WO2022207303A1

WO2022207303A1 - Lighting device for vehicles, and method for producing a lighting panel

Info

Publication number: WO2022207303A1
Application number: PCT/EP2022/056657
Authority: WO
Inventors: Martin Mügge
Original assignee: HELLA GmbH & Co. KGaA
Priority date: 2021-03-30
Filing date: 2022-03-15
Publication date: 2022-10-06
Also published as: DE102021107947A1

Abstract

The invention relates to a lighting device for vehicles, comprising a light source (1) and an optical unit (3) for generating a specified light distribution. The optical unit (3) comprises a lighting panel (6) which has a plurality of optical elements (9) on a rear face (7) facing the light source (1), wherein the optical elements (9) are designed such that the light (2) which is incident on the optical elements is deflected in a focusing region (10) of the front face (8), which is designed as a passage region (11), and with the exception of the passage regions (11), the front face (8) of the lighting panel (6) is provided with a dark coloration (13) in order to form a dark region (13) of the lighting panel (6).

Description

Lighting device for vehicles and manufacturing method of a lens

The invention relates to a lighting device for vehicles with a light source and with an optics unit for generating a predetermined light distribution, the optics unit comprising a lens which has a plurality of optics elements on a rear side facing the light source.

Furthermore, the invention relates to a method for producing a lens, the lens being formed on a light-entering rear side with a plurality of optical elements.

A lighting device for vehicles is known from DE 102018 125438 A1, which has a light source and an optical unit for generating a predetermined light distribution. The optics unit comprises a funnel-shaped light-guiding element and a lens which is arranged in front of the same in the main emission and which is provided with a plurality of optics elements on a rear side facing the light source. The optical elements are designed as micro-optical elements, for example in the form of prisms. The optical elements bring about a homogenization of the light. For design reasons, it is desirable that the lighting device has a dark appearance. Rear lights are known, for example, which are provided with a lens that is colored gray. If the light source is an incandescent lamp, a color filter is required to generate the required red or yellow signal color. If the light source is an LED light source, a color filter is not required because the LED light source itself emits colored light. A disadvantage of such a lighting device is that the transmission behavior of the lens deteriorates as the gray coloring of the lens increases. It is therefore desirable to ensure a dark appearance with a sufficiently high transmissivity. The object of the present invention is therefore to specify a lighting device for vehicles and a method for producing a lens in such a way that the lighting device has the darkest possible appearance with the lowest possible light losses.

To solve this problem, the invention is characterized in connection with the preamble of patent claim 1, characterized in that the optical elements are designed in such a way that the light striking them is deflected in a focusing area on the front side, which is designed as a transmission area, and that the front side of the lens, with the exception of the transmission areas, is provided with a dark coloring to form a dark area of the lens.

According to the invention, optical elements are arranged in the area of a light-entering rear side of a light disc, by means of which incoming light is collected, specifically on a focusing area that is located in the area of a light-emitting front side of the light disc. In addition, a dark coloring is provided in the area of the front side of the lens, so that the lighting device has a dark appearance. In order to keep light losses low, the dark coloring is not intended to cover the entire surface, but allows light to pass through, namely in the focusing areas on the front of the lens, into which the light is collected. The basic idea of the invention is therefore to focus or collect light passing through the lens onto an area of its front side that is small enough in relation to the total area of the front side, so that the lens has a dark appearance on the one hand, and large enough is that the required light output is given on the other hand. As a result, the lighting device can advantageously have a dark appearance when there is a relatively high luminous flux.

According to a development of the invention, the optical elements arranged on the back of the lens are arranged directly adjacent to one another. Before preferably the entire surface of the back is provided with the optical elements, so that on the front side of the lens there is a regular matrix-like arrangement of a plurality of focusing areas. Since the focusing areas are translucent and thus form a light area, the adjoining areas of the front face have a relatively low light permeability as dark areas. This ensures a homogeneous dark appearance with simultaneous homogeneous lighting. The matrix-like arrangement of the optical elements on the back can also be in two or more sub-areas, so that the dark lens can also cover several light functions and, in addition, has areas between the light functions without light-transmitting focusing areas.

According to a development of the invention, a wall thickness of the lens is selected such that the light collected from the back by the optical elements forms a collection point on the front of the lens or in the vicinity thereof. The focusing area or the transmission area of the light is therefore dimensioned smaller than the dimensions of the optical elements. As a result, the dark area of the front side can advantageously be made relatively large.

