EP2994695A1 - Reflector assembly having a plurality of reflectors and semiconductor light sources - Google Patents

Abstract

The invention relates to a reflector assembly (24) for a lighting device (31) comprising a plurality of reflectors (18, 19) for at least one semiconductor light source (27) each, wherein the reflectors (18, 19) are reflector sub-regions (18a, 18b, 19a, 19b) of a common, continuous sheet-metal part (11) and the reflector sub-regions (18a, 18b, 19a, 19b) have wing regions (21, 22) bent at least partially from the sheet-metal part (11; 41; 51). A lighting device (31) comprises at least one reflector assembly (24), wherein at least one semiconductor light source (27) is arranged on the sheet-metal part (11). A method is used to produce a reflector assembly (24), wherein the method comprises at least the following steps: introducing slits (23) into a sheet-metal part (11) in order to provide wing regions (20, 21) that can be bent from the sheet-metal part (11); and bending over the sheet-metal part (11) including bending out the wing regions (20, 21) in order to form at least one reflector (18, 19). The invention can be applied in particular to lamps for general lighting, in particular for area lighting.

Description

description

Reflector arrangement with multiple reflectors and

HalbleiterIichtquellen

The invention relates to a reflector arrangement for a

Lighting device having a plurality of reflectors for each at least one semiconductor light source. The invention further relates to a lighting device with at least one such reflector arrangement. The invention also relates to a method for producing such a reflector arrangement. The invention is particularly applicable to lights for general lighting, in particular for surface lighting. Linear arrays of multiple reflectors have heretofore been provided either by fabricating the reflectors one at a time and then mounting them side by side on a common carrier, or by inserting crossbars into a linear reflector trough. A linear reflector trough typically has a rectilinear, band-shaped bottom and laterally obliquely upstanding, reflective side walls. The cross blades may e.g. inserted in slots in the side walls or on the

Side walls snapped or glued. However, both arrangements are relatively complicated to produce.

It is the object of the present invention to overcome the disadvantages of the prior art at least partially and in particular a possibility for simplified

Providing a reflector arrangement with several

 Reflectors, in particular linearly arranged reflectors to provide.

This object is achieved according to the characteristics of the independent

Claims solved. Preferred embodiments are

in particular the dependent claims. The object is achieved by a reflector arrangement for a lighting device. The reflector arrangement has a plurality of reflectors for at least one semiconductor light source. The reflectors are reflector portions of a common continuous sheet metal part. The reflector portions have at least partially bent out of the sheet metal part wing areas.

This reflector assembly has the advantage that it is made of a single piece, namely the sheet metal part, so that there are no connection techniques for joining

several parts such as gluing, soldering, welding, etc. need to be used. Simple methods are sufficient for partially cutting out the wing areas and for reshaping the wing

Sheet metal part. The reflector assembly is also particularly stable ausgestaltbar due to their integral nature.

A reflector like a reflector for a

 Semiconductor light source or a (common) reflector for a plurality of semiconductor light sources.

Preferably, the at least one

Semiconductor light source at least one light emitting diode. at

If several LEDs are present, they can be lit in the same color or in different colors. A color may be monochrome (e.g., red, green, blue, etc.) or multichrome (e.g., white). This can also be done by the at least one

LED emitted light is an infrared light (IR LED) or an ultraviolet light (UV LED). Several

Light emitting diodes can produce a mixed light; e.g. a white mixed light. The at least one light-emitting diode may contain at least one wavelength-converting phosphor

(Conversion LED). The phosphor may alternatively or additionally be arranged away from the light-emitting diode

("Remote Phosphor"), eg on the reflector section or on the reflector. The at least one light-emitting diode can be in the form of at least one individually housed light-emitting diode or in the form of at least one LED chip. Several LED chips ^

can be mounted on a common substrate ("submount"). The at least one light emitting diode may be equipped with at least one own and / or common optics for beam guidance, e.g. at least one Fresnel lens,

Collimator, and so on. Instead of or in addition to inorganic light emitting diodes, e.g. based on InGaN or AlInGaP, organic LEDs (OLEDs, for example polymer OLEDs) can generally also be used. Alternatively, the at least one semiconductor light source may be e.g. have at least one diode laser.

That the wing areas from the remaining sheet metal part

In particular, the wing portions are partially separated from the rest of the sheet metal part, e.g. through one or more cuts.

