EP1420954A1 - Roller - Google Patents

Abstract

The invention relates to a roller (01,18,19,28) for a printing machine, comprising a rotatably mounted roller body (2) which can be placed on at least one counter roller, said roller having at least one axis (08) and at least one spring element (08) being able to be arranged between the roller body and a machine stand (04). The spring element is disposed between the roller body and the part of the axis which is used to fix the roller.

Description

description

roller

The invention relates to a roller according to the preamble of claims 1, 2, 3 or 20.

A roller is known from EP 0941 849 A1. In the case of the roller described there, axial sections protrude on the end faces, which are rotatably mounted in bearing shells. The bearing shells are connected to the machine frame by means of spring elements, so that when the roller is placed against a counter roller, the roller body can move radially. This resilient mounting of the roller in particular ensures that dimensional deviations, for example due to increased wear, can be compensated for. In addition, defined pressure forces between roller and counter roller can be realized in a simple manner by the resilient mounting.

The US 47 56 249 A describes an inking roller, the jacket tube is spring-mounted on its axis in the radial direction.

DE-PS 15 61 014 shows an inking roller, the axis of which is received in a sprung bearing.

The invention has for its object to provide a roller.

The object is achieved by the features of claims 1, 2, 3 or 20.

In the case of the proposed roller, the spring element is arranged between the roller body of the roller and the part of the axis which serves to fasten the roller. On The advantage of the roller is, in particular, that particularly compact designs are possible due to the arrangement of the spring element between the roller body and the axis. In addition, rollers can be retrofitted in existing printing presses without resilient bearing elements, in order to be able to achieve the desired suspension effect in this way without major conversion measures.

In order to implement the arrangement of the spring element between the roller body and the axis, the design of the axis itself is basically arbitrary. For example, it is conceivable to design the axis essentially in one piece, so that it extends in the interior of the roller body from one end face to the other. In the case of longer rolls in particular, it is advantageous if the roll body is mounted on two separate axes, which are each arranged in the region of one end face.

The design of the spring element is basically arbitrary. For example, it is conceivable to arrange spring-loaded bearing shells between the axis and the roller body, so that the roller body can move relative to the axis in the radial direction against a spring force. A particularly simple and inexpensive way of realizing the design principle is for the axis itself to be designed as a spring element. In other words, because of its design, the axis allows an at least slight elastic deformation, so that the roller body can be displaced relative to the clamping of the axis against the elastic restoring force required for the deformation of the axis.

According to a preferred embodiment, the axis is designed in the manner of a bar spring element. Due to the rod-like shape of the axle, it can be deformed transversely to its longitudinal axis and thereby enables the suspension effect.

If the rod spring element used as an axis has a rotationally symmetrical cross section, it can in particular be achieved that the Suspension characteristic of the bar spring element is essentially the same with respect to all radial directions.

If, on the other hand, the bar spring element has a non-rotationally symmetrical cross section, it becomes possible to set a predetermined, in particular direction-dependent, spring characteristic by appropriate selection of the cross section or by suitable arrangement of the cross section after the roller has been installed.

This is particularly advantageous if the roller is to be set against several counter-rollers at the same time. By a corresponding choice of the cross-section or its arrangement after installation of the roller, a different spring characteristic can be set compared to the different counter-rollers. If, for example, a rectangular cross-section is selected, it follows that the bar spring element has a significantly steeper spring characteristic than deformations in one direction, namely in the direction of the greatest width of the bar spring element, than in the direction running perpendicular thereto, namely the direction along the smallest width of the bar spring element.

If the cross-section or the arrangement of the cross-section of the bar spring element is selected appropriately, the bar spring element can be mounted with a direction-dependent preload, so that the reaction forces caused by the weight of the roller and acting differently on the different counter-rollers are compensated. As a result, it can be achieved that the same reaction forces act on all of the counter-rollers placed on the roller, regardless of their installation position relative to the vertical, and the weight of the roller essentially has no influence on the pressure between the roller and the various counter-rollers.

