EP1508441B1 - Rotary printing machine and former folder. - Google Patents

Abstract

Printing group (01) comprises a form cylinder (03) and an inking system (02) assigned to the form cylinder. The form cylinder has in the area of its barrel an axial length corresponding to six widths of a printed page. The form cylinder and the inking system are rotationally driven by mechanically independent drive motors (08, 17). Independent claims are also included for alternative printing groups. Preferred Features: The form cylinder and a transfer cylinder (07) are rotationally driven by at least one drive motor mechanically independently of another printing group.

Description

The invention relates to a web-fed rotary printing press according to the preamble of claim 1.

The DE 25 28 008 A1 shows a printing machine for a direct printing method with form cylinders, which can be equipped in the axial direction with six and in the circumferential direction with two printing plates, and counterpressure cylinders, which are assignable in the axial direction three and in the circumferential direction with a pressure felt. Both the pressure plates arranged next to one another and the pressure felts arranged next to one another are offset relative to each other in the circumferential direction.

Also the DE 25 10 057 A1 discloses a printing machine with direct printing method, wherein the cooperating with a counter-pressure cylinder form cylinder carries six on its width and on its circumference two printing plates.

By the JP 56-021860 A is a printing unit with form, transfer and impression cylinder known, each of the three cylinders is driven by its own drive motor.

By the DE 41 28 797 A1 is a triple-width web-fed rotary printing press with two on two different, superimposed planes arranged formers known.

From "Newspapers &Technology", December 2000, a printing press with six newspaper-wide printing units is known. The printing units are designed as bridge printing units, wherein the transfer cylinder with blanket sleeves are occupied.

The WO 01/70608 A1 discloses a turner bar assembly, wherein two substantially part-wide turning bars are each arranged displaceably on a carrier transversely to the direction of the incoming partial web. In each case laterally outside of the side frame, a register roller is arranged, whose longitudinal axis extends substantially parallel to the side frame and which is also displaceable along a rail in a direction transverse to the direction of the incoming partial web.

From the US 4,671,501 A a Falzaufbau is known, wherein two formers are arranged one above the other, the webs after passing through casserole rolls in front of a third funnel cut longitudinally, the sub-webs over a third funnel rotated by 90 ° and then combined into two strands of the two superposed funnels ,

By the EP 10 72 551 A2 is a folding structure with two vertically offset groups of formers known. Above each of the groups of formers is a harp, ie a group of collection, acceptance or Harfenwalzen arranged over which the respective partial webs of the associated group of formers are fed.

In the WO 97/17200 A2 a folding structure is known, according to which cut, transversely offset to each other part webs are fed to different formers. The horizontally juxtaposed former are z. T. vertically offset from each other.

The DE 44 19 217 A1 shows a superstructure of a web-fed rotary printing press with a turning device, wherein partial webs are offset by half a partial web width, to guide them over each other and feed a common former.

In the DE 100 16 409 A1 a six page wide bending machine and a three-cylinder printing unit is disclosed. The assignment of the transfer cylinder with blankets is alternating The opening in the area of the lateral surface has z. B. a width in the circumferential direction between 1 and 3 mm.

The DE 198 03 809 A1 D1 discloses a printing unit for four pages in newspaper format or for more, e.g. B. six or eight, juxtaposed printed pages in book format.

The DE 101 20 134 A1 discloses four printing form sections side by side and each section of a segment independent of the other segment for pressing or holding a lift.

The DE 24 22 696 A1 discloses a nine cylinder satellite printing unit in the embodiment of a six plate wide machine.

By Wolfgang Walenski, "The web offset printing", 1995, is in a leaflet between pages 96 and 97, a web offset newspaper printing machine u.a. disclosed with two sections each having at least two printing towers of stacked satellite printing units. Between these two sections, two folding structures are arranged, each with funnels arranged on superimposed planes.

The Ifra newspaper technology, 09/91. Pages 150, 152, 154, 156, 158, "6-Plate Wide Newspaper - History and Facts" discloses a schematic representation of a six-page wide eight-unit machine line with a folder assembly indicated therebetween. Two of the units have a nine-cylinder satellite printing unit with four pairs each of a transfer cylinder and an associated form cylinder. In connection with a six Newspaper pages wide and four pages in the scope 4x6-containing machine, the inlet of a six-page wide web is shown in three juxtaposed former.

By the DE 198 33 470 A1 are superimposed satellite printing units disclosed, wherein in one mode, a satellite cylinder with four, and in another mode two satellite cylinder with two transfer cylinders together or act.

The DE 44 30 693 A1 discloses a variety of possible drive variants for a wide variety of printing unit designs, namely bridge, six-cylinder, H and satellite printing units. In a printing press with functional units once H-printing units and once six-cylinder printing units are arranged stacked.

The invention has for its object to provide a web-fed rotary printing press.

The object is achieved by the features of claim 1.

The achievable with the invention advantages are in particular that a simple, inexpensive and space-saving design with high variability in the product or intermediate product is made possible.

In particular, there are also advantages in that, compared with a double-width printing press, production reliability is considerably increased at the same target strength of a product to be achieved. While maintaining the number of printing units but also the output of the printing press, or each printing unit can be increased by 50%.

The number of reelstands (investment), the frequency of reel changes (production safety) and the set-up time when webs are drawn in (cycle times) can be reduced compared to a double-width press for the same product thickness.

In an advantageous embodiment, the printing units are designed as nine-cylinder satellite printing units, which on the one hand has a high precision in the color register and on the other hand a low-vibration construction result. Vibrations are also reduced by the advantageous arrangement, design and mounting of lifts on the cylinders. On the one hand, openings on the lateral surfaces in the circumferential direction are minimized. Furthermore, at least on the transfer cylinder, the openings may be arranged alternately offset in the circumferential direction, that acts at least on a section length always a closed lateral surface with the forming or satellite cylinder together. Third, roundness and manufacturing costs are minimized by the fact that although the bales are provided on its entire effective length axially passing channels, but openings exist to the lateral surface only in the said sections. In the channels then z. B. optionally used devices for attachment of elevator ends and / or patches.

In the channel or in the channels of the forme cylinder, in each case at least six devices for the axial positioning of printing plates are arranged in the axial direction. These are z. B. designed as a form-fitting with pressure forming ends cooperating register pins which are arranged axially movable manually or remotely operable within the channel.

The execution of the printing units with associated pressing devices is advantageous in terms of a register-accurate or register-accurate reproducible equipping the form cylinder with printing plates. It can be fixed with these resting on the lateral surface of the cylinder lifts by at least one pressing element as needed, while one end of an elevator or more elevators for removal or assembly is released or are.

The mechanically independent of the cylinder pairs drive the (or the) satellite cylinder has particular advantages in terms of the possibility of variable operation. For example, during production, a setup, z. As a flying printing form change or washing done. Conversely, a web can be retracted while other cylinders or pairs of cylinders are standing or undergoing a set-up program. Also, it is advantageous to operate in the presence of rubber blankets with positive or negative promotional properties, the satellite cylinder with a different surface speed of the other cylinders.

In an advantageous embodiment, a superstructure of the printing press has at least one longitudinal cutting device with at least five knives spaced apart from one another transversely to the direction of travel of the paper. In an advantageous embodiment, each printing tower (or eight printing locations) is provided with two register devices movable transversely to the direction of travel of the paper to compensate for paths of the partial webs. These can structurally connected in each case with a part-web-wide turning devices be. Also subsequent, only partial webs associated guide elements are z. B. executed essentially only partial web width substantially. These designs allow a low-vibration, and thus tailor-made transport of the web. By inertia long, strong, caused only by the sub-web (s) guide elements caused web tension fluctuations (for example, load changes, change in printing speed) can be effectively reduced.

With regard to a reliable operation and a cost-saving design, it is also advantageous to provide in the superstructure the possibility of turning a partial web by an odd multiple of half a partial web. Thus, a retraction and printing of partial webs with half a funnel width (eg a newspaper page) can be omitted.

In terms of cost and space-saving design, it is in an embodiment of advantage, only one of two stacked formers a so-called. Harp, d. H. several i. d. R. ungetriebe Auflaufwalzen, vorzuordnen. On the other former, webs from the harp can be transferred. The two vertically stacked formers can be supplied from the same escape of superimposed sub-webs strands of variable thickness or partial web number.

In one embodiment, sub-webs from one of a funnel group associated harp of the other funnel group can be acted upon and vice versa. In an advantageous embodiment, only one of two stackers arranged one above the other is a so-called harp, ie a plurality of generally idle rollers (also called collection or take-off rollers). On the other formers then tracks from the common harp can be transferred. The two vertically stacked formers can be supplied from the same escape of superimposed sub-webs strands of variable thickness or partial web number.

In an advantageous embodiment of a turning device, the partial web is displaceable or offset only by an odd multiple of half the partial web width. So it can be z. B. avoid with little effort to print very narrow webs or provide additional printing units. The transversely movable to the web execution at least one of the turning bars allows a high variability.

The mechanically independent of the printing units drive rollers of the hopper structure and / or the folding apparatus is particularly advantageous in terms of a good registration and a variable operation.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below.

