• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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    • 专利摘要:
    The invention relates to a cover (20) for a luminaire device (10), in particular for a luminaire device (10) of a motor vehicle headlight, wherein the cover (20) comprises: an electrically activatable cover element (21A, 21B) which is dependent on an applied electrical voltage between at least one translucent state (21A) and an opaque state (21B) and having an inner surface (15) and an outer surface (35), and a partially translucent layer (22). The invention further relates to a lighting device (50), in particular a lighting device (50) for a motor vehicle, comprising such a cover (20).
    公开号:AT516080A1
    申请号:T50528/2014
    申请日:2014-07-28
    公开日:2016-02-15
    发明作者:Andreas Luger
    申请人:Zizala Lichtsysteme Gmbh;
    IPC主号:
    专利说明:

    Cover for a lighting device
    The invention relates to a cover for a lighting device, in particular for a lighting device of a motor vehicle headlight. The field of application of the invention is intended especially for use in motor vehicle (motor vehicle) main headlights. The invention can also be used for other purposes in the automotive sector, such as a cover in the vehicle taillight area and for lights in the interior of a motor vehicle. The invention further relates to lighting devices, in particular lighting devices for motor vehicles, which have a cover according to the invention.
    The last few years have shown that there is always a desire on the part of the customer to produce lighting elements of a motor vehicle headlight, such as a car. Light source, reflectors, lenses, light sticks etc. in the cold appearance (ie headlights or lighting device not in operation) behind high-gloss / mirrored covers to hide, whereas these are visible in the warm appearance (ie headlights or lighting device in operation) through the cover and do not affect the lighting and / or signaling functionality.
    The previously proposed concepts for meeting the above-mentioned customer requirements all had the disadvantage that the covers were either too transparent and thus did not sufficiently obstruct the view of the lighting elements or, on the other hand, provided an acceptable level of insight, but the light emitted by the lighting device Too much absorbed or reflected and therefore have the light or the light distribution influenced too much.
    One known concept is the use of a partially translucent mirror, also referred to as a semi-transmissive mirror, one-way mirror, spy mirror, police mirror or Venetian mirror, as a cover for lights. Partially translucent mirrors are well known to a person skilled in the art. This is a translucent member (e.g., a transparent glass sheet) which is mirrored on one side with a thin light-reflecting layer, while the other side of the component allows the light to pass unimpeded. The effect of the Venetian mirror is based on the fact that it is very bright on the coated side of the disc and very dark on the other side. Due to this difference in brightness, the disc is perceived by the viewer as an opaque mirror and from the dark area as transparent from the bright area.
    DE 9302516 Ul describes the design of a luminaire cover as a semitransparent mirror, which is almost opaque and mirrored in the "off" state of the luminaire, whereas it loses its mirror property in the "on" state of the luminaire and becomes translucent.
    In DE 102 61 648 B4 a semitransparent mirror is described in a luminaire housing through which a view of details within the lamp housing is possible in the switched-on state of the lamp, whereas the mirror in the off state acts like a normal mirror and the view into the lights inside denied.
    DE 200 18 807 U1 describes the use of a semitransparent mirror, which prevents the view of a reflector (i.e., retro-reflector) of a road vehicle in diffuse light incidence, while directed light rays impinge on the reflector and are reflected back.
    DE 20 2008 011 128 U1 discloses a cover device for a light-emitting material lamp comprising a cover element and a layer which is applied to the surface of the cover element, the visible light layer having a transmittance of at least 0.12 and a reflectance of at least 0.35.
    Practice has shown, however, that a cover based on a self-sufficient partially transparent mirror for use in automotive headlamps is not a satisfactory solution. It has been found in experiments with prototypes that a reflectance of about 70% or higher is necessary to ensure a desired by the customer highly reflective, non-transparent glare effect in the cold glow of a headlamp with the help of a self-sufficient partially transparent mirror. Due to this high degree of reflection, about 70% or more of the light emitted by the lighting device is lost in the cover. These high light losses are included
    Headlamps unacceptable, since the efficiency of the lighting device extremely decreases. A reduction in the degree of reflection and a concomitant increase in the transmittance lead to the cover again appearing too transparent in front of the lighting elements.
    Further known concepts use electrochromic materials such as electrochromic elements and disks or LC-glasses having a polymer liquid-crystal film (also referred to as PDLC glasses) whose transmission properties for light can be changed as a function of an applied electrical voltage. Electrochromic materials and LC glasses are well known to those skilled in the art. When opaque, electrochromic materials and LC glasses have a milky opaque appearance and are commonly used in building glazings, panoramic roofs, rear-view mirrors, vehicle glazing and displays, as well as in interior glazings designed to provide privacy ("privacy").