For some applications, for example when the roller is like an application roller is formed, which is placed on a forme cylinder and a distribution cylinder at the same time, it is necessary that the bar spring element does not compress in at least one direction.

In order to be able to ensure sufficient dynamic stability in all operating situations despite the resilient mounting of the roller body on the axle, it is desirable in some applications if a damping element is arranged between the axle and the roller body. By means of this damping element, an excitation of the roller, in particular in the region of its resonance frequencies, can be damped to such an extent that the roller body remains in a dynamically stable state at all times.

Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

Figure 1 is a roller in a partially shown cross section.

Figure 2 shows a roller frame with five rollers in a side view.

Fig. 3 shows a roller frame with three rollers in a side view.

The roller 01 partially shown in FIG. 1 has a rotatably mounted roller body 02, the peripheral surface of which can be set against a counter roller, not shown. The roller 01 is fastened to the machine frame of a printing press by means of a bearing element 03. The roller 01, e.g. B. the applicator roller can also be stored in levers for starting and stopping. The bearing element 03 can be adjusted remotely in order to move the roller 01 relative to the machine frame 04 or to change the pressure between the roller 01 and the counter-roller, not shown. The roller body 02 is by means of two bearings 06 arranged in the area of the end faces, for. B. roller bearing 06, rotatably mounted on axes 07. As an alternative to the exemplary embodiment shown, it is of course also conceivable to provide roller bearings 06 in the bearing element 03 for the rotatable mounting of the rolling element 02, in order thereby to enable a rotational relative movement between the axis 07 and the bearing element 03.

The axis 07 is as a spring element 07, for. B. formed as a rod spring 07. This is realized constructively in that the axis 07 is a spring element 08, for. B. has a bar spring element 08 which can be elastically deformed transversely to its longitudinal axis. The bar spring element 08 is rigidly clamped on the bearing element 03 and rigidly fastened with its opposite end to the end face of a sleeve 09. If a force acts radially to the longitudinal axis 11 of the roller 01 on the roller body 02, the bar spring element 08 is at least slightly elastically deformed by this force, so that the force acting on the roller body 02 causes an oppositely directed spring force.

The spring element 08 can also be made hollow in order to enable the entry and exit of a coolant-guided roller body 02.

In particular, the bending stiffness of the rod spring element 08 is selected such that a fixed force is generated largely independently of its deflection.

A damping element 12 is provided in the gap between the sleeve 09 and the rod spring element 08. In terms of design, this is achieved in that the gap between the sleeve 09 and the bar spring element 08 is filled with a vibration-damping material. The bar spring element 08 has a circular cross-section, so that the same spring characteristic results in the case of the roll body 02 being set against two counter-rolls in both directions of adjustment. If the roller 01 is set to the correct flattening on a counter roller using known adjusting devices, this setting is maintained by the bar spring element 08 even under dynamic stress with constant force. Vibrations that occur are kept below a tolerable limit by the damping element 12.

Fig. 2 shows an inking unit 13 with a plate cylinder 14, two distribution cylinders 16 and 17, a roller 18, z. B. an ink roller 18 and a roller 19, z. B. an application roller 19. The ink is transferred from the distribution cylinder 17 via the inking roller 18, the distribution cylinder 16 and the application roller 19 to the plate cylinder 14. The axis of the ink roller 18 has a circular spring element 21, for. B. a rod spring element 21, so that the spring characteristic of the inking roller 18 is approximately the same in both directions of adjustment 22 and 23 when employed on the distribution cylinders 16 and 17.

