It is aimed to suppress the influence of a positional deviation occurring in bringing two plate bodies aligned in advance into contact in a transfer apparatus for bringing two plate bodies into contact by pressing by a roller member. Alignment mechanisms 71 are mounted on a main frame 10 and an alignment stage 36 is mounted on the alignment mechanisms 71. A lower stage block 3, a transfer roller block 4 and a roller travel driver 5 are placed via a detachable stage 37 on the alignment stage 36. A positional relationship between a blanket BL held on a lower stage 31 and a transfer roller 431 for pushing up the blanket BL does not vary by an alignment adjustment. Thus, the influence of a positional deviation, a magnitude of which changes according to the amount of deflection of the blanket BL, can be suppressed.

It is aimed to provide a technique enabling a roller member to press a plate body with a uniform and stable pressing force. A transfer roller 431 configured to come into contact with a blanket BL and press the blanket BL against a substrate SB is rotatably supported by a pair of supports 430 on opposite end parts thereof. Supporting angles 4334 configured to support a rotary shaft of the transfer roller 431 are supported movably upward and downward by linear guides 4332, 4333 and biased upwardly by biasing portions 434. Displacements of the supporting angles 4334 by biasing forces are restrained at a predetermined height by stoppers 435, and the posture of the transfer roller 431 (inclination of the rotary shaft) when the transfer roller 431 approaches the blanket BL from below is controlled. Restraint by the stoppers 435 is released when the blanket BL is pressed against the substrate SB and a constant pressing force is applied to the blanket BL by the biasing forces.

It is aimed to provide a technique enabling a roller member to press a plate body with a uniform and stable pressing force. A transfer roller 431 configured to come into contact with a blanket BL and press the blanket BL against a substrate SB is rotatably supported by a pair of supports 430 on opposite end parts thereof. Supporting angles 4334 configured to support a rotary shaft of the transfer roller 431 are supported movably upward and downward by linear guides 4332, 4333 and biased upwardly by biasing portions 434. Displacements of the supporting angles 4334 by biasing forces are restrained at a predetermined height by stoppers 435, and the posture of the transfer roller 431 (inclination of the rotary shaft) when the transfer roller 431 approaches the blanket BL from below is controlled. Restraint by the stoppers 435 is released when the blanket BL is pressed against the substrate SB and a constant pressing force is applied to the blanket BL by the biasing forces.

According to one example there is provided a system for applying fluid to a substrate using a first and second array of fluid applicators.

A container is formed to include and interior region and a mouth opening into the interior region. The container includes a floor, a side wall coupled to the floor to define the interior region between the floor and the side wall, and artwork on the side wall.

A container is formed to include and interior region and a mouth opening into the interior region. The container includes a floor, a side wall coupled to the floor to define the interior region between the floor and the side wall, and artwork on the side wall.

A system for depositing an imprint onto a substrate includes a deposition surface having at least one outlet disposed therein, a substrate holder for holding the substrate against the deposition surface, means operatively associated with the deposition surface for supplying a material through said at least outlet to deposit said material onto the substrate, and a spacer member disposed in contact between the deposition surface and the substrate.

A method of achieving precision registration in a roll to roll process by simultaneously depositing multiple inks onto a printing roll. One of these inks prints a pattern of fiducial marks onto a substrate while another ink prints a predetermined pattern on the same substrate such that the predetermined pattern bears a predictable spatial relationship to the pattern of fiducial marks. Consequently, even if the ink forming the predetermined pattern is invisible, or has such low contrast with the substrate that it is effectively invisible, or even has been dissolved away in a subsequent processing step, it is still possible to know where the predetermined pattern is by referring to the pattern of fiducial marks.

A method of achieving precision registration in a roll to roll process by simultaneously depositing multiple inks onto a printing roll. One of these inks prints a pattern of fiducial marks onto a substrate while another ink prints a predetermined pattern on the same substrate such that the predetermined pattern bears a predictable spatial relationship to the pattern of fiducial marks. Consequently, even if the ink forming the predetermined pattern is invisible, or has such low contrast with the substrate that it is effectively invisible, or even has been dissolved away in a subsequent processing step, it is still possible to know where the predetermined pattern is by referring to the pattern of fiducial marks.

A process for preparing an ion-exchange membrane having a textured surface profile comprising the steps (i) and (ii): (i) applying a radiation-curable composition to a membrane in a patternwise manner; and (ii) irradiating and thereby curing the radiation-curable composition present on the membrane; wherein the radiation-curable composition comprises: a) 10 to 65 wt % of curable ionic compound(s) comprising one ethylenically unsaturated group; b) 3 to 60 wt % of crosslinking agent(s) comprising at least two ethylenically unsaturated groups and having a number average molecular weight below 800; c) 0 to 70 wt % of inert solvent(s); d) 0 to 10 wt % of free-radical initiator(s);and e) 0.5 to 25 wt % of thickening agent(s).