EP0735568A1 - Low pressure mercury vapour discharge lamp - Google Patents

Abstract

A compact fluorescent electric lighting unit has a U-shaped tube and one end (2a) has an inset pumping tube (5). During the evacuation and filling of the discharge U tube the ends of the pumping tube are open. A solid element of iron (6) is held in place with the aid of an external magnet and an amalgam or liquid mercury (8) is introduced. After filling with the inert gas the magnet is removed so that the iron or amalgam moves to the discharge end of the pumping tube. The end of the pumping tube is sealed by heating and squeezing together.

Description

The invention relates to a low-pressure mercury discharge lamp in accordance with the preamble of claim 1. The mercury is introduced into the lamp either in liquid or solid form, in particular as amalgam. The amalgam lamps can have different designs. For example, it can be conventional fluorescent lamps with a rod-shaped discharge vessel, or compact fluorescent lamps with curved tubes, for. B. U-shaped or H-shaped, or spherical electrodeless low-pressure discharge lamps.

Such compact fluorescent lamps are known for example from EP-A 373 567. The amalgam is introduced into the pump tube, the opening on the discharge side of which is slightly narrowed. Alternatively, the pump tube itself can also have a constriction, see e.g. EP-A 161 725.

Neues aus der Technik" Nr. 1/86 beschrieben, wobei das Hauptamalgam sich in einem geschlossenen Pumpstengel befindet, dessen Oberseite eine geringfügige asymmetrische Verengung aufweist. Dadurch soll vermieden werden, daß das Amalgam in den Kolben gelangt und die Leuchtstoffschicht oder andere Teile beschädigen kann, bzw. nicht die entsprechende Arbeitstemperatur erreicht.A spherical, electrodeless, low-pressure discharge lamp is known, for example, from EP-B 119 666. The main amalgam is placed in a cool depression. A variant of this lamp is in

News from the technology "No. 1/86 described, wherein the main amalgam is in a closed pump stem, the top of which has a slight asymmetrical narrowing. This is to prevent the amalgam from getting into the bulb and damaging the phosphor layer or other parts , or not reached the corresponding working temperature.

However, it is problematic that the amalgam can get into the discharge vessel if the opening is relatively wide, as in the prior art described so far, so that safe pumping and filling is ensured. On the other hand, the opening of the pump tube was previously narrowed to a capillary to safely prevent the amalgam from escaping (see DD-DWP 70 661). With today's modern high-performance production lines pumping and filling would be too time-consuming. Such capillaries should have a diameter of the order of 0.5 mm.

It is an object of the invention to provide a generic lamp which enables rapid and safe pumping and filling, but which on the other hand ensures that no amalgam can escape into the discharge space.

This object is achieved by the characterizing features of claim 1. Particularly preferred embodiments can be found in the subclaims.

The present invention makes use of the basic technologies of EP-A 581 160 and EP-A 228 005, the content of which is hereby expressly incorporated by reference. The latter describes a storage element for metering and introducing mercury as liquid metal or liquid or solid amalgam, the storage element being formed by a porous pressed body, in particular made of iron. The former describes a solid amalgam body or amalgam former body with a ferromagnetic component.

It has now been shown that these basic technologies, with a suitable modification, provide an ideal prerequisite for achieving a compromise between the two extremes which were mentioned above as the prior art.

A quick pumping and filling with safe retention of the mercury is achieved in a low-pressure mercury discharge lamp with a pump tube attached to the discharge vessel, the outer end of which has melted and the inner end of which is open, in that the mercury (Hg) is metallic or as amalgam (im hereinafter generally referred to as Hg body) is introduced into the pump tube. The discharge-side opening of the pump tube is narrowed. Together with the mercury body, a solid body is introduced into the pump tube in such a way that it partially acts as a plug for the mercury body to open the pump tube closes. An arrangement in which the solid body has a different cross section than the pump opening in each orientation is particularly advantageous. In this way, the effective opening for the mercury diffusion between the pump tube and the discharge vessel is kept very large during operation, but without the solid body or the mercury body being able to penetrate into the discharge vessel. At the same time, the special shape of the constriction enables mercury diffusion between the pump tube and the discharge space.

