FR2987460A1 - LIGHTING DEVICE GENERATING A VIRTUAL SPHERE - Google Patents

Abstract

The device according to the invention makes it possible compactly and integrable into existing installations a lighting system producing the effect of a virtual light sphere 6 with possibilities of interactivity without material contact. The invention comprises modified Fresnel lenses 1 for producing a virtual sphere 2 whose contrast and brightness are increased by a non-homogeneous illumination system 2, 3.

Description

The present invention relates to a non-aggressive lighting device for the eyes, of very small thickness, with energy saving and without any hot spot, characterized in that the light-emitting diode it produces a virtual light envelope of spherical shape to induce interactivity without material contact with light. The invention is concerned with decoration and ambient lighting. Due to its small thickness, the device 10 according to the invention can be easily embedded in partitions or at ground level inside existing boxes whose formats are standardized. In addition it can be a block to be then integrated in design for a decorative lighting application. Due to its low heat generation and low thickness, the invention can be used as interactive products for architectural lighting, stand design, partitioning, false ceilings etc. The invention also applies to light therapy. The invention may furthermore constitute a real estate element (integration in the ground or in a wall) or a movable element (attachment to a window, in a temporary floor, etc.). It will find an interest particularly in the architecture of the building. interior. The device according to the invention comprises a lighting system 2 diffusing through a diffusing slab 3 a non-homogeneous light 5, the assembly being combined with a doublet of modified Fresnel lenses 1, 1, the device according to the invention further comprises: - Light sources 2 placed laterally at the edges of a doublet of Fresnel lenses 1, the sources 2 illuminate 4 non-homogeneously simultaneously a diffusion slab 3 and a doublet 1 for the purpose of highlighting the virtual light sphere effect 6 produced by the Fresnel lens doublet 1, - a diffusion plate 3 is chosen for its optimal light scattering properties 5 symmetrically relative to the optical axis 11 of the doublet 1, it may be an acrylic slab or a microstructured slab designed to distribute in a surface manner the light 4 from the light sources 2 placed laterally STATE OF THE ART There are systems using Fresnel lenses to produce 3-dimensional light images. Most of these systems consist of a source (a screen, an OLED panel, a video projection system) and several Fresnel lenses assembled as a double condenser. This method corrects the distortion problems caused by simple positive lenses. These assemblies 40 systematically impose a minimum distance between the sources and the lenses (at least equal to the focal length) so that an undistorted real image is formed. The thickness of these systems is for similar opening sizes 5 to 6 times greater which makes them difficult to use in the context of a commercial application for lighting (due to the thickness of the partitions, the standard and about 120mm) These assemblies do not fall within the scope of the present invention because they impose a specific size not applicable to the areas covered by the invention. The objective of the invention is to fit into this standard to cover a wider field of applications. Finally these assemblies do not mention most cases a use for lighting and the interactive dimension is mentioned only as part of a video application and for other formats. There are also devices employing microstructured Fresnel lenses to diffuse light. These devices have the function of using the Fresnel lenses as a reflector or diffuser and not for the purpose of obtaining visual effects of an interactive nature. In addition, there is a class of Fresnel slab generating spherical distortions, but the effect produced is not optimal so that it does not fulfill the purpose of the invention, namely to create a spherical accent effect virtual in order to encourage interaction at the level of a furniture or real estate support integrated in the ground or in a wall. The systems encountered do not integrate the coupling optical detection / interactivity / optical generation (by a single medium) Interactivity in hardware contact to modulate a virtual light source using sensor is mentioned only in the case of a material contact on supports (by electrostatic transfer at the level of the skin) The invention finally proposes a solution for coupling a light scattering system allied to a beam concentrator system on a hybrid photo plate - electrical conversion and light emission.

