Provided herein are multilayer polymeric interlayers comprising ionomers and acoustic damping compositions, and glass laminates made from them, which provide an improved combination of hurricane resistance, acoustic damping properties and, optionally, solar barrier performance.

Provided herein are multilayer polymeric interlayers comprising ionomers and acoustic damping compositions, and glass laminates made from them, which provide an improved combination of hurricane resistance, acoustic damping properties and, optionally, solar barrier performance.

A method of thermoforming an article from an integrated transparent conductive film, comprising: applying an ultraviolet curable transfer coating to a first surface of a recipient substrate or to a first surface of a donor substrate, wherein the first surface of the donor substrate includes a conductive coating coupled thereto; pressing the first surface of the recipient substrate and the first surface of the donor substrate together to form a stack; heating the stack and activating the ultraviolet curable transfer coating with an ultraviolet radiation source; removing the donor substrate from the stack leaving a transparent conductive layer, wherein the ultraviolet curable transfer coating remains adhered to the first surface of the recipient substrate and to the conductive coating; laser etching an electrical circuit onto a transparent conductive layer second surface to form an integrated transparent conductive film; and thermoforming the integrated transparent conductive film to form the article.

The purpose of the present invention is to provide a laminate excellent in terms of rigidity and low specific gravity and a fiber-reinforced composite obtained from the laminate. The present invention relates to a laminate which comprises a fibrous sheet for reinforcement and a thermoplastic resin sheet, characterized in that (i) the thermoplastic resin sheet is a polypropylene resin composition comprising (A) 70-95 parts by weight of a polypropylene resin (A ingredient) and (B) 30-5 parts by weight of a polycarbonate resin (B ingredient) and (ii) the fibrous sheet for reinforcement is constituted of reinforcing fibers, the content of which is 20-150 parts by weight per 100 parts by weight of resin ingredients comprising the A ingredient and B ingredient.

The present invention provides methods of preparing peelable seal layers, methods of preparing multilayer films, peelable seal layers made therefrom, and multilayer films made therefrom. In one aspect, a method of preparing a peelable seal layer comprises (a) providing a first blend comprising (i) from 5 to 98 percent by weight of a reactor grade propylene based plastomer or elastomer having a molecular weight distribution of less than 3.5 and a density of less than 0.89 g/cc and (ii) from 2 to 95 percent by weight of a second polymer selected from the group consisting of polyethylene, polybutylene, and styrenic polymer and mixtures thereof; (b) providing at least one linear low density polyethylene; (c) blending the first blend with the at least one linear low density polyethylene to obtain a second blend; and (d) extruding the second blend to form a peelable seal layer, wherein the peelable seal layer has a heat seal initiation temperature less than 120 C. when sealed at a bar pressure of 40 psi with a dwell time of 0.5 seconds.

An object of the present invention is to provide an inorganic board suitable for achieving high specific strength and high freeze-thaw resistance as well as weight reduction and a method for producing the inorganic board. An inorganic board X1 according to the present invention includes a cured layer 11 that includes an inorganic cured matrix, an organic reinforcement material dispersed therein, and a hollow body that is attached to the organic reinforcement material and is smaller than the maximum length of the organic reinforcement material. A method for producing an inorganic board according to the present invention includes a first step of preparing a first mixture through mixing of an organic reinforcement material and a hollow body smaller than the maximum length of the organic reinforcement material, a second step of preparing a second mixture through mixing of the first mixture, a hydraulic material, and a siliceous material, and a third step of forming a second mixture mat by depositing the second mixture.

A non-slip mat comprises an absorbent top layer, an impermeable middle layer, a non-slip bottom layer, and a reinforced outer hem. The reinforced outer hem is formed on at least one edge of the non-slip mat by folding all the layers of non-slip mat at least once such that the bottom layer is facing the bottom layer and the top layer is disposed on both top and bottom surfaces. A method for applying an adhesive coating material on a canvas includes heating the adhesive coating material and at least one roller of an apparatus, advancing the canvas through the apparatus in a forward direction to contact the at least one heated roller, and while advancing the canvas, a uniform coating of the adhesive coating material is applied on a surface of the canvas with the at least one heated roller.

A subsea well equipment landing body (1) includes an indicator assembly to indicate landing of the landing body or to indicate locking of the landing body. The indicator assembly has a stem bore (7), a sliding stem (11) within the stem bore that has a stem head (23) protruding beyond an external face of the landing body. A stem channel (25) in the sliding stem extends between the stem head and a stem channel mouth (27), and is in fluid communication with the outside of the landing body. A hydraulic channel (9) in the landing body is in fluid communication with the stem bore. The stem channel mouth is positionable in a communicating position, in which there is fluid communication between the hydraulic channel and the stem channel, and a non-communicating position, without fluid communication between the hydraulic channel and the stem channel.

The present disclosure relates to a multilayer sheet comprising TPE (e.g., TPO) with at least one solid layer, and at least one foamed layer on the opposite side or one side of the solid layer. The web can be up to 3.2 meters wide with a gauge variation of less than 1%, and the average variation of the weight per unit area (gr/m.sup.2) of the sheet across the web is less than 2%. The foam sheet of the present invention can have an overal thickness of less than 50 mils with a bending stiffness value of less than 5, in Taber stiffness unit configuration according to TAPPI/ANSI T 489 om-15.

A self-adhesive thermal insulation product is provided. The self-adhesive thermal insulation product includes a fibrous polymeric backing, an adhesive layer, an insulation batt attached to the central adhesive portion, and a release layer. An adhesive tape for home insulation is also provided. The adhesive tape for home insulation includes a fibrous polymeric backing, an adhesive layer on a front surface of the fibrous polymeric backing, and a release layer. An adhesive seal is also provided.