The amount of a processing solution used is reduced, and the quality of an electroless plated fiber material is improved. The present invention relates to a manufacturing method for an electroless plated fiber material A4. The manufacturing method includes a step S5 of electrostatically spraying a solution B containing a catalyst precursor in a state of being electrically charged to a positive potential onto a fiber material A2 while grounding the fiber material A2 and moistening the fiber material A2, and electrostatically spraying a solution C containing a reducing agent in a state of being electrically charged to a positive potential onto the fiber material A2, and a step S7 of electrostatically spraying each of a solution D containing metal ions and a solution E containing a reducing agent each in a state of being electrically charged to a positive potential onto the fiber material A3 such that the solution D containing metal ions and the solution E containing the reducing agent react with each other in the same electric field on the fiber material A3 while grounding the fiber material A3 to which a catalyst is given and moistening the fiber material A3. The present invention relates to the electroless plated fiber material A4 manufactured by the manufacturing method. The present invention relates to a manufacturing system of the electroless plated fiber material A4.

The amount of a processing solution used is reduced, and the quality of an electroless plated fiber material is improved. The present invention relates to a manufacturing method for an electroless plated fiber material A4. The manufacturing method includes a step S5 of electrostatically spraying a solution B containing a catalyst precursor in a state of being electrically charged to a positive potential onto a fiber material A2 while grounding the fiber material A2 and moistening the fiber material A2, and electrostatically spraying a solution C containing a reducing agent in a state of being electrically charged to a positive potential onto the fiber material A2, and a step S7 of electrostatically spraying each of a solution D containing metal ions and a solution E containing a reducing agent each in a state of being electrically charged to a positive potential onto the fiber material A3 such that the solution D containing metal ions and the solution E containing the reducing agent react with each other in the same electric field on the fiber material A3 while grounding the fiber material A3 to which a catalyst is given and moistening the fiber material A3. The present invention relates to the electroless plated fiber material A4 manufactured by the manufacturing method. The present invention relates to a manufacturing system of the electroless plated fiber material A4.

The present invention relates to antimicrobial materials comprising copper and zinc incorporated into or coated on a substrate material, wherein the substrate comprises a rubber component. The present invention also relates to methods of obtaining said antimicrobial materials.

Graphene has been used in nanocomposites as constituents/doping in plastics or epoxy providing dramatic enhancement of the mechanical properties but have not progressed past the laboratory level novelty. This invention can provide a graphene based composite structure with a density less that 1.9 g/cm.sup.3 for a fiber, yarn, rope or cable and a density less that 1.5 g/cm.sup.3 for a sheet both structure have tensile and shear strength greater than either Aluminum or Steel; thus providing a graphene material that is both much lighter and stronger.

Graphene has been used in nanocomposites as constituents/doping in plastics or epoxy providing dramatic enhancement of the mechanical properties but have not progressed past the laboratory level novelty. This invention can provide a graphene based composite structure with a density less that 1.9 g/cm.sup.3 for a fiber, yarn, rope or cable and a density less that 1.5 g/cm.sup.3 for a sheet both structure have tensile and shear strength greater than either Aluminum or Steel; thus providing a graphene material that is both much lighter and stronger.

Articles, compositions, and methods for treating textiles and other materials with an antimicrobial compound during laundry and/or drying cycles are described. The articles and compositions include a metal ion having antimicrobial efficacy. Methods include the use of the articles and compositions in laundry and/or drying cycles to provide antimicrobial treatment of the textiles and materials.

Articles, compositions, and methods for treating textiles and other materials with an antimicrobial compound during laundry and/or drying cycles are described. The articles and compositions include a metal ion having antimicrobial efficacy. Methods include the use of the articles and compositions in laundry and/or drying cycles to provide antimicrobial treatment of the textiles and materials.

In a preferred embodiment, there is provided a modified fabric composition, the composition comprising a fabric member and an electroactive member for storing energy, wherein the fabric member comprises a fabric framework defining a deformable plane and a plurality of projections extending at an angle from the plane, and wherein the electroactive member is coupled to at least one of the projections.

The present disclosure relates to a wearable water triboelectric generator, wherein the water triboelectric generator comprises a first substrate having a first surface and a second surface, wherein the first surface and the second surface are opposing to each other; and wherein the first surface comprises a modified hydrophobic surface comprising a coating of hydrophobic cellulose oleoyl ester nanoparticles. There is also provided a wearable dual mode water and contact triboelectric generator comprising said water triboelectric generator and a contact triboelectric generator, wherein the water triboelectric generator and the contact triboelectric generator are arranged such that the first substrate of the water triboelectric generator completely surrounds or encapsulates the contact triboelectric generator.

The present disclosure relates to a wearable water triboelectric generator, wherein the water triboelectric generator comprises a first substrate having a first surface and a second surface, wherein the first surface and the second surface are opposing to each other; and wherein the first surface comprises a modified hydrophobic surface comprising a coating of hydrophobic cellulose oleoyl ester nanoparticles. There is also provided a wearable dual mode water and contact triboelectric generator comprising said water triboelectric generator and a contact triboelectric generator, wherein the water triboelectric generator and the contact triboelectric generator are arranged such that the first substrate of the water triboelectric generator completely surrounds or encapsulates the contact triboelectric generator.