DE102007059607A1 - Wall and / or ceiling light - Google Patents

Abstract

The present invention generally relates to a luminaire and in particular a wall and / or ceiling luminaire with at least one light source, preferably in the form of an LED, which is associated with a reflector arrangement with at least one reflector for deflecting the light emitted by the light source. In order to be able to build very small, it is proposed to arrange the at least one light source directly on a printed circuit board, by means of which the said light source is driven and / or supplied with energy. As a result, not only can be built very compact, but it is also a good heat dissipation achieved because part of the heat generated by the lamp can be derived directly across the circuit board area.

Description

The The present invention relates generally to a luminaire, and more particularly a wall and / or ceiling light with at least one light source preferably in the form of an LED, which is a reflector arrangement with at least one Reflector associated with the deflection of the light emitted by the lamp is.

Wall- and ceiling lights mounted as surface-mounted or wall-mounted and / or ceiling panels integrated, for example in Paneelausnehmungen can be sunk or can be sunk in the ground as a floor lamp, regularly subject to one Variety of different, often opposing arrangements. While on the one hand ever smaller sizes required On the other hand, high luminosity with uniform room illumination should nevertheless be achieved be achieved. It is not only the small size itself problematic and difficult with the required room lighting To bring harmony, but also the associated thermal Problems are difficult to solve. For small dimensions, the bulb sits at a small distance very close to the adjoining corpus areas, on the other hand there is a total of little corpus area for the dissipation of the resulting heat to disposal. On the other hand arise in small-sized, point-shaped light sources with high Luminosity often a dazzling effect and a perceived as unpleasant Light distribution.

Of these, The present invention is based on the object, to create an improved luminaire, the disadvantages of the state avoids the technique and the latter develops in an advantageous manner. In particular, a small-sized, easy-to-manufacture wall and / or ceiling light to be created with a high luminaire efficiency can generate a high amount of light at a designated target area.

According to the invention this Task by a lamp according to claim 1 solved. Preferred embodiments of the invention are the subject of the dependent claims.

Around to be able to build very small, It is proposed that at least one light source directly to arrange on a printed circuit board, by means of which said light source controlled and / or supplied with energy. This can not only be built very compact, but it will also be a good one Heat dissipation reached, since part of the heat generated by the light source are dissipated areally via the printed circuit board can.

Especially The advantage of using a printed circuit board, if one Are provided plurality of bulbs. In this case, yield special advantages in terms of the supply of lighting even if the mentioned bulbs are not immediately on the printed circuit board sit. The otherwise necessary, extensive connection cable can omitted or are these integrated into the printed circuit board, so that achieved in a variety of bulbs a compact arrangement can be.

are provided a variety of bulbs, can basically different arrangements the light source may be provided on the circuit board, for example a staggered, matritzenförmige Arrangement of the bulbs. A particularly advantageous embodiment of Invention may consist in that the bulbs from each other spaced apart in series next to each other. This is possible especially a small wall and / or ceiling lamp with slit-shaped Forming light emission. It may be advantageous if the printed circuit board an elongated, overall slim contour owns, for example in the form of a rectangle.

The a common printed circuit board associated bulbs can fundamentally different be educated. The different training of the bulbs can in different light colors, different performances and / or different illuminant geometries exist, preferably punctate, but also linear bulbs Can be used. In particular, light-emitting diodes (LEDs) are provided. In an advantageous manner Development of the invention can but also several similarly designed bulbs on one be arranged common printed circuit board.

Around a good heat dissipation to achieve, especially with dense arrangement of the bulbs, can advantageously a metal core board as a printed circuit board Find use. Especially in connection with the direct attachment The light source on the circuit board may have its metal core in particularly efficient way to dissipate the heat generated, on the one hand the heat which can be directly from the bulb into the printed circuit board On the other hand, however, may also include the heat that is in the form of light rays, for example by scattering and / or reflection on the circuit board surface acts.

