HU185834B - Sodium-vapour lamp of high pressure - Google Patents

Abstract

An electrode structure for sodium vapor lamps is disclosed having molybdenum metal wire coils wound around a tungsten shank to replace the customary all-tungsten electrode structure in these lamps. The improved electrode structures provide increased initial lumens with acceptable lumen maintenance.

Description

The present invention relates to a high pressure sodium vapor lamp. having a tubular light-transmitting ceramic material, hermetically sealed at high temperature thermally emitting electrodes at its ends, and having an ionizable charge, the electrodes being formed from a metal wire, a tungsten support and a stationary coil of heat-resistant material arranged around it.

The conventional electrode structure used in high pressure sodium vapor lamps consists of a tungsten support and tungsten wire wrapped thereon. These electrode structures are hermetically sealed in the tubular casing of a light-permeable ceramic tube, which is opposed to kct; the discharge tube contains a charge of ionizable material. Lamps of this general design are known, inter alia, from U.S. Patent Nos. 4,025,812 and 4,065,691, issued to General Electric.

The ceramic tubular casing is surrounded by an outer glass casing or jacket, which has an elongated head and is usually provided with a standardized thread at one end. The outer bulbs of high pressure sodium vapor lamps are usually pumped out to minimize the heat effect and maximize efficiency.

• Whole tungsten electrode structures are costly and present many difficulties in producing high pressure sodium vapor lamps. It is therefore an objective to replace this high-temperature metal as far as the operating conditions of the lamp allow. A disadvantage of tungsten fiber commonly used in the production of coils is that it tends to develop internal tube defects in the electrode structure, resulting in fiber breakage and failure of the manufacturing equipment used during electrode fabrication. In addition, adverse effects may occur during lamp operation. On the other hand, tungsten is needed because it can withstand very high operating temperatures of the electrode and withstand the strong corrosion effects of arcing inside the lamp. Although the material of the tungsten electrodes is dusted during the operation of the lamp, these electrodes provide an appropriate level of luminous efficiency for a very long time.

It is an object of the present invention to overcome the shortcomings of the described tungsten electrode structures.

The present invention is based on the surprising discovery that wrapping a molyhden wire around a tungsten support instead of a tungsten does not destroy the electrode so obtained during operation as would be expected when the electrode structure formed from inolibdcn alone is pressurized with high pressure sodium vapor. experiences were analyzed. A further surprising finding is that such an electrode structure, when compared to pure tungsten structures, assumes the same lamp construction, provides an increased initial light output, and subsequently provides an appropriate level of light utilization for a surprisingly long time. Accordingly, the operating conditions for high-pressure sodium vapor lamps are improved and there is no need for any substantial modification of the manufacturing process; nor does the cost of production increase.

To achieve this goal, we have developed a high-pressure non-volatile vapor lamp which is a tubular light-emitting lamp 2

It is provided with a ceramic bulb, hermetically sealed at the ends of the bulb with high-temperature thermal radiation electrodes, and comprises an ionizable charge, wherein the electrodes are formed from a metal wire, tungsten support ₅ and a heat-resistant upright coil arranged around it. material is made of molybdenum wire. It has been found to be particularly advantageous for the coil made of molybdenum wire to be threaded.

IQ In a preferred embodiment of the high pressure sodium vapor lamp according to the invention, the coil of molybdenum wire comprises a threaded outer and inner layer disposed on one another, the inner layer comprising separated threads, whereby oxide-emitting material mixed between the threads of the inner layer is highly desirable. in one of the electrode structures of the spout. An example of an emissive material is dibasic calcium tungstate.

In a further preferred embodiment, the molybdenum wire is wound around the end of the tungsten bracket closer to the ends of the bulb and in the helical inner layer the direction of the pitch is reversed relative to the outer layer. The direction of the pitch of the stacked layers is reversed and this prevents the coils from sliding into each other, thereby preventing the electrode material from degrading at an accelerated rate and, consequently, light output degradation.

In one embodiment, the high pressure sodium vapor lamp developed for this purpose provides 400 W of tel30 and a voltage drop of about 100 V. This lamp contains a hermetically sealed tubular light-permeable aluminum oxide ceramic bulb with thermally emitting electrodes and an excess amount of sodium alkali amalgam in the vapor state under these operating conditions, as well as an internal starter xenon gas, is provided with a glass-like, vacuum-free outer envelope, the opening of which is hermetically sealed with a glass support column, through which current conductors are connected to the thermionic electrodes, and the electrodes form a threaded inner and outer layer of thermoplastic material formed around the tungsten support directions are reversed, the threads of the inner layer are separated in space, and one of the electrodes has a mixed oxide-emission material in the space between the threads According to the invention, the threaded inner and outer layers are made of molybdenum wire.

