EP0579941A1 - Device for securing and changing the position of a cylinder covering - Google Patents

Abstract

The invention relates to a device for securing and changing the position of a cylinder packing of a printing unit cylinder with an axially parallel gap. At least one clamping spindle is provided for clamping a cylinder packing, a shaft having a toothing being engaged with toothings on the clamping spindles, and the shaft comprising a receiver for an adjusting tool on the part facing the gap opening. Clamping spindles (3, 4) are movable by means of an adjusting drive (6, 9; 18), received at the end face of a printing unit cylinder (1), in such a way that a cylinder packing (29) can be clamped in the circumferential direction simultaneously at its leading edge and trailing edge and the position of the cylinder packing (29) on the printing unit cylinder (1) can also be adjusted by means of actuators (16, 19, 20, 22, 23) in a defined manner on at least one of the clamping spindles (3, 4). <IMAGE>

Description

The invention relates to a device for fastening and for changing the position of a cylinder elevator on a printing unit cylinder with an axially parallel pit of a rotary printing press, in which at least one tensioning spindle is provided for tensioning a cylinder elevator.

DE 40 11 303 A1 discloses a device for fastening a rubber blanket on a rubber cylinder of an offset printing machine. An upper and a lower rail are fixed in a rubber cylinder with a locking screw. There are V-shaped recesses between the two rails, in which the ends of a rubber blanket are received. A disadvantage of this device from the prior art is the fact that no old position of the rubber blanket on the surface of the blanket cylinder can be carried out.

DE 29 10 880 C2, on the other hand, discloses a blanket clamping device in which two clamping spindles comprise straight-toothed ring teeth which engage in ring teeth of a toothed rack, which in turn is received by a threaded bolt. The threaded bolt is arranged in the pit base of the pit of the blanket cylinder and can be moved in a thread. The disadvantages of this blanket tensioning device can be seen in the fact that only a restricted tensioning path is available. Furthermore, there is no position correction of the position of the blanket on the blanket cylinder. Due to the straight toothing of the ring teeth, only a punctiform flank contact is possible, which results in very high Hertzian pressures, which can lead to premature wear. Furthermore, the stiffness of this blanket tensioning device unfavorable, since both tooth friction and thread friction must be overcome when actuated.

JP 58-177360 shows a device for tensioning the blanket for printing presses. In this device, two clamping spindles accommodated in a printing unit cylinder are each provided with an actuating drive consisting of worm wheel and worm. A disadvantage of this device, however, is the fact that when the blanket and the underlay are changed, the two clamping points have to be moved back and forth, which is time-consuming.

Starting from the outlined prior art, the invention has for its object to extend the life of a cylinder elevator, accompanied by an increase in the ease of use of a device for fastening and tensioning a cylinder elevator.

According to the invention the object is achieved in that clamping spindles can be moved via an actuating drive accommodated on the end face of a printing unit cylinder in such a way that a cylinder lift can be tensioned both in the circumferential direction on its front edge and rear edge at the same time and the position of the cylinder lift on the printing unit cylinder via actuators on at least one of the Clamping spindles is adjustable.

An advantage of the solution according to the invention is the fact that the clamping spindles are operated via a common actuator. Now it is no longer necessary to gradually approach the front and rear blanket clamping points. This significantly reduces the set-up time when changing the cylinder lift and when changing the document due to the pressure setting. In addition, it is now possible to vary the position of the cylinder lift on the jacket of the printing unit cylinder. This can the channel inlet edge of the cylinder lift, which is exposed to strong mechanical stresses, is shifted into the area of the cylinder channel, i.e. a pressure-free space. This results in a considerable increase in the lifespan of the cylinder lift.

In a further embodiment of the idea on which the invention is based, provision is made to arrange a tooth segment which can be variably fixed in the circumferential direction by clamping in at least one of the clamping spindles. This allows the clamping paths to be adapted to individual cylinder lifts. Furthermore, the position of the cylinder lift on the circumference of the printing unit cylinder can be influenced by adjusting screws on at least one of the clamping spindles. This offers the possibility of rotating at least one of the tensioning spindles relative to the cylinder lift so that after tensioning the cylinder lift again, the latter is displaced in the circumferential direction relative to its original position on the printing unit cylinder. In addition, a scale indicating the rotation is arranged on at least one of the clamping spindles.

