DE4038510A1 - Index adjustment for printing unit with pref. three printing mechanisms - involves each mechanism having platen cylinder, and rubber sheet cylinder with inclined toothed drive gearwheels - Google Patents

Abstract

Shaft pins (12-15) for the platen and rubber sheet cylinders (4-7) are located in a side wall (11), and are driven by drive gearwheels (18-23). All gearwheels involved have inclined toothing, whereby the teeth of wheels interengaging have a counterposed angle of inclination. On the shaft pin (13) of the one rubber sheet cylinder (4), and on that (14) of the other such cylinder (6) are located two drive gearwheels (19, 20; 21, 22) acting as double gearwheels. With the drive gearwheel (20) of the one rubber sheet cylinder (4) engages the main drive gearwheel (10) which is connected via a shaft (36) with the main drive of the machine. The other drive gearwheel (19) on the shaft pin (4) of the rubber sheet cylinder (4) meshes with the drive gearwheel (18) on the shaft pin (12) of the platen cylinder (5). USE - As an index adjustment for a three-part printing unit.

Description

The invention relates to a register setting device for a Printing unit with at least two, preferably three printing units, where each printing unit has a plate cylinder and a Blanket cylinder with helical drive gears on one has its journal, the blanket cylinder in pairs Are connected, all cylinders are axially displaceable and the Drive by means of a shaft with the main drive of the Machine connected, helical main drive gear is initiated.

A register actuator is designed to ensure that two or more machining or repetitive repetitions with the same period Printing processes on the material web no relative shift point to each other. For this purpose one has several printing units comprehensive printing unit or with several in a row switched printing units for each printing unit a page and Circumferential register setting provided.

It is known to change the register settings by moving Make printing unit cylinders, according to each helical gear drive inevitably a circumferential rotation of various printing unit cylinders results in then again by moving printing unit cylinders is compensated.

European patent application 02 86 982 shows a generic one Register setting device, in the case of two blanket cylinders, two each helical gears designed as double gears exhibit. The described interaction of the drive gears the different cylinders leave only a relative one Register setting on the plate cylinders over which the Main drive is initiated. This has disadvantages if another  Printing unit runs ahead. If a page register adjustment of the Plate cylinder, via which the drive is initiated, reached the plate cylinder is adjusted axially. Since that Gear of the main drive, which with the drive gear of the Combing plate cylinder, is not rotatable, the rotates Plate cylinder with helical teeth circumferentially and there its rotation to all subsequent cylinders of the printing unit. This can be caused by an axial displacement of the plate cylinder following blanket cylinder can be compensated. However, at the axially displaced plate cylinder the circumferential rotation by means of the non-rotatable gear of the main drive maintain. Thus, complete compensation must also be given Include the leading printing unit. This has a high one mechanical and electrical effort. Also prevented the described interaction of the drive gears one Register adjustment of all plate cylinders when the Main drive via a blanket cylinder.

The object of the invention is a device of the beginning to improve the type described so that a circumferential and / or Lateral register adjustment of each plate cylinder is possible, and neither other printing units of the printing unit nor printing units before or downstream pressure units can be influenced.

This object is achieved by the application of the features solved in the characterizing part of claim 1.

Below are two exemplary embodiments of the invention based on the Drawing described. They show highly schematic

Fig. 1 is a view of the cylinder configuration of a generic printing unit;

Fig. 2 shows a first embodiment as section II-II of Figure 1 of the configuration of the drive gears according to the invention.

Fig. 3 shows the first embodiment as section III-III of FIG. 1;

Fig. 4 shows a second embodiment as section II-II of Figure 1 of the configuration of the drive gears according to the invention.

Fig. 5, the second exemplary embodiment as a section III-III of FIG. 1.

In Fig. 1 a printing unit is shown, which preferably comprises three approximately Y-shaped printing units 1 , 2 , 3 . In the printing unit 1 a blanket cylinder 4 and a plate cylinder 5 are provided , in the printing unit 2 a blanket cylinder 6 and a plate cylinder 7 and in the printing unit 3 a blanket cylinder 8 and a plate cylinder 9 are provided. In both embodiments, a main drive gear 10 is assigned to the blanket cylinder 4 to initiate the drive. The main drive gear 10 could also be assigned to one of the other blanket cylinders. The plate and blanket cylinders 4 to 9 each have axle journals mounted on both sides in side walls, with only one side wall 11 with axle journals 12 to 17 being indicated in FIGS. 2 to 5 for reasons of clarity.

