DE102015115348A1 - Lighting device for a motor vehicle - Google Patents

Abstract

The invention relates to a lighting device for a motor vehicle, comprising at least one light source (1), a polarization rotation means (3), a first polarization filter means (2; 10) and a second polarization filter means (4; 14), the light source (1) thereto is formed to emit light (5), and wherein the illumination device is designed such that the light emitted by the light source (1) at least partially the first polarization filter means (2; 10), the means for polarization rotation (3) and the second polarization filter means (4; 14), the first polarization filter means (2; 10) comprising at least a first filter element (21; 101) and a first support element (22; 102), the at least one first filter element (21; 101) is disposed on a first surface of the first support member (22; 102), the first surface facing the polarization rotation means (3)

Description

The present invention relates to a lighting device for a motor vehicle according to the preamble of claim 1.

Lighting devices comprising a light source, a first polarizing filter means, a second polarizing filter means and a means for polarization rotation are used in the prior art in headlamps, which are used to illuminate a roadway in front of the vehicle. Usually, a headlight comprises a plurality of illumination devices. The light sources of the illumination devices serve different types of illumination of the roadway (e.g., bend light, city light, highway light, high beam). By the polarizing filter means and the means for polarization rotation of the respective lighting device can / can be darkened according to the principle of LC displays one or more light sources, so that their light does not reach the road. For example, a light source that illuminates an area far in front of the vehicle can be darkened in city traffic. It is thus possible to select from the large number of light sources that are intended to be used for illuminating the roadway for the selected type of lighting. The light of the other light sources can be filtered out so that it does not reach the road.

In the context of this description, a means for polarization rotation means, in particular, a means which transmits incident light and in so doing can rotate the polarization of the light. Preferably, the means for polarization rotation can rotate the polarization by 90 °. Particularly advantageous is a means for polarization rotation, which may have an active and an inactive state. In the active state, the polarization direction can be rotated, while in the inactive state, no rotation of the polarization direction takes place. For example, as a means for polarization rotation, a liquid crystal known from LC displays can be used.

In the context of this description, a polarizing filter means is understood to mean, in particular, a means which is suitable for essentially splitting unpolarized light into two parts of the light. In this case, a portion of the light is reflected and transmitted to one. Each of these parts of the light is polarized. In practice, however, minor fractions of the other polarization also occur in the respective proportion of light. These arise due to Fresnel reflections on the polarizing filter means. The larger the fraction of the respective other polarization, the worse the contrast ratio of the illumination device between the darkened and non-darkened state of the illumination device.

The invention has for its object to provide a lighting device with improved contrast ratio.

This object is achieved by a lighting device having the features of claim 1. Embodiments of the invention are indicated in the dependent claims.

The light source is designed to emit light. The illumination device is designed such that the emitted light at least partially reaches the first polarization filter means, the polarization rotation means and the second polarization filter means. The first polarizing filter means comprises at least a first filter element and a first support element. The first filter element is arranged on a first surface of the first support element. For example, the first polarizing filter means may be a wireframe polarizer. The wire grid polarizer can have a plurality of electrically conductive wires as filter elements. The support member may for example consist of a permeable to the light of the light source and electrically non-conductive material such as glass and / or plastic. The support element may also be referred to as a carrier plate or substrate.

The at least one first filter element can be arranged, for example, on the first surface or in the first surface.

According to the invention, it is provided that the first surface faces the means for polarization rotation. In the context of this description, the term "facing" is understood in particular to mean that a light beam transmitted or reflected by the means for polarization rotation can reach the first surface without being transmitted by the first polarization filter element. Accordingly, a light beam transmitted from the first polarizing filter element exiting the first polarizing filter element on the first surface at an angle between 0 ° and 180 ° can reach the polarization rotation means. In both cases it is not absolutely necessary that the direction of the light beam is influenced by other components, for example by reflection.

According to one embodiment of the invention, the means for polarization rotation between the first polarizing filter means and the second polarizing filter means may be arranged. In this arrangement, it is possible, for example, that the light during operation, first, the first Polarization filter means, then reaches the means for polarization rotation and then the second polarizing filter means. It is also possible that the light first reaches the second polarizing filter means, then the means for polarization rotation and then the first polarizing filter means.

