DE102019107825A1 - Lighting device for a motor vehicle - Google Patents

Abstract

Lighting device for a motor vehicle, in particular a headlight for a motor vehicle, comprising a plurality of light sources (1) from which light (2) emanates when the lighting device is in operation, an in particular monolithic optical component (3) which has at least one light entry surface (4) for the light (2) emanating from the light sources (1) and at least one light exit surface (6A, 6B) for the light (2) that has entered through the at least one light entry surface (4), the light (2) from the at least one light exit surface (6A, 6B ) Leaked light (2) generates a light distribution outside of the motor vehicle during operation of the lighting device, and the lighting device is designed such that by transferring the lighting device from a first state in which all light sources (1) emit light (2) into a second state in which a plurality of the light sources (1) emits light (2) and one or more of the Light sources (1) do not emit light (2) in which light distribution creates a vertical cut-off line.

Description

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

A lighting device of the type mentioned is from DE 10 2012 013 841 A1 known. The lighting device described therein is designed as a headlight and comprises a plurality of light sources from which light emanates when the lighting device is in operation. A light source generating a low beam is designed as a laser diode. Three further light sources are designed as light-emitting diodes (LEDs) and are used to generate a high beam as well as a cornering light and / or a fog light. The lighting device furthermore comprises a monolithic optical component which has a light entry surface for each of the light emitting diodes and a common light exit surface designed as a lens. By controlling the light sources, the low beam, high beam, cornering light and fog light can be switched on and off in a targeted manner, whereby a corresponding light distribution is generated outside the motor vehicle when the lighting device is in operation.

The problem on which the present invention is based is to create a lighting device of the type mentioned at the beginning, with which the light distribution generated by the lighting device can be made more variable.

According to the invention, this is achieved by a lighting device of the type mentioned at the outset with the characterizing features of claim 1. The subclaims relate to preferred embodiments of the invention.

According to claim 1 it is provided that the lighting device is designed in such a way that by transferring the lighting device from a first state in which all light sources emit light to a second state in which a plurality of the light sources emits light and one or more of the light sources does not Emit light in which the light distribution creates a vertical cut-off line. In this way, a matrix light distribution can be generated with little effort. Particularly in the case of a monolithic design of the optical component, a very flat structure possibly results, which requires little adjustment effort.

It can be provided that the plurality of light sources are at least partially arranged next to one another in a first direction. The plurality of light sources can be arranged in a first and in a second group of light sources, the two groups being spaced apart from one another, in particular in the first direction. The light sources can preferably be light-emitting diodes. By arranging the light sources next to one another, individual areas in the light distribution can be darkened by switching off individual light sources

There is the possibility that the optical component has at least one reflective surface, in particular a plurality of reflective surfaces, on which the light that has entered through the at least one light inlet surface is at least partially reflected in the direction of the at least one light outlet surface. In particular, the at least one reflective surface can be designed in such a way that the light which has entered through the at least one light entry surface is reflected by total internal reflection. In this way, the light emanating from the light entry surface can be deflected in a targeted manner with simple means in the interior of the optical component, with the losses being able to be minimized by the total reflection.

It can be provided that one of the reflective surfaces is assigned to each of the light sources, so that the light emanating from a light source is reflected by one of the reflective surfaces. In particular, the plurality of reflective surfaces can be arranged at least partially next to one another in the first direction. The light emanating from one of the light sources is thus passed on separately from the light from the other light sources, so that in the outside space in the light distribution by switching a single light source on and off, a merely local change in light intensity can largely be brought about.

There is the possibility that the at least one reflective surface is curved, in particular is curved in a concave manner, is preferably curved in two mutually perpendicular directions. In this way, the divergence of the light emanating from a light entry surface or a light source can be reduced.

Like the light sources, the plurality of reflective surfaces can also be arranged in a first and in a second group of reflective surfaces, the two groups being spaced apart from one another, in particular in the first direction.

It can be provided that the at least one light exit surface is curved, in particular is convexly curved, preferably is designed to be aspherically curved. In this way, the at least one light exit surface can emit the light project the optical component appropriately into the outside space.

