EP1377456A2 - Printing group pertaining to a printing machine comprising a pivotable transfer cylinder - Google Patents

Abstract

The offset printer has one or more printing station with a transfer cylinder (03,07) on either side of the paper. Each transfer cylinder has a printing cylinder (02,11) in contact with it. The printing cylinders may have thin aluminum printing plates wrapped around them, with their edges held by clamps in longitudinal grooves (4) in their cylindrical surfaces. The transfer cylinders may have blankets with their ends held in longitudinal grooves (6). The grooves in the cylinders are broken up into staggered sections. The cylinders are all the same diameter which corresponds to the length of each section of paper to be printed.

Description

description

Printing unit of a printing press with a pivotable transfer cylinder

The invention relates to a printing unit of a printing press with a pivotable transfer cylinder according to the preamble of claims 1 or 2.

A printing unit is known from DE 198 03 809 A1, the forme cylinder of which has one circumferential circumference and a plurality of printing plates in the longitudinal direction. A transfer cylinder cooperating with the forme cylinder has a double circumference and is designed in the circumferential direction with a printing blanket and in the longitudinal direction with two printing blankets which are arranged offset to one another in the circumferential direction.

JP 100 71 69 4 discloses printing group cylinders with four channels arranged next to one another and offset in the circumferential direction from one another. The printing unit cylinders have a so-called double circumference.

CH 345 906 discloses a device for a bumpless printing process, joints of four lifts arranged next to one another on transfer cylinders of double circumference and joints of four lifts arranged next to one another on a forme cylinder of double circumference being offset from one another.

A double printing unit is known from DE 198 15 294 A1, the axes of rotation of the printing unit cylinders being arranged in one plane. The cylinders have four times the width of a newspaper page (double width) and a circumference of one height of a newspaper page. The transfer cylinders have endless sleeves which can be exchanged laterally through openings in the side wall. US 41 25 073 A printing unit cylinders of simple scope are known which have a vibration damper. In the case of wider printing presses, the forme cylinder has a double circumference and two printing plates arranged one behind the other. The channels arranged next to one another in the longitudinal direction and receiving the pressure plates are additionally offset from one another in the circumferential direction.

A double printing unit is known from DE 44 15 711 A1, in order to improve the print quality, a plane perpendicular to the paper web is inclined by approximately 0 ° to 10 ° to the plane connecting the two axes of rotation of the transfer cylinders.

JP 57-131 561 discloses a double printing unit with axes of the printing unit cylinders arranged in one plane. The printing unit cylinders are arranged in phase to one another in such a way that channels for fastening the lifts to one another and in the two printing units acting together roll simultaneously.

DE 34 12 812 C1 also discloses a double printing unit, the cylinder axes being arranged in a common plane which is inclined to the plane of the web to be printed. The transfer cylinders are turned on and off along an almost rectilinear direction of movement by means of double eccentrics.

EP 08 62 999 A2 discloses a double printing unit with two transfer cylinders acting together, which are mounted in eccentric or double eccentric bushes for the purpose of turning them on and off. In another version, they are mounted in levers which are pivotally mounted eccentrically to the forme cylinder axis.

DE 44 35 986 A1 describes a device for switching a transfer cylinder on and off in a printing unit with an angle to one another Cylinders known, wherein the transfer cylinder mounted in a lever around the forme cylinder for starting is adjusted by a first actuating means via an eccentric to the forme cylinder, and then by a second actuating means acting on the lever to the impression cylinder. The lever is mounted eccentrically on the pin of the forme cylinder for adjustment purposes.

EP 07 41 013 A2 discloses a printing press with bridge-shaped printing units, the transfer cylinders mounted in levers being pivotable about the axis of rotation of the associated forme cylinder to form a walk-in space.

DE 44 02 389 A1 discloses four printing unit cylinders lying in one plane, the transfer cylinders being mounted in pivotable levers. The cylinders are switched off from one another by pivoting the forme cylinders, one of the transfer cylinders being turned off by the cooperating transfer cylinder as a result of the pivoting of the forme cylinder and as a result of gravity.

The invention has for its object to provide a printing unit of a printing press with a pivotable transfer cylinder.

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

The advantages that can be achieved with the invention consist in particular in that the measures create a printing press that is compact, low-vibration and robust, has a high production diversity, and requires a relatively low production and maintenance effort.

The minimization of the number of parts that can be moved in normal operation and during set-up, e.g. B. the waiver of the movement of all cylinders, by Frame walls, bearings, etc., ensure the robust and inexpensive construction.

With the linear arrangement of the printing unit cylinders, i. H. the arrangement of the axes of rotation of the printing unit cylinders in the print-on position essentially in one plane, the cylinders support each other. This reduces relative cylinder deflection. It is even possible to compensate the bending line (static) of the forme cylinder and the transfer cylinder with respect to one another.

Since the elevators on the cylinders are not held in channels that are continuous over the length of the cylinders, but in channels that are offset in the circumferential direction, channel blow during passage of the channel during the rolling of two interacting cylinders is considerably reduced. In an advantageous embodiment, the channels are arranged offset by 1 8 0 ° to one another in the case of two channels arranged next to one another in the longitudinal direction.

The arrangement of the printing unit cylinders and the channels is particularly advantageous in such a way that the channels of each cylinder offset from one another roll in the region of the opposite, offset channel of the cooperating cylinder. This allows the dynamic forces to be balanced. With a fixed offset angle of 1 8 0 ° and a linear arrangement of the cylinders for all production rates, i. H. Angular velocities, destructive interference, without having to vary an offset angle of the channels depending on the speed or frequency.

The arrangement of printing unit cylinders of a simple scope is particularly advantageous for printed products of smaller and / or variable page size and / or for printing shops with limited space. Compared to producing the same product on a double-dimension printing press (without collecting), no "double" plate change is required. In contrast to a double-dimension printing press in the collecting operation, it is possible to generate a page jump from two sides, and thereby creating increased flexibility in the printed product.

The construction of all printing unit cylinders with a single circumference allows a much more compact and lighter construction in comparison to printing units which have one or more cylinders with double circumference. Rubber blankets to be replaced are also smaller in the event of damage and are therefore less expensive

The use of printing blankets and printing plates enables the cylinders to be stably supported on both sides, whereby a simple, robust and inexpensive construction of the side frame receiving the printing unit cylinders is made possible.

With regard to a robust and simple construction, it is also advantageous if only the transfer cylinders have to be moved to turn the printing unit on and off. Although the forme cylinders can be mounted for the purpose of adjustment at a distance from the assigned transfer cylinder and, if necessary, the inking and, if present, dampening unit, the transfer cylinders can be turned on and off from one another and from the assigned forme cylinders advantageously only by moving the transfer cylinders.

A linear movement of the cylinders is made possible by a movement specially selected in the area of the pressure point and at the same time avoiding devices and movements of the forme cylinders are avoided. This also contributes to the robust and simple design.

In an advantageous embodiment, the transfer cylinders are arranged for this purpose in levers which are pivotally mounted eccentrically to the forme cylinder axis. Due to the special position of the pivot points and the size of the eccentric (to the axis of rotation of the forme cylinder) in connection with the selected inclination to the plane of the cylinder forming the pressure point or between the path and plane of the cylinder is quick parking of the assigned cylinders or clearing of the web possible. The operational starting and stopping takes place only by means of the transfer cylinder, and in a preferred embodiment by means of only one actuating movement.

