• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A headlight for motor vehicles, with at least one light source (1) whose light is directed to at least one light-processing element (7) and projected by the latter via an imaging optical system (9) as a light image (10) on the road (11), wherein the light-processing element a LCoS chip is to which a drive circuit (12) is assigned, wherein the pixel fields of the LCoS chip (7) in adaptation to the desired light image (10) have different geometry and / or dimension.
    公开号:AT517306A1
    申请号:T50477/2015
    申请日:2015-06-10
    公开日:2016-12-15
    发明作者:Michael Riesenhuber;Gerald Böhm
    申请人:Zkw Group Gmbh;
    IPC主号:
    专利说明:

    Headlight for motor vehicles
    The invention relates to a headlamp for motor vehicles, with at least one light source whose light is directed to at least one light-processing element and projected by this via an imaging optics as a light image on the road, wherein the light-processing element is a LCoS chip, which is associated with a drive circuit ,
    In the development of the current headlamp systems is increasingly the desire in the foreground to project as detailed as possible photo on the road, which can be quickly changed and adapted to the respective traffic, road and lighting conditions. The term "carriageway" 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 here corresponds to a projection on a vertical Area in accordance with the relevant standards relating to automotive lighting technology.
    According to the aforementioned need, different headlamp systems have been developed, of which the following are by way of example.
    Systems which project the light of a large number of LEDs via projection systems with individual lenses as a light image onto the roadway, wherein the brightness of the individual LEDs, which are controlled by a central processing unit, can be individually set or changed. See, for example, Applicant's Pixel-lite ™ Headlamp Systems, et al. in AT 513.738 Bl.
    Other headlamp systems operate with scanning, modulated laser beams, wherein the lighting starting point is at least one laser light source emitting a laser beam and associated with a laser driver used for power supply and monitoring the laser emission or e.g. is used for temperature control and is also set up to modulate the intensity of the emitted laser beam. By "modulating" it is to be understood that the intensity of the laser light source can be changed, be it pulsed continuously or in the sense of switching on and off. It is essential that the light output can be changed dynamically analogously, depending on which angular position a mirror deflecting the laser beam is. In addition, there is the possibility of switching on and off for a certain amount of time, in order not to illuminate or hide defined places. An example of a dynamic drive concept for generating an image by a scanning laser beam is described, for example, in the Applicant's document AT 514.633 B1.
    The headlight systems mentioned are sometimes very complex and expensive, so that there is a desire to create economical headlights, which nevertheless have a high flexibility with regard to the generated light image. In this sense, it has become known to use as light processing elements imagers having a large number of controllable pixel fields. Thus, DE 10 2013 215 374 A1 shows solutions in which the light of a light source is directed via a so-called "taper", a conical light-guiding element, to an LCD imager, to an LCoS chip or to a micromirror arrangement, in order then to pass over one Projection optics to be projected onto the roadway LCoS is a common acronym that stands for "Liquid Crystal on Silicon". These are chips with diagonals of e.g. 20 to 40 mm in length, which are constructed similar to an LCD screen, but have a segmented pixel structure, each pixel can be controlled and reflected or non-reflected depending on the control voltage. In order to give the best effect of the LCoS chip, it is necessary that the used light be polarized. The technology of chip design and control is well known and is currently used for projectors that can be built with very small dimensions.
    In turn, the chip driver receives signals from a central processing unit to which various sensor signals may be applied, e.g. Switching commands for switching from high beam to dipped beam or signals that are recorded, for example, by sensors, such as cameras, which detect the lighting conditions, environmental conditions and / or objects on the road. The signals can also originate from vehicle-vehicle communication information, which on the one hand has to comply with legal specifications for the projected photograph and, on the other hand, can be adapted to the respective driving situation.
    The invention is based on a headlamp of the initially cited type, which thus uses an LCoS.
    It is an object of the invention to provide a headlamp, which has a higher flexibility in the design of the light image, as the known solutions, yet a low-cost production should be possible and only one or a few individual light sources are required.
    This object is achieved with a headlamp of the type mentioned, in which according to the invention the pixel fields of the LCoS chip have different geometry and / or dimension in adaptation to the desired light image.
    The solution according to the invention not only provides an economically achievable realization of the task but also allows by appropriate design of the LCoS chip individual formations of the individual pixels. Furthermore, compared to most other known systems, a very high resolution can be achieved despite simple electronic control. Also, a headlight range adjustment without mechanical parts can be realized.
    It is advantageous if the pixel fields for the high-beam region of the light image are smaller than the remaining pixel fields, since a higher resolution is desired or required, especially in the high-beam range.
