DE20005670U1 - UV radiation device with an essentially closed reflector, in particular for curing UV-reactive adhesives - Google Patents

Description

UV irradiation device with essentially closed reflector, especially for curing UV-reactive adhesives

The present invention relates to an irradiation device for irradiating one or more objects with ultraviolet radiation (UV radiation). The irradiation is used to cure UV-reactive adhesives.

Known irradiation devices for irradiating one or more objects with UV radiation, such as those sold by the applicant under the type designation UFAPRINT LE, comprise an elongated gas discharge lamp, which is designed, for example, as a high-pressure discharge lamp, for emitting UV radiation and an elongated reflector made of highly reflective material, which extends along the gas discharge lamp and focuses the UV radiation on an irradiation line that is parallel to the gas discharge lamp in order to irradiate the object or objects on this line. The cross-section of the elongated reflector has (essentially) the shape of an ellipse, with the gas discharge lamp being arranged along the first focal line and the irradiation line lying on the second focal line of the ellipse. This well-known UV line emitter is used for all-round irradiation of thread-shaped objects and is used in particular for hardening coatings, markings, printing or varnishing of strand-, cable- and thread-shaped objects. The reflector consists of two reflector parts, each of which is arranged in a housing part. For irradiation, for example, a thread-shaped object is placed along the irradiation line in one of the housing parts. The two housing parts can be folded apart for this purpose. When closed, the two reflector parts lie opposite each other so that the gas discharge lamp is arranged in the focal line of one reflector part and the object to be irradiated is arranged in the focusing line of the other reflector part.

The disadvantage of this well-known UV line emitter is that only thread-like, endless objects (e.g. cables) can be continuously irradiated.

The object of the present invention is therefore to further develop the irradiation device known from the prior art described above for irradiating one or more thread-like objects with UV radiation in such a way that continuous irradiation of individual objects is possible.

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This object is achieved by an irradiation device for irradiating one or more objects with UV radiation according to claim 1. The irradiation device according to the invention comprises an elongated gas discharge lamp for emitting UV radiation, an elongated reflector made of highly reflective material, e.g. high-purity aluminum, which extends along the gas discharge lamp and essentially completely encloses it in such a way that the UV radiation is focused on an irradiation line. This extends parallel to the gas discharge lamp. The object or the adhesive point is guided along the focal line for irradiation. For the supply, the elongated reflector is provided with an opening extending in the longitudinal direction in the area of the irradiation line.

The irradiation device according to the invention thus enables the continuous irradiation of several objects. It is particularly advantageous that the objects to be irradiated are no longer limited to strand-, cable- or thread-shaped objects, but objects of practically any shape can be irradiated. For example, the irradiation device according to the invention thus enables the irradiation of adhesive bonds on any component along the irradiation line. The essentially completely closed shape of the elongated reflector also enables a very high irradiance and a very homogeneous and high-intensity intensity distribution along the irradiation line. The opening extending in the longitudinal direction enables the feeding and transport of the object(s) to be irradiated along the irradiation line, whereby it must be ensured that the point of the object(s) to be irradiated moves along the irradiation line.

The elongated reflector advantageously has an elliptical cross-section, with the gas discharge lamp being arranged along one focal line and the irradiation line lying on the other focal line. The elliptical cross-section has the advantage that the UV radiation emitted by the gas discharge lamp is completely focused on the irradiation line, so that highly efficient use of the radiation energy is guaranteed. The elliptical cross-sectional shape of the reflector enables an improved and more homogeneous intensity distribution of the UV radiation along the irradiation line and thus the objects to be irradiated, which enables overall energy savings, the peak temperature on the objects is lowered and the exposure time or irradiation time is shortened, so that more efficient and economical irradiation can be achieved. The homogeneous intensity distribution also has the further advantage in particular that rotation of the object or objects during the irradiation process, as is sometimes common with known devices,

may be eliminated entirely, thereby further reducing costs and increasing efficiency.

The opening is advantageously a slot extending in the longitudinal direction of the elongated reflector, through which a conveyor device can engage to feed the object(s) to the irradiation line. The slot is designed in such a way that the conveyor device can transport the object(s) along the irradiation line during the irradiation process. Alternatively, several objects are fed through the slot to the irradiation line by one or more transport devices, where they are then irradiated with UV light while stationary on the irradiation line (possibly while rotating). According to a first aspect of the present invention, the slot is on the side of the irradiation line facing away from the gas discharge lamp. According to a second aspect of the present invention, the slot is located to the side of the irradiation line.