In order to better absorb the thermal stresses, in a preferred embodiment of the invention, at least one heat sink may be provided, which advantageously has cooling ribs for enlarging the convection surface and the conductor board and / or the at least one reflector of the reflector assembly is associated. In particular, the said heat sink can be connected to the rear side of the printed circuit board and / or the rear side of the at least one reflector, so that a heat transfer from the printed circuit board and / or the reflector can be made to the heat sink and emitted by the cooling fins thereof.

to Achieving a good heat transfer the said heatsink are in an advantageous embodiment of the invention, the circuit board and the heat sink or the at least one reflector and the heat sink conform to each other, advantageously such that a full-surface concerns of the heat sink the back of the circuit board and / or at the reflector back is provided. The heat sink can For this purpose corresponding pads own that to the back the printed circuit board and / or the back of the reflector are shaped. Advantageously, the at least a heat sink here such that essentially the entire back the printed circuit board and the entire back of the at least one Reflector covered by the heat sink is. The heat sink and the reflector can in this case designed as separate components and in the said ways be adapted to each other. Alternatively, but also be provided that the reflector in the form of a coating directly applied to the heat sink is, so that, so to speak, the corresponding heat sink surface itself works as a reflector.

The said printed circuit board can on the heat sink in principle in various ways and be attached. To achieve a good heat transfer, the PCB advantageously non-positively against the corresponding Heat sink surface pressed and / or with this form-fitting connected. A preferred embodiment may this is that the printed circuit board in a cooling bag sits in the said circuit board from its back towards you lying edges encompassed by the heat sink is, wherein advantageously separate heat sink parts are provided, the mutually and / or tensioned on said printed circuit board are. According to an advantageous embodiment of the invention, the at least one reflector and the printed circuit board separate heat sink parts be assigned, which can be interconnected, advantageously such that the printed circuit board with its back to one between the Cooling body parts formed cooling bag is tense.

Regarding Shaping the lamp naturally in principle have different designs. However, a simple and inexpensive Manufacture with high variability in the outer dimensions of the lamp to enable be provided in a preferred embodiment of the invention that the luminaire body einschießlich at least the reflector is designed as an endless extruded profile, so that he is on a desired Length be cut to length can. In particular, too the printed circuit board and the at least one heat sink in each case as an endless extruded profile be formed so that these components of the lamp on the respectively desired lamp length be cut to length can. Preferably, the heat sink has web-shaped Cooling fins, extending parallel to the longitudinal direction extend the strand profile. As a result, in particular during production medium extruded profile extrusion or continuous casting very finely formed Ribs are provided, which even with very small size of the entire lamp a big Provide heat transfer surface.

Around a perceived by the human eye as pleasant room illumination to achieve and even at high light levels to avoid dazzling, is provided in development of the invention that at least a light source is arranged dimmed. The bulb is while concealed by body contours so that a direct, straight Viewing axis is prevented in the bulb. In particular, can In this case, the reflector arrangement be designed such that the said visual axis is concealed on the at least one light source is. The light generated by the bulb does not occur directly in the room to be illuminated, but at least once over one of the reflector surfaces directed, so no primary light is radiated from the lamp but only secondary, terziäres or repeatedly reflected light is emitted into the room. In addition to the glare-free This can be a uniform, atmospheric preferred Light propagation can be achieved. Advantageously, is the Reflector arrangement formed and / or such on the training of the bulb matched that emitted by the bulb Light is essentially full on reflector surfaces meets and of these almost completely in the area to be illuminated is steered.

In order to achieve a high luminaire operating efficiency and a high amount of light at the predetermined target, it can be provided that the reflector arrangement adjoins the printed circuit board on both sides of the at least one luminous means and reflector surface edges delimit a slot-shaped light exit cross section of the lamp. The reflector arrangement extending on both sides of the luminous means almost completely intercepts the light emitted by the luminous means and throws it in the desired direction in the desired direction with a desired beam path. Advantageously, the reflector arrangement essentially adjoins directly the printed circuit board front side carrying the at least one luminous means, so that light emitted by the luminous means substantially parallel to the printed circuit board is captured by the reflector. The lamp is as it were enclosed by the reflector assembly and the circuit board.

advantageously, the reflector assembly comprises a first reflector to be illuminated by the Seen from space behind the at least one light source arranged is, as well as a second reflector to be illuminated by the Seen from space before the arranged at least one light source and advantageously designed such that of the lighting means light incident on the second reflector from said second reflector is directed to the first reflector.