Fig. 2 shows the journals 12 to 15 of the plate and blanket cylinders 4 to 7 , which are mounted in the side wall 11 and are driven by drive gear wheels 18 to 23 . The drive gears 18 to 23 are rotatably mounted on the journal 12 to 15 . All of the drive gears 18 to 26 and 27 to 35 mentioned above and below have helical teeth, the teeth of gears meshing with one another naturally having an opposite helix angle. On the journal 13 of the blanket cylinder 4 and the journal 14 of the blanket cylinder 6 there are two drive gears 19 , 20 and 21 , 22 , which are designed as double gears and whose teeth have opposite helix angles. The main drive gear 10 , which is connected via a shaft 36 to the main drive of the machine, is in constant engagement with the drive gear 20 of the blanket cylinder 4 . The main drive gear 10 is rotatably mounted on the shaft 36 . The other drive gear 19 on the journal 13 of the blanket cylinder 4 meshes with the drive gear 18 on the journal 12 of the plate cylinder 5 . The drive gear 20 drives the drive gear 21 on the journal 14 of the blanket cylinder 6 , while the other drive gear 22 meshes with the gear 23 on the journal 15 of the plate cylinder 7 .

Fig. 3 shows how the drive of the printing unit 3 interacts with that of the previously described printing units 1 and 2 . Also on the journal 16 of the blanket cylinder 8 are two drive gears 24 , 25 , which are designed as double gears and whose teeth are provided with opposite helix angles. The drive gear 24 meshes with the drive gear 20 of the blanket cylinder 4 , while the other drive gear 25 drives the drive gear 26 on the journal 17 of the plate cylinder 9 . All drive gears 18 to 26 have the same diameter and are arranged in three planes. The drive gears 25 , 26 thus lie in the plane of the drive gears 22 , 23 and the drive gear 24 in the plane of the drive gear 21 .

FIGS. 4 and 5 show in an analogous manner as Figs. 2 and 3, a second embodiment for driving the plate and blanket cylinder 4 to 9. On the journal 13 , 14 , 16 of all the blanket cylinders 4 , 6 , 8 there are two drive gears 28, 29, 30, 31, 33, 34 , each designed as a double gear, the teeth of which also have opposite helix angles. The drive is initiated via the main drive gear 10 , which is rotatably mounted on a shaft 37 and is in engagement with the drive gear 29 of the blanket cylinder 4 . The other drive gear 28 of the blanket cylinder 4 drives the drive gear 27 on the journal 12 of the plate cylinder 5 . The drive gear 30 , which is seated on the axle pin 14 of the rubber blanket cylinder 6 , makes contact with the drive gear 29 , while the other drive gear 31 of the rubber blanket cylinder 6 drives the drive gear 32 on the axle pin 15 of the plate cylinder 7 . As can be seen in FIG. 5, the drive gear 33 on the axle pin 16 of the blanket cylinder 8 also meshes with the drive gear 29 of the blanket cylinder 4 , while the other drive gear 34 of the blanket cylinder 8 drives the drive gear 35 on the axle pin 17 of the plate cylinder 9 . This form of interaction of the drive gears 27 to 35 allows the drive gears 27 to 35 to be arranged in two planes, but it does require that the drive gears of the blanket cylinders 4 , 6 , 8 , that of the drive gears 27 , 32 , 35 of the plate cylinders 5 , 7 , 9 are engaged with a negative profile shift and thus the drive gears 27 , 32 , 35 of the plate cylinders 5 , 7 , 9 are provided with a positive profile shift relative to the other drive gears 29 , 30 , 33 of the blanket cylinders 4 , 6 , 8 .

The operation of the register adjustment for the plate cylinders 5 , 7 , 9 by means of the drive gears 18 to 26 or 27 to 35 by axial adjustment of corresponding plate blanket cylinders is the same in both exemplary embodiments and is therefore only described for the first exemplary embodiment.