    The use of liquid crystal panels to cover lighting equipment on motor vehicles has become known from DE 8812322 Ul.
    FR 2 605 086 B1 discloses the use of electrochromic material layers which, in the opaque (i.e., opaque) switched state, block the view of a headlamp and, in the translucent state, allow the exit of a headlamp beam.
    FR 2 927 858 Bl discloses the use of an electrochromic element as a screen protector on a motor vehicle headlamp. Here, a carrier element is subjected to electrochromic material, whereby the passage of light is blocked or allowed in dependence on the desired switching state of the electrochromic material.
    FR 2 965 889 Al describes an electrochromic element as a cover plate to mask the view of a headlamp module by changing the transmittance and thus to change the appearance of the headlamp.
    In US 8,256,940 B2, a cover glass for a headlight is disclosed. The cover glass is equipped with an electrochromic film that allows switching between a light-transmitting and an opaque state. Thus, on the one hand the function of the headlamp can be controlled and on the other unwanted reflections are prevented from the outside entering the headlamp light. The appearance or the design impression can be adjusted by the electrochromic film to customer requirements.
    However, a cover based on an electrochromic material or an LC glass does not have a high-gloss and mirrored appearance (design) and therefore does not correspond to the customer's intention mentioned in the introduction.
    It is therefore an object of the invention to provide a covering device for a lighting device, in particular for a lighting device of a motor vehicle headlight, which is perceived in the cold appearance (ie lighting device or headlights not in operation) as high gloss and at the same time the insight on the underlying lighting technology Prevents elements. This means that the impression of coldness in the viewer should give the impression that a high-gloss privacy cover is located in front of the light function and thus blocks the view of the lighting elements of the lighting device. On the other hand, however, the cover should have no relevant influence on the light function of the lighting elements positioned behind the cover in the warm appearance (i.e., lighting device in operation). This means that the light in the warm appearance can illuminate substantially unhindered through the cover / aperture, without larger light losses occur. At the same time, the light distribution should not or only slightly influenced.
    The object is achieved by a cover for a lamp device, in particular for a lamp device of a motor vehicle headlamp, which according to the invention an electrically activatable cover, which is switchable in response to an applied electrical voltage between at least one transparent state and an opaque state and which has an inner surface and a Having outer surface, and a partially transparent layer comprises.
    In order to achieve the object, according to the invention, an electrically activatable covering element (for example an electrochromic pane or LC glass of a type known per se) is combined with a partially transparent layer as used in a Venetian mirror. By applying an electrical voltage to the electrically activatable cover element, the transmittance of the cover can be changed. In the cold appearance (i.e., lighting fixture or headlamp is not in operation), the cover member is rendered opaque, while in the warm appearance (i.e., active operation of the fixture or headlamp) the cover member can be rendered translucent to light without significant light losses.
    The effect of a Venetian mirror is, as mentioned, all the more pronounced, the greater the difference in brightness between the dark and the bright side of the mirror. In the cold appearance of the lighting device or the headlamp, the electrically activated disk can assume an opaque state, which is why the area facing the lighting device, looks very dark. As a result, the reflectance of the partially transparent layer can be reduced to a minimum without the effect of a Venetian mirror in the cold appearance, i. a high-gloss mirroring, for the viewer is lost. When hot, the electrically activatable cover is switched back to light transparent. A minimum degree of reflection of the partially transparent layer has the advantage that in the active operating state of the light modules, the cover according to the invention has a high degree of transmittance. Compared with the Venetian mirror-based covers known from the prior art (transmittance at about 25%), the transmittance of the cover according to the invention can be increased to> 60%, so that the efficiency of the lighting device remains within an acceptable range. The luminous flux or the light distribution is only slightly influenced because on the one hand the reflectance of the partially transparent layer is kept very small and on the other hand, the electrically activatable cover in the light-transmitting state has a very high transmittance.
    The invention enables new hitherto unrealizable designs of lighting devices, in particular headlight designs in the off state. Thanks to the invention, the headlight in its cold appearance on a customer request high-gloss appearance, which does not or only slightly affect the warm-up operation of the headlamp. Furthermore, there is the possibility of headlamps not only in the cold, but also in daytime running the
    Hide main light functions behind an optically active shutter. Behind the cover according to the invention (synonymously also referred to as aperture) can not vorzuborgen only technically relevant components such as reflectors, lenses, light sticks, etc., but the aperture can also be used at the same time to other relevant in the body construction constructive configurations such as gap dimensions, pivoting joints ( ie clearance between fixed and movable panels of eg curve light modules) to cover. The cover according to the invention also has the advantage, due to its high-gloss appearance in the cold appearance, that expensive high-quality design screens can be saved.
