Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
  • G02B6/0003—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being doped with fluorescent agents
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
  • G02B6/0005—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being of the fibre type
  • G02B6/001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being of the fibre type the light being emitted along at least a portion of the lateral surface of the fibre
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/02—Optical fibres with cladding with or without a coating
  • G02B6/036—Optical fibres with cladding with or without a coating core or cladding comprising multiple layers
  • G02B6/03616—Optical fibres characterised both by the number of different refractive index layers around the central core segment, i.e. around the innermost high index core layer, and their relative refractive index difference
  • G02B6/03622—Optical fibres characterised both by the number of different refractive index layers around the central core segment, i.e. around the innermost high index core layer, and their relative refractive index difference having 2 layers only
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/02—Optical fibres with cladding with or without a coating
  • G02B6/036—Optical fibres with cladding with or without a coating core or cladding comprising multiple layers
  • G02B6/03616—Optical fibres characterised both by the number of different refractive index layers around the central core segment, i.e. around the innermost high index core layer, and their relative refractive index difference
  • G02B6/03638—Optical fibres characterised both by the number of different refractive index layers around the central core segment, i.e. around the innermost high index core layer, and their relative refractive index difference having 3 layers only
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/24—Coupling light guides
  • G02B6/42—Coupling light guides with opto-electronic elements

Definitions

• the invention relates to light-emitting devices with a light guide.
• Light-emitting devices with a light guide body are known, for example, from document WO 2006/038502 A1.
• the object of certain embodiments of the invention is to specify further light-emitting devices with a light guide body.
• An embodiment of the invention provides a light-emitting device which comprises: a radiation source for emitting radiation of at least one first wavelength, an elongated, curved light-conducting body into which the radiation emitted by the radiation source is coupled and which is first due to the coupled-in radiation Wavelength decouples light at an angle to its longitudinal axis.
• the efficiency of the light emission can be increased in this light-emitting device in that the light is arranged guide body not in the immediate vicinity of the radiation-emitting radiation source, but for example, is separated by a light guide from the radiation source.
• the radiation source is spatially separated, with the result that the operating temperature of the light guide body can be lowered, which can increase its reliability.
• the Lichtleitk ⁇ rper which is elongated, that has substantially an elongated extent, is optically coupled to the radiation source and serves both for further transport of the radiation of the radiation source and for the emission of light preferably over the entire region formed by the longitudinal direction.
• the optical waveguide can be embodied, for example, as a glass rod or as an optical fiber, in which the light is in each case guided as well as given off to the outside, for example by a corresponding surface treatment.
• the light guide body is optically coupled to the radiation source via a light guide.
• the radiation source is adapted to emit radiation in accordance with the colors red, green and blue (RGB).
• the radiation source is designed as an RGB module.
• the radiation source thus feeds radiation with different wavelengths, corresponding to the colors red, green and blue, into the optical waveguide. With a corresponding intensity of the different wavelengths in the emitted radiation, in total white light or light with a Set specific color temperature, which is emitted evenly by the light guide.
• reflective materials can be provided in a further embodiment at locations of curvature of the light guide body.
• the light guide body can be coated or printed with a reflective layer in order to prevent excessive coupling out of light energy at the curved parts.
• the surface of the light-guiding body can be roughened for better outcoupling of the light.
• the light guide body when pronounced as a glass fiber or plastic fiber on a roughened coat.
• the light guide body has a converter material which converts the radiation transported by the light guide into light of a second, longer wavelength.
• the light of the second, longer wavelength is emitted at an angle to the longitudinal axis of the light guide body.
• the efficiency of the light conversion can be increased. For example, reabsorption of the converted light of the longer, second wavelength by the radiation source can be reduced. Further, from the above-mentioned lowering of the operating temperature of the light guide body also follows a reduced temperature of the converter material, which in turn can increase its reliability.
• Such a spacing of the converter material from the radiation source can also be described as "remo- By conversion, the radiation of the first wavelength can preferably be converted to visible light of a second wavelength, wherein the second wavelength is greater than the first wavelength of the exciting radiation.
• the radiation-emitting radiation source emits short-wave radiation in the range of 210 to 500 nm, preferably in the range of 210 nm to 420 nm, more preferably in the range of 360 nm to 420 nm or in the more blue range of about 420 nm to 500 nm.
