EP1147535A1

EP1147535A1 - Discharge lamp comprising an electrode support

Info

Publication number: EP1147535A1
Application number: EP00982957A
Authority: EP
Inventors: Rainer Kling; Reinhold Wittkötter
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 1999-11-05
Filing date: 2000-10-06
Publication date: 2001-10-24
Anticipated expiration: 2020-10-06
Also published as: TW493202B; KR100465607B1; CA2358987C; KR20010101392A; WO2001035436A1; CN1199222C; CN1336000A; DE19953531A1; CA2358987A1; US6634917B1; JP2003514347A; JP4780887B2; DE50008959D1; ATE285119T1; EP1147535B1

Abstract

The invention relates to a method for producing a discharge lamp, which is preferably designed for dielectric barrier discharges. The innovation is that a frame is used in order to set, and secure in its position, an electrode running at a distance from the vessel faces in the discharge vessel of the discharge lamp. This frame is simultaneously used as an exhaust tube.

Description

Discharge lamp with electrode holder

Technical field

The invention relates to a method for producing a discharge lamp with a discharge vessel filled with a discharge medium and with an electrode running in the discharge vessel at a distance from the vessel walls. or is filled with the discharge medium and which is then sealed.

State of the art

Usually, a tube or the like, which projects through a wall of the discharge vessel, is also melted as a pump stem in the manufacture of the discharge vessel. After the discharge vessel is then tightly sealed except for the pump stem, an evacuation pump is connected to the outside of the pump stem and the discharge vessel is evacuated to the desired negative pressure. The discharge vessel is then filled with the discharge medium, usually a gas or gas mixture, by the pump handle. After the gas conditions in the discharge vessel have been set appropriately, the tube forming the pump stem is melted outside the discharge vessel, usually relatively close to the discharge vessel, in order to remove the entire discharge. the vessel must be closed completely vacuum tight. The pump stem is usually attached to the discharge vessel in such a way that it does not protrude into the interior of the discharge vessel.

Discharge lamps with a dielectric barrier discharge are a special type of discharge lamp. Here, the electrode and / or a counter electrode or a plurality of counter electrodes are separated from the discharge in the interior of the discharge vessel by at least one dielectric. The invention is not exclusively directed, but preferably, to such discharge lamps for dielectrically impeded discharges.

In such discharge lamps, a voltage is applied between the electrode and a counter electrode, which is also located in the discharge vessel or on the discharge vessel, as a result of which a discharge occurs between the electrode and the counter electrode in the discharge medium. During this discharge incoherent radiation is released. Depending on the type of lamp structure and in particular the discharge medium, ultraviolet or infrared radiation or visible light is emitted. Such a lamp is described for example in DE 196 36 965 AI.

A distinction is made between so-called bipolar and so-called unipolar discharge lamps.

In the case of a unipolar discharge lamp, one of the two electrodes permanently forms the anode and the other electrode forms the cathode. It is sufficient to separate the anode from the discharge by the dielectric. The vessel wall can also serve as the dielectric. In this case, only the cathode is located in the discharge vessel, whereas the anode or the anodes are applied to the outside of the vessel wall. This can be, for. B. are strips of a gold or platinum paste, which are printed directly on the vessel wall. In the case of the bipolar discharge lamp, the two electrodes are not distinguished from one another and both are shielded by a dielectric. By appropriate voltage changes, one electrode and sometimes the other electrode form the anode. The discharge lamps are preferably supplied with an in principle unlimited sequence of extremely short voltage pulses with a high repetition frequency. Please refer to W094 / 23442.

It is clear that successful and efficient discharge depends on the distance between the electrode and the counter electrodes. This applies in particular to discharge lamps with a dielectric barrier discharge, in which the efficiency depends strongly on the precise geometry of the discharge regions in the discharge vessel. Because of this dependence on the electrode geometry, even small changes in the position of an electrode would lead to a large reduction in the efficiency of the discharge lamp.

Presentation of the invention

It is therefore an object of the present invention to provide an inexpensive, simple method for producing a discharge lamp, in which a precise fit of the electrode is ensured during manufacture and in later use.

This object is achieved in that a holder made of non-conductive material is arranged in the discharge vessel, which fixes the electrode at a predetermined position in the discharge vessel and this holder or part of this holder as a pump stem or part of a pump stem and is used.

According to the invention, the pump stem that is required anyway in the production of a discharge lamp is used at the same time to hold tion or part of a bracket to serve. This enables the electrode to be securely positioned during manufacture in later use, additional process steps being minimized or additional process steps being even dispensed with entirely. This means that the production according to the invention is not at all or only slightly more expensive.

The holder or the part of the holder serving as a pump stem can in principle have any shape that is suitable for fixing or supporting the electrode accordingly. For use as a pump stem, it is only necessary for the corresponding part of the holder to have an opening which extends from the outside inwards into the discharge vessel and a possibility for tight connection of the evacuation and filling system.

