DE19944380A1 - Ultra-violet lamp for treating continuously moving material includes sensors to monitor radiation intensity and to keep it constant - Google Patents

Abstract

A radiation source, especially a UV lamp (11) for cross-linking continuous material (12), is controlled (14) by signals from sensors (13) that monitor the radiation intensity across the width of the material in order to keep it at a set constant value. The sensors (13) can be placed behind the material, at the side or traversed across the width, depending on the transparency or reflectivity of the material. An Independent claim is also included for the method of irradiating continuous materials by monitoring the radiation intensity at selected positions and comparing the average with a set value to control the process.

Description

The invention relates to a device for treating Material webs by means of radiation energy, through which the material web is moved in a conveying direction and in which at least one is perpendicular to the conveying direction extending radiation source is arranged around the Material web at least once over at least one Part of their width at least on one side To apply radiation energy. In particular concerns the invention a device for irradiating the Material web using UV light to network Coatings. It is therefore predominant in the following of UV radiation and a UV radiation source spoken without any restriction is.

Such so-called UV systems are known to to produce high quality surfaces. The surfaces can be shiny and smooth but also structured. It can be surfaces of paper webs or Plastic films or veneers for furniture. The layer to be treated, for example with silicone, is equipped with photo initiators to Exposure to light to bring about the desired networking. For consistent results it is necessary that with the layer to be treated for a predetermined time a predetermined intensity is irradiated. Otherwise may not be able to achieve the desired networking to be fully completed.  

The duration in which the material web of radiation energy exposed, results directly from the Conveying speed through the treatment device. The power of the radiation source must accordingly be adjusted to the desired and at this duration to apply the required amount of radiation. It is obviously that with the same Conveying speed but with fluctuating performance amount of radiation applied varies, for example to an irregular or insufficient Crosslinking of the coating can result.

It is in one under the harsh operating conditions such device can not rule out that especially with fast moving material webs Soiling of the radiation source, for example due to dust, moisture or other deposits, is coming. These deposits adhere to the Radiation exit area of the radiation source, so that the actually emerging intensity is reduced. Such radiation sources are also subject to aging, whereby their power output also decreases. Both effects can cause the one to be treated Layer not with the sufficient amount of radiation and, for example, networking is not is completed.

The invention has for its object a Device of the type described above train that irradiation of a material web in can be done essentially with the same intensity.

The object is achieved according to the invention in that in the area of the radiation source at least one sensor for  Detection of the emitted radiation intensity provided is that cooperates with a control unit that the detected radiation intensity with a setpoint compares and due to a deviation from the setpoint Power of the radiant energy source changes such that the emitted radiation intensity essentially remains constant. Due to the preferably continuous Capture the actually emitted and on the Radiation intensity acting on the material web and through tracking the power emitted for a constant Radiation intensity is achieved that too treating layer always with the required Radiation amount is applied. A constant one Result, for example, in networking can be guaranteed.

It can be provided that several sensors are along the width of the material web are arranged. This can tracking the power of the radiation source be improved and optimized. In particular, the Control unit comprise an evaluation unit or with this can be connected to several sensors for one Radiation source an average of the detected Radiation intensity determined, and that at its Deviation from the setpoint the power of the radiation source is changed. But it can also be useful if the control unit comprises an evaluation unit, which at the smallest of several sensors for a radiation source detected radiation intensity determined, and that at their Deviation from the setpoint the power of the radiation source is changed. This can ensure that all areas across the width of the web receive at least the required amount of radiation. So can, for example, inadequate networking only an area of the material web can be avoided.  

Where in detail the sensor or sensors are arranged are basically arbitrary as long as their Field of view can capture sufficient radiation energy. It can be provided that the sensors are below or are arranged above the material web. This assumes that the material web to be treated either at least partially for the radiation is transparent or at least partially reflective. This arrangement also presupposes that the Permeability or reflective properties do not change the path in the conveying direction. This would otherwise incorrectly tracking the performance of the Cause radiation source, and the even treatment the material web could no longer be guaranteed.

According to one embodiment of the invention provided that the sensor or sensors be so related to the radiation source is aimed to be that Field of view towards the radiation source is not is covered by the material web. Usually that is Radiation source wider than the web to be treated, see above that at least one sensor next to the material web below the radiation exit area of the Radiation source can be arranged in this way. It can of course on both sides of the material web Sensor arranged, its field of view in the direction on the radiation source not from the material web is covered.

