EP1467144A2 - Light generating device with reflector - Google Patents

Abstract

The light emitting device (1) comprises a reflector (2) and means serving for enhancement of heat removal from the reflector. An independent claim is also included for a reflector with an enhanced heat removal rate.

Description

The invention relates generally to lighting means, in particular, the invention relates to a light-generating device Device with reflector and cooling structure.

There are efforts, for example, in the area of Projection technology, light generating systems with the same or to reduce increased power. This is among other things desirable to achieve increased brilliance. For Projectors are still mostly conventional today Illuminants used, for example with filaments or in particular work with arcs. These light sources stand out compared to lasers as highly brilliant sources especially due to the high light output and the lifelike Color temperature and a high spectral blue component.

However, a high falls with such light sources Heat share. Due to the heat output generated the light generating systems or devices are not can be designed as small as possible to reduce the heat input to the Not to let the reflector get too high per unit area. This problem is particularly aggravated by Cold light reflectors, in which longer-wave Radiation components are not reflected, but by the Step through the reflector. Further problems arise from the high resulting when switching on and off Temperature changes.

The invention is therefore based on the object light-generating system, in particular a light-generating system To provide device, which is an improvement with regard to the problems mentioned above. This The task becomes surprisingly simple solved by the subject matter of the independent claims. Advantageous refinements and developments are also specified in the subclaims.

Accordingly, the invention sees a light-generating Device in front of a reflector, as well as a device includes to improve heat dissipation from the reflector.

According to a preferred embodiment of the invention a light-generating device is provided, in which the Device to improve heat dissipation with the Back of the reflector connected or arranged on this is. As the back or outside of the reflector is one the illuminant or that provided for the illuminant Understand the side facing away from the reflector.

It is particularly advantageous for more effective heat dissipation it when the device to improve heat dissipation comprises a radiation absorbing surface.

In particular, the device for improving the Heat dissipation a radiation absorbing coating comprise, it being particularly expedient if the Coating in the infrared range, especially in the spectral range Area of heat radiation absorbed. Such one Coating can also be done in a simple manner or not weakly absorbent materials of a reflector body, such as about a glass dome.

By means of such a radiation-absorbing surface or Coating can be emitted by the reflector or by the Heat radiation passing through the reflector is targeted there be absorbed so that at the radiation absorbing Surface improved cooling can be achieved.

A preferred further training provides that the Heat radiation absorbing coating on the outside of the reflector is arranged. The coating can entire outside or one or more sub-areas cover.

To improve heat dissipation, one can be used for cooling intended area also include vortex generating structures. For example, the structures can be at least one Area of the surface of the reflector may be arranged. A preferred embodiment of the invention provides that the vortex-generating structures on the outside of the reflector are arranged.

Are particularly suitable as vortex generating structures Dimpel or depressions, which may be circular, for example can. These are easy to manufacture and ensure Flow around one equipped with such structures Surface with a cooling fluid due to the vortex formation for an effective mixing of cold and hot fluid layers and thus more effective heat exchange.

The reflector can also be used with advantage self-cleaning surface. This prevents the accumulation or deposition of impurities among other things, can disadvantageously hinder heat dissipation. Self-cleaning properties can among other things also due to the vortex-forming structures mentioned above can be achieved, with a vortex formation Formation of flow dead zones and thus the deposition of contaminants such as dust is avoided.

In a further preferred development of the light generating device comprises the device for Improve heat dissipation with the reflector connected heat sink, so as to increase the effective cooling surface enlarge.

The heat sink can in particular also in the area of Connection to the reflector is adapted to the reflector Have shape to the heat conduction from the reflector in the To improve the heat sink.

It is also advantageous if the device for Improve heat dissipation on the reflector, especially arranged on the outside of the reflector thermally conductive layer comprises. This ensures one improved distribution and removal of the resulting Heat output. For example, a reflector can be used be provided with a metallic coating. In addition to one Such a coating also ensures improved heat dissipation for increased resistance to temperature changes because of the heat faster on the reflector body or parts of the Reflector body can be distributed and Temperature stresses in the reflector material can be avoided.

In particular, it is also advantageous if the reflector is used is provided with a coating comprising two layers, wherein a first layer is radiation absorbing and a second layer arranged above the first layer is thermally conductive. In this way, a reflection of the Radiation avoided through the first layer and the Radiation power entered specifically in this layer then the second layer for a more even Temperature distribution along the coated surface provides. According to a variant of this embodiment of the This layer on the outside of the reflector is also an invention arranged.

