FI100585B - Method and apparatus for applying the coating butter to paper or cardboard web - Google Patents

Description

5 100585

The present invention relates to a method for applying a coating to a surface of a moving paper web or board web with a nozzle applicator according to the preamble of claim 1.

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The invention also relates to an arrangement for carrying out the method.

In nozzle applicators, the coating composition is applied to the surface of the track 15 by a separate extrusion nozzle. There are various types of nozzle applicators, and the present invention relates to a jet applicator in which a coating composition is fed to a web as a jet through a narrow slot the width of the web. The device is also known as a fountain coater. In jet or fountain type application, typically the entire amount of applied coating is transferred to the surface of the track. The coating is applied against the track supported by the counter roll and usually the coating is leveled with a scraper blade against the same counter roll immediately after application of the coating. The coating jet can be adjusted by changing the width of the jet gap, the angle of the jet and the position of the lips forming the gap. The application of the coating puts little strain on the track and the need to pump the coating is reasonably small, so the required scraper blade load requirement is lower than, for example, in the brush roller application, which improves runnability and increases blade life.

European patent application 91306138.8 describes a nozzle applicator in which the application takes place as described above. The device includes a rotating counter roll, 35 a nozzle with a nozzle slot fitted in the vicinity of the track supported by the counter roll. The coating is fed to the track from the nozzle slot and scraped to the specified thickness with a scraper blade fitted to the counter roll. The nozzle is rotatably mounted so that its angle to the counter roll is adjustable. The rotation is made around the tip of the nozzle, so that the distance between the nozzle and the track does not change when the angle of the nozzle-5 is changed.

In a jet applicator, the energy of the coating jet must be sufficient to break the air curtain that accompanies the track. At high speeds, a considerable amount of air travels with the track, so the speed and mass of the jet (thickness, amount of application) must be increased so that the air layer does not cause uncoated patches. With a sufficiently fast jet and a large number of applications, track speeds of approx. 1500 - 1600 m / min can be reached with current equipment, 15 but then the large mass flow coming to the scraper blade easily causes sharp vibrations. To facilitate scraping, the amount of coating to be applied should be as close as possible to the final amount of coating, but with such devices such small amounts of coating cannot be achieved. However, if the application rate is less than 150 g / m 2, the scraper succeeds with a very reasonable blade load, so the jet applicator should reach such an application rate even at high speeds. However, with the above-mentioned application rate, the coating jet at high speeds 25 does not penetrate the air curtain accompanying the track well enough and would leave plenty of uncoated spots on the coating. Since the speed of the coating jet cannot be increased indefinitely, it is necessary to use a large amount of application to penetrate the air curtain. However, even with large amounts of appli-30, the coating will not be applied to the track surface if the track speed is above 1500 - 1600 m / min.

The object of the present invention is to provide a method and an arrangement by means of which air enters between the coating jet and the track 35.

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The invention is based on the arrangement of an air nozzle in front of the coating nozzle in the inlet direction of the track, with which an air jet is blown against the inlet direction of the track. The air jet prevents the air carried by the track from entering the application area.

More specifically, the method according to the invention is characterized by what is set forth in the characterizing part of claim 1.

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The arrangement according to the invention, in turn, is characterized by what is stated in the characterizing part of claim 7.

The invention provides considerable advantages.

The invention significantly improves the stability of the coating jet and reduces the risk of uncoated patches appearing. The amount of application can be reduced considerably by 20 and the coating layer becomes smoother, which makes scraping easier and the load on the track decreases as the blade load decreases. This improves driveability. The speed of the coating jet can be chosen more freely because the jet does not have to pass through the air layer. The amount of circulating coating 25 is reduced, resulting in better performance of filters and deaeration, which also improves the quality of the coating. Killing of the coating is also reduced because no air flow hits the coating jet. The method according to the invention does not stress the track and is completely intact. The coating speed can be increased because the air carried by the track does not interfere with the coating and the scraping is less stressed because the amount of coating applied can be kept smaller.

The invention will now be described in more detail with reference to the accompanying drawing, which is a schematic cross-section of one embodiment of the invention.

4 100585 The direction of travel of the track 2 to be coated is shown in the figure from left to right and the track 2 is supported by a counter roll 1. The nozzle application device is a so-called downstream, in which the coating jet 7 is directed to the track 2 downstream of the direction of travel of the track.

5 The applicator nozzle itself can be any known jet nozzle. The structure of the nozzle is very simple and comprises an application chamber into which the coating is fed and a nozzle gap 6 opening from this chamber. the position. These control devices are known per se, so it is not necessary to describe them here.

