• 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 vehicle headlight (501) comprising a light source unit (502), a controllable reflector (590), an optically transparent cover (504), an optical absorber (505), an optical shading element (506), and projection optics (507). The light source unit (502) is adapted to emit light and illuminate in a first propagation direction (510), in the beam path of the controllable reflector (590) is arranged and the controllable reflector (590), the light in a second propagation direction (520) whose beam path the projection optics (507) is arranged and oriented in a direction in front of the vehicle, at least partially reflected, and to form a light image in front of the vehicle. The optically transparent cover (504) is arranged in a second plane (551) between the light source unit (502) and the controllable reflector (590) such that light in the first propagation direction (510) and in the second propagation direction (520) is optically transparent cover (504) penetrates. The light emitted from the light source unit (502) is incident on the optically transparent cover (504) in the first propagation direction (510) and partially reflected therefrom in a fourth propagation direction (540) and in the fourth propagation direction (540) of the optical shading element (506) blocked.
    公开号:AT519055A1
    申请号:T50791/2016
    申请日:2016-09-08
    公开日:2018-03-15
    发明作者:Reisinger Bettina;Pürstinger Josef;Danner Markus
    申请人:Zkw Group Gmbh;
    IPC主号:
    专利说明:

    Summary
    Vehicle headlight (501), comprising a light source unit (502), a controllable reflector (590), an optically transparent cover (504), an optical absorber device (505), an optical shading element (506) and projection optics (507). The light source unit (502) is designed to emit light and to light in a first direction of propagation (510), in the beam path of which the controllable reflector (590) is arranged and the controllable reflector (590) the light in a second direction of propagation (520), in whose beam path is arranged the projection optics (507) and is oriented in one direction in front of the vehicle, at least partially reflected, and to form a light image in front of the vehicle. The optically transparent cover (504) is arranged in a second plane (551) between the light source unit (502) and the controllable reflector (590) such that light in the first direction of propagation (510) and in the second direction of propagation (520) is optically transparent cover (504) penetrates. The light emitted by the light source unit (502) falls on the optically transparent cover (504) in the first propagation direction (510) and is partially reflected by it in a fourth propagation direction (540) and in the fourth propagation direction (540) by the optical shading element (506) blocked.
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    vehicle headlights
    The invention relates to a vehicle headlight, comprising at least one
    Light source unit, at least one controllable reflector, at least one optically transparent cover, at least one optical absorber device, at least one optical shading element, and at least one projection optics, the light source unit being set up to emit light and to light in a first direction of propagation, in the beam path of which the controllable reflector is arranged, and the controllable reflector at least partially reflects the light in a second direction of propagation, in the beam path of which the projection optics are arranged and oriented in a direction in front of the vehicle, in order to form a light image in front of the vehicle, the controllable reflector being an arrangement of a Variety of controllable
    Individual mirrors, the reflecting surfaces of which, in a non-tilted state, are arranged flat in a first plane and as a rectangular matrix of individual mirrors, the light emitted by the light source unit falling on the controllable reflector in the first direction of propagation and from this in a first activated state Direction of the second direction of propagation is reflected and / or in a second controlled state of the controllable reflector is reflected in a third direction of propagation, and the optically transparent cover, in a second plane between the
    Light source unit and the controllable reflector is arranged such that light in the first direction of propagation and in the second direction of propagation penetrates the optically transparent cover.
    In the development of the current headlight systems, the desire to be able to project a high-resolution, homogeneous light image onto the roadway is becoming more and more important. The term “roadway” is used here for a simplified illustration, because it depends of course on the local conditions whether a photograph is actually on the roadway or extends beyond it. In principle, the light image in the sense used here is based on a projection onto a vertical surface in accordance with the relevant standards that apply to the KFZ2 / 37
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    Obtain lighting technology, defined. Furthermore, the generated light image should be adaptable to different traffic situations.
    In order to meet the need mentioned, headlights have been developed in which a variably controllable reflector surface is formed from a plurality of micromirrors and a light emission, which is generated by a light source unit, is reflected in the radiation direction of the headlight on selected areas.
    Such lighting devices are advantageous in vehicle construction because of their very flexible lighting functions, since the illuminance can be regulated individually for different lighting areas and any lighting functions can be implemented with different light distributions, such as a low beam light distribution, a cornering light light distribution, a city light light distribution, a motorway light Light distribution, cornering light distribution, high beam light distribution, additional high beam light distribution or for the formation of glare-free high beam (also known as Adaptive Driving Beam Headlighting System, ADB).