The said two reflectors or reflector parts or reflector partial surfaces can in this case fundamentally different be formed, wherein advantageously the said reflectors different in terms of arrangement and training are formed. In particular, the first reflector of the Bulb be spaced further than the second reflector, wherein the corresponding distance of the first reflector is a multiple of Distance of the second reflector may be. An advantageous execution can be best hen that said second reflector, which conceals the illuminant towards the room to be illuminated or fades, immediately adjacent to the at least one light source is arranged in front of said light source. This is the reason from the said second reflector reflected pixel of the luminous means very close to the corresponding unreflected pixel, so that achieved a homogeneous, targeted illumination of the target area becomes.

Of the second reflector, immediately in front of the at least one light source sitting, is advantageously at most slightly curved, wherein he advantageously can be trained just.

Of the from the illuminated room rear, first reflector may be different in shape. In preferred execution invention, the first reflector a trough-shaped, concave curvature possess, where advantageously the radius of curvature with increasing Distance from the PCB and / or the bulb increase can.

Around a fouling or even damage to the bulb and also a contamination of the front of the at least one lamp blended Reflector part to prevent, can in development of the invention a protective glazing be provided, which is the at least one luminous means covering towards the light exit cross section. The protective glass This can together with the PCB a dust-tight cavity limit, in which the light source is arranged. As usual Align the wall and / or ceiling light in front of the bulb blinded reflector part a dust and / or dirt trapping Alignment has, it may be advantageous in this case, the protective glass also on the pull the second reflector so that the protective glazing, the printed circuit board and said second reflector the aforementioned Limit cavity. The protective glazing is advantageous here Dustproof connected to the adjacent parts to the covered Cavity dust and / or dirt-tight to close. The Protective glazing is advantageously shaped such that you at usual Alignment of the lamp one to the open light exit cross section sloping orientation takes.

The Protective glazing is hiebei advantageously transparent, so as not to affect the luminaire efficiency. Nevertheless, due to the pre-glazed protective glass a certain scatter and / or reflection back to the light source or to the printed circuit board, is advantageously provided that the printed circuit board on its the reflector assembly facing front with an at least partially reflective surface preferably in the form of a white surface coating is provided. As a result, the part of the light directed back from the protective glazing from the circuit board surface turn back reflected and directed to the reflector assembly that this part of the light then in the desired direction into the area to be illuminated.

The Protective glazing can in development of the invention at its edges be connected to the aforementioned at least one heat sink, so that thermal loads on the protective glazing are reduced, by heat transferred from the protective glass on the heat sink and derived from this becomes.

The Invention will be described below with reference to a preferred embodiment and associated Drawings closer explained. In the drawings show:

1 a cross-section through a ceiling and / or wall lamp according to an advantageous embodiment of the invention, which shows a seated on a printed circuit board illuminants, the associated reflector assembly and the surrounding the printed circuit board and the reflector assembly heat sink, and

2 : a plan view of the printed circuit board off 1 showing the arrangement of the bulbs on this printed circuit board.

The drawn in the figures wall and / or ceiling lamp 1 has an overall elongated - roughly speaking - bar-shaped contour, so that it can be advantageously integrated into slot-shaped recesses in ceiling and / or wall panels, for example, can be installed sunk into corresponding panel slots. Even if this installation option due to the small size of the lamp 1 their advantages are particularly clear, however, in alternative use, the lamp can also be mounted in a projecting arrangement, so to speak on plaster and / or freestanding on corresponding fastening devices and brackets.

