DE20203305U1 - Assembly to expose a coated surface to ultra violet light, has an inlet opening to form a film of carbon dioxide gas, to create an inert atmosphere around the illuminated surface - Google Patents

Abstract

The assembly (1) to create an inert atmosphere, while an object is exposed to ultra violet light, blows CO2 gas through an inlet opening (2) into the treatment zone. A number of outlet openings, connected to the inlet opening, are side-by-side at one side of the inlet opening so that the blown gas covers the surface of the object (4) with a gas film (9). The ultra violet light is directed (8) at the object through the gas film.

Description

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Device for blowing out CO, for UV curing

The present invention relates to a device for blowing gaseous CO ₂ onto an object to be irradiated with radiation in the ultraviolet or visible range.

Methods and devices for irradiating objects with ultraviolet or visible radiation are known in various variations. Basically, these irradiation devices and methods use radiation to dry and/or cure or even disinfect adhesives, varnishes, plastics, paints, etc. This drying and curing takes place, for example, on objects such as compact discs (CDs), digital versatile discs (DVDs), etc., but also on adhesives used to bond small and tiny electronic components within electronic devices. UV radiation is also used to cure or dry surfaces, varnishes, plastics, etc. in the automotive industry, in plastics production, etc.

What all of the applications described have in common is that the irradiated objects or surfaces are dried, hardened or disinfected by the photochemical reactions triggered by the visible or ultraviolet radiation, depending on the radiation energy. The problem here is that the oxygen contained in the atmosphere in the irradiated object competes with the crosslinking caused by the photoinitiators contained in the irradiated surface. More precisely, the oxygen reacts with the photoinitiator radicals or the double bonds of the binders/monomers of the irradiated surface. This delays the crosslinking or hardening. Usually, attempts are made to solve this problem by using higher concentrations of photoinitiators and/or a higher radiation dose.

The disadvantages here are that the production speed is reduced as a result of the longer drying or curing time, that the higher energy and/or higher photoinitiator concentration increases the process costs and that an increased odor occurs due to the increased photoinitiator concentration and the residual monomer content. The prior art, such as WO/14468, attempts to reduce these disadvantages by cross-linking, i.e. irradiation in an inert atmosphere with nitrogen. The object or surface to be irradiated is flushed with nitrogen during irradiation or placed in a nitrogen atmosphere.

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However, the use of nitrogen also has major disadvantages. On the one hand, the specific weight of nitrogen is smaller than the specific weight of air, i.e. nitrogen is very volatile, which results in a very high consumption of nitrogen. If the high consumption of nitrogen is to be limited, a high level of construction effort is required to seal off the inert atmosphere. In particular, however, nitrogen as an inert gas has the disadvantage that a high degree of nitrogen purity must be achieved and maintained when curing or drying objects under visible or ultraviolet radiation, since the desired advantages of fast and efficient drying or curing are no longer available even with a very low residual oxygen content in the ppm range.

The present invention is therefore based on the object of providing a possibility for irradiating objects with radiation in the visible or ultraviolet range in an inert atmosphere with a structure that is as simple as possible and yet effective.

This object is achieved by a device for blowing out gaseous CO ₂ onto an object to be irradiated with radiation in the ultraviolet or visible range according to claim 1. In order to create an inert atmosphere on the surface of the object to be irradiated, the blowing device according to the invention has an inlet opening for introducing gaseous CO ₂ into the device and several outlet openings which are connected to the inlet opening, wherein the blowing device is designed in such a way and the outlet openings are arranged next to one another on one side of the blowing device in such a way that blown out CO ₂ covers the surface of the object to be irradiated.

The blow-out device according to the invention thus enables the creation of an inert atmosphere even for objects that cannot be immersed in a CO ₂ bath or for objects that have a complicated structure. The blow-out device according to the invention can be very simple and lightweight in order to be used flexibly. The design of the blow-out device according to the invention for use with gaseous CO ₂ as an inert gas for irradiating objects with ultraviolet or visible radiation is particularly advantageous because gaseous CO ₂ is heavier than air, i.e. it is less volatile. This results in significantly lower consumption and correspondingly lower costs when providing an inert atmosphere for the object or objects to be irradiated.

objects to be irradiated. Furthermore, gaseous CO ₂ has the particular advantage over nitrogen during irradiation that very good quality and speed in hardening, drying and disinfection is achieved even with higher oxygen concentrations in the CO ₂ of approx. 0.1 to 10 percent. The blowing device according to the invention takes this fact into account. Since it is very difficult to create a 100 percent inert atmosphere when blowing out and covering the surface of the object to be irradiated as a result of drafts, geometric irregularities, etc., a certain contamination of the surface to be irradiated with oxygen molecules cannot be avoided. However, the gaseous carbon dioxide used according to the invention still enables very rapid and high-quality irradiation.

