DE102006054382A1 - Printing unit of a printing machine with two stacked double printing units - Google Patents

Abstract

The device (01) has dual printing units (13, 14) including printing unit cylinders (03, 04, 06, 07, 08, 09, 11, 12) with front-side pins that are reciprocally supported on cartridges (17, 18), respectively. The cartridges are detachably arranged at a side frame (02) of a printing machine. The cylinders (03, 04, 11, 12) are fixedly arranged with respect to their respective rotation axes at the cartridges. The cylinders (06, 07, 08, 09) are arranged position-adjustably at the cartridges with respect to respective rotation axes of the cylinders (06, 07, 08, 09).

Description

The The invention relates to a printing unit of a printing machine with two superimposed arranged double printing units according to the preamble of the claim 1.

From the EP 12 32 062 B1 is a storage of a cylinder of a rotary printing machine is known, wherein a pin of a cylinder, in particular a forme cylinder is mounted in an angle-adjustable on a side frame eccentric bush, which in turn carries a bearing for the cylinder pin.

From the WO 03/013857 A2 an H-printing unit with two stacked double printing units is known, wherein the end-side pins of the printing unit cylinders are each mounted on an insert, which in turn is detachably arranged on the side frame of the printing press. The printing cylinder, in particular the forme cylinder are at least partially adjustable via slide or eccentric.

From the WO 98/53995 A1 is a drive for a cylinder of a rotary printing machine in connection with a bridge unit of a H-printing unit known, wherein printing cylinder, in particular transfer cylinders are mounted in eccentric bushings, which in turn are held directly in the side frame.

Of the Invention is based on the object, a printing unit of a printing press with two on top of each other arranged to create double printing units.

The The object is achieved by the Features of claim 1.

The particular advantages of the invention are that a particularly space-saving arrangement with comparatively simple Construction, simple operation and high bearing stiffness realized can be.

embodiments The invention are illustrated in the drawings and are in Following closer described.

It demonstrate:

1 a view of an H-printing unit according to the invention;

2 a view of a bridge printing unit of an H-printing unit in a viewing direction transverse to the view 1 , including side frame and additional side support plates;

3 a perspective view of the bridge printing unit after 2 ;

4 a perspective view of the storage of each one end of two cylinders in an insert;

5 another perspective view of the storage after 4 ;

6 a top view of the storage after 4 ;

7 a sectional view VII-VII of the storage according to 6 ;

8th a side view of a 3-ring eccentric bearing for use in a printing unit according to 2 or 3 or in a storage after 4 to 7 ;

9 a sectional view IX-IX of the 3-ring eccentric bearing according to 8th ;

10 a sectional view XX of the 3-ring eccentric bearing according to 8th ;

11 a sectional view XI-XI of the 3-ring eccentric bearing according to 8th ;

12 a perspective view of the 3-ring eccentric bearing according to 9 from the right;

13 a perspective view of the 3-ring eccentric bearing according to 9 from the left;

14 a perspective view of the left end of the bridge printing unit after 2 with additional parts of an eccentric actuator;

15 a perspective view of the right end of the bridge printing unit after 2 with additional parts of an eccentric actuator and drive wheels;

16 a sectional view of a right end of a printing unit together with side frame and additional support plate;

17 a sectional view of a left end of a cylinder of a printing unit together with side frame and additional support plate;

18 a roller scheme for driving the H-pressure unit after 1 ;

19 a scheme that the Radfluchten to roll pattern after 18 shows;

20 a sketch regarding the eccentric bearings of the left upper transfer cylinder according to the roller diagram 18 ;

21 a sketch concerning the Exzenterlagen the right upper transfer cylinder according to the roller diagram 18 ;

22 a sketch regarding the Exzenterlagen the left lower transfer cylinder according to the roller diagram 18 ;

23 a sketch regarding the Exzenterlagen the right lower transfer cylinder according to the roller diagram 18 ;

24 a sketch relating to a preferred position of the center of a pressure-in-position transfer cylinder relative to a cylinder assembly.

First, it will open 1 Referenced. In an otherwise not shown here printing unit 01 a printing press, for example a web-fed rotary printing press, in particular a web-fed rotary offset printing press of a type known per se, are on a side frame 02 the printing cylinder 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 , in particular printing cylinder 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 rotatable about their respective axis and stored in a suitable drivable manner.

In the case of the embodiment, the cylinders 03 ; 04 as a form cylinder 03 ; 04 and the cylinders 06 ; 07 as a transfer cylinder 06 ; 07 a first double printing unit 13 and the cylinders 11 ; 12 as a form cylinder 11 ; 12 and the cylinders 08 ; 09 as a transfer cylinder 08 ; 09 a second double printing unit 14 formed, wherein the transfer cylinder 06 ; 07 respectively. 08 ; 09 in printing operation for double-sided printing of a substrate web 16 that the printing unit 01 in the transport direction E from bottom to top, abut against each other in a conventional manner.