The device for improving heat dissipation can also advantageously a CVD and / or PVD coating of the Include reflector. This layer can in particular be a radiation-absorbing and / or heat-conducting layer include. CVD and PVD coatings can be large Variety of materials and also light as absorbent layers produce. For example, a silicon oxide layer can be used for this purpose with a high carbon content, especially with an amorphous one Carbon is deposited, the good one Has absorption properties. The CVD coating can also have one or more metal oxides, wherein under other oxides of the metals titanium, tantalum and niobium are. The process of PVD coating is also useful to deposit metallic layers, for example.

Instead of or in addition to a highly thermally conductive Coating the reflector can be the device for Improvement in heat dissipation is also advantageous with the Include metal foil in contact with reflector. This in Can bring in contact by gluing or Clamps between the reflector and another part respectively.

The light-generating device preferably also has a Air cooling on to heat components of the facility to improve heat dissipation. The air cooling can of course also be part of the facility for Improve heat dissipation. The air cooling can for example include a fan and / or as Convection cooling can be designed.

The light-generating device can itself be at least one Bulbs include or accordingly for the equipment be designed with a lamp. suitable Illuminants are, for example, ultra-high pressure lamps such as especially short-arc lamps, or halogen lamps.

Particular improvements through an inventive The device also results in particular from use of a cold light reflector, since a large part of the Heat radiation passes through the reflector and behind the reflector must be removed or otherwise behind surfaces lying strongly on the reflector.

In an advantageous development, the inventive Device can also be equipped with a housing. This can happen especially when using ultra high pressure lamps For safety reasons, the housing is useful as a splinter protection housing be designed. This can also be a housing also have at least one light-protected opening, through the cooling air can be supplied without light, which about through the reflector or through recesses in it reaches the housing body through the housing opening got outside.

To parts of the facility to improve heat dissipation making good thermal contact with the reflector connect, the device can also be a thermal Include connection to the reflector with thermal paste, or with the reflector over a thermal paste layer be connected to the reflector. For example Thermal grease between the reflector and a heat sink or a heat-distributing metal foil.

Good thermal contact can also be achieved with a springy and / or cup of the device adapted to the shape of the reflector to improve heat dissipation can be achieved, which hugs the reflector.

For the reflector are a variety of materials, such as about metal, glass, or glass ceramic. Due to the Improved heat dissipation provided according to the invention even plastics can be used. these can for example at least one of the plastics polycarbonate, Polyetherimide, polymethyl methacrylate, cyclic olefin, Olefin copolymer, polyether sulfone contain.

Composite materials can also be used for the reflector are used, such as a composite material one or more of the aforementioned plastics with one metallic material.

The invention also provides a reflector to provide that with a facility for improvement the heat dissipation is equipped and especially for the use in a device according to the invention may be suitable.

The device for improving the heat dissipation of the reflector according to the invention can according to one embodiment the invention a coating of at least one area include a surface of the reflector. A preferred one Further training provides that the coating on the Outside of the reflector is arranged. To heat dissipation To improve, the coating can be beneficial radiation absorbing, especially heat radiation or be infrared absorbing.

An advantageous development of such a reflector provides that the coating is highly thermally conductive Layer includes to better distribute heat output to reach on and in the reflector.

The device for improving heat dissipation can also surface-enlarging cooling structures of the reflector body, such as cooling fins or knobs to the Increase cooling capacity.

In the following the invention based on Embodiments and with reference to the Drawings explained in more detail, the same and similar Elements are provided with the same reference numerals and Features of different embodiments with each other can be combined.

Fig. 1

eine schematische Schnittdarstellung einer Ausführungsform einer erfindungsgemäßen lichterzeugenden Vorrichtung,

Fig. 2

eine Ausführungsform eines Kühlkörpers,

Fig. 3

einen Ausschnitt eines beschichteten Reflektors im Querschnitt,

Fig. 4

eine Ausführungsform eines erfindungsgemäßen Reflektors,

Fig. 5

eine weitere Ausführungsform eines erfindungsgemäßen Reflektors mit integriertem Leuchtmittel, und

Fig. 6

eine Ausführungsform eines erfindungsgemäßen Reflektors mit wirbelerzeugenden Strukturen.

