DE102020116264A1 - LIGHT GUIDE DEVICE, VEHICLE COMPONENTS AND VEHICLE - Google Patents

Abstract

A light guide device having a light guide and a light guide component is disclosed, wherein the light guide and the light guide component are integrally connected. The light guide device also has at least one coupling surface for light from at least one light guide component. The light guide has at least one decoupling structure in order to directionally decouple part of the light coupled into the light guide device, and the light guide component has at least one decoupling structure in order to diffusely couple out part of the light that is coupled into the light guide device. A vehicle component and a vehicle are also disclosed.

Description

The invention is based on a light guide device, a vehicle component and a vehicle.

In the automotive sector, light design, such as a light design of light functions, for example of signal light functions, is becoming more and more important and elements on the vehicle are also increasingly being illuminated, i. H. provided with active lighting elements that were previously unlit.

In order to realize a light design of the light of previous lights, for example previous signal lights, in the automotive sector, reflectors, diffusers, diffusers, OLEDs (organic light-emitting diodes), light guides with a round cross-section or other refractive optical elements are used.

The object of the present invention is to create a light guide device which is simple and inexpensive in terms of device technology and which can be used to fulfill a (signal) light function and / or to produce an aesthetically pleasing lighting. Another object of the invention is to create a simple and inexpensive vehicle component in terms of device technology and a vehicle which is simple in terms of device technology and inexpensive, each having a light guide device that can be used to fulfill a (signal) light function and / or to provide aesthetically pleasing lighting to create.

The object with regard to the light guide device is achieved according to the features of claim 1. Furthermore, the object with regard to the vehicle component is achieved according to the features of claim 12, and the object with regard to the vehicle is achieved according to the features of claim 14.

Particularly advantageous configurations can be found in the dependent claims.

According to the invention, a light guide device with at least one coupling surface for light from at least one light source is provided. The light guide device furthermore has at least one, in particular elongate, light guide and at least one light guide component which is integrally connected to the light guide. The at least one coupling surface is preferably formed in the light guide. The light guide has at least one decoupling structure in order to decouple part of the light coupled into the light guide device in a directed manner, in particular via a decoupling surface of the light guide. In other words, the light guide has at least one coupling-out structure, in particular a plurality of coupling-out structures, in order to couple out light in a bundled manner and thus create, for example, illumination that is dependent on the viewing angle. Furthermore, the light guide component has at least one decoupling structure, via which part of the light coupled into the light guide device, in particular via a decoupling surface of the light guide component, can be diffusely decoupled. In other words, the light guide component has at least one coupling-out structure, in particular a plurality of coupling-out structures, in order to couple out light in an undirected manner, in order, in particular, to create illumination that is independent of the viewing angle.

It is advantageous in this invention that the light emerging from the light guide, which is directed or bundled out, a light function of a vehicle, in particular a signal light function or lighting function, for example a turn signal and / or a brake light and / or a position light and / or a daytime running light and / or a side marker light, can be fulfilled and an aesthetically pleasing design effect can be achieved by the light that diffusely decouples from the light guide component via the at least one decoupling structure. Furthermore, the light guide device is very cost-effective, since the design effect as well as the light function can be fulfilled by a common light source, the light of which is coupled into the light guide device. Another advantage is that the light guide device is easily customizable, i. This means that the light guide and the light guide component can have the most varied of shapes and can thus be easily adapted to different areas of application. For example, the light guide device as a whole can have the shape of a vehicle component, in particular the shape of a vehicle headlight, a bumper, a decorative panel, and the light guide can be used, for example, for a turn signal, a position light, a side marker light, while the light guide component creates a design effect on the vehicle .

The signal light function (s) is / are preferably a turn signal function and / or a brake light function and / or a taillight function and / or a daytime running light function and / or a position light function and / or a fog light function and / or a combination and / or a partial function of the above and other functions intended.

A cornering light function and / or a fog light function and / or a low beam function and / or a high beam function and / or a combination and / or modification (for example Adaptive Driving Beam (ADB) or Adaptive Frontlighting System (AFS)) and / or part of the above as well further functions may be provided. AFS is an adaptive system that preferably controls all lighting functions or at least some of the lighting functions adaptively. It can be used, for example, in the low beam and high beam function and can provide a motorway light and / or a bad weather light and / or a city light. ADB is preferably used for high beam and can provide a glare-free high beam. For example, ADB is part of AFS.

It is also advantageous if the coupling surface of the light guide device is part of the light guide. In other words, the light source is preferably arranged in such a way that its light can be coupled directly into the light guide. This is advantageous because light can thus be coupled directly into the light guide and thus, for example, a larger part of the light that can be coupled into the light guide device via the coupling surface can be coupled out from the at least one output structure of the light guide and can thus be coupled out in a directional manner. Since the light coupled out by the light guide can thus have a high level of brightness, a light signal function, such as a brake light and / or a blinker and / or a daytime running light, can easily be implemented. As an alternative or in addition, the light guide component can have a coupling-in surface. It is also possible for the light guide device to have a plurality of coupling-in surfaces, one of the coupling-in surfaces in particular being part of the light guide.

The light guide can have an outer jacket surface, which is in particular a light guide surface. The light guide can preferably be at least partially enveloped by the light guide surface in order to guide light through the light guide. The light guide surface can be part of the light guide. The light guide component can, for example, be connected or formed in one piece with the light guide on the outer jacket surface or the light guide surface. That is, the outer jacket surface of the light guide can in particular be connected in one piece to an outer jacket surface of the light guide component.

Furthermore, viewed in a longitudinal direction of the, in particular elongated, light guide, the light guide component can project away from the light guide in one piece over part of the length of the light guide or over the entire length of the light guide. In particular, the light guide component can protrude away from the light guide surface of the light guide so that no light guide surface is provided in a connection area between the light guide component and the light guide. This means that the light guide surface of the light guide is pierced by the light guide component in an area where the light guide component is connected in one piece to the light guide. This is advantageous because in this way the light that is coupled in via the coupling surface can propagate in the, in particular the entire, light guide device. In particular, the light guide component protrudes from this, in particular over the entire length, of the, in particular elongate, light guide, for example in the form of a plate.

