EP0528372A1 - Apparatus for contactless guiding of a coated web - Google Patents

Abstract

A material band 1 coated with a liquid layer 2 runs through a dryer 13, in which guide elements 14 are arranged at a spacing from one another. The guide elements 14 have air-permeable or gas-permeable guide surfaces 9 facing the material band 1 and are acted upon with overpressure with air or gas via a common supply line 17 and inlet ducts 5 in each guide element. The guide air 10 or gas emerging from the guide surfaces forms an air or gas film of less than 1 mm thickness which guides the material band 1 in a troublefree manner and without any impairment of the blowing-sensitive liquid layer 2 and makes it slide over the guide elements 14.

Description

The invention relates to a method and a device for the contact-free guiding of a coated material strip in a drying zone, with the aid of a heated gas.

It is state of the art today to carry out a surface treatment in suspension dryers for foil or metal strips with the aid of an air jet system without contact (magazine "gas warm international", Volume 24 (1975), No. 12, pp. 527 to 531). The dryer air, which is enriched with solvent, is sucked off directly in the nozzle fields in order to eliminate the undesired transverse flow. This results in so-called nozzle dryers or impingement jet dryers, in which the stagnation point-like flow of individual nozzles is disadvantageous, which tends to cause flow-physical instabilities in both laminar and turbulent flow patterns, which inevitably lead to irreversible drying structures, particularly in the case of low-viscosity liquid films.

According to PCT application WO 82/03450, the dryer air is led from a vestibule via suitable inlet openings and flow deflectors into a calm intermediate space, from where part of the dryer air passes through in close proximity to the liquid jet to avoid stagnation point-like flows in the initial area of the dryer apparatus arranged porous filter element on the web to be dried. The mode of operation of such drying is based on the fact that between the porous protective shield and the liquid film to be dried a calm, but highly enriched solvent air flow forms, which is constantly renewed by exchange with the residual air transversely flowing over the porous medium and thus, due to the relatively short overall length, a predrying of the liquid film with reduced tendency to mottling is achieved.

This type of drying is predominantly characterized by diffusion of the solvent vapor / air mixture through the porous protective shield, which means that if there is almost no convective removal within the space between the belt and the protective shield, the liquid film can only dry out completely if the dryer lengths are very large or by adding subordinate auxiliary dryers.

Different drying processes and drying devices are used for drying large web-shaped goods on which layers of liquid are applied. Typical drying goods are, for example, metal or plastic belts on which liquid layers are applied, which usually consist of evaporable solution components that are removed from the liquid film during the drying process and non-evaporable components that remain on the carrier material after drying. In general, such become drying webs first through a drying zone and then through the actual drying zone. The coating gives the surfaces of the carrier materials special properties which are only present in the form after the drying process, as are desired for later use. An example of this is the coating of metal strips, in particular aluminum strips, with light-sensitive layers, which are assembled into printing plates. The coating of metal strips or plastic films with a solvent-containing wet film, hereinafter referred to as the liquid film, and its subsequent drying represent a process that requires special systems to ensure the desired product quality of the layers. The process steps of the drying and the final film drying are essential as the final process measures of the coating.

The uniform drying of the blow-sensitive coatings on the carrier material in dryers in which a dryer air flow runs parallel to the coated belt is mainly disturbed by mechanical guide elements, such as rollers, for the carrier material or the coated metal belt. Very good drying results with regard to the layer cosmetics are obtained with appropriate air guidance on the layer side to be dried if the material band is guided in close proximity to the dryer floor. If, for example, the material band is guided over a flat dryer floor, the Aluminum exists, so there is a risk that so-called longitudinal scratches occur on the underside of the material band, which can damage the coated material band or even render it unusable.

When designing the dryer floor with a soft material, e.g. a textile fabric, felt or fleece, such longitudinal scratches are avoided, but these carpets are cut at different widths of the material strips. Particles of the lining material then form, which occupy and thus contaminate the layer to be dried, as well as grooves in the lining material which impair uniform contact with the guide surface.

If the dryer floor is designed with a material that has a significantly lower coefficient of friction than the material band and that is temperature-resistant, e.g. Polytetrafluoroethylene, the mechanical resistance of this material to the edges of the material strip is not given in the long run.

The object of the invention is to further develop a method and a device so that a coated material band can be guided in a non-contact drying zone in such a way that the uniform drying of the liquid layer on the material band is not impaired and there are no signs of wear and tear on the guide devices.

This object is achieved in such a way that the material band is carried by a gas film with a thickness of less than or equal to 1 mm, which flows perpendicularly to the longitudinal and running direction of the material band and that the gas flow is interrupted several times below and in the longitudinal direction of the material band is.