• the preferably converted-converted light of the second wavelength emitted after the conversion has a longer wavelength than the radiation originally emitted by the radiation source and may be in a wavelength range of 400 to 800 nm depending on this radiation.
• the converter material may in particular be a phosphor which can be excited by the radiation emitted by the radiation source, for example to fluorescence.
• oxide-based phosphors such as barium-magnesium aluminates doped with europium, may be used, such as BaMgAl 2 O 17 : Eu 2+.
• strontium magnesium aluminates which are also doped with europium, such as, for example, SrMgAl 2 O 7: Eu 2+ and also chloroapatites with strontium, barium or calcium of the formula (Sr, Ba, Ca) 5 (PO 4) 3CI: Eu 2+ .
• barium aluminates for example Ba3 Al28 ⁇ - ) 45: Eu2 +. All these compounds emit light in the blue wavelength range when pumped in the near UV.
• Green-emitting phosphors are for example SrAl2Ü4: Eu ⁇ +.
• Green to green yellow-emitting phosphors are, for example, chloro-silicates of the formula Ca 8 Mg (SiC> 4) 4Cl 2 : Eu 2+ , Mn 2 + , which are doped with europium or manganese, and thiogallates of the general formula AGa 2 S 4 .Eu 2 + , Ce 2 + , where A can be selected from calcium, strontium, barium, zinc and magnesium.
• the converter materials or phosphors can also be used in such a way that they emit visible white light upon excitation with short-wave radiation and thus a conversion of the short-wave radiation into visible white light occurs.
• the conversion of the radiation of the first wavelength can also result in visible light of the second wavelength, which leaves no white light impression in the viewer, but instead has, for example, yellow, green, red or another arbitrary color.
• the optical fiber may comprise fibers containing a material selected from glass and plastic.
• the light guide may also include fiber optic cables or light guide rods.
• the optical waveguide may be constructed like a fiber, wherein a cross section through such a fiber shows a core region with a high refractive index, which is surrounded by a cladding region with a lower refractive index than the core region.
• the core region is able to transport coupled modes of light and short-wave radiation, for example by means of interference and reflection.
• a plurality of optical fibers can also be present, which are combined, for example, to form a fiber optic bundle, wherein each individual optical fiber can separately transport the radiation of the first wavelength emitted by the radiation source after the coupling to the fiber optic body or to the converter material.
• a further embodiment of a light-emitting device according to the invention may also comprise a plurality of radiation sources, it being possible, for example, for a radiation source to be present for each one light guide. The radiation of the first wavelength emitted by these radiation sources can then be bundled by means of the optical fibers into, for example, an optical fiber bundle and converted into the light of the second, longer wavelength after the radiation has been transported through the optical fiber bundle by means of the converter material.
• the radiation of the various radiation sources which is coupled into different optical fibers, is converted by means of different converter materials in visible light of different second wavelength, wherein by a mixture of this visible Light of different wavelength then a homogeneous white light impression for the viewer results.
• the radiation source may comprise, for example, a short-wave radiation source, in particular a UV laser diode, for example an N-based laser diode such as an InGaN laser diode.
• a short-wave radiation source in particular a UV laser diode, for example an N-based laser diode such as an InGaN laser diode.
• UV laser diodes are particularly well suited to emit a directional UV radiation that can be well coupled into an optical fiber.
• the radiation source can be connected to dissipate the heat loss, for example, with a heat sink.
• the radiation source can be directly connected to the heat sink, or be in thermal contact with it.
• the surface of the optical waveguide is coated or printed with the converter material.
• the light guide body is designed with a diffuse material, passes through the part of the radiation of the first wavelength or the short-wave radiation from a core of the light guide to the surface of the light guide, where it meets the converter material and into the light or the radiation of the second Wavelength is converted.
• the converter material may comprise nanoparticles enclosed in the light-conducting body are.
• the advantage of nanoparticles can be that they reduce the light scattering and thus the luminous intensity of the visible light emitted by the converter material becomes more uniform.
• the nanoparticles have particle diameters which lie at a few nanometers, for example between 2 to 50 nm, more preferably between 2 nm and 10 nm, since such small nanoparticles particularly well reduce light scattering of the converted visible light.
