This application is the U.S. national phase, under 35 USC 371 of PCT/EP2007/052794, filed Mar. 23, 2007; published as WO 2007/110386 A2 and A3 on Oct. 4, 2007, and claiming priority to DE 10 2006 013 955.0, filed Mar. 27, 2006, the disclosures of which are expressly incorporated herein by reference.
The present invention is directed to a device and to a method for feeding a material web to a printing unit of a web-fed rotary printing press. The printing press is provided with a reel stand that carries a material reel. The reel stand is arranged laterally next to the printing press alignment. At least one turning bar is arranged in a web path between the reel stand and the printing unit. That at least one turning bar is angled at 45° in relation to the direction of transport of the material web running up to it.
A device for feeding a material web to a printing couple is known from EP 1 468 826 A1. A plurality of printing units are arranged side by side in a machine alignment, viewed in the longitudinal direction of their printing couple cylinders. Reel changers are arranged next to this machine alignment, and are oriented with their rotational axes parallel to the printing couple cylinders. The web is turned, in its direction of transport, into the plane of the machine alignment via a turner bar, which is arranged above the printing unit, once the web has passed through the printing unit.
WO 2005/105447 A1 describes a device for feeding in a material web. A plurality of printing units are arranged side by side in a machine alignment, viewed perpendicular to the rotational axes of the printing couple cylinders. In one embodiment, reel changers are arranged next to this machine alignment and are oriented with their rotational axes perpendicular to the rotational axes of the printing couple cylinders. The direction of transport of the web is turned into the plane of the machine alignment, before the web enters the printing unit. This web turning is accomplished by using a turner bar, which is arranged inclined 45° in relation to the direction of transport of the incoming web and lying in a horizontal plane. In other embodiments, the reel changers are arranged aligned with the printing units in the same machine alignment, with their rotational axes parallel to the printing couple cylinders. These reel changers are situated either in a machine plane below the printing units, or are situated in the same machine plane.
A turner bar assembly is described in DE 198 58 602 A1 and is situated in a web path between printing couples, which are located upstream, in a direction of web travel, and a fold former, which is located downstream. The turner bars are arranged vertically to allow better accessibility.
Turner bars in the superstructure of a printing press are described in WO 2004/037696 A2. Air outlet openings are embodied as micro openings having diameters of, at most 500 μm, and especially at most 300 μm. The micro openings are open pores in a porous material or are openings of microscopic holes. In one embodiment, the micro openings extend around the entire 360° circumference of the turner bars and are supplied with air on both the web wraparound side and the non-wraparound side of the periphery of the turner bars.
DE 44 09 693 C1 describes a take-up device in a web path, downstream from the printing unit in the area of a turner bar assembly, and with which cut web sections are deflected laterally.
The object of the invention is to provide a device and a method for feeding a material web to a printing unit of a web-fed rotary printing press.
The object is attained according to the invention through the provision of a web-fed rotary printing press with a reel stand that carries a material reel. The reel stand is arranged laterally next to the machine alignment. At least one turner bar is arranged in the web path between the reel stand and the printing unit. The turner bar is inclined at 45° in relation to the direction of transport of the material web. The turner bar has outlet openings which are embodied as micro openings for the passage of a pressurized fluid. These outlet openings are located at least in an angular wraparound region of the material web. A maximum average diameter of these openings is 500 μm. The turner bar is supplied with air for passage through the micro openings over a length that is greater than the width of the area covered by the material web which wraps around the turner bar.
The benefits to be achieved with the present invention consist, among others, in that, during infeed of a web and/or during web processing that involves varying web widths, undisrupted operation, with a decreased need for manual intervention, is enabled. This applies especially to the configuration of the printing press presented here, in which the web to be fed in is turned inward from a longitudinal side of the machine.
