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In a vehicle, having a fixed supporting structure and a load movable relative thereto, a jam tolerant actuating system, a method for controlling this system including: Locating a physical coupling/decoupling mechanism between the load and an actuator assembly as close a practicable to the load; cons

In a vehicle, having a fixed supporting structure and a load movable relative thereto, a jam tolerant actuating system, a method for controlling this system including: Locating a physical coupling/decoupling mechanism between the load and an actuator assembly as close a practicable to the load; constructing the coupling/uncoupling mechanism to be reversible, and hence testable; and controlling the connection/disconnection via decision making electronics which will detect any system failure by monitoring, at a minimum: actuator main motor load and speed, and actuator output load. Also set forth are specific embodiments of pivotable rotary geared actuators as well as linear ball screw type actuators embodying the coupling/uncoupling mechanisms of this invention.

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1. An electromechanical actuator assembly, comprising: an actuator for attachment to a control surface,an electric motor providing control-surface motion,a load path for transferring the control-surface motion to the actuator,a coupling/decoupling mechanism including engageable and disengageble memb

1. An electromechanical actuator assembly, comprising: an actuator for attachment to a control surface,an electric motor providing control-surface motion,a load path for transferring the control-surface motion to the actuator,a coupling/decoupling mechanism including engageable and disengageble members that when disengaged from one another upon detection of a malfunction the load path is severed and when engaged to one another thereafter the load path is reestablished, anda coupling/decoupling gear train for transferring coupling/decoupling motion to the coupling/decoupling mechanism to engaged/disengage the members from one another. 2. An electromechanical actuator assembly as set forth in claim 1, wherein the load path further comprises a gear train. 3. An electromechanical actuator assembly as set forth in claim 2, wherein the gear train comprises speed-reducing gears. 4. An electromechanical actuator assembly as set forth in claim 2, wherein the load path further comprises a ballscrew that receives rotational movement from the gear train and a ballnut that moves linearly in response to rotational movement of the ballscrew. 5. An electromechanical actuator assembly as set forth in claim 4, wherein the ballnut is decoupled from the actuator by the coupling/decoupling mechanism upon detection of the malfunction. 6. An electromechanical actuator assembly as set forth in claim 1, further comprising a disconnect motor for providing the coupling/decoupling motion to the coupling/decoupling gear train. 7. In combination, a control surface and a pair of the electromechanical actuator assemblies set forth in claim 1, wherein both actuators are attached to the control surface whereby, upon decoupling of one load path upon detection of the malfunction, the control-surface motion can still be provided through the other load path. 8. In combination, a controller and the electromechanical actuator assembly set forth in claim 1, wherein the controller controls the motor and also controls the transfer of coupling/decoupling motion through the coupling/decoupling gear train. 9. The combination set forth in claim 8, further comprising a computer, and wherein the controller relays data regarding input-output loads to the computer, and wherein the computer compares this data to detect a malfunction. 10. The combination set forth in claim 9, wherein the data comprises motor speed, motor current, actuator output load, and/or actuator output position. 11. A vehicle comprising a control surface and the electromechanical actuator assembly set forth in claim 1, wherein the control surface is attached to the actuator and moves in response to control-surface motion provided by the motor and transferred through the load path. 12. A vehicle as set forth in claim 11, wherein the vehicle is an aircraft. 13. A vehicle as set forth in claim 12, wherein the control surface is a primary control surface. 14. A vehicle as set forth in claim 13, wherein the control surface is a secondary control surface. 15. A method of testing the electromechanical actuator assembly in the aircraft set forth in claim 12, said method comprising disengaging the members of the decoupling/coupling mechanism from one another to sever the load path and thereafter reengaging the members of the coupling/decoupling mechanism to one another to reestablish the load path for operation. 16. A method of testing as set forth in claim 15, wherein said steps are performed prior to each flight. 17. An aircraft comprising a control surface and a pair of the electromechanical actuator assemblies set forth in claim 1, wherein the control surface is attached to both actuators, whereby, upon decoupling of one load path upon detection of the malfunction, the control-surface motion can still be provided through the other load path. 18. An electromechanical actuator assembly, comprising: an actuator for attachment to a control surface,an electric motor providing control-surface motion,a load path for transferring the control-surface motion to the actuator,a coupling/decoupling mechanism for severing the load path upon detection of a malfunction and reestablishing the load path thereafter,a coupling/decoupling gear train for transferring coupling/decoupling motion to the coupling/decoupling mechanism, anda disconnect motor for providing the coupling/decoupling motion to the coupling/decoupling gear train. 19. A method of testing an electromechanical actuator assembly in an aircraft having a control surface, the electromechanical actuator assembly including an actuator for attachment to the control surface, an electric motor providing control-surface motion, a load path for transferring the control-surface motion to the actuator wherein the control surface is attached to the actuator and moves in response to control-surface motion provided by the motor and transferred through the load path, a coupling/decoupling mechanism for severing the load path upon detection of a malfunction and reestablishing the load path thereafter, and a coupling/decoupling gear train for transferring coupling/decoupling motion to the coupling/decoupling mechanism, said method comprising: decoupling the decoupling/coupling mechanism to sever the load path, and thereafterrecoupling the coupling/decoupling gear train to reestablish the load path for operation,wherein said steps are performed prior to each flight.