The solid can preferably be made of ferromagnetic material (in particular iron), so that it can be held in place at any point in the pump nozzle by means of a magnet during the pumping and filling process. In terms of processing technology, this has proven to be even more favorable than the use of a ferromagnetic amalgam (former) body, but this is not excluded.

The solid body can be spherical, ellipsoidal or irregular in shape, with the pump opening having a different shape, in particular an asymmetrical shape.

In a preferred embodiment, the solid forms at least approximately a circular cylinder (for example, exactly or tablet-shaped rounded or slightly elliptically distorted) with an assigned diameter and height. Good results can be achieved if the diameter of the solid body corresponds to between 50 and 90%, in particular 60 and 80%, of the inner diameter of the pump tube, so that there is sufficient space between the solid body and the pump tube wall. In particular, the height of the solid should be smaller than its diameter, in particular it should correspond to approximately 50 to 80% of the diameter of the solid. Experience has shown that this dimension is particularly favorable for the smooth functioning of the filling process with regard to a randomly changing orientation of the solid in the pump tube. This minimizes canting or damage. The solid can rotate freely in the pump tube.

The solid forms a plug, as it were, which only incompletely closes the pump opening. To ensure this, solids need to be and pump opening have a different shape. In one embodiment, the opening of the pump tube in the case of a circular solid (ball or circular cylinder) may not be circular, but rather should define a largest longitudinal and transverse dimension, the longitudinal dimension being larger than the transverse dimension.

Accordingly, in principle it is also possible in reverse to combine a non-circular solid (ellipsoid, cube or cuboid) with a circular opening.

As a reference for the geometric dimensions to be selected, in the case of a circular cylindrical solid body, either the largest transverse dimension is larger, in particular 0.1 to 0.4 mm larger than the height of the solid body, or that the largest longitudinal dimension is larger than is the diameter of the solid. If only one of these conditions is observed, it is advantageous that the narrowing of the opening extends over a certain height (typically 1 to 2 mm). Due to the different shape of the opening, the solid body can never completely close the opening in this case either. Ideally, both conditions are met at the same time.

The largest transverse dimension of the opening is particularly advantageously smaller than the diameter of the solid.

8" oder sichelförmig geformt sein. Sie kann eine beliebige asymmetrische Form aufweisen. Dabei spielt es prinzipiell keine Rolle, ob die Öffnung zentral oder dezentral in bezug auf das Pumprohr angebracht ist, jedoch ist eine dezentrale, insbesondere möglichst randnahe, Öffnung günstiger, weil sie mehr Gestaltungsmöglichkeiten für die Öffnung beläßt und es leichter ermöglicht, daß die Verengung sowohl in Längs- als auch Querrichtung größer als Höhe und Durchmesser des Festkörpers ist. Der Grund ist, daß sich wegen der nahen Wand des Pumprohrs die Öffnung und der Festkörper nicht zur bestmöglichen Deckung bringen lassen.In the case of a circular solid, the opening can preferably have an elliptical or crescent-like cross section. It can also be similar to one

8 "or crescent-shaped. It can have any asymmetrical shape. It does not matter in principle whether the opening is made centrally or decentrally with respect to the pump tube, but a decentralized opening, in particular as close to the edge as possible, is cheaper because it leaves more design options for the opening and more easily allows the narrowing in both the longitudinal and transverse directions to be greater than the height and diameter of the solid body, because the opening and the solid body are not being optimally possible due to the close wall of the pump tube Get coverage.

