The present invention provides a hard coating film having excellent optical characteristics and adhesion of a hard coating layer, and having excellent adhesion to a laminated film formed on the hard coating film.

The hard coating film comprises a hard coating layer containing an ionizing radiation curable resin composition provided on at least one surface of a base film, the hard coating film satisfying the following conditions (I), (II), and (III): condition (I): the ionizing radiation curable resin composition comprising an acrylic resin containing a (meth)acryloyl group; condition (II): a peak area ratio 1 ((A/B)100) of 5% or more (provided that in infrared spectrum measurement of the ionizing radiation curable resin composition in an uncured state, a peak area appearing at 3250 to 3500 cm.sup.1 is defined as A, and a peak area appearing at 1650 to 1800 cm.sup.1 is defined as B); and condition (III): a peak area ratio 2 ((C/B)100) of 30% or less (provided that in infrared spectrum measurement of the ionizing radiation curable resin composition in an uncured state, a peak area appearing at 1500 to 1580 cm.sup.1 is defined as C, and a peak area appearing at 1650 to 1800 cm.sup.1 is defined as B).

A coated polymer foil is described and can be produced via coating of a polymer foil with an aqueous composition comprising (A) a polymer which is obtained via free-radical polymerization and which is composed of from 10 to 80% by weight of a compound selected from ethylenically unsaturated anhydrides and ethylenically unsaturated dicarboxylic acids, the carboxylic acid groups of which can form an anhydride group, and (B) an alkanolamine having at least two hydroxy groups. The coating gives the polymer foil an oxygen barrier and can in particular be used for producing packaging.

A method for producing a primary laminate including a tabstock by feeding a seal laminate comprising bottom food contact layers including a foil layer and a top polyester layer to a laminating station wherein either the foil layer of the underside of the polyester layer has been printed; simultaneously feeding a tabstock, which is narrower than the seal laminate, to the laminating station such that the bottom of the tabstock and the top polyester layer of the seal laminate come into contact to form a primary substrate, simultaneously feeding a plastic film stock; and continuously extruding a polymeric adhesive between the top face of the primary substrate and bottom surface of the plastic film stock.

Method of manufacturing a vertically aligned laminated graphene based thermally conductive film. The method comprising: attaching first and second graphene film using a layer of nanoparticles and an adhesive; forming a layered film comprising a predetermined number of graphene film layers by repeating the steps of arranging a layer of nanoparticles, arranging an adhesive and attaching a graphene film; and laminating the layered film by applying pressure and heat to cure the adhesive, thereby forming a laminate film; cutting the laminate film at an angle in relation to a surface plane of the film to form the vertically aligned laminated graphene based thermally conductive film.

Provided is a cold rolled steel sheet with excellent press formability, which contains a binder satisfying specific requirements and wax satisfying specific requirements, and has a layer containing the wax in a specific mass ratio at a specific coating weight.

A composite film, a decorative film and a method of decorating a target substrate are provided. The composite film includes a substrate and a transfer layer disposed on a surface of the substrate. The transfer layer has a loss factor (tan ) in a range between 0.015 and 0.1. The composite film is configured to prepare a laminated thin film, a cold pressed film and a hot pressed film. By controlling property of the transfer layer, material cost of the processes for decorating the target substrate and procedure of waste treatment can be decreased.

A composite sheet material includes a cover sheet, a substrate and an adhesion promoting layer. The cover sheet has a cover sheet material. The substrate has a substrate material. The adhesion promoting layer is disposed between the cover sheet and the substrate. A first side of the adhesion promoting layer disposed towards the cover sheet has an affinity to bond with the cover sheet material. A second side of the adhesion promoting layer disposed towards the substrate has an affinity to bond with the substrate material.

An ionomer-based adhesive polymeric interlayer (API) that provides enhanced properties to rigid substrates through the use of polyvinyl acetal-based controlled debonding zone treatments, and rigid substrate-laminates comprising such interlayers.

A cell module is provided. The cell module includes a first substrate; a second substrate disposed opposite to the first substrate; a cell unit disposed between the first substrate and the second substrate; a first thermosetting resin layer disposed between the cell unit and the first substrate; a first protective layer disposed between the cell unit and the first thermosetting resin layer; and a second thermosetting resin layer disposed between the cell unit and the second substrate. The first protective layer includes a first polymer, wherein the cross-linking degree of the first polymer is 0 to 42.3%.

A transfer-type curable resin sheet for coating, including a coating layer composed of a curable resin composition that is capable of being cured by heat, moisture, or an active energy ray; and a transfer layer composed of a thermoplastic resin, the tack value at 23 C., on the surface of the coating layer on the side opposite to the surface on which the transfer layer is provided being 300 N/cm.sup.2 or more and 4,000 N/cm.sup.2 or less.