In a possible variant, the transfer cylinders can be mounted in double eccentric bushings, which, at least in the area close to the pressure point, enables an almost linear movement that is largely perpendicular to the plane of the cylinder axes.

The effective channel width is reduced by the lifts on the transfer cylinders, which are designed as so-called metal printing blankets, whereby the excitation of vibrations is advantageously further reduced and the non-printing area on the cylinders, i. H. the "white border" on the product or paper waste is reduced.

Particularly advantageous is the design of the printing unit with cylinders of simple circumference and the arrangement in one plane, with offset, but mutually rolling channels, and with elevators designed as metal printing blankets on the transfer cylinders.

In particular for washing, changing lifts, etc., cylinders or rollers in printing units must be switched off and on again in the operating state “pressure on”, ie a pressure on position. The necessary radial movement of the rollers also contains a movement component in tangential direction, the size of which depends on the structural design (lever and angle to the nip point) of the adjusting device.If the speed of the effective outer surfaces in the nip point arises due to the adjustment in relation to the operating state, this implies due to the surface friction of the roller materials used tangential friction force component which is opposite to the adjustment movement, the adjustment movement is thus inhibited or its speed is limited. This is particularly important in the case of printing unit cylinders in the case of so-called “winders”, since the high pressures that occur also result in large friction forces.

Therefore, in a method for turning cylinders on and off, it is advantageous to have a relative tangential speed in the area close to the contact, ie. H. in the area of the nip point of two co-operating cylinders or rollers, by means of deliberate rotation or rotation correlated with the movement, at least one of the cylinders or rollers involved is reduced. In addition to reducing the inhibition in the adjustment, an unnecessarily high load (friction, deformation) of the elevators and / or the outer surfaces of the cylinders or rollers involved is avoided.

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

Show it:

Figure 1 is a schematic representation of a double printing unit.

2 shows a schematic illustration of a three-cylinder offset printing unit;

Fig. 3 is a schematic representation of a double-wide double printing unit;

Fig. 4 is a schematic representation of a double-wide double printing unit, highly symmetrical;

FIG. 5 shows a schematic illustration of a linear double printing unit in section BB according to FIG. 1 with a curved adjustment path; FIG. FIG. 6 shows a schematic illustration of an angular double printing unit in section BB according to FIG. 1 with a curved adjustment path;

Fig. 7 is a schematic representation of an H-printing unit with a curved adjusting way;

Fig. 8 is a side view for the storage of the cylinders;

FIG. 9 shows a section of the mounting according to FIG. 8;

10 shows a section of a paired drive on the transfer cylinder;

FIG. 11 is a schematic front view according to FIG. 10;

Fig. 12 is a schematic front view of a double printing unit with cylinders of different sizes;

13 an assignment of the forme cylinder with four newspaper pages;

14 an assignment of the forme cylinder with eight tabloid sides;

15 an allocation of the forme cylinder with sixteen standing pages in book format;

16 an allocation of the forme cylinder with sixteen lying pages in book format.

A first printing unit 01 of a printing press, in particular a rotary printing press, has a first cylinder 02, e.g. B. a forme cylinder 02, and an assigned second cylinder 03, e.g. B. a transfer cylinder 03, (Fig. 1). In a print-on position AN their axes of rotation define R02; R03 a level E.

The forme cylinder 02 and the transfer cylinder 03 have at least one malfunction, z. B. an interruption 04; 06 in the lateral surface effective when unrolling. This interruption 04; 06 can be a joint of a leading and a trailing end of one or more elevators, which are arranged on the circumference, for example by means of magnetic force or cohesively. However, as shown below in the exemplary embodiments, channels 04; 06 or slots 04; 06 act which pick up the ends of elevators. The channels 04; Faults designated 06 are synonymous with other interruptions 04; 06 on the effective surface area, d. H. the outward-facing surface of the cylinder 02; 03.

The forme cylinder 02 and transfer cylinder 03 each have at least two channels 04; 06 (or interruptions 03; 04 etc.). These two channels 04; 06 are each in the longitudinal direction of the cylinder 02; 03 one behind the other, and staggered in the circumferential direction.

Assign the cylinders 02; 03 only a length L02; L03, which essentially corresponds to two widths of a newspaper page, there are only two channels 04; 06 arranged.

Channels 04; 06 are so on the two cylinders 02; 03 arranged that when the two cylinders 02; 03 each on one of the channels 06; 04 of the other cylinder 03; 04 unroll. The offset of the channels is preferably 04; 06 each cylinder 02; 03 approx. 180 ° in the circumferential direction. Thus roll after 180 ° Rotation of cylinders 02; 03 at least one pair of channels 04; 06 from one another, while on a longitudinal section a the cylinder 02; 03 the cylinders 02; 03 roll on each other undisturbed.

The transfer cylinder 01 of the first printing group 01 forms with a third cylinder 07; via a train 08; z. B. a printing material web 08, a printing point 09. This third cylinder 07 can be used as a second transfer cylinder 07 (FIG. 1) or as an impression cylinder 07 (FIG. 2), e.g. B. steel cylinders, or satellite cylinders 07. The axes of rotation R03 and R07 of the cylinder 03; 07 span a plane D in the print-on position AN (see FIG. 6).

In the embodiment according to FIG. 5, the axes of rotation R02; R03; R07 of the three interacting cylinders 02; 03; 07 during a print-on position AN here essentially in plane E, which in this case coincides with plane D, and run parallel to one another (see FIG. 5). If the satellite cylinder 07 has two printing points on its circumference, then a second printing unit, not shown, can also be arranged in the common plane E. However, it can also define its own level E, which is also different from the level D assigned to it.

As shown in the exemplary embodiment according to FIG. 1, the third cylinder 07 designed as a second transfer cylinder 07 interacts with a fourth cylinder 11, in particular a second forme cylinder 11 with an axis of rotation R11, and forms a second printing unit 12. The two printing units 01; 12 form a printing unit 13 printing on both sides simultaneously on the web 08, a so-called double printing unit 13.

In Fig. 5 all axes of rotation R02; R03; R07; R11 of the four cylinders 02; 03; 07; 11 during pressing, ie in the ON-ON position in the common plane E. or D and run parallel to each other. Fig. 6 shows a corresponding printing unit 13, wherein a pair of form and transfer cylinders 02, 03; 11, 07 a plane E, and the transfer cylinder 03; 07 which form level D different from levels E.

In the case of the double printing unit 13 (FIG. 1), the cylinders 07; 11 of the second printing unit 12 channels 04; 06 with the properties described above for the first printing group 01 with regard to the number and that of the offset to one another. Channels 04; 06 of the four cylinders 02; 03; 07; 11 are now preferably arranged so that two channels 04; 06 two interacting cylinders 02; 03; 07; 11 roll on top of each other.

In an advantageous embodiment, the forme cylinder 02 and the transfer cylinder 03 each have a length L02; L03, which are four or more widths of a printed page, e.g. B. a newspaper page, e.g. B. 1,100 to 1,800 mm, in particular 1,500 to 1,700 mm and a diameter D02; D03, e.g. B. 130 to 200 mm, in particular. 145 to 185 mm, the circumference of which corresponds essentially to the length of a newspaper page, hereinafter referred to as "single circumference" (FIGS. 3 and 4). The device is also advantageous for other dimensions in which the ratio between diameter D02; D03 and length L02 ; L03 of the cylinder 02; 03 is less than 0.16, in particular less than 0.12, or even less than or equal to 0.08.