SUMMARY OF THE INVENTION The device according to the invention makes it possible compactly and integrable in existing installations a lighting system producing the effect of a sphere of virtual light with possibilities of interactivity without material contact. The invention includes Fresnel lenses modified to produce a virtual sphere whose contrast and brightness are increased by a non-homogeneous lighting system. The non-homogenization of the lighting system simultaneously makes it possible to reduce the thickness of the system in the case where the sources are placed laterally between the diffusing slab and the merged Fresnel lens doublet. The Fresnel lenses specially designed for the invention have the characteristic of forming a cone of vision which envelops a virtual sphere of light tangent to the optical system. The optical system can simultaneously perform the beam concentrator function for an infra red detection application for interactivity with digital analog dimmers connected to the light sources. DETAILED DESCRIPTION OF THE FIELDS OF APPLICATION OF THE INVENTION The invention is particularly applicable to ambient lighting, interior architecture for integrations within partitions, soil, movable or real estate. The invention can be applied to light therapy by using sources for light therapy. The present invention can be integrated into the ground so that interactivity or for a table lamp is achieved. The invention can be exploited to create "paths of light" fun that interest the world of tourism and museums. Finally, various interactive applications can be adapted for an application to learning by biofeedback (motion sensor feedback in space, light, action ...) The invention can be characterized according to the following objects: - A first object of the present invention consists in that the means for the production of a virtual sphere are of the optical type and are made from a modified Fresnel lens. A second object of the invention consists in that the optical panel is A third object of the present invention is that it comprises a slab diffusing opaque, transparent or translucent light, or comprising other elements such as an OLED slab. a diffusing filter made of acrylic or glass (opal, sandblasted). A fourth object of the invention comprises led, oled, toled or fluocompact light sources. A fifth object of the present invention is characterized in that the light diffusion slab is a mirror, or a semi-reflective slab. A sixth object of the present invention is that it comprises motion sensors of the type infra-red, - A seventh object of the invention is that the assembly comprises electromechanical transduction systems by converting vibrations into electrical energy to power light sources, - An eighth object of the invention is that the Diffusion slab is combined with a liquid crystal slab whose opacity is controlled by an electrical voltage. A ninth object of the present invention is that the thickness of the lighting system is for information purposes only. order of 45mm for a slab of 350 mm side when the light sources are placed laterally between the light scattering slab and the doublet of Fresnel lenses, a tenth object of the present invention is that the Fresnel slab receives the application of a thin-film treatment whose function is to modulate the optical scattering, an eleventh object of the present invention consists in the fact that the light sources are placed behind the diffusion plate whose symmetry of illumination has as axis of symmetry the optical axis of the doublet of lenses, a twelfth object of the present invention consists in that the slab of diffusion is semi-reflective and is associated with a liquid crystal panel whose opacity is controlled by an electrical voltage, in this configuration, the luminaire is mounted in a partition and filled three functions: glass brick (LDC transparent tile); mirror function: opaque LCD panel, lighting function: active light source (OLED or side sources) - A thirteenth object of the present invention is that the diffusion slab contains an alternation of red, green and blue columns. The width of these columns is very small (less than 51 mm) Said diffusing slab is coupled with an OLED slab whose illumination is controlled at a network of columns facing the RGB column array (red, green blue) so that the whole produces a light of any color. A fourteenth object of the invention consists in that the previously described diffusion slab acts as an extra flat RGB slab which, associated with the doublet of lenses according to the invention, makes it possible to produce a flat luminaire with a color variation and operating on a base. OLED technology. Referring to the figures, the device according to the invention comprises: - A modified Fresnel slab 1 comprising 2 Fresnel lenses la and lb 15 - Sources 2, - A light diffusion slab 3 - An armature 10 - sensors 13 - An LCD panel 15 (liquid crystal) whose opacity is controlled by an electrical voltage V 20 - A semi-reflecting slab 16 - An OLED, TOLED or hybrid slab (photovoltaic property associated with a light emission property) - Motion sensors or vibration sensors - Electromechanical converters of vibrations in electricity to power the sources 2, 25 - A semi-translucent RGB filter comprising a series of columns alternately red, green and blue, - A control of selective lighting in columns of an OLED slab, the illuminated columns facing the columns of the previously described filter. An OLED panel providing uneven illumination with central axis symmetry coinciding with the optical axis of the modified Fresnel lenses according to the invention. The lighting device according to the invention is non-aggressive for the eyes, of very small thickness and can consist of a system for lighting with energy saving. Its diffusion mechanism minimizes the creation of hot spots even from the use of LED lamps devoid of focusing optics. The device according to the invention produces a virtual light envelope 6 of spherical shape to encourage interactivity 7 without material contact with light. The device according to the invention comprises a lighting system 2 diffusing through a slab. diffusing 3 a non-homogeneous light 5, the assembly being combined with a doublet of Fresnel lenses 1a, lb special modified 1.

