A can imprinting device includes a blanket wheel having a plurality of blankets. Each blanket has a printing surface and at least two of the printing surfaces having a first part and a second part that each have raised and recessed portions. The first raised portion is configured to form a positive image on a can body of the plurality of can bodies. The first raised portion of at least one of the blankets is different in form from the first raised portion of at least one other of the blankets. The second recessed portion is configured to form a negative image on the can body. The negative image is inverse to the positive image. The first part and the second part are disposed relative to each other such that the negative image aligns with the positive image on the can body.

Provided is a flexo printing plate which makes it possible to perform printing in which the discontinuity of density is not visually recognized by inhibiting the enlargement of halftone dots in the boundary between an image area having a low halftone dot rate and a non-image area. The flexo printing plate has a constitution in which the image area has a highlight halftone dot area having a halftone dot rate higher than 0% and equal to or lower than 10%, and within the highlight halftone dot area, among small dots constituting the highlight halftone dot area, at least one of the small dots adjacent to the non-image area that continues 10 mm or further from the edge of the highlight halftone dot area in a direction orthogonal to the edge has a distal end diameter smaller than the average of distal end diameters of the small dots in the highlight halftone dot area.

Provided is a flexo printing plate which makes it possible to perform printing in which the discontinuity of density is not visually recognized by inhibiting the enlargement of halftone dots in the boundary between an image area having a low halftone dot rate and a non-image area. The flexo printing plate has a constitution in which the image area has a highlight halftone dot area having a halftone dot rate higher than 0% and equal to or lower than 10%, and within the highlight halftone dot area, among small dots constituting the highlight halftone dot area, at least one of the small dots adjacent to the non-image area that continues 10 mm or further from the edge of the highlight halftone dot area in a direction orthogonal to the edge has a distal end diameter smaller than the average of distal end diameters of the small dots in the highlight halftone dot area.

A method of making a relief image printing element from a photosensitive printing blank is provided. A photosensitive printing blank with a laser ablatable layer disposed on at least one photocurable layer is ablated with a laser to create an in situ mask. The printing blank is then exposed to at least one source of actinic radiation through the in situ mask to selectively cross link and cure portions of the photo curable layer. Diffusion of oxygen into the at least one photocurable layer is limited during the exposing step and preferably at least one of the type, power and incident angle of illumination of the at least one source of actinic radiation is altered during the exposure step. The resulting relief image comprises dots and a dot shape that provide optimal print performance on various substrates, including corrugated board.

A method of making a relief image printing element from a photosensitive printing blank is provided. A photosensitive printing blank with a laser ablatable layer disposed on at least one photocurable layer is ablated with a laser to create an in situ mask. The printing blank is then exposed to at least one source of actinic radiation through the in situ mask to selectively cross link and cure portions of the photo curable layer. Diffusion of oxygen into the at least one photocurable layer is limited during the exposing step and preferably at least one of the type, power and incident angle of illumination of the at least one source of actinic radiation is altered during the exposure step. The resulting relief image comprises dots and a dot shape that provide optimal print performance on various substrates, including corrugated board.

An imaging printing form having a base body with an elastomeric coating, in which the elastomeric coating carries an engraving pattern. The elastomeric coating has a hard rubber with a hardness of greater than 40 Shore D, and more particularly greater than 70 Shore D. The hard rubber is based on butadiene-acrylonitrile rubber (NBR), carboxyl group-containing nitrile rubber (XNBR), hydrogenated acrylonitrile butadiene Rubber (HNBR) or combinations thereof.

An imaging printing form having a base body with an elastomeric coating, in which the elastomeric coating carries an engraving pattern. The elastomeric coating has a hard rubber with a hardness of greater than 40 Shore D, and more particularly greater than 70 Shore D. The hard rubber is based on butadiene-acrylonitrile rubber (NBR), carboxyl group-containing nitrile rubber (XNBR), hydrogenated acrylonitrile butadiene Rubber (HNBR) or combinations thereof.

An improved apparatus and method for forming images comprising Braille, raised print, regular print, or a combination is described. The architecture for the printing of Braille dots using marking material such as UV gel ink. The UV gel ink is deposited on a drum that has an array of closely packed raised features like mesas that are cup-shaped. The mesas on drum are filled with the UV gel ink and transferred to paper or another substrate. Partial curing can occur on the drum and the dots can be fully cured after transfer to the substrate. The mesas are shaped so that the dots take on a final shape consistent with usual Braille features.

Described herein are an apparatus and a method for direct engraving an elastomeric printing plate or sleeve by multiple laser beams simultaneously. In one embodiment, an elastomeric printing plate or sleeve is positioned on an imaging drum for direct engraving. The imaging drum is rotatable around its longitudinal axis. Such rotation defines a circumferential direction, also called the transverse direction. The axis of rotation defines an axial direction, also called the longitudinal direction. The printing plate or sleeve has an body and a surface made of an elastomer (made of polymer or rubber). A drive mechanism provides relative motion between a plurality of laser beams and the plate or sleeve in both the transverse and longitudinal directions.

Described herein are an apparatus and a method for direct engraving an elastomeric printing plate or sleeve by multiple laser beams simultaneously. In one embodiment, an elastomeric printing plate or sleeve is positioned on an imaging drum for direct engraving. The imaging drum is rotatable around its longitudinal axis. Such rotation defines a circumferential direction, also called the transverse direction. The axis of rotation defines an axial direction, also called the longitudinal direction. The printing plate or sleeve has an body and a surface made of an elastomer (made of polymer or rubber). A drive mechanism provides relative motion between a plurality of laser beams and the plate or sleeve in both the transverse and longitudinal directions.