University of Washington through its Center for Commercialization
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초록▼
Multiple embodiments of ferromagnetic shape memory alloy (FSMA) based torque actuators are described. These torque actuators include a magnetic trigger and an FSMA member, which when actuated by the magnetic trigger, produces a torque for rotating a member. Examples of magnetic triggers include hybr
Multiple embodiments of ferromagnetic shape memory alloy (FSMA) based torque actuators are described. These torque actuators include a magnetic trigger and an FSMA member, which when actuated by the magnetic trigger, produces a torque for rotating a member. Examples of magnetic triggers include hybrid magnetic triggers having at least one electromagnet and at least one permanent magnet. The FSMA member can be configured as a coil (or plate) spring and can be fabricated of a true FSMA alloy (i.e., an alloy that exhibits both ferromagnetic and shape memory properties) or of an FSMA composite that includes a ferromagnetic portion and an SMA portion. Several embodiments include a central orifice in which the FSMA member and an axial rod configured to rotate when actuated are disposed; the magnetic trigger system is disposed about the periphery of the orifice.
대표청구항▼
The invention in which an exclusive right is claimed is defined by the following: 1. A torque actuator comprising: (a) a magnetically actuatable member configured to impart a rotational motion when actuated, the magnetically actuatable member comprising a shape memory alloy; and (b) a magnetic trig
The invention in which an exclusive right is claimed is defined by the following: 1. A torque actuator comprising: (a) a magnetically actuatable member configured to impart a rotational motion when actuated, the magnetically actuatable member comprising a shape memory alloy; and (b) a magnetic trigger configured to selectively actuate the magnetically actuatable member, the magnetic trigger including a yoke configured to couple a magnetic flux from the magnetic trigger to the shape memory alloy. 2. The torque actuator of claim 1, wherein the magnetically actuatable member further comprises a ferromagnetic material. 3. The torque actuator of claim 1, wherein the shape memory alloy comprises at least one of: (a) a ferromagnetic shape memory alloy that exhibits both ferromagnetic and shape memory properties; and (b) a ferromagnetic shape memory alloy composite including a ferromagnetic portion and a shape memory alloy portion. 4. The torque actuator of claim 3, wherein the shape memory alloy comprises a super elastic grade of shape memory alloy. 5. The torque actuator of claim 1, wherein the magnetically actuatable member further comprises a ferromagnetic mass coupled with the shape memory alloy such that the ferromagnetic mass and the shape memory alloy move together, the ferromagnetic mass being configured to be attracted to the magnetic trigger when the magnetic trigger is activated. 6. The torque actuator of claim 1, wherein the magnetically actuatable member is disposed in a central orifice having a periphery, and the magnetic trigger is disposed about the periphery of the central orifice. 7. The torque actuator of claim 6, further comprising a shaft disposed in the central orifice, a first end of the magnetically actuatable member being coupled to the periphery of the central orifice, and a second end of the magnetically actuatable member being coupled to the shaft, such that actuation of the magnetically actuatable member causes the shaft to rotate. 8. The torque actuator of claim 6, further comprising an additional magnetically actuatable member disposed in the central orifice, the additional magnetically actuatable member being configured to increase an amount of torque generated by the torque actuator. 9. The torque actuator of claim 1, wherein the magnetic trigger comprises an electromagnet and a permanent magnet. 10. The torque actuator of claim 9, wherein the magnetic trigger includes at least one of: (a) a plurality of electromagnets; (b) a plurality of permanent magnets; and (c) a ring shaped permanent magnet. 11. The torque actuator of claim 10, wherein the plurality of electromagnets are configured to be energized simultaneously. 12. The torque actuator of claim 10, further comprising a control circuit for selectively energizing the plurality of electromagnets, the control circuit enabling less than all of the electromagnets to be energized simultaneously. 13. The torque actuator of claim 1, wherein the magnetically actuatable member comprises a coiled plate spring. 14. The torque actuator of claim 13, wherein the coiled plate spring comprises at least one of: (a) a plurality of ferromagnetic masses into which shape memory alloy elements have been introduced; and (b) a shape memory alloy plate coupled with a plurality of ferromagnetic masses. 15. The torque actuator of claim 14, wherein the shape memory alloy plate comprises a super elastic grade of shape memory alloy. 16. The torque actuator of claim 1, wherein the magnetic trigger produces a magnetic field strength sufficient to induce a stress-induced Martensitic transformation in the shape memory alloy when the magnetically actuatable member is actuated. 17. The torque actuator of claim 1, wherein the magnetic trigger further includes a permanent magnet portion and an electromagnet portion, the yoke further comprising a frame including a magnetically permeable portion configured to establish magnetic flux paths between the electromagnet portion and the permanent magnet portion of the magnetic trigger. 18. The torque actuator of claim 17, wherein the frame further comprises a non-magnetically permeable portion, the non-magnetically permeable portion being formed from a material having a lower density than the magnetically permeable portion, to reduce an overall mass of the torque actuator. 19. A rotary actuator comprising: (a) a rotating member configured to be selectively rotated; (b) a magnetically actuatable member configured to rotate the rotating member when actuated, the magnetically actuatable member comprising a shape memory alloy; and (c) a hybrid magnetic trigger configured to selectively actuate the magnetically actuatable member, the hybrid magnetic trigger comprising a permanent magnet portion, an electromagnet portion, and a yoke configured to couple a magnetic flux from the hybrid magnetic trigger to the shape memory alloy. 