DE4121512C1 - Pressure roller for intaglio rotary printing machine - has jacket supplied with electric charges controlled by support compression force - Google Patents

Abstract

The roller consists of a flexible tubular roll casing supported via an axial line of support elements on a central bearer, the elements being controlled singly or in groups so as to exert pressure in a pressure plane. The casing (1) is supplied with electrical charges so that charge feed is controlled by the pressure applied by the support elements (5), i.e. charge input increases with the pressure. The casing consists in part of moderately conductive material (10). The partial conductive support elements are connected to a charge feedline within the bearer (3) via a switch which only releases charge to the bearing surface when the support element exerts pressure on the casing (13). USE/ADVANTAGE - Gravure printing, etc. Charges restricted to support elements exerting pressure, confining pressure roller wear to active surfaces only for extended service.

Description

The invention relates to an impression roller of a gravure printing rotary machine with an elastic tubular Roll shell, which by means of several in the axial direction juxtaposed support elements on a central carrier is supported and in which the Support elements separated individually or in groups are controllable from each other to press forces in one Exercise press level.

Such impression roller is, for example, from the CH 6 71 732 previously known and is used, for example, for Printing wide webs in one gravure rotary machine, the web to be printed pressed against a forme cylinder by means of the impression roller to the one in the forme cylinder engraving Color on the web, for example one too printing paper web, a plastic film or a  Substrate to transfer. Such pressers have that Advantage that they have an even pressure Enable impact and across the roller width perfect printing of wide webs up to the Allow a range of 10 meters. By using several support elements with separate pressure medium supply such impressionists can be different Set web widths.

With gravure printing machines it is a known effect that due to the adhesive forces and / or the capillary The color does not always fully force the color The engraving leaves well, leading to a bad one Expression leads. To avoid this undesirable effect eliminate it is z. B. from DE 20 58 315 known Surface of the impression roller electrostatically charge so that with the help of electrostatic charge the capillary forces are overcome and the color completely reaches the substrate.

A charging method is known in which the electrostatic charging of the impression roller via a Corona discharge between one at the back of the Roller arranged at a small distance and the electrode Surface of the impression roller is generated, which on electrostatic charge on the roller surface generated, with the charge on the surface distributed and over the substrate and the form cylinder drains away. Because the electrode is above the impression roller is sometimes referred to as "top loading".  

Charging systems are also known, e.g. B. from EP 1 15 611, which the cargo from the side through the Apply the impression coat to the surface. To there is the jacket of the impression roller inside next from a highly insulating layer on which one Layer with good electrical conductivity applied is brought over at least one roller end the poorer conductive soft ones above Roll shell cover protrudes. With this as "Side Loading "well-known system becomes the outstanding part the highly conductive layer from the side over the entire roller width electrically charged, with the electrical charge over the less conductive Roll cover is distributed and its surface charges. This system has the advantage that none outer electrodes are required and therefore one Component that because of its pollution a name maintenance effort required, can be omitted.

With such procedures, however, often arises Task, with the same machine of different widths Print material webs with the same impression roller to have to. With narrower webs, this leads to that Problem that the surface of the impression roller on the Where there is no material web, use the Forme cylinder comes into direct contact because of the ge the same width applies across the entire width. However, since there is no web of goods in these places, ent there the isolating effect of the web and the electrostatic charge flows along the path of the least resistance, so preferably on this uncovered areas. Where the charge for  Color transfer to the web is needed So the charge is reduced and thus the printing result worsened. To avoid this disadvantage, be sits the impression roller known from DE 20 58 315 alternately distributed over the circumference for different lengths of time capable layers that are charged separately can be used to adjust the charge delivery to different Adjust web widths. The disadvantage here is that due to the gaps between the conductor layers the impression volume only in strips, d. H. unequal is moderately charged and not optimal print quality is achievable. Furthermore, the unbe covered surfaces of the impression roller Transfer the form cylinder to the impression surface, see above that this is faster due to abrasion and that in the Paint contained solvent is destroyed.

The invention is based, which disadvantages of the prior art Remove technology and create an impression roller, with which webs of different widths in the same machine using the electrostatic To print printing aid with improved print quality, without the impression roller on uncovered Surfaces are subject to rapid wear.

According to the invention, this object is achieved by that the roll shell so with electrical charges is supplied that the charge feed individually by the pressing force of the support elements in the sense is controlled that the charge supplied with the Exercise of a pressing force is increased.  

Advantageously, an increase in the same direction Charge delivery achieved with the pressing force be that the roller shell made of a material with moderate electrical conductivity exists and that Parts of the support elements made of electrically insulating Material are executed, at least their storage areas but have good electrical conductivity and with a supply line for electrical charge in the carrier are connected via a switch which one Freight flow to the storage area only releases if that Support element a pressing force on the roll shell exercises.