In the case of an elliptical narrowing, at least one dimension (transverse or longitudinal dimension) should be larger (by approximately 0.1 to 0.3 mm) than the height or the diameter of the solid body. The optimal range for an axial ratio of the narrowing is between 1.1 and 2.0, whereby the (shorter) transverse dimension should be greater than 1.0 mm in order not to hinder the diffusion.

In another embodiment, the circular opening of the pump tube is left. However, the effective cross section is narrowed by the fact that a piece of wire or the like spans the opening transversely and thus acts as a barrier.

Another possibility is the use of a glass foam plug, which is introduced into the circular cylindrical opening of the pump tube. In a first embodiment, the foam is at least partially open-pored in order to allow mercury to diffuse into the discharge vessel. In a second embodiment, the foam can also contain a high proportion of closed pores, but the opening is not completely closed by the glass foam plug, but a residual opening remains for the diffusion of the mercury. Finally, mixed forms of both embodiments are also possible.

In a first particularly preferred embodiment, the solid body can act not only as a stopper, but also as a sponge for the mercury body. In this case, as is known per se, the solid forms a porous matrix as the base body, which contains liquid mercury or liquid amalgam in its cavities. In addition, an amalgam partner that is favorable for the formation of the amalgam can be introduced behind the solid in liquid or solid form.

In a second particularly preferred embodiment, amalgam can also be used which is solid at room temperature. In this case, the solid is first poured into the pump tube and then the amalgam, so that the latter lies behind the solid with respect to the discharge-side pump opening. In this case, the nature of the solid plays no role, but still its geometric dimensions.

Figur 1

eine schematisierte Darstellung eines Entladungsgefäßes

Figur 2

eine vergrößerte Darstellung der Quetschdichtung mit dem Pumpstengel

Figur 3

eine Draufsicht auf die Pumpöffnung mit schematisierter Darstellung des Festkörpers in drei Varianten

Figur 4

eine vergrößerte Darstellung der Quetschdichtung mit dem Pumpstengel bei einer zweiten Ausführungsform

Figur 5

eine Draufsicht auf die Pumpöffnung des zweiten Ausführungsbeispiels

Figur 6

eine vergrößerte Darstellung der Quetschdichtung mit dem Pumpstengel bei einer dritten Ausführungsform

Figur 7

zwei weitere Ausführungsformen der Pumpöffnung

Figur 8

eine weitere Ausführungsform der verengten Pumpöffnung

Figur 9

zwei weitere Ausführungsformen der Pumpöffnung

The invention is explained in more detail below with the aid of several exemplary embodiments. It shows

Figure 1

a schematic representation of a discharge vessel

Figure 2

an enlarged view of the pinch seal with the pump stem

Figure 3

a plan view of the pump opening with a schematic representation of the solid in three variants

Figure 4

an enlarged view of the pinch seal with the pump stem in a second embodiment

Figure 5

a plan view of the pump opening of the second embodiment

Figure 6

an enlarged view of the pinch seal with the pump stem in a third embodiment

Figure 7

two further embodiments of the pump opening

Figure 8

a further embodiment of the narrowed pump opening

Figure 9

two further embodiments of the pump opening

Figure 1 shows a discharge vessel 1 for a compact fluorescent lamp, which is bent in a U-shape. It has two ends 2a, 2b in which electrodes (not visible) are squeezed. One end 2a is equipped in the middle with a pump tube 3, the narrow end 4 of which extends toward the discharge into the discharge vessel 1, while the circular end 5 remote from the discharge is accessible from the outside. During the evacuation and filling with the aid of a pump nozzle 9 and a seal 9a, both pump ends 4, 5 are initially still open. A solid 6, which consists of iron, is held by a magnet 7 in the middle of the pump nozzle 9. A liquid or solid amalgam (or liquid mercury) 8 is introduced into the pump tube behind it. After the discharge vessel has been filled with noble gas, the magnet 7 is removed, so that the solid 6 and the amalgam 8 (or Hg) slide to the discharge end 4 of the pump tube. The end of the pump tube remote from the discharge is then shortened and melted.

ist abgeschmolzen.FIG. 2 shows an enlarged illustration of the squeezing area 2a. The discharge-side pump tube end 4 is narrowed, so that the solid body 6 blocks the opening despite the orientation oriented upright and prevents the amalgam 8 from escaping into the discharge space. The end of the pump tube 5 remote from the discharge

has melted.