Alternatively, the light guide component, viewed in the longitudinal direction of the light guide, can protrude through part of the length of the light guide or over the entire length of the light guide, in particular perpendicular to the light guide, through the light guide. This is advantageous because a design effect is thus produced when the light guide device is viewed from above. If a person looks at the light guide device configured in this way, they can perceive the directed light that is decoupled from the light guide and diffuse light that decouples from the light guide component, the directed light being enclosed on both sides by the diffuse light in this exemplary embodiment .

In addition, viewed in its longitudinal direction, the, in particular elongated, light guide can protrude in sections or over its entire length from at least one outer jacket surface of the light guide component. This means that the light guide is connected in sections over its length or over its entire length to the light guide component, so that one section of the light guide protrudes from the light guide component and the other section lies within the light guide component. For example, the light guide component, in particular elongated, protruding from the light guide component, which is designed, for example, in the form of a plate and extends, for example, along a curve that can in particular be mathematically describable. The curve can extend two-dimensionally, that is to say in a plane, or three-dimensionally, that is to say in space.

The light guide can, for example, have a round or elliptical or rectangular or square or “keyhole-shaped” cross section. In particular, a partial section of the light guide protrudes from the light guide component, so that the light guide has a round or elliptical cross section, in particular with a flattened side or long side. Furthermore, it is also possible for the light guide to have a rectangular or square or triangular or polygonal or arcuate or hollow cylindrical cross section. In the automotive sector in particular, the light guide can also have a “keyhole-shaped” cross section. This means that the light guide protrudes from the light guide component with an essentially rectangular cross section, which is followed by a round cross section. In other words, the light guide can have a first stem-shaped section, with which protrudes from the light guide component, and the stem-shaped section can be followed by a round section which is further away from the light guide component than the stem-shaped section. The light guide component can for example protrude from the stem-shaped section or from the round section. It is also possible for part of the light guide component to protrude from the stem-shaped section and a further part to protrude from the round section. It is also possible for the cross-sectional shape to be free-form. In particular, the cross-sectional shape of the light guide can be designed as a function of what effect the cross-sectional shape of the light guide has on the light coupled out from the light guide via the at least one coupling-out structure. The cross-sectional shape can vary over the length of the light guide. The light guide can be shaped, for example, in such a way that the cross-sectional shape of the light guide can produce, for example, a lens effect that can act on the light decoupled from the light guide. This is particularly advantageous because the light that is coupled out from the light guide can be influenced so that the coupled out light is visible, for example, from an enlarged viewing angle.

It is also possible for the light guide to protrude on both sides from the light guide component, which in this exemplary embodiment is in particular plate-shaped, ie. H. protrudes from facing away from outer jacket surfaces of the light guide component. For example, the light guide can have an essentially round cross section, which is pierced by the light guide component, in particular centrally or offset from the center. In other words, a section of the light guide can protrude from an outer jacket surface of the light guide component, another section can lie within the light guide component and a further section can protrude from the outer jacket surface of the light guide component pointing away from the first section. This can also have effects on the light decoupled from the light guide, and thus a light image that is generated via the light guide component can be further adapted to various application requirements and design wishes.

In a further exemplary embodiment, the light guide can be formed flush with the light guide component on at least one side thereof. That is to say, the light guide cannot protrude from the light guide component at least on one side thereof. It is possible, for example, for the coupling-out surface of the light guide to form a flat surface with a surface of the light guide component. This means that the light guide with its coupling-out surface does not protrude from the light guide component.

Furthermore, the light guide can extend along at least one curve, which is curved or has different curvatures, i. that is, which can in particular be described mathematically, or extend along a straight line. The curve can, for example, be a spline curve and / or be defined in sections. The light guide can also be two-dimensional, i.e. H. extend in one plane or three-dimensionally in space. This is advantageous because there are thus a large number of different possibilities for designing the light guide and thus the light guide can be easily adapted to different areas of application. For example, this can be arcuate in order to adapt to a shape of a body part of a vehicle on which the light guide device is attached.

In a further exemplary embodiment, it is possible for a size and / or a shape of the cross section of the light guide to vary along its longitudinal direction. For example, the light guide can be "keyhole-shaped" in a first section and polygonal in a second section, wherein a transition section can be provided between the sections in which the "keyhole-shaped" cross section of the light guide gradually merges into a polygonal cross section of the light guide. This is advantageous because a wide variety of possibilities arise for designing the light guide.

The light guide component is preferably plate-shaped, wherein the light guide component can extend in a plane or three-dimensionally in space. This is advantageous because the light guide device can easily be integrated into installation spaces that do not expand far, in particular in one spatial direction, that is to say that the light guide device can be integrated into installation spaces that are narrow. The plate-shaped light guide component preferably has two outer circumferential surfaces, which are preferably at least partially at a parallel distance from one another and have a comparatively small distance from one another. Between these outer lateral surfaces, a further peripheral outer lateral surface is formed, which is preferably oriented approximately perpendicular to the two first outer lateral surfaces. In a further exemplary embodiment, the edge-side outer jacket surface can be rounded and / or and / or have a rounding and / or a chamfer for a specific function. For example, the edge-side outer jacket surface can be designed as a fastening means, for example as part of a tongue and groove connection. This is advantageous because the light guide device can thus easily be connected to a further component. The two parallel outer circumferential surfaces are preferably designed the same or only differ slightly in their shape. For example, they can be round or be rectangular or triangular or free-form. The shape of the light guide component can, in particular, be easy to describe using mathematical conditions. This is advantageous because the light guide component can thus be easily manufactured. However, it is also possible for the light guide component to be of free-form design. This is particularly advantageous because the light guide device can be integrated into an installation space of any shape or the light guide component can form a vehicle component, in particular a body part. For example, the light guide component can be a bumper or a decorative panel or a vehicle door or an engine compartment lid or a trunk lid.

