DE102015103660A1 - Lighting device with a light guide plate - Google Patents

Abstract

The invention relates to a lighting device (10) comprising at least one light guide plate (12), at least one lamp (14) and at least one light guide element (15), the light guide plate (12) having a peripheral side surface (16) and at least one perpendicular to the side surface Light emission surface (18), wherein the light guide element (15) has a light input surface (17) and a light output surface (19), wherein the light pipe element (15) at least one the light input surface (17) and light output surface (19) connecting interface (21) with a Has training in the light rays (23) of the coupled light of the lamp are totally reflected at this.

Description

The present invention relates to a lighting device with at least one light guide plate.

In the known lighting devices of the type mentioned, the light is at least one light coupled into the circumferential side surface of the light guide plate by irradiating the same with the light of the lamp. The injected light is e.g. Reflected on scattering bodies in the light guide plate to allow it to emerge from at least one light exit surface of the light guide plate as evenly as possible and flat. By providing at least one layer applied to the respective light exit surface, which is located between the light exit surface and a protective layer of the lighting device and consists of a material having a refractive index which is smaller than the refractive index of the material of the light guide plate, or by providing one of the light exit surface The light guide plate spaced by an air gap diffuser can be realized in known solutions advantageously over the entire light exit surface a uniform light emission. Due to the intended difference in the refractive index and the concomitant adjustment of the critical angle of total reflection, excessive light extraction in the vicinity of the respective luminaire is advantageously prevented. The production of such a multilayer construction is complicated and cost-intensive due to the majority of the components to be joined together. Furthermore, a translucent or transparent diffuser in the known solutions contributes to a considerable minimization of the overall efficiency of the luminaire, since components of the luminous flux are lost via the diffuser.

In the known lighting devices of the type mentioned also a low-loss coupling of the light in the light guide plate limits are set. In particular, a certain proportion of the light is reflected on the side surface and is lost for the intended radiation over the light exit surface of the light guide plate. In particular, in known lighting devices of the type mentioned, the respective lamp is spaced from the light guide plate to form an air gap. Due to the reflection of light components on the side surface or at the light gap, in some known solutions only a maximum of 91% of the total light or luminous flux can be non-directionally coupled into the light guide plate in a non-directional manner. The remaining 9% are reflected on the side surface and are lost. In order to prevent this relatively high proportion of the luminous flux, which is not coupled into the light guide plate, diffused or reflected at reflection surfaces in the space surrounding the lamp element or the luminaire with high glare, in some known solutions, the transition region between light and light guide plate or the air gap covered consuming.

Underlying task

It is an object of the invention to provide an alternative lighting device with a light guide plate, which is easy to manufacture and with which a low-loss coupling of the light is possible in the light guide plate.

Inventive solution

This object is achieved with a lighting device having the features of the independent claim 1.

The lighting device according to the invention comprises at least one light guide plate, at least one lamp and at least one light pipe element.

The light guide plate has a circumferential side surface and at least one light exit surface oriented at right angles to the side surface.

The light-conducting element has a light-incoupling surface for coupling or directed coupling of the light emitted by the luminaire into the light-conducting element and a light output plate oriented parallel to the side surface of the light-guide plate for decoupling the coupled-in light from the light-conducting element.

The light outcoupling surface is for coupling or for directed coupling of the coupled out of the light guide element light in the light guide plate on the side surface or lies flat against this or lies at this wholly or lies at this wholly flat.

In the case of the lighting device according to the invention, at least one means for decoupling the luminous light coupled into the light guide plate through the light exit surface is also provided.

The light-conducting element of the lighting device according to the invention has at least one interface connecting the light-incoupling surface and the light-outcoupling surface, wherein the boundary surface has an embodiment in which the light rays of the coupled light of the luminaire, which strike the interface immediately after being coupled into the light-conducting element, are totally reflectable at the interface and by the total reflection through the light outcoupling surface out of the Can be guided out of the light pipe element when the interface of the light pipe element to a predetermined medium, in particular air, adjacent.

In the light beams of the coupled-in light of the luminaire, which strike the interface immediately after being coupled into the light-conducting element, it is therefore light rays or light components of the coupled-in light which, without being deflected or deflected without being deflected substantially The light-guiding element first extends from the light-incoupling surface to the boundary surface, or it is the coupled-in light components or light beams that extend, inter alia (or with a section of their entire beam path) parallel or along a straight line which forms a point of the Light coupling surface connects with a point of the interface.

Furthermore, in the case of the lighting device according to the invention, the light guide plate consists of a material with a refractive index which corresponds to the refractive index of the material of which the light conducting element consists or deviates from this by a maximum of 20%. It is understood that under this refractive index deviation either one

Deviation to a smaller refractive index (negative deviation) or a deviation to a higher refractive index (positive deviation) is to be understood. The light guide plate is preferably made of a material having a refractive index which is within a range of 1.3 to 1.8.

The lighting device according to the invention is characterized in particular by providing the light-conducting element with the interface and by the concern of the light-outcoupling surface of the light-conducting element on the side surface of the light guide plate. By means of a der-like light pipe element can of the light of the lamp - which may include one or more light emitting diodes as light source - which is coupled via the light incidence surface in the light guide element due to the total internal reflection at the interface a large proportion of loss over the light output surface again from the Be guided or reflected light guide element out and reflected directly into the light guide plate or be steered, the side surface abuts the light output surface. To ensure that at the transition from the light output surface to the side surface of the light guide plate - on which the light output surface is applied - no reflection losses occur, the light guide plate is made of a material having a refractive index which corresponds to the refractive index of the material from which the light pipe element consists or a maximum of 20% deviates from this. Thus, it is advantageously ensured that the light coupled out via the light output surface is coupled into the light guide plate very lossless or completely lossless, so that none or only a very small proportion of the light radiated onto the light input surface by the light does not occur is coupled into the light guide plate. Overall, therefore, a low-loss and virtually glare-free coupling of the light of the lamp in the light guide plate is possible with the lighting device according to the invention. It is understood that this deviation of the refractive index is to be understood as meaning either a deviation from a smaller refractive index (negative deviation) or also a deviation from a higher refractive index (positive deviation).

In addition, due to the rectangular orientation of the side surface to the light exit surface and due to the parallel alignment of the light outcoupling surface of the light guide element to the side surface, the light or beams of light coupled by the total reflection in the light guide plate has a direction that is responsible for a large proportion of the coupled light Also, a total reflection at the light exit surface of the light guide plate has the consequence.

The coupled into the light pipe element light of the lamp is formed or aligned or bundled by the light pipe element or the interface of the light pipe element that almost all of the light coupled into the light pipe element luminous flux, with an efficiency> 90%, ideally 100% , Directed into the light guide plate is coupled, that the light flux thus formed in an angular range greater than or equal to the critical angle of total reflection at the light exit surface of the light guide plate can be reflected and directed in the light guide plate. This prevents an excessive and / or diffuse light extraction or luminance distribution in the immediate vicinity of the light guide element or in the immediate vicinity of the side surface of the light guide plate and creates the basis for an efficient and glare-free lighting device under lighting aspects. This also advantageously facilitates the design of the means for decoupling the coupled into the light guide plate luminaire light through the light exit surface, in particular in the form of efficient scattering structures in the light guide to achieve a glare-free light emission of the light guide over the at least one light exit surface. Likewise, further covers, such as, in particular, a translucent / opaque diffuser, can be dispensed with. The total reflection at the light exit surface advantageously prevents excessive light extraction in the immediate vicinity of the light-conducting element. It can be particularly advantageous to dispense with a known complicated to produce multilayer structure, in which one or more layers of a material with a refractive index of the light guide plate material reduced refractive index are gebacht on the light guide plate to excessive light decoupling in the immediate vicinity of the respective lamp to avoid.

