NL8601430A - Discharge lamp with noble gas filling, especially for impulse operation. - Google Patents

Description

NL 33.580-dV / lb *

Discharge lamp with noble gas filling, especially for pulse operation.

The invention relates to a discharge lamp with noble gas filling, in particular for pulse operation, which is suitable for delivering a high power and is provided with a tubular discharge vessel and an anode and a cathode arranged opposite each other in the interior of the discharge vessel. the anode and cathode being connected to associated current input means. A noble gas filling is arranged in the discharge vessel, which, in addition to noble gas, may only comprise mercury and is filled under a pressure of at least 10 millibars. The discharge lamp according to the invention is primarily used in photography, in the energization of lasers, in air and water traffic, in photochemistry and in stroboscopic application, when a specific impulse load of at least 100 J / cm2 is applied. 15 is desired, but the discharge lamp can also be used at lower impulse loads, if the requirements of operational reliability and service life justify this.

It is known that impulse operating light sources, which are designed as a noble gas-filled discharge lamp, are used in many areas of industry (this concerns in particular vehicle repair photography). The most commonly used impulse operating noble gas filling gas discharge light sources are provided with a discharge vessel consisting of normal glass or quartz glass and in manufacture it is important that the ends are cut to the desired size. tubular discharge vessel each time an electrode unit is soldered or otherwise mounted, which is glass-lined or flattened. In the low-power discharge lamps prepared for photographic applications, which are used with a lower number of lifts, such an embodiment is acceptable and the product can be manufactured by the known methods of industrial technology.

Pulse operation, however, means a really high mechanical load, especially at higher powers

860143C

* * - 2 - of the end regions of the discharge vessel of the light source, which leads to erosion of the electrode and thereby to a reduction in the life of the light source.

Increasing the life of such light sources has been the object of many inventions. For example, German Pat. No. 2,848,891 proposes to seal the discharge vessel by flat soldering using a metal plate. US patent 4,315,187 describes the connection of the electrodes to a protection plate at a certain distance from the gas discharge vessel. German Offenlegungsschrift 3,227,280 describes a solution in which the end sealing of the discharge vessel is ensured with a glass disc or a glass ceramic disc.

In the constructions shown, the aim was to increase the mechanical strength of the discharge vessel and to design the discharge vessel such that the shock waves cannot reach the ends of the discharge vessel by making an effective choice of material of the meeting area of the longitudinal shock waves and of the discharge vessel. to achieve. However, the known solutions generally cannot guarantee high power and high reliability at the same time.

The object of the invention is to provide a discharge lamp with noble gas filling, which can deliver a high power and which has a long service life and high reliability in pulse operation. The service life should be several times longer than that of the known light sources in pulse operation.

The invention is based on the insight that with the lamp constructions, which serve to ensure a high power under the conditions of the pulse operation, it is important not only to solder the discharge vessel voltage-free and to realize the end caps with a give the material of the desired strength, but also the wall of the discharge vessel, the necessary high strength. According to the invention, these requirements can best be met with an aluminum oxide ceramic material which is translucent. It should be noted here that aluminum oxide as a material for a ceramic discharge vessel 40 is currently only used in the high-pressure sodium 8601430 "3 - * * vapor lamp, in which glass or quartz cannot be used because of the presence of sodium, because sodium may cause unfavorable recrystallization.

The invention therefore relates to a discharge lamp with a noble gas filling, which is particularly suitable for impulse operation and high specific power output, and which is provided with a tubular discharge vessel and an anode and an anode arranged opposite each other in the interior of the discharge vessel. cathode, the anode and the cathode being connected to associated current input means, while in the discharge vessel a noble gas filling is arranged, which contains only noble gas (argon, xenon, kripton, helium and neon or a mixture of any composition thereof) under pressure of at least 10 millibars, wherein according to the invention the wall of the discharge vessel is formed from translucent ceramic aluminum oxide. The gas discharge light source according to the invention has a construction corresponding to the sodium vapor lamp, but contains a noble gas filling without other additives.

In photochemical applications it may be necessary to require a gas discharge lamp with noble gas filling, which must be able to emit ultraviolet radiation when a high specific power and impulse operation are delivered. This radiation can be achieved in a known manner by adding mercury, since this substance can shift the wave region in the direction of the ultraviolet radiation.

The principle of the invention can also be applied to such a discharge lamp, wherein the noble gas filling then consists of noble gas and mercury under pressure of at least 30 millibars.

