The invention relates to a floor covering element comprising an insulation layer (1) facing the floor when laid, a backing layer (2) of canvas, provided on the insulation layer (1) and connected to said insulation layer (1), at least the upper face of the backing layer (2) being coated with a primer (3a), wherein a primed layer (4) for at least partially optically designing the floor covering is applied to the primer (3a) on the upper face; and a transparent sealing coat (5) is provided on the printed layer (4), the surface structure of the sealing coat (5) being predetermined by the backing layer (2) of canvas and having a surface roughness (8a) of at least 7.5 μm, in particular at least 8.0 μm, preferably at least 9.4 μm.

A temporary antimicrobial roll-up floor cover includes a rugged upper layer that is impervious to water and pervious water vapor, and a lower antimicrobial wicking layer that quickly spreads water while transmitting water vapor, to facilitate evaporation of moisture that gets under the cover. The cover may also include one or more of a central layer containing a microporous membrane, a coating or film layer which may be perforated, and a stiffener lattice that resists folding, gathering and puckering without preventing the cover from rolling up. The coating layer adds additional resistance to folding, gathering and puckering without preventing the cover from rolling up. The coating may be perforated to increase water vapor transmission through the cover. One or more antimicrobial agents is incorporated into the wicking layer during extrusion of the airlaid mat forming the wicking layer.

A temporary roll-up floor cover includes a rugged upper layer that is impervious to water and pervious water vapor, and a lower antimicrobial wicking layer that quickly spreads water while transmitting water vapor, to facilitate evaporation of moisture that gets under the cover. The cover may also include one or more of a central layer containing a microporous membrane, a coating or film layer which may be perforated, and a stiffener lattice that resists folding, gathering and puckering without preventing the cover from rolling up. The coating layer adds additional resistance to folding, gathering and puckering without preventing the cover from rolling up. The coating may be perforated to increase water vapor transmission through the cover. One or more antimicrobial agents may be incorporated into the floor cover, for example, into the wicking layer during extrusion of the airlaid mat forming the wicking layer.

A three-dimensional interlayer composite carpet that can be washed without deformation is provided in the present invention, which includes a surface layer, a three-dimensional interlayer, and an anti-slip layer. The three-dimensional interlayer is composed of an upper knitted fabric layer, a lower knitted fabric layer, and a composite filament connecting layer arranged vertically in the middle and connecting the upper layer and the lower layer. The three-dimensional interlayer composite carpet adopting a composite filament connecting structure of the present invention has strong supporting force and high extensibility, and can be repeatedly folded for more than 1000 times. The washing shrinkage of 10 washings does not exceed 2%, and the composite carpet will not be deformed under long-term squeezing, heat, and moisture.

A foundry component for an apparatus for casting or handling a metal melt includes a metallic main body which is provided in a melt-contact surface region with an anticorrosion layer structure composed of one or more superposed layers. The anticorrosion layer structure has, as a sole layer or as one of a plurality of layers, a protective woven fabric body prefabricated as flexible woven fabric body from a woven fabric material which is casting temperature resistant or a nonwoven protective layer prefabricated as pliable nonwoven layer from a fiber nonwoven material or fiber paper material which is casting temperature resistant or a protective shaped body prefabricated as rigid shaped body from a material which is casting temperature resistant.

Aspects herein are directed to a textile, and garments produced from the textile, having one or more insulation zones and one or more pile zones where the pile zones seamlessly extend from the insulation zones. The textile includes a first woven layer, a second woven layer, and a nonwoven layer positioned between the first and second woven layers. In the insulation zone, the first woven layer, the second woven layer, and the nonwoven layer are unaffixed from each other. In the pile zone, fibers/filaments from the nonwoven layer are entangled with fibers, filaments and yarns from each of the first woven layer and the second woven layer.

Provided is a protection film including a plurality of layers, including a first carrier layer having a plurality of electrically conductive fibers; a metal layer; and a second carrier layer having a plurality of electrically conductive fibers. Each of the first and second carrier layers has a void volume at least partially filled with a hardenable composition. Also provided is a protection film including a first metal layer, a carrier layer, and a second metal layer, in which the carrier layer is at least partially filled with a hardenable composition. These films can provide lightning strike protection with suitable tensile, rigidity and tack properties for automatic tape layup and automatic fiber placement applications.

The invention relates to a filter medium comprising a reinforced non-woven fabric, to a method for the production thereof, and to the use thereof.

An impact energy dissipating fabric system includes a strike-face layer formed using a Z-axis flock fiber reinforced Organic Polymer Laminar Composite (OPLC), an energy absorbing core media layer attached adjacent the strike-face layer and formed using Foam Impregnated Flocked (FIF) layers and an Against The Body (ATB) Layers including Flocked Energy Absorbing Material (FEAM) attached adjacent to the energy absorbing core media layer and the layers are disposed on one another and coupled together with an adhesive, sewing or quilting.

A fabric (30) includes a first flexible fabric layer (32), having fabric emissivity properties in a visible radiation range that are selected so as to mimic ambient emissivity properties of a deployment environment of the fabric, and at least one second flexible fabric layer (34), which is joined to the first flexible fabric layer, and which is configured to scatter long-wave radiation that is incident on the fabric. The first and second flexible fabric layers are perforated by a non-uniform pattern of perforations (44) extending over at least a part of the fabric.