Furthermore, it can be provided that at least one Sensor back and forth across the conveying direction of the material web is movable. This can be useful in some cases his. The radiant energy emitted across the width is then determined in succession and  accordingly, for example as explained above, evaluated and used to control performance.

It is also possible to idle the radiation sources the device, ie without an inserted material web testing. This can be particularly useful if a detection of the radiation energy during the Operation is not or only insufficiently possible. After all, it can be achieved that the Radiation sources and the emitted radiation energy be monitored.

In the method according to the invention proceeded that the emitted radiation intensity in Area of the radiation source at at least one point detected and compared with a target value, and that in the event of a deviation from the nominal value, the performance of the Radiation source is changed such that the emitted radiation intensity essentially constant remains. The capture and change of the emitted Light intensity can be essentially continuous done during operation so that a constant result can be guaranteed. If the intensity at several points across the Direction of conveyance is detected can from the detected Intensity values are averaged, whereby if it deviates from the setpoint, a change in Power of the radiation source takes place. Can also be so be proceeded that the intensity at several Places across the conveying direction is detected, from the smallest value of the detected intensity values is determined, and if it deviates from the setpoint a change in the power of the radiation source he follows.  

According to a further embodiment of the invention it is provided that across several radiation sources to the conveying direction of each radiation source at least one Sensor is assigned and that the performance of everyone Radiation source from the sensor assigned to it is controlled. This has the advantage that a Performance tracking can be done even more precisely. In particular, radiation overloads along the Width can be avoided because of a tracking due to the lowest radiation energy detected only the performance of the element concerned Radiation source is increased. It is also possible different intensities along the width adjust.

The invention is based on the schematic Drawing explained in more detail. Show it:

Fig. 1 is a view of a device according to the invention parallel to the conveying direction,

Fig. 2 is a view on an apparatus according to another embodiment of the invention,

Fig. 3 is a view of a device according to another embodiment of the invention and

Fig. 4 is a view of a device according to yet another embodiment of the invention.

The devices shown in the individual figures for treating a material web with radiation energy are structured essentially the same. In the drawing are therefore the same and equivalent elements provided with the same reference numerals.  

The device has a radiation energy source 11 , for example a UV light source, which extends perpendicular to the conveying direction of a material web 12 . Radiation energy is applied to the material web by the radiation source. The material web moves in a conveying direction perpendicular to the plane of the drawing. The funds and the machine frame on which the elements are arranged and held are not shown for the sake of clarity.

In the area of the radiation source, sensors 13 are arranged which detect the radiation intensity actually emitted. The sensors cooperate with a control unit 14 which changes the power of the radiation source in such a way that the power is increased if the intensity is detected too low and vice versa. This basic structure is the same in all of the embodiments shown.

In the exemplary embodiment shown in FIG. 1, a plurality of sensors 13 are provided along the width of the material web 12 and are connected to an upstream evaluation unit 15 . In this evaluation unit, the detected intensities are averaged, for example, or the lowest detected intensity is determined. The result is fed to the control unit 14 which , in the event of a deviation of the result from a desired value, brings about a corresponding change in the power of the radiation source 11 .

In the embodiment shown in FIG. 2, the sensors 13 , 13 'are arranged next to the material web in such a way that their field of view 16 in the direction of the radiation source is not covered by the material web. In the example on the left in the drawing, the radiation source 11 is wider than the material web 12 , and sensor 13 looks directly into the radiation source. In the example on the right in FIG. 2, the sensor 13 'is arranged obliquely and looks into the space between the material web and the radiation source. The field of view 16 of this sensor is exposed to an oblique angle of incidence of the radiation. With such an arrangement of the sensor, the intensity monitoring is essentially independent of the type and width of the material web to be treated.

Furthermore, only one control unit 14 is provided here. With such sensors being arranged on both sides, however, an evaluation unit for evaluating the two signals can also be expedient, which can also be integrated in the control unit.

In the embodiment shown in FIG. 3, the radiation source 11 is divided into a plurality of segments 17 , 17 'transversely to the conveying direction. It is provided here that a sensor 13 , 13 'is assigned to each segment and that the control unit 14 controls the power of the individual segments separately on the basis of the signal detected in each case.

In FIG. 4, the sensor 13 is designed to be movable back and forth on a rail 19 transversely to the conveying direction of the material web in the direction of the double arrow 18 . This can also be used to monitor the intensity along the width. It can also be provided that the position of the sensor is detected in the case of several segments of the radiation source transversely to the conveying direction, as shown in FIG. 3. The intensity recorded at a specific position can be used to change the performance of the segment assigned to this position. Several sensors can also be provided side by side on the rail 19 .

