EP1534517A1

EP1534517A1 - Drive of a rotational body

Info

Publication number: EP1534517A1
Application number: EP03740115A
Authority: EP
Inventors: Erich Max Karl Gerner
Original assignee: Koenig and Bauer AG
Current assignee: Koenig and Bauer AG
Priority date: 2002-07-18
Filing date: 2003-07-03
Publication date: 2005-06-01
Also published as: DE10232552A1; AU2003284930A1; DE10232552B4; WO2004016430A1

Abstract

The invention relates to a drive of a rotational body (1) in a printing machine by a shaft (07) via a drive connection (06). The drive connection consists of a series of two couplings (08, 16) compensating an angle deviation, also comprising a third serial coupling (23) receiving an axial relative movement.

Description

description

Drive of a rotating body

The invention relates to a drive of a rotating body according to the preamble of claim 1 or 2.

EP 07 22 831 B1 discloses a drive for a cylinder, the cylinder driven by a motor being arranged to be axially displaceable for adjusting the side register. A rotor arranged coaxially on the journal of the cylinder is axially movable in the stator.

EP 10 00 737 A1 discloses driving a cylinder sleeve via a shaft which can be axially clamped against a disk. Between the drive motor and sleeve there is an axial coupling which enables the axial relative movement.

WO 98/51497 A2 discloses a drive for a rotating component, a journal of the rotating component being connected to the shaft or a rotor of a motor in a rotationally fixed manner via couplings which compensate for two angular deviations.

CH 451 968 A discloses a drive of a cylinder via a drive connection with couplings compensating for two angular deviations, designed as cardan joints, and a coupling which absorbs axial movement, designed as a shaft coupling provided with keyways.

The invention has for its object to provide a drive for a rotating body.

The object is achieved by the features of claim 1 or 2. The advantages that can be achieved with the invention consist in particular in that a drive is provided for pivotable and at the same time axially movable cylinders, with play in the circumferential direction being minimized. The drive connection allows the drive of such movable cylinders by means of any drive motors without the need for a special design.

In order to enable an axial relative movement between the cylinder and the drive motor fixed to the frame, at least one coupling which is flexible in the axial direction is arranged between the drive motor and the forme cylinder. It is in an advantageous embodiment as a torsionally rigid but flexible in the axial direction or compliant shaft coupling, for. B. executed as an expansion or compensating coupling. It is particularly advantageous to use a non-switchable form-locking multi-plate clutch, which, in contrast to other form-fitting clutches, is almost free of play in the circumferential direction without major manufacturing effort.

The compensation in the angle required, for example, when the cylinder is pivoted, takes place via at least one coupling compensating for angular deviations, which, in an advantageous embodiment, is also a torsionally rigid but flexible or flexible shaft coupling in the axial direction, e.g. B. executed as an expansion or compensating coupling. The coupling is form-fitting in the axial direction, but its length is flexible or flexible, e.g. B. performed by elastic and reversible deformation.

An embodiment is advantageous in which two couplings compensating for angular deviations and a shaft coupling having at least two flexible or flexible transmission elements in the axial direction are arranged in series between the cylinder and the drive motor.

The drive via the coupling is particularly important in the case of individual drives individually driven cylinders, but especially on the forme cylinder to adjust the side register, is an advantage. If the cylinders of a printing group are individually driven by a drive motor, the circumferential register can be changed on the basis of changes in the relative angular position of the drive motor, and the side register can be changed relative to one another by means of the axial displacement. In an advantageous embodiment, the drive motors are arranged coaxially with the cylinder to be driven.

In the case of cylinders driven in groups, in particular in pairs, the arrangement of the drive motor via the coupling to the forme cylinder of a jointly driven cylinder pair is advantageous. The drive on the forme cylinder means that the drive motor does not have to move when the transfer cylinder is in the up and down position, as is the case, for. T. is the case when driving directly on the transfer cylinder. A compromise based on such pivoting movements of the transfer cylinder in the position of the drive motor and the engagement of the gearwheels when the drive motor is arranged on the transfer cylinder can also be dispensed with when the forme cylinder is driven. In the other case, the latter can lead to tooth breakage or, due to the play in the drive, to a reduction in print quality.

