DE2324090A1 - HIGH PRESSURE GAS DISCHARGE LAMP - Google Patents

Description

PHN. 6500.

Note—: UV.i-; J. _ · .. ,, ^ UaiPcrti AERiEKEN
Αί, ίο: PHH- 6300

Registration dated ι 9 · Μ & ί 1973

High pressure gas discharge lamp.

The invention relates to a high-pressure gas discharge lamp with a discharge vessel that contains substances which are gaseous and / or vaporous when the lamp is in operation and at least one of which is a saturated vapor when the lamp is in operation supplies, and which has an outer coating at its end provided with an electrode. The invention further relates to a method for applying an outer coating to such a lamp.

A lamp of the type mentioned contains substance that has not yet been steamed when it is in operation. This unevaporated substance is located generally at the point in the lamp where the temperature is lowest. The mentioned lowest temperature is determined then the vapor pressure of the substance in question. In some cases

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the point with the lowest temperature is on the part of the wall of the discharge vessel around the electrodes and lies behind them. A control of the temperature in the room around the electrodes and behind them, e.g. by means of an appropriate Dimensioning the electrode space is difficult to carry out due to the presence of power supply lines connected to it Place are passed through the wall of the discharge vessel. The implementation of a power supply line can, for example, be carried out using a vacuum seal Melting into the material of the discharge vessel take place. Such a meltdown entails considerable restrictions in practice with regard to the dimensioning of the electrode space and the reproducibility of the chosen shape of this space. One episode The inadequate control of the lowest temperature in the lamp is that the lamps differ significantly from one another with regard to the light efficiency and the spectral distribution of the emitted radiation.

A solution to the problem described is possible if the temperature of the wall of the discharge vessel around the electrodes is measured around and behind them, bringing the point of lowest temperature to the appropriately sized central part of the Discharge vessel is moved. To increase the temperature of the To get around the electrodes and behind them part of the wall of the discharge vessel, it is known on the mentioned To apply an outer coating to part of the wall of the discharge vessel, which covers at least part of the incident radiation (ultraviolet radiation, visible radiation and infrared radiation) reflected or absorbed.

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As is known, thin reflective metal layers, for example made of gold or silver alloys, can be used as the outer coating. However, such metal layers have the disadvantage that they cannot withstand ^{temperatures of more than approximately 700 e G.}

It is also known to apply reflective white oxide layers, for example made of zirconium oxide, titanium oxide or aluminum oxide, as the outer coating. A disadvantage of these oxide layers is that they are difficult to apply. In order to achieve the desired effect, the oxide layers have to be relatively thick, which results in poor adhesion to the wall of the discharge vessel.

A disadvantage of both the metal layers and the white oxide layers is that they form a large part of the conspicuous Reflect radiation without causing an increase in the temperature of the wall of the discharge vessel.

Finally, it is known to use black layers, e.g. made of carbon, in order to control the temperature of the electrode surrounding wall part to increase. A disadvantage of these black layers, which is actually a very large part of the striking Absorbing radiation is that they largely re-emit the absorbed radiation.

The aim of the invention is to create an outer cover for the discharge vessel of a high-pressure gas discharge lamp, with the higher temperatures of the coated part of the wall of the discharge vessel compared to the known coatings are, while the aforementioned disadvantages do not occur.

A high-pressure gas discharge lamp mentioned at the beginning

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According to the invention, the type is characterized in that the coating made of a first layer that lies on the wall of the discharge vessel and a black or dark gray material with a high melting point and low vapor pressure, and consists of a second layer lying on top of the first layer and a white or almost white one contains white substances with a high melting point and low vapor pressure.

, It has been found that with a lamp according to according to the invention, a considerably greater increase in the temperature of the wall part around the electrode and behind it is obtained than when using the known reflective or absorbent layers. Even with very high average wall loads (e.g. cm) it has been found that there is no non-vaporized Fabric is present, which indicates that the coldest point in the lamp is on the middle part of the wall of the Discharge vessel lies. The use of a black or dark gray fabric in the first directly on the wall of the discharge vessel A layer lying on a lamp according to the invention has the advantage that practically all of the incident radiation is absorbed will. This leads to a greater temperature increase in the wall material than in the case of total reflection of the incident radiation. In a lamp according to the invention, the use of a second reflective and thus poorly emitting lamp Layer prevents the heat absorbed in the first layer from being lost again through radiation to the outside.