In the case where the light first reaches the second polarizing filter means, polarized light strikes the first polarizing filter means. The feature that the first surface faces the polarization rotation means is particularly advantageous in this case, since the light thus reaches the at least one first filter element without having to pass through the support element. In this way, if the light source is to be darkened, Fresnel reflections are reduced or even prevented when the light enters the first support element. The polarized light is reflected by the at least one first filter element - for example, electrically conductive wires. Fresnel reflections upon entry of the light into the first support member could result in light passing through the first polarizing filter means, although this is actually to be prevented. Experiments have shown that by such an arrangement, an increase in the contrast between darkened light source and non-darkened light source by about 25% is possible.

For example, in the case where the light first reaches the first polarizing filter means, the first polarizing filter element may be arranged to transmit p polarized light toward the polarization rotation means. Since the first surface faces the polarization rotation means, Fresnel reflections occur when the light enters the first support member. These Fresnel reflections have p- and s-polarizations. The p-polarized portion of the Fresnel reflections is transmitted through the first polarizing filter means while the s-polarized portion is reflected. The contrast between darkened light source and non-darkened light source is thus further increased

It is also possible that the light first reaches the first polarizing filter means and the first polarizing filter element is arranged so that s-polarized light is reflected in the direction of the means for polarization rotation. In this case, due to Fresnel reflections, a relatively small amount of p-polarized light passes in the direction of the polarization rotation means. This relatively small proportion of p polarized light can be filtered out by further polarization filter elements. Experiments have shown that the contrast between darkened light source and non-darkened light source can be increased by about 30% compared to the reverse orientation of the first polarizing filter means by this arrangement.

According to one embodiment of the invention, the second polarizing filter means may comprise at least a second filter element and a second support element. The at least one second filter element can be arranged on a second surface of the second support element. The second surface may face the means for polarization rotation. Thus, it is possible that the second polarizing filter means is formed similar to the first polarizing filter means. In the context of this description, the term "facing" is understood in particular to mean that a light beam transmitted or reflected by the means for polarization rotation can reach the second surface without being transmitted by the second polarization filter element. Accordingly, a light beam transmitted from the second polarizing filter element exiting the second polarizing filter element on the second surface at an angle between 0 ° and 180 ° can reach the means for polarization rotation. In both cases it is not absolutely necessary that the direction of the light beam is influenced by other components, for example by reflection. The at least one second filter element may be formed, for example, as an electrically conductive wire.

This arrangement of the second polarizing filter element further increases the contrast between the darkened light source and the non-darkened light source since both the first polarizing filter means and the second polarizing filter means have an advantageous arrangement for this purpose.

According to one embodiment of the invention, the light may be at least partially transmitted from the second polarization filter means to the polarization rotation means. The transmitted part is polarized in this case. In this case, the orientation of the second polarizing filter means is advantageous for increasing the contrast.

According to one embodiment of the invention, the light may be at least partially reflected by the second polarization filter means to the polarization rotation means. In this case, the orientation of the second polarizing filter means is also advantageous for increasing the contrast.

According to one embodiment of the invention, the illumination device may comprise a third polarization filter means arranged between the first polarization filter means and the polarization rotation means. The third polarizing filter means may comprise at least a third filter element and a third support element. The at least one third filter element can be arranged on a third surface of the third support element. The third surface may be the means for Facing polarization rotation. In the context of this description, the term "facing" is understood in particular to mean that a light beam transmitted or reflected by the means for polarization rotation can reach the third surface without being transmitted by the third polarization filter element. Accordingly, a light beam transmitted from the third polarizing filter element exiting the third polarizing filter element on the third surface at an angle between 0 ° and 180 ° can reach the means for polarization rotation. In both cases it is not absolutely necessary that the direction of the light beam is influenced by other components, for example by reflection. The at least one third filter element may be formed, for example, as an electrically conductive wire.

The third polarizing filter means may be particularly advantageous when the first polarizing filter means is arranged such that the light of the light source reflected by it reaches the polarization rotation means and the third polarization filter means is arranged between the first polarization filter means and the polarization rotation means. In this case, any impurities of the light reflected by the first polarization filter means are filtered out by the third polarization filter means with the polarization actually to be filtered out by the first polarization filter means.