    The term "luminaire device", also referred to herein as a luminaire, refers to a combination of a luminous means with components which influence the electromagnetic radiation radiated by the luminous means and project a desired illuminance distribution (for example, lawful low beam) in front of the motor vehicle. The construction of lighting devices including vehicle headlamps is well known and may vary depending on the type and use of the lighting device. The lighting device may, for example, projection system (light source, reflector assembly, refractive optical elements with / without diaphragms), reflection systems (light source, reflector), imaging systems (light source, intent optics, with / without additional imaging lens systems), light guides, luminous plates, OLED elements and any other Lighting components known to a person skilled in the art include. As light sources, halogen lamps, xenon lamps (HID), LEDs, laser light sources and the like can be used.
    Advantageously, the cover according to the invention, also referred to herein synonymously as an aperture, is used in lighting fixtures for motor vehicles (motor vehicles), in particular in headlights, and is suitable for any arbitrarily configured pig headlight module. The field of application of the invention is particularly advantageous for use in automotive headlamps. The invention can also be used for other purposes in the automotive sector, such as a cover in the vehicle taillight area and for lights in the interior of a motor vehicle. Although the invention is particularly advantageous for the motor vehicle sector, it can be useful in all areas where, on the one hand, the external appearance (design) of a lighting device is an important feature for a viewer and, on the other hand, an influence of the light or the light distribution be kept as low as possible (especially high transmittance).
    With respect to the terms synonymously used herein, "opaque", "opaque", and "opaque". and "opaque state &quot; the transmittance can be defined by the transmittance τ. Under "opaque" is in the known manner an opaque state with "milky &quot; To understand viewing impression. Physically, "opaque" means that no VIS radiation (380 <λ <800 nm) penetrates (τ = 0); with respect to the subject disclosure, as the upper bound for an opaque state, τ &lt; 0.01 is assumed, i. Up to 1% of a radiation intensity incident on a material penetrates this material and can be used on the other side. Preferably, however, τ = 0.
    As used herein, "translucent", "translucent" and "translucent" it should be understood that the electrically activatable visible light masking element is passable. It is essential for the functionality of headlamps if the covers connected downstream of a lamp unit in the optical beam direction have a very good optical transparency, i. a high degree of transmission, have. In the field of headlamp technology, there are target values for the efficiency of the light emission whose physical measure is the luminous flux. For projection modules, realistic values are 30-40%, reflective applications reach up to 60%. These values result from the losses in the system (reflectivity of the reflector surface, absorption losses in lens and lens) and a geometric degree of utilization, which depends on the available installation space, the emission characteristics of the light source and the design strategy of the lighting technician. If you want to hide a projection module behind a cover according to the invention and reach acceptable operating efficiency of the headlamp, the degree of transmission of the cover is preferably about 50%.
    The "inside surface of the cover member &quot; is the surface of the cover member facing the lamp device. Accordingly, under the &quot; outer surface of the cover member &quot; to understand that surface of the cover, which faces away from the lamp device.
    The term "headlight &quot; includes all types of automotive headlamps, particularly headlamps and taillights.
    Under the terms "partially translucent layer" or "partially translucent coating"; is a reflective layer or coating according to the type, as used in disposable mirrors (Venetian mirror, spy mirror) to understand. Such layers are known to the person skilled in the art.
    The term "coldness &quot; refers to the fact that the lighting device or the headlight is not in operation. The term "warm appearance" refers to the fact that the lighting device or the headlight is in operation and radiates law-compliant light distribution.
    Conveniently, the partially transparent visible light layer has a reflectance of 10% to 40%. This has the advantage that in the active operating state of the luminaire, the cover according to the invention has a high degree of transmission for visible light. This is of great relevance, above all, for the motor vehicle headlight sector.
    Even more preferred is when the partially transparent visible light layer has a reflectance of 10% to 25%.
