EP1532648A2

EP1532648A2 - Production method for a gas discharge device

Info

Publication number: EP1532648A2
Application number: EP03740011A
Authority: EP
Inventors: Lothar Hitzschke; Frank Vollkommer
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 2002-06-07
Filing date: 2003-05-22
Publication date: 2005-05-25
Also published as: JP2005529459A; KR100810167B1; WO2003105178A2; CN1675736A; US20060025033A1; DE10225612A1; US7261610B2; MY137419A; WO2003105178A3; TW200401328A; CN1675736B; KR20050004291A; CA2488707A1; TWI301993B

Abstract

The invention relates to a novel production method for a gas discharge device, in particular discharge lamps or plasma display devices, whereby the discharge chamber is flushed with the required filling gas within a chamber at elevated pressure.

Description

Manufacturing process for gas discharge device

Technical field

The present invention relates to a manufacturing method for a gas discharge device, in particular a discharge lamp or a plasma display unit (PDP). Gas discharge devices regularly have a discharge vessel for receiving a gaseous discharge medium. A manufacturing process for gas discharge devices therefore necessarily includes the step of filling the discharge vessel with this gas filling and closing the discharge vessel.

In this description it is assumed that the gas discharge device, for example the discharge lamp after the

Nerschenken is at least largely completed, which is why

Manufacturing process is considered to be at least essentially completed with the closing of the discharge vessel. Of course, this does not preclude the substantially finished discharge lamp from being provided with electrodes, coated with reflective layers, connected to assembly devices, or processed in some other way after the discharge vessel has been closed. The manufacturing process within the meaning of the claims should, however, be considered to have been realized with the closing of the discharge vessel. State of the art

As a rule, discharge vessels of discharge lamps or plasma display units are equipped with pump stems or other connections via which the discharge vessels can be pumped out and filled with the gas filling. These connections are usually sealed by fusing, after which protruding parts can be broken off or cut off.

The invention is particularly directed to gas discharge devices designed for dielectrically disabled discharges, and in particular to so-called flat radiators and to plasma display units. Both in the case of flat spotlights and in the case of plasma display units, the discharge vessel is flat and of a relatively large size in comparison with the thickness and has two essentially plane-parallel plates. In this respect, there are similarities in terms of manufacturing technology. Of course, the plates do not have to be flat in the strict sense of the word, but can also be structured. Flat spotlights are of particular interest for the backlighting of displays and monitors in liquid crystal technology (LCD). In contrast to LCD, plasma display units do not require backlighting because they are self-illuminating due to the generation of light by the gas discharge. Plasma display units have recently been used, among other things, in TV sets.

Manufacturing processes are also known from the technical field of flat radiators or plasma display units, in which the discharge vessel is pumped out and filled in a so-called vacuum furnace. The vacuum oven is an evacuable and heatable chamber. Pumping out - like with conventional ones Pump rod solutions also - unwanted gases and adsorbates removed in order to keep the gas filling of the finished discharge lamp as pure as possible.

Pump rod solutions and comparable procedures are associated with restrictions for the discharge vessel geometry. Processes in a vacuum furnace are costly because of the technical complexity for the vacuum furnace and, moreover, comparatively time-consuming.

Presentation of the invention

The invention is based on the problem of specifying a production method for a gas discharge device, in particular a discharge lamp and a plasma display unit, which is improved with respect to the step of filling and closing the discharge vessel.

The invention relates to a method for producing a gas discharge device, in particular a discharge lamp or a plasma display unit, in which a discharge vessel of the gas discharge device is filled with a gas filling and then sealed, characterized in that the discharge vessel is filled and sealed in a chamber which is flushed with the gas filling at excess pressure.

The invention is based on the knowledge that filling and closing steps carried out in appropriately designed chambers are preferable to solutions with pump stems or similar devices. In particular, they offer the possibility of simultaneously processing large numbers of discharge vessels. Otherwise, there are no boundary conditions for pumping and filling through a pump stem connection and for closing the Pump stem connection optimized discharge vessel structure. Instead, the design of the discharge vessel is largely free and all that is required is to handle the discharge vessel parts that are to be connected to one another for sealing, or to take the steps otherwise required for sealing.