Experiments have shown that the translucent ceramic material, consisting of aluminum oxide, is also transparent to ultraviolet radiation.

With regard to reliability and service life, the discharge lamp equipped with a noble gas filling surpasses the gas discharge light sources hitherto used for pulse operation. The construction according to the invention makes possible an increased load on the pipe wall, which leads to a favorable reduction of the size with high-power lamps.

36 C1430; - 4 -

It is advantageous that a higher loading capacity of the ends of the discharge vessel can be achieved when the aluminum oxide ceramic sealing elements are arranged at the ends of the discharge vessel in the same manner as in the case of the high-pressure sodium lamps and the current input means, which are made of a material, the coefficient of thermal expansion of which is adapted to the material of the sealing elements, ie the aluminum oxide ceramic, on the sealing elements and the sealing elements on the discharge vessel are attached in a vacuum-tight manner with a binder. In the production of the high pressure sodium lamps, it is known that the base component of the enamel binder is aluminum oxide, the oxide of other trivalent metals, optionally alkali earth oxide, being admixed, thereby adding the enamel with respect to the melting point and the coefficients of thermal expansion meet the requirements.

Due to the favorable thermal properties, niobium or alloys thereof, tantalum and alloys thereof or other alloys, for example an alloy based on iron, can be used as current input member.

In particular at higher powers it is expedient to assemble the current input members from several wires and to pass them through the closing element in the form of several parallel lines, the lines outside and inside the discharge vessel being reunited. If the power justifies it, it may be expedient to use a single tube instead of a multi-conductor power supply which is passed through the closure member.

The aforementioned method for sealing the ends of the discharge vessel offers the possibility of an asymmetrical design of the electrodes (anode, cathode), so that the adverse influence of the shock waves in the discharge vessel can be reduced. It is expedient to arrange the electrodes in such a way that they stick into the discharge vessel in such a way that half of the distance between the two electrode tips becomes smaller than 0.35 times the distance between the two tube ends. however, asymmetric 40 should be applied in such a way that the half-point of the 8601430-5 distance between the two electrodes and the half-point between the two tube ends are shifted relative to each other by at least 0.03 times the distance between the tube ends .

The invention is further elucidated with reference to the drawing, in which an exemplary embodiment is shown.

Fig. 1 is an embodiment of the light source according to the invention with gas discharge.

FIG. 2 is an outer balloon mounted embodiment of the light source according to the invention with gas discharge.

Depending on the respective field of application, the power and other special requirements, the pulse discharge light sources operating in pulse mode can be manufactured with different noble gas types (xenon, krypton, neon or helium). However, the gas quality does not affect the construction shape, the dimensions of course depend on the power.

The embodiment of FIG. 1 does not have an outer balloon, while FIG. 2 shows a gas discharge and impulse mode light source configured with an outer balloon. The balloon should be used there, whereby the tube ends may be heated to a temperature higher than 200-300 ° C or where the ambient air is humid due to the elevated lamp power.

As an example, the manufacture of an impulse operating gas discharge light source with noble gas filling with an impulse energy of 500 Ws and a nominal voltage of 1500 V is described.

The discharge lamp according to the invention is provided with a tubular discharge vessel 1 with stop-shaped sealing elements 2 and 3 made of aluminum oxide ceramic. The discharge vessel 1 is 80 mm long, has an inner diameter of 4.8 mm, and 35 is made of aluminum oxide ceramic. The shut-off elements 2 and 3 are provided with electrode armatures, which consist of an anode 4 resp. cathode 5 and current input members 6.7. The material of the current input members 6, 7 is niobium with a zircon content of 1% and the wire diameter 40 is 0.7 mm. The anode 4 is formed by an unactive

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- 6 - Spring tungsten block, possibly a cylindrical block wrapped with tungsten wire. The cathode 5 is activated tungsten, which is wound in a cylindrical shape.

The electrode luminaires are attached to the cathode resp.