The form cylinder 03 ; 04 ; 11 ; 12 can as a plate cylinder 03 ; 04 ; 11 ; 12 and the transfer cylinders 06 ; 07 ; 08 ; 09 as a rubber cylinder 06 ; 07 ; 08 ; 09 be educated. The transfer cylinder 06 ; 07 ; 08 ; 09 are in the case of the embodiment described here as a counter-pressure cylinder 06 ; 07 ; 08 ; 09 educated.

The printing cylinder 03 ; 04 ; 06 ; 07 respectively. 11 ; 12 ; 08 ; 09 of every double printing unit 13 ; 14 are in the case of the embodiment in each case in an approximately U-shaped constellation or, in the case of the underlying double printing unit 13 in a constellation corresponding to an inverted U for forming a bridge pressure unit, respectively 13 ; 14 arranged, with the two bridge pressure units 13 ; 14 are arranged one above the other and together a H-pressure unit 01 define. Each printing unit of each bridge printing unit 13 ; 14 are in a manner not shown, the usual peripheral units such as inking, dampening o. The like. Associated.

The cylinders 03 ; 04 ; 06 ; 07 respectively. 08 ; 09 ; 11 ; 12 each bridge printing unit 13 ; 14 are on both sides respectively on or in use 17 respectively. 18 stored, each detachable on the side frame 02 is fixed. The stakes 17 ; 18 are also bells 17 ; 18 called. The storage of the cylinders 03 ; 04 ; 06 ; 07 on the mutually provided inserts 17 the bridge printing unit 13 in particular, too 2 and from 3 clear. The storage of the cylinders 08 ; 09 ; 11 ; 12 on the two upper inserts 18 the upper double printing unit 14 is corresponding, but mirror-symmetrical.

At least the transfer cylinders 06 ; 07 ; 08 ; 09 are each at least between a print-on position in which they on the substrate web 16 or the respective opposite transfer cylinder 06 ; 07 ; 08 ; 09 abut, and a print-off position in which they are from the substrate web 16 or the respective opposite transfer cylinder 06 ; 07 ; 08 ; 09 are parked, movably arranged.

In the case of a preferred embodiment of the invention, all form cylinder 03 ; 04 ; 11 ; 12 the H-pressure unit 01 with regard to their respective axial position on the respective insert 17 respectively. 18 fixed, ie there is no adjustment of the forme cylinder 03 ; 04 ; 11 ; 12 provided in a direction perpendicular to its axis, while all transfer cylinders 06 ; 07 ; 08 ; 09 regarding their axial position to the respective application 17 respectively. 18 are arranged adjustable, in particular by means of a respective bearing 19 , z. B. an eccentric 19 , each from an eccentric bushing 19 , z. B. an eccentric 19 , in particular of a 3-ring eccentric bearing 19 can be formed, as this below in connection with 4 to 7 is discussed in more detail.

4 to 7 show the storage of a cylinder 03 , the one form cylinder 03 can be, and a cylinder 06 that is a transfer cylinder 06 can be at a mission 17 , The form cylinder 03 and the transfer cylinder 06 can, for example, the printing cylinder 03 ; 06 one of the printing units of the bridge printing units 13 ; 14 the H-pressure unit 01 according to 1 be. The other printing units of the bridge printing units 13 ; 14 can be designed accordingly.

The use 17 that does not detail in here manner in a corresponding recess of the side frame 02 the printing press is included and over its circumferential collar 21 by means of suitable fasteners on the side frame 02 can be fixed, two points in the axial direction of the cylinder 03 ; 06 extending through holes 22 ; 23 on, through which the pins pass 24 ; 26 the cylinder 03 ; 06 extend. In every through hole 22 ; 23 is a warehouse 19 ; 27 arranged over which the respective pin 24 respectively. 26 on the job 17 and on the side frame 02 the printing press for rotation of the forme cylinder 03 or of the transfer cylinder 06 is mounted about its respective axis.

The warehouse 27 for storage of the forme cylinder 03 is as a rolling bearing 27 educated. In detail, the warehouse 27 as a cylindrical roller bearing 27 formed with a tapered inner ring whose shape of the tapered shape of the corresponding, opposite portion of the pin 24 corresponds, so that by moving the inner ring of the bearing 27 in the axial direction, the bearing clearance can be adjusted. With the reference number 33 is a cover plate 33 denotes which the bearing 27 on the inside 31 of the insert 17 covers.

The axial length l4 of the bearing 27 is significantly smaller than the thickness measured in the axial direction or axial length l5 of the insert 17 or the bell 17 , In the case of the embodiment less than half the thickness l5 of the insert 17 , Furthermore, the thickness D1 of the side frame 02 much smaller than the thickness l5 of the insert 17 , The use 17 is with his the bale 28 of the cylinder 03 turned away, the collar 21 having side in or on the side frame 02 attached. In contrast, the camp 27 in the through hole 22 essentially flush with the bale 28 facing inside 31 arranged the insert, resulting in a high bearing stiffness.