The light guide component can furthermore be designed in the form of a plate, with different areas of the light guide component being able to be designed with different thicknesses. For example, the light guide component can be made thicker in the edge area and / or around the light guide than in the remaining area. Furthermore, it is also possible for the light guide component to have reinforcing struts. This is advantageous since the stability of the light guide device can be increased in this way.

In one exemplary embodiment, the light guide device can be integrated in at least one vehicle component, in particular a body part, for example in a bumper or in a decorative panel, or can be connected to at least one vehicle component. Furthermore, the light guide device can be designed as a vehicle component, in particular a body part. In particular, the light guide component can be designed as a vehicle component. For this purpose, the light guide device can, for example, have at least one fastening means with which it can be connected to the vehicle component in a form-fitting and / or force-fitting and / or cohesive manner. The fastening means is preferably arranged in such a way that it is not visible when looking at the light guide device attached to the vehicle that has the vehicle component.

Furthermore, it is possible for the light guide device to have at least one receptacle for a sensor and / or some other component. The receptacle can in particular be arranged on one side of the light guide device that is not visible in an assembled state. For example, if the light guide device is provided, for example, on a bumper or forms the bumper, an ultrasonic distance sensor can be accommodated in the receptacle. The receptacle can, for example, be a recess or a holder.

In a further exemplary embodiment, the light guide device can have at least two light guides, which in particular are each connected in one piece to the light guide component. For example, the light guides can run parallel to one another or also cross and / or touch one another. The light guides can each be described by different mathematical curves. The light guides can be designed to be the same, similar or completely different in terms of length, shape, course, cross section, etc. This is advantageous because it creates a variety of design options. It is also conceivable that a respective light guide carries out a light function and / or several light guides jointly carry out a light function and / or a combination thereof.

The coupling-out structure of the light guide component is arranged in particular on a side of the light guide component that points away from the coupling-out surface of the light guide component. In other words, the at least one outcoupling structure of the light guide component is not arranged on the outcoupling surface of the light guide component, but in particular on a surface pointing away therefrom. In particular, the light is reflected by the at least one coupling-out structure of the light guide (preferably via total internal reflection) and guided to the coupling-out surface. In particular, the coupling-out surface of the light guide component is smooth, while the side facing away from it has at least the one coupling-out structure. This is advantageous because the decoupling structure is thus not visible to an observer in the switched-off state. In the switched-on state, the structure of the coupling-out structure can be recognized by a light image emitted by the light guide device.

In order to decouple light diffusely from the light guide component, the light guide component preferably has a multiplicity of decoupling structures. These can be formed, for example, in that, for example, recesses or thickenings or projections, which are hemispherical, for example, are introduced into the light guide component. For example, the coupling-out structures are irregular, i. H. For example, asymmetrically and not in an orderly manner, arranged in order to couple light out of the light guide component in a diffuse and non-directional manner. This is advantageous because the illumination that is independent of the viewing angle can thus be generated. It is also possible that hemispherical recesses or projections are arranged regularly.

It is also possible for light to be coupled out from the light guide component via a rough surface. This means that a surface, in particular the surface facing away from the coupling-out surface, is rough. Light can be at the reflect the rough surface and decouple it via the decoupling surface. The rough surface can be produced, for example, by roughening with a laser. It is also possible that this can be generated during a manufacturing process of the light guide device, for example by casting or injection molding the light guide device.

In a further exemplary embodiment, the light guide component can have at least two different outcoupling structures, so that the light guide component has at least two regions with light outcoupling of different strengths. The light outcoupling can be different depending on the number and / or density and / or size and / or shape of the outcoupling structures. This means that the light guide component preferably has two areas which each have a different density and / or number of outcoupling structures and / or the size and / or shape of the outcoupling structures of the different areas is different.

It is also advantageous if at least one outer jacket surface of the light guide component, from which the light guide preferably protrudes, is at least partially a decoupling surface for light coupled into the light guide device, and the light guide surface or outer jacket surface of the light guide, which adjoins this decoupling surface, is the decoupling surface of the light guide is. That is, the at least one coupling-out structure of the light guide and the light guide component are preferably arranged on the same side of the light guide device. This is advantageous because the light that is coupled into the light guide device via the coupling surface of the light guide device is coupled out of the light guide device in one direction, so that a viewer of the light guide device preferably perceives the light that is coupled out of the light guide device. In other words, the light that is coupled into the light guide device is preferably decoupled from the light guide device in such a way that it can be perceived as a whole by a viewer.

The at least one coupling-out structure of the light guide is arranged on a side of the light guide that points away from the coupling-out surface for light that is coupled into the light guide device. In other words, the at least one coupling-out structure of the light guide is not arranged in the coupling-out area of the light guide. In particular, the light is reflected by the at least one coupling-out structure of the light guide and guided to the coupling-out surface. In particular, the at least one decoupling structure of the light guide is prism-shaped, d. H. the light guide has at least one prism-shaped recess and / or elevation on the side facing away from the coupling-out surface. In particular, the prism-like coupling-out structure is a reflection prism which is introduced into the light guide as a recess or is applied to it as a raised portion. The at least one prism-like coupling-out structure is preferably formed on the side of the light guide device that points away from the side from which the light is coupled out. The coupling-out structure can penetrate at least part of the cross section of the light guide. In particular, light that propagates in the light guide is coupled out from the coupling-out structure at least partially through the coupling-out structure embodied as an optical prism. Depending on the design or shape of the prism-shaped cutout, the direction in which light is coupled out of the light guide or the amount of light which is coupled out via the coupling out structure changes. It is also possible for the prism-like coupling-out structure to have at least one non-planar, but rather curved surface. This can be advantageous since a width of a light cone that can be coupled out via the coupling-out structure can be set.

