Artificial joints using agonist-antagonist actuators

US 8,870,967 B2
Filed: 10/29/2009
Issued: 10/28/2014
Est. Priority Date: 03/31/2005
Status: Active Grant

First Claim

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1. An agonist-antagonist actuator for controlling an orthotic, prosthetic or exoskeleton joint comprising, in combination:

a flexion actuator connected to each of first and second members that are connected for movement relative to one another about a single pivot point, whereby the single pivot point maintains a length of the orthotic, prosthetic or exoskeleton joint throughout flexion and extension of the first and second members of the orthotic, prosthetic or exoskeleton joint about the single pivot point, and wherein the flexion actuator includes a series combination of a first active element and a first elastic element, the flexion actuator being configured to draw the first and second members together, reducing the angle between the first and second members at the joint;

an extension actuator connected between the first and second members, the extension actuator comprising a series combination of a second active element and a second elastic element, the extension actuator being configured to urge the first and second members apart, increasing the angle between the first and second members at the joint, the extension actuator being in parallel with the flexion actuator, being independently activated at different moments in time from the flexion actuator, and operating to oppose the flexion actuator in an agonist-antagonist manner, whereby simultaneous actuation of the flexion actuator and the extension actuator will cause the actuators to operate in active opposition to each other about the single pivot point of the orthotic, prosthetic or exoskeleton joint; and

a controller for independently energizing the first active element and the second active element at different moments in time to control the movement of the first and second members at the orthotic, prosthetic or exoskeleton joint.

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Abstract

Artificial limbs and joints that behave like biological limbs and joints employ a synthetic actuator which consumes negligible power when exerting zero force, consumes negligible power when outputting force at constant length (isometric) and while performing dissipative, nonconservative work, is capable of independently engaging flexion and extension tendon-like, series springs, is capable of independently varying joint position and stiffness, and exploits series elasticity for mechanical power amplification.

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18 Claims

1. An agonist-antagonist actuator for controlling an orthotic, prosthetic or exoskeleton joint comprising, in combination:
- a flexion actuator connected to each of first and second members that are connected for movement relative to one another about a single pivot point, whereby the single pivot point maintains a length of the orthotic, prosthetic or exoskeleton joint throughout flexion and extension of the first and second members of the orthotic, prosthetic or exoskeleton joint about the single pivot point, and wherein the flexion actuator includes a series combination of a first active element and a first elastic element, the flexion actuator being configured to draw the first and second members together, reducing the angle between the first and second members at the joint;
  
  an extension actuator connected between the first and second members, the extension actuator comprising a series combination of a second active element and a second elastic element, the extension actuator being configured to urge the first and second members apart, increasing the angle between the first and second members at the joint, the extension actuator being in parallel with the flexion actuator, being independently activated at different moments in time from the flexion actuator, and operating to oppose the flexion actuator in an agonist-antagonist manner, whereby simultaneous actuation of the flexion actuator and the extension actuator will cause the actuators to operate in active opposition to each other about the single pivot point of the orthotic, prosthetic or exoskeleton joint; and
  
  a controller for independently energizing the first active element and the second active element at different moments in time to control the movement of the first and second members at the orthotic, prosthetic or exoskeleton joint.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The agonist-antagonist actuator of claim 1, wherein the first and second active elements comprise motors.
  - 3. The agonist-antagonist actuator of claim 2, wherein the motors are electric motors.
  - 4. The agonist-antagonist actuator of claim 2, further comprising a first transmission connecting the first active element to the first elastic element and a second transmission connecting the second active element to the second elastic element.
  - 5. The agonist-antagonist actuator of claim 4, wherein the transmissions are non-backdriveable.
  - 6. The agonist-antagonist actuator of claim 1, wherein the first and second elastic elements comprise springs.
  - 7. The agonist-antagonist actuator of claim 6, wherein the springs are hardening springs.
  - 8. The agonist-antagonist actuator of claim 6, wherein each of the springs has a different stiffness.
  - 9. The agonist-antagonist actuator of claim 1, wherein the orthotic, prosthetic or exoskeleton joint is an ankle joint and the flexion and extension actuators cooperatively operate such that energy is stored in the first elastic element during controlled plantarflexion and energy is stored in the second elastic element during controlled dorsiflexion.
  - 10. The agonist-antagonist actuator of claim 1, wherein the orthotic, prosthetic or exoskeleton joint is a knee joint and the flexion and extension actuators cooperatively operate such that energy is stored in the second elastic element during stance flexion and energy is stored in the first elastic element during stance extension.
  - 11. The agonist-antagonist actuator of claim 1, wherein the orthotic, prosthetic or exoskeleton joint is a knee joint and the flexion and extension actuators cooperatively operate such that energy is stored in the second elastic element during early swing and energy is stored in the first elastic element during late swing.