The switch is advantageously off as a position switch formed, which only the charge flow to the storage area releases when the support element assumes a position, where it exerts a compressive force on the roll shell, however, the charge flow is blocked when the support element is withdrawn from the roll shell and thus does not exert any pressing force.

However, the switch can also advantageously, in particular when using hydraulic support elements with a pressure medium are controlled as a pressure switch be formed, which only the charge flow freely there if the support element with a certain Hydraulic pressure is applied and thus a press exerts force, but not when switched off Hydraulic fluid pressure, d. H. if no pressing force is exercised.  

In a further advantageous embodiment, the Roll shell executed such. B. by storage conductive particles that contribute to its conductivity Pressure or compression increases. It flows automatically on the support elements that have a pressing force exert a larger amount of charge through the rollers coat through to the outer surface.

In this way it is automatically reached and ensured that a charge flow to the roll shell only takes place where the Support elements for generating a pressing force can be controlled without taking additional precautions would be necessary. When changing the support element Control to a different web width is automatic also only the area of the roll shell with supplied electrostatic charges wherever a web is treated.

The invention is based on the in the accompanying Figures reproduced embodiments closer explained. Show it:

Fig. 1 a printing machine with an impression roller in axial section and with a forme cylinder,

Fig. 2 shows a support element with position sensors,

Fig. 3 shows a support element with a pressure switch, and

Fig. 4 shows an impression roller with a roller jacket with pressure-dependent conductivity.

In Fig. 1 a impression roller is shown as it is set in for example in a rotogravure press. It consists of a roll shell 1 which is rotatable about a fixed support 2 and is driven by a forme cylinder 3 . A web 4 to be printed runs between the forme cylinder and the roller jacket 1 , the width of which in the exemplary embodiment shown is only about 55% of the maximum possible web width.

The roll shell 1 is layer-wise in diameter and at least partially segment-wise across the width, the individual layers being made of materials of different electrical conductivity, e.g. B. consist of different elastomers. The outermost layer 10 is, for example, an approximately 10-30 mm thick cover made of rubber, to which a sufficient amount of graphite or other conductive substances have been added in order to achieve a moderate electrical conductivity of the order of approximately 10 ⁵ -10 ⁷ ohms. The same applies to the layer 11 lying underneath. Within this layer there is an approximately 0.1-0.3 mm thick highly conductive layer 12 with a speci fi c resistance under 10 ohm · m, z. B. made of copper, silver or graphite. The innermost layer of the roll zenmantels 1 represents the base body extending over the entire width of the roll in the form of a tube 13 with about 1-3 mm wall thickness, the whole or at least in its surface layer as an electrical insulator with a very high specific resistance over 10 ⁸ Ohm · m is formed. For example, it can consist of a glass fiber reinforced plastic or a similar material.

To generate the required pressing force abge supported support elements 5 are provided inside the roll shell 1 against the carrier 2 , which form a series of axially juxtaposed support elements which can be acted upon separately or in groups with pressure-controllable pressure, such as. B. described in CH 5 91 640, as in Preßrich device movable hydrostatic support elements, or in another known type with controllable pressing force. It is thus possible to vary the force profile in the pressure gap over the width in such a way that the pressing force is significantly reduced at those points which are not covered by the paper web.

In order to completely cancel the contact pressure during operation of the impression roller with a reduced web and to completely prevent a charge flow to the forme cylinder outside the web, it is particularly advantageous to provide additional support elements 7 acting counter to the pressing direction in the end regions of the roll shell 1 , which only operate are loaded with reduced web width and thereby pull the roller jacket at the ends away from the forme cylinder and thus largely or even completely prevent the flow of charge at the ends. In addition, a lifting element 8 can be provided in the middle of the roller shell, which, with the support of the counter-supporting elements 7 , allows the roller shell 1 of the impression roller to be lifted off the forme cylinder 3 when the paper feed is at a standstill.

In order to ensure that electrical charge is only supplied at those points where a material web is present and a pressing force is exerted by the supporting elements, on the one hand the highly conductive layer 12 is built up segment by segment, in that it consists of individual rings 12 ¹ , 12 lying side by side in the axial direction ² ... 12 ⁵ , which are interrupted by insulating spaces 14 . The width and arrangement of the segment rings corresponds to the axial extent and arrangement of the support elements 5 , ie each support element 5 is assigned a corresponding conductive segment ring 12 ¹ , 12 ² ... 12 ^{5 in} terms of position.

The supporting elements 5 and the corresponding cylindrical bores 5 ⁰ in the carrier 2 are now configured such that the body of the respective support element feed 15 is fed in the carrier 2 5 only electric charge via an insulated voltage when either the support member 5 in the pressing position with respect to the inner layer 13 of the roll shell 1 or when the support element 5 receives a sufficient hydraulic medium pressure via the pressure medium line 6 , ie generates a compressive force on the layer 13 of the roll shell 1 .