The light guide plate may e.g. also be bent three-dimensionally, and in particular if in one embodiment, the light of the lamp or a bundle of rays of the luminous light on the light-conducting element in an angular range less than or equal to 35 ° in the light guide plate -. via a connection layer - can be coupled.

Furthermore, it is advantageous if preferably the material constituting the optical waveguide element has a refractive index which is at least 2% smaller than the refractive index of the material constituting the optical waveguide plate. By virtue of this difference, which is preferably provided, the light or beam of the luminous flux introduced into the light guide plate can be further bundled. As a result of the transition from a preferably optically less dense optical waveguide element (refractive index smaller than that of the lightguide plate) to a preferably optically denser optical waveguide plate, the light beams are known to be refracted towards the solder and thus the light beams or the beam bundle is narrowed, which is particularly advantageous to realize an almost lossless and virtually glare-free light coupling into the light guide plate. This bundling of the light beam also achieves a homogeneous light distribution in the light guide plate, which likewise contributes to an improvement in the glare-free lighting device, since a high luminance distribution is reduced near the peripheral side surface of the light guide plate where the light coupling takes place.

For coupling the luminaire light into the light incoupling surface, the luminaire is aligned correspondingly with respect to the light incoupling surface. Further, in determining the formation of the interface of the light pipe member, the orientation of the lamp with respect to the light input surface or the spatial light-emitting characteristic of the lamp with respect to the light coupling surface is included in order to provide the interface with its advantageous described effect of total reflection can , The determination of the interfacial formation or of the boundary surface course is then possible for the person skilled in the art, in particular on the basis of the laws of geometrical optics.

Apart from the light incoupling surface and the light outcoupling surface, the light conduction element is particularly preferably completely delimited by the interface (s) or outer surfaces, so that-apart from the light components which pass unhindered from the light incoupling surface to the light outcoupling surface-all the light components be coupled from the light on the light input surface in the light pipe element, totally reflected at the one or more interfaces and be directed through the light outcoupling surface out of the light pipe element out. This training brings advantageously a lossless or almost completely lossless light coupling of the light incident on the light incidence surface light in the light guide plate with it, and in connection with the advantageous prevention of excessive light extraction through the light exit surface of the light guide plate in the vicinity of the light guide element.

Overall, the lighting device according to the invention is therefore easy to produce due to the above and allows a low-loss coupling of the light of the lamp in the light guide plate.

The luminaire can comprise at least one light-emitting diode or a plurality of light-emitting diodes, or the light can comprise at least one light-emitting diode or a plurality of light-emitting diodes as the light source for generating the light to be coupled into the light guide plate.

The light exit surface of the light guide plate may be provided on any partial surface of the surface of the light guide plate. In particular, in the case of a light guide plate which comprises two mutually opposite cover surfaces and the peripheral side surface, the light exit surface may be made e.g. be provided on one of the two top surfaces. If two light exit surfaces are provided, a light exit surface can be provided on each of the two cover surfaces or one or each of the cover surfaces can form a light exit surface.

The means for decoupling or deflecting the light coupled in from the side surface into the light guide plate through the light exit surface can be any means which is set up for this decoupling or deflection of the light-emitting diode light. This agent may be e.g. to act a received in or on the light guide plate reflection means.

Particularly preferred may be the effect of the light control and the efficiency of the light extraction through the light exit surface, for example by additional Components in the light guide plate and / or be increased by scattering body on the surface of the light guide plate.

In the light guide plate may be any light guide plate, which is at least partially or entirely translucent. In particular, the light guide plate may particularly preferably be formed in one piece and / or multi-layered.

The thickness of the light guide plate or the thickness of the at least one piece of light guide plate is at least 2 mm.

In particular, the light guide plate may at least partially consist of a matrix material, which preferably comprises those materials which are transparent in the visible range of light, such as polycarbonate and / or polymethyl methacrylate and / or acrylate resins and / or methyl methacrylate-acrylonitrile-butadiene-styrene copolymers, Acrylic ester-styrene-acrylonitrile copolymers and / or styrene-acrylonitrile copolymers and / or polystyrene and / or styrene-methyl methacrylate copolymers and / or cycloolefin copolymers and / or polypropylene and / or liquid-crystalline polymers and / or polyamides and / or polyphenylene sulfone and / or polysulfone and / or polyethersulfone and / or polyethylene terephthalate and / or polybutylene terephthalate and / or inorganic glasses and / or mixtures and / or layer-wise combinations thereof.

The light-conducting element is formed at least partially or completely translucent. In particular, the light-conducting element may at least partially consist of a material comprising as matrix material polycarbonate and / or polymethyl methacrylate and / or acrylate resins and / or polystyrene and / or styrene-methyl methacrylate copolymers and / or cycloolefin copolymers and / or polyamides and / or polyphenylene sulfone and / or polysulfone and / or polyethersulfone and / or polyethylene terephthalate and / or polybutylene terephthalate and / or silicones and / or polyurethane and / or inorganic glasses and / or mixtures and / or layer-wise combinations thereof.

In particular, the light-conducting element may also be particularly preferably formed in one piece. The light-conducting element can be an extruded body in a particularly practical manner, ie a body which can be produced by extrusion in a simple and practical manner in large numbers.

In addition, the light-conducting element can have a division into at least two equally sized partial areas and / or at least two different-sized partial areas in at least one plane (orthogonal and / or horizontal direction to the longitudinal extension of the light guide plate). For better light guidance and / or light distribution, these subareas may differ in particular by the refractive index and / or the transparency and / or the composition of the matrix material. The indices of refraction of the individual subregions correspond to those of the light guide plate or deviate from it by a maximum of 20%. Such divided into subregions light-guiding elements can be advantageously prepared by extrusion and / or coextrusion and / or multi-layer extrusion and / or post-co-extrusion.