In a preferred embodiment of the method according to the invention, the part of the holder serving as a pump stem is designed in the form of a tube, which projects at one end through a wall of the discharge vessel into the discharge vessel. Basically, all that is required is an extension of the conventional pump stems used so far.

This method is particularly advantageous when the electrode has an elongated shape that extends essentially in a main direction of extension. The holder can be designed in such a way that it has an elongated support element which extends in the main direction of extension of the electrode and which supports the electrode on at least one partial area, the support element and the electrode being aligned coaxially or parallel to one another.

In this case, the above-mentioned inwardly elongated pump stem can be used as the support element or support tube. It can, therefore, by appropriate arrangement of the tube projecting into the discharge vessel to the electrode ensures simple, reliable support of the electrode.

Of course, it can also be a differently shaped support element, for example an elongated, plate-shaped support element or the like, which is provided with a corresponding tube part or has a corresponding bore. Likewise, the electrode can have any shape. For example, it can be longitudinal strips, waveforms, for example in the form of a sinusoid, zigzag electrodes, a coil or the like.

In a particularly preferred embodiment, the electrode extends helically around the support element on at least a partial area of the longitudinal extent. The advantages of this spiral electrode and the resulting structure of the discharges are shown in the previously cited DE 196 36 965 AI.

The electrode can be applied to the holder or an element of the holder in the form of a correspondingly structured conductive coating, for example made of gold or platinum paste. So z. For example, a helical inner electrode can be applied in this way to a support rod or support tube running in the direction of extension of the electrode. Strip-shaped, wave-shaped or zigzag-shaped electrodes can, for example, be applied to an elongated, plate-shaped support element.

A particularly preferred embodiment is a cylindrical discharge vessel with an inner electrode extending along the cylinder axis and a support element. It is consequently a discharge lamp with a central or concentric middle electrode. It is advisable to apply a plurality of strip-shaped counter electrodes running parallel to the cylinder axis on the vessel walls. In this way, the entire discharge space can be used effectively, the geometric arrangement required for this being relatively easy to generate. The problem that arises in this case of an exact central or concentric position of the central electrode during manufacture and continuous operation is solved by the invention.

The support element, for example in the form of the support tube serving as a pump stem, advantageously protrudes from an end face opposite a lamp base into the discharge vessel and is fastened to the corresponding end wall. In particular in the case of longer discharge vessels, a base on both sides can also be advantageous. Then the side of the pump stem is overlapped by a base.

Of course, the support element or the tube can also be so long that the electrode is supported over the entire length.

One or more openings which penetrate the tube wall and are located within the discharge vessel are preferably introduced into the support tube along the longitudinal extent. These openings enable better and more effective pumping or filling of the discharge vessel.

In a preferred embodiment, the discharge vessel is closed on one side by squeezing. Here, a metal foil is embedded, which serves as an electrical feedthrough for the inner electrode. This is attached to the metal foil, for example soldered on, and is partly pinched with one end, so that the electrode is held on one side by the pinch. In order to prevent a displacement of the electrode in the longitudinal direction of the support element, this advantageously has a holding projection which extends transversely to the longitudinal direction of the supporting element or a holding recess. The retaining projection can be corresponding knobs, lugs, spikes, etc., the retaining recess can be a groove or the like. Such knobs or lugs, for example, can be used to very well prevent a wire helix that runs around a support tube or a support rod against longitudinal displacement be secured.

An alternative embodiment of the holder provides that a spacer is located between the electrode and a vessel wall transverse to the main direction of extent of the electrode. Such a spacer can be a hook-like element, a tube or a pin, which is attached to a vessel wall and holds the electrode in position. Preferably, several such spacers are used along the main longitudinal extent of the electrode. In order to enable the function as a pump stem, a corresponding hole must of course be made in at least one of the spacers.

Of course, it is also possible to use, for example, a tubular support element and additionally spacers running transversely thereto. This is particularly useful when manufacturing very long lamps.

In a preferred embodiment of this additional spacer for fixing the support element, there is a holding disc, which is arranged transversely to the main direction of extension of the electrode and extends between the vessel walls and through which the electrode with the plug element extends at a predetermined position. Through such a holding disc ensures secure positioning in any direction.

Description of the drawings

The invention is explained below with reference to the accompanying drawings using exemplary embodiments. The features shown can be essential to the invention not only in the combinations mentioned but also individually or in other combinations. They represent:

FIG. 1 shows a schematic side view of a discharge lamp with a cylindrical discharge vessel and an axial central electrode, which is held by a support tube,

FIG. 2 shows a cross section through a discharge vessel according to FIG. 1, with a support tube and an additional holder in the form of a spacer,

3 shows a cross section through a discharge vessel according to Figure 1, with a support tube and an alternative additional holder in

Shape of a washer,

4 shows a cross section through a discharge vessel according to FIG. 1 with an alternative holder comprising a plurality of holding rods running transversely between the walls of the discharge vessel, one of which is used as a pump stamp.

