A method for manufacturing a thermal transfer from a high-loft substrate such as velvet. The method begins with a high-loft material sheet. The sheet is registered in a vacuum press, and a vacuum is applied to one side. A sublimation graphic is printed onto an opposing side of the high-loft material sheet. Next, an adhesive layer is laminated onto the opposing side of the printed sheet. The sheet is optionally laser-etched on the printed side, and is laser-cut into a desired shape. A protective release sheet is applied over the printed graphic. The method makes it possible to sublimation-print the transfer onto high-loft fabric such as velvet and yet still retain fine graphical registration and detail.

A unique heat transfer is disclosed for use on specific merchandising articles for a specific event. The heat transfer would be used to promote an event and would be used as a ticket to that event. The heat transfer comprises printed matter applied to a base material. The base material would be part of a clothing article, such as a t-shirt, cap, sweatshirt, garment, accessory etc. The printed matter would be visually recognizable information incorporating text, pictures, numbers, bar codes, and QR codes. The visually recognizable information can be printed with ultraviolet-curable inks, or other suitable inks. Once the heat transfer is applied to the clothing article, user would use the clothing article as a ticket to the event. The heat transfer on the clothing article would be scanned and the unique bar code and/or QR codes would be used to identify the user's seat location and other identifying details.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.

Components of articles that include an optical element that imparts structural color to the component are provided. Methods of making the components including the optical element, and methods of using the components such as to make an article of manufacture are provided.

Technologies are generally provided for textile items with breathable heat transfer labels. In some examples, a reversed design of a label may be printed onto a surface of a carrier using a water-based or solvent-based ink. A layer of a thermoplastic adhesive may be applied onto the surface of the carrier with the reversed design and a predefined pattern of holes may be laser-drilled into the carrier through the thermoplastic adhesive to avoid appearance of burn marks on an external surface of the label in the completed product. The carrier may be onto a garment or textile item by affixing the thermoplastic adhesive onto a surface of the garment and activating the thermoplastic adhesive. The carrier may then be removed revealing the design of the label with laser-drilled holes on the garment or textile item.

The present invention provide a multi-layered heat transfer sheet comprising a plurality of distinct pieces forming one or more consecutive patterns that form shapes or objects having discontinuous peripheries, as well as a method for producing and/or making said item. The method for forming the heat transfer decorations includes ablating one or more layers of a heat transfer sheet using a defocused laser to define at least one plurality of discrete pieces that together define a heat transfer decoration. A single pass of the defocused laser may ablate the one or more layers of the heat transfer sheet so as to define the discrete pieces.

As described above, one or more aspects of the present disclosure provide articles having structural color, and methods of making articles having structural color. The articles incorporate a primer layer having a percent transmittance of about 40% or less in conjuction with an optical element. The optical element and primer layer impart a structural color to the article.

One or more aspects of the present disclosure provide optical element transfer structures that include an optical element releasably coupled with a transfer medium and methods of making and using the optical element transfer structures. The optical element transfer structures can be used to dispose an optical element onto an article, whereby the optical element imparts a structural color to the article.

A method of manufacturing an in-mold decorative molded article includes supplying an in-mold transfer foil to a metal mold, injecting and cooling a molding resin and taking out an molded article formed of the molding resin cooled and cured in the metal mold in which a clear layer and a transfer layer having a decorative figure in the in-mold transfer foil are integrated on the surface by opening the mold, molding the molded article integrally with a cutting portion not necessary for a target product inside the metal mold by the molding resin at an outer periphery of the product and arranging a boundary of a printing region of the clear layer in the in-mold transfer foil in the cutting portion so as to be larger than the outer periphery of the product.

The present disclosure provides, in some examples, a method, a system, and a computer program for vectorizing a QR code with an image in an online store or platform, digitizing the QR code with associated image, printing the QR code with the image on a sublimation/heat transfer paper, placing the paper onto a fabric, loading a cutter machine with the fabric, cutting the fabric into a patch with design details of QR code, and placing the patch onto a garment.