In the horizontal direction, the at least two partial regions can be separated from one another by a reflective reflector device, preferably with a reflectance> 75%, ideally> 85%, on both sides (preferably highly reflecting). The reflector device may preferably comprise a layer, which may be particularly preferably provided on an aluminum support, wherein the layer was coated on both sides in a vacuum process with at least one reflection-enhancing further thin layer as a reflector and ideally also an outer highly transparent clearcoat and / or adhesion-promoting layer may have, so that a cohesive bond to the matrix material of the light pipe element is achieved. By means of the reflector device, the beams can be deflected in particular upwards and / or downwards. The reflector device may be formed in particular in the form or in the manner of a mirror or mirror-like element. In a preferred embodiment, the light guide plate on a plurality of means in the form of scattering bodies for coupling or deflecting the light emitted from the side surface in the light guide plate luminous light through the light exit surface through. The decoupling or redirecting takes place here by scattering the coupled light at the scattering bodies. In this preferred embodiment, a plurality of means are further provided for coupling or deflecting the coupled from the side surface in the light guide plate light of the lamp through the light exit surface, wherein the light guide plate having these means and each means is in the form of a scattering body. The scattering bodies, which are preferably accommodated in the light guide plate or in the material of the light guide plate, make it possible to effectively decouple or deflect the light coupled into the light guide plate via the side face through the light exit face, in particular by providing a large number of uniformly in the light guide plate Distributed scattering bodies can be realized over the entire light exit surface extending uniform light emission, accompanied by the creation of a pleasant light. In this respect, the lighting device according to the invention can be used in particular as a ceiling light, for example. The scattering bodies may alternatively or cumulatively also be provided on the surface of the light guide plate.

The scattering bodies can advantageously bring about a directional and / or diffuse decoupling through the light exit surface. Particularly preferably, the scattering elements cause a directed outcoupling.

The scattering bodies may e.g. by etching and / or e.g. Embossing and / or e.g. Ablation and / or e.g. Laser structuring and / or e.g. Printing and / or e.g. Screen printing and / or e.g. Digital printing and / or e.g. Transfer printing and / or e.g. Paint embossing process, in particular UV-curing coating, and / or by e.g. Applying a thin layer (<500 μm), for example in the form of a foil, which already has scattering bodies, and / or e.g. be generated by combinations thereof.

In particular, the scattering bodies can also be applied to the surface of the light guide plate and / or can protrude into the surface as depressions and / or can be mixtures thereof.

The scattering bodies are e.g. punctiform and / or diamond-shaped and / or e.g. elliptical and / or e.g. polygonal and / or e.g. polyhedral and / or e.g. prismatic and / or e.g. conical and / or e.g. partially spherical and / or e.g. cylindrical and / or have e.g. Mixed forms from this.

The scattering bodies can have smooth and / or micro-rough and / or textured surfaces.

It is advantageous if the scattering bodies preferably have heights of 10 μm-3 mm. For punctiform and / or prismatic structures, the lateral extent is particularly preferably between 10 μm and 6 mm.

Embodiments of scattering bodies which are applied as printing ink and / or as UV-curing coating have as matrix material acrylate resins and / or urethane resins and / or urethane acrylate resins and / or polyester resins and / or epoxy resins and / or epoxy acrylate resins and / or hybrid resins, for example known in so-called ORMOCER coating systems.

The scattering bodies can be transparent and / or have additives which have an increased refractive index relative to the matrix material of the light guide plate. The choice of additives includes pigments, for example, titanium dioxide, zinc sulfide, zinc oxide, barium sulfate and barium titanate, as well as glass, alumina, silicate, microglass, microballoons, crosslinked polystyrene, silver nanoparticles, and chalk.

In the scattering bodies, which are provided alternatively or cumulatively on the surface of the light guide plate, it may be any scattering body, which are adapted to effect the coupling or deflection by scattering effect or to realize. The size or the extent of the scattering bodies in the direction of their greatest extent is preferably within a range of 10 μm to 6 mm, particularly preferably within a range of 10 μm to 3 mm. With scattering bodies of such dimensions, it is possible to create a very uniform light through the sum of the scattering effects of all the scattering bodies, with as uniform a distribution as possible of the scattering bodies.

The scattering particles or scattering particles which can be distributed in the light guide plate are preferably of spherical and / or elliptical and / or polyhedron-like shape and preferably have smooth and / or rough and / or micro-rough and / or microstructured and / or textured Surfaces and / or combinations thereof. It is particularly advantageous if the scattering particles in the matrix material of the light guide plate in the dimension <20 .mu.m, ideally <10 .mu.m, with as narrow as possible a particle size distribution <± 5%.

Microglass spheres, hollow glass microspheres with a diameter smaller than 10 .mu.m, crosslinked polymer particles with a diameter smaller than 10 .mu.m, polymethyl methacrylate particles, crosslinked polybutyl methacrylate particles or crosslinked acrylic esters crosslinked polystyrene, polymethylsilsesquioxane microspheres made of polymethylsilsesquioxane composite microspheres prove to be particularly suitable Alumina and / or titanium dioxide surface modification (concentration: <0.1%, ideally <0.01%). Examples of these are TECHPOLYMER MBX, TECHPOLYMER MBP, TECHPOLYMER MB-C, TECHPOLYMER ARX, TECHPOLYMER SBX, TECHPOLYMER BMX, DIASPHERE, TOSPEARL, particles of KOBO.

In a practical embodiment of the lighting device according to the invention, the light outcoupling surface is provided on at least one connecting layer of the light-conducting element, via which the light-guiding element is materially connected to the side surface. By way of such a connection layer, an effective coupling of the light outcoupling surface to the side surface can be created.

The connecting layer may preferably be at least one polymer layer and / or an adhesive layer and / or a sol-gel layer and / or a lacquer layer. Likewise, the tie layer may have been applied by a physical coating process. The tie layer may consist of a combination of polymer and / or adhesive layer and / or sol-gel layer and / or layers produced by means of a physical coating process.

The bonding layer is preferably an adhesive layer. By a cohesive connection, in particular by a cohesive connection produced by means of an adhesive layer or an adhesive advantageously a very effective coupling and thus also a very low-loss coupling of the light can be realized.

Particularly preferably, the connecting layer consists of a material with a refractive index which corresponds to the refractive index of the material of which the light guide plate or the light conducting element consists, or deviates from this by a maximum of 20%. It is understood that this deviation of the refractive index is to be understood as meaning either a deviation from a smaller refractive index (negative deviation) or also a deviation from a higher refractive index (positive deviation).

In particular, the connection layer may at least partially or entirely consist of a material with a refractive index greater than or equal to that of the light-conducting element but less than or equal to the light-guide plate.

By thus provided matching or agreement, the refraction or reflection of the luminous light at the interface of compound layer and light guide plate or light guide element can be advantageously avoided or substantially reduced, along with a very low-loss coupling of the light in the light guide plate. A particularly good adaptation can be achieved if the bonding layer at least partially or entirely of a material having a refractive index greater than or equal to the light guide element but equal to that of the light guide plate, because of this increase in the refractive index of the light guide element to the light guide plate out a bundling of the light extending from the light pipe element into the light guide plate, resulting in both an advantage in minimizing the dazzling effect of the luminaire and in achieving a homogeneous light distribution in the light guide plate. Particularly preferably, the bonding layer has a high adhesion and / or a high light transmittance and / or a high temperature stability.

The transparency or light transmittance of the bonding layer in the visible range is preferably greater than 80%, particularly preferably greater than 94%.

The adhesive strength of the bonding layer is preferably greater than 0.5 N / cm, more preferably greater than 5 N / cm, in each case measured at room temperature and / or at 40 ° C., in order to advantageously avoid delamination / detachment.

The thickness of the bonding layer may preferably be within a range of 10 nm to 500 μm.