    The so-called digital light processing (DLP®) projection technology is used for the micromirror arrangement, in which images are generated by modulating a digital image onto a light beam. In this case, a rectangular arrangement of movable micromirrors, also referred to as pixels, divides the light beam into partial areas and then reflects it pixel by pixel either into the projection path or out of the projection path. This technology is based on an electronic component that contains an arrangement of micromirrors in the form of a matrix of mirrors and their control technology and is referred to as a “digital micromirror device (DMD). A DMD microsystem is an area light modulator (Spatial Light Modulator, SLM), which consists of matrix-shaped micromirror actuators, that is tiltable reflecting surfaces, for example with an edge length of about 16 μm or even less. The mirror surfaces are designed in such a way that they can be moved by the action of electrostatic fields. Each micromirror can be individually adjusted in its tilt angle and usually has two stable end states, between which it is possible to switch up to 5000 times within a second. The individual micromirrors can each be controlled, for example, by pulse width modulation (PWM) in order to depict further states of the micromirrors, their time-averaged, in the main beam direction of the DMD arrangement
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    Reflectivity lies between the two stable states of the DMD. The number of mirrors corresponds to the resolution of the projected image, whereby a mirror can represent one or more pixels. DMD chips with high resolutions in the megapixel range are now available. The technology underlying the adjustable individual mirrors is the
    Micro-Electro-Mechanical-Systems (MEMS) technology.
    While the DMD technology has two stable mirror states, and the reflection factor can be set by modulation between the two stable states, the “Analog Micromirror Device (AMD) technology has the property that the individual mirrors can be set in variable mirror positions that there are in a stable state.
    If an electronic component using DLP® technology is used in a vehicle headlight, it may be necessary to protect the component against external influences such as moisture or dust. This can be done by an optically transparent cover in front of the DLP® component, which is made of glass or plastic, for example. Although such covers are often provided with a high-quality anti-reflective coating, some of the incident light is nevertheless reflected. Therefore, the surface of the optically transparent cover can lead to undesirable reflections, which can disturb the light image generated by the vehicle headlight and / or degrade the contrast in the light image on the road. Especially for ADB vehicle headlights, it is important to achieve the highest possible contrast ratio in order to enable a high light intensity in the illuminated areas and accordingly a good view for the driver of the vehicle and at the same time glare values in the hidden segments, such as those e.g. are regulated by the ECE R123, where, for example, a certain light intensity is set as the upper limit for a classC light distribution in the HV point, so as not to dazzle oncoming traffic and / or road users driving ahead.
    It is an object of the present invention to overcome the disadvantages mentioned.
    The object is achieved according to the invention by a vehicle headlight of the type mentioned at the outset in that the light emitted by the light source unit falls in the first direction of propagation onto and from the optically transparent cover
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    P15370 partially reflected in a fourth direction of propagation and in the fourth
    Direction of propagation is blocked by the optical shading element.
    The optically transparent cover can cause disturbing reflections on the underside as well as on the top and can be reflected in the fourth direction of propagation.
    The solution according to the invention ensures that the light reflected or absorbed by the shading element is suppressed by the further light propagation in the direction of the second propagation direction in which the projection optics are located. This measure increases the contrast of the light image projected by the projection optics in front of the vehicle.
    It is particularly advantageous if an optical absorber device is located in the third direction of propagation, by means of which the light is converted into heat and a disruptive lighting effect within the vehicle headlight is prevented or reduced.
    As already mentioned, the controllable reflector with its arrangement of a plurality of controllable individual mirrors with their reflecting surfaces in the non-tilted state lies flat in the first level and the optically transparent cover lies in the second level.
    It is particularly advantageous if the second level is parallel to the first level, as a result of which a particularly simple arrangement can be created which offers cost and assembly advantages.
    Alternatively, it is also advantageous if the second plane lies at a third angle to the first plane, the third angle being larger than 0 ° and smaller than 15 °, preferably larger than 0 ° and smaller than 5 °. This improves the light image because the reflections can be further reduced by the optically transparent cover, in that the third angle ensures that the reflections are at least only partially directed in the second direction of propagation and only a smaller proportion by the optical shading element in the Photo must be suppressed.
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    If the third angle is greater than 0 °, it is advantageous if the projections in the first and fourth propagation directions overlap in such a way that the overlap is less than if the third angle is equal to 0 °. As a result, the shaded area in the projection in the first direction of propagation is significantly smaller and the imaging optics is thereby more efficient with the same imaging scale (corresponds to the width of the light distribution).
    Furthermore, it is advantageous if the shading element is arranged at least partially in the beam path of the second direction of propagation and in front of the projection optics, which enables the vehicle headlight to have a small design. In addition, only a small precision in the dimensions and the position of the shading element is required.
    Alternatively, it is particularly favorable if the shading element is arranged at least partially in the beam path of the second direction of propagation and after the projection optics. It can thereby be achieved that the shadowing and the associated optical reflections or thermal emissions are far from the optical
    Absorber device occur, which can be favorable for the distribution of the thermal losses.
    The shading element can be arranged in the form of a visual field diaphragm after the projection optics, since the visual field diaphragm limits the penetrating beam either at the location of the entrance or the exit of the visual field diaphragm. Both places are conjugated to each other, that is, they are linked with each other via the projection lens.
    It is particularly advantageous if the shading element is an aperture, which allows a particularly simple and inexpensive design.