Fig. 1

eine Rollenrotationsdruckmaschine in Seitenansicht;

Fig. 2

eine schematische Vorderansicht auf ein Druckwerk;

Fig. 3

eine schematische Draufsicht auf ein Druckwerk;

Fig. 4

einen Aufzug in perspektivischer Darstellung;

Fig. 5

einen Formzylinder; a: in perspektivischer Darstellung, b: im Längsschnitt, c: ein Halteelement, d: ein Halteelement mit Registereinrichtung;

Fig. 6

einen Übertragungszylinder; a: in perspektivischer Darstellung, b: im Längsschnitt, c: ein Halteelement, d: ein Füllelement;

Fig. 7

eine Vorrichtung zum Andrücken eines Aufzugs an einen Zylinder;

Fig. 8

ein erstes Ausführungsbeispiel für den Antrieb einer Neunzylinder-Satelliten-Druckeinheit;

Fig. 9

ein zweites Ausführungsbeispiel für den Antrieb einer Neunzylinder-Satelliten-Druckeinheit;

Fig. 10

ein drittes Ausführungsbeispiel für den Antrieb einer Neunzylinder-Satelliten-Druckeinheit;

Fig. 11

eine Ausführungsform des Ausführungsbeispiels gemäß Fig. 8;

Fig. 12

eine Übersicht über einen Überbau;

Fig. 13

ein erstes Ausführungsbeispiel einer kurzen Registereinrichtung;

Fig. 14

ein zweites Ausführungsbeispiel einer kurzen Registereinrichtung;

Fig. 15

ein Beispiel für eine Bahnwendung;

Fig. 16

eine Vorderansicht der Harfe mit gewendeter Bahn nach Fig. 15;

Fig. 17

einen Falzaufbau einer Rollenrotationsdruckmaschine;

Fig. 18

eine Seitenansicht des Falzyufbaus mit Bahnführung;

Fig. 19

eine Vorderansicht des Falzaufbaus mit Bahnführung.

Show it:

Fig. 1

a web-fed rotary printing press in side view;

Fig. 2

a schematic front view of a printing unit;

Fig. 3

a schematic plan view of a printing unit;

Fig. 4

an elevator in perspective view;

Fig. 5

a form cylinder; a: a perspective view, b: a longitudinal section, c: a holding element, d: a holding element with register device;

Fig. 6

a transfer cylinder; a: a perspective view, b: a longitudinal section, c: a holding element, d: a filling element;

Fig. 7

a device for pressing an elevator to a cylinder;

Fig. 8

a first embodiment for driving a nine-cylinder satellite printing unit;

Fig. 9

a second embodiment for driving a nine-cylinder satellite printing unit;

Fig. 10

a third embodiment for driving a nine-cylinder satellite printing unit;

Fig. 11

an embodiment of the embodiment according to Fig. 8 ;

Fig. 12

an overview of a superstructure;

Fig. 13

a first embodiment of a short register device;

Fig. 14

a second embodiment of a short register device;

Fig. 15

an example of a web turn;

Fig. 16

a front view of the harp with reversed track behind Fig. 15 ;

Fig. 17

a folding structure of a web-fed rotary printing press;

Fig. 18

a side view of Falzyufbaus with web guide;

Fig. 19

a front view of the folding structure with web guide.

In the Fig. 1 The web-fed rotary printing press shown by way of example has a left and a right section, each having at least two printing towers 01. The printing towers 01 have printing units 02, which z. B. at least three times wide, ie for the printing of six axially juxtaposed newspaper pages executed. The printing units 02 are designed as satellite printing units 02. The advantageous embodiment of the printing units 02 as nine-cylinder satellite printing units 02 ensures a very good Passerhaltigkeit or a low fan-out. However, the printing units 02 can also be used as ten-cylinder satellite printing units 02 or, if appropriate, also as printing units that can be operated in rubber-against-rubber printing, such as, for. B. be executed a plurality of bridge printing units or a H-printing unit 02. The printing units 02 are webs 03 supplied by rollers, not shown, in particular using reel changers.

Downstream of the printing towers 01 or printing units 02 continuous web 03, here above the printing towers 01, a superstructure 04 is provided for each section, in which the web 03 or webs 03 cut on longitudinal cutting devices 06, sub-webs by means of turning devices 07 possibly offset and / or crashed, by means of in Fig. 1 only indicated register devices 08 are aligned in the longitudinal register to each other and can be performed one above the other. Seen downstream of the web running direction, the superstructure 04 has at least one so-called harp 09 with a number of superimposed webs 03 or part webs 03a; 03b; 03c leading harp or caster rollers. The harp 09 determines the funnel inlet of the superimposed tracks 03. About this harp 09, the tracks 03 undergo a change in direction and are subsequently summarized either as a strand or as multiple strands and fed to at least one folding structure 11.

In the example, two Falzaufbauten 11 are arranged between the sections, which z. B. each have arranged on two different superposed planes folding former. However, the printing machine can also only a common, between the sections arranged folding structure 11, or only have a section and an associated folding structure 11. Also, the respective folding structure 11 may be performed with only one level of formers. Each folder assembly 11 are associated with one or more folders 12.

The printing unit 02 has several, in the example four, printing units 13, by means of which ink can be applied to the web 03 by an inking unit 14 via at least one cylinder 16 designed as a forme cylinder 16 ( Fig. 2 ). In the present example, for an embodiment of the printing unit 02 as a satellite printing unit 02, the printing unit 13 is designed as offset printing unit 13 for the wet offset and has in addition to the inking unit 14, a dampening unit 20 and another cylinder 17 designed as a transfer cylinder 17. The transfer cylinder 17 forms a pressure point with an abutment-forming impression cylinder 18. In the example of Fig. 1 the printing cylinder 18 is designed as a satellite cylinder 18, which forms further pressure points with further transfer cylinders 17 further printing units 13 in the print-on position. The printing cylinder 18 could also be designed as a transfer cylinder 18 in the formation of the printing units as a double printing unit in the rubber counter-rubber pressure. The same parts are given the same reference numerals, as far as they are not necessary for differentiation. However, a difference in the spatial position may exist and, in the case of the assignment of the same reference numbers, is generally disregarded.

The inking unit 14 has, in an advantageous embodiment, an ink fountain 15 extending over six print pages. In another embodiment, three each color about two pages wide ink boxes 15 are arranged side by side in the axial direction. The dampening unit 20 is designed in an advantageous embodiment as vierwalziges spray dampening 20.

The form cylinder 16 has in a first embodiment z. B. a circumference between 850 and 1,000 mm, in particular from 900 to 940 mm. The scope is z. B. for recording two stationary printed pages, z. As newspaper pages in broadsheet format, by means of two in the circumferential direction on the forme cylinder 16 successively fixable elevators 19, z. B. flexible printing plates 19, is formed. The printing plates 19 are mounted in the circumferential direction on the forme cylinder 16 and in the in Fig. 3 shown embodiment as each in the axial direction with a printed side stocked single pressure plate individually interchangeable.

The length L16 of the usable bale of the forme cylinder 16 is in the first embodiment z. B. 1,850 to 2,400 mm, in particular 1,900 to 2,300 mm and is in the axial direction for receiving z. B. at least six juxtaposed standing printed pages, especially newspaper pages in broadsheet format, measured (see Fig. 3 Sections A to F). Among other things, it depends on the nature of the product to be produced, whether in each case only one pressure side or several pressure sides in the axial direction are arranged side by side on a printing plate 19. In an advantageous broader variant of the first embodiment, the length L16 of the usable bale is between 2,000 and 2,400 mm.

In a second embodiment, the forme cylinder 16 has z. B. a circumference between 980 and 1300 mm, in particular from 1000 to 1200 mm. The length L16 of the usable bale is in this case z. B. 1,950 to 2,400 mm, in particular 2,000 to 2,400 mm. The occupancy corresponds to the o. G. Execution.

The transfer cylinder 17 also has a circumference z in the first embodiment. B. between 850 and 1,000 mm, in particular from 900 to 940 mm. The length L17 of the usable bale of the transfer cylinder 17 is in the first embodiment z. B. 1,850 to 2,400 mm, in particular 1,900 to 2,300 mm and is in the longitudinal direction of each other z. B. with three elevators 21, z. B. blankets 21, occupied (sections AB to EF). They extend in the circumferential direction substantially to the full extent. The blankets 21, the vibration behavior of the printing unit 13 in the case of operation favorably influencing, alternating, z. B. by 180 °, to each other ( Figure 3 ) arranged. In the wider version of the first embodiment, the length L17 of the usable bale is also between 2,000 and 2,400 mm.

In the second embodiment, the transfer cylinder has 17 z. B. a circumference between 980 and 1300 mm, in particular from 1000 to 1200 mm. The length L17 of the usable bale is in this case z. B. 1,950 to 2,400 mm, in particular 2,000 to 2,400 mm. The occupancy of elevators 21 corresponds to the first embodiment.

Diameter of bales of cylinders 16; 17 are in the first o. G. Execution z. B. from 270 to 320 mm, in particular from about 285 to 300 mm. In the second o. G. Execution is the diameter of bales of the cylinder 16; 17 z. B. from about 310 to 410 mm, in particular from 320 to about 380 mm. A ratio of a length of the usable bale of the cylinders 16; 17 to the diameter should be 5.8 to 8.8, z. B. at 6.3 to 8.0, in a wide version, especially at 6.5 to 8.0.

As length L16; L17 of the usable bale here is to be understood that width or length of the bale, which for receiving elevators 19; 21 is suitable. This corresponds approximately to a maximum possible web width of a web to be printed 03. Based on an entire length of the bale of the cylinder 16; 17 would be L16 to this length; L17 of the usable bale nor the width of any existing Schmitzringen, possibly existing grooves and / or possibly existing lateral surface areas added, which z. B. to operate clamping and / or clamping devices must be accessible.

In an advantageous embodiment, the satellite cylinder 18 also substantially the dimensions and ratios of at least the associated transfer cylinder 17 substantially.

