DE202014100656U1 - lamp - Google Patents

Abstract

Luminaire having a light source arranged on a base body (3), a main reflector (4) and a plurality of secondary reflectors (10) arranged adjustably separately on the main reflector (4), the main reflector (4) having a reflector base (5) and a reflector body (6) contains, characterized in that the light source as an LED module (9) is formed and that on the LED module (9) has a lens (16) for deflecting the light emitted by the LED module (9) also on the light in the Near the reflector base (5) lying areas of the reflector body (6) is arranged.

Description

The invention relates to a luminaire according to the preamble of claim 1.

Such a luminaire has a light source arranged on a basic body, a main reflector and a plurality of secondary reflectors which are arranged separately adjustably on the main reflector. The main reflector includes a reflector base and a reflector body with a reflector opening on which the secondary reflectors are arranged. Such a lamp is used to produce a basic lighting and additional accent lighting, with a uniform basic lighting can be achieved by the main reflector, while special lighting effects can be achieved by the individually adjustable secondary reflectors. In the previously known luminaires of this type conventional incandescent or gas discharge lamps are used as light sources. However, these have a relatively high power consumption and a significant heat development in the beam direction.

The object of the invention is to provide a luminaire of the type mentioned, which allows energy-saving, yet efficient lighting.

This object is achieved by a luminaire with the features of claim 1. Advantageous embodiments and advantageous developments of the invention are specified in the dependent claims.

In the luminaire according to the invention, the light source is designed as an LED module with a plurality of LEDs arranged on a carrier. Such light sources have a particularly long service life and high light output with lower power consumption and lower heat development compared to conventional light sources. However, such LED modules represent a lambertian radiator with a substantially directed to one side beam direction. In order to focus the radiated by the LED module light on the secondary reflectors, is on the LED module, a lens for deflecting the of the LED Module radiated light is also disposed on the lying in the vicinity of the reflector base areas of the reflector body. From the lying in the vicinity of the reflector base areas of the reflector body, the light can be directed to the reflector surfaces of the secondary reflectors.

In a particularly compact and space-saving design, the LED module can be designed as a so-called chip on board (COB) LED, in which a plurality of individual LED chips are mounted on a printed circuit board. The chip terminals and the circuit board are connected by wire bonding and the chip is then covered by epoxy resin and protected. The COB technology allows high LED packing densities so that more light can be emitted from a smaller area. In addition, a very flat and space-saving design can be achieved.

To achieve the desired light distribution, the lens may be formed in an expedient embodiment in the form of a cup or lid with a peripheral edge whose outer surface is multi-stepped several overlapping inclined surfaces. The bottom of the lens may include a central convex curvature and a plurality of domed concentric annular projections of a wedge-shaped cross-section.

The lens may e.g. be removably attached via a snap connection to an adapter ring of the body.

The secondary reflectors are expediently arranged pivotably in all directions on a holder fastened to the inside of the reflector body. Depending on the area of use, the secondary reflectors can have a concave, convex or even reflector surface. As a result, different lighting effects can be achieved.

Other features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the drawings. Show it:

1 a luminaire according to the invention in cross section and

2 a light mixer of in 1 shown lamp in cross section.

In the 1 in a cross section shown light contains one here from an adapter ring 1 and a heat sink 2 formed body 3 and a main reflector constructed here in the manner of a paraboloidal parabolic stump 4 , one at the bottom of the main body 3 arranged reflector base 5 and a curved reflector body 6 with a round reflector opening here 7 contains. The main reflector 4 points in its reflector floor 5 an opening 8th for one in the adapter ring 1 of the basic body 3 arranged LED module 9 as a light source.

In the area of the reflector opening 7 of the main reflector 4 are several separately adjustable secondary reflectors 10 intended. The secondary reflectors 10 Depending on the area of application, a concave, convex or even reflector surface can be used 11 and are at one on the inside of the reflector body 6 attached bracket 12 arranged pivotally. The holder 12 consists of one on the inside of the main reflector 4 fixed sheet metal with a in the central axis of the main reflector 4 arranged lower retaining bridge 13 on which two spaced apart slices 14 and 15 are attached. Between the two discs 14 and 15 are the spherical ends 16 of bars 17 stored at which the secondary reflectors 10 are attached. The spherical ends 16 the bars 17 are between the two discs 14 and 15 rotatably mounted so that the secondary reflectors 10 can be swiveled in all directions.

