A sublimation device includes a first heater and a second heater. The first heater includes a proximal end, a distal end, and an inner surface. The distal end is disposed opposite the proximal end. The inner surface extends between the proximal end and the distal end and at least partially forms a cavity. The second heater is disposed proximate the distal end of the first heater.

A processing liquid composition of the present disclosure subjected to textile printing and which is used by being attached to a fabric including fibers having a hydroxyl group, includes an oxazoline group-containing polymer and an aromatic carboxylic acid. An oxazoline value of the oxazoline group-containing polymer is preferably 100 or more and 600 or less.

A method of operating a sublimating device includes providing heat to a cavity of the sublimating device by increasing (i) a temperature of a heater to a predetermined target temperature and (ii) a temperature of a base heater to a predetermined standby temperature. The method further includes determining a difference between the predetermined target temperature and a reduced temperature of the heater. The method also includes determining whether a workpiece is arranged in the cavity based on the difference between the predetermined target temperature and a reduced temperature.

A composite image heat transfer is disclosed for use on specific merchandising articles, sports jerseys, or other apparel for a specific sport. A scannable mark would be embedded in a heat transfer positioned on a sports jersey, such as a jersey number or a club crest. The scannable mark would be scanned by a user to provide stats, personal information, or other information about the corresponding sports team/club and/or individual athlete. The user can also register the scannable mark and follow the sports team/club and/or athlete on social media. Thus, the composite image heat transfer with embedded scannable mark would link each jersey number with information related to the corresponding player/athlete, and each club crest would be linked to information related to the corresponding club/team. This would enable a strong interaction through social media and other web tools between athletes and/or clubs and fans.

A composite image heat transfer is disclosed for use on specific merchandising articles, sports jerseys, or other apparel for a specific sport. A scannable mark would be embedded in a heat transfer positioned on a sports jersey, such as a jersey number or a club crest. The scannable mark would be scanned by a user to provide stats, personal information, or other information about the corresponding sports team/club and/or individual athlete. The user can also register the scannable mark and follow the sports team/club and/or athlete on social media. Thus, the composite image heat transfer with embedded scannable mark would link each jersey number with information related to the corresponding player/athlete, and each club crest would be linked to information related to the corresponding club/team. This would enable a strong interaction through social media and other web tools between athletes and/or clubs and fans.

Coating outer surfaces of a polymeric panel with a decorative pattern printed on the outer surfaces using an ink which is transferred to the panel by sublimation in a vacuum chamber under predetermined temperature, pressure, and time conditions. The panel has a perimetral area having a greater thickness and at least one non-perimetral area having a smaller thickness. All the surfaces of the panel coated with the decorative pattern have a uniform finish. A protective layer is placed on a non-perimetric zone of the panel to prevent overheating during the panel curing process and to avoid imperfections on the decorative pattern from being formed on the non-perimetric zone.

It is the object of the present invention to provide a new polymer coating for low temperature plastics and plastic foams that allows for the application of disperse dyes in a sublimation process that preserves the original properties of the underlying plastic substrate. The composition includes an optically clear synthetic organic polymer base holding two layers, a first reflective layer supported by the low temperature plastic substrate that includes IR radiation reflecting additives, and a second layer supported by the first layer having light scattering particulate additives. The disperse dyes utilized in the invention may include additives to absorb IR radiation provided by an external IR source positioned above the disperse dyes causing the dyes to sublimate and diffuse quickly into the light scattering layer. The combination of these layers allows for diffusion of the disperse dye ink into the light scattering layer while protecting the low temperature plastic below.

It is the object of the present invention to provide a new polymer coating for low temperature plastics and plastic foams that allows for the application of disperse dyes in a sublimation process that preserves the original properties of the underlying plastic substrate. The composition includes an optically clear synthetic organic polymer base holding two layers, a first reflective layer supported by the low temperature plastic substrate that includes IR radiation reflecting additives, and a second layer supported by the first layer having light scattering particulate additives. The disperse dyes utilized in the invention may include additives to absorb IR radiation provided by an external IR source positioned above the disperse dyes causing the dyes to sublimate and diffuse quickly into the light scattering layer. The combination of these layers allows for diffusion of the disperse dye ink into the light scattering layer while protecting the low temperature plastic below.

In one method, a piece of nonwoven PET or PP fabric is formed into a tote bag using a bag forming device. Seams of the tote bag are ultrasonically welded using an ultrasonic bag welding device. The ultrasonic bag welding device includes at least one sonotrode. In another method, BOPP film is received and a full-color graphic is printed on the BOPP film for each tote bag using a printer. The printed BOPP film is received from the printer and nonwoven PP or PET fabric is received from a roll of nonwoven PP or PET fabric using a laminator. The printed BOPP film is laminated to the nonwoven PP or PET fabric. The printed BOPP film laminated to nonwoven PP or PET fabric is received from the laminator and a finished version of each tote bag is produced using an ultrasonic bag welding device.

In one method, a piece of nonwoven PET or PP fabric is formed into a tote bag using a bag forming device. Seams of the tote bag are ultrasonically welded using an ultrasonic bag welding device. The ultrasonic bag welding device includes at least one sonotrode. In another method, BOPP film is received and a full-color graphic is printed on the BOPP film for each tote bag using a printer. The printed BOPP film is received from the printer and nonwoven PP or PET fabric is received from a roll of nonwoven PP or PET fabric using a laminator. The printed BOPP film is laminated to the nonwoven PP or PET fabric. The printed BOPP film laminated to nonwoven PP or PET fabric is received from the laminator and a finished version of each tote bag is produced using an ultrasonic bag welding device.