Hot–Dog Structured Protective Nanocoating for Multifunctional Cotton Fabric Through Spray Assisted Layer–by–Layer Assembly

Multifunctional cotton fabric was preparation by low–cost and environmental–friendly spray–assisted layer–by–layer assembly to achieve simultaneously excellent self–extinguishing ability, antistatic property and antimicrobial activity. Especially, a novel hot–dog structured protective coating was designed through introducing polyaniline nanofibers into graphene nanosheets, which can exhibit unique structural advantages and give full play to the compound synergetic effect. More clearly, 3–aminopropyl triethoxysilane, ammonium polyphosphate and polyaniline were selected for phosphorus–silicon–nitrogen synergism in the assembled layer, while PANI nanofibers doped with various organic acids were penetrated into the graphene nanosheets for constructing more stable and efficient protective space. The optimized coated fabric exhibited the excellent self–extinguishing ability for 5 composite layers including phytic acid doped nanofiber, and a significantly enhanced LOI to 35.1 % from 18.1 % for neat cotton fabrics. Moreover, the peak heat release rate and the total heat release values were significantly declined by 78.3 % and 49.0 %, respectively. Furthermore, a low sheet resistance of 264.7 kΩ/sq for antistatic property, as well as remarkable growth inhibition of E. coli and S. aureus can be achieved. In addition, the fabrics also displayed the good washing durability. Therefore, such eco–friendly and facile large–scale fabrication approach has great potentials in application for multifunctional advanced textiles and could be employed to various other cellulose fibers.

Preparation of antistatic epoxy resin coatings based on double comb-like quaternary ammonium salt polymers

The antistatic epoxy resin coatings using double comb-like quaternary ammonium salt polymers as antistatic agents reach good antistatic property with lower addition amount because polymers can dissolve and nearly linearly arrange in the coatings.

Enhanced antistatic properties of polyethylene film/polypropylene-coated non-woven fabrics by compound of hot-melt adhesive and polymer antistatic agent

In this paper, the compound hot-melt adhesives were prepared by blending alkyl sulfonate polymer antistatic agent with modified rosin hot-melt adhesive and used for the preparation of polyethylene film/polypropylene-coated non-woven fabrics. The effects of the amount of antistatic agent on the melt viscosity, softening point, and thermal stability of the compounded hot-melt adhesives were studied. Then, the antistatic properties and its washing fastness of the coated non-woven fabrics were tested and analyzed. The results showed that the softening point and the melt viscosity of the hot-melt adhesives decreased after compounding, and the thermal stability of the compound hot-melt adhesives decreased in the high temperature range, which was not affected before 200℃. The surface inductive voltage, half-life, and specific resistance of the coated non-woven fabrics prepared from the compound adhesives decreased gradually with the increase of the amount of the antistatic agent, indicating that the antistatic property of the prepared fabrics was gradually improved. In addition, the fabrics still exhibited antistatic properties after soaping for several times. The influence of compound adhesive on the wettability of fabric surface was consistent with that of antistatic property. Finally, the mechanism of the hot-melt adhesive and antistatic agent compounding technology to improve the antistatic performance of the coated non-woven fabrics was elaborated, and the reason for its excellent soaping durability was also explained.

Antistatic surface properties of plastics using donor-accepter molecular compounding antistatic agent

In order to obtain transparent plastic material with antistatic property for optical communication application, cyclo olefin polymer (COP)/BN105 composite materials prepared by using injection molding have been evaluated. Surface resistance of the molded product decreased to 2×1011 Ω/sq along with an increase in BN105 content range up to 2 wt%. The samples showed excellent property to prevent the surface from dust adhesion. In addition, the samples containing BN105 less than 5 wt% did not show any decrease in transmittance without any significant change of tensile strength. The results indicate COP/BN105 as a promising plastic composite material with sufficient antistatic property as well as high transparency.

In situ polymerization and characterization of graphite nanoplatelet/poly(ethylene terephthalate) nanocomposites for construction of melt-spun fibers

This work described a set of graphite nanoplatelet/poly(ethylene terephthalate) (GnP/PET) nanocomposites synthesized via an in situ polymerization for construction of melt-spun fibers with enhanced antistatic property.