On the cone 24 of the forme cylinder 03 is one through the use 17 extending sleeve therethrough 32 slidably disposed in the axial direction. A first, the bale 28 of the forme cylinder 03 facing end face of the socket 32 acts on the inner ring of the bearing 27 , On a second, the bale 28 of the forme cylinder 03 opposite end face of the socket 32 acts an adjusting device not shown here or an adjusting mechanism for the axial adjustment or adjustment of the cylinder 03 Relative to the use 17 and thus relative to the side frame 02 ,

In addition, the socket can 32 with a drive means, for. B. a gear for driving the cylinder 03 be provided. Possibly. can also be provided a second gear to drive a color and / or dampening unit.

The warehouse 19 for storage of the transfer cylinder 06 is as a 3-ring eccentric 19 educated. The axial length l3 of the bearing 19 corresponds approximately to that of the camp 27 and is also significantly smaller than the thickness 15 of the insert measured in the axial direction 17 or the bell 17 in the case of the exemplary embodiment, therefore, less than half the thickness 15 of the insert 17 , The warehouse 19 is in the through hole 23 in turn, essentially flush with the bale 29 the transfer cylinder 06 or the bale 28 of the forme cylinder 03 facing inside 31 of the insert 17 arranged, which in turn results in a high bearing stiffness.

The 3-ring eccentric bearing 19 has an inner ring 34 , an outer ring 36 as well as between inner ring 34 and outer ring 36 arranged eccentric ring 37 on. Between the inner ring 34 and the eccentric ring 37 on the one hand and between the eccentric ring 37 and the outer ring 36 On the other hand, each designed as a cylindrical roller bearing bearings are provided. By means of a retaining ring 38 becomes the inner ring 34 kept in position.

The inner surface of the inner ring 34 is in turn tapered according to the tapered shape of the corresponding, opposite portion of the pin 26 of the cylinder 06 ,

The hole 39 , z. B. bearing bore 39 of the eccentric ring 37 for receiving the inner ring 34 and the circlip 38 is eccentric, so that the axis of rotation 41 of the pin 26 and thus the transfer cylinder 06 eccentric to the axis 40 the through hole 23 in use 17 and thus in the side frame 02 is stored. By turning or swiveling the eccentric ring 37 can the spatial position of the axis of rotation 41 Relative to the use 17 or to the side frame 02 be varied, which makes it possible, the transfer cylinder 06 from the form cylinder 03 to stop or hire them. For angular adjustment of the eccentric ring 37 this can be coupled with an adjusting device, not shown here, for example via a into a bore 42 inserted bolt.

8th to 13 show the above-described 3-ring eccentric 19 again in a little bit more detail.

How out 2 and 3 it can be seen that the arrangement is such that on one side of the printing unit 13 the cones 24 ; 26 the printing cylinder 03 ; 04 ; 06 ; 07 in the axial direction over the outside outside 45 of the insert 17 and thus also on the corresponding outside of the side frame 02 protrude. This page of the printing unit 13 is the drive side to which the drives not shown here for the rotation of Druckwerkszy soothing 03 ; 04 ; 06 ; 07 and possibly other components and possibly also a circumferential register device 72 are arranged (see. 16 ).

At the other, opposite side of the printing unit 01 stand the corresponding cones 24 ; 26 the printing cylinder 03 ; 04 ; 06 ; 07 but not before, as in particular from 2 and 14 becomes clear. On this side are eccentric actuators 43 arranged together with associated drives, by means of which the respective angular position of the eccentric rings 37 is changeable. The eccentric actuators 43 This page are in particular in 14 good to see. The two eccentric actuators shown there 43 are regarding a vertical section plane of the printing unit 13 formed mirror image and it is therefore sufficient, only one of the two eccentric actuators 43 to describe.

The eccentric actuator 43 includes a drive 49 and one around a pivot axis 44 pivotally mounted pivoting lever 46 with a first lever arm 47 that with the eccentric ring 37 of the 3-ring eccentric bearing 19 is drivingly connected, and with a second lever arm 48 that with the drive 49 , z. B. drive motor 49 , For example, a fluid drive 49 with a cylinder-piston arrangement 49 , connected is. At the second lever arm 48 is a stop arm 51 formed in the direction of the median plane of the printing unit 13 extends and Anschlagmaß with a central stop block 52 works together for both eccentric actuators 43 or their two stop arms 51 an adjustable stop, for example, for an exact pressure-on position of the transfer cylinder 06 , Are defined. The stop position is by means of the stop block 52 taken adjusting screws 53 adjustable.

The swivel lever 46 has a partially cylindrical in the case of the embodiment, in the axial direction from the outside into the through hole 23 of the insert 17 extending into coupling section 54 on, about the pivotal movement of the pivot lever 46 on the eccentric ring 37 is transferred to the effect that the eccentric ring 37 rotated by a corresponding amount and thus the associated transfer cylinder 06 is pivoted by a corresponding amount.

