DE10012347A1 - Curtain coating applicator for a moving paper/cardboard web has electrodes at given electrical potentials to generate magnetic fields to affect the coating medium flow between the applicator and web surface in direct or indirect coating - Google Patents

Abstract

The applicator station (10), to apply a coating of a liquid or paste medium (16) on one or both sides of the web surfaces (U) of a moving web, uses a curtain coating action. A unit (30) to generate an electrical field is near the curtain coating applicator (12), to give a supporting force for the coating curtain (18) which falls from the applicator (12) to the web coating surface (U). The coating medium (16) falls by gravity as a curtain (18) from the applicator (12) to the moving web coating surface (U). Or the applicator (12) is a free jet unit, where the ejection pulses carry the coating stream to the coating surface. The applicator (12) is held at a given electrical potential (V1), and a second electrical potential (VE or V2) is at the web coating surface (U), at least in the zone of the applicator (12). An electrode array (30) is at the upstream side of the applicator (12) and close to it, preferably at a gap from the web coating surface (U) and which is held at a third set electrical potential (V3). The electrode array (30) has at least one flat electrode, with a number of projections or needle points on the side towards the moving web, or it has a number of neighboring needle electrodes (32) across the web coating surface (U). A further electrode array (46) is downstream of the coating medium strike point (P) at the web coating surface (U), to generate an electrical field to give a force towards the coating medium (16) on the coated surface (U). The electrode array (46) is held at a fourth defined electrical potential (V4). The first and/or third and/or fourth electrical potentials (V1,V3,V4) have a value of 5-60 kV and preferably 30 kV. The second electrical potential is an earth potential (VE). The web (20 for coating is supported by a counter roller (22), at the application point where the coating medium is applied to the web surface directly or indirectly. The support roller (22) is in contact with an electrode, to hold it at the second electrical potential value (V2). The outer surface (22a) of the support roller (22) is in slip contact with the electrode (50), or the electrode is in slip contact with the roller shaft axis (A). Where the coating is applied directly, the web (20) passes around a web guide as an electrode (48), held at the second electrical potential (V2). A magnetic field generator can be used instead of or in addition to the electrode arrays (30) and/or (46), to affect the movement of the coating medium (16). A suction unit (34), to weaken the air layer (G) carried by the moving web surface (U), is in front of the electrode array (30) in the direction (L) of web travel. A drag scraper (36) is at the downstream end of the suction unit (34), with preferably a further electrode (40) between the scraper (36) and the downstream end of the suction unit (34), using a number of adjacent and preferably needle electrodes across the web or a flat electrode with a number of projections or needle points on the side towards the web, and at a gap of 2-30 mm from the web surface and with a floating electrical potential. The electrode array (40) is electrically insulated (42) against the suction unit (34). The applicator (12) and/or the suction unit (34) are held at a given electrical potential, and preferably earth potential (VE). An Independent claim is included for a web coating assembly with an edge guide to define the side edges of the coating curtain (18) over at least part of its falling movement through gravity, between the applicator (12) and the web coating surface (U). Preferred Features: At least one side edge guide has a surface structure so that the wetting angle set by the characteristics of the coating medium (16) and the guide surface is <= 90 deg . The curtain edge guide surface can be structured or roughened or toothed or has an outer spiral. At least one curtain edge guide is of glass or metal, and can slide laterally (Q) across the web coating surface (U). The curtain edge guide can be adjusted at an angle to the vertical. An electrode, at a given electrical potential, is near at least one coating curtain edge guide, and preferably parallel to it.

Description

The invention relates to a device for one-sided or two-sided Apply liquid or pasty application medium to one run the underground, including a curtain commission, which the Application medium as moving essentially due to gravity Releases curtain or veil to the surface, the surface at direct application of the surface of a material web, especially paper or cardboard, and with indirect application the surface of a transfer elements, preferably a transfer roller, which is the order medium then transfers to the surface of the material web.

When coating material webs using a curtain Commissioned work (also known as "curtain coating") the application medium to the surface in the form of an application medium Curtain, which is essentially due to gravity from Commissioned work moved to the underground. That the curtain commission is at a predetermined distance from the ground Among other things, it has the advantage that it breaks down, for example is exposed to a lower risk of damage. Curtain order works differ from other "contactless" commissioned works, for example free jet nozzle applicators, in which the movement of the order medium from the order work to the substrate mainly comes from the ejection impulse from the delivery nozzle of the application unit, fundamental because the shape of the curtain emerging from the dispensing nozzle only the interplay between the surface tension of the Application medium and gravity. The surfaces tension tries to remove the curtain that is related to its volume or its cross-sectional area has a very large surface or circumferential length has to contract so as to reduce its surface area. This  Effect only resists gravity, which the curtain too stretch seeks. It is therefore easy to see that it is all the more difficult a uniformly thick application gas medium over the entire working width Obtain curtain, the larger this working width.

