FR3008479A1 - LIGHT EMITTING MIRROR WITH LIGHT EMITTING DIODES AND ITS FORMATION - Google Patents

Abstract

The invention proposes a light-emitting diode illuminating and illuminating mirror (100) comprising a facade glazing (1) with a mirror layer (2) (11), an elongate or in-frame diffusing pattern (3) on the rear side, and a diode-carrying reflective surround supplemented by a bottom reflector. For the elongate pattern (3), a distance D1 between the first longitudinal edge (31) and each emitting face of the first group of diodes (41) is at least 10 mm. For the frame pattern, a distance D1 between the injection contour of the pattern (31 '') and each emitter face of the first group (41) of at least 10mm. The bottom reflector comprises a transparent wall (1 ', 1' ') with an inner main face (11') coated with a so-called bottom reflective layer (7); with a TL light transmission of at most 10% on the outside. The invention also provides a method of forming the illuminating mirror.

Description

The present invention relates to illuminating mirrors and more particularly to a light emitting diode illuminating mirror and its forming method. Light-emitting diodes (LEDs) were originally used to provide warning lamps or indicator lights for electrical and electronic devices, and have already been used for a few years to illuminate signaling devices such as traffic lights. signaling, motor vehicle lights (turn signals, position lights), or portable lights or markers. The interest of the diodes is their long life, their illuminating efficiency, their robustness, making the equipment employing them more durable, and requiring a reduced maintenance.

Recently their use has developed in the field of mirrors to provide illuminating mirrors. From the patent application WO2012028819, in the first embodiment shown in FIG. 1, is known an LED illuminating mirror which comprises: a glazing unit with a first main face forming the rear face, and a second principal face forming the front face; a mirror central zone, diffusing patterns on the rear face of the glass obtained here by sanding or acidizing the glass, peripheral to the mirror, along the first longitudinal edge of the glazing with a width of less than 200 mm, a group of diodes inorganic electroluminescent (or LED) arranged on the side of the rear face, along the most peripheral longitudinal edge of the diffusing strip. Each of the diodes has a given emission spectrum in the visible, for example a white light, and with a main emission radius F, said first main ray, substantially parallel to the rear face. The emission cone may be, for example, lambertian. The beam of each diode is divergent and defined by a half-angle at half-height of 60 °.

The mirror further comprises on the side of the rear face, a profile forming a reflector of the light coming from the diodes, positioned along the most central edge of the diffusing band. The reflector profile is metallic, for example made of anodized aluminum, with a thickness of less than or equal to 3 mm, and comprises: a so-called main portion which is elongated and oblique with respect to the rear face, extending until it comes into contact with the rear face, - an elongated part, extending the main part, facing the rear face.

The reflector section also includes an elongated lateral portion, extending the flat portion and substantially normal to the rear face, and carrying diodes on their PCB or PCB. To hide the end of the main part, the central mirror area overflows below the main part. The mirror is fixed to a wall (wall, ceiling, partition ...) by the lateral part forming an entourage of the mirror with a return on the front face. As an example of the dimensions of the various elements: - the surface of the glazing is 600x600mm and it is an extra-clear glass of 2.9mm thickness, - the distance between the wall and the glazing is 28mm, - the width of each first illuminating strip is 40mm and the length of each first illuminating strip is 550mm, - the width of the central decorative zone is approximately 400mm, - each card holder diodes, is 10mm wide, 550mm long, d thickness of the order of 1.9 mm and, - the diodes, without optics, are of height of the order of 2 mm, width less than 6 mm, with a regular distance between diodes of 18 mm, - the height, distance between the diodes and the first scattering patterns are of the order of 15mm, the diodes have an individual power of 0.3VV (approximately), an efficiency of at least 40 Im / VV (lumens / Watt). Homogeneity can be improved without penalizing the efficiency or complicating the design of the mirror For this purpose, the present invention firstly proposes an illuminating mirror which comprises: a glazing, plane or curved, of mineral glass, said facade glazing , with a first main face forming the front face, and a second main face forming the rear face and a wafer, glazing preferably with a thickness of less than 6 mm, better than 5 mm, TL light transmission greater than 85%, better greater than or equal to 90%, - on the back side, a metal layer based on silver (preferably silver or essentially silver, and typically coated with a protective layer), called the mirror layer, giving the functionality mirror on the front face, with a luminous reflection RL greater than 85% better than or equal to 90% measured on the front side of the mirror, in particular a metal layer present in a central zone of the glass ge façade and preferably (also) periphery, - a pattern diffusing rear side adjacent to the mirror layer (preferably in the central zone), possibly surrounded by the mirror layer except in the edge or edges of the facade glazing such that shaping areas, pattern diffusing into a continuous diffusing element or more spaced scattering elements pattern of lateral dimension of at least 10 mm, even of at least 20mm and less than or equal to 230mm, better at 200mm and even less than 150mm, diffusing pattern which is chosen from at least one of the following motifs: an elongated lateral dimension pattern which is the width VV1 and of length L1 (greater than VV1), preferably greater than 100mm, of at least 150 mm, even at least 200mm, or 300mm, in particular rectangular pattern, in L in a triangle, or not geometric, preferably inscribed in a rectangular zone or in L, - disc or square pattern of lateral dimension which is the radius o u the side r1, - frame pattern, in one or more spaced bands, lateral size band (s) which is the band width VV1, frame pattern extending over a length L 1 (greater than VV1) of preferably greater than 100mm, better still at least 150mm, even at least 300mm, for example a frame whose outer contour is spaced from the edge of the front glazing by at most 50mm. The facade glazing with the diffusing pattern presents a At least 90% and even at least 95% blur on the front side, a TL light transmission of more than 40% better than or equal to 50% and even at least 65% front side.

On the side of the rear face, the mirror according to the invention further comprises a first group of light emitting diodes, in a row, on a first printed circuit board called first PCB, preferably emitting from the top and even (substantially) perpendicular to the facade glazing, carried by a profile said support piece, the diodes each having: preferably a transmitting face parallel to the first PCB, a given emission spectrum in the visible, preferably polychromatic, especially white, a main light ray F forming an angle of at most 5 ° with the facade glazing (average plane of the glazing if curved) and preferably at most 10 ° with the bottom reflector (or at the mean plane) from the bottom reflector if it is curved, concave towards the interior space), - a beam diverging and defined by a half-angle at half-height of at least 40 ° better by at least 50 ° (angle defined at from radius F of angle to 0 ° ), the adjacent diode bundles of the first group overlapping on the diffusing pattern - including an efficiency of the PCB diode array of at least 80 Im / VV. The mirror according to the invention further comprises a so-called main reflector, rear side, preferably metal or plastic profile or coated glass (metallized, lacquered, enamelled ...), having a reflective wall and / or a so-called principal reflective layer. internal space side on a given wall or opposite side and on a transparent wall (preferably plastic), main reflector facing the first group of diodes and spaced from the first group of diodes by a so-called internal space, the light rays from the diodes is propagating in the inner reflective space preferably plane or concave towards the internal space. The first PCB is arranged (substantially all) along a first longitudinal edge of the elongate pattern or surrounds (continuously or in pieces) the disk or square pattern or surrounds (in continuous or in pieces) an internal outline or external, the frame pattern said injection contour, (without necessarily being parallel or equidistant from the scattering pattern). The mirror according to the invention further comprises a so-called bottom reflector, rear-side side - in particular parallel to the facade glazing or concave towards the internal space - able to receive light beams from the face of the first group of diodes. back and back on the diffusing pattern or on the main reflector, bottom reflector spaced from the diffusing pattern with a distance H of at most 40mm, better not more than 30mm and in particular at least 10mm better from less 15mm. The bottom reflector according to the invention comprises a transparent wall - preferably with a thickness of at most 6 mm, and even at least 0.5 mm with an internal main face oriented towards the internal space (smooth or optionally textured , diffusing) and an outer main face (preferably smooth) opposite to the inner space coated with a so-called bottom reflective layer; the wall and the layer assembly having a light transmission TL external side opposed to the internal space TL of at most 10%, better at most 5% and even at most 3%. A reflective surround (back side) has the support piece and the main reflector surrounds (depending on any type of outline) the elongated pattern or the disc or square pattern. Or a reflective surround (back side) comprises the support piece surrounds the injection contour of the frame pattern and another reflective surround (back side) having the main reflector surrounds the other contour of the frame pattern. The reflective surround is a monolithic frame or a plurality of pieces abutting or spaced less than 5mm, the reflective surround being attached to the rear face, and the other reflective surrounding possibly being a monolithic frame or a plurality of pieces abutting or spaced apart from each other. less than 5mm, the reflective surround being attached to the back face. Reflector naturally means an element reflecting visible light. The first group of diodes (and preferably the entire support part) is arranged (preferably under the mirror layer and / or a masking layer), with: a distance ei between the facade glazing (preferably with the mirror layer) ) and each transmitting face of the first group of diodes greater than or equal to 5 mm better than or equal to 10 mm, a distance ef between the internal main face of the bottom reflector and each emitting face of the first group of diodes such that the difference in absolute value ei - ef is less than or equal to 20 mm better than or equal to 1 mm, and with - for the elongated pattern (rectangular band, L, U etc.), a distance D1 between the first longitudinal edge and each emitting face of the first diode group of at least 10mm, better at least 12mm and even at least 15mm and preferably at most 40mm and better at most 30mm and even at most 20mm - for the pattern in disc or square, a distance D between the b ord of the diffusing pattern and each emitting face of the first group of diodes at least 10mm, better at least 12mm and even at least 15mm and preferably at most 40mm and better at most 30mm and even at least at most 20mm - for the frame pattern, a distance D1 between the injection contour of the diffusing pattern and each emitter face of the first group 41 of at least 10mm, better still at least 12mm and even at least 15mm and preferably at most 40mm and better at most 30mm and even at most 20mm. When VV1 or VV1 is greater than 70mm, the main reflector has an inner wall (preferably flat) forming an angle of at most 5 ° with the front glazing and preferably at most 10 ° with the bottom reflector and carries a printed circuit board, called the second PCB, and in front of the support part (and the first PCB with a vertical offset tolerance), second PCB with a second group of light-emitting diodes, in a row, preferably emitting from the top and even substantially perpendicular to the facade glazing the diodes (identical or similar to the first group) each having: - preferably an emitting face perpendicular to the second PCB - a given emission spectrum in the visible, of polychromatic preference, especially white, especially similar or identical to the emission spectrum of the first group, - a main light ray F 'forming an angle of at most 5 ° with the glazing facade (average plane of the glazing if curved) and preferably at most 10 ° with the bottom reflector (or the middle plane of the bottom reflector if it is curved, concave towards the interior space ), - a beam diverging and defined by a half-angle at half-height of at least 40 ° or even 50 ° (angle defined from the radius F 'of angle at 0 °), (similar or identical to the beam of first group) the adjacent diode bundles of said second group overlapping on the diffusing pattern, in particular a color temperature distinct from at most 200K of the color temperature of the first group of diodes, in particular an efficiency of the diode assembly on PCB at least 80Im / VV.

The second group of diodes, (and the main reflector preferably) is arranged (preferably under the mirror layer and / or a masking layer) with: a distance ei between the facade glazing (preferably with the layer mirror) and each emitting face of the second group of diodes greater than or equal to 5 mm better than or equal to 10 mm, a distance f f between the internal main face of the bottom reflector and each emitting face of the second group of diodes such that the difference in absolute value ei - ef is less than or equal to 20mm better is less than or equal to 10mm, and with - for the elongated pattern (in rectangular band, in L, in U, in triangle) the diodes of the second group being along the second longitudinal edge, with a distance D2 between the second longitudinal edge and each emitting face of the second group of diodes of at least 10 mm, better still at least 12 mm and even at least 15 mm and preferably from not more than 40 mm and better not more than 30mm and not more than 20mm, - for the frame pattern the diodes of the second group being along the other distinct contour of the injection contour, other injection contour, with a distance of 2 between the other injection contour and each emitting face of the second group of diodes of at least 10 mm, better at least 12 mm and even at least 15 mm and preferably at most 40 mm and better than 30mm and even more than 20mm. The invention makes it possible to illuminate in a homogeneous and efficient manner various patterns on the back of a mirror and to hide the illuminating system (diode, transformer, etc.) attached to the rear of the facade glazing: choice of the specific background reflector with the reflective layer on the rear face, - thanks to the choice of the surround forming with the bottom reflector with a light box, - to the positioning of the diodes: orientation of F, F ', sufficient distance from the pattern diffusing by the control of the distances D1 (where appropriate D2), position vis-à-vis the diffusing pattern (ei) and the bottom reflector (ef). In addition to allow greater freedom to architects and designs, hotel rooms for example, the lighting solution is flexible adapting to the requested reasons even wide width. The Applicant has surprisingly found a significant increase in homogeneity with the bottom reflector according to the invention compared to: - a raw or polished metal plate or even coated with a white reflector on the internal space, - or even a transparent plate coated with a reflective layer on the inner side, side internal space. When the reflective layer is deposited on the back of the transparent plate, the LED light passes through the thickness of the plate before being diffused by the reflective layer. A possible explanation is that this allows certain light rays to be guided in the plate to be diffused further into the glazing and thus contribute to the homogenization of the illumination of the pattern. When the dedicated housing is formed of a transparent casing in pastique with a reflective layer is preferably chosen as plastic polycarbonate. If the illuminating mirror were placed without a bottom reflector and on a white wall, the submicron asperities would make the homogeneity even worse and the absorption of the material too strong The bottom reflector, positioned facing the scattering pattern against the surrounding area, to create a closed light box to diffuse light from the LEDs on the diffusing pattern area. The diodes are positioned to form a continuous illuminating area along the length of the scattering pattern. The "intra-group" distance between adjacent diodes of the first group may preferably be the same for all the diodes to simplify beam overlap. The arrangement of the diodes makes it possible to hide the hot spots of the diodes at large angles for the user while keeping a lighting of the effective diffusing zone while not moving too far away.