In one embodiment of the method, the gas stream flows both in the direction of travel and opposite to the direction of travel of the material strip. The material band is guided over guide elements, and depending on the permeability of the guide elements, the gas pressure rises to 1 bar or more before the gas exits the guide elements. Air is expediently used as the gas which has a higher temperature than its surroundings in the drying zone.

In the method, a so-called gas or air lubrication between the material band and the guide elements is achieved, which takes place at very small intervals. The distance between the material band and the guide elements is considerably less than 1 mm, but can also be up to 1 mm. With appropriate selection of materials for the guide elements, which are generally permeable to air, the gas or air pressure to be specified is substantially lower than 1 bar. The relationship between the gas or air pressure to be specified for the lubrication and the gas or air permeability of the material for the guide elements is particularly important for achieving a uniform and uninterrupted gas or air film between the Material tape and the guide elements transverse to the direction of the material tape. The exit energy of the gas or air from the guide elements must be quickly converted into heat and pressure by the formation of micro-vortices, which increase the effectiveness of the gas or air film, as a result of which the flow of material around the band edges has a deleterious effect on the blow-sensitive Liquid layer is avoided.

A device for the contact-free guiding of a coated material band through a dryer according to the invention is characterized in that below the material band that passes through the dryer, guide elements are arranged at equal intervals from one another, each of which has a gas-permeable surface that is the underside of the material band is facing.

In an embodiment of the device according to the invention, each guide element contains an inlet channel for the gas supply and the guide elements are connected to a common supply line for the gas supply. The supply line is separated from the line for the supply of drying gas or drying air and is operated independently.

For the extraction of the outflowing drying gas, a common suction line is expediently available for all guide elements.

In a further embodiment of the invention, the guide element has a cuboid-shaped, air-permeable body, which is arranged lengthways transversely to the direction of travel of the material band and flows drying gas in the longitudinal direction via a central inlet channel into the interior of the guide element. The material of the body of the guide element is sintered metal or porous glass. The three outer sides of the cuboid body of the guide element, which do not face the material band, are sealed on the outside with a barrier layer made of lacquer or plastic against undesired gas leakage.

The further embodiment of the invention results from the features of claims 12 to 20.

With the invention, the advantage is achieved that the gas or air supply under the material strip does not take place over the entire surface, that a uniform sliding effect of the material strip is obtained over the entire web width without the material strip being pushed up at the edges. Interruptions due to slight depressions of the sliding surfaces of the guide elements, which lie transversely to the material band, have proven to be particularly advantageous.

Figur 1

eine schematische Schnittansicht durch einen Trockner, mit einer Anzahl von erfindungsgemäßen Führungselementen für das Materialband,

Figur 2

eine Schnittansicht einer ersten Ausführungsform eines Führungselements nach der Erfindung,

Figur 3

eine Schnittansicht einer zweiten Ausführungsform eines Führungselements nach der Erfindung, und

Figur 4

eine Schnittansicht einer dritten Ausführungsform eines Führungselements nach der Erfindung.

The invention is explained in more detail below with reference to exemplary embodiments of the device which are shown in the drawings. Show it:

Figure 1

is a schematic sectional view through a dryer, with a number of guide elements according to the invention for the material strip,

Figure 2

2 shows a sectional view of a first embodiment of a guide element according to the invention,

Figure 3

a sectional view of a second embodiment of a guide element according to the invention, and

Figure 4

a sectional view of a third embodiment of a guide element according to the invention.

FIG. 1 shows a dryer 13 with a so-called air-lubricated guide for a material strip 1. The material strip 1 runs from an inlet into the dryer 13 around a deflection roller 11, which is opposite an application roller 19 for a liquid layer 2. After the liquid layer 2 has been applied to the material strip 1 by the application roller 19, it enters the dryer 13 through a gap and is guided horizontally over guide elements 14. On the back of the dryer 13, the coated material strip 1 emerges from a gap and is guided downwards via a deflection roller 12. The dryer 13 has a housing 15, through the underside of which a supply line 17 and a suction line 18 are passed. Each of the guide elements 14 is connected to the common supply line 17 for the gas or air supply. Normally air is used as the guide gas for the material strip 1, whereby the air is at a higher temperature than the environment inside the dryer 13. Each of the guide elements 14 contains an inlet channel 5 for the gas or air supply. The supply line 17 is separated from the line for the supply of drying air and is operated independently. A unit 16 for the air supply, which is not shown in detail, consists of an air compressor with an upstream fine filter and a downstream heat exchanger, as well as corresponding pipes and fittings with a corresponding control system. The guide surfaces 9 of the guide elements 14 facing the material strip 1 are gas or air permeable, so that the air flows perpendicularly onto the material strip 1. An air film 7 forms on which the coated material strip 1 slides with the blow-sensitive liquid layer 2 without mechanical contact with the guide surfaces 9 of the guide elements 14.