    Alternatively, it is advantageous if the shading element is a further, additional optical absorber, that is to say a shading absorber, in particular if the shadowed light can be converted directly into heat at the shading element and the optical absorber device of the vehicle headlamp consequently does not additionally heat up. This ensures that the optical absorber device of the
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    Vehicle headlights dimensioned smaller and more cost-effective and consequently a smaller overall size of the headlamp can be achieved.
    The shading element or the shading absorber and the optical absorber device of the vehicle headlamp can, however, also be designed in one piece as a common component in order to keep the number of components to be mounted in a vehicle headlamp low and consequently the construction, assembly, service and component costs to be low hold.
    It is advantageous if the light emitted by the light source unit falls on the optically transparent cover in the first direction of propagation at a first angle, the first angle being in a range between 50 ° and 65 °, preferably between 55 ° and 60 °. This results in a particularly compact design in that the components used can be arranged closely next to one another.
    In a particularly advantageous embodiment of the invention, the light source unit can comprise at least one semiconductor light source, preferably a high-power LED, a high-current LED or a laser diode in conjunction with an optical converter (“phosphor”) and preferably primary optics in the form of an optical lens system to create a particularly inexpensive arrangement. Semiconductor light sources have, among other things, a particularly high degree of efficiency and consequently generate little waste heat, so that an associated cooling device can be implemented at low cost. The use of plasma-based light sources is also possible.
    The invention and its advantages are described in more detail below with reference to non-limiting exemplary embodiments, which are illustrated in the accompanying drawings. The drawings show in
    Figure 1 is a schematic perspective view of an arrangement of optical components for a vehicle headlight according to the prior art, which comprises a controllable reflector.
    2 shows a schematic representation of the functional principle of an arrangement in a first configuration, comprising a controllable reflector;
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    3 shows a schematic illustration of the functional principle of an arrangement in a second configuration, comprising a controllable reflector with an optically transparent cover in a first angular position;
    4 shows a schematic illustration of the functional principle of an arrangement in a third configuration, comprising a controllable reflector with an optically transparent cover in the first angular position;
    5 shows a schematic representation of the functional principle of an arrangement according to the invention;
    6 shows a schematic illustration of the functional principle of an arrangement in a fourth configuration, comprising a controllable reflector with an optically transparent cover in a first angular position;
    7 shows a schematic representation of the functional principle of an arrangement in a fifth configuration, comprising a controllable reflector with an optically transparent cover in a second angular position;
    8 shows an embodiment of a projection lens with a diaphragm;
    9a shows a light distribution as it is generated by a vehicle headlight in DLP® technology according to the prior art;
    9b shows an intensity distribution in section A-A according to FIG. 9a;
    10a shows a light distribution as it is generated by a vehicle headlight according to the invention;
    10b shows an intensity distribution in section B-B according to FIG. 10a.
    Exemplary embodiments of the invention will now be explained in more detail with reference to the figures. In particular, parts which are important for the invention are shown in a headlight, it being clear that a headlight also contains many other parts, not shown, which enable sensible use in a motor vehicle, such as in particular a car or motorcycle. For the sake of clarity, cooling devices for components, control electronics, further optical elements, mechanical adjustment devices or brackets are not shown, for example. In other exemplary embodiments, not shown, several of the components explained can be used within a headlight.
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    In the further descriptions, the term “different configurations” refers to the geometrical arrangement of different components with respect to dimensions, distances and angular positions.
    The term different “angular position of an optically transparent cover refers to the arrangement of a transparent cover in relation to a controllable reflector regarding dimensions, distances and angular positions.
    In the following description of the figures, reference is made to directions of propagation, it being clear that this means all light beam components of an emitted light, the optical axis of which runs in the respectively designated direction of propagation or also parallel to it.
    It is known to the person skilled in the art that the arrangements shown are sketched with ideally assumed dimensions, distances and angular positions, deviations from these having to be taken into account in a practical implementation. This also applies to the real course of light beam components, which can have deviations from the ideal, parallel course, which can be caused, for example, by the practical design of optical elements such as lenses or reflectors.
    The figures shown show individual embodiments of the invention, the embodiments shown not restricting the invention and its scope according to the appended claims. This also means that the individual embodiments shown can be combined with one another as desired and thereby form the subject matter of the scope of protection of the appended claims. For example, the embodiment according to FIG. 5 can be combined with that according to FIG. 6 and is also the subject of the scope of protection of the appended claims. The designs discussed for individual figures and their advantages therefore apply to all embodiments.
    In Fig. 1 is a perspective view of an arrangement of a schematic
    Vehicle headlights 101 shown in the prior art, the one
    Light source unit 102, primary optics 103, a controllable reflector 190, which in one
    Electronics housing 100 is housed, an optically transparent cover 104, an optical absorber device 105 and a projection optics 107,107a.
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    The light source unit 102 includes a light source that emits light at least into the first
    Direction of propagation 110 emitted. The first direction of propagation 110 starts from the light source unit 102 or the light source contained therein
    Primary optics 103 to the controllable reflector 190, which has a variety of controllable ones
    Includes individual mirror 191.192. The controllable reflector 190 is connected to control electronics, which controls the controllable reflector 190 and is arranged, for example, in the electronics housing 100 and, in addition to the power supply, can also provide appropriate cooling of the controllable reflector 190. So that the controllable reflector 190 can modulate the light in accordance with its optical task, it projects through a recess from the electronics housing 100 and is thus accessible to the further optical components in order to interact with them.
