EP0775575A2 - Device for centrally adjusting sheet guiding elements in a sheet-fed rotary printing machine - Google Patents

Abstract

The adjusting device has sheet guide elements on the drive side (AS) and on the operating side (BS), each of which have jointly driven adjustments. A drive mechanism (3) can be connected to adjustments on one or both of the two machine sides (AS,BS). The drive mechanism can be connected to a first chain wheel (7) on the drive side engaging with a chain (1) driving the adjustments of the sheet guide elements on this machine side. Alternatively, the drive mechanism can be connected to a second chain wheel (8) on the operating side and engaging with a chain driving the adjustments of the sheet guide elements on this machine side. The drive mechanism can be simultaneously connected to both chain wheels. The drive mechanism consists of a crankshaft (3) and the two chain wheels.

Description

The invention relates to a device for the central adjustment of sheet guiding elements of a sheet-fed rotary printing press according to the preamble of claim 1, in particular the sheet guiding elements in the feeder and delivery of such a sheet-fed rotary printing press.

Sheet guide elements for the lateral sheet guide can be adjusted individually or centrally together in known printing presses in order to be able to adapt the sheet guide elements to the format of the sheet to be printed. The individual adjustment is carried out regularly by actuators with a manually or motor-operated spindle, with markings being helpful to facilitate the correct setting. According to the state of the art, central adjustments are also often made manually by means of actuators which are coupled to one another on each of the two machine sides by a drive chain synchronously driven by hand or by electric motors. Also known are electromechanical central adjustment devices in which, if necessary, electromotive individual drives, in particular servomotors, are switched for the sheet guiding element adjustment by a control program. Such a central adjustment of the sheet guiding elements, for example when changing the format, is very complex and accordingly expensive. Adjustments can only be carried out with predefined programs, so that intermediate settings, for example for off-center printing of sheets, can only be reached or are hardly possible in difficult ways.

Accordingly, it is an object of the invention to develop a device for the central adjustment of the sheet guide elements, preferably in the feeder and delivery of a sheet-fed rotary printing press, with a device for mutually independent adjustment of the sheet guide elements on the drive side (AS) and on the operator side (BS).

To achieve this object, an education according to claim 1 is provided according to the invention.

These training features achieve greater flexibility in adjusting the sheet guide elements and adapting them to a specific print job. In particular, the adjustment of the sheet guiding elements for printing processes that are not aligned with the longitudinal center of the sheets is facilitated. Eccentric printing is therefore easier to do.

The adjustment links of the sheet guiding elements are often connected to one another on each machine side by a circulating chain. In such cases, in order to achieve a cost-effective construction, it is proposed that a sprocket engage on each side of the machine in the drive chain for the adjusting members of the sheet guiding elements, these sprockets being able to be coupled either individually or simultaneously with a drive member. This drive member preferably consists of a shaft which can be rotated by hand or by motor and which can be coupled to the two chain wheels by means of a clutch which can be engaged and disengaged. This coupling can each consist of a gear wheel connected to one of the two chain wheels in a rotationally fixed manner and a gear wheel arranged on the drive shaft in a rotationally fixed manner, the toothing of which can optionally be inserted into the toothing of one of the two first gear wheels or both gear wheels. Another preferred solution is that the clutch consists of one There is a pair of bevel gears in which a bevel gear is axially displaceable in the direction of its axis of rotation. These axially displaceable bevel gears of both bevel gear pairs are arranged coaxially to one another in a rotational test and spring-loaded in the direction towards one another, the axes of rotation of the bevel gears, each of which is rotatably coupled to one of the two sprockets, with their rectified axes of rotation being offset from one another by the amount of the axial displaceability of the former bevel gears. This creates mechanically simple and therefore inexpensive, robust adjustment devices that allow central adjustment of all sheet guide elements or only the adjustment of the sheet guide elements on one machine side, so that the sheet guide elements on the two machine sides can be adjusted independently of one another with respect to the longitudinal center of the machine.