    The production or the application of a partially transparent coating on a surface facing the viewer of a carrier substrate is known to the person skilled in the art. In order to obtain the thin films required for a minimum reflectance, the partially transparent film is preferably made of a metal oxide material. In this case, the surface is vapor-deposited with metal oxides (high and low-refractive index metal oxides) in a manner known per se, wherein a sequence of thin layers with different refractive index is applied until an overall layer having a desired reflectance is achieved. The reflectance can also be carried out depending on the wavelength, so that the coatings can be used in addition to the increase in efficiency for the generation of color impressions - especially in the design of the cold phenomenon. The exact composition of the layers and their thickness (typically on the order of 25 nm to 150 nm) are dependent on the particular manufacturer. Multilayer metal oxide layers and methods for
    Application of such metal oxide layers are described, for example, in WO 2001/042821 A1 and EP 2 492 251 A1. Common materials include MgF2 (magnesium fluoride), S1O2 (silicon dioxide), EKh (hafnium dioxide), T1O2 (titanium dioxide), Ta2Ü5 (tantalum pent-xid) and M ^ Os (niobium pentoxide).
    In a particularly easy to implement and effective first embodiment of the cover according to the invention, the partially translucent layer is at least partially applied directly on the outer surface of the cover. Depending on the desired appearance (design), the entire outer surface or only a portion of the outer surface of the cover member may be coated with the partially transparent layer.
    In order to reduce the reflection of light emitted by the luminaire device at the boundary surfaces of the cover element, so-called Fresnel reflections, it is particularly advantageous if an antireflection coating (AR coating, AR coating) is applied at least in regions on the inner surface of the cover element. The reflectance can typically be reduced by about 4% by applying an AR coating on the inner surface of the cover member; the transmittance of the cover is thereby increased. Preferably, the entire inner surface of the cover member is coated with the AR coating. AR coatings and their preparation are well known to those skilled in the art. Common coating materials include MgF2 (magnesium fluoride), S1O2 (silica), Hf2 (hafnium dioxide), T1O2 (titanium dioxide), Ta2Ü5 (tantalum pentoxide) and Nb ^ Os (niobium pentoxide). By tuning the wavelength of the anti-reflection coating, color impressions can also be created on the cover in a manner known per se.
    In addition to the numerous antireflection coatings available, the reflection of the light emitted by the luminaire device at the boundary surfaces of the cover element can also be reduced by means of special nanostructures, so-called moth eye structures, applied to the surfaces of the cover element (see, for example, Bläsi et al., Reflection with Moth Eye Structures 92 (2002) 5; Miller F., Nanostructured surfaces, Fraunhofer magazine 2.2005: 8-12). These nanostructures are advantageously used on plastic surfaces where vapor deposition with AR coatings is difficult by conventional techniques.
    In a further embodiment, the cover has a translucent intermediate element (eg a translucent glass or plastic disk) with an inner surface and an outer surface, the inner surface of the intermediate element facing the outer surface of the cover element and the partially translucent layer at least partially covering the outer surface of the outer surface Intermediate element is applied. By analogy with the inner and outer surfaces of the cover member, the term "inner surface of the intermediate member &quot; on that surface of the intermediate element, which faces the lighting device. Accordingly, under the &quot; outer surface of the intermediate member &quot; to understand that surface of the intermediate element which faces away from the lighting device. In a variant, the inner surface of the intermediate element is arranged in direct contact with the outer surface of the cover. In another variant, the inner surface of the intermediate member and the outer surface of the cover are spaced apart. This embodiment is less efficient and has a more complex structure due to the additional interfaces compared to the first embodiment described above, and therefore it is less preferable. Also in this embodiment, it is advantageous if the inner surface of the cover is at least partially coated with an AR coating according to the above statements. Preferably, the entire inner surface of the cover member is coated with the AR coating. In addition, in this embodiment, at least in some areas an AR coating may also be applied to the outer surface of the cover element. Preferably, the entire outer surface of the cover member is coated with the AR coating. By an AR coating both the inner and the outer surface of the cover, the degree of reflection of about 8% can be reduced to less than 0.5%.
    In an advantageous variant, the electrically activatable cover element comprises an electrochromic material. Such cover elements are also known to a person skilled in the art under the name "electrochromic glass", "electrochromic disk". or "electrochromic cell" are known and used in the usual way in the automotive sector (vehicle glazing, rear-view mirrors, headlamp covers ...) and building glazings. For example, suitable cover elements are described in FR 2 605 086 B21, FR 2 927 858 B1, FR 2 965 889 A1 and US 8,256,940 B2. By applying an electrical voltage, usually a DC voltage, the light transmittance of the electrochromic disc changes. Depending on the technology, this process may take longer (several minutes) or shorter (<1 second). Frequently used electrochromic materials are for example tungsten oxide,
    Molybdenum trioxide, polyaniline, tungsten trioxide, nickel oxide, iron hexacyanoferrate (Prussian blue), 3,4-polyethylenedioxithophene (PEDOT) and 3,4-polyethylenedioxypyrrole (PEDOP). Further electrochromic polymers suitable for the invention can be found in EP10273997 B1.
