SE527683C2 - Lighting with LED`s for e.g. projectors or medical devices, comprises diodes mounted on transparent plate in front of mirror - Google Patents

Abstract

The diodes (1) are mounted on a transparent plate (2) and a mirror (3) is located in front of each diode in order to reflect light back towards and through the plate. A heat conducting medium is provided in the space between the plate and mirror and is in direct contact with the diodes in order to cool them.

Description

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I q. . - Il oc: once uno a.. 10 15 20 25 527 683 i -: ". °... '.: - ---- g, _, z-'On oss 000 leo; gg ....: °'. 00 I won nouaso O Û OBJECT OF THE INVENTION The object of the present invention is to alleviate or overcome the above-mentioned problems and to provide a lighting arrangement with diodes / chips as light source, which is capable of delivering increased power and an extended service life. compared to traditional LED Arrays.

A further object is to provide a lighting arrangement with LEDs as the light source, which is capable of delivering a sufficient brightness / effect for applications where, for example, a laser or discharge lamp is traditionally used as the light source. Examples of such applications are lighting of certain types of microdisplays, in eg projectors or the like, exposure to photoresist, curing of adhesives, headlights with collimated light where you want to be able to control the color without filtering the light, different types of medical light treatments, etc.

Brief description of the invention This object is achieved by means of a lighting arrangement according to the appended independent claim.

Further objects of the invention appear from the dependent claims.

The above and further features and advantages of the invention will be apparent to those skilled in the art from the following detailed description of non-limiting embodiments of the invention for the scope of the invention.

Brief Description of the Drawing The embodiments are described with reference to the accompanying drawing, in which like or similar parts have been given the same reference numerals and in which: Fig. 1 schematically shows a lighting arrangement according to a first embodiment of the present invention and Fig. 2 schematically shows an example of an application of a second embodiment of the present invention.

Detailed Descriptions of Embodiments of the Invention Referring to Fig. 1, a first embodiment of the present invention may comprise two or more light emitting diodes / chip 1 arranged at fixed distances on the surface of the surface. uno »nouon vv oo, no * 0, .. uno above auo c oo a 0 ao a transparent disc 2. On the disc 2 is arranged the power supply of the diodes (not shown) in any known manner. For example, by steaming on a glass sheet on a metallic layer, which is then etched away with the exception of a conductive pattern.

The diodes 1 are each arranged to emit light in the direction of the transparent disk 1 within a cone with an aperture angle of substantially 1809. To collect and direct emitted light, a mirror 3 is arranged in front of each diode 1. The mirror 3 is so designed that it captures and reflects light emitted from each point on and in each direction from the surface of the diode 1 as far as possible so that the light rays form a substantially parallel light beam flowing orthogonally to and through the transparent disk 2 around the diode 1.

The mirror 3 can be constituted by a concave reflecting surface, for example formed as an impression in a structure 5. The shape of the impression can be described as concave or cup-shaped to meet the requirement to collect the light rays, which is essential to increase the yield from each individual diode.

An important factor for the life of LEDs is that their temperature is kept low. The possibility of increasing the light output by supplying the diode an increased current (override) is also affected by how efficiently the diode can be cooled. The cooling is provided according to the present invention by allowing a heat transporting medium to circulate around the semiconductor junction of the diode and the light emitting surface. The heat transporting medium is thus present in the space between the transparent disc 2 and the mirror 3. The agent is inert, ie does not decompose or react chemically, is transparent to the current wavelength range and is electrically insulating so that no current is conducted in the liquid. In the embodiment according to Fig. 1, the cooling is effected by arranging a passage 4 between adjacent diode units (ie diode 1 and mirror 3) and by causing a heat-transporting medium to circulate through the lighting arrangement by means of a pump. To further increase the cooling effect, a heat exchanger can be connected to dissipate excess heat from the heat transporting medium. An example of a suitable heat transport medium is silicone oil. In many applications it is of the utmost importance that the light sources of the lighting arrangement, here diode units 1,3, are as close as possible so that the light output per area unit in the lighting arrangement is as high as possible. An example of an application where this applies is when the lighting arrangement is to be used as a light source for lighting 10 15 20 25 527 683 7 -neon; n n nunna- n o n o nu en .- r fl. 1 .... anno - u n u coon een. o soon 0 n uooo 0 1 nu once ov 0 0 ono nu u 0 Q 0 oooaoo 0 0 una uoa nu ooccoo Q 0 0: canon of a microdisplay with limited numerical aperture (NA), as schematically shown in Fig. 2. l In the embodiment according to Fig. 2, a lighting arrangement is used which basically corresponds to the embodiment described above. In addition, for each diode 1, on the opposite surface of the transparent disk 2, a preferably aspherical correction lens 6 has been fitted, this in order to further collect and arrange the reflected light. With this correction of the light field, a significantly improved uniform parallel luminous flux is obtained.

