DE29903225U1 - Device for treating a material web using radiation energy - Google Patents

Description

Device for treating a material web using radiation energy

Description

The invention relates to a device for treating material webs using radiation energy, by means of which the material web is moved in a conveying direction and in which at least one radiation energy source extending perpendicular to the conveying direction is arranged in order to expose the material web to radiation energy at least once over at least a portion of its width at least on one side. In particular, the invention relates to a device for irradiating the material web using UV light to crosslink coatings. In the following, therefore, reference is mainly made to UV radiation and a UV radiation source, without this being a restriction.

Such so-called UV systems are known for producing high-quality surfaces. These surfaces can be shiny and smooth, but also structured. They can be the surfaces of paper webs or plastic films, or even veneers for furniture.

0 The layer to be treated, for example with silicone, is provided with photoinitiators in order to achieve the desired cross-linking through the action of UV light. It has been shown that exposure to the otherwise "cold" UV light still results in a strong 5 heating of the material web to be treated.

It is known to cool the side facing away from the UV radiation source using a cooling plate. However, this cooling is no longer sufficient for larger material webs and larger plastic layers as well as several UV light sources one after the other to keep the material web at the desired temperature.

The invention is therefore based on the object of designing a device of the type described at the outset in such a way that further treatment, in particular sufficient cooling of the material web, is possible in order to keep it at a desired temperature.

The object is achieved according to the invention in that in the conveying direction in front of and/or behind and/or in the area of the radiation energy source at least one feed means for a gaseous medium is provided, extending perpendicularly to the conveying direction, in order to apply the gaseous medium to the material web at least once over at least a portion of its width at least on one side for cooling or heating and/or moistening or drying. The material web can be cooled or heated and/or dried or moistened by the gaseous medium. It is obvious that further treatment of the web is possible through these measures. The gaseous medium can be tempered or moistened according to the required conditions, so that optimal and versatile treatment is possible. Above all, it is now possible to cool the material web and to keep it at the desired temperature even when high radiation power is applied.

In principle, it is advisable if the exposure 5 by the radiation energy and the gaseous medium is

the same side of the material web. However, it can also be provided that the exposure to radiation energy occurs on both sides and/or the exposure to the gaseous medium occurs on both sides. It can also be provided that the exposure to the gaseous medium and the radiation energy occurs on opposite sides of the material web.

In principle, it is advantageous if the exposure to radiation energy and the gaseous medium takes place alternately in the conveying direction. In particular, the intermediate cooling that this enables means that the material web can be kept at an essentially constant temperature even when there are several sources of radiation energy.

Furthermore, it is expedient if the material is exposed to different radiation energy and/or exposed to different gaseous media, particularly those with different temperatures and/or humidity, in the conveying direction. This makes it possible to achieve a desired temperature/humidity profile in the conveying direction of the material web during treatment.

According to a further embodiment, it is provided that the exposure to radiation energy and the gaseous medium takes place in a space that is essentially closed off from the outside atmosphere. It is expedient if the exposure to radiation energy and the gaseous medium takes place in an inert, in particular oxygen-poor, atmosphere. In the absence of oxygen, for example, the cross-linking of the silicone by the UV light is more effective. It can be provided here

that the gaseous medium is nitrogen or nitrogen-enriched air.

According to another embodiment of the invention, the gaseous medium is at least partially circulated. This has the advantage that the process is economical, especially when using inert gas. It is expedient or possibly also necessary to cool or heat the gaseous medium and/or dehumidify or moisten it before applying it to the material web.

When the material web is exposed to a gas stream, there is often a risk that particles will detach from it or that solids will precipitate. It is therefore intended, particularly when the gaseous medium is circulated, that the gaseous medium is filtered before it is exposed to the material web. This can prevent a concentration of such suspended particles in the gas stream.