• the particle diameter can also influence the wavelength of the converted light, for example due to the quantum size effect. For example, smaller diameter nanoparticles produce converted light of shorter wavelength compared to larger diameter nanoparticles.
• the nanoparticles of the converter material are enclosed in the sheath of an optical waveguide embodied as a glass fiber.
• the radiation of the first wavelength can partially escape from the core into the cladding region, where it in turn strikes the converter material.
• a portion of the radiation of the first wavelength is converted into the light of the second wavelength, while the remaining radiation of the first wavelength is further transported in the core of the glass fiber, ie along the longitudinal axis of the light guide.
• the curved light guide body forms a two-dimensional area.
• the light guide is bent so that it fills a given area as evenly as possible. It can be formed by the light guide surface shapes that are round or rectangular or any other have polygonal shape.
• the light-conducting body may, for example, have a meander-shaped or spiral or serpentine shape within the two-dimensional region. Because of the usually small spatial extent of the optical waveguide, in particular when designed as a glass fiber, the region in which the light guide is arranged can be made very flat. Thus, with various embodiments of light-emitting devices, thin area light sources can be manufactured and operated.
• an optical component can be present which interacts with the converted light or with a radiation of the first wavelength emerging from the optical waveguide.
• This optical component can interact, for example, with the converted light or with the radiation of the first wavelength emerging from the optical waveguide, for example short-wave radiation by means of scattering, refraction, reflection, deflection or diffraction.
• the optical component can comprise, for example, a diffusing screen which can be arranged approximately parallel to the surface formed by the curved light-guiding body or in another way in the beam path of the light coupled out of the light-guiding body.
• the converted light can be spread in space by the diffuser. Thus, a more uniform emission of the light can be achieved.
• a detection device may additionally be present which can detect and thus indicate damage to the light guide and / or the light guide body. This can be particularly advantageous because it can be quickly detected whether the optical waveguide and / or the optical waveguide are damaged and thus also harmful light is radiated to the outside for the observer.
• the detection device which can detect damage to the optical waveguide and / or the light-guiding body, also controls a power supply (current and / or voltage supply) for the radiation-emitting radiation source and can thus damage the optical waveguide and / or the light guide Switch off energy supply, with the result that the potentially dangerous emission of short-wave radiation, for example, UV radiation from the damaged optical fiber and / or the light guide is interrupted.
• a power supply current and / or voltage supply
• the detection device is able to switch off the energy supply of the radiation-emitting radiation source as a function of the detection of the damage of the light guide and / or of the light guide body.
• the detection device comprises a second radiation source for emitting radiation of a third wavelength.
• the second radiation source comprises a laser diode which is set up to emit red light.
• the second radiation source emits radiation having a wavelength in the range from 630 nm to 770 nm, for example.
• the detection device comprises a detector for detecting the radiation of the third wavelength.
• a detection of the radiation of the third wavelength can indicate a functional capability of the light guide and of the light guide body.
• the light guide and the light guide body between the second radiation source and the detector are arranged.
• the second radiation source can couple the radiation of the third wavelength at the same end of the light guide as the first radiation source into the light guide, from where it is transported with undamaged light guide and light guide over this to the detector at a remote end of the light guide. If the radiation of the third wavelength is detected in the detector, it can be assumed that both the light guide and the light guide body are undamaged and no potentially dangerous radiation can escape from the light guide or the light guide body.
• the second radiation source and the detector are arranged at one end of the light guide and the light guide body at another end of the light guide. For example, it can be detected again whether the radiation of the third wavelength emitted by the second radiation source reaches the detector. It can be assumed that with an undamaged light guide and an undamaged light guide body, the radiation of the third wavelength substantially unhindered reaches the distal end of the light guide body, wherein there is no re-radiation or reflection of the radiation of the third wavelength.
• the third wavelength radiation may reflect at the damaged location.
• the reflected radiation of the third wavelength is transmitted via the light guide body.
• the light guide depending on the location of the damage, transported back to the detector and can be detected there. In this case, detection of the radiation of the third wavelength may indicate damage to the optical waveguide and / or the optical waveguide.
• the detection can also be made dependent on a threshold, which corresponds to a low reflection of the radiation of the third wavelength with undamaged light guide and undamaged light guide body. If the detected radiation of the third wavelength is above this threshold value, damage can again be assumed.
