NL7907437A - Sodium vapour discharge lamp - has auxiliary conductor lying along outer surface of tube to assist in starting - Google Patents

Abstract

The high pressure sodium vapour discharge lamp includes an outer envelope enclosing a discharge tube in a vacuum. The discharge tube itself comprises a clear envelope of chemically stable material enclosing sodium, xenon and a buffer gas which is one of the group including mercury and cadmium. Two electrodes are sealed into the two ends of the tube. One of the discharge electrodes (4) includes a projecting conductor (9) which extends from the electrode towards the inner surface of the side wall of the tube, with a set gap separating it from the wall. A conductor (8) intended to assist starting is placed longitudinally on the outside surface of the wall, with one end being opposite the conductor inside the wall. This conductor is connected to a voltage equal to that on the other discharge electrode. The conductor is arranged to be disconnected when the temperature of the lamp reaches a chosen level by a bimetal switch.

Description

ê * 49 335 / AH / AS ... 1_

High pressure sodium vapor discharge lamp.

The invention relates to a high pressure sodium vapor discharge lamp, which consists of a translucent gas discharge tube, which contains sodium vapor, a buffer gas and xenon gas.

In general, high pressure sodium vapor discharge lamps have twice the efficiency of conventional high pressure mercury lamps and further exhibit a convenient color effect and therefore attract attention as energy-saving light sources in order to replace the high pressure mercury lamp in the near future. . In a discharge tube of a conventional high pressure sodium vapor discharge lamp, the xenon gas is sealed airtight under a pressure of can 20. Torr as a starting gas with a low thermal conductivity. By adding the xenon gas, the starting voltage of the high pressure sodium vapor discharge lamp becomes about 2 kV, which is very high relative to the starting voltage of less than 200 V of the mercury lamp. Furthermore, a high pressure sodium vapor 20 discharge lamp of high efficiency has been proposed, in which xenon was introduced under a pressure of more than 150 Torr, for example 350 Torr, whereby the lamp efficiency was about 10% higher than that of a with xenon gas below a pressure of about 20 Torr filled lamp. In such a lamp with xenon gas

under high pressure the starting voltage of the lamp increases even further, for instance to about 8 to 9 kV for a high pressure sodium vapor discharge lamp, filled with xenon gas under a pressure of 350 Torr. In such a lamp, the starting voltage can be reduced to about 3.5 kV for a high pressure sodium discharge lamp of 360 W when using a jump starter wire, but such a voltage of 3.5 kV

7907437 _2 _ \ ΐ is still higher for actual use and exposed to the risk of initiating a breakdown of the ballast insulation and associated lamp circuit.

The object of the invention is to provide a high-pressure sodium vapor discharge lamp, filled with xenon gas under very high pressure, but with a low starting voltage, which makes it possible to provide a lamp construction without the risk of insulation breakdown.

This object is achieved according to the invention by using a starting auxiliary guide formed along its length on the outer wall of a discharge tube thereof and further using a projecting portion of a conductor emerging from the electrode protrudes in the direction of the pipe wall and is connected to one electrode.

According to the invention, the starting voltage of the high pressure sodium vapor discharge lamp with a high pressure xenon gas of 150-350 Torr can be reduced to a low voltage of 3 kV or less.

The invention will be explained in more detail below with reference to the drawing, which shows by way of example a favorable embodiment of the discharge lamp according to the invention. Herein shows:

Fig. 1 shows a top view of a discharge tube of a high-pressure sodium vapor discharge lamp 30 without protruding conductor part on its electrodes, FIG. 2 is a longitudinal section of the lamp of FIG. 1,

Fig. 3 is a graph of the DC starting voltage of the discharge tube of FIG. 1 and 2 as a function of the distance f from the end 7907437. 3 _ K 4 from an electrode to the end of an auxiliary starting conductor,

Fig. 4 is an enlarged partial side view and partly a longitudinal section 5 of a favorable embodiment of the high-pressure sodium vapor discharge lamp according to the invention,