The in the adapter ring 1 arranged LED module 9 is designed as a so-called chip on board (COB) LED. In this LED module 9 a plurality of individual LED chips mounted on a circuit board, wherein the chip terminals and the circuit board are connected by wire bonding. The chip is then covered by epoxy resin and protected. LED modules manufactured using COB technology have a longer life and higher light output compared to conventional light sources. In addition, such LED modules also have less heat development in the beam direction. In addition, such LED modules can also be built very flat and thus require only a small installation space.

On the LED module 9 is an in 2 separately shown lens 18 arranged through which the of the LED module 9 also sheds light on the near the reflector base 5 lying areas of the reflector body 6 can be steered. The cup-shaped lens made of a highly transparent material 18 has a floor 19 and a circumferential, multi-stepped on the outside edge 20 with several superimposed inclined surfaces 21 on the outside. The floor 19 the lens 18 contains on the outside a central, convex curvature 22 and several to the vault 22 concentric annular projections 23 which have a wedge-shaped cross-section. The Lens 18 includes detents not shown here, via which the lens 18 in the manner of a snap connection detachable to the adapter body 1 of the basic body 3 can be attached.

The Lens 18 represents a Fresneloptik combined with light-mixing structures, whereby optimal mixing can be achieved and the formation of visible color fringes can be avoided especially at the outer edge positions and on the adjustable secondary reflectors. Through the lens 18 Both a basic lighting and a directed focusing of the light is achieved on the secondary reflectors.

How special 1 shows, is the lens 18 designed so that part of the LED module 9 radiated light to that in the area of the refectory bottom 5 lying inner part of the reflector body 6 steered and from there to the reflector surfaces 11 the secondary reflectors 10 is reflected to produce focused and directable light cone for creating special lighting effects. About the lens 18 But also a homogeneous basic lighting is achieved directly under the lamp, without the holder 12 in the projection.

Claims (10)

Luminaire with a on a basic body ( 3 ) arranged light source, a main reflector ( 4 ) and several at the main reflector ( 4 ) separately adjustable arranged secondary reflectors ( 10 ), the main reflector ( 4 ) a reflector base ( 5 ) and a reflector body ( 6 ), characterized in that the light source as an LED module ( 9 ) and that on the LED module ( 9 ) a lens ( 16 ) for deflecting the from the LED module ( 9 ) radiated light also on the near the reflector base ( 5 ) lying areas of the reflector body ( 6 ) is arranged. Luminaire according to claim 1, characterized in that the LED module ( 9 ) is designed as a chip on board LED. Luminaire according to claim 1 or 2, characterized in that the lens ( 16 ) in the form of a cup with a bottom ( 19 ) and a peripheral edge ( 20 ) is trained. Luminaire according to claim 3, characterized in that the edge ( 20 ) of the lens ( 18 ) is stepped on the outside several times over several inclined surfaces ( 21 ) contains. Luminaire according to claim 3 or 4, characterized in that the floor ( 19 ) of the lens ( 18 ) on the outside a central, convex curvature ( 22 ) and several to the vaulting ( 22 ) concentric annular projections ( 23 ) having a wedge-shaped cross-section. Luminaire according to one of claims 1 to 5, characterized in that the lens ( 18 ) via a snap connection detachable on an adapter ring ( 1 ) of the basic body ( 3 ) is attached. Luminaire according to one of claims 1 to 6, characterized in that the secondary reflectors ( 10 ) at one on the inside of the reflector body ( 6 ) mounted bracket ( 12 ) arranged rotatable and pivotable. Luminaire according to claim 7, characterized in that the holder ( 12 ) from one on the inside of the main reflector ( 4 ) fixed plate with a in the central axis of the main reflector ( 4 ) arranged lower retaining web ( 13 ), on which two spaced-apart discs ( 14 . 15 ) are attached. Luminaire according to claim 8 characterized in that (between the two discs 14 . 15 ) the spherical ends ( 16 ) of bars ( 17 ) to support the secondary reflectors ( 10 ) are attached. Luminaire according to one of claims 1 to 9, characterized in that the secondary reflectors ( 10 ) a concave, convex or even reflector surface ( 11 ) exhibit.

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