3. The electromechanical actuator of claim 1 further comprising a cylindrical piston aligned with and engaging the push plates for sliding motion from the first position to the second position. 4. The electromechanical actuator of claim 1 further comprising resilient members urging the adjacent segments to expand upon sliding of the push plates to the second position. 5. The electromechanical actuator of claim 4 wherein each segment in the drive coupling has first and second opposed slots in circumferential alignment and wherein the resilient members comprise a plurality of springs received in the first and second opposed slots, respectively, of adjacent segments, said springs compressed in said active position and urging said segments into the released position upon sliding of the push plates to the second position. 6. The electromechanical actuator of claim 4 wherein the push plates each incorporate a tab, said tab extending from the grooves of the segments in the first position and further comprising a piston, said piston having a first position engaging the tabs in an extended position, said piston movable to a second position depressing the tabs to slide the push plates into said second position. 7. An electromechanical actuator comprising: a drive housing connected to a motor for rotational motion;a screw and actuating nut, the actuating nut having a plurality of engagement bosses;a drive coupling concentrically received within the drive housing and having a plurality of segments equal to the plurality of engagement bosses, each segment having a cavity to receive a respective one of the engagement bosses, the segments cooperatively positionable from an active position radially compressed to engage the bosses within the cavities to a released position radially expanded to disengage the bosses from the cavities and wherein each segment incorporates a torque engagement slot in an outer semi-cylindrical surface and wherein the drive housing incorporates a plurality of torque ribs equal in number to the plurality of segments, each torque rib extending from an inner surface of the drive housing in alignment with each respective torque engagement slot. 8. The electromechanical actuator of claim 7 wherein each segment in the drive coupling has first and second opposing grooves in circumferential alignment and further comprising: a plurality of push plates, each push plate received for sliding motion in the first groove and second groove, respectively, of adjacent segments of the plurality of segments, said push plates having a first position retaining the segments in the active position and a second position releasing the segments into the released position; and,resilient members urging the adjacent segments to expand upon sliding of the push plates to the second position. 9. The electromechanical actuator of claim 8 wherein each segment in the drive coupling has first and second opposed slots in circumferential alignment and wherein the resilient members comprise a plurality of springs received in the first and second opposed slots, respectively, of adjacent segments, said springs compressed in said active position and urging said segments into the released position upon sliding of the push plates to the second position. 10. The electromechanical actuator of claim 8 wherein the push plates each incorporate a tab, said tab extending from the grooves of the segments in the first position and further comprising a piston, said piston having a first position engaging the tabs in an extended position, said piston movable to a second position depressing the tabs to slide the push plates into said second position. 11. The electromechanical actuator of claim 8 further comprising a ring gear circumferentially extending from the drive housing for connection to the motor. 12. The electromechanical actuator of claim 8 wherein each push plate has at least one release hole and further comprising a plurality of release pins extending radially inward from an inner surface of the drive housing wherein said release pins engage each push plate in the first position and, upon sliding of the push plates in the grooves to the second position, align with the at least one release hole allowing radial expansion to the released position for the drive coupling; and,a cylindrical piston aligned with and engaging the push plates for sliding motion from the first position to the second position. 13. A jam release system for an electromechanical actuator comprising: a screw and actuating nut;a segmented expandable drive coupling having a plurality of segments concentrically engaging an equal plurality of bosses radially extending from a circumferential surface of the actuating nut, each segment having a cavity to receive a respective one of the engagement bosses, the segments cooperatively positionable from a first position radially compressed to engage the bosses within the cavities to a second radially expanded position to disengage the bosses from the cavities; and,a release mechanism responsive to a control signal, the release mechanism maintaining the drive coupling in the first active position and releasing the drive coupling upon receipt of the control signal. 14. The jam release system for an electromechanical actuator defined in claim 13 wherein each segment in the drive coupling has first and second opposing grooves in circumferential alignment and the release mechanism comprises: a plurality of push plates, each push plate received for sliding motion in the first groove and second groove, respectively, of adjacent segments of the plurality of segments, said push plates having a first position retaining the segments in the first active position and a second position releasing the segments into the second radially expanded position. 15. The jam release system for an electromechanical actuator defined in claim 14 wherein the release mechanism further comprises resilient members urging the adjacent segments to expand upon sliding of the push plates to the second position. 16. The jam release system for an electromechanical actuator defined in claim 14 wherein each segment in the drive coupling has first and second opposed slots in circumferential alignment and further comprising a plurality of springs received in the first and second slots, respectively, of adjacent segments of the plurality of segments, said springs compressed in said first active position and urging said segments into the second radially expanded position upon sliding of the push plates to the second position. 17. The jam release system for an electromechanical actuator defined in claim 16 wherein each push plate has at least one release hole and further comprising: a plurality of release pins extending radially inward from an inner surface of a drive housing concentrically containing the drive coupling wherein said release pins engage each push plate in the first position and, upon sliding of the push plates in the grooves to the second position, align with the at least one release hole allowing radial expansion to the released position for the drive coupling. 18. The jam release system for an electromechanical actuator defined in claim 17 wherein each push plate incorporates a tab, said tab extending from the grooves of the segments in the first position and the release mechanism further comprises a piston, said piston having a first position engaging the tabs in the first position, said piston movable to a second position depressing the tabs to slide the push plates into said second position.
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이 특허에 인용된 특허 (11)
Reed ; Jr. Richard G., Electro-mechanical clutch actuator.
Blanding,David E.; Watanabe,Atsuo J., Fault-tolerant electro-mechanical actuator having motor armatures to drive a ram and having an armature release mechanism.
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