EP1735814A2

EP1735814A2 - High-pressure discharge lamp

Info

Publication number: EP1735814A2
Application number: EP05742319A
Authority: EP
Inventors: Michael Brinkhoff; Hans-Jürgen Keck; Rainer Kling
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 2004-04-16
Filing date: 2005-04-14
Publication date: 2006-12-27
Anticipated expiration: 2025-04-14
Also published as: US20070200504A1; WO2005101455A2; DE102004019185A1; CN100585790C; CA2562726A1; US7973482B2; JP2007533087A; JP4560085B2; CN1943005A; DE112005001399A5; WO2005101455A3; EP1735814B1

Abstract

A high-pressure discharge lamp with an axial symmetry axis and metal halogenide filling has electrodes with shafts designed as pins with a diameter of 0.5 to 1.15 mm. The halogen for the halogenide is composed of iodine and possibly bromine components, iodine being used alone or in combination with bromine, and the bromine/iodine atomic ratio amounting to maximum 2.

Description

High pressure discharge lamp

Technical field

The invention is based on a high-pressure discharge lamp according to the preamble of claim 1. These are metal halide lamps with double-sided squeezing with a high output of at least 1600 W. The invention further relates to an associated luminaire.

State of the art

Such lamps are known from EP 391 283 and EP 451 647. They are generally suitable for horizontal and vertical arrangement in a reflector.

From DE-A 38 29 156 a generic lamp is known which recommends a relatively high bromine / iodine ratio of 1.5 to 4. Therefore, a relatively large diameter of the shafts of the electrodes of 1.5 to 2 mm is necessary because bromine strongly attacks the shafts.

Presentation of the invention

It is an object of the present invention to provide a high-pressure discharge lamp according to the preamble of claim 1, in which the service life satisfies high requirements, in particular in which the decrease in the transparency of the discharge vessel over the service life is largely eliminated.

This object is achieved by the characterizing features of claim 1. Particularly advantageous refinements can be found in the dependent claims.

In particular, a discharge lamp is presented that is suitable for both horizontal and vertical operation in a luminaire. This high-pressure discharge lamp has the features of an elongate discharge vessel as the only against the piston, which defines an axial axis of symmetry and which is sealed on two sides by sealing parts, for example by squeezing or melting, and which encloses a discharge volume, with two electrodes on the axis facing each other, and which has an ionizable filling made of mercury, noble gas and metal halides contains, as well as power supplies, which are connected to the electrodes via foils and which exit at the ends of the discharge vessel, the lamp consuming at least 1600 W. The shafts are designed as pins with a diameter of 0.5 to 1.15 mm. At the same time, the halogen for the halides is composed of the components iodine and possibly bromine, either only iodine or bromine and iodine being used together, the atomic ratio bromine / iodine being a maximum of 2. It is preferably a maximum of only 1.45.

To improve the thermal budget, at least part of the seal, usually a pinch that is adjacent to an electrode, is preferably provided with a reflective coating. The coating is a metallic or non-metallic layer, in particular made of zirconium oxide. This coating extends from the pinch edge at least 2 mm to the film, in particular at least over the entire length of the shaft inserted into the pinch. It is applied on one side when the lamp is installed close to the vertical in a reflector, ie with a maximum deviation of 45 ° to the vertical. When installed close to the horizontal with a deviation of less than 45 ° to the horizontal, this coating is applied on both sides to both bruises.

To further improve the thermal budget, part of the two seals can be matted, as is known per se. The matting is preferably a layer roughened by sandblasting or etching.

Metal halides of mercury and from the group of the elements Cs and rare earth metals such as Dy or Tm or Ho are particularly suitable as part of the filling, since they can be used to set a color temperature of at least 3300 K, preferably at least 3800 K. Depending on the desired color temperature, it is advisable to add sodium and / or manganese as the halide to the other metal halides. In addition, thallium halide, in particular thallium iodide, can be used to improve the color rendering index. The high-pressure discharge lamp is designed to be particularly compact in that the discharge vessel (2) is the only bulb.