    It is also advantageous if the pixel fields for the high-beam region of the light image are formed as standing rectangles
    In an expedient development, the pixel fields for the apron of the light image can be square and have a larger area than the pixel fields for the high beam area
    In an expedient variant, it is provided that at least one row of diamond-shaped pixel fields is arranged between the pixel fields for the high beam area and the pixel fields for the apron.
    A further useful training is characterized in that between the pixel fields for the high beam area and the pixel fields for the apron an array of pixel fields is arranged whose area is not larger than the area of the adjacent pixel fields for the high beam area and / or the apron.
    It may also be advantageous if the pixel fields S are formed for at least one edge area of the light image with a smaller area than the pixel fields for the high beam area and / or the pixel fields for the apron.
    In another expedient variant, it is provided that the pixel fields have a convexly curved boundary on their outer edge for at least one edge region of the light image. For the realization of the invention it is particularly expedient if the light source is followed by a first polarizer, which divides the light beam of the light source into two beam paths, wherein a first beam path is directed directly to the LCoS chip and a second beam path via a depolarizer and a Mirror device is also directed to the LCoS chip and between the LCoS chip and the imaging optics, a second polarizer is provided. In this case, the depolarizer may have a liquid crystal layer.
    Another particularly useful embodiment for realizing provides that the light source is followed by a first polarization splitter, which splits the light beam of the light source into two beam paths, with a first beam path directed to a first LCoS chip and a second beam path to a second LCoS chip and a second polarization splitter is disposed in front of the imaging optics to combine the first and second beam paths.
    In this case, it is often advantageous if the second beam path is deflected via a mirror device, which is located before and / or after the LCoS chip.
    The invention together with further advantages is explained in more detail below by way of example embodiments, which are illustrated in the drawing. In this shows
    1 shows the essential components of the invention for a headlamp according to the invention with an LCoS chip,
    2 shows an embodiment of the invention in a schematic representation with respect to FIG. 1, with emphasis on the components important for a preferred beam path, FIG.
    3 shows a further embodiment of the invention in a representation corresponding to FIG. 2,
    4 shows a first example of an inventive design of the pixel fields of an LCoS chip to form a desired light distribution,
    5, 6 and 7 show further examples of the design of the pixel arrays of an LCoS chip according to the invention to form a desired light distribution.
    Fig. 8 and 9 in each case six individual representations under the control according to the invention designed pixel fields for generating a cornering light to the left or right pan and
    10 shows the design of the pixel fields of an LCoS chip according to the invention for forming a sliding light range.
    With reference to Fig. 1, an embodiment of the invention will now be explained in more detail. In particular, the important parts for a headlight according to the invention are shown, it being understood that a motor vehicle headlamp contains many other parts that allow its meaningful use in a motor vehicle, in particular a car or motorcycle. Lighting starting point of the headlamp is a light source 1, which emits a light beam 2, and which is associated with a driver 3, said driver 3 for powering the light source 1 and for monitoring or e.g. serves for temperature control and can also be configured to modulate the intensity of the radiated light beam. By "modulating" in the context of the present invention is meant that the intensity of the light source can be changed, whether continuous or pulsed, in the sense of switching on and off. In addition, there is the possibility of switching on and off for a certain time. In this case, LED light sources are preferably used, which can be operated with high currents - one speaks of "high power LEDs" - to achieve the highest possible luminous flux and thus the highest possible luminance on a LCoS chip Light source 1 is designated Us.
    The control 3 in turn receives signals from the central processing unit 4, which sensor signals sl ... si ... sn can be supplied. These signals can on the one hand, for example, switching commands to switch from high beam to low beam or on the other hand, signals that are taken, for example, from sensors such as cameras, which conditions the lighting conditions, Umweltbe conditions and / or objects on the road. Also, the signals may originate from vehicle-vehicle communication information. The arithmetic unit 4 drawn here schematically as a block can be contained completely or partially in the headlight, wherein the arithmetic unit 4 is also assigned a memory unit 5.
    The light source 1 may be arranged downstream of an optics 6, the formation of which depends inter alia on the type, number and spatial placement of the lamps used, such as laser diodes or LEDs and the required beam quality, and which should ensure, above all, that of the Light emitted light hits as homogeneously as possible on the optically active surface of a LCoS chip 7.
    The focused or shaped light beam 2 now passes to this LCoS chip 7, on which by appropriate control of the individual pixel fields, a light image 8 is formed, which can be projected via an imaging optics 9 as a light image 10 on a street 11. The arithmetic unit 4 supplies signals sa to a chip driver 12 which controls the individual pixels, i. Pixel fields of the array 7 in the manner corresponding to the desired light image. Certain light / light images can be stored in the memory unit 5. The individual micromirrors of the array 7 can be individually controlled with regard to the frequency, the phase and the deflection angle.