The air pressure or gas pressure before the air or gas emerges from the guide elements can rise to 1 bar or more and depends essentially on the permeability of the guide surfaces 9. The more permeable these guide surfaces 9 are, the smaller the pressure increase within the guide elements 14 before the air or gas escapes. The distance between the underside of the material strip 1 and the guide surfaces 9 is less than 1 mm, but can also be up to 1 mm. The air film 7 flows both in the running direction and opposite to the running direction of the Material tape 1 from, the spaces existing between two guide elements function as outflow areas for the air film. Since the outflowing amounts of air are very small, the guidance and flow behavior within the dryer 13 is not influenced overall, so that there are also no disruptions to the layer cosmetics when the liquid layer 2 dries on the material strip 1.

Through the inlet channels 5, the air flows into the air-permeable bodies of the guide elements 14 and up through the guide surface 9 as guide air 10 against the material strip 1. In order that the guide air 10 does not flow laterally and downwards through the outer walls of the guide elements, these outer walls are sealed , as will be described in more detail below.

FIGS. 2 to 4 show different embodiments of guide elements 14, 32, 33, which can each be used in the dryer 13 according to FIG. 1. Figure 2 shows a single guide element 14 of the dryer 13 in detail. The guide element 14 consists of a cuboid air-permeable body 3, which is supplied from the inside with finely filtered air via a central inlet channel 5. The air-permeable body 3, which is arranged along its length transversely to the running direction of the material strip 1, consists of sintered metal or porous glass. Three outer sides 24, 25, 26 of the body 3, which are not facing the material strip 1, are externally covered with a barrier layer 4 made of lacquer or plastic against unwanted Sealed air outlet from the body 3. The fourth outer side 27, which lies opposite the underside of the material strip 1 at a distance of less than or equal to 1 mm, in particular at a distance which is considerably less than 1 mm, has outwardly sloping, inclined partial surfaces 30, 31 which are aligned with the underside of the material band 1 form outflow zones for the outflowing air. The guide air is guided centrally through the inlet channel 5 longitudinally to the guide surface 9 only against the material strip 1, in order then to flow into and against the strip running direction to form an air film 7 into the adjacent outflow zones. The surface of the guide surface 9 is relatively rough.

FIG. 3 shows a further embodiment of a guide element 32, which consists of a distributor pipe 6 with through openings 8 in the region of the guide surface 9 and a jacket 20 which surrounds the distributor pipe 6. The jacket 20 is permeable to air or gas and consists of a fleece or felt coated with polytetrafluoroethylene. The guide air 10, which flows in through the distributor pipe 6, exits through the passage openings 8, flows through the jacket 20 and forms an air film 7 between the peripheral surface of the jacket 20 and the underside of the material strip 1, which transports the material strip as a kind of lubricating film and over the Guide elements 32 can slide. The guide air 10 emerges from the jacket 20 mainly below the material strip 1 in the area of the guide surface 9. Further material for the jacket 20 can be fabrics coated with polytetrafluoroethylene, glass or carbon fibers.

FIG. 4 shows a further embodiment of the guide element 33, which consists of a distributor pipe 6 with through openings 8 for the air, a jacket 34 made of sintered metal or porous glass, sliding seals 21 and a protective jacket 22. The air-permeable jacket 34 is kept at a distance from the distributor pipe 6 by the sliding seals 21 applied to the distributor pipe 6. The protective jacket 22 encloses the jacket 34, with the exception of a flat polygonal surface 35 which faces the underside of the material strip 1. On the inside of the protective jacket 22 there is a continuous sliding seal 23 which, like the sliding seals 21, consists for example of polytetrafluoroethylene. The sliding seals 21 and 23 can, for example, be glued to the supply pipe 6 or to the inside of the protective jacket 22. The air-permeable jacket 34 is rotatable relative to the supply pipe 6, so that the entire circumferential surface of the air-permeable jacket 34 can be used by rotating the jacket 34 as soon as its flat polygonal surface 35, which faces the material strip 1, is not contaminated by internal or external contamination is more functional.