The aberration is reduced with a correction lens.

Further ifig. 2 shows how the lighting arrangement is placed in front of a collecting lens 7, the purpose of which is to refract the substantially parallel light beams from the individual diode mirror units 1,3 so that they are superimposed on a microdisplay 8 arranged at a certain distance from the collecting lens 7. Since displays often have limited numerical aperture NA (ie are only receptive to light incident within a cone with a limited aperture angle) and requirements for high brightness, it is desirable that the lighting arrangement is compact to be able to be placed close to the display. This can be done according to the present invention i.a. thanks to efficient cooling.

In the application according to Fig. 2, mirrors and lens systems are further designed to produce as far as possible an image (projection) of each light-emitting surface on the micro-display 8. This means that light emitted from each point on the surface of the chip, regardless of which direction, is mirrored and is refracted so that the light hits the display 8 at a point corresponding to the emission point in the projectile / image.

By applying the invention described above, we have achieved the objects stated initially. Furthermore, the efficient cooling of the diode / chip has meant that both the mirror and the correction lens can be manufactured with high precision in large series through cost-effective injection molding of plastic materials. Complicated details for clusters of diodes and aspherical shapes can thus be manufactured in one piece. The mirror can be manufactured by evaporating a metallic condition with a high reflectance for the current wavelength range on the structure. The correction lens can be made of polycarbonate, PMMA, or other plastic that is suitable for optical injection molding. 00: us o o. 09 ooo and oo q o o g to oo. oo coon O o o Û I Û Ü U I I noe noe uooo n 10 15 Û .. Û.- o o u n 'a a'. '° ,:' vu: en o nu o a n v o u o o o o o o u u c oo n .Ü- OIÛ -. ÜÜÜ Ü I I o oo: 2 2 '°: °' ::: v 0 a: ':' 0 0 co o uu oo: 0: a:: z It is common to use a lighting arrangement with essentially only one wavelength. For this purpose, only LEDs emitting the desired wavelength are preferably arranged in the lighting arrangement.

There are also applications where it is desirable to have several different wavelengths for emitted light. In such cases, LEDs of the desired wavelength can be selected and mounted in the lighting arrangement.

There are also applications where it is desirable to be able to individually regulate individuals or groups of LEDs in the lighting arrangement. This can be achieved by etching the circuit pattern corresponding to the regulation on the transparent disc before mounting the LEDs. By then connecting the various individuals or groups of LEDs to a control equipment, the user can influence the current emitted wavelength.

Claims (4)

527 683 C, [New] Patent Claim Lighting arrangement with diode chip as light source, having two or more diodes (1) mounted on a disc (2), characterized in that the disc (2) is transparent, that a mirror (3) is arranged in front of each diode chip (1) ) reflecting light emitted from the diode back towards and through the disc and that a heat conducting medium is arranged in the space between the disc and the mirror and in direct contact with the diode for dissipating heat from the diode (1) and that an aspherical correction lens is arranged at the opposite side of the disc (2) in relation to and at each diode (1) for correction of the reflected light beam path. Lighting arrangement according to claim 1, characterized in that the mirror (3) has a concave shape in order to re-reflect light emitted from each point on and in each direction from the surface of the diode (1) as far as possible so that the reflected light rays form a substantially parallel light beam flowing towards and through the transparent disk (2) around the diode (1). Lighting arrangement according to one of the preceding claims, characterized in that diodes having different wavelengths of emitted light are arranged in the arrangement. 4. Lighting arrangement according to claim 3, characterized in that control means are arranged for individual control of the diodes corresponding to different wavelengths of emitted light.