The high-pressure discharge lamp is characterized by the use of electrodes with a shaft and head, in which the shafts have a maximum diameter of 1.15 mm. Such thin shafts have so far not been used for such lamps, since the filling previously contained a relatively large amount of bromine for an optimal halogen cycle which specifically attacks the shafts. However, it has been found that for a relatively low color temperature, which does not exceed 6000 K, a relatively low-bromine filling can be used in a complete departure from the previous teaching, with a bromine / iodine mixture of up to an atomic ratio as the halide of a maximum of 2 can be used.

The low-bromine filling is particularly advantageous when low color temperatures are desired with the light color neutral white with color temperatures between 3300 and 4800 K, with either iodine alone or a bromine / iodine mixture up to an atomic ratio of up to 1.45 being preferred as the halide is. Such low color temperatures have so far not been possible with generic lamps. Such little bromine has little impact on the stems. Typical is the use of pure iodine at low powers (typically 1600 W power) up to a Br / J ratio of 1.0 ± 0.2 at higher powers (typically 2000 W). the specified performance relates to standard operation.

The thin shafts are particularly important because they affect a critical point in the functioning of the lamp. The pin-shaped shaft is melted into the quartz glass and is under high thermal stress and high tension. The quartz glass does not adhere to the pin, but a capillary inevitably forms between the pin and the quartz glass. Part of the filling condenses in the capillary, which forms a dead volume for the filling. This effect leads to the poor maintenance of such lamps which has been observed to date, but which seemed inevitable. In a departure from the previous technology, it is now evident that, with careful selection of the amount of bromine, thin pins are not only sufficiently stable, so that the current load of typically 10 to 20 A is not a problem, but has the great advantage of a significantly lower dead volume associated with it , Because the thinner a pin, the narrower the dead volume in the seal around it. In addition, thin pencils improve the Heat build-up in the area of the electrodes. In particular, only one electrode can be equipped with a thin shaft in vertical operation, while the other has a conventional thick shaft with a typical 1.5 mm diameter. The thin shaft also allows a relatively long distance between the film and the discharge volume, which reduces the risk of explosion and reduces the thermal load on the film. The risk of explosion is due to the notch effect of the foil in the quartz glass. The longer distance increases the dead volume only insignificantly, so that it is still considerably below the value of thick pencils as previously used. A typical axial length of the pin in the quartz glass, calculated from the pinch edge to the beginning of the film, is now 5 to 7 mm, whereas previously a maximum of 4 mm was used. An optimum for the diameter of the shaft with regard to stability on the one hand and dead volume on the other hand is approximately 0.9 to 1.1 mm. The shafts are made, for example, from conventional tungsten material.

Such lamps can be operated with a moderate cycle, which leads to excellent maintenance. The lamps not only achieve an exceptionally long service life in the range of 2500 to 6000 and typically 4500 hours, but also an excellent stability of the lighting properties. This is of the order of at least 90% at 1500 hours.

The filling allows a high luminous efficacy of at least 90 Im / W with good color rendering of at least Ra = 85. In combination with the long service life, this lamp is therefore ideal for general lighting purposes.

The lamp according to the invention also achieves a lifespan of at least 2500 hours in the particularly critical vertical operation in a compact luminaire, as a rule the lifespan is at least 4000 hours. Vertical operation enables a particularly high luminaire efficiency.

The light color is neutral white for applications in rooms or at dusk, and neutral white de luxe (HPS) with a color temperature of around 4100 to 4400 K and an Ra of at least 85 is well suited for the highest demands on color rendering. The lamp according to the invention is also suitable for indirect lighting, for example with mirror projector systems, in which a high luminous flux is required.

Often light-active metal halide fillings contain small amounts of sodium and / or manganese as a component. This enables high luminous efficacies and the desired color components to be achieved. In contrast, a high sodium content leads to increased corrosion of the discharge vessel, although it is usually made of quartz glass. Therefore, the proportion of Na is chosen to be as low as possible in addition to the other constituents thallium, cesium and customary rare earth metals such as Dy, Ho or Tm, and in particular sodium is completely or partially replaced by manganese.