Of course, the first and second PCBs may form only one PCB, particularly flexible PCBs all around the scattering pattern. The choice to make an optimized remote diode-carrying surround of the diffusing pattern guarantees the best efficiency. The diodes are judiciously positioned around the scattering pattern. For widths beyond 70mm, the second group of diodes is necessary for homogeneity, the lighting is very homogeneous up to a pattern width of 230mm better still 200mm. In particular, the (maximum) width of the scattering pattern (constant or variable) may preferably be less than 200 mm or even less than or equal to 150 mm, in particular to leave a large (central) mirror area. A (substantially) right main reflector makes it possible to position its edge more precisely with respect to the edge of the diffusing pattern and to place the second group of diodes more easily with F 'at normal or near normal. In the present invention, the term "light-emitting diode" (or shortened diode) means a quasi-point source, generally inorganic, typically based on a semiconductor chip, a source distinct from an OLED (organic diode) providing an extended illuminating surface . Preferably according to the invention when referring to a distance of an element (diode emitting face, surrounding wall, box, base or profile return, mirror support, etc.) at the edge of the diffusing pattern is considered the distance ("horizontal") between the orthogonal projection of the element on the plane of the scattering pattern and the edge of the scattering pattern. For example, it is D1, D2 (D3 and D4 defined later). Preferably, for simplicity, the diodes of each group are chosen with the same (only) main direction of emission F. A diverging beam is chosen to spread the light sufficiently on the scattering pattern. And preferably, for uniform illumination, the diodes of each group are chosen with the same spectrum, mono or polychromatic.

The emission cone may be symmetrical or asymmetrical with respect to F. The emission cone may be, for example, lambertian. The dispersion angle, δ, of a material, is the angle between the maximum luminous intensity direction (Imax) of the reflected light and the direction of the luminous intensity of value lmax / 2, when the curve luminous intensity can be assumed to be symmetrical around the direction of lmax (which is typically the case when the angle of incidence is 0). The reflection of a material is said to be perfectly diffuse when Ô is 60 °. If Ô is close to 0 °, the reflection or transmission is considered as specular (also called regular). If 0 <Ô <15 °, the reflection or transmission is said to diffuse narrow. If 15 ° <Ô <45 °, the reflection or transmission is said broad diffusion. If 45 ° <δ <60 °, the reflection or transmission can be considered as total diffusion. TL light transmission and light reflection RL according to the invention are calculated in a conventional manner under a D65 illuminant, according to the EN410 standard. In the preferred embodiment, the reflective layer is a diffuse reflective layer, especially white, with preferably a light reflection RL greater than or equal to 80% of the outer side, opposite the internal space. For example, it is a painting, a lacquer, an enamel.

A lacquer is a non-transparent coating, generally opaque, and which may comprise at least one polymeric resin, at least one pigment, and generally mineral fillers. The polymeric resin serves to bind the pigments and mineral fillers, while the pigments are intended to impart the desired color and opacity. The lacquer may comprise, as any lacquer, a binder based on synthetic resin, of a polymeric nature. The binder is preferably based on acrylic resin, in particular crosslinked with melamine and / or an isocyanate. The binder may also be a polyurethane resin, obtained by crosslinking, by an isocyanate or a polyisocyanate, of hydroxylated resins, in particular polyester resins or polyethers, or preferably acrylic resins (or polyacrylates). This particular combination makes it possible in particular to obtain low water permeabilities, good mechanical properties (for example in terms of scratch resistance). The binder of the lacquer may also contain or be based on alkyd resin (s), obtained by chemical reaction between at least one polyol, at least one polyacid and at least one fatty acid or an oil. These alkyds are preferably short in oil, that is to say that the weight content of oil or fatty acid in the resin is preferably less than or equal to 40%. The polyols may be, for example, glycerol or pentaerythritol compounds. The polyacids may be based on phthalic anhydride. The oils can be drying (such as linseed oil, wood or china oil), semi-drying (such as soybean oil, tall oil, safflower or dehydrated castor oil), or non-drying (such as coconut oil or castor oil). In order to improve their water-resistance properties, the alkyd binders can also be modified with monomers such as styrene, vinyltoluene or acrylates or with phenolic or epoxy resins. Heat-curing aminoplast alkyd resins are particularly advantageous binders for lacquer. The aminoplast crosslinking agent is preferably a urea-formaldehyde or melamine-formaldehyde resin, which gives good resistance to water, especially when they are provided at a rate of 20 to 30% by weight relative to the dry alkyd binder.

The lacquer may also comprise a binder based on a thermosetting acrylic resin, for example obtained by crosslinking an acrylic resin carboxylated with an epoxy resin, formophenol or melamine-formaldehyde or an isocyanate, with a carboxamide-functional acrylic resin. an epoxy or alkyd binder, or an epoxy-functional acrylic resin with acids or polyamines. The lacquer preferably has a permeability to water at 25 ° C, expressed in cm3.cm.cm2.s1.Pa1 less than 10-6, or even less than 5.10-7, and especially less than 10-7. An adhesion promoter may preferably be present dispersed in the lacquer and / or in the form of a layer interposed between the lacquer layer and the bottom reflector plate. Adhesion promoters with a glass, such as silanes, can also be dispersed in the lacquer. The lacquer may comprise pigments, inorganic and / or organic, preferably mineral. Among the pigments employed, there are, for example, oxides of titanium or zirconium optionally doped with ions of transition elements, or mixed oxides of zircon type (ZrSiO4). The pigments are preferably free of heavy metals such as cadmium or lead. The lacquer may also contain mineral fillers intended to optimize its physicochemical parameters, for example its viscosity. The total content of mineral species (pigments and fillers) of the lacquer is preferably, expressed as a percentage by weight relative to the solids content, of between 40 and 70%, and even between 50 and 60%. The thickness of the lacquer is, for example, between 40 and 60 μm. The clarity L * can be at least 65.

A diffuse reflective layer is preferred on the opposite side of the inner space because it renders the colors better than with a specular reflection layer. The color temperature on the mirror is then closer to that of the diodes.

This layer may be diffuse reflection and specular for example with a coefficient in diffuse reflection equal to at least 0.8 times the coefficient in specular reflection. In an alternative and satisfactory embodiment, the reflective layer is a specular reflective layer preferably based on silver (even essentially silver and typically coated with a protective layer) with a luminous reflection RL preferably higher or equal to 85%, 88% and even 90%, on the internal space side. The edges (internal and / or external) of the scattering pattern may be straight or curved.

It is preferred that the scattering pattern be off-center, that the mirror be kept in the central area by at least 500mm by 500mm. The inner edge is spaced preferably at least 200mm from the middle of the facade glazing. The peripheral zone between the outer edge and the edge of the facade glazing with mirror is preferably at least 25 mm.

From a dimensional point of view, one can provide at least one of the following characteristics: the width of the diffusing pattern is of width less than 30% of the width of the facade glazing (even 20% or 10%), the length of the diffusing pattern is at least 50 mm, better at least 100 mm and even at least 200 mm and in particular substantially equal to the length of the lateral or longitudinal edge of the corner facing glazing (square, rectangular). .). The choice of making a "dedicated" case for a pattern diffusing in a restricted area of the total surface of the glazing is more economical than a "total" case substantially covering the rear of the facade glazing, in particular for large mirrors. size of at least 500mm in length and weight. Preferably the distance between the main reflector and the slice of the plate bottom reflector is at most 5 mm.

It is preferred that the surround has no wall connecting the main reflector to the diode support part or any other wall under the diffusing pattern. It is preferred that the entourage is based on straight profile (s) extending rectilinear optionally bent L or U (forming a frame).

It is preferred that: the length of the surround and the bottom reflector is at least equal to the length of the diffusing pattern, the length of the surround and the bottom reflector is at least 50 mm better than at least 100mm and even 200mm and in particular, substantially equal to the length of the lateral or longitudinal edge of the facade glazing, with corners (square, rectangular ...), - for an elongated pattern, the end diode of the first group (and the second group) is less than 1 cm from the first lateral edge of the scattering pattern and the other end diode of the first group (and the second group) is less than 1 cm from the second side edge of the scattering pattern. The surround preferably comprises one or internal walls, in the zones without diodes, which are at a distance less than 10mm from the edge of the diffusing pattern and optionally at most 5mm. For VV1 or VV'1 less than or equal to 70 mm, it is preferred to have, for greater efficiency: - for the elongated pattern, a distance Dr2 between the second longitudinal edge and the main reflector (the base in particular) devoid of diodes of at most 10mm and better not more than 2mm, and even at the edge, without exceeding the diffusing pattern, and possibly exceeding not more than 5mm on the inner face of the bottom reflector, - for the frame pattern, a distance Dr between the other surround (the base in particular) devoid of diodes and the other contour of at most 10mm and better not more than 2mm, and even at the edge, without exceeding the diffusing pattern, and possibly exceeding at most 5mm on the inner side of the bottom reflector. The surround comprises in particular: - one or profiles possibly devoid of diodes, including L or U, with facade glazing side a return towards the internal space, back recessed of at most preferably 5mm or edge the pattern diffusing or protruding on the edge of the scattering pattern of at most 5mm, and / or the (or each) hanging profile in the internal space and devoid of diodes, has facade glazing side, a return direction internal space, recessed not more than 5mm preferably or at the edge of the pattern diffusing or protruding on the edge of the diffusing pattern of not more than 5mm, and / or a wall or flank of a section box rectangular or square or a spacer of rectangular or square section, sidewall or spacer devoid of diodes, recessed by at most 5mm preferably or the edge of the pattern diffusing or protruding on the edge of the scattering pattern of at most 5mm. Thus, on the bottom reflector side, the possible return (s) of the profile (s) of the entourage or profile (s) of attachment of the entourage preferably exceeding at most 5mm on the bottom reflector facing the diffusing pattern. Rear side of the facade glazing, the possible return (s) of the profile (s) of the entourage or profile (s) of attachment of the entourage preferably does not exceed the rear face on the diffusing pattern. For simplicity, the surround may be of rectangular contour and / or follows the contour of the diffusing pattern preferably by means of profiles (preferably metallic) straight and U-shaped section and / or L including butted or spaced less than 1 mm or jointed by butt joint (preferably sealant). If necessary we can replace one or mirror areas outside the inner space of the entourage by one or decorative areas or even functional (switch etc). For example, a partial mirror is preferably central and a decorative glaze (white, colored, etc.) is used, preferably at the periphery.

The diffusing pattern can therefore even be peripherally and surround by the mirror layer completed by the decorative layer (enamel etc.). It is preferred that the entourage remains masked by the mirror layer and / or the decorative layer as well as the attachment of the mirror to a wall. In the case of an entourage describing a frame, all around an elongated pattern in particular inscribed in a rectangular area, the surround may comprise laterally connecting the main reflector and the support part a first part or side part along a first side edge of the elongate pattern, carrier of a PCB called third card with a third group of diodes identical or similar to the first group of diodes, the third PCB optionally comprises a reflective covering layer around the third group of diodes, with: a distance D3 between the first lateral edge and each transmitting face of the third group of at least 10 mm, better still at least 12 mm and even at least 15 mm and preferably at most 40 mm and better at most 30 mm and even at most 20mm, a distance e3 between the facade glazing (preferably with the mirror layer) and each emitting face of the third group less than or equal to 10 mm, distance e3 between the inner main face of the bottom reflector and each emitting face of the third group such that the difference in absolute value e3 - e'3 is less than or equal to 20 mm better is less than or equal to 10 mm. And the entourage may comprise laterally connecting the main reflector and the support part, a second part or lateral part carrying a PCB called fourth PCB with a fourth group of diodes identical or similar to the first group of diodes, the fourth card PCB optionally comprises a reflective covering layer around the fourth group of diodes, with: a distance D4 between the second lateral edge and each emitting face of the fourth group of diodes of at least 10 mm, better still at least 12 mm and even at least 15 mm and preferably at most 40 mm and preferably at most 30 mm and even at most 20 mm, - a distance e 4 between the facade glazing (preferably with the mirror layer) and each emitting face of the fourth group of diodes less than or equal to 10mm, a distance e4 between the inner main face of the bottom reflector and each emitting face of the fourth group of diodes such that the difference in absolute value e4 - e4 is less than or equal to 20mm better is less than or equal to 10mm.

Naturally the first, second, third, four cards can only form a PCB, especially sufficiently flexible PCB. When the elongate pattern is of length L1 greater than or equal to 200 mm, if diodes are placed along one or more lateral edges of the elongate pattern, a certain inhomogeneity which is nonetheless acceptable is allowed locally.