The coating of material webs using a curtain applicator, that the web of material the application medium as essentially difficult moves the application medium curtain or veil due to force, is from the coating of photographic films, tapes and the like has long been known. However, the material webs have These fields of application have a considerably smaller width than this modern plants for the production of paper and cardboard webs where material web widths of more than 10 m are required. Form an application medium curtain that is uniformly thick over this width and being able to keep it stable is a task that is anything but is obvious from the comparatively easy to control known narrow application medium curtains suggestions for a functional solution to be expected. In addition, the move Material webs in modern plants for the production of paper and Cardboard webs with speeds of up to 3000 m / min what a Is a multiple of the speed at which the known move narrow material webs, and also another high Represents a burden on the stability of the application medium curtain.

DE 199 03 559 A1 presents a whole series of active principles, which should make it possible to carry along the material web Air boundary layer immediately in front of a curtain application weaknesses. On the possibilities of the efficiency of these active principles improve, this document is not considered.

WO 97/03009 deals with the problem of drying Material webs after the application of media, namely printing inks,  especially in deep web offset and flexo printing. She suggests that Gas molecules on the surface of the material web by means of a corona Ionize discharge and accelerate toward an electrode to due to the gas exchange at the Material surface to increase the drying efficiency.

For the sake of completeness, we refer to the further state of the art DE 198 03 240 A1 and DE 198 29 449 A1 referenced.

In contrast, it is an object of the present invention, the "curtain Coating "for use in plants for manufacturing or / and finishing of wide and fast moving material webs, preferably from Paper or cardboard to further improve, especially what the Stabili of the curtain.

This object is achieved by a device for one-sided or double-sided application of liquid or pasty Application medium on a running surface, including a curtain Commissioned work, which is the order medium as essentially gravity moving curtain or veil on the surface emits, with the surface the surface of a direct application Material web, in particular made of paper or cardboard, and with indirect Apply the surface of a transfer element, preferably one Transfer roller, which is the application medium then to the surface transmits the web of material, and the subsurface in the area of Curtain applicator on a first predetermined electrical Potential is kept and that in the direction of the underground in front of the Curtain application an electrode arrangement at a distance from that Is arranged underground, which on one of the first potential different, second predetermined electrical potential is maintained.  

In contrast to conventional curtain applicators, moved the application medium curtain in the curtain according to the invention Application device not only under the influence of gravity or not only under the influence of the ejection pulse from the discharge nozzle to the underground. Rather, this movement is caused by an electrostatic Force supported by the electrical field between the electrical the arrangement and the surface of the application medium curtain is practiced and the curtain on its way from the dispensing nozzle to Seek to stretch underground (pre-stretching). Therefore, either at equal distance between the dispensing nozzle and the surface the stability of the Curtain can be increased, or the distance between the dispensing nozzle and Choose a larger surface for the given desired stability become.

The latter is particularly advantageous when you consider that the Total stretch of the application medium from one to the other Dispensing nozzle determined curtain thickness up to the thickness of the ultimately on the surface applied layer of application medium from the Pro product of the above-described stretching of the curtain on the Away from the dispensing nozzle to the surface and the contact extension composed of the difference between the speed the curtain immediately before it hits the ground and the Running speed of the surface when the application medium comes into contact comes from the underground. To achieve one as equal as possible moderate order shift, it is advantageous if the Total stretching as evenly as possible from pre-stretching and contact stretch composed. Because the application medium curtain is all the more vulnerable for external influences, for example for the influence of the underground air boundary layer, the longer the path of the application medium from the discharge nozzle to the surface, this always runs in practice on the Desire for the strongest possible extension.  

Beyond that, however, the electric field is also applied to the curtain exerted a force that is orthogonal to the direction of its fall has trending component, d. H. the electrode arrangement pulls the Curtain on. This force component also helps to Curtain against the influence of the surface of the underground stabilize entrained air boundary layer.

The electrode arrangement can comprise at least one flat electrode. The flat electrode can be on its side pointing towards the surface have a plurality of protrusions or needle tips. Alternative is however, it is also possible for the electrode arrangement to have a plurality of Individual arranged adjacent to one another in the transverse direction of the subsurface electrodes, preferably needle electrodes. Through the use of Needle tips or needle electrodes can be achieved that the electro not only arrange their surroundings by means of the earth pot tially formed electric field, but that it is beyond discharge processes can also occur in which the surrounding area air is at least partially ionized, and the resulting Load carriers lead to a charging of the application medium curtain. After such charging, the movement of the application medium can Curtain can be influenced even more effectively by the electric field.

