DE8209544U1 - DEVICE FOR TREATING DENTAL MATERIALS - Google Patents

Description

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Device for treating dental materials

The invention relates to a device for treating dental materials as described in the preamble of the claim 1 is given in more detail.

In the field of dental technology, e.g. for the production of dental prostheses, such as crowns, individual teeth, bridges, Parts of the teeth or whole teeth, dental materials used, which by means of a photoinitiator system with light are polymerizable and curable.

Due to the inherent color of the polymerization initiators they contain, these materials have an undesirable effect It has a yellow tinge, but this is reflected in an irreversible reaction by means of subsequent irradiation permanently to one of the natural tooth color Bleach the color. A radiation in a range of approx. 400 μm is typically used for this bleaching process up to approx. 500 nm (with a maximum of approx. 46O nm) required, wherein the irradiation process is to be carried out over a longer period of time, for example 30 minutes. This irradiation at the same time results in the desired polymerisation of the material.

For the curing process, exposure devices have been developed that use halogen-quartz lamps as light sources insert. Such exposure devices are described in DE-OS 2 901 534 and EP-A 0037 461, for example.

With these exposure devices, a not inconsiderable amount of heat is generated, which is within what is necessary for curing Exposure time the dental prosthesis heats up. One Such a temperature increase has a disadvantageous effect because the synthetic resins used have a different coefficient of thermal expansion than e.g. the metal crowns have,

that are to be veneered with the synthetic resin. At the end of the curing process, therefore, occur easily when cooling Thermal stresses, which can also cause cracks and gaps at the synthetic resin-metal interface the synthetic resin itself is subject to cracking.

In the known devices, the reflector has a special coating on the light source as well the use of filters and cooling fans has reduced the heat radiation, but there is still another Reduction of the thermal radiation thrown on the parts to be treated is desirable.

In the case of the known devices it has also proven to be disadvantageous that they consist of a point source with an associated Parabolic mirror existing light source illuminates the objects essentially with a parallel bundle of rays. Accordingly, shading of individual areas can occur, especially with curved dental prostheses. so that in the shaded areas the synthetic resin compound does not or only incompletely cures and fades. This effect also has a disadvantageous effect on the adhesive strength that can be achieved between a synthetic resin coating and a metal surface such as a metal bridge structure. Be on the surface of the metal parts sintered small metal beads so that the metal surface becomes rough and between the beads and the metal surface small undercut areas are created into which the still liquid plastic penetrates during application. After the plastic has hardened, these metal beads act as anchors for the entire plastic coating. These Anchoring effect is lost, however, if no light reaches the undercut areas due to the shadowing and the plastic does not or only insufficiently cures there.

Furthermore, in the known devices it must be taken into account as a source of error that an operator

accidentally inserting the workpiece to be treated the wrong way round, i.e. the workpiece to be cured and bleached Plastic lies on the side facing away from the lighting device.

For these reasons, there is a further requirement for irradiation devices of the type specified that a The objects to be treated are illuminated as evenly as possible on all sides.

Accordingly, the object of the present invention is to provide a device for treatment as specified in the introduction to modify dental materials in such a way that the radiation used for curing and bleaching affects the material not heated and this radiation hits the workpiece to be treated as evenly as possible from all sides meets.

This task is done with a device for handling Dental materials according to the preamble of claim 1 according to the characterizing part of this claim specified way resolved.

Further, advantageous refinements of the invention emerge from the subclaims.

According to the invention it is provided as a light source for the exposure to the one that triggers the polymerization Use light fluorescent tubes. Such fluorescent tubes show on the one hand a low heat development, on the one hand Others they are not punctiform, but emit flat - so that the light they emit has no preferred direction has, but is diffusely distributed. This results in a uniform illumination of the would take a tooth replacement part provided area. the The recording is surrounded by the fluorescent tube (s) used for lighting. Will only be a single fluorescent tube is used, it is spatially shaped, e.g. bent in a helical shape, so that light from all sides can be directed towards the im Inside the coil located recording is emitted. Preferably there are two rows of such fluorescent tubes

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provided, for example on the floor and ceiling of the | Device between which the receptacle for the dental prosthesis is arranged.