In one further advantageous improvement in accordance with the present invention, the turner bar is configured with openings through which air can flow. These openings are preferably embodied as micro openings. This measure makes it possible to pressurize or to supply the turner bar with air along a maximum length of the turner bar which is provided for web processing in the printing press. This compressed air supply can be provided regardless of the web width selected at the time, and without requiring that non-wraparound edge areas of the turning bar be covered. By configuring the openings as micro openings having, for example, an average maximum opening diameter of 500 μm, the leakage flows of compressed fluid in non-wraparound areas of the turning bar, and the pressure losses in the wraparound areas of the turning bar are kept low enough that a mechanical covering of non-wraparound areas is no longer required. This also facilitates the provision of a compact structure, because accessibility to the turning bar, for covering the non-wraparound areas of the bar, when shifting from one web width to another is no longer necessary.
In a further improvement in accordance with the present invention, it is also advantageous to provide a transport device, preferably between the reel changer and the printing unit, but to provide such a transport device at least around the turner bar and extending into the printing unit, for use in accomplishing a non-manual, such as, for example, motorized, infeed of a leading edge of a web. This also eliminates a regular intervening step. Particularly when combined with a turner bar that is equipped with micro openings, an undisrupted infeed is possible because the turner bar can be pressurized or supplied with compressed air over its entire length during the web infeed process and without experiencing a significant drop in pressure through uncovered areas of the turner bar.
Local conditions existing in a printing plant frequently include boundary conditions which preclude positioning of reel changers and the like in a cellar. Alternatively height may be limited by a maximum building height and/or by the height of a preexisting facility. In such cases, for example, the placement of reel changers in a cellar or the arrangement of the printing units in a so-called “table assembly,” or in other words on a plane above the reel changer, must be ruled out. In such cases, it is advantageous to install the reel changer and the printing units within a shared system plane, in parterre arrangement. In contrast to printing presses arranged in such a parterre configuration, in which the reel changers are also arranged in the machine alignment, a similar printing press, also in parterre configuration, and having its reel changers arranged to the side of the machine alignment, is shorter in structure, and ordinarily requires shorter web paths. This also contributes to the most undisrupted operation of the printing press that is possible.
A further improvement of the printing press in accordance with the present invention, and which is advantageous, in terms of variable web widths, can be achieved wherein the webs or the web sections are guided to the folding unit or to the former assembly at an orientation which is 90° out of the machine alignment. In this case, the infeed direction of the former assembly is rotated 90° in relation to the machine alignment of the printing press, and can advantageously also be offset laterally from the machine alignment. In the case of varying web widths, and therefore also of varying web section widths, in the case of full webs that are four or six newspaper pages in width, for example, fold formers of a former assembly can remain stationary, while the new web sections are aligned on the former noses in the superstructure via movable turner bars.
Preferred embodiments of the present invention are represented in the set of drawings and are described in greater detail in what follows.
The drawings show in
a-6b perspective representations of the turner bar assembly arranged below an operating platform a) with an infeed tip and b) with an infeed apron; in
Referring initially to
A plurality of printing units 01 can be stacked to form a printing tower, such as may be seen, for example, in
In the example of printing couples 02, which are represented as being configured as offset printing couples, the printing couple cylinders 04 that cooperate with the web 03 are configured as transfer cylinders 04, each of which cooperates with a forme cylinder 05 that carries a printing forme. In the case of printing couples 02 which are configured as direct printing couples, such as, for example, intaglio, planographic or letterpress printing couples, the printing couple cylinders 04 that cooperate with the web 03 can also be configured as the printing couple cylinders that each carry the printing forme.