In general, with regard to the print quality and / or the dimensioning of the motors, it can be advantageous to adjust the concentricity by arranging a gear, in particular a reduction gear, e.g. B. between the drive motor and the cylinder, in particular between the drive motor and the clutch closest to the drive motor to improve. Here comes in particular a front-mounted gear unit, the drive motor, z. B. a planetary gear in question.

In one embodiment, the drive motor can be arranged directly axially to the forme cylinder or to the driven cylinder. Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

Figure 1 shows a first embodiment for driving a cylinder. Fig. 2 shows a first embodiment for driving a cylinder.

A rotating body 01, in particular a cylinder 01 or a roller 01, for. B. a forme cylinder 01, a printing press, in particular a rotary printing press, is on one end face with a shaft 04 rotatably mounted in a side frame 03, z. B. a so-called. Pin 02, rotatably connected. The pin 02 of the cylinder 01 is movable with respect to the side frame 03, for. B. pivoted in an eccentric bearing 04, stored. The pin 02 is operatively connected to a drive motor 05 on the end face via a drive connection 06.

In a first embodiment (FIG. 1), the drive connection 06 has a coupling 08, z. B. designed as a spring washer or multi-plate clutch 08 on. In order to ensure an exact radial alignment and an axial distance as well as an angle change around a fixed and defined pivot point D, the coupling 08 in an advantageous embodiment parallel to a torsionally rigid transmission element 09 has a bearing 11, e.g. B. a spherical bearing 11 on. This spherical bearing 11 can, for. B. in the radial direction to a play-free setting. The torque is transmitted via the transmission element 09, and is fixed in the axial direction via the joint bearing 11.

The transmission element 09 is, for. B. as a spring washer 09 or disk set 09, which on one side with a first coupling half 12 and on the other side is torsionally rigidly connected to a second coupling half 13. Such a clutch 08 is also referred to as a flexible all-metal clutch, as a diaphragm or all-steel multi-plate clutch. The first coupling half 12 is designed, for example, as the socket 02 comprising the socket 02, which is connected by means of a clamping element 14 to the socket 02 in a torsionally rigid manner, and has, for. B. the convex outer surface of the spherical bearing 11. The second coupling half 13 is connected to the shaft 07 in a torsionally rigid manner and has the concave inner surface of the spherical bearing 11.

The second end of the shaft 07 is connected in a torsionally rigid manner to a second coupling 16 which compensates for an angular deviation and which is designed, for example, like the first coupling 08. It also has a first coupling half 17, a transmission element 18, for. B. spring washer 18 or disk set 18, a second coupling half 19 and a spherical bearing 21. In contrast to the first clutch 08, the second clutch half 19 is torsionally rigid, but in the axial direction relative to a second clutch half 22 of a third clutch 23, e.g. B. another spring washer or multi-plate clutch 23, arranged. For this purpose, the second coupling half 19 of the second coupling 16 is designed, for example, as a sliding bush 19, which is arranged for axial guidance via a sliding fit 24 or a sliding seat 24 on a bushing 26 carrying the second coupling half 22 of the third coupling 23. The second coupling half 19 of the second coupling 16 here simultaneously represents the first coupling half 19 of the third coupling 23, which as an axial relative movement between the coupling halves 19; 22 enabling clutch 23 is executed.

For this purpose, she has z. B. at least one, in an advantageous embodiment, as shown, two transmission elements 27; 28 in series between its first coupling half 19 and its second coupling half 22. The two transmission elements 27; 28 are also in an advantageous embodiment as spring washers 27; 28 or plate packs 27; 28 (each with several spring washers), which are arranged in series by means of threaded bolts between the first coupling half 19, an intermediate ring 29 and the second coupling half 22.