Fig. 5 is a side view of an embodiment of the high-pressure sodium vapor discharge lamp, in which the discharge tube 100 of FIG. 4 is enclosed in a vacuum-drawn glass balloon 21,

Fig. 6 is a graph of the DC starting voltage of the lamp of FIGS. 4 and 5 as a function of the gap distance d from the end of a conductor projection 9 of an electrode 6 to 15 the inner surface of a tube wall of the discharge tube of FIG. 4, and

Fig. 7 shows the electrical circuit diagram of the lighting device in which the lamp according to FIG. 5 is used.

A favorable embodiment of the high-pressure sodium vapor discharge lamp according to the invention consists of an outer balloon, in which vacuum-sucked space a discharge tube is enclosed, which consists of a transparent and chemically stable tube envelope, in which sodium vapor, xenon gas and a buffer gas are contained. of which the buffer gas consists of mercury and / or cadmium, discharge electrodes are sealed at the two end parts of the tube envelope, the lamp being characterized in that, first of all, the withholding electrodes are provided with a protruding conductor part. extends from this electrode in the direction of an up to close to an inner surface of a side wall of the pipe casing with a predetermined gap therebetween, and that a starting auxiliary guide 7907437 * 4 is placed longitudinally on the outer surface of this side wall in such a way that this starting aid guide is opposite the outer end portion of the projection conductor part via the side wall, which starting auxiliary conductor has a connection which imprints a potential corresponding or substantially corresponding to that of the other discharge electrode.

In carrying out tests with regard to the starting characteristics of high-pressure sodium vapor discharge lamps filled with xenon gas as starting gas, it has been found according to the invention that the starting voltage of the lamp can be greatly reduced by providing an excellent part of a (metal) conductor, which protrudes from one of the electrodes towards the inner surface of the side wall of the pipe casing, providing a starting auxiliary conductor strip (wire) to the outer surface of this side wall, and applying the potential, which matches whether after-20 matches that of the other electrode enough on the jump starter.

As shown in Figures 1 and 2, the discharge tube, which is placed in a vacuum-drawn outer glass balloon, has a translucent tube envelope 1, 25 formed from a ceramic polycrystalline aluminum oxide tube or a single crystal aluminum tube, as well as a pair of electrodes 6 and 7. The electrodes 6 and 7 are formed of tungsten coil windings in which an electron-emitting material 30 is held and are located close to the both ends of the tube casing 1, being carried by niobium tube lead-in wires 4 and 5, which penetrate the casing and are attached to end plugs 2 and 3. In the tube casing 35 1, there is entrapped sodium as light-emitting 7907437-5 - «* material, mercury as a buffer gas and xenon as a rare starting gas. A starting auxiliary conductor strip 8, formed of 0.8 mm diameter molybdenum wire, is placed on the outer surface of the wall of the tube casing 1 and is connected to the one electrode terminal 5.

According to the invention, it has been tried experimentally to investigate how the starting voltage of the discharge tube changes when one end b of the starting auxiliary conductor 8 changes position with respect to one electrode 6, while the other end a as the remains in place at the end of the sheath 1 and is electrically connected to the other electrode 7 so that the potential of the other electrode 7 is pushed onto the starting auxiliary conductor 8. FIG. 3 shows a graph of the manner in which the starting voltage (for which a DC voltage has been selected in the tests carried out) depends on the distance f from the end of the electrode 6 to the end of the starting auxiliary conductor 8. The various curves in this graph have resp. refers to pressures of 350 Torr, 250 Torr and 20 Torr and the xenon gas with which the tube casing 1 is filled. As shown in FIG. 3, the starting voltage appears to be the greatest when the end of the starting auxiliary conductor 8 is as close as possible to the electrode 6. The starting voltage is namely depending on the distance f between the end of the jump start guide and the end of the electrode 6 and decreases as the distance f becomes shorter.