The printing unit 01 receives the web 03 for printing from at least one reel stand 06 for a web 03 that is to be unwound. At least one deflection bar 07, such as, for example, at least one turner bar 07, is situated in the web path between reel stand 06 and printing unit 01. Turner bar 07 is inclined or angled at 45° in relation to the direction of transport T1 of the web 03 running up to it from the reel stand 06. Preferably, only one turner bar 07 is provided in the path of one web 03 between its reel stand 06 and the printing unit 01, and is inclined or is angled at 45° in relation to the respective direction of transport T1 of the incoming web 03. The turner bars 07 are arranged “horizontally” within a horizontal plane. In other words, a longitudinal axis L, as may be seen, for example, in
The reel stand 06 is preferably configured as a reel changer 06. It may be configured, for example, as a stationary reel changer. Preferably, the reel stand 06 is configured as a reel changer 06 for changing reels at production speed and is thus capable of accomplishing a “flying” reel change. The printing unit 01 and the reel changer 06 that supplies the web 03 to the printing unit 01 are arranged offset from one another, as viewed with respect to the direction of the rotational axes R04 of the printing couple cylinders 04. In particular, the printing unit 01 that comprises side frames 09 at its end surfaces, and the reel changer 06, that comprises end surface side frames 11, are arranged spaced from one another, when viewed in the direction of the rotational axes R04 of the printing couple cylinders 04. In the case of a plurality of printing units 01, which are all arranged in one machine alignment, the reel changer or changers 06 is or are arranged laterally next to the machine alignment, as may be seen in
After the web 03 has passed through the printing units 01 and, if applicable, through a superstructure, which is not specifically represented in detail in
The former assembly 12 can have one or more, for example, two, three or even four fold formers 19, which may be arranged side by side horizontally, and which are situated transversely to the direction of transport T2 from the same machine plane, as indicated by a dotted-dashed line in
In
As can be seen in
In the embodiment of the present invention, as depicted in
With either a manual or an automated reel loading device 22, as seen schematically in
Also shown, by way of example in
After passing around the turner bar 07, the web 03 can be guided from the top of the machine, via one or more deflection rollers 42 or deflection rods that extend parallel to the printing couple cylinders 04. The web 03 is thus guided into the printing unit 01, passing through the printing unit 01 from “top to bottom”, as seen in
As can be seen in
With this arrangement of the turner bar or bars 07 above the plane of the printing unit 01, a compact arrangement, with respect to the web leads and web lengths, and with respect to the number of guide elements, the web tension, and the like is provided. No cellar or other provisions in the area of the operating platform 17 are necessary. On the web path from the reel changer 06 to the printing unit 01, a deflection of only 90° is necessary. In this elevated arrangement, the turner bar 07 can be conventionally configured. However, in an advantageous further improvement the turner bar 07 can be configured as will be described in what follows. It is also advantageous, especially due to the provision of a path between reel changer 06 and turner bar 07 that must be bridged, to provide a transport device 31 for a non-manual infeed, as will be discussed below.
In one particularly advantageous embodiment of the present invention, and especially with respect to variable web widths and/or an automatic infeed, the turner bar 07 has outlet openings 23, which may be embodied as micro openings 23. Outlet openings 23, which are intended for the passage of a pressurized fluid, and may be configured, for example, as air outlet openings 23, are located at least in an angular wraparound region of the web 03, for example in an angular region of less than 270°. In this case, micro openings 23 are understood as being openings on the surface of the component, which micro openings 23 have an average diameter of less than or equal to 500 μm, advantageously have an average diameter less than or equal to 300 μl, and especially have an average diameter less than or equal to 150 μm.
In a preferred embodiment of the present invention, which is represented in
In the wraparound area of the turner bar 07, areas with different levels of perforation, such as, for example, areas with different hole number densities and/or hole diameters, can be provided for different angular regions. These different areas can be, for example, the web lead-in area, the trailing area of the web, or an area of the turner bar 07 that lies between these lead-in and trailing areas and which is wrapped by the web.
The microscopic holes 27 can be produced using a process in which the surface to be perforated, which may be, for example, a 2-3 mm thick aluminum sheet or pipe or pipe segment, is perforated using an electron beam. Alternatively, perforation of the turner bar 07 can also be achieved using an etching technique. However, in this case, the thickness of the material to be perforated, such as a sheet, a pipe, or a pipe segment should be less than 2 mm in the area to be perforated. In particular, such a thickness should not exceed 1.5 mm.
