EP0235166B1 - Device for applying a liquid to a material web - Google Patents

Abstract

The applicator cylinder (2) can be driven in both rotation directions. In order to coat the material web (1) using a counter-rotating system a spreader cylinder is applied to the applicator cylinder (6). In this way it is possible to draw off the liquid film (1) from the same reservoir zone (5) as with a concomitantly-rotating system. This saves displacing the metering cylinder (4) which remains in situ during both counter and concomitant rotation.

Description

The invention relates to a device for applying a liquid to a material web according to the preamble of claim 1. Such devices are used, for example, on roll coating machines for coating paper or cardboard. The possibly pretreated, printed or unprinted material web is guided past the application roller, which applies a lacquer film to the material web. The coated web of material is then fed to a dryer which e.g. Depending on the nature of the lacquer, the coating hardens or dries by UV polymerization or by infrared radiation.

Known roll coating machines can apply the coating film in the same direction or in the opposite direction to the material web. To change the operating mode, however, the machine has to be changed: in the case of a synchronous coating, the reservoir zone is arranged in the feed direction before the material web enters the application roller, while the metering roller or the reservoir zone is arranged in the feed direction if the coating is counter-rotating Material web) is arranged behind the application roller. In both cases, the paint film leaves the reservoir zone with the liquid to be applied through a thin gap which is formed between the metering roller and the application roller.

To change from co-rotating coating to counter-rotating coating, either a second metering roller has to be fed against the application roller and the first metering roller has to be disengaged, or separate storage locations for the metering roller have to be provided in both operating modes, which then requires a conversion of the coating system. In this context, the supply of the liquid or the lacquer to be applied either to both metering rollers or changing them in different operating modes poses particular problems. The changeover is also very complex since the rollers first have to be cleaned, for which purpose the liquid still in the reservoir zone has to be removed. The changeover takes time and personnel.

It is therefore an object of the invention to provide a device of the type mentioned at the outset in which a changeover of the metering roller is no longer necessary and in which the liquid film is removed from the same reservoir zone both in the case of co-rotating coating and counter-rotating coating.

According to the invention, this object is achieved by a device which has the features of claim 1. The retention of the metering roller on one side of the application roller and the arrangement of the additional distributor roller, which can be coupled or uncoupled, allows coating in the simplest way to only coat with one metering roller in the same direction and in the opposite direction. In the case of synchronous coating, the additional distributor roller is disengaged and swiveled away and in itself has no function. The coating is carried out in a manner known per se, in that the liquid film is discharged downward from the reservoir zone through the gap between the metering roller and application roller and is applied in synchronization with the web feed. In order to be able to coat a material web in the opposite direction with the same device, only the direction of rotation of the application roller has to be changed and the distributor roller has to be coupled. The liquid film is removed from the same reservoir zone, but not downwards through the gap between the metering roller and application roller, but upwards against the apex of the application roller. In order to ensure a uniform liquid film on the application roller, the distributor roller now takes over the actual dosing function.

The distributor roller is particularly advantageously deliverable to the upper half of the application roller approximately in the region of the apex of the application roller. In this way, excess liquid which accumulates in front of the gap between the distributor roller and applicator roller can flow back into the reservoir zone.

The distributor roller can preferably be driven in the opposite direction to the application roller, so that an optimal distribution of the liquid film takes place. The distributor roller can preferably be driven by a gear which can be coupled to the axis of the application roller. This ensures that the distributor roller always has the correct direction of rotation in counter-rotating operation. The gear unit and the distributor roller preferably form a unit which can be displaced against the application roller or away from it by means of an infeed device. In this way, in synchronous operation, in which the distributor roller has no function, there is no need to drive gear parts unnecessarily.

If the infeed has at least one rack, which meshes with a gear on the displaceable unit in such a way that the latter can be displaced along the rack by rotating the gear, the gear unit can be fed with the distributor roller without effort and coupled effortlessly.