Figure 3a shows that the solid body 6 shown transversely here and the pump opening 4 are coordinated. The pump tube 3 has an inner diameter of approximately 2.5 mm and a wall thickness of 0.75 mm. The pump opening 4 is arranged elliptically and centrally with respect to the pump tube 3. The largest longitudinal dimension is approximately 1.70 mm (corresponding to double the large semi-axis), the largest transverse dimension (corresponding to double the small semi-axis) is approximately 1.4 mm. The solid is a circular cylinder with a diameter of 1.8 mm and a height of 1.2 mm. The formation of the opening extends over a height h of approximately 1.6 mm (FIG. 2). Due to the different shape of the opening, the solid body cannot close the opening even when it is lying crosswise.

As Figure 3b and 3c shows, it is also possible to choose other dimensions. Fig. 3b shows the case mirrored to Fig. 3a, that the longitudinal dimension of the opening is larger than the diameter of the solid. FIG. 3c shows the best case theoretically (because of the unimpeded diffusion) that the largest longitudinal or transverse dimension of the opening is larger than the diameter or the height of the solid. However, this opening is very difficult to make. A plasma torch is advantageously used for this.

Such regular pump openings are produced by two gas burners located opposite one another, which are directed at the originally circular opening of the pump tube with different intensities. The melted glass contracts and forms an out-of-round (here elliptical) opening.

In a second embodiment (FIGS. 4 and 5), the pump opening 10 is arranged decentrally and is asymmetrically shaped. It is partial again blocked by the solid body 11, which here is a porous compact with a circular cylindrical shape. It contains liquid mercury in its matrix. Fig. 5 shows that the pump opening 10 has a crescent shape. The inner diameter of the pump tube is 2.5 mm. The largest longitudinal dimension of the opening is 2.5 mm, the largest transverse dimension is 1.5 mm. The compact has a diameter of 1.8 mm and a height of 1.2 mm.

Such irregular pump openings are produced by a gas or plasma torch, which is directed on one side to the area of the originally circular opening, which is opposite the later crescent-shaped opening.

In a third exemplary embodiment (FIG. 6), a body 16 made of solid amalgam or solid amalgam partner is arranged behind the solid body 15. As is known per se, it consists of a bismuth / indium alloy in a ratio of approximately 2: 1 or else a bismuth / lead / tin alloy. Further examples are alloys made of Bi-Pb or Bi-Pb-In or Bi-Pb-Ag. In addition, they each contain a few percent mercury. With regard to the amalgams used, reference is made, for example, to EP-A 373 567, EP-A 327 346, DE-OS 35 10 156, EP-A 157 440 and US-A 4 093 889.

8"-ähnliche Form der Pumpöffnung 21 gezeigt. Der Quersteg 22 der

8" ist dabei aus verfahrenstechnischen Gründen nicht vollständig ausgebildet.FIG. 7a schematically shows the top view of a pump opening 20 with a crescent shape, in FIG. 7b is one

8 "-like shape of the pump opening 21. The cross bar 22 of the

8 "is not fully developed for procedural reasons.

FIG. 8 shows the top view of a pump opening 25 with a circular shape, a piece of wire 26 narrowing the opening 25 transversely.

FIG. 9a shows the top view of a pump opening 30 with a circular shape, a glass foam plug 31 completely closing the opening 30. The foam consists of open pores. The thickness of the plug is, for example, on the order of about 2 to 10 mm.

FIG. 9b shows a top view of a pump opening 30 with a circular shape, a glass foam plug 35 partially (75%) opening 30 closes. The remaining opening 40 allows sufficient diffusion even if the glass foam consists predominantly of closed pores.

