Lighting device for vehicles

Abstract

A lighting device for vehicles with an elongated light guide comprising an end face for the coupling-in of light, into which a light beam radiated from a light source can be coupled-in. The lighting device further comprises elements for the coupling-out of light for the deflection of the coupled-in light beam in the direction of a front skin surface of the elongated light guide, on which the light beam can be coupled-out for the generation of a given light function, such that the front skin surface of the elongated light guide is connected to a rear skin surface by means of a curved dispersion surface. At least one light directing element is arranged between a row of light sources and the light guide so that the light of the light sources arranged in a row can be coupled into the rear skin surface or the curved dispersion surface of the light guide.

Claims

1. A lighting device for vehicles comprising: an elongated light guide including: an end face for the coupling-in of light, into which a light beam radiated from a light source can be coupled-in, and elements for the coupling-out of light for the deflection of the coupled-in light beam in the direction of a front skin surface of the elongated light guide, on which the light beam can be coupled-out for the generation of a given light function, a curved dispersion surface connecting the front skin surface of the elongated light guide to a rear skin surface of the elongated light guide, and at least one light directing element located between a row of light sources and the light guide so that light from the light sources arranged in a row can be coupled into the rear skin surface of the light guide, and wherein the at least one light directing element is embodied as a cuboidal light guide element extending between the row of light sources and the elongated light guide.

2. The lighting device according to claim 1, wherein the light sources assigned to the elongated light directing element can be sequentially switched on or off for the creation of an illumination which is locally changeable in the longitudinal direction of the light guide.

3. The lighting device according to claim 1, wherein a second light beam coupled into a surface for the coupling-in of light of the light guide element facing the light sources can be deflected in direction of the light guide by means of total reflection on the lateral surfaces of the light guide element.

4. The lighting device according to claim 1, wherein the light directing element is segmented in the longitudinal direction.

5. The lighting device according to claim 1, wherein the light directing element is continuous in the longitudinal direction.

6. The lighting device according to claim 1, wherein the light directing element has open slots or closed slots on the side facing the row of light sources.

7. The lighting device according to claim 1, wherein on both sides of a median plane of the light guide, there are light directing elements arranged, each of which has a row of light sources assigned on a surface for the coupling-in of light facing away from the light guide and each of which has, on the side for the coupling out of light facing the light guide, a surface for the coupling-out of light following the contour of the curved dispersion surface of the light guide.

8. The lighting device according to claim 1, wherein an intermediate lens is positioned and located between the light guide element and the elongated light guide.

9. The lighting device according to claim 8, wherein the intermediate lens is cuboidal.

10. The lighting device according to claim 8, wherein the intermediate lens abuts the light guide element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Reference is now made more particularly to the drawings, which illustrate the best presently known mode of carrying out the invention and wherein similar reference characters indicate the same parts throughout the views.

(2) FIG. 1: a schematic lateral view of a lighting device according to a first embodiment of the invention with a light guide element embodied as a reflector,

(3) FIG. 2: a schematic lateral view of a lighting device according to FIG. 1 with an alternative light source arrangement according to a second embodiment,

(4) FIG. 3: a perspective representation of the lighting device according to FIG. 2 without representation of a light guide,

(5) FIG. 4: a perspective representation of the lighting device according to FIG. 2 with the light guide shown,

(6) FIG. 5: a lateral view of a lighting device according to a third embodiment with a light directing element embodied as a light guide element,

(7) FIG. 6: a schematic representation of the switching process of the additional light sources arranged in a row in the longitudinal direction of the light guide,

(8) FIG. 7: a lateral view of the lighting device according to a further embodiment with an intermediate lens,

(9) FIG. 8: a top view of the embodiment according to FIG. 7,

(10) FIG. 9: a top view of an embodiment with a light directing element which is continuous in the longitudinal direction,

(11) FIG. 10: a top view of a light directing element having slots,

(12) FIG. 11: a top view of a light directing element having closed slots,

(13) FIG. 12: a lateral view of a light directing element with directed surface for the coupling-out of light.

(14) FIG. 13: a lateral view of the light directing element with prism-shaped surface for the coupling-out of light.