The light guide preferably also has at least two coupling-out structures, in particular a multiplicity of coupling-out structures. In particular, the coupling-out structure of the light guide can be designed in such a way that light is evenly coupled out over the length of the light guide. The light guide preferably has a plurality of coupling-out structures. These can, for example, be made smaller in an area that is closer to the coupling surface than in an area that is further away from the coupling surface in order to regularly couple light from one end of the light guide to the other end. In particular, the number and / or the size and / or the spacing and / or the geometry of the coupling-out structures of the light guide can be dependent on the size and / or the length of the light guide. For example, the number of decoupling structures 10 to several hundred. The width of a light cone of the light that is coupled out by the light guide via the plurality of coupling-out structures can be adjusted via the distribution, an angular distribution and / or size of the coupling-out structures.

In a further exemplary embodiment, the light that is coupled out via the at least one coupling-out structure of the light guide component and / or the light guide can couple into a further optical element. For example, the coupling-out surface of the light guide component and / or the light guide can be followed by a screen, which is formed in particular from lacquer. It is also possible that the light that is decoupled from the light guide component and / or the light guide, for example, in a cover plate, which is formed in particular from a refractive material, and / or in a mirror as an alternative or in addition to the above mentioned aperture. This means that the light guide component and / or the light guide can - in particular also partially - be covered by further functional materials / layers, such as, for example, metals and / or lacquers and / or primers and / or foils and / or multi-layer systems. This is advantageous since protection of the component, for example from environmental influences (for example UV protection, protection against falling rocks), can be guaranteed. In addition, such a layer can increase the aesthetic appearance of the component. For example, the light guide device can have at least partially metal-coated, for example chrome-plated, surfaces and / or colored painted surfaces. Combinations are also possible, for example metallic paint with "metal flakes" in the paint.

If an optical element is present, the coupling-out can also be changed as a result - in particular also differently in different areas. If, for example, the optical element is a layer, such as a lacquer, this can have different thicknesses in different areas of the light guide and / or the light guide component and / or be made of different materials. In particular, this also includes a partial and possibly varying perforation of the layer. Thus, the coupling out of light can be influenced by the different layer thicknesses or the different materials.

The at least one light source of the lighting device can each be a light emitting diode (LED) and / or an organic LED (OLED) and / or a laser diode and / or a laser activated remote phosphor (LARP) principle working light source, and / or as a halogen lamp, and / or as a gas discharge lamp (High Intensity Discharge (HID)), and / or in connection with a projector working according to a digital light processing (DLP) principle. Thus, a variety of alternatives are available as a light source.

The light source (s) can be white (e.g. also warm white and / or cold white) and / or yellow and / or orange and / or red and / or blue and / or green or some other color. Several colors can also be combined in one component (e.g. using "color wheels" or different "sub-light sources"). The colors and / or radiation angles can be modified by downstream / intermediate optics (in particular also already integrated in the component light source). Examples of this are conversion dyes (typically e.g. with "white" LEDs, which are implemented by blue LEDs with partially yellow converters), silicone lenses (on LEDs) or "only" the glass bulb of a HID or halogen lamp.

In particular, light from at least two light sources, in particular from a multiplicity of light sources, can be coupled into the light guide device. The light from the at least two light sources can be coupled in, for example, via a common coupling surface of the light guide device. However, it is also possible for the light guide device to have several, in particular different, coupling-in surfaces which are arranged in particular on the light guide. In particular, coupling surfaces can be provided on the two end surfaces of the elongated light guide. It is also possible that a coupling-in surface can be on the surface of the light guide on which the at least one coupling-out structure of the light guide is arranged. In particular, the at least one coupling-out structure can additionally serve as a coupling-in surface for light from a light source. Additionally or alternatively, light can also be coupled into the light guide component, with the positioning of the coupling surface of the light guide component being dependent on the installation space and / or design. That is, for example, at least one light source can be provided where the installation space allows it and offers sufficient space and / or where the light source is not visible from the outside, for example when viewing a vehicle component on which the light guide device is provided.

The light sources can in particular be controlled individually, for example via a control unit, in particular via a control unit of a vehicle, on which the light guide device can be attached. This is advantageous because different light patterns can thus be generated, depending on which light sources are switched on. As an alternative to this, control takes place in individual chains or rows, i.e. at least two light sources are connected together.

In particular, at least two light sources emit light with a different color. These can be switched on and off at the same time or at times at the same time or independently of one another and not at the same time, in particular via the control unit. This means that a wide variety of light patterns can be created. For example, light sources that emit different colors can be switched on at the same time, and thus a mixed color can be emitted via the light guide device.

It is advantageous if the light guide device has at least one collimator and / or an optically active surface, which is, for example, free-shaped, as a coupling structure. This can in particular be dependent on the area of application in which the light guide device is to be provided. In particular, the collimator is a "total internal reflection" (TIR) collimator, so effectively at light as possible to bundle and couple into the light guide device.

In particular, a vehicle component with the light guide device is provided. The vehicle component can in particular be a vehicle headlight, but it is also possible that the vehicle component is, for example, a fender or a bonnet or a trim panel or a bumper or a vehicle door or a tailgate or another body part of a vehicle.

Furthermore, a vehicle with the light guide device is provided. The vehicle can be an aircraft or a water-based vehicle or a land-based vehicle. The land vehicle can be a motor vehicle or a rail vehicle or a bicycle. The vehicle is particularly preferably a truck or a passenger car or a motorcycle. The vehicle can also be designed as a non-autonomous or partially autonomous or autonomous vehicle.

A light guide device having a light guide and a light guide component is disclosed, wherein the light guide and the light guide component are integrally connected. The light guide device also has at least one coupling surface for light from at least one light guide component. The light guide has at least one decoupling structure in order to directionally decouple part of the light coupled into the light guide device, and the light guide component has at least one decoupling structure in order to diffusely couple out part of the light that is coupled into the light guide device. A vehicle component and a vehicle are also disclosed.