On the other hand, the inventors assume that a vacuum furnace means an effort that is unnecessary in terms of both the equipment costs and the processing times.

Instead, according to the invention, a chamber is to be used in which the gas filling for the discharge vessel is present under excess pressure. The chamber therefore does not have to be evacuable. Instead, unwanted residual gases are removed by purging the chamber. By eliminating the high vacuum-tight seal of the furnace and the evacuation steps, the manufacturing process is significantly cheaper and shortened.

In addition, the aim is to reduce the thermal inertia of the chamber and in particular the chamber walls and not to make them too thick. This can be achieved in that the overpressure according to the invention is not too great. The invention also includes embodiments in which this excess pressure is up to, for example, 1 bar. However, it is preferred not to exceed 300 mbar or, more advantageously, not to exceed 100 mbar.

The chamber walls in the large areas are therefore preferably at most 8 mm, better at most 6 mm and, in the optimal case, at most 4 mm thick. Of course, profile structures can occur. A favorable lower limit for the overpressure is 10 mbar and a preferred value for the lower limit is 50 mbar.

Furthermore, as already mentioned, the invention provides for the chamber to be flushed with the gas filling. This flushing can take place in that, due to a simple construction of the chamber, any existing leaks or deliberately provided openings as a result of the excess pressure allow the corresponding gas atmosphere to flow out and this is introduced into the chamber in order to maintain the excess pressure. An alternative is to use an actual gas outlet line. However, even when using a gas outlet line, the fact that the excess pressure leads to an outflow from possible leaks or leaks is to be regarded as an essential advantage of the invention. In addition to the purging effect of a gas atmosphere, which is more favorable in any case at excess pressure, for removing contaminants in the chamber, for example gases escaping from discharge vessel parts, the penetration of contaminants through openings in the chamber is thus counteracted. This eliminates the need for complex seals, which increase costs and can lead to additional circumstances, for example when opening or closing the chamber.

It is preferably provided that the chamber can be heated, that is, in the general sense, it is an oven. The heating can expel adsorbates and impurities contained in certain components of the discharge vessel and also initiate other process steps, as will be explained in more detail below. In particular, the heating may be necessary to close the discharge vessel. The chamber is preferably completely heatable. This also eliminates the requirements for temperature-resistant seals, which conventionally lead to technical problems or a corresponding expenditure of time and money. For example, the flat contact between simple sealing surfaces is sufficient for sufficient tightness, since remaining leaks are unproblematic due to the internal overpressure of the chamber. In the context of the invention, however, the chamber can also be open in the actual sense, that is to say allow the atmosphere inside the chamber to flow out not only through leaks but also through actual outlet openings. It has already been established that such an outlet opening can in particular also exist in a gas outlet line.

In order to shorten the process times, it may also be desirable not only to be able to heat the chamber quickly, but also to be able to cool it quickly. A low thermal inertia of the chamber sought by the invention is a first aspect. The chamber can also be forced-cooled. In this case, it is preferable to bring a cooling block into contact with the chamber, so that there is no actual passage of a cooling medium through the chamber itself. The cooling block can e.g. be water cooled. As it is not heated to the high process temperatures in the chamber itself, water cooling is not a problem. The cooling block can cool the chamber quickly and easily thanks to its flat contact with the chamber.