Around both ends of the transfer cylinder 06 to pivot synchronously is for each eccentric actuator 43 each a synchronization device 56 provided, cf. also 15 , Each synchronization device 56 includes a spindle 57 parallel to the cylinder axes of one side of the printing unit 13 to the other side of the printing unit 13 extends and at its two ends in each case a swivel arm 58 carries, whose free end in the case of in 14 illustrated printing unit page by means of a push rod 59 or a coupling 59 with the swivel lever 46 is coupled (in 14 is the push rod also on the right side 59 not shown). On the other, in 15 shown printing unit page are for synchronous adjustment of the local 3-ring eccentric 19 corresponding pivot lever 46 (including a common stop block 52 ) provided and the local pivot arms 58 are correspondingly over coupling 59 with these swivel levers 46 drivingly connected.

At least the eccentric actuators 43 the in 14 shown one side of the printing unit 01 can on the side frame 02 , but preferably on a plate-shaped carrier 61 or a carrier plate 61 be attached or stored by the side frame 02 spaced apart from the outside and on the side frame 02 for example by means of bolts 62 is releasably fixed (see. 2 ). The swivel levers 46 including stop block 52 the other side (cf. 15 ) can be used immediately 17 be stored or attached and from there via the through holes 23 of the insert 17 to the eccentric rings 37 the 3-ring eccentric bearing 19 intervention.

16 shows the drive side of the bridge printing unit 13 , so the right side in the presentation according to 2 , The cones 24 ; 26 the cylinder 03 ; 06 protrude over the outside of the insert 17 in front. On the cones 24 respectively. 26 the cylinder 03 respectively. 04 are sockets 63 ; 64 placed, which are each displaceable in the axial direction by a certain amount and their respective first, the bale 28 respectively. 29 the cylinder 03 ; 06 facing end face with the inner ring of the bearing 27 or the inner ring 34 of the 3-ring eccentric bearing 19 interact. On the second, the bale 28 respectively. 29 the cylinder 03 ; 06 opposite end face of the socket 63 respectively. 64 acts an adjustment 66 respectively. 67 , z. As a provided with a centering disc 66 respectively. 67 attached to the end face of the pin 24 respectively. 26 screwed on. Between disc 66 respectively. 67 and end face of the pin 24 respectively. 26 can spacers 68 to be ordered.

A carrier 69 in the form of a carrier plate 69 is from the side frame 02 arranged spaced apart from the outside and, for example by means of bolts 71 on the side frame 02 releasably fixed, cf. also 2 , This carrier plate 69 in particular, a circumferential register device 72 wear that over the socket 63 with the pin 24 of the forme cylinder 03 is drivingly coupled and by means of which the respective circumferential register is adjustable.

17 again shows the operating side of the bridge printing unit 13 , so the left side in the illustration according to 2 , The carrier 61 in the form of a carrier plate 61 is from the side frame 02 spaced apart from the outside and, for example, by means of bolts, not shown here 62 on the side frame 02 releasably fixed. This carrier plate 61 in particular, a thrust bearing device 73 and possibly also a page register device 74 wear. The thrust bearing device 73 is about another eccentric camp 77 in the carrier plate 61 stored, over the pin extension 76 with the pin 26 the transfer cylinder 06 coupled and fixed the axis position of the transfer cylinder 06 , By means of the side register device 74 is the axial position of the forme cylinder 03 , So its position along its axis of rotation, changeable and thus the respective correct side register of the forme cylinder 03 adjustable.

The dimensions of the components of the printing unit 13 are chosen so that in conjunction with the selected arrangement of the components with a comparatively compact overall dimensions results in a reliable and stable operation, in particular, a high rigidity of the bearing of the cylinder 03 ; 04 ; 06 ; 07 , which increases the print quality. In detail, the following dimensions or size ratios are preferably used:
With a web width l1 of the printing material web 16 of preferably 1,000 mm +/- 10% results in an axial length l2 of the bales 28 ; 29 the cylinder 03 ; 04 ; 06 ; 07 of preferably 950 mm to 1250 mm, in particular from 1000 mm to 1200 mm, for example, of 1110 mm +/- 5%. The diameter d2 of each pin 24 ; 26 the cylinder 03 ; 04 ; 06 ; 07 is preferably 55 mm to 75 mm, in particular 60 mm to 70 mm, for example 65 mm +/- 5%.

The diameter d3 of each bale 28 ; 28 the cylinder 03 ; 04 ; 06 ; 07 usually varies depending on the application and may for example be 150 mm to 250 mm, in particular 169 mm to 222 mm +/- 5% or 195 mm +/- 15%.