• Damage to light guides or light guide bodies can be carried out, for example, before operation of the first radiation source, which causes the emission of light from the light guide body.
• a short radiation pulse is emitted by the second radiation source before operation and a detection result measured in the detector is evaluated.
• it can be checked prior to operation of the light-emitting device, whether a hazard-free operation of the first radiation source can take place.
• short radiation pulses can be emitted by the second radiation source and detected accordingly by the detector in order to be able to determine damage to the light guide body or light guide during operation.
• the radiation pulses of the third wavelength are preferably temporally so short that this radiation process is not noticed, for example, by a human observer.
• the detector may be coupled to one end of a light guide in a light-conducting manner, the light guide body then being arranged at the other end of this light guide.
• This light guide may be part of a larger optical fiber network, such as a fiber optic bundle.
• the other optical fibers of this bundle can then be connected to the radiation source and, for example, only this one optical fiber can be connected to the first detector.
• the Detektionsvorri ⁇ htung that can detect damage to the light guide and / or the light guide may also include a first electrically conductive compound that extends in the light guide and in the light guide. Furthermore, there are then means for checking the functionality of this first electrically conductive connection, wherein the operability of the first electrically conductive connection indicates the functionality of the light guide and the light guide.
• the first electrically conductive compound advantageously along the main axis of the light guide or the light guide and thus can particularly sensitive damage to the light guide and / or the light guide display.
• Means for checking the operability of this first electrically conductive connection may comprise, for example, a power supply which applies an electrical pulse to the first electrically conductive connection.
• ge connection for example, gives a wire, and thus checks its length over the course of the light guide. The length of the first electrically conductive connection, for example of the wire, is then determined by the pulse reflection at the other end of the wire and the transit time.
• a second electrically conductive connection to additionally run through the light guide and the light guide body, which forms a circuit with the first electrically conductive connection and furthermore the means for checking the functionality of this first electrically conductive connection comprise a device which corresponds to the device shown in FIG Circuit can detect current flowing.
• This may, for example, be a transistor circuit which only supplies the first radiation source with energy when the circuit is closed and thus indicates the integrity of the light guide and of the light guide body.
• the first and second electrically conductive connections can be brought together, for example, at the distal end of the light guide body to form a current loop, for example by means of a metal sleeve or a metal ring.
• the second electrically conductive connection extends through the light guide at a distance from the first electrically conductive connection and the means for checking the operability of the first electrically conductive connection can detect a voltage applied between the first and second electrical connection.
• the capacitor effect between the first and second electrically conductive connections spaced apart from one another can be measured, and the capacitance change or RC resonance shift can thus be measured. Disruption of the light guide or the light guide are checked.
• the light guide and the light guide body on a cladding region and a core region, wherein the electrically conductive compounds are brittle than the respective core region.
• the electrically conductive connections can also run on or in the cladding region of the light guide and / or of the light guide body, or run, for example, between the cladding region and the core region.
• the electrically conductive connections can also be arranged circumferentially in or on the optical waveguide, so that then advantageously a mechanical load bearing on the optical waveguide can also be detected from different directions. This applies analogously to the Lichtleitk ⁇ rper.
• the electrically conductive connections can also be made so thin that they preferably break before the light guide and / or the light guide body, in particular break the respective core areas.
• Brittleness is generally understood to mean the property of solids under stress to break rather than undergo plastic or elastic deformation.
• a lighting device comprising one of the above-mentioned light-emitting devices.
• Such a lighting device may for example be a lamp, table lamp, ceiling light or any other lighting devices, which are preferably designed as surface light sources.
• a further embodiment of the invention is also a display comprising one of the above-mentioned light-emitting devices.
• a light-emitting device is used as a component of such a display, which emits light flat according to the display surface of the display.
• Such a planar illumination is suitable, for example, especially for LCD backlighting.
• the invention also relates to displays in which the backlighting contains a light-emitting device as described above.
• the displays are preferably not themselves emissive and are, for example, liquid crystal displays having a liquid crystal matrix.
• FIGS. 1 and 2 show various embodiments of light-emitting devices according to the invention.
• FIGS. 3 and 4 show various embodiments of an optical waveguide with converter material.
• FIGS. 5 to 7 show various embodiments of light-emitting devices with a detection device.
• FIGS. 8A to 1OB show various embodiments of light-conducting elements with electrically conductive connections.