It is also advantageous if the opening or slot for feeding the object(s) is provided with light traps to prevent UV radiation from escaping from the elongated reflector. This largely prevents harmful effects on the eyes and skin.

The elongated reflector is advantageously arranged in a housing, the opening for feeding the objects being defined between two reflector parts, each of which can be opened up laterally with an associated housing part. This design is particularly advantageous if the opening is designed as a slot that lies on the side of the irradiation line facing away from the gas discharge lamp.

Alternatively, the elongated reflector can be arranged in a housing in which a single reflector part extending along the irradiation line can be opened up laterally with an associated housing part. This design is particularly advantageous if the opening for feeding the object(s) is designed as a slot that is located laterally to the irradiation line.

It is also advantageous if the elongated reflector in the area of the high-pressure discharge lamp consists of two reflector parts that can be folded in to close the gas discharge lamp. (= shutter system)

The present invention is explained in more detail below with reference to the accompanying drawings, in which

Fig. 1 is an external view of the longitudinal side of an irradiation device according to the invention,

Fig. 2 is an external view of a transverse side of the irradiation device shown in Fig. 1,

Fig. 3 is a cross-sectional view of a first embodiment of an irradiation device according to the invention,

Fig. 4 is a cross-sectional view of a second embodiment of an irradiation device according to the invention, and
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Fig. 5 is a measurement diagram of the intensity distribution around the irradiation line as a function of the measurement angle.

Fig. 1 shows the external view of the long side of an irradiation device 1 according to the invention for irradiating one or more objects with UV radiation. The irradiation device 1 according to the invention comprises a housing 2 which consists of several housing parts. The external view of an irradiation device 1 according to the invention shown in Fig. 1 shows, for example, an upper housing part 2a and a lower housing part 2b, each of which extends in the longitudinal direction. Both housing parts 2a and 2b are connected with hinges 6, by means of which the lower housing part 2b can be folded away or opened laterally, i.e. upwards out of the plane of the drawing. The front sides of the irradiation device 1 according to the invention are closed off by front housing parts 3a and 3b. Inside the housing 2 there is an elongated reflector which surrounds an elongated gas discharge lamp, e.g. in the form of a high-pressure discharge lamp. Both elements are explained in more detail below with reference to Figs. 3 and 4. A connector plug for the power connection of the high-pressure discharge lamp is provided on the top of the housing 2 of the irradiation device 1. The energy released in the form of heat inside the housing 2 when objects are irradiated is transported away by air cooling. Fresh air is sucked in on the underside of the housing 2 and transported away on the top of the housing 2 via an exhaust air duct 4. The total length of the irradiation device 1 according to the invention, i.e. more precisely the length of the high-pressure gas discharge lamp, is

depending on the UV dose required or to be applied for the curing of the adhesive.

Fig. 2 shows an external view of the transverse side of the irradiation device 1 shown in Fig. 1. Fig. 2 shows a top view of the front housing part 3a, which closes off the longitudinally extending housing 2 on one side. Above the front housing part 3a, the connector plug 5 is shown schematically, while to the left and right of the front housing part 3a, the hinges 6 are shown, which connect the upper and lower housing parts of the housing 2 to one another in such a way that the lower housing parts can be folded upwards. In the middle lower area of the front housing part 3a, an opening 7 designed as a slot is shown, which extends vertically downwards from approximately the middle of the front housing part 3a. The opening 7 is used to feed objects to be irradiated with UV radiation. The irradiation line

(13) extends in the longitudinal direction of the irradiation device 1 and is therefore shown only as a point in Fig. 2. As explained in more detail below with reference to Figs. 3 and 4, the irradiation line 13 lies on the second focal point line, which is defined by the cross-sectionally elliptical structure of the elongated reflector inside the housing 2. All dimensions are in millimeters.

Fig. 3 shows a cross section through a first embodiment of an irradiation device 1 according to the invention. The first embodiment of the irradiation device 1 according to the invention shown in Fig. 3 corresponds to the irradiation device shown in Figs. 1 and 2.

1. As can be seen in Fig. 3, the housing 2 of the first embodiment shown comprises a total of three housing parts 2a, 2b and 2c extending in the longitudinal direction. The two lower housing parts 2b and 2c are each pivotably connected to the upper housing part 2a by a hinge 6. The two lower housing parts 2b and 2c can be folded away or opened up at the side.