The 3-ring eccentric bearing 19 the transfer cylinder 06 respectively. 07 may have an outer diameter d4 of preferably 130 mm to 190 mm, in particular from 145 mm to 175 mm, for example of 160 mm +/- 5%, and an inner diameter d5 corresponding to the diameter d2 of the pins 24 ; 26 Thus, preferably 55 mm to 75 mm, in particular 60 mm to 70 mm, for example 65 mm +/- 5%. The eccentricity e of the 3-ring eccentric bearing 19 may preferably be 8 mm to 24 mm, in particular 12 mm to 20 mm, for example 16 mm +/- 10%; Furthermore, the eccentricity e of the 3-ring eccentric bearing 19 preferably 1/10 +/- 50%, in particular 1/10 +/- 25%, for example 1/10 +/- 10% of the outer diameter d4 of the 3-ring eccentric bearing 19 be. The axial length l3 of the 3-ring eccentric bearing 19 may preferably be 40 mm to 70 mm, in particular 50 mm to 62 mm, for example 56 mm +/- 5%.

The warehouse 27 of the forme cylinder 03 respectively. 04 may have an outer diameter d6 of preferably 80 mm to 120 mm, in particular from 90 mm to 110 mm, for example, of 100 mm +/- 5%, and an inner diameter d7 corresponding to the diameter d2 of the pins 24 ; 26 Thus, preferably 55 mm to 75 mm, in particular 60 mm to 70 mm, for example 65 mm +/- 5%. The axial length l4 of the bearing 27 may preferably be 35 mm to 65 mm, in particular 45 mm to 55 mm, for example 50 mm +/- 5%.

The side frame 02 or, strictly speaking, the two sides of the printing unit 01 respectively. 13 arranged frame plates 02 may have a thickness D1 of 30 mm to 100 mm, preferably of 40 mm to 80 mm, for example of 60 mm +/- 10%. The carrier plates 61 ; 69 In contrast, can be dimensioned slightly smaller according to the weaker load, preferably with a thickness D2 of 25 mm to 55 mm, in particular from 35 mm to 45 mm, for example, 40 mm +/- 5%.

At the z. In 2 on the left side of the print page 01 the distance a1 is the support plate 61 to the side frame 02 (Clear width) preferably 60 mm to 120 mm, in particular 75 to 105 mm, for example, 93 mm +/- 10%. At the in 2 on the right side of the printing unit 01 is the distance a2 of the local support plate 69 to the side frame 02 (Clear width) preferably 150 mm to 300 mm, in particular 200 to 275 mm, for example 250 mm +/- 5%.

The on both sides of the printing unit 01 arranged frame plates 02 of the side frame 02 are spaced apart by a distance a3 (clear width) of preferably 1,000 mm to 1,500 mm, in particular 1,150 mm to 1,400 mm, for example 1,280 mm +/- 5%, the distance a4 of the mutually facing sides of the bale 28 respectively. 29 and the adjacent rack plate 02 is preferably 70 mm to 100 mm, in particular 75 mm to 95 mm, for example 85 mm +/- 5%.

A preferred distance a6 (clear width) between a bale 28 ; 29 associated inside of a side frame 02 and the bale 28 ; 29 assigned inside 31 an insert held therein 17 may preferably be 60 mm to 100 mm, in particular 70 mm to 90 mm, for example 80 mm +/- 10%.

Furthermore, the axial length l5 of the insert 17 preferably 80 mm to 150 mm, in particular 100 mm to 135 mm, for example, be 120 mm +/- 10%.

So far in the above the dimensions for example, as indicated, are the measures of the illustrated preferred embodiment.

From the above it follows in particular that the bearings 27 ; 19 very close to the respective bale 28 ; 29 of the associated cylinder 03 ; 06 can be arranged, resulting in, inter alia, the aforementioned high bearing stiffness. The distance a5 between the facing sides of the bale 28 ; 29 and the associated warehouse 19 ; 27 may preferably be 5 mm to 20 mm, in particular 7.5 mm to 15 mm, for example, as shown 10 mm +/- 10%.

Accordingly, a preferred range of the ratio of axial length l2 of a bale 28 ; 28 to the distance a5 between bales 28 ; 29 and bearings 27 ; 19 in the range between 50 and 250, in particular in the range between 75 and 150 are.

Furthermore, a preferred range of the ratio of diameter d3 of a bale 28 ; 29 to the distance a5 between bales 28 ; 29 and bearings 27 ; 19 range between 8 and 40.

Furthermore, a preferred range of the ratio of an axial length l2 of the bale 28 ; 29 to the diameter d3 of the bale 28 ; 29 between 4.3 and 7.4, in particular between 5 and 6.5.

