DE102010027322A1 - Optical element for expansion of light distribution of e.g. headlight, of motor car, has optic component comprising surface with surface normal, where orientation of normal is differentiated from orientation of another normal of substrate - Google Patents

Abstract

The element has an optically permeable substrate with a surface normal, and a structure (102) formed on the substrate. The structure consists of identical shaped elementary cells (10), and a refractive micro optic component (1) is arranged in each elementary cell. The refractive micro optic component comprises a surface with another surface normal. Orientation of the latter surface normal is differentiated from orientation of the former surface normal of the substrate. The substrate and the refractive micro optic component are made of glass or plastic. An independent claim is also included for an illumination device of a motor car, comprising a multi-LED-light source and an optical element.

Description

The present invention relates to lighting devices for motor vehicles such as a headlamp or a tail lamp and more particularly, the present invention relates to an optical element for expanding a light distribution of a corresponding illumination device for homogenizing the light intensity distribution using light sources having an irregular radiation characteristic, such as multi or Array LED light sources.

State of the art

DE 10 2005 041 234 A1 describes a headlamp for vehicles with a plurality of LED light sources, which are combined in a common light-emitting surface, wherein at least one LED light source of an optical unit is assigned to partially generate a predetermined light distribution, wherein one or more LED light sources on or can be switched off, so that the light distribution is changeable. Due to a spacing between the individual LED light sources, a light intensity distribution is generated by the optical unit, which has horizontal and / or vertical gaps. These are perceived inter alia as light fingers or as gaps in the road and can be disturbing.

There are approaches by roughening one or more surfaces to achieve a homogenization of the light intensity distribution. A disadvantage of this approach is the associated relatively high absorption loss due to stochastic scattering effects as well as an adverse effect on the light distribution, which can go along with it.

task

Object of the present invention is the homogenization of the light intensity distribution when using multi or array light sources, in particular LED light sources with multiple light emitters, by closing unwanted gaps in the light intensity distribution, so that a homogeneous light distribution of a lighting device can be achieved.

To achieve this object, an optical element for expanding a light distribution of a lighting device according to claim 1 is disclosed and further, a lighting device is disclosed in particular for a motor vehicle according to claim 13 of the present invention.

According to a first embodiment of the present invention, an optical element for expanding a light distribution of a lighting device comprising an optically transmissive substrate having a first surface normal, wherein on the substrate, a structure is formed, which consists of a plurality of identically constructed unit cells, wherein Each unit cell is arranged a refractive micro-optic component having at least one surface with at least one second surface normal whose orientation differs from the orientation of the first surface normal of the substrate.

The refractive micro-optic components may have different geometries. For example, the refractive micro-optic component may have the shape of a hemisphere or a semiellipsoid. The surface or the surface of a corresponding refractive micro-optic component also has surface portions whose surface normals differ from the orientation of the surface normal of the substrate. A surface normal is a vector standing vertically on a surface. Due to the difference between the first surface normal of the substrate and the second surface normal of the refractive micro-optic component, light transmitted through the optical element is refracted, whereby the light distribution existing from this light is widened so that light gaps in the light distribution can be closed. The refractive micro-optic components can also have other geometries, such as geometries with two, three, four or six surfaces whose respective surface normals are different from the first surface normal of the substrate, such as three-sided pyramids or quadrilateral pyramids or correspondingly other geometries with correspondingly many surfaces.

An optical element on the surface of which a structure consisting of a plurality of three-sided pyramids is formed has a threefold angular radiation characteristic.

In the optical element described above, at least two refractive micro-optic components may also be arranged in each unit cell.

Each of the unit cells described above may in turn be divided into at least two sub-cells, wherein in each of the sub-cells at least one refractive micro-optic component is arranged. By a corresponding division of the unit cells into corresponding sub-cells, it is possible to realize different structures on the substrate of the optical element, which can be adapted to the emission characteristics of different illumination devices.