According to one embodiment of the invention, the first polarization filter means, the second polarization filter means and / or the third polarization filter means can each be designed as a wire grid polarizer. A wireframe polarizer is particularly easy to manufacture. Due to the special orientation of the polarizing filter means relative to the means for polarization rotation can be used Drahtgitterpolarisatoren without Fresnel reflections lead to undesirable effects.

According to one embodiment of the invention, the first polarization filter means may be arranged so that the light has a vertical polarization after transmission through the first polarization filter means. In the context of this description, vertical polarization is understood to mean, in particular, a polarization perpendicular to the earth's surface. Such an arrangement is particularly advantageous when the light reaches the first polarizing filter means before the means for polarization rotation. Laboratory tests have shown that in such an arrangement, the contrast in comparison to an arrangement in which the transmitted light is horizontally polarized by about 20% higher.

According to one embodiment of the invention, the illumination device may comprise a mirror and another polarization rotation means. A first portion of the light may be reflected by the first polarizing filter means towards the means for polarization rotation. A second portion of the light may be transmitted by the first polarizing filter means in the direction of the mirror. Both the first portion of the light and the second portion of the light may be polarized. The mirror can reflect the second portion of the light in the direction of the further means for polarization rotation. In this way, both the light reflected by the first polarizing filter means and the light transmitted by the first polarizing filter means is used for illumination, whereby the contrast between darkened light source and non-darkened light source is further increased.

It is also possible for the means for polarization rotation and the further means for polarization rotation to be sections of a single component.

Reference to the accompanying drawings, the invention is explained in more detail below. The same reference numerals are used for the same or similar components and components with the same or similar function. Showing:

1a a schematic view of a lighting device according to an embodiment of the invention;

1b a schematic view of an in 1a used polarizing filter means;

1c a schematic view of an in 1a used polarizing filter means;

2a a schematic view of a lighting device according to an embodiment of the invention;

2 B a schematic view of an in 2a used polarizing filter means;

2c a schematic view of an in 2a used polarizing filter means; and

3 a schematic view of a lighting device according to an embodiment of the invention.

In the 1a illustrated illumination device comprises a light source 1 , a first polarizing filter means 2 , a means for polarization rotation 3 and a second polarizing filter means 4 , The light source 1 For example, it may include one or more light emitting diodes or one or more lasers. The first polarizing filter means 2 and the second polarizing filter means 4 can each be designed as Drahtgitterpolarisator. The means for polarization rotation, for example, a Liquid crystal include, as it is known from LC displays. The means for polarization rotation can thus be switched to an active state and to an inactive state. In the active state, it rotates the polarization direction of incident light by 90 ° and transmits it. In the inactive state, it does not turn the polarization direction, but only transmits the light.

The polarization direction is represented in the figures by a directional arrow and the designation E _x or E _y .

In operation, the light source sends 1 light 5 out. The light 5 is in the case of a light emitting diode as a light source 1 unpolarized. The light 5 encounters the first polarizing filter means 2 , A first part of the light 6 is polarized in the y direction and by the first polarizing filter means 2 transmitted. A second part of the light 7 is polarized in the x direction and by the first polarizing filter means 2 reflected.

The first part of the light 6 reaches the means for polarization rotation 3 , Im in 1a shown state is the means for polarization rotation 3 in the active state, so that the polarization direction of the first portion of the light 6 is rotated in the x direction. The first part of the light is in this state in 1a with the reference number 6 ' characterized. The first part of the light 6 ' then encounters the second polarizing filter means 4 and is transmitted so that it, for example, reaches a lane in front of a vehicle and illuminates it. If the means for polarization rotation 3 is in the inactive state, there is no rotation of the polarization and the first portion of the light 6 is from the second polarizing filter means 4 reflected, so he does not get on the road.

If the second polarizing filter means 4 the first part of the light 6 ' reflected, becomes the light source 1 referred to as darkened. If the second polarizing filter means 4 the first part of the light 6 ' transmits, becomes the light source 1 referred to as not darkened.

The first polarizing filter means 2 has first filter elements 21 and a first support element 22 on. The second polarizing filter means 4 has second filter elements 41 and a second support element 42 on. Both the first filter elements 21 as well as the second filter elements 41 can be electrically conductive wires. The first support element 22 and the second support element 42 can each one for the light 5 transparent substrate made of plastic and / or glass.