In an advantageous embodiment, each of the two cylinders 02; 03 two channels 04; 06, which each extend continuously at least over a length which corresponds to two widths of a newspaper page (FIG. 3).

Each cylinder 02; 03 but also more than two channels 04; 06 may be arranged. In this case, two channels 04; 06 in alignment, or alternately. However, for example with four channels 04; 06 the two the end faces of the cylinders 02; 03 adjacent channels 04; 06 in a common alignment, and the two “inner” channels 04; 06 in a common alignment, but offset in the circumferential direction from the former (FIG. 4).

Are the interruptions 04; 06 actually as channels 04; 06 or slots 04; 06, the channels 04; 06 a little longer than the width or double the width of the printed page. Possibly. they can have two channels 04; 06 also overlap slightly in the circumferential direction. This cannot be seen in such detail in FIGS. 1 to 4, which are only shown schematically.

With regard to the excitation or damping of vibrations caused by channel impact, it is particularly advantageous if the channels 04; 06 on the respective cylinder 02; 03; 07; 11 are offset from each other by 180 °. Channel 04; 06 between the forme cylinders 02; 11 and the transfer cylinders 03; 07 of the two printing units 01; 12 simultaneously and in the area of the same section in the longitudinal direction of the cylinders 02; 03; 07; 11 from; z. B. on the same page, e.g. B. a side I (Fig. 1, 3 and 4) of the double printing unit 13 in one stage of the cycle, and in the other phase on a side II, or with more than two channels 04; 06 per cylinder 02; 03; 07; 11, for example in the area of the center of the cylinder 02; 03; 07; 11th

Due to the offset arrangement of the channels 04; 06 and the unwinding of all channels 04; 06 in the manner described, and in addition, if necessary, the linear arrangement of all cylinders 02; 03; 07; 11 in a plane E, the excitation of vibrations is significantly reduced. Due to the synchronous and possibly symmetrical unwind on the two printing units 01; 12 there is a destructive interference of the excitations which occurs when the offset of the channels 04; 06 on the cylinders 02; 03; 07; 11 180 ° from the speed of the cylinders 02; 03; 07; 11 or the frequency takes place independently. Are the interruptions 04; 06 actually as channels 04; 06 executed, so they are in an advantageous embodiment with a gap of small width, for. B. less than or equal to 3 mm, in the area of a lateral surface of the forme cylinder 02; 11 or transfer cylinder 03; 07 executed, which ends of one or more elevators, for. B. one or more blankets, on the transfer cylinder 03; 07 or ends of one or more elevators, e.g. B. one or more printing plates on the forme cylinder 02; 11 records. The elevator on the transfer cylinder 03; 07 is preferably designed as a so-called metal printing blanket, which has an ink-carrying coating on a metallic base plate. The bent ends are in the case of transfer cylinders 03; 07 for example by clamping and / or tensioning devices and in the case of forme cylinders 02; 11 by clamping devices in the channels 04; 06 held.

In each of the channels 06 of the transfer cylinder 03, a single, continuous clamping and / or tensioning device or - in the case of channels passing through several newspaper page widths - a plurality of clamping and / or tensioning devices can be arranged one behind the other in the longitudinal direction. The channels 04 of the forme cylinder 02 each also have, for example, one or more clamping devices.

Preferably, the forme cylinder 02; 11 and in the channels 06 of the transfer cylinder 03; 07 a "minigap technology" is used, in which a leading end is inserted into a narrow channel 04; 06 with an inclined leading hooking edge, the elevator is wound onto the cylinder 02; 03; 07; 11, the trailing end also in channel 04; 06 is inserted, and the ends are clamped against slipping out, for example by means of a rotating spindle or a pneumatic device.

However, it can also be used both for the elevator on the forme cylinder 02; 11, as well as for the elevator of the transfer cylinder 03; 07 a as a narrow slot 04; 06 executed channel 04; 06 be arranged without a clamping device, which receives the ends of the lifts. The ends are here, for example, by their shape and / or the geometry of the slot in slot 04; 06 held.

The transfer cylinder 03; 07 have z. B. in an advantageous embodiment (Fig. 3) only two, circumferentially offset by 180 ° to each other, each having at least one width which corresponds to two widths of a newspaper page. In this case, the elevators or channels 04 of the forme cylinders 02; 11 complementary to this and must either have, as shown, two continuous channels 04 each having a length of two newspaper page widths, or alternatively pairs of adjacent channels 04 arranged in alignment, each with a length of a newspaper page width. In the former case, each interruption 04 of the forme cylinder 02; 11 in an advantageous embodiment, two clamping devices each of a length which essentially corresponds to a width of a newspaper page.

The forme cylinder 02; 11 are in an advantageous embodiment with four in the longitudinal direction of the forme cylinder 02; 11 bendable lifts arranged side by side occupy, which have a length in the circumferential direction of a little over the length of the printed image of a newspaper page, and in the longitudinal direction a width of about a newspaper page. With the arrangement of continuous channels 04 and only one clamping device per channel 04; 06, which has a length of two widths on one newspaper page, it is also possible to mount lifts with a width of two newspaper pages, so-called panorama printing plates.

For printing units 01; 12, for which a need for equipping with panorama printing plates can be excluded, an arrangement can also be advantageous, the lifts which are adjacent to side I and the 'outer' lifts adjacent to side II to one another align and the "inner" elevators are aligned with one another and are arranged offset by 180 ° to the former (FIG. 4). This highly symmetrical arrangement additionally reduces or prevents the risk of vibration excitation in plane E, which is caused by the non-simultaneous passage which can result in channels 04, 06 on side I and side II, also alternately tensioning and relaxing the web 08 alternately on side I and side II, and thereby causing the web 08 to vibrate.

The arrangement of the interruptions 04; 06 on the respective cylinder 02; 03; 07; 11 and between the cylinders 02; 03; 07; 11 and possibly the linear arrangement of the cylinders 02; 03; 07; 11 are in training also particularly on cylinder 02; 03; 07; 11 apply, which have a length L02; L03, which corresponds essentially to six times the width of a newspaper page. Here, however, it can be advantageous to transfer cylinders 03; 07 and / or the forme cylinders 02; 11 with a diameter D02; D03 to be carried out, which results in a volume which is substantially twice the length of a newspaper page.

For a technically simple and robust design of the double printing unit 13, the forme cylinders 02; 11 in an advantageous embodiment with respect to their axes of rotation R02; R11 fixed. For switching the printing units 01; 12 are the transfer cylinders 03; 07 with respect to their axes of rotation R03; R07 are designed to be movable and are at the same time from the associated forme cylinder 02; 11 and of the cooperating transfer cylinder 03; 07 can be switched off or adjusted to this. In this embodiment, only the transfer cylinders 03; 07 moves while the forme cylinder 02; 11 remain in their fixed, possibly previously adjusted position. The form cylinders 02; 11 however in appropriate devices, e.g. B. in eccentric or double eccentric bushings, in linear guides or in levers. The transfer cylinder 03; 07, as shown schematically in FIGS. 5 and 6, can be moved along a curved adjusting path 17. The travel path 17 and the transfer cylinder 03; 07 in a print-down position AB are shown in broken lines in FIG. 5.

