A surface treatment method for a composite surface of a basic casing is provided. The composite surface is cooperatively formed by an outer surface and four sidewalls surrounding the outer surface. The surface treatment method includes following steps. A heat transferring film is provided. A printing pattern film is formed on a portion of the heat transferring film via a digital inkjet printing process. The heat transferring film is formed on the composite surface via a vacuum heat transfer process, with edges of the heat transferring film being wrapped around the sidewalls and the printing pattern firm being attached to the outer surface.

A heat press for decorating substrates includes a support frame, a lower platen assembly supported on the support frame, and a linkage assembly having at least an upper link arm pivotally coupled with the support frame for movement to and between first and second positions. An upper platen assembly is coupled with the support frame by the linkage assembly for movement relative to the lower platen assembly to and between an open condition away from the lower platen assembly, and a closed condition adjacent the lower platen assembly, as the upper link arm is moved to and between the first and second positions. A linear actuator cooperates with the linkage assembly to further move the upper platen assembly in the closed condition in a direction to clamp an upper platen against a lower platen by moving an actuator rod from an extended position toward a retracted position.

An object of the present invention is to provide a laminated member for decoration that can be molded into a complicated shape and has a superior hardcoating property. The present invention relates to a laminated member for decoration having a protective film, a coating layer and a resin substrate, wherein the surface roughness Rz(a) of the adhesive layer of the protective film on the side where the coating layer is located and the surface roughness Rz(b) of the coating layer of an unheated sample formed by peeling the protective layer, the surface roughness being taken on the side opposite from the resin substrate, define Rz(b)/Rz(a)×100 having a prescribed relationship; the surface roughness Rz(b) and the surface roughness Rz(bh) of the coating layer of a heated sample prepared by heating the unheated sample under a prescribed condition, the surface roughness being taken on the side opposite from the resin substrate, satisfy at least one of Formulas (2) and (3) below:

0%≤Rz(bh)/Rz(b)×100<30%  (2), and

0≤Rz(bh)≤Rz(b)<0.5 μm  (3);

and the unreacted (meth)acryloyl groups of the coating layer of the heated sample irradiated with a prescribed amount of active energy rays have disappeared 10 to 100% as compared with the coating layer of the unheated sample.

A casing component according to an embodiment of the present technology includes a to-be-decorated area and a decoration portion. The to-be-decorated area includes a plurality of to-be-decorated surfaces to be decorated, the plurality of to-be-decorated surfaces being formed such that adjacent to-be-decorated surfaces have different heights. The decoration portion includes a metal layer formed in each of the plurality of to-be-decorated surfaces.

Provided is an image transfer material, comprising a support, optionally at least one barrier layer, a melt transfer layer, and an image receiving layer. Also provided is a process for preparing the image transfer material. Further provided is a heat transfer process using the disclosed material. In the heat transfer process, after imaging, the image receiving layer and melt transfer layer are peeled away from the optionally barrier-coated support material and placed, preferably image side up, on top of a receptor element. A non-stick sheet is then optionally placed over the imaged peeled material and heat is applied to the top of the optional non stick sheet. The melt transfer layer then melts and adheres the image to the receptor element. A composition comprising: at least one self-crosslinking polymer, and at least one dye retention aid.

A laminate that possesses dye sublimation properties, particularly for use as tagless labels and embellishments for garments, apparel, fabric items and so forth such as sportswear fabrics, clothing and accessories is provided. The laminate includes a dye sublimation ink layer that overlies a substrate in which the dye sublimation ink interacts with the substrate's chemical make-up.

A method of customizing an article with graphics applied using a graphic transfer assembly is disclosed. The method includes a step of creating or selecting a customized graphic to be applied to an article. The article and the customized graphic are placed within the graphic transfer assembly. A deformable membrane may apply the customized graphic to curved portions of the article.

A heat transfer label and method for preparing same, the heat transfer label including (a) a support portion and (b) a transfer portion over the support portion, for transfer of the transfer portion from the support portion to an article upon application of heat to the support portion while the transfer portion is placed into contact with the article. The transfer portion includes at least a protective lacquer layer, an ink layer, and an adhesive layer, wherein at least one of the protective lacquer layer, the ink layer, and the adhesive layer is UV-curable. Further, the heat transfer label may additionally include a tie-coat layer, which may be a UV-curable tie-coat layer. Further, each of the plurality of layers of the transfer portion of the heat transfer label may be UV-curable.

A film for decorative forming includes a layered structure in which a protective layer and a colored layer are arranged sequentially in this order on a base material film, wherein, when a storage elastic modulus of the protective layer at 100° C. is written as E′a(100) and a storage elastic modulus of the colored layer at 100° C. is written as E′b(100), E′a(100) and E′b(100) satisfy conditions (1) to (3): (1) E′a(100)/E′b(100) is less than or equal to 8, (2) E′a(100) is greater than or equal to 10 MPa, (3) E′b(100) is less than or equal to 12 MPa.

A transfer laminate (35), comprising a carrier film having an adhering decorative element having a solid, pigmented, partially cured decorative layer, is laminated on the decoration side onto a substrate (40) having a temperature between 50 and 70° C. on the decoration side, on which substrate a coating that can be painted over has been applied in the course of a traditional process. The paint layer of the coating that was applied last is still moist and tacky after the intermediate drying thereof. The transfer laminate (35) is laminated onto the still moist and tacky paint layer on the substrate (40), and at least the region of the transfer laminate (35) containing the decorative element is pressed onto the substrate coating over the entire area at a pressure of 0.2 to 5.0 bar for 40 to 240 seconds. Then the carrier film is quickly cooled to a temperature less than 20° C. and then removed from the substrate coating, wherein the decorative element remains on the substrate coating. The device for transfer lamination forms an applicator (10), which comprises: two flexible membranes (20, 22), which are both clamped pressure-tight on a common frame (12) along the perimeter of the membranes in such a way that an intermediate space is created therebetween, in which a flexible warm—or hot-water layer (27) can be enclosed; a chamber (30), which can be filled with compressed air, wherein overall such an arrangement is created that a gradual introduction of compressed air into the chamber (30) moves the two flexible membranes (20, 22) and the flexible warm—or hot-water layer (27) jointly in the manner of a balloon onto the substrate surface (42) to be coated in order to apply the transfer laminate (35) to and press the transfer laminate onto said substrate surface (42) without bubbles.