    Although essential components are described in the illustration according to FIG. 1, it should be "clear that, for example, appropriate cooling means can be provided to prevent overheating of the LCoS chip, be it active means, such as fans, Peltier elements, etc. or passive, such as IR filters in the beam path.
    Before the particularly important design of the pixel fields according to the invention is explained, suitable beam paths or the components required for this purpose will be described with reference to two embodiments.
    2 shows schematically, without the details of FIG. 1, which of course also apply here, that the light source 1, a first polarizer 13 is arranged downstream, which divides the light beam 2 of the light source into two beam paths, wherein a first beam path 2- 1 is directed directly to the LCoS chip 7 and a second beam path 2-2 via a depolarizer and a mirror device, here three mirrors 16,17,18, is also directed to the LCoS chip and between the LCoS chip 7 and the Imaging optics 9, a second polarizer 19 is provided. This embodiment offers a particularly high photometric efficiency because of the formation of the second beam path 2-2. However, it should be emphasized that one could also omit this beam path and thus also the mirrors 16, 17 and 18 as well as the depolarizer 13, if such a high efficiency is not necessary.
    In Fig. 3, another variant is shown, which also contributes to increasing the efficiency, which is also working with two beam paths, but with two LCoS chips, so that one can speak of a doubling. For identical or comparable parts while the same reference numerals are used.
    The light beam 2 coming from the light source 1 or the optics 6 is split into two beam paths 2-a and 2-b in a first polarization splitter 20, wherein the first beam path 2-a reaches a first LCoS chip 7a and generates the same Illuminated image passes from this via a second polarization splitter 21 on the imaging optics 9 as a light image on a road (the photo and the road are not shown in Figs. 2 and 3, as already explained in Fig. 1).
    The second beam path 2-b passes through two deflecting mirrors 16 to a second LCoS chip 7b and from there through the second polarization splitter 21 and also passes through the imaging optics 9 as a light image of a road. In the case of synchronously driven LCoS chips, on the one hand the optical efficiency is approximately doubled on the other hand, and on the other hand, the heat load of the LCoS chips by incident light remains lower.
    4 shows a first example of an embodiment of the pixel fields of an LCoS chip, wherein these pixel fields have different sizes and geometries. It should be noted that in this example, for simplicity, not the entire width of the chip is shown. The arrangement corresponds to the light image generated by the LCoS chip, which is correspondingly enlarged enlarged as a light image projected onto the street.
    The two upper rows Fl, F2 of pixel fields serve to generate a high beam distribution, wherein in principle each pixel is rectangular and the pixels have the same size, except those of the left column, which are smaller, here approximately square. The total area of the pixel arrays Fl and F2 is the largest optically effective area of the LCoS chip.
    A row A below serves in this example, an asymmetric low-beam distribution, it consists here on five rhombs, which are bounded on the left and right of a smaller in the area triangle.
    The bottom row V of pixel fields is used for the apron lighting, wherein the pixel fields are rectangular and have the same size except for the last pixel field on the far right.
    FIG. 5 shows a further example of an embodiment of the pixel fields of an LCoS chip, an embodiment with corresponding control for producing a low-beam light distribution being shown, and hatched pixel fields mean light-connected, non-hatched pixel fields but dark-switched pixels and the hatched area underneath means a another light source produced apron lighting VF. Here, an upper row AO of pixel fields consists of standing rectangles of equal size and geometry, an underlying row AM of diamonds of equal size and geometry, but with smaller area than the rectangles of the row AO, and a lowest row AU of squares of the same size and geometry Geometry with approximately the same area as the rhombs of the
    Series AM. In this and the following figures, therefore, the pixel fields are not shown as such but already in their projection as a light image 10, which, however, does not change the geometry of the pixel design.
    The illustration of FIG. 6 shows the same pixel field arrangement as FIG. 5, but here the pixel fields or the LCoS chip are driven to generate a Femlichtverteilung. Again, there is drawn from a different light source apron lighting.
    In a further variant, in a representation like FIGS. 5 and 6, FIG. 7 shows that in order to produce a "softer" outlet in certain edge areas, the corresponding pixel areas can be made smaller Rectangles are provided, but rectangles, which are followed by three or two relatively narrow strips S, which of course can be controlled individually as well as every other pixel field individually upper limit B graded, namely to the right or left edge down convex.
    It should be noted at this point that those pixel fields which are "responsible" for the high-beam range are preferably smaller than the remaining pixel fields Such a configuration is also shown in part in Fig. 7, in other figures the pixel fields The reason for smaller dimensions of the high beam pixel fields is the fact that in the high beam range usually a higher resolution is desired, especially since this area is subjected to a higher intensity and here also the furthest Farther objects naturally mean smaller areas to be hidden and therefore require the higher resolution.
