WO2012130813A1

WO2012130813A1 - Led lighting device

Info

Publication number: WO2012130813A1
Application number: PCT/EP2012/055349
Authority: WO
Inventors: Ivo Kips
Original assignee: Kips Led Verlichting Bvba
Priority date: 2011-03-25
Filing date: 2012-03-26
Publication date: 2012-10-04
Also published as: DE102011006183A1

Abstract

A lighting device (12) for receiving an LED luminous means (70), which device comprises a supply region (14), a light generating region (16) and a main body (10) extending in a longitudinal direction, wherein the main body has a luminous means carrier section (35), on which a plurality of luminous means receptacles (30) having a groove (33) for fixing the luminous means (70) are provided in the light generating region (16), wherein at least two luminous means receptacles (30) have a different spatial orientation, and wherein the supply region (14) has a channel (18, 206) having a channel base (22) and a side wall (24).

Description

LED lighting device

The present invention relates to a lighting device for receiving an LED lighting device, which has a supply region, a light-generating region and a base body.

The development of lighting devices in the past has always been based on the lamps used. In turn, the design of the bulbs used was largely determined by the methods of light generation used.

For bulbs that generate their light by means of a Glühwendeis, the conventional pear shape is known. Such a shaped light bulbs can be space-saving, namely with only a socket of small size, attached. The electrical connections of the Glühwendeis are led out together at one end of the bulb. The attachment of the bulb in the socket can be done in different ways. The most widespread is to provide each matching thread to the base of the lamp and in the socket, by means of which the light source can be screwed into the socket.

Furthermore, so-called bayonet mountings are known in which the lighting means has radially projecting pins on its base. In the version of the bulb receptacles are arranged, can be hooked into the pins. When inserting the light source, the light source is pressed next in the socket and then rotated, whereby the pins are blocked by the socket and the bulb is fixed in the socket.

In addition, there are also bulbs of this basic form, which are held by external means in the socket.

It is also known, in particular with bulbs which have a long filament and in their interior a special gas mixture to protect the Glühwendeis to arrange the filament in a cylindrical glass hollow body together with the gas mixture. The connections of the glow turn ice are led out at opposite ends of the glass hollow body. Sockets for these lamps usually have two spaced-apart Klammem, which surround the ends of the lamps and so make electrical contact.

Even with many gas discharge lamps, for example in fluorescent tubes, the light source has a cylindrical glass hollow body. However, due to the more complex light generation process, several electrical connections in the form of pins are provided at each end. The attachment to the sockets for such bulbs functions such that a slot-shaped inlet for the pins is provided on the sockets. As soon as the light source is inserted into these slots, the light source is rotated about its axis and thus fixed in the socket.

In recent years, light-emitting diodes (LEDs) have become important for lighting. In order to use LEDs in existing installations, it is known to produce lamps with LEDs in the known form factors and to integrate the necessary converter electronics in the light source. Thus, the previous bulbs (annealing helix, gas discharge lamp) are usually replaced without LEDs on the existing socket.

However, since the existing versions and lighting devices are tuned to the light generating method used in each case, resulting in the use of LEDs in these form factors

Disadvantage.

LEDs are essentially punctiform light sources. If, as in most lighting applications, a uniform illumination desired with little shadow, so it is known to arrange several LEDs side by side in a light source. If the number of individual LEDs is large enough, there is no noticeable shadow cast through this illumination. For the illumination of interiors, a plurality of LEDs are arranged on a strip-shaped carrier together with the control electronics as the light source, the carrier having on its rear side an adhesive layer for fastening the light source.

It is an object of the present invention to provide a lighting device which takes into account the special properties of LED lamps.

To solve this object, a lighting device for receiving an LED light source is proposed, which has a supply area, a light generating area and a base body which extends in a longitudinal direction, wherein the base body has a Leuchtmittelträ- gerabschnitt on which in the light generating area a plurality of Illuminant receptacles is provided with a groove for fixing the illuminant, wherein at least two illuminant receptacles have a different spatial orientation and wherein the supply region has a channel with a channel bottom and a side wall. Since LED bulbs are preferably formed strip-shaped in order to extend the light generation to the largest possible area and thus to ensure the most uniform possible illumination of the object to be illuminated, a size and shape of the lamp corresponding bulb receptacle is required. Fluorescent tubes having a similar extension along their axis to strip LED bulbs require only two suspension points because the glass from which they are made provides sufficient stability. To achieve similar stability, it would be necessary to equip LED bulbs with reinforcements.