The influence of the air carried on the surface of the subsurface to keep the boundary layer on the curtain low, it is proposed that the electrode arrangement in the running direction of the substrate is a front Direction to weaken the air boundary carried by the subsurface layer is upstream. This can weaken the air boundary layer device include a suction device, with the help of the Air boundary layer can be actively removed from the running surface.

For example, at the downstream end of the suction device Drag scraper in contact with the surface  his. This drag scraper seals the suction device to the environment down and hinders the further movement of the air boundary layer to open supporting structure. As a result, the air carried in the air boundary layer dammed up what the laminar character of the flow of the air boundary layer at least partially destroyed. This facilitates suction and increases the Suction efficiency of the suction device. Thus the air boundary layer can pass through the suction device designed according to the invention is particularly effective weakened, if not completely removed from the surface.

The drag scraper can be a flexible film, preferably made of plastic, Metal sheet or a composite material may be formed. The flexible Foil nestles against the suction of the suction device the substrate, which improves the sealing on the one hand and prevents others from building a new air boundary layer. Is the Drag scraper made of sheet metal, preferably stainless steel sheet with a thickness of at most 0.1 mm. As beneficial have also scrapers made of composite material with a Surface coating made of Teflon proven. The composite material ensures doing so for the required temperature resistance and flexibility Teflon surface coating for low friction between the drag scraper and the running surface. Furthermore, the Drag scraper curved in the direction of travel, which is the elastic end softened and further reduces friction with the surface.

In a development of the invention it is proposed that in the area of Suction device, preferably between the downstream end of the Suction device and the scraper, another electrode arrangement is provided. Also with the help of this further electrode arrangement can influence the air boundary layer carried by the subsurface and especially weakened. Especially when the other electrodes arranging a plurality of each other in the transverse direction of the substrate adjacent individual electrodes, preferably needle electrodes,  comprises, or if the further electrode arrangement at least one Includes flat electrode, which points towards the underground Side has a plurality of projections or needle tips, it can between the tips of the further electrode arrangement and the lower discharge processes also occur. These discharges disrupt the laminar disturbance of the air boundary layer and at least convert it partially into a turbulent flow, which means vacuuming the air boundary layer relieved and thus the effectiveness of the suction device further improved. To support the emergence of these discharges suggested that the further electrode arrangement be from the underground has a distance of between about 2 mm and about 30 mm.

The further electrode arrangement can in principle be connected to an external one Power supply must be connected. However, it is also possible and constructively even easier to implement if the electrical Potential of the further electrode arrangement is kept in suspense ("floating potential"). In this case, the further electrode arrangement due to the discharges emanating from the first electrode arrangement charged and thus also to a different from the ground potential Brought potential. To reduce the capacity of the other electrodes order and for security reasons it is proposed that the white tere electrode arrangement on the suction device of this electrically is arranged in isolation.

That or the predetermined electrical different from the earth potential Potentials can have a value of between 5 kV and approximately, for example 60 kV, preferably about 30 kV.

As already mentioned above, the substrate is preferably on Earth potential held. This can be achieved, for example, by that a counter element, preferably a counter roller, which with direct Order supports or supports the material web in the area of the order work  whose surface the application work the application medium with indirect Application, is in contact with an electrode to place it on the to hold the second predetermined electrical potential. In addition or Alternatively, however, it can also be provided that the surface of the Counter element is in sliding contact with the electrode. After all it is also possible that the electrode with a bearing shaft of the counter roller is in electrically conductive contact. With direct order comes as Another alternative is to add a web of material for example as a web guiding element on the second electrode predetermined electrical potential, thus preferably the earth potential, holds.

For safety reasons, it is also proposed that the curtain Application work and / or the suction device on a predetermined electrical potential, preferably earth potential.

The invention is explained below using an exemplary embodiment based on the attached drawing will be explained in more detail. It shows:

Fig. 1 is a rough schematic side view for explaining the structure and function of an application device according to the invention.

In the single figure, an application device according to the invention is generally designated 10. It comprises a curtain applicator 12 with a dispensing nozzle 14 , from which application medium 16 in the form of a curtain 18 is dispensed onto a substrate U moving in the running direction L. In the exemplary embodiment shown, the subsurface U is the surface 20 a of a material web 20 which partially wraps around the peripheral surfaces of a support roller 22 in the region of the application unit 12 .