It will now be based on the 18 . 19 . 1 and 15 the drive of the H-printing unit 01 explained. As in particular from 15 becomes clear, are the printing cylinder 03 ; 04 ; 06 ; 07 the printing unit 13 each other by means of gears 78 ; 79 ; 81 ; 82 drivingly connected, as well as the printing cylinder 08 ; 09 ; 11 ; 12 the further printing unit 14 (see. 1 ) by means of the gears 83 ; 84 ; 86 ; 87 , see. 18 , For the common drive of all printing cylinders 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 the H-pressure unit 01 is a common drive motor 88 provided, which via a gear 89 , For example, a drive pinion 89 a gear 91 drives, which in turn with two other gears 92 and 93 engaged. The gear 91 can also be omitted, so that the drive pinion 89 with the gears 92 and 93 is engaged. The gear 92 stands with the gear 78 of the forme cylinder 03 and the gear 93 with the gear 86 of the forme cylinder 11 in drive connection. The gear 93 can be designed as an adjustable double wheel to the position (register) of the two double printing units 13 ; 14 adjust. The gear 92 can be used as a clutch to stop the lower double printing unit 13 be educated. The drive motor 88 can be a position and / or speed-controlled drive motor 88 be and in particular device fixed and in particular coaxial with the drive pinion 89 or to the gear 91 be arranged.

In 19 are with the reference numbers 94 and 96 Intermediate gears 94 ; 96 in the drive train between gear 91 and gears 92 and 93 designated and with the reference numeral 97 one with the gear 78 of the forme cylinder 03 intermeshing intermediate gear 97 over which the non-illustrated drive wheels of an inking unit and / or a dampening unit can be coupled.

From the 20 to 23 are the Exzenterlagen the transfer cylinder 06 ; 07 ; 08 ; 09 the H-pressure unit 01 according to 1 recognizable in the room. Shown in each case are the center MB defined by the respective center axis of the eccentric bush 19 (according to the axis 40 the through hole 23 ) and by the respective axis of rotation 41 the corresponding transfer cylinder 06 ; 07 ; 08 ; 09 defined center MZ of the cylinder in pressure-on position 06 ; 07 ; 08 ; 09 or transfer cylinder 06 ; 07 ; 08 ; 09 (corresponding to the axis of rotation 41 ), as well as the corresponding angles α, the line passing through the respective points MB and MZ 98 with the horizontal H occupies, and the angle β to the point MZ during rotation of the corresponding eccentric ring 37 the associated 3-ring eccentric 19 or the corresponding pivoting of the associated transfer cylinder 06 ; 07 ; 08 ; 09 is pivoted in the pressure-off position, ie the angle between the line 98 and the straight line 99 ,

In the case of the transfer cylinder 08 according to 20 the angle α is 28 ° and the angle β is 13 °. In the case of the transfer cylinder 09 according to 21 the angle α is 24 ° and the angle β 19 °. In the case of the transfer cylinder 06 according to 22 the angle α is 28 ° and the angle β is 13 °. In the case of the transfer cylinder 07 according to 23 the angle α is 24 ° and the angle β 19 °.

The arrangement is preferably selected overall so that when adjusting the cylinder position near the pressure-on position, a change in the axial distance of the corresponding transfer cylinder, z. B. the transfer cylinder 08 to the adjacent transfer cylinder, z. B. to the transfer cylinder 09 and a change in the axial distance of the corresponding transfer cylinder 08 to the associated form cylinder, z. B. to form cylinder 11 in a ratio of at least approx approximately 1: 1. This condition is met in the case of the embodiment described here. This condition will generally be satisfied, for example, especially if, as in 24 sketched, the center MZ of the transfer cylinder 08 and the center MB of the corresponding eccentric bushing 19 at least approximately on a straight line 98 lying vertically on an angle bisector 101 between the straight line 102 representing the center MZ with the center MF of the associated forme cylinder 11 connects and that straight line 103 , the center MZ with the center MÜ of the adjacent transfer cylinder 09 combines. Straight 98 should be with the bisector 101 preferably include an angle γ between 60 ° and 120 °, in particular an angle between 75 ° and 105 °.

The execution of the double printing unit 13 essentially also apply to the double printing unit 14 ,

01

Printing unit H-type printing unit

02

Side frame, frame panels

03

Cylinder, Printing cylinder, forme cylinder, plate cylinder

04

Cylinder, Printing cylinder, forme cylinder, plate cylinder

05

-

06

Cylinder, Printing cylinder, transfer cylinder, Rubber cylinder, impression cylinder

07

Cylinder, Printing cylinder, transfer cylinder, Rubber cylinder, impression cylinder

08

Cylinder, Printing cylinder, transfer cylinder, Rubber cylinder, impression cylinder

09

Cylinder, Printing cylinder, transfer cylinder, Rubber cylinder, impression cylinder

10

-

11

Cylinder, Printing cylinder, forme cylinder, plate cylinder

12

Cylinder, Printing cylinder, forme cylinder, plate cylinder

13

Double printing, Bridge printing unit

14

Double printing, Bridge printing unit

15

-

16

printing material

17

Commitment, Bell jar

18

Commitment, Bell jar

19

Camp, Eccentric, eccentric, eccentric, 3-ring eccentric

20

-

21

Collar ( 17 ; 18 )