The velocity distribution of the air flow accompanying the track 2 is shown in Figure 3. As is known, the flow velocity is greatest in the vicinity of the moving surface and decreases as it moves away from the surface, as shown in Figure 3. The entry of this air stream between the coating jet 7 and the track 2 is prevented by the air flow of the fan 8 blowing from the slot 8. The air jet part of the nozzle is formed by an air duct 9 delimited by a wall 10, which opens through the air jet slot 8 behind the coating jet 7. In addition to the wall 10, the air gap 8 is delimited by a front wall 11 which reverses the air flow against the incoming direction of the track 2. The air is blown towards the track 25 and against its incoming direction at a suitable angle so that the air jet hits the track if its direction does not change under the influence of the air accompanying the track. Naturally, the currents in the area of the air jet depend on the velocities and energies of the air accompanying the jet and the track.

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The air flow blown against the direction of movement of the track 2 prevents the air accompanying the track from entering the application area by molding the air off the surface of the track. The energy of the air flow to be blown determines the conditions in the space 12 between the air jet and the cover jet 7. The already very low blown air energy gives a better application result, but it is naturally advantageous that there is no overpressure in space 12 or that there is little underpressure. . The appropriate air jet speed can be easily adjusted by changing the pressure of the air supplied to the nozzle gap.

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The air nozzle must be kept clean to ensure its operation. When using nozzle application in a downward direction with the track to be coated, there will be little spatter in the inlet direction of the track if the speeds of the track and the jet 10 are properly matched. Naturally, however, some splashing occurs, especially in the event of disturbances and when the equipment is started up. The adhesion of splashes to these nozzles in these situations can be reduced by using humidified air and cooling the air to be blown and the surfaces of the nozzle.

In addition to the above, the present invention has other embodiments. The air nozzle may be part of the coating nozzle as described above, but a separate nozzle may also be used. A separate nozzle is suitable for retrofitting if it can be installed close enough to the coating nozzle. If the distance between the air nozzle and the coating nozzle increases, the access of air to the area between the nozzles must be restricted, for example by a housing, but then the structure becomes complicated and the efficiency of the air design is reduced. The air nozzle can be made adjustable. The most important variable to be adjusted is the angle of the jet with respect to the path, in addition to which it is conceivable that the width of the adjustment gap is changed to control the speed of the jet. However, it is simpler to adjust the jet speed by changing the pressure of the air to be sprayed. The direction of the jet can also be parallel to the tangent of the track, so that it does not face the surface of the track. In this case, the speed of the jet must be so high that it creates a vacuum between the jet and the track, which prevents the air carried by the track from entering the application zone at high speed.

Claims (11)

100585 A method of applying a coating to the surface of a moving paper or board web (2), the method 5 - applying the web (2) to a rotatable counter roll (i), - applying the coating (7) to the web (2) in a proximal, non-contact and through a nozzle slot (6) adapted to the direction of travel of the track, and - the coating (7) is applied to the track (2) in an amount substantially completely transferred to the track (2), characterized in that - air is blown against the direction of travel of the track (2) 20 transversely to the direction of travel of the track and in the direction of entry of the track through an air nozzle (8, 9, 10, 11) arranged in front of the nozzle slot (6). Method according to Claim 1, characterized in that the jet of the air nozzle (8, 9, 12, 11) is directed at an angle to the surface of the track (2). Method according to Claim 1 or 2, characterized in that the speed of the air jet is adjusted by varying the pressure of the air to be sprayed. Method according to one of Claims 1, 2 or 3, characterized in that the coating stream (7) to be sprayed from the nozzle slot (6) is directed downstream of the track (2). 100585 Method according to one of Claims 1 to 4, characterized in that the speed of the web (2) to be coated is at least 1500 m / min and the amount of coating to be applied is at most 150 g / m 2. 5 Method according to one of Claims 1 to 5, characterized in that the air jet is placed as close as possible to the coating jet (7) and the velocity of the air jet is adjusted so that a vacuum is created between the air jet and the coating jet (7). An arrangement for applying a coating to the surface of a moving paper or board web (2), comprising: 15. a rotatable counter roll (1) for supporting the web (2), and - in contact with the web (2), intact and transverse to the direction of travel 20 for supplying the coating (7) of the nozzle gap (6) to the track (2), characterized in the direction of entry of the track 25 in front of the nozzle slot (6) and picking up the air nozzle (8, 9, 10, 11) adapted to blow the track 2) against the direction of travel. Arrangement according to Claim 7, characterized in that the air nozzle (8, 9, 12, 11) is oriented at an angle to the surface of the track (2). An arrangement according to claim 7 or 8, characterized by means 35 for adjusting the speed of the air jet by changing the pressure of the air to be sprayed. 100585 s Arrangement according to one of Claims 7 to 9, characterized in that the nozzle slot (6) is directed downstream of the track (2). Arrangement according to one of Claims 7 to 10, characterized in that the air nozzle (8, 9, 10, 11) is arranged as close as possible to the coating nozzle (7), preferably as an integral part thereof. 100585