A pressureless high-frequency suspension thermal transfer printer is disclosed, in which a high-frequency signal of 60-100 Hz is generated by a high-frequency switching power supply, and a high-frequency energy conversion motor is driven to convert a signal into high-frequency mechanical vibration which produces 60-100 Hz high-frequency waves which propagate in a longitudinally diffused manner in which an entire transfer printing surface is covered in a direction that is perpendicular to the transfer printing surface, avoiding wasteful loss in the direction of lateral propagation parallel to the transfer printing surface, so that the high-frequency waves act on a molecular movement during the transfer printing process to the greatest extent, which effectively changes a state of the molecular movement, enhances a molecular penetration force, realizes replacement of physical pressure with the high-frequency waves, completely changes a thermal transfer printing process, and achieves pressureless thermal transfer printing.

A pressureless high-frequency suspension thermal transfer printer is disclosed, in which a high-frequency signal of 60-100 Hz is generated by a high-frequency switching power supply, and a high-frequency energy conversion motor is driven to convert a signal into high-frequency mechanical vibration which produces 60-100 Hz high-frequency waves which propagate in a longitudinally diffused manner in which an entire transfer printing surface is covered in a direction that is perpendicular to the transfer printing surface, avoiding wasteful loss in the direction of lateral propagation parallel to the transfer printing surface, so that the high-frequency waves act on a molecular movement during the transfer printing process to the greatest extent, which effectively changes a state of the molecular movement, enhances a molecular penetration force, realizes replacement of physical pressure with the high-frequency waves, completely changes a thermal transfer printing process, and achieves pressureless thermal transfer printing.

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.

There is provided a drinking or eating vessel comprising an inner surface that defines a volume for receiving liquid or solid food and an outer surface that supports a polymeric coating and a decorative layer; wherein the polymeric coating comprises a polymer formed by curing a coating mixture on the outer surface of the drinking or eating vessel, said coating mixture comprising a matting agent; wherein the polymeric coating has an inner surface in contact with the drinking or eating vessel and an outer surface exposed to contact by a user of the vessel; and wherein the decorative layer forms a diffuse layer within the polymeric coating. Also provided are corresponding processes for producing the drinking or eating vessel.

There is provided a drinking or eating vessel comprising an inner surface that defines a volume for receiving liquid or solid food and an outer surface that supports a polymeric coating and a decorative layer; wherein the polymeric coating comprises a polymer formed by curing a coating mixture on the outer surface of the drinking or eating vessel, said coating mixture comprising a matting agent; wherein the polymeric coating has an inner surface in contact with the drinking or eating vessel and an outer surface exposed to contact by a user of the vessel; and wherein the decorative layer forms a diffuse layer within the polymeric coating. Also provided are corresponding processes for producing the drinking or eating vessel.

The present invention relates to a preparation comprising a light stabilizer, its use for the production of a transfer medium, a process making the same, as well as a transfer medium and its use.

A method for texturing a thermoplastic substrate, while forming a dye sublimation image in the thermoplastic substrate is provided. A stack comprising a thermoplastic substrate and a plurality of processing layers is provided, wherein the plurality of processing layers comprise a dye carrier having a dye image and an elastomeric membrane and wherein at least one of the processing layers of the stack is textured. A vacuum pressure is provided on the stack through an elastomeric membrane, wherein the stack is clamped together. The stack is heated to at least a sublimation temperature of the stack, wherein texture from at least one of the process layers is transferred to the thermoplastic substrate. The thermoplastic substrate is cooled to a release temperature. The vacuum pressure is removed. The thermoplastic substrate is removed from the stack.

A method for texturing a thermoplastic substrate, while forming a dye sublimation image in the thermoplastic substrate is provided. A stack comprising a thermoplastic substrate and a plurality of processing layers is provided, wherein the plurality of processing layers comprise a dye carrier having a dye image and an elastomeric membrane and wherein at least one of the processing layers of the stack is textured. A vacuum pressure is provided on the stack through an elastomeric membrane, wherein the stack is clamped together. The stack is heated to at least a sublimation temperature of the stack, wherein texture from at least one of the process layers is transferred to the thermoplastic substrate. The thermoplastic substrate is cooled to a release temperature. The vacuum pressure is removed. The thermoplastic substrate is removed from the stack.

Provided is a decorative building material and a method of manufacturing the same, and more particularly to a decorative building material which is manufactured by a simple process and has a print layer excellent in sharpness, realism, and stereoscopic effect as well as having a functional layer such as an impact absorbing property and a manufacturing method thereof. The method of manufacturing a decorative material includes the steps of: (S1) preparing a transfer film on which a pattern is printed; (S2) preparing a substrate comprising polyvinyl chloride resin, a white film comprising polyvinyl chloride resin, and a transparent film comprising polyvinyl chloride resin; (S3) laminating the white film, the transparent film, and the transfer film on the substrate in order and at the same time performing a heat treatment under pressure; and (S4) peeling off the transfer film.

Provided is a decorative building material and a method of manufacturing the same, and more particularly to a decorative building material which is manufactured by a simple process and has a print layer excellent in sharpness, realism, and stereoscopic effect as well as having a functional layer such as an impact absorbing property and a manufacturing method thereof. The method of manufacturing a decorative material includes the steps of: (S1) preparing a transfer film on which a pattern is printed; (S2) preparing a substrate comprising polyvinyl chloride resin, a white film comprising polyvinyl chloride resin, and a transparent film comprising polyvinyl chloride resin; (S3) laminating the white film, the transparent film, and the transfer film on the substrate in order and at the same time performing a heat treatment under pressure; and (S4) peeling off the transfer film.