In a further embodiment of the idea on which the invention is based, at least one of the clamping spindles in the front area of the printing unit cylinder has an opening which enables a tool to be attached. It is thus possible for the printer, after relaxation of the rubber blanket by the actuating drive and releasing the toothed segment clamp on one of the tensioning spindles, to rotate the latter by an adjustment path readable on the scaling body.

In a further variant of the subject matter of the invention, actuators are accommodated in a fork designed in a tooth segment. An actuator designed as an adjusting screw is rotatably received in a bearing pin and moves an adjusting pin on a circular path around the center of the tensioning shaft. This can be achieved in an advantageous manner that in Depending on the thread pitch of the set screw, a very sensitive displacement of the cylinder lift is possible, with which very small displacements of the cylinder lift on the jacket of the printing unit cylinder are possible. Areas of the cylinder lift which are exposed to strong mechanical stresses can now be shifted to areas which are not mechanically critical, as a result of which the service life of the cylinder lift can be extended considerably. It is envisaged that the adjusting pin engages in the non-rotatably received scale body on at least one of the clamping spindles. This ensures that the rotation introduced into the clamping spindle in accordance with the rotation of the adjusting screw can be read off the scaling body, while the toothed segment receiving the actuators remains at rest.

The invention will be explained in detail with reference to a drawing.

Fig. 1

eine Seitenansicht eines Stelltriebs mit Schneckenrädern am Druckwerkzylinder,

Fig. 1a

die zugehörige Draufsicht;

Fig. 2

einen an der Stirnseite des Druckwerkzylinders aufgenommenen Stelltrieb mit Zahnsegment,

Fig. 2a

eine Draufsicht auf diesen;

Fig. 3

ein Zahnsegment, welches Stellglieder aufnimmt,

Fig. 4

eine Draufsicht auf Stelltrieb und am Zahnsegment befestigte Stellglieder,

Fig. 5

eine Seitenansicht des Zahnsegmentes,

Fig. 6

eine über eine Stellschraube erzeugte Verdrehung einer der Spannspindeln,

Fig. 7, 8

verschiedene Positionen des Zylinderaufzuges auf dem Mantel eines Druckwerkzylinders.

It shows:

Fig. 1

a side view of an actuator with worm wheels on the printing unit cylinder,

Fig. 1a

the associated top view;

Fig. 2

an actuator with toothed segment received on the front side of the printing unit cylinder,

Fig. 2a

a top view of this;

Fig. 3

a tooth segment, which receives actuators,

Fig. 4

a plan view of the actuator and actuators attached to the toothed segment,

Fig. 5

a side view of the tooth segment,

Fig. 6

a rotation of one of the clamping spindles generated by an adjusting screw,

7, 8

different positions of the cylinder lift on the jacket of a printing unit cylinder.

Fig. 1 shows the side view of an actuator with worm wheels on the printing unit cylinder.

A printing unit cylinder 1 receives two clamping spindles 3 and 4 on its end faces. On the clamping spindles 3, 4, a worm wheel 6 is arranged in the form fit, which abuts a collar 5 on the end face of the printing unit cylinder 1. An actuating shaft 7 is mounted in a bearing block 12 fastened by screws 14 to the end face of the printing couple cylinder 1. At this there is a worm 9 which is in engagement with the two worm wheels 6 of the clamping spindle 3 and 4. On the upper part of the actuating shaft 7, an actuating head 8 is designed, through which the actuating shaft 7 is moved. The lower end of the adjusting shaft 7, the shaft journal 10, is rotatably received in a bore 11 of the cylinder journal 2. Between the worm 9 and the bearing block 12 there is an axial bearing 13, by means of which the torque required to actuate the actuating shaft 7 is reduced.

In Fig. 1a can also be seen that the worm gears 6 are accommodated on the ends of the clamping spindles 3, 4 via keys.

