EP1779050A1

EP1779050A1 - Irradiation unit

Info

Publication number: EP1779050A1
Application number: EP05767850A
Authority: EP
Inventors: Oliver Treichel; Klaus Ebinger; Joachim Jung; Günter Fuchs
Original assignee: IST Metz GmbH
Current assignee: IST Metz GmbH
Priority date: 2004-08-06
Filing date: 2005-07-19
Publication date: 2007-05-02
Anticipated expiration: 2025-07-19
Also published as: DK1779050T3; DE102004038592A1; EP1779050B1; US20080277600A1; US7858956B2; WO2006015694A1; ATE546702T1

Abstract

The invention relates to an irradiation unit for the UV irradiation of particularly web-shaped substrates, comprising a housing (10), a tubular UV lamp (12), arranged therein and a reflector arrangement (14), running along the UV lamp (12). According to the invention, a simple exchangeability may be achieved, whereby the reflector arrangement comprises a support profile (22), retained in the housing (10) and a reflector profile (24), embodied as a shape-retaining molded piece which may be detachably connected thereto.

Description

BesÜ: rahlungssggr © gat

description

The invention relates to an irradiation unit for UV irradiation of particular sheet-like substrates with a housing, a rod-shaped UV lamp arranged therein and a reflector arrangement extending along the UV lamp.

The UV drying and crosslinking of paints, inks and adhesives utilizing the energy content of light quanta in the UV light range with the help of long-stretched medium-pressure gas discharge lamps has been widely used in industry for over 30 years in the printing, packaging and surface industries. Solvent-free in the process and the availability of high crosslinking densities at processing times in the passage of fractions of a second are the main features of this technique. Medium-pressure gas discharge lamps emit light from the short-wave UV over the visible range up to the long-wave IR. The effect of the reflector in such UV aggregates should not be underestimated. Depending on the shape and geometry, its proportion of the total emission effective on the substrate is 50 to 90%. In the case of selective reflection, the ratio of UV light to IR heat share can also be controlled. In this context it has already been proposed to clamp flexible metal strips as a reflector fixed to the housing. A disadvantage here is that it is thus not possible to adapt a specific reflector geometry in a simple manner. Moreover, it seems questionable whether such constructions can prove themselves in industrial continuous operation under high temperature stressing.

Proceeding from this, the present invention seeks to improve an aggregate of the type specified in that the Prior art disadvantages have been avoided and a variable use is possible.

To solve this problem, the feature combination specified in claim 1 is proposed. Advantageous embodiments and developments of the invention will become apparent from the dependent Ansprü¬ surfaces.

Accordingly, it is proposed according to the invention that the reflector arrangement has a carrier profile held in the housing and a reflector profile which can be detachably connected thereto and is designed as a dimensionally stable molded part and thus exchangeable. As a result, a modular structure is created in a simple manner, which makes it possible to optimally adapt the irradiation profile to the respective process conditions. Through the use of profiled bodies, a defined geometry is predetermined over the length of the lamp, which can also be exchanged at short notice with regard to various parameters such as the chemical formulation of the coating agent to be hardened, the still acceptable heat input to the substrate and the irradiation duration or dose can be adjusted. The correct interpretations often only result after extensive tests. This can certainly take place shortly before or only during commissioning, for example in the printing plant on site. Variability in reflector geometry avoids costly risks. Changes in the product or coating chemistry can be selectively accommodated by choosing the appropriate reflector profile. The use of solid profiles ensures high thermal stability. In addition, the reflector profiles are easily accessible for maintenance or cleaning.

Advantageously, a plurality of reflector profiles with different reflector geometries and / or surface coatings as Baukastensys¬ system optionally connectable to the carrier profile, wherein by uniform Connecting surfaces regardless of the reflector geometry easy installation is guaranteed.

A further improvement provides that the reflector profile and the carrier profile can be brought into contact with one another by means of positive connection surfaces in flat heat-conducting contact. It is advantageous if the reflector gate profile and the carrier profile are held in mutual surface contact via connecting means, in particular screw connections.

An ivlontageeinfachung results from the fact that the connecting means are operable from the rear side facing away from the reflector profile of the carrier profile. It is also favorable if the connecting means are accessible from the outside of the housing by housing flaps that can be closed, for example.

A further advantageous embodiment provides that the connecting means seen in the profile direction preferably allow a thermal compensation play between reflector profile and carrier profile via a slot mounting.

In structurally advantageous implementation, the connecting means are formed by the shaft preferably screwed to stop in the reflector profile and the head side preferably via spring and / or sliding discs on the Träger¬ profile supported bolt.

Advantageously, the carrier profile can be acted upon by cooling, in particular ei¬ ne water cooling with coolant. This can be realized in that the carrier profile is provided with profile channels for the passage of coolant. This also makes it possible to exchange the reflector profiles without interrupting the cooling system in a short time.