In contrast, the axis of the application roller 19 has a rectangular spring element 24, for. B. a rod spring element 24. The rectangular design of the bar spring element 24 and a correspondingly suitable arrangement ensures that the bar spring element 24 enables an essentially rigid mounting with a very steep spring characteristic when it is set against the plate cylinder 14 in the setting direction 26. In other words, this means that the application roller 19 can only be displaced in the setting direction 26 with correspondingly high forces. In order to adjust the flattening of the application roller 19 against the plate cylinder 14, the bearing element 03 must be designed to be displaceable in the direction of adjustment 26. The rod spring element 21 can then be rotated again in the direction of adjustment 26 for fine adjustment. In the setting direction 27, on the other hand, the application roller 19 springs in relatively slightly when it is set against the distribution cylinder 16, since the bar spring element 24 has its smallest width in this direction. In the case of an asymmetrical spring element, the spring element can be made rotatable, so that the pressure, viewed from the basic setting, can be both increased and decreased. The bearing element 03 is then designed such that the spring element can be clamped.

In Fig. 3 is a combination of rollers from a roller 28 which against two rollers 29 and 31, z. B. two counter-rollers 29 and 31 is shown. Since the counter roller 31 is arranged below the roller 28, a weight force 32 caused by the weight of the roller 28 acts on the counter roller 31. In the end result, after installation of the roller 28, the same setting forces 33 and 34 will act on the counter rollers 29 and 31 the roller 28, the axis of a spring element 36, z. B. has a bar spring element 36, mounted so that the bar spring element 36 has a different bias along the adjustment directions 37 and 38. The weight force 32 acting on the counter-roller 31 can be compensated for by a suitable choice of the difference between the prestresses along the adjustment directions 37 and 38, so that the adjustment forces 33 and 34 correspond in terms of amount as desired. Of course, a different ratio between the different between the rollers 28; 29; 31 acting forces can be adjusted.

The axis 07 and the roller body 02 are z. B. non-rotatably connected. In another embodiment, the roller body 02 rotates relative to the axis 07.

The spring element 08 has a flat spring characteristic.

The force generated by the spring element (e.g. contact force to a counter roller and / or counter cylinder) is almost independent of the deflection (in the area of the deflection that occurs, the change in force is, for example, less than 50%). LIST OF REFERENCE NUMBERS

01 roller

02 roller body

03 bearing element

04 machine frame

05 -

06 bearings, roller bearings

07 axle, spring element, bar spring

08 spring element, bar spring element

09 sleeve

10 -

11 longitudinal axis (01)

12 damping element

13 inking unit

14 plate cylinders

15 -

16 distribution cylinders

17 distribution cylinders

18 roller, ink roller

19 roller, applicator roller

20 -

21 spring element, bar spring element

22 Direction of attack

23 direction of attack

24 spring element, bar spring element

25 -

26 Direction of attack

27 Direction of attack roller

Roller, counter roller

-

Roller, counter roller

weight force

contact force

contact force

-

Spring element, bar spring element

setting direction

setting direction

Claims

Expectations

1. roller of a printing press, with a rotatably mounted roller body (02), the roller (01; 18; 19; 28) having at least one axis (07) and at least one spring element (08) between roller body (02) and machine frame ( 04) is arranged, characterized in that the axis (07) has a spring element (08; 21; 24; 36).

2. Roller of a printing press, with a rotatably mounted roller body (02), the roller (01; 18; 19; 28) having at least one axis (07) and at least one spring element (08) between the roller body (02) and the machine frame ( 04), characterized in that the spring element (08; 21; 36) has a rotationally symmetrical cross section.

3. roller of a printing press, with a rotatably mounted roller body (02), the roller (01; 18; 19; 28) having at least one axis (07) and at least one spring element (08) between roller body (02) and machine frame ( 04), characterized in that the spring element (24) has a non-rotationally symmetrical cross section, the cross section and the arrangement of the cross section of the spring element (24) being selected in accordance with a predetermined direction-dependent spring characteristic.

4. Roller according to claim 1, 2 or 3, characterized in that the roller body (02) is employed at least on a distribution cylinder (14; 16; 17) and at least one counter roller (17; 28; 29; 31).

