A method of manufacturing a printing cylinder. The method comprises providing a moulding apparatus comprising a cylindrical moulding vessel defining a moulding cavity (101). The vessel comprises at least one inlet for the ingress of moulding material. The method comprises performing an injection moulding operation comprising: injecting moulding material through the at least one inlet to substantially fill the moulding cavity with moulding material; and effecting hardening of the moulding material within the vessel (102). The method comprises removing the printing cylinder (103). At least part of the injection moulding operation is performed in the presence of an active pressure being applied to the moulding cavity.

Flexographic printing members amenable to aqueous (or organic) development do not exhibit the deleterious effects on printing performance characteristic of some conventional alternatives. Embodiments of the invention utilize a photopolymerizable layer comprising, consisting of, or consisting essentially of a photopolymerization initiator and a water-dilutable (but not water-soluble) monomer.

Flexographic printing members amenable to aqueous (or organic) development do not exhibit the deleterious effects on printing performance characteristic of some conventional alternatives. Embodiments of the invention utilize a photopolymerizable layer comprising, consisting of, or consisting essentially of a photopolymerization initiator and a water-dilutable (but not water-soluble) monomer.

A device for imprinting cans comprises a plurality of ink cartridges that supply ink to a plurality of printing plates; the printing plates communicate with transfer blankets fixed to a drum, the transfer blankets move ink from the printing plates and apply it to cans; each transfer blanket includes a different art in low relief which produces an image on cans in addition to the image produced by printing plates; the device is preferably a rotary dry offset printer.

A device for imprinting cans comprises a plurality of ink cartridges that supply ink to a plurality of printing plates; the printing plates communicate with transfer blankets fixed to a drum, the transfer blankets move ink from the printing plates and apply it to cans; each transfer blanket includes a different art in low relief which produces an image on cans in addition to the image produced by printing plates; the device is preferably a rotary dry offset printer.

A photosensitive flexographic printing form, and process for manufacturing the same. The printing form includes a base, a first series of relief patterns having a first elevation with respect to the base in an image area of the base, and a second series of relief patterns having one or more elevations lower than the first elevation and located outside of the image area.

A photosensitive flexographic printing form, and process for manufacturing the same. The printing form includes a base, a first series of relief patterns having a first elevation with respect to the base in an image area of the base, and a second series of relief patterns having one or more elevations lower than the first elevation and located outside of the image area.

The present invention relates to a printing form for flexographic printing. The printing form contains microcell patterns on its relief printing surface. The presence of these microcell patterns allows for printing with a higher anilox roll volume. Also disclosed are five specific microcell patterns.

A method of improved screening to increase stability in flexographic printing is provided. The method is performed by a flexographic printing system. The flexographic printing system includes a computer system and a flexographic printing device. The method includes analyzing the first proposed graphical input of the printing job to identify at least one highlight area containing a plurality of halftone graphical elements in the first proposed graphical input, determining an amount of white space between the plurality of the halftone graphical elements in the first proposed graphical input, assigning at least one graphical element to be placed in a spatial relationship with each of the plurality of the halftone graphical elements, generating a second proposed graphical input by placing the at least one graphical elements on the first proposed graphical input based on the respective assignment, and instructing the flexographic printing device to print the second proposed graphical input.

A method for writing an imageable material using multiple beams includes preparing subsequent patterns each having Y rows of N pixel locations, said subsequent patterns including first and second patterns; where the first and the second pattern overlap with each other in an overlap area consisting of O columns and Y rows of pixel locations; selecting for each row i of said first pattern Mi1 pixel locations; selecting for each row i of said second pattern Mi2 pixel locations; writing simultaneously, for each row i, said Mi1 selected pixel locations by moving the N beams in a fast scan direction relative to said imageable material; and moving said N beams relative to said imageable material in a slow scan direction over (N-O) pixel locations; writing simultaneously, for each row i, said Mi2 selected pixel locations by moving the N beams in a fast scan direction relative to said imageable material.