    The primary optics 103 and the projection optics 107, 107a can be designed in several parts or in several stages in order to be adapted to the respective imaging requirements. In addition, the primary optics 103 can be part of the light source unit 102, for example in order to use a common assembly device or to be easier to adjust. Alternatively, the primary optics can be designed as a beam-shaping mirror system. In other words, it is also possible that the first direction of propagation does not lead straight from a light source unit through optical lenses of a primary optics to a controllable reflector. For example, the light can be redirected via a curved mirror.
    In a first activated state, the controllable reflector 190 is set up to at least partially deflect the light into a second direction of propagation 120, in which an imaging or projection optics 107 is arranged. The projection optics 107 is set up to form a light image in front of a vehicle.
    In a second activated state of the controllable reflector 190, light can be reflected in a third direction of propagation 130, in which an optical absorber device 105 is located.
    2 is a schematic representation of the functional principle of an arrangement of a
    Vehicle headlights 201 according to the prior art in a first configuration
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    P15370 shown, which essentially corresponds to the arrangement of FIG. 1 and is shown in a detailed side view.
    A light source unit 202 is set up to emit light, a significant proportion of the light emitted by the light source unit 201 being directed as a light beam in a first direction of propagation 210 in which a controllable reflector 290 is arranged. A primary optics 203 in the form of a lens system is arranged between the light source unit 202 and the controllable reflector 290, which is suitable for focusing the light in the plane 250 of the controllable reflector; for the sake of simplicity, largely parallel light rays are shown in the figures, to radiate and consequently the controllable reflector 290 to be illuminated uniformly, and the light-emitting surface of the light source unit 202 is located in the focus of the primary optics 203. For example, semiconductor light sources in the form of LEDs can be used as the light source of the light source unit 202. For example, the geometric center of the light-emitting surface of the LED can be arranged in the focal point of the primary optics 203. The primary optics 203 are often already integrated in an LED component and the LED component can illuminate the controllable reflector 290 largely uniformly. The lens system can consist of collecting and / or diverging lenses.
    The emitted light is represented by two first light beams 211, 212, which form beam parts of the light directed in the first propagation direction 210. The first two light beams 211, 212 are parallel to one another. The first direction of propagation 210 extends from the light source unit 202 through the primary optics 203 to the controllable reflector, in which two controllable individual mirrors 291, 292 are shown as examples.
    The controllable reflector 290 at least partially reflects the light in a second direction of propagation 220, in which an imaging or projection optics 207 is arranged. The projection optics 207 is set up to form a light image in front of the vehicle.
    The controllable reflector 290 comprises an arrangement with a plurality of controllable ones
    Individual mirrors 291, 292, the reflective surfaces of which are not tilted
    Basic position together form a first plane 250 and are arranged, for example, as a rectangular matrix of individual mirrors 291, 292.
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    The light emitted by the light source unit 202 falls in the first
    Direction of propagation 210 at a first angle a2 onto the controllable reflector 290 or its individual mirror 291, 292 and is reflected by the latter at the surface normal 260 of the mirror surface of the individual mirror 291 in a first activated state in the direction of the second direction of propagation 220. In a second activated state of the controllable reflector 292, the light is reflected at the surface normal 261 of the mirror surface of the individual mirrors 292 at a second angle β2 in a third direction of propagation 230, in which an optical absorber device 205 is located.
    Accordingly, the angle a2 corresponds to an angle of the incident light beam with respect to the controllable reflector 290 or the plane 250. The angle β2 corresponds to an angle of the reflected light beam of the controllable reflector 290 in a fading-out state of the controllable reflector 290 or the individual mirror 292 with respect to the plane 250.
    A non-tilted basic position of an individual mirror is understood to mean that stable state in which the individual mirror does not experience any deflection with respect to its axis of rotation and thus assumes a neutral position. Consequently, in this state the mirror surfaces of all the individual mirrors together form the plane 250. Usually, this state can only be achieved in a configuration of a DMD chip if there is no actuation or if there is no operating or control voltage on the DMD chip or on the individual mirrors.
    In addition, each individual mirror has two further stable states, which correspond to the end positions of the pivoting of the individual mirrors and, for example, can be pivoted to an angle of + 12 ° and -12 °, starting from the non-tilted state. It is clear that the end positions do not have to be the maximum possible pivoting of the individual mirrors, but rather those positions of the individual mirrors in which a stable state of the mirror can be achieved in a pivoted position. Consequently, the two stable states serve primarily to switch the direction of reflection of an incident light beam between two defined directions and preferably to achieve either radiation or absorption of the light in these two directions. The described tilting can be implemented with a DMD as well as with an AMD.
