Additional headlights for vehicles and headlight system

专利摘要:
Auxiliary headlight (3) for a vehicle, which is adapted to generate a light image in front of the vehicle by emitting light from at least one light module (4) and projecting it in front of the vehicle through a downstream imaging optical system (5), the auxiliary headlight (3 ) comprises: at least one first light module (4a) for generating a first light emission by at least one first light source (10a), at least one second light module (4b) for generating a second light emission by at least one second light source (10b), at least one primary optic (11 ), wherein the primary optics has a plurality of light guide elements (12) and each light guide element (12) has a light entry surface (12ef) for coupling in a light emission, and a light exit surface (12af), wherein the first light emission into at least a first light guide element (12a) Primary optics (11) coupled, the second light emission in at least a second Lichtführungse Lement (12b) of the primary optics (11) coupled, at least one of the primary optics (11) downstream aperture with at least a first aperture, which faces the light exit surface of the first light guide element (12a) and at least a second aperture, the light exit surface of the second light guide element ( 12b), wherein the primary optics (11) and the diaphragm produce a total light image from the light emissions, and an imaging device (5) downstream of the diaphragm projects the total light image as a light image in the emission direction of the additional headlight (3) as an overall light image.
公开号:AT518098A1
申请号:T51074/2015
申请日:2015-12-17
公开日:2017-07-15
发明作者:Danner Markus；Taudt Lukas
申请人:Zkw Group Gmbh；
IPC主号:

专利说明:

Auxiliary headlights for vehicles
The invention relates to an auxiliary headlamp for a vehicle, which is adapted to generate a light image in front of the vehicle by emitting light from at least one light module and to project by a downstream imaging optics in front of the vehicle.
In the development of the current headlight systems is increasingly the desire in the foreground to project a light image on the road, which can be quickly changed and adapted to the respective traffic, road and lighting conditions.
For this purpose, various headlights, such as headlights and auxiliary lights, used to produce different light images on the road. The term "road surface" is used here for a simplified representation, because of course it depends on the local conditions, whether a photo is actually on the roadway or extends beyond it.In principle, the photograph in the sense used corresponds to a projection on a vertical surface in accordance with the relevant standards relating to automotive lighting technology.
In order to meet this stated need, among other things, headlights have been developed which form a luminous matrix from a plurality of individual radiators. Such lighting devices are commonly used in the automotive industry and serve, for example, the imaging of glare-free high beam by the light is usually emitted by a plurality of light sources and is bundled by a corresponding plurality of juxtaposed light guides (intent optics / primary optics) in the direction of radiation. The light guides have a relatively small, funnel-shaped cross-section and therefore emit the light of their associated individual light sources very concentrated in the emission direction. The light guides forward the light from the light sources to a position that is as close as possible to a spatially curved plane, the Petzval plane of the upstream imaging optics. However, especially with the use of a larger number of high-power light sources, this type of matrix headlamp has limitations in terms of dissipation of its thermal dissipation. Consequently, headlights that produce dynamic light images with a particularly high intensity, very expensive to produce.
Different traffic situations each make different specific requirements for the headlights of a vehicle. It may also be desired in addition to the illumination of the road by a low beam or high beam to make the driver aware of specific hazardous situations by appropriate visual signaling. Such a dangerous situation represents, for example, a narrowing of the road through a construction site. Many drivers can hardly estimate the distance between the vehicle and the road boundary because the driver has no direct view from the driver's perspective on the road boundary as well as on the outer boundary of the vehicle. For this purpose, the function of an "Optical Lane Assist" has already been proposed.
DE 10 2009 009 472 A1 describes such a system which projects lines onto the roadway in front of the vehicle in order to signal the driver a safe avoidance direction in the event of a detected collision probability.
An object of the present invention is to find a simple, compact and inexpensive embodiment for a line headlight.
This object is achieved with an auxiliary headlight of the type mentioned above such that, according to the invention, the function of an auxiliary high beam is combined with the function of a line light in order to achieve a very compact design by realizing it in a common component and thereby to obtain cost advantages. Thus, an auxiliary headlight of the aforementioned type is improved such that a first light module is adapted to generate a first light image with at least a first light distribution having at least a first, substantially vertically oriented, linear intensity maximum, and a second light module is arranged to to generate a second light image with a second light distribution having at least a second, substantially rectangular intensity maximum, and to superimpose the light images of both light modules, wherein the first intensity maximum is located vertically below the second intensity maximum.
Especially in the integration of several lighting devices with similar lighting properties in a common component, the advantage achieved increases significantly. According to the invention, an auxiliary high beam is combined with a line light in one component, both lighting devices each having high optical power with strong optical focusing, i. having a small aperture. Advantageous, therefore, inter alia, the simple, combined design of the projection lens, and the common cooling or electrical control of both power light sources. The assembly of the headlight is simplified, inter alia, by a common primary optics and aperture, the reduced number of mounting devices manifests itself in lower material costs, smaller size and reduced assembly time.
The entire projection arrangement consists of light source, primary optics and imaging optics (projection lens). The imaging optics can lead to distortion depending on the design. The distortion is a geometric aberration of optical systems, which leads to a local change of the magnification. The scale change is based on a change in magnification with increasing distance of the pixel from the optical axis. The distortion is therefore rotationally symmetric about a point, which is also called distortion center. The cause of the distortion is due to apertures that narrow the beam of the image in front of or behind the main plane of an optical system with aperture error. If the magnification increases to the edges of the image field, then a square is recorded as a pillow. In the opposite case one speaks of barrel distortion. It is also possible for higher order distortions to occur, and the overlapping of different orders can lead to a wave-shaped image of straight lines ("wavy distortion") .The degree of distortion is known from DIN ISO 9039: Optics and Photonics - Quality Assessment of Optical Systems - Determination of Distortion (ISO 9039: 2008).
It is also clear that projection projections may occur in the projection of a light image onto the roadway in front of the vehicle, for example, a light image may appear trapezoidally distorted on the roadway, since the projection plane is not oriented normal to the emission direction of the light. These projection distortions arise in addition to the previously mentioned distortions.