For fastening by means of a groove, it is sufficient to provide a corresponding flange or projection on the LED illuminant, which can be inserted into the groove. Thus, by providing a groove, a simple and reliable mounting of the luminous means to the lighting device can be achieved. In addition, less material is needed to mechanically reinforce the bulb.

The channel can accept both power and signaling cables. It is therefore no longer necessary to provide separate cable channels. In addition, a drive electronics for the light source can be accommodated in the channel. Thereby, the control electronics can be performed separately from the light source, so that in case of failure of the control electronics or the bulb only the defective part must be replaced.

Due to the fact that the light-generating region has a plurality of illuminant receptacles, a plurality of LED illuminants can be operated simultaneously in the same illuminating device and thus the illuminance can be increased. Advantageous embodiments of the lighting device are the subject of the dependent claims.

In a preferred embodiment, the illuminant carrier section has a bend in a cross section perpendicular to the longitudinal direction, the orientation of the illuminant receptacles being determined by an orientation of the tangential plane to the illuminant carrier section.

Since the alignment of the illuminant receptacles follows the shape of the illuminant support section, it is thereby possible in a simple manner to determine the possible radiation angles through the bending of the illuminant support section.

The main direction of emission of the LED lamps depends on the illuminant receptacle into which the illuminant is inserted. Since the illuminant support portion has a bend in cross section, it is possible to easily adjust a radiation characteristic of the illumination apparatus. If, for example, lighting is desired only toward one side of the lighting device, then only on this side are lighting means used in the lighting fixtures. The assignment of the illuminant recordings can be changed at a later date without much effort.

The illuminant receptacle can have a contact surface for the LED illuminant. The aging of LEDs is accelerated by high operating temperatures. When the LED illuminant is applied to the bulb receptacle, in operation, the heat generated by the LEDs can be absorbed and dissipated by the material of the illuminant receptacle. This lowers the operating temperature of the LEDs, extending their life. In a particularly preferred embodiment, the illuminant receptacle has two grooves which are arranged on opposite sides of the illuminant receptacle and whose openings face each other. In order to reliably find support in such a luminous means receptacle, it is sufficient if the luminous means has uneven areas on its longitudinal sides, which are dimensioned such that they fit into the grooves. This saves material for additional flanges or protrusions on the light source. It is only necessary to widen the carrier of the lamp slightly.

The illuminant receptacles can be arranged so that they each connect to one another at one of their sides. As a result, a particularly space-saving arrangement is achieved.

The illuminant receptacles may be inclined at an angle to each other. Each LED illuminant has a predetermined angle of radiation. If a broader illumination is desired than is possible with a single illuminant, further LED illuminants can be inserted into the illumination device, which emit their light in a different direction than the already existing illuminant. Thus, the lighting device can be used for different lighting tasks. In particular, it is still possible after the installation of the lighting device to change its radiation angle in a simple manner.

Advantageously, the channel at an opening on a projection. At such projections different elements can be hooked. For example, modules with transducer electronics may have projections and springs by means of which they are releasably wedged between the projections in the channel. Furthermore, it is possible with a similar attachment to attach cables in the channel, for example, a strain relief provide. Likewise, with the aid of the projections, a fastening device with a latching profile or a clamping spring can be fastened in the channel, by means of which the lighting device can be detachably fastened to other objects, for example ceilings and walls.

The main body can be made of a light metal, in particular aluminum. The use of light metals causes the resulting heat is well dissipated and the weight of the lighting device is low. Thus, less energy must be expended for their transport. Furthermore, the attachment of the lighting device is easier because the fasteners used must bear a lower weight. In addition, most light metals can be continuously cast, so that a basic body with a substantially constant cross section for the lighting device is easy to produce.

The main body may have a fastening device for a cover. Such a cover, which protects the lamps from accidental mechanical action from the outside, can thus be integrated into the lighting device. The cover not only protects the bulbs from external mechanical impact, but also prevents people from intentionally or otherwise touching the bulbs. Since LED bulbs can reach a high operating temperature, thereby injury is avoided.

In the channel, a driver device may be arranged, with which the bulbs used in the light bulb receptacles are controllable. An external installation of control or energy conversion devices is therefore not required.

In a preferred embodiment, the luminous means carrier section has the shape of a cylinder, wherein a base of the cylinder is at least partially is limited by an ellipse cutout. This ensures a uniform arrangement of the illuminant receptacles, so that a uniform illumination of the object to be illuminated can be achieved.

