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Artificial Muscle

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Artificial Muscle Kori Brabham Misti Marr Andy Smith Paul Lee Natural vs. Artificial Muscle What does a natural muscle do? It is a contractile organ. – PowerPoint PPT presentation

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Title: Artificial Muscle


1
Artificial Muscle
  • Kori Brabham
  • Misti Marr
  • Andy Smith
  • Paul Lee

2
Natural vs. Artificial Muscle
  • What does a natural muscle do?
  • It is a contractile organ.
  • It consists of fibers which actuate force and
    motion in response to nervous stimulation.
  • How does it work?
  • Muscles contract by the chemo-mechanical action
    of the proteins actin and myosin.
  • Joints of the body are arrayed such that they
    comprise muscles which oppose each other.

3
Natural vs. Artificial Muscle
  • How can we develop replacements for the natural
    muscle?
  • Develop biomimetic actuators.
  • Emphasis on implantable technologies (not on the
    the forefront now).
  • What do we have to work with?
  • Electrical/pneumatic servos (robotic limbs, late
    1940s-present).
  • New materials.
  • Synthetic polymers
  • Carbon

4
What constitutes a muscle?
  • Any system or combination of sub-systems can be
    considered a muscle
  • hydraulic/pneumatic cylinder.
  • electromagnetic servo.
  • biological muscle tissue.
  • In short, anything which accomplishes actuation
    under the command of a stimulus.
  • Muscles primarily exert energy (ATP) to bring
    about
  • motion, acceleration (?v/ ?t or ?2x/ ?t2).
  • force application (Fm.a).

5
Muscles Revisited
  • Muscle cells are highly specialized for
    contraction.
  • ONLY contract and relax
  • Abduction and adduction
  • Actin and myosin vary in amounts and
    configuration, depending on cell function.

6
Three types
  • Skeletal voluntary and striated
  • Cardiac involuntary, striated, and branched
  • Smooth involuntary and unstriated

7
The Design of Natural Muscle
  • Muscles are simply transducers
  • They change the chemo-electric signal from nerves
    to mechanical energy.
  • Artificial muscles should be similar in
    resilience and in the ability to produce large
    actuation strains
  • http//www.unm.edu/amri/protect/

8
Brief Timeline
  • 1619 - Descartes postulated that sensory impulses
    activated muscle (reflection)
  • 1780 - Galvani noticed frog muscles would
    contract with electrical apparatus

9
Brief Timeline (contd)
  • 1968 Rubber artificial muscle
  • Involved several thread running along a
    longitudinal axis
  • Compressed air is injected

10
Brief Timeline (contd)
  • 1968 - Model Postural Control
  • A biped walking machine is required to maintain
    its balance while standing and walking

11
Artificial MuscleAn Overview
  • Many types of artificial muscle.
  • McKibbin muscle actuators
  • Inflatable air tubes, delivering large force at a
    low frequency.
  • PAN-chemically stimulated by pH change.
  • Electrically Stimulated Tissues
  • IPMC
  • Solenoids (not presented)
  • Piezo-active polymers and ceramics (not presented)

12
A Review of Current Technology
13
The McKibben Artificial Muscle
14
History
  • First developed in the 1950's by American
    physician Joseph L. McKibben
  • originally intended to actuate artificial limbs
    for amputees
  • More recently was commercialized in the 1980's by
    Bridgestone Rubber Company of Japan
  • patented and called Rubbertuator
  • Presently the Shadow Robot Group of England
    manufactures these actuators for robotic
    applications

15
How its made
  • Consists of an internal bladder
  • Bladder is covered by a braided mesh shell
  • Attached at either end to tendon-like structures

16
How it works
  • Internal bladder is pressurized
  • Bladder expands in a balloon-like manner against
    the braided shell
  • Shell constrains the expansion to maintain a
    cylindrical shape
  • As the volume of the bladder increases due to the
    increase in pressure, the actuator shortens and
    produces tension

17

Advantages of the McKibben Artificial Muscle
  • High force to weight ratio
  • Lightweight
  • Low Cost
  • Smooth
  • Size availability
  • Flexible
  • Powerful
  • Damped
  • Effective

18
Comparison to biological muscle
  • Force-length properties are reasonably close
  • Force-velocity properties are not close
  • a device called a hydraulic damper that operates
    in parallel with the McKibben muscles has been
    created
  • McKibben muscles are attached to a spring-like
    device that simulates the tendon properties and
    energy storage of a real muscle

19
Ionic Polymer-Metal Composite
20
How its made
  • Composed of a perfluorinated ion exchange
    membrane
  • Consist of a polymer matrix that is coated on the
    outer surface with platinum in most cases (silver
    and copper have also been used)
  • coating aids in the distribution of the voltage
    over surface
  • Made into sheets that can be cut into different
    shapes and sizes as needed

21
How it works
  • Uses electricity (electrodes, conductors, etc.)
    to operate
  • A circuit is connected to surface to produce
    voltage difference, causing bending
  • Strips can bend and flap dramatically which
    allows movement

22
Advantages of IPMC
  • Light
  • Compact
  • Driven by low power
  • and low voltage
  • Large strain capability

23
Comparison to biological muscle
  • High fracture tolerance
  • Large actuation strain
  • Inherent vibration damping
  • Responds to electricity with elasticity and
    responsiveness similar to those shown to
    biological muscle

24
Nanotube Artificial Muscle
  • Invented by Max Plank Institute, produced by
    AlliedSignal.
  • Based on Carbon nanotubes (bucky tubes).
  • Sub-microscopic Carbon sheets (formed into tubes)
    filled with electrolytes.

