Shape Memory Alloy-Based Spring Bundle Actuator Controlled by Water Temperature

Shape Memory Alloy-Based Spring Bundle Actuator Controlled by Water Temperature

This paper proposes a novel artificial muscle, shape memory alloy (SMA) spring bundle actuator (SSBA), which can be applied to robotic arms while replacing the motor-gear mechanism. Artificial muscles applicable to robotic arms should have characteristics, such as high contraction strain comparable...

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Veröffentlicht in:IEEE/ASME transactions on mechatronics 2019-08, Vol.24 (4), p.1798-1807
Hauptverfasser: Park, Cheol Hoon, Choi, Kyung Jun, Son, Young Su
Format: Artikel
Sprache:eng
Schlagworte:
Actuation
Actuators
Artificial muscle
Artificial muscles
Bundling
Cold water
Controllability
Cooling
faucet-like valve
Force
Linearity
Muscles
Ohmic dissipation
Product design
Proportional integral derivative
Resistance heating
Robot arms
Robotics
Shape memory alloys
SMA spring bundle actuator
Springs
Springs (elastic)
Stability
Water heating
Water temperature
water temperature control
Wires
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container_title IEEE/ASME transactions on mechatronics
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creator Park, Cheol Hoon
Choi, Kyung Jun
Son, Young Su
description This paper proposes a novel artificial muscle, shape memory alloy (SMA) spring bundle actuator (SSBA), which can be applied to robotic arms while replacing the motor-gear mechanism. Artificial muscles applicable to robotic arms should have characteristics, such as high contraction strain comparable to that of skeletal muscles, high load capacity, fast actuation frequency, and force/position controllability. To improve the low efficiency and slow cooling of the Joule heating, which is widely used for SMA heating, the SMA spring bundle is heated and cooled using hot and cold water. A faucet-like valve was developed to control the temperature of water supplied to the SSBA, and the force generated by the SSBA with respect to the water temperature change was confirmed to be very linear compared to that of the conventional SMA actuators. Owing to this linearity, the force control of the SSBA was easy by using a simple proportional-integral-derivative controller. A bundle weighing 12 g and consisting of 24 SMA springs was able to actuate with a contraction strain of more than 50% and actuating frequency of 1 Hz under a mass condition of 10 kg. Further, it could generate 130 N of force with respect to a temperature change from 28 °C to 82 °C. The flexion-extension motion of an arm of 1-Hz actuating speed was possible by applying two SSBAs antagonistically to an arm of one degree-of-freedom. This proposed artificial muscle offers the possibility of lightweight and safe robotic arms.
doi_str_mv 10.1109/TMECH.2019.2928881
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Artificial muscles applicable to robotic arms should have characteristics, such as high contraction strain comparable to that of skeletal muscles, high load capacity, fast actuation frequency, and force/position controllability. To improve the low efficiency and slow cooling of the Joule heating, which is widely used for SMA heating, the SMA spring bundle is heated and cooled using hot and cold water. A faucet-like valve was developed to control the temperature of water supplied to the SSBA, and the force generated by the SSBA with respect to the water temperature change was confirmed to be very linear compared to that of the conventional SMA actuators. Owing to this linearity, the force control of the SSBA was easy by using a simple proportional-integral-derivative controller. A bundle weighing 12 g and consisting of 24 SMA springs was able to actuate with a contraction strain of more than 50% and actuating frequency of 1 Hz under a mass condition of 10 kg. Further, it could generate 130 N of force with respect to a temperature change from 28 °C to 82 °C. The flexion-extension motion of an arm of 1-Hz actuating speed was possible by applying two SSBAs antagonistically to an arm of one degree-of-freedom. 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Artificial muscles applicable to robotic arms should have characteristics, such as high contraction strain comparable to that of skeletal muscles, high load capacity, fast actuation frequency, and force/position controllability. To improve the low efficiency and slow cooling of the Joule heating, which is widely used for SMA heating, the SMA spring bundle is heated and cooled using hot and cold water. A faucet-like valve was developed to control the temperature of water supplied to the SSBA, and the force generated by the SSBA with respect to the water temperature change was confirmed to be very linear compared to that of the conventional SMA actuators. Owing to this linearity, the force control of the SSBA was easy by using a simple proportional-integral-derivative controller. A bundle weighing 12 g and consisting of 24 SMA springs was able to actuate with a contraction strain of more than 50% and actuating frequency of 1 Hz under a mass condition of 10 kg. Further, it could generate 130 N of force with respect to a temperature change from 28 °C to 82 °C. The flexion-extension motion of an arm of 1-Hz actuating speed was possible by applying two SSBAs antagonistically to an arm of one degree-of-freedom. 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Artificial muscles applicable to robotic arms should have characteristics, such as high contraction strain comparable to that of skeletal muscles, high load capacity, fast actuation frequency, and force/position controllability. To improve the low efficiency and slow cooling of the Joule heating, which is widely used for SMA heating, the SMA spring bundle is heated and cooled using hot and cold water. A faucet-like valve was developed to control the temperature of water supplied to the SSBA, and the force generated by the SSBA with respect to the water temperature change was confirmed to be very linear compared to that of the conventional SMA actuators. Owing to this linearity, the force control of the SSBA was easy by using a simple proportional-integral-derivative controller. A bundle weighing 12 g and consisting of 24 SMA springs was able to actuate with a contraction strain of more than 50% and actuating frequency of 1 Hz under a mass condition of 10 kg. Further, it could generate 130 N of force with respect to a temperature change from 28 °C to 82 °C. The flexion-extension motion of an arm of 1-Hz actuating speed was possible by applying two SSBAs antagonistically to an arm of one degree-of-freedom. This proposed artificial muscle offers the possibility of lightweight and safe robotic arms.</abstract><cop>New York</cop><pub>IEEE</pub><doi>10.1109/TMECH.2019.2928881</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0002-3367-7718</orcidid><orcidid>https://orcid.org/0000-0001-7942-7311</orcidid></addata></record>
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1941-014X
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recordid cdi_ieee_primary_8764008
source IEEE Electronic Library (IEL)
subjects Actuation
Actuators
Artificial muscle
Artificial muscles
Bundling
Cold water
Controllability
Cooling
faucet-like valve
Force
Linearity
Muscles
Ohmic dissipation
Product design
Proportional integral derivative
Resistance heating
Robot arms
Robotics
Shape memory alloys
SMA spring bundle actuator
Springs
Springs (elastic)
Stability
Water heating
Water temperature
water temperature control
Wires
title Shape Memory Alloy-Based Spring Bundle Actuator Controlled by Water Temperature
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