If the side register of the plate cylinder 5 is to be set, the plate cylinder 5 is displaced axially. This results in a slight circumferential adjustment of the plate cylinder 5 , which results from the helical teeth of the drive gears 18 , 19 and the holding of the drive gears 19 , 20 of the blanket cylinder 4 by means of the main drive gear 10 . In order to compensate for this circumferential adjustment of the plate cylinder 5 , the blanket cylinder 4 is axially displaced. With the main drive gear 10 held , the drive gear 20 of the rubber blanket cylinder 4 is rotated between the main drive gear 10 and the drive gear 21 of the rubber blanket cylinder 6 , the main drive gear 10 and the drive gear 21 being comparable to a fixed screw nut, in the threaded bore of which the drive gear 20 is like one Screw turns. So there is no register influence on other printing units.

If the side register of the plate cylinder g is to be adjusted, the plate cylinder 9 is displaced axially and the resulting circumferential adjustment is only compensated for by an axial adjustment of the blanket cylinder 8 . When setting the side register of the plate cylinder 7 , the resulting circumferential adjustment of the plate cylinder 7 also has to be compensated only by means of an axial displacement of the blanket cylinder 6 .

If a circumferential adjustment of the plate cylinder 5 is to be brought about, only the blanket cylinder 4 is axially displaced, a circumferential adjustment of the plate cylinders 7 and 9 is achieved by axially displacing the blanket cylinders 6 and 8 without further compensation of other plate cylinders having to be carried out.

The axial or radial adjustment path for register adjustment is usually 3 mm.

The axial movements of the various plate blanket cylinders 4 to 9 take place in a known manner, as described in the document of the European patent application 02 86 982, by means of threaded bushes, register actuators and position controllers.

Claims (5)

1. Register setting device for a printing unit with at least two, preferably three printing units, each printing unit having a plate cylinder and a blanket cylinder with helically toothed drive gears on one of its axle journals, the blanket cylinders are connected in pairs, all cylinders are axially displaceable and the drive is by means of a a shaft is connected to the main drive of the machine, helically toothed main drive gear, characterized in that each blanket cylinder ( 4 , 6 , 8 ) each have two helically toothed drive gears ( 19 , 20 , 21 , 22 , 24 , 25 and 28 , 29 , 30 , 31 , 33 , 34 ), which are designed as a double gear and whose teeth are provided with opposite helix angles, each with a drive gear ( 19 , 22 , 25 or 28 , 31 , 34 ) of a double gear with the drive gear ( 18th , 23 , 26 or 27 , 32 , 35 ) of the respectively assigned plate cylinder ( 5 , 7 , 9 ), the other drive gear ( 20 , 21 , 24 or 29 , 30 , 33 ) with another of a blanket cylinder ( 4 , 6 , 8 ) that is not with a drive gear ( 18 , 23 , 26 or 27 , 32 , 35 ) of a plate cylinder ( 5 , 7 , 9 ) interacts, meshes and that the main drive gear 10 connected to the main drive with a drive gear ( 20 , 21 , 24 or 29 , 30 , 33 ) one of the rubber blanket cylinders ( 4 , 6 , 8 ) cooperates, which does not mesh with a drive gear ( 18 , 23 , 26 or 27 , 32 , 35 ) of a plate cylinder ( 5 , 7 , 9 ). 2. Register actuating device according to claim 1, characterized in that the drive gears ( 18 to 26 ) of the plate and blanket cylinders ( 4 to 9 ) are arranged in three planes. 3. Register actuating device according to claim 2, characterized characterized in that all drive gears have the same size Have diameter.   4. Register actuating device according to claim 1, characterized in that the drive gears ( 27 to 35 ) of the plate and blanket cylinders ( 4 to 9 ) are arranged in two planes. 5. Register actuating device according to claim 4, characterized in that the drive gear wheels ( 28 , 31 , 34 ) of the rubber blanket cylinder ( 4 , 6 , 8 ), with a drive gear wheel ( 27 , 32 , 35 ) of the respectively assigned plate cylinder ( 5 , 7 , 9 ) interact, compared to the other drive gears ( 29 , 30 , 33 ) of the blanket cylinders ( 4 , 6 , 8 ) with a negative profile shift, thus the drive gears ( 27 , 32 , 35 ) of the plate cylinders ( 5 , 7 , 9 ) with a positive Profile shift are provided.