• FIG. 11 shows a further embodiment of a light-emitting device
• FIG. 12 shows an exemplary embodiment of a lighting device with a light-emitting device according to the invention.
• FIG. 1 shows a light-emitting device in which a radiation source 5, for example a UV diode laser, which is thermally conductively connected to a heat sink 6, emits short-wave radiation 11 (for example UV radiation), which is coupled into an optical waveguide 10 ,
• the short-wave light 11 emitted by the radiation source 5 is coupled in at one end 10A of the light guide 10.
• the optical waveguide 10 also includes a cladding region IOC, the short-wave radiation 11 transported through the optical waveguide 10 is coupled out of the optical waveguide 10 at the second end 1OB of the optical waveguide 10 and coupled into an end 2OB of an optical waveguide 20.
• the end 1OB of the optical waveguide 10 and the end 20B of the optical waveguide 20 are thus optically coupled with each other.
• the light guide 20 for example, an elongated, elongated glass rod or a glass fiber has a curvature and is executed meandering or serpentine.
• the Lichtleitk ⁇ rper is thus carried out flat and forms a two-dimensional area.
• the light guide body 20 comprises a converter material 15, via which the short-wave radiation 11, which is supplied via the light guide 10, is converted into visible light having a longer wavelength 12.
• the Lichtleitk ⁇ rper 20 transported while the radiation 11 along the longitudinal axis of the Lichtleit stresses 20, so that over the entire length of the Lichtleit stressess 20 to the second end 2OE a uniform light emission of the converted light 12 can take place.
• the surface of the light guide body 20 may be roughened to cause scattering of the converted light 12.
• FIG. 2 shows a further embodiment of a light-emitting device.
• the radiation source 5 is configured to emit red, green and blue colors corresponding to radiation and has a module 5A for generating red light, a module 5B for generating green light and a module 5C for generating blue light.
• the radiation 11, which is coupled from the radiation source 5 into the light guide 10, comprises light of different wavelengths according to the radiation emitted by the modules 5A, 5B, 5C.
• the result for the radiation 11 is white light or light of a specific color temperature, which is transported via the light guide 10 into the light guide body 20 for radiation there.
• the light guide 20 is designed for example as a curved or curved glass rod or as an optical fiber made of glass or plastic.
• the light guide 20 is designed so that both the radiation 11 is transported from one end 2OB to the other end 2OE and at an angle to the longitudinal axis, for example transversely to the longitudinal axis of the light guide 20 as light 12 is emitted.
• the light guide body 20 may have a reflective layer 20A at certain points, which prevents an excessive proportion of the radiation 11 or of the light 12 from being emitted at this point. Thus, a uniform radiation of the light 12 is achieved.
• the shape of the light guide 20 shown in Figure 2 is designed in this embodiment as a simple arc. However, other two-dimensional regions can also be formed by the light-guiding body 20, for example in the case of a meander-shaped or serpentine embodiment corresponding to the exemplary embodiment in FIG. 1.
• FIG. 3 shows an exemplary embodiment of an optical waveguide 20 which is designed as a glass fiber.
• the light guide body 20 or the glass fiber has a core 2OC and a jacket 2OD, which are shown as a cross section of an elongated glass fiber.
• a layer of converter material 15 is provided on the surface of the optical waveguide 20, by which the radiation 11 of the first wavelength converts to light of a second, longer wavelength.
• a further layer 45 is provided on the glass fiber 20, which reflects a radiation 11 of the first wavelength and is transparent to the light 12 of the second wavelength.
• the surface of the light guide body 20 may be coated or printed with the converter material 15, for example.
• Refractive indices of core region 2OC and cladding region 20D can be designed so that both a transport or a conduction of the radiation 11 by reflection and interference in the core region 2OC takes place and also meet parts of the radiation 11 through the cladding region 2OD on the layer with the converter material 15 there to generate the light of the second, longer wavelength.
• the layer 45 allows the converted light 12 to exit the light guide body 20, but at the same time prevents potentially dangerous short-wave radiation 11 from being emitted from the light guide body 20.
• FIG. 4 shows a further exemplary embodiment of an optical waveguide 20 designed as a glass fiber.
• 2OD converter material 15 is provided, which comprises nanoparticles in this exemplary embodiment.