(15) FIG. 14: a lateral view of the light directing element with pillow-shaped optic elements on the surface for the coupling-out of light,

(16) FIG. 15: a lateral view of the light directing element with an etched surface for the coupling-out of light,

(17) FIG. 16: a lateral view of a light directing element with a coupling-in optics according to a first embodiment,

(18) FIG. 17: a lateral view of a light directing element with a coupling-in optics according to a second embodiment,

(19) FIG. 18: a lateral view of a light directing element with a coupling-in optics according to a third embodiment,

(20) FIG. 19: a lateral view of a light directing element with a coupling-in optics according to a fourth embodiment, and

(21) FIG. 20: a lateral view of a lighting device with two light directing elements.

DETAILED DESCRIPTION

(22) In the following detailed description numerous specific details are set forth in order to provide a thorough understanding of the invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these specific details. For example, the invention is not limited in scope to the particular type of industry application depicted in the figures. In other instances, well-known methods, procedures, and components have not been described in detail so as not to obscure the present invention.

(23) A lighting device for vehicles is arranged in a tail or front region of a vehicle. The lighting device can be used for the creation of a light function, in which the light can be changeably radiated with regard to place and/or time.

(24) According to a first embodiment following FIG. 1, the lighting device has an elongated light guide 1 to the rear of which, with regard to the main radiation direction H, a light directing element embodied as a reflector 2 is assigned. The reflector 2, like the light guide 1, has an elongated embodiment and extends preferably in a horizontal direction in parallel to the same. A row of light sources 3 is arranged spaced relative to one another in the longitudinal direction of the reflector 2 on a back of the reflector 2 facing away from the light guide 1.

(25) The cross section of the light guide 1 is trumpet-shaped and has a rear skin surface 4, a front skin surface 5, as well as a curved dispersion surface 6, 6 connecting the rear skin surface 4 with the front skin surface 5. The reflector 2 is symmetrically arranged relative to a longitudinal mean plane M of the light guide 1, wherein the identically shaped dispersion surfaces 6, 6 facing one another connect the narrow rear skin surface 4 having a plane embodiment with the front skin surface 5 having a cylindrical embodiment. On an end face of the light guide 1 which is not represented, a light source is arranged, which radiates a first light beam L1 into the light guide, which is coupled-in at a end face of the light guide 1 and is directed onto the skin surfaces 4, 5, 6, 6 of the light guide 1 in the longitudinal direction E of the same.

(26) The rear skin surface 4 has prism-shaped optic elements as elements for the coupling-out of light 7, by means of which the light beams L1 hitting them are deflected in the direction of the front skin surface 5. These light beams L1 are then coupled-out on the front skin surface 5 for the creation of the light function.

(27) The embodiment of the reflector 2 is preferably symmetrical relative to the longitudinal mean plane M and has outer reflector surfaces 2 and inner reflector surfaces 2. The opposing outer reflector surfaces 2 extend into a region in the vicinity of the curved dispersion surface 6 resp. 6, so that light beams L2 radiated from the light sources 3 are coupled into the curved dispersion surfaces 6, 6 in the light guide 1. The inner reflector surface 2 extends in a region close to the longitudinal mean plane M so that light beams L2 (partial light beams) are reflected in direction of the outer reflector surface 2. The inner reflector surfaces 2 preferably converge in the longitudinal mean plane M, so that no light L2 radiated from the light sources 3 can directly hit the rear skin surface 4 and/or the curved dispersion surfaces 6, 6. The light beams L2 exclusively hit the curved dispersion surfaces 6, 6 once they have been deflected once or several times on the outer reflector surface 2.

(28) Once the light beam L2 has entered the light guide 1, it is deflected by means of the curved dispersion surface 6, 6 so that it is coupled out on the front skin surface 5 in the main radiation direction H. Herein, the dispersion of the second light beam L2 preferably has the same dispersion as the first light beam L1. The light dispersion, particularly in the vertical direction, is therefore identical.

(29) The reflector surfaces 2, 2 can have a smooth surface or an optical structure. The optical structure can for example be embodied as pillow optics or striped optic elements. Alternatively, the optical structure can also be achieved by means of erosion or etching or lasering.

(30) The reflector 2 can be fastened in a carrier element or a bezel of the lighting device in which the light guide 1 is held.

(31) According to the first embodiment corresponding to FIG. 1 the light sources 3 are embodied as LED light sources being arranged on a common rigid carrier plate 8.

(32) According to a second embodiment of the invention corresponding to FIGS. 2 to 4, and in contrast to the first embodiment, a row of lateral-LED-light sources 3 can be assigned to the reflector 2. In contrast to the first embodiment, these are not arranged on a printed circuit board running vertical to the longitudinal mean plane M, but on a printed circuit board 8 running parallel to the longitudinal mean plane M, resp. parallel to the main radiation direction H.