• Anordnung für ein Fahrzeug, die zumindest ein Fahrzeugbauteil mit einem optischen Element und/oder mit einer Lichtquelle hat, wobei das Fahrzeugbauteil und eine Lichtauskoppelfläche des optischen Elements und/oder eine Lichtauskoppelfläche der Lichtquelle eine, insbesondere gemeinsame und/oder durchgängige und/oder einheitliche, Fläche bilden, die mit einer lichtundurchlässigen Schicht versehen ist, wobei zumindest ein Abschnitt der Schicht in einem Bereich der Lichtauskoppelfläche des optischen Elements und/oder der Lichtauskoppelfläche der Lichtquelle perforiert ist.

The applicant reserves the right to make an independent claim on the following:

• An arrangement for a vehicle which has at least one vehicle component with an optical element and / or with a light source, the vehicle component and a light coupling-out surface of the optical element and / or a light coupling-out surface of the light source having, in particular, a common and / or continuous and / or uniform, Form a surface which is provided with an opaque layer, at least a portion of the layer being perforated in a region of the light coupling-out surface of the optical element and / or the light coupling-out surface of the light source.

The optical element can, for example, be the light guide device, and the light guide component of the light guide device can, for example, form a common and / or continuous and / or uniform surface with the vehicle component. This surface can be coated with the opaque layer, for example with lacquer. The opaque layer on the light guide device can, for example, be partially or partially perforated. For example, part of the light guide of the light guide device can be heavily perforated, so that a lot of light can be coupled out of the coupling-out surface of the light guide, and the light guide component can be less strongly perforated, so that less light can escape. It is also possible for the light guide and / or the light guide component to have different sections that are perforated differently. In particular, at least one perforated section can form a character such as a logo.

• 1a und 1b jeweils eine (unterschiedliche) perspektivische Ansicht einer Lichtleitervorrichtung gemäß einem Ausführungsbeispiel,
• 2a und 2b jeweils eine (unterschiedliche) perspektivische Ansicht eines Lichtbilds der Lichtleitervorrichtung der 1a und 1b,
• 3 eine Querschnittansicht einer Lichtleitervorrichtung gemäß einem weiteren Ausführungsbeispiel,
• 4 eine perspektivische Ansicht einer Lichtleitervorrichtung gemäß einem weiteren Ausführungsbeispiel, und
• 5 eine Draufsicht einer Lichtleitervorrichtung gemäß einem weiteren Ausführungsbeispiel.

In the following, the invention is to be explained in more detail on the basis of exemplary embodiments. The figures show:

• 1a and 1b each a (different) perspective view of a light guide device according to an embodiment,
• 2a and 2 B each a (different) perspective view of a photograph of the light guide device of FIG 1a and 1b ,
• 3 a cross-sectional view of a light guide device according to a further embodiment,
• 4th a perspective view of a light guide device according to a further embodiment, and
• 5 a plan view of a light guide device according to a further embodiment.

1a shows an optical fiber device 1 with an elongated light guide 2 extending along a straight line and an optical fiber component 4th that are integral with the light guide 2 connected is.

The light guide component 4th is plate-shaped, that is to say cuboid with a small height, and has a rectangular basic shape. That is, the light guide component 4th has two large rectangular outer circumferential surfaces that are parallel to each other. Furthermore, the two outer jacket surfaces are congruent. The light guide protrudes from one of these outer circumferential surfaces 2 which has a round shape in cross section with a flattened side, the flattened side with the outer surface of the light guide component 4th connected is. In other words, the light guide has 2 essentially a semicircular cross-section. It is also possible that the light guide 2 Is formed in the shape of a segment of a circle and due to the one-piece design with the light guide component 4th appears semicircular.

The light guide 2 also extends from a short edge of the rectangular outer jacket surface, from which it protrudes, to the other short edge of the rectangular outer jacket surface of the light guide component 4th so that the light guide 2 the outer surface of the light guide component 4th divides into two equal halves. The light guide component 4th cantilevered in a longitudinal direction of the light guide 2 Over the entire length of the light guide on both sides and rectangular and symmetrical from the light guide 2 the end.

There is also a coupling area 6th the light guide device 1 on one of the semicircular bases or end faces of the elongated light guide 2 intended. It is also possible that both base areas of the elongated light guide 2 Are coupling surfaces. A light source whose light enters the coupling surface 6th can be coupled in is not shown here. The light that enters the coupling surface 6th Can be coupled in can be via a coupling-out surface 8th of the light guide 2 uncouple directed or bundled. The light coming through the coupling surface 6th is coupled in via at least one coupling-out structure, which is not shown here, since it is located on the of the coupling-out surface 8th of the light guide 2 facing away surface is located to the decoupling surface 8th of the light guide 2 guided. The decoupling surface 8th is U-shaped or semicircular in cross-section and is connected to the outer surface of the light guide component 4th connected from which the light guide 2 protrudes. That is, the coupling-out area 8th is at least part of the outer surface of the light guide 2 . The outer surface of the light guide component 4th , from which the light guide 2 protrudes, can also be a decoupling surface 10 be over the light that over the coupling surface 6th can be coupled in, diffusely via at least one coupling-out structure of the light guide component 4th , which is not shown here, can be decoupled. The light couples from the coupling-out surface 10 diffuse and / or omnidirectional, that is, there is illumination that is independent of the viewing angle due to the light emanating from the coupling-out surface 10 decoupled, generated. That is, the angular distribution of the light emission of the light guide component 4th is different from that from the light guide 2 .

In 1b is the light guide device 1 shown from a different perspective. It is the one from the side from which the light guide is coming from 2 cantilevered away, pointing side of the light guide device 1 shown. In 1b is shown that the light guide 2 a plurality of decoupling structures 12th having. These are on the of the decoupling surface 8th groundbreaking side of the light guide 2 and are arranged in series in such a way that they have the shape of the light guide 2 correspond. The decoupling structures 12th can be, for example, individual prism-like recesses that are in the light guide 2 are introduced. Light coming through the coupling surface 6th , s. 1a , is coupled in, can of the coupling-out structures 12th are reflected and to the decoupling surface 8th of the light guide 2 be guided.