In particular, the at least one light exit surface can map an imaging plane that runs through the optical component in the region of the at least one reflective surface into a projection plane in which the light distribution is generated when the lighting device is in operation. In the area of the at least one reflective surface, the light beams emanating from the individual light sources are preferably still separated from one another, so that an image of a plane from this area can ensure that the light from the individual light sources is also not overlapped in the light distribution in the outside space and is arranged next to one another is.

There is the possibility that a first and a second light exit surface are provided, which are arranged next to one another, in particular in the first direction. The first group of light sources can form a first optical channel together with the first group of reflective surfaces and the first light exit surface and the second group of light sources together with the second group of reflective surfaces and the second light exit surface form a second optical channel. Each of the optical channels can selectively transport the light from individual, separately controllable light sources.

It can be provided that the light of the first optical channel at least partially overlaps the light of the second optical channel in the light distribution. In this way a higher illuminance can be achieved in the center of the generated light distribution.

• 1 eine perspektivische Ansicht eines schematisch dargestellten optischen Bauteils einer ersten Ausführungsform einer erfindungsgemäßen Beleuchtungsvorrichtung;
• 2 eine Ansicht von unten auf ein schematisch dargestelltes optisches Bauteil einer zweiten Ausführungsform einer erfindungsgemäßen Beleuchtungsvorrichtung;
• 3 eine Ansicht von hinten auf das Bauteil gemäß 1;
• 4 eine Draufsicht auf ein schematisch dargestelltes optisches Bauteil und mehrere schematisch dargestellte Lichtquellen einer dritten Ausführungsform einer erfindungsgemäßen Beleuchtungsvorrichtung;
• 5 eine Seitenansicht des Bauteils und der Lichtquellen gemäß 4.

The invention is explained in more detail below with reference to the accompanying drawings. It shows:

• 1 a perspective view of a schematically illustrated optical component of a first embodiment of a lighting device according to the invention;
• 2 a view from below of a schematically illustrated optical component of a second embodiment of a lighting device according to the invention;
• 3 a view from behind of the component according to 1 ;
• 4th a plan view of a schematically illustrated optical component and a plurality of schematically illustrated light sources of a third embodiment of a lighting device according to the invention;
• 5 a side view of the component and the light sources according to FIG 4th .

Identical and functionally identical parts are provided with the same reference symbols in the figures. Furthermore, a Cartesian coordinate system is shown in some of the figures.

The embodiments of a lighting device according to the invention shown in the figures are designed as headlights. The lighting device comprises a plurality of light sources 1 , which are designed as light emitting diodes (LED) and from which light during operation of the lighting device 2 goes out. The light sources 1 can be controlled individually or separately.

Out 4th it can be seen that the light sources 1 in two groups A ₁ and B ₁ are divided, which are spaced from each other in a first direction X. Within the individual groups A ₁ , B ₁ are the individual light sources 1 arranged side by side in the first direction X. In the illustrated embodiments there are a total of 12 light sources 1 intended. There is definitely the possibility of more or less light sources 1 to be provided.

The lighting device further comprises a monolithic, transparent optical component 3 whose length and width are significantly greater than its height (see for example 1 and 3 ).

The optical component has on its rear upper side 3 at least one, in particular a plurality of light entry surfaces 4th on (see 4th ) through which the light sources 1 outgoing light 2 into the optical component 3 can occur. Here are the light entry surfaces 4th as well as the light sources 1 in two groups A ₄ and B ₄ divided, which are spaced from each other in the first direction X. Within the individual groups A ₄ , B ₄ are the individual light entry surfaces 4th arranged side by side. Each of the light sources is there 1 one of the light entry surfaces 4th assigned so that that of the respective light source 1 outgoing light 2 into the assigned light entry surface 4th entry.

In 4th are a total of 12 light entry surfaces 4th indicated in the respective group A ₄ , B ₄ are schematically separated from one another by dashed lines. It is between the light entry surfaces 4th the first group A ₄ and the light entry surfaces 4th the second group B ₄ a recess 9 of the optical component 3 intended. There is definitely the possibility that the individual light entry surfaces 4th in the two groups A ₄ , B ₄ seamlessly adjoin each other so that a uninterrupted surface of the component 3 in the area of the respective group A ₄ , B ₄ the light entry surfaces 4th can be provided. In this way then each of the groups assigns A ₄ , B ₄ only one continuous light entry surface 4th on.