In the optical element described initially, each unit cell may have at least two sub-cells, wherein in each subcell at least two refractive micro-optic components are arranged. By a corresponding division or subdivision of the unit cells into corresponding sub-cells and a corresponding arrangement of at least two refractive micro-optical components in each subcell structures can be realized on the substrate of the optical element, which can be adapted to different geometries and radiation characteristics of different lighting devices. For example, gaps in lighting can be closed in lighting devices that consist of an LED line. That is, the lighting device includes, for example, four LEDs (light emitting diodes) that are spaced from each other. By an optical element according to the present invention on the substrate surface, a structure is formed, are arranged in the plurality of identically designed unit cells micro-optical components with two surfaces, the usually occurring gaps in light can be closed. For example, when an LED array is used in the lighting device, without horizontal optical element according to the present invention, by projection or projection of the light source, both horizontal and vertical light gaps occur. By an optical element according to the present invention, on the substrate surface, a structure is formed, are arranged in the plurality of identically designed unit cells refractive micro-optical components, each having four surfaces, the horizontal and vertical gaps in the luminous intensity distribution by appropriate orientation of the optical element to be closed to the LED array.

In the optical elements described above, each refractive micro-optic component may have N faces, and the refractive micro-optic components on the pattern may have M different orientations such that the optic has an n-fold angular radiation characteristic, where n is the product of the number N of faces each Micro-optics component and the number M of different orientations of the refractive micro-optic components is.

For example, if an optical element has refractive micro-optic components each having three faces, and if these refractive micro-optic components have two different orientations, then the optical element has a six-fold angle ray tracing technique (3 × 2 = 6).

In the optical elements described above, n may be two or three or four or six, so that the corresponding optical element has a corresponding bidentate or a threefold or a fourfold or a sixfold angular radiation characteristic. By way of example, a hexagonal angular radiation characteristic of the optical element can be achieved by arranging refractive micro-optic components with a six-sided base surface on the surface of the optical element. On the other hand, a sixfold Winkelabstrahlcharakteristik the optical element can be achieved in that on the surface of the optical element, two different refractive micro-optic components are arranged, each having a three-sided base area, the orientation of which differs from each other, so that the respective surface normals of the sides of the refractive micro-optic components differ from each other.

In the case of the optical elements described above, the surface or surfaces of the refractive micro-optic components may be flat or curved. For example, a micro-optic component may have a hemispherical shape that has only one surface, wherein this surface in turn has different surface normals depending on the position on the surface. The respective refractive micro-optic components may also be conical, for example, so that the corresponding surfaces of the refractive micro-optic components are planar.

In the case of the optical elements described above, in the case in which at least two refractive micro-optic components are arranged in an elementary cell, the corresponding refractive micro-optic components can be arranged differently oriented. As a result, as already described above, a sixfold angular radiation characteristic of an optical element can be achieved, for example, by arranging two refractive micro-optic components with a triangular base area in each unit cell, with the refractive micro-optic components being differently oriented in the unit cell. By appropriate arrangement, each unit cell of a corresponding optical element has six surfaces of refractive micro-optic components whose respective surface normals are different from the first surface normal of the substrate. As a result, a sixfold emission characteristic of the optical element is achieved in this exemplary case.

In the optical elements described above, the refractive micro-optic components may be spaced apart or adjacent to each other. By an appropriate design of the optical element, the optical Element adapted to different light sources. For example, spacing of the refractive micro-optic components relative to one another may result in part of the light emitted by the light source being transmitted through the optical element unbroken, whereas another part of the light emitted by the light source is refracted by the corresponding refractive micro-optical components of the optical element. Consequently, a part of the light emitted from the light source is transmitted through the optical element, whereas a different part of the light emitted from the light source is refracted and thus deflected.

In the above-described optical elements, the unit cells may be spaced apart from each other or adjacent to each other. By appropriate design of an optical element, this can be adapted to different geometries and shapes of light sources, and furthermore different light emission characteristics of corresponding optical elements can be achieved.

In the above-described optical elements, the substrate and the refractive micro-optic components may be formed of glass or plastic. The substrate and the refractive micro-optic components may also be formed of different materials. For example, the substrate may be formed of glass, whereas the refractive micro-optic components are formed of plastic. In general, both the substrate and the refractive micro-optic components may be formed of any optically transmissive material.