In the illustrated embodiment, the lamp includes 1 a variety of bulbs 2 in the form of button-shaped LEDs 3 that is directly on a printed circuit board 4 mounted and connected to conductors inside the printed circuit board 4 are integrated. As 2 shows, the LEDs can 3 thereby advantageously spaced from each other be lined up next to each other, wherein for a slot lamp in 2 shown alignment along a straight line can be particularly advantageous. In the illustrated embodiment are different colored LEDs 3 provided, the light can mix in the target area advantageously homogeneous, so that a simple adjustment of homogeneous light colors is given, which is achieved by a good color overlay in the target area.

The printed circuit board 4 has in the illustrated embodiment an elongated, approximately rectangular contour, wherein it is advantageously flat. The printed circuit board 4 can be made as a semi-finished so to speak, which is then cut to the required length depending on the desired lamp size. About in the body of the printed circuit board 4 integrated and / or on the surface of the printed circuit board 4 applied conductor tracks, cf. 2 , that will be on the circuit board 4 sitting LEDs 3 supplied with electrical energy and controlled. By the arrangement of the LEDs 3 directly on the printed circuit board 4 can be a particularly compact design of the lamp 1 realize and accomplish a good heat dissipation. The lamp shown in the figures 1 may, for example, be considered in cross section as this 1 exhibits cross-sectional dimensions of less than 100 mm in width and less than 50 mm in height. The length of the lamp is advantageously almost freely selectable, since the components designed as continuous extruded profiles can be cut to the desired length and along the printed circuit board 4 a corresponding arbitrary plurality of bulbs 2 can be arranged.

As 1 shows is the printed circuit board 4 and the LEDs arranged thereon 3 a reflector arrangement 5 assigned to both sides of the LEDs 3 to the printed circuit board 4 adjoins and the LEDs 3 encloses together with the PCB front, so to speak. The aforementioned reflector arrangement 5 directly to the printed circuit board 4 adjacent, defines it with reflector surface edges 6 and 7 a slot-shaped light exit cross-section 8th lying in a plane which is essentially - roughly speaking - perpendicular to the plane of the printed circuit board 4 extends, cf. 1 ,

The reflector arrangement 5 includes in the illustrated embodiment two reflectors 9 and 10 , wherein a first reflector 9 Seen from the illuminated space behind the light-emitting diodes 3 is arranged while the second reflector 10 viewed from the direction mentioned in front of the light-emitting diodes 3 is arranged and covers it as a kind of aperture, so that of the light-emitting diodes 3 no direct light can be thrown into the room to be illuminated. The light-emitting diodes 3 are of the reflector assembly 5 dimmed or so obscured that they are not directly visible.

The mentioned second reflector 10 is here, how 1 shows, directly on the light emitting diodes 3 arranged, ie the second reflector 10 sits at the in 1 drawn alignment just below the light emitting diodes 3 on the printed circuit board 4 , This extremely small distance or the immediately adjacent arrangement of the second reflector 10 causes the virtual pixel of the light emitting diodes 3 that of the second reflector 10 on the first reflector 9 thrown there, in the immediate vicinity of the directly from the light-emitting diodes 3 on the first reflector 9 Thrown pixel is located so that a targeted luminance distribution is achieved in the target area to be illuminated.

As 1 shows are the two reflectors 9 and 10 thereby formed differently. In the illustrated embodiment, the first reflector 9 trough-shaped convexly curved, while the second reflector 10 is essentially planar. In the illustrated embodiment, the radius of curvature of the first reflector increases 9 with increasing distance from the printed circuit board 4 from. The area is the two reflectors 9 and 10 also differently formed. The first reflector 9 is designed substantially larger than the second reflector 10 , The latter has - roughly speaking - only about a quarter to a third of the area of the first reflector 9 , although this ratio may also change depending on the design of the reflector geometry.

As 1 shows is the second reflector 9 to the circuit board 4 and / or to the plane of the light exit cross section 8th tilted inclined at an angle, in particular to the first reflector 9 tilted, where he imagined a connecting line between the LEDs 3 and the reflector surface edge 6 of the first reflector 9 cuts through or covers. This will cause the direct line of sight to the LEDs 3 and eliminates the associated glare.