In another case with an entourage describing a frame, all around an elongated pattern, the surround may comprise laterally connecting the main reflector and the support piece: a first piece or a lateral part along a first lateral edge of the frame; elongate pattern, devoid of diodes, - a second piece or side portion along a second side edge of the elongate pattern, devoid of diodes. In the absence of the third group and the fourth group of diodes it is preferred to have, for greater efficiency: a distance Dr3 between the first lateral edge and the first lateral piece of at most 10 mm and better not more than 2 mm , and even at the edge, without exceeding the diffusing pattern, and possibly exceeding by not more than 5 mm on the inner face of the bottom reflector, - a distance Dr4 between the second lateral edge and the second lateral piece of not more than 10 mm and better not more than 2mm, and even at the edge, without exceeding the diffusing pattern, and possibly exceeding at most 5mm on the inner face of the bottom reflector. In a preferred embodiment for eliminating as much as possible the hot spots at large angles, the surround carries diodes of the first group, possibly of the second group, and other diodes (along the side edge or edges of an elongated pattern, for example ), the distance between the emitting face of each of the diodes and the edge of the nearest pattern is at least 10mm and preferably at most 40mm. Better the distance between the emitting face of each of the diodes and the edge of the nearest pattern is at least 12mm and even at least 15mm and better at most 30mm and even at most 20mm. It is preferred to significantly reduce the vision of the low-angle hot spots of a user, at a short distance from the mirror in the central area, that: - when VV1 70 mm, the first longitudinal edge of the elongated pattern is the innermost, the reflector main, along the second longitudinal edge is devoid of second PCB with diodes or - when VV1 70 mm, the injection contour of the frame pattern is the innermost of the contours, and the other contour, is devoid of second PCB with diodes.

When VV1 70 mm or when VV1 70 mm, the main reflector may be oblique or preferably has an inner wall, flat, forming an angle of at most 5 ° with the facade glazing and preferably at most 10 ° with the bottom reflector. The elongate pattern may be inscribed in a rectangular R-shaped area where the pattern is square or disk or is in a frame, and the reflective surround forms a rectangle (and the other reflective surround forms a rectangle). The elongate pattern may be of particular shape, in particular in the form of an L or comb, the reflective surround along the edges of the elongate pattern. The elongated pattern may be inscribed in a rectangular strip extended by at least one other rectangular band, such as an L (a T, an F, an E, a comb, etc.), with a protruding distance from the other band less than 20mm, the PCB in front of the longitudinal edge of the pattern with the other band is linear. The elongated pattern may be inscribed in a rectangular strip extended by at least one other rectangular band, such as an L or F or E, with a projection distance of each other band is greater than 20mm, the first PCB in front of the first longitudinal edge of the pattern with the return follows the outline of the pattern, skirting the other band. In one embodiment, at least with an edge, said end, diffusing pattern is up to a shaped edge of the edge of the facade glazing or within 2mm of the shaped edge. The reflective surround for the elongated or disc or square pattern, the reflective surround or the frame pattern of the other reflective surround includes a so-called end piece having a base whose width is less than or equal to the width the shaped edge is against, fixed or bonded to the shaped edge (rear face) - for example by a sealing element such as silicone sealant - and a return to the internal space against or preferably attached to the bottom reflector preferably by an adhesive, in particular an L-shaped section piece, end piece devoid of diodes. The end edge may be all or part of a side edge of the elongate diffusing pattern or all or part of the outer longitudinal edge of a long side or a short side of the frame pattern or one side of the square pattern or disc . Two side edges of the elongated pattern may be end edges (each with an end piece as described) and optionally all or part of the outer longitudinal edge may be an end edge.

Thus when VV1 70mm, the second longitudinal edge of the elongated diffusing pattern is the outermost (of the central area of the mirror), includes all or part of the end edge, the main reflector has the end piece or when W'1 70 mm, the other outline of the frame pattern is the outermost, includes all or part of the end edge and the other reflective surround includes the end piece. The end piece can be less than 2mm wide even at 1mm. It is preferably a straight section section L along the end edge, profiled on the bottom reflector such as glazing. The shaping may be: - cut-to-square, round or square notch, - cut edges or bevelled edge; or grinded or grinded ground or grind smooth or polished with a matte (satin) or polished slice for example according to EN12150, - or a shaping like a chamfer, a bevel.

The width of the shaped edge can be at most 4mm and even 2mm or 1mm. The term wall for the bottom reflector is taken in the broad sense, and does not imply a minimum thickness. It can be a movie or a sheet. The wall may be flexible or rigid, mineral or organic.

The term plate for the bottom reflector is taken in the broad sense and does not imply a minimum thickness. It can be a film or a leaf, it can be flexible or rigid, mineral or organic. For a better mechanical strength, however, a rigid wall is preferred for the bottom reflector (bottom of a box or plate). It is also preferred for heat resistance even better a mineral glass plate with a thickness of less than 6 mm and at least 0.5 mm. The transparent, flat or concave wall towards the internal space may be a plate, the reflective surround (and even the other reflective surround) forms a spacer between the plate bottom reflector and the facade glazing the reflective surround ( and even the other reflector surround) extends to leave a maximum clearance of less than 5mm with the glazing facade The transparent wall plate can exceed at most 5mm of the entourage. The transparent wall may be glazed, flat or curved toward the internal space, made of mineral glass with a thickness of less than 6 mm.

The transparent wall may be plastic with a thickness of less than 6 mm, preferably chosen from polycarbonate or polymethylmethacrylate. The wall of the bottom reflector may be a plastic film such as a fluoropolymer film, in particular FEP (Fluorinated ethylene propylene in English), ETFE (ethylene-co-tetrafluoroethylene in English). In particular, it is possible to envisage as a bottom reflector a transparent wall (glass or even plastic), in particular a glazing unit or the bottom of a transparent box (planar or concave), with on the inner space side a diffuse white reflection layer: enamel, lacquer (as already described), paint, qualified as a white reflector, with a TL of at least 20% or even 30% and on the opposite side to the internal space, a specular reflection layer such as a mirror with money. The support piece (preferably metal) and / or the main (preferably metallic) reflector, preferably the surrounding (preferably metallic) and even the other (preferably metallic) surround is chosen from: - a hollow spacer or in particular with a rectangular or square lateral section between the facade glazing and the bottom reflector, preferably adhesively secured to the façade glazing and to the flat plate bottom reflector, in particular a spacer having a thickness greater than or equal to 5 mm (by example for prefixing a double-sided adhesive) and preferably at most 15 mm, - a preferably U-shaped part or Z or H turned to 900, which comprises a carrier base of the first PCB and on both sides of first and second wings or returns, the first return being between the base and the facade glazing preferably being fixed by adhesive (preferably double-sided), and the second return being between the bottom e and the bottom reflector in flat plate preferably being fixed by adhesive (preferably double-sided), returns with identical orientations to the internal space or opposite the internal space, or with opposite orientations, back each preferably of width greater than or equal to 5 mm and preferably of at most 30 mm, - an L-shaped part which comprises a bearing base of the first PCB and on either side a single wing or return, the return being between the base and the bottom reflector preferably fixed by adhesive (preferably double-sided) to the bottom reflector in a flat plate, - an I-shaped part (of rectangular or square lateral section) in particular of thickness less than 5 mm and even at 3mm or 1.5mm which has a bearing base of the first PCB fixed by profile (s) to attach to the flat plate bottom reflector and / or facade glazing.

For example, an L-shaped attachment profile is mechanically fixed to the base and fixed by an adhesive (preferably double-sided) to the facade glazing (under the mirror layer), and another L-shaped attachment profile mechanically fastened to the base and fixed by adhesive (preferably double-sided) to the bottom reflector, each profiled with a width greater than or equal to 5 mm and preferably not more than 30 mm.

For the entourage are typically selected four U-shaped or I with brackets or four spacers rectangular or square section. The surround (and / or the other surround) may preferably comprise one or internal walls, in the zones without diodes, which are at a distance less than 10 mm from the edge of the scattering pattern and possibly at most 5 mm.

The entourage (and / or the other entourage) comprises for example: - one or profiles possibly devoid of diodes, in particular L or U, with facade glazing side a return towards the internal space, return indented d at most 5mm or preferably at the edge of the pattern diffusing or protruding on the edge of the scattering pattern of at most 5mm, and / or the (or each) fastening profile in the internal space and devoid of diodes, comprises on the facade glazing side, a return toward the internal space, preferably at least 5 mm recessed, or at the edge of the diffusing or protruding pattern on the edge of the scattering pattern of not more than 5 mm, and / or wall or side of a box of rectangular or square section or a spacer of rectangular or square section, sidewall or spacer devoid of diodes, recessed by at most 5mm preferably or at the edge of the pattern diffusing or protruding on the edge of the pattern diffusing of not more than 5mm. Thus, on the bottom reflector side, the possible return (s) of the profile (s) of the entourage or profiling (s) of attachment of the entourage preferably exceed at most 5mm on the bottom reflector facing the diffusing pattern. Rear side of the facade glazing, the possible return (s) of the profile (s) of the entourage or profiling (s) of attachment of the entourage does not exceed (s) preferably of the back side on the motive broadcasting.

The plastic bottom reflector may be a plate extended on either side by the main reflector and the support piece, forming a monolithic piece called caisson. We can consider any section of box. It is preferred that the box has one or more returns to the internal space (or opposite) of at least 5 mm for fixing for example by adhesive (double-sided) otherwise one or more preferably at least two profiles hooks like brackets mechanically fixed preferably to the box. In particular, the monolithic box may be I-section, thickness or connection width with the rear face less than 5 mm in particular of at most 2 mm (possibly with sidewall (s) or wall (s) sub-area (s) shaped (s) of the facade glazing). The box is attached to the rear face, under the mirror layer, directly by an adhesive (double-sided) on its edge and / or indirectly via at least two hanging profiles, in particular L, in the internal space, with adhesive (double-sided) on their edges, along at least two walls or opposite sides of the box.

We can prefer a fixing by three or four sides of the box for example with three or four profiles (one profile per sidewall). The casing, for example, less than 2 mm thick, is preferably chosen from polycarbonate or polymethyl methacrylate (PMMA). It is preferred that the scattering pattern be off-center, that the mirror be kept in the central area by at least 500mm by 500mm. The inner edge is spaced preferably at least 200mm from the middle of the facade glazing. The peripheral zone between the outer edge and the edge of the facade glazing with mirror is preferably at least 25 mm. Preferably, a central mirror zone is preserved over at least 30% or even the majority of the surface of the facade glazing, still 60 or even 80%. Preferably the first PCB comprises a reflective covering layer around the first group of diodes and the second PCB comprises a reflective covering layer around the second group of diodes and the same for any third or fourth PCB.

The diffusing pattern is a texturing of the rear face and preferably a sandy back side. The diffusing pattern is arranged on the rear face to be protected and the front face preferably in contact with the external environment can be smooth and easily cleaned.

The diffusing pattern is preferably formed by surface texturing of the glazing, in particular sandblasting, acidizing, abrasion or by adding a diffusing element, especially in a layer, preferably by screen printing of an enamel or a diffusing layer or formed from a diffusing plastic material. If the diffusing pattern is enamel, acidification is formed the diffusing pattern on a glazing with a partial mirror. The sanding allows him to remove the mirror (painting and silvering). Acid etching, sandblasting, etching (advantageously by laser) or screen printing may be preferred because providing a delineation of the treated areas easily controllable and reproducible industrially.

Acidic glass includes the SAINT-GOBAIN GLASS Satinovo® glass and the SAINT-GOBAIN GLASS Smoothlite® diffuser glass. The glazing (bare) can have a TL of at least 70%, better by at least 80%. The glazing can be made of clear or even extra-clear mineral glass. For extra-clear glass; reference can be made to application W004 / 025334 for the composition of an extra-clear glass.

In particular, it is possible to choose a silicosodocalcic glass with less than 0.05% of Fe III or Fe 2 O 3. We can choose, for example, the SAINT-GOBAIN Diamant® glass, the SAINT-GOBAIN® Solar Glass®, the SAINT-GOBAIN® Albarino® glass (textured or smooth), the Pilkington OptiVVHITE® glass, and the Schott B270® glass. In addition, a mineral glass is preferred for the facade glazing for its many advantages: - the glass having a good resistance to heat, it can be close to the diodes despite the fact that they constitute hot spots, - the glass is mechanically resistant so that it is easy to clean and does not scratch, which is of particular interest for panels installed in places imposing strict hygiene, - glass meets the requirements of fire safety standards. It may be as an example, depending in particular on the aesthetic rendering or the desired optical effect and / or the destination of the mirror: - glass of standard composition, such as Planilux® glass from SAINT-GOBAIN GLASS , of slightly green coloring, extra-clear glass without coloring (neutral) such as the Diamant® and Solaire® glasses of SAINT-GOBAIN GLASS. According to one characteristic, the diodes can be encapsulated, that is to say that is, to include a semiconductor chip and an envelope, for example epoxy resin or PMMA, encapsulating the chip. The functions of this envelope can be multiple: protection of the oxidation and humidity, conversion of wavelength, diffusing element. The diode may be for example a semiconductor chip of the order of one hundred pm or mm; and possibly with a minimal encapsulation for example of protection. It is not necessary to use optics such as lenses directing the light emitted by the diode to the privileged areas. The diodes can be embedded in a common protective material (waterproof, dustproof ...).

