DE19632665C2 - Luminaire with a reflector and a diffusely scattering component - Google Patents

Description

The invention relates to a lamp with a reflect gate and a diffusely scattering component corresponding to the Preamble of claim 1.

Such a lamp is through DE-PS 6 16 604 known. The known lamp has a second egg parabolic reflector, the tapered part of which the first reflector part, the illuminant, one with one Filament provided general service lamp, takes up. To the tapered reflector part closes as a second reflector part of the door the narrower area of an approximately truncated cone the reflector screen, which is made of translucent material consists. The reflector screen also surrounds a translucent central diffusely scattering component, which has the shape of a Has conical jacket, the tip of which is from the reflector screen-formed light exit plane is very close. The diffuse scattering separate flat conical component shines with its luminous surface to that of the trans  lucent reflector screen formed inner reflector surface towards the light, which is reflected there as well also the translucent reflector screen to the outside penetrates. The spherical cap of the general service lamp protrudes into the cone formed by the diffuse scattering flat component shaped interior. Because the diffuse scattering flat Component of the light exit formed by the reflector screen is very close, the shielding angle is so also the geometric shadow space, also shielding space called, very small.

In DE-PS 12 62 182 is Isaac's for the first time Goodbar and Edison Price founded Darklight technology described which are not in their model representation more, as usual before, from a point light source, but rather from a luminous surface proceeds from an infinitesimally large number of individual ner light points is composed. The one of each A beam of outgoing light is PS 12 62 182 calculated to thereby the course of curvature of the To determine the reflector different from that in the DE-PS 61 66 04 described reflector entirely from one opaque material, namely metal, consists.

Peculiarity of such darklight reflectors, which applies both to rotationally symmetrical light sources (see DE-PS 12 62 182 Fig. 1) and for cylindrical, ie also for elongated light sources (see DE-PS 12 62 182 Fig. 2), it is that the light emitted by the luminous surface of the illuminant is completely invisible within the shielding space. The cross section of the Abschirmungsrau mes is also formed in the reflector according to DE-PS 12 62 182 from the free leg of a shielding angle and an outward extension of the flat light exit surface. The prerequisite for this is that the luminous surface of the illuminant must be arranged within a specific illuminant receiving space. The light receiving space is located in the rear area of the reflector and is defined by the extensions of the free legs of the shielding angle, which extend into the reflector space and intersect each other, which, as previously mentioned, forms the shielding or shadow space outside the reflector. The intersecting extensions of the free legs of all the shielding angles applied to the front reflector edge thus form the front limit of the light receiving space. This boundary must not be penetrated by the luminous surface of the illuminant towards the light exit surface of the reflector if no light reflected directly from the light source via the reflector is to be visible within the shielding space.

Problems arise in connection with the known luminaire according to DE-PS 12 62 182 mainly used very powerful high-voltage or low-voltage halogen lamp pen or when using compact fluorescent lamps especially in connection with wall washer reflector segments ten, which are described in DE-OS 23 36 418. Such Powerful light sources usually show a strong structured discontinuous surface shape, while according the DE-PS 12 62 182 uniformly rotationally symmetrical or uniformly cylindrical luminous surfaces required are tongue.

The object of the invention is that in the preamble of Luminaire described in claim 1, especially darklight reflector lights, considering one easy handling largely independent of the Make the type of illuminant to be used.

According to the invention, this object solved that the interior of the reflector in a rear Area and divided into a front area, where the rear area is the lamp receiving space for the Illuminant forms, being opposite each other inclined towards the axis of symmetry of the reflector a stretching, intersecting extensions of the free end leg of the shielding angle a front Cross-sectional limitation of the lamp receiving space lay, whereby the separate diffusely scattering light component at the front cross-sectional boundary of the Illuminant space bordered or between the cross Limitation of the cut of the lamp receiving space and the Illuminant is arranged, which is spatially arbitrary trained lamp surface.

According to the invention, an initially primary Light source, e.g. B. a high-voltage halogen lamp with strong ge structured surface, to a secondary light source, because the separate, flat, diffuse light Component to be regarded as the primary primary illuminant is.  

It is important that the diffuse light scatter end separate flat component not like known, frosted glass domes to protect against shattering on undefi nated place in front of the lamp inside the Reflector interior are arranged. Rather, it is gone  against an unconditional requirement according to the invention that the effective surface of the light diffusing ge separated flat component at most as far as in the reflector is arranged in the front that it is just in the front cross-section limitation of the lamp holder room is located.