    As an alternative to electrochromic disks, a glass made of liquid crystal (LC) technology (also called "LC glass") can be used. In a further advantageous variant, the electrically activatable cover element therefore comprises an LC glass. The heart of the LC lens is a polymer liquid crystal film sandwiched between two conductive disks and connected to a power source. In particular, LC glasses include polymer dispersed liquid crystals (PDLC) and suspended particle devices (SPD). Preferably, therefore, the LC glass is a PDLC glass or an SPD element, more preferably an SPD element. The structure and operation of PDLC glasses or SPD elements are well known to the person skilled in the art. In a PDCL glass, the liquid crystal molecules align by applying a voltage, and the PDLC glass becomes transparent due to the changed scattering behavior of the liquid crystal molecules. With no applied voltage, a PDLC glass assumes an opaque state (typically milky, opaque appearance). SPD elements comprise dissolved light-absorbing, rod-shaped suspended particles which align themselves due to an applied voltage, so that an SPD glass becomes transparent. In the de-energized state, the suspended particles are stochastically distributed, which is why the SPD element assumes a light-absorbing state. An LC glass suitable for the present invention is described, for example, in the abovementioned DE 8812322 U1.
    Conveniently, the electrically activatable cover is in the opaque state when the lighting device is not in operation (cold) or in the translucent state when the lighting device is in operation (warmth).
    Another object of the invention is also the use of the cover according to the invention as an optically activated aperture for automotive lights, in particular as optically activated aperture for motor vehicle headlights. According to this use, the electrically activatable cover is in the opaque (opaque) state when the car lamp or the headlamp is not in operation (cold) and in the translucent state when the car lamp or the headlamp is in operation ( Warm appearance).
    The invention further relates to a lighting device, in particular a lighting device for a motor vehicle, comprising a lighting device according to a known type and as described above and one of the lamp device in the optical beam direction downstream cover according to the invention as described and defined herein. The lighting device according to the invention can be used in the entire automotive sector (for example, cars, trucks, motorcycles, etc.). The lighting device for a motor vehicle is preferably a motor vehicle headlight. The cover is conveniently arranged in the vehicle headlight in the optical beam direction between the lamp device and a lens of the motor vehicle headlight. Car headlamps include headlamps (also referred to as headlamps) and tail lights. Particularly advantageous cover of the invention, however, is used in headlights. A further advantageous variant of a lighting device for motor vehicles according to the invention relates to automotive interior lights.
    The invention will be further described by way of non-limitative examples and accompanying drawings, in which:
    1a shows a schematic representation of a variant of a headlight according to the invention in a side view,
    1b shows a schematic representation of a further variant of a headlight according to the invention in a side view,
    2 shows an arrangement of a lighting device and an embodiment of the cover according to the invention, wherein the cover is in the light-transmitting state,
    FIG. 3 shows the arrangement of FIG. 2 with the cover in the opaque state, FIG.
    4 shows an arrangement of a luminaire device and a further embodiment of the cover according to the invention, wherein the cover is in the light-permeable state,
    FIG. 5 shows the arrangement of FIG. 4 with the cover in the opaque state, FIG.
    6a and 6b show the known functional principle of an LC glass,
    7 shows by way of example the layer structure of a partially transparent layer,
    Fig. 8a shows the Fresnel reflection on a glass substrate, and
    Fig. 8b shows the Fresnel reflection on a glass substrate coated with an anti-reflection coating.