• Figur 1 eine bekannte Vorrichtung im Gleichlaufbetrieb,
• Figur 2 eine bekannte Vorrichtung im Gegenlaufbetrieb,
• Figur 3 eine erfindungsgemässe Vorrichtung im Gleichlaufbetrieb,
• Figur 4 eine erfindungsgemässe Vorrichtung im Gegenlaufbetrieb,
• Figur 5 eine Seitenansicht auf eine erfindungsgemässe Vorrichtung mit schematisch dargestellten Getriebeteilen, und
• Figur 6 eine vereinfachte Draufsicht auf die Zustellvorrichtung.

An embodiment of the invention is shown in the drawings and will be described in more detail below. Show it:

• 1 shows a known device in synchronous operation,
• FIG. 2 shows a known device in counter-rotating operation,
• FIG. 3 shows a device according to the invention in synchronous operation,
• FIG. 4 shows a device according to the invention in reverse operation,
• Figure 5 is a side view of an inventive device with schematically illustrated gear parts, and
• Figure 6 is a simplified top view of the delivery device.

Figures 1 and 2 show the operation of a device known per se. An application roller 2 can be driven in both directions of rotation C and D. The material web 3 is always advanced in the direction of arrow A and pressed by the counter-pressure roller 12, which rotates in the direction of arrow B in synchronization with the material web 3. In the feed direction in front of the application roller 2, a metering roller 4 is arranged, which can be set in the direction of arrow H. The metering roller 4 forms, together with the application roller 2, a reservoir zone 5 for the liquid to be applied. A liquid film 1 is drawn off from this reservoir zone through the gap between the application roller 2 and the metering roller 4 and transferred to the material web 3. The liquid which adheres to the metering roller 4 is stripped off with a doctor blade 11.

For a counter-rotating coating, the metering roller 4 is now removed and reinstalled in the feed direction after the application roller 2 at prepared bearing points. In this position, too, the metering roller 4 can be advanced in the direction of arrow H. However, the application roller 2 now rotates in the direction of the arrow D in the opposite direction to the advance of the material web 3. The liquid film is not pressed onto the material web, but is scraped off on the surface of the material web. Before the metering roller 4 can be changed, it is evident that the liquid in the reservoir zone 5 must first be drained off and a new liquid supply must be connected in the opposite direction.

FIGS. 3 and 4 show the device according to the invention. In Figure 3, the arrangement of the rollers and the directions of rotation are the same as in Figure 1. The mode of operation is also unchanged. In addition, a distributor roller 6 is provided, which is adjustable in the direction of arrow G and remains in the waiting position during synchronous operation.

If the application device is to be operated in the counter-rotation mode, the distributor roller 6, as shown in FIG. 4, is delivered to the application roller 2. With the infeed there is a coupling to the drive device of the rollers. At the same time, the metering roller 4 is fed as close as necessary to the application roller 2 so that the desired amount of lacquer is conveyed upward through the gap.

The direction of rotation of the application roller is changed for counter-rotating operation. The liquid film 1 is discharged from the same reservoir zone 5 as in synchronous operation, but does not leave the reservoir zone downwards through the gap between the application roller and the metering roller, but rather upwards against the apex of the application roller 2. In section 14 between the metering roller 4 and the distributor roller 6, the layer thickness of the liquid film is relatively uncontrolled. A distribution of the liquid and an adjustment of the film thickness takes place, however, through the distributor roller 6, which now takes on a function similar to that of the metering roller 4 in the exemplary embodiment according to FIG Gravity can flow back into the reservoir zone 5.

The distributor roller 6 rotates in the direction of arrow I in the opposite direction to the application roller 2 and is also provided with a doctor blade 11.

FIG. 5 schematically shows, for example, a gear arrangement with which the distributor roller 6 can be driven. The gear 7 is driven by the axis 8 of the application roller 2, on which a drive gear 16 is arranged. In the engaged state, this gear meshes with the gear 17, the axis of which drives a toothed belt 18. The rotational movement is finally transmitted to the distributor roller 6 via further gear wheels 19.

