Methods of producing a graphic mesh for a solar module are described in which mesh parameters such as warp fiber thickness, weft fiber thickness, and open area size are determined to meet a target energetic efficiency and a chromatic effectiveness. In some embodiments, chromatic effectiveness is based on mesh count, where the mesh count is set according to a distance at which the mesh will be viewed when assembled into the solar module. The mesh has a plurality of warp fibers having the warp fiber thickness and a plurality of weft fibers having the weft fiber thickness, that are interlaced to form a plurality of mesh unit cells. A graphic appearance is printed into the mesh using a coloring substance, where the coloring substance is absorbed by the fiber material to form the graphic mesh.

A water-repellent structure includes: a base material; and a water-repellent layer located on a surface of the base material. The water-repellent layer contains water-repellent particles and filler particles having an average particle size that is 20 times or more as large as an average particle size of the water-repellent particles.

Methods of producing a graphic mesh for a solar module are described in which mesh parameters such as warp fiber thickness, weft fiber thickness, and open area size are determined to meet a target energetic efficiency and a chromatic effectiveness. In some embodiments, chromatic effectiveness is based on mesh count, where the mesh count is set according to a distance at which the mesh will be viewed when assembled into the solar module. The mesh has a plurality of warp fibers having the warp fiber thickness and a plurality of weft fibers having the weft fiber thickness, that are interlaced to form a plurality of mesh unit cells. A graphic appearance is printed into the mesh using a coloring substance, where the coloring substance is absorbed by the fiber material to form the graphic mesh.

Methods of producing a graphic mesh for a solar module are described in which mesh parameters such as warp fiber thickness, weft fiber thickness, and open area size are determined to meet a target energetic efficiency and a chromatic effectiveness. In some embodiments, chromatic effectiveness is based on mesh count, where the mesh count is set according to a distance at which the mesh will be viewed when assembled into the solar module. The mesh has a plurality of warp fibers having the warp fiber thickness and a plurality of weft fibers having the weft fiber thickness, that are interlaced to form a plurality of mesh unit cells. A graphic appearance is printed into the mesh using a coloring substance, where the coloring substance is absorbed by the fiber material to form the graphic mesh.

A coated staple fiber (1) suitable for obtaining protective and floating padding, having a core consisting of at least one natural and/or man-made organic staple fiber (F) and comprising: I) a base tackifier layer (A) which covers the natural and/or man-made organic staple fiber (F) and which comprises a hydrocarbon resin II) an intermediate heat insulating and fire retardant layer (B) which covers the base layer (A) and which comprises aerogel microparticles evenly but not continuously distributed, III) a top hydrophobic layer (C) which covers the intermediate layer (B) and which comprises organosilanes, wherein the base layer (A) binds the intermediate layer (B) to the natural and/or man-made organic staple fiber (F) and the intermediate layer (B) is included between the base layer (A) and the top layer (C).

A coated staple fiber (1) suitable for obtaining protective and floating padding, having a core consisting of at least one natural and/or man-made organic staple fiber (F) and comprising: I) a base tackifier layer (A) which covers the natural and/or man-made organic staple fiber (F) and which comprises a hydrocarbon resin II) an intermediate heat insulating and fire retardant layer (B) which covers the base layer (A) and which comprises aerogel microparticles evenly but not continuously distributed, III) a top hydrophobic layer (C) which covers the intermediate layer (B) and which comprises organosilanes, wherein the base layer (A) binds the intermediate layer (B) to the natural and/or man-made organic staple fiber (F) and the intermediate layer (B) is included between the base layer (A) and the top layer (C).

An aqueous binder composition. The aqueous binder composition is obtainable by radically initiated polymerization of vinyl acetate and ethylene, in the presence of polyvinyl alcohol in an aqueous medium, wherein (a) 50 to 94 wt % of vinyl acetate, (b) 5 to 40 wt % of ethylene, (c) 0.2 to 5 wt % of acrylamide and/or methacrylamide, and (d) 0.2 to 5 wt % of maleic anhydride and/or maleic acid are copolymerized in the presence of a polyvinyl alcohol having a degree of hydrolysis of 80 to 99 mol %. The amounts in wt % are each based on the total weight of the comonomers and add up in each case to 100 wt %.

A method for producing a resin composition including a first kneading step for loading acetylated cellulose fibers having a weighted average fiber length of 0.20 mm to 1.50 mm, a compatibilized resin, and urea in a kneading machine and kneading the same.

A fabric printable medium includes a fabric base substrate including yarn strands and voids among the yarn strands; a finishing coating attached to the yarn strands of the fabric base substrate to form coated yarn strands; and pore spaces among the coated yarn strands and coinciding with at least some of the voids of the fabric base substrate. The finishing coating includes a crosslinked polymeric network. The fabric printable medium further includes a fire retardant coating applied to aback-side of the coated yarn strands.

In one embodiment, a fabric is treated by creating a treatment solution comprising a fluid repellant and an antimicrobial compound, creating a treatment foam from the treatment solution, and applying the treatment foam to only an outer side of a fabric so as to coat the outer side of the fabric with the fluid repellant and the antimicrobial compound without coating an inner side of the fabric with the fluid repellant and the antimicrobial compound.