The tie layer may consist of a combination of polymer and / or adhesive layer and / or sol-gel layer and / or layers produced by means of a physical coating process.

If the tie layer is a polymer layer, it may consist of polyurethane or polymethyl methacrylate-poly-n-butyl acrylate block copolymer and / or an adhesion-modified silicone elastomer and / or ethylene vinyl acetate and / or a copolyester.

In order to achieve sufficient adhesion of the preferably polymer-based tie layer to the side face and / or the light guide element, at least one of the sides adjacent to the polymer-based tie layer, i. the side surface and / or the surface of the light pipe element are activated by corona discharge or flame treatment or plasma coating process or aerosol process or excimer or microwave excitation or laser or UV radiation or ionizing radiation or actinic radiation or by treatment with surface sulfuric acid or caustic soda.

When the tie layer is an adhesive layer, it preferably comprises at least one binder selected from polyvinyl alcohol and / or polyvinyl butyral and / or polyvinyl pyrrolidone and / or polyethylene vinyl acetate copolymers and / or polyvinyl acetate and / or acrylates and / or methacrylates and / or Urethanes and / or polyesters and / or polyethers and / or urethane acrylates and / or cyanomethyl acrylates and / or cyanoethyl acrylates and / or cyanomethyl methacrylates and / or cyanoethyl methacrylates and / or (meth) acrylic acid derivatives and / or polymethyl methacrylate and / or epoxy resins and / or silicones and / or or silicone copolymers and / or fluoropolymers and / or linear or branched vinylhydrogenpolysiloxanes and / or mixtures thereof.

If the bonding layer is a sol-gel layer, then it has at least one silane compound and / or one fluorosilicate compound and / or one silicic acid ester.

The silane compound may be selected from or the silane compound may include allyltrialkoxysilanes and / or allyldialkoxysilanes and / or allylmonoalkoxysilanes and / or undecenyltrialkoxysilanes and / or vinyltrialkoxysilanes and / or vinyldialkoxysilanes and / or vinylmonoalkoxysilane and / or tetraalkoxysilane and / or trialkoxysilane and / or glcidyloxypropylalkoxysilane and / or carbamates and / or aminosilanes and / or 3-mercaptopropyltrialkoxysilanes and / or fluorosilanes.

Examples of these are vinyltrimethoxysilane and / or vinyltriethoxysilane and / or vinyltriisopropoxysilane and / or vinyltributoxysilane and / or vinyltris (2-methoxyethoxy) silane and / or vinyltris (2-ethoxyethoxy) silane and / or vinyldimethylmethoxysilane and / or vinyldimethoxysilane and / or vinylphenyldimethoxysilane and / or Vinylphenyldiethoxysilan and / or Vinyldiethoxysilan and / or vinylmethyldiethoxysilane and / or Vinylphenylmethylmethoxysilan and / or allyltrimethoxysilane and / or allyldimethoxysilane and / or allylmethyldimethoxysilane and / or allyltriethoxysilane and / or allyldimethoxysilane and / or allylmethyldimethoxysilane and / or Allyldiethoxysilan and / or allylmethyldiethoxysilane and / or undecenyltrimethoxysilane and / or allyloxyundecyltrimethoxysilane and / or 1,3-diallyltetramethyldisiloxane and / or vinyltriacetoxysilane and / or 1,3-divinyltetramethyldisiloxane and / or vinyltetramethyldisiloxane and / or 1,3-divinyltetraphenyldisiloxane and / or 3-glycidyloxypropyltrimetho xysilane and / or 3-glycidyloxypropyltriethoxysilane and / or N-trimethoxysilylmethyl-O-methyl-carbamate and / or N-dimethoxy (methyl) silylmethyl-O-methylcarbamate and / or N-methyl [3- (trimethoxysilyl) -propyl] carbamate and / or 3-aminopropyltrimethoxysilane and / or N- (2-aminoethyl) -3-aminopropyltrimethoxysilane and / or N- (n-butyl) aminopropyltrimethoxysilane and / or bis (3-triethoxysilylpropyl) amine and / or bis (3-trimethoxysilylpropyl) amine and / or oligomeric amino / alkylalkoxysilanes and / or perfluorooctyltriethoxysilane and / or trifluoropropylsilanes and / or polyfluoroalkylsilanes.

The fluorosilicate compound may be selected from or the fluorosilicate compound may comprise tris (pentafluoroethyl) difluorosilicate and / or bis (pentafluoroethyl) trifluorosilicate and / or tri (n-heptafluoropropyl) difluorosilicate and / or bis (n-heptafluoropropyl) trifluorosilicate and / or tris ( n-nonafluorobutyl) difluorosilicate and / or bis (n-nonafluorobutyl) trifluorosilicate and / or tris (n-tridecafluorohexyl) difluorosilicate and / or bis (n-tridecafluorohexyl) trifluorosilicate.

If the connecting layer is a lacquer layer, it preferably has at least one acrylate and / or one methacrylate and / or one polyfunctional compound, for example ethoxylated trimethylolpropane tri (meth) acrylate and / or tripropylene glycol di (meth) acrylate and / or trimethylolpropane tri (meth) acrylate and or diethylene glycol di (meth) acrylate and / or pentaerythritol tetra (meth) acrylate and / or pentaerythritol tri (meth) acrylate and / or dipentaerythritol hexa (meth) acrylate and / or 1,6-hexanediol di (meth) acrylate and / or neopentyl glycol di (meth) acrylate and o / or polyester (meth) acrylates and / or fatty acid-modified polyester (meth) acrylates and / or propoxylated glyceryl tri (meth) acrylate and / or ethoxylated bisphenol-A di (meth) acrylate and / or isobornyl acrylate and / or amino-modified polyethers (meth) acrylates and / or aliphatic urethane (meth) acrylates and / or silicone (meth) acrylates and / or epoxy acrylates and / or fluorine-containing compounds.

If the bonding layer is a layer that is applied by means of a physical coating method, this may be CVD (Chemical Vapor Deposition) and / or PVD (Physical Vapor Deposition) and / or PECVD (Plasma Enhanced Chemical Vapor deposition) and / or PICVD (Plasma Impulse Chemical Vapor Deposition) and / or LPCVD (Low Pressure Chemical Vapor Deposition) and / or TCVD (Thermal Chemical Vapor Deposition).

If the bonding layer is in the form of a layer comprising an adhesive layer and / or a sol-gel layer and / or a lacquer layer, this may be a thermally and / or chemically and / or radiation-curing system and / or a combination thereof . form.

Chemically curing systems include polymerizations and / or polyaddition reactions and / or polycondensation reactions and / or hydrosilylation reactions and / or crosslinking reactions. Radiation-curing systems are in particular photochemically curing systems such as UV and / or NIR and / or electron beams and / or microwaves.

The bonding layer may comprise, for refractive index modification, ie, increase or decrease in refractive index, micro- and / or nanoscale compounds and / or components, such as nanoscale particles and / or crystals, and / or nanoporous materials composed of sols and / or gels and / or metals and / or metal oxides and / or metal sulfides and / or doped metal oxides and / or silicates and / or fluorine-containing compounds can be obtained and / or mixtures thereof.