The transmission elements 27; 28 allow spring travel in the axial direction due to elastic deformation, but allow a torsionally rigid connection due to their rigidity in the circumferential direction. The second coupling half 19 of the second coupling 16 is non-rotatably connected via the transmission element 19, but is axially movably connected to the bushing 26 via the coupling 23 in cooperation with the sliding fit 24. The socket 26 connected to the second coupling half 22 of the third coupling 23 is, in an advantageous embodiment by means of a clamping element 31, connected to a shaft 32 of the drive motor 05 in a torsionally rigid manner. In an advantageous embodiment, the drive motor 05 is fixed to the frame, for example on a holder 33 connected to the side frame 03.

In interaction with the sliding fit 24, the, in particular two, serial transmission elements 27; 28, clutch 23 in this way a relative movement in the axial direction between the shaft 07, and thus the cylinder 01, on one side and the bushing 26, and thus the drive motor 05, on the other side. An axial movement of the cylinder 01, for example to adjust the side register, relative to the drive motor 05 fixed to the frame is thus possible. The first two clutches 08; 16 together allow pivoting of the cylinder 01 in a direction perpendicular to the axial direction of the cylinder 01 by compensating for deviations in the angle and / or offset between the axis of rotation R01 of the cylinder 01 and the axis of rotation R05 of the drive motor 05 fixed to the frame.

In a second exemplary embodiment (FIG. 2), the drive connection 06 between the cylinder 01 and the drive motor 05 fixed to the frame again has two couplings 08 which compensate for an angular deviation; 16 and an axial relative movement enabling or receiving coupling 23. In contrast to FIG. 1, however, the first coupling 08 compensating for angular deviations is arranged on the shaft 32 of the drive motor 05, while the coupling 16 compensating for angular deviations and the coupling 23 absorbing axial relative movement are arranged on the journal 02 of the cylinder 01. The arrangement of the two last-mentioned couplings 16 and 23 can be carried out in the same manner, but in the opposite direction to FIG. 1, or as shown in FIG. 2. Here, the shaft 07 overlaps the coupling 23 spatially, the couplings 08; 16 are, however, arranged one behind the other in the direction of action. In contrast to FIG. 1, the socket 26 now encompassing the pin 02 simultaneously represents the second coupling half 26 of the third coupling 23. However, as in FIG. 1, a coupling half 22 connected to the socket 26 can also be arranged.

It is particularly advantageous in both exemplary embodiments that the compensation of the angular movement or the offset and the compensation of the axial movement are decoupled from one another. The torsionally rigid coupling 23 for axial compensation does not allow any change in the angle in its axis of rotation, i. H. all parts of this coupling 23 are fixed with respect to their axis of rotation. In an advantageous embodiment, the axis of rotation of the coupling 23 is fixed to the motor or frame, i. H. on the side of the clutch 08 facing the motor 05; 16 arranged. Conversely, the torsionally rigid couplings 08; 16 no relative axial movement, the spherical bearing fixes the coupling halves 12, 13; 17, 19 at an axial distance from one another with respect to a fixed pivot point.

In principle, the drive connection 06 is also for the drive from a drive motor 05 via a gear, from another cylinder, or from a shaft via a drive wheel (not shown) which is fixed to the frame and rotatably mounted, e.g. B. a gear or a pulley, suitable or which is then rotatably connected instead of the drive motor 05 with the rotatable but fixed to the shaft 32. The Drive motor 33 can, in particular in the case of direct axial drive, also a step-down gear, z. B. have a planetary gear.

LIST OF REFERENCE NUMBERS

01 rotating body, cylinder, roller, forme cylinder

02 shaft, journal (01)

03 side frame

04 eccentric bearings

05 drive motor

06 Drive connection

07 wave

08 clutch, first, spring washer, multi-plate clutch

09 Transmission element, spring washer, plate pack

10 -

11 bearings, spherical bearings

12 coupling half, first (08), socket

13 coupling half, second (08)

14 clamping element

15 -

16 clutch, second, spring washer, multi-plate clutch

17 coupling half, first (17)

18 transmission element, spring washer, plate pack

19 coupling half, second (17), sliding bush, first (23)

20 -

21 bearings, spherical bearings

22 coupling half, second (23)

23 clutch, third, spring washer, multi-plate clutch

24 Sliding fit, sliding fit 5 - 6 socket 7 transmission element, spring washer, plate pack 28 Transmission element, spring washer, plate pack