5. Roller according to claim 1, 2 or 3, characterized in that the roller body (02) has two axes (07) which are each in the area of an end face of the roller (01) at least in sections along the axis of rotation (11) of the roller ( 01) extend.

6. Roller according to claim 1, 2 or 3, characterized in that the spring element (08) is part of the axis (07).

7. Roller according to claim 1, characterized in that the spring element (08; 21; 36) has a rotationally symmetrical cross section.

8. Roller according to claim 1, characterized in that the spring element (24) has a non-rotationally symmetrical cross section, the cross section and the arrangement of the cross section of the spring element (24) being selected in accordance with a predetermined direction-dependent spring characteristic.

9. Roller according to claim 8, characterized in that the roller (19; 28) on rollers (29; 31) or cylinder (14; 16) can be adjusted simultaneously, the cross section and the arrangement of the cross section of the spring element (24; 36 ) is selected in accordance with a predetermined spring characteristic compared to cylinders (14; 16) and the individual rollers (29; 31).

10. Roller according to claim 8 or 9, characterized in that the spring element (24) has a cross section, so that the spring element (24) in at least one direction allows substantially no elastic deformation.

11. Roller according to claim 10, characterized in that the roller (19) is designed in the manner of an application roller (19) which can be placed on a plate cylinder (14) and a distribution cylinder (16), the cross section and the arrangement of the spring element (24) are selected such that the application roller (19) is mounted essentially rigidly relative to the plate cylinder (14).

12. Roller according to one of claims 8 to 11, characterized in that the cross section and the arrangement of the cross section of the spring element (36) is selected such that the weight force (32) of the roller (28) caused on the different counter-rollers ( 29; 31) reaction forces having different strengths are essentially compensated by the spring force after assembly of the roller (28), so that essentially equal adjusting forces (33; 34) act on all counter-rollers (29; 31).

13. Roller according to one of claims 1 to 12, characterized in that a damping element (12) between the roller body (02) and the part of the axis (07) which serves to fasten the roller (01) is arranged.

14. Roller according to one of claims 1 to 13, characterized in that a sleeve (09) is arranged between the roller body (02) and at least one of the axes (07) having a spring element (08), on which the roller body (02) is rotatable is mounted and its end face facing the inside of the roller (01) is connected to one end of the spring element (08).

15. Roller according to claim 14, characterized in that the damping element (12) is arranged in the space between the sleeve (09) and spring element (08), in particular substantially completely fills this space.

16. Roller according to one of claims 1 to 15, characterized in that the spring element (08) is detachably attached to the roller (01).

17. Roller according to one of claims 1 to 16, characterized in that on the roller (01) either spring elements (08) or combinations of spring elements (08) with different properties can be arranged.

18. Roller according to one of claims 1 to 17, characterized in that the axis (07) is fastened to the machine frame (04) by means of adjustable bearing elements (03).

19. Roller according to claim 1, 2 or 3, characterized in that the spring element is designed as a bar spring (07).

20. Roller of a printing press with a rotatably mounted roller body (02), the roller (01; 18; 19; 28) having at least one axis (07) and at least one spring element (08) between roller body (02) and machine frame (04 ) is arranged, characterized in that the axis (07) of the roller (01) is at least partially designed as a bar spring (07).

21. Roller according to claim 1, 2, 3, 5 or 20, characterized in that the axis (07) and the roller body (02) is non-rotatably connected.

22. Roller according to claim 1, 2, 3, 5 or 20, characterized in that the roller body (02) prints relative to the axis (07).

23. Roller according to claim 1, 2, 3 or 20, characterized in that the spring element (08) has a flat characteristic curve.

24. Roller according to claim 1, 2, 3 or 20, characterized in that the force generated with the spring element is largely independent of the deflection.

25. Roller according to claim 1, 2, 3 or 20, characterized in that the roller is designed as an ink roller.