In the illustrated embodiment, the first reflector extends 9 while arcuate about - roughly speaking - of the light-emitting diodes 3 remote edge of the printed circuit board 4 until about down to the height of the LEDs 3 , see. 1 ,

In the illustrated embodiment, the printed circuit board 4 as well as the light-emitting diodes arranged thereon 3 from a protective glazing 11 covered, which is transparent, preferably clear and may for example consist of acrylic glass. The protective glass 11 extends advantageously also above or in front of the second reflector 10 so that the protective glass 11 along with the circuit board 4 and the second reflector 10 a cavity 12 limited, in which the light-emitting diodes 3 are arranged. The protective glass 11 is advantageously dustproof connected to the adjacent component contours.

To the through the light emitting diodes 3 dissipate heat generated to a sufficient extent and to avoid thermal overload, is a heat sink 13 provided the reflectors 9 and 10 the reflector assembly 5 as well as the printed circuit board 4 surrounds each back. In the illustrated embodiment, the heat sink comprises 13 while a plurality of heat sink parts that can be positively connected to each other and each have a plurality of cooling fins 16 exhibit. In the illustrated embodiment is a first heat sink part 14 provided, which is essentially the printed circuit board 4 and the second reflector 10 cools while a second heat sink part 15 the first reflector 9 cools.

To get a good heat transfer from the PCB 4 on the heat sink 13 to reach, sits the circuit board 4 in the illustrated design in a cool bag 17 coming from the two heatsink parts 14 and 15 is limited, said cooling bag 17 to the contour of the printed circuit board 4 is conformed. In particular, said printed circuit board sits 4 in a slot-shaped pocket in the heat sink part 15 , wherein an opposite edge region of the printed circuit board 4 from a paragraph of the other heat sink part 14 is gripped in a form-fitting manner, so that the printed circuit board 4 full-surface and full against the connection contour of the aforementioned heat sink part 15 can be pressed. The connection surfaces of the heat sink 13 to the printed circuit board 4 as well as the reflectors 9 and 10 are each conformed to form, it being advantageously possible to provide that the reflectors 9 and 10 can be applied directly in the form of a coating layer on the surface of said heat sink. In other words, the reflectors 9 and 10 be formed directly from corresponding surfaces of the heat sink or of coatings applied thereto.

As 1 shows, sits the protective glass 11 with their opposite edges in corresponding pockets of the heat sink 13 . 50 that also the protective glass 11 Can give off heat to the corresponding heat sink parts.

To get off the protective glass 11 not to lose reflected light or through the protective glazing 11 To influence the efficiency as little as possible, is in an advantageous manner of the invention, the protective glass 11 facing front side of the printed circuit board 4 formed reflective, wherein according to an advantageous embodiment of the invention, the front of the printed circuit board 4 may be white coated or painted.

As 1 shows, advantageously, not only the circuit board 4 , but also the other essential components of the lamp 1 be formed in the form of continuous extruded profiles, in particular the heat sink parts 14 and 15 , the reflector arrangement 5 as well as the protective glazing 11 , so that different lamp sizes can be made in a simple manner with low component diversity. The corresponding endless extruded parts only need to be cut to the desired length.

As 1 shows owns the lamp 1 advantageously a fastening device 18 , which allows adjustment movements, in particular a pivoting of the lamp 1 allows. The corresponding pivot bearing means of the fastening device 18 can be designed differently, in the illustrated embodiment in an advantageous manner to the heat sink 13 a pivoting eye is formed, which can be threaded onto a bearing rod and thus also permits an adjustment of the attachment in the longitudinal direction by moving on said rod.