In the above-described optical elements, the plurality of unit cells may be arranged on the substrate periodically or quasi-periodically. A periodic arrangement of the corresponding unit cells is advantageous for a simple production of a corresponding optical element. In the case of a quasi-periodic arrangement of the unit cells and thus of the corresponding refractive micro-optic components arranged in the unit cells, fewer unit cells may, for example, be arranged in the center of the optical element than in the edge region of the optical element. On the other hand, in the center of another optical element, more unit cells and thus more refractive micro-optic components can be arranged, as in peripheral areas of this optical element. By appropriate arrangements can be adjusted within certain limits, to which extent which angle changes of the light field, which is emitted by the light source, the light field is impressed, or which luminous flux should be unaffected by the component.

According to another aspect of the present invention, a lighting device, in particular for a motor vehicle, is disclosed, wherein the lighting device comprises a light source, one of the optical elements described above, and an imaging device. In this case, the optical element between the light source and the imaging device is arranged. The light source may be, for example, a multi-LED light source in which a plurality of LEDs are arranged either linearly or in a grid. Also, the light source may be an incandescent lamp having one or more filaments. Also, the light source may be, for example, a halogen light source. The imaging device may be, for example, one or more lenses. However, the imaging device is not limited to refractive imaging devices, but the imaging device can also be realized with reflective components. For example, the imaging device may be a mirror system for imaging the light source.

Reference to the accompanying drawings, the invention is explained in more detail below. Showing:

1 a lighting device according to the present invention;

2 a light distribution generated with an arrangement of a four-chip LED as a light source and a headlight lens as an imaging device, and having undesirable gaps in light distribution;

3 the effect of an optical element according to the present invention on the light distribution achieved with an arrangement of four-chip LED as a light source and a headlight lens as a light source;

4 an isometric view of a structure formed on a substrate of an optical element according to the first embodiment of the present invention;

5 an isometric view of another structure formed on a substrate of an optical element according to the first embodiment of the present invention;

6 a plan view of a structure formed on a substrate of an optical element according to the first embodiment of the present invention;

7 an isometric view of yet another structure formed on a substrate of an optical element according to the first embodiment of the present invention;

8th an isometric view of a structure formed on a substrate of an optical element according to the first embodiment of the present invention;

9 a plan view of a structure formed on a substrate of an optical element according to the second embodiment of the present invention;

10 an isometric view of a structure formed on a substrate of an optical element according to the third embodiment;

11 an enlarged view of the isometric view 10 ;

12 a plan view of a structure formed on a substrate of an optical element according to the third embodiment of the present invention;

13 a plan view of another structure formed on a substrate of an optical element according to the third embodiment of the present invention;

14 a transverse view of an optical element according to the present invention.

In 1 is a schematic view of a lighting device 400 represented according to the present invention. In 1 is the optical element 100 advantageous between the light source 200 and the imaging device 300 arranged. A preferred form of an optical element 100 is a refractory element having a cover glass-shaped substrate, which is in the immediate vicinity of a light source, such as an LED light source, and in front of an imaging device, such as the primary optics or the lens group of an imaging device attached, so that the optical element 100 can be kept very compact.

However, the present invention is not limited to this arrangement, but the optical element 100 can also be behind the imaging device, for example 300 be arranged so that the imaging device 300 between the light source 200 and the optical element 100 is arranged.

2 shows a light distribution with an arrangement of four-chip LED as the light source 200 and a headlight lens as an imaging device 300 is generated, and has the undesirable gaps in the light distribution. The unwanted gaps in the light distribution originate in the spacing of the LEDs of the four-chip LED. In the 2 shown light gaps are arranged vertically according to the spacing of the individual LEDs. When using an array chip LED as the light source 200 has the correspondingly generated light distribution in addition to the vertical gaps in space also not shown horizontal gaps in light.

In 3 is a light distribution shown with an arrangement of four-chip LED as a light source 200 and a headlight lens as an imaging device 300 is generated, wherein an optical element 100 according to the present invention between the light source 200 and the imaging device 300 is arranged. 3 shows the effect of an optical element 100 according to the present invention on the light distribution. In the 2 shown light gaps can by arranging an optical element 100 according to the present invention between the light source 200 and the imaging device 300 getting closed. Corresponding horizontal gaps, which in the case of an array chip LED as the light source 200 can also occur with an optical elements 100 be closed in accordance with the present invention.

