EP0741019A2 - Individually driven folding apparatus for a rotary printing machine - Google Patents

Abstract

The folder is driven by its own drive motor (10) which is coupled mechanically only to the folder. The mechanical coupling is provided by a drive pinion (10.1) on the motor side and by a spur wheel on the cylinder side. The drive can act on the folding flap cylinder or on the cutter cylinder or on the collecting cylinder. The drive motor can drive through a toothed belt any gear wheel in the entire drive train between cutter cylinder and delivery. The drive can also take place on an intermediate wheel in active connection with the drive train with a one-step translation ratio between drive motor and gearwheel. The individual drive allows the folder to turn to any position independently of the position of the printing mechanism.

Description

The invention relates to an individually driven folder for a rotary printing press according to the preamble of claim 1.

In conventional rotary printing presses, the folders are driven and synchronized by a main drive via a longitudinal shaft.

An example of a known drive, for example according to DE 41 27 321 A1, is shown schematically in FIG. 1. Here, the coupling from the longitudinal shaft 1.10 to the folding apparatus, comprising a knife cylinder 2, a collecting cylinder 3 and a folding jaw cylinder 4, takes place mechanically via a longitudinal shaft gear box 1, various gear stages 1.20, a shaft 1.23 to an intermediate wheel 1.3 or coupled to a bevel gear 1.24 alternatively to the knife cylinder 2 coupled with a bevel gear 1.24. The cylinders 2, 3 and 4 are mechanically coupled to one another via spur gears. The disadvantage here is that the cylinders 2, 3 and 4 to each other and can assume any position in relation to the longitudinal shaft 1.10 in the region of the tooth play. This is due to the effective moments on the cylinders such as cornering controls, cutting strokes and the like. Irregularities that cannot be avoided as a result are noticeable in the folding tolerances.

The invention has set itself the task of creating a folder in which the register setting can be carried out individually for the folder while preventing, at least reducing, the tooth play of the gears in the drive train of the folder.

This object is solved by the subject matter of claim 1.

According to the invention, a folder of a rotary printing press with at least one folder cylinder and a knife cylinder for individually driving the folder has a drive motor which is mechanically coupled only to the folder. As a result, tooth play problems only have to be counteracted in the area of the folder, while the drive motor for the folder for driving the other components of the printing press is electrically synchronized. The single drive allows the folder to be rotated to any folding position regardless of the position of the printing units, thereby making it easy to move to the cutting register. This advantage is particularly useful when feeding paper into a back-up folder, since with such a back-up folder the cutting register can be approached via a zero position of the drive that serves as a reference. The folding tolerances are minimized by the invention.

Furthermore, the folder according to the invention allows the free arrangement of the folder to the printing units because of the mechanical coupling with the printing units that is no longer required and advantageously also for a fold structure and a fold superstructure, without causing additional costs.

Since there is preferably no mechanical connection between the folder and the folder structure or the folder superstructure, the freedom in the configuration of these three functional groups is also increased. For example, only one structure and one superstructure can be assigned to two folders.

In a preferred embodiment, a drive motor drives onto the folding jaw cylinder via a mechanical coupling, preferably a motor-side pinion and a cylinder-side spur gear. This enables high gear ratios to be achieved in one step and in a space-saving manner. The omission of a longitudinal shaft gearbox and all drive components, such as shafts and gears, including idler gear, results in a cost reduction. Because of its comparatively large inertia and small operating torques, the drive is coupled to a particularly quiet location of the folder in this embodiment variant. The web tension on the collecting cylinder, the frictional moments of the cylinder bearings, the pull roller drive and the cutting stroke create a moment that counteracts the driving motor. This can prevent a flank change in the drive from the motor-side pinion to the cylinder-side spur gear and between the cylinder spur gears of the cylinders of the folder from occurring by the control of the drive motor. Another advantage is that the arrangement of the drive on the jaw cylinder and the always equilateral tooth contact prevents a change between driving and braking engine operation, and the engine only runs in the driving area. Such a change of company would otherwise easily damage the drive of the folder. If pulsed operating moments occur that can lead to disruptive edge changes in the drive, it is sufficient to keep the tooth contact, especially between the pinion and the spur gear, always in the same place with an additional moment on the jaw cylinder. Such a torque is comparatively small compared to the drive torque and can be introduced, for example, by an electric brake or a friction brake.

In a likewise preferred embodiment, the motor-side pinion meshes with any other gearwheel arranged after the knife cylinder in the drive train of the cylinders of the folder.

Another variant is to couple the drive motor where, according to the prior art, the longitudinal shaft gear box is located.

In a further preferred embodiment variant, the drive motor drives the knife cylinder via a toothed belt. The mass of the knife cylinder can be added to the low own mass of the drive motor, whereby the control dynamics can be improved. A translation between the drive motor and knife cylinder can also be provided in more than one stage.

The drive from the motor via a toothed belt to the collecting cylinder is further preferred. Here, too, the mass of the collecting cylinder, which is larger than that of the knife cylinder, can be added to the low own mass of the drive motor, which, as already mentioned, improves the control dynamics. Again, a multi-stage translation between the drive motor and the collecting cylinder can be preferred.