The lighting device may comprise a fastening device with a clamping spring and a retaining flange, wherein the retaining flange is blocked in the mounted state of at least one projection. Thus, a simple mounting of the lighting device is possible because the fastening device can be mounted separately from the lighting device. Subsequently, the lighting device can be placed on the fastening device, so that the clamping spring and the retaining flange engage in the projection.

The fastening device may have on the clamping spring a tab for releasing the connection between the fastening device and the lighting device. As a result, a simple degradation of the lighting device is ensured.

The invention will be described in more detail below with reference to embodiments, which are shown schematically in the figures. Show it:

1 shows a cross section through an embodiment of the lighting device.

Fig. 2a is a plan view of a strip-shaped LED lighting means;

Fig. 2b shows a detail of the cross section of Fig. 1 with an inserted

LED bulbs;

3a shows a latching profile for a channel of the lighting device; Fig. 3b, the latching profile of Fig. 3a in the engaged state and

The basic body 10 shown in cross-section in FIG. 1 of a first embodiment of the LED lighting device 12 according to the invention consists of a continuous casting profile which extends along a longitudinal direction perpendicular to the plane of the drawing. The main body 10 has a supply area 14 and a light generating area 16.

In order to receive supply lines and supply devices, the supply area 14 has a channel 18. The channel 18 has a channel bottom 22 and side walls 24. The cross-sectional area of the module channel 18 is large enough to accommodate modules, such as a driver for the illuminants.

The side walls 24 have projections 26 in the region of an opening of the channel 18 on the end side. The projections 26 are directed towards each other on opposite side walls 24 and formed so that modules with snap springs can be clamped thereto. In addition, the projections 26 are formed so tight that the base 10 can be held for attachment of these. It is also possible to hook on these projections 26 springs, which hold in the channel 18 embedded cables. Similar constructions allow additional cable or module mounts to be inserted into the channel 18.

If the base 10 is mounted horizontally, so that the channel bottom 22 extends perpendicular to the action of gravity, so modules and cables can be inserted into the channel 18 without further attachment. Special fasteners and strain reliefs are usually only necessary if the channel bottom 22 has a significant slope. Thus, in the supply area 14 all necessary for the supply of the bulbs units and lines can be accommodated.

On sides of the main body 10 grooves 28 are arranged, in which a cover can be used. Among other things, the cover serves to protect the lighting device 12 from damage. In addition, the cover can have additional optical properties with which the light emitted by the lighting device 12 is influenced. For example, the cover may be dull, clear or colored or have Fresnel lenses.

The light generating area 16 is the area of the main body 10 that is mainly perceived by a viewer. Usually, the base body 10 is thus installed so that the supply area 14 of a ceiling or wall and the light generating area 16 faces a room to be illuminated. In the light generating area 16 in particular receptacles for illuminants are arranged.

The light-generating region 16 has a light-emitting-medium carrier section 35, on which nine light-emitting means receptacles 30 are arranged in this embodiment. Each of the illuminant receptacles 30 has a contact surface 31. Some of the contact surfaces 31 coincide in this embodiment with the channel bottom 22. On longitudinal sides of the contact surfaces 31 projections 32 are arranged, are incorporated in the grooves 33. The grooves 33 extend substantially parallel on opposite sides of the contact surfaces 31. The openings of the grooves 33 are each directed in pairs towards each other.

The illuminant carrier section 35 is bent so that each illuminant receptacle 30 has an illuminant inserted in it in a different direction aligns. The illuminant support portion 35 has the shape of a half cylinder whose axis extends along the longitudinal direction. The base of the cylinder from which the half-cylinder originated is circular in this case. The use of ellipses or other shapes as a base is possible depending on the desired radiation characteristics.

The illuminant receptacles 30 arranged on the illuminant carrier section 35 align a luminous means arranged therein in such a way that its main emission direction is substantially perpendicular to the surface of the illuminator

Illuminant carrier portion 35 is oriented. The main emission direction of the luminous means resulting from the arrangement of the illuminant receptacle 30 is referred to as alignment of the illuminant receptacle 30.

When using bulbs with a correspondingly adapted radiation angles, it is possible to achieve a uniform illumination of the object to be illuminated. The radiation angle of the lighting means should be adjusted so that the illumination areas of the individual lamps complement each other to a uniform illumination area of the entire arrangement.