    FIGS. 8 and 9 show, starting from a pixel configuration of FIGS. 5 and 6, how cornering light can be realized by correspondingly driving the pixel fields, wherein in FIGS. 8a to 8f a gradual swing to the left and correspondingly in FIGS. 9a to 9f, the corresponding activation process is shown in the case of a pivoting to the right-in the case of a corresponding impact of the steering wheel.
    Finally, there is shown in Fig. 10 yet another example of a pixel array design which may be considered as a variant of that of Fig. 4, where the row A of pixel fields is finer divided than the corresponding row of Fig. 4. More specifically, there are four Al series to A4 before, which have narrow strip-shaped pixel fields in the height direction, the strips, except those on the left and right edge, are diamond-shaped. The margins of the series Al to A4 are rudimentary, shortened available. Through this finer resolution you can achieve a sliding headlamp leveling, which is to be understood here as a substantially flowing increase or decrease in the beam range, thus a substantially stepless control of the headlamp range, as her known and used to a driver from conventional technology ago.
    权利要求:
    Claims (12)
    [1]
    claims
    1. Headlamp for motor vehicles, with at least one light source (1) whose light is directed to at least one light-processing element (7) and projected by the latter via an imaging optics (9) as a light image (10) on the road (11), wherein the light-processing element an LCoS chip is, to which a drive circuit (12) is assigned, characterized in that the pixel fields of the LCoS chip (7) in adaptation to the desired light image (10) have different geometry and / or dimension.
    [2]
    2. Headlight according to claim 1, characterized in that the pixel fields for the high beam region of the light image (10) are smaller than the remaining pixel fields
    [3]
    3. Headlight according to claim 1 or 2, characterized in that the pixel fields for the high beam region of the light image (10) are formed as standing rectangles
    [4]
    4. Headlight according to one of claims 1 to 3, characterized in that the pixel fields for the apron (V) of the light image (10) are square and have a larger area than the pixel fields for the high beam area (Fl, F2)
    [5]
    5. Headlight according to claim 1, characterized in that between the pixel fields for the high beam area (Fl, F2) and the pixel fields for the apron (V) at least one row (A, AM) diamond-shaped pixel fields is arranged.
    [6]
    6. Headlight according to one of claims 1 to 5, characterized in that between the pixel fields for the high beam area and the pixel fields for the apron an array (AM) of pixel fields is arranged whose area is not greater than the area of the adjacent pixel fields for the high beam area and / or the apron.
    [7]
    7. Headlight according to one of claims 1 to 6, characterized in that the pixel fields (S) for at least one edge region of the light image (10) are formed with a smaller area than the pixel fields for the high beam area and / or the pixel fields for the apron.
    [8]
    8. Headlight according to one of claims 1 to 7, characterized in that the pixel fields for at least one edge region of the light image (10) at its outer edge a convex curved boundary (B).
    [9]
    9. Headlight according to one of claims 1 to 8, characterized in that the light source (1) a first polarizer (13) is arranged downstream, which divides the light beam (2) of the light source into two beam paths (2-1, 2-2) wherein a first beam path is directed directly to the LCoS chip (7) and a second beam path is also directed via a depolarizer (14) and mirror means (16, 17, 18) to the LCoS chip and between the LCoS chip and the imaging optics (9), a second polarizer (19) is provided.
    [10]
    10. Headlight according to claim 9, characterized in that the depolarizer (14) comprises a liquid crystal layer.
    [11]
    11. Headlight according to claim 9, characterized in that the light source (1) a first polarization splitter (20) is arranged downstream, which the light beam (2) of the light source in two beam paths (2-a, 2-b), with a first Beam path (2-a) to a first LCoS chip (7a) and a second beam path (2-b) to a second LCoS chip (7b) is directed, and a second polarization splitter (21) arranged in front of the imaging optical system (9) is to unite the first and second beam path.
    [12]
    12. Headlight according to claim 11, characterized in that the second beam path (2-b) via a mirror device (16, 17) is deflected, which is located before and / or after the LCoS chip (7-b).
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    法律状态:
    2021-02-15| MM01| Lapse because of not paying annual fees|Effective date: 20200610 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50477/2015A|AT517306B1|2015-06-10|2015-06-10|Headlight for motor vehicles|ATA50477/2015A| AT517306B1|2015-06-10|2015-06-10|Headlight for motor vehicles|
    DE202016102988.0U| DE202016102988U1|2015-06-10|2016-06-03|Headlight for motor vehicles|
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