In particular, it is possible to use micro- and / or nanoscale compounds and / or constituents which have a negative refractive index.

Advantageously, the micro- and / or nanoscale compounds and / or components are used to reduce the refractive index of the bonding layer in a concentration of 0.001-5 wt% and with a particle size smaller than 30 microns, to reduce the total refractive index of the bonding layer.

Micro- and / or nanoscale compounds and / or constituents are preferably selected from or preferably comprise magnesium fluoride and / or calcium fluoride and / or sodium fluoride and / or zirconium fluoride and / or titanium fluoride and / or aluminum fluoride and / or tin fluoride and / or airgel and / or or pyrogenic silica and / or polymeric hollow glass spheres and / or glass-based hollow spheres and / or zeolites and / or graphene.

The fluorine-containing compounds of the tie layer are preferably selected from, and preferably include, fluoroalkyl acrylates and / or fluoroalkyl methacrylates and / or fluoroalkyl alcohols and / or fluoroalkyl esters and / or fluoroalkylolefins and / or fluorosilanes and / or fluorosilicones and / or fluorosilicates and / or mixtures thereof. In a further practical embodiment of the lighting device according to the invention, the luminaire has at least one luminous light exit surface for light emitted by the luminaire, which is connected in a materially bonded manner to the light coupling surface via a surface connecting layer. By way of such a surface connecting layer, an effective coupling of the luminous light exit surface to the light coupling surface can be created. If the luminaire comprises at least one light-emitting diode, the light-emitting exit surface is a luminous-light exit surface for light emitted by the light-emitting diode.

The surface bonding layer establishes a material-bonding connection between the light-conducting element and the luminaire or between the luminous-light exit surface and the light-coupling surface. The surface-bonding layer can preferably be at least one polymer layer and / or an adhesive layer and / or a sol-gel layer and / or a lacquer layer ,

By a cohesive or a cohesive and transparent connection, in particular by a cohesive connection or a polymer layer produced by means of an adhesive layer or an adhesive advantageously a very effective coupling and thus also a very low-loss coupling of the light can be realized in the light pipe element.

Particularly preferably, the surface connecting layer consists of a material with a refractive index which corresponds to the refractive index of the material constituting the light guide plate or the light conducting element, or deviates from this by a maximum of 20%. It is understood that this deviation of the refractive index is to be understood as meaning either a deviation from a smaller refractive index (negative deviation) or also a deviation from a higher refractive index (positive deviation). By thus provided matching or agreement, the refraction or reflection of the luminous light at the interface of Flächenverbindungsschicht and lamp or light pipe element can be advantageously avoided or substantially reduced, along with a very low-loss or completely lossless coupling of the light the light in the light pipe element. In particular, the surface bonding layer may also be made of a material having a refractive index which is between the refractive index of the material of the lightguide plate and the refractive index of the material of the lightguide element, which may be advantageous in certain applications.

The surface-bonding layer may in particular consist of a combination of polymer and / or adhesive layer and / or sol-gel layer and / or layers which have been produced by means of a physical coating method.

If the surface-bonding layer is a polymer layer, it may consist of polyurethane or polymethyl methacrylate-poly-n-butyl acrylate block copolymer and / or an adhesion-modified silicone elastomer and / or ethylene vinyl acetate and / or a copolyester.

In order to achieve sufficient adhesion of the preferably polymer-based surface bonding layer on or at the light coupling surface and / or the luminous light exit surface, at least one side of the polymer-based surface bonding layer and / or the light coupling surface of the light coupling element may be corona discharge or flame treatment or plasma coating process or aerosol process or excimer or microwave excitation or laser or UV radiation or ionizing radiation or actinic radiation or by treatment with sulfuric acid or sodium hydroxide solution on the surface.

If the surface bonding layer is an adhesive layer, it preferably comprises at least one binder selected from polyvinyl alcohol and / or polyvinyl butyral and / or polyvinyl pyrrolidone and / or polyethylene vinyl acetate copolymers and / or polyvinyl acetate and / or acrylates and / or methacrylates and / or urethanes and / or polyesters and / or polyethers and / or or urethane acrylates and / or cyanomethyl acrylates and / or cyanoethyl acrylates and / or cyanomethyl methacrylates and / or cyanoethyl methacrylates and / or (meth) acrylic acid derivatives and / or polymethyl methacrylate and / or epoxy resins and / or silicones and / or silicone copolymers and / or fluoropolymers and / or linear or branched vinylhydrogenpolysiloxanes and / or mixtures thereof.

If the surface bonding layer is a sol-gel layer, then it has at least one silane compound and / or one fluorosilicate compound and / or one silicic acid ester.

In a preferred embodiment of the lighting device according to the invention, the luminaire has at least one luminous light exit surface for light emitted by the luminaire, wherein the luminous light exit surface is spaced from the light coupling surface of the light conducting element or, in an alternative embodiment, the luminaire is spaced from the light coupling surface.

This preferred embodiment - in which the light-emitting exit surface is spaced from the light-incoupling surface of the light-conducting element - is particularly advantageous for a directed coupling. By narrowing the beam in the material (ie the directed coupling), the light can get more into the depth of the plate and sets back less effective way. As a result, the decoupling at the edge of the plate is less likely and the luminance distribution more homogeneous.

As a result of the spacing, the light emitted by the luminaire into the medium of air can advantageously be focused in the transition from the medium air into the optically denser medium of the light conduction element, whereby a low-loss coupling into the light guide plate is favored. The luminaire light exit surface may be any luminaire light exit surface known to those skilled in the art, wherein the luminous light exit surface is e.g. may be a surface of a light passage plate or any other optical element through which the light of a luminous means, such as in particular e.g. a light emitting diode, is directed therethrough.

Particularly preferably, the light-emitting exit surface of the lamp is arranged in a recess of the light-conducting element or particularly preferably the light is arranged at least partially or in regions or entirely in a recess of the light-conducting element. Depending on the application, a space-saving solution can be realized by providing a recess on the light-conducting element, such that the space required for the luminaire or a section or a region of the luminaire is advantageously displaced into the recess.

In a further preferred embodiment of the luminous device according to the invention, the luminaire has at least one luminous light exit surface for light emitted by the luminaire, wherein the luminous device further comprises at least two light-conducting elements and at least two light guide plates, each light guide plate comprising two cover surfaces and the circumferential side surface, wherein a cover surface of one of the two light guide plates rests flat against a cover surface of the other of the two light guide plates, wherein the light guide elements lie flat against each other or arranged one above the other and are connected to each other via a reflection means of a sheet-like reflective material between the light guide elements, wherein the light guide elements further each having a recess have, which together form a coherent recess in which the luminous light exit surface of the luminaire with Abstan D is arranged to the light input surface of each of the two light pipe elements. A training according to this preferred embodiment is particularly advantageous for the realization of a ceiling light for providing so-called. Direct and indirect light, such that in the appended to the ceiling state, a light guide plate is provided for irradiating the ceiling (indirect light) and the other light guide plate for directly illuminating the respective room serves (direct light). The light exit surfaces are provided in this further preferred embodiment, in each case on the top surface, which does not lie flat against a top surface of the other light guide plate. By the reflection means of the sheet-like reflective material, which has two light-reflecting sides facing away from each of which faces one of the two light-guiding elements, the light coupled into the respective light-guiding element can not pass into the other light-conducting element. Thus, a visually appealing separation of direct and indirect light is effectively promoted.

