The present invention provides a system and process for direct-to-transfer printing, including heat presses and corresponding heat press stations through which the heat presses are indexed, and at which garments are (1) dressed upon the heat presses; (2) the garments are pre-pressed; (3) thereafter components are sequentially placed on top of and fused with their corresponding garments by applying heat and pressure; and (4) the finished garments are unloaded from the heat presses. The present invention also provides a component on a carrier sheet for use in such a direct-to-transfer printing system and process, which includes identification and registration symbols (such as barcodes, QR codes or other suitable markings) in addition to a design or embellishment. The present invention further provides an ASR system for use with a direct-to-transfer printing system.

The present invention provides a system and process for direct-to-transfer printing, including heat presses and corresponding heat press stations through which the heat presses are indexed, and at which garments are (1) dressed upon the heat presses; (2) the garments are pre-pressed; (3) thereafter components are sequentially placed on top of and fused with their corresponding garments by applying heat and pressure; and (4) the finished garments are unloaded from the heat presses. The present invention also provides a component on a carrier sheet for use in such a direct-to-transfer printing system and process, which includes identification and registration symbols (such as barcodes, QR codes or other suitable markings) in addition to a design or embellishment. The present invention further provides an ASR system for use with a direct-to-transfer printing system.

The present disclosure relates to a pretreatment device capable of increasing a number of media on which a pretreatment can be performed within a fixed period. The pretreatment device includes a platen, a pretreatment portion configured to perform the pretreatment on a medium set on the platen, and a belt configured to convey the platen from a set position to the set position via the pretreatment portion. The medium is placed on the platen at the set position. Thus, since the belt conveys the platen on which the medium is set, the pretreatment device is able to perform the pretreatment on a plurality of the media within the fixed period.

Disclosed is a pallet for printing on an article of clothing. The pallet includes a mount plate including a first end and a second end and a top plate including a first end and a second end. The second end of the top plate located at the second end of the mount plate. A gap is between the top plate and the mount plate. A collar plate is located on the first end of the mount plate. The first end of the mount plate extends beyond the first end of the top plate to define a space between the top plate and the collar plate.

Disclosed is a pallet for printing on an article of clothing. The pallet includes a mount plate including a first end and a second end and a top plate including a first end and a second end. The second end of the top plate located at the second end of the mount plate. A gap is between the top plate and the mount plate. A collar plate is located on the first end of the mount plate. The first end of the mount plate extends beyond the first end of the top plate to define a space between the top plate and the collar plate.

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.

Systems and methods for film positive print transfers during screen printing utilize positive artwork, one or more film positive design backups and one or more presses are presented. A screen having positive artwork creates one or more positive artwork design backups, which are stored for later use or used immediately. One or more items are screen printed with the positive artwork design. The one or more positive artwork design backups may be removed from storage and used to transfer the positive artwork to one or more replacement items.

Systems and methods for film positive print transfers during screen printing utilize positive artwork, one or more film positive design backups and one or more presses are presented. A screen having positive artwork creates one or more positive artwork design backups, which are stored for later use or used immediately. One or more items are screen printed with the positive artwork design. The one or more positive artwork design backups may be removed from storage and used to transfer the positive artwork to one or more replacement items.

A transfer-printing ink contains a pigment and a fixing resin. The mass ratio of the pigment to the fixing resin is 1:1 to 1:5, and the ink has a viscosity of 3 mPas to 10 mPas at 23 C. The ink is ejected onto a transfer paper base by an ink-jet recording device when transfer paper is prepared. The ink is then transferred from the transfer paper to cloth as a result of the transfer paper, with the cloth laid over it, being heated.

A transfer-printing ink contains a pigment and a fixing resin. The mass ratio of the pigment to the fixing resin is 1:1 to 1:5, and the ink has a viscosity of 3 mPas to 10 mPas at 23 C. The ink is ejected onto a transfer paper base by an ink-jet recording device when transfer paper is prepared. The ink is then transferred from the transfer paper to cloth as a result of the transfer paper, with the cloth laid over it, being heated.