By appropriate wall thicknesses, it is possible that the reflector profile facing away from its connecting surface with the carrier profile and has a curved reflector surface deviating from its contour profile. The connection surface can therefore be formed uniformly for a standardized receptacle, while the reflector surface is selectively adapted to the radiation conditions.

In order to allow a spectral influence, it is advantageous if the reflector profile is provided on its side facing the UV lamp profile side with a reflection coating.

For a high load or stability, it is advantageous if the reflector profile is formed as a solid body of a solid material. In terms of manufacture, it is advantageous in this case if the reflector profile and the carrier profile preferably consist of extruded aluminum parts.

A further simplification also with regard to the required apparatuses for the reflector coating results from the fact that a plurality of reflector profiles are assembled on the face side as a profile strand. It should be ensured that the joints, which may have a lower reflection value, are offset with a pairwise reflector arrangement and are not opposite each other.

To improve the heat transfer, it may be advantageous if between the connecting surfaces of reflector profile and carrier profile, a heat conducting, in particular thermal paste is introduced.

Advantageously, in each case a carrier profile and an associated reflector gate profile are arranged in pairs on both sides of a longitudinal center plane of the UV lamp. For a closure function of the irradiated housing opening, it is possible for two reflector profiles, together with associated carrier profiles, to be arranged in the housing so as to be pivotable relative to each other about an axis extending in the profile direction. In the following the invention will be explained in more detail with reference to an embodiment schematically illustrated in the drawing. Show it

1 shows a UV irradiation unit for drying printing webs in cross section. and

Fig. 2 is a partial enlargement of a screw in the region of a reflector assembly of the unit according to Fig.1.

The UV irradiation unit shown in the drawing consists essentially of a box-shaped housing 10, a rod-shaped UV lamp 12 arranged therein, a reflector arrangement 14 for reflecting the UV light radiated into the housing 10 onto a base-side housing opening 16 and an absorber 18 for dissipating heat loss via a cooling device, not shown.

The UV lamp 12 is arranged as a double-ended medium-pressure gas discharge lamp in the central longitudinal plane 20 of the housing 10 and emits its radiation via the housing opening 16 to the substrate web guided underneath or to the object to be irradiated. In order to increase the irradiation of the object, the UV lamp 12 is surrounded in its pointing into the housing interior sector over its length by the reflector assembly 14, the reflected light according to reflector geometry divergent, parallel or bundled through the housing opening 16 through becomes. It is also conceivable that different reflection geometries are realized in reflector subregions.

For optional adjustment of the reflector properties, the reflector arrangement 14 comprises carrier profiles 22 and detachably connected reflector profiles 24. The carrier and reflector profiles are arranged in pairs on both sides of the longitudinal center plane 20 of the housing 10 or the UV lamp 12. orders, wherein the profile direction is parallel to the lamp axis. They are made of aluminum as massive extruded profile parts, so that in particular the reflector profiles 24 are designed to be dimensionally stable as complex shaped moldings. It is possible to use different reflector profiles 24 in the manner of a modular system. This is shown in FIG. 1 for the sake of better illustration for two reflector geometries on the left and right of the middle plane 20, wherein profile-like parts are usually arranged mirror-symmetrically in practical use, but in principle also a-symmetrical arrangements are possible.

The reflector profiles 24 and carrier profiles 22 can be brought into positive contact with large-area heat-conducting contact via complementary complementary connection surfaces 26, 28. For effective heat dissipation, the carrier profiles 22 can be connected to the cooling device via profile channels 30 for the passage of cooling water. In this way it is possible to work with high lamp powers in the range of a few 10 kW.

The carrier profile 22 and the reflector profile 24 are held in mutual contact in the region of the connecting surfaces 26, 28 via screw connections 32. In order to simplify assembly or reflector replacement at the place of use, for example in a printing press, it is expedient if the screw connections 32 are accessible from the outside of the housing by housing flaps 34.

As shown in FIG. 2, the screw connections 32 are formed by stud bolts 36, which can be screwed into the reflector profile 24 from the rear side 38 of the carrier profile 22. In the connection state, the stud bolts 36 are screwed with their stepped threaded shaft 40 to stop in the reflector profile 24. The screw head 42 is supported by disc springs 44 and sliding discs 46 with defined adhesion to the support section 22. In order to enable a thermal compensation clearance, the step opening 48 is formed in the profile direction as a slot. - / -

Due to the freely deformable profile geometry, the reflector surface 50 of the reflector profiles 24 facing the UV lamp 12 can be designed independently of the profile contour of the connection surface 26. Elliptic, parabolic and circular reflector geometries as well as combinations thereof are used. Also conceivable are reflector surfaces 50 with Freilinien¬ forms.