Elevators 19; 21 are like in Fig. 4 shown schematically z. B. as flexible plates executed, wherein the designed as a blanket 21 elevator 21 as a so-called. Metal blanket 21 with an arranged on a support plate 23 elastic and / or compressible layer 22 (dashed lines) is executed (in Fig. 4 are the alone the metal blanket 21 reference numerals connected by dashed lines). A plate-shaped printing plate 19 and a support plate 23 for a rubber blanket is usually made of a flexible, but otherwise dimensionally stable material, for. B. of an aluminum alloy, and has two opposite, in or on the cylinder 16; 17 to be fastened ends 24; 26 with a material thickness MS of z. B. 0.2 mm to 0.4 mm, preferably 0.3 mm, said ends 24; 26 for training as suspension legs 24; 26 each along a bending line with respect to the extended length I of the elevator 19; 21 by an angle α; β are bent between 40 ° and 140 °, preferably 45 °, 90 ° or 135 ° ( Fig. 4 ). A leading end 24 is, for example, at an acute angle α of 40 ° to 50 °, in particular 45 °, and a nachaufendes end 26 at an angle β of 80 ° to 100 °, in particular 90 °, folded. When in the circumferential direction of the cylinder 16; 17, in particular of the transfer cylinder 17, only a single elevator 21 is applied, the length I of the elevator 21 corresponds approximately to the circumference of this cylinder 17th

Basically, the folded ends 24; 26 of the elevators 19; 21 each in a on the circumference of the respective cylinder 16; 17 longitudinally axially parallel, slot-shaped opening can be inserted, wherein the ends 24; 26, for example, be held by their shape, friction or deformation. However, they can also be fixed by means of spring force, by pressure medium or an effective during operation centrifugal force operable means. The slot-shaped openings for axially juxtaposed pressure plates 19 on the forme cylinder 16 are in an advantageous embodiment in each case in alignment, z. B. as a continuous slot-shaped opening (as described below), arranged, while the openings for the juxtaposed on the transfer cylinder 17 blankets 21 are not continuous, but offset from one another in the circumferential direction by 180 °.

Fig. 5a and b ) In a perspective view of an example of an advantageous embodiment of the forme cylinder 16. In the cylinder 16 two channels 27 are provided, both channels 27 throughout in the axial direction of the cylinder 16 at least over the entire length of the six sections A to F in the bale extend ( Fig. 5b ). They are in the circumferential direction of the cylinder 16 z. B. offset by 180 ° to each other. The arranged below a lateral surface 30 in the interior of the cylinder 16, z. B. as circular holes running channels 27 have, at least over the length of the six sections A to F a narrow, slot-shaped opening 28 to the lateral surface 30 of the cylinder 16 on ( Fig. 5a ). A slot width s16 of the opening 28 on the forme cylinder 16 in the circumferential direction is less than 5 mm and is preferably in the range of 1 mm to 3 mm (FIG. Fig. 5c ).

The folded ends 24; 26 of the printing plate 19 are now each in one of the circumferentially axially parallel openings 28 can be inserted and are, at least the trailing end 26, fixed by a arranged in the channel 27 holding device 29, 31.

The holding device 29, 31 here has at least one clamping piece 29 and a spring element 31 ( Fig. 5c ). The not shown right angle beveled trailing suspension legs 26 (see Fig. 4 ) preferably abuts against a wall of the opening 28 that is essentially completely shaped for bending and is pressed there by the clamping piece 29 by a force exerted by the spring element 31 on the clamping piece 29. The acute angle beveled leading suspension leg 24, not shown, (see Fig. 4 ) preferably abuts a wall of the opening 28 that is substantially complementary to the fold and that forms a hooked edge or nose with the jacket surface 30 at an acute angle α 'of 40 ° to 50 °, in particular 45 °. To release the clamping of the trailing end 26, an adjusting means 32 is provided in the channel 27, which at counteracts its operation of the force exerted by the spring element 31 on the clamping piece 29 force and the clamping piece 29 pivots away from the wall or the end 26.

In an advantageous embodiment, in each channel 27 not only a clamping piece 29, but over the length of the sections A to F axially adjacent a plurality of clamping pieces 29 in the manner of segments each having at least one spring element 31 is arranged (in Fig. 5a from the cylinder 16 "pulled out" shown). In the embodiment, each section A to F more, z. B. six, such clamping pieces 29 according to Fig. 5c arranged, wherein in the middle between the clamping elements 29 of each section A to F, here between the third and the fourth clamping element 29 of each section A to F, in each case a registration stone 35 exhibiting Passerelement 33 (FIGS. Fig. 5d ) is arranged. The register stone 35 or Passerstift 35 z. B. in a groove of a base 34 in the axial direction manually displaced and adjustable. The index block 35 can in unillustrated development also via axially guided in a vacant cavity of the channel 27 and the fitting element 33 actuator z. B. a motor-driven threaded spindle, be axially movable.

The actuating means 32 is designed in the illustrated embodiment such that when actuated the holding device (s) 29, 31, ie all the clamping pieces 29, are simultaneously closed or loosened over the length of the sections A to F. The adjusting means 32 is as in Fig. 5a from the cylinder 16 "pulled out" represented as at least over the length of the sections A to F reaching, axially extending in the channel 27 and actuated by pressure reversibly deformable hollow body 32, z. B. as a hose 32, executed. This hose 32 is according to Fig. 5c with the clamping pieces 29 acting together in the channel 27 arranged so that it counteracts the self-locking the holding device closing spring elements 31 upon actuation. Through the areas of passer elements 33 it is passed ( Fig. 5d ).

Fig. 6a and b ) shows in a perspective view an example of an advantageous embodiment of the transfer cylinder 17. The cylinder 17 has two channels 36; 37 provided, wherein both channels 36; 37 continuously in the axial direction of the cylinder 17 at least over the entire length of the six sections A to F and three sections AB; CD; EF, in bale stretch ( Fig. 6b ). They are in the circumferential direction of the cylinder 17 z. B. offset by 180 ° to each other.

The two arranged below a lateral surface 40 in the interior of the cylinder 17, z. B. as circular holes running channels 36; 37, have a total of z. B. three, each axially extending, at least in each case over the length of a section AB; CD; EF reaching narrow, slot-shaped openings 38; 39; 41 to the lateral surface 40 of the cylinder 17 towards ( Fig. 6a ). Two of the three openings 38; 39 are in communication with the same channel 36 and are aligned with each other in the axial direction, but spaced from each other on the lateral surface 40. Axial between the two openings 38; 39 is a the shape of the remaining lateral surface 40 weiteretzender, insbesonderer undisturbed section U without opening. The two aligned, z. B. with the same channel 36 communicating openings 38; 39 are preferably the face-side openings 38; 39, wherein the third opening 41 extends axially at least over the central gate CD and offset by 180 ° to the other openings 38; 39 is arranged. A slot width s17 of the uncovered opening 38; 39; 41 on the transfer cylinder 17 in the circumferential direction is less than 5 mm in each case and is preferably in the range of 1 mm to 3 mm ( Fig. 6c ). For manufacturing purposes, in each case at one or at two of the ends of the slots 38; 39; 41 radially extending holes 42 may be provided, which is closed or closed in the operating state of the cylinder 17 by means of a plug, not shown ( Fig. 6b ). The plug has an outer surface which continues the otherwise cylindrical contour of the cylinder 17 in the mounted state in the region of the bore 42. In the circumferential direction of the cylinder 17 in a section perpendicular to the axis of rotation in an advantageous embodiment only one of the openings 38; 39; 41 or one the shortened by the plug opening 38; 39; 41 arranged one behind the other. In this section, the openings 38 thus overlap; 39; 41 or shortened by the plug opening 38; 39; 41 not.

The folded ends 24; 26 of the blanket 21 are now each in one of the circumferentially axially parallel openings 38; 39; 41 inserted and are, at least the trailing end 26, respectively by at least one in the channel 36; 37 arranged holding device 43, 44 fixable. Preferably, the two ends 24; 26 of the same blanket 21 through the same opening 38; 39; 41 in the same channel 36; 37 led.

The holding device 43, 44 has here in each case at least one clamping piece 43 and a spring element 44 (FIG. Fig. 6c ). The not shown right angle beveled trailing suspension legs 26 (see Fig. 4 ) preferably arrives at a wall of the opening 38 that is substantially complementary to the fold; 39; 41 to the system and is pressed there by the clamping piece 43 by a force exerted by the spring element 44 on the clamping piece 43 force. The acute angle beveled leading suspension leg 24, not shown, (see Fig. 4 ) preferably arrives at a wall of the opening 38 that is substantially complementary to the fold; 39; 41, which forms a hooking edge or nose at an acute angle α 'of 40 ° to 50 °, in particular 45 ° with the lateral surface 40, to the plant. To release the clamping of the trailing end 26 is in the channel 36; 37 at least one actuating means 46; 47; 48 is provided, which counteracts the force exerted by the spring element 44 on the clamping piece 43 in its operation force and the clamping piece 43 pivots away from the wall. Advantageously, for each of the three openings 38; 39; 41 in each associated channel 36; 37 at least one actuating means 46; 47; 48 provided (in Fig. 6a from the cylinder 17 "pulled out" shown).

In an advantageous embodiment, in each channel 36; 37 not just a clamping piece 43, but are about the length of sections AB; CD; EF axially next to each other a plurality of clamping pieces 43 as individual segments, each with at least one spring element 44 arranged (in Fig. 6a from the cylinder 17 "pulled out" shown). In the exemplary embodiment, each section AB; CD; EF and per opening 38; 39; 41 several, z. B. ten, such clamping pieces 43 according to Fig. 6c arranged. In sections AB; CD; EF of the respective channel 36; 37, which have no opening to the lateral surface 40, instead of the holding device 43, 44 or the holding devices 43, 44 at least one filling element 49 (FIG. Fig. 6d ) in the channel 36; 37 arranged. In the example, several, z. B. eleven, this filling elements 49 as individual segments in the relevant, no opening having section AB; CD; EF of the channel 36; 37 arranged. Centered between the retainers 43, 44 of each section AB; CD; EF, ie in the region between the sections A and B or E and F, here between the fifth and sixth clamping element 43, can also each have a filling element 49 (FIG. Fig. 6d ) can be arranged. The filling element 49 has substantially the cross section of the channel 36; 37 imitated cross-section and at least one axially continuous opening 51, through which a means for the actuating means 46; 47; 48 is feasible.