Furthermore, in addition to or as an alternative to the gaseous exposure to the gaseous medium, the web can be cooled or heated by means of at least one tempered contact roller. This has the advantage that, in addition to the thermal treatment of the web, it can also be supported. The contact roller can, for example, be arranged in the area of exposure to the gaseous medium on the opposite side of the material web.

The invention is explained in more detail below with reference to the schematic drawing, the only figure of which shows the

shows the basic structure of a device according to the invention.

The device shown in the drawing has an upper box 11 and a lower box 12, between which a material web 13 is guided in the conveying direction 14. The material web 13 can, for example, be pulled through the device. In the embodiment shown, the device is shown horizontally and the following description refers to such an orientation. In principle, however, the device can also be arranged vertically or in another orientation. The relative arrangements described are then to be understood accordingly. The upper box 11 can be raised or swiveled from the lower box 12 by lifting means (not shown) for maintenance purposes or for inserting the material web 13.

A large number of radiation energy sources 15 0 are provided, which are located above the material web 13 in the upper box 11. The radiation sources extend transversely to the conveying direction 14 and thus perpendicular to the plane of the drawing at least over the entire width of the material web. The radiation sources 15 can be designed as UV light sources in order to cause a plastic layer on the material web to crosslink. Cooling plates 16 are provided in the lower box below the material web in the area of the UV light sources in order to dissipate radiant heat. The basic arrangement 0 of a single UV light source above a cooling plate is basically known and therefore requires no further explanation.

In the conveying direction between the UV light sources 5, gas supply means 17 are arranged, the nozzles 18 of which are in

Direction towards the material web 13. Furthermore, terminal gas supply means 19 can also be provided. The nozzles 18 are designed as slot nozzles and extend at least over the entire width of the material web 13 transversely to the conveying direction 14 perpendicular to the plane of the drawing. A gaseous medium can be applied to the material web 13 via these gas supply means 17. As a rule, the gaseous medium is used to cool the material web, but other applications are also possible, in particular defined moistening, drying or even heating.

In the embodiment shown in the drawing, the supply means for the gaseous medium and the radiation energy source are located on the same side of the material web 13. The material web is therefore exposed to the gaseous medium on one side. However, it is also possible to provide such gas supply means 17 or radiation energy sources 15 above and below or only below the material web 13.

As shown in the drawing, the radiation energy sources 15 and the supply means 17 for the gaseous medium are arranged alternately in the conveying direction. In the embodiment shown, the same UV light sources are arranged between the same gas supply means 17, 19. In principle, however, the design, in particular the size and performance of individual radiation energy sources and gas supply means in a device can be selected as desired and adapted to the respective requirements.

During operation, the material web 13 is moved through the device in the conveying direction 14. During this process, 5 it is alternately treated with radiation energy and with a

gaseous medium, in particular a cooling gas. This can prevent overheating of the material web even with large web widths or high radiation outputs.
5

By irradiating the material with UV light, for example, a chemical cross-linking process is initiated in a plastic layer on the material web. It has been shown that this process is more effective in an inert, oxygen-poor environment. In particular, the amount of photoinitiators can be reduced. The device shown in the drawing is therefore essentially sealed off from the outside atmosphere. At the web inlet 20 and the web outlet 21 there are corresponding blocking or locking means that largely prevent the entry of ambient air. In the exemplary embodiment, the blocking means at the web inlet 20 is designed as a blocking nozzle 22 and at the web outlet as a brush 23.

Contact or guide rollers 24 are also provided in the lower box 12. These extend transversely to the conveying direction 14 over the entire width of the material web 13. The material web 13 can be supported on these contact rollers. It can be provided that these rollers 24 are tempered, in particular cooled, in order to achieve further cooling of the material web. In the embodiment shown, the contact rollers 24 are arranged in the area of the gas outlet opening 18 0 on the opposite side of the material web 13.

In principle, however, it can also be provided that instead of or in addition to these contact rollers 24 floating nozzles 25 are provided, via which the

The material web is pulled through the device in a floating manner. This option is shown in the drawing on the right.

