Use of Textile Friction to Mimic Hill's Model in Dynamic Contraction of Braided Artificial Muscles

Bertrand Tondu

doi:10.4028/www.scientific.net/AST.84.39

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HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 84Use of Textile Friction to Mimic Hill's Model in...

Use of Textile Friction to Mimic Hill's Model in Dynamic Contraction of Braided Artificial Muscles

Abstract:

Several types of artificial muscles are actually able to mimic the active spring-like behaviour characterizing the tension-length diagram of the skeletal muscle but the natural damping expressed by the typical tension-velocity Hill’s relationship is not so easy to integrate in a simple way into the artificial muscle functioning. We discussed the use of a textile braided sheath, particularly in the case of the so-called McKibben structure to obtain a Hill’s model-like dynamic behaviour of the artificial muscle. Experiments are reported to compare “quick-release” experiments – as defined in muscular physiology – between artificial muscles whose braided weave is made of metallic strands and of rayon textile strands. It is shown that only in the second case a typical hyperbolic tension-velocity is highlighted with a curvature close to this of human skeletal muscle. It is also shown how the typical laws of friction in textile can explain this analogical behaviour with the Hill’s-model interpreted as a force model including a typical non-linear viscous component. An original interpretation of Hill’s model in terms of natural load-variations adaptation is given and so the advantage for an artificial muscle to get this biomimetic character.

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Periodical:

Advances in Science and Technology (Volume 84)

Pages:

39-44

DOI:

https://doi.org/10.4028/www.scientific.net/AST.84.39

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Online since:

September 2012

Authors:

Bertrand Tondu

Keywords:

Artificial Muscles, Hill’s Curve, Mckibben Muscle

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