In order to drive off organic contaminants, such as binder materials in so-called glass solders or phosphor and reflection layers, it may be advantageous to heat the discharge vessel in an oxygen-containing atmosphere, for example in air, before filling. This atmosphere can be kept in a constant flow in order to remove the expelled impurities. Furthermore, the discharge vessel can be flushed with an inert gas before filling and, if necessary, after heating in the oxygen-containing environment. In addition to the actual discharge gas, that is to say the gas whose light emission is technically used for the discharge (which may also be a discharge gas mixture), the gas mixture can also contain other gases, in particular noble gases, during the filling. The discharge gas is preferably Xe. The noble gas added can be, for example, Ne and / or He. In particular, in addition to the discharge gas, another gas can be present which has a Penning effect in relation to the discharge gas, that is to say it promotes ionization of the discharge gas via its own excitation. This applies to the discharge gas Xe for Ne. Furthermore, a buffer gas can be added, which serves to achieve a desired total pressure during filling and in the finished, cooled discharge lamp at a predetermined target partial pressure of the discharge gas and, if appropriate, of the Penning gas. The partial pressures and the total pressure during filling must always be set so that they reach the desired values at the expected operating temperatures of the discharge lamp. For the discharge gas Xe, partial pressures of 60-350 mbar, preferably 70-210 mbar and particularly preferably 80-160 mbar, should preferably be selected (based on room temperature).

Furthermore, it can be provided to connect a noble gas freezing unit and / or collecting device, for example, to the gas outlet line to the chamber in which a gas filling containing noble gases is used for filling, in order to be able to reuse at least some of the expensive noble gases. So that the noble gas freezing unit does not have to be too large or if it is missing To limit the consumption of noble gas to such a freezing unit, the noble gas flow can be stopped immediately after the discharge vessel has been closed. It is also possible to switch to a different gas atmosphere or gas flow, which is less expensive. It is preferably air.

Overall, in order to minimize mechanical stresses and for the most uniform possible temperature distribution and precise temperature control, the gases flowing into the chamber should essentially have the discharge vessel temperature present at that time. This means that the deviations in the temperatures should not be greater than +/- 100 K, preferably not greater than +/- 50 K, depending on the actual discharge vessel temperature.

In particular, the gases can be guided through a gas inlet line brought to the chamber temperature over a longer distance. This gas inlet line can, for example, be drilled or milled into a solid part of the chamber and have a corresponding shape for extension, for example a meandering shape.

In this invention, a particularly simple embodiment is preferred, in which the necessary process steps for heating, rinsing, filling and closing the discharge vessel take place in one and the same chamber. This does not even necessarily have to include a conveyor. It is preferably not operated continuously, but rather loaded and emptied in batches.

In such a chamber, it may be necessary, as in a vacuum oven, to separate chamber parts from one another in order to separate the interior of the chamber to load and empty. The areas of the chamber parts which come into contact with one another when the chamber is closed are preferably provided with a vacuum channel, via which this contact surface can be suctioned off when the chamber is opened and closed. This suction serves on the one hand to keep contaminants out of the interior of the chamber (comparable to a vacuum cleaner), on the other hand one chamber part can be pressed against the other, and thirdly an effective sealing function can be achieved. The vacuum channel removes contaminants that could penetrate from the outside before they reach the interior of the chamber. On the other hand, it intensifies a counterflow of the gas present in the interior of the chamber at excess pressure, which further prevents the ingress of contaminants. For this purpose, the vacuum channel can also be connected to a noble gas collecting or freezing device.

Brief description of the drawings

An exemplary embodiment is described in detail below with reference to the accompanying drawings. Individual features disclosed can also be essential to the invention in other combinations.

FIG. 1 shows a schematic sectional view through a system for producing a discharge lamp or a plasma display unit using the method according to the invention; and

FIG. 2 shows a schematic plan view of the system from FIG. 1.

Preferred embodiment of the invention

Figure 1 shows the system according to the invention in a sectional view. The system 1 shown there is essentially flat and corresponds to in the orientation of the flatness of the flat lamp discharge lamps or plasma display units to be produced, which are to be arranged in an interior 10 in a metal block 2. There is no flat lamp discharge lamp or plasma display unit shown, but these are, for example, known flat radiators designed for dielectrically impeded discharges, the discharge vessel of which essentially consists of a ceiling plate and a base plate which are connected to one another at one edge , Electrodes are arranged in or on the discharge vessel and are at least partially separated from the discharge space in the discharge lamp by a dielectric. Regarding the structural details, reference is made to the following earlier patent applications by the same applicant: US-A 2002/163311 and US-A 2002/163296. For the present context, it is only important that the discharge vessels are filled with a gas filling as the discharge medium during manufacture and then sealed.