(33) Identical components resp. identical component functions of the exemplary embodiments are marked with identical reference signs.

(34) According to a represented alternative embodiment, the light sources can also be embodied as OLED light sources, in which the light beam L2 is not radiated in a punctiform manner, as described in the above embodiments, but from a lighting panel.

(35) According to a further embodiment of the invention according to FIG. 5, the light directing element can be embodied as a light guide element 12 extending as a solid body between the row of light sources 3 and the light guide 1. The light guide element 12 has a jaw-shaped cross-section and has two light guide legs 12, 12 extending on both sides of the longitudinal mean plane M. The front ends of the light guide legs 12, 12 extend into a region in the vicinity of the curved dispersion surface 6, 6. The two light guide legs 12, 12 each have outer lateral surfaces 13 and inner lateral surfaces 14, on which the coupled-in light beam L2 can be fully reflected. In a free end region of the light guide legs 12, 12 the light beams L2 are coupled-out on the inner lateral surfaces 14, so that they can enter the light guide 1 through the curved dispersion surfaces 6, 6. Subsequently a deflection, already described above, occurs inside the light guide 1, so that they are coupled-out on the front skin surface 5 in the main radiation direction H in an identical manner.

(36) To switch the lighting device on, the light sources 3, 3 are sequentially switched on by means of a control device which is not represented, starting preferably from an innermost side of the vehicle toward an outermost side of the vehicle. By this means, light L2 is, by and by, coupled into the light guide 1 in the longitudinal direction E by means of the light directing element 2, 12 and radiated from its front skin surface 5. This results in a wandering light function resp. a light strip which is extended by and by along the longitudinal direction E of the light guide 1. A wiping effect is created, which can for example be used when a direction indicator function, a tail light function or a daytime running light function is switched on.

(37) FIG. 6 gives a schematic representation of the light radiated from the light guide 1 in the longitudinal direction E against the switching points. At the beginning of the switching process, a light source 3, 3 preferably facing the vehicle inside is switched on at the point in time t.sub.0, so that a light radiation L2 is effected in the longitudinal direction E across a first partial section E1 of the light guide 1. At the end of a time interval t, the neighboring light source 3, 3 is switched on in addition, so that an illumination of the light guide 1 across a partial section E2 being larger than the partial section E1 is effected. Subsequently, further light sources 3, 3 are switched on sequentially in addition at time intervals of t, until the light guide 1 is lit across its entire extension. The light guide 1 then radiates the light L2 provided by the light directing element 2, 12 across its entire length. The process of switching on the light sources 3, 3 is thus completed. Subsequently, the first light beam L1 of the light source situated on the front-side surface for the coupling-in of light of the light guide 1 can be radiated via the front skin surface 5 in addition by switching it on, so that an increase in illuminance is created across the entire length of the light guide 1. Either the light sources 3, 3 assigned to the light directing elements 2, 12 can remain switched on or they are switched off so that the light guide 1 is illuminated exclusively by the first light beam L1.

(38) For the creation of the direction indicator function, the light sources 3, 3 assigned to the light directing element 2, 12 as well as the light sources assigned to the light guide 1 are switched off simultaneously after the lapse of a given time interval, so that after a given pause, the described switching process can start again. The switching on of the lighting device therefore effects the creation of a light strip extending in the longitudinal direction, the light strip being determined by the extension of the light guide 1.

(39) The light guide 1 and the light directing element 2, 12 may have a straight or a curved shape.

(40) The light sources 3, 3 have main axes A, which run in the main radiation direction H resp. vertically to the longitudinal direction E of the light guide 1 resp. the light directing element 2, 12. The light sources 6, 6 are preferably arranged at identical distances. The light source assigned to the light guide 1 being arranged on the end face for the coupling-in of light of the same has a main axis running vertical to the main radiation direction H resp. in the direction of the longitudinal direction E of the light guide 1, if the light guide 1 has a straight shape. If the light guide 1 has a curved shape, the main axis of this light source is preferably arranged in the direction of a normal of the surface for the coupling-in of light at the end face of the light guide 1.

