EP0989587A1 - High pressure discharge lamp and associated luminaire - Google Patents

Abstract

A high pressure discharge lamp has an elongated discharge vessel (2) which defines an axial axis of symmetry and surrounds a discharge volume. Two electrodes (6) protrude on the axis. The vessel is cylindrical in the radial direction. The discharge vessel has in a limited region that includes the coldest spot, a reflecting coating, radially asymmetric. The coating is a metallic or non-metallic layer or is a layer roughed up by sand blasting or etching. The coating possesses an axial length of at least 30% of the discharge volume and actually extends over the whole discharge volume in the axial direction. In the radial direction, the coating includes a maximum central angle of at least 30 and no more than 180.

Description

Technical field

The invention is based on a high-pressure discharge lamp according to the preamble of claim 1. These are in particular metal halide lamps with bilateral crushing, especially with high performance.

State of the art

A high-pressure discharge lamp is already known from the document DE-A 44 43 354, which has a radially asymmetrical coating on the piston. It deals is an aperture lamp. That means an increased radiation is achieved from an uncovered narrow piston area in that the remaining piston surface is provided with a reflective coating. The Coating covers a considerable part of the piston surface.

Axially asymmetrical coatings of the piston have been described in various ways been. For example, DE-GM 94 01 436 has a two-sided pinch Metal halide lamp known, which is installed axially in a reflector to achieve a high luminous flux and a high uniformity of the radiation. In addition to the well-known heat accumulation domes at the ends, this is used Lamp also a completely encircling in the middle of the bulbous discharge vessel Circular ring as a radially symmetrical layer.

Presentation of the invention

It is an object of the present invention to provide a high-pressure discharge lamp to provide the preamble of claim 1, in which the wall load of Discharge vessel and thus the temperature of the coldest point (cold spot) increased is.

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

A high wall load increases the proportion of the filling substances in the discharge arc and is desirable because it makes the electrical and lighting technology Data of the lamp can be significantly improved.

An improvement in this data has so far been made by changing the filling composition and a reduction in the volume of the discharge vessel sought. So far, this has meant a high level of development effort with an uncertain Result. It was also able to adjust the light distribution curve the lamp has not been made so far.

According to the invention, there is a radially asymmetrical reflective coating on one essentially radially symmetrical discharge vessel (i.e. in the radial direction is essentially circular cylindrical). This coating is in a localized area that includes the coldest point, and has a limited extent, the size of which is preferably between 5 and 40% the surface of the discharge vessel is as little as possible around the shadowing to keep.

This reflective coating can by means of a physical and / or chemical Treatment of the surface of the discharge vessel can be produced. For example, a metal coating known per se is suitable (Aluminum) or non-metallic materials (especially zirconium oxide), or a layer made by sandblasting or etching. By selecting the Layer geometry and the coating process can be lamp-specific Data, especially the color rendering, color temperature and light distribution curve and the color location can be varied and set exactly as desired.

This improvement of the electrical and lighting data is due to a targeted asymmetrical coating of the discharge vessel in the area of the coldest Job achieved. Particularly large improvements are made with high-wattage (at least 400 W to well over 1000 W) metal halide lamps without an outer bulb achieved, because here the heat loss due to the lack of the outer bulb particularly is critical.

The coldest spot on these lamps is usually behind the electrodes Find. For this reason, the ends of the discharge vessel are often included Heat accumulation dome equipped. This causes the coldest point (the but then at a higher temperature than if you did not use a calotte) the lowest point of the discharge vessel can be found, what by the effect of gravity is conditional. Because the discharge arc is through the Buoyancy deflected upwards. A discharge vessel that is as isothermal as possible is desired. The extent of the cold area around the coldest point (and accordingly the temperature gradient) determines the extent of the asymmetrical Coating. This can be either a limited spot or axial elongated, for example band-like. The spot is round or oval or elliptical.