The adjusting means 46; 47; 48 is designed in the illustrated embodiment such that when actuated the holding means 43, 44 of a section AB; CD; EF, ie all clamping pieces 43 of a section AB; CD; EF, simultaneously closed or solved. The adjusting means 46; 47; 48 is in Fig. 6a from the cylinder 17 "pulled out" shown. In the channel 36 (with two openings 38, 39) in each case an adjusting means 46 extends at the front side; 47 over at least the corresponding length of the section AB; EF. The middle opening 41 associated adjusting means 48 also extends over at least the corresponding length of the associated portion CD. However, it may also extend at least on one side to the front side of the cylinder 17, if it is advantageous for a supply of resources ( Fig. 6a ). The adjusting means 46; 47; 48 are each as axially in the channel 36; 37 extending and actuated by pressure medium reversibly deformable hollow body 46; 47; 48, z. B. as a hose 46; 47; 48, executed. This hose 46; 47; 48 is according to Fig. 6c with the clamping pieces 43 so cooperating in the channel 36; 37 arranged to counteract the self-locking the holding device 43, 44 closing spring elements 44 when actuated. Through the regions of filling elements 49 to be passed, it is passed through this or its opening 51 ( Fig. 6d ).

In another embodiment of the channels 36; 37, these can also not be carried out continuously over the entire length. For example, in the area of each section AB; CD; EF one channel 36 each; 37, possibly provided with a corresponding holding device, wherein the channel 37 of the central elevator 21 is offset from the two outer by 180 °. This is in 6E indicated only schematically.

In a particularly in connection with the six pages wide printing units 02 and cylinders 16; 17 advantageous embodiment is at least two cylinders 16; 17, in particular two forme cylinders 16, at least one of the printing towers 01 each have a device 52 for pressing an elevator 19; 21 to a cylinder 16; 17, in particular a printing plate 19 to the forme cylinder 16, (hereinafter Andrückvorrichtung 52) assigned. This is z. B. advantageous if in two corresponding printing units 13 a faster, z. B. flying plate change to be made. In particular, it is advantageous for a fast, safe and exact product change if all of the forme cylinders 16 of a printing tower 01 are assigned such a pressing device 52. A corresponding pressing device 52 has one or more pressing elements 53; 54, z. B. strips, plungers or rolling elements 53; 54, which, which and / or to one or more elevators 19; 21 is either adjustable or are. As a result, a controlled and guided pulling or clamping and / or detachment or removal of the elevator 19; 21 allows. It is also possible, an end 24; 26 of the elevator 19; 21 in the corresponding channel 27; 36; 37 and the opening 28; 38; 39; 41 to move in or a loosened end 24; 26 and the partially released elevator 19; 21 down in a desired position. The pressing device 52 extends along the cylinder 16; 17 at least in the entire range of sections A to F, ie in the effective for printing area of the bale.

In the Fig. 7 described embodiment of the pressing device 52 is in particular also in conjunction with in Fig. 5 described embodiment of the reaching across all sections A to F common actuator 32 advantage. In this constellation, a single or group-wise mounting, changing and / or removing is also possible for six next to each other on the forme cylinder 16 arranged printing plates 19, without having to take place within the forme cylinder 16 an increased amount of controls or equipment supply. The manufacturing, assembly and maintenance simplifies considerably.

The pressing device 52 has sections A to F (in the case of six elevators 19 arranged next to each other) or section AB; CD; EF (in three juxtaposed elevators 21) at least a first pressure element 53, z. B. rolling element 53, on. In an advantageous embodiment according to Fig. 7 it has sections A to F and section AB respectively; CD; EF in a circumferential direction of the cylinder 16; 17 spaced from this first rolling element 53 second pressing element 54, z. B. rolling element 54, on. In Fig. 7 in the case of the forme cylinder 16, only central portions B, C and D and the rolling elements 53 associated with these portions B, C and D are; 54 is shown. Each section A to F or AB to EF is a first rolling element 53 or a group of axially adjacent to each other first rolling elements 53 and z. B. a second rolling element 54 or a group of axially juxtaposed second rolling elements 54 are arranged. In the example, a first rolling element 53 and a group of three second rolling elements 54 are shown per section A to F or AB to EF. Advantageous in terms of the risk of possible tilting and possibly faulty axial alignment is the arrangement of groups of at least two each independently movable rolling elements 53; 54. A single rolling element 53; 54 for a section A to F and AB to EF, for example, as in the longitudinal direction almost over the length of the section A to F and AB to EF extending roller 53; 54 executed, a rolling element 53; 54 of a group, however, z. B. only as the highest a fraction of the length of the section A to F and AB to EF having roller 53; 54th

The axially juxtaposed rolling elements 53; 54 and, if provided, the circumferentially successively arranged rolling elements 53; 54 are in principle independently movable on, for example, a traverse 56 (or more traverses 56) arranged. The single first rolling element 53 or the group of first rolling elements 53 of each section A to F or AB to EF and, if provided, the single second rolling element 54 or the group of second rolling elements 54 of each section A to F and AB to EF are independent of each other by their own adjusting means 57; 58 actuated. These adjusting means 57; 58 are, for example, as reactable with pressure medium reversibly deformable hollow body 57; 58, in particular as a hose 57; 58 executed. But it can also be provided differently type of electrically or magnetically actuable actuating means.

For mounting an elevator 16; 17 in one of the sections A to F and AB to EF is the leading, z. B. pointed acute end 24 of the elevator 16; 17 in the relevant opening 28; 38; 39; 41 introduced. The first or first rolling elements 53 assigned to this section A to F or AB to EF and, if provided, the second rolling elements 54 assigned to this section A to F or AB to EF are coupled to the cylinder 16; 17 or to be wound up, already hinged elevator 19; 21 hired. Are already one or more other elevators 19; 21 on the cylinder 16; 17 are arranged and are to remain there, then the first and / or second rolling elements 53, which concern this section A to F or AB to EF, will also be arranged; 54 to the respective elevator 19; 21 hired. When first and second rolling elements 53; 54 are provided, presses when rolling the cylinder 16; 17 with the rolling elements 53; 54, the second rolling element 54, the trailing bent end 26 of the elevator 19; 21 in rolling into the opening 28; 38; 39; 41. Is or only first rolling elements 53 are provided, it is pushed in through them. Preferably, in this case, the rolling elements 53 remain; 54 stationary, while the cylinder 16; 17 is rotated in a direction of production P. The or in a release position (open) located holding means for the sections A to F and AB to EF, z. B. one or more clamping pieces 29; 43, changes or change to its or their holding or clamping position (closed). After the holding means has changed from its release position to its holding position, all rolling elements 53; 54 of the respective section A to F and AB to EF from the cylinder 16; 17 or its elevator 19; 21 turned off.

When unclamping a lift 19; 21 is to distinguish whether one or more other elevators 19; 21 on the cylinder 16; 17 should remain. In this case, initially at least one of the lift to be left 19; 21 associated rolling elements 53; 54 in the region of the trailing end 26 and near the opening 28; 38; 39; 41 employed or hired. The elevator 19 to be released; 21 associated rolling element 53; 54 may remain parked or be. The holding means for the sections A to F or AB to EF is opened. The trailing end 26 of the elevator 19 to be solved; 21 is by the residual stress from the channel 27; 36; 37, while the lifts to be left 19; 21 through the rolling elements 53; 54 are held down. The holding means is closed again. Does the pressing device 52 each have first and second rolling elements 53; 54, the elevators to be left 19; 21 advantageously held down by at least the second rolling elements 54. When removing intended elevator 19; 21, first at least the second rolling element 54 is turned off, so that the end 26 of the channel 27; 36; 37 can escape, and the first rolling element 53 employed, so that the already partially dissolved elevator 19; 21 still on the cylinder 16; 17 is managed and held.

Subsequently, the cylinder 16; 17, preferably counter to the direction of production P, are rotated until the leading end 24 of the channel 27; 36; 37 removed, and the elevator 19; 21 can be removed. Are when unclamping the elevator 19; 21 no remaining elevators 19; 21, so the rolling elements 53; 54 of the not to be solved elevator 19; 21 concerned sections A to F and AB to EF during the procedure, in principle, any operating positions, preferably off, occupy.

It can thus on the lateral surface 30; 40 of the cylinder 16; 17 elevators 19; 21 by at least one pressure element 53; 54 fixed as needed, while an end 24; 26 of an elevator 19; 21 or more elevators 19; 21 is released, d. H. at this time is not pressed or are.

In an advantageous embodiment, the cylinder 16; 17; 18 of the printing unit 02 driven so that the printing units 13 of the printing unit 02 are rotatably driven in each case at least by one of the other printing units 13 mechanically independent drive motor 61. In the case of the satellite printing unit 02, the satellite cylinder or cylinders 18 are likewise rotationally drivable by a drive motor 61, mechanically independently of the associated printing units 13. The drive motors 61 are preferably as with respect to their angular position controlled electric motors 61, z. B. as asynchronous motors, synchronous motors or DC motors. In an advantageous embodiment is between the drive motor 61 and the driven cylinder 16; 17; 18 or cylinder pair 16, 17; 18, 18 at least one gear 62, in particular at least one reduction gear 62 (such as pinion, attachment and / or planetary gear) arranged. The individual drives contribute to high flexibility and to avoid vibrations in the mechanical drive system, and thus also to high quality in the product. In the following FIGS. 8 to 10 have only the components of the right half of the figure corresponding reference numerals, since the left side corresponds to the right mirror image. There are respectively for upper and lower printing units alternative configurations for inking or dampening units 14, if available; 20 indicated, which are to be transmitted alternately to each other.

In Fig. 8 all nine cylinders have 16; 17; 18 each have their own drive motor 61, which in each case z. B. via a gear 62 on the cylinder 16; 17; 18 drives. The inking unit 14 shown above has, in addition to other, unspecified rollers on two distribution cylinders 63 which are rotationally driven together by means of a separate drive motor 64. The two distribution cylinders 63 are axially movable and driven by an unillustrated drive means for generating an axial stroke. The inking unit 14 shown below has only one distribution cylinder 63. The dampening unit 20 shown above has, in addition to other, not designated rolls on two distribution cylinders 66 which are rotationally driven together by means of a separate drive motor 67. The two distribution cylinders 66 are axially movable and driven by an unillustrated drive means for generating an axial stroke. The dampening unit 20 shown below has only one distribution cylinder 66. In a variant which is indicated in the upper printing units 13 by dotted lines, the inking and / or dampening unit 14; 20 not by its own drive motor 64; 67, but from one of the cylinders 16; 17; 18, in particular from the forme cylinder 16 ago via a mechanical coupling, z. B. via gears and / or belts, rotationally driven.