On its way from the dispensing nozzle 14 to the underground U, the carrier medium 16 is accelerated. This leads to a reduction in the thickness of the curtain 18 from the value D in the region of the dispensing nozzle 14 to the value d immediately before the point of impact P on the substrate U (pre-stretching). Due to the difference between the speed of the application medium curtain 18 immediately before the impact position P and the running speed of the substrate U, the application medium 16 is stretched again when it hits the substrate U, so that the application layer 24 applied to the substrate U ultimately has the thickness s (Contact extension). The total stretching of the application medium 16 results as the product of the stretching factors of pre-stretching and contact stretching.

In practice, the application medium 16 is usually stretched more when striking the underground U than on the way from the dispensing nozzle 14 to the underground U, since the falling distance between the dispensing nozzle 14 and the underground U is not arbitrarily large in view of the most stable curtain 18 possible can choose. Too much contact stretching has a partial effect on the uniformity of the application layer 24 applied to the substrate U.

The applicator 10 of the invention now provides a means by which one, either at the same height of fall between discharge nozzle 14 and base U, the pre-stretching of the curtain 18 can amplify or how to reduce the fall height between the discharge nozzle 14 and base U at the same pre-stretch, and thus the curtain 18 can stabilize. Namely, according to the invention, the application medium curtain 18 is not only left to gravity on its way from the dispensing nozzle 14 to the substrate U, but also electrostatic forces are exerted on it. This strengthening of the forces stretching the curtain 18 has a higher stability of the application medium curtain 18 , since the surface tension of the application medium 16 , which tries to contract the curtain 18 in the sense of a reduction in its surface area, remains constant.

To provide the electrostatic forces, an electrode arrangement 30 is provided according to FIG. 1 in the running direction L directly in front of the application unit 12 , which can comprise, for example, a flat electrode extending in the transverse direction Q with a plurality of needle tips, or of a plurality of ones in the transverse direction Q. adjacent needle electrodes 32 may be formed. Arrangement of the electrodes 30, a predetermined voltage V ₁ is applied while the surrounding parts of the application device 10, namely, the application unit 12, the backup roller 22 and a with respect to the running direction L upstream of the electrode assembly 30 provided suction box 34 to the weakening of the material web 20 entrained air boundary layer are kept at ground or earth potential V _E.

Not only does an electric field build up between the electrode arrangement 30 and its environment, which is kept at ground potential, but discharges occur between the needle tips or needle electrodes 32 and the environment, which are indicated in FIG. 1 by the dashed lines E. As a result of these discharges E, the application medium 16 of the curtain 18 is electrically charged, so that it is accelerated in the electrical field between the electrode arrangement 30 and the support roller 22 towards the support roller 22 , which supports the pre-stretching.

In addition, a force is exerted on the curtain 18 as a result of the discharges E, which has a component that runs orthogonally to the direction of its fall movement. This force component also helps to stabilize the application medium curtain 18 against the influence of the air boundary layer G carried on the surface of the material web 20 .

As already mentioned above, the suction box 34 serves to weaken the air boundary layer G. To increase the suction efficiency, a drag scraper 36 is provided on the outlet side of this suction box 34 , which is in sliding contact with the surface 20 a of the material web 20 and seals the suction area of the suction box 34 on the outlet side . The drag scraper 36 can for example be made of a composite material coated with Teflon. Due to the use of a composite material, the scraper 36 has sufficient temperature resistance and flexibility, and due to the surface coating with Teflon, there is sufficient low friction.

According to the invention, a further electrode arrangement 40 is now provided between this drag scraper 36 and the suction box 34 , which is attached to the suction box 34 via electrical insulation 42 . The further electrode arrangement 40 can in turn be formed either by a flat electrode with a plurality of needle tips or a plurality of needle electrodes arranged adjacent to one another in the transverse direction Q. The electrode arrangement 40 can in principle be connected to an external voltage supply. In the illustrated embodiment, however, it is in a floating state with regard to its electrical potential (“floating potential”), but is charged as a result of the discharges E emanating from the electrode arrangement 30 and is thus also brought to a potential different from the ground potential.

Due to the small distance of the tips of the electrode arrangement 40 from the base U, the charging of the electrode arrangement 40 is sufficient to also allow discharges e to occur between the tips of the electrode arrangement 40 and the base U. These discharges e disturb the laminar flow of the air boundary layer G and convert it at least partially into a turbulent flow. This facilitates the suction of the air boundary layer G from the surface 20 a of the material web and thus improves the effectiveness of the suction box 34 .

