WO2013030099A1 - Light source device - Google Patents

Abstract

The invention relates to a light source device, comprising at least one LED (1) having a light emission side and a rear side opposite the light emission side, wherein the at least one LED (1) is arranged on a circuit board (11), wherein an arrangement plane of the at least one LED (1) is defined by the circuit board (11); at least one main heat sink (2), which is coupled to the rear side of the at least one LED (1), wherein the main heat sink (2) has a jacket surface; wherein the jacket surface of the main heat sink (2) has at least one first (25a), one second (25b), and one third partial surface (25c), wherein the first partial surface (25a) extends parallel to the arrangement plane, wherein the second partial surface (25b) includes a first angle with the first partial surface (25a) and the third partial surface (25c) includes a second angle with the first partial surface (25a), wherein the two angles are different and the second partial surface is designed as a first standing surface and the third partial surface is designed as a second standing surface.

Description

 description

Light source device

Technical area

The present invention relates to a Lichtquellenvor ^¬ direction with at least one LED with a Lichtab ^¬ beam side and the Lichtabstrahlseite opposite rear, wherein the at least one LED is arranged on a circuit board, wherein defined by the board ei ^¬ ne arrangement level of at least one LED is, at least one main heat sink, which is coupled to the back of the at least one LED, wherein the main heat sink has a lateral surface. It also relates to a light source device with at least ei ^¬ ner LED with a Lichtabstrahlseite and one of the light ^¬ emitting side opposite back, wherein the at least one LED is arranged on a circuit board, at least one main heat sink, which is coupled to the back of at least one LED, and a dri ^¬ bervorrichtung for operating the at least one LED, wherein the driving device comprises at least one port for coupling to a voltage supply.

PRIOR ART Generic light source devices are used, for example, as construction site luminaires. A construction site luminaire 30 known from the prior art is shown in FIG. This includes a covered by a glass disc 32 ^¬ array 34 having a plurality of LEDs. An impact shield 36 surrounds the combination of LED array 34 and glass pane 32. At the back is a Unillustrated main heat sink for cooling the LEDs of the LED array 34 is provided. Furthermore, a swivel arm 38 is provided at the back, by means of which the construction site lamp 30 can be set up in the operating state for illuminating an object with a fixed emission direction.

A disadvantage of the known from the prior art construction light is that only LEDs with a ^¬ be marginalized power can be used, otherwise a permissible operating temperature is exceeded, which would lead to damage to the building site lamp. A wide ^¬ rer disadvantage is that in the known construction ^¬ provide light only two viewing angle can be realized even in capped construction site lamp 30 30, by means of the folded-down pivoting arm 38 and on the other in a lay-flat on a surface construction light, particularly when using the swing arm The arrangement is comparatively unstable to the influence of wind or vibrations, as they are usually found on construction sites.

Presentation of the invention

The object of the present invention in a first aspect is to further develop a generic light ^¬ source device of the first type such that different radiation directions possible in a simple manner with high stability ^¬ the. The object according to this first aspect is achieved by a light source device having the features of patent claim 1.

The present invention is based on the finding that different emission directions can be set particularly stable if the main heat sink itself is used for this purpose. According to the invention, therefore, the lateral surface of the main cooling body has at least a first, a second and a third part surface, wherein the first partial area of the Minim ^¬ least parallel to the plane of arrangement of an LED, wherein the second surface portion includes egg ^¬ NEN first angle to the first area and the third Partial surface includes a second angle to the first partial surface, wherein the two angles are different and the second partial surface as a first standing surface and the third partial surface is formed as a second Stand ^¬ surface. The light source device, for. B. a construction site, so can be made pers to ver ^¬ different partial surfaces of the lateral surface of the main heat sink pers, whereby different Abstrahl ^¬ directions in relation to the arrangement level can be realized. The main heat sink is accordingly stable from ^¬ formed that the light source device can be placed on ^{verschie ¬} dene partial surfaces of the lateral surface and thereby can shine in different solid angles. In this way can be avoided a folding element, as known from the prior art, in which there is a risk that it will collapse by wind influence or Erschüt ^¬ Chippings or falling over the building site light can not prevent. The light source device is so robust that it can easily stand up can be used a construction site and also offers a op ^¬ timale illumination of the workplace because of the special design of the main heat sink with footprints different light radiation re- are alisierbar.

In a preferred embodiment further includes the outer surface of a fourth surface portion, which includes a drit ^¬ th angle to the first surface portion and is formed as the third supporting surface. Thus, a further possibility for positioning the light source device is given.