At a e.g. rectangular or square formed light guide plate, the peripheral side surface of two pairs opposite or facing each other flat partial surfaces is formed.

In a practical embodiment of the lighting device according to the invention, the light guide element is formed in its shape and also has a refraction difference> 3%, but less than 20% to the refractive index of the light guide plate, that the light tuft entering the light guide plate irradiates <± 38 ° in the light guide plate, whereby an angle of incidence on the light exit side or light exit surface of> 52 °, ideally> 60 ° results. This is particularly advantageous in order to shorten the path length of the light beam in the light guide plate, whereby the probability of diffuse scattering at scattering centers or losses in the light guide plate (attenuation) are lowered. Due to the directed irradiation, a significantly more homogeneous luminance distribution can be achieved, which is associated in particular with higher luminances in the center of the light guide plate. This has the advantage that larger light emitting device dimensions or lighting device surfaces can be realized and that the number of means for decoupling or the number of scattering structures, which also influence the light guidance and light distribution in addition to the decoupling, can be reduced.

The thickness of the light guide plate may preferably be 6 mm or 10 mm. The thickness of the light guide plate can be adapted in particular to respective applications.

In a practical embodiment of the lighting device, this has a circumferentially extending around the light guide plate frame with a circumferentially extending around the side surface inner surface. On the frame or the inner surface of the lamp or the lights can be kept and mounted in a simple and practical way very reliable. In particular, by means of the frame a plurality of light-emitting diodes can be provided, which can be provided by attachment to the frame or the inner surface, e.g. Particularly preferably along the circumferential extending side surface of the light guide plate can be arranged sequentially or in rows. In particular, an at least single-row arrangement of the light-emitting diodes may preferably be present.

In particular, the frame may comprise a plurality of interconnected polymer profiles. Very stable and lightweight polymer profiles can be produced inexpensively by extrusion. In particular, by joining several polymer profiles e.g. a square or rectangular frame are created, the dimensions of which can be very well adapted to the dimensions of the respective light guide plate by appropriate length selection of the polymer profiles. The frame may in particular be reinforced or mechanically reinforced by at least one reinforcing element, which may in particular be a band-shaped reinforcing element, which may preferably be extruded into at least one of the polymer profiles, accompanied by a substantial increase in the stability of the frame or lighting device. In particular, by providing the polymer profiles together with the reinforcing element, a much lighter and more compact lighting device can be provided in comparison with known light-guide plate lighting devices. The reinforcing element can particularly advantageously at least partially consist of a metallic material, together with a very effective reinforcement. Furthermore, by providing a metallic material, a very effective heat dissipation and heat distribution of the heat generated during operation of the lights can be realized, which has a particularly advantageous effect on the life of the lamp or lights. A polymer profile with an extruded metallic reinforcing element can be used particularly advantageously with processing processes customary in the furniture industry - e.g. known from approaching furniture edges - be milled or milled for machining or shaping.

Particularly preferably, the frame comprises a circumferentially extending around the light guide plate band, wherein one of the two opposite sides of the band forms a visible and circumferential outer surface of the lighting device. In this way, a visually very sophisticated lighting device can be provided, in which the peripheral outer surface in the form of a band side can cause a visually very appealing appearance. Particularly advantageously, the lights and / or other devices of the lighting device between the other of the two opposite sides of the band and the light guide element can be arranged, whereby the lights and / or the other devices in opaque or nearly opaque formation of the band outside the lighting device not visible are, in conjunction with the creation of a visually very appealing lighting device, in which the light can escape only through or over the intended light exit surface or the intended light exit surfaces. The band may particularly preferably be an edge band. Furthermore, the band can at least partially consist of a polymer material. Particularly preferably, the band consists of a laminate material.

The laminate material may be a metal band or be formed in the form of a metal strip. Optimal thermal management, optimal heat dissipation, optimal distribution of heat on the metal can be achieved with a metal band External surface, also be realized in conjunction with an increase in the contact surface to the air. Furthermore, a stiffness can be realized by means of a metal strip for the entire lighting device, with which bending of the light guide plates can be effectively avoided or significantly minimized.

It is particularly advantageous that on the basis of the frame with the belt extending circumferentially around the light guide plate in conjunction with automated processes that are common in the furniture industry, radii and corners can be displayed. The preferably having a multi-layer structure frame can be set by notches and / or milling in the profile or polymer profile at an angle equal to or less than 90 ° around corners. In addition, lips may be extruded to cover the margins or to enhance the hermetic encapsulation of the frame. In particular, the frame may be formed in the form of a polymer profile. Such a polymer profile is characterized by easy weldability, which can be used to attach additional holders.

The above band or edge band may in particular be reinforced or mechanically reinforced by a reinforcing element, which may in particular be a band-shaped reinforcing element, which is preferably attached to the other of the two opposite sides of the band or flatly connected to this side, along with a substantial increase in the stability of the frame or the lighting device. In particular, by providing the tape together with the reinforcing element, a much lighter and more compact lighting device can be provided in comparison with known light-guide plate lighting devices. The reinforcing element can particularly advantageously at least partially consist of a metallic material, together with a very effective reinforcement. Furthermore, by providing a metallic material, a very effective heat dissipation and heat distribution of the heat generated during operation of the lights can be realized, which has a particularly advantageous effect on the life of the lamp or lights. The reinforcing element may also comprise a fibrous and / or fibrous material. Examples include fabrics and / or braids and / or long fibers and / or short fibers and / or scrims and / or knitted fabrics in the form of glass fibers, carbon fibers and / or polymer fibers and / or ceramic fibers and / or combinations thereof.

The band-shaped reinforcing element may for advantageous weight reduction of the lighting device preferably have a thickness which is smaller than 5 mm.

From the band-shaped reinforcing element can advantageously be made by forming a holding profile in a simple manner.

In a particularly preferred embodiment of the lighting device, at least one luminaire having a plurality of light-emitting diodes and at least one holding band having a first side and a second side opposite thereto are provided, wherein the luminaire with the plurality of light-emitting diodes is attached to the first side of the holding band or ., Wherein the lamp with the plurality of light-emitting diodes is only or exclusively attached to the first side of the retaining band. In this case, in particular, a plurality of luminaires can also be provided, wherein each individual luminaire has a plurality of light-emitting diodes, and all luminaires or light-emitting diodes provided in total are attached to the first side or only to the first side of the retaining band.

By providing the retaining band, a lighting device can be provided or created in a structurally simple manner, in which the lights or LEDs along the circumferential extending side surface of the light guide plate can be arranged successively, in such a way that the lights or light-emitting diodes preferably in the longitudinal direction the tether are arranged successively. For successively arranging the luminaires or light-emitting diodes along the circumferentially extending side surface of the lightguide plate, the tether is merely to be arranged or guided around the peripheral side surface or around the circumferential side surface in a simple manner.

Preferably, in particular for realizing the above successive arrangement of the light emitting diodes along the side surface, the second side of the tether is attached to or adhered to the circumferentially extending inner surface of the above frame.