In a preferred embodiment of said lamp having a wattage of about 400 W, the emission-sensitive material is dibasic calcium tungstate.

The present invention will now be described in detail with reference to the accompanying drawings, in which reference is made to exemplary embodiments. In the drawing it is

Figure 1 is a cross-sectional view of a sodium vapor lamp having a novel electrode structure according to the invention,

Figure 2 is an enlarged cross-sectional view of an electrode of the sodium vapor lamp of Figure 1,

Figure 3: Comparison of luminous power using molybdenum and tungsten.

The high pressure sodium vapor lamp I of the present invention (Fig. 1) is capable of delivering a net power of about 400 W in the illustrated embodiment. Transparent with 2 outer jacks connected to a standard 3-threaded head

It has 185 834 hermetic seals and includes 4 glass support posts extending into the outer shell 2. In accordance with known principles, relatively heavy current conductors 5 are passed through the glass support column 4, the outer ends of which are connected to the shell 7 and the tip contact 8 of the screw head 3. The inner bulb 9 formed as a discharge tube in the outer bulb 2 is tubular and is disposed in the axis of symmetry of the outer bulb 2. The inner bulb 9 is formed as a light-transmitting ceramic tube. Preferably, the material is polycrystalline alumina ceramic which is crystalline, but it is also possible to form a single crystal of alumina when the material is glassy transparent. Felső The upper end of the tubular portion enclosing the discharge is closed by an alumina ceramic in which 11 niobium wires are arranged as a current conductor in a hermetically sealed lead-through. The current supply supports a top electrode, which is essentially similar to the bottom electrode. The lower electrode is shown in Figure 2. The outer portion of the niobium wire 11 is passed through a loop 12 and continues as a transverse staple wire 13 in the support bar 14. With this arrangement, the thermal expansion of the discharge during operation of the lamp is not problematic while the lower end of the tube is rigidly gripped. 15 flexible metal supports provide a continuous good electrical connection. The support rod 14 is connected to the current inlet 6 by welding and its upper end is held by a spring plate 16 which is connected to a coupling element 17 in the dome portion of the outer bulb 2. Preferably, 18 reflective metal strips are arranged around the upper end of the discharge tube to provide the desired temperature range for the upper hermetic seal, which is particularly important for smaller lamps of up to 250 Watt. The lower stopper and electrode support of the discharge tube comprise an aluminum oxide-based ceramic stopper 20 having a central aperture through which a thin-walled niobium tube 21 serves as both a suction tube and a current feeder. The niobium tube 21 is guided through, sealed in and sealed by a sealing plug 20 made of alumina-based ceramic, thereby forming a seal 22 in FIG. The neck portion of the closure 20 extends into the inner envelope 9, while its end rests on the shoulder portion of the closure 20. The hermetic seal between the inner bulb 9 and the aluminum oxide-based ceramic stopper 20 is provided by sealing material 23 and 24 (Fig. 2).

SUMMARY OF THE INVENTION The present invention is in itself an electrode structure, which is illustrated in detail in FIG. This electrode structure is comprised of two layers of molybdenum wires 25 and 26, which are wound around the end of a tungsten support 27 towards the discharge closure member. The tungsten support 27 or the niobium tube 21 as the current inlet on the outer shroud 2 is so protruding from the inner shoe 9 that it can be securely deformed so that the tungsten support 27 remains free for a sufficient length. For this purpose, the support must be deformed, and preferably at a transition point such that there is still sufficient space to accommodate excess amalgam. The arrangement shown, also known as the butterfly arrangement, is such that the tungsten support is provided with a flattened portion, or 28 wing portions, as required. On both sides of the bracket, channels are retained for communication with the lower portion 30 of the exhaust pipe. This connection allows the sodium mercury amalgam to move through the vapor form, but not as a liquid under normal operating conditions, even when the lamp (is rotated). The molybdenum wires on the tungsten support 27 can be formed as superimposed thread-shaped layers, wherein the molybdenum wire 25 forms the inner layer which is welded to the tungsten support 27 and is tightly wound to the outer layer from the molybdenum wire 26. Λ Reverse thread pitch direction is achieved by rotating the tungsten support 27, but reversing the thread direction or line and thereby providing external threads with an opposite internal winding direction.the wire to be wound is passed through a solution of a material of sufficient enthusiasm The only remaining step in preparing the electrode in this manner is to place the holder of the coated electrode in the niobium tube prior to flattening. The internal helical layer of molybdenum wire 25 is formed by separating the threads so as to introduce into the space between the threads an emissive material, preferably the dibasic calcium voliramate. Further structural elements of the aisle electrode unit support are shown in Figure 1. The discharge tube is held in the outer bulb 2 by a connector 31 extending from the niobium tube 21 to the support bar 32. The niobium 21 is joined to the rain by welding at one end and supported by the current inlet 5 at the other end.