According to a development of the invention, the optical elements have a grid-like arrangement in a preferably square, rectangular, hexagonal or strip-shaped design, so that the transmission areas or focusing areas on the front of the lens also have a preferably square, rectangular, hexagonal or strip-shaped shape. Due to the elliptical basic shape, the light can be spread more widely in the horizontal direction than in the vertical direction, which is desirable for signal light functions.

According to a development of the invention, the optical elements have a basic shape with dimensions in the millimeter range or micrometer range or nanometer range. The smaller the basic shapes, the greater the number of passage areas and the smaller the passage areas are dimensioned. The smaller the basic shape, the greater the resolution, so the passbands for are imperceptible to an observer. It can thus be created a homogeneous dark appearance of the lens in the non-operating state.

According to a further development of the invention, the optical elements are arranged regularly and distributed over the back of the lens, which leads to a particularly homogeneous appearance.

According to a further development of the invention, the dark coloring on the front side of the lens can be formed by a dark coating, the coating being partially removed by means of a laser, specifically in the focusing areas on the front side. Alternatively, the dark coloring can also be achieved by printing the lens on the front. This can advantageously be done in a one-time manufacturing step.

To solve this problem, the invention in connection with the preamble of patent claim 10 is characterized in that a light-emitting front side of the lens is provided with a dark coating in a first step and in a second step by means of a laser in focusing areas of the front side on which the light hitting the optical elements is focused, the dark coating is removed so that the front of the lens is translucent in the focusing areas as transmission areas, or it is printed with a dark colour, leaving out the focusing areas on the front, or it is wrapped in foil with a foil that is printed dark over its surface with the exception of transmission areas, which cover the focusing areas when applied to the lens.

The particular advantage of the method according to the invention is that several re ways are possible to create a dark appearance ver a lens on the one hand and to emit a sufficiently large luminous flux to generate a predetermined light distribution on the other hand. The dark coloring on the front that matches the optical elements to be arranged on the back can done by printing or coating. Printing the front side of the lens by means of a screen printing process, for example, enables simple production, since only one additional work step is required.

Further advantages of the invention result from the further dependent claims.

An embodiment of the invention is explained in more detail below with reference to the drawings.

Show it:

1 shows a schematic structure of a lighting device,

2 shows a front view of a lens of the lighting device,

3 shows a rear view of the lens and FIG. 4 shows a cross section through the lens.

A lighting device for vehicles is preferably embodied as a rear light that is installed in a rear area of a vehicle. The lighting device has a light source 1 for emitting light 2 and an optical unit 3 for generating a predetermined light distribution. The light distribution can be, for example, a tail light, brake light, or direction indicator light function.

The light source 1 is designed as an LED light source or LED chip. The light source 1 is arranged on a support plate 4 .

The optics unit 3 comprises a reflector 5, on which the light 2 emitted by the light source 1 is deflected in the main emission direction H of the lighting device becomes. Light downstream of the reflector 5, a lens 6 is arranged, the device in front of preferably an opening of a housing, not shown, Illumination, in which the light source 1 and the reflector 5 are arranged, covers. The light 2 enters at a rear side 7 of the lens 6 facing the reflector 5 and/or the light source 1 and at a front side 8 of the lens 6 facing away from the reflector 5 and/or the light source 1 .

The back 7 of the lens 6 is seen with a plurality of optical elements 9 ver. The front side 8 of the lens 6 is flat and/or has no optical elements 9 . The lens 6 extends flat in one plane or is designed to be slightly curved in order to follow the contour of the body opening edge.

The optical elements 9 each have a convex surface, so that the light 2 striking them is collected or focused in a focusing area 10 , the focusing area 10 being located in the area of the front side 8 of the lens 6 . The focusing area 10 can be arranged directly on the front side 8 and/or in front of and/or behind the front side 8 in the main emission direction F1. In the present exemplary embodiment, as can be seen from Figure 4, the focusing area 10 is located in an area of the front side 8 which is arranged in the main emission direction H in front of the front side 8 of the lens 6. The focusing area 10 is therefore located directly on the front side 8 of the Lens 6 and / or near the front 8 of the same.

As can be seen from Figure 4, a transverse extent 11 of the focusing area 10 is smaller than a transverse extent 12 of the optical elements 9.