    Fig. La and Fig. Lb show a schematic representation of two variants of a headlight 50 for a motor vehicle, each in side view (shown in transparent). The main headlight 50 includes a housing 52 with a cover plate 51. In the housing 52, an optical lighting device 10 is arranged for headlights. The lighting device 10 is constructed according to a conventional manner and can, for example, projection systems (light source, reflector, lens with / without aperture), reflection systems (light source, reflector), imaging systems (light source, intent optics, with / without additional imaging lens), optical fiber (eg Light sticks), luminous plates, OLED elements, and any other lighting components known to those skilled in the art. As light sources, halogen lamps, xenon lamps (LEDs), LEDs, laser light sources and the like can be used. The luminaire device 10 according to FIG. 1a is a classical projection module with a pedestal of a xenon lamp 12 (high-pressure discharge (HID) lamp), a reflector 15 with an elliptical basic shape and a projection lens 16. In the luminaire device 10 according to FIG Fig. Lb is an imaging system 18 with LED 13 in attachment optics. Between the lighting device 10 and the cover plate 51, a cover 20 according to the invention (also referred to as cover 20) is arranged in the optical beam direction. The aperture shown in Fig. La and Fig. Lb consists of a disc-shaped LC glass 21A / 21B in a conventional manner (for the description of Funktionsprin zip of a LC glass see Fig. 6a and Fig. 6b) and one on a Outer surface 35 of the electror-rochromic element 21A / 21B applied partially transparent layer 22 according to known manner (Venetian mirror). Instead of the LC glass, an electrochromic element can be used in a manner known per se. The LC glass 21A / 21B is connected to a power source 25. In response to an applied voltage, the LC glass 21A / 21B is switchable between a translucent state 21A (see Figure 6b) and an opaque / opaque state 21B (see Figure 6a): • Warm up of the headlamp 50 (ie the lighting device 10 or the headlight 50 is in operation), the LC glass 21A / 21B is switched to the light-transmitting state 21A (see Fig. 6b). The light generated by the lighting device 10 can thereby pass through the aperture 20 and the cover plate 51 through to the outside. In the cold phenomenon of the headlamp 50 (i.e., the lamp device 10 and the headlamp 50 are turned off), on the other hand, the LC glass 21A / 21B is in the opaque state 21B (see Fig. 6a). Consequently, the region 23 behind the stop 20 facing the lighting device 10 is rendered very dark, which is why the effect of the partially semipermeable layer 22, i. a high-gloss representation of the aperture 20 for an outside observer 30 (see Fig. 2-5), is very pronounced.
    Fig. 2 shows an arrangement of a lighting device 10 in its warm appearance as described above and an advantageous embodiment of the diaphragm 20 according to the invention, wherein the aperture 20 is switched to translucent in the warm appearance. Fig. 3 shows the arrangement of Fig. 2, wherein the lighting device 10 is not in operation (cold appearance) and the aperture 20 is therefore connected opaque. As described above with respect to FIGS. 1 a and 1b, the cover 20 comprises an LC glass 21A / 21B (alternatively an electrochromic element) which is connected between a light-transmitting state 21A (current in FIG. 2 and FIG ) and an opaque / opaque state 21B (current off, Fig. 3 and Fig. 6a) can be switched according to a conventional manner. The LC glass 21A / 21B has an inner surface 15 facing the luminaire device and an outer surface 35 facing the viewer 30. On the outer surface 35 of the LC glass 21A / 21B facing the observer 30 is a partially transparent layer 22 of known type (Venetian mirror) applied. In the cold appearance (FIG. 3), the layer 22 for the observer 30 appears as a high-gloss aperture concealing the lighting elements of the lighting device 10. In order to reduce the reflection of the light emitted by the luminaire device 10 on an inner surface 15 of the LC glass 21A / 21B, an antireflection coating 25 (AR coating, AR coating) is additionally applied to the inner surface 15. The AR coating 25 is made by vapor deposition with a metal oxide.
    Fig. 4 shows an arrangement of a lamp device 10 and a further embodiment of the diaphragm 20 according to the invention, wherein the aperture 20 is switched to translucent in the warm appearance. Fig. 5 shows the arrangement of Fig. 4, wherein the lighting device 10 is not in operation (cold appearance) and the aperture 20 is therefore connected opaque. As described above with respect to FIGS. 1a and 1b, the diaphragm 20 comprises an LC glass 21A / 21B (alternatively an electrochromic element) which is connected between a light-transmissive state 21A (current in FIG. 2 and FIG ) and an opaque / opaque state 21B (current off, Fig. 3 and Fig. 6a) can be switched according to a conventional manner. The LC glass 21A / 21B has an inner surface 15 facing the luminaire device and an outer surface 35 facing the viewer 30. In order to reflect the light emitted by the luminaire device 10 on the inner surface 15 or the outer surface 35 of the LC glass 21A / 21B Reduce, on both the inner surface 15 and on the outer surface 35 is additionally applied an antireflection coating 25 (AR coating, AR coating). The AR coating 25 is formed by vacuum evaporation techniques using CVD (Chemical Vapor Deposition) or PVD (Physical Vapor Depositio) processes with e.g. Metal oxides produced. The diaphragm 20 further comprises a transparent intermediate member 24 (disk of glass or a polymer material) having an inner surface 26 and an outer surface 27. The intermediate member 24 is the LC glass 21A / 21B downstream in the optical beam direction and spaced therefrom. On the observer 30 facing outer surface 27 of the intermediate element 24 is a partially transparent layer 22 applied in a conventional manner (Venetian mirror). In the cold appearance (FIG. 5), the layer 22 for the viewer 30 appears as a high-gloss aperture covering the lighting elements of the lighting device 10.