Show it:

Fig. 1

2 shows a schematic sectional illustration of an embodiment of a light-generating device according to the invention,

Fig. 2

one embodiment of a heat sink,

Fig. 3

a section of a coated reflector in cross section,

Fig. 4

one embodiment of a reflector according to the invention,

Fig. 5

a further embodiment of a reflector according to the invention with integrated illuminant, and

Fig. 6

an embodiment of a reflector according to the invention with vortex-generating structures.

In Fig. 1 is a cross-sectional view through a Embodiment of a light-generating device according to the invention Device shown as a whole with the reference symbol 1 is designated.

The light-generating device 1 comprises a reflector 2 with an inside 4 and an outside 6, and one Device for improving the heat dissipation from the reflector 2. The inside 4 is concavely curved, so that light is one Illuminant, which is in or in front of the curved Inside defined cavity is arranged by Reflection from the surface of the inside 4 is bundled.

The reflector can be made of metal, glass, glass ceramic, or Be made of plastic, or a composite material of two or more of these materials. As material for a plastic reflector or a reflector with a Composite material reflector bodies can in particular Plastics polycarbonate, polyetherimide, Polymethyl methacrylate, cyclic olefin, olefin copolymer, or polyether sulfone can be used. The is preferred Reflector 2 of the embodiment shown in Fig. 1 also designed as a cold light reflector.

At the focal point of the concave inside 4 of the reflector dome a lamp 10 is arranged. The illuminant 10 comprises in this embodiment, an ultra high pressure lamp whose Legs 101, 102 through cutouts 12 of the reflector 2 are led.

In this embodiment of the invention, the device is to improve heat dissipation with the back of the Connected reflector. The facility to improve the Heat dissipation comprises a coating 8 on the outside of the reflector 6. This coating is considered to be heat radiation absorbing Coating formed. This coating can, for example, by CVD coating of the reflector be produced, or also include a PVD coating. Through CVD and PVD coating can be done easily in particular also deposited multi-layer coatings be, for example, by coating the composition of the process gas is changed.

Heat radiation, which during operation of the device from Illuminant 10 is emitted, passes through the Reflector body and is then on the back or Outside 6 of the heat radiation absorbing Surface serving coating 8 absorbed. This also leads to prevent back reflection of the heat radiation is, so that a reduction in the coating 8 Heat radiation shares in the spectral distribution of the cone of light emitted occurs.

In addition to the property as a light-absorbing surface, the Coating 8 also serve for improved heat distribution, if the coating 8 comprises a thermally conductive layer. This not only leads to a targeted absorption of Radiant energy, which is then dissipated by layer 8 can be improved, but also among other things Resistance to temperature changes of the reflector 2.

In order to operate in the coating 8 by absorption and To be able to dissipate heat conduction, includes the device for improving heat dissipation furthermore a heat sink 16. This is with an area the reflector outside 6, or the coating 8 connected to the reflector outside 6. The heat sink 16 has one in the area of connection to the reflector Receiving cup 32 for the reflector, the surface of which has a shape adapted to the reflector. With that the Contact surface between heat sink 16 and reflector 2 for more effective cooling increases.

To further improve the thermal contact, between Heat sink 2 and reflector with a thermal connection Thermal paste 14 available.

In addition, in this embodiment, the invention air-cooling device as a component the device to improve heat dissipation from Reflector provided. This includes a fan 18, which sucks in an air stream and blows on the heat sink or generates an air flow flowing around the heat sink, by sucking air from the direction of the heat sink. The Heatsink has a channel 24 through which the air of the fan 18 and flow through openings 28 again can escape. Inner cooling fins 26 in the channel 24 provide additional heat exchange. The cooling is additional supported by outer cooling fins 30.

The cooling fins 26 and 30 can also m different from in Fig. 1 schematically shown, along the flow direction of the Air flow generated by the fan 18 run. Can too the heat sink is solid, that is to say without a channel 24 which, among other things, reduces the manufacturing effort. On Such a heat sink is in a perspective view in Fig. 2 shown. In the cylindrical shown in Fig. 2 Heat sinks 16 run the cooling fins 30 along the Axis of symmetry of the body.

The surface of the heat sink 16 can additionally be one or cover several surfaces with vortex-generating structures. Examples of such vortex generating structures are defined roughness or depressions.