Preferably, the diodes can thus be simple chips or with a low volume encapsulation of the SMD type ("Surface Mounting Device" in English) or "Chip on Board" rather than the conventional, (first generation) voluminous diodes. low power and luminous efficiency. From a dimensional point of view, it is possible to provide at least one of the following characteristics for the diodes: the diodes are less than 1 cm high, or even 5 mm, the diodes are less than 1 cm in width (diameter), the diodes are identical and regularly spaced from one another with an intra-group distance designating the distance between the axes of the successive diodes, possibly of the same order as the eigenvalues of the diodes, the number of diodes of the first group is at least equal to to 10. The diode can be: - a diode "medium power" that is to say greater than 0.1 VV or brightness greater than or equal to 8 lumens, - a diode "high power" that is say greater than or equal to 1 VV or brightness greater than or equal to 80 lumens. The robustness of the diodes is particularly interesting in intensive uses such as in public transport such as trains, planes, coaches, pleasure boats ... The group or groups of diodes can be coupled to control means for transmitting light is permanently or intermittently, with different intensities, or a given color, or different colors, especially depending on the amount of natural light.

It can be provided that: the length of the PCB is substantially equal to the length of the support piece, the first PCB (each PCB) is less than 1 cm thick better than or equal to 5 mm, first PCB is flexible and for example surrounds the scattering pattern, - the diodes and / or the PCB are free of layer, varnish or sealing encapsulation. A reflective surface for providing mirror function is usually a silver-based layer. The mirror may be the SGG Miralite product of the Applicant Company, with a protective paint for oxidation. The mirror according to the invention can include any other functional coating (anti-scratch, antifouling, etc.) on the back side of a heating layer for an anti-condensation effect.

The lighting of the first illuminating area can be decorative, architectural, signaling or display. The illuminating and illuminating mirror may be particularly intended for: - the building, as a ceiling lamp, wall tile; a partition, - to a transport vehicle, in particular public transportation, train, metro, tramway, bus or aquatic or aerial vehicle (airplane), - street or urban lighting, - a window of street furniture, as a part of a bus shelter, a railing, a display, a display case, a shelf element, - an interior furnishing glazing, a bathroom wall, a piece of furniture. If necessary we can replace one or mirror areas outside the inner space of the entourage by one or decorative areas or even functional (switch etc). For example, a partial mirror is preferably central and a decorative glaze (white, colored, etc.) is used, preferably at the periphery.

The diffusing pattern can therefore even be peripherally and surround by the mirror layer completed by the decorative layer (enamel etc.). It is preferred that the entourage remains masked by the mirror layer and / or the decorative layer as well as the attachment of the mirror to a wall.

Finally, the invention proposes a method of forming an illuminating mirror comprising a plurality of diffusing entities on a so-called carrier facade glazing on the rear face of a so-called mirror layer of silver layer, diffusing entities inscribed in a rectangular zone Rtot of width VVtot greater than 230 mm, the method comprising the division of the rectangular zone Rtot into several rectangular zones R1, R2, R3, each of width less than 230 mm defining a given scattering pattern, each zone R1, R2, R3 being surrounded by a reflective surround with diodes having a distance of at least 10 mm, preferably at least 12 mm and even at least 15 mm and preferably at most 40 mm and better at most 30 mm and even at most 20 mm between each emitting face of the diodes and the rectangular zone, each reflective surround being preferably under the mirror layer, each reflective surround being against or even fixed to a bottom reflector or each Reflector ntourage part of a monolithic piece shaped box. At least one or each reflective surround is or against or even attached to a bottom reflector which preferably comprises a transparent wall with an internal main face oriented towards the rear face and an opposite external main face, external main face coated with a layer reflective so-called background; the transparent wall assembly and bottom reflective layer having a TL light transmission of at most 10%, outer side, opposite to the internal space. And / or at least one or each reflective surround is part of a box-shaped monolithic piece further comprises a bottom reflector preferably with a transparent wall with an inner main face oriented towards the rear face and an opposite outer main face. outer main face coated with a so-called bottom reflective layer; the transparent wall assembly and bottom reflective layer having a TL light transmission of at most 10% externally, opposite the internal space. It is preferred that all the enclosures are part of boxes (with possible common wall) or are spacers (with possible common wall) with a plate bottom reflector. The length of at least one zone R1 to R3 is at least 200 mm, preferably at least 400 mm. Preferably the width of a zone R1 to R3 is at most 150 mm and even at most 120 mm and at least 10 mm and better still at least 20 mm. It is possible to provide a support for fixing the mirror, said mirror support, preferably a metal support (and a rear face), fixed to the rear face and / or to the bottom reflector, in particular which comprises an attachment aperture or means for fixing to a wall, especially a wall or furniture. The mirror support may therefore be devoid of any protruding part of the edge of the facade glazing and is chosen from: - one or more profiles fixed to the rear face, preferably metallic, and / or a (preferably metallic) plate fixed by bonding or mechanically on the outer main surface of the u bottom reflector and with a fastening means (hook, retaining means, etc.). The mirror support in particular forming: - a monolithic frame in the central zone of the mirror and / or peripheral of the mirror, in particular distinct from the dedicated or common waterproof housing, spaced apart frame or attached to the housing, - several profiles including frame (two, three or four straight sections spaced or abutted) in the central zone of the mirror and / or peripheral of the mirror, in particular with at least one section distinct from the dedicated waterproof case (of the entourage) or of the common box, spaced or folded and / or possibly at least one profile serving for the entourage, and / or two lateral or longitudinal profiles to the facade glazing possibly serving for the surrounds of several diffusing patterns. It may be preferable to leave a free space in the central area to place a non-condensing heating element of the mirror layer. The bottom reflector may be of any shape rectangular or round or square. It can be a metal frame or plastic or glass all around the facade glazing to serve for several diffusing patterns and leave in the center space for attachment to a wall. The mirror support is for example spaced or attached to the outside of the entourage and / or the dedicated or common housing, in particular with a hooking aperture sufficiently offset from the bottom reflector for attachment to a fixing wall (furniture, Wall). The mirror support may have an attachment aperture in a plane parallel to the rear face or normal to the rear face. The fixing wall (wall or furniture) may have one or more fastening hooks. It may be desired to use in particular use profiles for the entourage that are not strong enough to participate in fixing the mirror, being too thin typically.

In a first embodiment, the bottom reflector is a plate (flat or concave towards the facade glazing, without returns against the rear face), the mirror support comprises a profile which forms a wall of the surround (support piece, reflector main etc), including a U-section straight section or closed type of square or rectangular. The mirror support is fixed for example an adhesive (double-sided) on the bottom reflector, preferably identical (or similar) to an adhesive (double-sided) for fixing (fixing) to the facade glazing. This mirror support may have at least one part or end protruding from the bottom reflector (under the rear face, on the mirror layer) for fixing the illuminating mirror to a wall (the two ends or protruding ends of the bottom reflector are better provided). on two opposite edges of the bottom reflector). The profile is preferably metal (aluminum etc.) at least 1.5 mm thick. The double-sided adhesive between the mirror support and the bottom reflector may have a width (of contact with the bottom reflector) of at least 10 mm and in particular identical to that with the facade glazing and even a thickness of less 1mm. In this embodiment we take advantage of the mounting profile to form the housing or even the support part. This profile may be more peripheral than the diffusing pattern or in the central area of the mirror.

In a second embodiment, the bottom reflector is a plate (flat or concave without returns on the rear face), the mirror support forms a wall of the surrounding (support piece, main reflector, etc.), in particular is a profile (straight ) of U-shaped or closed section of rectangular or square type. This mirror support is adhesively secured to the edge of the bottom reflector.

Other details and advantageous features of the invention appear on reading the examples of illuminating mirrors according to the invention illustrated by the following figures: FIGS. 1, 2, 3, 4, 5, 6, 7, 8, 9 , 9 ', 9 "are schematic views, possibly partial, in section of a light-emitting diode illuminating mirror in different embodiments of the invention; FIGS. 1', 1a, 2 ', 2a, 3a, 4a; 5a, 5'a, 5 ", 6a, 6'a, 7a, 8a are schematic front (back side) views of the illuminating mirrors; FIGS. 1a, 1b to 11 show examples of the diffusing patterns and the arrangement of the diodes on the PCB, FIGS. 1m and 1n show examples of profiles with PCBs and diodes used for two adjacent diffusing patterns.

It is specified that for the sake of clarity the various elements of the objects (including angles) represented are not necessarily reproduced on the scale. FIG. 1 schematically represents a longitudinal sectional view of a light-emitting diode illuminating mirror 100 in a first embodiment of the invention.

The mirror 100 comprises a front glazing 1, made of flat mineral glass, for example a rectangular glass sheet, with a first main face 11 forming the rear face with lateral and longitudinal edges, and a second main face 12 forming the front face. , and a slice 13, glazing preferably less than 6mm thick, with a light transmission of at least 85%, such as the PLAN ILUX glass sold by the applicant company. The rear face 11 is coated with a metal layer 2 based on silver (made by silvering) called the mirror layer, giving the mirror functionality on the front face, with a light reflection RL of at least 85%, coated itself a protective layer (not shown), mirror layer present in particular in a central zone of the facade glazing, and at the periphery of the glazing. Take for example a glass with a partial mirror MIRALITE or MIRALITE EVOLUTION sold by the applicant company. On the rear face, a diffusing pattern 3 is adjacent to the mirror layer 2 in the central zone, the mirror layer surrounding the diffusing pattern, preferably alone or possibly with a masking layer (decorative enamel, etc.). More specifically, it is preferred that the rear face 11 comprises the mirror layer with one or discontinuities formed or filled by the diffusing pattern and even other scattering patterns. The diffusing pattern is capable of modifying the light transmission of the facade glazing 1, for example so that it is between 40 and 85% on the front side of the mirror. The diffusing pattern prevents too intense transmission of the rays (direct lateral or reflected by the bottom reflector in particular) emitted by the diodes, substantially reduce the glare of an individual looking towards the mirror 100. The facade glazing 1 with the Diffusing pattern 3 has a blur of at least 90% or even at least 95% on the front side of the mirror as measured by Hazemeter conventionally. The pattern diffusing on the rear face 11 of the glass is preferably obtained by texturing the glass preferably already coated with the mirror layer, in particular by sanding. The pattern can also be formed by acidifying the glass as produced for the SAINT-GOBAIN GLASS Satinovo® glass. Finally, the diffusing pattern 3 may be a diffusing layer (in this case a partial mirror is preferably made from the outset) preferably mineral essential, for example made by screen printing of an enamel (white) screen printing having the advantage of allow to obtain any type of design with well-defined boundaries. It may be an enamel such as that made for Smoothlite® glass from SAINT-GOBAIN GLASS or a Lambertian enamel for example as described in the example of application WO2012168647 To form a luminous pattern, one chooses placing on the side of the rear face 11 a first group of inorganic light-emitting diodes 41 (or LEDs) along the longitudinal edge 31 preferably the innermost to the diffusing pattern 3. The choice of the internal edge avoids visual discomfort ( hot spots at low angle, less than 10 °) when a person looks at the mirror in the central area at close range. Preferably, for simplicity, the PCB 40 is parallel to the inner edge and all along the inner edge 31. The diodes are aligned, in a row, and evenly distributed on the first PCB 40, of the bar type (rigid or flexible ), rectilinear, in particular aluminum, and optionally with a diffusing layer around the diodes 41, for the recycling of rays, in the form of a white paint or lacquer. It is preferred that the end diodes be within 1 cm of the side edges of the elongated pattern. For simplicity of assembly, the diodes 41 each have an emitting face perpendicular to the PCB 40 ("top emitting English") rather than a lateral side emission ("side emitting" in English). The first PCB 40 is carried (from the rear) by a profile said support piece 51. Here is inserted a thermal conductive fastening material 6 which is for example glue or double-sided adhesive tape to obtain even better thermal dissipation. The adhesive tape has the advantage of providing a calibrated thickness, allowing the PCB of the diodes to be perfectly flat and to ensure that the diodes are all equidistant from the reflector or scattering pattern. In addition, the adhesive tape allows its prior attachment to the PCB. It is also possible to use thermal grease between the PCB and the base, such as the compound CK4960® sold by Jetart. The PCB 40 may be metallic. Then the diodes are soldered on tracks that are electrically insulated from the metallic material of the PCB. Since the metallic material of the PCB is thermal conductor, the PCB can be directly pressed against the thermal conductive base to achieve heat dissipation. Fixing the PCB to the base can then be carried out for example by clipping and / or screwing but it can retain a double-sided adhesive.

The diodes 41 are SMD type or "Chip on Board" type. Each of the diodes 41 has a given emission spectrum in the visible, for example a white light, and with a main emission radius F, said first main beam, forming an angle of less than 5 ° with respect to the facade glazing 1. If the radius F is very inclined towards the mirror layer then the LEDs are visible more easily by the user.