In the lever 18 shown schematically in FIG. 5, one of the transfer cylinders 03 is pivotally mounted about a pivot axis S. The pivot axis S is here z. B. in the plane E. The lever 18 has a length between the mounting of the axis of rotation R03; R07 of the transfer cylinder 03; 07 and the pivot axis S, which is larger than the distance of the axis of rotation R03; R07 of the transfer cylinder 03; 07 from the axis of rotation R02; R11 of the associated forme cylinder 02; 11 in print-on position ON. This means that the transfer cylinder 03; 07 and the associated forme cylinder 02; 11, and vice versa for queuing.

However, the pivot axis S can in particular, as described in more detail below, eccentrically to the axis of rotation R02; R11 of the associated forme cylinder 02; 11, e.g. B. be arranged at a distance from the plane E. The storage in a lever 18 is preferably carried out on side I and on side II of the double printing unit 13.

In a further embodiment, not shown, the travel path 17 z. B. by the storage of the transfer cylinder 03; 07 generated in eccentric bushings, not shown, especially in double eccentric bushings. With double eccentric bushings, a largely linear adjustment path can be generated in the area of the pressure-on position AN, but in the area further away from the pressure point 09, if necessary, a curve-shaped adjustment path 17 can be generated, which means that the transfer cylinder 03; 07 from the cooperating transfer cylinder 07; 03 as from the associated forme cylinder 02; 11 or vice versa allowed. Also for them Using eccentrics, the storage on side I and on side II of the double printing unit 13 is advantageous.

5 and 6, the course of the web 08 is shown by the pressure point 09 located in the print-on position ON. The plane E of the double printing unit 13 (FIG. 5) or the respective printing unit 01; 12 (Fig. 5, 6) and the plane of the web 08 intersect in an advantageous embodiment at an angle α of 70 ° to 85 °. Assign the transfer cylinder 03; 07 a circumference, which corresponds to the length of about a newspaper page, the angle z. B. between 75 ° and 80 °, preferably about 77 °, the transfer cylinders 03; 07, however, has a circumference which corresponds approximately to the length of two newspaper pages, the angle z. B to choose between 80 ° and 85 °, preferably about 83 °. This choice of the angle α contributes to the safe and quick release of the web 08 and / or the parking cylinder 03; 07 from each other with minimized travel 17, and on the other hand minimizes negative influences on the printing result, which are caused by the degree of partial wrapping of the transfer cylinder 03; 07 is significantly influenced (duplication, lubrication, etc.).

At least one of the transfer cylinders 03; In an advantageous embodiment, 07 can be switched off to such an extent that the web 08 drawn in can be guided through the printing point 09 without contact by means of other printing units during printing operation.

The double printing unit 13 (here in a linear design) is multiple, as shown in FIG. 7, for example twice, in a printing unit 19, for. B. a so-called. H-printing unit 19, can be used in a common side frame 20. In FIG. 7, the separate designation of the parts which are the same as the upper double printing unit 13 for the double printing unit 13 located below is omitted. If all cylinders 02; 03; 07; 11 with a circumference which essentially corresponds to a length of a newspaper page can be in terms of installation space, ie at a height h of the printing unit 19 save on. Of course, this also applies to individual printing units 01; 12, for double printing units 13 and for printing units configured differently, which several printing units 01; 12 have. However, instead of saving on height h, the priority can also be achieved if the cylinders 02; 03; 07; 11, e.g. B. for the purpose of changing lifts, cleaning and washing, maintenance etc., lie.

The pressure on or off position ON; AB is shown exaggerated in all figures for clarity. 7 indicates the transfer cylinders 03; 07 in a second possible position along the travel path 17, with here, for example, the upper double printing unit 13, e.g. B. for the purpose of printing form change, in the print-down position AB, and the lower double printing unit 13, z. B. is operated for the purpose of continued production, in the print-on position AN.

In an advantageous embodiment, each of the printing units 01; 12 at least one separate drive motor 14 for the rotary drive of the cylinders 02; 03; 07; 11 on. The drive motor 14 is designed as an electric motor, in particular as an asynchronous motor, synchronous motor or as a DC motor.

In an embodiment shown schematically in FIG. 7, this can be a single drive motor 14 for the respective printing group 01; 12, which in this case, in an advantageous embodiment, is initially placed on the forme cylinder 02; 11 drives, and from there via a mechanical drive connection, for. B. spur gears, timing belts, etc., on the transfer cylinder 03; 07 is driven. However, for reasons of space and torque flow, it can also be advantageous to move the drive motor 14 to the transfer cylinder 03; 07 and from there to the forme cylinder 02; 11 to drive.

The printing unit 01; has a high degree of flexibility in the various operating situations such as continuous printing, registration, elevator change, washing, web feed etc. 12 in a version of its own, and of the other drives mechanically independent drive motor 14 per cylinder 02; 03; 07; 11 (Fig. 7 shown in dashed lines for the upper double printing unit 13).

For special needs, for example for only one-sided imprinter operation or just a requirement to change the relative angle of rotation of the forme cylinders 02; 11 to each other, a drive is also possible, one of the forme cylinders 02; 11 of a printing group 01; 12 its own drive motor M, and the remaining cylinders 02; 03; 07; 11 of the printing group 01; 12 have a common drive motor 14.

The type of drive from FIG. 7 (top and bottom) are each shown as examples and thus to the other printing units 01; 12 or to transmit the other double printing unit 13.

In an advantageous embodiment, the drive motor 14 drives coaxially between the axis of rotation R02; R03; R07; R11 and motor shaft, if necessary via an angle and / or offset compensating coupling detailed below. The drive can, if a "co-movement" of the drive motor 14 or a flexible coupling between the drive motor and the cylinder 02; 03; 07; 11 to be possibly moved should be avoided, can also take place via a pinion.

Should the transfer cylinder 03; 07 driving drive motor 14 are carried during the actuating movement, this can also be in a further development on a corresponding guide, for. B. carried on an outside of the side frame 20.

In a development of the invention, it is advantageous if the respective forme cylinder 02; 11 assigned inking unit 21 and, if present, the assigned dampening unit 22 by one, independent of the drive of the printing unit cylinder Drive motor is driven in rotation. In particular, the inking unit 21 and any dampening unit 22 which may be present can each have their own drive motor. In the case of an anilox inking unit 21, the anilox roller can be, and in the case of a roller inking unit 21, the distribution cylinder or cylinders can be rotated individually or in groups. The one or more distribution cylinders of a dampening unit 22 can also be driven in rotation individually or in groups.

8 and 9 show an exemplary embodiment for the realization of the curved adjustment path 17 by means of the lever 18.

FIG. 8 shows a side view, of two of which are each on the end face on the transfer cylinder 03; 07 (dashed) arranged pin 23 only one is visible. The lever 18 is pivotally mounted about the pivot axis S, which is preferably stationary (but possibly adjustable) with respect to the side frame 20. The axes of rotation R02; R03; R07; R11 of the cylinder 02; 03; 07; 11 are in the illustrated embodiment in the print-on position again in a plane E, which here with the plane D between the cylinders 03; 07 coincides.