5 shows a cross section through a discharge vessel according to FIG. 1 with an axially extending support tube and a plurality of radially extending cross supports. Figure 1 shows a first embodiment of a discharge lamp according to the invention. This discharge lamp 1 has a discharge vessel 2 made of quartz glass, which is held on one side in a base 5.

The inside of the discharge vessel 2 is filled with a discharge medium. The present exemplary embodiment is an excimer discharge lamp which is filled with xenon. With such an excimer discharge lamp, VUV radiation is generated with high efficiency, which is used industrially, for example in the cleaning of wafers, for ozone production or for water purification.

The lamp has a central helical electrode 6 within the cylindrical discharge device. This is the cathode, which is at a negative high voltage. On the outside of the discharge vessel 2 there are a plurality of strip-shaped electrodes 7 running parallel to the cylinder axis. These are the anodes. They are separated from the discharge space by the wall 3 of the discharge vessel 2. The lamp is therefore designed for dielectrically impeded discharges.

As the holder 10, the lamp 1 has an axial support tube 9, which projects from the end wall 4 opposite the lamp base 5 into the interior of the discharge vessel 2. The helical electrode 6 is partially guided around this support tube 9. In order to prevent displacement of the helical electrode 6 in the axial direction, a holding projection 12 in the form of a knob is formed on the support tube 9.

The holder consists of a non-conductive material, such as glass, quartz glass or ceramic.

First, the discharge vessel 2 is closed on the end wall 4 opposite the base region, the support tube 9 being in a Central opening 8 is sealed and fixed in the end wall 4. To form the end wall 4 with the enclosed support tube 9, the open cylindrical vessel is heated and the support tube 9 is held by suitable aids, while the cylinder wall falls inwards under the action of heat. This closure can also be done by crushing.

The filament 6 is then also squeezed within the base region when the cylindrical discharge vessel 2 is sealed in a vacuum-tight manner (not visible). In the area of the opposite end wall 4, it is held by the support tube 9.

To apply the helix 6 to the support tube 9 or to insert the support tube 9 into the helix 6, the helix 6 is screwed onto the support tube 9, the holding projection 12 moving between the helical gears.

The support tube 9 is simultaneously used as a pump stem by pumping the discharge vessel 2 through the support tube 9 and filling it with gas via the tube 9. In the case of longer discharge lamps, it makes sense that at least one, preferably a plurality of openings 11 are arranged along the support tube 9 in the tube side walls in order to enable the discharge vessel to be pumped out quickly and effectively.

Of course, the support tube 9 can not only be held in the end wall 4, but can also extend longitudinally through the entire discharge vessel 2 into the base region 5 and, if appropriate, also be fastened in the end wall in the base region 5, for example be pressed in during production. As in the exemplary embodiment shown, the helix 6 can be a wire helix. Alternatively, however, the helix can also be applied to the support tube 9 by means of a conductive one Paste, for example gold or platinum paste or the like, can be applied. In the case of a continuous support tube 9, which is also squeezed in the base area, it is advantageous if the electrode 6 is formed by a wire or a metal foil in the squeeze area and then the electrode is made of the structured, conductive coating within the discharge vessel 2 above the squeeze point consists of the support tube 9, the lower area of the coil consisting of wire or the metal foil and the upper area of the coil of course being correspondingly contacted with one another.

Because of the holder according to the invention, it is possible to manufacture lamps according to the exemplary embodiment according to FIG. 1 in almost any length. Currently, a maximum length of 20 cm can be produced without such a holder, without a secure fit of the electrode 6 being endangered. Experimentally, lamps with a length of more than 85 cm are currently produced in the manner according to the invention.

FIGS. 2-5 each show alternative exemplary embodiments for a holder.

In the embodiment shown, the support tube 9 is relatively long. In another embodiment, not shown, the support tube is only approx. 2 cm long and supports an approx. 12 cm long helix only in the end area.

The exemplary embodiment shown in FIG. 2 is a hook-shaped spacer 14, which is attached at one end to the vessel wall 3, for example is melted, and additionally fixes the support tube 9 transversely to the direction of extension. In order to hold the support tube 9 with the helix 6 securely over a longer distance in this way, a plurality of such spacing devices can be arranged along the longitudinal direction. Holder 14 may be arranged, which also advantageously extend radially outwards in different directions. A favorable distance between such spacer hooks 14 is approximately 15 cm.