The outside of the jacket 34 consists of flat polygon surfaces 35 which are connected to one another by rounded transition surfaces 36. These transition surfaces 36 facilitate the rotation of the jacket 34 with respect to the fixed protective jacket 22, since they only have small ones with the sliding seal 23 Partial areas and not in contact over the total area.

The passage openings 8 of the fixed distributor pipe 6 face the material strip 1, and two sliding seals 21 are located in the immediate vicinity of the passage openings 8, while two further sliding seals 21 are applied to the distributor pipe 6 at diametrically opposite locations. With the help of the guide elements 14, 32 or 33, the material strip 1 is guided in the dryer 13 without mechanically moving parts, such as rollers, and the blow-sensitive liquid layer 2 is dried largely without problems.

Claims (20)

Process for the contact-free guiding of a coated material strip in a drying zone, with the aid of a heated gas, characterized in that the material strip is carried by a gas film with a thickness of less than or equal to 1 mm, which flows onto the material strip perpendicular to the longitudinal and running directions and that the gas flow is interrupted several times below and in the longitudinal direction of the material strip. A method according to claim 1, characterized in that the gas flow partially flows both in the running direction and opposite to the running direction of the material strip. Method according to claim 1, characterized in that the material strip is guided over guide elements and that, depending on the permeability of the guide elements, the gas pressure rises to 1 bar or more before the gas exits the guide elements. A method according to claim 1, characterized in that air is used as gas which has a higher temperature than its environment in the drying zone. A method according to claim 1, characterized in that the gas film between the material band and the Guide elements flows transversely to the direction of the material band. Device for the non-contact guidance of a coated material strip through a dryer, characterized in that guide elements (14; 32; 33), each of which is gas-permeable, are arranged at regular intervals below the material strip (1) which passes through the dryer (13) Has guide surface (9) which faces the underside of the material strip (1). Apparatus according to claim 6, characterized in that each guide element (14; 32; 33) contains an inlet channel (5) or a supply pipe (6) for the gas supply and that the guide elements (14; 32; 33) to a common supply line ( 17) are connected for the gas supply. Apparatus according to claim 7, characterized in that the supply line (17) is separated from the line for the supply of drying gas or drying air and is operated independently. Apparatus according to claim 8, characterized in that there is a common suction line (18) for all guide elements (14; 32; 33) for the suction of the outflowing drying gas. Apparatus according to claim 6, characterized in that the guide element (14) has a cuboidal air-permeable body (3) which is arranged lengthways transversely to the direction of travel of the material strip (1) and that drying gas via a central inlet channel (5) into the interior of the guide element (14) flows in the longitudinal direction. Apparatus according to claim 10, characterized in that the material of the body (3) of the guide element (14) is sintered metal or porous glass and that the three outer sides (24, 25, 26) of the cuboid body (3) of the guide element, which is not the Material tape (1) are facing, are sealed on the outside with a barrier layer (4) made of lacquer or plastic against unwanted gas leakage. Apparatus according to claim 10, characterized in that the outside (27) facing the material strip (1) is chamfered towards the contour edges (28, 29) of the guide element (14), in and against the strip running direction, and in that inclined partial surfaces () 30, 31) of the outside (27) with the underside of the material band (1) form outflow zones for the outflowing gas. Apparatus according to claim 6, characterized in that the guide element (32) consists of a distributor pipe (6) with passage openings (8) for the gas and a gas-permeable jacket (20) surrounding the distributor pipe. Device according to claim 13, characterized in that the jacket (20) consists in each case of a nonwoven, felt, fabric, glass or carbon fiber coated with polytetrafluoroethylene. Device according to Claim 13, characterized in that the passage openings (8) face the material strip (1). Apparatus according to claim 6, characterized in that the guide element (33) consists of a distributor pipe (6) with passage openings (8) for the gas, a jacket (34) made of sintered metal or porous glass, which by means of sliding seals applied to the distributor pipe (6) (21) is kept at a distance from the distributor pipe (6), and there is a protective jacket (22) which encloses the jacket (34), with the exception of a flat polygon surface (35) which faces the underside of the material band (1) . Apparatus according to claim 16, characterized in that the protective jacket (22) is equipped on its inside with a sliding seal (23) and is fixed in relation to the rotatable jacket (34). Device according to claim 16 or 17, characterized in that the sliding seals (21; 23) are made of polytetrafluoroethylene. Device according to claim 16, characterized in that the outside of the jacket (34) consists of flat polygon surfaces (35), connected by rounded transition surfaces (36). Apparatus according to claim 16, characterized in that the passage openings (8) of the fixed distributor pipe (6) face the material strip (1) and that two sliding seals (21) are applied to the distributor pipe (6) at diametrically opposite locations.

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