Fig. 2 shows an actuator with toothed segment accommodated on the end face of the printing unit cylinder. In this variant, 6 is instead of a worm wheel Tooth segment 18 is provided on the clamping spindle 4. By means of a clamping screw 19, its non-positive connection with the clamping spindle 4 can be canceled; the frictional connection between actuator and tensioning spindle 4 must therefore be interrupted at this point. In Fig. 2a it can be seen that in this variant of the subject of the invention, instead of a collar 5, a scaling body 16 is positively connected to the clamping spindle 4 via a feather key 17. The zero point of the scale on the scale body 16 is located opposite a notch on the toothed segment 18. There is also an opening 15 on the clamping spindle 4 for attaching a tool.

When the machine is at a standstill, the printer first actuates the clamping spindles 3 and 4 via the actuating head 8 of the actuating drive and relaxes a cylinder lift. After loosening the clamping connection on the clamping screw 19, the clamping spindle 4 can be rotated relative to the toothed segment 18 in one or the other circumferential direction by means of a tool acting on the opening 15. The toothed segment 18 remains in the rest position during this operation due to the self-locking between the worm 9 and the toothing of the toothed segment 18 and can therefore be used as a reference point for the quantitative evaluation of the torsion path of the clamping spindle 4. After the corresponding rotation of the clamping spindle 4, the non-positive connection between the clamping spindle 4 and the toothed segment 18 is restored by tightening the clamping screw 19. A cylinder lift is then tensioned by rotating the control shaft 7 via the control head 8. A cylinder lift now assumes a different position in the circumferential direction on the printing unit cylinder 1 with respect to its original position.

In Fig. 3, a tooth segment is shown, which receives several actuators.

In this variant, a toothed segment 18 is actuated via an actuating shaft 7 which is mounted analogously to the explanations in FIGS. 1 and 2. The adjusting shaft 7 is mounted on the one hand in the bearing block 12 and on the other hand with the shaft journal 10 in the bore 11 of the cylinder journal 2. In this variant, the toothed segment 18 is configured such that a set screw 20 is rotatably received in a bearing pin 22. The set screw 20 passes through this bearing pin and moves a set pin 23 on a circular path when rotated. The adjusting bolt 23 is in turn rotatably received in the scaling body 16.

Fig. 4 shows a top view of this variant. The toothed segment 18 is provided on the set screw side with a fork 21 which bridges the rotatably mounted bearing pin 22. In the scaler body 16, the adjusting bolt 23 is received in a broken line; The scaler body 16 is in turn - similar to the embodiment in Fig. 2a - positively connected to the clamping spindle 4 via a feather key 17. From the side view of the toothed segment 18 shown in FIG. 5 it can be seen that when the adjusting screw 20 is rotated in the bearing pin 22, the adjusting pin 23, which is mounted in the scaler body 16, rotates the latter and, via the feather key 17, the clamping spindle 4.

6 shows a rotation of the clamping spindle 4 generated by an adjusting screw. The scaling body 16 behind the toothed segment 18, which is held in position by the worm 9, is shown in a rotated position compared to its rotational position in FIG. 3 . Since the scaling body 16 is positively connected to the clamping spindle 4, the rotation of the clamping spindle 4 can be seen from a comparison of the rotational position of the parallel key 17 in FIGS. 3 and 6. About the pivoting movement of the adjusting bolt 23 that occurs when the scaling body 16 is rotated to compensate, the set screw 20 is movable in the fork 21 of the toothed segment 18.

It should be noted that both of the clamping spindles 3 and 4 can be connected to a toothed segment 18 which can be variably fixed in the circumferential direction; be it with the variant shown in Figures 2 and 2a, be it with the variant shown in Figures 3, 4, 5 and 6. This increases the area available for shifting the cylinder lift on the jacket of the printing unit cylinder 1.

Figures 7 and 8 show different positions of a cylinder lift on the jacket of a printing unit cylinder.