22

Through Hole

23

Through Hole

24

Cones ( 03 )

25

-

26

Cones ( 06 )

27

Camp, Roller bearing, Cylindrical roller bearings

28

Bales ( 03 )

29

Bales ( 06 )

30

-

31

Inside ( 17 )

32

Rifle

33

Cover plate

34

inner ring

35

-

36

outer ring

37

eccentric

38

circlip

39

Bore, bearing bore ( 37 )

40

Axis ( 23 )

41

Rotation axis ( 26 )

42

Drilling ( 37 )

43

Eccentric actuating device

44

Pivot axis ( 43 )

45

Outside ( 17 )

46

Swivel lever ( 43 )

47

Lever arm ( 46 )

48

Lever arm ( 46 )

49

Drive, Drive motor, fluid drive, cylinder-piston arrangement

50

-

51

Stop arm ( 46 )

52

stop block

53

Adjusting screw ( 52 )

54

Coupling section ( 46 )

55

-

56

synchronizer

57

Spindle ( 56 )

58

Swivel arm ( 56 )

59

Push rod, coupling ( 56 )

60

-

61

Carrier, carrier plate

62

bolt

63

Rifle

64

Rifle

65

-

66

adjusting, disc

67

adjusting, disc

68

spacer

69

Carrier, carrier plate

70

-

71

bolt

72

Circumferential register device

73

axial bearing

74

Lateral register device

75

-

76

Zapf extension

77

eccentric

78

gear

79

gear

80

-

81

gear

82

gear

83

gear

84

gear

85

-

86

gear

87

gear

88

drive motor

89

Gear, pinion

90

-

91

gear

92

gear

93

gear

94

intermediate gear

95

-

96

intermediate gear

97

intermediate gear

98

Just

99

Just

100

-

101

bisecting

102

Just

103

Just

e

Transport direction ( 16 )

H

horizontal

e

Eccentricity ( 19 )

D1

Thickness ( 02 )

D2

Thickness ( 61 ; 69 )

MB

Focus ( 19 )

MF

Focus ( 03 ; 04 ; 11 ; 12 )

MT

Focus ( 06 ; 07 ; 08 ; 09 )

MZ

Focus ( 06 ; 07 ; 08 ; 09 )

a1

distance

a2

distance

a3

distance

a4

distance

a5

distance

a6

Distance, inside

d2

Diameter ( 24 ; 26 )

d3

Diameter ( 28 ; 29 )

d4

Outer diameter ( 19 )

d5

Inside diameter ( 19 )

d6

Outer diameter ( 27 )

d7

Inside diameter ( 27 )

l1

Web width ( 16 )

l2

Length, axial ( 28 ; 29 )

l3

Length, axial ( 19 )

l4

Length, axial ( 27 )

l5

Length, axial, thickness ( 17 )

α

angle

β

angle

γ

angle

Claims (22)