The device according to the invention furthermore comprises: light sources 2 placed laterally at the edges of a Fresnel lens doublet 1, the sources 2 illuminate 4 in a non-homogeneous manner simultaneously a diffusion slab 3 and a doublet 1 for the purpose of highlighting the virtual light sphere effect 6 produced by the Fresnel lens doublet 1. But the light sources 2 may be positioned behind the diffusion slab 2 to produce a source direct, - a diffusion slab 3 is chosen for its optimum light diffusion properties 5 symmetrically with respect to the optical axis 11 of the doublet 1, it may be an acrylic slab or a slab microstructured studied to distribute in a surface fashion light 4 from light sources 2 placed 10 laterally, furthermore the diffusion slab may be a mirror or a semi-reflecting slab, - An armature 10 which may comprise motion sensors and or vibration sensors 13, 13bis, 14, - an electromechanical vibration transduction system 13bis, - a digital analog control box 13 connected to the motion sensor system for modulating the luminous intensity or the color of the sources 2. In order to increase the contrast of the virtual light sphere 6 and to reduce the overall thickness of the device, the illumination produced by the sources 2 and the diffusion plate 3 is inhomogeneous and is preferentially of rotation symmetry around the optical axis 11 of the doublet 1, the doublet 1 of Fresnel lenses Ia, lb is placed facing the diffusion slab 3, the doublet 1 is designed to produce a cone of 20 vertex vision 8 producing the visual effect of a virtual sphere 6, 6a, 6b of light. More precisely, the microstructures 9 of the Fresnel lenses 1a, 1b that compose the doublet 1 are calculated by exploiting the limit refraction phenomenon, in addition to accentuating the virtual sphere effect 6. Said Fresnel lenses are modified at their surface level. microstructured by the deposition of 25 thin layers to produce inhomogeneous local scattering of the light beams 8a, 8b by microroughness effect (scalar model and pseudo periodicity effect study), the Fresnel lens doublet 1 can be arranged according to different arrangements depending on the purpose to be achieved, including the desired minimum thickness of the system. The cone of vision depends on the position of the observer (its axis varies) so that depending on the position of the observer, the resulting envelope of the cones of visions induces a spherical surface. As an example we will take a Fresnel optical slab of not equal to 0.508mm (space between two consecutive turns) The law connecting the slope of the prisms at their distance to the center will be an approximately linear law for the first centimeters. The size of the slab will be 320mmx320mm. The space between the diffusion slab and the 45mm Fresnel slab doublet. With reference to FIG. 4, the device according to the invention may consist of an element integrating into a partition in order to produce several functions: lighting elements, light window, shutter. For this it will include a diffusion slab 3 associated with a liquid crystal panel 15 whose opacity is controlled by an electrical voltage and a semi-reflective slab 16. In addition, the diffusion slab 2 may be an OLED slab and be translucent or transparent or bright. The device according to this variant may constitute a light window with 3 states: illuminated, mirror (reflecting with the semitransparent slab) 40 or transparent.

Claims (10)