In contrast to Fig. 8 the two cylinders 16; 17 each printing unit 13 in the execution to Fig. 9 each driven by a common drive motor 61 on the transfer cylinder 17. The drive can be axial, z. B. via a gear 62, done or via a on a drive wheel of the transfer cylinder 17 driving pinion. From the drive wheel of the transfer cylinder 17 can then be driven off to a drive wheel of the forme cylinder 16. The drive connection 68 (shown as a connecting line) can be made as a gear connection or via belt and is executed encapsulated in development. For the drive of the color and possibly dampening unit 14; 20 via their own drive motors 64; 67 or a cylinder 16; 17; 18 is basically that too Fig. 8 applied.

In contrast to Fig. 9 the two cylinders 16; 17 each printing unit 13 in the execution to Fig. 10 Although each of a common drive motor 61, but driven on the forme cylinder 16. The drive can again axially, z. Example, via a gear 62, done or via a on a drive wheel of the forme cylinder 16 driving pinion. From the drive wheel of the forme cylinder 16 can then be driven off to a drive wheel of the transfer cylinder 17. The drive connection 68 may as well Fig. 9 be explained set forth. For the drive of the color and possibly dampening unit 14; 20 via their own drive motors 64; 67 or a cylinder 16; 17; 18 is basically that too Fig. 8 applied.

Unlike the in Fig. 8 or 9 indicated by dotted lines execution without own rotary drive of the inking and / or dampening unit 14; 20, it is advantageous in a development, from the transfer cylinder 17 to the inking and / or dampening unit 14; 20 to drive. Thus, a clear moment flow can be achieved and possibly occurring tooth flank changes can be avoided. An embodiment of such a drive train is shown schematically in FIG Fig. 11 shown.

The drive motor 61 drives via a pinion 71 on a rotationally rigidly connected to the forme cylinder 16 drive wheel 72, which in turn drives on a torsionally rigidly connected to the transfer cylinder 17 drive wheel 73. The drive wheel 73 is either widened or it is a second drive 74 connected to the transfer cylinder 17. The widened or additional drive wheel 73; 74 drives via a rotatably mounted on a pin 76 of the forme cylinder 16 drive wheel 77 on a drive wheel 78 of the inking and / or dampening unit 14; 20. The drive wheels 72; 73; 74; 77; 78 are preferably designed as gears. In the event that the forme cylinder 16 is adapted to be axially displaceable axially by, for example, ± ΔL, at least the pinion 71 and the drive wheels 72 to 74 are straight meshed executed. Between the drive motor 61 and the gear 62 of the pinion 71 and the drive wheel 72 may additionally be a dashed lines indicated, encapsulated auxiliary gear 62 'may be arranged. Alternatively, the drive to the forme cylinder 16 can also take place axially on the journal 76, wherein, if appropriate, an axial movement of the forme cylinder 16 takes place via an unillustrated, axial relative movement between the forme cylinder 16 and the drive motor 61 receiving coupling. The satellite cylinder 18 is also driven in this illustration via a pinion 71 on an associated drive wheel 79, in particular gear 79. Each driven by an independent drive motor 61 drive train is in an advantageous embodiment, at least for themselves, possibly encapsulated in even smaller units (stiched in Fig. 11 shown).

The described embodiments of the printing unit 02 and the printing units 13 and their cylinders 16; 17; 18 and the drive allows a low-vibration, accurate printing high quality with a low on the achievable product strength technical and spatial complexity.

After printing the z. B. six printed pages wide web 03 runs this, possibly via unspecified baffles and / or draw rollers, in the area of the superstructure 04 and z. B. guided by the slitting devices 06 ( Fig. 12 ). This has z. B. a roller 81, for example, a driven by its own drive motor 80 pull roller 81, with which pressure rollers can work together to avoid slippage. Longitudinal cutting device 06 and the draw roller 81 may also be carried out separately from each other, but preferably with the longitudinal cutting device 06 as a reprisal another roller acts together. In this longitudinal cutting devices 06, the web 03, for example, in several, z. B. three, partial web widths 03a; 03b; 03c, short part tracks 03a; 03b; 03c (symbolized by center lines, lines 03a, 03b merely indicated), cut longitudinally before these partial webs 03a; 03b; 03c subsequent guide elements, for. B. rolling register devices 08, turning bars of turning devices 07, Auflaufwalzen for be fed to the funnel inlet or draw rolls. In order to achieve a low-vibration web transport with respect to the web tension, individual, several or all non-driven or only by friction with the web 03a; 03b; 03c driven guide elements which are used to guide partial webs 03a; 03b; 03c are provided are executed with a reduced length. Thus, in addition to the length of the otherwise for z. B. six pages wide machines large required strength of the vanes and thus significantly reduce the inertia. The risk of vibrations in the web tension, which otherwise exists in particular when there is a change in speed, is effectively reduced, which in turn is reflected in the passer-loading and thus in the quality of the print. The following remarks on the guide elements of reduced length, the lateral location changeability and the assignment of a register roll to another guide element are to be applied to a variety of printing machines, but of particular advantage i. V. m. wide, z. B. six plates wide machines.

Fig. 12 shows in a perspective oblique view, a first embodiment of at least a portion of the superstructure 04. Exemplary is in Fig. 12 the partial web 03b shown as turned from the center to the outside part web 03b. A second of the partial webs 03a; 03c could also be turned into another flight, for example, by means of a second such turning device 07. A second turning device can, for. B. above or below the first turning device 07 lie.

The turning device 07 has, as a guide element 82, as usual, two parallel or crossed turning bars 82, which with the transport direction of the incoming part web 03a; 03b; 03c form an angle of about 45 ° or 135 °, and by means of which an incoming web 03a; 03b; 03c is laterally displaceable and / or can be staggered. The turning bars 82 advantageously have a length L82, the projection of which on the transverse extent of the incoming partial web 03a; 03b; 03c insignificantly larger, z. B. 0% to 20% larger than the width of the incoming partial web 03a; 03b; 03c, ie the length L82 is approximately 1.4 to 1.7 times the partial web width. At least the length L82 is selected such that its projection is less than or equal to twice the width of a two-side width partial web 03a; 03b; 03c, ie the length L82 is at most 2.8 times the partial web width. In an advantageous embodiment, the turning bars 82 are each mounted individually on carriers 83, which transverse to the direction of the incoming partial web 03a; 03b; 03c can be moved on at least one guide 84. The now "short" turning bars 82 can now bring depending on the requirements of the desired web guide in the required position. Under certain circumstances, both turning bars 82 may be mounted on such a carrier 83.

Staggered, turned, transferred and / or fallen partial webs 03a; 03b; 03c experienced with respect to other partial webs 03a; 03c i. d. R. offset in the direction and are therefore corrected by means of a register device 08 in the longitudinal register. The register device 08 has, as a guide element 86, at least one roller 86 which can be moved parallel to the running direction. The roller 86 or a plurality of rollers 86 of the register device 08 advantageously have a length L86 which is insignificantly larger, for. B. 0% to 20% greater than the width of the incoming partial web 03a; 03b; 03c is. At least the length L86 is less than or equal to twice the width of a two-side-width partial web 03a; 03b; 03c. In an advantageous embodiment, the register device 08 is transverse to the direction of the incoming partial web 03a; 03b; 03c stored on at least one guide 87 movable. The now narrow register device 08 or its short rollers 86 can now be brought to the required position from the desired web guide as required.

In addition to the cutting, possibly turning and possibly registers the sub-web 03a; 03b; 03c in the superstructure 04 u. U. on more, non-driven guide elements, such as guide rollers, not shown, performed before they ultimately a the folding structure 11 upstream casserole or Harfenwalze 88 of the so-called. Harp 09 ( Fig. 1 ) is supplied. For straight from running webs 03 or partial webs 03a; 03b; 03c is in the superstructure 04 upstream of the harp roller 89, for example, over the full web width b03 reaching, in the transport direction spatially variable register roller 91 and a guide roller 92 is arranged.

In an advantageous embodiment, a length L88 of a guide roller and / or harp roller 88; 93 insignificantly larger, z. B. 0% to 20% greater than the width of the incoming partial web 03a; 03b; 03c. At least the length L88; L93 ( Fig. 13 ) smaller than or equal to twice the width of a two-side wide partial web 03a; 03b; 03c. In the embodiment according to Fig. 12 For example, the "short" harp roller 88 is realized as a section 88 of a harp roller 89 which is divided in this embodiment but extends over a total of six printing pages wide web 03. The sections 88 are rotatably supported independently of each other here.

The "short" harp roller 88; 93 as a guide element 88; However, instead of or in addition to a section 88, FIG. 93 may also, as in FIG Fig. 13 shown, as individually arranged on a frame harp roller 93 executed. This can then either fixed to the frame, or on a support 94 on a guide 96 transversely to the direction of the incoming part of the web 03a; 03b; 03c be arranged variable in location.

Since the offset when turning, shifting, falls, etc. only this part of the web 03a; 03b; 03c and is bound to their special web guide, in an advantageous embodiment, the required register device 08 at least one of the course of the partial web 03a; 03b; 03c determining guide elements, such. B. the turning device 07 or a turning bar 82 or the harp 09 or a "short" harp roller 93, are assigned.

In Fig. 13 is the "short" register device 08 z. B. the "short" harp roller 93 assigned and along with this on the guide 96 transversely to the direction of incoming partial web 03b; 03c adjustable.

In Fig. 14 is the "short" register device 08 z. B. associated with one of the "short" turning bars 82 and together with this on the guide 84 transversely to the direction of the incoming part web 03b locally variable. Although this arrangement is shown here for crossed turning bars 82, but on parallel turning bars 82 from Fig. 11 apply. In the case of the crossed or mutually orthogonal turning bars 82 is at least one (here two) guide roller 97 with perpendicular to the axis of rotation of the roller 81 extending axis of rotation.