The pivot axis S of the lever 18 is eccentric to the axis of rotation R02; R11 of the forme cylinder 02; 11 is arranged and lies outside the plane E or D. A pivoting of the lever 18 about the pivot axis S by means of a drive means 44, for. B. by means of a pressure medium cylinder 44, via an adjusting means 46, for. B. a one-part or multi-part coupling 46, for example via a lever or toggle mechanism 46, causes the transfer cylinder 03; 07 simultaneously from or to the associated forme cylinder 02; 11 and from or to the other transmission cylinder 07; 03. The toggle mechanism 46 is articulated to the lever 18 and to a pivot point fixed to the frame. The advantageously double-acting pressure cylinder acts z. B. on a movable joint of the toggle mechanism. The axes of rotation R02; R11 the forme cylinder 02; 11 at rest. So that the movement of the two end levers 18 per transfer cylinder 03; 07 takes place synchronously, the adjusting means 44 can connect the two adjusting means 44 to a shaft 47, e.g. B. have a synchronous shaft 47, or be connected to such. To the desired, e.g. B. linear arrangement of the cylinders 02; 03; 07; 11 to ensure a stop 48 is provided for each lever 18, which is preferably made adjustable.

The drive and actuating means 44; 46 are designed and arranged in such a way that the transfer cylinders 03; 07 in the direction of the obtuse angle β (for straight web run 180 ° -α) between web 08 and level D or E.

The eccentricity e-S of the pivot axis S to the axis of rotation R02; R 1 of the forme cylinder 02; 11 is between 7 and 15 mm, in particular approximately 9 to 12 mm. The eccentricity e-S is in the position of the transfer cylinder 02; 03; 07; 11, d. H. the axes of rotation R03; R07 are in the above Level D, oriented so that an angle ε-S between the level D of the cylinders 03; 07 and the connecting plane V of the pivot axis S and the axis of rotation R02; R11 is between 25 ° and 65 °, advantageously between 32 ° and 55 °, in particular between 38 ° and 52 °, the pivot axis S preferably in the region of an obtuse angle β between the plane D and the incoming or outgoing web 08, and is further apart from the printing point 09 than the axis of rotation R02; R11 of the associated forme cylinder 02; 11. With vertical, and, except for an offset possibly caused by partial wrapping, straight web run and an angle 77 ° between the plane D and the plane of the web 08, the eccentric e-S z. B. an angle of 12 ° to 52 °, advantageously 19 ° to 42 °, in particular 25 ° to 37 ° to the horizontal H.

In the ideal case, ie in the case of never changing conditions and tolerance-free production, the arrangement as described so far satisfies the requirement for starting and stopping the printing units 01 without further adjustment mechanisms; 12 or des Double printing unit 13.

However, in order to compensate for any manufacturing tolerances that may arise and / or to be able to make a basic setting for the elevators, substrates, etc., there are further adjustment options for adjustment purposes:

The axis of rotation R02; R11 of the forme cylinder 02; 11 is adjustable, e.g. B. also eccentrically for its attachment to the side frame 20, here to a bore 49, stored. In the present case, a pin 51 of the forme cylinder 02; 11 arranged in an eccentric bearing 52 or an eccentric bearing bush 52 which is pivotally mounted in the bore 49.

A pivot axis S51 of the forme cylinder 02; 11 is eccentric to the axis of rotation R02 by an eccentricity of 5 to 15 mm, in particular approximately 7 to 12 mm; R11 of the forme cylinder 02; 11 and is located outside of level E.

The eccentricity e-S51 is in the position of the form and associated transfer cylinder 02, 03; 11, 07, d. H. the axes of rotation R02, R03 and R11, R07 lie in the plane E, oriented so that an angle ε-S51 between the plane E of the pair of cylinders 02, 03 or 11, 07 and a connecting plane of the pivot axis S51 and the axis of rotation R02; R11 of the forme cylinder 02; 11 is between 25 ° and 65 °, advantageously between 32 ° and 55 °, in particular between 38 ° and 52 °. The pivot axis S5 is preferably in a half-plane, which is more distant from the axis of rotation R03; R07 of the assigned transfer cylinder 03; 07 as the axis of rotation R02; R11 of the associated forme cylinder 02; 11 lies.

The swivel axis S51 for the eccentric mounting of the forme cylinder 02; 11 coincides with the pivot axis S of the lever 18 in the exemplary embodiment according to FIG. 8. The coincidence of the pivot axis S and S51 is not mandatory, but it is useful. In particular by means of the pivot axis S which is stationary with respect to the side frame 20 and which is caused by pivoting the forme cylinder 02; 11 is not influenced, allows simple and exact adjustment. Basically, the lever 18 could also be arranged on an eccentric flange of the bearing bushing 53 receiving the pins 51, which, however, when twisting a simultaneous adjustment of the distances between the form 02; 11 and transfer cylinder 03; 07 and between the transfer cylinders 03; 07 would have resulted.

In an advantageous embodiment, the two pivot axes S51 (and / or S) and S23 of a pair of form and transfer cylinders 02, 03; 11, 07 arranged on two different sides of the level E.

The position of the forme cylinder 02; 11 corresponding to the desired position with respect to the plane E or with regard to the required distance from the transfer cylinder 03; 07 for the pressure-on position adjustable by slightly turning the eccentric bearing 52. This position is fixed, for example after the setting has been made, by means not shown.

In order to set the pressure gap at the pressure point 09 in the print-on position, at least the pins 23 of one of the two transfer cylinders 03; 07, here the transfer cylinder 07, adjustable. You are e.g. B. also eccentrically in the associated lever 18. An eccentricity e-S23 of a pivot axis S-23 to the axis of rotation R03; R07 of the transfer cylinder 03; 07 is between 1 and 4 mm, especially around 2 mm. The eccentricity e-S23 is in the position of contact of the cylinders 03; 07, ie the axes of rotation R03; R07 lie in plane D, oriented so that an angle ε-S23 between plane D and the connecting plane of the swivel axis S-23 and the axis of rotation R07 (R03) is between 70 ° and 110 °, advantageously between 80 ° and 100 °, is in particular between 85 ° and 95 °. For example the angle ε-S23 should be approx. 90 °.

FIG. 9 shows an embodiment according to FIG. 8 in a representation of a section along the plane E. The pin 51 of the forme cylinder 02; 07 are each in bearings 54, z. B. rolling bearings 54, rotatably mounted. In order to be able to make an adjustment or a correction of the side register, in an advantageous embodiment this bearing 54 or an additional axial bearing (not shown) enables the movement of the forme cylinder 02; 11 or its pin 51 in the axial direction. The bearings 54 are arranged in the eccentric bearing 52 or in the eccentric bearing bush 52, which in turn is pivotably arranged in the bore 49 in the side frame 20. In addition to the eccentric bearing bush 52 and the bearing 54, further bearing rings and slide or roller bearings can be arranged between the bore 49 and the pin 51. The lever 18 is on a to the forme cylinder 02; 07 out of the side frame 20 projecting part of the bearing bush 52, and pivotally mounted relative to this. The lever 18 takes in its end remote from the pivot axis S the pin 23 of the transfer cylinder 03; 07, which is rotatable in a bearing 56, and this is arranged in the case of the transfer cylinder 07, pivotable about the pivot axis S-23 in an eccentric bearing 57 or in an eccentric bearing bush 57. Such a pivotable bearing bush 57 can, if necessary, also for both transfer cylinders 03; 07 be arranged.

Advantageously, at least on one drive side of the printing press, the side frame 20 has recesses 58 in which the pins 23 of the transfer cylinder 03; 07 are pivotable. The actuating means 46; 53 or drive means 44 are not shown in FIG. 8.

The rotary drive of the cylinders 02; 03; 07; 11 takes place by means of their own, mechanically driven by the respective other cylinders 02; 03; 07; 11 independent drive motors 14, which are preferably arranged fixed to the frame. The latter has the Advantage that the drive motors 10 do not have to be moved.