The backup roller 22 can be kept in different ways on the ground potential V _E. For example, the roller axis A can be connected to a sliding contact, as described, for example, in DE 197 33 333 A1. Additionally or alternatively, however, a sliding contact 50 connected to the surface 22 a of the roller 22 can also be provided. Finally, the material web 20 can also be held at ground potential V _E via contacts formed by web guiding elements 48 , for example.

Claims (19)

1. Device ( 10 ) for one-sided or two-sided application of liquid or pasty application medium ( 16 ) to a running surface (U), comprising a curtain application unit ( 12 ), which the application medium ( 16 ) as a gravity-moving curtain or releases veil ( 18 ) to the underground (U),
wherein the substrate (U) with direct application is the surface ( 20 a) of a material web ( 20 ), in particular made of paper or cardboard, and with indirect application the surface of a transfer element, preferably a transfer roller, which then applies the application medium to the surface of the Material web transfers,
characterized in that the substrate (U) in the area of the curtain applicator ( 12 ) is kept at a first predetermined electrical potential (V _E ) and in the direction (L) of the substrate (U) in front of the curtain applicator ( 12 ) an electrode arrangement ( 30 ) is arranged at a distance from the substrate (U), which is held at a second predetermined electrical potential (V ₁ ) different from the first potential (V _E ). 2. Application device according to claim 1, characterized in that the electrode arrangement ( 30 ) comprises a plurality of individual electrodes, preferably needle electrodes ( 32 ), arranged adjacent to one another in the transverse direction of the substrate. 3. Applicator according to claim 1, characterized in that the electrode arrangement ( 30 ) comprises at least a flat electrode which has a plurality of projections or needle tips on its side pointing towards the surface. 4. Application device according to one of the preceding claims, characterized in that the electrode arrangement ( 30 ) in the running direction (L) of the substrate (U) has a device ( 34 ) for weakening the air boundary layer carried by the substrate (U) upstream (G) . 5. Applicator according to claim 4, characterized in that the air boundary weakening device comprises a suction device ( 34 ). 6. Applicator according to claim 5, characterized in that at the downstream end of the suction device ( 34 ) with the base (U) in sliding contact scrapers ( 36 ) is provided. 7. Applicator according to one of claims 4 to 6, characterized in that in the area of the air boundary weakening device ( 34 ), preferably between the downstream end of the suction device ( 34 ) and the scraper ( 36 ), a further electrode arrangement ( 40 ) is provided. 8. Applicator according to claim 7, characterized in that the further electrode arrangement ( 40 ) comprises a plurality of individual electrodes, preferably needle electrodes, arranged adjacent to one another in the transverse direction of the substrate. 9. Application device according to claim 7, characterized in that the further electrode arrangement ( 40 ) comprises at least one flat electrode, which has a plurality of projections or needle tips on its side pointing towards the surface. 10. Applicator according to one of claims 7 to 9, characterized in that the further electrode arrangement ( 40 ) is at a distance of between approximately 2 mm and approximately 30 mm from the substrate. 11. Applicator according to one of claims 7 to 10, characterized in that the electrical potential of the further electrode arrangement ( 40 ) is kept in suspension. 12. Application device according to one of claims 7 to 11, characterized in that the further electrode arrangement ( 40 ) is arranged on the air boundary layer weakening device ( 34 ) in an electrically insulated manner ( 42 ). 13. Applicator according to one of the preceding claims, characterized in that a counter element, preferably a counter roller ( 22 ), which supports the material web ( 20 ) in the region of the curtain applicator ( 12 ) in the case of direct application or on the surface of which the curtain Application unit applies the application medium for an indirect application, is in contact with an electrode in order to keep it at the first predetermined electrical potential (V _E ). 14. Applicator according to claim 13, characterized in that the surface ( 22 a) of the counter element ( 22 ) with the electrode ( 50 ) is in sliding contact. 15. Applicator according to claim 13 or 14, characterized in that the electrode is in contact with a bearing shaft (A) of the counter roller ( 22 ). 16. Application device according to one of claims 13 to 15, characterized in that, in the case of direct application, the material web ( 20 ) is held at the first predetermined electrical potential (V _E ) by an electrode, for example in the form of a web guiding element ( 48 ). 17. Applicator according to one of the preceding claims, characterized in that the second predetermined electrical potential (V ₁ ) has a value of between approximately 5 kV and approximately 60 kV, preferably approximately 30 kV. 18. Applicator according to one of the preceding claims, characterized in that the first predetermined electrical potential (V _E ) is the earth potential. 19. Applicator according to one of the preceding claims, characterized in that the curtain applicator ( 12 ) and / or the air boundary layer weakening device ( 34 ) is kept at a predetermined electrical potential (V _E ), preferably earth potential.