12. An orthotic, prosthetic or exoskeleton joint with agonist-antagonist actuator control, comprising, in combination:
- an orthotic, prosthetic or exoskeleton joint, the orthotic, prosthetic or exoskeleton joint including first and second members, and a single pivot point linking the first and second members for movement relative to one another at the single pivot point, the single pivot point maintaining a length of the orthotic, prosthetic or exoskeleton joint during rotation of the first and second members about the single pivot point;
  
  a flexion actuator spanning the orthotic, prosthetic or exoskeleton joint and connected to each of the first and second members, the flexion actuator comprising a series combination of a first active element and a first elastic element, the flexion actuator being configured to draw the first and second members together, reducing the angle between the first and second members at the joint;
  
  an extension actuator spanning the orthotic, prosthetic or exoskeleton joint and connected between the first and second members, the extension actuator comprising a series combination of a second active element and a second elastic element, the extension actuator being configured to urge the first and second members apart, increasing the angle between the first and second members at the joint, the extension actuator being in parallel with the flexion actuator, being independently activated at different moments in time from the flexion actuator, and operating to oppose the flexion actuator in an agonist-antagonist manner, whereby simultaneous actuation of the flexion actuator and the extension actuator will cause the actuators to operate in active opposition to each other about the single pivot point of the orthotic, prosthetic or exoskeleton joint; and
  
  a controller for independently energizing the first active element and the second active element at different moments in time to control the movement of the first and second members at the orthotic, prosthetic or exoskeleton joint.
- View Dependent Claims (13, 14, 15, 16, 17, 18)
- - 13. The orthotic, prosthetic or exoskeleton joint of claim 12, wherein the first and second active elements comprise motors.
  - 14. The orthotic, prosthetic or exoskeleton joint of claim 13, further comprising a first transmission connecting the first active element to the first elastic element and a second transmission connecting the second active element to the second elastic element.
  - 15. The orthotic, prosthetic or exoskeleton joint of claim 12, wherein the first and second elastic elements comprise springs.
  - 16. The orthotic, prosthetic or exoskeleton joint of claim 12, wherein the orthotic, prosthetic or exoskeleton joint is an ankle joint and the flexion and extension actuators cooperatively operate such that energy is stored in the first elastic element during controlled plantarflexion and energy is stored in the second elastic element during controlled dorsiflexion.
  - 17. The orthotic, prosthetic or exoskeleton joint of claim 12, wherein the orthotic, prosthetic or exoskeleton joint is a knee joint and the flexion and extension actuators cooperatively operate such that energy is stored in the second elastic element during stance flexion and energy is stored in the first elastic element during stance extension.
  - 18. The orthotic, prosthetic or exoskeleton joint of claim 12, wherein the orthotic, prosthetic or exoskeleton joint is a knee joint and the flexion and extension actuators cooperatively operate such that energy is stored in the second elastic element during early swing and energy is stored in the first elastic element during late swing.

Specification

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Current Assignee
Massachusetts Institute of Technology
Original Assignee
Massachusetts Institute of Technology
Inventors
Herr, Hugh M., Magnusson, Lee Harris, Endo, Ken
Primary Examiner(s)
WATKINS, MARCIA LYNN

Application Number

US12/608,627
Publication Number

US 20100241242A1
Time in Patent Office

1,825 Days
Field of Search

623/24, 623/27, 623/42, 623/46, 623/25, 623/39, 623/40, 623/44, 623/45, 623/47, 623/48, 623/49, 623/50, 623/52, 623/57, 623/59, 623/61, 623/62, 623/64, 602/5, 602/16, 602/20, 602/21, 602/22, 602/23, 602/26, 602/27, 602/30, 601/5, 601/33, 601/34
US Class Current

623/24
CPC Class Codes

A61F 2/60   Artificial legs or feet or ...

A61F 2/605   Hip joints

A61F 2/64   Knee joints

A61F 2/6607   Ankle joints

A61F 2/70   electrical

A61F 2/72   Bioelectric control, e.g. m...

A61F 2/741   using powered actuators, e....

A61F 2002/5003   having damping means, e.g. ...

A61F 2002/5004   operated by electro- or mag...

A61F 2002/503   for adjusting elasticity, f...

A61F 2002/5033   for adjusting damping

A61F 2002/5075   Multiple spring systems inc...

A61F 2002/6657   having a plate-like or stri...

A61F 2002/6818   for braking

A61F 2002/701   operated by electrically co...

A61F 2002/704   computer-controlled, e.g. r...

A61F 2002/7625   for measuring angular position

A61F 2002/763   for measuring spatial posit...

A61F 2002/7635   for measuring force, pressu...

A61F 2002/764   for measuring acceleration

A61F 2002/7645 : for measuring torque, e.g. ...

B25J 19/0008 : Balancing devices

B62D 57/032 : with alternately or sequent...

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Artificial joints using agonist-antagonist actuators

First Claim

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Abstract

Citations

18 Claims

Specification

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Artificial joints using agonist-antagonist actuators

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

Citations

18 Claims

Specification

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Solutions

Use Cases

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