EP0783408B1 - Flexographic press with variable printing length - Google Patents

Abstract

PCT No. PCT/EP96/01452 Sec. 371 Date Dec. 18, 1996 Sec. 102(e) Date Dec. 18, 1996 PCT Filed Apr. 3, 1996 PCT Pub. No. WO96/38304 PCT Pub. Date Dec. 5, 1996A flexographic printing press with one or several color printing units (12), which are disposed at the periphery of a common back pressure cylinder (10) and, in each case, have an impression cylinder (14; 14') and an applicator roll (16) and the impression cylinder of which can be driven independently of the back pressure cylinder, characterized in that each applicator roll (16) can be driven over a gear assembly (32, 40; 32') with a fixed transmission ratio by a central wheel (24) fixed on the shaft (22) of the back pressure cylinder (10).

Description

The invention relates to a flexographic printing machine according to the preamble of Claim 1.

Flexographic printing presses usually have several inking units Scope of a common impression cylinder are arranged and each have a printing cylinder and an application roller. The application roller is used to ink the clichés on the printing cylinder. Typically has the applicator roller on its surface for this purpose uniform well grid, the wells for example with the help of a Chamber knife can be filled with printing ink. The application roller with the ink-filled cup rolls on the circumference of the printing cylinder and passes the color on the raised, printing parts of the clichés. It is it is important that the application roller and the impression cylinder have exactly the same peripheral speed own so that the color when applied to the printing cylinder is not blurred. This is usually achieved in that on the shaft of the applicator roller sits an applicator roller gear with a combs the pressure cylinder gear sitting on the shaft of the pressure cylinder, where the pitch circle diameter of the applicator roller gear is equal to the outer diameter the application roller and the pitch circle diameter of the pressure cylinder gear is equal to the outside diameter of the impression cylinder.

Most of the printing material wraps around the impression cylinder of its circumference, so that between the impression cylinder and the printing material practically no slip occurs and thus the web speed of the substrate equal to the peripheral speed of the impression cylinder is. Ideally, the peripheral speed of the impression cylinder is correct and thus also the web speed of the substrate with the Circumferential speed of the printing cylinder match, so that the print image is transferred cleanly to the printing material.

The drive is used in numerous conventional flexographic printing machines of the inking units via a seated on the shaft of the impression cylinder Central wheel, that with the pressure cylinder gears of all inking units combs and its pitch circle radius is equal to the outer radius of the impression cylinder (plus the thickness of the substrate), so that any slip between the printing cylinder and the substrate is avoided.

Since the transmission ratio between the impression cylinder and the impression cylinder can only assume discrete values corresponding to the number of teeth ratio between the impression cylinder gear and the central gear, in this case only discrete values can be selected for the circumference of the impression cylinder, namely integer multiples of U / Z, where U the circumference of the impression cylinder and Z is the number of teeth on the central wheel. The value Zd = U / Z is then the number of teeth on the pressure cylinder gear. The circumference of the printing cylinder determines the so-called printing length, ie the length of the repetitive printing images produced by rolling the printing cylinder onto the printing material in the longitudinal direction of the printing material.

If the substrate is continuously fed to a downstream processing station, For example, a punch that continues to register with the printed image should work, the print length must be exactly the same as the working length match the downstream processing station.

In many practical applications, the working length is now the downstream one Machine specified by the requirements for the product. For example, it is often desirable to help out of the substrate a punch sheets are punched out with a predetermined length, the each carry a single printed image in register. In this case it should consequently the print length can be adapted to the desired sheet length. Here it often proves problematic that the print length is only in discrete Steps can be varied.

So far, the price has been helped by targeting a certain one Slip between the impression cylinder and the substrate on the impression cylinder brings about, while the applicator roller still slip-free rolls on the impression cylinder. The peripheral speed of the impression cylinder is then slightly different from the peripheral speed of the impression cylinder, and the image is checked as it is transferred to the substrate blurred so that the actual print length varies from the circumference of the Printing cylinder around the slip factor S differs by the ratio the peripheral speeds of the impression cylinder and impression cylinder given is. The rough setting of the print length is then carried out by suitable choice of the number of teeth of the pressure cylinder gear and the circumference of the printing cylinder, and the fine adjustment of the printing length takes place via the Slip factor S.