By an additional surface coating 52 of the reflector profiles 24, the spectral range of the reflected light can be influenced. High-purity aluminum surfaces reflect the entire spectrum, while so-called cold-light mirror coatings reflect only selected spectral bandwidths in the UV range, depending on the design. In addition to the water cooling, the heat absorbed in the reflector arrangement 14 can also be dissipated through the air cooling system with suction through the exhaust air duct 54.

The UV and IR emission of the gas discharge lamp 12 can not be switched on and off spontaneously for physical reasons. Therefore, it is intended to bring the reflector assembly 14 during startup or Betriebsun¬ interruptions in a standby position in which the Gehäuseöff¬ opening 16 is mechanically sealed against radiation passage. For this purpose, the carrier profiles are movable relative to one another about a pivot axis or axis of rotation running parallel to the profile direction, the IR power being absorbed by the cooled absorber 18. From this position can be changed without significant loss of time by pressing the folding or rotating mechanism in the production mode. Instead of a movable reflector, it is also possible to use a separate closure system.

Claims

1. Irradiation unit for UV irradiation of in particular web-shaped substrates with a housing (10), a rod-shaped UV lamp (12) and a UV lamp (12) extending along the reflector assembly (14), characterized the reflector arrangement (14) has a carrier profile (22) held in the housing (10) and a reflector profile (24) which can be detachably connected thereto and formed as a dimensionally stable molded part.

2. Irradiation unit according to claim 1, characterized in that a plurality of reflector profiles (24) with different Reflektorgeo¬ metrics and / or surface coatings as a modular system optionally with the carrier profile (22) are connectable.

3. Irradiation unit according to claim 1 or 2, characterized gekenn¬ characterized in that the reflector profile (24) and the carrier profile (22) via positive connection surfaces (26,28) are engageable with each other in flat Wärmeleitkontakt.

4. irradiation unit according to one of claims 1 to 3, characterized ge indicates that the reflector profile (24) and the carrier profile (22) via connecting means (32), in particular screw connections are held in mutual contact.

5. irradiation unit according to claim 4, characterized in that the connecting means (32) of the reflector profile (24) abge¬ facing back (38) of the carrier profile (22) are operable forth.

6. irradiation unit according to claim 4 or 5, characterized gekenn¬ characterized in that the connecting means (32) by for example - Q - closable housing flaps (34) from the outside of the housing (10) are accessible forth.

7. Irradiation unit according to one of claims 4 to 6, character- ized in that the connecting means (32) in the profile direction hen hen preferably via a slot bearing (48) a thermal compensation game between the reflector profile (24) and carrier profile (22) er¬ ,

8. irradiation unit according to one of claims 4 to 7, characterized ge indicates that the connecting means (32) by shank vor¬ preferably abutment in the reflector profile (24) screwed and head side preferably via spring and / or sliding discs (44,46 ) on the carrier profile (22) supported bolt (36) are formed.

9. irradiation unit according to one of claims 1 to 8, characterized ge indicates that the carrier profile (22) by cooling, in particular a special water cooling can be acted upon with coolant.

10. Irradiation unit according to one of claims 1 to 9, characterized ge indicates that the carrier profile (22) is provided with profile channels (30) for the passage of coolant.

11. Irradiation unit according to one of claims 1 to 10, characterized in that the reflector profile (24) facing away from its Verbin¬ training surface (26) with the carrier profile (22) and deviating from the contour of the curved curved reflector surface (50).

12. Irradiation unit according to one of claims 1 to 11, characterized in that the reflector profile (24) on its UV lamp

(12) facing profile side with a reflective coating (52) ver¬ see is.

13. Irradiation unit according to one of claims 1 to 12, characterized in that the reflector profile (24) is formed as a solid body of a solid material.

14. Irradiation unit according to one of claims 1 to 13, characterized in that the reflector profile (24) and the carrier profile (22) preferably consist of extruded profile parts made of aluminum.

15. Irradiation unit according to one of claims 1 to 14, characterized in that a plurality of reflector profiles (24) are assembled as a profile strand frontally.

16. Irradiation unit according to one of claims 1 to 15, characterized in that between the connecting surfaces (26,28) of

Reflector profile (24) and carrier profile (22) a heat conducting, insbeson dere thermal paste is introduced.

17. Irradiation unit according to one of claims 1 to 16, characterized in that in each case a carrier profile (22) and a zugeordne¬ tes reflector profile (24) in pairs on both sides of a longitudinal center plane (20) of the UV lamp (12) are arranged.

18. Irradiation unit according to one of claims 1 to 3, character- ized in that two reflector profiles (24) together with zugeord¬ Neten carrier profiles (22) are arranged in each case about an axis extending in the direction of profile pivotally against each other in the housing (10) ange¬ ,