A strip LED 70 for use in a bulb receptacle 30 is shown in FIG. 2a. The LED illuminant 70 has a carrier 72, on which individual LEDs 74 are arranged. The carrier 72 has in a connection section 76 electrical connections 78 which can be connected to a voltage source. In the carrier 72 run supply lines which connect the LEDs 74 to the electrical terminals 78 and so provide energy.

Along longitudinal sides 80 fastening sections 82 are kept free, which can be inserted into the grooves 33. The main emission direction of such an LED illuminant 70 is usually oriented perpendicular to the plane of the carrier 72. Since the LEDs 74 do not emit parallel light beams, the radiation characteristic of the LED illuminant 70 has a spatial radiation angle in which most of the light generated by the LEDs 74 is focused.

As shown by way of example in FIG. 2b for one of the illuminant receptacles 30, the illuminant 70 is inserted into the grooves 33 for mounting in the illuminant receptacle 30 in such a way that it is held by the grooves 33 at its attachment sections 82. If the base 10 is mounted horizontally, a further fixation of the lamp 70 is not necessary.

However, if the base body 10 is inclined, then it may be expedient to fix the lighting means 70 with a releasable fastening means, for example a screw, in order to prevent it from sliding out of the illuminant receptacle 30. It is also possible to provide the longitudinal sides of the luminous means 70 with a friction-increasing coating. As a result, unwanted sliding out of the luminous means 70 is indeed prevented, but also the insertion of the luminous means 70 becomes more difficult. Another fixation option is to provide at the ends of the body caps, hold the bulb 70.

When the luminous means 70 is inserted into the illuminant receptacle 30, it rests against the contact surface 31 with a rear wall. Due to the contact between luminous means 70 and contact surface 31, heat conduction between the luminous means 70 and the base body 10 is made possible. A not inconsiderable part of the electrical power which the lighting means 70 receives is converted into heat. As a result, the lamp 70 heats up during operation sometimes strong. To prevent overheating of the bulb 70, this heat must be dissipated. In addition, the life of LED bulbs 70 shortened when they are operated at elevated temperatures. Since the base body 10 conducts the heat away from the contact surfaces 31, it cools the LED lighting means 70, so that their life is extended. To improve the heat transfer between the LED light source 70 and the contact surface 31, thermal paste can be used.

The illuminant receptacles 30 are each inclined by an angle α. The size of the angle α is dependent on the respective lighting task. Frequent values of .alpha. Are between 90.degree. And 270.degree., Values of around 160.degree. For main body 10 with nine illuminant receptacles 30 are particularly preferred. For base body 10 with five illuminant receptacles 30, a value of 144.degree. Is preferred. If the arrangement of the illuminant receptacles 30 follows the shape of the illuminant carrier section 35, the angle α also depends on the shape of the illuminant carrier section 35. The angle α does not necessarily have to be the same between all illuminant receptacles 30.

The base body 10 has a substantially the same cross section over its entire length. However, openings are often provided for the passage of cables, fasteners or other purposes. Therefore, the main body 10 can be produced particularly easily by continuous casting. The above-mentioned further openings are then incorporated following the continuous casting.

In principle, the extent of the basic body 10 can be chosen as desired. Thus, it may be expedient to illuminate a passage with a lighting device 12 whose base body 0 has an extension in the longitudinal direction, which corresponds to the width of the passage. When the lighting device 12 is used in public places it is desirable if the base body 10 extends in the longitudinal direction over two or more meters. As a result, a theft of the lighting device 2 is made more difficult due to their bulky dimensions.

The width of the main body 10 can be adapted to the desired application. Thus, the base body 10 can be widened to provide space for the attachment of additional illuminant receptacles 30. It is also possible to reduce the width if less than nine illuminant receptacles 30 are to be provided.

In order to ensure a good heat dissipation, the base body 10 is made of metal. Preferably, a light metal, in particular aluminum, is used, since this has a lower weight, whereby the attachment of the lighting device 12 is simplified.

For fastening the base body 10, for example on a wall or a ceiling, is a fastening device 200, as shown in Fig. 3a. The fastening device 200 has a clamping spring 202 which can be inserted into the channel 18. The clamping spring 202 has a retaining flange 204, which rests on the projection 26 in the inserted state.