To facilitate homogeneity, the diodes are preferably chosen with the same (only) main direction of emission F. For uniform illumination, the diodes are chosen with the same spectrum in the visible, mono or polychromatic. We prefer a white or yellow light. The emission cone may preferably be symmetrical with respect to F. The emission cone may be, for example, lambertian. The beam of each diode is divergent and defined by a half-angle at half-height of 60 °. The adjacent diode bundles of the first group overlapping on the surface of the scattering pattern. The distance e between the emitting face and the rear face (the mirror layer) is greater than 5 mm better than or equal to 10 mm in order to prevent the diode from heating the paint and the silvering thus degrades it. The distance ef between the emitting face and the bottom reflector is such that ei - ef 20mm, better '10mm, to improve the homogeneity of the illumination. The radius F may preferably be centered. The distance e is substantially equal to ef and between 15mm and 25mm.

In order to make the lighting efficient and durable, a light reflector box defining an internal space 14, dedicated to the diffusing pattern, and comprising: a reflective surround surrounding the diffusing pattern, of external length greater than or equal to the length L1 and of external width greater than or equal to the width VV1, glued to the facade glazing by the rear face 11 by an adhesive 61, for example sealing with liquid water including a double-sided adhesive tape, - in several parts, profiled, spaced apart less than 5 mm or to be sealed by so-called butt joints which are putty 63, - or alternatively in a piece forming a monolithic frame (preferably of rectangular shape), - a bottom reflector under form of a transparent plate 1 ', said bottom, such as a mineral glass pane or a plastic coated on the rear main face 11' opposite the main face 12 'opposite the pattern diffusing 3, a reflective layer preferably diffuse reflective reflection 7, white, which is a lacquer or paint or an enamel, bottom reflector longer than the length L1 and width greater than the width VV1, glued with the surrounding by an adhesive 62 for example sealing liquid water including a double-sided adhesive tape, bottom reflector 1 'whose slice 13' is vis-à-vis the slice 13 or preferably back a few mm at least, - the facade glazing 1 in the area of the diffusing pattern 3, forming the cover of the housing if necessary, waterproof liquid water.

If the design of the pattern allows (as detailed later), it is preferred that the reflective surround forms a rectangular frame from two, three or four straight sections (preferably curved) and preferably of section (constant), of height (constant) and identical material. In fact one can choose as many profiles as sides of the diffusing pattern for example six profiles for an L etc.

When the diffusing pattern is elongated, inscribed in a rectangular area; defined by two longitudinal edges and two lateral edges The reflective surround therefore comprises for example four U-shaped profiles 51 to 54 identical with a base perpendicular to the facade glazing and on both sides of the base two wings or returns oriented towards the internal space 14, therefore: - the support part 51, reflecting the light on both sides of the first PCB, with a base 5 perpendicular to the facade glazing and on both sides of the base two returns 5a , 5b oriented towards the internal space 14, - a said main reflector 52 positioned in front of the first PCB, - to laterally partition the light, first and second lateral parts 53 and 54 (see Figure la), along the side edges of the elongated diffusing pattern, for maximum recycling of light rays. The wing 5a of the support piece facade glazing side is fixed to the rear face 11 by the double-sided adhesive 61 which is a strip all along the support piece with a width of at least 5mm which is called width contact with the mirror layer (protected). The wing 5b is fixed to the bottom reflector 1 'by the double-sided adhesive 62, identical, for example with a contact width of at least 5mm. It is the same for the profiles 52 to 54.

For simplicity, each adhesive strip 61 was precollected on the wings 5a on the facade glazing side before being fixed on the mirror layer. Then, after gluing, we realize necessary all four abutments. The abutment seals 63 are for example white or transparent silicone, or again this double-sided adhesive, however this is less easy to put in place.

In a simple manner, each profile 51 to 54 of the reflective surround is: metallic, preferably of aluminum, anodized, rough, polished or optionally coated with a diffuse reflection layer around the diodes 2, for the recycling of rays, - or plastic, for example PMMA or PC, coated with a specular or diffuse reflecting layer for ray recycling, in the form of a white paint or lacquer on the inside or outside face. In a simple manner, the reflective section 51 to 54 is straight metal, of U section, of thickness less than or equal to 3 mm even at 1 mm. Alternatively, the reflector profile 51 to 54 is PC or PMMA coated, straight, U-section, thickness less than or equal to 5mm. The main reflector, the support piece, the first and second lateral parts flanking the diffusing pattern, preferably rectangular frame, and are spaced apart for example from a constant distance from the scattering pattern. The first PCB 40 does not need to have encapsulation, a tropicalization varnish for watertightness if the case is waterproof. Alternatively, the profiles 51 to 54 are spaced less than 1mm are joined by butt joint and the PCB and the diodes are waterproof. The double-sided adhesive on almost all the surrounding provides a satisfactory first level of sealing and maintains a robust and durable attachment.On the other side edge of the facade glazing 100 can be duplicated means to make a second light pattern effective, homogeneous and durable: second diffusing pattern, second PCB with the diodes, second reflective surround 51a, 52a, second bottom reflector and second fixing means (and even second sealing means). The first PCB 40 comprises a power supply wire 91 coming out of the support piece 51 via an opening sealed by means of a cable clamp, wire leading to a connector 92 and to the connection wire of the second PCB for the second diffusing pattern. As shown in FIG. 1A, the second PCB (like the first PCB) is electrically powered via a feed wire 91 'leaving the support piece 51a of the second card via a sealed opening and connected to a resistant transformer 93 to the humid atmosphere. It is preferred to avoid making a surrounding diffusing element 3i of small extent (typically less than 110mm in length even less than 200mm in length) while preserving the homogeneity and efficiency. It is furthermore preferred not to interpose separating reflective walls between the support piece and the main reflector in the pattern area. In an example 1A, one chooses as tape or double-sided adhesive tape (for sealing according to IP44) a foam (hardened) acrylic with two main faces with an acrylic adhesive such as hyper joint H9012 (thick 1.2mm) or H9008 (thickness 0.8mm), sold by the company Nitto Denko, width reduced to 10mm. The seal for the abutments is a silicone with the choice white or transparent which joins it RUBSON HP. The dimensions of the parts and distances between parts are the following: - the surface of the glazing facade 1 is 600x900mm and it is a glass of 4mm thick, - the surface of the bottom glazing 1 'is 480x160mm and it is a 4mm thick glass, - U-shaped profiles 51 to 54 are 1mm thick, 480mm long, 51a wings width is 20mm, base 5 is 25mm wide - longitudinal edge side, distance between the edge of the glazing 1 'and the glazed portion of the facade 1 is 45mm, - lateral edge side, the distance between the edge of the glazing 1' and the glazed facade slice 1 is 65mm, - the width of the central zone of mirror is approximately 700mm, - the width of the mirror peripheral area between the inner edge and the edge is 70mm, - the height H of the internal space (between bottom reflector and glazing facade) is 25mm about. To meet the IP 44 sealing standard, the glazing 100 is placed according to the example 1A in an oven, glazing 100 without fastening element (s) 8 to a wall type wall, elements described below. The oven test for sealing follows the protocol FCBAAMB-FIN 004 defined by the NF furniture, according to different cycles indicated in Table 1. Oven cycle Temperature (° C) Moisture content (%) Duration (Week) 1 23 (+ 1- 2) 50 (+ 1-5 stabilization) 1 2 23 85 2 3 23 30 2 4 40 30 1 5 23 (+ 1- 2) 50 (+ 1-5 stabilization) 1 Table 1 The test is conclusive: the seal is confirmed and the fixation of the light box reliable. With the aforementioned alternative tapes, the test is also conclusive. Avoid double thick tape too thick, greater than 3mm and even 2mm. By replacing the double-sided adhesive with a glue, ultraviolet or even two-component, the seal is broken. On the other hand, the glue may overflow into the internal (and external) space at the expense of optical performance. Furthermore, concerning the fixing of the illuminating mirror 100, it is preferred that the mirror is not fixed to the wall via the outer face of the plate bottom reflector to avoid tearing of the adhesive 62 by sliding of the bottom reflector or by excess weight forward. As a variant, the main reflector is in L and the base of the main reflector 52 is under the shaped edge (for example a beveled slice of the facade glazing) and the pattern 3 extends to near or even until shaped edge. The main reflector 52 is then not carrying diodes even if the outer edge of the scattering pattern stops at the shaped edge, so there is no formation of low angle hot spots. The bottom reflector side wing is preferably not overflowing under the pattern of more than 5mm. In a variant, the base of the lateral reflector 53 or 54 is under the shaped edge (beveled edge of the facade glazing) and the pattern 3 extends to near or even to this shaped edge. The reflector 53 is then not carrying diodes even if the outer edge of the scattering pattern stops at the shaped edge, so there is no formation of low angle hot spots. The bottom reflector side wing is preferably not overflowing under the pattern of more than 5mm.

Alternatively, the flanges of the U-shaped sections may be oriented away from the internal space and, if appropriate, the diodes may be placed on the base opposite the wings because the rear face of the mirror reflects the more lateral received rays. It is preferable to avoid for the entourage the use of one or more profiles in particular of thickness less than 5 mm and / or width of contact with the facade glazing and with the bottom reflector less than 5 mm or so Fixed by L-shaped brackets (square) as detailed later. The illuminating mirror 100 is fixed to a wall (furniture, wall, ceiling, partition ...) using one or more profiles said fastening profiles 8, 81 to 84, here separated from one of the profiles 51 to 54 above the entourage.

For mechanical reasons, it is preferred that the bottom reflector in the form of a (mineral) glass plate does not participate in fixing at the risk of loosening the adhesive sealing strips 62 and because the (mineral) glass is enough heavy. Still in Example 1A, four fastening profiles 81 to 84 forming a peripheral frame, abutting, are used near the edge of the facade glazing less than 15 mm. In fact, the bottom reflector is shifted inward with respect to the edge of the facade glazing. The fastening frame 8 is therefore glued in the area of the protruding rear face of the bottom reflector 1 '. We choose more precisely four U-shaped profiles 81 to 84 with a bottom and two returns directed towards the inside of the glazing, each: - in aluminum, - wide of 30mm, height (of the base) between the returns of 15mm, long 890mm, thickness of the order of 1.5mm, returns spaced 5mm from the edge of the facade glazing, - the width of the double-sided adhesive tape 61 'on the fastening profiles, 20mm. - With an attachment opening 80 on a wing (rather than preferably a double-sided adhesive or glue).

To evaluate the fixing of the illuminating mirror, the illuminating mirror 100 is fixed on a wall by hooks engaging in the fixing openings, a weight of 1 kg is placed on the mirror 100 and the test of the oven described in FIG. Table 1. It is found that the attachment is intact: no mirror support section is collapsed or even slipped.

Alternatively, if the fixing profiles are replaced by one or more fixing plates placed on the plate bottom reflector on its outer face, it is found that the fixing is less reliable. The profiles 81 to 84 are masked by the mirror layer 2 and are devoid of return on the front face contrary to the prior art.

The front face 12 of the facade glazing is devoid of masking element or fixing, or even walking or hollow macroscopic at least 1 pm and also surface texturing for the diffusion of light. This makes it easy to clean the front panel. Rather than a U-shaped section, a typically rectangular or hollow rectangular closed section can be employed. Still for example 1A: - the PCB 40 carries 30 diodes, is 10mm wide, is flexible, with a thickness of about 1mm, - the PCB 40 and 41 diodes has an efficiency between 80 and 90 Im / VV, the distance ei between the diodes and the scattering pattern is of the order of 10 mm, the distance ef between the diodes and the bottom reflecting surface of the bottom reflector is of the order of 10 mm, the diodes , without optics, are of height of the order of 3mm, width less than 4mm, with a regular distance between diodes of 10mm +/- 2mm.

As shown in FIG. 1, which is a view from below of the illuminating mirror 100, the diffusing pattern 3 is elongated, composed of five spaced-apart diffusing elements 3i, in the form of rolls of identical or similar size, inscribed in a rectangular band R (solid line ). The width VV1 of the pattern 3, the band R is centimeter and less than 70mm. The diffusing pattern 3 is spaced from the slice 13 of the facade glazing.