4 shows an isometric view of a structure 102 on a substrate 101 an optical element 100 is formed according to a first embodiment of the present invention. The structure 102 is made up of a large number of identically designed unit cells 10 formed, wherein in each unit cell 10 a refractive micro-optic component 1 is arranged. In the 4 shown refractive micro-optic components 1 in the appropriate unit cells 10 are arranged, have a vierzählige symmetry, that is, that the refractive micro-optic components 1 have four surfaces whose respective surface normals differ from a first surface normal of the substrate. In the 4 shown structure 102 of the substrate 101 of the optical element 100 is highly symmetric, and by such an arrangement, the production of the master, which is a negative of the corresponding structure 102 is facilitated in two similar processing steps.

In the in 4 shown structure 102 border the individual unit cells 10 and the individual refractive micro-optic components 1 together. However, the present embodiment and the present invention are not limited thereto. Rather, the respective unit cells 10 be spaced apart, so that in the unit cells 10 arranged refractive micro-optic components 1 spaced apart from each other. The arrangement of the unit cells 10 on the substratum 101 may be symmetric or quasi-symmetric.

5 shows another structure 102 on a substrate 101 an optical element 100 is formed according to the first embodiment of the present invention. In 5 have the respective refractive micro-optic components 1 in the respective unit cells 10 a threefold symmetry. This will accomplish that one of a light source 200 emitted light field through an optical element 100 transmitted, wherein the optical element 100 a structure 102 as in 5 shown after passing through the optical element 100 has a threefold symmetry. Consequently, the structure has 102 , in the 5 is shown, a threefold Winkelabstrahlcharakteristik on.

In 6 is a supervision of a structure 102 on a substrate 101 an optical element 100 is formed according to the first embodiment of the present invention. In the 6 The structure shown consists of a large number of identically designed unit cells 10 , and in each unit cell 10 is a micro-optic component 1 arranged, which has the shape of a pyramid with four-sided base. The Winkelabstrahlcharakteristik a corresponding optical element 100 is in this case fourfold, as in each elementary cell 10 arranged refractive micro-optic components 1 each having four surfaces having second surface normal whose orientation differs from the orientation of the first surface normal of the substrate. A light field created by a corresponding optical element 100 is irradiated points after irradiation of the optical element 100 like this one in 6 is shown, a fourfold symmetry.

7 shows an isometric view of a structure 102 on a substrate 101 an optical element 100 is formed according to the first embodiment of the present invention. In the 7 shown refractive micro-optic components 1 are spaced from each other in both horizontal and vertical directions. A light field created by a corresponding optical element 100 Consequently, only the micro-optic components are diffracted, whereas the light field passing through the substrate is diffracted 101 radiates, is not diffracted at the positions where no refractive micro-optic components 1 are arranged. By a corresponding arrangement of the refractive micro-optic components 10 on the substrate 101 of the optical element 100 can be achieved that not the entire light field, that of the light source 200 is emitted through the optical element 100 is bent.

8th is an isometric representation of a structure 102 on a substrate 101 an optical element 100 is formed according to the first embodiment of the present invention. In the in 4 to 7 shown structures 102 act the corresponding optical elements 100 with a respective discrete value or with respective discrete values of the refractive edge or the refractive edges on the angle spectrum. In 8th is a structure 102 shown in which the angular spectrum is influenced in a main direction over a continuous edge course. For the refractive micro-optic components 1 that are in the respective unit cells 10 are arranged, one recognizes two flat surfaces, which influence a main direction, and a curved surface, which influences the angular distribution in the main direction perpendicular thereto. In a structure 102 like these in 8th For example, a parameterization of the curved patches can be selected via splines.