In an advantageous development, in the superstructure 04 of a three-wide printing machine per entire web 03 two such, with register and turning device 08; 07 or with register and harp roller 93 together "spatially variable" devices arranged above or below each other.

The guides 84; 96 ( FIGS. 13 and 14 ) of the aforementioned embodiments can be realized in many different ways. For example, the guides 84; 96 be designed as spindles with at least sections threaded, which rotatably mounted on both sides and z. B. are rotatably driven by a drive, not shown. The carriers 83; 94 can in the manner of sliding blocks in rigid guides 84; 96, z. B. on profiles, be performed. In this case, a drive of the carrier 83; 94 also via a drivable spindle or otherwise done.

By means of the transversely adjustable turning bar 82 are variable transfers or offset of partial webs 03a; 03b; 03c over one or two partial web widths (or even multiples of a half partial web width) away possible. Here, the printed partial webs 03a; 03b; 03c in the flight of one of several, here three, transverse to the direction of juxtaposition of the former 101; 102; 103 ( Fig. 15 ) of the folder assembly 11. The transfer takes place, for example, to the requirement to correspond to different strengths of individual strands or ultimately intermediate or end products, at the same time an effective printing should be done with the fullest possible web widths.

For n full tracks to be printed 03; 03 '(eg n printing towers 01) of a respective maximum width b03 of m printed pages, the superstructure 04 advantageously has at least (n * (m / 2 - 1)) turning devices 07. In the case of a six page wide printing machine and z. B. three tracks 03; 03 '(or three printing towers 01) per section are six turning devices 07 per section of advantage.

In one embodiment of a printing press with z. B. two sections of three printing towers 01 and a total of six provided for the two-sided four-color four printing pages wide webs 03; 03 '; 03 "are arranged at least three turning devices 07 per section.

In an advantageous embodiment of a printing machine with z. B. two sections of two printing towers 01 and a total of four provided for the two-sided four-color printing six printed pages wide webs 03; 03 '; For example, four turning devices 07 per section are arranged in this printing press In this printing press with two sections or a total of four printing towers 01 (four webs 03, 03 '), a product with a total thickness of 96 pages can be produced in the collective operation.

In addition to the offset of a partial web 03a; 03b; 03c by an integer multiple of its partial path width b03a, an operation is advantageous, wherein a partial path 03a; 03b; 03c is offset by an odd multiple of half the partial web width b03a and / or funnel width (ie by a factor of 0.5, 1.5, 2.5) ( Fig. 15 ). This can be done by means of long over the entire width of the printing press or the width b03 of the entire web 03 reaching turning bars (not shown), but also advantageously by means of the above-described portable "short" turning bars 82. The Turning bars 82 are then, for example, as in Fig. 15 shown arranged so that the first of the partial web 03a; 03b; 03c looped turning bar 82 at least over an entire width of a subsequent folding former 101; 102; 103 is aligned, while the second turning bar 82 at least with two adjacent halves of two juxtaposed subsequent formers 101; 102; 103 is aligned.

The partial track 03a offset by an odd multiple of half the funnel width b101 or partial track width b03a; 03b; 03c thus runs "between" the formers 101; 102; 103. This is in Fig. 15 and 16 on the example of the six printed pages wide funnel arrangement on a two-side-wide sub-web 03a; 03b; 03c shown, but also to transfer to machines of other widths. There is thus no need for only one printed side wide partial webs 03a; 03b; 03c or partial webs 03a; 03b; 03c half a funnel width b101 printed as such and are passed through the machine. A high variety in the product is nevertheless possible.

The part track 03a offset by an odd multiple of half the part track width b03a; 03b; 03c is in front of the former 101; 102; 103 in a between the two aligned folding hoppers 101; 102; 103 longitudinal flight cut and runs on the folding structure 11 and the harp 09, ie undivided and / or split harp roller 89 and / or "short" harp roller 93 to ( Fig. 16 ).

In Fig. 16 is a schematic section of the Fig. 15 with exemplary differently executed harp rollers 89; 93, wherein, for example, the partial web 03c has been offset from its original position (shown unfilled) by one and a half partial web widths b03a. It can, for example, if they are provided with a further longitudinal cutting device 104 in front of the formers 101; 102; 103 is cut (then in each case one printed page or newspaper page wide), each half in each case with the partial webs 03a and 03b on each of a former 101; 102 are led. The two (intermediate) products then have z. B. in each case at least one pressure side wide partial web 03c1; 03c2 a previously two pages wide partial web 03a; 03b; 03c on. In addition, partial webs 03a '; 03b '; 03c 'from others, z. B. in another printing unit 02 or another printing tower 01 printed webs 03 'on one or more of the harp rollers 89; 93 accumulate. The sub-webs 03a, 03a ', 03c1 running over or under one another in the same flight; 03b, 03b ', 03c2; 03c 'can now z. B. each to a strand 109; 111; 112 summarized a former 103; 102; 103 are supplied. In the exemplary embodiment, it is therefore possible to use two webs 03, each printed on both sides, in double-size and three-width printing units (for example four-color). 03 'produce products or intermediates (also called books or books) with the following, depending on the occupancy of the forme cylinder 16 and the corresponding operation of the folder 12 different number of pages: In single production, ie the forme cylinder 16 is in the circumferential direction with two printing plates 19 different Printed pages A1, A2 to F1, F2 (or A1 ', A2' to F1 ', F2' for the second web 03 ') occupied and takes place in the folder 12, a cross-cutting and collecting, so are on the strands 109 and 111 respectively two different booklets each with 10 printed pages, and over the strand 112 two different booklets each with 4 printed pages generated. A total product has z. B. 48 pages. If this printing machine is operated in double production, ie the forme cylinder 16 is in the circumferential direction with two printing plates 19 same printed pages A1, A1; to F1, (or A1 ', A1' to F1 ', F1') occupied and in the folder 12 is not collecting, so are on the strands 109, 111 and 112, two identical successive issues of the above page numbers generated. It produces a total product with only 24 pages, but with double output.

The harp rollers 89; 93, in particular if they are executed undivided over the full length, can be rotationally driven in a development on its own, not shown drive motors. These are then z. B. with respect to their speed, u. U. also their location, run controllable and are to take over current setpoints with the machine control or an electronic master axis in combination.

As in Fig. 17 shown, the folding structure 11 has at least two stacking rollers 101, 106 arranged one above the other; 102, 107; 103, 108, whose planes of symmetry S in each case in a common escape of the printing press straight through part of web 03a; 03b; 03c lie. In particular, the planes of symmetry S of the two stacked formers 101, 106 fall; 102, 107; 103, 108 substantially together with a median plane M of a two printed pages wide, straight running, only deflected in the vertical direction partial web 3a; 3b; 3c (3a ', 3b', 3c ', 3a ", 3b", 3c ", 3a'", 3b '", 3c''', etc.) The partial webs 3a, 3b, 3c, etc. are in Fig. 17 from one below (to Fig. 18 ) explained reason partially drawn and shown in dotted line to another part.

For the six printing pages wide printing press are according to Fig. 17 two vertically staggered groups of three formers 101, 102, 103 and 106, 107, 108 respectively. For four printing-wide presses, this can be two, for eight pages wide printing presses each four funnels beneneinander. In each case an upper and a lower former 101, 106; 102, 107; 103, 108 are aligned in pairs in the above-mentioned manner to one another and to a respective center plane M. The three formers 101; 102; 103 and 106, respectively; 107; 108 of a group are transverse to the direction of the partial webs 03a; 03b; 03c offset from one another next to each other and arranged in an advantageous embodiment substantially at a same height. However, they may also be vertically offset from each other and / or have different vertical dimensions, but then z. B. in the horizontal plane at least partially overlap.

Seen in the web running direction, the folding structure 11 at least in front of one of the superimposed groups of formers 101; 102; 103 and 106, respectively; 107; 108 the funnel inlet of the webs 03; 03 '; or partial webs 03a; 03b; 03c defining harp 09, ie a group of several parallel, offset in the radial direction casserole or Harfenwalzen 89; 93, over which different tracks 03; 03 'or partial webs 03a; 03b; 03c; or 03a '; 03b '; 03c 'etc. are transferred from the superstructure 04 in the folding structure 11. Following the harp rollers 89; 93 they become a strand 109; 111; 112 or multiple strands 109; 111; 112 summarized. The later position of the partial web 03a; 03b; 03c; or 03a '; 03b '; 03c 'in strand 109; 111; 112 or their printed pages in the intermediate and / or end product is inter alia by the choice of a relative position to other, the harp 09 continuous partial webs 03a; 03b; 03c; or 03a '; 03b '; 03c 'already set in the harp 09. The harp rollers 89; 93 of a harp 09 are mutually vertically and / or horizontally offset and preferably stored as a unit in a common frame. In principle, for each of the vertically offset groups of formers 101; 102; 103 and 106, respectively; 107; 108 such a harp 09 may be provided.

To save height, have in an advantageous embodiment, as in Fig. 1 and Fig. 19 shown, the two superimposed, but in their plane of symmetry aligned folding hopper 101, 106; 102, 107; 103, 108 a common harp 09 on. For n full tracks to be printed 03; 03 '(eg n printing towers 01 of a section) of a respective maximum width b03 of m printed pages, the harp 09 advantageously comprises at least (n * m / 2) harp rollers 88; 89; 93, whose axes of rotation z. B. are substantially in a common plane, and which are preferably stored in a common frame. In the case of the present six pages width printing machine and z. B. two tracks 03; 03 '(or two printing towers 01) are at least six harp rollers 88; 89; 93 per harp 09 of advantage.

In one embodiment of a section of the printing press with three printing towers 01 and three provided for the two-sided four-color printing tracks 03; 03 '; 03 ", at least nine harp rollers 88, 89, 93 are arranged per harp 09. In this section, a product with a total thickness of 72 pages can then be produced in the collecting operation.