The elongated pattern is defined by a first longitudinal edge 31, said internal, on the side of the central zone of the mirror, a second outer longitudinal edge 32, the most peripheral, along the lateral edge of the front glass 1, a first edge lateral 33 (top in the figure), a second opposite lateral edge 34. The dashed lines show the contours (the slice 13 ') of the bottom reflector 1' which is not shown to clarify the figure. The distance D1 between the inner edge 31 and each closest emitting face on the first PCB is at least 10 mm. The maximum distance Dmax between the inner edge 31 and the nearest emitting face and even the majority or each emitter face on the first PCB is preferably less than or equal to 40mm. The distance between the base 5a of the U-shaped support piece 51 and the inner longitudinal edge 31 is less than 20mm. Preferably, the ends of the wings of the support piece are at the edge of the diffusing pattern and are of predetermined width to place the diodes at the distance D1 of at least 12 mm. It is preferred that the ends of the wings do not exceed under the diffusing elements of at most 5 mm because the bottom reflector by its layer 7 forms a better reflector. The distance between the base of the main reflector 52 (devoid of PCB, diodes) and the inner longitudinal edge is less than 10mm. Preferably the ends of the wings of the main reflector 52 are at the edge of the diffusing pattern. It is preferred that the ends of the wings do not exceed under the diffusing elements of at most 5 mm because the bottom reflector by its layer 7 forms a better reflector. The distance between the base of a lateral piece 53 or 54 and the lateral edge is less than 10 mm. Preferably the ends of the wings of this part 53 or 54 are at the edge of the diffusing pattern. It is preferred that the ends of the wings do not exceed under the diffusing elements of at most 5 mm because the bottom reflector by its layer 7 forms a better reflector. The main reflector (as the side parts) could be oblique with respect to the facade glazing, as in the prior art, but this complicates the room, the way to guarantee the seal and is more bulky and imposes a peripheral mirror area even greater minimum. In example 1A: the width VV1 of the elongated pattern (therefore of the area R) is 40 mm, the length Li of the elongated pattern (therefore of the area R) is 420 mm, the distance D 1 is 15 mm. single row of diodes along the inner longitudinal edge 31 (or outer) is sufficient for uniformity of illumination to normal as VV1 is less than or equal to 70mm, we can however add another row of diodes along the edge external longitudinal, if we want to further increase the luminous efficiency. In this case, the main reflector carries this second row of diodes on its normal base to the facade glazing of at most 5 °. If it is desired to increase the efficiency by adding a row of diodes once the product has been designed, it is easy to break the seal between the sections by removing the bottom reflector for example by means of alcohol. It is the same for the replacement of the diodes (change of color, breakdown, change of power ...). A single row of diodes along the inner (or outer) longitudinal edge is not sufficient for homogeneity of illumination to normal if VV1 is greater than 70mm. We must add another row of diodes symmetrically on the base of the main reflector profile 52, so here the outermost or even for simplicity surrounding the entire pattern. In this case, the main reflector carries this second row of diodes on its normal base to the facade glazing of at most 5 °.

In an example 1B, the differences with example 1A are as follows: the width VV1 of the elongated pattern (hence of the area R) is 116 mm, the PCB 40, carries 90 diodes spaced apart with a regular distance 15mm, surrounding the whole pattern. As shown in FIG. 1a, the distance D2 between the external longitudinal edge and each emitting face of the second row of diodes 42 is then at least 10 mm. The maximum distance Dmax between the outer edge 32 and the nearest emitting face and even the majority or each emitter face on the first PCB is less than or equal to 40mm. Diodes (on PCB) can also be placed on the lateral edges, carried for example by the lateral parts 53, 54 of the reflective surround. These diodes on the side edge or edges have no significant influence on the homogeneity even if Li is greater than or equal to 200mm. The distance D3 between the lateral edge and each nearest emitting face is then at least 10 mm. The maximum distance Dmax between the lateral edge 33 and the nearest emitting face and even the majority or each emitting face on the first PCB is preferably less than or equal to 40 mm. The distance D4 between the opposite lateral edge and each nearest emitting face is then at least 10 mm. The maximum distance Dmax between the lateral edge 34 and the nearest emitting face and even the majority or each emitter face on the first PCB is preferably less than or equal to 40 mm. When the PCB 40 is flexible, completely surrounding the diffusing pattern 3 of a single PCB, with regularly distributed diodes, is simpler and faster than setting two groups of diodes on two PCBs along the inner and outer edges 31, 32 and connect them by one of the side edges 33, 34 for a common power supply. The arrangement of the diodes along the edges depends on the design of the diffusing pattern. Regardless of the diffusing pattern, care is taken to ensure that the distance between each edge of the diffusing pattern and each nearest emitting face is at least 10 mm and preferably less than or equal to 40 mm. The reflective surround and the diodes are positioned in the same manner, respecting D1 and, where appropriate, D2, D3, and D4, and the bottom reflector for a diffusing pattern forming a single rectangular band R, as shown in FIG. In the band R of the scattering pattern there may be locally one or more mirror areas preserved, as shown by the dashed lines. FIG. 1c shows a pattern composed of a series of scattering elements 3i, round or oval, for example, of various sizes, inscribed in a rectangular zone R (or square if necessary) passing through the edges of the elements of the most attractive pattern. decentered. We then define: - D1 as the distance between the inner edge 31 of the scattering pattern 3 (thus also the inner longitudinal edge of the area R) and the nearest emitting face (always opposite the inner edge), which distance is at least 10 mm and preferably at most 40 mm, D 2 as the distance between the outer edge 32 of the diffusing pattern (and therefore of the area R) and the emitting face closest to the row of diodes (always opposite the external edge), of at least 10 mm and preferably less than or equal to 40 mm, - D3 as the distance between the first lateral edge of the diffusing pattern (thus also of the area R) and the emitting face closest to the row of diodes (always facing the side edge), at least 10mm and preferably less than or equal to 40mm as for the other diodes, - D4 as the distance between the second side edge (thus also of the area R) and the face emitter closest to the row of diodes (always opposite the lat ral) of at least 10mm and preferably less than or equal to 40 mm as for the other diodes. The entourage, the PCB or PCBs, the diodes are at equal distances from the zone R. FIG. 1d shows a pattern diffusing in C pattern inscribed in a rectangular zone R with two "longitudinal" edges 31, 32, the first edge 31 including the end edges 31e and 31'e. D1 is then defined as the distance between the longitudinal inner edge 31 of the zone R and the emitting face closest to the row of diodes (always facing the inner edge); D2 as the distance between the outer longitudinal edge 32 of the zone R and the emitting face closest to the row of diodes (always opposite the outer edge), D3 as the distance between the first lateral edge 33 of the zone R and the emitting face closest to the row of diodes (always facing the edge 33), D4 as the distance between the second lateral edge 34 of the zone R and the emitting face closest to the row of diodes (always opposite edge 34). D1 to D4 is at least 10mm and preferably less than or equal to 40mm. Figure 1c shows a pattern diffusing disk 3 'pattern inscribed in a square or rectangular R area (if oval, ellipsoid). In this configuration it is preferred to place the diodes all around the disk either by forming a rectangular frame or following the round outline if the PCBs and the entourage are fit (sufficiently flexible) to form a round. D is the distance between the edge 31 'of the round and each face is at least 10 mm and preferably less than or equal to 40 mm. FIGS. 1f to 1j show the location of the diodes 41, 42 necessary for a good homogeneity for an L-shaped scattering pattern thus comprising a return or "small arm" of length Lt and of width VVt, projecting with respect to a rectangular strip R of width VV1 and longer than Lt. As shown in FIG. 1f, when Lt is greater than or equal to 20 mm, for homogeneity the first PCB 40 is placed along the inner edge 36 of the return and the inner edge 31 of the strip, thus reproducing an L (in a single curved PCB for example) with a distance, preferably constant, D1 between the emitting face 41 and the inner edge 31 or 36 of at least 10 mm and preferably less than or equal to 40mm.

VVt and VV1 are less than or equal to 70mm so it is not necessary to place the diodes also on the outer edge of the return 33 'and on the edges 32, 33 of the strip. As shown in FIG. 1g, when Lt is less than 20 mm, for homogeneity the first PCB 40 can be placed along the (small) end edge 35 of the return and the inner edge 31 of the strip, so the extension or a row of diodes 41 rectilinear (in a single PCB for example) with a variable distance to the larger scattering pattern between the emitting face and the inner edge 31 that the inner edge 36 of the return. The distance D1 at the small edge 35 is at least 10 mm and preferably less than or equal to 40 mm. VVt and VV1 are less than or equal to 70mm so it is not necessary to place the diodes also on the outer edge 33 of the return and on the edges 32, 33 of the strip. The L-shaped pattern may have other shapes, in F, comb, with a return placed otherwise in the extension of the band, possibly with one or other projections of width less than or equal to 20mm (shown in dotted lines) we will place the diodes in the same way, rectilinearly. As shown in FIG. 1h, when Lt is greater than or equal to 20 mm, for homogeneity the first PCB 41 is placed along the (large) inner edge 36 of the return and the inner edge 31 of the strip, and even of the edge 35 (in a single curved PCB for example) with a distance D1 between each emitting face and the inner edge 31, 35 or 36 of at least 10 mm and less than or equal to 40 mm. Since VV1 is greater than 70 mm, the diodes are also placed on the longitudinal outer edge 32 of the strip. We can also put all around the pattern for simplicity. As shown in FIG. 1i, when Lt is greater than or equal to 20 mm, for homogeneity the first PCB 40 is placed along the (large) inner edge 36 of the return and the inner edge 31 of the strip, thus reproducing a L (in a single curved PCB for example) with a distance between the emitting face of the diodes and these inner edges 31, 36 of at least 10 mm and preferably less than or equal to 40 mm.

Since VVt and VV1 are greater than 70 mm, the diodes 42 are also placed on the outer edge of the return 33 'and the outer edge 32 and the lateral edge 33 of the strip. It can also be put all around for simplicity so on the edges 35 and 34, end edges. Figure 1j shows a triangle pattern 3 for which diodes are placed on two sides of the triangle or all around for simplicity or if the maximum width of the total pattern is greater than 70mm. FIG. 1k shows a diffusing pattern forming a frame 3 "with a rectangular inner contour 31" (or with rounded corners) and a rectangular outer contour 32 "(or with rounded corners) .In this configuration it is preferred to place the diodes all around the inner contour forming a preferably rectangular frame with a distance D1 (constant) between the nearest emitting face and the internal contour of at least 10mm and preferably less than or equal to 40mm.

As shown in Figure 1 'which is a rear view of a mirror 10 "incorporating the frame pattern 3" the reflective surround 51b to 54b meanwhile is a rectangular frame all around the outer contour. In this frame pattern configuration the reflective surround can form with the bottom reflector (shown in dashed lines) and the facade glazing a sealed case that does not include the support piece 51 and two mirror support profiles 81, 82 are used on the lateral edges of the glazing. Again, if the width VV1 of the frame pattern is greater than 70mm, all around the outer contour 32 'of the similar diodes 42 are also placed on the surround with a distance D2 between the nearest emitting face and the inner contour of at least 10mm and preferably less than or equal to 40mm.

Figure 11 (with two zooms) shows how to position the diodes in the case of diffusing elements close enough but too wide in width to be surrounded by a single entourage. It is arranged to define as many scattering patterns as necessary, elongated and each of them respectively inscribed in a rectangular (or square) area R, R1, R2 of width VV1, VV2, VV3 less than 230mm, better than 200mm, each area R, R1, R2 being distant from the emitting faces - of the distance D1, D 1, D "1 of the longitudinal edge (preferably internal 31, 31 ', 31") of at least 10 mm and preferably less than or equal to 40 mm, - where appropriate of the distance D 2, D'2, D " 2 (if VV1 greater than 70mm) of the other longitudinal edge (preferably external 32, 32 ', 32 ") of at least 10mm and preferably less than or equal to 40mm, and (for simplicity) if necessary distances D 3, D 3, D 3 and / or D 4, D 4, D 4 of the lateral edges (preferably 33 to 34 ") of at least 10 mm and from 40mm or less, the surrounds are not represented for the sake of clarity. In FIG. 1m, it is shown that a surrounding wall such as a U-shaped section can serve both as a diode support piece for two adjacent patterns.

In Figure 1 n, it is shown that for two adjacent patterns can be used a same section of rectangular or square section. One proceeds in the same way as for the figures if to lh when one or the patterns are in L to place motif pattern the diodes. Of course, in FIGS. 1a to 11 (except the) when a profile of the surround does not comprise diodes (longitudinal edge, lateral edge), it is preferred to place it as close as possible to the edge of the diffusing pattern, for example at less than Lomm. FIG. 2 schematically represents a partial cross-sectional view of a light-emitting diode illuminating mirror 200 in a second embodiment of the invention.

Only differences from the first mode are described. The illuminating mirror 200 differs in particular from the mirror 100 first by the width VV1 of the pattern, greater than 70mm. A single row of diodes 41 along the inner edge 31 (or outer) is not sufficient for the homogeneity of the illumination to normal. One adds another row of diodes 42 identical or similar to the first row, on the base of the main reflector profile 52, thus along the outermost edge 32. It is recalled that the main reflector is preferably normal to the facade glazing for a better homogeneity. The main spokes F, F 'of the two groups 41, 42 are therefore at an angle of at most 5 ° with the facade glazing.

Again, the distance D2 between the outer edge and the emitter face closest to the diode on the second PCB is at least 10mm. The maximum distance Dmax between the outer edge and each emitting face on the second PCB is less than 40mm.

The first PCB may be connected to the second PCB 40 'between the side edge of the diffusing pattern and the side piece of the surround. In fact, for simplicity, the first and second PCBs can be replaced by a single PCB and diodes are placed all around the diffusing pattern 3, the PCB being carried by the reflective surround 51 to 54. The diodes at or below proximity of the corners are at a distance from the edge closest to the diffusing pattern of at least 10 mm: The base glazing is this time, in a variant, coated with a mirror-reflecting layer 7 ', preferably a mirror layer, such as a silverware protected by his painting. In fact we can choose a background glass with mirror area identical to the front glazing (except here by their size). As a variant of attachment with respect to FIG. 1, as shown in FIG. 2a, the fastening frame 8, 81 to 84 is in the central zone of the mirror 200. Also the outer edge of the diffusing pattern 31 may be closer to the edge 13 of the facade glazing, typically less than 25mm taking into account the distance D2 and the thickness of the profile of the entourage 52. The scattering pattern 3 is here composed of five diffusing elements 3 complex shape (round and rectangular) joined) or non-geometric variant inscribed in a rectangular area R as already explained which can be used to define D1, D2 and possibly D3 and D4 if necessary. FIG. 2 'schematically represents a rear-end view of a light-emitting diode illuminating mirror 200' in a variant of the second embodiment of the invention.

