Extrusion of CNT-modified Polymers with Low Viscosity - Influence of Crystallization and CNT Orientation on the Electrical Properties

Steinmann, Wilhelm; Vad, Thomas; Weise, Benjamin Alexander; Wulfhorst, Johannes; Seide, Gunnar Henrik; Gries, Thomas; Heidelmann, Markus; Weirich, Thomas E.

doi:10.1177/096739111302100801

Cited by 18 publications

(25 citation statements)

References 26 publications

(26 reference statements)

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“…Conductive fibers (especially short or long fibers) are placed in a non-conducting matrix material and can form conductive paths within the material, if a so-called percolating network is formed from the single filaments. If the fiber volume content passes the percolation threshold, a spontaneous increase of conductivity can be found at this point [64]. 2.…”

Section: Electrical Propertiesmentioning

confidence: 98%

Essential Properties of Fibres for Composite Applications

Steinmann

Saelhoff

2016

Textile Science and Clothing Technology

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In this chapter, essential properties of fibres required for fabricating good performance composites are presented. Fundamental aspects of these properties and principles of their characterization techniques are discussed. Firstly, the geometrical aspects of fibres (for short and endless fibres) are described. The second part deals with the different types of structures in fibres with respect to molecular orientation mostly responsible for anisotropy of fibres. In the third part, the mechanical properties (especially tensile properties) and failure mechanisms for different types of fibres are discussed and correlated to the structure of the fibres. The following part is concerned with the surface of fibres, which is responsible for the interaction of the fibres with the matrix material in composites and has a large influence on the wetting behavior and adhesion to matrix materials. In the last parts, further physical properties (heat capacity, thermal conductivity, thermomechanical properties and electrical conductivity) and the durability of fibres are described.

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Section: Electrical Propertiesmentioning

confidence: 98%

Essential Properties of Fibres for Composite Applications

Steinmann

Saelhoff

2016

Textile Science and Clothing Technology

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“…Fire retardant properties of nanocomposite bicomponent fibers are one of the most interesting characteristics for aviation industries . A conductive or magnetic nanomaterial in the core section can give new properties to the bicomponent fibers for using in electronic or smart clothing products . Some of these advanced functional fibers may be used in artificial organs, i.e., muscles or vessels.…”

Section: C/s Fibersmentioning

confidence: 99%

“…Their attempts led to polling effect in melt‐spun bicomponent fibers, using PVDF's piezoelectric capability and CNT's conductivity . Steinmann et al . also used this idea for developing conductive nanocomposite fibers.…”

Section: C/s Fibersmentioning

confidence: 99%

Recent advances in core/shell bicomponent fibers and nanofibers: A review

Naeimirad

Ali

Kotek

et al. 2018

J of Applied Polymer Sci

141

103

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There has been a steady progress in developing synthetic fibers in the past few years. Bicomponent fibers and nanofibers in a core/shell (C/S) configuration, including two dissimilar materials have presented unusual potential for use in many novel applications. These fibers can be produced using a variety of materials via different techniques i.e., coaxial melt spinning and electrospinning. In this review, we discuss the recent advances in C/S fibers and nanofibers' production. The first part has been assigned to the bicomponent fibers manufacturing technology, while production and applications of C/S nanofibers have been described in the second part.

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“…Furthermore, in addition to agglomeration occurring with all nanoparticles, slender elongated ones (i.e. tubes, wires, fibers) can deform (Steinmann W. et al, 2013) or even fracture (Triambulo R.E. et al, 2014), for example during manufacturing (e.g., ultrasonication, compounding), possibly leading to conductivity reduction.…”

Section: Electrical Conductivitymentioning

confidence: 99%

Nanoparticle Filler Content and Shape in Polymer Nanocomposites

Blattmann

Pratsinis

2019

KONA

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Car tires, sealing caulk and high-voltage cable insulators are prime examples of commercially available and widely used composites of polymers containing nanostructured particles. In fact, myriads of applications can be realized but the usefulness of such nanocomposites depends heavily on composition, morphology, concentration and dispersion homogeneity of the nanoparticle filler in the polymer matrix. Optimizing these characteristics while ensuring economically feasible fabrication, determines the extent to which new products integrate nanocomposites. This review discusses challenges and manufacturing options of polymer nanocomposites and, in particular, which and how much nanoparticle fillers improve electrical/thermal conductivity, dielectric permittivity, gas permeability, magnetization and mechanical stability by critically reviewing and classifying over 280 peer-reviewed articles. Lastly, the economic, environmental and health implications associated with these materials are highlighted.

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Extrusion of CNT-modified Polymers with Low Viscosity - Influence of Crystallization and CNT Orientation on the Electrical Properties

Cited by 18 publications

References 26 publications

Essential Properties of Fibres for Composite Applications

Essential Properties of Fibres for Composite Applications

Recent advances in core/shell bicomponent fibers and nanofibers: A review

Nanoparticle Filler Content and Shape in Polymer Nanocomposites

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