The present invention relates to a UV-curable ink composition, a method for producing a bezel pattern of a display substrate using same, and a bezel pattern produced thereby, the UV-curable ink composition comprising a colorant, an epoxy compound, an oxetane compound and a photopolymerization initiator, wherein a content ratio of the epoxy compound to the oxetane compound is 1:0.5 to 1:6 and the curing dose amount of the ultraviolet curable ink composition is 20 to 5,000 mJ/cm.sup.2.

A mandrel wherein a portion of the mandrel body outer surface is conical; i.e., flared outwardly, is provided. In this configuration, the necked can is drawn against the conical portion of the mandrel body outer surface while a generally cylindrical portion of the mandrel body extends into the can. Further, the space between the cylindrical portion of the mandrel body and the can is pressurized so as to resist deformations in the can during the decorating process. In an exemplary embodiment, the mandrel includes an elongated mandrel body with an outer surface, a proximal, first end, a proximal medial portion, a distal medial portion, and a distal, second end and having an axis of rotation. The mandrel body outer surface includes an elongated conical portion; the mandrel body outer surface conical portion is disposed adjacently about the mandrel body first end.

The present invention relates to a UV-curable ink composition, a method for producing a bezel pattern of a display substrate using same, and a bezel pattern produced thereby, the UV-curable ink composition comprising a colorant, an epoxy compound, an oxetane compound and a photopolymerization initiator, wherein a content ratio of the epoxy compound to the oxetane compound is 1:0.5 to 1:6, a taper angle after being cured is 0 to 30, and optical density (OD) value is 0.05 to 2.5 per a film thickness of 1.0 m.

The present disclosure describes a printing machine for direct printing on containers, comprising: a continuously rotatable carousel for conveying the containers, a plurality of printing units, and stationary docking stations for docking the printing units to the periphery of the carousel. Due to the fact that the printing machine comprises rail guides stationarily associated with the docking stations and used for separately moving the printing units from a docked-on operating position outwards to a maintenance position spaced apart from the carousel, and back again, the printing units can easily be made accessible from several sides for maintenance and they can be locked quickly and reproducibly at their operating position.

Disclosed is a double-station airtight grade printing device, comprising a station I driving cylinder, a station II driving cylinder, a moving platform II, sensor supports, visual sensors, support frames, lifting cylinders, guide posts, lifting platforms, steel grade printers and the like. In the working process of the device, a wheel inlet roller bed continuously feeds wheels, and a station I and a station II alternatively receive the wheels, thereby avoiding long-time waiting of the wheels on the wheel inlet roller bed.

A mandrel wherein a portion of the mandrel body outer surface is cortical; i.e., flared outwardly, is provided. In this configuration, the necked can is drawn against the conical portion of the mandrel body outer surface while a generally cylindrical portion of the mandrel body extends into the can. Further, the space between the cylindrical portion of the mandrel body and the can is pressurized so as to resist deformations in the can during the decorating process. In an exemplary embodiment, the mandrel includes an elongated mandrel body with an outer surface, a proximal, first end, a proximal medial portion, a distal medial portion, and a distal, second end and having an axis of rotation. The mandrel body outer surface includes an elongated conical portion; the mandrel body outer surface conical portion is disposed adjacently about the mandrel body first end.

What is disclosed is system which facilitates the application of a mark to a surface of an object in a direct-to-object print system and a direct-to-object print system configured to use various embodiments of the present marking system. The present marking system comprises a camera for capturing an image of an object retained by an object holder configured to slideably traverse a support member positioned to be parallel to a plane formed by at least one printhead configured to eject in onto a surface of the object. A processor receives an image of an object held and communicates the image to a display. A mark to be printed on the object is retrieved and overlaid on the object in the image. A location of the overlaid mark is determined and communicated to a controller which causes the printhead to print the mark on the object at the location.

The present disclosure relates to methods and apparatuses for printing and drying inks on substrates. Printing systems may include a metering device positioned between a printing station and a light source. During operation, the printing station deposits ink onto a substrate to define a printed region. And the light source directs infrared light onto the substrate to define an illumination zone. The printed region is advanced from the printing station to the metering device and from the metering device through the illumination zone, wherein the ink is dried with infrared light traveling from the light source, which also heats the substrate and changes the modulus of elasticity of the substrate. In turn, the metering device isolates the printing station from the change in the modulus of elasticity to help reduce phase shifts caused by changes in the modulus of elasticity resulting from heat in the substrate.

A manufacturing method of a tool surface mark includes a first cleaning step, a first electroplating step, a second cleaning step, a drying step, a printing step, a cation removal step, and a second electroplating step. In the first electroplating step, the surface of the tool is electroplated, and a first protective layer is formed on the surface of the tool. In the cation removal step, the tool is placed into an electrolyte and then electrically connected to an anode, the anode is electrically energized, and metal cations on the surface of the tool and on the printing pattern are dissolved. In the second electroplating step, the surface of the tool is electroplate at potions without the printing pattern to form a second protective layer. The yield of the printing pattern increases and the printing pattern does not easy peel off.

What is disclosed is system which facilitates the application of a mark to a surface of an object in a direct-to-object print system and a direct-to-object print system configured to use various embodiments of the present marking system. The present marking system comprises a camera for capturing an image of an object retained by an object holder configured to slideably traverse a support member positioned to be parallel to a plane formed by at least one printhead configured to eject in onto a surface of the object. A processor receives an image of an object held and communicates the image to a display. A mark to be printed on the object is retrieved and overlaid on the object in the image. A location of the overlaid mark is determined and communicated to a controller which causes the printhead to print the mark on the object at the location.