The tether may preferably be made of a polymeric material, in particular a thermoplastic material, e.g. advantageous to be able to form a stable adhesive bond or a cohesive connection to the inner surface of the above frame.

Particularly advantageously, the retaining strip on conductor tracks for energizing and / or driving the lamp and electronic devices for energizing and / or driving the lamp on the conductors, wherein the conductor tracks and the electronic devices are provided only on the first side of the tether, and wherein the electronic devices are spaced from the light. The fact that the conductor tracks and the electronic devices - as well as the at least one light with the plurality of light-emitting diodes - are arranged only on the first side or only on one side of the tether, can advantageously of a complex or complicated connection or interconnection with many separate contacts, as it is known from known light-emitting devices with light guide plates, apart. The retaining band can be arranged in a simple and practical manner along the peripheral side surface or guided around the light guide plate along the circumferential side surface, so that advantageously only two terminals can be sufficient for the contacting, along with an advantageous reduction of the production effort. The fact that the electronic devices are arranged at a distance from the luminaire brings with it the advantage that these devices advantageously do not obstruct or disturb the arrangement or mode of operation of the respective luminaire.

In the above further practical embodiment of the lighting device according to the invention, in which the lamp has at least one light-emitting exit surface for radiated light from the lamp, which is materially connected via a surface connecting layer with the light input surface, there is, if the lamp also has at least one light emitting diode or a plurality of light-emitting diodes, preferably a flat and positive connection between each light-emitting diode and the light-conducting element. In this case, the light-emitting diodes and / or further components or electronic components of the luminaire are particularly preferably enclosed over the entire width of the light-emitting diodes or the at least one light-emitting diode over the entire surface with the material of the surface connection layer and have a material connection to the light conduction element. The surface connecting layer may preferably be applied at least in sections to a carrier of the lighting device and form a material connection to the light conducting element or the light coupling surface. Particularly preferably, the width of the light-conducting element is greater than that of the light-emitting diode or the light-emitting diodes.

Another planar connection layer can also envelop the entire luminaire or luminaire arrangement and thus produce an adhesive bond to the retaining means with interconnects in addition to an adhesive bond to the luminaire.

When in the above and subsequent statements the term "translucency" is used, it is meant that this translucency exists for at least part of the spectrum of visible light, preferably for the entire spectrum of visible light.

Brief description of the drawings

Embodiments of the invention will be explained in more detail with reference to the accompanying drawings. In the drawing show:

1A a very schematic sectional view of a first embodiment of a lighting device with a sectional plane perpendicular to a top surface and parallel to two opposite partial surfaces of the circumferential side surface of a cuboid light guide plate of the lighting device;

1B a very schematic three-dimensional representation of a light guide plate to illustrate the sectional plane of the 1A ;

2 a very schematic sectional view of a second embodiment of a lighting device with a sectional plane as in 1A and

3 a very schematic sectional view of a third embodiment of a lighting device with a sectional plane as in 1A ,

The lighting device 10 to 1 includes a light guide plate 12 , a light 14 with a plurality of light emitting diodes 20 as a light source and a light pipe element 15 , wherein in the sectional view according to 1A only one LED 20 and a light pipe element 15 is shown.

The 1B illustrates the position or orientation of the cutting plane 1A , The cutting plane 58 is perpendicular to a deck area 42 of two opposite top surfaces 42 . 43 and parallel to two opposite planar faces 60 the surrounding side surface 16 (see also 1A ) of the cuboid light guide plate 12 the lighting device 10 oriented.

The light-emitting diodes 20 the light 14 are along one of the four faces 60 the circumferential side surface arranged successively to over the entire extent of this partial surface 60 a light coupling into the light guide plate 12 to realize.

The light guide plate 12 has the circumferential side surface 16 and one on the top surface 42 the light guide plate 12 provided light exit surface 18 on, perpendicular to the circumferential side surface 16 oriented or oriented.

The lamp 14 points for each LED 20 one light-emitting exit surface each 22 for from that of the respective light emitting diode 20 emitted light 24 on.

The light pipe element 15 has a light input surface 17 for coupling the lamp 14 emitted light 24 in the light pipe element 15 and one parallel to the side surface 16 oriented light output surface 19 for decoupling the coupled-in light from the light-conducting element 15 on. The light pipe element 15 is between the side surface 16 and each of the light-emitting exit surfaces 22 arranged.

The light output surface 19 is for coupling the out of the light pipe element 15 decoupled light in the light guide plate 12 on the side surface 16 is applied.

The formed in the form of an elongated extrusion body light pipe element 15 has two the light input surface 17 and light output surface 19 connecting interfaces 21 each in the form of an outer surface.

Each of the interfaces 21 has a formation or a shape or a course, in the or the light beams 23 of the injected light 24 the light 14 or the light emitting diodes 20 immediately after coupling into the light-conducting element 15 on the interface 21 meet, at the interface 21 totally reflecting and by total reflection through the light output surface 19 through out of the light pipe element 15 are steerable out when formed in the form of the outer surface interface 21 of the light pipe element 15 in air 31 adjacent as a given medium.

The light guide plate 12 consists of a material with a refractive index, which is the refractive index of the material from which the light-conducting element 15 exists, corresponds to or deviates from this by a maximum of 20%.

The light guide plate 12 has a variety of means 26 in the form of scattering bodies 54 for decoupling from the side surface 16 in the light guide plate 12 coupled light-emitting diode light 24 through the light exit surface 18 through, wherein the decoupling or

Redirecting the light-emitting diode light 24 by scattering the coupled-in light 24 at the scattering bodies 54 takes place (illustrated in the figures only very schematically with reference to a few scattering bodies).

The light output surface 19 is at a connection layer 30 of the light pipe element 15 provided over which the light pipe element 15 with the side surface 16 is connected cohesively.

The critical angle α of the total reflection at each interface 21 of the light pipe element 15 is defined according to the refractive index for each material, if the respective interface 21 to the medium 31 so the air is adjacent.

Each of the luminaire light exit surfaces 22 is over a surface connecting layer 28 with the light coupling surface 17 is connected cohesively.

Both the surface connection layer 28 as well as the connection layer 30 consists of a material with a refractive index, which is the refractive index of the material from which the light guide plate 12 or the light pipe element 15 exists, corresponds to or deviates from this by a maximum of 20%.

The lighting device 10 to 2 differs from the embodiment according to 1 essentially in that each luminaire light exit surface 22 the light 14 or the light emitting diodes 20 (or the lamp 14 ) from the light input surface 17 spaced and in a recess 25 of the light pipe element 15 is arranged. Also in this embodiment, the light output surface 19 at a connection layer 30 of the light pipe element 15 provided over which the light pipe element 15 with the side surface 16 is connected cohesively. The light input surface 17 comprises three angularly arranged partial surfaces 29 ,

The light-emitting diodes 20 the lights 14 are on a track 34 a holding means 35 appropriate. Another flat connecting layer 33 represents a cohesive bond between the holding means 35 and the light pipe element 15 forth, which advantageously provides an encapsulation and thus glare is avoided. This further planar connection layer 33 does not have to be transparent.