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    FIG. 3 shows a schematic representation of the functional principle of an arrangement of a vehicle headlight 301 according to the prior art in a second configuration, which corresponds to a further development of the arrangement according to FIG. 1 or FIG. 2 and a controllable reflector 390 with an optically transparent cover 304 in a first angular position in which the controllable reflector 390 and an optically transparent cover 304 are aligned parallel to one another.
    The optically transparent cover 304 can nevertheless reflect incident light on its surface, even if the surface is provided with an anti-reflective coating, for example. An anti-reflective coating only reduces the amount of unwanted reflections, but there are residual reflections that can interfere with the light image of a vehicle headlight because they reduce the contrast. The optically transparent cover 304 can be made of an optically transparent glass or a plastic such as acrylic or polycarbonate, it being important for the material used to be highly translucent.
    The optically transparent cover 304 is arranged in a second plane 351, parallel to the first plane 350, between a light source unit 302 and the controllable reflector 390 such that light in a first propagation direction 310 and in a second propagation direction 320 can penetrate the optically transparent cover 304 ,
    In addition, light along a third direction of propagation 330 can penetrate the optically transparent cover 304 if light is directed in the direction of an optical absorber device 305.
    The light emitted by a light source unit 302 can be in the first
    If the direction of propagation 310 falls on the optically transparent cover 304 at the first angle a3, the surface thereof is partially reflected and parallel to the second direction of propagation 320 in a fourth direction of propagation 340.
    The statements of the preceding figures apply analogously to the remaining elements and representations of the vehicle headlight 301 shown.
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    The fourth direction of propagation 340 can be in the beam path of the imaging or
    Projection optics 307 be located and lead to unwanted scattered light which, like the light distribution generated by the arrangement, is projected in one direction in front of the vehicle and can form a photograph in front of the vehicle. The unwanted scattered light or its light image often reduces the contrast of the light image which is projected in the second direction of propagation 320, which undesirably impairs the light function of the vehicle.
    FIG. 4 shows a schematic representation of the functional principle of an arrangement of a vehicle headlight 401 according to the prior art in a third configuration, which represents an alternative variant of the arrangement according to FIG. 1, FIG. 2 or FIG. 3 and a controllable reflector 490 with a includes optically transparent cover 404 in the first angular position, in which controllable reflector 490 and optically transparent cover 404 are aligned parallel to one another.
    The controllable reflector 490 comprises an arrangement of a multiplicity of controllable individual mirrors 491, the reflecting surfaces of which, in a non-tilted state, are arranged flat in a first plane 450 and as a rectangular matrix of individual mirrors 491.
    The optically transparent cover 404 is between in a second plane 451
    The light source unit 402 and the controllable reflector 490 are arranged such that light in a first propagation direction 410 and in a second propagation direction 420 can penetrate the optically transparent cover 404.
    The statements of the preceding figures apply analogously to the remaining elements and representations of the vehicle headlight 401 shown.
    The first angular position of the optically transparent cover 404 is defined such that the first plane 450 is arranged parallel to the second plane 451.
    The third configuration is characterized in terms of its angle of incidence in that a first angle a4 with respect to the first plane 450 is less than the corresponding first one
    Angle a3 on the first plane 350 of the arrangement according to FIG. 3. By this choice of the first
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    Angle α4 can be achieved that no or at least significantly less light in the fourth direction of propagation 440 in the optical region of the projection optics 407 and no disturbing stray light is generated that would be undesirable in the light image in front of the vehicle.
    However, this third configuration has the disadvantage that the efficiency of the entire arrangement is adversely affected because less light can be received by the light source. In addition, the controllable reflector 490, often a DLP® chip, is restricted in the maximum permissible angle of incidence, so that the use of grazing light incidence, that is, if a light beam is only partially in the desired one
    Direction of projection is blasted, is not expedient.
    5 schematically shows a vehicle headlight 501 according to the invention with important components, which comprises a light source unit 502, primary optics 503, a controllable reflector 590, an optically transparent cover 504, an optical absorber device 505, an optical shading element 506 and a projection optics 507.
    The light source unit 502 is set up to emit light and into a first one
    Direction of propagation 510 to light up, in the beam path of which the controllable reflector 590 is arranged. The controllable reflector 590 at least partially reflects the light in a second direction of propagation 520, in the beam path of which the projection optics 507 are arranged and oriented in a direction in front of the vehicle in order to form a light image in front of the vehicle.
    The controllable reflector 590 comprises an arrangement with a multiplicity of controllable individual mirrors 591, 592, the reflecting surfaces of which in a non-tilted basic position together form a first plane 550 and are arranged, for example, as a rectangular matrix of individual mirrors 591, 592
    The light emitted by the light source unit 502 falls in the first
    Direction of propagation 510 at a first angle a5 onto the controllable reflector 590 and is driven by the latter in a first controlled state in the direction of the second
    Direction of propagation 520 reflected. In a second controlled state of the
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    P15370 controllable reflector 590, the light is reflected at a second angle β5 in the direction of the optical absorber device 505.
    The optically transparent cover 504 is between in a second plane 551
    The light source unit 502 and the controllable reflector 590 are arranged such that light in the first propagation direction 510 and in the second propagation direction 520 can penetrate the optically transparent cover 504.