• the light guide body 20 in turn comprises a layer 45, which is impermeable to the radiation 11 of the first wavelength and transmissive to the light 12 of the second wavelength.
• the embodiment of a light-emitting device shown in FIG. 5 comprises a detection device 25, which can detect damage to the light guide 10 and / or the light guide body 20.
• the detection device 25 has a second radiation source 25E for emitting a radiation 13 of a third wavelength, which is in thermal contact with a further heat sink 6A.
• a detector 25D for detecting the radiation 13 of the third wavelength is provided at the remote end 20E of the optical waveguide 20.
• the third wavelength radiation 13 is coupled into the optical fiber 10 in place of or in addition to the first wavelength radiation 11 to pass over Optical fiber 10 and the light guide body 20 to be transported to the detector 25D.
• the radiation of the third wavelength can be detected in sufficient intensity by the detector 25D.
• the optical fiber 10 or the optical fiber body 20 or the optical fiber 10 and the optical fiber 20 have damage, such as a breakage, the third wavelength radiation 13 can not be detected by the detector 25D or can be detected only at a low intensity.
• the light-conducting elements 10, 20 have been damaged, and that, for example, a power supply of the radiation source 5 is switched off via a coupling of the detector 25D to the first radiation source 5.
• the emission of potentially harmful radiation 11 from the light-emitting device can be prevented.
• the second radiation source 25E may, for example, be embodied as a laser for emitting red laser light. An examination for damage to the light-conducting elements 10, 20 can be carried out both before and during operation of the first radiation source 5.
• FIG. 6 shows a further exemplary embodiment of a light-emitting device with a detection device 25, in which the second radiation source 25E and the detector 25D are arranged at one end 10A of the light guide 10.
• a light guide body 20, not shown in the figure, is disposed at another end 1OB of the light guide 10, also not shown.
• it can be determined via the detector 25D based on a reflected radiation 13 of the third wavelength whether there is damage to the light-conducting elements 10, 20. For example, in the case of damage to the optical waveguide 10 and / or the optical waveguide 20, increased reflection of the radiation 13 may occur, which may be detected by the detector 25D, for example as a function of a threshold value.
• a current or voltage supply of the first radiation source 5 can be switched off, similar to the exemplary embodiment in FIG. 5, in order to prevent the escape of dangerous radiation from the light-emitting device to prevent.
• FIG. 7 shows another embodiment of a light-emitting device according to the invention, in which a detection device 25 is present, which can detect damage to the light guide 10.
• a first electrical connection 25A as a wire
• a second electrically conductive connection 25B also formed as a wire parallel to each other in the cladding region IOC of the light guide 10 and in the cladding region 2OD of the light guide.
• Both electrically conductive connections 25A and 25B are connected in a circuit and are in electrical contact with the means 25C for checking the operability of the electrically conductive connection.
• these means 25C for example a transistor circuit, simultaneously control the power supply for the radiation source 5.
• the closed circuit of the electrically conductive connections 25A and 25B interrupted
• the power supply for the radiation source 5 can be switched off immediately and thus the emission of potentially harmful short-wave radiation 11 (for example UV radiation) from the light-emitting device can be prevented.
• FIGS. 8A and 8B show an optical waveguide 10 which comprises a core region 10E and a cladding region IOC surrounding the core region 10E, the core region having a higher refractive index than the cladding region.
• the core region can conduct light or radiation, for example short-wave radiation, by reflection and interference.
• a first electrically conductive connection 25A is present, which winds around the cladding region or is arranged circumferentially around the optical waveguide and thus can detect possible damage or breakage of the optical waveguide at the various points.
• FIG. 8B is a cross section through the light guide at the position marked 200.
• an electrically conductive connection 25A two electrically conductive connections could also run on the jacket region IOC, wherein these then form a closed circuit as described above or the capacitor effect between the parallel connections can be determined, thus detecting damage to the light guide could be.
• a first electrically conductive connection 25A and a second electrically conductive connection 25B extend in the cladding region 2OD of the light guide body 20.
• FIG Fig. 9A shown light guide 20.
• two electrically conductive capable connections 25A and 25B may also pass only an electrically conductive connection through the cladding region 2OD.
• the two electrically conductive connections may, for example, run parallel to the main axis 300 of the optical waveguide, or, as shown in FIGS. 8A and 8B, they may also be wound around this.