Finally, such a toothed belt can also be used to drive the jaw cylinder.

In another preferred embodiment of the invention, the drive motor drives via a toothed belt on any gear in the entire drive train between the knife cylinder and the delivery, for example a paddle wheel. In this case, the drive can also take place on an intermediate wheel that is operatively connected to the drive train. The required gear ratio from the drive motor to the gear is advantageously one-step, so that again a space-saving solution is created.

If a first and a second folder are provided, the following setup variants are preferred:

Both folders can be placed at the system level, in particular as left and right folders in a so-called back-to-back arrangement or as double folders with delivery on the same side of the machine. The first option is particularly narrow with correspondingly short transfer paths for the train. The second variant, i.e. the double folder offers the advantage that both layers are on one side of the machine and two identical folders can be used. Both types of installation allow operation on one level.

A first folder can also be placed at plant level, while a second folder is offset in the machine basement, i.e. at the role changer level. As a result, short web transfer paths and unhindered access to the folders are achieved. If a fold structure and a fold superstructure are set up on the machine table, i.e. on the system level, the overall height is low.

Finally, both folders can be set up in the basement, namely as a double folder with a separate structure and superstructure stored on the machine table, or as Double folder in a common superstructure and superstructure. Because of the arrangement in the machine cellar, both variants are characterized by their low overall height above the machine level. Furthermore, because they are arranged on one level, they are particularly easy to use.

In all of the aforementioned exemplary embodiments, only one structure and one superstructure can advantageously be provided for a plurality of folding apparatuses.

In a further embodiment of the invention which can advantageously be combined with the aforementioned exemplary embodiments, the folder itself can be moved. If the folder structure and the superstructure are placed on a yoke, a back-up folder, if one is provided, can be pushed in instead of the main folder if required. Depending on which shifting method is used, no additional space is required in the system. If the machine table itself is used as a yoke construction and the folders are placed in the basement, this also results in a low overall height.

In principle, the fold structure and the fold superstructure can also be arranged to be movable on a yoke construction.

The invention can be combined particularly advantageously with the drive and control concept disclosed in EP 0 644 048 A2, the teaching of which is hereby incorporated.

Fig. 2

einen einzeln angetriebenen Falzapparat,

Fig. 3

eine erste Stellvariante für zwei Falzapparate, wobei ein Falzapparat in einem Maschinenkeller angeordnet ist,

Fig. 4

die Stellvariante von Fig. 3 in detaillierterer Darstellung,

Fig. 5

eine zweite Stellvariante, bei der mehrere Falzapparate nebeneinander im Maschinenkeller angeordnet sind und

Fig. 6

eine dritte Stellvariante für mehrere Falzapparate, die je zu einer Seite links und rechts eines Druckwerks angeordnet sind.

Preferred exemplary embodiments of the invention are described below with reference to figures. Show it:

Fig. 2

an individually driven folder,

Fig. 3

a first adjustment variant for two folders, one folder being arranged in a machine cellar,

Fig. 4

3 in a more detailed representation,

Fig. 5

a second setting variant in which several folders are arranged side by side in the machine cellar and

Fig. 6

a third setting variant for several folders, which are arranged to the left and right of a printing unit.

In Fig. 2, a printing web B runs through a capping device 20, a pair of traction rollers 21 arranged behind it, over a collecting cylinder 3 with an associated knife cylinder 2, is cut transversely there and then from the collecting cylinder 3 onto the jaw cylinder 4 and from there onto a paddle wheel serving as delivery means 5 passed. Instead of the paddle wheel 5, an endlessly rotating means of transport with grippers for the folded printed copies can also be provided.

In the illustrated embodiment, the jaw cylinder 4 is driven directly by a drive motor 10. The mechanical coupling between the drive motor 10 and the jaw cylinder 4 is formed via a motor-side pinion 10.1 and a cylinder-side spur gear 4.1.

3 shows a printing press, which is an example of the gain in flexibility with regard to the installation options of the self-propelled folder. In this exemplary embodiment, a folder F1 is set up in the machine basement on the same level as roll changers R1, R2, R3 and R4, while printing units D1, D2 and D3 are in alignment on an overlying system level 100. A folding structure 30, which has at least one hopper on one or more levels, is arranged above the folding device F1 and is mounted on the folding device. The folding superstructures 30, 40 are arranged between the two printing units D2 and D3, so that the printing webs run in from two sides.

In addition to this first folder F1, a second folder can be provided. This second folder is preferably also arranged in the machine cellar or on the plant level 100, preferably approximately flush with the lower folder superstructure 30.

The printing webs can optionally be fed to one of the folders. In the example of FIG. 3, only the folder F1 in the machine basement is in operation. If two folding apparatuses are provided, some of the printing webs which are conveyed further behind the printing units can be fed to different former levels of the folding structure 30, as shown by dashed lines as an example. The longitudinally folded printing webs then reach the second folder from an upper former level, while the printing webs folded in a lower former level 30 continue to be fed to the first folder F1.