In an advantageous embodiment of a printing machine with z. B. two sections of two printing towers 01 and a total of four provided for the two-sided four-color printing six printed pages wide webs 03; 03 '; 03 ", at least six harp rollers 88, 89, 93 are arranged per harp 09 of a section These six harp rollers 88, 89, 93 per section, here twelve, can be arranged in two structurally separate harps 09, eg over a common folding structure 11 or two folding structures 11, but also in a structurally common harp 09 eg in two alignments be In this printing press with two sections or a total of four printing towers 01 (four tracks 03, 03 ') is then in the collecting a product with a Total thickness of 96 pages can be generated.

In one embodiment of a printing press with z. B. two sections of two printing towers 01 and a total of four provided for the two-sided four-color printing six printed pages wide webs 03; 03 '; 03 ", at least six harp rollers 88, 89, 93 are arranged per harp 09 of a section These six harp rollers 88, 89, 93 per section, here twelve, can be arranged in two structurally separate harps 09, eg over a common folding structure 11 or two folding structures 11, but also in a structurally common harp 09 eg in two alignments be In this printing press with two sections or a total of four printing towers 01 (four tracks 03, 03 ') is then in the collecting a product with a Total thickness of 96 pages can be generated.

If only one folding structure 11 is provided for two sections, the number of harp rollers required is 89; 93 according to the configuration of the two sections. If the folding structure 11 is arranged between these two sections, then either all the harp rollers 89; 93 in an escape or to save height the harp rollers 89; 93 of each section each arranged in alignment and the alignment with each other in the radial direction offset horizontally. The harp rollers 89; 93 of the two escapes are here z. B. again arranged in a common frame.

Are, as in Fig. 1 indicated, although two folding assemblies 11 provided for the two sections, it may still be advantageous for at least one of the two harps 09 a number of harp rollers 89; 93, possibly in the two above-mentioned alignment, which would be required for both sections. Thus, there is an even greater degree of flexibility in product strength and composition. In a section printed sheets 03; 03 'can now be supplied to the other section if necessary for further processing of the harp 09 and vice versa.

According to Fig. 18 is at least one of the partial webs 03a; 03b, 03c, etc., which are in front of the upper former 101; 102; 103 arranged common harp 09 passes through, on the lower former 106; 107; 108 feasible or guided. Depending on the desired strength of the individual intermediates (booklets, books) are more or less of the partial webs 03a; 03b; 03c etc. on the upper and lower former 101; 102; 103 and 106, respectively; 107; 108 to convict. Depending on the production requirements so different strands 109; 111; 112; 113; 114; 116 on the respective lower and upper former 101; 102; 103 and 106, respectively; 107; 108 will be given. For example, the dashed in Fig. 17 partial webs shown as strand 113; 114; 116 on the respective lower former 106; 107; 108, and the solid on the respective top Former 101; 102; 103 led. This is, depending on where the "separation" in superimposed partial webs 03a; 03b; 03c etc. from the common harp 09 is a flexible production of different strong intermediates (booklets, books) or end products possible with reduced effort. In Fig. 18 is a second escape from harp rollers 89; 93 shown by dashed lines, by means of which, as described above, for example, partial webs 03a; 03b; 03c etc. can be recorded from another section.

In the case of multi-colored products, it is advantageous in the use of the described harp 09 folder assembly 11 in terms of flexibility, all printing units 02 or printing towers 01 or the paths of the web 03; 03 'with the same color perform. So z. B. the web 03; 03 'and / or partial web 03a; 03b; 03c etc. or the printing unit 13 for a colored cover sheet flexibly selectable and the strength of the intermediates variable.

The aforementioned folding structure 11 with only one harp 09 for two superposed formers 101; 102; 103; 106; 107; 108 is also suitable for other printing machines with different cylinder widths and cylinder circumferences. Such, from two stacked formers 101; 102; 103; 106; 107; 108 and a common harp 09 existing Falzoberbau 11 may also be arranged on a third former with its own harp 09. The described folding structure 11 with a plurality of vertically offset formers 101; 102; 103; 106; 107; 108 assigned harp 09 is also on three superposed formers 101; 102; 103; 106; 107; 108 well applicable.

Outside pages, for example, of an outer book can thus be assigned to a specific web guide and / or a specific printing tower / printing unit.

Through the multiple formers 101; 102; 103; 106; 107; 108 associated harp 09 it is possible, the superimposed partial webs 03a; 03b; 03c etc. depending on the desired product to flexibly process books of different sizes, without the need for a great deal of additional, unnecessary dislocations of partial webs 03a; 03b; 03c etc. would be required. So z. B. of four superimposed partial webs 03a; 03b; 03c etc. in one case, three tracks on one and one on the other former 101; 102; 103; 106; 107; 108 are guided, while another time each two partial webs 03a; 03b; 03c etc. summarized on a former 101; 102; 103; 106; 107; 108 are guided. It is particularly advantageous that adjacent strands 109; 111; 112; 113; 114; 116 different degrees, as in Fig. 17 represented, can be summarized.

The formers 101; 102; 103; 106; 107; 108 in each case upstream Zug 117 and funnel inlet rollers 118 have in an advantageous embodiment as well as provided in the folding structure 11 draw rollers 121 ( Fig. 19 ) each have their own drive motors 119. In Fig. 19 is the draw roller 117 for the lower group of the formers 106; 107; 108 not visible. The respective drive motor 119 of the draw rollers 121 is in Fig. 19 merely represented by filling of the relevant draw roller 121. Each of the formers 101; 102; 103; 106; 107; 108, at least one such driven draw roller 121 is arranged downstream in an advantageous embodiment, which with pressure rollers or a pressure roller on the strand 109; 111; 112; 113; 114; 116 cooperates. In addition, the folding structure 11 preferably has non-driven guide rollers 122, via which the one printing side wide strands 109; 111; 112; 113; 114; 116 can be performed.

Particularly advantageous, for. B. with regard to the compliance / adjustment of longitudinal registers, also has the folder 12 at least one own, of the printing units 02 mechanically independent drive motor 120. While the drive motors 119 of the tractor inlet rollers 117; 118; 121 of the folding structure 11 and / or driven tension rollers 81 of the superstructure 04 only have to be controlled in terms of speed (with regard to an angular position), the drive motor 120 is designed to be adjustable or regulated with respect to its angular position on the folding apparatus 12 in an advantageous embodiment.

Thus, it is possible in one embodiment, the mechanically independently driven printing units 02 and the folding apparatus 12 (or their drive motors 61, 120) to specify an angular position with respect to a virtual electronic master axis. In another embodiment, for. B. determines the angular position of the folder 12 (or its drive motor 120) and based on this, the relative angular position of the printing units 02 and 13 printing units specified for this. The z. B. only with respect to their speed controlled drive motors 80; 119 of the driven rollers 81; 117; 118 receive their speed specification, for example, from the machine control.

• ein Buch mit zwölf Seiten, oder
• ein Buch mit vier Seiten und ein Buch mit acht Seiten, oder
• zwei Bücher mit sechs Seiten, oder
• drei Bücher mit vier Seiten

und weitere Variationen produzieren.
In Sammelproduktion verdoppeln sich die Seitenzahlen der dann jeweils aus zwei längsgefalzten Abschnitten gesammelten Zwischenprodukte.By the execution of the web-fed rotary printing machine with triple-wide and double-sized transfer and forming cylinders and the corresponding execution of the folding structure, can be by means of a train, for example, in double production

• a book with twelve pages, or
• a book with four pages and a book with eight pages, or
• two books with six pages, or
• three books with four pages

and produce more variations.
In collected production, the page numbers of the intermediate products then collected from two longitudinally folded sections are doubled.

For printing in tabloid format the respective page numbers have to be doubled. The dimensioning of the cylinder 16; 17; 18 and the groups of formers 101; 102; 103; 106; 107; 108 is to be applied to each "lying" printed pages, wherein in the circumferential direction or direction of the web 03; 03 ';03a;03b; 03c is a section A; B; C has two lying print pages, the form cylinder 16 then z. B. has a scope corresponding to four horizontal printed pages in tabloid format. The number of printed pages in the longitudinal direction remains per web 03; 03 ';03a;03b; 03c and cylinder 16; 17; 18 or funnel width exist.

LIST OF REFERENCE NUMBERS

01

printing tower

02

Printing unit, satellite printing unit, nine-cylinder satellite printing unit ten-cylinder satellite printing unit, H printing unit

03

Train, subway

03a

Train, subway

03b

Train, subway

03c

Train, subway

03c1

part web

03c2

part web

04

superstructure

05

-

06

Slitter

07

Turning device, turning device

08

register means

09

harp

10

-

11

folding structure

12

folding

13

Printing unit, offset printing unit

14

inking

15

paintbox

16

Cylinder, forme cylinder

17

Cylinder, transfer cylinder

18

Printing cylinder, satellite cylinder

19

Elevator, printing form, printing plates

20

Dampening unit, spray dampening unit

21

Elevator, blanket, metal blanket

22

layer

23

support plate

24

End, leading, suspension leg

25

-

26

End, trailing, suspension leg

27

channel

28

opening

29

Clamping piece, clamping element

30

lateral surface

31

spring element

32

Adjusting means, hollow body, hose

33

Passer element

34

base

35

Registration stone, Passerstift

36

channel

37

channel

38

Opening, slot

39

Opening, slot

40

lateral surface

41

Opening, slot

42

drilling

43

Clamping piece, clamping element

44

spring element

45

-

46

Adjusting means, hollow body, hose

47

Adjusting means, hollow body, hose

48

Adjusting means, hollow body, hose

49

filler

50

-

51

opening

52

pressure device

53

Pressing element, first, rolling element, roller, roller

54

Pressure element, second, rolling element, roller, roller

55

-

56

traverse

57

Adjusting means, hollow body, hose

58

Adjusting means, hollow body, hose

59

-

60

-

61

Drive motor, electric motor

62

Transmission, reduction gear

62 '