Figur 1

eine schematische Darstellung der auf einer Maschinenseite durch eine Antriebskette miteinander gekuppelten Verstellglieder für Bogenführungselemente,

Figur 2

ein Ausführungsbeispiel für eine Vorrichtung zur Kupplung der beiden Antriebsketten auf AS und BS mit einem Antriebsglied,

Figur 3

ein weiteres Ausführungsbeispiel für eine Vorrichtung zur Kupplung der beiden Antriebsketten auf AS und BS mit einem Antriebsglied, welches mit beiden Antriebsketten gekuppelt ist,

Figuren 4 und 5

Schemadarstellungen entsprechend Figur 3 in der Kupplungsstellung mit einer der beiden Antriebsketten für die Verstellglieder der Bogenführungselemente,

Figur 6

eine schematische Darstellung der Übertragungsglieder für die Verstellbewegungen auf beide Maschinenseiten in Draufsicht und

Figur 7

eine Seitenansicht der Anordnung nach Figur 6.

Exemplary embodiments of the invention are shown schematically in the drawing. Show it:

Figure 1

1 shows a schematic representation of the adjusting elements for sheet guiding elements which are coupled to one another on one machine side by a drive chain,

Figure 2

An embodiment of a device for coupling the two drive chains to AS and BS with a drive link,

Figure 3

another embodiment of a device for coupling the two drive chains to AS and BS with a drive link which is coupled to both drive chains,

Figures 4 and 5

3 in the coupling position with one of the two Drive chains for the adjusting links of the sheet guiding elements,

Figure 6

a schematic representation of the transmission elements for the adjustment movements on both machine sides in plan view and

Figure 7

a side view of the arrangement of Figure 6.

On each of the two machine sides AS and BS, actuators for sheet guiding elements are coupled to one another by an endlessly rotating drive chain 1 or, if appropriate, by a plurality of rotating drive chains. This drive chain 1 or drive chains 1 of both machine sides can be coupled to one another by a transverse shaft 2, which enables a synchronous movement of the drive chains 1 on each of the two machine sides for a common adjustment of the sheet guiding elements, which is not shown in the drawing for the sake of a better overview are.

The exemplary embodiment of the device for optionally jointly or individually adjusting the sheet guiding elements on both machine sides in FIG. 2 is designed for manual operation. A manually rotatable control shaft 3 can be coupled via a spur gear 4 and a bevel gear 5 and 6 either either with one of the two drive chains 1 on each of the two machine sides or with both drive chains 1 simultaneously. A bevel gear of both bevel gear 5 and 6 is each directly connected via a shaft to a sprocket 7 or 8, which engages in the drive chain 1. The respective other bevel gear of both bevel gear transmissions is directly connected to a spur gear 9 or 10, both of which are independent of one another, but are mounted coaxially to one another and with their teeth in the teeth of a drive gear 11 intervene, which is arranged displaceably in the direction of its axis of rotation, so that a tooth engagement can be achieved either with only one of the two spur gears 9 and 10 or with both spur gears 9 and 10 by axial displacement of the gear 11. It is thus possible to simultaneously couple the crankshaft 3 with only one drive chain on one of the two machine sides or with both drive chains in a rotationally fixed manner in order to carry out adjustments of the sheet guiding elements either only on one machine side or simultaneously on both machine sides.

In the exemplary embodiment in FIGS. 3, 4 and 5, the crankshaft 3, which can be driven by hand or by motor, rotates through a bevel gear 12, 13 of the two bevel gear pairs 5 and 6, the other bevel gears 15 and 16 of which are arranged on fixedly mounted output shafts 17 and 18 which are coupled with the sprockets 8 and 7 engaging in drive chains 1 on the drive side and on the operating side. The bevel gears 12 and 13 of both bevel gear pairs 5 and 6 are rotatably fixed, but axially displaceable on the crankshaft 3. The axial displaceability is limited by stops, for example by a fixed pin 19, 20 of the crankshaft 3, which engages in an axial slot 21, 22, respectively. Both gears 12 and 13 are axially cushioned in the direction of their tooth engagement with the associated bevel gear 15 and 16, respectively. 3 to 5 helical springs 23 are indicated in the drawing figures. Such an arrangement enables the crankshaft 3 to be coupled with each of the two output shafts 17 and 18, as shown in FIG. 3, in order to be able to carry out adjustments synchronously on both machine sides. However, it is also possible, by axially displacing the crankshaft 3, to optionally couple the crankshaft 3 with one of the two output shafts 17 and 18, respectively the representation in FIG. 4 or corresponding to the representation in FIG. 5.