As a result, they can be bent out at their at least one free edge against adjacent areas of the sheet metal part. The bent out wing area and the to it

adjacent, unbent portions of the sheet metal part are thereby offset from one another, e.g. staggered. The

Wing sections are still connected to the rest of the sheet metal part by at least one non-intersecting transition (also referred to as a "material bridge")

Wing areas allow a particularly diverse

Shaping the reflectors. The cuts can e.g. be introduced by a laser separation method.

It is generally preferred that the reflectors

Shell reflectors with correspondingly reflective

trained interior walls are. The reflector portions or the reflectors may be generally reflective or diffuse reflective. At least one semiconductor light source may then illuminate light into the reflector through a neck opening or be arranged on the reflector at the half opening. Light typically enters one of the neck openings

opposite light exit opening of the reflector. The light exit opening usually has a larger cross-section than the neck opening. The sheet metal part may be metallic, eg made of aluminum or steel, but also made of thin plastic ("plastic sheet") .The sheet metal part is however not limited to this and may eg also be a thin metal-laminated plastic or the sheet metal part can generally be considered a thin one It is an embodiment that the sheet metal part is bent to at least one linear reflector trough, wherein the

Reflector trough a band-shaped bottom and laterally thereof each having at least one upturned side wall. In particular, the linear reflector trough likes at each

Longitudinal side of the soil along the bottom have a continuous side wall. This embodiment allows the formation of the reflector trough by simple bends or kinks along straight, in particular parallel to each other bending lines. Such a reflector trough is particularly easy to produce, if the sheet metal part itself is already band-shaped.

It is still an embodiment that the side walls have the reflector portions and bent out

Wing areas of the reflector sections in the

 Reflector trough are bent into it. This allows the

Reflectors are generated by simply bending in the wing areas in the reflector trough. In particular, a reflector can be formed by at least two bent wing regions of opposite reflector subregions and by sections of the side walls lying between the wing regions. Such a reflector may in particular be a circulating reflector or shell reflector.

It is yet another embodiment that the two

Reflector sections of a common reflector symmetrical to a median plane which is perpendicular to the ground are formed.

It is a further development that the two reflector subregions are mirror-symmetrical to the median plane

are formed. For this purpose, in particular two wing areas are present per reflector on each side wall, ie per

Reflector four wing areas. The wing portions of a reflector portion are separated by an intermediate (middle) reflector portion of the side wall (which remains on the side wall). The wing areas are in particular with respect to a longitudinal extent of the

Reflector troughs in front and behind this middle

Reflector section arranged, but otherwise

cut free. To form a deflected into the reflector trough reflector wall may be opposite

Wing areas similar to gates in the reflector trough

be bent in, so that the reflector has two two-part reflector walls there. The wing areas can be bent into their parallel position in the reflector trough or even so that they are inclined

to stand by each other . In particular, it is preferred that there is no or no between adjacent wing regions

significant gap remains through which light could escape laterally. For this purpose, the wing regions are preferably provided with a width which corresponds at least to half the width of the reflector trough at the corresponding height.

It is still a further development that the two reflector subregions are perpendicular to the ground

 Center axis point symmetrical or formed by 180 ° rotational symmetry. To the reflector walls across the

Form reflector trough, then only one wing area is available per reflector on each side wall. To form a reflector wall projecting into the reflector trough, the wing areas can be similar to gates in the reflector trough

be bent in, but now in particular one-piece. In particular, it is preferred that between such _r

Wing area and the opposite side wall no or no significant gap remains, through which light could escape laterally. For this purpose, the wing regions are preferably provided with a width which corresponds at least to a width of the reflector trough (at the corresponding height).

It is also an embodiment that

 Placement areas for arranging the semiconductor light sources are located on the ground. In particular, thereby the

Reflectors as shell reflectors for at least one

Serve semiconductor light source.

The semiconductor light sources may be arranged directly or indirectly on a placement region. For example, a packaged semiconductor light source may be connected with its bottom directly to the bottom of the reflector trough, e.g. attached to it. Electrical contacting of a semiconductor light source may, for example, occur via top-side contacts, e.g. can be connected via bonding wires with associated electrical connection lines, in particular conductor tracks. Alternatively, the likes

 Semiconductor light source may be a packaged semiconductor light source, which rests with at least one lower-side electrical contact directly on an electrical connection line, in particular conductor track, and with this example.

can be soldered. The housed semiconductor light sources may in particular be surface mountable components (SMT components). However, the semiconductor light sources may be e.g. also a front mounted on a substrate

Semiconductor chip, e.g. LED chip, with the substrate rests on the back of the sheet metal part.