Both projection distortions and distortions can be reduced or compensated by an appropriate predistortion. It is therefore favorable if, during the generation of the light distributions in the headlight, a predistortion is carried out, for example through a diaphragm, and as a result an overall equalized light image is projected or at least a reduction of the disturbing effect is achieved.
The first, substantially vertically oriented, linear intensity maximum thus means the rectified light projection, in which projection distortions and / or distortions are reduced, possibly also a perspective representation of the projected line with a vanishing point in the direction of travel or in the roadway for realistic representation with central projection Take into account. A certain line width in the projection is provided so that the projected line of the vehicle assistance system is clearly visible from the driver's perspective.
It is advantageous if the long sides of the substantially rectangular intensity maximum are horizontally oriented in order to obtain a favorable light distribution for an additional high-beam light.
In a preferred embodiment, the first intensity maximum is horizontal within the horizontal width of the second intensity maximum. Due to the small distance between the two intensity maxima, the aperture of the entire optics is small and a particularly small, compact and cost-effective design is achieved.
A further preferred embodiment of the additional headlamp provides that the first intensity maximum and the second intensity maximum are arranged at a vertical distance from each other. Although both light distributions of the additional headlamp have similar luminous properties, but preferably serve different applications in the near or far range in front of the vehicle. The line light of the first light module preferably projects a line on the roadway in the range of 2 to 20 meters in front of the vehicle, the auxiliary high beam of the second light module projects in the high beam area, i. preferably at a distance of more than 50 meters a rectangle to support another high beam. For this reason, it is advantageous if both light distributions have no overlap in their intensity maxima.
According to the invention, the first and second light image can be projected simultaneously or alternatively, and the electrical or thermal system components can be designed accordingly. If it is determined, for example, that either only line light or only additional high-beam light are active, preferably as a function of the speed of the vehicle, then the common cooling device can be made smaller and more cost-effective. It can be used both an active and a passive cooling device.
A particularly advantageous embodiment of the auxiliary headlamp according to the invention comprises: at least one first light module for generating a first light emission by at least one first light source, at least one second light module for generating a second light emission by at least one second light source, at least one primary optic, wherein the primary optics comprises a plurality of light guide elements Each light guide element has a light entry surface for coupling in a light emission, and a light exit surface, the first light emission coupled into at least a first light guide element of the primary optics, the second light emission coupled into at least a second light guide element of the primary optics, at least one of the primary optics downstream aperture with at least one first aperture, which faces the light exit surface of the first light guide element and at least one second aperture, the Lic The primary optics and the diaphragm produce a total light image from the light emissions and one of the diaphragm downstream imaging optics project the total light image as a light image in the emission of the auxiliary headlight as a total light image.
Said arrangement provides a particularly cost-effective additional headlamp, which produces the desired light distributions in the installation position of the vehicle and reduces the number of mounting devices when assembled by a common primary optics and aperture, and significantly reduces production in the form of lower material costs, smaller size and shorter assembly time improved.
It is particularly favorable if all the light exit surfaces of all light guide elements lie in one surface, since the construction is thereby simplified.
In addition, the construction is simplified if the light exit surfaces of all light guide elements, which are assigned to the same light module, form a common light exit surface.
An efficient design of both light modules provides that all
Light guide elements of the first light module, are structurally separated from those of the second light module to functionally decouple both light modules and to reduce unwanted light coupling of the other light module.
To further simplify the construction and to reduce the manufacturing costs, a common support is provided for all light guide elements.
In a particularly favorable variant, the light output of the first light module is improved such that the first light module comprises a plurality of light sources, which are arranged substantially vertically in a row one above the other.
In a further, particularly favorable variant, the light output of the second light module is improved such that the second light module comprises a plurality of light sources which are arranged substantially horizontally in a row next to one another.
Since the imaging optics inverts the orientation of the light image during the projection, it is advantageous to take this circumstance into account in the arrangement of the light modules by arranging the first light module over the second light module.
Cost-effective cooling can be structurally particularly well implemented when the first light module and the second light module are adjacent and use a common cooling device.
A cost-effective control device can be structurally particularly well implemented when the first light module and the second light module are controlled by a common control device. It is favorable if unevenness of the roadway, loading conditions of the vehicle or curvy road courses are taken into account by the fact that the additional headlight is mechanically pivotable about at least one axis, thus projecting the light images depending on the situation and reducing said influence.