With the invention is a symmetrization or Uniformization of discontinuous illuminant surfaces range from high performance light sources even together slope with wallwasher reflectors according to DE-OS 23 36 418 been achieved.

According to an embodiment variant according to the invention the diffusely scattering component can be grid-like Have light passage openings. The grid-like Light passage openings can scatter from a diffuse the component made of transparent or opaque Be formed material.

The diffusely scattering component can also be made of wire braid in which the braid openings are the form grid-like light passage openings.

Furthermore, the invention provides that the diffuse scattering component made of translucent (translucent) opaque (frosted glass-like) material.

Another advantageous variant of the invention characterizes net is characterized in that the diffusely scattering flat component from the individual forming air passage gaps elements is composed. Such air passage  crevices or air vents, which are also of Light passage openings can be formed an air circulation that allows the cooling of a high-performance Illuminant is used.

With a compact lamp, with z. B. spherical, piston-like or the like, in particular articulated surface represents the diffusely scattering component according to the invention essentially represent rotationally symmetrical body. This can adapt to the intersecting extensions the free legs protruding into the reflector interior angle of the shielding angle, tapering towards the front, conical or be frustoconical.

With an elongated lamp with cylindrical on the other hand, the dif fus scattering component expediently one forwards (i.e. for Light exit surface) closed, essentially trough-like or trough-like bodies.

An embodiment of the invention, which is in the has proven particularly practical use, is ge indicates that the diffusely scattering component at least one that also serves to handle the assembly Has air passage opening.

Another variant of the invention is that at a compact lamp with z. B. spherical, piston-like or the like surface the one essentially rotationally symmetrical body representing diffuse scattering Component has the light passage opening, which rotates is arranged symmetrically to the axis of rotation of the lamp.  

Looks analogous to the latter features of the invention a further embodiment of the invention that an elongated lamp with a cylindrical top the surface is essentially trough-like or trough-like Diffuse scattering component representing the body Has air passage opening, which is mirror symmetry stric to the longitudinal median plane of the lamp.

The diameter (e.g. with a rotationally symmetrical diffusely scattering component) or the width (e.g. with a essentially diffuse scattering trough or trough-like Component) of the respective air passage opening can to the total diameter or the total width of the diffuse scattering component behave approximately as 1: 6 to 1: 7.

Such an air passage opening, which purpose moderately represents a finger passage opening that the easy handling of the diffusely scattering component in the Assembly or disassembly is lighting technology practically without influence. This is because everyone of course, air that lets light through step opening within the lamp receiving space is located behind its front cross-sectional boundary. On on the other hand provide the rela according to the invention tively large air openings especially powerful high-voltage or low-voltage Ha logen lamps an extremely effective cooling.

That cooling is especially in combination with the The aforementioned air passage opening in the manner of a synergi tical effect in a further embodiment of the invention  improved by the fact that between the outer edge of the diffuse scattering component and the adjacent reflector surface an air passage gap is formed.

According to a preferred invention The exemplary embodiment is the air passage gap of locking or attachment points between the diffusely scattering Component and the reflector interrupted.

Preferred embodiments are shown in the drawings games according to the invention, it shows

Fig. 1 shows a schematic cross section through a lamp with a reflector,

Fig. 2 in the same mode of representation according to FIG. 1 a modified embodiment,

FIG. 3 shows a partial area of the representation according to FIG. 2 approximately in natural size and

Fig. 4 is a view of the hollow side of a sheet-like diffusely scattering component with the omission of reflector areas approximately according to the view arrow labeled IV in Fig. 3.

The lamp is generally designated by reference number 10 . It is e.g. B. a ceiling lamp 10 , which is inserted into the ceiling section A of a building ceiling, the ceiling view area of which is designated D.

The lamp 10 has a reflector 12 having a rotationally symmetrical reflector surface 11 . The reflector 12 forms in the rear area of its interior 20 a lamp receiving space 13 for a lamp 14 , which can represent, for example, a low or a high-voltage halogen lamp.

The front region of the reflector 12 is delimited by its front reflector edge 15 , which extends flush with the ceiling view surface D.

The reflector edge 15 delimits a flat light exit surface E.

A shielding or shadow space R can be seen outside the reflector 12 . The shielding space R is formed by the free leg S of the shielding angle α rotating about the axis of rotation y. The shielding angle α is formed between the free leg S and an outward extension 17 of the planar light exit surface E. In the case of the exemplary embodiment shown, this extension 17 is synonymous with the ceiling view surface D.