For this purpose, the discharge lamps are brought individually or in small numbers into the chamber 10 in the system 1 from FIG. 1, a flat metal cover 3 being lifted off the chamber 10. SF6 glass pieces are interposed between the base plate and the cover plate of each discharge lamp, which create a sufficient distance between the two plates so that the discharge space in the respective discharge vessels communicates with the space 10.

The metal cover 3 is then placed on top and thus closes the chamber 10 from the outside. Via a vacuum channel 6 shown in section, which opens towards the cover 3, the cover 3 can be sucked in and held firmly on the metal block 2. The underside of the metal block 2 under the chamber 10 is a relatively thin metal wall 11 with a thickness of 3.5 mm. It is drawn a little thicker in FIG. 1 to clarify the heating device which will be explained later. The metal cover 3 has a thickness of approximately 2 mm. The chamber 10 is thus delimited by thin-walled system parts over the majority of its outer surfaces.

The metal block 2 can be heated overall, also in the area of the thin wall 11 under the chamber 10, by means of an electrical heater 4 shown in section, with only a low thermal inertia resulting in the area of the thin walls. The cover 3 can in turn be heated by a symbolically indicated heater 8.

Furthermore, a gas can be introduced into the chamber 10 via a gas line 5 and an inlet E, which gas can leave the chamber 10 again via a line 9 and an outlet A. The chamber 10 can therefore be flushed via lines 5 and 9. The lines in each case meander in the metal block 2, as indicated by the double section through the line 5 and through the line 9, so that the line length within the metal block is lengthened and the gas flows preheated into the chamber 10 and against a certain flow resisted within line 9 leaves the chamber again. This flow resistance can be generated by a suitably dimensioned cross section of the line 9 or also by a deliberately introduced obstacle (throttle). A back pressure should therefore form in the chamber 10 during the rinsing.

The outlet A is connected to a rare gas freezing device in order to be able to recover the rare gases used for the gas filling. Overall, the chamber can be heated with it, first flushed in an oxygen-containing atmosphere, namely dry air, then flushed with an inert gas, namely argon, and finally flushed with a mixture of He, Ne and Xe under an overpressure of 250 mbar. Ne serves as Penning gas and buffer gas, He only as buffer gas. The temperature in the chamber 10 rises to a temperature of approximately 500 ° C., so that the SF6 parts mentioned soften and the ceiling plate supported by you drops and is placed on the base plate. There is already a glass solder (type 10045 from the manufacturer Ferro) that is so soft at this temperature that there is a tight adhesive bond between the two plates of the discharge vessel.

The noble gas flow can now be switched off and it can be switched to dry air for cooling.

In order to accelerate the cooling, a water-cooled cooling block (not shown) can be brought into flat contact with the underside of the metal block 2 in order to cool it down quickly by thermal conduction. Due to the flat geometry of the metal block 2 and in particular the thin walls of the wall 11 and the cover 3, the temperature in the chamber 10 drops relatively quickly. The discharge lamp in the chamber 10 or the plurality of discharge lamps contained therein can therefore be quickly removed again. Production is therefore carried out in batches.

While the cover 3 rests on the chamber 10, it is held by the vacuum in the vacuum channel 6 against the excess pressure in the chamber 10 and, if this is not sufficient, could also be fastened by means of mechanical clamps or by weighting. The excess pressure in the chamber 10 leads to a permanent low Outflow of the gas atmosphere from the chamber 10 through the incompletely sealed contact surfaces between the cover 3 and the metal block 2 into the vacuum channel 6. At the same time, the vacuum channel 6 sucks off contaminants entering from outside, so that these cannot reach the chamber 10. The combination of the purging process in the chamber 10 on the one hand and the excess pressure driving the contaminants outwards on the other hand ensures that the desired gas purity in the chamber 10 is produced quickly and thoroughly. The vacuum channel 6 thus forms a closure device, a seal and a contamination barrier.