In the case of lamps with a rather small wattage, in particular approximately 1600 W, the ends of the discharge vessel can preferably be coated with a reflective layer only for a short time, typically 2 mm. This applies above all to neutral white fillings with a color temperature of 4000 to 4800 K. Overall, this increases the temperature of the cold spot, but also the film end temperature and the wall load, so that they achieve optimal values. An optimal film end temperature is 350 to 390 ° C. It can be specifically adjusted, for example, by the distance of the film from the discharge volume and its length. At higher temperatures, there is a risk of early corrosion, which will shorten the service life. The wall load is best at around 60 to 75 W / cm ² .

In the case of rather high-watt lamps, in particular 1800 to 2500 W and more, fillings with little or no proportion of Na are preferably used. A longer length of the reflective layer is also recommended here. Starting from the pinched edge, it should encompass at least the shaft up to the film and in particular at least the part of the film on which the shaft is welded. It preferably extends a few millimeters further.

Since these lamps are significantly more exposed to heat, a frosting of the bruises is also recommended. This makes it possible to limit the temperature of the film ends to a maximum of 350 to 390 ° C even in a narrow luminaire.

The temperature at the end of the film is particularly critical. The matting should therefore cover the area of the outer film end. It advantageously extends to the end of the bruising. Inside, towards the discharge, it can at least extend at least to the middle of the film, possibly also significantly beyond, for example to the inner end of the film.

Typical distances between the electrode tips are 25 to 35 mm for particularly compact lamps, but distances of up to 100 mm or more are also possible. The minimum distance is 20 mm.

characters

The invention will be explained in more detail below with the aid of several exemplary embodiments. Show it:

Figure 1 shows a metal halide lamp in side view;

Figures 2 and 3 each another embodiment of a metal halide lamp.

Description of the drawings

FIG. 1 schematically shows a 1600 W high-pressure discharge lamp 1 without an outer bulb with a length of approximately 190 mm, as is described in more detail, for example, in US Pat. No. 5,142,195. It is intended for use in reflectors, whereby it is arranged axially to the reflector axis.

The discharge vessel 2 made of quartz glass defines a longitudinal axis X and is designed as a barrel body 3, the generatrix of which is a circular arc. The discharge volume is approximately 20 cm ³ . The rod-shaped tungsten electrodes 6 with the helix 7 pushed on as the head are axially aligned at the two ends of the discharge vessel in bruises 5. The electrodes 6 are fastened to foils 8 in the pinch 5, on which external current leads 9 attach. A ceramic base 11 with putty (not shown) is attached to the end 20 of the pinch 5 remote from the discharge. The discharge vessel 2 contains a filling of an inert gas as the starting gas, mercury and metal halides. HgBr2 and HgJ2 as well as the light-active filling NaJ, CsJ, TU and DyJ3 as well as TmJ3 are used as metal halide. The ratio Br / J is about 0.2. The lamp is operated horizontally. The cold filling pressure of the starting gas is at most 1 bar.

In this embodiment, the light color is realized in neutral white with a typical color temperature of 4000 K through the filling. A typical diameter the shaft 6 of the electrode is 1.0 mm. After a service life of 2000 hours, the increase in the operating voltage was only 4% and the maintenance of the luminous flux was 10%.

In the case of a vertically operated 2000 W lamp (FIG. 2), the metal halide HgBr2 and the light-active filling NaJ, CsJ, TIJ3 and DyJ3 and TmJ3 are recommended. The ratio Br / J is about 0.9.

A typical filling is:

CsJ: 0.05 to 0.3 µmol / cm ³ ;

DyJ3: 0.2 to 0.8 µmol / cm ³ ;

NaJ: 0 to 1.4 µmol / cm ³ ;

MnJ2: 0 to 2.4 µmol / cm ³ ;

T: 0.05 to 0.7 µmol / cm ³ ;

TmJ3: 0.2 to 0.8 µmol / cm ³ ;

HgJ2: 0 to 1.5 µmol / cm ³ ;

HgBr2: 0 to 3 μmol / cm ³ .