On its the light entry surfaces 4th opposite underside has the optical component 3 a plurality of reflective surfaces 5 on (see 2 and 5 ), of which that through the light entry surfaces 4th entered light 2 is reflected, in particular substantially to the right in 5 or essentially in the Z direction. Here are the reflective surfaces 5 as well as the light entry surfaces 3 and the light sources 1 in two groups A ₅ and B ₅ divided, which are spaced from each other in the first direction X. Within the individual groups A ₅ , B ₅ are the individual reflective surfaces 5 arranged side by side. Each of the light sources is there 1 or each of the light entry surfaces 4th one of the reflective surfaces 5 assigned so that that of the respective light source 1 outgoing and through the corresponding light entry surfaces 4th entered light 2 on the assigned reflective surface 5 occurs.

The reflective surfaces 5 are designed or so in the optical component 3 arranged that the through the light entry surfaces 4th entered light 2 is reflected by total internal reflection. The reflective surfaces 5 are slightly concave with respect to both the X-direction and the Y-direction (see 2 and 5 ), so that the divergence of the light entry surfaces 4th outgoing light 2 is decreased.

The optical component has on its front side 3 two light exit surfaces 6 _A , 6 _B on, through which the reflective surfaces 5 outgoing light 2 from the component 3 can escape (see 2 , 4th and 5 ). Here are the light exit surfaces 6 _A , 6 _B arranged side by side in the first direction X. Each of the light exit surfaces 6 _A , 6 _B is aspherically convex so that it is an imaging plane parallel to an XY plane 7th that are in the area of reflective surfaces 5 through the optical component 3 runs (see 5 ), in a projection plane in which the light distribution is generated during operation of the lighting device.

The first light emitting surface 6 _A forms together with the first group A ₁ of the light sources 1 , the first group A ₄ the light entry surfaces 4th and the first group A ₅ the reflective surfaces 5 a first optical channel A. , whereas the second light exit surface 6 _B together with the second group B ₁ of the light sources 1 , the second group B ₄ the light entry surfaces 4th and the second group B ₅ the reflective surfaces 5 a second optical channel B. forms (see 4th ). Any of the optical channels A. , B. can selectively use the light 2 of the individual separately controllable light sources 1 the corresponding group A ₁ , B ₁ of the light sources 1 transport.

Through the described design of the optical component 3 is the light in the light distribution to be generated 2 of the individual light sources 1 in the form of a light segment next to the light 2 an adjacent light source 1 arranged. Through targeted control of the light sources 1 a desired light distribution can be generated in the exterior of the motor vehicle, for example with one or more vertical light-dark boundaries. The edges between the reflective surfaces 5 form the vertical light-dark borders of the light segments in the projection plane. In particular, by switching off one of the light sources 1 that of this light source 1 corresponding light segment are removed, so that the light distribution in the area of this light segment has a reduced intensity or, if appropriate, no more light intensity.

The light exit surfaces 6 _A , 6 _B are designed so that this can be done through the two optical channels A. , B. light passing through 2 overlaps at least in a central area of the light distribution. In 4th and 5 are the optical axes 8 _A , 8 _B of the light exit surfaces 6 _A , 6 _B drawn, which extend in the Z direction of the drawn coordinate system. It turns out that the optical axis 8 _A the first light exit surface 6 _A runs in an XY plane that is one of the light sources 1 cuts in the middle, whereas the optical axis 8 _B the second light exit surface 6 _B runs in an XY plane between two light sources 1 is arranged.

This offset of the optical axes in the X direction allows the optical channels in the overlap area A. , B. can be achieved that the width of the light segments is halved.