The side of the fiber optic component 4th that of the decoupling surface 10 the light guide component 4th points away, can also have decoupling structures that are small and irregular, provided on this side. Since these coupling-out structures are small, they are not shown for the sake of simplicity. For example, the outer circumferential surface from the coupling-out surface 10 the light guide component 4th pointing away, be roughened so that light enters the coupling surface 6th coupled in, diffuse and non-directional from the coupling-out surface 10 decoupled.

In 2a is a photograph shown taken from the light guide device 1 is emitted when light enters the coupling surface 6th couples and the light guide device 1 viewed from a top view.

It can be seen that light is emitted from the coupling-out surface 8th of the light guide 2 over the entire length of the light guide 2 decoupled. Light coming from the coupling-out surface 8th of the light guide is decoupled, is directed and therefore appears bright (er) in the viewing direction. The periodic light and dark stripes originate from the coupling-out structures, with a single stripe therefore perpendicular to a longitudinal direction of the light guide 2 extends.

From the coupling area 10 the light guide component 4th also couples out light, in particular in an area that is close to the coupling surface 6th the light guide device 1 is arranged because the coupling-out structure of the light guide component 4th has not been optimized for homogeneity. In other words, the light couples into the light guide device 1 is coupled, from the light guide component 4th rather from an area of the decoupling surface 10 from that is close to the coupling surface 6th is located. The further away from the coupling surface 6th an area of the coupling-out surface 10 is, the less light is coupled out. From the coupling area 10 the light guide component 4th decouples the light diffusely, which is why a large part of the light guide component in particular appears relatively dark from this viewing direction.

In 2 B there is shown a light image generated when entering the light guide device 1 over the coupling surface 6th Light is coupled, and the light guide device 1 is viewed in perspective, so that the decoupling surfaces 10 the light guide component 4th and the coupling-out area 8th of the light guide 2 are viewed at an angle of approx. 45 °.

Because the light from the coupling-out surface 8th of the light guide 2 is coupled out directionally, is the light image that is produced by the light guide 2 is emitted depending on the viewing angle. That means, depending on the viewing angle, the light image that comes from the light guide changes 2 is emitted. The decoupling structure 12th , s. 1b , is designed in such a way that the light that passes through the coupling-out surface 8th coupled out, rather when considering the light guide device as in 1a is visible, that is to say that a beam angle of a light cone that passes over a respective one of the decoupling structures 12th is decoupled, is rather small. Hence the light that comes out of the light guide 2 decoupled, s. 2 B , when considering the decoupling surfaces 10 the light guide component 4th and the coupling-out area 8th of the light guide 2 at an angle of approx. 45 ° rather less visible or has compared to the viewing direction 2a significantly less intensity (is "darker").

From the viewing direction of the 2 B you can mainly see the light image that comes from the light guide component 4th is generated.

3 Fig. 10 shows a cross-sectional view of a light guide device 14th of another embodiment. The light guide device 14th has 3 light guides 16 , 17th , 18th , 20th and an optical fiber component 22nd on.

The light guides 16 , 18th , 20th collar on one side of the light guide component 22nd from which the light that enters the light guide device 14th is coupled, decoupled. The light guide 17th protrudes on the side pointing away from it.

The light guide component 22nd of this embodiment, as well as the light guide component 4th the 1a , approximately plate-shaped, the plate thickness of the light guide component 22nd varies over the cross section and the plate-shaped light guide component 22nd is additionally bent or curved in one area. The curved area is located in an edge area of the light guide component 22nd and is weakly bent or curved in a direction from the side from which the light guide is taken 16 , 18th , 20th protrude, pointing away, while the remaining area of the light guide component 22nd is not curved, that is, is flat. The arc is approximately 45 °.

In the area in which the arcuate edge area adjoins the area which is planar, the light guide component has 22nd also a thickening. On the side of the light guide component 22nd facing away from the side from which the light guides 16 , 18th , 20th protrude, the thickening is formed like a bump in cross section. On the side facing away from the bulge-like projection, the thickening is approximately ramp-shaped and becomes steadily thicker. The light guide component 22nd becomes steadily thicker in cross section from the arcuate edge area, then retains a uniform thickness and then becomes steadily thinner again. In the area where the light guide component 22nd has a uniform thickness in cross section, is the light guide 16 arranged.

The light guide 16 protrudes from the light guide component 22nd with a first section which is rectangular in cross section, and the rectangular section is followed by a section which is round in cross section. The light guide 16 is therefore "keyhole-shaped". In other words, the light guide cantilevers 16 from the light guide component 22nd stem-shaped in a first section, followed by a round cross-sectional section. There is also a round light source 24 at a coupling surface 26th which is a base or end face of the round section of the light guide 16 is shown whose light enters the light guide device 14th coupled.

In an area that is close to the area of the light guide component 22nd connects, in which the cross section of the light guide component 22nd becomes steadily thinner, another area follows, in which the cross-section has a constant thickness. This area of the fiber optic component 22nd is thinner than the area from which the light guide 16 protrudes. The light guide protrudes from this area 17th on the opposite side of the light guide 16 the end. That is, the light guide 17th is on the side from which this enters the light guide device 14th Coupled light coupled out, flush with the light guide component 22nd educated. The light guide 17th is free-shaped in cross-section with a wide flattened (linear) section. Furthermore, this has a coupling surface 27 on, in which the light from three round light sources 28 coupled. These are in series in the direction of extension of the light guide component 22nd arranged. That is, the three light sources 28 couple their light into the common coupling surface 27 a. The light sources 28 can each be designed, for example, as an LED and can, for example, emit light with a different color in each case. Furthermore, it is possible for these to be individually controllable via a control unit, which is not shown here.

The light guide component 22nd maintains a constant thickness in connection with the light guide 17th at. The light guide cantilevers there 18th from, which is also formed in the shape of a segment of a circle. The light guide 18th protrudes on the side from which the light guide 16 cantilevered, and from the side from which the light guide 17th protrudes, points away. The light guide 18th has a coupling surface 29 on, in which the light is a light source 30th coupled. The light guide 18th is in an area of the light guide component 22nd arranged in which this seen in cross section from a thinner area merges into a thicker area.