(41) According to a further embodiment of the invention according to the FIGS. 7 and 8, a light directing element arranged between the row of light sources 6 and the light guide 1 can be embodied as an essentially cuboidal light guide element 22 and followed by an intermediate lens 22 arranged in the same main radiation direction H. The light guide element 22 is segmented and has narrow sides 23, 23 facing away from each other. Parallel to the longitudinal mean plane M of the light guide 1, the light guide element 22 is limited by opposing flat sides 24, 24. On a front side facing the light guide 1, the light guide elements 22 are each monolithically connected with the continuous intermediate lens 22 in the longitudinal direction E. The intermediate lens 22 has a contour 25 following the course of the light guide 1, on which the light L2 is coupled-out in the direction of the rear skin surface 4 of the light guide 1. In this execution of the invention, the light beam L2 is exclusively coupled-in on the rear skin surface 4 of the light guide 1. The rear skin surface 4 has preferably a prism-shaped structure as coupling-out elements, which on one hand allows a deflection of the light L1 coupled-in in the longitudinal direction E of the light guide 1 toward the front skin surface 5, and on the other hand allows an entrance of the second light beam L2.

(42) According to a further embodiment of the invention according to FIG. 9, a light guide element 26 can be embodied continuously in the longitudinal direction E. Optionally, the intermediate lens 22 can be omitted.

(43) According to a further embodiment of the invention according to FIG. 10, a light guide element 27 can have slots 28 having a depth t1 being smaller than a depth t2 of the monolithically embodied light element 27. The slots 28 extend from a side on which the light is coupled-in of the light directing element 27 in the direction of a side for the coupling-out of light of the same without it being reached. The light guide segments 27 separated in this manner are each assigned to a light source 3.

(44) According to a further embodiment of the invention according to FIG. 11, a light guide element 29 can be provided, which has closed slots 30 in contrast to the light guide elements 27 according to FIG. 10.

(45) On a side for the coupling-out of light facing the light guide 1, a light guide element 31 can have a directed optic structure 32, for example a Fresnel structure.

(46) Alternatively, a light guide element 33 can also have a prism-shaped structure 34 on the side for the coupling-out of light. Alternatively, a light guide element 35 can also have an optical structure provided with pillow-optics elements 36 on the side for the coupling-out of light. Alternatively, a light guide element 37 can also have an etched or lacquered structure 38 on the side for the coupling-out of light.

(47) According to a variant of the invention, a light guide element 39 can have a concave depression 40 on a side for the coupling-in of light. According to a further alternative according to FIG. 17, a light guide element 41 can be embodied tapered in the direction of the side for the coupling-in of light, wherein a depression 42 is assigned to the LED light source 3. Depending on the installation space, the LED light source 3 can also be arranged at an angle, for example 45 degrees, relative to a longitudinal direction of a light guide element 43. To this end, the light guide element 43 has a lateral depression 44 on the side for the coupling-in of light. According to a further embodiment of the invention according to FIG. 19, the light source 3 can also be arranged at a right angle relative to the longitudinal direction of a light guide element 45. The light guide element 45 has a deflecting nose 46 comprising a refection surface 47, on which the light L2 coupled-in via a depression 48 is deflected in the longitudinal direction of the light guide element 45.

(48) According to a further embodiment of the invention according to FIG. 20, plate-shaped light guide elements 46, 46 are arranged on both sides of the mean plane M of the light guide 1, each of which has a row of light sources 3 assigned on a side for the coupling-in of light. The light guide elements 46, 46 each have a curved surface for the coupling-out of the light 47, 47 on the side for the coupling-out of light, following the contour of the curved dispersion surface 6, 6 of the light guide. Preferably, there is a constant distance b between the contour of the surface for the coupling-out of light 47, 47 on one hand and the curved dispersion surface 6, 6 on the other hand.

LIST OF REFERENCE SIGNS

(49) 1 Light guide 2, 2, 2 reflector external, internal 3, 3 Light source 4 Rear skin surface 5 Front skin surface 6, 6 Curved dispersion surface 7 Elements for the coupling-out of light 8, 8 Carrier plate 9 10 11 12, 12, 12 Light guide legs 13 Outer lateral surfaces 14 Inner lateral surfaces 22, 22 Light guide element/intermediate lens 23, 23 Narrow sides 24, 24 Flat sides 25 Contour 26 Light guide element 27 Light guide element 28 Slots 29 Light guide element 30 Slot 31 Light guide element A Axis H Main radiation direction M Longitudinal mean plane E Longitudinal direction L1, L2 Light beam