With this procedure, of course, the speed of the printing cylinder be infinitely variable relative to the speed of the impression cylinder. In EP 0 459 098 A1 and DE 33 36 792 C2 becomes a flexographic printing machine for this purpose described in which a special drive is provided for the inking units be, which allows the speed of the printing cylinder with respect to to vary the speed of the impression cylinder. In this known flexographic printing machine the shaft of the impression cylinder carries two identical designs Central wheels. One of these central wheels sits firmly on the shaft of the impression cylinder and serves to drive the impression cylinder while the second central wheel on the shaft of the impression cylinder is rotatable and serves to drive the pressure cylinder gears. The two central wheels are coupled with each other by a differential gear, through which by a suitable auxiliary drive an additional speed is fed. With the help of this Auxiliary drive can then be the speed of the pressure cylinder independently regulate the speed of the impression cylinder.

The object of the invention is to provide a flexographic printing machine in which the print length is infinitely variable without slippage between the printing cylinders and printing material occurs.

This object is achieved with those specified in claim 1 Features resolved.

According to the invention, in the case of a flexographic printing press, the one mentioned at the outset Type of each application roller via a gear transmission with a fixed gear ratio through a seated on the shaft of the impression cylinder Central wheel can be driven. The speed of the pressure cylinder is therefore not only of the speed of the impression cylinder, but also from the speed of the Application rollers independently, and by the fixed gear ratio between the central wheel and the application rollers ensures that the peripheral speed of the application rollers always with that of the impression cylinder or the printing substrate matches. The choice of print length takes place according to the invention via a suitable choice of the diameter the impression cylinder. In general, therefore, the circumference of the impression cylinder be a non-integer multiple of U / Z. The separate drive for the pressure cylinder is regulated so that the peripheral speed of the Printing cylinder with the peripheral speed of the impression cylinder and consequently also corresponds to the peripheral speed of the application roller. It therefore does not occur between the impression cylinder and the substrate there is still a slip between the impression cylinder and the application roller, and the determination of the print length is made solely on the scope of the Printing cylinder. This has the advantage that with each of the continuously selectable Print lengths get an indelible and thus clean print image becomes.

Advantageous further developments and refinements of the invention result itself from the subclaims.

In a preferred embodiment, the pressure cylinders are driven via a second one, rotatably seated on the shaft of the impression cylinder Central wheel, that with the pressure cylinder gears of all inking units combs. The gear drives for driving the application rollers are then preferably each formed by an intermediate gear on the freewheel the shaft of the impression cylinder sits and on the one hand with the on the shaft of the Counter pressure cylinder fixed central wheel and on the other hand with the application roller gear combs. This intermediate gear preferably has the same Pitch circle and the same number of teeth as the pressure cylinder gear. Hereby becomes a particularly simple and compact structure of the entire drive system and rational production of the various gear elements enables. A change in the printing length can be done in this embodiment accomplish in a particularly rational manner by simply the impression cylinders together with the respective impression cylinder gear and idler gear can be replaced. Because the above Gears sit on the shaft of the impression cylinder, they form together with the printing cylinder is a unit that is easy to change when changing the printing cylinder can handle.

If a change in the printing length of the printing cylinder against such exchanged with a different scope and consequently also with a different diameter the center distances between them inevitably change the impression cylinder and the impression cylinder on the one hand and between the impression cylinder and the application roller on the other hand. So even with larger ones Changes in the center distance of the gear mesh between the different Tooth edges are preserved, the pressure cylinder gear and the intermediate gear is dimensioned so that its pitch circle diameter comes as close as possible to the diameter of the impression cylinder. With stepless In general, the choice of print length will still have certain diameter differences remain. However, these can be replaced by a larger one or smaller foot play of the meshing gears balanced will.