Both the first polarizing filter means 2 as well as the second polarizing filter means 4 are aligned so that the filter elements 21 respectively. 41 each on a surface of the support element 22 respectively. 42 arranged, the means for polarization rotation 3 is facing. In the case of the first polarizing filter means 2 This orientation is advantageous because when entering the first support element 22 occurring Fresnel reflections of the light 5 polarized in the y direction and from the first polarizing filter means 2 be transmitted. In the case of the second polarizing filter means 4 This orientation is advantageous because Fresnel reflections are to be avoided, that of the second polarizing filter means 4 transmitted portion of the light 6 '' would contaminate.

In the 1b and 1c are the first polarizing filter means 2 and the second polarizing filter means 4 shown schematically. It is in particular the orientation of the filter elements 21 respectively. 41 to recognize. The first filter elements 21 are arranged in a horizontal direction, ie parallel to the ground, so that vertical, ie perpendicular to the ground, polarized light is transmitted. Accordingly, the second filter elements 41 arranged in the vertical direction, so that horizontally polarized light from the second polarizing filter means 4 is transmitted.

Laboratory tests have shown that the horizontal arrangement of the first filter elements 21 a 20% higher contrast between darkened and non-darkened light source 1 allows.

In the 2a illustrated illumination device comprises a light source 1 , a first polarizing filter means 10 , a second polarizing filter means 13 , a third polarizing filter means 14 and a means for polarization rotation 3 , That from the light source 1 emitted light 5 reaches the first polarizing filter means 10 , An x-polarized first portion of the light 11 is reflected and polarized in the y direction second portion of the light 12 is transmitted. The first part of the light 11 reaches the second polarizing filter means 13 and is transmitted by him. The transmitted first portion of the light is in 2a with the reference number 11 ' characterized. The first part of the light 11 ' reaches the means for polarization rotation 3 , In the active state of the means for polarization rotation 3 becomes the polarization direction of the first portion of the light 11 ' turned in the y-direction. In this state, the first portion of the light in 2a with the reference number 11 '' characterized. The first part of the light 11 '' reaches the third polarizing filter means 14 and is transmitted.

The first polarizing filter means 10 includes first filter elements 101 and a first support element 102 , The second polarizing filter means 13 includes second filter elements 131 and a second support element 132 , The third polarizing filter means 14 includes third filter elements 141 and a third support element 142 ,

The general functioning of the lighting device off 2a similar to the functioning of the lighting device 1a , Even with the lighting device off 2a is the surface of the support element 102 . 132 respectively. 142 at which the filter elements 101 . 131 respectively. 141 are arranged, the means for polarization rotation 3 facing. This also applies to the first polarizing filter means 10 to. One from this surface of the first support element 102 reflected light beam reaches the means for polarization rotation 3 , Even with the lighting device off 2a is this orientation of the polarizing filter means 10 . 13 and 14 advantageous to reduce or avoid disturbing effects by Fresnel reflections.

In 2 B is the orientation of the first filter elements 101 shown in horizontal direction. Accordingly, in 2c the orientation of the second filter elements 131 in the vertical direction and in 2d the orientation of the third filter elements 141 shown in horizontal direction.

The second polarizing filter means 13 is in the lighting device according to 2a advantageous to erroneous reflections of the first polarizing filter means 10 to filter out polarized in y-direction light.

In the 3 illustrated lighting device comprises a first polarizing filter means 2 , a second polarizing filter means 13 , a third polarizing filter means 14 and a means for polarization rotation 3 in a similar or similar way to that described above 2a was explained. In contrast to the lighting device off 2a becomes the second portion of the light transmitted by the first polarizing filter means 12 through a mirror 15 in the direction of another means for polarization rotation 3 reflected. This also makes the second part of the light 12 using a fourth polarizing filter means 4 which is arranged similarly to the second polarizing filter means 4 out 1a , to use for illumination of the roadway. Both the first part of the light 11 as well as the second part of the light 12 can by switching the two means for polarization rotation 3 in the inactive state of the third polarizing filter means 14 and the fourth polarizing filter means 4 be filtered out.