Particularly preferably, the first, the second and the third angle are different from each other, so that at least three different radiation directions can be realized. In a preferred embodiment, the lateral surface further comprises a fifth partial surface which encloses a fourth angle to the first partial surface and is formed as a fourth base surface. In this way, even four different positioning options and thus emission directions can be realized. Particularly preferably, the lateral surface of a white ^¬ tere part surface which is parallel to the first surface portion, wherein the second, the third and the fourth sub-area or the second, the third, the fourth and the fifth surface portion between the first and the wide ^¬ ren Partial surface are arranged. The main heat sink thus has the shape of an irregularly shaped truncated pyramid. By the further partial surface, which is formed as a fifth base, a radiation direction can be realized vertically upwards. Preferably, in the light source device there is a driver device for operating the at least one LED, wherein the driver device has at least one connection for coupling to a power supply.

Preferably, the main heat sink on a plurality of fins, which are arranged projecting from the first part surface ^¬ . By forming the length and height of the respective fins, the respective partial surfaces of the main cooling body are thereby realized. The fins are designed so stable that the light source device can stand well on the formed as a footprint partial surfaces and also does not cause shocks or a nudge immediately to the fall of the light source device. In a particularly preferred embodiment, the fins extend radially. In this way, it is ensured that, irrespective of on which part of the surface ^¬ the light source device is stored, a chimney is formed, can be radiated by the heated air due to convection. In other words, such a configuration of the fins of the main heat sink allows a flow of the heated air from the bottom up regardless of the position of the light source device. This can be independent of the location of the construction site light satisfactory cooling results erzie ^¬ len.

Preferably, the main heat sink has a recess, wherein the fins extend radially to this recess. The recess ensures that through the radially inwardly extending fins there is no bottleneck that would prevent convection.

Preferably, the recess is arranged where the second, the third and the fourth or the second, the third, the fourth and the fifth partial surface would converge without the recess. In this way, the chimney effect is enabled in all layers of the light source device.

Preferably, each fin has an outer end and an inner end oriented towards the center of the main cooling body, wherein the inner ends of adjacent fins have a predeterminable minimum distance. Thus, the stack effect can be in a predetermined amount safely stel ^¬ len. Preferably, the predetermined minimum distance by Varia ^¬ tion of the length of the individual fins is set. In other words, therefore, the individual fins have different lengths in their extension to the recess. It may be provided that the connection for coupling with the at least one power supply is designed to be pivotable. As a result, the light source device can be coupled to a power supply independently of its instantaneous position in such a way that the connection is exposed to the least possible bending or shearing forces.

According to a second aspect of the present invention, the object is to develop a light source device of the aforementioned second type such that a higher emission power is made possible. This object is achieved by a Lichtquellenvorrich ^¬ processing with at least one LED having a Lichtab ^¬ radiating side and a radiant light over ^¬ lying back side, which is disposed on a circuit board, at least one LED, at least one main cooling ^¬ body with the back of at least a LED is coupled ge ^¬ and a drive device for operating the at least one LED, wherein the driving device comprises at least one port for coupling to a voltage supply. The light source device further comprises a front heat sink, which is thermally coupled to the main heat sink.

The present invention according to the second aspect is based on the finding that a higher Abstrahlleis ^¬ tion is made possible when measures are taken to improve the cooling capacity, that is, the dissipation of heat generated by power loss. According to the invention it is therefore provided that the light source device further comprises a front heat sink, which is thermally coupled to the main heat sink. The additional use of a front heat sink, the effective cooling capacity can be significantly increased, so that more powerful LEDs or larger numbers of LEDs can be used. This results in a significant increase in the light emission.

The embodiments described above in connection with the present invention according to the first aspect also apply mutatis mutandis to the present invention according to the second aspect and vice versa. It should also be noted that the present invention according to the first or In the second aspect, embodiments, features, and features are not mutually exclusive, but that one or more of the embodiments, aspects, or features described herein may each be combined with one or more other of the embodiments, aspects, or features described herein.