By means of a web 25 on the printing unit cylinder 1, an axially parallel pit of the printing unit cylinder 1 is divided into two recesses 28, one of which receives one of the clamping spindles 3 and 4. There is a lower clamping bar 31 on the clamping spindles 3 and 4, which receives an upper clamping bar 26 via screws 27. The ends of a cylinder lift 29 are received between the upper clamping bar 26 and the lower clamping bar 31. In order to hold the pair of clamping strips when clamping on the clamping shaft 3, the clamping strips 31 are connected to holding clips 30, which in turn are fastened to the clamping spindles 3, 4 by means of screws 32. 7, the clamping spindles 3 and 4 are arranged in an approximately symmetrical position with respect to one another, which corresponds approximately to a first clamping position of a new cylinder elevator 29 on the outer surface of the printing unit cylinder 1. After a certain service life, the cylinder elevator 29 can then be moved on the jacket of the printing cylinder 1 with reference to its original position shown in FIG. 7 with the aid of the device according to the invention. For example, the clamped on the clamping spindle 4 Area of the cylinder lift 29 in the case of hardening or occurring porosity of the channel inlet edge in the area of the recess 28, where the mechanical stresses are eliminated. For example, small damage to the cylinder elevator 29 caused by paper crumpling can under certain circumstances be relocated to non-printing areas.

REFERENCE SIGN LIST

1

Printing cylinder

2nd

Cylinder journal

3rd

Clamping spindle

4th

Clamping spindle

5

Federation

6

Worm wheel

7

Control shaft

8th

Adjusting head

9

slug

10th

Shaft journal

11

drilling

12th

Bearing block

13

Thrust bearing

14

screw

15

opening

16

Scaling body

17th

adjusting spring

18th

Tooth segment

19th

Clamping screw

20th

Set screw

21

fork

22

Bearing bolt

23

Adjusting bolt

24th

attack

25th

web

26

upper terminal block

27

Clamping screw

28

Recess

29

Cylinder lift

30th

Retaining clip

31

lower terminal block

32

screw

Claims (10)

Device for fastening and for changing the position of a cylinder lift on a printing unit cylinder with an axially parallel pit of a rotary printing machine, in which at least one tensioning spindle is provided for tensioning a cylinder lift and a toothed shaft is in engagement with toothings on the tensioning spindles, the shaft being at that of the pit opening facing part includes a receptacle for an adjusting tool,
characterized,
that tensioning spindles (3, 4) can be moved via an actuator (6, 9, 18) accommodated on the end face of a printing unit cylinder (1) in such a way that a cylinder lift (29) can be tensioned both in the circumferential direction on its front and rear edges at the same time as well The position of the cylinder lift (29) on the printing unit cylinder (1) can be set in a defined manner on at least one of the clamping spindles (3, 4) via actuators (16, 19, 20, 22, 23). Device for attaching and changing the position of a cylinder elevator according to claim 1,
characterized,
that on at least one of the clamping spindles (3, 4) a tooth segment (18) which can be variably fixed in the circumferential direction by means of a clamp (19) is provided. Device for attaching and changing the position of a cylinder elevator according to claims 1 and 2,
characterized,
that the position of the cylinder lift (29) on the circumference of the printing unit cylinder (1) can be influenced by actuators (19, 20) on at least one of the clamping spindles (3, 4). Device for attaching and changing the position of a cylinder elevator according to claim 1,
characterized,
that on at least one of the clamping spindles (3, 4) a scale indicating the rotation (16) is arranged. Device for attaching and changing the position of a cylinder elevator according to claim 1,
characterized,
that at least one of the clamping spindles (3, 4) has an opening (15) in the front area of the printing unit cylinder (1) which enables a tool to be attached. Device for attaching and changing the position of a cylinder elevator according to claim 2,
characterized,
that in the toothed segment (18) a fork (21) is executed, which actuators (20, 22) receives. Device for attaching and changing the position of a cylinder elevator according to claims 2 and 6,
characterized,
that the actuator (20) is movable in a bearing pin (22). Device for attaching and changing the position of a cylinder elevator according to claim 7,
characterized,
that the actuator (20), designed as an adjusting screw, moves an adjusting bolt (23) on a circular path. Device for attaching and changing the position of a cylinder elevator according to claim 8,
characterized,
that the adjusting pin (23) engages in the non-rotatably received at least one of the clamping spindles (3, 4) scaling body (16). Device for attaching and changing the position of a cylinder lift according to one or more of the preceding claims,
characterized,
that when the cylinder lift (29) is relaxed, by rotating the actuators (19, 20) on at least one of the clamping spindles (3, 4) through the scaling body (16) and the adjusting bolt (23), at least one of the clamping spindles (3, 4) relative to the relaxed Cylinder lift (29) is rotatable.

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