Because the combination according to the invention of a black absorbent layer and a white reflective layer

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Layer has a significantly greater temperature-increasing effect than the known individual layers of absorbent material suffice in a lamp according to the invention for bringing about the same temperature increase thinner layers than with the known lamps. This is an important advantage because it is known to be thin Layers generally adhere better than thick layers. It has also been found that white layers in general adhere better to a black layer than to the material of the discharge vessel, which is often made of quartz glass. With a lamp according to the invention can thus while maintaining good adhesion the second, white layer can be used in a greater thickness than is possible with the known lamps with only one white layer. A lamp according to the invention also has the advantage that a more even temperature distribution over the wall of the discharge vessel results, so that large temperature differences along the wall are avoided.

In this context, a black or dark gray substance is to be understood as a substance that has a reflectance of at most 0.2. A white or almost white substance is to be understood as meaning a substance that has a degree of reflection of at least 0.5. If these substances are applied to the discharge vessel in the form of a layer, the degree of reflection of the layer may differ somewhat from that of the substances themselves. It is of course necessary that the substances used for the two layers have a high melting point (for example above 1000 ^° K). It is also necessary that these substances have a low vapor tension (eg less than 10 Torr at 1200 "K).

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The material used for the first layer is preferably carbon, carbides (e.g. tungsten carbide), silicates (e.g. tungsten silicate or molybdenum silicate), borates (e.g. molybdenum borate) or mixtures of these substances and the material for the second layer is at least one ceramic oxide (e.g. calcium oxide, magnesium oxide, Zirconium oxide, aluminum oxide and Thoriümöx-id) were chosen.

In a preferred embodiment of a lamp according to According to the invention, the first layer consists essentially of carbon or graphite and the second layer consists essentially of Zirconia, because these materials give the best results. It was also found that these materials easily get in good shape apply adhesive layers.

In a lamp according to the invention the outer TTeberzug is preferably around the electrode and extends to hbchstens 5 ro ^m beyond the discharge end of the electrode facing. If the coating were to extend further towards the middle part of the discharge vessel, too large a part of the useful radiation emitted by the lamp would be absorbed.

A lamp according to the invention can, for example, be a high pressure sodium vapor Discharge lamp with a discharge vessel made of e.g. polycrystalline aluminum oxide, sodium, mercury and contains an inert gas. In such a lamp, the sodium and the mercury are present in excess, so that the lamp is in operation saturated sodium and mercury vapors are produced. A good command of the lowest temperature and thus the sodium and Mercury vapor pressure is very important for the lamp to work properly.

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The invention can be used with particular advantage in a

Find high pressure gas discharge lamp application, their discharge vessel consists of quartz glass or hard glass and is filled with mercury, at least one noble gas and at least one metal halide. Included the coating around the electrode (and possibly also around at least a part of the fuse of the power supply line) attached, with this covering up to a maximum of 2 mm on the other side of the Discharge facing end of the electrode extends. In these at least Halogen containing lamps are often used, which evaporate only with difficulty (e.g. sodium iodide and the iodides of the rare earth metals). These halides are present in excess. In such a lamp according to the invention containing at least one halide, it is particularly advantageous that in addition to a shift of the coldest point of the lamp to the middle part of the discharge vessel, resulting in reproducible lamps » also an increase in the lowest temperature prevailing in the lamp occurs. As a result, a larger amount of the hard-to-evaporate halide can be brought into the discharge, thereby causing the efficiency of the lamp and the spectral distribution of the emitted radiation can be influenced favorably.

It is generally preferred to have both ends of the discharge vessel a lamp according to the invention with an outer Cover to be provided to the temperature of the wall of the discharge vessel around both electrodes (and possibly behind them).

Preferably, an outer cover that consists of a first layer of carbon and a second layer of zirconia

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oxide is applied to a high-pressure gas discharge lamp using a method according to the invention, in which the end of the discharge vessel near the electrode is coated with a first layer of a graphite suspension which, after drying, is in turn coated with a second layer consisting of a suspension consists of zirconium oxide in a solvent and a binder-containing suspension medium, after which the coating thus obtained is then dried and heated in air to a temperature of 25O ⁰ C to 500 ⁰ C. The suspension layers can be applied, for example, by dipping, spraying or painting with a brush. When heating the coating at 250 ⁰ C - 500 ⁰ C, the suspension medium and the binder are expelled and there is good adhesion of the layers to one another and to the discharge vessel.

It is useful in a method according to the invention as the first layer a colloidal solution of graphite in water (e.g. the product known under the trade name "Aquadag") and as second layer a suspension of zirconium oxide in an organic solvent (e.g. butyl acetate) containing an organic binder (e.g. Nitrocellulose) is used. By applying an aqueous This is because the suspension for the first layer and an organic suspension for the second layer is a mixture of the two Layers that would result in an undesirable graying of the white zirconium oxide layer are practically excluded.

An embodiment of the invention is explained in more detail below with reference to the drawing.