An elongated reflector 9 made of highly reflective material, for example high-purity aluminum, is arranged inside the housing 2. In the embodiment shown, the elongated reflector 9 has an elliptical cross-section and essentially completely surrounds an elongated high-pressure discharge lamp 8 for emitting UV radiation. The high-pressure discharge lamp 8 extends longitudinally along the first focal line of the elliptical reflector 9, with the objects being guided with their adhesive point in the irradiation line 13. The essentially closed elliptical reflector 9 enables uniform all-round irradiation of the parts of one or more objects to be irradiated along the

Irradiation line 13, onto which all of the UV radiation emitted by the high-pressure discharge lamp 8 is focused. This achieves a very high irradiance, which enables the highest production speeds to be achieved.
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The reflector 9 consists of four reflector parts 9a, 9b, 9c and 9d. The reflector parts 9a and 9d are assigned to the housing part 2a and the reflector parts 9b and 9c are each assigned to the housing part 2b or 2c and fastened to it. Accordingly, the two lower reflector parts 9b and 9c can be folded away with the respective associated housing part 2b or 2c so that the interior of the reflector 9 is accessible, for example in order to replace the high-pressure discharge lamp 8. Each reflector part 9a, 9b, 9c and 9d consists of a base part with cooling fins and an inserted, replaceable reflector sheet (e.g. high-purity aluminum). When closed, the reflector sheets of the reflector parts 9a, 9b, 9c and 9d together form the elongated reflector 9 with an elliptical cross-section.

The reflector 9 and the housing 2 have an opening 10 in the form of a slot in the lower part. The objects are fed to the irradiation line 13 by a conveyor system or a transport device 14. In the example shown, a needle 11 is glued in the plastic base part 12, the adhesive being hardened by the UV radiation from the high-pressure discharge lamp 8 focused on the irradiation line 13. The opening 10 is on the side of the irradiation line 13 facing away from the high-pressure discharge lamp 8 and corresponds to the opening 7 in the front housing part 3a, as shown in Fig. 2. The objects fed through the opening 7 of the front housing part 3a are fed to the irradiation line 13 through the opening 10 formed by the reflector 9 and the housing 2, or are transported along it.

The two upper reflector parts 9a and 9d can be folded into a closed position, which is indicated in Fig. 3 with 9a' and 9d'. In this closed position, practically no UV radiation escapes downwards from the high-pressure discharge lamp. This shutter system is closed pneumatically during production interruptions and when problems occur and the lamp power is reduced to approx. 30%. This prevents "burning" of objects already in the UV system.

■ The reflector layer of the reflector 9 is preferably made of high-purity aluminum (99.99% aluminum), so that the UV radiation is reflected onto the objects to be irradiated with practically no loss. The connected load of the high-pressure

For example, the power consumption of a discharge lamp is between 1.5 and 10 kW. The high-pressure discharge lamp 8 can be designed for various applications. For example, UV radiation in the range from 380 to 315 nm is suitable for curing UV-reactive adhesives and plastics, particularly since many plastics only become more permeable to radiation from 350 nm, which means that adhesive applied to the inside hardens better. Here, for example, gallium doping of the high-pressure discharge lamp is advantageous, since the radiation spectrum of the UV radiation is shifted into the longer wavelength range of > 350 nm. For other irradiation purposes, other dopings may be advantageous, such as iron doping or mercury doping. High-pressure discharge lamps with mercury doping are generally cheaper, simpler in construction and more robust, but have less UV radiation in the longer wavelength range. They are advantageously used, for example, in the curing of surface coatings and the like, where UV radiation in the range of 280 to 200 nm is used. An iron doping, such as

e.g. in metal halide lamps, is also suitable for curing adhesives, but not as good as gallium doping. Depending on the application, a low-pressure gas discharge lamp can also be used.

Although not shown in Fig. 3, light traps can be provided in the region of the opening 10 on the lower housing parts 2b and 2d to prevent the escape of UV radiation.

Fig. 4 shows a cross section through a second embodiment of the irradiation device according to the invention. The main difference from the first embodiment shown in Fig. 3 is the arrangement of the opening 15 for feeding the object or objects to be irradiated. In the second embodiment, the opening 15 is arranged laterally to the irradiation line 13, so that the transport device or the feed system 17, through which the objects to be irradiated are fed to the irradiation line 13, projects laterally through the housing 2 and the reflector 9 into the interior of the reflector. In the example shown in Fig. 4, the lower part of the irradiation device 1 is formed from two housing parts 2e and 2f, each with an associated reflector part 9e or 9f. The housing part 2e with the reflector part 9e forms the larger part. The opening 15 is formed between the housing part 2e with the reflector part 9e and the housing part 2f with the reflector part 9f. The housing part 2e is attached to the upper housing part 2a with a hinge 6, so that the lower housing part 2e with the reflector part 9e can be folded away or opened to the side. It should be noted that the upper housing part 2a with the associated reflector part 9c can also be made in one piece with the

attached housing part 2f with the associated reflector part 9f. All other functions and features of the second embodiment shown in Fig. 4 correspond to those of the first embodiment. The above explanations with respect to the first embodiment are therefore also applicable identically to the second embodiment.