The further light guide protrudes from the thicker area 20th from the light guide component 22nd the end. This is approximately semi-elliptical in cross section. The elliptical light guide 20th also has a coupling surface 32 on, in which the light is a light source 34 can be coupled. The light source is not symmetrical on the coupling surface 32 arranged, but is on one side of the light guide 20th placed closer to the light guide 18th is.

The light that comes out of the coupling structures of the light guide component 22nd that are not shown here, coupled out, coupled into an optical element 35 a. The optical element 35 for example, the entire side of the light guide component 22nd , from which the light guide 16 , 18th , 20th cantilever, cover. For example, the optical element 35 be a varnish. Light coming out of the light guides 16 , 18th , 20th decouples, does not couple into the optical element 35 a. Outer jacket surfaces of the light guides 16 , 17th , 18th , 20th are for example free and not through the optical element 35 covered.

Light coming out of the light guide 17th coupled out, coupled into a further optical element 36 a. This can also, for example, like the optical element 35 , be formed from paint. The optical elements 35 , 36 can for example be made of different materials and / or have different colors. Alternatively or additionally, it is possible that these are perforated, in particular by a laser, the respective perforation of the optical elements 35 , 36 preferably differ from one another, so that different optical effects can be generated.

In 4th Figure 3 is another embodiment of an optical fiber device 37 shown that, as well as the light guide device 1 the 1a , a plate-shaped, rectangular, cuboid-shaped light guide component 38 having. That is, the light guide component 38 has two large rectangular outer circumferential surfaces that are parallel to each other and congruent. Furthermore, the light guide device 37 a light guide 40 which has a round cross-sectional shape with a flattened side, the flattened side being arranged on one side, the at least one coupling-out structure of the light guide 40 which is not shown here.

The light guide 40 is arcuate or curved and integral with the light guide component 38 tied together. One end of the curved, elongated light guide 40 is in one corner of the plate-shaped light guide component 38 educated. The light guide 40 extends approximately in a 90 ° arc. The other end of the elongated light guide 40 is on one long side of the rectangular light pipe component 38 located and closer to a corner of the light pipe component 38 that is diagonally opposite the corner of the light guide component 38 is at the other end of the light guide 40 is arranged.

The light guide 40 cantilevered on one outer lateral surface of the light guide component 38 and also on the outer lateral surface of the light guide component pointing away from it 38 the end. In other words, the light guide component projects 38 from the arched light guide 40 away so that the cross section of the light guide 40 from the fiber optic component 38 is broken. As well as from the light guide 2 the 1a couples light coming into the light fixture 37 is coupled in from a coupling-out surface 42 of the light guide 40 directed or bundled. From a decoupling surface 44 the light guide component 38 couples light entering the light guide device 37 is coupled, diffuse or omnidirectional.

In this exemplary embodiment, the coupling-out surface 44 the light guide component 38 five different light extraction areas 46 , 48 , 50 , 52 , 54 on. The coupling-out structures of the light guide component 38 , which are not shown here, and the light outcoupling areas 46 to 54 are assigned are each different. The light extraction areas 46 to 54 are on the plate-shaped light guide component 38 one side of the light guide 40 arranged. The section of the outer jacket surface of the light guide component 38 on the other hand, there is no light extraction area and no light extraction. The light extraction area 46 is directly on the light guide 40 arranged and follows its shape and is thus arcuate. This is followed by the light decoupling area 48 on and on these the light decoupling area 50 . The light extraction area 52 is essentially elliptical with the essentially elliptical light extraction area 54 trained in its center. From the light extraction area 46 For example, more light can be coupled out per unit area than, for example, in the area 48 . This means that the light decoupling area would be for a viewer 46 appear brighter than the light extraction area 48 . For this purpose, in particular, the outcoupling structures of the light outcoupling areas 46 and 48 differently designed. For example, they can differ in that they have a different number of coupling-out structures, the size of the coupling-out structures and the density of the coupling-out structures and the shape of the coupling-out structures are different.

It is possible that the light guide device 37 is coated with a clear coat that is translucent and / or transparent. In particular, the coupling-out area 42 of the light guide 40 and the Decoupling surface 44 the light guide component 38 painted or coated with clear lacquer. The clear lacquer layer is preferably designed as a protective layer and therefore as the last layer, preferably on an entire surface of the light guide device that is visible from the outside 37 educated.

The light extraction areas 50 , 52 , 54 are coated or lacquered with at least one opaque lacquer layer. The opaque lacquer layer is preferably arranged under the clear lacquer layer. This means that the light shines from the clear coat into the coat of paint. The lacquer layer was partially removed, in particular by means of a laser. That is, the light decoupling areas 50 , 52 , 54 have lacquer perforations that are each designed differently.

The light extraction area 50 is covered in percentage more with the opaque lacquer layer than the light decoupling area 52 or the light extraction area 54 . That is, if the light decoupling areas 50 , 52 , 54 have the same coupling-out structure, is that of the light coupling-out area 50 emitted light that can be perceived by a viewer is darkest in comparison. That is, from the light extraction area 50 little light is emitted per unit area. The lacquer layer of the light extraction area 50 is regularly punctiform perforated. The light extraction area 52 is coated with a multitude of lacquer dots. This means that the majority of the paint layer has been removed. The lacquer layer of the light extraction area 52 reduces the amount of light output per unit area only slightly compared to an uncoated light output area. This means that a viewer perceives the light coupling-out area as being brighter than, for example, the light coupling-out area 50 or 54 . In the light extraction area 54 the paint layer is removed in strips. This means that it has stripe-shaped lacquer fields that emit light from the coupling-out area 44 decoupling, reflecting or absorbing so that it cannot decouple.

The light guide device 37 can be attached to a vehicle 55 be arranged, which is indicated here by a dashed line.

5 shows a further embodiment of an optical fiber device 56 with a light guide component 58 , which is free-form, and with two light guides 60 , 62 , which are each arcuate.