Printing unit ( 01 ) of a printing machine with two stacked double printing units ( 13 ; 14 ), wherein the end-side pin ( 24 ; 26 ) of the printing cylinder ( 03 ; 04 ; 11 ; 12 ; 06 ; 07 ; 08 ; 09 ) of a double printing unit ( 13 ; 14 ) on both sides of each insert ( 17 ; 18 ), which in turn detachably on the side frame ( 02 ) of the printing machine is arranged, characterized in that the two form cylinder ( 03 ; 04 respectively. 11 ; 12 ) at least one double printing unit ( 13 ; 14 ) with respect to their respective axis of rotation used ( 17 ; 18 ) are fixed and that the two transfer cylinders ( 06 ; 07 ; respectively. 08 ; 09 ) this at least one double printing unit ( 13 ; 14 ) with respect to their respective axis of rotation used ( 17 ; 18 ) are arranged adjustable in position. Printing unit according to claim 1, characterized in that the transfer cylinders ( 06 ; 07 ; respectively. 08 ; 09 ) each by means of an eccentric device ( 19 ) are adjustable in position with respect to their axis of rotation. Printing unit according to claim 1 and 2, characterized in that all the form cylinder ( 03 ; 04 ; 11 ; 12 ) of the H printing unit ( 01 ) with respect to their respective axis of rotation for each use ( 17 ; 18 ) are fixed and that all corresponding transfer cylinders ( 06 ; 07 ; 08 ; 09 ) by means of one in each case ( 17 ; 18 ) arranged eccentric device ( 19 ) are adjustable in position with respect to their axis of rotation. Printing unit according to claim 2 or claim 3, characterized in that the eccentric devices ( 19 ) in the corresponding inserts ( 17 ; 18 ) are arranged. Printing unit according to one of claims 2 to 4, characterized in that the eccentric devices ( 19 ) each of a 3-ring eccentric bearing ( 19 ) are formed. Printing unit according to one of the preceding claims, characterized in that the axes of the forme cylinder ( 03 ; 04 respectively. 11 ; 12 ) and the transfer cylinder ( 06 ; 07 ; respectively. 08 ; 09 ) of a double printing unit ( 13 ; 14 ) are not in a common plane. Printing unit according to claim 6, characterized in that the double printing units ( 13 ; 14 ) each as a bridge printing unit ( 13 ) or reverse bridge printing unit ( 14 ) are formed. Printing unit according to one of claims 5 to 7, characterized in that a middle eccentric ring ( 37 ) of the 3-ring eccentric bearing ( 19 ) with an eccentric actuator ( 43 ) is drivingly connected. Printing unit according to one of the preceding claims, characterized in that a clear distance (a5) between a bale ( 28 ; 29 ) of a cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) and the opposite bearing ( 19 ; 27 ) of the cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) between 5 mm and 20 mm, preferably between 7.5 mm and 15 mm, ins special at 10 mm +/- 10%. Printing unit according to claim 1 or 9, characterized in that the ratio of an axial length l2 of a bale ( 28 ; 29 ) of a cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) to the distance (a5) between bales ( 28 ; 29 ) and bearings ( 19 ; 27 ) is greater than 16, preferably greater than 40. Printing unit according to claim 9 or 10, characterized in that the ratio of a diameter d3 of the bale ( 28 ; 29 ) of a cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) to the distance (a5) between bales ( 28 ; 29 ) and bearings ( 19 ; 27 ) is in the range between 8 and 40. Printing unit according to one of the preceding claims, characterized in that the ratio of an axial length l2 of the bale ( 28 ; 29 ) of a cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) to the distance (a5) between bales ( 28 ; 29 ) and bearings ( 19 ; 27 ) is in the range between 50 and 250, in particular in the range between 75 and 150. Printing unit according to one of the preceding claims, characterized in that the ratio of the axial length l2 of the bale ( 28 ; 29 ) of a cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) to the diameter of the bale ( 28 ; 29 ) of the cylinder ( 03 ; 04 ; 06 ; 07 ; 08 ; 09 ; 11 ; 12 ) is between 4.3 and 7.4, in particular between 5 and 6.5. Printing unit according to one of claims 2 to 13, characterized in that when adjusting the axial position of a transfer cylinder ( 06 ; 07 . 08 . 09 ) near a pressure-on position of this transfer cylinder ( 06 ; 07 . 08 . 09 ) a change in the distance of the axis of this transfer cylinder ( 06 ; 07 . 08 . 09 ) to the axis of the adjacent transfer cylinder ( 06 ; 07 . 08 . 09 ) and a change in the distance of the axis of this transfer cylinder ( 06 ; 07 . 08 . 09 ) to the axis of this transfer cylinder ( 06 ; 07 . 08 . 09 ) associated with the form cylinder ( 03 ; 04 ; 11 ; 12 ) in a ratio of at least approximately 1: 1. Printing unit according to claim 14, characterized in that the center (MZ) of the transfer cylinder ( 06 ; 07 . 08 . 09 ) and the center (MB) of the corresponding eccentric bush ( 19 ) at least approximately on a straight line ( 98 ) which is perpendicular to an angle bisector ( 101 ) between the line ( 102 ), the center (MB) of the eccentric bush ( 19 ) with the center (MF) of the associated forme cylinder ( 03 ; 04 ; 11 ; 12 ) and that line ( 103 ), the center (MB) of the eccentric bush ( 19 ) with the center (MT) of the adjacent transfer cylinder ( 06 ; 07 . 08 . 09 ) connects. Printing unit according to claim 15, characterized in that the center (MZ) of the transfer cylinder ( 06 ; 07 . 08 . 09 ) and the center (MB) of the eccentric bush ( 19 ) containing straight line ( 98 ) with the bisector ( 101 ) includes an angle (γ) between 60 ° and 120 °. Printing unit according to claim 16, characterized that the angle (γ) in a range between 75 ° and 105 °. Printing unit according to claim 2, characterized in that the bearing ( 19 ) a 3-ring eccentric bearing ( 19 ). Printing unit according to claim 18, characterized in that the 3-ring eccentric bearing ( 19 ) comprises two bearings, between which a rotatable eccentric ring ( 37 ) with eccentric bearing bore ( 39 ) is arranged. Printing unit according to claim 18 or 19, characterized in that the 3-ring eccentric bearing ( 19 ) Includes rolling bearing. Printing unit according to one of claims 18 to 20, characterized in that the cylinder ( 06 ; 07 ; 08 ; 09 ) with another cylinder ( 03 ; 04 ; 11 ; 12 ) cooperates, the axial position with respect. Of the side frame ( 02 ), ie is not adjustable in the radial direction. Printing unit according to one of claims 18 to 21, characterized in that the 3-ring eccentric bearing ( 19 ) in a mission ( 17 ; 18 ), which in turn is releasably attached to a side frame ( 02 ) of the rotary printing machine is arranged.