It should be emphasized that the length of the irradiation device 1 according to the invention, and in particular the length of the high-pressure discharge lamp 8 and the dimensions of the associated reflector 9, depend on the intended use and must be adjusted according to the requirements. However, it is important that the elongated reflector 9 extends lengthways to the high-pressure discharge lamp 8 and encloses it essentially completely in such a way that the UV radiation emitted by the high-pressure discharge lamp 8 is focused on an irradiation line 13 which is parallel to the high-pressure discharge lamp 8 in order to irradiate the object(s) on this line. Furthermore, the opening 10 or 15 extending in the longitudinal direction must be provided in the area of the irradiation line 13 for feeding the object(s).

Figure 5 shows a measurement result for the intensity distribution along the irradiation line 13 as a function of the measurement angle in relation to the high-pressure discharge lamp 8. The intensity distribution shown was recorded using a quartz rod measuring device. It can be seen that the irradiation device 1 according to the invention enables an extremely homogeneous radiation intensity along the irradiation line 13, which is due in particular to the optimized geometry of the reflector 9 (beam path to the irradiation line 13) and on the other hand to the compact design of the reflector 9. In particular, the areas of maximum intensity directly under the high-pressure discharge lamp 8 (0° angle) and in the angle ranges around 130° and 240° are normally problematic, since experience has shown that these areas represent problem zones with regard to curing with UV radiation, particularly when curing adhesives. However, the irradiation device 1 according to the invention also enables a very homogeneous intensity distribution in these areas. In the area of the elliptical reflector system, additional reflectors can be provided on the front side, which generate an additional reflection in the longitudinal direction of the reflector 9. A rotation of the objects to be irradiated during transport along the irradiation line 13 is therefore no longer necessary in every case. In the second embodiment shown in Fig. 4, however, such a rotation device 8 for rotating the objects 16 to be irradiated during irradiation is shown schematically.

Claims (9)

1. Irradiation device (1) for irradiating one or more objects with UV radiation, with
an elongated gas discharge lamp (8) for emitting UV radiation,
an elongated reflector (9) made of highly reflective material which extends along the gas discharge lamp (8) and encloses it substantially completely in such a way that the UV radiation is focused on an irradiation line (13) which is parallel to the gas discharge lamp (8) in order to irradiate the object or objects on this line,
wherein the elongated reflector (9) has, in the region of the irradiation line (13), an opening (10; 15) extending in the longitudinal direction for feeding the object or objects. 2. Irradiation device (1) according to claim 1, characterized in that the elongated reflector (9) has an elliptical cross-section, the gas discharge lamp (8) being arranged along one focal line and the irradiation line (13) being located on the other focal line. 3. Irradiation device (1) according to claim 1 or 2, characterized in that the opening (10; 15) is a slot extending in the longitudinal direction of the elongate reflector, through which a transport device (14; 17) for feeding the object or objects to the irradiation line (13) can engage. 4. Irradiation device (1) according to claim 3, characterized in that the slot (10) is located on the side of the irradiation line facing away from the gas discharge lamp. 5. Irradiation device (1) according to claim 3, characterized in that the slot (15) is located laterally to the irradiation line. 6. Irradiation device (1) according to one of claims 1 to 5, characterized in that the opening (10; 15) is provided with light traps to prevent the escape of UV radiation. 7. Irradiation device (1) according to one of claims 1 to 6, characterized in that the elongate reflector (9) is arranged in a housing (2), the opening (10) for feeding the objects being defined between two reflector parts (9b, 9d) extending along the irradiation line (13), which can each be folded open laterally with an associated housing part (2b, 2c). 8. Irradiation device (1) according to one of claims 1 to 6, characterized in that the elongate reflector (9) is arranged in a housing (2), wherein at least one reflector part (9e) extending along the irradiation line (13) can be folded open laterally with an associated housing part (2e). 9. Irradiation device (1) according to one of claims 1 to 8, characterized in that the elongated reflector (9) in the region of the gas discharge lamp consists of two reflector parts (9a, 9c) which can be folded in to close the gas discharge lamp (8).