DE102008053488A1 - reflector lamp - Google Patents

Abstract

Disclosed is a lamp, in particular a Kurzbogenentladungs- or incandescent lamp, with an elongated light source, in particular a discharge arc or a filament, and a reflector with a reflector axis, wherein the light source is disposed substantially along the reflector axis and the reflector an inner refractive and a outer reflecting surface, which are arranged at a predetermined distance from each other.

Description

Technical area

This The invention relates to a lamp, in particular a short-arc discharge lamp or a light bulb with a reflector.

State of the art

at Reflector lamps causes the reflector to transform the distribution of the light emitted from a light source into one for an application usable light distribution. For Projections or fiber lighting is the task of Reflectors in it, one as possible huge Part of the light of the light source in a through an area and a Coupling acceptance angle defined aperture.

Such Reflectors are often designed as a rotational figure of a conic section, wherein the light source in a first focus or its immediate Environment is arranged.

by virtue of the elongated one Geometry of the light emitting volume of many light sources (e.g. B. discharge arc, filament) is the spatial extension in one direction significantly larger than in the other directions. It is known that when this arrangement longest Extension along the axis of the reflector greater efficiency the light coupling into an aperture can be achieved as at other orientations.

at However, this arrangement can one for a light coupling in an aperture on for efficient reflector have the disadvantage that a lower Part of the reflected light falls on a part of the light source and scattered or absorbed there and thus lost as useful light goes or even the lamp damages. In particular, in short-arc discharge lamps, in which a burner is arranged along the reflector axis, in the case of the state the art known elliptical reflectors a part of the reflected Light incident on the end of the burner shaft, causing this Part of the burner and in particular the power supply can be heated undesirable. Under The term burner is here by the way meant the actual lamp without a reflector. For a short arc discharge lamp So this is essentially the discharge vessel with the electrodes, at a (Halogen) incandescent lamp the lamp vessel with the Filament.

Presentation of the invention

aim The invention is a reflector design and a lamp with a specify such a reflector, which is an efficient coupling allows the light of the lamp in an aperture. Another aspect is the reduction of shading by parts of the lamp, in particular a lamp shaft.

These Task is solved by a lamp, in particular a short-arc discharge lamp, with a light source and a reflector with a reflector axis, along the light emitted by the light source in the direction of a Aperture is emitted, the light source substantially axially to Reflector axis is aligned and the reflector is an inner refractive and an outer reflective area which are arranged at a predeterminable distance from one another are.

In contrast, in conventional reflectors, the inner surface is reflective. The reflector design according to the invention thus provides an additional refractive surface and thus a further degree of freedom for the optical design of the reflector. In simulations, it has been found that an increase in the coupling efficiency into the aperture in the range of 3% to 5% can be achieved. Another advantage of using an inner refractive and an outer reflective surface is that the reflected rays may be farther from the burner (cf. 1 and 2 ), whereby a shading of light or a heating of the burner over conventional reflectors can be reduced.

Especially an embodiment is advantageous in which a reflector is used, which consists of a dome, whose outer surface is mirrored is. This backside mirroring may be metallic or of a dielectric layer system consist. The inside of the calotte can also, as another embodiment shows to be anti-reflective.

The inner refractive and the outer reflective area can be shaped identically or differently, with spherical, elliptical, parabolic, hyperbolic or generally aspherical rotation body ver used can be. The shape of the surfaces is essential by the interpretation of the lamp light using determined optical system.

Particularly advantageous is an embodiment in which both surfaces of the reflector represent ellipsoids of revolution and the center of the light source is located between the two primary focal points of the inner or outer surface. In addition, in this case, advantageously, the aperture can be arranged at a greater distance than the two secondary focal planes. As a result, with the same spot size on the aperture Light incident at a slightly smaller angle causes and thus achieved a coupling with higher efficiency.

Furthermore, it has been found that the use of a reflector according to the invention over a previous front-surface mirrored reflector is particularly advantageous in an etendue of the aperture of less than 30 mm ² sr.

moreover it is the reflector of the invention advantageous if the distance of the primary foci of the inner and outer elliptical shaped surfaces 2-3 mm is. In this case, preferably, the inner ellipse a larger numerical eccentricity as the outer ones have, the ratio the eccentricities at about 101% -110%, especially at about 104%.

Of Furthermore, it is advantageous if the inner reflective surface a smaller focal length than the outer. The relationship focal lengths of inner and outer surfaces preferably at 60-90%, especially between 70-80%.

at Such an arrangement or training, the wall thickness, ie the distance between inner and outer surface, over the entire reflector nearly be constant, so that no specific due to the reflector design according to the invention Manufacturing difficulties during pressing of the dome occur. A advantageous glass thickness of the reflector is between 4-6 mm.

In a further embodiment can be with the inner refractive surface and the outer reflective area provided reflector also closed with a windscreen and optionally filled with a gas be.

Further Advantages and advantageous embodiments are defined in the figures, the description and the dependent claims.

Brief description of the drawings

in the The invention will be explained in more detail with reference to drawings. Show it:

1 a schematic representation of a first embodiment of the invention,

2 a schematic representation of an elliptical reflector with Vorderflächenverspiegelung according to the prior art,

3 a schematic representation of another embodiment of the invention.

Preferred embodiment of invention

in the Following are the same or similar features with the same Reference numeral.