29 intermediate ring

30 -

31 clamping element

32 wave

33 bracket

D pivot point

R01 axis of rotation (01)

R05 rotation axis (05)

Claims

Expectations

1. Drive of a rotary body (01) of a printing press from a shaft (32) via a drive connection (06), which has in series two couplings (08; 16) compensating for an angular deviation and a third coupling (23) absorbing an axial relative movement, characterized in that the two couplings (08; 16) compensating for an angular deviation have an articulated bearing (11) parallel to a torsionally rigid transmission element (09), and in that the coupling (23) absorbing an axial relative movement is designed as a spring washer or multi-plate coupling (23) is the parts of which are arranged fixedly with respect to an axis of rotation of the clutch (23).

2. Drive of a rotary body (01) of a printing press from a shaft (32) via a drive connection (06), which has in series two couplings (08; 16) compensating for an angular deviation and a third coupling (23) absorbing an axial relative movement, characterized in that all three couplings (08; 16; 23) each have at least one torsionally rigid, deformable transmission element (09; 27; 28) which is positively connected in the axial direction and that the coupling (23) absorbing the axial relative movement in the drive train is not between , but is arranged before or after the two couplings (08; 16) compensating for the angular deviation.

3. Drive according to claim 2, characterized in that the axial relative movement receiving clutch (23) is designed as a spring washer or multi-plate clutch (23), the parts of which are arranged fixedly with respect to an axis of rotation of the clutch (23).

4. Drive according to claim 1 or 2, characterized in that a coupling half (19) of the axial relative movement receiving coupling (23) is slidably mounted on a shaft (02; 32) in the axial direction.

5. Drive according to claim 1 or 2, characterized in that the axial relative movement receiving coupling (23) has two transmission elements (27; 28) arranged in series.

6. Drive according to claim 1 or 2, characterized in that the transmission element (09) is designed as an axially elastically deformable spring washer or plate pack (09).

7. Drive according to claim 1, characterized in that the axial relative movement receiving coupling (23) in the drive train is not arranged between, but before or after the two, the angular deviation compensating couplings (08; 16).

8. Drive according to claim 2 or 5, characterized in that the transmission element (27; 28) is designed as an axially elastically deformable spring washer or plate pack (27; 28).

9. Drive according to claim 1 or 2, characterized in that the angular deviation compensating clutches (08; 16) is designed as at least one spring washer or at least one disk pack (09; 18) having disk clutch (08; 16).

10. Drive according to claim 1 or 2, characterized in that the two couplings (08; 16) which compensate for the angular deviation are connected to one another in a torsionally rigid manner and rigidly in the axial direction.

11. Drive according to claim 10, characterized in that one of the Couplings (08; 16) compensating for angular deviation are torsionally rigidly connected to a shaft (02) of the cylinder (01) and the other torsionally rigidly connected to the shaft (32) assigned to the drive side of the drive connection.

12. Drive according to claim 11, characterized in that the axial relative movement receiving coupling (23) is arranged on the shaft (32) assigned to the drive side.

13. Drive according to claim 11, characterized in that the coupling (23) accommodating the axial relative movement is arranged on the shaft (02) assigned to the cylinder (01).

14. Drive according to claim 1 or 2, characterized in that the shaft (32) is designed as a motor shaft or an axial extension of a drive motor (05).

15. Drive according to claim 1 or 2, characterized in that the shaft (32) is rotatably connected to a drive wheel which can be driven by a drive motor (05).

16. Drive according to claim 14 or 15, characterized in that the drive motor (05) only drives the rotary body (01) individually.

17. Drive according to claim 14 or 15, characterized in that the drive motor (05) is arranged fixed to the frame.

18. Drive according to claim 15, characterized in that the drive wheel is arranged fixed to the frame.

19. Drive according to claim 1 or 2, characterized in that the rotary body (01) is designed as a forme cylinder (01) movable in its axial direction.

20. Drive according to claim 1 or 2, characterized in that the rotary body (01) is designed as a forme cylinder movable vertically to its axial direction (01).