Preferably, the front heat sink has a non-coupled to the main heat sink radiating surface, wherein the front cooling body is arranged such that the beam is from ^¬ surface oriented toward the light emission side of the at least one LED. "Non-coupled to the main heat sink" in this context means that the front heat sink ei ^¬ ne its radiating surface having opposite rear side which is thermally coupled to the main heat sink In this way, the entire upper ^¬ surface of the light source device for cooling purposes can be almost used, whereby -. Without active cooling measures, such as a blower and the like - a maximum exhaust beam power is made possible the circuit board is preferably coupled via a thermal interface material with the main ^¬ heat sink, wherein the thermal interface material is particularly designed to be elastically a be ^¬ Sonders preferred.. Thermal interface material is available under the name T-flex from the company Laird.This coupling can compensate for unevenness of the heat sinks, which means that their surfaces do not need to be milled, so that more cost-effective heat sinks are used Accordingly, it may be provided that the front cooling body is connected to the main cooling body via a thermal interface material. is coupled by, wherein also here preferably the thermal ^¬ cal interface material is elastic. In addition to the already mentioned aspect of balancing unevenness ^¬ units of the heat sink or the circuit board thereby the substrate is connected to the main heat sink and achieved a seal against moisture. This reduces the risk of moisture ingress between heatsinks without the need for additional measures. Instead of using a single board, the invention can also be implemented with a variety of boards.

Preferably, the main heat sink on a circumferential shock ^¬ protection device, in particular made of plastic, on. In this way, regardless of which light emission direction is selected, the light source device is reliably protected against damage by an uneven ground and the like, since the impact protection device ensures a certain distance. At the same time, the substrate on which the light source device stands is protected against damage due to excessive temperatures. In particular, the circumferential Stoßschutzvorrich ^¬ tion may also be present in the present invention according to the first aspect.

It is particularly advantageous if the impact protection device comprises a first, main and the front heat sink contacting component and a second, Außenoberflä ^¬ surface of the impact protection device forming component on ^¬ has, wherein the first component of a more elastic material than the second component , In this way, manufacturing tolerances can be compensated. In addition, the fixation between the heat sinks can be ensured thereby.

Further preferably, a handle is formed in the impact protection device, which serves for easy transport of the light source device. In addition, the handle allows positioning of the light source device, without the possibly heated heat sinks would have to be touched. Preferably, the handle is not centrally located due to the a-symmetrical weight distribution as a result of the different angles of incidence of the abovementioned partial surfaces. In particular, the handle can also represent an advantageous embodiment according to the first aspect of the invention.

At least one coupling device for mechanical and / or electrical coupling of a plurality of light source devices can be arranged in the impact protection device. Such coupling devices can be used to couple any number of light source devices to achieve a desired brightness. Only one of these coupled light source devices needs to be coupled to a power supply.

Finally, it is preferred if the driver device is mounted on the side of the main heat sink, which is not coupled to the front heat sink. Thereby, the driving apparatus is largely thermally decoupled from the LEDs, resulting in an increase in the life of the components of the driving device, and thus the light source device ^¬. The light source device may further comprise a channel in which connection lines connecting the circuit board to the driver device are arranged. It can be provided that in the channel at least one gradation is formed such that thereby the distance between the current-carrying areas of the board and the main heat sink is increased. In this way, a voltage flashover between current-carrying areas of the board and the main cooling body can be reliably prevented, which results in increased safety for a user of the light source device.

For the same purpose, a recess in the main heat sink can be provided in the area of the channel, which recess is designed in such a way that the distance between current-carrying areas of the circuit board and the main heat sink is thereby increased.

The light source device may further comprise a moisture-permeable membrane, in particular a Goretex membrane, which is arranged such that moisture present in cavities of the light source device can escape from the light source device. In this way, damage to the light source device by water ingress is reliably avoided.

Furthermore, a sealing ring and a transparent pane arranged above the at least one LED can be provided, wherein the sealing ring is arranged between the pane and the front cooling body. This causes the disc, the front heat sink, the thermal interface material and the main heat sink to the fixed. Moreover, the entry of moisture is prevented.

Further preferred embodiments emerge from the subclaims.

Short description of the drawing (s)

In the following, embodiments of the invention with reference vorlie ^¬ constricting be described in more detail to the accompanying drawings. Show it:

Figure 1 is a schematic representation of a known from the prior art light source device with an LED array.

2 shows different schematic representations of a first embodiment of a light source device ^{according to the} invention;

FIG. 3 shows further views of the exemplary embodiment illustrated in FIG. 2 of a light source ^device according to the invention; FIG.

FIG. 4 is an exploded view of the light source device shown in FIG. 2 and FIG. 3; FIG.

FIG. 5 shows various views of a second embodiment of an inventive Lichtquel ^¬ lenvorrichtung;

Fig. 6 various views of a third embodiment of an inventive Lichtquel ^¬ lenvorrichtung; and 7 shows various representations of the main heat sink used in the embodiment of a light source device according to the invention shown in FIG.

