DE19649324C2 - Revolving body of rotation - Google Patents

Description

The invention relates to a circumferentially changeable Rotational body, e.g. B. a roller for a Rotary printing machine according to the preamble of Claim 1.

DE 42 23 900 C2 is a pull roller, especially for changing the web tension in Rotary printing machines known. With this roller is the circumferential length due to the arrangement of one on the Roller jacket arranged pressure medium hose adjustable.

The invention has for its object a to create circumferentially variable cylinders.

This object is achieved by the features of the characterizing part of claim 1 solved.

The advantages that can be achieved with the invention exist especially in that the circumferentially changeable Lateral surface of the cylinder both flat and is designed to be unyielding, so that no bleeding a guided material web takes place.

Use of the cylinder can thus, for. B. as  Blanket cylinders in printing units from Rotary printing presses take place. It can be on one previously used calibrated paper beam to be dispensed with.

Furthermore, the cylinder can Web-fed rotary printing machines with advantage as Deflection roller are used, the diameter of which changeable thickness of the paper web strand is adaptable. Finally, the cylinder can also be shortened as a belt roller in flat belt drives find their belt pulleys for an input or output a variable diameter to change the speed should have.

An embodiment of the invention is in the Drawing shown and will be described in more detail below described.

Show it

Figure 1 is a schematic representation of a longitudinal section through a circumferentially variable cylinder.

Fig. 2 shows a cross section II-II of FIG. 1, but designed as a full section.

A circumferentially variable rotating body, e.g. B. a cylinder 1 has two side windows 2 ; 3 , which z. B. are connected by a shaft 4 or a cylindrical threaded element. The right side window 3 has a hub 6 on its side facing the left side window 2 , on which, for. B. is mounted by means of slide bearing 7, a gear 8 . Between the side windows 2 ; 3 there is a circumferentially changeable cylinder-like support element 11 acting in the radial direction A to the longitudinal axis 9 of the cylinder 1 . Coaxial to the support element 11 is a cylindrical helical spring 12 , the abutment end 13 of which is mounted in the left side window 2 . A force application point end 14 of the helical spring 12 is connected to the gear 8 rotatable on the hub 6 . The gear 8 meshes with a drive gear 16 of a drive 17 , for. B. a side window fixed actuator. Thus, the force application point end 14 of the coil spring 12 is provided with a device 6 , 7 , 8 , 16 , 17 for the rotational movement of the windings 15 about its longitudinal axis 9 in order to selectively change the diameter of the coil spring 12 . A drive 17 can also be designed as a manual drive.

A mandrel diameter b of the helical spring 12 lies against an outer diameter c of the support element 11 . The spring wire of the turns 15 has z. B. a rectangular cross section 18 , so that straight surfaces extend in the axis-parallel direction. This results in a smooth outer lateral surface of the helical spring 12 .

A distance d located between the resilient windings 15 of the helical spring 12 is smaller, is z. B. only a tenth to a fifth, compared to the width of a turn 15 . The resilient windings 15 of the helical spring 12 each have a plastic coating on their outer circumference 19 . This plastic coating, e.g. B. rubber can be vulcanized onto the circumference 19 of the coil spring 12 .

The cylindrical support element 11 consists of a frustoconical rotary element 21 , which has a threaded bore 22 over its axial length. The threaded bore 22 is with the two side windows 2 ; 3 connecting shaft 4 , or threaded element in a positive connection. A rotation of the rotary element 21 on the threaded element and thus moving the same in the axial direction F can, for. B. done in that the rotary element 21 has a gear 24 on its base 23 facing the first side window 2 . The gear 24 of the rotary element 21 meshes with a drive gear 26 of a side window fixed drive 27 , for. B. an actuator.

Coaxially on the lateral surface 28 of the frustoconical rotary element 21 are a number n, z. B. four, movable in the radial direction A, in the circumferential direction from each other by a distance i, z. B. 3 mm separate frustoconical segments 31 to 34 are arranged. The segments 31 to 34 are arranged on the frustoconical rotary element 21 in such a way that the jointly formed support element 11 forms a cylinder 1 which can be changed in circumference.

Each segment 31 to 34 has on its outer side of the circumference facing the coil spring 12 a part of z. B. two annular grooves 36 ; 37 , in each of which an annular spring 38 ; 39 is performed.

Each segment 31 to 34 expediently has on its side facing the hub 6 a groove 41 which extends in the radial direction of movement A and into which a hub 42 which engages with the hub engages. As a result, the segments 31 to 34 are arranged on the rotary element 21 in a manner fixed against relative rotation.

The operation of the circumferentially variable roller 1 is as follows. If the circumferential length of the cylinder 1 is to be reduced, the drive 27 for changing the diameter or the circumference of the support element 11 is first actuated. The rotary element 21 moves in the direction F to the left, ie in the direction of the side window 2 by a predetermined amount. This can e.g. B. can be determined by a not shown on the drive 27 rotational angle position encoder. The four segments 31 to 34 are by means of the ring springs 38 ; 39 pressed in the direction of the lateral surface 28 of the rotary element 21 , so that the outer diameter c of the cylindrical support element 11 is reduced.

Now the end of the force point 14 of the coil spring 12 is rotated by means of the drive 17 , that is, the coil spring 12 is tensioned until the mandrel diameter b of the coil spring 12 has decreased to the outside diameter c of the support element 11 . Thus, the same diameter b; c reached ( Fig. 1).

If the diameter of the cylinder 1 is to be increased, the procedure is reversed.