The extensions S1 of the free legs S of the shielding angle α extend into the interior 20 of the reflector 12 and cross each other at a crossing point K. If one imagines that the leg extensions S1 rotate about the axis of rotation y, the leg extensions S1 form above the Intersection point K the surface of a cone 19th This conical surface is at the same time the front boundary 19 of the lamp receiving space 13. The reflector surface 11 is designed so that light which telaufnahmeraum of the Leuchtmit emanating 13, only reflected so that this light is not visible within the shield space R.

To a small extent to the rear in the direction of Leuchtmit tel 14 offset from the front boundary 19 away is a light diffusely scattering separate flat component 18 with a conical surface. The flat construction part 18 is detachably attached at individual points 21 or all around on the reflector surface 11 in a manner not shown, for example locked.

The flat component 11 can consist of a body made of translucent opaque (that is, a total of frosted glass-like) material, for example a plastic injection molded component. The flat component 18 has air through openings 22 which serve the air circulation for cooling the lamp 14 .

While the illuminant 14 practically forms a secondary light source, the pointed conical surface of the flat component 18 pointing towards the flat light exit surface E represents a luminous upper surface 16 which fulfills the function of a primary illuminant. It is conceivable that the flat construction part 18 has a comparative and symmetrical effect with regard to the high luminance of a discontinuous surface illuminant 14 .

The dashed line provided on the left in the drawing Line F is intended to run the course of a wallwasher element performing reflector segment according to DE-PS 23 36 418 identify and show that the arrangement shown can also be a wallwasher reflector lamp.

Based on the drawing it is also conceivable that the Re reflector 12 can overall represent an elongated cylindrical component which extends symmetrically to the longitudinal center plane M into the paper plane of the drawing. The illuminant 14 would also be cylindrical in this case, for example circular cylindrical.

The diffusely scattering flat construction part 18 shown in FIG. 2 forms a truncated cone-like hollow body with its narrower area pointing downward toward the light exit surface E, the small circular area of which forms an air passage opening 23 overall.

In the specific exemplary embodiment, the air passage opening 23 has a diameter DL = 20 mm, while the total diameter DG of the component 18 is approximately 130 mm. DL therefore behaves like 1: 6.5 to DG.

From Fig. 3 it can clearly be seen that the component 18 is detachably connected to the re reflector 12 at the locking or fastening points 21 . For this purpose, the reflector 12 has a longitudinal axis with its long axis over a small partial circumference extending longitudinally rectangular slot-like locking opening 24 , which cooperates with a radially short locking pin 25 with a flat rectangular cross-section. Diametrically opposite, the component 18 has on its outer edge 27 a locking lug 26 which cooperates with the concave reflector surface 11 , which is relatively closely curved at that point, snap-locking.

The component 18 suitably consists of a ge certain spring return force having inherently elastic body. Namely, the component 18 is a plastic injection molded part made of polycarbonate, which is translucent, that is to say translucent, but due to special pigment inclusions it represents a frosted-glass, diffuse, scattering flat body.

The longitudinal rectangular locking opening 24 together with the locking pin 25 ensures a flat rectangular cross section with only two locking or fastening points 21, a tilt-free radial fastening position of the component 18 .

It is conceivable that the air passage opening 23 , which, as can be seen from FIG. 2, is located within the lamp receiving space 13 , allows effective cooling air circulation. The latter is still improved by the fact that a circumferential air passage gap 28 is present between the outer edge 27 of the construction part 18 and the adjacent reflector surface 11 . In the event that the diffusely scattering surface-like component is trough-shaped or trough-shaped in the case of an elongated illuminant, each air passage gap extends parallel and in a straight line to the adjacent reflector surface. The respective air passage gap 28 is only interrupted by the locking or fastening points 21 between the diffusely scattering construction part 18 and the reflector 12 .

As seen in Fig. 3 is conceivable that the air passage opening 23 at the same time constitutes a finger punch-through opening, the hen a Herunterzie in a simple manner and at the same time 18 allows disengagement of the component from its fastening location on the reflector 12. An assembly of the component 18 is carried out in the reverse manner just as simple that one pushes the inherently elastic component 18 with its upward-facing hollow side centrally into its fastening position.

