An encapsulated polymeric article is disclosed. The encapsulated polymeric article may include a polymer substrate and a metallic outer shell at least partially encapsulating the polymer substrate. The encapsulated polymeric article may be fabricated by a method comprising: 1) providing a mandrel in a shape of the encapsulated polymeric article, 2) shaping the metallic outer shell on the mandrel, 3) removing the mandrel from the metallic outer shell, and 4) molding the polymeric substrate into the metallic outer shell through a port formed in the metallic outer shell to provide the encapsulated polymeric article.

A multi-layered sheet material (1) including a reinforcing support (2) having a polymer coating (3) on at least one side, alternatively on both sides, wherein the reinforcing support (2) includes at least one textile fabric (6), such as a supporting woven fabric (6a), wherein the fabric (6), has at least two surface regions (13a; 13b; 34a; 34b) that differ from each other in at least one mechanical property, as well as a crossway element, such as a crossway bellows, for components, vehicles, building connections, or for flight passenger bridges or staircase bridges, including at least one such multi-layered sheet material, and a vehicle, a building connection, and a flight passenger or staircase bridge including such a crossway element.

A film for laminating glass includes a first surface layer, a second surface layer opposite the first surface layer, and an interlayer disposed between the first surface layer and the second surface layer, wherein the interlayer includes a trioxane-based compound.

A thermal shield system with wireless control capabilities including a multi-layer shield, a housing containing a power source and processor, and a programmable control mechanism, wherein the control mechanism is in communication with the processor to facilitate direct or remote manual programming of time and temperature of the shield system. The multi-layer shield includes a perimeter having a first layer comprised of reflective material, a second layer comprised of a plurality of conductive pads arranged in a plurality of rows within a structural support sheet, a third layer comprised of thermal material, an electrical wire running through and connecting said conductive pads of the second layer, and a surround spanning the perimeter of the shield. The surround of the shield has flexibility to allow folding or rolling for compact storage of said shield and having rigidity to provide structural integrity of said shield. The electrical wire connects each of the plurality of conductive pads in a series to generate consistent and uniform heat while minimizing depletion of the power source.

A multiaxial fabric resin base material includes a multiaxial fabric base material laminate impregnated with a thermosetting resin (B), the multiaxial fabric base material laminate including fiber bundle sheets layered at different angles, the fiber bundle sheets including unidirectionally aligned fiber bundles stitched with stitching yarns composed of a thermoplastic resin (A), the multiaxial fabric base material laminate being penetrated in the thickness direction by other bodies of the stitching yarns, and being stitched with the other bodies of the stitching yarns such that the yarns reciprocate at predetermined intervals along the longitudinal direction, the thermoplastic resin (A) constituting the stitching yarns having a softening point, the softening point being higher than the resin impregnation temperature of the thermosetting resin (B).

An acoustic composite comprising a plurality of discrete air flow resistive layers layered on top of each other including a top layer and one or more lofted fibrous layers produced by a lapping process, the top layer having a specific air flow resistance that is greater than a specific air flow resistance of the one or more lofted fibrous layer.

Laminated glazings with embedded wire circuits, have many uses. But, due to the higher cost of manufacture, they are not widely used. This invention provides a process to reduce the cost of production for embedded wire laminated glazing. Rather than embedding the wire one interlayer at a time, several circuits are produced on the same sheet, cut out and then inserted into the interlayer of each separate laminate during assembly, reducing the direct labor and capital investment required.

A display module is provided, which encloses a display assembly by using a flexible cover, thereby sealing a first gap between a backlight housing and a support structure and a second gap between the support structure and a display panel. It can isolate external water vapor and dust from entering an interior of the display assembly, thereby improving the dustproof and waterproof capabilities of the display module, and further improving the reliability of the display module.

Laminated glass includes: an outer glass plate having a first side and a second side; an inner glass plate that is arranged opposing the outer glass plate and has substantially the same shape as a shape of the outer glass plate; and an intermediate layer arranged between the outer and the inner glass, wherein the intermediate layer has a heat-generating layer including: a first bus bar that extends along an end portion closer to the first side; a second bus bar that extends along an end portion closer to the second side; and a plurality of heating lines arranged so as to connect the first bus bar and the second bus bar to each other, and when a predetermined voltage is applied between the first and second bus bars, an amount of heat generated per unit length of each of the heating lines is 2.0 W/m or less.

A laminated glazing usable as a heatable glazing for means of transportation. Also, a method for producing the laminated glazing and a method for decreasing the sheet resistance of the laminated glazing.