In contrast to the depiction shown in
In the embodiment of the present invention, which is represented in
In connection with the handling of variable web widths, such as, for example, in an embodiment of the printing press for use in the printing of full webs 03 of different widths, such as, for example, for producing different product formats, it is advantageous for the active length L07 of the turner bar 07 to be sized to match the maximum web width which will be provided for processing. The openings 28 or the microscopic holes are thus to be provided over a length L07 of the turner bar 07 which length L07, in projection on the width of the incoming web 03, corresponds to at least the maximum web width. This maximum web width can correspond, for example, to the width of at least two, or for example to a width of four, six or even eight newspaper pages in a specific print format such as, for example, a broadsheet format). If a narrower web 03, for example having the width of the same number of pages, but in a smaller print format, or having the width of a smaller number of printed pages, is to be fed to, and deflected by the turner bar 07, then edge areas of the turner bar 07 that are not wrapped need not be covered, as is otherwise customary. This is because the special structure of the air outlet openings 23 as micro openings 23, such as open pores or microscopic holes 23, results in only low leakage flows and results in low pressure losses. In one operating situation, for processing a preferably full web 03, that is narrower than the maximum possible web width, the turner bar 07 is charged or pressurized with compressed air over its entire length L07 that is equipped with micro openings. This pressurized or compressed air exits through the micro openings 23 over the entire length L07 of the turner bar 07 that has micro openings 23. However, in the uncovered edge areas of the turner bar 07 only a slight leakage flow through the uncovered micro openings 23 occurs.
The microporous layer 29 is made, for example, of a porous material. Advantageously, the layer 29 is made of a sintered material, especially is made of a sintered metal. In this case, the porous material advantageously has pores having an average pore size of 5-50 μm, and especially having a pore size of 10-30 μm. A degree of openness on the outward facing surface of the porous material lies between 3% and 30%, and preferably lies between 10% and 25%.
In a variation of the present invention which is not specifically represented here, the turner bar 07, in the embodiment with micro openings 23, can also have another special surface coating which particularly promotes the sliding of the web. One example of this embodiment would be the provision of a surface coating of a material of, for example 1.5 to 4 mm thick, and especially of 2 to 3 mm thick, and, for example, with a circular or a circle segment profile, such as, for example, an aluminum profile, with a glass bead structure. A coating that increases wear resistance can also be applied to this structure. In a further improvement, it is possible to provide a blowing device in the area shortly in front of, or directly in the winding gap of the web to the turner bar 07, with which blowing device air can be blasted under the web, and which air is carried along by the web to support the formation of an air cushion between the turner bar surface and web.
In an advantageous further improvement in accordance with the present invention, in the web path from the reel changer 06 up to the point of infeed into the printing unit 01, a transport device 31 is provided for accomplishing a non-manual, such as, for example, a motorized, infeed of a leading edge of a web. This transport device 31 preferably also extends at least in the web path up to behind the printing unit 01. In principle, with respect to the turner bar 07, this transport device 31 can be independent of the special configuration of the turner bar 07 with micro openings 23. However, this further improvement is particularly advantageous when it is combined with the configuration of the turner bar 07 with micro openings 23.
In an embodiment of one of the two crossed turner bars 07, represented by way of example from a perspective view in
To enable the helical or the spiral path of the infeed chain 33 in the guide 32, the guide 32 is preferably configured such that it can be bent in two spatial directions that are perpendicular to its direction of transport, at least around a maximum radius of curvature of 1,000 mm. One advantageous embodiment of the chain 33 that can be guided in the guide 32 is represented in
In an embodiment of the present invention, which is represented in
On the path between the reel changer 06 and the printing unit 01, full webs 03 having a width of, for example, at least two, or for example, of four, six or even eight newspaper pages in broadsheet format are fed in.
To infeed a web 03, its leading edge, such as, for example, a triangular leading edge 39; 41, is coupled to the belt 37 or to a holding element 36, indicated in
While preferred embodiments of a device and a method for feeding a material web to a printing unit of a web-fed rotary printing press, in accordance with the present invention, have been set forth fully and completely hereinabove, it will be apparent to one of skill in the art that changes in, for example, the specific type of printing press, the source of supply of the compressed air and the like could be made without departing from the true spirit and scope of the present invention which is accordingly to be limited only by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
10 2006 013 955 | Mar 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/052794 | 3/23/2007 | WO | 00 | 10/17/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/110386 | 10/4/2007 | WO | A |
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Number | Date | Country | |
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20100224088 A1 | Sep 2010 | US |