It is basically possible to have at least one

Semiconductor light source on the side of the floor

to arrange, in particular to fix, on which also the reflector is formed. This page is also referred to as the front of the following without limitation of generality ^

Bodens called. Alternatively or additionally, it is possible that at least one semiconductor light source is arranged on that side of the floor, in particular is fastened, which faces away from the reflector. This page is in

The following without limitation of generality as well

Designated back of the floor. At a back

Arrangement, the at least one semiconductor light source, in particular by a recess in the bottom in the direction of the front through. Alternatively or additionally, the at least one semiconductor light source can be arranged in one

Recess inserted in the ground or performed to the front.

It is also an embodiment that electrical

Connecting lines to the mounting areas run on the ground. This allows a simple electrical connection of the semiconductor light sources. The

Semiconductor light sources can by means of the electric

Connecting lines to be connected in series and / or parallel to each other. The electrical connection lines may be, for example, cables, wires or printed conductors. When using non-isolated connection lines, e.g. Conductor tracks, these can rest in particular on an electrically insulating layer on the ground.

In general, a course of the electrical

Connecting lines not on any area of the

Sheet metal part limited. You can e.g. Run on areas of the sheet metal part, which no bottom of a

Reflect reflector troughs.

It is also an embodiment that wing portions, which cross electrical connecting lines, the

 Traverse connecting lines spaced. This can be an unwanted electrical contact with exposed

 Connecting lines as well as an unwanted mechanical stress on the connecting lines through the

Wing areas are prevented. It is still an embodiment that the reflector arrangement has a plurality of reflector troughs. As a result, a particularly high number of reflectors can be provided by a one-piece reflector arrangement, in particular also

a large area. This is particularly advantageous for

Area lights.

It is still an embodiment that the several

Reflector troughs are surrounded by a common frame, which holds the reflector troughs. This allows a simple way several reflector troughs at the same

Reflector arrangement can be provided, which

Reflector troughs are multifarious and largely independent of each other are malleable.

The sheet metal part may generally have at least one recess. The recess can be introduced, for example, by local cutting, punching, etc. in the sheet metal part. The at least one recess may in particular serve to conduct a semiconductor light source and e.g. be introduced in the bottom of a reflector trough.

The object is also achieved by a lighting device having at least one reflector arrangement as described above, wherein at least one semiconductor light source is arranged on the sheet metal part. The lighting device may be designed analogously to the reflector arrangement and have the same advantages.

Thus, it is a development that the lighting device has at least one reflector arrangement with at least one reflector trough, wherein the at least one

Semiconductor light source is disposed at the bottom of the reflector trough. It is also an embodiment that at least one electrical connection line runs at the bottom of the reflector trough. "

It is also a continuing education that in one

Reflector trough arranged semiconductor light sources and

associated interconnections on a common

Substrate are arranged. As a result, their arrangement on the sheet metal part can be done in a particularly simple and time-saving manner. Thus, by arranging, in particular attaching, the

common substrate on the sheet metal part (for example, by gluing a back of the substrate) arranged all the functional elements located thereon in one step, in particular fixed. Also, an alignment of the functional elements in the arrangement can be omitted.

It is still a development that the common substrate is a band-shaped - flexible or rigid - circuit board, which together with the semiconductor light sources and the

Connecting lines forms a so-called light strip, in particular an LED strip. Such light bands are e.g. in the form of LED ribbons from Osram, e.g. of the type LINEARLight,

commercially available. The use of a luminous band has the further advantage of being e.g. by

Retaining tabs on the sheet metal part form-fitting and / or

is frictionally fastened. The retaining tabs are in particular also herausbiegbare on the sheet metal part

Subareas.

The type of lighting device is not limited and may be, for example, a lamp or a lamp. Particularly preferred is an embodiment as a light for

General lighting, in particular for area lighting. The lamp may in particular be a ceiling light or a wall lamp.

The problem is also solved by a method for

Producing a reflector arrangement as described above.

The procedure may at least follow the steps below

comprising: (i) inserting slots in a sheet metal part to provide for bending out of the sheet metal part Wing portions; and (ii) bending the sheet metal part including bending out the wing portions to form at least one reflector, in particular

Bowl reflectors.

The method may be formed analogously to the reflector arrangement and / or the lighting device and has the same advantages. In particular, in step (ii), the method may include bending the sheet metal part, including bending out the wing sections, to form at least one linear one

Include reflector troughs, in particular with at least two reflectors. The forming of the reflectors may be like bending out the wing area into the associated one

Include reflector trough inside.