• a first electrically conductive connection 25A and, parallel thereto, a second electrically conductive connection 25B run on the surface of the cladding region IOC of the optical waveguide 10.
• These electrically conductive connections can be, for example, described above to be connected to a circuit or a capacitor effect occurring in these parallel connections can be measured and so damage to the optical fiber can be reliably detected.
• FIG. 11 shows a further embodiment of a light-emitting device.
• the light-conducting body 20 is designed in a spiral shape.
• the radiation source 5 can in turn be embodied as an RGB module which emits the radiation 11 as substantially white light which is emitted as light 12 via the spiral-shaped light-conducting body 20.
• the radiation source 5 can be embodied as a UV diode laser in order to emit short-wave radiation 11 (for example UV radiation), which is transported via the light guide 10 to the light guide body 20, where it encounters converter material 15 encompassed by the light guide body 20. In this case, the short-wave radiation 11 is converted into light of longer wavelength 12.
• FIG. 1 shows a further embodiment of a light-emitting device.
• the light-conducting body 20 is designed in a spiral shape.
• the radiation source 5 can in turn be embodied as an RGB module which emits the radiation 11 as substantially white light which is emitted as light 12 via the spiral-shaped light-conducting body 20.
• the short-wave radiation emitted by the radiation source 5 is coupled into a light guide 10 at one end 10A of the light guide and fed into the light guide 20 after being transported through the light guide 10 at the other end 1OB of the light guide.
• the light-guiding body 20 again has converter material 15, by means of which the short-wave radiation 11 is converted into light of longer wavelength 12.
• the light guide body 20 is arranged flat in a rear projection unit 50.
• the light guide body 20 forms in this embodiment, a rectangular area, which corresponds for example to a screen surface of a display.
• an optical element 60 is provided in this embodiment, which is embodied, for example, as a diffusing screen and arranged in the beam path of the decoupled from the light guide 20 light.
• the optical component 60 By the optical component 60, a more uniform emission of the converted light 12 can be achieved.
• the rear projection unit 50 has, for example, a fiber fixing 51, via which a mechanical fixing of the light guide 10 in the rear projection unit 50 can be achieved.
• a second radiation source 25E for emitting radiation of a third wavelength 13 and a detector 25D for detecting the radiation 13 are also provided.
• the detection device 25 can be used to detect damage to the optical waveguide 10 and / or the optical waveguide 20 in order to prevent leakage of light. To prevent potentially dangerous radiation from the lighting device 100.
• the radiation source 5, for example a laser may be spatially separated spatially from the actual luminaire, which is formed by the light-conducting body 20.
• This facilitates, for example, the maintenance and accessibility of lighting devices with such light-emitting devices.
• the spatial separation for example, a replacement of the light source or a control electronics in a scheduled maintenance area, while the actual light source, the light guide 20, for example, in a difficult or complex accessible space, such as a clean room, an explosion-proof room, a Lighthouse, a transmission towers or similar.
• the spatial separation and thus simplified maintenance can also be used in displays, in particular liquid crystal displays in frequently used traffic areas or high building positions.
• the light-guiding body 20 Due to the possibility of carrying out the light-guiding body 20 with thin glass fibers or other thin light-conducting elements, in particular surface light sources with flat designs can be used as illumination means. For example, large-scale room lighting can be realized, which cause a uniform light radiation.
• the invention is not limited to the embodiments shown here.
• the features shown in certain embodiments may also be implemented in the other embodiments.
• Other variations are For example, with regard to the geometric Ausgestal ⁇ tion of the light guide 20 possible.

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• Physics & Mathematics (AREA)
• General Physics & Mathematics (AREA)
• Optics & Photonics (AREA)
• Optical Couplings Of Light Guides (AREA)
• Planar Illumination Modules (AREA)
• Arrangement Of Elements, Cooling, Sealing, Or The Like Of Lighting Devices (AREA)
• Devices For Indicating Variable Information By Combining Individual Elements (AREA)
• Light Guides In General And Applications Therefor (AREA)
• Liquid Crystal (AREA)
• Luminescent Compositions (AREA)

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• 2006
  • 2006-12-22 DE DE102006061164.0A patent/DE102006061164B4/de active Active
• 2007
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• 2014
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