To the pivoting movement of the transfer cylinder 03; To compensate 07, an angle and offset compensating coupling 61 is arranged between the transfer cylinder and the drive motor 10. This can be designed as a double joint 61 or, in an advantageous embodiment, as an all-metal coupling 61 with two torsionally rigid but axially deformable plate packs. The all-metal coupling 61 can simultaneously compensate for the offset and the change in length caused therefrom. It is essential that the rotary motion is transmitted without play.

The drive of the forme cylinder 02; 11 has a coupling 62 between pin 51 and drive motor 14, which clutch has at least one axial relative movement between cylinder 02; 11 and drive motor 14 takes. In order to also allow manufacturing tolerances and any necessary movements of the forme cylinder 02; 11 for adjustment purposes, the clutch 62 is also designed as an at least slight angle and offset compensating clutch 62. This is also designed in an advantageous embodiment as an all-metal clutch 62 with two torsionally rigid but axially deformable disk packs. The axial movement is absorbed by the plate packs which are positively connected in the axial direction to the pin 51 or to a shaft of the drive motor 14.

In an advantageous further development, between each of the drive motors 14 and the cylinder 02; 03; 07; 11 a transmission 63 interposed. This gear 63 can be connected to the drive motor 14 attachment gear 63, e.g. B. be a planetary gear 63. However, it can also be used as another reduction gear 63, e.g. B. from pinion or belt and drive wheel. A single encapsulation of the transmission 63 is advantageous, which can be implemented in a simple manner, in particular in the case of an auxiliary transmission 63. The lubricant spaces created in this way are spatially limited and prevent contamination of neighboring machine parts as well contribute to increasing the quality of the product.

In the case of the paired drives of the cylinders 02; schematically indicated in FIG. 6 in the lower double printing unit 13; 03; 07; 11 is the drive on the forme cylinder 02; 11 - e.g. B. via the attachment gear 63 or a pinion on a drive wheel of the forme cylinder 02; 11. The advantage here is the formation of interacting drive wheels between the form and transfer cylinders 02, 03; 11, 07 each with a spur gear. The latter also applies to a possibly arranged pinion between the drive motor 14 and the drive wheel of the forme cylinder 02; 11. One of the above in this case, individual encapsulation extends around the paired drive of two cylinders 02, 03; 11, 07

In a variant shown in FIGS. 10 and 11, a pairwise drive can also be driven from the drive motor (possibly via further gear parts, not shown) through a pinion 59 to a drive wheel 61 of the transfer cylinder 03; 07 if, for example, a special torque flow is to be achieved.

An axis of rotation R59 of the pinion 59 is then preferably fixed to the frame such that a straight line G1 defined by the axis of rotation R59 of the pinion 59 and the pivot axis S of the lever 18 has a straight line defined by the pivot axis S of the lever 18 and the axis of rotation R03; R07 of the transfer cylinder 03; 07 defined level E18 includes an opening angle η in the range of + 20 ° to - 20 °.

In a further development, one of the axes of rotation R02; R11 of the associated forme cylinder 02; 11 and the axis of rotation R59 of the pinion 59, a straight line G2 with the line G1 defined by the axis of rotation R59 of the pinion 59 and the pivot axis S of the lever 18 an opening angle λ in the range from 160 ° to 200 °. The aforementioned statements regarding the drive and the pivoting of the transfer cylinder 03; 07 and the design of the lever 18 are to be applied to printing units in which the cylinders 02; 03; 07; 11 do not all have the same circumference or diameter (FIG. 12). For example, the forme cylinder or cylinders 02; 11 have a circumference U, which in the circumferential direction a pressure side, for. The cooperating transfer cylinder 03; 07 has, for example, a circumference or diameter which corresponds to an integer multiple (greater than 1) of that of the forme cylinder 02; 11 , ie it has, for example, a length of two or even three printed pages in newspaper format (or adapted accordingly to other formats).

If the printing point is 03; 07 and a z. B. as a satellite cylinder 07; 03 executed impression cylinder 07; 03 formed, forme and transfer cylinders 02; 11; 03; 07 have a simple circumference and the associated impression cylinder 07; 03 be made many times larger.

The aforementioned designs also advantageously achieve increased rigidity of the printing unit. This is particularly advantageous in connection with cylinders 02; 11; 03; 07, which have a length that corresponds to at least four or even six standing printed pages, in particular newspaper pages.

The execution of the cylinder 02; 03; 07; 11 double width and - at least the forme cylinder 02; 11 - with "single scope" enables, in contrast to printing presses with double scope and single width, a significantly higher product variability. The maximum number of possible print pages is the same, but in the case of the single-width printing units 01; 12 double scope in the collecting operation in two different " Books "or" booklet ". In the present case the double-wide printing units 01; 12 of simple circumference, the (double-wide) webs 08 are cut lengthwise after printing. In order to achieve a maximum stitching strength, one or more partial webs in the so-called folding superstructure or turning deck are guided one above the other and z. B. folded on a folder without a collector to a booklet. If such stapling thicknesses are not required, some partial webs can be guided one above the other, but others can be guided together on a second former and / or folder. However, two products of the same thickness can also be fed onto two folders without being transferred. There is therefore a variable strength of two different products. If at least two product deliveries are provided in the case of a double folder or two folders, depending on the arrangement, the two booklets or products can be guided side by side or one above the other to one side of the printing press or to the two different sides.

The double-width printing press of a simple scope has a high degree of variability, particularly in the grading of the possible number of pages in the product, in the so-called "page jump". While the thickness per booklet (position) for the printing press with double the circumference and single width in the collecting operation (ie maximum product thickness) ) can only be varied in steps of four printed pages, the double-width printing press of simple scope described allows a "page jump" from two pages (eg in newspaper printing). The product strength and in particular the "distribution" of the printed pages on different issues of the overall product or products is considerably more flexible.

After the web 08 has been cut lengthwise, the partial web is thus either guided onto a folding former and / or folder which is different from the corresponding partial web, or else it is turned to escape the latter. That is, in the second case, the partial web is brought into the correct longitudinal or cutting register before, during or after turning, but before merging with the "straight webs". This is done depending on the channels 04; 06 of a cylinder 02; 03; 07; 11 in an advantageous embodiment by corresponding execution of the Turning decks (e.g. preset distances between the bars or the path sections) are taken into account. The fine adjustment or control is carried out with the adjustment paths of the cut register control for the relevant partial web and / or partial web strand, in order to bring partial webs of two different running levels onto one another in register, if necessary.

The forme cylinder 02; 11 can now be equipped in the circumferential direction with one and in the longitudinal direction with at least four standing printed pages in broadsheet format (FIG. 13). Alternatively, this forme cylinder 02; 11 also optionally in the circumferential direction with two and in the longitudinal direction with at least four lying printed pages in tabloid format (Fig. 14) or in the circumferential direction with two and in the longitudinal direction with at least eight standing printed pages in book format (Fig. 15) or in the circumferential direction with four and in the longitudinal direction with at least four lying printed pages in book format (FIG. 16) by means of one in the circumferential direction of the forme cylinder 03 and its longitudinal direction at least one flexible printing plate which can be arranged thereon.