In Fig. 3b, a fastening device 200 is shown, which is inserted into a channel 206. The retaining flange 204 rests against the projections 208 of the channel 206, so that the fastening device 200 is wedged in the channel 206. By means of tabs 210, which protrude beyond the upper edge of the channel 206, the fastening device 200 can be removed from the channel 206. For this purpose, the tabs 210 are pressed together so far that the retaining flange 204 is no longer retained by the projections 208. The fastening device 200 has a tube 212 which is fixedly connected to the clamping spring 202. The tube 212 leads to a ceiling or wall to which it is attached. Thus, it is possible to first attach the comparatively light fastening device 200 and then attach the lighting device 12, 12 to the fastening device 200.

It is possible to provide the grooves 33 not in the longitudinal direction but transversely thereto. The grooves 33 would then not be incorporated into the projections 32, but in the contact surfaces 31. If on a rear side of the carrier 72 fasteners, for example in the manner of a dovetail attached, then the grooves 33 can also be incorporated into the contact surfaces 31.

Regardless of all other features of the body 10, the contact surfaces 31 can be configured just. Since the LED bulbs 70 are usually flat and formed with a flat back, thereby the contact and the heat transfer between the LED bulb 70 and the base body 10 can be improved. In order to improve the heat transfer, thermal grease can additionally be used.

With the lighting device 10 according to the invention, it is possible to optimally utilize the properties of LEDs 74 for illumination. In addition, supply lines can be transported in the body 12, so that an additional attachment outside the lighting device is not necessary.

The illumination device 10 makes it possible, depending on the lighting task, to equip different illuminant receptacles with LED illuminants 70 and thus to change the radiation characteristic of the illumination device 10. Since the control electronics (driver) separately from the Illuminant 70 is executed, it is possible to replace defective transducers or drivers, without having to replace the LED bulbs 70 and vice versa. This avoids unnecessary waste and reduces the running costs of lighting.

LIST OF REFERENCE NUMBERS

Main body 210 Lashing device 212 Pipe supply area

Light generation area α angle channel

channel bottom

Side wall

head Start

groove

Illuminating device receiving

contact surface

head Start

groove

Illuminant carrier section illuminant

carrier

LED

connecting section

Electrical connection

long side

Mounting section fastening device

clamping spring

retaining flange

channel

head Start

Claims

claims

An illumination device (12) for receiving an LED light source (70) having a coverage area (14), a light generation area (16), and a base body (10) extending in a longitudinal direction, the base body having a light source support portion (35), on which in the light generating area (16) a plurality of illuminant receptacles (30) with a groove (33) for fixing the illuminant (70) is provided, wherein at least two illuminant receptacles (30) have a different spatial orientation and wherein the supply region (14) has a channel (18, 206) with a channel bottom (22) and a side wall (24).

2. Lighting device according to claim 1, characterized in that the illuminant carrier portion (35) in a direction perpendicular to the longitudinal cross section has a bend, wherein the orientation of the illuminant receptacles is determined by an orientation of a tangential plane to the illuminant support portion (35).

3. Lighting device according to one of the preceding claims, characterized in that the illuminant receptacle (30) has a contact surface (31) for the LED lighting means (70).

4. Lighting device according to one of the preceding claims, characterized in that the illuminant receptacle (30) has two grooves (33) which are arranged on opposite sides of the illuminant receptacle (30) and whose openings are facing each other.

5. Lighting device according to one of the preceding claims, characterized in that the illuminant receptacles (30) each adjoin one another on one side.

6. Lighting device according to one of the preceding claims, characterized in that the illuminant receptacles (30) at an angle (a) are inclined to each other.

7. Lighting device according to one of the preceding claims, characterized in that the channel (18, 206) at an opening has a projection (26, 208).

8. Lighting device according to one of the preceding claims, characterized in that the base body (10) made of a light metal, in particular made of aluminum.

9. Lighting device according to one of the preceding claims, characterized in that the base body (10) fastening means (28) for a cover.

10. Lighting device according to one of the preceding claims, characterized in that in the channel (18, 206) a driver device is arranged, with the lighting means (30) used in the illuminant means (70) are controllable.

1 1. Lighting device according to one of the preceding claims, characterized in that the illuminant carrier portion (35) has the shape of a cylinder cutout, wherein a base surface of the cylinder cutout is partially bounded by an ellipse cutout.

12. Lighting device according to one of the preceding claims, characterized in that it comprises a fastening device (200) with a clamping spring (202) and a retaining flange (204), wherein the retaining flange (204) in the assembled state of at least one projection (26, 208 ) is blocked.

13. Lighting device according to claim 12, characterized in that the fastening device (200) on the clamping spring (202) has a tab (210) for releasing the connection between the fastening device (200) and lighting device (12).