The light-generating device 1 comprises in FIG. 1 shown embodiment also a housing 20th This housing 20 can serve as splinter protection, what especially when using ultra high pressure lamps as Illuminant is advantageous.

The housing 20 also has a variety of light-protected openings 22 on which the air exchange allow for cooling while preventing Light which, for example, through the openings 12 in the Reflector 2 enters the housing, comes out. To the openings 22 can be provided with suitable screens, that block direct light emission.

In Fig. 3 is a cross section of a section coated reflector 2 shown. The substrate or the Reflector body 3 is similar to that in FIG. 1 embodiment shown on the reflector outside 6 with provided a coating 8. The coating 8 is both radiation absorbing as well as highly heat conductive. To Layer 8 comprises a first layer 81, which on the Reflector body 3 is applied and one over the first Layer 81 applied second layer 82. The first layer 81 is radiation absorbing, which property especially for those emitted by the lamp Heat radiation shares apply. The radiation absorbing For example, by a high property Layer roughness and / or a sufficient proportion of amorphous carbon can be achieved in the layer.

The second layer 81 arranged above is high thermally conductive. For example, this layer 82 can be a suitable metal. The first layer 81 prevents that essential radiation components from the second layer 82 be reflected back and so for example with one Cold light reflector again make a spectral contribution can.

Fig. 4 shows an embodiment of an inventive Reflector 2, which has a device for improving the Heat dissipation is equipped and also in one Device 1 according to the invention can be used, such as it is shown by way of example in FIG. 1. The reflector includes a reflector body 3 with a concavely curved Inside 4, which is the reflective surface of the Reflector 2 for the light emitted by a lamp forms, the inner surface 4, for example with a radiation reflective coating is equipped. This can be used as an interference filter or dielectric mirror be carried out, which is in the manner of a cold light reflector visible light reflects and longer-wave light can transmit.

The device for improving heat dissipation includes this embodiment, surface-enlarging cooling structures of the reflector body 3 in the form of cooling fins 31 on the Outside 6 on. The cooling fins 31 extend at this embodiment, for example, along the Axis of symmetry of the reflector body 3. This configuration is advantageous, among other things, if an additional Air cooling with a fan that is used Airflow generated in the direction of the axis of symmetry. additionally the reflector 2 on the outside 6 also have vortex-generating structures around the Improve air mixing during cooling.

In the reflector body 3, similar to that in FIG. 1 Embodiment shown openings 12 which the Shots and arrangement of the illuminant in the reflector allow the inside 4.

Furthermore, the facility for improving Heat dissipation of a coating 8 of at least one area of the Outside of the reflector 2. The coating 8 can advantageous as the coating shown in Fig. 3 with a lower, radiation-absorbing layer 8 and one of these first layer 81 covering second layer 82, the second layer 82 is highly thermally conductive and the Temperature compensation serves.

5 is another embodiment of a reflector 2 according to the invention, or one light generating device 1 shown. At this Embodiment of the invention is the illuminant 10 in Integrated reflector 2. The illuminant can, for example, as shown, a halogen bulb or another one Ultra high pressure lamp. The reflector 2 is also like in the embodiments described above on his Outside 6 with a coating 8 as part of a Provided device to improve heat dissipation. The Coating 8 serves to absorb radiation and can also have heat-conducting properties.

In addition to the coating 8 is on the outside 6 of the Reflector 2 is a heat-conductive metal foil 34, which with the Reflector 2, or with its coated Outside 6 is in contact as a further component of the Applied device to improve heat dissipation Metal foil 34 can be due to its flexibility and Fit the flexibility well to the shape of the reflector 2 and serves the better distribution of the heat output in particular on the outside of the reflector 6.

6 shows a further preferred embodiment of a reflector according to the invention 2. In this embodiment includes the device for improving heat dissipation vortex generating structures in the form of dimples or Wells 36, which can be circular, for example and which are arranged on the outer surface 6 of the reflector. The recesses 36 can, for example, in a regular patterns, for example in the form of a hexagonal matrix on the outer surface 6 or a portion of the outer surface 6 may be arranged. The depressions ensure the flow around the Reflector with a cooling fluid, such as air in particular an intensive swirling of the fluid and thus for one improved heat exchange of the surface of the reflector 2 with the cooling fluid.

It will be apparent to those skilled in the art that the above to understand exemplary embodiments described and the invention is not limited to them, but can be varied in many ways without the Leave the scope of the invention.