It is obvious that shown by everyone Embodiment actually monitoring emitted radiation intensity can be performed can. The power of the radiation source can be corresponding be adjusted. This makes it possible to treating material web always with the same to apply the prescribed amount of radiation, whereby a constant product quality is achieved becomes.

Claims (17)

1. Device for treating a material web by means of radiation energy, in particular by means of UV light for crosslinking coatings, through which device the material web ( 12 ) is moved in a conveying direction and in which at least one radiation source ( 11 ) extending perpendicular to the conveying direction is arranged, In order to apply radiation energy to the material web at least once over at least a portion of its width, characterized in that at least one sensor ( 13 , 13 ') is provided in the region of the radiation source for detecting the emitted radiation intensity, said sensor being connected to a control unit ( 14 ) interacts, which compares the detected radiation intensity with a target value and changes the power of the radiation energy source due to a deviation from the target value such that the emitted radiation acting on the web essentially corresponds to the target value and in particular k remains constant. 2. Device according to claim 1, characterized in that a plurality of sensors ( 13 ) are arranged along the width of the material web ( 12 ). 3. Apparatus according to claim 1 or 2, characterized in that the sensors ( 13 ) are arranged below or above the material web. 4. Device according to one of claims 1 to 3, characterized in that the one or more sensors ( 13 , 13 ') are aligned relative to the radiation source ( 11 ) that their field of view ( 16 ) in the direction of the radiation source not from the Material web is covered. 5. The device according to claim 4, characterized in that the radiation source ( 11 ) is wider than the web to be treated and that at least one sensor ( 13 ) is arranged next to the web such that its field of view ( 16 ) is not covered by the material web . 6. Apparatus according to claim 4 or 5, characterized in that on both sides of the material web ( 12 ) a sensor ( 13 , 13 ') is arranged, the visual fields ( 16 ) in the direction of the radiation source is not covered by the material web. 7. Device according to one of claims 1 to 6, characterized in that at least one sensor ( 13 ) can be moved back and forth transversely to the conveying direction of the material web ( 12 ). 8. Device according to one of claims 1 to 7, characterized in that an evaluation unit ( 15 ) is provided which, in the case of a plurality of sensors ( 13 ) for a radiation source ( 11 ), determines an average value of the radiation intensity detected, and in the event of its deviation from the desired value the power of the radiation source is changed. 9. Device according to one of claims 1 to 8, characterized in that an evaluation unit ( 15 ) is provided which, in the case of a plurality of sensors ( 13 ) for a radiation source ( 11 ), determines the lowest detected radiation intensity, and that when they deviate from the desired value, the Power of the radiation source is changed. 10. Device according to one of claims 1 to 9, characterized in that in the case of a plurality of radiation sources ( 17 , 17 '), at least one sensor ( 13 , 13 ') is assigned transversely to the conveying direction of each radiation source. 11. Method for treating a web of material Radiation energy, in particular by means of UV light for Crosslinking of coatings in which the Material web moved in a conveying direction and at least once over at least a section of its width at least one side is exposed to radiation energy is characterized in that the emitted Radiation intensity in the area of the radiation source recorded at least one place and with a setpoint is compared, and that if there is a deviation from Setpoint the power of the radiation source is changed such that the emitted radiation intensity in essentially corresponds to the setpoint. 12. The method according to claim 11, that the performance of Radiation source because of the detected intensities is changed that the emitted radiation intensity remains essentially constant. 13. The method according to claim 11 or 12, characterized characterized in that the capture and change of emitted light intensity essentially done continuously.   14. The method according to claim 11 or 13, characterized characterized that the intensity in several places transversely to the conveying direction is detected that from the detected A mean value is formed, and that at its Deviation from the nominal value a change in the performance of the Radiation source takes place. 15. The method according to claim 11 or 13, characterized characterized that the intensity in several places transversely to the conveying direction is detected that from the detected Values the smallest value is determined, and that at whose deviation from the setpoint changes the Power of the radiation source takes place. 16. The method according to any one of claims 11 to 15, characterized characterized in that the sensor or sensors so relative to Radiation source are aligned that their field of vision towards the radiation source not from the Material web is covered. 17. The method according to any one of claims 11 to 16, characterized characterized in that across several radiation sources to the conveying direction of each radiation source at least one Sensor is assigned and that the performance of everyone Radiation source from the sensor assigned to it is controlled.