9 is a supervision of a structure 102 on a substrate 101 an optical element 100 is formed according to the second embodiment of the present invention. In 9 are the respective unit cells 10 diamond-shaped and formed adjacent to each other. In every unit cell 10 each are two refractive micro-optic components 1 arranged. The refractive micro-optic components 1 within an elementary cell 10 have different orientations. Each micro-optic component 1 the structure shown 102 has a threefold Winkelabstrahlcharakteristik. Due to the different orientations of the individual refractive micro-optic components 1 has the optical element 100 with the structure 102 , in the 9 is shown, a sechzählige Winkelabstrahlcharakteristik on. The hexagonal Winkelabstrahlcharakteristik of the optical element 100 This results from the fact that one half of the refractive micro-optic components 1 , which have a threefold Winkelabstrahlcharakteristik is oriented differently than the other half of the refractive micro-optic components 1 , This shows each unit cell 10 two refractive micro-optic components 1 and correspondingly six areas of the microcomponents 1 , wherein the respective surface normals of the six surfaces of the first surface normal of the substrate 101 differ.

A corresponding hexagonal Winkelabstrahlcharakteristik an optical element 100 can also be achieved by that in a unit cell 10 only a refractive micro-optic component 1 is arranged, which has six surfaces whose respective surface normal from the first surface normal of the substrate 101 different.

However, the second embodiment of the present invention is not limited to that of the respective unit cells 10 adjacent to each other, but the respective unit cells 10 can be spaced apart from each other. Also, the illustrated refractive micro-optic components 1 be adjacent to each other, or may be spaced apart as shown.

10 is an isometric representation of a structure 102 on a substrate 101 an optical element 100 is formed according to the third embodiment of the present invention. 11 is a corresponding enlarged view of the isometric representation of 10 , The structure 102 according to the third embodiment of the present invention is made of adjoining unit cells 10 formed, each unit cell 10 from four sub-cells 9 consists. In every subcell 9 is a refractive micro-optic component 1 arranged. In the in 10 and 11 Example shown is in each subcell 9 a fourfold refractive micro-optic component 1 arranged. However, the third embodiment is not limited to that of the respective refractive micro-optic components 1 have a vierzählige symmetry, but the respective refractive micro-optic components 1 may have a two or three or sixteen symmetry. In the in 10 and 11 shown structure 102 consists of the unit cell 10 from four sub-cells 9 where three of the sub-cells 9 are formed the same, whereas the fourth subcell 9 the unit cell 10 has a different geometry and size. At the in 10 and 11 shown structures 102 These are structures that allow the setting of two different angle values for each spatial direction. Thus, provides an appropriate structure 102 optically expanded design options. In the in 10 and 11 shown structures 102 are three of the four subcells 9 designed so that a proportionately higher influence of the angular spectrum by the refracting surfaces of this kind subcell 9 he follows. By such a geometric division and by possible spacings within the unit cell 10 or the repeat units to each other can be adjusted within certain limits, to which extent which angular changes are impressed, or which luminous flux component unaffected by the optical element 100 occurs.

12 shows a different structure 102 on a substrate 101 an optical element 100 is formed according to the third embodiment of the present invention. Each unit cell 10 has two subcells 9 on. In the two subcells 9 an elementary cell 10 each are two refractive micro-optic components 1 arranged with threefold symmetry. Here are the refractive micro-optic components 1 a subcell 9 in this subcell 9 arranged differently than refractive micro-optic components 1 in the other subcell 9 the unit cell 10 , In the 12 shown structure 102 that on the substrate 101 of the optical element 100 is formed, causes the optical element 100 has a sechzählige Winkelabstrahlcharakteristik. Corresponding design possibilities of the structure 102 are useful to set a predetermined ratio between the affected luminous flux and luminous flux with unchanged angular distribution can. Furthermore, prescriptions can result from the spacings to be selected between the refractively effective elements from the requirements of microscopic production, which makes certain channel-like structures with a flat surface look favorable in order to be able to introduce processing tools to the actual structures.