Only the differences from the second mode are described. The illuminating mirror 200 'differs in particular from the mirror 200 by the first pattern forming a large L (hence six sides) on a lateral and longitudinal edge of the facade glazing 1 and by another pattern in small L (hence six sides) on the outside. Another longitudinal side edge of the facade glazing 1. Two L-shaped surrounds are used: - first surround with six U-shaped sections 51 to 56 abutted by mastic 63 such as silicone, ie one profile per side or edge of the large diffusing pattern - Second surround with six U-shaped profiles 51a to 56a abutted by mastic 63 such as silicone so again a profile by side or edge of the small scattering pattern.

A single glazing 1 'is used, with the specular reflecting layer 7' (or diffuse 7), to form the two bottom reflectors of the small and large diffusing pattern, thus forming a frame, absent from the center of the mirror, for wall mounting. , (inner and outer contour 13 'of the potted glass 1). This glazing 1 'of mineral glass may alternatively be a plastic made of PMMA or polycarbonate. We can also use for each entourage a L-shaped glazing, so the shape of each scattering pattern. FIG. 3 schematically represents a partial view in longitudinal section of a light-emitting diode-illumination mirror 300 in a third embodiment of the invention. Only differences from the first mode are described. The illuminating mirror 300 differs in particular from the mirror 100 by the size of the bottom reflector 1 'which extends in the central zone and the zone of the second diffusing pattern (not shown).

In other words, only one bottom reflector is used for the two scattering patterns. In addition, the four U-shaped profiles forming the reflective surround of the first diffusing pattern are replaced by profiles 51 'to 54' as spacers, of rectangular or square closed section. For greater efficiency, the sidewall 5 'internal space side of the main reflector 52' is at the border with the outer edge 32 of the diffusing pattern or less than 10mm. As shown in FIG. 3a, each diffusing pattern 3 is formed of two diffusing elements 3i in strips inscribed in a rectangular zone R. In addition, the reflective case is a case common to each diffusing pattern, instead of using a dedicated case by diffusing pattern, and also surrounds the feed wire 91 and the transformer 93. To do this the side profiles 53 'and 54' are enlarged. The diode support parts 51 'and 51'a more central than the main reflectors 52 are not part of the waterproof housing. The support parts 51 'and 51'a are not necessarily joined to the common box. It is of course possible to use a U-shaped profile (or H or Z or even L) for the diode support piece 51 'or 51'a. Figure 4a schematically shows a rear view of a light-emitting diode illuminator mirror 400 in a fourth embodiment of the invention. Figure 4 is a partial side sectional view from a longitudinal edge 131 of the facade glazing 1.

The diffusing pattern 3 inscribed in a rectangular zone R is in the form of six bubbles (including a cut-off bubble) and whose lateral edge 34 extends to the shaped edge Z of the wide edge 34 of at most 2 mm. In order preferably the diffusing pattern 3 in all its extent, a non-return profile is placed against the rear face 11, which is a square 54 ", L, metallic (or reflective) against or possibly joined to the rear face by a joint said edge which is a silicone sealant 610 white or preferably transparent in the zone Z. The single return 54b, reflector bottom side 1 ', extending opposite the diffusing pattern 3 and still fixed by the double adhesive face 62. The square is 0.8mm thick, even 1mm thick The square 54 "is devoid of diodes (source of hot spots). Alternatively, is used for the entourage a plastic box (with reflective layer on the back), in U, with a thickness of at most 0.8 mm or even 1 mm, possibly with attachment profiles for the support piece profiles 51 and main reflector 52 for a contact width of at least 5 mm on the rear face 11 with the adhesive 61 preferably double-sided. The same system of square and edge joint can be made under a shaped edge of the other side edge (in addition); again square devoid of diodes and even realize the same system of square and edge seal on a longitudinal edge and the main reflector is not carrying diodes. Fixing by the adhesive (double-sided) 61 on three sides of the back side or even on two sides is sufficient. Alternatively one can realize a plastic box with reflective layer (outer face) with returns of fasteners or hanging profiles except in the shaped edge or as described. Figure 5a schematically shows a rear and partial view of a light emitting diode illuminator mirror 500 in a fifth embodiment of the invention. FIG. 5 is a partial longitudinal sectional view of this mirror 500. In this configuration, the case further comprises three U-shaped sections for example glued by the double-sided adhesive 61 to the rear face of the facade glazing 1 and under the mirror layer 2 and the double-sided adhesive 62 to the bottom reflector 1 '.

A fourth section 8, straight, in U with a base 8a and two returns 8b opposite the internal space 14 (or in a rectangular or square closed section, spacer type), made of metal (alternatively plastic or in glass and with a reflective layer). This fourth section has a contact width of the adhesive 61 'of at least 10 mm for good attachment of the mirror and a material thickness of at least 1.5 mm and possibly a height H' greater than H. This profile 8 serves not only for attachment to a wall (furniture, wall ...) via one or two mounting openings 80 but also for the entourage, as support part of the diodes on the face 8'a.

This fastening profile thus carries via this right wall 8'a the first PCB 40 with the diodes 41 along the longitudinal inner edge 31 of the scattering pattern 3, for example three bubbles with a width of at most 60mm and at a distance D1 of at least 12 mm from the inner edge 31. The surface of this fastening section opposite the edge 13 'of the reflector 1' is sealed by adding a "lateral" sealing element such as a silicone sealant 64 'or a double-sided adhesive 64. The profile is abutted with the profiles 53 'and 54' by sealant 63 silicone. Alternatively rather than cumulatively, the longitudinal outer section (main reflector) can be replaced by a mirror support section in the same configuration. This is also possible if it is a common box including surrounding also a second scattering pattern. Figure 5'a schematically shows a rear and partial view of a light emitting diode mirror 500 'in a variant of the fifth embodiment of the invention.

This mirror 500 'differs from the mirror 500 in that the fastening profile 8 replaces not a support part of the first PCB but a profile, forming part, as preferably longitudinal wall at the inner edge (or external variant) of the housing common of the first PCB 40 and the power supply. Here the diode support section 51 'for example a spacer of square or rectangular section is not necessarily abutted or fixed by adhesive or joined to the other lateral sections 53', 54 '. Figure 5 "schematically shows a rear view of a 500-light-emitting diode illuminating mirror in a new embodiment of the invention.

It differs from the mirror 500 in that each scattering pattern 3 (strip with central return, forming a "T" therefore with eight sides or edges) is surrounded by a PCB on seven profiles (type spacers of rectangular or square lateral section, butt jointed 63 or spaced less than 5mm) and on one of the profiles 81 or 82 mirror support forming part of the fastening profile 8 (four-piece frame 81 to 84 in the central mirror area). Each of the profiles is part of the surrounding of a diffusing pattern and carries the diodes for its pattern diffusing on a portion 810, 820 of the profile.

Figure 6a schematically shows a rear and partial view of a light emitting diode illuminator mirror 600 in a sixth embodiment of the invention. Figure 6 is a partial view and longitudinal section of the mirror. In this configuration, the reflector surround further comprises three U-shaped profiles attached to the rear face of the facade glazing 1 under the mirror layer 2, for example glued by the double-sided adhesive 61 and to the bottom reflector 1 'for example by the double-sided adhesive 62. A fourth section 8 right, is U with a base 8a and two returns 8b opposite the inner space 14 (or as a rectangular or square section closed profile) is between the bottom reflector 1 'and the facade glazing 1 but of different dimensions. This profile 8 is preferably metal or plastic or reflective layer glass. It has a material thickness of at least 1.5 mm, a width of contact with the mirror layer by the double-sided adhesive 61 'of at least 10 mm and a contact width with the bottom reflector of at least 10mm.

This section 8 carries, via a straight wall 8'a of the base, the first PCB with the diodes 41 along the longitudinal inner edge 31 of the diffusing pattern 3, for example three rollers 3i with a width of at most 65 mm and at a distance of distance D1 of at least 10mm from the inner edge 31 of the diffusing pattern. This profile 8 serves not only for the entourage but also for fixing to a wall (furniture, wall ...). Also this fastening profile 8 comprises two protruding ends 8c, 8d (here longitudinal) of the bottom reflector 1, on two opposite edges ends still under the mirror layer 2 at the periphery of the facade glazing 1 and with means for fixing such that an opening 80 or a double-sided adhesive. Alternatively or cumulatively, the longitudinal outer section (main reflector) can be replaced by a mirror support section in the same configuration. Figure 6'a schematically shows a rear and partial view of a light emitting diode mirror 600 'in a variant of the sixth embodiment of the invention. This mirror 600 'differs from the mirror 600 in that the fastening profile 8 replaces not a support part of the first PCB but a profile, forming part, preferably as a wall along the inner edge (or the outer edge alternatively ), a common sealing box of the first PCB 40 and the power supply 93. Here the diode support profile 51 'for example of rectangular section, is not necessarily abutted or attached by adhesive or seal to the other lateral sections 52 ', 53', 54 ', for example of rectangular section.

FIG. 7 schematically represents a partial view in longitudinal section of a light-emitting diode illuminating mirror 700 in a seventh embodiment of the invention. Only differences from the first mode are described. The illuminating mirror 700 differs in particular from the mirror 100 by the main reflector 52 'which is a profile (spacer and between the mirror layer 2 and the bottom reflector 1 ") of rectangular section along the outer longitudinal edge 32. FIG. schematically a partial longitudinal sectional view of a light-emitting diode-illumination mirror 800 in an eighth embodiment of the invention, only the differences with respect to the first mode are described, the illuminating mirror 800 differs from the mirror 100 by the choice of the surrounding assembly and bottom reflector A plastic box 50 (in PMMA, in PC) is used, of which: the bottom, plane (or concave towards the internal space) coated with a reflecting layer 7 (preferably diffuse reflection); ) on the outer face opposite to the inner space forms the bottom reflector 1 "and - four side walls or flanks 501, 502, 503, 504, normal to the facade glazing, coated with a half he reflective 7 (preferably diffuse reflection) opposite external face to the internal space are part of the reflective surround. More precisely, the casing does not have a simple U-shaped section but also has a return 50a towards the internal space and provided with the double-sided adhesive 61 all around its periphery. The return oriented in the internal space is perpendicular to the side walls 501 to 504, and surrounds the diffusing pattern 3 without overflowing on the scattering pattern 3. The thickness of the box is less than 5mm, for example 0.8mm. The return may also be coated with a reflective layer (preferably diffuse reflection) on the outer face opposite the internal space and in contact with the double-sided adhesive 61. This box may be made for molding, extrusion, the reflective layer 7 being deposited before or after forming.

In a variant of fixing, the frame return (or a part of the frame return) is external to the internal space but the compactness is lost and the diffusing pattern is removed from the edge of the facade glazing. FIG. 9 schematically represents a partial sectional view. longitudinal view of a light-emitting diode illuminating mirror 900 in a ninth embodiment of the invention. Only differences from the eighth mode are described. The illuminating mirror 900 differs from the mirror 800 firstly by the shape of the box and by its fixing. A box of simple U-shape is used with a thickness of about 1 mm, it is made of plastic, such as polycarbonate or PMMA with a reflective layer 7 opposite the internal space 14. The bottom is flat (or alternatively concave to the internal space). The thickness of the box is less than 5mm, for example 3mm. For its attachment, two fastening profiles 511, 512 are used, which are L-shaped brackets each with: - a part against a side wall 501, 502 of the surround and along a longitudinal edge 31, 32 of the pattern diffusing 3 and internal space side 14, - a portion at 90 ° against the mirror layer 2 always in the internal space and without exceeding the edge 31, 32. Alternatively, four brackets of fasteners are used on the four sides.

The fixing is done by screws 6th. Two diode strips 41, 42 bonded by double-sided adhesive 6 are placed on the attachment profiles 511, 512 along the edges 31, 32. The box 50 is for example fixed to a wall, a furniture wall, via fastening plates 8 'with fastening loops, metal plates glued for example via the same double-sided adhesive 6' on the layer 7 'or by drilling with screws. FIG. 9 'schematically represents a partial view of a longitudinal section of a light-emitting diode illuminating mirror 900' in a variant of the ninth embodiment of the invention.

Only the differences from the ninth mode are described. The illuminating mirror 900 'differs from the mirror 900 first by its external attachment to the internal space by the brackets 511, 512 external to the box. Alternatively four brackets are used (one bracket per wall of the box).

