HU196014B - Current input wire of electric discharge lamp - Google Patents

Abstract

Electric discharge lamp, particularly one of an output not exceeding 400 W, comprising a tube (1) made of a translucent material and sealed at two ends by respective closing elements (2), electrodes (7) arranged oppositely on respective electrode rods (8) in the interior of the tube (1) for defining a discharge space and lead-in conductors (4) for supplying electric current to the electrodes (7), fixed by means of mechanical deformation to the respective electrode rod (8), at least one lead-in conductor (4) including a hollow part for containing a liquid phase filling composition and having at least one capillary connecting the discharge space and the interior of the hollow space for ensuring a path of transportation of the filling composition when it is in vapour phase, wherein the lead-in conductor (4) is fastened by flattening to the electrode rod (8) on its section (10) lying in the interior of the tube (1).

Description

BACKGROUND OF THE INVENTION The present invention relates to an electric discharge lamp in the form of a suction tube hermetically secured therethrough, which is mechanically and electrically bonded to the electrode rod by a mechanical deformation. The current feeder according to the invention can be used primarily for high pressure sodium lamps.

A 27.54.001. DE-A-001 930 discloses an electrical discharge lamp, more particularly a ceramic discharge vessel, wherein the discharge vessel is made of a transparent polycrystalline alumina tube, the two ends of which are also sealed with aluminum oxide closures. In the holes formed in the closures are provided current conductors made of metal, preferably niobium, having a coefficient of thermal expansion close to that of the discharge material, which are connected to the electrodes and closures of the discharge vessel and provide a hermetic seal between the closures and the current conductors. The discharge vessel contains sodium and mercury additives and a noble gas charge as a starter gas. To the current inlet, the electrode rod is mechanically secured so that the electrode rod extends deeply into the current inlet suction tube passing through the closure, and the current inlet is flattened onto the electrode rod by mechanical defonation. Since the current inlet also serves as a suction pipe, the pump fitting is closed hermetically by the end of the pumping and filling process, which is furthest away from the inlet. A space between the two flaps of the current conductor as described above serves to store a liquid additive during operation of the discharge lamp, and capillaries formed during flattening of the electrode stick ensure the passage of the vapor discharge material between the discharge chamber and the reservoir. The disadvantage of this solution is that the flattening of the electrode rod outside the discharge tube significantly increases the required length of the current inlet, i.e. the suction tube. Because of the high cost of niobium, it also means that the coldest point of the discharge vessel is far beyond the source of the discharge, i.e. the arc, electrodes, and therefore requires the intervention of the coldest-point temperature required for optimum discharge lamp operation, at least 400 * V. for models with less power. In practice, this usually means that separate heat reflecting surfaces have to be provided at each end of the discharge tube, which further increases the cost, and an inaccurately defined thermal contact between the surface of the ceramic material of the discharge tube and the heat-reflecting clamps.

A further disadvantage is the increase in the temperature of the discharge vessel by means of additional heating.

It is an object of the present invention to provide a current lead-in for an electric discharge lamp that provides advantageous placement of the glide point, the possibility of pumping the discharge vessel through the suction tube and storing the liquid phase discharge material outside the discharge area.

The present invention is based on the discovery that the mechanical connection of the electrode rod and the current conductor must not be made outside, but inside, the Cooling Tube, because this way the coldest-point temperature can be achieved much more easily.

SUMMARY OF THE INVENTION This object is solved by a current discharge conductor of an electric discharge lamp, which is formed as a suction tube hermetically secured therethrough in the closure member closing the discharge lamp discharge lamp, which is mechanically and electrically bonded to the electrode rod by mechanical deformation. This has been further developed in accordance with the present invention by laying the current conductor on the electrode rod in the region of the current conductor discharge tube.

According to the invention, it is advantageous for the current conductor to have a four-leaf clover-shaped cross-section in the flattening region.

It is also advantageous if the current feeder and the electrode rod are fixed by spot welding in addition to flattening.

The current feeder according to the invention can be manufactured without technological modification, enables the economical and reliable production of low-power high-pressure discharge lamps, and provides the proper Indeg point of the discharge vessel. The discharge vessel of the present invention may be conventionally placed in an outer jacket and may, in one embodiment, be provided with an Edison threaded head.

The invention will now be described in more detail with the help of the drawing, in which the power supply is exemplified. is shown. In the drawing it is

Figure 1 is a longitudinal sectional view of a portion of the discharge vessel of the present invention, and

Figure 2 is a sectional view taken along line II-II of the discharge vessel of Figure 1.

The discharge tube 1 of the preferred embodiment shown in Fig. 1 is made of pd-crystalline alumina and the end of the discharge tube 1 shown in the drawing is also provided with a ceramic closure 2 made of alumina. The closure 2 is normally soldered to the discharge tube 1 by soldering 3 made of oxides of various metals, which provides a hermetic seal. The same solder 3 has a solder current 4 in the closure 2 which, since it also serves as a suction tube, is made of a thin-walled niobium tube. After completion of the pumping and filling process, the end 5 of the current lead-in 4 through the sealing element 2 is hermetically sealed and the end 6 of the electrode 7 extends into the end 6 of the electrode 1. The current 4 from the electrode 8 is also fixed by a flap 10, which is implemented by means of a four-jaw flattening device, also by mechanical deformation. Consequently, the inlet cross-section of the current 4 in the region of flattening 10 a

Figure 2 shows a four leaf clover shape. By flattening 10, capillaries 9 are formed in the inlet 4 which are sized to prevent the additive located in the section of the inlet tube 4 between flattening and hermetically sealed end 5 from entering the discharge chamber in a liquid state, but allowing it to travel in vapor phase.

Further steps in the manufacture of the discharge vessel and discharge lamp are well known. You can see the 10 flattening

By placing 1 ^ 6,014 in the discharge tube, the cold chamber, also known as the reservoir, containing the liquid additive extends inside the discharge vessel 1, which in itself ensures the achievement of the intended objectives. Particularly significant advantages are provided by the power supply arrangement according to the invention for small high pressure sodium lamps having a rated power of 50-250 W.

To ensure flawless electrical contact between the current feeder 4 and the electrode rod 8, it is advantageous that the device for drawing the current feeder 4 onto the electrode rod 8 is also a spot welding device which, in addition to mechanical connection, also provides a cohesive connection between said parts.

Claims (3)

An electrical discharge lamp of an electric discharge lamp, in particular a discharge lamp having a power of less than 400 W, which is formed in a closure member hermetically secured to the discharge vessel closure member, which is mechanically and electrically electrically and electrically connected to the electrode rod allows the transport of a vapor-phase additive between the discharge chamber and the cold chamber. _ Capillary component is formed, wherein je 11 e ¹⁰ comprises using as the current supply is rálapítva rain (4) around the electrode (8) inside the arc tube (1) sections. Power supply according to Claim 1, characterized in that it has a four-leaf clover shape in the region of the flattening Ig (10). Power supply according to Claim 1 or 2, characterized in that the current supply (4) and the electrode rod (8) are mechanically flattened and spot welded.