In the present exemplary embodiment, the light 2 impinging on the reflector 5 is made parallel, so that it impinges on the back 7 of the lens 6 essentially perpendicularly to the extension of the lens 6 . Consequently, the focusing area 10 of each optical element 9 is located in front of the respective optical element 9 in the main emission direction. The entire rear side 7 of the lens 6 is preferably provided with the optical elements 9 . The optical elements 9 are arranged directly adjacent to one another. The optical elements 9 are preferably of the same size and of the same shape.

The optical elements 9 can be formed in a millimeter range, for example 1.5 mm to 3 mm. Alternatively, the optical elements 9 as micro-optical elements can have a transverse extension or dimension (basic shape), which runs in the direction of extension of the lens 6, of 0.02 mm to 0.3 mm or 0.2 mm to a maximum of 1 mm. The optical elements designed as cushion or strip optics have such a width and/or height dimension or grid dimension. These optical elements 9 can be formed, for example, by a laser processing machine. Alternatively, the optical elements 9 can also be dimensioned even smaller, specifically in a micrometer or nanometer range of 0.001 mm to 0.1 mm.

At least the front side 8 of the lens 6 is provided with a dark coloring to form a dark area 13 of the lens 6, so that the lighting device has a dark appearance when cold. So that a luminous flux required for generating the light distribution can exit from the lighting device or the lens 6, the front side 8 of the lens 6 is left out of the dark coloring in the focusing area 10. One dimension 11 of the focusing area 10 on the front side 8 is formed as a transmissive area that is translucent or crystal clear, while the remaining area of the front side 8 as a dark area 13 is non-translucent or colored dark. The surface of the focusing area 10 on the front side 8 is characterized in that the light 2 diffracted by the optical elements 9 strikes it, while the non-focusing area or dark area 13 is characterized in that no light 2 strikes it and is therefore dark in color can. The focusing area 10 thus specifies the transmission areas 11 for the light 2, while the remaining part (dark area 13) of the front side 8, colored dark, lets little or no light 2 through. As can be seen from Figure 4, a wall thickness w of the lens 6 is selected in such a way that the light 2 diffracted at the optical elements 9 is collected or concentrated to such an extent on the front side 8, with such a reduction in area that by coloring the non-focusing areas 13 of the lens 6 have a dark appearance on the one hand and the luminous flux required to generate the light distribution can still be emitted on the other hand. In the present exemplary embodiment, the ratio between the area of the transmission region 11 on the front side 8 and the area of the base area of the optical elements 9 on the rear side 7 is in a range of less than 1/3.

In the present exemplary embodiment according to FIG. 2 and FIG. 4, the optical elements 9 have an oval basic shape, preferably in the horizontal direction, so that elliptically shaped focusing regions 10 or transmission regions 11 are formed, as can be seen from FIG. Alternatively, the basic shapes of the optical elements 9 can also be circular, cushion-shaped as shown in FIG. 3, or have another shape.

The optical elements 9 are arranged in a matrix-like manner in a grid, each with a predetermined basic shape. This basic shape can be square, rectangular, hexagonal or strip-shaped. The focusing areas 10 are also arranged in a grid and are each smaller in their dimensions than the basic shape of the optical elements 9, due to the focusing effect of the respective optical elements 9. The basic shape of the focusing areas 10 corresponds to the basic shape of the optical elements 9.

If the basic shape of the optical elements 9 is square, the basic shape of the focusing areas 10 is also square. The higher the number of optical elements 9 per surface, the greater the resolution of the transmission areas 11, so that the transmission areas 11 are not perceptible to the human eye either in the cold or in the warm state of the lighting device.

The lighting device or the lens 6 thus has a homogeneous dark appearance. To produce the dark coloring of the lens 6, the lens 6 produced for example by injection molding with a dark coating, for example with a metallic coating over the entire surface, can be seen on the front 8 ver. The metallic coating can take place, for example, by vapor deposition or sputtering, for example with dark chrome. In a subsequent production step, a laser is used to remove the dark coating in the focusing areas 10 and transmission areas 11.

According to a further variant of the invention, the dark coloring can be effected by printing. In this case, the front side 8 can be printed with a dark material, for example by means of a screen printing process, with the focussing areas 10 or transmission area 11 being omitted. Alternatively, an inkjet printing process can also be used.