In the exemplary embodiment in FIGS. 6 and 7, the one gearwheel 15 held in a machine-fixed bearing is connected via the output shaft 17 by a chain drive 24 with adjusting members 25 on one machine side, while the other gearwheel 16 held in a machine-fixed bearing is connected via a chain drive 26 is connected to the transverse shaft 2, which in turn actuates adjusting members 27 arranged on the other machine side. Instead of the chain drives 24 and 26 shown, belt drives or gear wheel connections can also be provided between the output shafts 17 and the adjusting members 25 on the one hand and the output shaft 18 and the transverse shaft 2. The adjusting members 25 and 27 have, for example, spindle threads which pass through the threaded nuts of the machine elements to be adjusted, in order to thereby achieve adjusting movements of these elements in the direction of the arrow symbols 28 and 29 transversely to the longitudinal direction of the printing press. A coupling of the two bevel gears 15 and 16 for the purpose of a synchronous adjustment of elements for sheet alignment and sheet guiding on both sides of the printing press takes place, for example, in the manner shown in FIG. 3 and described above.

REFERENCE SIGN LIST

1

Drive chain

2nd

wave

3rd

crankshaft

4th

Helical gear

5

Bevel gear

6

Bevel gear

7

Sprocket

8th

Sprocket

9

Spur gear

10th

Spur gear

11

gear

12th

Bevel gear

13

Bevel gear

14

15

Bevel gear

16

Bevel gear

17th

Output shaft

18th

Output shaft

19th

Cones

20th

Cones

21

slot

22

slot

23

feather

24th

Chain drive

25th

Adjusters

26

Chain drive

27

Adjusters

28

Arrow icon

29

Arrow icon

Claims (6)

Device for the central adjustment of sheet guiding elements of a sheet-fed rotary printing press, in which sheet guiding elements on the drive side (AS) and sheet guiding elements on the operating side (BS) each have adjustment elements which can be driven together,
characterized by
that a drive member (3) can optionally be coupled with adjusting members on one of the two machine sides (AS or BS) or with adjusting members on both machine sides (AS and BS). Device according to claim 1,
characterized by
that the drive member (3) either with a first sprocket (7) engaging on the drive side (AS) in a chain (1) driving the adjusting members of the sheet guiding elements on this machine side or with one on the operating side (BS) in one of the adjusting members of the sheet guiding elements this machine side driving chain (1) engaging second sprocket (8) or with both sprockets (7,8) can be coupled simultaneously. Device according to claims 1 and 2,
characterized by
that between a drive member from a crankshaft (3) and the two sprockets (7,8) a clutch that can be engaged and disengaged is provided. Device according to claim 3,
characterized by
that the clutch consists of one with one of the two sprockets (7, 8) non-rotatably connected gear (15, 16) and one on the crankshaft (3) non-rotatably arranged gear (12, 13), the toothing of which optionally in the toothing of one of the the former gears (15, 16) or both gears (15, 16) can be inserted. Device according to claim 3,
characterized by
that the clutch consists of a pair of bevel gears (5, 6) in which a bevel gear (12, 13) is arranged axially displaceably on the crankshaft (3) in the direction of its axis of rotation. Device according to claim 5,
characterized by
that the axially displaceable bevel gear (12, 13) of both bevel gear pairs (5, 6) are arranged in a rotationally fixed manner on the common axis of rotation and are spring-loaded in the direction against one another, and the axes of rotation of the bevel gears (15, rotationally fixedly coupled with one of the two chain wheels (7, 8) 16) are offset with their rectified axes of rotation by the amount of axial displacement of the former bevel gears (12, 13).

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