1 shows a preferred embodiment of the present invention, in which schematically the geometry of the reflector 1 with an inner refractive elliptical surface 2 and an outer reflective elliptical surface 4 is shown. The curvature of the inner refractive surface 2 is chosen so that the focal point F1 _in closer to the light exit opening 6 of the reflector 1 is located as the focal point F1 _{out of} the outer reflective surface 4 , Both foci F1 _in ; F1 _out represent the primary focus of the reflector 1 where preferably the center of a light source 8th between the two primary foci F1 _in ; F1 _{out is} arranged.

The light source itself is preferably a short arc discharge lamp 22 in which the discharge arc 21 longitudinal to the reflector axis 10 is aligned. The short arc discharge lamp 22 hereinafter referred to as Brenner for brevity, consists of a glass bulb and two protruding into the glass bulb electrodes (not shown), between which forms a discharge arc. The interior of the glass bulb is hermetically sealed and filled with a discharge gas mixture. In the shafts of the burner 23 . 24 the electrodes are melted down. The burner 22 Can be fixed to the reflector 1 However, it is also possible to use an insertable, separate burner.

Beams of light from the light source 8th are delivered to the inner surface 2 of the reflector 1 in the glass body of the reflector, so the area 18 coupled between inner and outer surface. The light gets on the inner surface 2 towards the outer surface 4 broken, reflected there due to the mirroring, again on the inner surface 2 Broken due to the transfer in air and then towards the light exit opening 6 issued.

So no unwanted reflections on the inner surface 2 can occur, the inner surface 2 also have an anti-reflection coating.

The additional refraction on the inner surface can increase the efficiency of coupling into the aperture on the order of 3% to 5%, especially if the etendue of the aperture is less than 30 mm ² sr.

In addition, due to the additional Bre can be achieved at the transition between air and glass that shading effects or heating of the burner can be better avoided than elliptical reflectors with Vorderflächenverspiegelung. This becomes particularly clear in a comparison between a light beam 16 the reflector according to the invention and a corresponding light beam 20 a mirrored on the inside, so conventional reflector 26 (see. 2 ). The comparison between the light rays 16 and 20 clearly shows that the light beam 20 closer to the reflector axis 10 runs (see distance D ₁ ) and thus the risk of heating and possibly the damage of the burner and shading effects is greater. In contrast, the light beam shows 16 from the reflector according to the invention a greater distance D ₂ to the reflector axis, so that the disadvantages of a reflector according to the prior art due to the greater distance between the light beam and the reflector axis can be avoided.

Preferably the wall thickness of the reflector is almost equal everywhere and is advantageously in the vertex 4-6 mm.

As described above, in elliptical shape of the surfaces of the reflector, the numerical eccentricity of the inner ellipse (e _in ) is preferably larger than that of the outer ellipse (e _out ), and the ratio between e _in and e _{out is} about 104%. In addition, the inner ellipse preferably has a smaller focal length than the outer ellipse, and is typically in the range of 70-80% of its focal length. With such a choice of eccentricity and focus, the wall thickness over the entire reflector is substantially consistent, allowing for easy and cost-effective manufacture.

As in 1 2, the aperture of the receiver optics is preferably arranged outside of both secondary focal planes F2 _in , F2 _out .

3 shows alternatively the use of the reflector according to the invention 1 with a halogen burner 30 whose axially oriented to the burner longitudinal axis filament 32 along the reflector axis 10 is arranged.

Claims (16)

A lamp comprising an elongate light source and a reflector having a reflector axis, wherein the elongated light source is oriented substantially parallel to the reflector axis and wherein the reflector is configured to concentrate the light emitted from the light source outside the reflector, characterized in that the Reflector has an inner refractive and an outer reflective surface, which are arranged at a predetermined distance from each other. A lamp according to claim 1, wherein inner and outer surfaces of the Reflectors represent rotational figures of conic sections or aspherical shapes are. A lamp according to claim 1 or 2, wherein the elongated Light source is substantially along the reflector axis extending arc of a discharge lamp. A lamp according to claim 3, wherein the arc is a length of less than 2 mm. A lamp according to claim 1 or 2, wherein the elongated Light source a substantially along the reflector axis extending filament a light bulb is. A lamp according to any one of the preceding claims, wherein the outer surface of the Reflectors a dielectric coating or a metallic Coating has. A lamp according to any one of the preceding claims, wherein the inner surface of the reflector is provided with an anti-reflection layer. A lamp according to any one of the preceding claims, wherein the inner and the outer surface of the reflector each represent a part of a Rotationsellipsoiden. A lamp according to claim 8, wherein the primary foci the two ellipsoids of revolution have a distance from each other, and the center of the elongated Light source between the two primary focal points arranged is. A lamp according to claim 9, wherein the spacing of the two primary Focal points about 2-3 mm. A lamp according to claim 8, wherein the inner surface is a larger numeric eccentricity as the outer surface has, especially 2-7% bigger, and / or the inner surface has a smaller focal length than the outer surface, in particular a focal length of 60-90% the focal length of the outer surface. A lamp according to any one of the preceding claims, wherein the distance between inner and outer surface over the reflector is substantially constant is. Lamp according to one of the preceding claims, wherein the distance between the inner and outer surface of the reflector at the apex of Reflectors 3-7 mm, in particular 4-6 mm. Lighting system with a lamp according to one of the claims 8 to 11 and an optical system, wherein the aperture of the optical Systems arranged on the reflector axis is at a greater distance to the light source as the secondary focal planes both surfaces of the reflector. Lighting system according to claim 14, wherein the optical System is an optical fiber. Illumination system according to claim 14, the optical System is a projection device.