The invention relates to a high-pressure discharge lamp with a base at one end in accordance with the precharacterizing clause of claim 1. Of particular concern here are high-pressure discharge lamps, preferably metal halide lamps, but also, for example, halogen incandescent lamps. In this case, an elongate, in particular ceramic, discharge vessel is often used as the lamp bulb.
EP-A 1 109 199 describes a high-pressure lamp with a base at one end, in which the outer bulb is surrounded by a reflector. The reflector contour is not divided up in any other way.
One disadvantage of this high-pressure lamp is the fact that color effects may result in the image when metal halide lamps are used in these conventional reflectors, owing to the filling condensate which is generally deposited at the bottom in the burner of the lamp. This effect is particularly marked in the horizontal operating position, the condensate acting as a color filter and being reproduced by a conventional reflector as a “yellow dot” with markedly lower color temperatures in the upper half of the projection plane.
DE 38 08 086 has already disclosed a reflector whose contour comprises various shaped sections, some of which represent free-form surfaces. This reflector is envisaged for use in vehicle headlights together with incandescent lamps. The concept of free-surface contours is explained, for example, in detail in EP-A 282 100.
One object of the present invention is to provide a lamp with a base at one end in accordance with the precharacterizing clause of claim 1 which, as far as possible, avoids color effects.
This object is achieved by the characterizing features of claim 1. Particularly advantageous refinements are described in the dependent claims.
In the case of conventional reflectors, only positive angles are produced. This means that, in relation to the lamp axis or its parallel, there are always only rays reflected back by the reflector contour which form positive angles with the axis, i.e. intersect the axis again in the far field.
If the reflector lamp is divided into four quadrants in the lateral section, which quadrants are formed by the lamp axis and the reflector opening, in the case of a conventional reflector, the quadrants are always assigned crosswise. In the horizontal operating position, this means that light from the lower half, i.e. by definition the second quadrant, irradiates the opposite half (in the imaging plane), by definition the fourth quadrant. Conversely, light from the upper half (first quadrant) of the lamp is assigned to the lower half (in the projection plane), i.e. the third quadrant. This clear assignment does however cause high color scattering in lamps which have a condensate as the filling. This is because the region which contains the condensate, i.e. generally always the lower quadrant in the horizontal operating position, thus receives its radiation only indirectly via the condensate, which colors the radiation yellow and thus creates a dot with a lower color temperature. The region which contains no condensate, i.e. generally always the upper quadrant in the horizontal operating position, obtains its radiation without any change, in this case the color temperature is markedly higher. With conventional measurements using an Ulbricht sphere, this problem is not indicated since the measurement in this case takes place integrally over the entire sphere and there is no local resolution.
According to the invention, the reflector is now contoured such that both zones obtain approximately half the light of each quadrant. In practice, this should be at least 35% instead of the optimum 50%. The first zone is calculated such that it sends the light into the quadrant which lies directly above it without intersecting the lamp axis. Only the second zone is calculated such that light assigned to it conventionally intersects the lamp axis and falls in the other quadrant of the projection plane. Averaging is thus achieved. In each case approximately half the radiation in one quadrant of the projection plane originates from the quadrant below on the emission side, and the other half originates from the opposite quadrant on the emission side. This compensating effect until now needed to be achieved incompletely and with great effort by a suitably patterned cover disk.
In detail, the lamp with a base at one end has an inner vessel which is sealed in a vacuum-tight manner, in particular an elongate discharge vessel made from ceramic or quartz glass, which is accommodated, under certain circumstances, in an outer bulb. It is irrelevant here whether the discharge vessel is cylindrical or round.
The inner vessel is also surrounded by a reflector. The inner vessel is preferably a unit comprising a discharge vessel with an outer bulb. It is particularly preferably a ceramic discharge vessel, in particular a metal halide lamp for general lighting purposes.
In this case, a base having electrical terminals bears, on the one hand, the inner vessel and, on the other hand, the reflector part. The electrical terminals are normally connected to power supply lines which produce an electrical contact with a luminous means in the interior of the inner vessel, which luminous means is implemented, for example, by electrodes in the interior. Without restricting the invention, outer electrodes may also be used, or an electrode-less configuration. Instead of a ceramic discharge vessel, a discharge vessel made from quartz glass or hard glass may also be used. An outer bulb as part of the inner vessel is not absolutely necessary, but is often desired.
In addition to the base insulator, the base has a conventional part facing the lampholder, for example a screw base attachment or a bayonet-type base attachment or GU base.
The inner vessel, i.e., for example, the lamp bulb or the outer bulb, which contains a discharge vessel, or the discharge vessel in the case where there is no outer bulb, is preferably held in the central opening by means of a spring clip, as is known per se.
Power supply lines are generally passed out of the lamp bulb and are connected to the electrical terminals of the base. A particularly flexible and time-saving solution consists in clamping connections being used for the connection between the electrical terminals and the power supply lines, as is known per se.
The base also generally has a part facing the lampholder, which is at least partially connected to the base insulator by means of crimping, as is known per se. This part contains, for example, a conventional screw thread or pin of a bayonet-type base etc.
A typical application is a metal halide lamp which contains a filling with or without a mercury content, possibly with an inert starting gas, advantageously a noble gas.
The invention will be explained in more detail below with reference to a plurality of exemplary embodiments. In the drawing:
The lamp in
A reflector 2 is fitted on the outside around the outer bulb 5. It is divided into a section having a contour 35, a neck part 9, to which the base is fixed, resting on one end and the reflector opening 36, which is sealed by a simple cover disk 37, resting on the other end of said section.
The operation of a previous reflector is shown by way of example in
In the case of the color-compensated reflector (
In this manner, the resulting scattering of the color temperature over the projection plane 50 is considerably reduced in comparison with a conventional reflector.
The two zonal layers 38, 39 of the reflector mean that a reflector segment bII (
In this manner, the variation of the color temperature in the projection plane may be considerably reduced, in particular by at least 50%.
In particular, a transition zone may also be inserted between the first and the second zonal layer, said transition zone avoiding a sharp kink between the two zones 38 and 39. In addition, an adaptation zone may also be provided between the first zonal layer 38 and the neck 9 and/or an adaptation zone may be provided between the second zonal layer and the rim of the reflector opening.
The contour of the reflector may be faceted in one or more of the zonal layers, as known per se, in order to improve uniformity further still.
Finally, the rim of the reflector can preferably be flanged (40) in the vicinity of the opening such that it holds the cover disk 37 directly. A separate holding mechanism (ring) can be dispensed with. This is possible in particular when using an aluminum reflector having a low wall thickness.
Number | Date | Country | Kind |
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102004058750.7 | Dec 2004 | DE | national |