According to an advantageous development of the invention, the compensation takes place the center distances by a corresponding profile shift in the Printing cylinder gear and the intermediate gear. By this measure can ensure a perfect gear meshing, and with a predetermined Number of teeth of the pressure cylinder gear and the intermediate gear can be a relatively large range of diameters of the printing cylinder cover. Since the pressure cylinder gear and the intermediate gear in general The profile shift can remain on the shaft of the associated printing cylinder each specifically to the diameter of the printing cylinder in question be adjusted.

According to a preferred embodiment of the invention, the two gears sitting on the shaft of the impression cylinder, one of which the impression cylinder and the application rollers and the other the impression cylinder drives, each driven directly by an associated electric motor, and the speed of at least one of these electric motors becomes like this regulated that the desired speed ratio between the impression cylinder and the printing cylinders is manufactured. This will build up the transmission unit further simplified since the two central wheels are not need to be coupled together by a differential gear. This Construction thus enables a more compact construction of the gear unit, a reduction in weight and a reduction in moment of inertia of the masses to be driven, which in turn means the energy losses, reduces wear and noise. In addition, the two central wheels and the associated gear trains independently drive each other at any desired speed. If, for example the inking units have been brought into the ineffective position and only the impression cylinder is to be driven, so only needs the drive for the impression cylinders to be switched off without any more Clutches must be operated. The application rollers run in not with this case because the idler gears are in the inoperative position of the inking units do not comb with the associated central wheel.

The latter measure, i.e. the independent direct drive of the two Central wheels through associated electric motors, without coupling the two Central wheels through a differential gear is also on a flexographic press according to the preamble of claim 1 is advantageous in which the characteristic features of this claim are not realized.

A preferred embodiment of the invention is described below the drawing explained in more detail.

Fig. 1

eine schematische Darstellung des Antriebssystems einer Flexodruckmaschine; und

Fig. 2

eine schematische Darstellung der wesentlichen Teile aus Figur 1 für den Fall, daß die Flexodruckmaschine für eine andere Drucklänge als in Figur 1 eingerichtet ist.

Show it:

Fig. 1

a schematic representation of the drive system of a flexographic printing press; and

Fig. 2

a schematic representation of the essential parts of Figure 1 for the case that the flexographic printing machine is set up for a different printing length than in Figure 1.

Several inking units 12 are arranged on the circumference of an impression cylinder 10, only one of which is shown in FIG. 1. The inking unit 12 has an impression cylinder 14 and an application roller 16. The printing cylinder has a cylindrical core 18, on the circumference of which a pressure plate 20 is stretched, the outer surface of which the desired print image appropriate cliché forms and the effective diameter as well as the effective The circumference of the printing cylinder is determined.

The impression cylinder 10, the impression cylinder 14 and the application roller 16 stand together in their operating position with their outer surfaces in contact and rotate at their same circumferential speeds respective axes. The application roller 16 provided with a cell grid but runs with its peripheral surface through the paint chamber of a not shown Chamber doctor and then gives the ink picked up in the process Course of their rotation from the pressure cylinder 14. From the impression cylinder 14, the printing ink in the printing parts on the (not shown) Transfer printing material that wraps around the impression cylinder 10.

A first central wheel sits on the shaft 22 of the impression cylinder 10 in a rotationally fixed manner 24, which is driven by an electric motor 26. In the shown Example includes the drive train between the central wheel 24 and the electric motor 26 a gearwheel seated on the output shaft of the electric motor 28 and another gear 30 with the gear 28 and the central gear 24 combs. Optionally, the gear 28 on the circumference of the Central wheel 24 may be arranged so that it meshes directly with the central wheel. In this case, the gear 30 can be omitted and the electric motor 26 driven in the opposite direction.

The central gear 24 continues to mesh with a free-running idler gear 32, which is rotatable by means of a bearing 34 on the shaft 36 of the printing cylinder 14 is arranged. The intermediate gear 32 in turn meshes with one Applicator roller gear rotatably seated on the shaft 38 of the applicator roller 16 40.

