A no-back device for a power drive unit is configured such that, during operation of the power drive unit, the no-back device does not supply magnetic or frictional force against power drive unit rotation. The no-back device is implemented either redundantly or no-redundantly, and includes a latch r
A no-back device for a power drive unit is configured such that, during operation of the power drive unit, the no-back device does not supply magnetic or frictional force against power drive unit rotation. The no-back device is implemented either redundantly or no-redundantly, and includes a latch rotor and an electromagnet. In both embodiments, the latch rotor is coupled to the power drive unit to rotate therewith, and the electromagnet is coupled to receive a flow of current and, upon receipt thereof, generates a magnetic field force that opposes rotation of the latch rotor. In the redundant embodiment, the no-back device further includes one or more permanent magnets, and the magnetic field generated by the electromagnet selectively opposes or aids the magnetic field supplied by the permanent magnet(s).
대표청구항▼
We claim: 1. An actuator assembly, comprising: a power drive unit adapted to receive drive power and configured, upon receipt of the drive power, to rotate; an actuator coupled to the power drive unit and configured, in response to power drive unit rotation, to move to a position; a latch rotor cou
We claim: 1. An actuator assembly, comprising: a power drive unit adapted to receive drive power and configured, upon receipt of the drive power, to rotate; an actuator coupled to the power drive unit and configured, in response to power drive unit rotation, to move to a position; a latch rotor coupled to the power drive unit to rotate therewith, the latch rotor comprising a main body having N-number of lobes extending radially therefrom, N being a number greater than one; (N/2)-number of permanent magnet pole pairs spaced apart from and at least partially surrounding the latch rotor, each of the permanent magnet pole pairs supplying a permanent magnetic field that opposes rotation of the latch rotor; and an electromagnet adapted to receive a flow of electrical current and configured, upon receipt thereof, to generate a magnetic field that simultaneously opposes all of the permanent magnetic fields supplied from the permanent magnet pole pairs or simultaneously aids all of the permanent magnetic fields supplied from the permanent magnet pole pairs, the electromagnet comprising: a latch stator non-rotationally mounted adjacent to, and at least partially surrounding, the latch rotor, the latch stator having the permanent magnet pole pairs mounted thereon, and a plurality of latch windings wound around at least a portion of the latch stator, the latch windings disposed adjacent the magnet pole pairs and adapted to receive the flow of electrical current, the latch windings wound on the latch stator such that, upon receipt of the flow of electrical current, the latch windings simultaneously generate the same number of magnetic pole pairs as there are permanent magnet pole pairs. 2. The actuator assembly of claim 1, wherein at least a portion of each of the plurality of lobes comprises a magnetically permeable material. 3. The actuator assembly of claim 1, wherein the actuator comprises: an actuation member coupled to the power drive unit and configured, in response to rotation of the power drive unit, to rotate. 4. The actuator assembly of claim 3, wherein the actuator further comprises: a translation member disposed adjacent the actuation member and configured, upon rotation of the actuation member, to translate to a position. 5. The actuator assembly of claim 4, wherein: the actuation member comprises a ballscrew; and the translation member comprises a ballnut mounted against rotation on the ballscrew and configured, upon rotation of the ballscrew, to translate to the position. 6. An actuator drive unit assembly, comprising: a power drive unit adapted to receive drive power and configured, upon receipt of the drive power, to rotate; a latch rotor coupled to the power drive unit to rotate therewith, the latch rotor having N-number of lobes extending radially therefrom, N being a number greater than one; (N/2)-number of permanent magnet pole pairs spaced apart from and at least partially surrounding the latch rotor, each of the permanent magnet pole pairs supplying a permanent magnetic field that opposes rotation of the latch rotor; and an electromagnet adapted to receive a flow of electrical current and, upon receipt thereof, to generate a magnetic field that simultaneously opposes all of the permanent magnetic fields supplied from the permanent magnet pole pairs or simultaneously aids all of the permanent magnetic fields supplied from the permanent magnet pole pairs, the electromagnet comprising: a latch stator non-rotationally mounted adjacent to, and at least partially surrounding, the latch rotor, the latch stator having the permanent magnet pole pairs mounted thereon, and a plurality of latch windings wound around at least a portion of the latch stator, the latch windings disposed adjacent the magnet pole pairs and adapted to receive the flow of electrical current, the latch windings wound on the latch stator such that, upon receipt of the flow of electrical current, the latch windings simultaneously generate the same number of magnetic pole pairs as there are permanent magnet pole pairs. 7. The assembly of claim 6, wherein at least a portion of each of the plurality of lobes comprises a magnetically permeable material. 8. An actuation control system, comprising: a control circuit adapted to receive input signals and operable, in response thereto, to selectively supply drive control signals and latch control signals; a power drive unit coupled to receive the drive control signals and operable, in response to the drive control signals, to rotate; a latch rotor coupled to the power drive unit to rotate therewith; a plurality of permanent magnets spaced apart from and at least partially surrounding the latch rotor, each of the permanent magnets supplying a permanent magnetic field that opposes rotation of the latch rotor; and a latch electromagnet coupled to receive the selectively supplied latch control signals and configured, when the latch control signals are supplied, to generate a magnetic field that (i) simultaneously opposes the permanent magnetic fields supplied from all of the permanent magnets or simultaneously aids the permanent magnetic fields supplied from all of the permanent magnets and (ii) does not induce a torque in the latch rotor wherein the latch electromagnet comprises: a latch stator non-rotationally mounted adjacent to, and at least partially surrounding, the latch rotor, and a plurality of latch windings wound around at least a portion of the latch stator, the latch windings coupled to receive the selectively supplied latch control signals and configured, when the latch control signals are supplied, to generate the magnetic field, wherein the permanent magnets are mounted on the latch stator and are disposed adjacent each of the latch windings. 9. The system of claim 8, wherein: each of the one or more permanent magnets has one or more pole pairs; and the coils are wound on the latch stator such that, upon receipt of the latch control signals, the coils generate the same number of magnetic pole pairs as there are permanent magnets. 10. The system of claim 8, wherein: the latch rotor comprises a main body having a plurality of lobes extending radially therefrom. 11. The assembly of claim 10, wherein at least a portion of each of the plurality of lobes comprises a magnetically permeable material. 12. The system of claim 8, further comprising: a power source coupled to receive the latch control signals and operable, upon receipt thereof, to supply the flow of electrical current to the electromagnet.
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이 특허에 인용된 특허 (49)
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