    The embodiment of the diaphragm 20 according to the invention shown in FIGS. 2 and 3 is preferred over the other embodiment shown in FIGS. 4 and 5 because of its simpler structure and greater efficiency.
    FIGS. 6a and 6b show the functional principle known per se of an LC glass or an electrochromic cell, here by way of example with reference to the LC glass 21A / 21B shown in the figures. Fig. 6a shows the LC glass 21A / 21B in its opaque state 21B (current off, reference numeral 215b), whereas Fig. 6b shows the LC glass in its translucent state 21A when the voltage is applied (current on, reference numeral 215a). The LC glass 21A / 21B is made of a polymer liquid crystal film 212 having liquid crystals 213 dissolved therein. The polymer liquid crystal film 212 is sandwiched between two conductive layers 211, for example, indium tin oxide (ITO) layers. This construct is in turn embedded between two coverslips 210. When an electric voltage is applied to the two conductive layers 211, the dissolved liquid crystals 213 arbitrarily arranged in the electroless state in the polymer liquid crystal film 212 align in a preferred direction, and the LC glass 21A / 21B assumes its transparent state (FIG. 6b) ). When the voltage is removed, the dissolved liquid crystals regain their disordered state and the LC glass 21A / 21B becomes opaque again (Figure 6a).
    Fig. 7 shows by way of example the layer structure of a multilayer partially transparent layer 22 applied to a support substrate 21A / 21B, 24 (see LC glass 21A / 21B of Figs. 2 and 3 and intermediate element 24 of Figs. 4 and 5, respectively) is. The layer 22 has a triple layer structure of a first metal oxide material 22A (e.g., S1O2) and a second metal oxide material 22B (e.g., T1O2). To produce the layer structure shown in FIG. 7, the surface of the carrier substrate 21A / 21B, 24 is vapor-deposited with metal oxides (high and low-refractive index metal oxides) in a manner known per se. Thereby, a sequence of thin films with different refractive index is applied to the substrate 21A / 21B, 24, until the layer 22 has reached the desired reflectance. Multilayer metal oxide layers and methods for applying such metal oxide layers are described, for example, in WO 2001/042821 A1 and EP 2 492 251 A1. Common materials include MgF2 (magnesium fluoride), S1O2 (silica), HfÜ2 (hafnium dioxide), T1O2 (titanium dioxide), Ta20 ^ (tantalum pent-xid), and Nb20s (niobium pentoxide).
    FIG. 8a shows the transmission and absorption behavior of light (Fresnel formulas) on a transparent pane 210, in the example a transparent glass substrate 210. The stated percentages correspond to meaningful and not restrictive reference values. When light strikes the transparent disk 210, part of the light is reflected at the interfaces of the disk 210. The remaining part propagates through the disk 210 (transmission). At normal incidence and a refractive index of n = 1.50, the reflectance of a transparent disk per interface transition is about 4%, i. in total about 8%. With a larger angle of incidence, the reflectivity is correspondingly higher; this situation is described by the Fresnel formulas. Overall, the transmittance is around 91%, whereby material-related absorption losses (typically between 0.5 and 1%) are taken into account.
    FIG. 8 b shows the transmission and absorption behavior of light (Fresnel formulas) on the transparent pane 210 when it is additionally coated with an antireflection coating 25 at an interface. The AR coating 25 reduces the reflection at the interface and increases the transmittance of the disk 210 (94%).
    Example:
    The following is an exemplary comparison of the transmittance of different covers (irises) based on reasonable and non-limiting guide values. The actual efficiencies (reflectance, transmittance, and absorption losses) of the individual components depend, on the one hand, on the choice of materials and, on the other hand, on the requirements for visibility protection (customer-dependent subjective parameter) and the required overall transmittance.