    The light emitted by the light source unit 502 falls in the first
    Direction of propagation 510 at the first angle a5 on the optically transparent cover 504, is partially and parallel to the second of this
    Direction of propagation 520 is reflected in a fourth direction of propagation 540 and is blocked in the fourth direction of propagation 540 by the optical shading element 506.
    The optical shading element 506 overlaps the projection area of the projection optics 507 insofar as the second direction of propagation 520 and the fourth direction of propagation 540 each have a common area of light propagation with respect to their directions of propagation.
    In this exemplary embodiment of the invention, the light source unit 502 comprises at least one semiconductor light source, preferably a power LED, a high-current LED or a laser diode. Furthermore, the light source unit 502 and the primary optics 503 can preferably be designed in the form of an optical lens in a common component. The primary optics 503 bundles the emitted light and directs the bundled light onto the controllable reflector 590. In this case, beam shaping can be set up in such a way that as much light as possible falls on the rectangular surface of the controllable reflector 590 to be illuminated and does not return unused in the form of heat must be dissipated. The shown embodiment of the light source unit 502 shows an exemplary structure. However, many other variants for a light source unit are conceivable, which are familiar to the person skilled in the art.
    In this example, the shading element 506 is an aperture, which allows a particularly simple and inexpensive design. However, when designing the
    Vehicle headlights take into account that the bezel, if applicable
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    P15370 can have reflective properties, does not lead to undesirable impairments in the light image of the vehicle headlight. It is expedient if the shading element 506 reflects light to the optical absorber device 505 in the form of a reflecting diaphragm. In this case, the optical absorber device 505 can take over the conversion of light into heat and can dissipate the heat in a suitable manner.
    Alternatively, the shading element 506 can be an optical absorber. This is advantageous in that the shadowed light can be converted to heat directly at the shading element 506, and therefore the optical absorber device 505 of the vehicle headlight is not additionally heated. In this way, it can be achieved that the optical absorber device 505 is dimensioned smaller and more cost-effectively and, consequently, a smaller overall size of the headlight is achieved.
    In this exemplary embodiment, the shading element is designed as an aperture 506 and is at least partially arranged in the beam path of the second direction of propagation 520 and in front of the projection optics 507 in order to prevent unwanted light in the fourth
    To reduce direction of propagation 540, as well as a small design of the
    Reach vehicle headlights 501 and require low precision in the dimensions and position of the shading element 506. The aperture 506 can be designed as part of the projection optics 507, so that positioning errors are minimized.
    The width of the overlap area of the projections in the directions of propagation 520 and 540 defines a parameter 570. This parameter 570 specifies by how much the first direction of propagation 520 is covered or reduced in its beam path by the shading element 506. This reduction limits the degrees of freedom in the design of a vehicle headlight and may require larger individual components or a larger overall design, which is undesirable.
    Alternatively, the shading element 506 in the fourth direction of propagation 540 can be arranged at least partially in the beam path of the second direction of propagation 520 and after the projection optics 507, as a result of which the shadowing and the associated optical reflections or thermal emissions occur geometrically far away from the optical absorber device, which is advantageous for the distribution
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    P15370 can be the thermal loss inside the vehicle headlight. This
    Embodiment is shown in Fig. 6.
    In the embodiment of the invention according to FIG. 5, the second level 551 is located parallel to the first level 550.
    FIG. 6 shows a schematic representation of the functional principle of an arrangement of a vehicle headlight 601 according to the invention in a fifth configuration, which is a further development of the arrangement according to FIG. 5, wherein a shading element or an aperture 606 is arranged in the fourth direction of propagation 640 after a projection lens 607.
    For the remaining elements and representations of the vehicle headlight 601 shown, the explanations of the previous figures apply analogously, in particular the design of the shading element 606.
    FIG. 7 shows a schematic representation of the functional principle of an arrangement of a vehicle headlight 701 according to the invention in a fourth configuration, which comprises a controllable reflector 790 with an optically transparent cover 704 in a second angular position, in which the controllable reflector 790 and the optically transparent cover 704 are one Include third angle y7 that is greater than 0 °.
    The controllable reflector 790 comprises an arrangement of a multiplicity of controllable individual mirrors 791, 792, the reflecting surfaces of which, in a non-tilted basic position, form a first plane 750 together flat and are arranged, for example, as a rectangular matrix of individual mirrors 791, 792
    The optically transparent cover 704 is between in a second plane 751
    The light source unit 702 and the controllable reflector 790 are arranged such that light in the first direction of propagation 710 and in the second direction of propagation 720 can penetrate the optically transparent cover 704.
    The statements of the preceding figures apply analogously to the remaining elements and representations of the vehicle headlight 701 shown.
    18/37
    P15370
    The second angular position of the optically transparent cover 704 is defined such that the second plane 751 lies at a third angle y7 to the first plane 750.
    This measure makes it possible to achieve that significantly less light from the fourth direction of propagation 740 reaches the optical region of the projection optics 707 and generates disturbing scattered light that would be undesirable in the light image in front of the vehicle.