Under certain circumstances, the geometric arrangement of the asymmetrical coating determined by an associated lighting system (e.g. a lamp), since this is the location and extent of the cold area around the coldest Place can affect. The essential part of a lighting system is usually a reflector, for example as a channel reflector or ellipsoid reflector is trained.

The position of the asymmetrical coating relative to the pump tip can be advantageous Define the discharge vessel, as these are potential during operation of the lamp Heat sink is best positioned at the top. Accordingly, the asymmetrical coating just opposite the pump tip. Also for practical reasons there is no coating in the area of the pump tip desirable to avoid optical distortion and adhesion problems of the coating to avoid at the pump tip.

The lamp is preferred in the horizontal burning position (based on the longitudinal axis) operated and is characterized by a coating that extends in the axial direction extends at least over 30% of the length of the discharge volume and the in the radial direction over at least a central angle of 30 ° with the deepest Extends the point of the discharge vessel as the center of the center angle. The maximal Length of the coating in the axial direction is the entire length of the Discharge vessel limited and in the radial direction by a central angle of 180 ° at most, otherwise the effect of shading would be too great. Here is in radial direction for the cross section of the discharge vessel a circular shape or elliptical shape that approximates the circular shape. In the axial direction the discharge vessel is elongated and preferably has either the shape of a Barrel body, a cylinder or an ellipse.

The asymmetrical coating advantageously extends close to the ends of the discharge volume where the electrodes are located. You can also do both The well-known heat accumulation dome ends.

A wall lamp is particularly suitable as a lighting system, with one on the side behind the horizontal lamp attached elongated reflector. This avoids that the asymmetrical coating is worth mentioning Shadowing caused by the radiation emitted by the lamp.

The coating according to the invention increases the lighting technology Data of a lamp possible without major changes to other parameters. It can even the same reflector paste as used for the end mirroring will be used. Also there are no additional costs in the production, since no additional process step is required. The additional consumption Reflector paste can be neglected.

A particularly valuable environmental point of view is that because of the higher Operating temperature a reduction in the amount required to fill a lamp absolute amount of Hg around 10-20 mg is possible. That being said no change in the filling composition to improve lighting technology Data required.

To ensure the required clear orientation of the lamp in the correct operating position can ensure on a known orientable base-socket system can be used, as described, for example, in US Pat. No. 5,731,656 is. This can very easily be the one required for maintaining an optimal effect Installation position with the asymmetrical coating facing downwards is ensured become.

characters

Figur 1

eine Metallhalogenidlampe in Seitenansicht

Figur 2

einen Querschnitt durch die Metallhalogenidlampe der Figur 1

Figur 3

ein weiteres Ausführungsbeispiel einer Metallhalogenidlampe in Draufsicht auf eine Quetschung

Figur 4

eine um 90° gedrehte Seitenansicht der Lampe aus Figur 3

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

Figure 1

a metal halide lamp in side view

Figure 2

2 shows a cross section through the metal halide lamp of FIG. 1

Figure 3

a further embodiment of a metal halide lamp in plan view of a pinch

Figure 4

3 shows a side view of the lamp from FIG. 3 rotated by 90 °

Description of the drawings

1 and 2 schematically show a 2000 W high-pressure discharge lamp 1 without Outer bulb shown with a length of about 190 mm, such as in US Pat. No. 5,142,195 is described in more detail. It is intended for use in reflectors, but it is now arranged horizontally and transversely to the reflector axis instead of axial.

The discharge vessel 2 made of quartz glass defines a longitudinal axis X and is designed as a barrel body, the generatrix of which is an arc. The discharge volume is approximately 20 cm ³ . The rod-shaped tungsten electrodes 6 with the helix pushed on are axially aligned at the two ends of the discharge vessel in pinches 5. The electrodes 6 are fastened to foils 8 in the pinch 5, on which external current leads 9 attach. At the distal end of the pinch 5, a ceramic base 10 is fastened with putty. The discharge vessel 2 contains a filling made of an inert gas, mercury (180 mg is now sufficient instead of approx. 200 mg) and metal halides. The ends of the discharge vessel are provided with a heat accumulation cap 13 made of zirconium oxide.