For the manufacture of such a glass foam plug, for example, water glass is used, the water of which is suddenly expelled by heating. The escaping water vapor causes the glass to foam, thereby forming pores.

Claims (20)

Low-pressure mercury discharge lamp with a discharge vessel (1), a pump tube (3) being attached to the discharge vessel (1), the outer end (5 ') of which has melted and the inner end (4) of which is open, with mercury (Hg) being metallic or as amalgam is introduced in the pump tube (3), characterized in that the discharge-side opening (4) of the pump tube is narrowed, and that together with the mercury a solid (6; 11; 15) is introduced in the pump tube so that it covers the discharge-side opening of the Pump tube partially closed. Low-pressure mercury discharge lamp according to claim 1, characterized in that the solid body has a different cross-section than the pump opening in every orientation. Low-pressure mercury discharge lamp according to claim 1, characterized in that the solid forms at least approximately a circular cylinder with an associated diameter and height. Low-pressure mercury discharge lamp according to claim 3, characterized in that the diameter of the solid body corresponds to between 50 and 90%, in particular 60 and 80%, of the inside diameter of the pump tube. Low-pressure mercury discharge lamp according to Claim 3, characterized in that the height of the solid is smaller than its diameter, the height corresponding in particular to approximately 50-80% of the diameter of the solid. Low-pressure mercury discharge lamp according to claim 3, characterized in that the opening of the pump tube defines a largest longitudinal and transverse dimension, the longitudinal dimension being larger than the transverse dimension, in particular by a factor of 1.1 to 2.0. Low-pressure mercury discharge lamp according to claim 6, characterized in that the largest transverse dimension is larger, in particular 0.1 to 0.4 mm larger than the height of the solid body. Low-pressure mercury discharge lamp according to claim 6, characterized in that the largest longitudinal dimension is larger than the diameter of the solid body. Low-pressure mercury discharge lamp according to claim 6, characterized in that the largest transverse dimension is smaller than the diameter of the solid. Low-pressure mercury discharge lamp according to claim 1, characterized in that the opening is elliptical, crescent, sickle or

8 "- is shaped similarly. Low-pressure mercury discharge lamp according to claim 1, characterized in that the solid is ferromagnetic. Low-pressure mercury discharge lamp according to claim 1, characterized in that the solid body has a porous matrix as the base body. Low-pressure mercury discharge lamp according to claim 1, characterized in that the mercury or its amalgam is liquid and in particular is embedded in the matrix. Low-pressure mercury discharge lamp according to Claim 1, characterized in that the amalgam is solid at room temperature and is arranged behind the solid body with respect to the pump opening. Low-pressure mercury discharge lamp according to Claim 1, characterized in that the pump tube (3) is arranged at one end (2a) of the discharge vessel. Low-pressure mercury discharge lamp according to Claim 15, characterized in that the end (2a) is closed by means of a pinch. Low-pressure mercury discharge lamp according to Claim 1, characterized in that the opening is narrowed by means of a transverse piece of wire (26). Low-pressure mercury discharge lamp according to Claim 1, characterized in that the pump tube is closed by means of a glass foam plug (31; 35), the narrowed opening (30) being formed in that at least part of the pores of the glass foam plug (31) is open and / or in that a free residual opening (40) remains. Low-pressure mercury discharge lamp according to claim 1, characterized in that the opening of the pump tube is arranged decentrally. A process for producing a fluorescent lamp, characterized in that a pump tube with a narrowed opening is produced, which is sealed in an opening of the discharge vessel, then a solid and possibly another body is introduced into the pump nozzle, then the discharge space via the pump nozzle and the associated pump tube is evacuated, the solid body being held in the pump nozzle, and then an inert gas is filled into the discharge vessel at low pressure, then the solid body and possibly the further body is introduced into the pump tube and finally the pump tube is closed.

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