The pitch circle diameter of the central wheel 24 coincides with the outer diameter of the impression cylinder 10. There is also agreement between the pitch circle diameter of the idler gear 32 and the outer diameter of the printing cylinder 14 and between the The pitch circle diameter of the applicator roller gear 40 and the diameter the application roller. By the electric motor 26, the impression cylinder 10 and the applicator roller 16 driven, the gear ratio by the ratio of the number of teeth of the applicator roller gear 40 and the central wheel 24 is fixed. The ratio of the diameter and Circumferences of the application roller 16 and the impression cylinder 10 corresponds this transmission ratio, so that the applicator roller 16 has the same peripheral speed like the impression cylinder 10.

There is a separate one for driving the printing cylinders 14 of all inking units 12 Electric motor 42 provided, the output gear 44 with a second central gear 46 which rotates with the help of a bearing 48 on the Shaft 22 of the impression cylinder 10 is mounted. The second central wheel 46 in turn meshes with a pressure cylinder gear 50, which rotatably on the Shaft 36 of the impression cylinder sits.

In the example shown, the ring gears of the two central wheels 24 and 46 identical. The ring gear of the pressure cylinder gear 50 is with the Gear ring of the intermediate gear 32 identical. In the shown in Figure 1 The situation therefore also corresponds to the pitch circle diameter of the pressure cylinder gear 50 the diameter of the printing cylinder 14. The transmission ratio between the pressure cylinder 14 and the second central wheel 46 is the ratio between the number of teeth on the pressure cylinder gear 50 and the second central gear 46, and the ratio between the circumference of the impression cylinder 14 and the circumference of the impression cylinder 10 corresponds to this gear ratio. Hence the Circumferential speed of the printing cylinder 14 with the circumferential speeds the application roller 16 and the impression cylinder 10 are identical, if the second central wheel 46 is driven at the same speed as the first central wheel 24. For this purpose, the two electric motors 42 and 26 synchronized by an electronic control system 52.

Under these conditions, however, the circumference of the impression cylinder can 14 certain print lengths only take discrete values because of the circumferential ratio of the impression cylinder and impression cylinder always the quotient must correspond to two integers, namely the ratio of Number of teeth of the pressure cylinder gear 50 and the second central wheel 46.

If a print length different from these discrete values is required according to the invention, the printing cylinder 14 is replaced by a printing cylinder 14 'replaced with another outer diameter, as shown in Figure 2. In the example there, the core 18 of the printing cylinder remains unchanged, and only a pressure plate 20 with a larger thickness is clamped. However, the thickness of the printing plates can optionally be left unchanged be and the core 18 of the impression cylinder can be varied.

When the printing cylinder 14 'is replaced, the ones on its shaft are also removed 36 seated gears with replaced. In Figure 2 is therefore instead of Intermediate gear 32 an intermediate gear 32 'with a larger tip diameter provided, and accordingly the pressure cylinder gear 50 from Figure 1 in Figure 2 by a pressure cylinder gear 50 'with a larger Tip circle diameter replaced.

As an example, assume that the print length difference between the situations shown in Figures 1 and 2 is smaller than the distance between the discrete values, which the possible number of teeth of the Intermediate gear 32 and the pressure cylinder gear 50 correspond. The Intermediate gear 32 'in FIG. 2 therefore has the same number of teeth as the intermediate gear 32 in Figure 1, and the same applies to the impression cylinder gears 50 and 50 '. Thus, since the gear ratio in Figure 2 is the same is as in Figure 1, the pressure cylinder 14 'with an excessive peripheral speed run when the central wheels 24 and 46 with the same Speed would be driven. With the help of the control system 52 is therefore in the case shown in Figure 2, the speed ratio between the electric motors 26 and 42 regulated so that the peripheral speed of the printing cylinder 14 'with the peripheral speeds of the application roller 16 and of the impression cylinder 10 is held in agreement. To this The same is true for the printing length chosen in FIG. 2, which is not a discrete one Tooth tooth ratio corresponds to a slip-free rolling of the pressure cylinder 14 both on the application roller 16 and on the impression cylinder 10 guaranteed.