Fig. 4 shows the setup of the second folder F2 mentioned on the system level 100. The first folder F1 is again placed in the roll changer level, on the same level with the roll changers, not shown, while the second folder F2 is arranged next to the machine to a machine side. The folding structure 30 with one or more funnel levels is mounted on the machine table.

In the example according to FIG. 4, both the storage and the drive of the folding structure 30 take place mechanically independently of the drive and the storage of the folding apparatus.

Fig. 5 shows two folders F1, F2 arranged side by side on one level - on the machine table or on the roll changer level. Only the first folder F1 is in operation, while the second folder serves as a backup.

The printing web or webs are fed to the folding device F1 again via a folding structure 30 received on a yoke J. The yoke J is mounted independently of the folding devices F1 and F2, which means that the first folding device F1 is also replaced by the back-up folding device F2 is enabled. Replacing the folder F1 with the back-up folder F2 is particularly easy if the two folders can be moved (F1 → F1 'or F2 → F2').

6 shows another example demonstrating the flexibility with regard to the configurability of the printing press. The printing press has six printing units D1 to D6, of which three printing units are arranged one behind the other as seen in the web conveying direction and two such rows of three are set up side by side. Folders F1, F2, F3 are placed to the left and right of the last printing unit D1 and D4 of the two printing unit rows of three such that one of the folding units, F2, is arranged between the last two printing units D1 and D4, so that printing webs from these two Printing units can be fed to the center-mounted, in this case common folder F2. The two further folders F1 and F3 are arranged on the free outer sides of each of the printing units D1 and D4.

Above each of the folders F1, F2, F3 there is an associated folder structure with former or former. while above the two last printing units D1 and D4 next to the folders F1 and F3 are arranged the necessary deflection rollers and turning bars for feeding the printing webs. The folded printed copies can be displayed uniformly in the machine longitudinal direction. However, which in turn demonstrates the flexibility of the solution according to the invention, it can also take place to the sides in the case of the two outer folders F1 and F3.

Claims (17)

Folding apparatus of a rotary printing press, with at least one knife cylinder (2) and one folding jaw cylinder (4),
characterized in that
for the individual drive of the folder, a drive motor (10) is provided which is mechanically coupled only to the folder. Folding apparatus according to claim 1, characterized in that the drive motor (10) drives onto the folding jaw cylinder (4) via a mechanical coupling. Folding apparatus according to claim 1, characterized in that the drive motor (10) drives onto the knife cylinder (2) via the mechanical coupling. Folding apparatus according to claim 1, characterized in that the drive motor (10) drives via the mechanical coupling onto a collecting cylinder (3) of the folding apparatus. Folding apparatus according to claim 1, characterized in that the drive motor (10) drives on a gearwheel in the drive train between the knife cylinder (2) and a delivery means (5). Folding apparatus according to one of the preceding claims, characterized in that the mechanical coupling by a motor-side drive pinion (10.1) and by a on the shaft of the directly driven cylinder (2, 3, 4) or a gear in the drive train between the knife cylinder (2) and a delivery means (5) or an intermediate wheel is formed for this drive train. Folding apparatus according to one of claims 1 to 5, characterized in that the drive motor (10) via a toothed belt on the directly driven cylinder (2, 3, 4) or a gear in the drive train between the knife cylinder (2) and a delivery means (5) or an idler gear drives to this drive train. Folding apparatus according to one of the preceding claims, characterized in that at least one drive motor (10) is provided for driving the folding apparatus. Rotary printing press
marked by
a folder (F1, F2, F3) which, by being equipped with at least one drive motor (10) of its own, is driven mechanically independently of at least printing units (D1 - D6) of the printing press and can be placed and registered independently thereof. Rotary printing machine according to claim 9, characterized in that a first folder (F1) and a second folder (F2) are provided, both of which are arranged one behind the other on a system level in the longitudinal direction of the press as left and right folders in a back-to-back arrangement or for are placed on the same side of the printing press as a double folder. Rotary printing machine according to Claim 9, characterized in that a first folder (F1) is arranged at the system level and a second folder (F2) is arranged vertically offset from the first folder (F1) at the roll changer level. Rotary printing machine according to claim 9, characterized in that a first folder (F1) and a second folder (F2) are arranged on the roll changer level. Rotary printing machine according to one of claims 9 to 12, characterized in that at least one of the folders (F1, F2), preferably both or, in the case of several folders, all the folders, can be moved. Rotary printing machine according to one of Claims 9 to 13, characterized in that a folding structure (30) is driven mechanically independently by the folding apparatus (F1, F2, F3) and preferably also by other components of the printing machine, for example the printing units (D1 - D6). Rotary printing machine according to one of claims 9 to 14, characterized in that the folding structure (30) is mounted independently of the downstream folding apparatus (F1, F2), preferably on the machine level or elevated. Rotary printing machine according to one of Claims 9 to 15, characterized in that the folding superstructure (30, 40) is mounted independently of the assigned folding apparatus (F1, F2, F3), preferably on the machine level or elevated on a yoke (J). Rotary printing machine according to one of Claims 9 to 16, characterized in that a folding structure (30) is provided for more than one folding device (F1, F2).

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