Claims (15)

1. luminaire ( 10 ) with a reflector ( 12 ) and a diffusely scattering component ( 18 ), the reflector ( 12 ) forming at least one symmetrically designed reflector surface ( 11 ) and a lamp receiving space ( 13 ) for at least one lamp ( 14 ) and is delimited at the front on the light exit side by a front reflector edge ( 15 ) which surrounds a planar light exit surface (E), a luminous surface ( 16 ) formed in the light exit direction at a distance after the illuminant ( 14 ), formed by the separate flat component (which diffuses the light) 18 ), is arranged, the light emitting from the luminous surface ( 16 ) to the reflector surface ( 11 ), the luminous surface ( 16 ) in a section containing the axis of symmetry (y) of the lamp ( 10 ) within a certain angular range Shielding angle (α) in the geometric shadow space (R), the shielding angle (α) by a free end leg l (S) and a leg formed by an outward extension ( 17 ) of the cutting line of the light exit surface (E), characterized in that the interior ( 20 ) of the reflector ( 12 ) in a rear area and in a front area is divided, the rear area forming the lamp receiving space ( 13 ) for the lamp ( 14 ), with each other lying, inclined to the axis of symmetry (y) of the reflector ( 12 ) extending into this, intersecting extensions (S1) of the free end leg set (S) of the shielding angle (α) has a front cross-sectional boundary (19) of the lamp receiving space (13), wherein the light diffusing separate two-dimensional component (18) anrandet of the lamp receiving space (13) to the front cross-sectional boundary (19) or between the cross-sectional boundary ( 19 ) of the lamp receiving space ( 13 ) and the lamp ( 14 ) are arranged is, which has a spatially arbitrarily designed lamp surface. 2. Luminaire with a reflector according to claim 1, characterized in that the diffusely scattering component ( 18 ) has grid-like light passage openings ( 22 ). 3. lamp with a reflector according to claim 2, characterized in that the grid-like light Diffusely scattering component with passage openings is formed from opaque material. 4. lamp with a reflector according to claim 3, characterized in that the diffusely scattering component consists of wire mesh. 5. Luminaire with a reflector according to claim 1 or according to claim 2, characterized in that the diffusely scattering component ( 18 ) consists of translucent opaque or milk glass-like material. 6. Luminaire with a reflector according to one of the claims che 1 to 5, characterized in that the diffuse scatter end flat component from between them air passage column-forming individual elements is composed. 7. lamp with a reflector according to one of Ansprü che 1 to 6, characterized in that with a compact th illuminant ( 14 ) with z. B. spherical, piston-like or the like. The diffusely scattering component ( 18 ) represents a substantially rotationally symmetrical body. 8. lamp with a reflector according to claim 7, characterized in that the rotationally symmetrical body per, tapering towards the front, conical or frustoconical is trained. 9. Luminaire with a reflector according to one of the claims che 1 to 6, characterized in that with a langge stretched bulbs with a cylindrical surface diffusely scattering component a closed at the front represents essential trough or trough-like body. 10. Luminaire with a reflector according to one of claims 1 to 9, characterized in that the diffusely scattering component ( 18 ) has at least one air passage opening ( 23 ) which is also used for assembly handling. 11. Luminaire with a reflector according to claim 10, characterized in that with a compact illuminant tel ( 14 ) with z. B. spherical, piston-like or the like. Surface which has a substantially rotationally symmetrical body representing diffusely scattering component ( 18 ) has the air passage opening ( 23 ) which is arranged rotationally symmetrically to the axis of rotation (y) of the lamp ( 10 ). 12. Luminaire with a reflector according to claim 10, characterized in that in the case of an elongated illuminant with a cylindrical surface, the diffusely scattering component, which essentially represents a trough or trough-like body, has the air passage opening ( 23 ) which is mirror-symmetrical to the longitudinal center plane (M). the lamp ( 10 ) extends. 13. Luminaire with a reflector according to one of claims 10 to 12, characterized in that each air passage opening ( 23 ) forms a finger passage opening. 14. Luminaire with a reflector according to one of claims 10 to 13, characterized in that an air passage gap ( 28 ) is formed between the outer edge ( 27 ) of the diffusely scattering component ( 18 ) and the adjacent reflector surface ( 11 ). 15. Luminaire with a reflector according to claim 14, characterized in that the air passage gap ( 28 ) is interrupted only by locking or fastening points ( 21 ) between the diffusely scattering component ( 18 ) and the reflector ( 12 ).