    Cover according to the prior art (only partially translucent mirror): Partially translucent mirror: reflectance ~ 70%
    Fresnel reflections: ~ 4%
    Transmittance (total): 100% - 70% - 4% = ~ 26%
    Cover according to the invention (electrochromic cover element / LC glass + partially translucent coating):
    Electrochromic Covering Element / LC Glass: Transmittance ~ 75%
    Partially translucent layer: reflectance ~ 10%
    Fresnel reflections: reflectance ~ 4%
    Transmittance (total): 75% -10% - 4% = 61%
    Cover according to the invention (electrochromic cover element / LC glass + partially translucent coating + AR coating):
    Electrochromic Covering Element / LC Glass: Transmittance ~ 75%
    Partially translucent layer: reflectance ~ 10%
    Transmittance (total): 75% -10% = 65%
    The exemplary comparison shows that the transmittance can be increased by the invention of ~ 26% (prior art, only partially translucent mirror) to ~ 60-70%.
    权利要求:
    Claims (16)
    [1]
    Claims 1. A cover (20) for a luminaire device (10), in particular for a luminaire device of a motor vehicle headlamp, characterized in that the cover (20) comprises: an electrically activatable cover element (21A, 21B) which, depending on an applied electrical voltage between at least one translucent state (21A) and one opaque state (21B) and having an inner surface (15) and an outer surface (35), and a partially translucent layer (22).
    [2]
    2. Cover according to claim 1, characterized in that the partially translucent layer (22) at least partially on the outer surface (35) of the cover (21A, 21B) is applied.
    [3]
    3. Cover according to claim 2, characterized in that the cover (20) has a translucent intermediate element (24) with an inner surface (26) and an outer surface (27), wherein the inner surface (26) of the intermediate element (24) of the outer surface (26). 35) of the cover (21A, 21B) faces and wherein the partially translucent layer (22) at least partially on the outer surface (27) of the intermediate element (24) is applied.
    [4]
    4. Cover according to one of claims 1 to 3, characterized in that on the inner surface (15) of the cover (21A, 21B) at least partially an anti-reflection coating (25) is applied.
    [5]
    5. Cover according to claim 3 and 4, characterized in that on the outer surface (35) of the cover (21A, 21B) at least partially an anti-reflection coating (25) is applied.
    [6]
    6. Cover according to one of claims 1 to 5, characterized in that the partially transparent layer (22) for visible light has a reflectance of 10% to 40%.
    [7]
    7. Cover according to claim 6, characterized in that the partially transparent layer (22) for visible light has a reflectance of 10% to 25%.
    [8]
    8. Cover according to one of claims 1 to 7, characterized in that the partially translucent layer (22) is made of a metal oxide material.
    [9]
    9. Cover according to one of claims 1 to 8, characterized in that the electrically activatable cover comprises an electrochromic material.
    [10]
    10. Cover according to one of claims 1 to 8, characterized in that the electrically activatable cover member (21A, 21B) comprises a glass which is embodied in liquid crystal (LC) technology.
    [11]
    11. Cover according to one of claims 1 to 10, characterized in that the electrically activatable cover (21A, 21B) in the opaque state (21B) is when the lighting device (10) is not in operation, and that the electrically activatable Covering element (21A, 21B) is in the light-transmitting state (21A) when the lighting device (10) is in operation.
    [12]
    12. Lighting device (50), in particular a lighting device for a motor vehicle, comprising a lighting device (10) and one of the lighting device (10) in the optical beam direction downstream cover (20) according to one of claims 1 to 11.
    [13]
    13. Lighting device according to claim 12 in the form of a motor vehicle headlight (50).
    [14]
    14. Lighting device according to claim 13, characterized in that it is the vehicle headlight is a headlight or a tail light.
    [15]
    15. Lighting device according to claim 13 or 14, characterized in that the cover (20) in the motor vehicle headlight in the optical beam direction between the lamp device (10) and a cover plate (51) of the motor vehicle headlight is arranged.
    [16]
    16. Lighting device according to claim 12 in the form of a motor vehicle interior lamp.
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    同族专利:
    公开号 | 公开日
    EP2979926B1|2019-08-28|
    AT516080B1|2016-04-15|
    EP2979926A1|2016-02-03|
    CN105318248A|2016-02-10|
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    法律状态:
    2016-11-15| HC| Change of the firm name or firm address|Owner name: ZKW GROUP GMBH, AT Effective date: 20161014 |
    2021-03-15| MM01| Lapse because of not paying annual fees|Effective date: 20200728 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50528/2014A|AT516080B1|2014-07-28|2014-07-28|Cover for a lighting device|ATA50528/2014A| AT516080B1|2014-07-28|2014-07-28|Cover for a lighting device|
    EP15175785.3A| EP2979926B1|2014-07-28|2015-07-08|Vehicle lamp|
    CN201510452223.6A| CN105318248A|2014-07-28|2015-07-28|Cover plate for light device|
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