The drawing shows a high-pressure gas discharge lamp according to the invention, which is suitable for a power of 2000 W. '' The discharge vessel made of quartz glass has a cylindrical

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drical part 1, which has an outer diameter of about 30 mm. Conical parts 2 and 2 are connected to the two ends of part 1 and are closed by pinch feet 4 and 5, respectively. In the pinch feet 4 and 5, power supply elements 6 and 1, respectively, are fused in a vacuum-tight manner. These current supply elements are connected within the discharge vessel to electrodes 8 and 9, which consist of tungsten filaments attached to tungsten pins. The distance between the two electrodes 8 and 9 is approximately 100 mm. In practice, the lamp is mostly housed in an external bulb (not shown) that is evacuated or filled with an inert gas. The discharge vessel is filled with 150 mg Hg, 6 mg Dy, 12 mg HgI ₃ , 5 mg TlI, 3 mg CsI and 0.3 mg NaI and also with argon under a pressure of 20 Torr.

The dysprosiumjοdid that formed in operation of the lamp and the sodium iodide are also present in excess, i.e. that in operation there is a saturated vapor of dysprosium iodide and Sodium iodide forms while still unevaporated Dysproeiurajodid and Sodium iodide are present. These unevaporated iodides are located at the points on the wall of the discharge vessel that have the lowest temperature. In order to prevent that the point with the lowest temperature is on the one surrounding the electrode 8 Part of the wall of the discharge vessel (the conical part 2 and part of the pinch foot 4) is an outer coating 10 is applied to the part of the discharge vessel lying around the electrode 8 and behind it. The TJeberzug 10 lies on one Part of the pinch foot 4 and extends on the conical part 2 up to a distance of a few mm from the tip of the electrode

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The coating 10 consists of a first carbon layer lying directly on the quartz glass, which is applied by means of an "Aquadag" suspension, and a second zirconium oxide layer lying on the first layer. The zirconia layer is. by means of a suspension of 150 g ZrOp in I50 g Bu ty lace fact, the 5 wt. 'contains fo nitrocellulose applied. The electrode 9 is of a. Covering 11, which corresponds to the coating 10.

It has been found that when the lamp described is in operation, the point with the lowest temperature on the Wall of the discharge vessel is on the cylindrical part 1. When the lamp is in operation, non-evaporated iodide is perceived on the cylindrical part 1 approximately at the level of the arrow 12, when the lamp is operated in a vertical position. At the lamp was a lamp current of 9 * 7 A, a lamp voltage of 230 V, a luminous flux of about 170,000 Im, a color temperature of the emitted radiation of about 65OO K and a color rendering index Ba of more than 85 measured.

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Claims (7)

-11- PHN. 6300. 2324030 PATENT CLAIMS : Γΐ. ) High pressure gas discharge lamp with a discharge vessel, that contains substances that are gaseous and / or vaporous during operation of the lamp and at least one of which, in operation, supplies a saturated vapor, and that provided with an electrode on it The end has an outer coating, characterized in that the coating of a first layer, which is on the wall of the discharge vessel and contains a black or dark gray substance with a high melting point and low vapor pressure, and of a The second layer, which lies on top of the first layer, consists of a white or almost white material with a high melting point and a low one Contains vapor pressure. 2. High-pressure gas discharge lamp according to claim 1, characterized in that the first layer consists essentially of at least one of the substances carbon, carbides, silicates and borates and the second layer consists essentially of at least one ceramic oxide. 3. High-pressure gas discharge lamp according to claim 1 or 2, characterized in that the first layer consists essentially of Carbon and the second layer consisting essentially of zirconium oxide consists. 4 »high pressure gas discharge lamp according to claim 1, 2 or characterized in that the coating surrounds the electrode and * up to a maximum of 5 mm from the end of the Electrode extends. 5. High pressure gas discharge lamp according to one or more of the preceding claims, in which the discharge vessel made of quartz 309849/0431 -12- PHN. 6300. 2324030 glass or hard glass and with mercury, one or more Noble gases and one or more ketallhalogeniden is filled, characterized in that the coating surrounds the electrode and extends up to a maximum of 2 mm to the end of the electrode facing the discharge. 6. A method for applying an outer TJeberzuges on a high pressure gas discharge lamp according to claim 3 »4 or 5» characterized in that the end of the discharge vessel near the electrode is coated with a first layer of a graphite suspension and the first layer after drying with a second layer is coated, which consists of a suspension of zirconium oxide in a suspension medium containing a solvent and a binder, and that the resulting coating is heated to a temperature of 250 "- 500 ⁰ C after drying in air. 7. The method according to claim 6, characterized in that a colloidal solution of graphite in for the first layer Water and, for the second layer, a suspension of zirconium oxide in an organic solvent containing an organic binder contains is used. 309849/0431