A printing blanket is provided which includes a reinforcing layer formed from a polymeric fabric reinforcing material which softens and flows at a temperature less than that used in the final curing step of forming the blanket or a polymeric reinforcing material having a thickness of between about 0.003 inches and 0.010 inches. The reinforcing layer provides a smooth surface to support an outer print surface layer and provides improved print performance while enabling a reduction in the overall thickness of the reinforcing layer.

A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and a paste transfer layer on the PET layer. The entire blanket has a Tan value of 0.05 to 0.10. The foam can be made of polyurethane, polyethylene, nitrile-butadiene rubber, silicone, or a combination thereof. The paste transfer layer can be made of silicone rubber, fluoro rubber, fluorosilicone rubber, a combination thereof, or a multi-layered structure thereof.

An intermediate transfer member (ITM) (44) of printing system (10), the ITM includes: (a) an outer layer (102) configured to receive droplets (11) of printing fluid for producing an image thereon, and transfer the image to target substrate (50), and (b) a stack (107) of flexible support layers, the stack includes a mesh (109), having a first section impregnated in a first layer (106) having a first elastic modulus in an axis in which a tension force is applied to the ITM (44), and a second section impregnated in a second layer (108), which is placed in contact with the first layer (106) and has in the axis, a second elastic modulus different from the first clastic modulus. In response to applying to the ITM (44) a specified level of the tension force, the stack (107) is configured to retain a predefined elongation of the ITM (44) along the axis.

A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam; a supporting layer on the foam; and a paste transfer layer on the supporting layer. The paste transfer layer is an inter-penetrating polymer network of silicone rubber and fluoroelastomer.

A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and a paste transfer layer on the PET layer. The foam has a Shore A hardness of 20 to 80 and a thickness of 0.5 mm to 1.5 mm, wherein the foam has a higher Shore A hardness corresponding to a greater thickness.

The present invention relates to printing blankets, pipe liners, conveyor belts, inflatable articles, collapsible containers, protective clothing, and other types of coated fabrics that are manufactured with a thermoplastic block copolymer (TBC). This TBC can be a thermoplastic polyurethane (TPU), a copolyester (COPE), a copolyamide (COPA) or a polyurethaneurea (TPUU). The subject invention more specifically discloses a printing blanket or printing sleeve and a cured in place liner for a passageway or pipe. The TBC is (I) the reaction product of (1) a hydrophobic polyol or polyamine, (2) a polyisocyanate or an aromatic dicarboxylic acid, and (3) a linear chain extender containing 2 to 20 carbon atoms, or (II) the reaction product of (1) a hydrophobic polyol or polyamine, and (2) a carboxyl terminated telechelic polyamide sequence.

An imaging member includes a surface layer comprising a fluoroelastomer-fluorosilicone composite. Methods of manufacturing the imaging member and processes for variable lithographic printing using the imaging member are also disclosed.

A nanowire device of the present description may be produced with the incorporation of at least one hardmask during the fabrication of at least one nanowire transistor in order to assist in protecting an uppermost channel nanowire from damage that may result from fabrication processes, such as those used in a replacement metal gate process and/or the nanowire release process. The use of at least one hardmask may result in a substantially damage free uppermost channel nanowire in a multi-stacked nanowire transistor, which may improve the uniformity of the channel nanowires and the reliability of the overall multi-stacked nanowire transistor.