The blow-out device according to the invention is advantageously designed as a strip, with the outlet openings arranged next to one another on one of the elongated sides. In this case, a single row of outlet openings is advantageously provided. This design of the blow-out device according to the invention is very light and easy to handle and is particularly advantageous when irradiating flat surfaces and in particular two-dimensional surfaces.

In an alternative embodiment, the blow-out device according to the invention is advantageously designed as an elongated plate, with the outlet openings arranged next to one another on one of the elongated sides. Advantageously, several rows of outlet openings are provided. This embodiment is particularly advantageous when irradiating three-dimensional surfaces or objects, since the several rows of outlet openings also allow surfaces with unevenness or surfaces with sections at different heights to be effectively irradiated.

The blow-out device according to the invention is advantageously made of a flexible material. This allows for easy adaptation to the respective shape of the object or surface to be irradiated.

Alternatively, the blow-out device according to the invention can be made of a rigid material.

The outlet openings of the blow-out device according to the invention are advantageously designed as slot nozzles, hole nozzles or the like.

A mixture of different outlet openings in one blow-out device is possible and even advantageous in certain applications.

Advantageously, side wall elements are provided next to the outlet opening to prevent the escape of blown-out CO _2. Due to the higher specific density of CO ₂ compared to air, the blow-out device according to the invention will typically cover a surface to be irradiated or an object to be irradiated from top to bottom with the gaseous CO _2. In this case, it is useful to create a lateral boundary using the side wall elements so that the gaseous CO ₂ falls downwards and cannot escape sideways, in order to lay a homogeneous and effective CO ₂ carpet over the surface to be irradiated. In addition, the side facing away from the surface to be irradiated between the two side wall elements can also be covered with a type of curtain to prevent the gaseous CO ₂ from escaping away from the surface to be irradiated. In order to still allow the surface to be irradiated through the _CO2 carpet, a radiation-permeable window is provided in this case, through which the ultraviolet or visible radiation is irradiated onto the surface to be irradiated by means of a suitable irradiation device.

Advantageously, the blow-out device according to the invention is provided with a fastening device for fastening the blow-out device to a holding device. The holding device can be, for example, a type of tripod or the like to which the blow-out device can be securely fastened. The fastening device comprises, for example, one or more hooks or the like.

The blow-out device according to the invention is advantageously designed as an attachment for an irradiation device for irradiating an object with radiation in the ultraviolet or visible range. This makes it easy for the user to attach the blow-out device according to the invention, for example to a hand-held device for irradiating objects, and to carry out the irradiation in an inert atmosphere in a simple and efficient manner.

The present invention is explained in more detail in the following description using a preferred embodiment with reference to the accompanying drawings, in which

Fig. 1 is a schematic perspective view of a blow-out device according to the invention on a surface to be irradiated,

Fig. 2 is a bottom view of a first embodiment of a blow-out device according to the invention, and

Fig. 3 is a bottom view of a second embodiment of a blow-out device according to the invention.

Fig. 1 shows an embodiment of a blow-out device 1 according to the invention for blowing gaseous CO ₂ onto an object to be irradiated with radiation in the ultraviolet or visible range. In the case shown, the object to be irradiated is a part of a surface 4, such as a side door of an automobile or the like that is to be repaired or repainted.

The blow-out device 1 comprises an inlet opening 2 through which gaseous carbon dioxide (CO ₂ ) is introduced, for example from a CO ₂ storage container 5 via a hose 6. Inside the blow-out device 1 there is a line in the form of a channel or the like through which the gaseous CO ₂ passes from the inlet opening 2 to several outlet openings 3 through which it is blown out over the surface to be irradiated. The blow-out openings 3 cannot be seen in Fig. 1, but can be seen in the representations of various designs of the blow-out device 1 or Γ in Figures 2 and 3.

1 and 2, the blow-out device 1 according to the invention is designed as a strip, with the outlet openings 3 arranged next to one another in a single row on one of the elongated sides of the blow-out device 1. In the further exemplary embodiment shown in FIG. 3, the blow-out device is designed as an elongated plate, with the outlet openings arranged next to one another in three rows on one of the elongated sides. The blow-out device of FIGS. 1 and 2 with the single row of outlet openings 3 prepares a rather thin two-dimensional film of gaseous CO ₂ over the surface 4 to be irradiated. The exemplary embodiment of the blow-out device Γ according to the invention shown in FIG. 3 with the three adjacent rows of blow-out openings 3 creates a somewhat wider curtain or carpet of gaseous CO ₂ over the surface to be irradiated. The thickness and homogeneity of the blown-out CO ₂ over the surface to be irradiated also depends on the type and shape of the blow-out openings 3. The blow-out openings 3 can be, for example, hole nozzles, slot nozzles, etc. Furthermore, the blow-out openings 3 can be in

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Depending on the intended application, the blow-out openings 3 can be very close to one another or relatively far apart. Furthermore, the overall arrangement of the blow-out openings 3 and the type of blow-out openings 3 can be arbitrary. Furthermore, the material of the blow-out device 1 according to the invention can be rigid or flexible depending on the desired area of application.