By means of the double-width printing press and at least the forme cylinders 02; 11 simple scope are thus depending on the occupancy of the forme cylinder 02; 11 with lying tabloid pages or standing newspaper, in particular broadsheet pages, with lying or standing book pages different products can be produced depending on the width of web 08 used:

Thus, with the double printing unit 13, it is possible to produce products in broadsheet format in a gradation from two standing print pages arranged on the forme cylinder (“two-page jump”).

In the case of a width of web 08 corresponding to four or three or two standing printed pages or a standing printed page in broadsheet format, the production of one from one layer is in the above sequence with eight or six or four or two printed pages of existing product in broadsheet format possible.

The double printing unit has a web width corresponding to four standing printed pages in broadsheet format for the production of two single-layer products in broadsheet format with four printed pages in one product and four printed pages in the other product or with two printed pages in one product and six Print pages can be used in the other product. In the case of a web width corresponding to three standing printed pages, it can be used for the production of two single-layer products in broadsheet format with four printed pages in one product and two printed pages in the other product.

Furthermore, the double printing unit 13 has a web width corresponding to four standing printed pages in broadsheet format for the production of a two-layer product in broadsheet format with four printed pages in one layer and four printed pages in the other layer or two printed pages in one layer and six printed pages usable in the other layer. With a web width corresponding to three standing printed pages, it can be used for the production of a two-layer product in broadsheet format with four printed pages in one layer and two printed pages in the other layer.

In the case of printed pages in tabloid format, the double printing unit for the production is in a gradation of four lying on the forme cylinder 02; 11 arranged printed pages of changeable products ("four-page jump") can be used in tabloid format. Correspondingly, the double printing unit 13 with a web width corresponding to four or three or two lying printed pages or a lying printed page is suitable for producing a sixteen from one layer in the above order or twelve, eight or four printed pages of existing product in tabloid format. The double printing unit is with a web width corresponding to four lying print pages in tabloid format for the production of two products in tabloid format each consisting of one layer with eight printed pages in one product and eight printed pages in the other product or with four printed pages in one product and twelve Print pages can be used in the other product. With a web width corresponding to three lying printed pages, it can be used for the production of two tabloid-sized products each with four printed pages in one product and eight printed pages in the other product.

For products in book format, the double printing unit 13 is standing on the forme cylinder 02; 11 arranged printed pages of changeable ("eight page jump") products can be used.

With the double printing unit 13, with a web width corresponding to eight or six or four or two standing printed pages, the production of a product in book format consisting of one layer in the above sequence with thirty-two or twenty-four or sixteen or eight printed pages is possible.

With a web width corresponding to eight standing printed pages in book format, the double printing unit 13 is for the production of two single-layer products in book format with sixteen printed pages in one product and sixteen printed pages in the other product or twenty-four printed pages in one product and eight Print pages can be used in the other product. In the case of a web width corresponding to six standing printed pages in book format, it can be used for the production of two single-layer products in book format with sixteen printed pages in one product and eight printed pages in the other product.

Next is the double printing unit 13 for products in book format for production in one Grading of eight changeable products lying on the forme cylinder 03 can be used ("eight page jump") (double cross fold).

With a web width corresponding to four or three or two horizontal printing pages or a horizontal printing page in book format, the double printing unit 13 is suitable for producing a product consisting of one layer in the above sequence with thirty-two or twenty-four or twenty or sixteen or eight printing pages Book format usable.

The double printing unit is with a web width corresponding to four lying printed pages in book format for the production of two one-layer products in book format with sixteen printed pages in one product and sixteen printed pages in the other product or twenty-four printed pages in one product and eight printed pages usable in the other product. With a web width corresponding to three lying printed pages in book format, it can be used for the production of two single-layer products in book format with sixteen printed pages in one product and eight printed pages in the other product.

If the two partial web strands are folded lengthways on different hoppers and then fed into a common folder, the above is to be used for the distribution of the product on different, combined booklets or layers with the variable number of pages described.

LIST OF REFERENCE NUMBERS

01 printing unit

02 cylinders, form cylinders

03 cylinder, transfer cylinder

04 break, channel, slot

05 -

06 break, channel, slot

07 cylinders, transfer cylinders, impression cylinders, satellite cylinders

08 web, printing material web

09 pressure point

10 -

11 cylinders, forme cylinders

12 printing unit

13 printing unit, double printing unit

14 drive motor

15 -

16 -

17 travel, curved

18 levers

19 printing unit, H printing unit

20 side frame

21 inking unit, anilox inking unit, roller inking unit

22 dampening system

23 pins (03, 07)

44 drive means, pressure medium cylinder

45 -

46 adjusting means, coupling, toggle mechanism

47 pivot point, shaft, synchronous shaft

48 stop 49 hole

50 -

51 pins (02; 11)

52 eccentric bearings, bearing bush, eccentric

53 positioning means

54 bearings, roller bearings

55 -

56 bearings

57 eccentric bearings, bearing bush, eccentric

58 recess

59 sprockets

60 -

61 drive wheel

E level

E18 level

D level

G1 straight

G2 straight

V connection level

H horizontal

M drive motor

S swivel axis

S23 swivel axis

S51 swivel axis

U scope (02, 11)

AB pressure-down position

ON pressure-on position a longitudinal section h height

D02 diameter

D03 diameter

L02 length (02) L03 length (03)

R02 axis of rotation

R03 rotation axis

R07 axis of rotation

R11 axis of rotation

R59 axis of rotation

I side

II side

Angle ß Angle ε-S Angle ε-S23 Angle ε-S51 Angle η Angle (E18, G1) λ Angle (G1.G2)

Claims

Expectations

1. Printing unit of a printing press, which has at least three cylinders (02; 03 07; 11. Namely a forme cylinder (02; 11), a transfer cylinder (03; 07) and an impression cylinder (07; 03), the transfer cylinder (02; 03; 07; 11) for mounting or stopping on an impression cylinder (07; 03) on the end in two levers (18) which can be pivoted about a pivot axis (S), and the levers (18) can be pivoted by at least one drive means (44) characterized in that the drive means (44) is designed as a cylinder (44) which can be pressurized and which acts on a movable joint of a toggle lever mechanism (46) connected to the lever (18) and a pivot point (47) fixed to the frame.

2. Printing unit of a printing press, which has at least three cylinders (02; 03; 07; 11), namely a forme cylinder (02; 11), a transfer cylinder (03; 07) and an impression cylinder (07; 03), the transfer cylinder ( 02; 03; 07; 11) for mounting on or off a counter-pressure cylinder (07; 03) is mounted on the end face in two levers (18) which can be pivoted about a pivot axis (S), characterized in that the pivot axis (S) of the lever (18) is arranged in a fixed position with respect to a side frame (20), in that the lever (18) is arranged concentrically on an eccentric bushing (52) mounted in the side frame (20) and accommodating a pin (51) of the forme cylinder (02; 11).

3. Printing unit according to claim 2, characterized in that the levers (18) by at least one drive means (44) are pivotable, which is designed as a pressurizable cylinder (44) and on a movable joint with the lever (18) and a toggle mechanism (46) connected to a frame-fixed pivot point (47).

4. Printing unit according to claim 1 or 2, characterized in that the impression cylinder (07; 03) is designed as a transfer cylinder (07; 03) also mounted on the end face in levers (18), to which a further forme cylinder (11; 02) is assigned.

5. Printing unit according to claim 1, 2 or 4, characterized in that the pivoting movement of the two end levers (18) of the transfer cylinder (03; 07) is synchronized via a shaft (47).

6. Printing unit according to claim 1, 2 or 4, characterized in that at least one cylinder (44) pressurizable with pressure medium is provided for each lever (18).