Reduction gear

63

distribution cylinder

64

drive motor

65

-

66

distribution cylinder

67

drive motor

68

drive connection

69

-

70

-

71

pinion

72

drive wheel

73

drive wheel

74

drive wheel

75

-

76

spigot

77

drive wheel

78

drive wheel

79

Drive wheel, gear

80

drive motor

81

Roller, draw roller

82

Turning bar, guide element

83

carrier

84

guide

85

-

86

Roller, guide element

87

guide

88

Overrun roller, harp roller, section

89

Bearing roller, harp roller, guide element

90

-

91

register roll

92

deflecting

93

Overrun roller, harp roller, register roller, guide element

94

carrier

95

-

96

guide

97

deflecting

98

-

99

-

100

-

101

formers

102

formers

103

formers

104

Slitting device, means

105

-

106

formers

107

formers

108

formers

109

strand

110

-

111

strand

112

strand

113

strand

114

strand

115

-

116

strand

117

pulling roller

118

Former inlet roller

119

drive motor

120

drive motor

121

pulling roller

122

guide roll

A

section

B

section

C

section

D

section

e

section

F

section

A1, A2

pressure side

B1, B2

pressure side

C1, C2

pressure side

D1, D2

pressure side

E1, E2

pressure side

F1, F2

pressure side

b03

Width, web, web width

B03A

Width, partial web

b23

Width (23)

b27

Width (27)

b101

hopper width

I

length

L16

length

L17

length

L82

length

L86

length

L88

length

L93

length

M

midplane

MS

material thickness

P

production direction

S

plane of symmetry

S16

slot width

S17

slot width

U

section

'

corresponding designation of a second or partial web

α

angle

β

angle

α '

angle

Claims (35)

1. Web-fed rotary printing machine having a left-hand and a right-hand section each having at least one printing unit, which is implemented as a nine-cylinder satellite printing unit (02) having four pairs each comprising a transfer cylinder (17) and an associated forme cylinder (16) and also an impression cylinder (18) that interacts with the transfer cylinders (17) when in the print-on position, the transfer and forme cylinders (17; 16) being designed with a width for printing six newspaper pages arranged axially beside one another in each case, characterized in that the left-hand and right-hand section in each case has at least two printing towers (01), each of which has two nine-cylinder satellite printing units (02) arranged one above the other, which are designed with a width for printing six newspaper pages arranged axially beside one another, and in that between the two sections there are arranged two folder structures (11), which in each case have folder formers (101; 102; 103; 106; 107; 108) arranged in two different planes lying one above the other.
2. Web-fed rotary printing machine according to Claim 1, characterized in that, at least on the transfer cylinder, the openings are arranged to be offset alternately in the circumferential direction in such a way that, at least on a section length, a closed circumferential surface always interacts with the satellite cylinder.
3. Web-fed rotary printing machine according to Claim 1, characterized in that transfer cylinder (17) and forme cylinder (16) have a circumference which corresponds to at least two upright pages, in particular newspaper pages in broadsheet format, arranged one after another in the circumferential direction.
4. Web-fed rotary printing machine according to Claim 1, characterized in that the transfer cylinder (17) has three dressings (21) arranged beside one another in the axial direction on three sections (AB; CD; EF) of its circumferential surface (40).
5. Web-fed rotary printing machine according to Claim 1, characterized in that the forme cylinder (16) has at least three dressings (19) beside one another in the axial direction and two dressings (19) in the circumferential direction in each case on six sections (A; B; C; D; E; F) of its circumferential surface (30).
6. Web-fed rotary printing machine according to Claim 1, characterized in that the forme cylinder (16) has six dressings (19) beside one another in the axial direction on its circumferential surface (30).
7. Web-fed rotary printing machine according to Claim 5 or 6, characterized in that ends of the dressings (19) arranged beside one another are aligned with one another in the axial direction.
8. Web-fed rotary printing machine according to Claim 4 or 5, characterized in that, in order to accommodate ends (24; 26) of the dressings (19; 21) on its circumferential surface (30; 40), the cylinder (16; 17) has at least two openings (28; 38; 39; 41) running axially and offset in relation to one another in the circumferential direction.
9. Web-fed rotary printing machine according to Claims 5 and 8, characterized in that, on the circumferential surface (30) of the forme cylinder (16), two openings (28) offset by 180° in relation to each another in the circumferential direction extend at least over the entire length of the six sections (A to F).
10. Web-fed rotary printing machine according to Claims 4 and 8, characterized in that, on its circumferential surface (40), in the region of the three sections (AB to EF), in each axial row of the openings (38; 39; 41), the transfer cylinder (17) has at least one section (U) that continues the shape of the remaining circumferential surface (40).
11. Web-fed rotary printing machine according to Claim 1, characterized in that at least two forme cylinders (16) of the printing unit (02) are in each case assigned a pressure device (52) for pressing a dressing (19) onto the forme cylinder (16).
12. Web-fed rotary printing machine according to Claim 1, characterized in that transfer cylinder (17) and forme cylinder (16) are coupled mechanically in pairs in order to drive them and are driven mechanically independently of associated impression cylinders (18).
13. Web-fed rotary printing machine according to Claim 12, characterized in that the pair comprising forme cylinder (16) and transfer cylinder is driven by means of an individual drive motor (61), and the impression cylinder (18) has an individual drive motor (61).
14. Web-fed rotary printing machine according to Claim 1, characterized in that, in a nine-cylinder printing unit, all four pairs of cylinders (16; 17) have an individual drive motor (61) in each case, and the satellite cylinder (18) has an individual drive motor (61).
15. Web-fed rotary printing machine according to Claim 1, characterized in that the cylinders (16; 17; 18) in each case have a drive motor (61) that is mechanically independent of the other cylinders (16; 17; 18).
16. Web-fed rotary printing machine according to one of Claims 12 to 15, characterized in that the drive from the drive motor (61) is provided via a transmission (62), in particular a gear transmission (62).
17. Web-fed rotary printing machine according to Claim 1, characterized in that, on their circumferential surface (40), the transfer cylinders (17) have three dressings (21) beside one another in the axial direction in each case, the ends (24; 26) of which are arranged in at least one channel (36; 37) running axially and having an opening (28; 38; 39; 41) to the circumferential surface (30; 35) with a width (s17) in the circumferential direction that is less than or equal to 3 mm.
18. Web-fed rotary printing machine according to Claim 17, characterized in that the dressings (21) are in each case implemented as a resilient and/or compressible layer (22) arranged on a carrier plate (23).
19. Web-fed rotary printing machine according to Claim 17, characterized in that it has at least two, in particular three, printing towers, which represent a section and to which a common superstructure (04) and a common folder structure (11) are assigned.
20. Web-fed rotary printing machine according to Claim 19, characterized in that the superstructure (04) has at least one guide element (82; 08; 93) which can be moved transversely as desired with respect to the running direction of the web (03) into the running path of three part webs (03a; 03b; 03c) arranged beside one another.
21. Web-fed rotary printing machine according to Claim 19, characterized in that the folder structure (11) has at least one group of folder formers (101; 102; 103; 106; 107; 108) arranged beside one another transversely with respect to the running direction of the web (03).
22. Web-fed rotary printing machine according to Claim 1 or 19, characterized in that the folder structure (11) has at least two folder formers (101, 106; 102, 107; 103, 108) arranged one above another, the vertically extending planes of symmetry (S) of which are aligned with one another.
23. Web-fed rotary printing machine according to Claim 11, characterized in that a channel (27) of the forme cylinder (16) has retaining devices (29, 31) for fixing ends (24; 26) of the dressings (19) arranged beside one another, the retaining devices (29; 31) of the channel (27) being capable of actuation by a common actuating means (32).
24. Web-fed rotary printing machine according to Claim 1, characterized in that it has two sections each with two printing towers, and in that at least one folder structure (11) is arranged between the two sections.
25. Web-fed rotary printing machine according to Claim 1, characterized in that it has two sections each with three printing towers, and in that at least one folder structure (11) is arranged between the two sections.
26. Web-fed rotary printing machine according to Claim 24 or 25, characterized in that two folder structures (11) are arranged between the sections.
27. Web-fed rotary printing machine according to Claim 1, characterized in that between the two sections there are arranged two folder structures (11), which in each case have two groups, arranged on two different planes lying one above the other, each comprising three folder formers (101, 102, 103; 106, 107, 108) arranged offset in relation to one another transversely with respect to the running direction of part webs (03a; 03b; 03c).
28. Web-fed rotary printing machine according to Claim 1, characterized in that, at least before one of the groups of folder formers (101; 102; 103 or 106; 107; 108) arranged one above another, the folder structure (11) has a group comprising a plurality of parallel infeed rolls (89; 93) arranged offset in relation to one another in the radial direction, over which various webs (03; 03') or part webs (03a; 03b; 03c or 03a'; 03b' 03c') and so on are transferred from the superstructure (04) into the folder structure (11).
29. Web-fed rotary printing machine according to Claim 1, characterized in that one group of infeed rolls (89; 93) is provided for each of the vertically mutually offset groups of folding formers (101; 102; 103 or 106; 107; 108).
30. Web-fed rotary printing machine according to Claim 1, characterized in that a common group of infeed rolls (89; 93) is provided for the two folder formers (101, 106; 102, 107; 103, 108) that are arranged one above the other but aligned with each other in their plane of symmetry.
31. Web-fed rotary printing machine according to Claim 1, characterized in that at least one of the two folder structures (11) is assigned a group of infeed rolls (89; 93) having a number of infeed rolls (89; 93), over which webs (03; 03') printed in one of the two sections can be fed to infeed rolls (89; 93) of the other of the two sections for further processing.
32. Web-fed rotary printing machine according to Claim 28, characterized in that a second group of infeed rolls (89; 93) is provided for the folder structure (11), by means of which infeed rolls part webs (03a; 03b; 03c, etc.) can be picked up from another section.
33. Web-fed rotary printing machine according to Claim 1, characterized in that, on its circumferential surface (30), the forme cylinder (16) bears six dressings (19) formed as printing formes (19) and arranged beside one another in the axial direction.
34. Web-fed rotary printing machine according to Claim 1, characterized in that each folder structure (11) is assigned a folding apparatus (12).
35. Web-fed rotary printing machine according to Claim 34, characterized in that the folding apparatus (12) has an individual drive motor (120) mechanically independent of the printing units (02).

Images