An impression station of a printing system comprises a rotatable impression cylinder with an impression cylinder gap housing a plurality of grippers recessed therein. A pressure cylinder assembly comprises a pressure cylinder comprising a pressure cylinder gap and an angle portion joining a trailing edge of the pressure cylinder gap and an outer circumferential surface of the pressure cylinder. A compressible blanket is disposed around the circumference of the pressure cylinder. A margin insert is interposed between the pressure cylinder and the compressible blanket at least at the angle portion, such that a local external geometry of the pressure cylinder assembly at the angle portion is changed by the presence of the margin insert. The change in the local external geometry of the pressure cylinder assembly due to the presence of the margin insert is effective to reduce a dimension of an unprinted leading-edge margin.

According to aspects of the embodiments, there is provided a method of measuring the amount of fountain solution employed in a digital offset lithography printing system. Fountain solution thickness is measured using a diffractive optical element (DOE) configured with grating surfaces varying in a periodic fashion to hold an amount of fountain solution. When radiated with a light source the combination of the grating surface and the fountain solution therein reduces the scattering of the surface structure (“contrast”) that gives rise to a diffraction pattern. The diffractive optical element can be placed on the printing blanket of the lithography printing system or on a separate substrate.

An impression station of a printing system comprises a rotatable impression cylinder with an impression cylinder gap housing a plurality of grippers recessed therein. A pressure cylinder assembly comprises a pressure cylinder comprising a pressure cylinder gap and an angle portion joining a trailing edge of the pressure cylinder gap and an outer circumferential surface of the pressure cylinder. A compressible blanket is disposed around the circumference of the pressure cylinder. A margin insert is interposed between the pressure cylinder and the compressible blanket at least at the angle portion, such that a local external geometry of the pressure cylinder assembly at the angle portion is changed by the presence of the margin insert. The change in the local external geometry of the pressure cylinder assembly due to the presence of the margin insert is effective to reduce a dimension of an unprinted leading-edge margin.

A container body decorator (10) has a controller (300) with a software stored in a memory. A plurality of ink-jet printing heads (108) is in communication with the controller (300). A segmented image transfer blanket (116) has a circumferential configuration with an inner surface opposite a printing surface. A printing site (124) is located along the segmented image transfer blanket (116). A container body handling module (200) delivers container bodies to the printing site (124).

A container component decorating system has a decorating station (156), a container component handling module (102), a supply of colored inks, and inkjet printheads (124). The decorating station (156) delivers art graphics to container components (14) in a manufacturing queue (22). The inkjet printheads (124) comprise nozzles through which the colored inks are delivered. A flush cycle controller activated a flush cycle of the nozzles to deposit a flush cycle ink pattern (109) on a substrate to restore a meniscus (110) on the nozzles.

A printing assembly is disclosed for thermal transfer printing onto a surface of a substrate. The assembly comprises at least one first printing system comprising a transfer member having opposite front and rear sides with an imaging surface on the front side, a coating station at which a monolayer of thermoplastic particles is applied to the imaging surface, an imaging station at which energy is applied by a thermal print head, optionally via the rear side of the transfer member, to selected regions of the imaging surface to render particles coating the selected regions tacky, a transfer station at which the imaging surface of the transfer member and the substrate surface are pressed against each other to transfer to the substrate the particles that have been rendered tacky to form an adhesive image; and at least one more printing system downstream from the first system.

A printing assembly for thermal transfer printing is disclosed. The assembly comprises at least one first printing system comprising a transfer member having an imaging surface on the front side, a coating station at which a monolayer of thermoplastic particles is applied to the imaging surface, an imaging station at which electromagnetic radiation (EM) is applied, optionally via the rear side of the transfer member, to selected regions of the imaging surface to render the particles coating the selected regions tacky, a transfer station at which only the regions of the particles coating that have been rendered tacky are transferred to a substrate to form an adhesive image; and at least one more downstream printing system. The transfer member includes on its front side an EM radiation absorbing layer, the imaging surface being formed on, or as part of, the absorbing layer, and on its rear side a body which can optionally be transparent to EM radiation.

An inkjet image forming apparatus includes a transferer and a hardware processor. The transferer transfers, onto a recording medium, ink that is ejected from an inkjet head and is borne on a transfer member. The hardware processor performs control for reducing transferability of the ink in a case where the ink borne on the transfer member is not-to-be-transferred ink, compared with a case where the ink is to-be-transferred ink.

A printing template for use during an aqueous inkjet printing process in which ink is transferred onto a printable layer. The printing template includes a printable layer having two sides, and a shaped perimeter, the first side defining a printable surface. The printing template further includes a carrier layer sized and configured to entirely encompass the shaped perimeter of the printable layer. The carrier layer includes a first side and a second side opposite the first side. The first side includes an adhesive coating causing the first side of the carrier layer securely associated with the second side of the printable layer during the printing process, and is thereafter allowing removal of the carrier layer from the printable layer after completion of the printing process. Further, a predefined number of parts in a desired shape are die cut through the printable layer up until the carrier layer.

A system (10) includes an intermediate transfer member (ITM) (44) and a substrate conveyor (80). The ITM (44) is configured to receive droplets of one or more printing fluids so as to form an image thereon, and to transfer the image to a target substrate (50). The substrate conveyor (80) is configured to grip and move the target substrate (50) to and from the ITM (44) for transferal of the image, the substrate conveyor (80) includes one or more rotatable elements (110, 200), which are configured to provide mechanical support to the target substrate (50), such that, when the target substrate (50) moves over the one or more rotatable elements (110, 200), at least one of the rotatable elements (110, 200) is configured to rotate in response to a physical contact with the target substrate (50).