According to the invention, to provide a high pressure 260 W mercury vapor discharge lamp, an aluminum oxide discharge tube having an inner diameter of 7.4 mm was used, 79074 37.6.

Z r \ a tube thickness of 0.7 mm and a distance of 83 mm between the electrodes. As shown in Fig. 4, a protruding conductor part 9 was formed on the electrode 6 and the starting voltages were measured for 5 different gap distances d between the end of the protruding conductor part 9 and the inner surface e of the tube wall 1. As protruding conductor part 9 use a 0.7 mm diameter molybdenum rod attached to a stem-10 portion of the wool frame winding of the electrode 6 by spot welding. The results of the measurement results are shown in the graph according to Fig. 6, in which the curves with respect to those in Fig. 3 show a drastic improvement in the starting voltage due to the application of the protruding conductor part 9.

Similar tests were performed for lamps of different power, yielding similar results. In particular for high power lamps of 700 and 1000 W, the starting voltages are considerably reduced. This can be explained by the fact that in such high power lamps, where the gap d between the end surface of the electrode and the inner surface 25 e of the tube wall 1 is large, and therefore the provision of only a starting auxiliary guide 8 on the outer surface of the pipe wall 1 does not significantly reduce the starting voltage, thus applying the protruding conductor part 9, which protrudes in the direction of the starting auxiliary conductor 8, can effectively increase the potential gradient in the gap.

Below are some technical data of a practical exemplary embodiment of the discharge lamp manufactured according to the invention: 79074 37 _ 7 ~

Jr m

tube input power ...................... 360 W.

discharge tube 1: inner diameter ......... 7.4 mm tube thickness .............. 0.7 mm distance between the 5 electrodes ......... ... 83 mm material .......... only crystal-alumina electrodes 6, 7: outer diameter of spiral ............ 3.6 mm 10 starting auxiliary conductor 8: molybdenum wire of .. 0.8 mm protruding conductor part 9: molybdenum wire of ........... 0.7 mm distance d ..................... ........... 0.5 mm enclosed gas: sodium .................. 4.5 mg 15 mercury ....... .............. 20 mg xenon gas .................. 350 Torr

The starting aid conductor 8 is connected to the electrode 7 via a bimetal switch 10 as shown in Fig. 7, which is opened in response 20 at a high temperature of the discharge tube 1 in order to disconnect the starting aid guide 8 from the opposite electrode 7 after the ignite to prevent sodium loss from the discharge tube due to an unnecessary connection of the jump starter 8 to the electrode 7.

Fig. 7 shows the electrical circuit diagram of this embodiment of the decomposition lamp according to the invention. A conventional alternating current is fed through a single wire coil ballast 14 for a conventional 400 W mercury lamp to the high pressure sodium vapor discharge lamp 15 of the invention, wherein in the balloon 21 or in the part 22 (FIG. 5) a bimetal starter switch 12, a series resistor 11, a ceramic capacitor 13 of 3000 pF and a bimetal switch 10 are provided. As in the circuit diagram according to Fig. 5 79074 37

i «W

shown, the capacitor 13 and the series circuit formed by the resistor 11 and the switch 12 are connected in parallel across the terminals 4 and 5 of the discharge tube, so that the lamp 15 can be started in a known manner by supplying a ignition voltage through the cord coil 14, The series resistor 11 serves to limit the cut-off current of the bimetal starter switch 12 to a value of 0.5 A and must also cause the bimetal 10 starter switch 12 to open due to the joule -heat effect of this flow. The capacitor 13 is used to suppress the delivery of an extremely high ignition voltage and also to form the ignition voltage pulse to obtain a sufficient pulse width. Capacitor 13 serves namely. for protecting the lamp arrangement against damage from insulation penetration and also ensuring the starting effect. Tests have shown that the starting voltage for the 360 W lamp from the above exemplary embodiment is approx. 2 kV and, on the other hand, the average value of induced high voltages across the terminals of the discharge tube 100 is approx.