Claims (22)

Luminaire, preferably wall and / or ceiling light, with at least one light source ( 2 ) preferably in the form of an LED ( 3 ), which has a reflector arrangement ( 5 ) with at least one reflector ( 9 . 10 ) is assigned to the deflection of the light emitted by the light source, characterized in that the lighting means ( 2 ) on a printed circuit board ( 4 ), which is provided for the power supply and / or control of the lighting means. Luminaire according to the preceding claim, wherein on the printed circuit board ( 4 ) a plurality, preferably at least three, illuminants ( 2 ) spaced from each other, are preferably lined up next to each other. Luminaire according to one of the preceding claims, wherein the printed circuit board ( 4 ) has a metal core. Luminaire according to one of the preceding claims, wherein the at least one luminous means ( 2 ) surface, in particular form-fitting and / or material fit on the printed circuit board ( 4 ) is attached. Luminaire according to one of the preceding claims, wherein the printed circuit board ( 4 ) and / or the at least one reflector ( 9 . 10 ) at the back with at least one preferably cooling fins ( 16 ) having heat sink ( 13 ) are connected. Luminaire according to the preceding claim, wherein the heat sink ( 13 ) one to the back of the PCB and / or the reflector ( 9 . 10 ) has conformed heat transfer surface which sits fully on the back of the circuit board and / or the reflector back. Luminaire according to the preceding claim, wherein the printed circuit board ( 4 ) in a cool bag ( 17 ), in which the printed circuit board ( 4 ) from its rear side on opposite edges of the heat sink ( 13 ), wherein preferably two separate heat sink parts ( 14 . 15 ) are provided, which against each other and / or on the printed circuit board ( 4 ) are tensionable. Luminaire according to one of the preceding claims, wherein the luminaire body including at least the at least one reflector ( 9 . 10 ) is formed as an endless extruded profile and cut to a desired length. Luminaire according to claim 5 or one of the dependent claims, wherein the printed circuit board ( 4 ) and / or the at least one heat sink ( 13 ) are each formed as an endless extruded profile, wherein preferably the heat sink ( 13 ) parallel to the longitudinal direction of the extruded profile cooling fins ( 16 ) having. Luminaire according to one of the preceding claims, wherein the light source is arranged dimmed. Luminaire according to the preceding claim, wherein the reflector arrangement ( 5 ) is designed such that it has a viewing axis on the at least one light source ( 2 ) obscured. Luminaire according to the preamble of claim 1 or one of the preceding claims, wherein the reflector arrangement ( 5 ) a first reflector ( 9 ), which, viewed from the room to be illuminated, behind the at least one light source ( 2 ), and a second reflector ( 10 ), which, viewed from the space to be illuminated, faces the at least one illuminant ( 2 ) is arranged and designed such that of the lighting means ( 2 ) on the second reflector ( 10 ) falling light on the first reflector ( 9 ) is directed. Luminaire according to the preceding claim, wherein the second reflector ( 10 ) directly to the at least one light source ( 2 ) adjacent in front of said lamp ( 2 ) is arranged. Luminaire according to one of the two preceding claims, wherein the second reflector ( 10 ) smaller in area than the first reflector ( 9 ) is formed, preferably less than one-half as large, in particular less than a third times as large as the first reflector is formed. Luminaire according to one of claims 12-14, wherein the two reflectors ( 9 . 10 ) have different curvatures. Luminaire according to one of claims 12-15, wherein the first reflector a runny, concave curvature having. Luminaire according to one of claims 12-16, wherein the second reflector ( 10 ) is formed. Luminaire according to one of the preceding claims, wherein the reflector arrangement ( 5 ) on both sides of the at least one light source ( 2 ) to the printed circuit board ( 4 ) and reflector surface edges ( 6 . 7 ) has a slot-shaped light exit cross-section ( 8th ), which is inclined to the plane of the printed circuit board, preferably approximately at right angles to the plane of the printed circuit board ( 4 ). Luminaire according to one of the preceding claims, wherein the at least one luminous means ( 2 ) to the light exit cross-section of a transparent protective glazing ( 11 ) is covered. Luminaire according to the preceding claim, wherein the protective glazing ( 11 ) and the printed circuit board ( 4 ) define a preferably dust-tight cavity, in which the at least one light source ( 2 ) is arranged. Luminaire according to one of the two preceding claims, wherein the protective glazing ( 11 ) at the edge on the at least one heat sink ( 13 ) connected. Luminaire according to one of the preceding claims, wherein the printed circuit board ( 4 ) on its reflector assembly ( 5 ) is provided with an at least partially reflecting surface, preferably in the form of a white surface coating.