A laser-engravable pad printing plate comprising at least (a) a metal support, (b) an adhesion layer, (c) a laser-engravable recording layer having a layer thickness of 20 m to 200 m, (d) a cover film,
characterized in that the laser-engravable recording layer (c) comprises (c1) 40 to 95 wt % of a polyvinyl alcohol, (c2) 5 to 50 wt % of an IR absorber, (c3) 0 to 30 wt % of an inorganic filler, (c4) 0 to 20 wt % of a crosslinker, and (c5) 0 to 10 wt % of further additives.

A laser-engravable pad printing plate comprising at least (a) a metal support, (b) an adhesion layer, (c) a laser-engravable recording layer having a layer thickness of 20 m to 200 m, (d) a cover film,
characterized in that the laser-engravable recording layer (c) comprises (c1) 40 to 95 wt % of a polyvinyl alcohol, (c2) 5 to 50 wt % of an IR absorber, (c3) 0 to 30 wt % of an inorganic filler, (c4) 0 to 20 wt % of a crosslinker, and (c5) 0 to 10 wt % of further additives.

An automatic processing device of a carbon fiber tube includes a polishing device, a washing device, a first drying device, a printing device, a painting device and a second drying device centrally disposed along an identical axis in sequence to form an automatic production line. The polishing device includes feeding mechanisms disposed on two sides of a frame respectively and a positioning-polishing mechanism disposed between the feeding mechanisms. The printing device includes a supporting mechanism and a rolling-printing mechanism mounted on the frame. The disclosure aims at providing an automatic processing device of a carbon fiber tube and a processing method thereof, combining the polishing device, the printing device and the painting device as a whole. Separate processes such as polishing, printing and painting of the conventional carbon fiber tube are integrated to achieve the automatic production in the production line, which can significantly speed up the schedule.

According to the invention there is an apparatus for printing onto cylindrical structures comprising: a plurality of inker devices each comprising a print cylinder and one or more servomotors for adjustably controlling the position or orientation of a print cylinder; a blanket device comprising a plurality of print blankets, in which the blanket device is configured to bring each print blanket into contact with the print cylinders to transfer ink from the print cylinders to the print blanket, and to bring each print blanket into contact with a cylindrical structure to achieve printing thereon; a transporter for transporting the cylindrical structures into and out of contact with the print blankets; and an automatic print correction system comprising a print inspection device for detecting a misregistration of ink transferred from one or more of the print cylinders onto a print blanket, and a controller for controlling the servomotors of the print cylinders to correct the misregistration in response to data received from the print inspection device.

A method for forming a dye sublimation image in a vibrating membrane employed in a musical instrument comprising the steps of: providing an image, digitally prepared or otherwise, consisting of a simulated animal skin or another form of graphic; printing the image on a substrate employing a heat transfer ink dye; joining the substrate with the printed image with a sheet of a gas permeable membrane comprised of bi-axially oriented non-woven polyester fibers having a plurality of surface pores and vibrating and musical note producing capability; applying a combination of heat and pressure to the joined substrate with the printed image and the membrane to cause the individual surface pores to expand to enable the dye to gasify and permeate the surface pores to transfer the image; and, cooling the membrane to enable the surface pores to seal closed and encase the image within the surface of the membrane to protect against delamination and wear when the membrane vibrates which results from the intense and constant pounding of a drumstick, a mallet, a person's hand or some other rigid-like object.

A method for forming a dye sublimation image in a vibrating membrane employed in a musical instrument comprising the steps of: providing an image, digitally prepared or otherwise, consisting of a simulated animal skin or another form of graphic; printing the image on a substrate employing a heat transfer ink dye; joining the substrate with the printed image with a sheet of a gas permeable membrane comprised of bi-axially oriented non-woven polyester fibers having a plurality of surface pores and vibrating and musical note producing capability; applying a combination of heat and pressure to the joined substrate with the printed image and the membrane to cause the individual surface pores to expand to enable the dye to gasify and permeate the surface pores to transfer the image; and, cooling the membrane to enable the surface pores to seal closed and encase the image within the surface of the membrane to protect against delamination and wear when the membrane vibrates which results from the intense and constant pounding of a drumstick, a mallet, a person's hand or some other rigid-like object.

According to one embodiment, a tablet printing apparatus includes: a conveyor belt configured to convey a tablet; a first suction path configured to suck the tablet to hold the tablet on the conveyor belt and suck the conveyor belt while allowing the conveyor belt to convey the tablet; a second suction path configured as a different path from the first suction path to suck only the conveyor belt while allowing the conveyor belt to convey the tablet; and a printer configured to perform printing on the tablet conveyed by the conveyor belt.

A method for operating a device for printing hollow cylinder is provided. The device comprises a rotating segmented wheel with a plurality of printing cylinders arranged successively along the periphery of the device. A plurality of plate cylinders are provided in association with the segmented wheel. According to a printing process to be performed, a selected quantity of plate cylinders is thrown onto the segment wheel or is thrown off the segment wheel. In a first printing process, a first partial quantity of thrown-on plate cylinders transfers printing ink to a plurality of the printing blankets arranged on the segment wheel. At the end of the printing process, at least some of the plate cylinders, that were thrown on the segment wheel in the first printing process, are thrown off the rotating segment wheel. During constant uninterrupted rotation of the segment wheel, for the implementation of a second printing process, a second partial quantity of plate cylinders is thrown onto the segment wheel and respectively transfer printing ink to a plurality of the printing blankets arranged on the segment wheel. The respective printing forme of at least one plate cylinder involved in the first printing process, and uninvolved in the ongoing second printing process, is changed during the ongoing printing process.

The present disclosure relates to a robotic apparatus and methods for automatic nail polish application on natural or artificial finger or toe nails.

A system for printing on a multi-dimensional object includes a plurality of print heads, and a printing chase comprising one or more alignment elements configured to provide accurate registration of an object holder (also configured as an object packaging) relative to the print heads. The system further includes an actuator configured to move the printing chase relative to the print heads. The system is configured to receive information corresponding to an alignment element that is employed for positioning the object holder on the printing chase, determine a position a printable area using the retrieved information, receive information relating to print data to be printed on the printable area, use the determined position of the printable area to control a movement of the printing chase relative to the print heads, and operate the print heads to eject marking material onto the printable area to print data on the printable area.