In a laminated steel plate in which steel plates are joined to both faces of a core layer, the core layer is formed of a meshed wire group formed using wires in a mesh form and a resin sheet, the wires forming the meshed wire group have a tensile strength of 601 MPa or higher, and an opening of the meshed wire group is equal to or less than ten times the thickness of the steel plates. By thus defining the tensile strength of the wires, light-weightness can be achieved compatibly with high rigidity and shock resistance, and by defining the opening of the meshed wire group, workability and shape stability after being processed can be improved.

A laminate comprises one or more electrically-conductive layers and one or more electrically-insulative layers coupled to the electrically-conductive layer(s). Each of the electrically-conductive layer(s) can comprise at least 90% by weight of copper. Each of the electrically-insulative layer(s) can comprise a layer of polymeric aerogel. For at least one of opposing front and back surfaces of the laminate, at least a portion of the surface is defined by one of the electrically-conductive layer(s).

Low-density thermoplastic expandable microspheres are disclosed. Various low-density structures, in particular, sandwich panels, based on foam prepared from the low-density microspheres, are also disclosed. Process of preparing low-density polymeric microspheres, per se, and the corresponding low-density structures, based on the microsphere foam, are also disclosed.

Fire retardant laminates including a textile layer, a protective layer, and a fire retardant are provided. The protective layer includes a porous membrane and a coating layer. The porous membrane is positioned between the textile layer and the coating layer. The fire retardant includes one or more phosphonate esters of the general formula: ##STR00001##
where n=0 or 1, R.sub.1 and R.sub.2 are C.sub.1-C.sub.4 alkyl, R.sub.3 is H or C.sub.1-C.sub.4 alkyl, and R.sub.4 is a linear or branched alkyl. At least a portion of the phosphonate ester in the fire retardant laminate resides in the coating layer. The fire retardant laminates are suitable for use in protective garments that provide full flammability and burn protection, even after exposure to flammable materials such as petroleum, oils, and lubricants. A method of rendering the fire retardant laminate fire retardant is also provided.

A down-proof fabric includes a base fabric, an adhesive layer disposed on the base fabric, and at least one down-proof functional layer disposed on the adhesive layer. The down-proof functional layer includes a plurality of voids to block the penetration of the down. The present disclosure improves the drawbacks of conventional down-proof techniques and provides a light, thin, and breathable down-proof fabric with good hand feeling.

Water impermeable, air permeable membrane assemblies are described herein. In some embodiments, the assemblies include a polymer membrane and at least one support structure. Certain assemblies are configured to provide an acoustic impedance having phase angle of +45 degrees to −45 over a frequency range of 50 to 20,000 Hz.

The invention relates to a method for producing a surface-structured layered material which has a backing layer (I) and a polyurethane layer (2) connected thereto, the backing layer (I) used, in particular in pieces, being a leather, preferably a smoothed full-grain leather or a split cowskin, a textile material, preferably a woven fabric or a knitted fabric, a cellulose fibre material, a split foam, a leather fibre material or a microfibre fleece and being connected to the layer (2), and the layer (2) applied to the backing layer (I) being at least one, preferably a single layer formed of a PU foam, in particular containing gas pockets, preferably a whipped PU foam optionally containing hollow microspheres and/or a PU foam containing hollow microspheres. According to the invention: —the PU foam, in particular containing gas pockets, is created with a PU dispersion mixture, wherein the individual PU dispersions used to create the PU dispersion mixture exhibit different softening points in the dry state; —to create the PU dispersion mixture, one or more PU dispersions having heat—preferably melting and contact adhesive properties and a softening point in the dry state greater than 40° C., preferably greater than 45° C., in an amount of 18 to 52 wt ¾ of the finished PU dispersion mixture is/are mixed with one or more PU dispersions without melting and contact adhesive properties and with a softening point greater than 95° C., preferably greater than 125° C., in an amount of 39 to 73 wt ¾ of the finished PU dispersion mixture; —the PU dispersion mixture for the layer (2) is applied to the backing layer (I) with a thickness such that the layer has a thickness in the dried state of 0.075 to 0.450 mm, preferably 0.150 to 0.280 mm; —before or during structuring of the PU foam, a further layer (3) of a non-foamed PU dispersion which is a mixture of multiple PU dispersions is applied to the layer (2); —the backing layer (I) is optionally cut or punched into banks or pattern parts before or after the application of the PU foam, in particular after the drying thereof, and the coated blanks or pattern parts are subjected to stamping or structuring under pressure and temperature; and —the backing layer (1), the further layer (3) and the layer (2) are compressed and joined to one another and structured with a die (4) under application of a contact pressure of 4 to 48 kg/cm2, preferably 4 to 48 kg/cm2, in particular 18 to 25 kg/cm2.

An embodiment of the present invention provides a polyolefin microporous membrane, including: a first porous layer containing a polyolefin and having a structure including a first rod-shaped crystal extending in one direction and plural first plate-shaped crystals arranged in a separated state and intersecting the first rod-shaped crystal, and a second porous layer containing a polyolefin and having a structure including a second rod-shaped crystal extending in another direction intersecting the one direction and plural second plate-shaped crystals arranged in a separated state and intersecting the second rod-shaped crystal.

A cast piece cooling method, a gel sheet, a multilayer microporous polyethylene separator, and a preparation method are provided. The cast piece cooling method includes: changing an opening degree of a die head so that a molten material flowing out of the die head is an arc-shaped molten material; calendering a cast piece so that the arc-shaped molten material passes vertically through a gap between a first casting roller and a pinch roller to form a calendered cast piece; and gradually cooling, so that the calendered cast piece is guided and transported along surfaces of other casting rollers to the last casting roller, and cooling the calendered cast piece, to obtain a gel sheet.

A display device is disclosed, including: a back plate, a display module disposed on a side of the back plate, a cover plate disposed on a side of the display module away from the back plate, and a buffer layer disposed on a side of the back plate away from the cover plate. Wherein, the buffer layer includes at least one of at least one first sub-buffer layer, at least one second sub-buffer layer, and at least one third sub-buffer layer. The first sub-buffer layer is made of a foamed material with a completely closed hole structure, the second sub-buffer layer is made of a foamed material with a half-open and half-closed hole structure, and the third sub-buffer layer is made of a foamed material with a completely open hole structure.