Because of the larger diameter of the printing cylinder 14 'is in FIG Distance between the shafts 36 and 22 and the distance between the Shafts 36 and 38 each slightly larger than in Figure 1. To ensure nevertheless that the intermediate gear 32 'and the pressure cylinder gear 50' properly Comb with the assigned gears is with the intermediate gear 32 'and the pressure cylinder gear 50' a (positive) profile shift intended. Accordingly, these tooth edges have the same number of teeth the tip circle diameter enlarged so that a sufficiently deep Gear meshing with the opposite gears guaranteed and the evolutionary profiles are changed in a known manner such that the tooth flanks roll perfectly against each other, although the center distances of the meshing gears here are larger than that Sum of their pitch circle radii.

If an even larger print length is desired, at which the circumferential ratio between impression cylinder 14 'and impression cylinder 10 closer to the next higher tooth tooth ratio, so the intermediate gear 32 'and the pressure cylinder gear 50' replaced by gears, each have one more tooth. Provided that by the diameter of the printing cylinder certain center distance is smaller than the sum of Pitch circle radii, is used with a negative profile shift, so that the gears mesh perfectly with sufficient foot play.

Claims (8)

1. Flexographic press having one or more inking units (12) which are arranged on the circumference of a common counter-impression cylinder (10) and each have an impression cylinder (14; 14') and an applicator roll (16) and whose impression cylinder is drivable independently of the counter-impression cylinder, characterised in that each applicator roll (16) is simultaneously drivable, via a toothed gearing (32, 40; 32') having a fixed transmission ratio, by a planet wheel (24) arranged securely on the shaft (22) of the counter-impression cylinder (10).
2. Flexographic press according to claim 1, characterised in that the diameter of the rolling circle of the planet wheel (24) is equal to the outside diameter of the counter-impression cylinder (10), in that an applicator roll toothed wheel (40) is arranged in a rotationally secure manner on the shaft (38) of the applicator roll (16) and its rolling circle diameter is equal to the outside diameter of the applicator roll (16), and in that the planet wheel (24) and the applicator roll toothed wheel (40) are coupled to one another by an intermediate toothed wheel (32; 32').
3. Flexographic press according to claim 2, characterised in that the intermediate toothed wheel (32; 32') is arranged in a freewheeling manner on the shaft (36) of the impression cylinder (14; 14').
4. Flexographic press according to claim 3, characterised in that the impression cylinder (14; 14') and the intermediate toothed wheel (32; 32') arranged on its shaft (36) each form an exchangeable unit.
5. Flexographic press according to any one of the preceding claims, characterised in that the circumference of the impression cylinder (14') is different from each integral multiple of U/Z, wherein U is the circumference of the counter-impression cylinder (10) and Z is the number of teeth of the planet wheel (24).
6. Flexographic press according to claims 4 and 5, characterised in that the intermediate toothed wheels (32; 32') of the various units each have the same number of teeth, but different profile offsets according to the different axial distances between the impression cylinder (14) and the counter-impression cylinder (10), and between the impression cylinder (14) and the applicator roll (16).
7. Flexographic press according to any one of the preceding claims, having a second planet wheel (46) which is rotatably arranged on the shaft (22) of the counter-impression cylinder (10) and which meshes with impression cylinder toothed wheels (50) arranged in a rotationally secure manner on the shafts (36) of the impression cylinders (14) of each inking unit (12), characterised in that each of the two planet wheels (24, 46) is drivable by its own electric motor (26, 42) and in that the speeds of the electric motors are regulatable to a preset speed ratio by an electronic regulating system (52).
8. Flexographic press according to claim 7, characterised in that the second planet wheel (46) has the same toothing as the first planet wheel (24) and in that the impression cylinder toothed wheel (50; 50') has the same toothing as the intermediate toothed wheel (32; 32') arranged on the same shaft (36).

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