A novel fabric combination is provided to absorb electromagnetic radiation (ER) and electromagnetic field (EMF) waves. The fabric combination may be shaped into a wearable garment or an electronics case or cover. The fabric combination includes carbon yarn or carbon pieces, elastic yarn, and a soft yarn, such a wool or cotton. No metals configured to reflect ER and EMF waves are used, such as silver. The elastic yarn is a carbon stretch yarn made up of synthetic elastic fabric, such as spandex, and carbon fibers. The fabric combination absorbs ER and EMF waves from the environment, produced by electric devices, such as phones, laptops, tablet computers, microwaves, ovens, robots, 4G, 5G, Wi-Fi radiation, Bluetooth, or any other device or environmental sources emitting ER and EMF.

A textile sleeve for routing and protecting an elongate member has a wrappable wall including a textile layer having an inner surface and an opposite outer surface extending lengthwise between opposite ends and widthwise between opposite edges. The opposite edges are configured to be wrapped about a central longitudinal axis to bound a central cavity extending lengthwise along the central longitudinal axis between the opposite ends. The textile layer is formed of yarns interlaced with one another, wherein a least some of the yarns include metal wire(s). A silicone-based layer is disposed about the outer surface of the textile layer to provide enhanced heat-resistance, dielectric protection and impact resistance.

Provided are a cloth and a protective product, which allow for any color appearance and have excellent protection performance against electric arcs. The cloth has a woven fabric structure, wherein a front-surface spun yarn containing an infrared absorber- and/or electrically conductive agent-containing fiber and not containing carbon is located on a front surface, while a back-surface spun yarn containing a carbon-containing fiber is located on a back surface, and the cloth has an ATPV value of 8.0 cal/cm.sup.2 or more in Arc Resistance Test ASTM F1959-1999.

The agricultural greenhouse of the invention and the plant cultivation method using the same can cultivate plants economically and efficiently with less energy per crop yield, as it is provided with a CO.sub.2 supply means, a heat-ray shielding means, and a dehumidification and cooling means, the heat-ray shielding means is formed of using a heat-ray reflecting film, and plural through holes are formed in the heat-ray shielding means. The heat-ray reflecting film structure can cultivate plants by the agricultural greenhouse utilizing sunlight economically and efficiently as it has a structure that narrow band-shaped tapes obtained by cutting a multi-layer laminated film made by laminating at least two kinds of resin layers with different refractive indices alternately and having an average transmittance at 80% or more for visible light and an average reflectance at 70% or more for heat-ray is woven or knitted as a warp or a weft.

A wrappable woven sleeve includes a wall having opposite edges extending lengthwise between opposite ends. The opposite edges are configured to be wrapped about a central longitudinal axis, whereupon the wall takes on a tubular configuration with an inner surface of the wall bounding an enclosed cavity sized for receipt of an elongate member to be protected therein and an outer surface of the wall facing radially outwardly from the central longitudinal axis. The wall is woven with warp filaments extending generally parallel to the central longitudinal axis and weft filaments extending generally transversely to the warp filaments. One or more of the warp filaments are wire to shield against passage of low frequency EMI. A foil layer is fixed to the outer and/or inner surfaces of the wall to shield against passage of high frequency EMI.

An electromagnetic shielding device (40) including at least one hollow protective textile sleeve (50) having a main rest diameter D1 and an interior volume configured to receive one or several elongated element(s) (20, 21), at least one hollow connecting textile sleeve (60) having a rest diameter D2, D2 greater than D1. The protective textile sleeve (50) comprises a substantially annular front part (52) having a front open end (54), the connecting textile sleeve (60) includes a substantially annular rear part (62) having a rear open end (64), and the shielding device (40) includes a first electrically conductive, in particular at least partially annular, securing area (70) in which the rear part (62) of the connecting sleeve (60) and the front part (52) of the protective sleeve (50) are at least partly secured.

An innovative high-energy oxidative method using metallic copper and chlorine liquid to produce a superior copper chloride II element using electromagnetic induction and magnetic forces. This invention involves copper undergoing oxidation while in its highest energy state according to basic principles of electromotive forces described in Faraday's law. The copper attaches to a magnetic receptacle and held in place by a copper lid cover. Research studies demonstrate that metallic copper is not magnetic; however, when a magnetic field approaches copper, the electrons and subatomic particles forms a higher resistance against the magnets—Generating a force field response towards the approaching magnets. The oxidation of copper in its highest energy state provides additional improvements and benefits in copper's antimicrobial and antiviral properties. This new method for oxidizing copper chloride in its highest subatomic energy state provides vast improvements and coverage in the fight against microorganisms and the invisible pathogens abroad.

Fabrics and garments are disclosed that have dual protection against flash fires and electrical arc flashes. The fabrics can be made from spun yarns containing an intimate blend of fibers. The fibers contained in each yarn can include modacrylic fibers, natural cellulose fibers, and inherently flame resistant fibers.

The agricultural greenhouse of the invention and the plant cultivation method using the same can cultivate plants economically and efficiently with less energy per crop yield, as it is provided with a CO.sub.2 supply means, a heat-ray shielding means, and a dehumidification and cooling means, the heat-ray shielding means is formed of using a heat-ray reflecting film, and plural through holes are formed in the heat-ray shielding means. The heat-ray reflecting film structure can cultivate plants by the agricultural greenhouse utilizing sunlight economically and efficiently as it has a structure that narrow band-shaped tapes obtained by cutting a multi-layer laminated film made by laminating at least two kinds of resin layers with different refractive indices alternately and having an average transmittance at 80% or more for visible light and an average reflectance at 70% or more for heat-ray is woven or knitted as a warp or a weft.

A mesh structure is a knitted fabric or woven fabric including element wires of a zirconium copper fiber or element wires of a stainless steel fiber.