An actuator includes a shape-memory alloy (SMA), a power supply that transmits electrical current, a heat source positioned proximate to the SMA, a heat sink positioned proximate to the SMA, and a control module. The control module causes the power supply to transmit the electrical current to the he
An actuator includes a shape-memory alloy (SMA), a power supply that transmits electrical current, a heat source positioned proximate to the SMA, a heat sink positioned proximate to the SMA, and a control module. The control module causes the power supply to transmit the electrical current to the heat source in response to receiving a first signal, thereby causing the heat source to heat the SMA via induction heating. The control module also causes the power supply to cease transmitting the electrical current to the heat source in response to receiving a second signal, thereby causing the heat source to stop heating the SMA. The control module also causes the power supply to transmit the electrical current to the heat sink in response to receiving the second signal, thereby causing the heat sink to cool the SMA via magneto-thermal convection cooling.
대표청구항▼
1. An actuator, comprising: a shape-memory alloy (SMA);a power supply configured to transmit electrical current;a heat source positioned proximate to the SMA;a heat sink positioned proximate to the SMA;a sensor coupled to the SMA or positioned proximate to the SMA, wherein the sensor is configured t
1. An actuator, comprising: a shape-memory alloy (SMA);a power supply configured to transmit electrical current;a heat source positioned proximate to the SMA;a heat sink positioned proximate to the SMA;a sensor coupled to the SMA or positioned proximate to the SMA, wherein the sensor is configured to measure a distance between the sensor and the SMA; anda control module configured to cause the power supply to: transmit the electrical current to the heat source in response to receiving a first signal, thereby causing the heat source to heat the SMA via induction heating;cease transmitting the electrical current to the heat source in response to receiving a second signal, thereby causing the heat source to stop heating the SMA, wherein the second signal is received after the distance is measured to be less than or greater than a predetermined amount; andtransmit the electrical current to the heat sink in response to receiving the second signal, thereby causing the heat sink to cool the SMA via magneto-thermal convection cooling. 2. The actuator of claim 1, wherein the SMA has a first shape when the first signal is received, and wherein the SMA transforms into a second, different shape when the SMA is heated to above a predetermined temperature. 3. The actuator of claim 2, wherein the SMA has the second shape when the second signal is received, and wherein the SMA transforms back into the first shape when the SMA is cooled to below the predetermined temperature. 4. The actuator of claim 3, wherein the SMA causes a movable component on a mobile unit to actuate from a first position to a second position when the SMA transforms from the first shape into the second shape. 5. The actuator of claim 4, wherein the movable component is selected from the group consisting of an aileron, a rudder, an elevator, a spoiler, a flap, and a slap, and wherein the mobile unit is an aircraft. 6. The actuator of claim 1, wherein the heat source comprises a coil that is wrapped helically around the SMA. 7. The actuator of claim 1, wherein the heat sink comprises a metallic slab that is configured to capture heat energy using ion cooling. 8. The actuator of claim 1, further comprising an adiabatic chamber, wherein the SMA, the heat source, and the heat sink are positioned within the adiabatic chamber. 9. The actuator of claim 1, wherein the second signal is received in response to the distance becoming less than the predetermined amount. 10. The actuator of claim 1, wherein the second signal is received in response to the distance being zero such that the SMA contacts the sensor. 11. The actuator of claim 1, wherein the heat sink comprises a laser that cools the SMA by trapping ions. 12. A mobile unit, comprising: a movable component; andan actuator configured to actuate the movable component between a first position and a second position, the actuator comprising: a shape-memory alloy (SMA);a power supply configured to transmit electrical current;a heat source positioned proximate to the SMA;a heat sink positioned proximate to the SMA;a sensor coupled to the SMA or positioned proximate to the SMA, wherein the sensor is configured to measure a distance between the sensor and the SMA; anda control module configured to cause the power supply to: transmit the electrical current to the heat source in response to receiving a first signal, thereby causing the heat source to heat the SMA via induction heating, wherein the SMA transforms from a first shape to a second shape when heated to above a predetermined temperature, and wherein the movable component actuates from the first position into the second position in response to the SMA transforming from the first shape into the second shape;cease transmitting the electrical current to the heat source in response to receiving a second signal, thereby causing the heat source to stop heating the SMA, wherein the second signal is received after the distance is measured to be less than or greater than a predetermined amount; andtransmit the electrical current to the heat sink in response to receiving the second signal, thereby causing the heat sink to cool the SMA via magneto-thermal convection cooling, wherein the SMA transforms from the second shape back to the first shape when cooled to below the predetermined temperature, and wherein the movable component actuates from the second position into the first position in response to the SMA transforming from the second shape back into the first shape. 13. The mobile unit of claim 12, further comprising an adiabatic chamber, wherein the SMA, the heat source, and the heat sink are positioned within the adiabatic chamber. 14. The mobile unit of claim 13, wherein the heat source comprises a coil that is wrapped helically around the SMA. 15. The mobile unit of claim 14, wherein the movable component is selected from the group consisting of an aileron, a rudder, an elevator, a spoiler, a flap, and a slap, and wherein the mobile unit is an aircraft. 16. A method for actuating a movable component, comprising: supplying electrical current from a power supply to a heat source in response to receiving a first signal, thereby causing the heat source to heat a shape-memory alloy (SMA) via induction heating, wherein the SMA transforms from a first shape into a second shape when heated to above a predetermined temperature, and wherein the movable component actuates from a first position into a second position in response to the SMA transforming from the first shape into the second shape;measuring a distance between a sensor and the SMA using the sensor, wherein the sensor is coupled to or positioned proximate to the SMA; andsupplying the electrical current to a heat sink in response to receiving a second signal after the distance is measured to be less than or greater than a predetermined amount, thereby causing the heat sink to cool the SMA via magneto-thermal convection cooling, wherein the SMA transforms from the second shape back into the first shape when cooled to below the predetermined temperature, and wherein the movable component actuates from the second position into the first position in response to the SMA transforming from the second shape back into the first shape. 17. The method of claim 16, further comprising ceasing to transmit the electrical current to the heat source in response to receiving the second signal, thereby causing the heat source to stop heating the SMA. 18. The method of claim 17, further comprising: measuring a temperature of the SMA after the first signal but before the second signal; anddisplaying the temperature when the temperature becomes greater than the predetermined temperature. 19. The method of claim 18, wherein the second signal is received in response to displaying the temperature. 20. The method of claim 19, wherein the heat source comprises a coil that is wrapped helically around the SMA.
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