Since there is a certain gas consumption anyway due to the chamber volume and the batch production, the loss caused by the gas flowing out along the sealing surfaces between the cover 3 and the metal block 2 does not play an important role. Otherwise, this area can also be suctioned off and connected to the rare gas execution unit if this makes economic sense.

The chamber 10 can accommodate, for example, a 21 "lamp (42.7 cm x 32 cm). It then has internal dimensions of approximately 50 cm x 40 cm x 5 cm. The vacuum channel 6 can be 10 mm wide and 4 mm deep, for example ,

Although the invention was explained in more detail in the above embodiment using a flat radiator, the invention is not restricted to this. Rather, the advantageous effects of the invention can also be achieved with other types of discharge lamps and in particular also with plasma display units.

Claims

claims

1. A method for producing a gas discharge device, in particular a discharge lamp or a plasma display unit, in which a discharge vessel of the gas discharge device is filled with a gas filling and then sealed, characterized in that the filling and closing of the

Discharge vessel takes place in a chamber (10) which is flushed with the gas filling at excess pressure.

2. The method according to claim 1, wherein the chamber (10) is heatable.

3. The method according to claim 1 or 2, wherein the overpressure is at least 10 mbar.

4. The method according to any one of the preceding claims, in which a gas outlet line (9) is used for purging.

5. The method according to any one of the preceding claims, at least claim 2, wherein the chamber (10) after closing the discharge vessel by contact with a water-cooled

Cooling block is cooled.

6. The method according to any one of the preceding claims, at least claim 2, wherein the discharge vessel is heated in an oxygen-containing atmosphere before filling.

7. The method according to any one of the preceding claims, wherein the

Discharge vessel is flushed with an inert gas before filling and, if necessary, after heating in the oxygen-containing environment.

8. The method according to any one of the preceding claims, in which the discharge vessel is filled with a gas filling which contains a buffer gas for increasing the internal pressure in addition to the discharge gas provided for the light generation.

9. The method according to any one of the preceding claims, wherein the

Discharge vessel is filled with a gas filling, which contains a noble gas with a Penning effect in relation to the discharge gas in addition to the discharge gas provided for the light generation.

10. The method according to any one of the preceding claims, wherein the discharge gas provided for the light generation is Xe and that

Discharge vessel is filled with a partial pressure of Xe such that it contains a partial pressure of Xe in the range of 60-350 mbar at room temperature.

11. The method according to any one of the preceding claims, in which a noble gas freezing device or collecting device is connected to the chamber (10).

12. The method according to any one of the preceding claims, in which after the discharge vessel is closed, the noble gas flow is shut off.

13. The method according to claim 12, wherein after closing the

Discharge vessel is switched to a cheaper gas.

14. The method according to any one of the preceding claims, at least claim 2, wherein the gas filling containing the discharge gas provided for the light generation and optionally thereafter in the gases to be introduced into the chamber (10) flow in at a temperature which essentially corresponds to the discharge vessel temperature present.

15. The method according to any one of the preceding claims, wherein the chamber (10) has at least mostly wall thicknesses (3.11) of at most 8 mm.

16. The method according to any one of the preceding claims, in which the discharge vessel in one and the same chamber (10) is heated, rinsed, filled and sealed.

17. The method according to claim 16, in which the chamber (10) can be opened by separating two chamber parts (2, 3) and a contact surface between the two chamber parts (2, 3) can be subjected to a pressure force via a vacuum channel (6) ,

18. The method according to any one of the preceding claims, wherein the gas discharge device is designed as a discharge lamp for dielectrically disabled discharges.

19. The method according to any one of the preceding claims, wherein the gas discharge device is a flat radiator or a plasma display unit with a discharge vessel, which has two substantially plane-parallel discharge vessel plates.