A relatively narrow coating 9 on the lower pinch 3a lowers the wall load caused thereby. A wall load value of at most 75 W / cm ² is desirable. A wall load of 65 to 70 W / cm ² provides good results. In addition, the heat accumulation effect is further increased by the shaft 23 being lengthened and the film 8 being shortened, in each case seen in axial length. The embedding of the shaft in the pinch is then at least 6 mm. The coating 9 extends approximately from the pinch edge to the end of the shaft on the film. The ends of the coating are designated by the reference numbers 30 and 29. A matting 12 is also applied to both shafts 3a and 3b and extends for both the upper and the lower pinch approximately from the outer end 20 of the pinch up to 60% of the length of the film. The inner end of the matting is labeled 31. Another exemplary embodiment is shown in FIG. It is a 2000 W metal halide lamp 40 for a horizontal burning position, which is otherwise similar to that described in FIG. 2. It is suitable for neutral white light colors from 3500 to 4800 K. The uniform temperature distribution allows the use of thin pins 41 as a shaft (0.5 to 1.15 mm in diameter), which can be more densely embedded in the quartz glass when squeezed and reduce the volume of the capillaries surrounding them as dead space. Such a thin shaft 41 must be compatible with the design of the halogen cycle process, in particular through careful selection of the bromine / iodine ratio as shown above. Such thin shafts also limit heat dissipation, so that additional heat build-up occurs at this point, which prevents the formation of a metal halide sump. This enables a symmetrical reflector coating 42 on the two bruises 43 with a small axial length, which avoids shadowing. A narrow coating 42 on the two bruises 43 reduces the resulting wall load to approximately 60 W / cm ^z . In addition, the heat accumulation effect is increased by the shaft 41 being lengthened and the film 44 being shortened, as seen in each case in axial length. The embedding of the shaft in the pinch is about 12 mm. The coating 42 extends from the pinch edge 42a to 2 mm beyond the end of the shaft on the film, the outer end is designated 42b. The ends of the coating are designated by the reference numbers 30 and 29. A matting 45 extends on both bruises approximately from the outer end 46 of the bruise to 60% of the length of the film. The inner end of the matting is labeled 47. It slightly overlaps the outer end of the coating.

HgBr2 and the light-active filling MnJ2, CsJ, TU and DyJ3 and TmJ3 are used as the metal halide. The ratio Br / J is about 1.1.

Claims

claims

1. High-pressure discharge lamp with an elongate discharge vessel (2) as the only bulb which defines an axial axis of symmetry and which is closed on two sides by seals and encloses a discharge volume, with two electrodes (6), the shafts of which are connected to foils, facing each other on the axis , and which contains an ionizable filling of mercury, noble gas and metal halides, as well as with power supply lines which are connected to the electrodes via foils and which emerge at the ends of the discharge vessel, the lamp consuming at least 600 W, characterized in that the shafts are designed as pins with a diameter of 0.5 to 1.15 mm and that the halogen for the halides is composed of the components iodine and possibly bromine, either only iodine or bromine and iodine being used together, the atomic bromine / iodine ratio is a maximum of 2.

2. High-pressure discharge lamp according to claim 1, characterized in that at least part of the seal, which is adjacent to an electrode, is provided with a reflective coating.

3. High-pressure discharge lamp according to claim 2, characterized in that the coating is a metallic or non-metallic layer, in particular made of zirconium oxide.

4. High-pressure discharge lamp according to claim 1, characterized in that in each case part of the two seals is matted.

5. High-pressure discharge lamp according to claim 1, characterized in that the filling contains at least metal halides of mercury and from the group of elements Cs and rare earth metals.

6. High-pressure discharge lamp according to claim 5, characterized in that the filling additionally contains metal halides of sodium and / or manganese.

7. High-pressure discharge lamp according to claim 5, characterized in that the rare earth metals are selected from the group Dy, Ho, Tm.

8. High-pressure discharge lamp according to claim 1, characterized in that the electrodes have shafts with a diameter of 0.9 to 1.1 mm.

9. High-pressure discharge lamp according to claim 1, characterized in that the electrode shafts have an axial length over which they are embedded in the quartz glass of at least 5 mm, advantageously 6 mm.

10. High-pressure discharge lamp according to claim 1, characterized in that the color temperature of the lamp is at least 3300 K, in particular 3800 to 4800 K.

11. High-pressure discharge lamp according to claim 1, characterized in that the maximum bromine / iodine ratio is 1.45 and is in particular in the range 0.8 to 1.2.

12. High-pressure discharge lamp according to claim 5, characterized in that the filling additionally contains a metal halide of the thallium.