The light guide component 58 has a decoupling surface 64 , which is planar and free-shaped. The light guides 60 , 62 collar from the light extraction surface 64 the light guide component 58 the end. A first end of the light guide 60 and a first end of the light guide 62 extend next to one another at an edge region of the light guide component 58 . The respective light guides extend from their respective first end 60 , 62 arcuate, with the light guide 60 , 62 extend roughly in the same direction. The other two ends of the light guide 60 , 62 are further apart, like the two first ends, which are at the edge region of the light guide component 58 are arranged. The other ends of the light guide 60 , 62 are not exposed. The arch of one light guide 60 is slightly larger, ie slightly over 90 °, while the arc of the second light guide 62 is slightly smaller than 90 °.

The decoupling surface 64 the light guide component 58 has two different light extraction areas 66 , 68 on. The light extraction area 68 extends between the two light guides 60 , 62 . The light extraction area 66 surrounds the light guide 60 , 62 and is partly also between the light extraction area 68 and the respective light guides 60 , 62 arranged. The light extraction areas 66 , 68 couple out a different amount of light based on a unit area. For example, the light decoupling area 68 decouple more light than the light decoupling area 66 .

The light guide device 56 can on a vehicle component 70 be arranged, which is indicated here by a dashed line.

List of reference symbols

1, 14, 37, 56

Light guide device

2, 16, 17, 18, 20, 40, 60, 62

Light guide

4, 22, 38, 58

Fiber optic component

6, 26, 27, 29, 32

Coupling surface

8, 42

Outcoupling surface of the light guide

10, 44, 64

Outcoupling surface of the light guide component

12th

Decoupling structure

24, 28, 30, 34

Light source

35, 36

Optical element

46 - 54, 66, 68

Light extraction areas

55

vehicle

70

Vehicle component

Claims (14)

Light guide device with at least one light guide (2, 16, 17, 18, 20, 40, 60, 62), which has at least one coupling surface (6, 26, 27, 29, 32) for light from at least one light source (24, 28, 30 , 34), and with at least one light guide component (4, 22, 38, 58) which is integrally connected to the light guide (2, 16, 17, 18, 20, 40, 60, 62), characterized in that the The light guide (2, 16, 17, 18, 20, 40, 60, 62) has at least one decoupling structure (12) for directionally decoupling part of the light coupled into the light guide device (1, 14, 37, 56), and the light guide component (4, 22, 38, 58) has at least one decoupling structure in order to diffusely couple out part of the light coupled into the light guide device (1, 14, 37, 56). Light guide device according to Claim 1 , wherein the at least one coupling surface (6, 26, 27, 29, 32) is part of the light guide (2, 16, 17, 18, 20, 40, 60, 62) in order to emit light into the light guide (2, 16, 17, 18, 20, 40, 60, 62) to be coupled. Light guide device according to Claim 1 or 2 , wherein the light guide component (4, 22, 38, 58) on an outer surface of the light guide (2, 16, 17, 18, 20, 40, 60, 62) is formed in one piece with the latter. Optical fiber device according to one of the Claims 1 until 3 , the light guide component (4, 22, 38, 58) seen in the longitudinal direction of the light guide (2, 16, 17, 18, 20, 40, 60, 62) in sections over the length of the light guide (2, 16, 17, 18 , 20, 40, 60, 62) or over the entire length of the light guide (2, 16, 17, 18, 20, 40, 60, 62) protrudes from the outer surface so that the light guide (2, 16, 17, 18, 20, 40, 60, 62) is connected in sections over its length or over its entire length to the light guide component (4, 22, 38, 58). Light guide device according to Claim 4 , at least one outer jacket surface of the light guide component (4, 22, 38, 58) with at least one of the outside jacket surfaces of the light guide (2, 16, 17, 18, 20, 40, 60, 62), which at least partially has a decoupling surface (8, 42 ) for light that is guided via the at least one decoupling structure (12) of the light guide (2, 16, 17, 18, 20, 40, 60, 62), and this outer surface of the light guide component (4, 22, 38 , 58) is at least partially a decoupling surface (10, 44, 64) for light which is guided over the at least one decoupling structure of the light guide component (4, 22, 38, 58). Optical fiber device according to one of the Claims 1 until 5 , wherein the light guide component (4, 22, 38, 58) viewed in a longitudinal direction of the light guide (2, 16, 17, 18, 20, 40, 60, 62) over part of the length of the light guide (2, 16, 17, 18, 20, 40, 60, 62) or over the entire length of the light guide (2, 16, 17, 18, 20, 40, 60, 62) from the light guide (2, 16, 17, 18, 20, 40, 60, 62) protrudes or protrudes through the light guide (2, 16, 17, 18, 20, 40, 60, 62). Optical fiber device according to one of the Claims 1 until 6th wherein the light guide component (4, 22, 38, 58) is plate-shaped. Optical fiber device according to one of the Claims 1 until 7th , this having at least two light guides (2, 16, 17, 18, 20, 40, 60, 62) which are each connected in one piece to the light guide component (4, 22, 38, 58). Optical fiber device according to one of the Claims 1 until 8th , wherein the light guide component (4, 22, 38, 58) has at least two different outcoupling structures, so that the light guide component (4, 22, 38, 58) with at least two light outcoupling areas (46, 48, 50, 52, 54, 66, 68) having different levels of light coupling. Optical fiber device according to one of the Claims 1 until 9 wherein the light that is coupled out via the at least one coupling-out structure of the light guide component (4, 22, 38, 58) is coupled into at least one further optical element (35, 36). Light guide device according to Claim 10 , wherein the further optical element (35, 36) is a protective layer, a lacquer layer, a multilayer system or a metal layer. Vehicle component with the light guide device (1, 14, 37, 56) according to one of the Claims 1 until 11 . Vehicle component according to Claim 12 , wherein the light guide component (4, 22, 38, 58) of the light guide device (1, 14, 37, 56) represents a body component. Vehicle with the light guide device (1, 14, 37, 56) according to one of the Claims 1 until 13th .

Images