Textile Muscle Fibers Made by and for Continuous Production Using Doped Conducting Polymers

Like skeletal muscles having a fibrous structure, conducting polymers can actuate upon electrical stimulation and can be shaped into fibers. Through textile assembly strategies of such fibers, complex actuating architectures are possible. However, state‐of‐the‐art strategies using short pieces of ya...

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Bibliographic Details
Published in:Macromolecular materials and engineering 2024-12, Vol.309 (12), p.n/a
Main Authors: Huniade, Claude, Martinez, Jose G., Mehraeen, Shayan, Jager, Edwin W. H., Bashir, Tariq, Persson, Nils‐Krister
Format: Article
Language:English
Subjects:
actuation
Conducting polymers
Continuous fiber composites
Continuous fibers
Continuous production
Electrical stimuli
Fibrous structure
Filaments
i-textiles
Immersion coating
Knitting
Muscles
Polyamide resins
Polymerization
Polypyrroles
Polystyrene resins
Skeletal muscle
Softness
Styrene
Textil och mode (generell)
textile fibers
Textiles
Textiles and Fashion (General)
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Summary:Like skeletal muscles having a fibrous structure, conducting polymers can actuate upon electrical stimulation and can be shaped into fibers. Through textile assembly strategies of such fibers, complex actuating architectures are possible. However, state‐of‐the‐art strategies using short pieces of yarn, which compel manual integration, are not fully taking advantage of textiles. To manufacture actuating textiles that best exploit textile properties like softness and pliability, and to enable production upscaling, a production of continuous, actuating fibers is presented here. These fibers are produced from commercial polyamide 6/6 filaments by first continuously dip‐coating in a modified commercial poly(3,4−ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) dispersion before the electropolymerization of polypyrrole (PPy), where the fibers are withdrawn continuously through an electrolyte solution containing the pyrrole monomer. By employing a cyclic dip‐coating with individual viscosity, drying temperature, and withdrawal speed for each layer, and by adjusting the tension, speed, and applied potential of the electropolymerization, their isotonic strain is enhanced threefold. Their specific tension, at 400   µN   tex −1 , reaches slightly higher than human skeletal muscle fibers. Furthermore, these continuous actuating fibers produced on the meter are processable in an industrial knitting machine. This study anchors the development of textile muscle fibers for future textile muscles.
ISSN:1438-7492
1439-2054
1439-2054
DOI:10.1002/mame.202400217