13 shows a structure 102 on a substrate 101 an optical element 100 is formed according to the third embodiment of the present invention. In the 13 shown structure 102 is by unit cells 10 formed, each unit cell 10 from two subcells 9 is formed. The individual unit cells 10 are spaced from each other. In the respective subcells 9 each are two refractive micro-optic components 1 each arranged with threefold symmetry. In a first subcell 9 an elementary cell 10 are the refractive micro-optic components 1 spaced apart, whereas the two micro-optic components 1 the other subcell 9 the unit cell 10 at another position of the subcell 9 are arranged, and wherein the corresponding refractive micro-optic components 1 have a different spacing. Also in 13 shown structure 102 generates a hexadecimal output angle distribution with which a transversally isotropic influence of the output angle distribution can be realized to a good approximation. One recognizes 13 well, what design options arise to incorporate issues of microscopic manufacturing. The channel-like structures can be matched to manufacturing technology favorable travel paths of the machining head.

In 14 is a cross section of an optical element 100 represented according to the present invention. Out 14 is the design of the optical element 100 good to see. On the substrate 101 of the optical element 100 is a structure 102 educated. It should be noted that the in 14 shown sizes are not to scale.

LIST OF REFERENCE NUMBERS

1

refractive microepiped component

9

subcell

10

unit cell

100

optical element

101

substratum

102

structure

200

light source

300

imaging device

400

lighting device

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005041234 A1 [0002]

Claims (13)

An optical element ( 100 ) for expanding a light distribution of a lighting device, comprising an optically transmissive substrate ( 101 ) with a first surface normal, wherein on the substrate ( 101 ) a structure ( 102 ), the structure ( 102 ) from a multiplicity of identically designed unit cells ( 10 ), where in each unit cell ( 10 ) at least one refractive micro-optic component ( 1 ), which has at least one surface with at least one second surface normal whose orientation differs from the orientation of the first surface normal of the substrate ( 102 ) is different. The optical element ( 100 ) according to claim 1, wherein each unit cell ( 10 ) at least two subcells ( 9 ), and wherein in each subcell ( 9 ) at least one refractive micro-optic component ( 1 ) is arranged. The optical element ( 100 ) according to claim 1, wherein each unit cell ( 10 ) at least two subcells ( 9 ), and wherein in each subcell ( 9 ) at least two refractive micro-optic components ( 1 ) are arranged. The optical element ( 10 ) according to any one of claims 1 to 3, wherein each refractive micro-optic component ( 1 ) N faces, and wherein the refractive micro-optic components ( 1 ) on the structure ( 102 ) M have different orientations, so that the optical element ( 100 ) has an n-fold angular radiation characteristic, where n is the product of the number N of surfaces of each micro-optic component ( 1 ) and the number M of different orientations of the refractive micro-optic components ( 1 ). The optical element ( 100 ) according to claim 4, wherein n is two or three or four or six, so that the optical element ( 100 ) correspondingly has a bidentate or a threefold or a fourfold or a sixfold Winkelabstrahlcharakteristik. The optical element ( 100 ) according to one of claims 1 to 5, wherein the surface or the surfaces of the refractive micro-optic component ( 1 ) is designed plan or curved. The optical element ( 100 ) according to one of claims 3 to 6, wherein in a subcell ( 9 ) the refractive micro-optic components ( 1 ) are oriented differently. The optical element ( 100 ) according to one of claims 3 to 7, wherein the refractive micro-optic components ( 1 ) are spaced from each other or adjacent to each other. The optical element ( 100 ) according to any one of claims 2 to 8, wherein in the at least two sub-cells ( 9 ) the refractive micro-optic components ( 1 ) are arranged differently oriented. The optical element ( 100 ) according to any one of claims 1 to 9, wherein the unit cells ( 10 ) are spaced from each other or the unit cells ( 20 ) adjoin one another. The optical element ( 100 ) according to any one of claims 1 to 10, wherein the substrate ( 101 ) and the refractive micro-optic components ( 1 ) are made of glass or plastic. The optical element ( 100 ) according to one of claims 1 to 11, wherein the plurality of identically formed unit cells ( 10 ) on the substrate ( 102 ) are arranged periodically or quasi-periodically. Lighting device ( 400 ), in particular for a motor vehicle, comprising - a light source ( 200 ); An optical element ( 100 ) according to any one of claims 1 to 12; and - an imaging device ( 300 ), wherein the optical element ( 100 ) between the light source ( 200 ) and the imaging device ( 300 ) is arranged.

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