REVENDICATIONS1. Thin lighting device with economy CLAIMS1. Thin-energy-saving, non-hot spot lighting device characterized in that it produces a virtual light envelope 6 of spherical shape to evoke interactivity 7 without material contact with the light, the device according to the invention comprises a lighting system 2 diffusing by means of a diffusing slab 3 a non-homogeneous light 5, the assembly being combined with a doublet of modified Fresnel 1a, 1b lenses 1, The device according to the invention comprises in addition: Light sources 2 placed laterally at the edges of a Fresnel lens doublet 1 or behind the diffusion slab, the sources 2 simultaneously illuminate 4 a diffusion slab 3 and a doublet 1 for the purpose of highlighting the virtual light sphere effect 6 produced by the doublet of Fresnel lenses 1, - A diffusion plate 3 is chosen for its properties optimal summers of light scattering 5 symmetrically with respect to the optical axis 11 of the doublet 1, it may be an acrylic slab or microstructured slab studied to distribute in a surface manner the light 4 resulting from light sources 2 placed laterally, 20 - An armature 10 which may comprise motion sensors and or vibration sensors 13, 13a, 14 - An electromechanical vibration transduction system 13a, - A digital analog control box 13 connected 14 to the motion sensor system to modulate the luminous intensity or the color of the sources 2, 25 A liquid crystal panel whose opacity is modulated by an electric voltage, - An OLED panel to create an inhomogeneous light of axial symmetry confused with the optical axis of the Fresnel lens doublet, - A TOLED slab, - A translucent, red, green, blue (RGB) filter which has bands alternately 30 ouge, green, blue, - control of the brightness of an OLED slab per strip, the latter coinciding with the bands of the RGB filter, - a translucent diffusing slab 35 In order to increase the contrast of the virtual luminous sphere 6 and to reduce the overall thickness of the device, the illumination produced by the sources 2 and the diffusion slab 3 is inhomogeneous and is preferably of symmetry of revolution around the optical axis 11 of the doublet 1, the doublet 1 of Fresnel lenses 1a , lb is placed facing the diffusion slab 3, the doublet 1 is designed to produce a vertex viewing cone 8 producing the visual effect of a virtual sphere 6, 6a, 6b of light, More precisely the microstructures 9 of the Fresnel lenses la, lb, which compose the doublet 1 are calculated by exploiting the limit refraction phenomenon, in addition to accentuate the virtual sphere effect 6, said Fresnel lenses are modified at their surface mic 9, by the deposition of thin layers to produce inhomogeneous local scattering of the light beams 8a, 8b by microroughness effect (scalar model and pseudo periodicity effect study), the Fresnel lens doublet 1 can be arranged according to different Arrangements according to the purpose to be achieved, including the desired minimum thickness of the system, the device according to the invention may comprise a semi-transparent slab, a variable-opacity liquid crystal slab and an OLED slab to constitute an inhomogeneous light source with several states: mirror, luminous state, transparent state. 2. Device according to claim 1 for producing a minimum thickness system with 2 Fresnel lenses la and lb composing the doublet 1 characterized in that the microstructured faces 9 of the Fresnel lenses la, lb which make up the doublet 1 are positioned opposed to the observer 7 in order to form the effect of a virtual double virtual envelope 6a, 6b positioned elsewhere to mask the sources 2 out of its cone of vision 8, the sources 2 being placed on the periphery of the doublet 1 at a distance much less than the focal length of the optical system. 3. Device according to claim 1 characterized in that the microstructured faces 9 of the Fresnel lenses la, lb which make up the doublet 1 are positioned in double condenser (turns facing each other); the sources 2 being placed at the periphery of the doublet 1 at a distance much smaller than the focal length of the optical system. 4. Device according to claim 1 characterized in that the sources are placed behind the diffusion slab 2 so as to directly illuminate the doublet of modified Fresnel lenses 1 while forming a non-homogeneous light source. 5. Device according to claim 1 characterized in that one uses an OLED type slab to create a non-homogeneous light source. 6. Device according to claim 1 characterized in that the lighting device according to the invention is a self-energy system, for this purpose the device is associated with a hybrid light-emitting slab 3bis (photoelectric conversion function and function of emission) to deliver a non-homogeneous light 40 that is time-adjustable and color-adjustable, the Fresnel lens doublet 1 has a dual function which is a beam concentrator to the hybrid slab and a light scattering function 5. 7. Device according to claim 1 characterized in that it constitutes an energy autonomous system, for this purpose the armature 10 comprises an electromechanical transduction system 13a vibrations of the type of those encountered in the mobile phone intended to supply energy light sources 2 and sensors 13. 8. Device according to claim 1 characterized in that it comprises motion sensors for example infrared-type sensors and transduction or vibration transducers 13 connected to sources 2 to create interactivity 7 without material contact at the level of the virtual sphere of light 6, the interactivity may consist of a modulation of the light intensity or a modulation of the color by a connection with an analog sensor RGB type. 9. Device according to claim 1 characterized in that a liquid crystal slab whose opacity is controlled by an electrical voltage, a semi-reflecting slab and an OLED slab are combined to produce a non-homogeneous light source with 3 states. : illuminated, mirror and transparent. 10. Device according to claim 1 characterized in that one combines a semi-translucent RGB filter composed of alternately red, green and blue strips facing an OLED panel whose brightness is controlled at the strips facing the filter strip. , the system for producing a non-uniform light source with variable color. 25