In the 3 illustrated lighting device can also be used as a combination of the two in the 1a and 2a be understood lighting devices shown. The lower light path corresponds to the off 2a known light path. The upper light path can out with the light path 1a are compared, wherein the first polarizing filter means 2 out 1a not needed because of the mirror 15 reflected second portion of the light 12 ' already polarized.

LIST OF REFERENCE NUMBERS

1

light source

2

Polarizing filter means

21

filter element

22

supporting member

3

Means for polarization rotation

4

Polarizing filter means

5

light

6

First part of the light

7

Second part of the light

10

Polarizing filter means

101

filter element

102

supporting member

11

First part of the light

12

Second part of the light

13

Polarizing filter means

131

filter element

132

supporting member

14

Polarizing filter means

141

filter element

142

supporting member

15

mirror

Claims (9)

Lighting device for a motor vehicle, comprising at least one light source ( 1 ), a means for polarization rotation ( 3 ), a first polarizing filter means ( 2 ; 10 ) and a second polarizing filter means ( 4 ; 14 ), the light source ( 1 ) is adapted to light ( 5 ), and wherein the illumination device is designed such that the light emitted by the light source ( 1 ) emitted light ( 5 ) at least partially the first polarizing filter means ( 2 ; 10 ), the means for polarization rotation ( 3 ) and the second polarizing filter means ( 4 ; 14 ), wherein the first polarizing filter means ( 2 ; 10 ) at least a first filter element ( 21 ; 101 ) and a first support element ( 22 ; 102 ), wherein the at least one first filter element ( 21 ; 101 ) on a first surface of the first support element ( 22 ; 102 ), characterized in that the first surface of the means for polarization rotation ( 3 ) is facing. Lighting device according to claim 1, characterized in that the means for polarization rotation ( 3 ) between the first polarizing filter means ( 2 ; 10 ) and the second polarizing filter means ( 4 ; 14 ) is arranged. Lighting device according to the preceding claim, characterized in that the second polarizing filter means ( 4 ; 14 ) at least one second filter element ( 41 ; 141 ) and a second support element ( 42 ; 142 ), wherein the at least one second filter element ( 41 ; 141 ) on a second surface of the second support element ( 42 ; 142 ), and wherein the second surface of the means for polarization rotation ( 3 ) is facing. Lighting device according to one of the two preceding claims, characterized in that the light ( 5 ) at least partially from the first polarizing filter means ( 2 ) to the means for polarization rotation ( 3 ) is transmitted. Lighting device according to at least one of the preceding claims, characterized in that the light ( 5 ) at least partially from the first polarizing filter means ( 10 ) to the means for polarization rotation ( 3 ) is reflected. Lighting device according to at least one of the preceding claims, characterized in that the illumination device comprises a third polarization filter means ( 13 ) disposed between the first polarizing filter means ( 10 ) and the means for polarization rotation ( 3 ), wherein the third polarizing filter means ( 13 ) at least a third filter element ( 131 ) and a third support element ( 132 ), wherein the at least one third filter element ( 131 ) on a third surface of the third support element ( 132 ), and wherein the third surface of the means for polarization rotation ( 3 ) is facing. Lighting device according to the preceding claim, characterized in that the first polarizing filter means ( 2 ; 10 ), the second polarizing filter means ( 4 ; 14 ) and / or the third polarizing filter means ( 13 ) are each formed as Drahtgitterpolarisator. Lighting device according to at least one of the preceding claims, characterized in that the first polarizing filter means ( 2 ; 10 ) is arranged so that the light ( 5 ) after transmission through the first polarizing filter means ( 2 ; 10 ) has a vertical polarization. Lighting device, characterized in that the illumination device is a mirror ( 15 ) and another means for polarization rotation ( 3 ), wherein the illumination device is designed such that a first portion of the light ( 6 ; 11 ) from the first polarizing filter means ( 2 ; 10 ) in the direction of the means for polarization rotation ( 3 ) and a second portion of the light ( 7 ; 12 ) from the first polarizing filter means ( 2 ; 10 ) in the direction of the mirror ( 15 ), the mirror ( 15 ) the second part of the light ( 7 ; 12 ) in the direction of the further means for polarization rotation ( 3 ) reflected.

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