Provided herein is a topcoat composition comprising at least one fluorosilicone, a hydride-functional crosslinking agent, an infrared-absorbing filler, and at least one dispersant that is non-reactive with the hydride-functional crosslinking agent, by weight based on a total weight of the topcoat composition, wherein the topcoat composition has a degree of crosslinking between about 10 micrograms/hour/milligrams to about 20 micrograms/hour/milligrams. Further provided herein are methods of making the topcoat composition, as well as an imaging blanket and methods of reducing coating defects on a media coated using the imaging member.

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.

Provided herein is an imaging blanket for variable data lithography comprising (i) a substrate and (ii) a thermally-conductive composition disposed on the substrate comprising a silicone elastomer and a thermally-conductive filler selected from metal oxides, wherein the thermally-conductive composition has a thermal conductivity ranging from about 0.6 W/m.sup.2 to about 1.6 W/m.sup.2. Further provided herein a method of making the imaging blanket, as well as a printing system comprising the imaging blanket, wherein the imaging blanket has improved thermal conductivity.

A multilayer imaging blanket for a variable data lithography system, including a multilayer base including a sulfur-containing layer; and a cured topcoat layer including a polyurethane in contact with the sulfur-containing layer of the multilayer base.

A method for manufacturing a printing blanket including an elastic body that can be repeatedly used by removing a sheet is provided. According to the above of the present invention, the printing blanket includes an elastic body and a sheet bonded to the elastic body and performs printing by pressing the sheet against a printing object surface. The method includes a sheet fixing step of fixing the sheet at a periphery of a region in which the sheet is to be bonded to the elastic body; an elastic body placing step of placing the elastic body so that a bonding surface of the elastic body faces a bonding surface of the sheet that is fixed; a wax applying step of forming a wax layer on a surface of the elastic body; an adhesive applying step of applying an adhesive to at least one of the sheet and the elastic body that is provided with the wax layer on the surface thereof; and a pressing step of pressing the sheet and the elastic body against each other and bringing the sheet into close contact with the elastic body provided with the wax layer such that the adhesive is interposed therebetween while stretching the sheet along the surface.

There are provided a printing blanket which maintains the accuracy of printing of an image, and also prevents a failure of transfer of an ink from an original printing plate to the printing blanket, a method for manufacturing the printing blanket, and a printing method using the printing blanket. The printing blanket according to the present invention includes an elastic body which deforms in conformity to the shape of a to-be-printed surface. The elastic body includes a printing surface to be pressed against the to-be-printed surface. In the printing surface, an entire region is provided with a plurality of irregularities are formed over the entire surface of the printing surface, and an elevation difference from a highest part of the irregularities to a lowest part thereof falls within the range of 2 to 20 μm.

An intermediate transfer member (ITM) (210, 310, 320, 330, 400, 410, 420, 430, 500, 520, 540, 600, 700, 802) configured for receiving ink droplets to form an ink image thereon and for transferring the ink image to a target substrate (226), the TTM (210, 310, 320, 330, 400, 410, 420, 430, 500, 520, 540, 600, 700, 802) includes one or more layers (273, 277, 373, 379, 602, 604, 606, 608, 610, 704, 706, 708, 712) and one or more markers (33, 333, 335, 392, 408, 418, 428, 448, 458, 612, 710, 804, 806) integrated with at least one of the one or more layers (273, 277, 373, 379, 602, 604, 606, 608, 610, 704, 706, 708, 712) at one or more respective marking locations along the ITM (210, 310, 320, 330, 400, 410, 420, 430, 500, 520, 540, 600, 700).

An imaging blanket for variable data lithography. The imaging blanket comprises a substrate. A foam layer is disposed on the substrate. An elastomeric layer is disposed on the foam layer, the elastomeric layer comprising a silicone elastomer. The elastomeric layer has a Shore A hardness ranging from about 50 Shore A to about 100 Shore A.

Provided are a printing blanket and a printing method that enable printing on a printing member having a curved surface at an edge. The printing blanket includes a base member made of an elastic material having a three-dimensional shape with a recessed portion or a hole portion in a center of the base member and a ridge line surrounding the recessed portion or the hole portion, and a printing surface arranged on a surface of the base member on an outer side from the ridge line.