EP0730957B1 - Device for adjusting the oscillating assembly - Google Patents

Abstract

The drive cogwheel (2) is connected to the drive of the printer. The drive is transmitted from a drive gearing (5) on a shaft (3) carrying the drive cogwheel via one or more planetary wheels (12) movable on a circle round the shaft, to a driven element (7). The planetary wheels move between the drive gearing and an internally cogged hollow wheel (14) adjustably fixed in its rotary position by the adjustment.

Description

The improvement relates to a device for adjusting the trituration insert in inking units of printing machines according to the preamble of the claim 1. A device of this type is known from US-A-2700335 known.

In inking units of printing machines there are distribution rollers for the distribution of transporting printing ink used, which is an axially reciprocating Carry out movement. For special requirements when setting the Color transport, it is desirable the location of the reciprocating movement in relation to the general rotational movement of the printing press change.

In DE 38 14 927 C1 an intermediate gear in printing machines for Adjusting the phase position of the axial rubbing movement of distribution rollers described. It serves the back and forth movement of the Friction rollers in an inking unit of a printing press in relation to a general To make rotational movement adjustable in a printing unit. To is between the drive from the printing press and the crank-shaped Output to the friction rollers used the intermediate gear mentioned. It has an eccentrically attached crank pin on a drive shaft on who carries a transmission element. On the transmission element is on the one hand a gear is provided and on the other hand a disc is attached, which carries three cam rollers. The cam rollers engage in corresponding openings a control disc, which is mounted on the drive shaft. The openings have a around the diameter of the cam rollers Measure of the eccentricity of the crank pin enlarged diameter. The Gear on the transmission element engages in an internal toothing An output element, which is mounted in the housing of the intermediate gear. On this output element is a drive lever for the back and forth Movement of the friction rollers slidably coupled. The coupling takes place in a known way.

The control disk is in turn provided with an external toothing in which an adjusting gear engages, which can be held or adjusted by a chain drive.
The drive movement takes place through eccentric rotation of the transmission element. The gearwheel of the transmission element rolls in the internal toothing of the output element and drives it with the appropriate reduction. Apart from the eccentric movement relative to the housing, the transmission element remains at rest, the cam rollers rotating in the openings of the control disk. By adjusting the control disc with the adjusting gear, the output movement can be adjusted relative to the drive.

The intermediate gear is quite compact, but it is relatively complicated and expensive to manufacture.

From US-PS 2700335 a device for driving friction rollers is known. The rubbing movement is generated by means of a planetary gear, a fixed one Stroke adjustment is provided. The relative position of the drive and the rubbing movement can be changed at certain points by locking a spring pin.

From US-PS 3077159 is a device for driving friction rollers with variable Hub known. One over a hollow gear with internal and external teeth is the movement of a crank to drive the friction rollers relative to the machine drive changeable so that the stroke of the friction rollers from zero to a maximum can be changed.

The object of the improvement is therefore to make the transmission cheaper to manufacture and to make it even more compact.

The solution to the problem results from the characterizing part of claim 1. Standard components can advantageously be used here lower the cost of manufacture. In addition, the transmission is only in essentially arranged in two levels. This is the level of reduction and the setting in which the actual planetary gear lies. In the other level are the output with the output element and the friction drive arranged. The entire gear arrangement is thereby again designed much more compact.

An exemplary embodiment of a transmission according to the invention is as follows represented by drawings.

Figur 1

einen Schnitt in Achsrichtung und

Figur 2

einen Schnitt in der Ebene der Planetenräder.

It shows

Figure 1

a section in the axial direction and

Figure 2

a section in the plane of the planet gears.

In Figure 1 is a section through the device in a plane through a central axis shown. The device is on the machine frame 1 of a printing press appropriate. It initially contains a drive gear 2 with a machine-synchronized part of the drive of the printing press connected is. The drive gear 2 is mounted on a shaft 3. The shaft 3 is stored on one side by means of a bearing 4 in the machine frame 1. On the opposite side of the shaft 3 are side by side in the axial direction a drive toothing 5 and a needle bearing 6 are provided. The needle bearing 6 engages in an output element 7. The output element In principle, 7 is constructed as a hollow cylindrical body, on the inside formed according to the needle bearing 6 on the end of the shaft 3 is. On the output element 7 there is also a clamping device 8 intended. At the clamping device 8 is a collar sleeve 10 Drive lever 9 swiveling e.g. attached via a roller bearing. The drive lever 9 leads to deflection gears for the initiation of a reciprocating Movement of friction rollers in an inking unit of the printing press.

The clamping device 8 permits the coupling of the drive lever 9 different positions with respect to the axis of rotation of the output element 7. This results in 7 crank movements when the output element rotates with different radius or stroke. The Clamping device is designed conventionally and for example as a T-piece in a corresponding groove. The T-piece can be anywhere the groove by means of a screw in the axis of movement of the drive lever 9 be clamped.