In addition, the walls of the housing can be provided with mirrors 5 or reflectors so that the light is incident on the detailed Kerkstoff to be treated from all sides. The total intensity emitted by the fluorescent tubes determines the required exposure time. This is usually set in advance. In order to ensure that during an irradiation process through | an unnoticed failure of individual fluorescent tubes | is radiated light intensity is not reduced and thus the f required for curing total intensity does not reach I, the fluorescent tubes are connected in series. Does the 'i failure of a single fluorescent tube then the failure of all fluorescent result, so that the faulty operation of the device can be detected.

The usual one-component materials that can be cured with visible light have a sensitizer that is excited by light with a wavelength of around 46Ο nm. Accordingly, fluorescent tubes are forthcoming ■ Trains t whose emission maximum between 400 and 500 nm, and in) ■■ located nm special about 460th Such an emission can be achieved with fluorescent tubes which preferably have a coating of a barium magnesium aluminate doped with europium. ;

As described in the above-mentioned EP ~ A 0037 461 ' is, a one-component material forms a smear layer on its surface during curing by means of light, if oxygen is present in the surrounding atmosphere, because oxygen molecules inhibit polymerisation! beers. In order to remedy this problem, the dental prosthesis was previously placed in a metal container with a mirror on the inside placed, which is covered with a pane of glass and in front of the

Irradiation was evacuated. The mirroring is at

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However, this device is somewhat blind over time because of the vapors emanating from the one-component material react under the action of light on the surface of the mirror layer and form a coating. This topping is difficult to remove, and removing it easily scratches or blinds the mirror. In order to avoid these difficulties, according to a further, particularly preferred embodiment of the invention provided, a gas-tight sealable container made of a permeable for the light required in each case Material, in particular a container made of glass or quartz to be used. This container is out of the housing of the device removable so that it can be easily wiped and cleaned.

In another embodiment, this embodiment of the invention described above is further developed in such a way that that a vacuum meter is connected to the vacuum connection, which can be switched on and off via a switch controls the fluorescent tubes. The fluorescent tubes are only switched on when a certain pressure is reached in the Inside the container and thus a critical oxygen content is below. Should be due to external influences The sealing of the container will decrease during the irradiation and air will penetrate into the container, so the The irradiation is switched off and the user is notified of the error via a signal.

In a further embodiment, the receptacle is provided with two gas connections so that the oxygen can be displaced by a gas flow, e.g. nitrogen or argon. A control of the gas flow can be done with a flow meter.

In the following the invention will now be based on the in the Figures illustrated embodiments described and explained in more detail.

Figure 1 shows schematically a first embodiment of the device according to the invention,

Figures 2 and 3 show further embodiments.

In the embodiment of Figure 1 are located in a housing 1 on the inside of the bottom 8 and the ceiling 9 each a row 21 or 22 of fluorescent tubes. These fluorescent tubes have a coating of a Barium magnesium aluminate, which is doped with europium, so that the fluorescent tubes achieve their emission maximum in one Show spectral range υτα 460 nm. With light of this wavelength the sensitizer added to the one-component material is activated, the polymerization and the bleaching causes.

For better utilization of the fluorescent tubes 2 emitted light are arranged on the inside of the housing reflectors 3, which are in the selected spectral range have a high reflection coefficient. Instead of such reflectors, the corresponding Inner sides of the floor 8, the ceiling 9 and the side walls 5 with a reflective coating, e.g. made of aluminum or be made of chrome. Instead of such reflectors attached to the walls, an inside mirrored, cylinder open at the end can be provided, in the interior of which the receptacle is arranged.

Between the two rows 21 and 22 of fluorescent tubes 2, the receptacle 4 designed as a container is for the tooth replacement part 13 is arranged. This container 4 consists made of a material that is transparent to the desired spectral range. For a spectral range of 460 nm comes glass and quartz are considered as materials. In the example shown, the container 4 has a vacuum connection 6.

The tooth replacement part 13 to be treated is placed in the container 4, which is then sealed with a flexible seal The closure cover 14 is placed and the container 4 is evacuated. A vacuum riveter 11 is connected to the vacuum connection 6 connected, which controls a switch 15, through the switch 15 is the supply voltage to the fluorescent tubes 2 placed. As soon as a certain minimum vacuum in the container

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4 is reached, the vacuum meter 11 actuates the switch 15 and closes it, so that the supply voltage is applied to the fluorescent tubes and the irradiation begins.
In the embodiment shown, the container 4 receiving the dental prosthetic item 13 can be removed from the housing 1 by means of a drawer 12, for example in order to clean it.