25
Nanotube Artificial Muscle (contd)
  • When a voltage is applied the sheets contract to
    do work.
  • Possible limitation electrically actuated.
  • Being investigated by Defense Advanced Research
    Projects Agency (DARPA) as bucky paper.

26
Polyacrylonitrile (PAN)
  • Combination of gel and plastic. Tough.
  • Contracts under pH changes.
  • Contraction occur in 20 ms to a -20 strain.
  • Very similar to human muscle in speed, exceeds
    human muscle in max force per cm2 (2x).

27
Polyacrylonitrile (PAN) (cont)
  • Must be surrounded by solutions in latex tubes.
  • Some models have been developed which simulate
    muscle movement.
  • University of NM project.

28
Electro-active Muscle Transducers
  • Uses compliant electrodes to electrically
    stimulate electro-active elastomeric materials.
  • Produce strains in excess of 100, and pressures
    greater that 100 psi.
  • Spherical joints have been developed based on the
    actuator.
  • Developed by SRI International, Inc.

29
Electro-active Muscle Transducers (contd)
  • AKA Electrostrictive or dielectric elastomer.
  • Exhibit a mechanical strain when subjected to an
    electrical field.
  • Striction capability exceeds piezoelectric
    ceramics.
  • Most common are PMMA-based.
  • Produce a positive force/expansion.
  • Use tiny robotic muscles.

30
A Novel Use for AM
  • Smart implants with tiny perforations that
    contain a pharmaceutical, plugged by artificial
    muscles.
  • The implant has tiny sensors which sense blood
    concentrations of certain chemicals.

31
A Novel Use for AM (contd)
  • The artificial muscle then will shrink to allow a
    drug to pass freely.
  • When concentrations of the sensed chemical rises
    in the blood, the muscle then relaxes to plug the
    holes a gain.

32
Honorable Mention Replacement Prosthetic Limbs
  • Started as passive replacements to fill clothing
    or act as support.
  • Archeological evidence of prostheses in ancient
    India and Egypt--Queen Vishpla, Elis.
  • Infection and blood loss.
  • 1600s-1800s
  • Great increase in health technology styptic
    antibiotics, anesthetics, blood clotting
    chemicals.
  • Prosthetic units were developed with lighter
    weight and greater articulation (motion learned
    and controlled by amputee).
  • 1940s-1980s Emphasis on actuation.
  • 1980s-Present Emphasis on realism.

33
Replacement Prosthetic Limbs (contd)
  • Number of Companies that specialize in
    prosthesis/orthotics
  • North Shore Orthotics-Prosthetics, Inc.
  • Ohi, SCOPe, many others.
  • Limb replacements are actuated
  • By other existing muscles directly.
  • By EMG generated by nearby existing muscles
  • Balance.

34
Artificial Muscle
  • Applications in Robots

35
Types of Robots
  • Miniature robots
  • Wall climbers
  • Exploring rovers

36
Miniature Robots
  • Submersible bots with plastic muscles
  • Ability to someday pick up single cells
  • Positive and negative ions shrink and swell the
    polymer

37
Wall Climbers
  • Air Rubbertuator
  • Capable of difficult inspections
  • Aircraft
  • Bridges
  • Nuclear power plants
  • Obstacles, inclines, stairs, vertical movement.

38
Robots in Space
  • Ability to probe, dig, photograph and analyze
  • No gears or complex mechanical systems
  • Lighter and less complex robots
  • Smaller
  • Not sensitive to dust

39
Capabilties
  • Grasping
  • Wiping
  • Muscle groups working together

40
Grasping
  • Electric charge applied to plastic ribon
  • Charged particles pushed to one side lengthens
    that side

41
Wipers
  • Two-way wiping motion produced
  • Applications onto cameras or sensors

42
Muscles Working Together
  • Creates more than one motion
  • Bionic men and women???
  • Could replace human muscles

43
Legs and Wheels
  • Able to handle most terrain
  • Durable
  • Reliable
  • Not as good as four legs

44
A Way of the Future
  • Cheap
  • Durable
  • Lightweight
  • Conserve Power

45
References
  • Electroactive Polymer Actuators webpage
  • Artificial Muscle Research Institute
  • SRI International, Inc.
  • Opthalmatronix, Inc.
  • Ohio State University
  • www.spacedaily.com
  • Max Planck Society
  • University of New Mexico -- cape.uwaterloo.ca
  • BBC News
  • Science Daily
  • Discovery Channel
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