LIST OF REFERENCE NUMBERS

1

Light generating device

2

reflector

3

reflector body

4

Inside of 2

6

Outside of 2

8th

Heat radiation absorbing coating

10

Lamp

12

Recess in 2nd

14

Thermal Compounds

16

heatsink

18

fan

20

casing

22

Protected opening in 20

24

Channel in 16th

26

Inner cooling fins in 24

28

Openings to 24

30

outer cooling fins from 16

31

Cooling fins of 2

32

Receptacle in 16

34

metal foil

36

vortex-producing depressions

81

radiation absorbing layer of 8

82

highly thermally conductive layer of 8

101,102

Connecting legs of 10

Claims (34)

Light generating device (1), which has a reflector (2), as well as means for improving heat dissipation covered by the reflector (2). Light-generating device according to claim 1, characterized in that the device for improving the heat dissipation is connected to the reflector outside (6) or is arranged thereon. Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a radiation-absorbing surface, in particular a heat radiation-absorbing surface. Light generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a radiation-absorbing, in particular a heat radiation-absorbing coating (8). Light-generating device according to claim 5, characterized in that the heat radiation-absorbing coating (8) is arranged or applied on the outside of the reflector (6). Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a surface with vortex-generating structures. Light generating device according to claim 6, characterized in that the vortex generating structures comprise depressions, for example circular depressions (36). Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a heat sink (16) connected to the reflector (2). Light-generating device according to claim 8, characterized in that the heat sink in the area of the connection to the reflector has a shape adapted to the reflector. Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a heat-conducting layer arranged on the reflector, in particular on the outside of the reflector. Light-generating device according to one of the preceding claims, characterized by air cooling. Light-generating device according to one of the preceding claims, characterized in that the air cooling comprises a fan or convection cooling. Light-generating device according to one of the preceding claims, characterized by at least one lamp. Light generating device according to claim 13, characterized in that the illuminant comprises an ultra-high pressure lamp, in particular a short arc lamp, or a halogen lamp. Light generating device according to one of the preceding claims, characterized in that the reflector comprises a cold light reflector. Light-generating device according to one of the preceding claims, characterized by a splinter protection housing. Light-generating device according to one of the preceding claims, characterized by a housing with at least one light-protected opening. Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a thermal compound connection with the reflector. Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a resilient cup or a cup which is adapted to the shape of the reflector and which conforms to the reflector (2). Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a metal foil (34) brought into contact with the reflector (2). Light-generating device according to one of the preceding claims, characterized in that the reflector (2) comprises at least one of the materials metal, glass, glass ceramic, plastic. Light generating device according to claim 20, characterized in that the reflector (2) comprises a material which contains at least one of the plastics polycarbonate, polyetherimide, polymethyl methacrylate, cyclic olefin, olefin copolymer, polyether sulfone. Light generating device according to one of the preceding claims, characterized in that the reflector (2) comprises a composite material. Light-generating device according to one of the preceding claims, characterized in that the device for improving the heat dissipation comprises a CVD or PVD coating of the reflector (2). Light-generating device according to one of the preceding claims, characterized in that the reflector (2) is equipped with a self-cleaning surface. Reflector (2) with a device to improve the Heat dissipation, in particular for a device according to any of the preceding claims. Reflector according to claim 26, characterized in that the device for improving the heat dissipation comprises a coating (8) of at least a region of a surface of the reflector (2). Reflector according to claim 27, characterized in that the coating is applied to the outside (6) of the reflector. Reflector according to claim 27 or 28, characterized in that the coating (8) is radiation absorbing, in particular heat radiation absorbing. Reflector according to one of claims 27 to 29, characterized in that the coating (8) comprises a highly thermally conductive layer. Reflector according to one of Claims 27 to 30, characterized in that the coating comprises two layers (81, 82), a first layer (81) being radiation-absorbing and a second layer (82) arranged above the first layer (81) being highly thermally conductive , Reflector according to one of claims 26 to 31, characterized in that the device for improving the heat dissipation comprises vortex-producing structures in at least one area of the surface of the reflector (2). Reflector according to claim 32, characterized in that the vortex-producing structures comprise depressions, for example circular depressions (36). Reflector according to one of claims 26 to 33, characterized in that the device for improving the heat dissipation comprises surface-enlarging cooling structures of the reflector body (3), for example cooling ribs (31) or knobs.

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