Advantageous in terms of luminous efficiency, cost and size is the use of light-emitting diodes (LEDs) or power LEDs (high-current light emitting diodes) as light sources.
It is particularly advantageous if a plurality of vehicle headlights form a headlight system and form an adaptive overall light image in that the light image of the auxiliary headlight is superimposed on at least one further light image of a headlight, in particular if a vehicle comprises a left and a right auxiliary headlight and a left and a right main headlight. Accordingly, there are particularly favorable, very variable overall light images, which preferably depend on the situation of the vehicle when the left and right auxiliary headlights each project different light images.
A headlamp system that builds on the existing light distribution of the headlight with a light distribution of a high beam or a low beam with the auxiliary headlight is particularly effective and inexpensive.
The invention and its advantages are described in more detail below by way of non-limiting examples, which are illustrated in the accompanying drawings. The drawings show in:
1 is a vehicle in front view with headlamps and auxiliary lights,
2a is a perspective view of the additional headlamp, without aperture,
2b shows the perspective view of the light module in detail A,
3a is the front view of the additional headlamp, without aperture,
3b shows the front view of the additional headlamp in detail B,
4a shows the front view of light module with holder, without aperture,
4a shows the perspective detail view of the light module with holder without aperture in section A-A,
5 shows the front view of light module with diaphragm,
6 is the perspective view of light module with diaphragm,
7 is a perspective view of additional headlamps with imaging optics,
8 is a perspective rear view of the additional headlight with imaging optics and cooling fins,
9 shows the exploded view of the additional headlamp with imaging optics
10 shows the light image with the line-shaped light distribution of the left auxiliary headlamp,
Fig. 11, the light image with the linear light distribution of the right
Additional headlight,
12 shows the light image with the (rectangular) light distribution of an additional high-beam of the left additional headlamp,
13 shows the light image with the (rectangular) light distribution of an additional high-beam of the right high-beam additional headlamp,
14 shows the light image of the light distribution of a low beam of the left main headlamp, FIG. 15 shows the superimposed light image of low beam of FIG. 14 and line of FIG. 10 of the left main and auxiliary headlamp, FIG.
16 is the superimposed light image of dipped beam and line of FIG. 11 of the right main and auxiliary headlamp,
17 shows the superimposed overall light image of the left-hand main and auxiliary headlight from FIG. 15 and the right main headlight and additional headlight from FIG. 16, FIG.
FIG. 18 shows the superimposed overall light image projected onto the roadway from the vehicle from the left-hand main and auxiliary headlamp from FIG. 15 and the right main and additional headlamp from FIG. 16, FIG.
19 shows the light image of the light distribution of a high beam of the left main headlight,
FIG. 21 shows the superimposed light image of the high beam of FIG. 19 and the auxiliary high beam of FIG. 12 of the left main and auxiliary headlight, FIG.
FIG. 22 shows the superimposed light image of the high beam of FIG. 20 and the auxiliary high beam of FIG. 13 of the right main and auxiliary headlight;
FIG. 23 shows the superimposed overall light image of the left main and auxiliary headlight from FIG. 21 and the right main and auxiliary headlight from FIG. 22 projected onto the roadway from the vehicle. FIG.
FIG. 24 shows the superimposed light image of the high beam of FIG. 10 and the auxiliary high beam of FIG. 12 and the line light of FIG. 10 of the left main and auxiliary headlamp, FIG.
FIG. 25 shows the superimposed light image of the high beam of FIG. 20 and the auxiliary high beam of FIG. 13 and the line light of FIG. 11 of the right main and auxiliary headlight, FIG.
FIG. 26 shows the superimposed overall light image of the left main and additional headlamp from FIG. 24 and the right main and additional headlamp from FIG. 25, FIG.
FIG. 27 shows the superimposed overall light image projected onto the roadway from the vehicle of the left main and additional headlight from FIG. 24 and the right main and auxiliary headlight from FIG. 25.
FIGS. 10 to 27 show different light distributions, intensities of the isolux curves being shown by way of example in FIGS. 14 and 15, the intensity amounts of which apply to all FIGS. 10 to 27. The luminous intensities used by way of example can be converted into illumination intensities, as is familiar to the person skilled in the art.
With reference to Fig. 2a, an embodiment of the invention will now be explained in more detail. In particular, the important parts for a headlamp according to the invention are shown, it being understood that a headlamp still contains many other parts that allow a meaningful use in a motor vehicle, in particular a car or motorcycle.
In Fig. 1, an overview of a vehicle 1 is shown, the left and right headlights 2 and 2 'and auxiliary lights 3 and 3' has. The two main headlights 2,2 'preferably produce a light distribution of low beam or high beam. The two additional headlights 3, 3 'generate a linear light distribution and a light distribution of a secondary high-beam in two modules, all light distributions are activated individually or in combination of the headlights, as well as the combination of left and right headlights is possible to account for the particular driving situation wear. The position of the individual headlights 2, 2 ', 3 and 3' on the vehicle 1 may vary and depends inter alia on the design of the vehicle. A near-lane position of auxiliary lights 2,2 'on the vehicle 1 may be advantageous.
In Fig. 2a, the arrangement of the additional headlight 3,3 'is shown in overview. The additional headlight 3 consists of a light module 4, which emits the light, shapes and projected by a downstream imaging optics 5 in front of the vehicle as a light image 6. Detail A in FIG. 2b shows the light module 4, which has a first light module 4a for generating first light emissions 9a 'and 9a "by first light sources 10a' and 10a", and a second light module 4b for generating second light emissions 10b ', 10b "and 10b The primary optics 11 has a plurality of light guide elements 12, each light guide element 12 having a light entry surface 12ef for coupling in a light emission, and a light exit surface 12af. The light guide elements 12 of the primary optics form in this embodiment two groups for two different light distributions, which are represented by the associated light sources by the light modules 4a and 4b.