2.5 kV, which has sufficient influence higher than the starting voltage of the lamp, as a result of which the lamp can be started with a high reliability. Furthermore, during operating tests of the lamp, in view of the low value of the induced high voltage in the lamp arrangement relative to the conventional high-pressure sodium vapor discharge lamps, no insulation breakdown of the cord coil (ballast) and electric chain has been found.

Furthermore, the improved lamp characteristics according to the invention have been tested on a further embodiment, namely a lamp of 630 W with 7907437 9 ar -λ, the same construction data as in the previous embodiment, with the exception of the following values; the inner diameter of the discharge tube 5 of polycrystalline alumina ......... 9.7 mm distance between the electrodes ............... 130 mm distance d ..... ............................. 0.5 mm

This embodiment of a 630 W lamp has a starting voltage which is almost as low as that of the previous embodiment of the 360 W lamp, while the starting voltage of a lamp of 630 W without protruding conductor 9 is 4.5 kV, this is about 1.0 kV more than in the aforementioned exemplary embodiment of the 15 360 W lamp. The 630 W lamp can be reliably and stably started using a conventional single cord coil ballast for a 700 W mercury lamp.

The protruding conductor part 9 need not necessarily be rod-shaped, but may also be in the form of a ring or a disc.

The meaning of the protruding conductor part 9 consists in that for the distance d between the inner surface e of the pipe wall 1 and the outer end of the protruding conductor part 9, it is chosen a certain short distance, which lies between 0.3 and 0 , 7 mm. If the distance d is chosen to be longer than 0.7 mm, the starting voltage will not be reduced sufficiently. If, on the other hand, the distance d 30 is chosen to be shorter than 0.3 mm, as a result of this short gap distance, each ignition discharge will always concentrate in a very small area, which increases the chance that this area will be exposed to an undesired effect, whereby weather The probability is increased to form cracks 79074 37-10 on the tube casing. It has been found experimentally that the optimum distance is between 0.4 and 0.6 mm.

Conclusions.

790 74 37

Claims (7)

1. High-pressure sodium vapor discharge lamp, consisting of an outer balloon, in a vacuum-sucked space of which a discharge tube is enclosed, which tube consists of a transparent and chemically stable tube casing, containing sodium and xenon gas, as well as a buffer gas, which consists of mercury and / or cadmium, while further discharge electrodes are sealed at both ends; parts of the tube casing, characterized in that at least one of the discharge electrodes has a protruding conductor part which protrudes from this electrode in the direction of the inner surface of a side wall of the tube casing close to this inner surface with a predetermined 15 defined gap distance therebetween, and that a starting auxiliary guide is arranged longitudinally on the outer surface of the side wall such that it is opposite the outer end of the protruding conductor portion with the side wall therebetween, which starting auxiliary guide has a potential potential printed, which corresponds or substantially matches that of the other discharge electrode. 2. High pressure sodium vapor discharge lamp according to claim 1, characterized in that the xenon gas is contained under a pressure of 150 Torr (mnHg) or more. 3. High pressure sodium vapor discharge lamp according to claim 1, characterized in that the predetermined gap distance between the outer end of the protruding conductor part and the inner surface of the side wall is between 0.3 and 0.7 mm. High-pressure sodium vapor discharge lamp 5 according to claim 1, characterized in that the electrical circuit comprises a switch which is opened after closing the discharge tube discharge. High pressure sodium dap discharge lamp 10 according to claim 4, characterized in that the switch is a bimetal switch which is opened when exposed to heat from the discharge tube. 6. High pressure sodium vapor discharge lamp according to claim 1, characterized in that the discharge lamp further comprises a capacitor and a series circuit formed by a starting switch and a current control resistor, which capacitor and. series chain are connected in parallel across the two discharge electrodes. High pressure sodium vapor discharge lamp according to claim 1, characterized in that the protruding conductor part and the starting auxiliary conductor are formed from molybdenum wires. 7907437