20. The rotary actuator of claim 19, wherein the magnetically actuatable member comprises a plate spring. 21. The rotary actuator of claim 20, wherein the plate spring comprises at least one of: (a) a plurality of ferromagnetic masses that include shape memory alloy wires comprising a super elastic grade of shape memory alloy; and (b) a shape memory alloy plate coupled with a plurality of ferromagnetic masses. 22. The rotary actuator of claim 19, wherein the magnetically actuatable member and the rotating member are disposed in a central orifice, and the magnetic trigger is disposed about a periphery of the central orifice. 23. The rotary actuator of claim 19, wherein the magnetic trigger includes at least one of: (a) a plurality of electromagnets; (b) a plurality of permanent magnets; and (c) a ring shaped permanent magnet. 24. The rotary actuator of claim 19, further comprising an additional magnetically actuatable member configured to increase a torque produced by the rotary actuator. 25. The rotary actuator of claim 19, wherein the magnetic trigger comprises a plurality of electromagnets, and the plurality of electromagnets are configured to be energized simultaneously. 26. A method for rotating a mass, comprising the steps of: (a) coupling a magnetically actuatable member to the mass, the magnetically actuatable member comprising at least one of: (i) a ferromagnetic shape memory alloy exhibiting both ferromagnetic and shape memory properties; and (ii) a ferromagnetic mass coupled to a shape memory alloy; and (b) using a magnetic force to displace the magnetically actuatable member by energizing a magnetic trigger, displacement of the magnetically actuatable member causing a corresponding rotation of the mass, wherein energizing the magnetic trigger includes the step of employing a yoke to couple a magnetic flux from the magnetic trigger to the shape memory alloy. 27. The method of claim 26, wherein the step of using the magnetic force to displace the magnetically actuatable member comprises the step of inducing a Martensitic transformation in the shape memory alloy to provide a torque applied to the magnetically actuatable member. 28. The method of claim 26, wherein the step of using the magnetic force comprises the step of applying both flux from a permanent magnet and flux from an electromagnet to displace the magnetically actuatable member. 29. The method of claim 26, wherein the shape memory alloy coupled to the ferromagnetic mass comprises a super elastic grade of shape memory alloy. 30. A spring comprising a ferromagnetic shape memory alloy (FSMA) composite, the FSMA composite including a ferromagnetic material and a shape memory alloy (SMA) material, the FSMA composite having a generally quadrilateral cross sectional shape, such that the ferromagnetic material exhibits a generally stretched X shaped cross sectional shape, with the SMA material being disposed in depressions formed in an outer surface of the ferromagnetic material, so that the resulting FSMA composite attains the generally quadrilateral cross sectional shape, the SMA material in the depressions being distributed peripherally about the generally quadrilateral cross sectional shape. 31. A method for fabricating a spring comprising a ferromagnetic shape memory alloy (FSMA) composite, the spring having a generally quadrilateral cross-sectional shape, the method comprising the steps of: (a) providing a ferromagnetic material having a generally quadrilateral cross-sectional shape; (b) forming a plurality of peripheral depressions into an outer surface of the ferromagnetic material, such that the ferromagnetic material obtains a generally stretched X shaped cross-sectional shape; and (c) filling the plurality of depressions with a shape memory alloy (SMA), so that the resulting FSMA composite spring attains the generally quadrilateral cross sectional shape, the SMA material in the depressions being distributed peripherally about the generally quadrilateral cross sectional shape. 32. A method for selectively controlling a stroke of a linear actuator, comprising the steps of: (a) providing a plurality of individual ferromagnetic shape memory alloy (FSMA) spring actuators, each FSMA spring actuator comprising a FSMA spring and a hybrid magnetic trigger configured to selectively actuate the FMSA spring, the hybrid magnetic trigger comprising a permanent magnet portion, an electromagnet portion, and a yoke configured to couple a magnetic flux from the hybrid magnetic trigger to individual FSMA spring actuators; (b) assembling the plurality of FSMA spring actuators into a stack to achieve a desired linear stroke; and (c) selectively actuating at least one of the plurality of FSMA spring actuators, wherein increasing the number of FSMA spring actuators that are actuated will result in a larger linear stroke. 33. A spring actuator, comprising: (a) a first spring assembly including a ferromagnetic shape memory alloy (FSMA) spring and a corresponding drive unit, the drive unit including at least one permanent magnet, at least one electromagnet, and a yoke configured to direct magnetic flux into the FSMA spring; and (b) at least one additional spring assembly, each additional spring assembly including a ferromagnetic shape memory alloy (FSMA) spring and a corresponding drive unit including at least one permanent magnet, at least one electromagnet, and a yoke configured to direct magnetic flux into the FSMA spring in the additional spring assembly, the first spring assembly and each additional spring assembly being configured in a stack. 34. A hybrid magnetic trigger configured to enable a shape memory alloy member to be selectively actuated, the hybrid magnetic trigger comprising: (a) at least one permanent magnet; (b) at least one electromagnet; and (c) a yoke configured to couple a magnetic flux from the hybrid magnetic trigger to the shape memory alloy, such that when the hybrid magnetic trigger is energized, the shape memory alloy is attracted to the yoke and is thereby actuated, the yoke comprising a plurality of fences configured to direct magnetic flux from the hybrid magnetic trigger into the shape memory alloy. 35. The torque actuator of claim 9, wherein the magnetic trigger includes a ring shaped permanent magnet.
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