The bending can in particular a bending or angling of two portions of the sheet metal part to a common

Include bending line.

It is a development that the bending of the sheet metal part for forming at least one linear reflector trough a

Bend to the same side along two parallel

Bending lines includes. The area between the two

 Bend lines can serve as a floor, the two areas on the side of the floor can serve as sidewalls. The

Wing areas can at least partially from the

Side walls are bent out. In particular, the wing regions can be completely bent out of the side walls, alternatively or additionally bent out of the side walls and out of the bottom.

The above-described characteristics, features and advantages of this invention as well as the manner in which they are achieved will become clearer and more clearly understood

In connection with the following schematic description of exemplary embodiments that are associated with the Drawings are explained in more detail. It can to

Clarity identical or equivalent elements must be provided with the same reference numerals. Fig.l shows a plan view of a sheet metal part for producing a reflector assembly according to a first

 Embodiment;

2 shows in a view obliquely from above the

 finished reflector arrangement of Fig.l;

Fig.3-6 shows the reflector assembly of Figure 2 in one

 Cross-sectional view with differently shaped side edges;

7 shows the sheet metal part from Fig.l with additional electrical wiring and equipment with

 Semiconductor light sources;

 8 shows a plan view of a sheet metal part for producing a reflector assembly according to a second embodiment; and

9 shows a plan view of a sheet metal part for producing a reflector arrangement according to a third

Embodiment.

Fig.l shows a top view of a section of a

Sheet metal part 11 for producing a reflector assembly according to a first embodiment. The sheet metal part 11 is made of metal, e.g. Steel or aluminum, at least

is formed on one side reflective. The sheet metal part 11 is formed here linearly band-shaped with a longitudinal axis L. The sheet metal part 11 is partially provided with slots 23 and partially bent to produce the reflector assembly 24 shown in Figure 2. Thus, parallel to and symmetrical to the longitudinal axis L four longitudinally extending bending lines Bl, B2, B3 and B4 are present, on which the sheet metal part 11 is bent. In particular, the sheet metal part 11 at the inner

Bend lines B2 and B3 from the image plane in the direction of

Viewer bent up. This creates a trench or linear reflector trough 13 to 15 with a in the

Longitudinal L extending central bottom 13 and two thereof laterally outgoing side walls 14 and 15. The bottom 13 is of the side walls 14 and 15 through the inner

Bend lines B2 and B3 delimited. The side walls 14 and 15 may be bent at the outer bending lines Bl and B4 and there form side edges 16 and 17.

The side walls 14 and 15 each have a plurality of reflector subregions 18a, 18b, 19a, 19b, wherein each two subregions 18a, 18b and 19a, 19b with respect to the longitudinal axis L are opposite and symmetrical.

 Adjacent reflector portions 18a, 19a and 18b, 19b of the same side wall 14 and 15 are arranged equidistant from each other.

Each of the reflector subregions 18a, 18b, 19a, 19b has a central region 20 which extends continuously between the two associated bending lines Bl, B2 or B3, B4

extends. On both sides of the central regions 20, viewed in a longitudinal extension along the longitudinal axis L, there are regions which are referred to below as

"Wing regions" 21, 22 and which are delimited from the central region 20 by bending lines B5, B6 The bending lines B5, B6 extend in a straight line over the entire height of the central region 20 between the

Bend lines Bl, B2 or B3, B4. Here are the run

Bend lines B5, B6 obliquely, in such a way that the

Central area 20 of the inner bending line B2 or B3 to the outer bending line Bl or B4 expands or increases in its width. The central region 20 thus has the shape of an isosceles trapezium.

The wing portions 21, 22 are separated by respective through slots 23 from the remaining sheet metal part 11. The wing areas 21 and 22 thus depend only on the

Bend lines B5 and B6 with the rest of the sheet metal part 11 together and can therefore be bent out of the sheet metal part 11 at the bending line B5 or B6. The wing portions 21, 22 may alternatively be cut into the ground 13, as indicated by the dotted lines

Lines indicated. This gives the wing portions 21, 22 a larger area, which increases a light output.

2 shows in a view obliquely from above the sheet metal part 11 finished bent reflector assembly 24. The side walls 14 and 15 and the bottom 13 form the linear reflector trough 13 to 15, to which the side edges 16 and 17 connect. The side edges 16 and 17 may constitute part of the reflector trough 13-15.