In addition, an asymmetrical coating 4 is applied to the discharge vessel 2, specifically opposite the pump tip 3 in the lowest-lying region in the installed state, which contains the coldest point T. The asymmetrical coating 4 also consists of zirconium oxide and is an elongated, approximately oval spot that has an axial width a of approximately 50% of the width of the barrel body. Its maximum radial extent extends over a central angle of approximately α = 55 ^° (see FIG. 2). In the side view of FIG. 1, in which the pump tip 3 is at the top, only the front half of the spot can be seen.

Another exemplary embodiment is shown in FIGS. It is a matter of a 1000 W metal halide lamp 19 similar to that described in FIG. 1. Figure 3 shows a plan view of a pinch 23. In Figure 4, the lamp 19 is from below seen. The asymmetrical coating 20 extends over the entire axial length of the volume of the discharge vessel 21 and is at the ends with the heat accumulation dome 22 in connection. The radial expansion corresponds to one Center angle of about 90 °. The lamp is intended for installation in a lamp, whose elliptical reflector 25 sits laterally next to the lamp 19. The main radiation direction forward is represented by an arrow 26.

In particular, the color locus, the color rendering and the luminous flux are significantly improved compared to the prior art due to the asymmetrical coating. In addition, the operating voltage of the lamp is raised on average by 20 V to approximately 125 V. A comparison between an uncoated and a coated lamp can be found in Table 1, where the luminous flux Φ (in klm), the color coordinates x and y and the color rendering index Ra are given for both lamps. There is a significant improvement in the luminous flux (by 7%) and the color rendering index (by 15%). The color locus is much closer to white (x, y = 0.333) or to the curve for the Planck radiator. Uncoated lamp Coated lamp Φ (klm) 80.7 86.8 x 0.297 0.332 y 0.377 0.368 Ra 75 86

A smudge-proof reflector paste based on zirconium oxide was used as the coating material used. Their layer thickness and homogeneity correspond to the usual Value for heat accumulation domes. The lamp was in an area around the coldest Coated point at which filling condensate forms during operation. This area is in the special case on the side opposite the pump tip.

Claims (12)

High-pressure discharge lamp with an elongate discharge vessel (2), that defines an axial axis of symmetry and encloses a discharge volume, wherein two electrodes (6) face each other on the axis, and which is essentially circular cylindrical in the radial direction, characterized in that that the discharge vessel (2) in a limited area, which the includes the coldest point, radially asymmetrical a reflective coating (4). High-pressure discharge lamp according to claim 1, characterized in that the Coating a metallic or non-metallic layer or through Sandblasting or etching is roughened layer. High-pressure discharge lamp according to claim 1, characterized in that the Coating an axial length of at least 30% of the discharge volume owns. High-pressure discharge lamp according to claim 1, characterized in that the Coating extends in the axial direction over the entire discharge volume. High-pressure discharge lamp according to claim 1, characterized in that the Coating in the radial direction a maximum central angle α of at least Encloses 30 °. High-pressure discharge lamp according to claim 1, characterized in that the Coating in the radial direction a maximum central angle α of at most Encloses 180 °. High-pressure discharge lamp according to claim 1, characterized in that the Filling contains mercury and metal halides. High-pressure discharge lamp according to Claim 1, characterized in that it is operated in a horizontal burning position, the coldest point (T) being the deepest Point is located. High-pressure discharge lamp according to claim 1, characterized in that heat accumulation domes (13) are attached to the ends of the discharge vessel. High-pressure discharge lamp according to claim 1, characterized in that the discharge vessel (2) is the only bulb. High-pressure discharge lamp according to claim 1, characterized in that the lamp has an orientable base. Lighting system with a high-pressure discharge lamp according to one of the preceding Expectations.

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