FIG. 9 "schematically represents a longitudinal sectional view of a light-emitting diode-reflecting mirror 900" in another variant of the ninth embodiment of the invention. Only the differences from the ninth mode are described. The illuminating mirror 900 "differs from the mirror 900 by its extent over almost the entire surface of the facade glazing 1 possibly surrounding the power supply or even other diffusing patterns (not shown) Optical measurements are made on illuminating mirrors with four architectures of reflectors for evaluating the efficiency and homogeneity of the luminance with the normal Examples Ex1 and Ex2 are examples according to the invention Examples Ex1com and Ex2comp are comparative examples made by the Applicant. four examples, the illuminating mirror comprises a facade glazing with a mirror layer, a scattering pattern, a reflective surround and diodes on a PCB as already described for example 1. More specifically, in the four examples, the diodes are the product called 5MD3528 from the company ILLUSION LED Limited color temperature 3200K.The PCB with the diodes has an effective For the diodes, colorimetric variations of +/- 0.005 are preferably chosen for X and Y of the CIE 1931 colorimetric diagram. The RL is, like the TL, defined in the EN410 standard. The measurements were carried out under illuminant D65 with a Konica Minolta CM-3700d spectrophotometer. In the four examples, the façade glazing is a 4mm Planilux glazing of the plaintiff company covered on its back side with a layer of silver of at least 50 nm with a protective paint. The silvering and its protection were sandblasted to form the diffusing pattern giving a blur of 95% and a TL of about 70%. This is the product Miralite REVOLUTION, sandblasted, the company Applicant. In Example Ex1, the glazing of the bottom reflector is provided with a diffuse reflective layer which is on its outer main face and therefore opposite to the internal space. Specifically, it is the white Planilaque product of the Applicant company composed of a 4mm Planilux glazing and a white lacquer. In Example Ex2, the bottom reflector glazing is provided with a specular reflecting layer which is on the outer face and therefore opposite to the internal space. More specifically, it is the product Miralite REVOLUTION, the Applicant company consisting of a 4mm Planilux glazing covered on its outer surface with a silver layer of at least 50 nm, with a protective paint. In the comparative example Excomp1, the glazing of the bottom reflector is provided with a diffuse reflective layer which is on the inner face and thus on the internal space side. More precisely, it is the product Planilaque white composed of a Planilux glazing of 4mm and a white lacquer. In the other comparative example Excomp2, the bottom reflector is an aluminum plate covered with a diffusing white paint. Table 2 below shows the optical measurements of case comparison using the four aforementioned bottom reflectors. luminance indicates the difference in luminance with normal, reflecting the degree of homogeneity of illumination from one longitudinal edge to the other. Ex1 Ex2 Ex1comp Ex2comp RL (%) 55 92 80-85 85-97 TL (c) / 0) 2.3 0 2 - Flux (lm) 40 46 45 42 Efficiency (Im / VV) 12 14 13 12 T ° Color 3480-3500 3600-3650 3480-3490 3460-3500 (° K) Luminance min (cd / m2) 500 450 450-500 500 Luminance max (cd / m2) 800 700 800-1000 1000-1100 Aluminance (cd / m2) - 300 250 500 500 Table 2 The protocol for measuring flow and efficiency is as follows, for each example. The mirror is first fixed in the center of an integrating sphere to measure the luminous flux and the color temperature of the light extracted from the scattering pattern. From the measured luminous flux, it is then possible to calculate the luminous efficiency of the mirror. Then the mirror is positioned under a Lumicam camera to measure the luminance at normal at each point of the pattern and determine the homogeneity of the illumination. The reflectors on the outer face of the glazing (Examples 1 and 2) allow illumination of the most homogeneous diffusing zone. One possible explanation is that part of the light reflected by the lacquer or mirror is guided into the glass, which improves the homogeneity of the lighting. The RL value of Example 1 measured is not significant because it does not take into account light propagating in the wafer.

The reflector with the diffusing layer on the external face (example 1) also makes it possible to keep a color temperature close to that of the diodes (approximately 3200K), unlike the mirror reflector on the rear face. The light transmission TL measured on the outside of the internal space is low enough not to lose light.

The internal space-side surface of the glass plate may be smooth as here or alternatively textured or with a diffusing layer.

Claims (13)

REVENDICATIONS1. Illuminating mirror (100 to 700, 800, 900, 900 ', 900 ") which comprises: - a facade glazing (1) made of mineral glass, with a first main face forming the front face (12), and a second main face forming the rear face (11) and a wafer, - on the rear face, a metal layer (2) based on silver, called the mirror layer, giving the mirror function on the front face, in particular present in a central zone of the glazing unit facade, - a diffusing pattern (3, 3 ', 3 "), on the rear side and adjacent to the mirror layer, lateral dimension pattern of at least 10 mm and less than or equal to 230 mm, diffusing pattern (3) in a continuous diffusing element (3) or a plurality of spaced diffusing elements (3i), an elongated lateral dimension pattern which is the width VV1 or disk or square pattern (3 ') of lateral dimension which is the radius or side r1 or pattern ( 3 ") in a frame, in one or more spaced bands, lateral size band (s) which is the width W1 , the façade glazing (1) with the diffusing pattern (3, 3 ', 3 ") having a blur of at least 90%, a TL light transmission exceeding 50% on the front side, - on the back side a first group of light-emitting diodes (41), in a row, on a first printed circuit board called PCB 40, carried by a said support member section (51, 51 ', 501), the diodes each having: - a light beam principal F at an angle of not more than 5 ° to the facade glazing; - a diverging beam defined by a half-angle at mid-height of not less than 40 °, the adjacent diode bundles of the first group overlapping on the diffusing pattern, - a so-called main reflector (52, 52 ', 502), on the rear side, comprising a reflecting wall and / or a so-called main reflecting layer (7, 7'), main reflector facing the first group of diodes and spaced from the first group of diodes by a so-called internal space (14), - a so-called reflector of fo nd (1 ', 1 ", 501), rear side, adapted to receive from the first group of diodes light rays away from the rear face and back on the diffusing pattern or on the main reflector, reflector background spaced from the diffusing pattern by a distance H of at most 40mm and at least 10mm, - the first PCB (40) being arranged along a first longitudinal edge (31) of the elongate pattern (3) or surrounding the disk or square pattern (3 ') or surrounding a contour (31') of the frame pattern (3 "), said injection contour (31"), characterized in that the bottom reflector comprises a transparent wall (1 ', 1 ") with an inner main face (11') facing the inner space (14) and an outer main face (12 ') opposite to the inner space, outer main surface coated with a so-called bottom (7, 7 '); the transparent wall assembly and bottom reflective layer (7,7 ') having a light transmission TL of at most 10% on the outer side which is opposite to the internal space, in that a reflective surround comprising the support piece ( 51, 51 ', 501), and the main reflector (52, 52', 502) surrounds the elongated pattern (3) or disk or square pattern (3 ') or a reflective surround comprising the support piece surrounds the outline of the injection of the frame pattern (3 ") and another reflective surround comprising the main reflector surrounds the other contour of the frame pattern, the reflective surround being a monolithic frame or a plurality of abutting or spaced pieces of less than 5mm, reflector surround being attached to the rear face, and the other reflective surround possibly being a monolithic frame or a plurality of pieces abutting or spaced less than 5mm, the other reflective surround being attached to the rear face, in that the first diod group es is arranged with: a distance ei between the facade glazing and each emitting face of the first group of diodes (41) greater than or equal to 5 mm, a distance ef between the inner main face (11 ') of the bottom reflector and each emitting face of the first group of diodes (41) such that the difference in absolute value ei - ef is less than or equal to 20mm, and with: - for the elongated pattern (3), a distance D1 between the first longitudinal edge (31 ) and each emitting face of the first group of diodes (41) of at least 10 mm, - for the disk or square pattern (3 '), a distance D between the edge of the scattering pattern (3') and each emitting face of the first group of diodes (41) of at least 10 mm, - for the frame pattern, a distance D1 between the injection contour of the pattern (31 ") and each emitter face of the first group (41) of at least 10 mm, and in that: - when VV1 or VV'1 is greater than 70 mm, the main reflector has an inner wall forming a an angle of at most 5 ° with the facade glazing (1) and carries a printed circuit board, said second PCB (40 '), in front of the support part (51,510), second PCB with a second group of light-emitting diodes (42), in a row, the diodes each having: - a main light ray F 'forming an angle of not more than 5 ° with the façade glazing, - a diverging beam defined by a half-angle at half height of at least 40 °, the adjacent diode bundles of the second group overlapping on the scattering pattern (3 to 3 ") the second group of diodes is arranged with: - a distance ei between the facade glazing and each emitting face of the second group of diodes (42) greater than or equal to 5 mm, a so-called vertical distance ef between the internal main face (11 ') of the bottom reflector and each emitting face of the second group of diodes (42) such the difference in absolute value ei - ff is less than or equal to 20mm '- and p for the elongate pattern, the diodes of the second group (42) being along the second longitudinal edge with a distance D2 between the second longitudinal edge opposite the first longitudinal edge and each emitting face of the second group of diodes (42) of at least 10mm '- for the frame pattern the diodes being along the other distinct contour of the injection contour (32 "), said other injection contour with a distance D'2 between the other injection contour and each emitting face of the second group of diodes (42) of at least 10mm. 2. illuminating mirror (100, 300 to 700, 800, 900, 900 ', 900 ") according to claim 1 characterized in that the reflective layer (7) is a diffuse reflective layer. 3. illuminating mirror (200) according to claim 1 characterized in that the reflective layer (7 ') is a specular reflective layer preferably based on silver. 4. Illuminating mirror (100 to 700, 800, 900, 900 ', 900 ") according to one of the preceding claims, characterized in that the diffusing pattern (3) is elongated, the entourage carries diodes of the first group (41). ) optionally the second group (42) and / or other diodes (43 44), the distance between the emitting face of each of the diodes and the edge of the nearest elongated pattern is at least 10mm. Illuminating mirror (100, 300, 400, 600 to 700, 900 ") according to one of the preceding claims, characterized in that when VV1 is less than or equal to 70 mm, the first longitudinal edge (31) of the elongate pattern is the innermost, and the main reflector (52, 512) along the second longitudinal edge (32) is devoid of a second PCB with diodes or that when VV1 is less than or equal to 70 mm, the injection contour the 3 "frame pattern is the innermost of the contours, and the other outline is devoid of diodes. 6. illuminating mirror (100 to 700, 800, 900, 900 ', 900 ") according to one of the preceding claims characterized in that the scattering pattern (3) is inscribed in a zone (R) of rectangular shape and / or in that the elongated diffusing pattern (3) is of particular shape in the form of an L or a comb, the reflective surround along the edges (31, 32) of the elongate pattern. 7. illuminating mirror according to one of the preceding claims characterized in that the elongate pattern (3) is inscribed in a rectangular band extended by at least one other rectangular band, such as an L or F or E or a comb, with a projection distance of each other strip is less than or equal to 20 mm, the first PCB (40) opposite the first longitudinal edge of the pattern with the other strip is linear or in that the elongate pattern (3) is inscribed in a rectangular band extended by at least one other rectangular band, such as an L or an F or an E or a comb, with a protruding distance from each other band greater than 20mm, the first PCB facing the first longitudinal edge of the pattern with the return follows the outline of the pattern, skirting the other band. 8. illuminating mirror (400) according to one of claims 1 to 7 characterized in that an edge of the diffusing pattern (3) goes to a shaped edge Z of the slice (13) of the facade glazing or at least 2mm of the shaped edge, for the elongate pattern or disc or square reflective surround, or for the frame pattern (3 ") the other reflective surround, comprises a piece (54"), said end, having a base (54 ") having a wafer, of thickness (ep) less than or equal to the width of the shaped edge, which is against or fixed or connected to the shaped edge, a piece having a return (54b) towards the internal space against or preferably attached to the bottom reflector 1 ', in particular L-section piece, end piece devoid of diodes. 9. illuminating mirror (100 to 700, 800, 900, 900 ', 900 ") according to one of the preceding claims characterized in that the transparent wall (1') is a glazing thickness less than 6mm or the transparent wall is plastic (1 ') preferably selected from polycarbonate, polymethylmethacrylate. 10. Illuminating mirror (100 to 700) according to one of the preceding claims characterized in that the wall (1 ') transparent, flat or concave towards the internal space, is a plate, the reflective surround forms a spacer between the plate bottom reflector (1 ') and the front glazing (1) and / or the reflective surround extends to leave a maximum clearance of less than 5mm with the front glazing or the bottom reflector. 11. illuminating mirror (100 to 700) according to one of the preceding claims characterized in that the support member and / or the main reflector, preferably the surrounding is selected from: - a hollow or solid spacer including rectangular side section or square, between the facade glazing and the bottom reflector, - a part, in particular U, which comprises a bearing base of the first PCB and on either side of the first and second wings or returns, the first return being between the base and the facade glazing, and the second return being between the base and the flat plate bottom reflector, an L-shaped part which comprises a base carrying the first PCB and on each side a single wing or return, the return being between the base and the bottom reflector, - a part which comprises a bearing base of the first PCB to the bottom plate reflector fixed by profile (s) to attach to the bottom reflector. plate flat and / or glazing facade. 12. illuminating mirror (800, 900, 900 ', 900 ") according to one of claims 1 to 9 characterized in that the plastic bottom reflector is a plate (1") extended on both sides by the main reflector (512) and the support piece (511), forming a monolithic piece called caisson (50). Illuminating mirror (100 to 700, 800, 900, 900 ', 900 ") according to one of the preceding claims, characterized in that the diffusing pattern (3) is a texturing of the rear face (11) and preferably a sanded back side.