As a result of the training or form of the inner partial surfaces 29 can be beneficial from the light 14 into the medium 31 Air emitted light at the transition from the medium 31 Air in the optically denser medium of the light pipe element 15 be bundled, creating a low-loss coupling into the light guide plate 12 is favored. At the luminaire light exit surface 22 It may be any known to those skilled luminaire light exit surface 22 act, wherein the luminaire light exit surface 22 For example, may be a surface of a light passage plate or any other optical element through which the light of a light source, such as in particular, for example, a light emitting diode 20 , is directed through.

The lighting device 10 to 3 differs from the embodiment according to 2 essentially in that the lighting device 10 two light pipe elements 15 having, via a reflector device 36 are connected together from a sheet-like reflective material, and further two light guide plates 12 and two lights 14 each having a plurality of light emitting diodes 20 includes, wherein a top surface 42 one of the two light guide plates 12 on a deck surface 43 the other of the two light guide plates 12 lies flat. Furthermore, the light pipe elements 15 one recess each 25 on, which together form a coherent recess 27 form, in which the light-emitting exit surfaces 22 the lights 14 with distance to each light coupling surface 17 the two light pipe elements 15 or light transmission elements 15 are arranged. Each light coupling surface 17 in this embodiment comprises two angularly arranged partial surfaces 29 , The light-emitting diodes 20 the lights 14 are - as well as in the embodiment according to 2 - on a conductor track 34 a holding means 35 appropriate. Alternatively, in the embodiment according to 3 instead of the two lights 14 a single luminaire may be provided with larger luminous light exit surfaces for the light-emitting diodes.

Also in the embodiment according to 3 is the light output surface 19 each light pipe element 15 at a connection layer 30 of the respective light pipe element 15 provided, via which the respective light pipe element 15 with the respective side surface 16 is connected cohesively.

LIST OF REFERENCE NUMBERS

10

lighting device

12

Light guide plate

14

lamp

15

Light guiding member

16

circumferential side surface

17

light injection

18

Light-emitting surface

19

light coupling

20

led

21

interface

22

Shine light exit surface

23

beam of light

24

light

25

recess

26

Means for decoupling

27

coherent recess

28

Surface bonding layer

29

subarea

30

link layer

31

medium

33

further planar connection layer

34

conductor path

35

holding means

36

reflector device

42

cover surface

43

cover surface

54

diffuser

58

cutting plane

60

subarea

Claims (9)

Lighting device ( 10 ) with at least one light guide plate ( 12 ), at least one lamp ( 14 ) and at least one light pipe element ( 15 ), - wherein the light guide plate ( 12 ) a circumferential side surface ( 16 ) and at least one perpendicular to the side surface oriented light exit surface ( 18 ), - wherein the light-conducting element ( 15 ) a light input surface ( 17 ) for coupling the lamp ( 14 ) radiated light ( 24 ) in the light pipe element ( 15 ) and one parallel to the side surface ( 16 ) oriented light output surface ( 19 ) for decoupling the coupled-in light from the light-conducting element ( 15 ), - wherein the light output surface ( 19 ) for coupling in from the light-conducting element ( 15 ) coupled out light in the light guide plate ( 12 ) on the side surface ( 16 ), at least one means ( 26 ) for decoupling in the light guide plate ( 12 ) coupled luminaire light ( 24 ) through the light exit surface ( 18 ) is provided through, - wherein the light-conducting element ( 15 ) at least one light input surface ( 17 ) and light output surface ( 19 ) connecting interface ( 21 ), the interface ( 21 ) has an embodiment in which light rays ( 23 ) of the coupled-in light ( 24 ) of the luminaire ( 14 ), which immediately after being coupled into the light-conducting element ( 15 ) on the interface ( 21 ), at the interface ( 21 ) totally reflecting and by the total reflection by the light output surface ( 19 ) through from the light pipe element ( 15 ) are steerable out when the interface ( 21 ) of the light pipe element ( 15 ) to a pre-given medium ( 31 ), and - wherein the light guide plate ( 12 ) consists of a material having a refractive index which corresponds to the refractive index of the material from which the light-conducting element ( 15 ), equal or deviate from this by a maximum of 20%. Lighting device ( 10 ) according to claim 1, characterized in that the light output surface ( 19 ) on at least one connecting layer ( 30 ) of the light pipe element ( 15 ) is provided, via which the light-conducting element ( 15 ) with the side surface ( 16 ) connected is. Lighting device ( 10 ) according to claim 2, characterized in that the connecting layer ( 30 ) consists of a material with a refractive index, which is the refractive index of the material from which the light guide plate ( 12 ) or the light pipe element ( 15 ), equal or deviate from this by a maximum of 20%. Lighting device ( 10 ) according to one of the preceding claims, characterized in that the luminaire ( 14 ) at least one luminaire light exit surface ( 22 ) for the lamp ( 14 ) emitted light ( 24 ) having a surface connecting layer ( 28 ) with the light input surface ( 17 ) is integrally connected. Lighting device ( 10 ) according to claim 4, characterized in that the surface bonding layer ( 28 ) consists of a material with a refractive index, which is the refractive index of the material from which the light guide plate ( 12 ) or the light pipe element ( 15 ), equal or deviate from this by a maximum of 20%. Lighting device ( 10 ) according to one of claims 1 to 3, characterized in that the luminaire ( 14 ) at least one luminaire light exit surface ( 22 ) for the lamp ( 14 ) emitted light ( 24 ), wherein the luminous light exit surface ( 22 ) is spaced from the light input surface. Lighting device according to claim 6, characterized in that the light-emitting exit surface ( 22 ) of the luminaire ( 14 ) in a recess ( 25 ) of the light pipe element ( 15 ) is arranged. Lighting device ( 10 ) according to one of claims 1 to 3, characterized in that the luminaire ( 14 ) at least one luminaire light exit surface ( 22 ) for the lamp ( 14 ) emitted light ( 24 ), wherein the lighting device ( 10 ) at least two light pipe elements ( 15 ) and at least two light guide plates ( 12 ), each light guide plate ( 12 ) two cover surfaces ( 42 . 43 ) and the circumferential side surface ( 16 ), wherein a cover surface ( 42 ) one of the two light guide plates ( 12 ) on a deck surface ( 43 ) of the other of the two light guide plates ( 12 ) lies flat, wherein the light-conducting elements ( 15 ) lie flat against each other or arranged one above the other and via a reflection device ( 36 ) of a sheet-like reflective material between the light-conducting elements ( 15 ), wherein the light-conducting elements ( 15 ) each have a recess ( 25 ), which together form a contiguous recess ( 27 ), in which the luminous light exit surface ( 22 ) of the luminaire ( 14 ) at a distance from the light coupling surface ( 17 ) each of the two light-conducting elements ( 15 ) is arranged. Lighting device ( 10 ) according to one of the preceding claims, characterized in that the light guide plate ( 12 ) a variety of means ( 26 ) in the form of scattering bodies ( 54 ) for decoupling the from the side surface ( 16 ) in the light guide plate ( 12 ) coupled luminaire light ( 24 ) through the light exit surface ( 18 ).

Images