Furthermore, the shaft 3 is at least in the area of the drive toothing 5 assigned three planet gears 12. The planet gears 12 each sit on one Bearing pin 13, which on the opposite of the clamping device 8 Are arranged on the output element 7 side. The planet gears 12 Finally, comb the outside with the internal toothing 15 of a ring gear 14. The ring gear 14 is annular and has one on the outside Set gear ring 16. Furthermore, the ring gear 14 has one on one side Guide ring 22 which extends laterally of the gear ring 16.

The gear arrangement is centered by means of a bearing 11 the output element 7 is guided in an upper housing part 18. The Upper housing part 18 is by means of a lower housing part 17 with the machine frame 1 connected. The ring gear 14 is rotatable, but entirely without bearings On the one hand, the guide ring 22 of the ring gear 14 is rotatably seated in a centering collar 23, which is an annular backward rotation to the side of Bearing seat extends on the upper housing part 18. On the other hand there is the ring gear 14 with the side facing away from the guide ring 22 on a guide collar 25 on the lower housing part 17. The whole arrangement is finally made using of the lower housing part 17 attached to the machine frame 1. The lower part of the housing 17 can be centered on the bearing 4 to the center of the shaft 3.

An actuating shaft 20 is rotatably mounted in the upper housing part 18. she wears a Setting gear 19, which meshes with the toothing 16 of the ring gear 14. On the other end of the control shaft 20, a sprocket 21 is arranged with which is connected to a chain drive, not shown.

Upper housing part 18 and lower housing part 17 are mutually connected via a collar 24 aligned, connected with several retaining screws and attached to the machine frame 1 via the lower housing part 17.

In Figure 2, the device is a section in the plane of the planet gears 12th shown by the representation of Figure 1. The concentric one is clearly visible Arrangement of shaft 3, planet gears 12 and ring gear 14. Likewise on the top of the ring gear 14, the adjusting gear 19 in engagement with the Set teeth 16 shown. The sprocket 21 is concentric with it Attachment is cut at three points of the upper housing part 18. The Lower housing part 17 and the attachment points to the machine frame 1 are partially visible.

The function is as follows: The device represents a planetary gear. The output element 7 represents the web of the epicyclic gear. The drive movement takes place via the drive gear 2 from the printing press forth. The movement is described below by the drive toothing on the Shaft 3 on the planet 12 and from this via the bearing pin 13, with a corresponding Reduction of 1: 3 or 1: 4, for example, on the bridge or the output element 7 transmitted. The ring gear 14 is in each case held on the adjusting gear 19. By turning the ring gear 14 with the adjusting gear 19, starting from the sprocket 21 and the adjusting shaft 20, is a change in the relative position of the output element 7 and the drive gear 2 possible. The ring gear rotates in its seat between the upper part of the housing 18 and lower housing part 17. The output element 7 rotates via the needle bearing 6 on the shaft 3. The adjustment can be remotely controlled respectively.

Reference list

1

Machine frame

2nd

Drive gear

3rd

wave

4th

camp

5

Drive teeth

6

Needle bearing

7

Output element

8th

Clamping device

9

Drive lever

10th

Collar sleeve

11

camp

12th

Planet gear

13

Bearing bolt

14

Ring gear

15

Internal teeth

16

Gear ring

17th

Lower part of the housing

18th

Upper part of the housing

19th

Setting gear

20th

Control shaft

21

Sprocket

22

Guide ring

23

Centering collar

24th

Federation

25th

Leadership association

Claims (3)

1. Device for adjusting the relative position of the to and fro movement of oscillating rollers in inking units of printing presses with a drive gear (2) arranged on a shaft (3) which is connected with the drive of the press, with a planet gear which can be driven from the shaft (3) and is connected with a driven element (7) generating the to and fro movement of the oscillating rollers by means of planet wheels (12), wherein a central gear, which is provided in the form of a drive toothing (5) on the shaft (3) is engaged with the planet wheels (12) and connected via these with the driven element (7) as stud, and with a linking device influencing the relative position of the driven element relative to the shaft, characterised in that the linking device is constructed as a hollow gear (14) which is arranged concentrically to the shaft (3) and which meshes by means of an inner toothing (15) with the planet wheels (12) and that an adjusting device acts on the hollow gear (14), so that its rotational position is determined, in that, as adjusting device, an adjusting gear (19) driven remotely controllably is provided meshed with an adjusting toothing (16) on the outer side of the hollow gear (14), and that on the drive element (7), a drive connection slidable with reference to the rotational axis of the driven element (7) is provided to generate the oscillating movement of oscillating rollers.
2. Device according to Claim 1, characterised in that the driven element (7) is arranged rotatably in a housing (17, 18) and the end of the shaft (3) remote from the drive gear (2) is arranged rotatably in the driven element (7).
3. Device according to Claim 1 or 2, characterised in that the hollow gear (14) is arranged in an annular seat (22, 23, 24) slidingly rotatably within a housing (17, 18) concentrically to the shaft (3).

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