As shown in Fig. 1, the blowing device 1 according to the invention is advantageously used in such a way that the gaseous CO ₂ is blown out downwards, i.e. the outlet openings 3 are directed downwards. Since gaseous CO ₂ is heavier than air, it falls downwards of its own accord in a normal atmosphere and thus forms a film over or a curtain in front of the surface to be irradiated. The gaseous CO ₂ can also be blown into the blowing device 1 according to the invention under pressure, so that it is also blown out again under pressure from the outlet openings 3. This makes it possible to use the blowing device 1 according to the invention in other application geometries and, for example, to blow out the gaseous CO ₂ sideways. As indicated in Fig. 1 by the arrow 8, visible or ultraviolet radiation is radiated through the film or curtain 9 of gaseous CO ₂ onto the surface 4 to be irradiated. In order to prevent the gaseous CO ₂ from escaping sideways, as shown in Fig. 1, the blow-out device 1 according to the invention can have side wall elements 7 which laterally delimit the gaseous CO ₂ 9. The wall elements 7 can be made of flexible or rigid material. It is important that they are designed in such a way that when the blow-out device 1 is placed on the surface 4, they also lie close to the surface in order to prevent the gaseous CO ₂ from escaping.

In a further embodiment, the blow-out device 1 or Γ according to the invention can have a further cover between the two wall elements 7 in order to prevent the gaseous CO ₂ 9 from escaping to the outside. In order to enable irradiation of the surface 4, a radiation-permeable window is necessary in this cover, through which the surface 4 can be irradiated by means of a corresponding irradiation device.

It should be emphasized that the blow-out device 1 or Γ according to the invention is not limited to the embodiments shown in Figures 1 to 3. In addition to the forms shown, the blow-out device 1 according to the invention can take any other suitable form that allows gaseous CO ₂ to be blown out to cover a surface to be exposed to visible or ultraviolet radiation.

irradiated surface. Furthermore, two or more inlet openings 2 can be provided.

The blow-out device 1 or Γ according to the invention can further comprise a fastening device, such as one or more hooks, for fastening the blow-out device 1 or Γ to a holding device. The holding device can be, for example, a tripod or the like, to which the blow-out device is fastened and brought close to the surface or object to be irradiated. Alternatively, the blow-out device 1 or Γ according to the invention can be designed as an attachment for an irradiation device, such as a lamp or a hand-held device, for irradiating the object with radiation in the ultraviolet or visible range. Any type of irradiation device can be used, such as low-pressure, medium-pressure or high-pressure lamps, light-emitting diodes or any other type of radiation source for ultraviolet or visible light, e.g. daylight. The wavelength of the radiation can be selected between 200 and 700 mm.

Claims (12)

1. Device ( 1 ) for blowing gaseous CO ₂ ( 9 ) onto an object to be irradiated with radiation in the ultraviolet or visible range in order to create an inert atmosphere on the surface of the object to be irradiated, comprising an inlet opening ( 2 ) for introducing gaseous CO ₂ into the device ( 1 ), and
several outlet openings ( 3 ) connected to the inlet opening ( 2 ),
wherein the blow-out device ( 1 ) is designed in such a way and the outlet openings ( 3 ) are arranged next to one another on one side of the blow-out device,
that the emitted CO ₂ covers the surface of the object ( 4 ) to be irradiated. 2. Device ( 1 ) for blowing out gaseous CO ₂ according to claim 1, characterized in that it is designed as a strip, wherein the outlet openings ( 3 ) are arranged next to one another on one of the elongated sides. 3. Device ( 1 ) for blowing out gaseous CO ₂ according to claim 2, characterized in that a single row of outlet openings ( 3 ) is provided. 4. Device ( 1 ) for blowing out gaseous CO ₂ according to claim 1, characterized in that it is designed as an elongated plate, wherein the outlet openings ( 3 ) are arranged next to one another on one of the elongated sides. 5. Device ( 1 ) for blowing out gaseous CO ₂ according to claim 4, characterized in that several rows of outlet openings ( 3 ) are provided. 6. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 5, characterized in that it is made of flexible material. 7. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 5, characterized in that it is made of rigid material. 8. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 7, characterized in that the outlet openings ( 3 ) are designed as slot nozzles. 9. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 7, characterized in that the outlet openings ( 3 ) are designed as perforated nozzles. 10. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 9, characterized in that lateral wall elements ( 10 ) are provided next to the outlet openings ( 3 ) to prevent escape of blown-out CO ₂ . 11. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 9, characterized in that a fastening device is provided for fastening the blowing-out device to a holding device. 12. Device ( 1 ) for blowing out gaseous CO ₂ according to one of claims 1 to 9, characterized in that it is designed as an attachment for an irradiation device for irradiating an object with radiation in the ultraviolet or visible range.