According to a further embodiment of the invention, the front side 8 of the lens 6 produced by injection molding, for example, can be provided with a printed film. The printed film can be laminated or glued onto the front side 8 of the lens 6 . The film has transparent transmission areas 11 and non-transmission areas 13 surrounding them (i.e. dark or black printing), with the printing ensuring that the transmission areas cover the respective focusing areas 10 of the front side 8 of the lens 6 . For example, the printed film can be inserted into a mold of an injection molding machine and then back-injected with a corresponding plastic compound to shape the lens 6.

For example, the lens 6 can consist of a plastic material or a glass material.

The matrix-like arrangement of the rear-side optical elements 9 can also take place in two or more partial areas of the lens 6, so that the dark lens 6 can also cover several light functions and also has areas between the light functions without translucent focusing areas 10. Between the partial areas of the lens 6, the same has a continuous dark area 13 on the front 8.

Reference List

1 light source

2 light

3 optics unit

4 support plate

5 reflector

6 lens

7 back

8 front

9 optical elements

10 focus zones

11 pass band

12 transverse extent

13 non-focus area

H main beam direction w wall thickness

Claims

patent claims

1. Lighting device for vehicles with a light source (1) and with an optics unit (3) for generating a predetermined light distribution, the optics unit (3) comprising a lens (6) on a light source (1) facing the back (7) has a plurality of optical elements (9), characterized in that the optical elements (9) are formed in such a way that the light (2) striking them is deflected in a focusing area (10) of the front side (8). , which is designed as a transmission area (11), and that the front side (8) of the lens (6), with the exception of the transmission areas (11), is provided with a dark coloring (13) to form a dark area (13) of the lens (6 ).

2. Lighting device according to claim 1, characterized in that the back (7) of the lens (6) is provided with a plurality of optical elements (9) arranged adjacent to one another.

3. Lighting device according to claim 1 or 2, characterized in that the front (8) of the lens (6) exclusively in the focusing area (10) arranged transparent transmission areas (11) and the non-transparent dark area (13).

4. Lighting device according to one of claims 1 to 3, characterized in that the optical elements (9) have a convex surface and that a wall thickness (w) of the lens (6) is designed such that on the convex surface of the optical elements (9 ) entering light (2) on the front (8) of the lens (6) or in a vicinity of the front (8) of the lens (6) is collected.

5. Lighting device according to one of claims 1 to 4, characterized in that the optical elements (9) are arranged like a matrix in a grid, each with a predetermined basic shape and that the focal area (10) is smaller in its dimensions than the basic shape of the OP tic elements (9).

6. Lighting device according to one of claims 1 to 5, characterized in that the basic shape of the optical elements (9) lie in a millimeter range or micrometer range or in a nanometer range.

7. Lighting device according to one of claims 1 to 6, characterized in that the optical elements (9) are arranged regularly over the surface of the back (7) of the lens (6) or in several partial areas of the lens and that the optical elements (9) are formed the same size.

8. Lighting device according to one of claims 1 to 7, characterized in that the dark coloring of the front (8) of the lens (6) in the dark areas (13) is formed by a dark coating in the transmission areas (11) of the Front (8) is removed by a laser.

9. Lighting device according to one of claims 1 to 7, characterized in that the dark coloring is formed by printing or by laminating a printed film provided with the dark coloring.

10. A method for producing a lens (6), wherein the lens (6) on a light-entering back (7) with a plurality of optics elements (9) is formed, characterized in that a light-emitting front side (8) of the lens (6)

- Is provided in a first step with a dark coating and in a second step by means of a laser in Focussing areas (10) of the front (8) on which the optical elements (9) impinging light (2) is focused, from which dark coating be freed so that the front (8) of the lens (6) in the focusing areas (10) as transmission areas (11) is translucent, or

- is printed with a dark color, the focusing areas (10) of the front (8) are omitted, or

- Is foiled with a foil that is printed dark over its surface with the exception of transmission areas (11), which cover the focusing areas (10) in a state applied to the light disc (6).

11. The method according to claim 10, characterized in that the printed film is placed in a mold space and then a plastic compound is introduced into the mold space, so that the film is back-injected with a translucent material to form the lens (6).

12. The method according to claim 10, characterized in that the film is laminated onto the front side (8) of the lens (6).