FIG. 3 shows as a spacer a continuous holding disc 15 through which the support tube 9 with the helix 6 runs in the middle. This holding disc 15 supports the support tube 9 with the helix 6 in addition to all sides with respect to the vessel walls 3.

FIG. 4 shows a holder in the form of two holding rods 16, 17 running one behind the other in the longitudinal direction of the filament 6, each of which extends transversely through the discharge vessel 3 from one wall side to the other. These holding rods are fastened to the wall 3 on at least one side, for example melted down. At least one of these holding rods 16, 17 is designed as a hollow pump stem 17, which projects at one point with a section 19 from the discharge vessel 2 and has at least one, preferably a plurality of, openings 20 in the discharge vessel 2. In this version, too, it makes sense if several such rods 16, 17 are used one behind the other in the longitudinal extent of the helix 6.

In the exemplary embodiment according to FIG. 5, an axially extending support tube 9 is again used. This axially extending support tube 9 is supported by a plurality of radially extending cross supports 18, which extend between the support tube 9 and the side wall 3 of the discharge vessel 2.

In a further exemplary embodiment, not shown, the axially extending support tube does not run inside the coil 6 but outside the coil 6. Thus, the inner helical electrode 6 is also separated from the discharge space by a dielectric, namely the wall of the support tube. Such a lamp is suitable for bipolar operation on. Another alternative is to completely surround the electrode with dielectric material, for example to melt the electrode into dielectric material. The electrode can again have any shape. In this case, the electrode is virtually integrated in the holder.

Claims

claims

1. A method for producing a discharge lamp (1) with a discharge vessel (2) filled with a discharge medium and with an electrode (6) which is spaced apart from the vessel walls (3) in the discharge vessel (2), the discharge vessel (2) being manufactured a pump stem is attached to the discharge vessel (2), through which the discharge vessel (2) is evacuated and / or filled with the discharge medium, and which is subsequently sealed, characterized in that a holder (10, 14.) in the discharge vessel (2) - 18) made of non-conductive material, which fixes the electrode (6) at a predetermined position in the discharge vessel (2), and this holder (10, 14 - 18) or part of this holder (10, 14 - 18) as a pump stem or part of a pump stem is formed and used.

2. The method according to claim 1, characterized in that the part serving as a pump stem of the holder (10) in the form of a tube (9) is formed, which has one end through a wall (4) of the discharge vessel (2) in the discharge vessel ( 2) protrudes.

3. The method according to claim 1 or 2, characterized in that an opening (11) penetrating the tube wall is introduced into the walls of the tube (9) along its longitudinal extent in the discharge vessel (2).

4. The method according to claim 1, 2 or 3, characterized in that the electrode (6) has an elongated shape extending essentially in a main direction of extension.

5. The method according to any one of the preceding claims, characterized in that the holder (10) is an elongated in the main extending direction of the electrode (6) extending support element (10) which supports the electrode (6) in at least one partial area.

6. The method according to claim 5, characterized in that the support element (10) is designed as a support tube (9) which is used as a pump stem.

7. The method according to claim 5 or 6, characterized in that the electrode (6) and / or the support element (10) are arranged so that the electrode (6) at least on a portion of its longitudinal extension helically around the support element (10th ) runs around.

8. The method according to any one of the preceding claims, characterized in that the discharge vessel (2) is cylindrical and the electrode (6) and / or the support element (10) are aligned along the cylinder axis.

9. The method according to any one of the preceding claims, characterized in that the support element (10) from a lamp base (5) opposite end face into the discharge vessel (2) and is fastened in or on the end wall (4).

10. The method according to any one of the preceding claims, characterized in that the supporting element (10) is provided with a holding projection (12) extending transversely to the longitudinal direction of the supporting element or a holding recess.

11. The method according to any one of the preceding claims, characterized in that as a holder or part of the holder between the electrode (6) and / or a support element (9, 10) and a vessel wall tion (3) a spacer (14, 15) extending transversely to the main direction of extension is arranged.

12. The method according to claim 11, characterized in that as a spacer (15) arranged transversely to the main direction of extension of the electrode (6), extending between the vessel walls (3)

Holding disc (15) is used, through which the electrode (6) and the support element (9, 10) runs at a predetermined position.

13. The method according to any one of the preceding claims, characterized in that the electrode is applied to the holder in the form of a structured, conductive coating.

14. The method according to any one of the preceding claims, characterized in that the electrode is at least partially arranged within at least part of the holder.

15. The method according to claim 12, characterized in that the electrode is arranged at least partially within a support tube.

16. The method according to claim 13, characterized in that the electrode is arranged to extend helically within at least a portion of its lamp extension within the support tube.

17. The method according to any one of the preceding claims, characterized in that the holder is made of glass, quartz glass or ceramic.

18. The method according to any one of the preceding claims, characterized in that the discharge lamp (1) is designed for dielectrically disabled discharges.