    The parameter 770 defines the width of the overlap area of the projections in the direction of propagation 720 and 740. In comparison, the parameter 770 is smaller than the parameter 570 according to FIG. 5, whereby an increase in the efficiency of the projection optics and in particular an improvement in the photograph can be achieved by the third angle y7 ensures that the reflections are at least only partially directed in the second direction of propagation 720 and consequently only a smaller proportion has to be suppressed in the light image by an optical shading element 706.
    It is clear that with a multi-part projection optics, a shading element can also be located between the individual elements of the multi-part projection optics. In this case, it is a question of defining which elements of the multi-part projection optics form the most important function of a projection optics and consequently act as the “main projection optics”. Consequently, a shading element can be arranged in front of or after the main projection optics, analogously to the arrangements according to FIGS. 5, 6 and 7.
    8 shows one embodiment of a projection lens 807 and one
    Shading element or a diaphragm 806, the diaphragm 806 being applied to the projection lens 807. With this embodiment it can be achieved that these two components of a vehicle headlight are manufactured in such a way that they are optically and mechanically matched to one another and only a common holder is required, which offers cost advantages. Depending on the orientation of the
    Projection lens 807, an arrangement analogous to FIG. 5, FIG. 6 or FIG. 7 can be created.
    9a shows a light distribution of a vehicle headlamp in DLP® technology according to the prior art, the light distribution using a checkerboard-like test pattern,
    19/37
    P15370, which is shown via a horizontal axis H and a vertical axis V, is defined and the differently hatched areas show different areas, each with the same light intensity.
    FIG. 9b shows the intensity distribution according to FIG. 9a in the sectional plane A-A, in which it can be seen that in the case shown, with a checkerboard-like test pattern, the intensities fluctuate between a minimum value 100 and a maximum value 101. A contrast value can be determined from the ratio of these two extreme values 101 to 100.
    10a shows a light distribution of a vehicle headlight according to the invention in a representation analogous to FIG. 9a.
    FIG. 10b shows an intensity distribution according to FIG. 10a in the section plane BB, in which it can be seen that in the case shown, with a checkerboard-like test pattern, the intensities fluctuate between a minimum value 110 and a maximum value 111, the minimum value 110 being significantly lower than the minimum value 100 according to FIG. 9b, or almost zero, and consequently the vehicle headlight according to the invention creates a significantly better contrast value in the light image.
    20/37
    P15370
    LIST OF REFERENCE NUMBERS
    100
    101.201, 301.401, 501, 601, 701
    102.202, 302.402, 502, 602, 702
    103.203, 303.403, 503, 603, 703
    190,290, 390,490, 590, 690, 790
    191, 291, 391,491, 591, 691, 791,
    192,292, 392,492, 592, 692, 792
    104,304,404, 504, 604, 704
    105, 205, 305.405, 505, 605, 705
    506, 606, 706, 806
    107,107a, 207, 307,407, 507, 607, 707, 807
    210,310,410, 510, 610, 710
    211, 311, 411, 511, 611, 711,
    212,312,412, 512, 612, 712
    120,220, 320,420, 520, 620, 720
    221,321,421, 521, 621, 721
    130,230, 330,430, 530, 630, 730
    232,332,432, 532, 632, 732
    440,540, 640, 740
    441, 541, 641, 741,
    342,442, 542, 642, 742
    250,350,450, 550, 650, 750
    351, 451, 551, 651, 751
    260, 360,460, 560, 660, 760,
    261,361,461, 561, 661, 761
    570, 770 α2, α3, α4 α5, α6, α7 β2, β3, β4, β5, β6, β7
    electronics housing
    vehicle headlights
    Light source unit
    Primary optics controllable reflector controllable individual mirrors optically transparent cover optical absorber device optical shading element projection optics first direction of propagation first light beams second direction of propagation second light beams third direction of propagation third light beams fourth direction of propagation fourth light beams first level second level
    surface normal
    Characteristic for overlap first angle second angle
    21/37
    P15370
    21 Y7 third angle Η horizontal axis V vertical axis 100,101,110,111 Light intensity or illuminance
    22/37
    P15370
    权利要求:
    Claims (11)
    [1]
    claims
    1. vehicle headlight (501, 601, 701), comprising at least one
    Light source unit (502, 602, 702), at least one controllable reflector (590, 690, 790), at least one optically transparent cover (504, 604, 704), at least one optical absorber device (505, 605, 705), at least one optical shading element (506, 606, 706, 806) and at least one projection optics (507, 607, 707, 807), the light source unit (502, 602, 702) being set up to emit light and to point in a first direction of propagation (510, 610, 710) light up, in the beam path of which the controllable reflector (590, 690, 790) is arranged, and the controllable reflector (590, 690, 790) the light in a second direction of propagation (520, 620, 720), in the beam path of which
    Projection optics (507, 607, 707, 807) is arranged and oriented in one direction in front of the vehicle, at least partially reflected, in order to form a light image in front of the vehicle, the controllable reflector (590, 690, 790) being an arrangement of a multiplicity of controllable individual mirrors (591, 691, 791, 592, 692, 792), the reflecting surfaces of which in a non-tilted state are arranged flat in a first plane (550, 650, 750) and as a rectangular matrix of individual mirrors (191, 291), The light emitted by the light source unit (502, 602, 702) in the first direction of propagation (510, 610, 710) falls on the controllable reflector (590, 690, 790) and from it a first controlled state in the direction of the second
    Direction of propagation (520, 620, 720) is reflected and / or in a second controlled state of the controllable reflector (590, 690, 790) is reflected in a third direction of propagation (532, 632, 732), and the optically transparent cover (504, 604, 704) is arranged in a second plane (551, 651, 751) between the light source unit (502, 602, 702) and the controllable reflector (590, 690, 790) such that light in the first direction of propagation (510, 610 , 710) and in the second direction of propagation (520, 620, 720) the optically transparent
    Cover (504, 604, 704) penetrates,
    23/37
    P15370 characterized in that the light emitted by the light source unit (502, 602, 702) in the first
    Direction of propagation (510, 610, 710) falls on the optically transparent cover (504, 604, 704) and is partially reflected by it in a fourth direction of propagation (540, 640, 740) and in the fourth direction of propagation (540, 640, 740) the optical
    Shading element (506, 606, 706, 806) is blocked.