Λ The characteristics of the high pressure sodium vapor lamp described above and the proposed novel electrode structure were verified. The operating conditions of a 400 W lamp were investigated by measuring high pressure sodium vapor lamps of the state of the art with pure tungsten electrode structure and the same structure but using molybdenum electrode structure after 100 hours of operation. The results of the comparative test tests are shown in Table 1 and Figure 3.

Table 1

Test Lamps number Coil material Lm / W functional Stress, V 1 15 tungsten 119.1 95.8 2 15 molybdenum 121.2 95.0 3 25 tungsten 120.3 107.0 tungsten 119.8 97.1 4 25 mGÜbdén 122.1 96.9 molybdenum 121.6 100.3

Λ From the above results it is obvious that the lamps with the molybdcn electrode were better, the mini ones with the pure tungsten electrode. and the first 100 hours of lamp operation showed higher light utilization.

-3185834

The curves of Figure 3 show results for a longer-term study of the change in light utilization level. The comparison shows a decrease in relative luminous efficacy (curve B) for 400 W lamps with molybdenum electrodes compared to tungsten lamps (curve A), although at a slower rate during the initial period. We do not yet know what this unexpected result is, it may be due to the different behavior of refractory metals during operation.

Since molybdenum is more flexible than tungsten, the outer layer is wound tighter during electrode fabrication than tungsten, allowing better retention of the emissive material and thus providing greater light utilization within the first 100 hours of operation. During the process, it appeared that the degradation of molybdenum coils is faster than that of tungsten in the given lamp environment. However, as the number of operating hours increases further electrolyte containing the molybdenum lamp with _two ródstruktúrával the erosion process slows down, it is better than the lamps with tungsten elektródstruktúrával pure material for mar smaller, i.e. by a light loss recovery level of the emission material. From the foregoing, it is clear that high pressure sodium vapor lamps are useful advances with the new electrode structures. It will also be apparent to those skilled in the art of light source production that the improved electrode structure of these lamps is capable of replacing conventional pure tungsten electrode structures. Solutions other than those described above may be used to seal the ceramic discharge tube, and in addition, the present invention may be utilized. Accordingly, the scope of the invention is defined by the appended claims.

Claims (8)

Patent claims 1. A high pressure sodium vapor lamp having a tubular light-transmissive ceramic material having hermetically sealed high-temperature radiant electrodes at the ends of the bulb and having an ionizable charge wherein the electrodes are formed from and surrounded by a tungsten metal wire holder, that the electrode heat-resistant coil is made of molybdenum wire (25.26). An embodiment of a high pressure sodium vapor lamp according to claim 1, characterized in that the coil made of molybdenum wire (25,26) is helical. An embodiment of a high pressure sodium vapor lamp according to claim 1 or 2, characterized in that the coil formed of molybdenum wire (25, 26) comprises a helical thread, an outer layer and an inner layer disposed on one another and the inner layer comprising separate threads. . An embodiment of a high pressure sodium vapor lamp according to claim 3, characterized in that the threads of the helical inner layer made of molybdenum wire (25) comprise an oxide-emitting material mixed with one of the electrodes. 5. An embodiment of a high pressure sodium vapor lamp according to claim 4, characterized in that the emitting material is dibasic calcium tungstate. 6. High pressure sodium vapor lamp according to claim 3, characterized in that the molybdenum wire (25, 26) is wound around the end of the tungsten support (27) and in the helical inner layer the direction of the pitch is reversed to the outer layer. . 7. High pressure sodium vapor lamp containing an inner sheath of hermetically sealed tubular light-permeable aluminum oxide ceramic with thermally emitting electrodes and an excess of sodium mercuric anh is provided with a glass-like vacuum-free outer envelope, the opening of which is hermetically sealed with a glass support column and through which current leads are connected to the thermionic electrodes, and the electrodes comprise a thermally threaded inner and outer layer of threaded material around the tungsten support. the ascending directions are reversed, the threads of the inner layer are separated in space, and one of the electrodes has mixed oxide emissions in the space between the threads intact material is characterized in that the threaded inner and outer layers are made of molybdenum wire (25, 26). 8. Sodium vapor lamp embodiment according to claim 7, characterized in that the emitting material is dibasic calcium tungstate.