The physical separation of both light modules serves to decouple the optical propagation paths. The first light emission 9a ', 9a "couples into a first light guide element 12a of the primary optics 11 and the second light emission 9b', 9b", 9b "'couples into a second light guide element 12b of the primary optics 11. The light sources 10a', 10a", 10b ', 10b "and 10b'" may be loosely or firmly coupled to the respective light entry surfaces. The type of said coupling is determined, inter alia, by the design of the light sources 10a ', 10a ", 10b', 10b" and 10b '", wherein a distance between light entry surfaces and light sources may be constructively provided to mechanical loads, such as vibrations or different temperature expansions of individual components to be able to counter.
Light guide elements 12 together with a diaphragm (not shown in this figure) form the light emissions and form the light image. The diaphragm usually ensures sharp contours in the light image, the light guide elements 12 for a suitable areal radiation characteristic. Usually, the cross section of the light guide elements 12 increases from the light entry surface 12ef to the light exit surface 12af. Consequently, the light exit surfaces 12af are larger than the corresponding light entry surfaces 12ef of the respective light guide element 12.
It is advantageous if the surface 16 is a plane and thereby allows a particularly simple construction of the primary optics 11. Moreover, it is advantageous if the light exit surfaces of all light guide elements 12a, 12b, which are assigned to the same light module 4a, 4b, form a common light exit surface and all light guide elements of the first light module 4a are structurally separated from those of the second light module 4b to provide coupling between to reduce both light modules 4a and 4b. For a high efficiency of the additional headlight 3, this is very important, since the generated light emission is to be transformed as lossless as possible in the desired light distribution.
The primary optic 11 may be made from an elastic (e.g., silicone, photopolymer, etc.) or solid (e.g., polycarbonate, thermoplastics, photopolymers, glass, etc.) material, and the particular choice may be determined by commercial requirements. The primary optics are produced particularly simply by an injection molding process.
3a shows the additional headlight 3 with a holder 17 for the mechanical fastening of the light modules 4a and 4b in the auxiliary headlight 3, without mounted aperture and without imaging optics 5. In detail B in Fig. 3b is the position of the first light module 4a for generating the linear intensity maximum 8a through the associated light guide elements 12a ', 12a "and of the second light module 4b for generating the rectangular shaped intensity maximum 8b through the associated light guide elements 12b', 12b", 12b '"in the light distribution.
In addition, an axis of rotation D is shown, about which the auxiliary headlight 3 is mechanically pivotable in order to enable tracking of the generated light distributions 9 following the course of the road. A second axis of rotation for pivoting about a further, for example, horizontal axis is not shown. The holder 17 is embodied here in one piece in order to fix the light guiding elements of the primary optics 11. Consequently, only a common attachment is necessary and design, manufacture, assembly, etc. are simplified.
In Fig. 4a and Fig. 4b respectively the light modules 4a and 4b and the two-part primary optics 11 are shown, which is held with a holder 17 in position. The
Holder can be made of an elastic or solid material, wherein structural reinforcements are advantageous only in the area around the light guide elements 12 and the edge region of the holder 17 in order to keep the weight of the holder 17 as low as possible. The light sources 10 themselves are usually held by a printed circuit board (not shown).
Fig. 5 shows the light module 4a, 4b in front view with mounted aperture 13, which has two apertures 13a, 13b, in addition to the light guide elements 12 to form the light emission 9a, 9b. By the aperture 13 particularly sharp contours are pronounced in the light distribution, which is essential, for example, for the line projection and their visibility through good contrast. The common panel 13 allows, among other things, a cost-effective and simple design, manufacture or assembly and supports the compact and lightweight design of the additional headlamp. The panel 13 is fixed by one or more mounting points 22 in the auxiliary headlight 3, wherein the mounting points 22 are particularly advantageously designed as holes through which screws connect the panel with another part of the auxiliary headlight 3. As an alternative to screws, connectors, rivets or the like are possible. On the other hand, for example, an adhesive connection technique is suitable to achieve a compact and lightweight design. In the present example, the holder 17 is designed such that it has at the positions of the screw recesses to support a common attachment by the aforementioned screws of panel 13 with a housing of the auxiliary headlight 3 with intermediate bracket 17, wherein the screws, the aperture 13 connect to the housing of the auxiliary headlight 3 and a cooling device 18 may be part of the housing. The assembly thus proves to be particularly easy and fast, also the number of components required for the auxiliary headlight 3 is kept minimal. The use of four screws is advantageous, this is achieved by a special stability and freedom from distortion by mechanical or thermal loading forces. Screws as a detachable connection have particularly favorable properties in terms of maintenance. Furthermore, the structure is particularly simple if in the composite of aperture 13, holder 17 and housing of the auxiliary headlight 3, a circuit board 21 (not shown) is inserted, which comprises at least a plurality of light sources 10 and is fixed by the same attachment, wherein the circuit board 21 and The light sources 10 arranged thereon are thermally well connected to the housing.