PREFERRED EMBODIMENT OF THE INVENTION In the following explanations, the same reference numerals are used for identical and equivalent components of the various embodiments. These are for the sake of clarity only once ^¬ introduces. FIGS. 2 to 4 show various schematic representations of a first ^exemplary embodiment of a light source ^device according to the invention.

Behind an array with a plurality of LEDs 1, a main heat sink 2 is arranged. A front heat sink is designated 3. The main heat sink 2 has a Mantelflä ^¬ che, which corresponds to an irregular truncated pyramid. Its lateral surface has a plurality of partial surfaces 25a to 25f, wherein the first partial surface 25a is oriented parallel to the arrangement plane of the LEDs 1. The second partial area 25b includes an angle of 85 ° to the first partial area 25a, the third sub-surface 25c a Win ^¬ angle of 70 °, the fourth surface portion 25d at an angle of 50 °, the fifth surface portion 25e at an angle of 30 °. The sixth partial surface 25f runs parallel to the first partial surface 25a. The specified angles are only ^¬ play and can vary depending on the application. Due to the different angles, the light source device in different positions relative to a Pad are positioned so that in this way the emission direction of the LEDs 1 is also varied. In order to thermally separate a driver device 5 from the LEDs 1, it is located on the side of the main heat sink 2 facing away from the LEDs. The main heat sink 2 has a plurality of fins 6, whereby the contact surfaces with the housing 7, 8 of the driver device 5 and so that the heat transfer is kept low. The housing 7, 8 of the driver device 5 also has space for arranging the connection to the power supply (not shown) on the rear side. This is preferably pivotally arranged to the difference ^¬ union layers in which a light source device according to the invention to a backing can be arranged to take into account.

The housing 7, 8 of the driver device 5 and a circumferential impact protection 9 prevent the main heat sink 2 can come into direct contact with the pad. This allows air to flow into the fins 6 and prevents damage to the main heat sink 2.

A handle 10, part of the surge protection 9 is and is not located centrally on ^¬ due to the asymmetric weight distribution, enables positioning of the light source device ^¬ without the heated cooling bodies 2, 3 to touch.

The light source device can be constructed according to various security classes. Thus, a touchable supply ^¬ voltage can already be provided by the driver device 5. But it can also the LED substrate, that is, the board 11, so isolated that the relevant rules are met. This can be done for example by means of ceramic or even using FR4 boards. Instead of a circuit board 11 shown in the embodiment, a plurality of individual boards can be used.

In the embodiment shown in the figures, a double insulation is ensured by using a FR4 board and an underlying thermal interface material (TIM) 12. The LEDs 1, in this case single LEDs are used, but also multi-chip LEDs are used, are applied to the substrate 11, which in turn is connected via the TIM 12 to the main heat sink 2. The waste heat of the LEDs 1 is derived in this way in the main heat sink 2. Likewise, the front heat sink 3 is also thermally connected via the TIM 12.

In order to ensure the connection of the two heat sink 2, 3, they are firmly connected to each other, in this case by means of a screw 13. Due to this fixation results for both the circumferential impact protection 9 as well as for the internal construction a defined distance in which positions the components Need to become. To take account of manufacturing tolerances find here elastic components application. In addition to the connection of the board 11 to the main heat sink 2 and the connection of both heat sinks 2, 3, the TIM 12 also assumes the task of sealing against moisture. To compensate for manufacturing tolerances of the shock protection 9 is made of two different plastics, a solid and an elastic. The elastic part ensures the fixation between the heat sinks 2, 3. In this case, small tips can be provided on the heat sinks 2, 3, which drill into the impact protection 9, or small tips on the impact protection, which bend during fixation.

The fixation of the components to one another is fulfilled with respect to the inner elements of the light source device by a sealing ring 15, which is arranged between the front cooling body 3 and a transparent pane 14. The sealing ring 15 fixes the disc 14, a spacer 16 and the board, that is, the substrate 11, between the heat sinks 2, 3. The sealing ring 15 also prevents the entry of moisture at this point.

The spacer 16 positions the disc 14 and prevents contact with the front heat sink 3, which is particularly important when using glass for the disc 14. Between the disc 14 and the spacer 16, further elements with optical properties, such as lenses, reflectors and the like may be arranged. Connecting lines between the driver device 5 and the substrate 11 with the LEDs 1 extend in a plastic channel 17. This channel 17 protrudes through the main ^¬ heat sink 2, the TIM 12 and the substrate 11 in a cavity below the spacer 16. Would the front heat sink 3 on protrude the spacer 16, the spacer 16 would ensure insulation to the heat sink 3. In this cavity, the lines are connected to the substrate 11.