According to another embodiment variant of a drive for the frustoconical rotary element 21 , instead of the drive 27 , 26 , 24, a number, for. B. four, side disc-mounted screws 43 may be provided, which are each in operative connection with a threaded bore 44 located in the rotary element 21 (shown in dashed lines). A threadless shaft can then be used instead of the threaded element 4 .

The cylinder 1 can be centered on both side windows 2 ; 3 each have a shaft journal 46 ; 47 have.

According to a further embodiment variant, the outer circumference 19 of the helical spring 12 can be provided with a rubber blanket. Thus, the cylinder 1 can also be used as a circumferentially variable blanket cylinder.

Reference list

1

cylinder

2nd

Side window, left

3rd

Side window, right

4th

Wave (

2nd

;

3rd

)

5

-

6

Hub (

8th

)

7

Bearings (

8th

)

8th

gear

9

Longitudinal axis (

1

)

10th

-

11

Support element, cylindrical (

1

)

12th

Coil spring, cylindrical

13

Abutment end (

12th

)

14

Force point end (

12th

)

15

Swirl (

12th

)

16

Drive gear (

17th

)

17th

drive

18th

Cross-section (

15

)

19th

Outer circumference (

12th

)

20th

-

21

Rotating element, frusto-conical (

11

)

22

Tapped hole (

21

)

23

Floor space (

21

)

24th

gear

25th

-

26

Drive gear (

27

)

27

drive

28

Lateral surface (

21

)

29

-

30th

-

31

Segment (

11

)

32

Segment (

11

)

33

Segment (

11

)

34

Segment (

11

)

35

-

36

Groove (

31

to

34

)

37

Groove (

31

to

34

)

38

Ring spring (

36

)

39

Ring spring (

37

)

40

-

41

Groove (

31

to

34

)

42

Cam (

6

)

43

Screw (

31

to

34

)

44

Tapped hole

45

-

46

Shaft journal (

1

)

47

Shaft journal (

1

)
Aradial direction of movement
Faxial direction of movement (

21

)
b mandrel diameter (

12th

)
c outer diameter (

11

)
ddistance (

18th

)
eBreadth (

18th

)
iDistance (

31

,

32

;

32

,

33

)
nNumber (

31

to

34

)

Claims (14)

1. A circumferentially variable cylinder ( 1 ) for rotary printing machines, characterized in that a circumferentially adjustable cylinder-like support element ( 11 ) is arranged on a shaft ( 4 ), onto which a cylindrical coil spring ( 12 ) is threaded that an abutment end ( 13 ) of the coil spring ( 12 ) is directly or indirectly connected to the shaft ( 4 ) in that a force application point end ( 14 ) of the helical spring ( 12 ) is provided with a device for the rotational movement of the windings ( 15 ) about its longitudinal axis ( 9 ) to the diameter (b ) to change the coil spring ( 12 ) optionally. 2. Rotary body according to claim 1, characterized in that the mandrel diameter (b) of the helical spring ( 12 ) abuts the outer diameter (c) of the support element ( 11 ). 3. Rotary body according to claims 1 and 2, characterized in that the spring wire has a rectangular cross section ( 18 ). 4. Rotary body according to claims 1 to 3, characterized in that the distance (d) between the resilient turns ( 15 ) is smaller than the width (e) of the spring wire. 5. Rotary body according to claims 1 to 4, characterized in that the resilient windings ( 15 ) each have a plastic coating on their outer circumference ( 19 ). 6. Rotary body according to claims 1 to 5, characterized in that the device for the rotational movement of the windings ( 15 ) about its longitudinal axis ( 9 ) consists of a on a side plate ( 3 ) of the roller hub ( 6 ), on which a Gear ( 8 ) is rotatably mounted, which meshes with a drive gear ( 16 ) of a side window fixed drive ( 17 ). 7. Rotary body according to claims 1 to 6, characterized in that the cylindrical support element ( 11 ) consists of a frustoconical in the axial direction (F) movable rotary element ( 21 ) which coaxially on its lateral surface ( 28 ) a number (n) in radial Direction (A) movable, frustoconical segments ( 31 to 34 ) separated from each other in the circumferential direction carries that the rotary element ( 21 ) and the segments ( 31 to 34 ) together form the circumferentially adjustable cylindrical support element ( 11 ). 8. Rotary body according to claims 1 to 7, characterized in that the frustoconical rotary element ( 21 ) over its axial length has a threaded bore ( 22 ) and on its base ( 23 ) has a gear ( 24 ). 9. Rotary body according to claim 8, characterized in that the frustoconical rotary element ( 27 ) on a two side plates ( 2 ; 3 ) firmly connecting threaded element ( 4 ) is arranged. 10. Rotary body according to claims 8 and 9, characterized in that the gear ( 24 ) of the frustoconical rotary element ( 21 ) meshes with a drive gear ( 26 ) of a drive ( 27 ). 11. Rotary body according to claims 1 to 10, characterized in that each segment ( 31 to 34 ) has at least part of an annular groove ( 36 ; 37 ) on its circumference, that in the groove ( 36 ; 37 ) an annular spring ( 38 ; 39 ) is performed. 12. Rotary body according to claims 1 to 7, characterized in that the frustoconical rotary element ( 21 ) by means of a linear drive ( 43 ) located in the right side window ( 3 ) is arranged displaceably in the axial direction (F). 13. Rotary body according to claim 12, characterized in that the rotary element ( 21 ) on a two side windows ( 2 ; 3 ) fixedly connecting threadless shaft is arranged. 14. Rotary body according to claims 1 to 13, characterized in that the circumferentially variable cylinder ( 1 ) is used as a roller, cylinder, drum or belt roller.