Fig. 6 shows the light module 4a, 4b in the perspective view with mounted aperture.
Fig. 7 shows the very compact auxiliary headlight 3 in the front view, on which the imaging optics 5 is placed. It is the axis of rotation D to see the auxiliary headlight 3 can be mechanically pivoted.
FIG. 8 shows the additional headlight 3 in the rear view with the common cooling device 18 for the light module 4a, 4b located on the rear side. With selective use of line light and additional high beam, preferably depending on the speed of the vehicle, the common cooling device 18 can be made small, lightweight and inexpensive. The auxiliary headlight 3 is pivotable about the axis of rotation D. Not shown is the common control unit 19, which electrically controls the two light modules 4a and 4b. The common control unit 19 achieves cost and weight advantages.
Fig. 9 shows the auxiliary headlight 3 in the exploded view with imaging optics 5 and holder 17 and circuit board 21 with light sources 4 (not shown). The bracket 17 may be made of an elastic or rigid material. Due to the common support 17 for the two-part primary optics 11 a simple construction or assembly is supported, and achieved a compact design of auxiliary headlamp. In addition to the light sources 10, the printed circuit board 21 can usually comprise further electronic circuits, such as driver and logic stages for switching the light sources 10 or the control unit 19, as well as connection units for connection to cables for control and power supply. Advantageously, the common design of the connection units for both light modules to keep the wiring harness in the vehicle easy. The circuit board 21 may be configured to support a suitable thermal connection between light sources 10 and cooling device 18, for example through openings in the circuit board 21. In many cases, the optical emission surface of the light source 10 is equipped with special cooling contacts to allow a convenient connection to a heat sink. The cooling by the cooling device 18 can be active, i. be executed by a fan for air cooling or liquid cooling, in the present example, the cooling device 18 is a passive heat sink.
Figures 10 to 27 show Cartesian images with angle scales on both axes according to the UNECE guidelines for uniform conditions for the approval of motorcycle headlamps (e.g., TRANS / WP.29 / 343) representing isolux lines for different intensities.
Fig. 10 shows the photograph of the left auxiliary headlamp with its first light distribution 7a 'and its first, line-shaped intensity maximum 8a', i. a line light distribution.
Fig. 11 shows the photograph of the right auxiliary headlamp with its first light distribution 7a "and its first, line-shaped intensity maximum 8a", i. a line light distribution.
Fig. 12 shows the photograph of the left auxiliary headlamp with its second light distribution 7b 'and its second, substantially rectangular intensity maximum 8b', i. an additional high-beam light distribution. The substantially rectangular intensity maximum can be, for example, square, rectangular, trapezoidal or even elliptical and have pointed or rounded corners. Special forms of the intensity maximum are also conceivable in order to obtain the best possible light distribution depending on the traffic situation. Likewise, a dynamic form of the intensity maximum, which is actively adapted for example by the respective traffic situation, is possible. This dynamic adaptation can mean the targeted switching off of individual areas within the intensity maximum, in order to obtain a glare-free high beam and to selectively block the oncoming traffic.
Fig. 13 shows the photograph of the right auxiliary headlamp with its second light distribution 7b "and its second, substantially rectangular intensity maximum 8b", i. an additional high-beam light distribution.
In Fig. 14, the light distribution of the low beam of the left main headlamp is shown with a typical asymmetry in the cut-off line.
Fig. 15 shows the photograph of the left auxiliary headlamp with the line-shaped light distribution of Fig. 10, which is superimposed on the low beam light distribution of the left main headlamp of FIG. 14.
Fig. 16 shows the photograph of the right auxiliary headlight with the linear light distribution of FIG. 11, which is superimposed on the low beam light distribution of the right main headlamp.
17 shows the superimposed overall light image of the left and right auxiliary headlamps with line-shaped intensity maxima in the respective light distribution, as well as of the left and right main headlamps, each with a low-beam light distribution.
FIG. 18 illustrates the total light distribution according to FIG. 17 as a light image by projection onto the roadway in front of the vehicle. Compared to the aforementioned light images, the projection view contains the perspective image distortions.
In Fig. 19, the high beam light distribution of the left main headlamp is shown.
In Fig. 20, the high beam light distribution of the right main headlamp is shown.
Fig. 21 shows the high beam light distribution of the left main headlamp together with the additional high beam light distribution of the left auxiliary headlamp.
Fig. 22 shows the high beam light distribution of the right main headlamp together with the additional high beam light distribution of the right auxiliary headlamp.
FIG. 23 shows the total light distribution according to FIG. 22 as a light image by projection onto the road ahead of the vehicle.
Fig. 24 shows the high beam light distribution of the left main headlamp together with the additional high beam light distribution and the line light distribution of the left auxiliary headlamp.
Fig. 25 shows the high beam light distribution of the right main headlamp together with the additional high beam light distribution and the line light distribution of the right auxiliary headlamp.
Fig. 26 shows the superimposed total light distribution of the left and right auxiliary headlamp with line intensity maxima in the respective light distribution together with the respective additional high-beam light distribution, and the left and right main headlamp, each with a high-beam light distribution.
FIG. 27 illustrates the total light distribution according to FIG. 26 as a light image by projection onto the road ahead of the vehicle.