FIG. 2 shows a further embodiment in which the housing 1 is opened with a flap 19. In this Flap 19 as well as in the base 8 are two fluorescent tubes 2. These fluorescent tubes are different from the embodiment shown in Figure 1 curved U-shape so that they are relatively short are, but still emit a lot of light.

In this second embodiment, the closure cover 14 is preferably arranged in the flap 19, in particular suspended therein by one or more springs. When closing the lid 19, the lid 14 is spring-loaded on the seal 16 of the receptacle 4 pressed and the receptacle 4 zwanqsläufiq closed, Ei _n electromagnet 17 ensures complete closure of the flap and thus of the receptacle 4 and then sets, for example via a switch, Vacuum pump, not shown, in operation. After the prescribed vacuum has been reached, the fluorescent tubes are switched on for a preset time by means of the switch 15 controlled by the vacuum meter 11. In the event of insufficient sealing or failure to achieve the prescribed vacuum within a certain time, an error display appears on the display panel 18 of the device, and an acoustic signal may also be emitted.

Figure 3 shows an alternative embodiment to the device according to Figure 1. Instead of two rows of fluorescent tubes, only a single fluorescent tube is provided helically surrounds the receptacle 4. With the help of the drawer 12, the receptacle 4 can be moved into the interior of the helix.

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drive so that evenly light on all sides

falls on the workpiece 13 assigned in the receptacle

Claims (15)

SHIP ν. FUNeR * .SZCRenC. SCHÜßßü-HOPF EBBINGHAUS FINCK MARIAHILFPLATZ 2 & 3, MÖNCHEN SO POST ADDRESS: POST BOX 95OI60. O-8000 MÖNCHEN 35 ESPE Gabrik Pharmaceutical April 2, 1982 Preparate GmbH DEG-13 646 PROTECTIVE APPLICATION 1. Device for treating dental materials with Radiation of a selected spectral range, with a housing (1) in which at least one light source (2) and a reflector (3) and a receptacle (4) are arranged for the parts to be treated, characterized in that the receptacle arranged in the housing (1) (4) is surrounded by one or more fluorescent tubes (2) emitting the selected spectral range. 2. Apparatus according to claim 1, characterized net that the receptacle (4) from a spatially shaped Fluorescent tube is surrounded. 3. Apparatus according to claim 1, characterized in that along by two opposite one another Walls (8,9) of the housing each have a row (21, 22) of several fluorescent tubes (2) is arranged. 4. Device according to one of claims 1 to 3, characterized in that: at least one of the walls (8,9) is provided with a mirror (3) reflecting the selected spectral range. 5. Device according to one of claims 1 to 4, characterized in that the fluorescent tubes (2) are connected in series. 6. Device according to one of claims 1 to 5, characterized in that the fluorescent tubes (2) in a spectral range between 400 and 500 nm, in particular at about 46C> nm have the emission maximum. 7. Apparatus according to claim 6, characterized in that the fluorescent tubes (2) with one Europium-doped coating made of a barium-magnesium-aluminate exhibit. 8. Apparatus according to any one of claims 1 to 7, characterized in that the receptacle (4) is a Gas-tight sealable container is made of a material that is permeable to the selected spectral range consists, 9. Apparatus according to claim 8, characterized in that that the container (4) is made of glass. • ti »· I · I t • · • • • · t •
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• • «· • · 10. Apparatus according to claim 8 or 9, characterized marked || records that the container (4) with a vacuum I connection (6) is provided. % 11. Device according to claim 8 or 9, characterized by § shows that the container (4) with two gas I Conclusions is provided. ί 12. Apparatus according to claim 10, characterized in that a vacuum gauge is provided, which controls the switching on and off of the fluorescent tube (s) (2). 13. Apparatus according to any one of claims 1 to 12, characterized in that the receptacle (4) from the Housing (1) is removable. 14. Device according to one of claims I to 13, characterized characterized in that the housing (1) on the floor (8) and in the ceiling (9) air passage openings (1O). 15. Device according to one of claims 1 to 14, characterized characterized in that the recording (4) of reflective surfaces is surrounded.