The entire transmission 7 forms, together with the distributor roller 6, a displaceable unit 20 which can be displaced along the rack 13 in the arrow direction G. The unit 20 can have, for example, side walls 21, which at the same time carry bearing points for the different transmission parts.

Figure 6 shows, for example, two racks 13 which are arranged in the direction of displacement G. The distributor roller 6 is mounted between the two parallel side walls 21 and 21 'of the unit 20. The two side walls also form a bearing point for the axis 22, which is provided on one side with a rotary handle 23. On the axis 22, the gears 10 and 10 'are arranged, which mesh with the racks 13 and 13'. By turning the rotary handle 23, the unit 20 can obviously be moved back and forth along the toothed racks in the direction of arrow G. When turning away, the gear 17 of the gear comes out of engagement with the drive gear 16. The unit 20 is moved so far that it does not hinder the work process when the applicator roller is operating in synchronism. Of course, it is also conceivable to implement the transmission on the transmission 7 in a different way.

The coupling shown in FIG. 6 can also advantageously be carried out analogously to a drive (not shown) of the metering roller 4 instead of to the drive of the application roller 2. This variant would even have the advantage that the metering roller 4 and distributor roller 6 could be controlled independently of the speed of the application roller 2. As a result, the thickness of the liquid or lacquer layer transferred could be set completely independently of the speed of the application roller 2.

Claims (9)

1. Apparatus for applying a liquid to a web of material (3) comprising an applicator roll (2) which can be driven in both directions of rotation and at the surface of which the web of material can be advanced tangentially in the same direction or in the opposite direction of movement, and a metering roll (4) which can be moved towards the applicator roll (2) and which is so arranged that, together with the applicator roll (2), it forms a reservoir zone (5) for the liquid to be applied, wherein in a first direction of rotation the liquid can be pressed through the gap formed at the bottom of the reservoir zone (5) between the applicator roll (2) and the metering roll (4) and from there can be conveyed or transferred on to a web of material, characterised in that in a second opposite direction of rotation of the applicator roll (2) the liquid can be conveyed freely upwardly out of the reservoir zone (5), that is to say away from the gap between the metering roll (4) and the applicator roll (2), and that there is provided a distributor roll (6) which when the drive is in the second opposite direction can be moved towards the applicator roll (2) in the region between the reservoir zone (5) and the line of contact of the web of material and the applicator roll (2), and that the liquid to be applied can be metered through the gap formed between the distributor roll (6) and the applicator roll (2).

2. Apparatus according to claim 1 characterised in that the distributor roll (6) is arranged at the periphery of the applicator roll between the upper zenith thereof and the metering roll (4) which is arranged at a lower level, and that an accumulation ofliquid which is formed at the entry gap between the distributor roll (6) and the applicator roll (2) can flow back under the influence of the force of gravity into the reservoir zone (5).

3. Apparatus according to claim 1 or claim 2 characterised in that the metering roll (4) is arranged upstream of the applicator roll (2) in the direction of forward feed movement of the web of material (3) and that, when the applicator roll (2) is driven, the distributor roll (6) can be selectively uncoupled or can be driven together with the applicator roll.

4. Apparatus according to claim 3 characterised in that the distributor roll (6) can be moved towards the upper half of the applicator roll (2).

5. Apparatus according to one of the preceding claims characterised in that the distributor roll (6) can be driven in opposition to the applicator roll (2).

6. Apparatus according to one of the preceding claims characterised in that the distributor roll (6) can be driven by a transmission means (7) which can be coupled to the shaft of the applicator roll (2).

7. Apparatus according to one of the preceding claims characterised in that the distributor roll (6) can be driven by a transmission means which can be coupled to the shaft of the metering roll (4).

8. Apparatus according to claim 6 or claim 7 characterised in that the transmission means (7) and the distributor roll (6) form a unit which is displaceable towards and away from the applicator roll (2) by means of an adjusting device.

9. Apparatus according to claim 8 characterised in that the adjusting device comprises at least one toothed rack (13) which meshes with a gear on the displaceable unit in such a way that the displaceable unit is displaceable along the rack by rotary movement of the gear.

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