权利要求:
Claims (23)
[1]
claims
Auxiliary headlight (3) for a vehicle, which is adapted to generate a light image (6) in front of the vehicle (1) by emitting light from at least one light module (4) and by a downstream imaging optics (5) in front of the vehicle to project, characterized in that a first light module (4a) is adapted to produce a first light image (6a) having at least a first light distribution (7a) with at least a first, substantially vertically oriented, linear intensity maximum (8a), and a second light module (4b) is arranged to generate a second light image (6b) having a second light distribution (7b) with at least one second, substantially rectangular intensity maximum (8b), and the light images (6a, 6b) of both light modules ( 4a, 4b), wherein the first intensity maximum (8a) is located vertically below the second intensity maximum (8b).
[2]
Second auxiliary headlight (3) according to claim 1, characterized in that the long sides of the substantially rectangular intensity maximum (8b) are oriented horizontally.
[3]
3. auxiliary headlamp (3) according to claim 1 or 2, characterized in that the horizontal position of the first intensity maximum (8a) within the horizontal width of the second intensity maximum (8b).
[4]
4. auxiliary headlamp (3) according to one of claims 1 to 3, characterized in that the first intensity maximum (8a) and the second intensity maximum (8b) are separated by a vertical distance.
[5]
5. auxiliary headlamp (3) according to one of claims 1 to 4, characterized in that the first light image (6a) and / or the second light image (6b) is projected.
[6]
6. auxiliary headlight (3) according to one of claims 1 to 5, characterized in that the auxiliary headlight (3) comprises: at least a first light module (4a) for generating a first light emission (9a) by at least one first light source (10a), at least a second light module (4b) for generating a second light emission (9b) by at least one second light source (10b), at least one primary optic (11), wherein the primary optics has a plurality of light guide elements (12) and each light guide element (12) has a light entry surface (12) 12ef) for coupling in a light emission (9a, 9b) and a light exit surface (12af), the first light emission (9a) coupling into at least one first light guide element (12a) of the primary optic (11), the second light emission (9b) in at least a second light guide element (12b) of the primary optics (11) coupled, at least one of the primary optics (11) downstream aperture (13) with at least a first diaphragm nöffnung (13 a), which faces the light exit surface of the first light guide member (12 a) and at least a second aperture (13 b) which faces the light exit surface of the second light guide element (12 b), wherein the primary optics (11) and the diaphragm (13) a Generate overall light image (14) from the light emissions (9a, 9b) and one of the diaphragm (13) downstream imaging optics (5) the total light image (14) as a light image (6) in the emission direction of the auxiliary headlamp (3) as a total light image (15).
[7]
7. auxiliary headlamp (3) according to claim 6, characterized in that the light exit surfaces (12af) of all the light guide elements (12) lie in a surface (16).
[8]
8. auxiliary headlamp (3) according to claim 6 or 7, characterized in that the surface (16) is a plane.
[9]
9. auxiliary headlight (3) according to any one of claims 6 to 8, characterized in that the light exit surfaces (12af) of all the light guide elements (12) associated with the same light module (4a, 4b) form a common light exit surface (12af).
[10]
10. auxiliary headlamp (3) according to one of claims 6 to 9, characterized in that the light guide elements (12) of the first light module (4a) of those of the second light module (4b), are structurally separated.
[11]
11. auxiliary headlamp (3) according to one of claims 6 to 10, characterized in that for all the light guide elements (12) has a common support (17) is provided.
[12]
12. auxiliary headlight (3) according to one of claims 6 to 11, characterized in that the first light module (4a) comprises a plurality of light sources (10a ', 10a "), which are arranged substantially vertically in a row one above the other.
[13]
13. auxiliary headlight (3) according to one of claims 6 to 12, characterized in that the second light module (4b) comprises a plurality of light sources (10b, 10b ', 10b "), which are arranged substantially horizontally in a row next to each other.
[14]
14. auxiliary headlamp (3) according to one of claims 6 to 13, characterized in that the first light module (4a) is arranged vertically above the second light module (4b).
[15]
15. auxiliary headlight (3) according to one of claims 6 to 14, characterized in that the apertures (13a, 13b) of the diaphragm (13) are substantially linear and / or rectangular.
[16]
16. auxiliary headlight (3) according to one of claims 6 to 15, characterized in that the first light module (4a) and the second light module (4b) on a common cooling device (18) are arranged.
[17]
17. auxiliary headlight (3) according to one of claims 6 to 16, characterized in that the first light module (4a) and the second light module (4b) are driven by a common control device (19).
[18]
18. auxiliary headlight (3) according to one of claims 6 to 17, characterized in that the auxiliary headlight (3) about at least one axis (D) is pivotable.
[19]
19. auxiliary headlight (3) according to one of claims 6 to 18, characterized in that the light sources (10a, 10b) are LEDs.
[20]
20. Headlight system (20) according to one of claims 1 to 19, characterized in that the headlight system (20) comprises at least one headlight (2) and at least one auxiliary headlight (3) and the light image (6) of the auxiliary headlight (3) at least from another light image (6a) of the main headlamp (2) is superimposed.
[21]
21. A headlamp system (20) according to claim 20, characterized in that a vehicle (1) comprises a left and a right auxiliary headlight (3,3 ') and a left and a right headlight (2,2').
[22]
22 headlamp system (20) according to claim 20 or 21, characterized in that the left and right auxiliary headlamps (3, 3 ') each different light images (6', 6 ") projects.
[23]
23. headlamp system (20) according to any one of claims 20 to 22, characterized in that the light distribution of the main headlamp (2) is a light distribution of a high beam or a low beam.

