Patent Application
20110088578
The present invention relates generally to folder superstructures for web printing presses, to nip rolls used in multi-ribbon transport, as well as to a method for operating a printing press.
As described in U.S. Patent Application Publication 2006/0157924, hereby incorporated by reference herein, in a web printing press, a web or webs may be printed in various printing units. The webs then may enter a folder superstructure. There, the webs may be slit into ribbons, which are then superimposed to form a ribbon bundle, before passing to a former. The ribbon bundle in the folder superstructure may be drawn over a roller at the top of the former called an RTF by driven nip rolls located after the nose of the former. The ribbon bundle then may pass to a folder where the ribbon bundle is cut into signatures.
The nip rolls may be spring-loaded against each other in an adjustable manner so as to set the pressure or “squeeze.” Nip rolls with urethane or rubber outer layers are known. These rubber or urethane coatings are incompressible, as no air, microspheres or other gas inclusions are added to make them compressible.
A ribbon bundle may, for example, have six ribbons. The draw nip of the nip rolls can create uneven upstream longitudinal tensions of the different ribbons. A small change in nip pressure can also create large ribbon tension changes. To address uneven web tensions, gathering rolls or additional driven pull rolls upstream of the RTF are known.
Sometimes, the RTF can be a hard roll paired with a relatively soft nip roll. The nip that may be formed by the hard-soft nip roll often produces tension differences among the ribbons that pass through the nip. The RTF nip may be effective in both reducing the amount of air entrained between the ribbons as well as reducing the lateral motion of the ribbons along the RTF roll.
Tension differences may be minimized, for example, via a reduction in the angle of paper wrap over the RTF and a reduction in the nip squeeze. However, both of these approaches may reduce the ability of the nip to remove the entrained air between the ribbons and decrease the ability to prevent ribbon weave.
The present invention provides a folder superstructure including: a former; a first top of former roll located upstream of the former and having a compressible outer layer; and a second top of former roll forming a nip with the first top of former roll.
The present invention also includes a method for operating a printing press including: printing at least one web; forming a plurality of ribbons from the at least one web; and passing the ribbon bundle through top of former rolls located upstream of the former, at least one of the top of former rolls having a compressible layer.
A preferred embodiment of the present invention will be elucidated with reference to the drawings, in which:
Ribbon bundle 12 is directed towards a ribbon nip entry 20 in RTF 26. RTF 26 includes top of former rolls 21, 25, which may be compressible. Ribbon bundle 12 enters ribbon nip entry 20 and passes through top of former rolls 21, 25. Top of former rolls 21, 25 may then guide ribbon bundle 12 towards a former 52. Once ribbon bundle 12 reaches former 52, former 52 may then impart a longitudinal fold to the ribbon bundle 12, which is drawn over the former 52 by infeed rollers 22, 27, respectively. However, it is also possible that ribbon bundle 12 may be gathered by RTF 26 without necessarily going over former 52.
As shown in
Ribbon bundle 12 is configured in such a way as to enable it to enter ribbon nip entry 20 in a manner as to minimize tension differences related to a nip entry angle. For the purposes of this disclosure, the nip entry angle may be defined as angle A (see
Top of former roll 21 may be driven by a mechanical connection to a main drive for folder superstructure 51 or alternately be motor driven by a motor similar to drive motor 28 or need not be driven at all. Top of former roll 21, for example, may be adjustable with respect to top of former roll 25 to set a squeeze S. Top of former roll 21 preferably may be similar in construction to top of former roll 25.
As a ribbon bundle 30, in this example with six ribbons, passes through the nip between top of former rolls 21 and 25, the tension downstream from the nip varies between the ribbons. Thus, for example, an outermost ribbon 32 will have a different tension in the longitudinal direction than ribbon 34. Advantageously, it has been found that the use of top of former rolls 21, 25 with compressible outer layers according to the present disclosure may reduce the amount of tension between ribbons 32, 34 in ribbon bundle 30. Thus, lead rolls 10, 11, for example, may not need to be adjusted as much or as far. Make-ready times and set-up may be reduced. Change in squeeze or pressure also does not result in as large ribbon-to-ribbon tension changes as with incompressible rolls, and thus pressure adjustments may be simplified.
An exit angle of RTF 26 may be set to an angle, for example, eight degrees, which could allow center slitting or perforation of the ribbon bundle. An anvil and knife of the slitter or perforator system could be concentric with the nip between top of former rolls 21 and 25.
The method of operation may include that RTF 26 is thrown off and adjusted in such a way so that the location of the ribbon bundle exiting the nip between top of former rolls 21 and 25 may be controlled relative to former 2
In the preceding specification, the invention has been described with reference to specific exemplary embodiments and examples thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of invention as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.