5, the anode side is designed differently, such that a longer path of the current input member 7 than at the current input member 6 is soldered into the discharge vessel 1, so that the asymmetry of the arrangement of the electrodes, which in this case is 3 mm, is ensured. . The flow input member 7 is attached to the closure element 3 with an enamel binder and the closure element 3 is simultaneously attached to the end of the discharge vessel 1 by means of an enamel ring. As the enamel, a mixture of aluminum oxide and alkaline earth is used, which is set at a melting point of 1350 ° C. The enamel is heated, melted in vacuum or under a shielding gas, then cooled; then the entire armature is turned over, the closure element 2 with the electrode armature containing the anode 4 and the enamel binder is placed in the end of the discharge vessel 1; the whole is heated to the melting point, during which time the discharge vessel 1 is evacuated to vacuum; even before melting, the filling gas, for example xenon, is supplied with suitable pressure, after which the armature is cooled and the discharge vessel 1 is soldered. After the soldering has been carried out, the pressure of the xenon gas in the discharge vessel is 300 millibars, while the distance between the ends of the electrodes is 43 mm. The embodiment described here forms a light source with gas discharge and without suction tube. (It should be noted that soldering the two pipe ends at the same time can of course also be solved.) In the so-called version with suction tube, in which a niobium tube is used as the current-supplying member and suction tube, the steps of soldering and emptying respectively. filling with gas must be carried out separately. A solution with suction tube can be motivated when filling gas with a relatively high pressure, otherwise this embodiment forms a more expensive solution.

In the embodiment according to Fig. 2, the soldered discharge vessel 1 is mounted on a holder 8 and 8, respectively. 9 and 40 in a tubular outer balloon 10 of borosilicate hard glass 8 6 0 14 3 0 - 7 glass. After evacuation to vacuum, the outer balloon 10 is suitably filled with argon to about atmospheric pressure, soldered and fitted with a head 11 with Edison fitting.

5 A flash lamp, which generates ultraviolet radiation for the photopolymerization, uses four series-connected gas discharge lamps, which are fed via a capacitor of 15 jaF from a voltage source of 1500 V. The light sources of the flash lamp are made with an inner diameter of 8 mm, the distance from the ends of the electrodes being 46 mm and the discharge vessel containing xenon under pressure of 160 millibars and mercury in an amount which ensures the saturated vapor pressure.

Using the same technique, light sources according to the invention can be manufactured with different dimensions and with other noble gas filling. It is also possible to manufacture light sources falling under the scope of protection using other techniques.

δ s 0 1 430

Claims (8)

1. Discharge lamp with noble gas filling, in particular for impulse operation, comprising a tubular discharge vessel and an anode and cathode arranged in the interior of the discharge vessel, the anode and the cathode being connected to associated current input means, the noble gas filling contains only noble gas under pressure of at least 10 millibar, characterized in that the wall of the discharge vessel (1) is formed of translucent ceramic aluminum oxide. 2. Discharge lamp with noble gas filling, in particular for pulse operation, comprising a tubular discharge vessel and an anode and cathode arranged in the interior of the discharge vessel, the anode and the cathode being connected to associated current input means, the noble gas filling being exclusively contains noble gas and mercury with a gas pressure of at least 10 millibars, characterized in that the wall of the discharge vessel (1) is formed of translucent ceramic aluminum oxide. Discharge lamp according to claim 1 or 2, characterized in that sealing elements (2, 3) consisting of translucent ceramic alumina are arranged at the ends of the tubular discharge vessel (1), the sealing elements (2, 3) and the current input means (6, 7) are made of a material having a coefficient of thermal expansion in the same area and a vacuum-tight connection is present between the sealing elements (2, 3) and the discharge vessel (1). Discharge lamp according to any one of the preceding claims, characterized in that the current input means (6, 7) consist of niobium or a niobium alloy. Discharge lamp according to any one of claims 1 to 3, characterized in that the current input means (6, 7) consist of tantalum or a tantalum alloy. Discharge lamp according to any one of the preceding claims, characterized in that the current input means (6, 7) are formed from a plurality of wires guided in parallel by the sealing elements (2, 3). Discharge lamp according to any one of claims 1 to 5, 8601430-9 - characterized in that the current input means (6, 7) are formed as tubes passed through the closing elements (2, 3). Discharge lamp according to one of the preceding claims, characterized in that the distance between the parts of the anode (4) and the cathode {5) projecting into the interior of the discharge vessel (1) is at most 0.35 times. is as great as the distance between the ends of the discharge vessel (1), the anode (4) and the cathode (5) being arranged asymmetrically in the discharge vessel (1) relative to each other such that the half-point of the distance between the anode (4) and the cathode (5) and the halving point of the distance between the ends of the discharge vessel (1) are shifted by at least 0.03 times the distance of the two ends. 8601430