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公开号 | 公开日

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AT518098B1|2017-11-15|

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JP6526340B2|2019-06-05|

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WO2017100812A1|2017-06-22|

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CN108368986A|2018-08-03|

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EP3390899A1|2018-10-24|

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JP2018537356A|2018-12-20|

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US20180370419A1|2018-12-27|

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CN108368986B|2020-10-16|

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EP3390899B1|2021-03-31|

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US10632901B2|2020-04-28|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE102014203313A1|2014-02-25|2015-08-27|Volkswagen Aktiengesellschaft|Lighting device for a motor vehicle|

---

WO2015133302A1|2014-03-03|2015-09-11|株式会社小糸製作所|Vehicle lamp and vehicle lamp control system|CN110736070A|2018-07-19|2020-01-31|嘉兴海拉灯具有限公司|kinds of car light modules and kinds of car lights|US20060023461A1|2002-01-14|2006-02-02|Richard Knight|Vehicular dynamic angle adjusted lighting|

---

JP4535965B2|2005-08-16|2010-09-01|株式会社小糸製作所|Vehicle lighting|

---

US20110096562A1|2008-03-26|2011-04-28|Lambert Chad D|Fog Lamp and the Like Employing Semiconductor Light Sources|

---

US8475019B2|2008-05-01|2013-07-02|Magna International Inc.|Hotspot cutoff D-optic|

---

DE102008048764A1|2008-09-24|2010-03-25|Hella Kgaa Hueck & Co.|Lighting device for motor vehicle for producing e.g. signal functions, has light conducting segments comprising two flat sides for total reflection of incoming light, and two narrow sides on light coupling and decoupling sides, respectively|

---

DE102009009472B4|2009-02-19|2021-12-30|Volkswagen Aktiengesellschaft|Method for supporting a driver of a vehicle and driver assistance system for a vehicle|

---

DE102011118274A1|2010-12-03|2012-07-26|Docter Optics Gmbh|Headlight lens for a vehicle headlight|

---

JP5659835B2|2011-02-08|2015-01-28|スタンレー電気株式会社|Vehicle lighting|

---

DE102011077636A1|2011-04-27|2011-11-03|Automotive Lighting Reutlingen Gmbh|Light module for head lamp system of motor vehicle i.e. motor car, has sub modules separately controlled to generate set of strip-shaped segments of spot distribution, where strip-shaped segments are complement to spot distribution|

---

JP5719697B2|2011-06-10|2015-05-20|株式会社小糸製作所|Vehicle headlamp device|

---

EP3056385B1|2011-09-01|2018-06-06|Koito Manufacturing Co., Ltd.|Automotive headlamp apparatus|

---

AT512246B1|2011-11-22|2014-02-15|Zizala Lichtsysteme Gmbh|LED PROJECTION MODULE AND HEADLIGHTS WITH MODULE|

---

US9033562B2|2011-12-27|2015-05-19|Ichikoh Industries, Ltd.|Vehicle headlamp|

---

AT512864B1|2012-05-09|2014-12-15|Zizala Lichtsysteme Gmbh|Lighting device for generating a segmented light distribution and motor vehicle headlights and headlamp system|

---

DE102013200442B3|2013-01-15|2014-02-13|Automotive Lighting Reutlingen Gmbh|Light module for a motor vehicle headlight, which is set up to generate strip-shaped light distributions|

---

FR3006421B1|2013-05-30|2017-08-11|Valeo Vision|LIGHTING MODULE FOR MOTOR VEHICLE PROJECTOR, PROJECTOR EQUIPPED WITH SUCH MODULES, AND PROJECTOR ASSEMBLY|

---

AT514967B1|2013-10-25|2015-08-15|Zizala Lichtsysteme Gmbh|Microprojection light module for a motor vehicle headlight|

---

JP6796764B2|2016-09-13|2020-12-09|パナソニックＩｐマネジメント株式会社|Mounting base, light emitting device, lighting device for moving body and moving body|DE102016109147A1|2016-05-18|2017-11-23|Hella Kgaa Hueck & Co.|Headlamp module with a dipped beam function and with a high beam function based on LEDs|

---

US10816156B2|2017-02-14|2020-10-27|Everlight Electronics Co., Ltd.|Light guiding element, light guiding device, and lighting module|

---

EP3677829A4|2017-10-10|2020-10-14|Great Wall Motor Company Limited|Primary lens, light-emitting assembly, light-emitting system, and headlight|

---

FR3073925B1|2017-11-20|2020-11-13|Valeo Vision|OPTICAL ELEMENT FOR AUTOMOTIVE VEHICLE OPTICAL MODULE|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

---

ATA51074/2015A|AT518098B1|2015-12-17|2015-12-17|Additional headlights for vehicles and headlight system|ATA51074/2015A| AT518098B1|2015-12-17|2015-12-17|Additional headlights for vehicles and headlight system|

---

PCT/AT2016/060121| WO2017100812A1|2015-12-17|2016-12-09|Additional headlamp for vehicles|

---

EP16819419.9A| EP3390899B1|2015-12-17|2016-12-09|Additional headlamp for vehicles|

---

CN201680074155.7A| CN108368986B|2015-12-17|2016-12-09|Auxiliary headlight for a vehicle|

---

JP2018531410A| JP6526340B2|2015-12-17|2016-12-09|Additional floodlight for vehicles|

---

US16/061,816| US10632901B2|2015-12-17|2016-12-09|Additional headlamp for vehicles|