A platen assembly for printing on face masks which includes a base member having a plurality of jig members mounted thereon. The base member has a top surface and a bottom surface, with its bottom surface operative to attach to a platen holding mechanism of a conventional direct to garment printer. Each of the jig members may be attached to the top surface of the base member and hold a single face mask in such a manner that it can be printed on. Edges of the base member and of each jig member include interface portions which allow portions of the face mask to be selectively threaded through to more effectively keep the face masks in place, being held smooth and taught.

A hybrid heat transfer label assembly and method for producing the label assembly are provided. The label assembly includes a carrier layer, a non-digitally printed protective layer disposed above the carrier layer, a digitally printed layer disposed above the non-digitally printed protective layer, and a non-digitally printed layer disposed above the digitally printed layer. The non-digitally printed protective layer, the digitally printed layer, and the non-digitally printed layer form a label that is configured to separate from the carrier layer and adhere to an article upon application of heat to the carrier layer.

A hybrid heat transfer label assembly and method for producing the label assembly are provided. The label assembly includes a carrier layer, a non-digitally printed protective layer disposed above the carrier layer, a digitally printed layer disposed above the non-digitally printed protective layer, and a non-digitally printed layer disposed above the digitally printed layer. The non-digitally printed protective layer, the digitally printed layer, and the non-digitally printed layer form a label that is configured to separate from the carrier layer and adhere to an article upon application of heat to the carrier layer.

A method may be provided for manufacturing a panel that may include a substrate and a top layer provided on the substrate. The top layer may have a printed motif and a translucent or transparent synthetic material layer provided above the printed motif. The panel may have a structure or relief at the surface. The method may involve milling profiles into the substrate to obtain mechanical coupling means for coupling together two of the panels. The structure or relief and/or the printed motif may be realized after milling the profiles into the substrate.

A method may be provided for manufacturing a panel that may include a substrate and a top layer provided on the substrate. The top layer may have a printed motif and a translucent or transparent synthetic material layer provided above the printed motif. The panel may have a structure or relief at the surface. The method may involve milling profiles into the substrate to obtain mechanical coupling means for coupling together two of the panels. The structure or relief and/or the printed motif may be realized after milling the profiles into the substrate.

A printing system, a soft deposit system, a sanitary mask printing system, a sustainable mask printing system, processes, and methods of use are presented. The present disclosure provides the state of the art with a printing system for printing on delicate material. Whereas delicate material has been impossible to consistently, rapidly, and efficiently print upon, the present disclosure relates to a printing process and method of printing for printing custom pieces on delicate sustainable masks. More specifically, and without limitation, the present disclosure relates to a process and method of printing with respect to healthcare and virtual reality sanitary masks.

A stamp for micro-transfer printing includes a support having a support stiffness and a support coefficient of thermal expansion (CTE). A pedestal layer is formed on the support, the pedestal layer having a pedestal layer stiffness that is less than the support stiffness and a pedestal layer coefficient of thermal expansion (CTE) that is different from the support coefficient of thermal expansion (CTE). A stamp layer is formed on the pedestal layer, the stamp layer having a body and one or more protrusions extending from the body in a direction away from the pedestal layer. The stamp layer has a stamp layer stiffness that is less than the support stiffness and a stamp layer coefficient of thermal expansion that is different from the support coefficient of thermal expansion.

A stamp for micro-transfer printing includes a support having a support stiffness and a support coefficient of thermal expansion (CTE). A pedestal layer is formed on the support, the pedestal layer having a pedestal layer stiffness that is less than the support stiffness and a pedestal layer coefficient of thermal expansion (CTE) that is different from the support coefficient of thermal expansion (CTE). A stamp layer is formed on the pedestal layer, the stamp layer having a body and one or more protrusions extending from the body in a direction away from the pedestal layer. The stamp layer has a stamp layer stiffness that is less than the support stiffness and a stamp layer coefficient of thermal expansion that is different from the support coefficient of thermal expansion.

A thread printing system includes a source spool containing thread. The system also includes various print heads, each of which is fluidly connected to an ink tank. The print heads are positioned to direct and apply ink to a segment of the thread as the thread travels along a transport path along from the source spool. The system also includes a fuser having one or more print rollers that are connected to a heating element. The fuser receives the dyed thread and fuses the ink to the thread. The system may include a controller that is configured to apply ink of different colors to different segments of the thread.

In some embodiments, a printer system may include a location sensor, a motor and driver assembly configured for adjusting a print position of a subsequent image on a substrate having a first side and a second side and at least one wireless communication device, and an optical sensor. Adjustment of the print position may be based on detection of the wireless communication device using the location sensor and a subsequent determination of whether the corresponding printed image is properly aligned with the wireless communication device using the optical sensor.