If safety distances are required at this point, 17 steps 18 can be introduced into the channel, which ensure these distances. Alternatively or additionally, a recess 19 may be provided in the heat sink 2 to ensure these distances.

In order to ensure the tightness at this point, a further sealing ring can be applied to the channel 17. To the escape of moisture to ge ^¬ währleisten, can be placed anywhere a moisture permeable membrane, in particular a Goretex membrane, are introduced. Fig. 5 shows a second embodiment of an OF INVENTION ^¬ to the invention the light source device. In this case, the spacer 16 and the shock protection 9 is united in one part. The space for the connection of the LEDs 1 is located under a cover 20, which is also part of the element 9, 16.

The terminal 21 to a power supply is made pivotable, whereby the light source device can also be placed on the back.

In the impact protection 9 lateral coupling devices 22 may be provided, which allow a coupling of multiple light source devices with each other.

FIG. 6 shows a third exemplary embodiment of a light source ^device according to the invention, in which the main heat sink 2, see FIG. is executed in part. As can be seen particularly clearly in FIG. 7, the fins 6 extend radially to a recess 23. The recess 23 is arranged where these partial surfaces 25b, 25c, 25d, 25e would converge without recess. Each fin 6 has an outer and an the center of the main cooling body 2 orien ^¬ patented inner end, said inner ends Benach ^¬ barter fins 6 have a predetermined minimum distance. This predefinable minimum distance is set by varying the length of the respective fins 6. In this embodiment, regardless of the position of the light source device a chimney effect is achieved, whereby a particularly high cooling capacity is made possible in all layers of the light source device.

Claims

Expectations Light source device with at least one LED (1) with a light-emitting side and a rear side opposite the light-emitting side, the at least ^one LED (1) being arranged on a circuit board (11), with an arrangement plane of the at least one LED passing through the circuit ^board (11). (1) is defined; at least one main heat sink (2) which is coupled to the back of the at least one LED (1), the main heat sink (2) ^having a lateral surface; characterized, that the lateral surface of the main heat sink (2) has at ^least a first (25a), a second (25b) and a third partial surface (25c), wherein the first partial surface (25a) runs parallel to the ^arrangement plane, the second partial surface (25b) enclosing a first angle to the first partial surface (25a) and the third partial surface (25c) enclosing a second angle to the first partial ^surface (25a). , whereby the two angles are different and the second partial surface (25b) is designed as the first ^standing surface and the third partial surface (25c) is designed as the second standing surface. Light source device according to claim 1, characterized in that the lateral surface further has a fourth partial surface (25d), the fourth partial surface (25d) having a third angle to the first Partial area (25a) includes and is designed as a third standing ^area . 3. Light source device according to claim 2, characterized, that the first, the second and the third angles are different from ^each other. Light source device according to one of the preceding claims, characterized, that the lateral surface further has a fifth ^partial surface (25e), which encloses a fourth angle to the first ^¬th partial surface (25a) and is designed as a fourth standing surface. 5. Light source device according to one of the preceding claims, characterized, that the lateral surface has a further partial surface (25f) which runs parallel to the first partial surface (25a), the second (25b), the third (25c) and the fourth partial surface (25d) or the second (25b), the third (25c), the fourth (25d) and the fifth partial surface (25e) are arranged between the first (25a) and the further partial surface (25f) and the further partial surface (25f) is designed as a fifth standing surface is. 6. Light source device according to one of the preceding claims, characterized in that a driver Device (5) for operating the at least one LED (1) is present, wherein the driver device (5) has at least one connection (21) for coupling to a power supply. 7. Light source device according to one of the preceding claims, characterized, that the main heat sink (2) has a plurality of fins (6) which are arranged ^standing up from the first partial surface (25a). 8. Light source device according to claim 7, characterized, that the fins (6) extend radially. 9. Light source device according to claim 8, characterized, that the main heat sink (2) has a recess (23), the fins (6) extending radially to this recess (23). 10. Light source device according to claim 9, characterized, that the recess (23) is arranged where the second (25b), the third (25c) and the fourth (25d) or the second (25b), the third (25c), the fourth (25d) and the fifth partial area (25e) would converge without the ^recess (23). Light source device according to one of claims 8 to 10, characterized, that each fin (6) has an outer end and an ^inner end oriented towards the center of the main heat sink (2), the inner ends of ^adjacent fins (6) having a predeterminable minimum distance.