By the reflector regions 18a and 18b, 19a and 19b respective reflectors 18 and 19 are formed. The reflectors 18 and 19 are each as a truncated pyramid

 Tray reflectors formed. The four reflective sidewalls are composed of the central regions 20 and opposite wing regions 21 and 22, which are bent vertically into the reflector trough 13 to 15

adjoining wing portions 21 and 22 themselves

Opposite reflector portions 18a, 18b and 19a, 19b located in the reflector trough 13 to 15

Forming reflective side walls, their width is half the width of the reflector trough 13 to 15 and the distance of the side walls 14, 15 at the appropriate height. This will form a gap between them

adjacent wing areas 21 and 22 prevents or at least kept so small that it no

Significant loss of light results.

The section of the bottom 13 delimited by the wing regions 21 and 22 may also be reflective and serves as the assembly region 25 for at least one

Semiconductor light source.

The wing portions 21 and 22 are taken here on its underside and from the bottom 13 so that they are in

bent out state may extend to the bottom 13. The wing portions 21 and 22 have on their bottom 13 facing the bottom one (in Fig.l not

drawn) recess 26, wherein the recesses 26 adjoin one another and together form a central passage.

3 shows the finished reflector arrangement 24 from FIG. 1 in a cross-sectional view with differently shaped side edges 16 and 17. While in the variant of the reflector arrangement 24 shown in FIG. 2 the side edges 16 and 17 are vertically upright, they are along in FIG the outer bending lines Bl and B4 bent vertically downwards. In contrast, in Figure 4, the side edges 16 and 17 are folded over horizontally along the outer bending lines Bl and B4. The side edges 16 and 17 are formed curved in Fig.5 in cross section from the bending line Bl or B4 downwards, curved in Figure 6 to the side.

7 shows the sheet metal part 11 with additional electrical wiring and equipment with semiconductor light sources.

In addition to the sheet metal part 11 of Fig.l is now the

band-shaped bottom 13 at the mounting areas 25 each occupied by a semiconductor light source in the form of a light emitting diode 27. The type of light-emitting diodes 27 is basically

Any, they are here designed as LED chips, which via an electrically insulating substrate 28 on the

Placement area 25 are fixed, for example, are glued. Between the equipping regions 25 and the light-emitting diodes 27, electrical connection lines run in the form of two parallel conductor tracks 29. The conductor tracks 29 are applied to the floor 13 via an electrically insulating layer 30 and supply the light-emitting diodes 27 with electrical energy. The conductor tracks 29 extend in the finished bent state of the sheet metal part 11 through the recess 26 of the wing portions 21 and 22, so that the wing portions 21 and 22 cross the tracks 29 spaced. The so-equipped, finished bent sheet metal part 11 can serve as a lighting device 31.

8 shows in plan view a simplified sketch of a sheet-metal part 41 for producing a reflector arrangement 42 according to a second exemplary embodiment.

The sheet metal part 41 differs from the sheet metal part 11 in that it now has three rows R1, R2, R3 of four linearly arranged reflectors 18 and 18a, 18b and not just one row. The sheet metal part 41 can thus be bent to a reflector assembly 42, which three

has contiguous linear reflector troughs Tl, T2, T3 similar to the reflector troughs 13 to 15. neighboring

Reflector troughs Tl to T3 are connected by the same side edges 16.

Alternatively, the reflector portions 18a, 18b, etc. may also be completely bent out of the sheet metal part 41 and, in particular, may be additionally fixed in the following, e.g. through a lid.

9 shows in plan view a simplified sketch of a sheet-metal part 51 for producing a reflector arrangement 52 according to a third exemplary embodiment. The sheet metal part 51 is formed similarly to the sheet metal part 41, but now the common reflector troughs T4, T5 or T6 forming rows of four reflectors 18a, 18b are cut out of the sheet metal part 51 to a transition 53 on the end sides of the bottom 13 rectangular. The associated rectangular sections 54 thus extend between the two transitions 53. This reflector arrangement 52 has the advantage that the

Reflector troughs T4 to T6 now no longer at their

Side edges are related, but are independently formable. The reflector troughs Tl to T3 still hang together mechanically via a common, circumferential frame 55 which holds the reflector troughs T4 to T6 at their transitions 53. The reflector troughs T4 to T6 can also be electrically connected to each other, for example, the fact that common tracks traverse the transitions 53 and run on the common frame 55.