7. Printing unit according to claim 1 or 4, characterized in that the pressurized cylinder (44) are double-acting.

8. Printing unit according to claim 1 or 4, characterized in that the levers (18) are employed in a respective pressure-on position (AN) on an adjustable stop (48) fixed to the frame.

9. Printing unit according to claim 1, characterized in that the forme cylinder (02; 11) is pivotally mounted about a pivot axis (S51) arranged eccentrically to its axis of rotation (R02; R11).

10. Printing unit according to claim 9, characterized in that the pivot axis (S) of the lever (18) and the pivot axis (S51) of the forme cylinder (02; 11) coincide.

11. Printing unit according to claim 1, characterized in that the pivot axis (S) is arranged stationary with respect to a side frame (20) by the lever (18) is arranged concentrically on an eccentric bushing (52) mounted in the side frame (20) and receiving a pin (51) of the forme cylinder (02; 11).

12. Printing unit according to claim 1 or 2, characterized in that axes of rotation (R02; R03; R07; R11) of the forme cylinder (02; 11), the transfer cylinder (03; 07) and the impression cylinder (07; 03) in a printing On position (AN) of the cylinders (02; 03; 07; 11) lie in a common plane (E).

13. Printing unit according to claim 1 or 2, characterized in that an axis of rotation (R02; R11) of the forme cylinder (02; 11) is mounted fixed to the frame during the pivoting in and out.

14. Printing unit according to claim 2 or 11, characterized in that by means of an eccentric bushing (52) a distance between a rotation axis (R02; R11) of the forme cylinder (02; 11) and a rotation axis (R03; R07) of the transfer cylinder (03; 07) is adjustable.

15. Printing unit according to claim 1 or 2, characterized in that an adjusting device is provided, by means of which a distance between a rotation axis (R03; R07) of the transfer cylinder (03; 07) and a rotation axis (R07; R03) of the impression cylinder (02; 11) is adjustable

16. Printing unit according to claim 9, characterized in that in the print-on position (AN) of the forme and associated transfer cylinder (02; 03; 07; 11) a connection plane through the axis of rotation (R02; R11) of the forme cylinder (02; 11) and the pivot axis (S51) an angle (ε-S51) with a plane (E) through the axes of rotation (R02; R03; R07; R11) of the form and associated transfer cylinder (03; 07), which is between 25 ° and is 65 °.

17. Printing unit according to claim 15, characterized in that the transfer cylinder (03; 07) is movably mounted in a direction perpendicular to its axis of rotation (R03; R07) by means of the second adjusting device with respect to the lever (18).

18. Printing unit according to claim 17, characterized in that the second adjusting device has an eccentric bushing (57) which is pivotably mounted in the lever (18) about a pivot axis (S23) and which accommodates a pin (23) of the transfer cylinder (03; 07).

19. Printing unit according to claim 18, characterized in that in the print-on position (AN) of at least the form cylinder, the associated transfer cylinder and the impression cylinder (02; 03; 07; 11) a connection plane through the axis of rotation (R03; R07 ) of the transfer cylinder (03; 07) and the pivot axis (S23) of the pin (23) form an angle (ε-S23) with a plane (D) through the axes of rotation (R03; R07) of the cylinder (03) forming the pressure point (09) ; 07), which is between 70 ° and 110 °.

20. Printing unit according to claim 4 or 20, characterized in that an eccentricity (e-S) of the pivot axis (S) to the axis of rotation (R02; R1) of the forme cylinder (02; 11) is between 7 and 15 mm.

21. Printing unit according to claim 1 or 2, characterized in that in the printing position (AN) of at least the form cylinder, the associated transfer cylinder and the impression cylinder (02; 03; 07; 11) a connecting plane (V) through a The axis of rotation (R02; R11) of the forme cylinder (02; 11) and the pivot axis (S) form an angle (ε-S) with a plane (D) through the axes of rotation (R03; R07) of the cylinder (03) forming the pressure point (09) ; 07), which is between 25 ° and 65 °.

22. Printing unit according to claim 1 or 2, characterized in that the forme cylinder (02; 11) and the transfer cylinder (03; 07) is assigned a common drive motor (14) driving on the forme cylinder (02; 11) for the rotary drive ,

23. Printing unit according to claim 1 or 2, characterized in that the forme cylinder (02; 11) and the transfer cylinder (03; 07) is assigned a common drive motor (14) driving the transfer cylinder (03; 07) for the rotary drive ,

24. Printing unit according to claim 1 or 2, characterized in that the forme cylinder (02; 11) and the transfer cylinder (03; 07) each have a mechanically independent drive cylinder (02; 03; 07; 11) drive motor (14) for the rotary drive is assigned.

25. Printing unit according to claim 22, 23 or 24, characterized in that a gear (63) is arranged between the drive motor (14) and the cylinder to be driven (02; 03; 07; 11).

26. Printing unit according to claim 22 or 24, characterized in that the drive motor (14) of the forme cylinder (02; 11) is arranged fixed to the frame.

27. Printing unit according to claim 23 or 24, characterized in that the drive motor (14) of the transfer cylinder (03; 07) is arranged fixed to the frame.

28. Printing unit according to claim 26, characterized in that the drive connection between the forme cylinder (03; 07) and the associated drive motor (14) has a relative movement between the forme cylinder (02; 11) and the drive motor (14) is carried out receiving.

29. Printing unit according to claim 27, characterized in that an angle and / or offset compensating coupling (61) is arranged between the drive motor (14) and the transfer cylinder (03; 07).

30. Printing unit according to claim 1 or 2, characterized in that a plane (E) of axes of rotation (R02; R03; R07; R11) of at least one form and associated transfer cylinder (02, 03; 07, 11) by an angle (α ) from 75 ° to 85 ° inclined to the plane of a web (08) passing through the printing unit.

31. Printing unit according to claim 1 or 2, characterized in that at least two of the cylinders (02; 03; 07; 11) of the printing unit each have at least one axially extending interruption (04; 06) on their effective lateral surface, which are arranged alternately rolling on one another are.

32. Printing unit according to claim 1 or 2, characterized in that at least the forme and the transfer cylinder (02; 03; 07; 11) each have a circumference which essentially corresponds to a section length of a printed page in newspaper format.

33. Printing unit according to claim 1 or 2, characterized in that the forme cylinder (02; 11) has a circumference which essentially corresponds to a section length of a printed page in newspaper format and the transfer cylinder (03; 07) has a circumference which is an integral multiple not equal to one of the circumference of the assigned forme cylinder (02; 11).

34. Printing unit according to claim 1 or 2, characterized in that the forme cylinder (02; 11) has a circumference which is essentially a section length of a Corresponds to the printed page in newspaper format and the transfer cylinder (03; 07) has a circumference which corresponds to an integer multiple not equal to one of the circumference of the assigned forme cylinder (02; 11).

35. Printing unit according to claim 1 or 2, characterized in that the cylinders (02; 03; 07; 11) have a length (L02; L03) in the region of their bale in the longitudinal direction, which corresponds essentially to four widths of a newspaper page.

36. Printing unit according to claim 1 or 2, characterized in that at least two cylinders (02; 03; 07; 11) of the printing unit each have at least two interruptions (04; 06) on the effective lateral surface, which in the longitudinal direction of the respective cylinder (02 ; 03; 07; 11) next to each other, but offset to each other in the circumferential direction.