According to Fig. 2 this is achieved by a position switch. This consists of an electrically insulating ring 16 on the piston of the support element 5 , which is arranged in relation to the confluence of the charge supply line 15 in the carrier 2 so that when the support element 5 is withdrawn, ie not pressurized, the line 15 opens onto the insulating ring 16 and thus no electrical charge is supplied in the support element 5 . Only when the support element is pressurized via line 6 and moves into the pressing position, is there a conductive contact between the voltage supply line 15 and the body of the support element 5 , so that the support element and an electrically conductive ring 17 in the insulating layer 13 spatially assigned segment ring 12 electrical charge is supplied, which is supplied via the moderately conductive outer jacket of the web to be printed.

As shown in Fig. 3, a pressure switch 18 can be used to control the charge flow instead of a position switch, which is provided in the pressure medium supply line 6 and controls an electrical switch 19 in the charge supply line 15 such that the charge flow is only released when a predetermined hydraulic medium pressure prevails in the pressure supply line 6 . This ensures that an electrical charge to the roll shell is only passed through those support elements 5 , which are pressurized and accordingly exert a certain pressing force on the roll shell.

While FIG. 2 shows a hydrostatic support element having hydrostatic bearing surface, the support member 5 is provided in Fig. 3 with a hydrodynamic bearing surface.

Instead of controlling the charge supply directly via the support elements 5 , as shown in FIG. 4, the charge flow can also be controlled by forming the intermediate layer 11 of the roll shell 1 . In this example, the intermediate layer 11 of the roll shell consists of a pressure- or deformation-dependent material. Layers with embedded conductive particles, such as graphite or metal spheres, which normally have a certain distance from one another, have proven suitable, so that the layer has only a moderate conductivity. When pressure is exerted or the layer is deformed, for example under the influence of the support elements 5 , the layer is compressed so that the conductive particles approach or even touch one another. Therefore, the conductivity is markedly increased in the event of pressure deformation.

The conductive layer 12 is formed here as a continuous layer, at the ends 12 ^{0 of which} electrical charge is supplied via a slip ring 20 . In those places where the supporting elements do not exert any pressing force, the resistance of the layer 11 closing on the outside is relatively high, so that only a small charge flows away there. At the points at which the support elements 5 are pressurized and exert a pressing force, the conductivity of the layer 11 is greatly reduced and the electrical charge preferably flows out to these support elements. It is hereby achieved that cargo is automatically conveyed to the outer surface of the impression roller only at the points where a pressing force is really exerted, ie specifically at the points where a web 4 is located.

Claims (6)

1. impression roller of a rotogravure printing machine with an elastic tubular roller shell, which is supported by means of a plurality of supporting elements arranged next to one another in the axial direction on a central support and in which the supporting elements can be controlled individually or in groups separately from one another in order to exert pressing forces in a pressing plane, characterized in that the roller jacket ( 1 ) is supplied with electrical charges such that the charge supply is controlled individually by the pressing force of the support elements ( 5 ) in the sense that the charge supplied is increased with the application of a pressing force. 2. impression roller according to claim 1, characterized in that the roller shell ( 1 ) partially consists of a material ( 10 ) with moderate electrical conductivity and that the at least partially conductive support elements ( 5 ) with a feed line ( 15 ) for electrical charge in Carriers are connected via a switch ( 16 , 18 , 19 ), which only releases a charge flow to the bearing surface when the support element ( 5 ) exerts a pressing force on the roller shell ( 13 ). 3. impression roller according to claim 2, characterized in that the switch as a position switch ( 16 ) is formed, which only releases the charge flow to the bearing surface when the support element ( 5 ) assumes a position in which there is a pressing force on the roller shell ( 13th ) exerts, but blocks the charge flow when the support element ( 5 ) is withdrawn from the roller shell ( 16 ) and thus exerts no pressing force. 4. impression roller according to claim 2, characterized in that the support elements ( 5 ) are hydraulically pressurized bar and the switch is designed as a pressure switch ( 18 , 19 ), which only releases the charge flow when the support element ( 5 ) with a certain hydraulic pressure is applied and thus exerts a pressing force, but not when the hydraulic medium pressure is switched off, ie when no or too little pressing force is exerted. 5. impression roller according to claim 1, characterized in that the roller shell ( 1 ) is designed so that its conductivity increases locally when pressure or compression by a support element ( 5 ). 6. impression roller according to claim 5, characterized in that at least one layer ( 11 ) of the roll shell has inclusions of conductive particles which approach the layer upon compression deformation of the layer.