Although the invention is shown in detail by the

Embodiments have been further illustrated and described, the invention is not limited thereto and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Generally, "on", "an", etc. may be taken to mean a singular or a plurality, in particular in the sense of "at least one" or "one or more" etc., unless this is explicitly excluded, e.g. by the expression "exactly one", etc.

Also, a number may include exactly the specified number as well as a usual tolerance range, as long as this is not explicitly excluded.

Reference sign

11 sheet metal part

 13 floor

14 sidewall

 15 side wall

 16 margin

 17 margin

 18 reflector

18a, 18b reflector portion

 19 reflector

 19a, 19b reflector portion

 20 middle region of a reflector portion 21, 22 wing portions

23 slot

 24 reflector arrangement

 25 equipping area

 26 recess of a wing area

 27 LED

28 substrate

 29 trace

 30 electrically insulating layer

 31 lighting device

41 sheet metal part

42 reflector arrangement

 51 sheet metal part

 52 reflector arrangement

 53 transition

 54 section

55 surrounding frame

 Bl, B4 outer bending lines

 B2, B3 inner bending lines

 B5, B6 Bend lines of the wing areas

 L longitudinal axis

R1-R3 rows of reflectors

 T1-T6 reflector troughs

Claims

claims

Reflector arrangement (24; 42; 52) for a

 Lighting device (31), comprising a plurality of reflectors (18, 19) for at least one

 Semiconductor light source (27), wherein

 - The reflectors (18, 19) reflector portions (18a 18b, 19a, 19b) of a common, continuous sheet metal part (11; 41; 51) are and

 the reflector subregions (18a, 18b, 19a, 19b)

 at least partially from the sheet metal part (11; 41; 51) bent out wing portions (21, 22).

A reflector assembly (24; 42; 52) according to claim 1 wherein

- The sheet metal part (11, 41, 51) to at least one

 linear reflector trough (13-15; T1-T3; T4-T6) is bent,

 - The reflector trough (13-15, T1-T3, T4-T6) one

 band-shaped bottom (13) and laterally thereof each have a bent-up side wall (14, 15),

- The side walls (14, 15), the reflector portions (18a, 18b, 19a, 19b) and have

 - bent-out wing portions (20, 21) of the reflector portions (18a, 18b, 19a, 19b) in the

 Reflector trough (13-15, T1-T3, T4-T6) are bent.

A reflector assembly (24; 42; 52) according to claim 2, wherein a reflector (18, 19) is formed by at least two folded wing portions (20, 21) of opposed reflector portions (18a, 18b, 19a, 19b) and between the wing portions (20 , 21) lying portions (20) of the side walls (14, 15) is formed. 4. Reflector arrangement (24; 42; 52) according to one of claims 2 to 3, wherein the two reflector subregions (18a, 18b, 19a, 19b) of a common reflector (18, 19) symmetrical to a perpendicular to the ground (13)

standing median plane are formed.

Reflector arrangement (24; 42; 52) according to one of claims 2 to 4, wherein mounting areas (25) for

Arranging the semiconductor light sources (27) on the bottom (13) are located.

A reflector assembly (24; 42; 52) according to claim 5, wherein electrical connection leads (29) are connected to the

Placement areas (25) on the bottom (13) extend.

A reflector assembly (24; 42; 52) according to claim 6, wherein wing portions (20, 21) which are electrical

Crossing connecting lines (29), the

Crossed connecting lines (29) spaced.

A reflector assembly (52) according to any one of claims 2 to 7, wherein the reflector assembly (52) comprises a plurality of

Reflector troughs (T4-T6), by a

common frame (55) are surrounded, which the

Reflector troughs (T4-T6) stops.

Lighting device (31) comprising at least one

Reflector arrangement (24; 42; 52) according to one of

preceding claims, wherein at least one

Semiconductor light source (27) on the sheet metal part (11; 41; 51) is arranged.

A lighting device (31) according to claim 9, comprising at least one reflector assembly (24; 42; 52) according to any one of claims 2 to 9, wherein the at least one semiconductor light source (27) is secured to the bottom (13, 25) of the reflector trough (13-15; T1-T3; T4-T6).

A method of manufacturing a reflector assembly (24; 42; 52) according to any one of claims 1 to 8, said method comprising at least the following steps: - Introducing slots (23) in a sheet metal part (11) for providing from the sheet metal part (11) herausbiegbaren wing areas (21, 22);

 - bending the sheet metal part (11) including bending out the wing areas (21, 22) to form at least one reflector (18, 19).