List of reference symbols

1

Light source

2

light

3

optical component

4th

Light entry surface

5

reflective surface

6 _A

first light exit surface

6 _B

second light exit surface

7th

Mapping plane

8 _A

optical axis of the first light exit surface

8 _B

optical axis of the second light exit surface

A.

first optical channel

B.

second optical channel

A ₁

first group of light sources

B ₁

second group of light sources

A ₄

first group of light entry surfaces

B ₄

second group of light entry surfaces

A ₅

first group of reflective surfaces

B ₅

second group of reflective surfaces

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• DE 102012013841 A1 [0002]

Claims (15)

A lighting device for a motor vehicle, in particular a headlight for a motor vehicle, comprising - a plurality of light sources (1) from which light (2) emanates when the lighting device is in operation, - an, in particular monolithic, optical component (3), which has at least one light entry surface ( 4) for the light (2) emanating from the light sources (1) and at least one light exit surface (6 _A , 6 _B ) for the light (2) that has entered through the at least one light entry surface (4), the light (2) coming from the at least one light exit surface (6 _A , 6 _B ) leaked light (2) generates a light distribution outside of the motor vehicle during operation of the lighting device, characterized in that the lighting device is designed in such a way that by transferring the lighting device from a first state in which all light sources (1) Emit light (2) in a second state in which a plurality of the light sources (1) emit light (2) sends and one or more of the light sources (1) do not emit light (2) in which a vertical light-dark boundary is created. Lighting device according to Claim 1 , characterized in that the plurality of light sources (1) are arranged at least partially next to one another in a first direction (X). Lighting device according to one of the Claims 1 or 2 , characterized in that the plurality of light sources (1) are arranged in a first and in a second group (A ₁ , B ₁ ) of light sources (1), the two groups (A ₁ , B ₁ ), in particular in the first direction (X), are spaced apart. Lighting device according to one of the Claims 1 to 3 , characterized in that the light sources (1) are light emitting diodes. Lighting device according to one of the Claims 1 to 4th , characterized in that the optical component (3) has at least one reflective surface (5), in particular a plurality of reflective surfaces (5), on which the light (2) entered through the at least one light entry surface (4) at least partially into Direction of the at least one light exit surface (6 _A , 6 _B ) is reflected. Lighting device according to Claim 5 , characterized in that the at least one reflective surface (5) is designed so that the light (2) which has entered through the at least one light entry surface (4) is reflected by total internal reflection. Lighting device according to one of the Claims 5 or 6th , characterized in that one of the reflective surfaces (5) is assigned to each of the light sources (1), so that the light (2) emanating from a light source (1) is reflected by one of the reflective surfaces (5). Lighting device according to one of the Claims 5 to 7th , characterized in that the plurality of reflective surfaces (5) are arranged at least partially next to one another in the first direction (X). Lighting device according to one of the Claims 5 to 8th , characterized in that the at least one reflecting surface (5) is curved, in particular is curved in a concave manner, is preferably curved in two mutually perpendicular directions. Lighting device according to one of the Claims 5 to 9 , characterized in that the plurality of reflective surfaces (5) are arranged in a first and in a second group (A ₅ , B ₅ ) of reflective surfaces (5), the two groups (A ₅ , B ₅ ), in particular in the first direction (X), are spaced from one another. Lighting device according to one of the Claims 1 to 10 , characterized in that the at least one light exit surface (6 _A , 6 _B ) is curved, in particular is convexly curved, preferably is designed to be aspherically curved. Lighting device according to one of the Claims 1 to 11 , characterized in that the at least one light exit surface (6 _A , 6 _B ) images an imaging plane, which runs through the optical component (3) in the region of the at least one reflective surface (5), into a projection plane in which the lighting device is in operation the light distribution is generated. Lighting device according to one of the Claims 1 to 12 , characterized in that a first and a second light exit surface (6 _A , 6 _B ) are provided which, in particular in the first direction (X), are arranged next to one another. Lighting device according to Claim 13 , characterized in that the first group (A ₁ ) of light sources (1) together with the first group (A ₅ ) of reflective surfaces (5) and the first light exit surface (6 _A ) forms a first optical channel (A) and that the second group (B ₁ ) of light sources (1) together with the second group (B ₅ ) of reflective surfaces (5) and the second light exit surface (6 ₃ ) form a second optical channel (B). Lighting device according to Claim 14 , characterized in that the light (2) of the first optical channel (A) at least partially overlaps the light (2) of the second optical channel (B) in the light distribution.

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