    [2]
    2. Vehicle headlight (101) according to claim 1, characterized in that an optical absorber device (505, 605, 705) is located in the third direction of propagation (532, 632, 732).
    [3]
    3. Vehicle headlight (101) according to claim 1 or 2, characterized in that the second level (551, 651, 751) is parallel to the first level (550, 650, 750).
    [4]
    4. Vehicle headlight (201) according to claim 1 or 2, characterized in that the second plane (551, 651, 751) lies at a third angle (y6) to the first plane (550, 650, 750), the third angle ( y7) is greater than 0 ° and less than 15 °, preferably greater than 0 ° and less than 5 °.
    [5]
    5. Vehicle headlight (501, 601, 701) according to one of claims 1 to 4, characterized in that the shading element (506, 606, 706) at least partially in the beam path of the second direction of propagation (520, 620, 720) and in front of the projection optics ( 507, 607, 707, 807) is arranged.
    [6]
    6. Vehicle headlight (501, 601, 701) according to one of claims 1 to 5, characterized in that the shading element (506, 606, 706) at least partially in the beam path of the second direction of propagation (520, 620, 720) and according to the projection optics ( 507, 607, 707, 807) is arranged.
    [7]
    7. The vehicle headlight (501, 601, 701) according to one of claims 1 to 6, characterized in that the shading element (506, 606, 706) is an aperture.
    [8]
    8. Vehicle headlight (501, 601, 701) according to one of claims 1 to 6, characterized in that the shading element (506, 606, 706) is an optical absorber.
    24/37
    P15370
    [9]
    9. Vehicle headlight (501, 601, 701) according to one of claims 1 to 8, characterized in that the shading element (506, 606, 706) and the optical absorber device (505, 605, 705) is designed as a common component.
    [10]
    10. Vehicle headlight (501, 601, 701) according to one of claims 1 to 9, characterized in that the light emitted by the light source unit (502, 602, 702) in the first direction of propagation (510, 610, 710) at a first angle (α5, α6, a7) falls on the optically transparent cover (504, 604, 704), the first angle (α5, α6, a7) being in a range between 50 ° and 65 °, preferably between 55 ° and 60 ° ,
    [11]
    11. Vehicle headlight (501, 601, 701) according to one of claims 1 to 10, characterized in that the light source unit (502, 602, 702) at least one semiconductor light source, preferably a power LED, a high-current LED or a laser diode, and preferably comprises primary optics (103, 203) in the form of an optical lens.
    25/37
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    同族专利:
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    KR102155080B1|2020-09-11|
    JP6739630B2|2020-08-12|
    US10619816B2|2020-04-14|
    AT519055B1|2018-06-15|
    KR20190046944A|2019-05-07|
    CN109690180B|2021-09-07|
    JP2019526911A|2019-09-19|
    US20190195459A1|2019-06-27|
    CN109690180A|2019-04-26|
    EP3510320A1|2019-07-17|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50791/2016A|AT519055B1|2016-09-08|2016-09-08|vehicle headlights|ATA50791/2016A| AT519055B1|2016-09-08|2016-09-08|vehicle headlights|
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    US16/329,645| US10619816B2|2016-09-08|2017-06-26|Vehicle headlight|
    CN201780054889.3A| CN109690180B|2016-09-08|2017-06-26|Vehicle head lamp|
    EP17739179.4A| EP3510320A1|2016-09-08|2017-06-26|Vehicle headlight|
    JP2019512988A| JP6739630B2|2016-09-08|2017-06-26|Vehicle floodlight|
    PCT/AT2017/060158| WO2018045402A1|2016-09-08|2017-06-26|Vehicle headlight|
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