It can be provided that fresh air is used as the gaseous medium. In the embodiment shown, the gaseous medium is circulated. For this purpose, at least one corresponding suction channel 26, a compressor or fan 27 and corresponding supply channels 28 are provided. This has the advantage that inert gases can also be used economically as the gaseous medium. Nitrogen or nitrogen-enriched air can be considered as the gaseous medium in particular.

A heat exchanger 29 is provided in the gas circuit to bring the gaseous medium to the desired temperature, i.e. in particular to cool it. A humidifier or dryer (not shown) can also be arranged in the circuit to influence the humidity of the gas. In the embodiment shown in the drawing, a gas flow is heated and divided uniformly. It is of course possible to provide separate heat exchangers, humidifiers, dryers, fans and/or throttles 30 for each gas supply means 17, 19 in order to optimally adjust the gas flow supplied in each case. An additional heat exchanger 31 is shown as an example in the dashed line on the right in the drawing.

By applying a gaseous medium to the material web 13, it will generally be unavoidable that suspended matter will be discharged. In particular, photoinitiators tend to precipitate. In order to prevent a concentration of these substances in the gas circuit,

To avoid this, at least one filter 32 is provided for the gaseous medium. The pollutants can be discharged through a branch 33. Furthermore, an inert gas or nitrogen source 34 is provided in order to enrich the circuit with nitrogen.

It is obvious that with such a device, a versatile treatment of a material web is possible. In particular, the web is prevented from overheating even with high radiation output. The material web can therefore always be kept at an optimal temperature.

10 List of reference symbols

11 Upper box 12 Lower box 13 Material web 14 Conveying direction 15 Radiant energy source 16 Cooling plate 17 Gas supply means 18 jet 19 Gas supply means 20 Track entry 21 Railway exit 22 Locking nozzle 23 brush 24 roller 25 Floating nozzle 26 Suction channel 27 Fan 28 Feed channels 29 Heat exchanger 30 throttle 31 Heat exchanger 32 filter 33 branch 34 Nitrogen source

Claims (9)

&bull; · «ff·* · ·· &igr;&kgr;&igr; ·· ·· Device for treating a material web by means of radiation energy Claims 1. Device for treating a material web (13) using radiation energy, in particular using UV light for cross-linking coatings, by means of which the material web is moved in a conveying direction (14) and in which at least one radiation energy source (15) extending perpendicularly to the conveying direction is arranged in order to apply radiation energy to the material web at least once over at least a partial section of its width at least on one side, characterized in that in the conveying direction in front of and/or behind and/or in the area of the radiation energy source at least one feed means (17, 18) for a gaseous medium is provided, extending perpendicularly to the conveying direction, in order to apply the gaseous medium to the material web at least once over at least a partial section of its width at least on one side for cooling or heating and/or moistening or drying. 2. Device according to claim 1, characterized in that the supply means (17, 18) for the gaseous medium and the radiation energy source (15) are arranged on the same side 0 of the material web (13). 3. Device according to claim 1 or 2, characterized in that the radiation energy sources (15) and the supply means (17, 18) for the gaseous medium are arranged alternately in the conveying direction. &psgr; B 4 « -t < · · · ··· ft * 11 4 C · « 4. Device according to one of claims 1 to 3, characterized in that the device is designed to be substantially sealed off from the outside atmosphere. 5. Device according to one of claims 1 to 4, characterized in that at least one contact roller (24) for cooling or heating the material web (13) is arranged in the conveying direction. 6. Device according to claim 5, characterized in that the contact roller (24) is arranged in the region of the gas outlet opening (18) on the opposite side of the material web. 7. Device according to one of claims 1 to 6, characterized in that at least one heat exchanger (29, 31) is provided in order to heat or cool the gaseous medium. 8. Device according to one of claims 1 to 7, characterized in that at least one dryer or humidifier is provided for the gaseous medium. 9. Device according to one of claims 1 to 8, characterized in that at least one filter (32) is provided for the gaseous medium.