FR2903563A1 - ELECTRIC HEATING MIRROR - Google Patents

Abstract

Electric heating mirror (100) comprising: - a glass substrate (1) having first (12) and second main faces (11), - a mirror reflecting layer (2) on the first main face, - a heating element electrical connector (3) facing one of the first or second major faces, the reflective layer being chromium-based and the glass substrate being thermally toughened.

Description

The present invention relates to a mirror

  electric heater and more particularly an electric heating mirror having a glass substrate, a mirror reflecting layer and an electric heating element. Electric heated bathroom mirrors perform two different functions. In addition to their primary function of reflecting light rays like any mirror, they also emit a little heat to remove the fog that forms on the front of the mirror. In a known structure, the electric heating mirror comprises a glass sheet having on its back side a silver layer mirror coated with a protective layer and a tacky resistive heating film. These electric heated mirrors are fragile. Also, it is the object of the present invention to provide a robust electric heating mirror preferably of simple design and / or manufacture. The invention further proposes to expand the range of electric heating mirrors available and / or to make possible new applications. To this end, the invention proposes an electric heating mirror comprising: a glass substrate comprising first and second main faces, a mirror reflecting layer on the first main face, an electric heating element facing the one of the first or second major faces, the glass being thermally toughened and the reflective layer being a chromium-based layer. Due to the thermal quenching, the electric heating mirror according to the invention is more resistant and safe, and less dangerous in case of breakage, especially during transport or installation. Thermal quenching is naturally the last stage of manufacture of the mirror made at high temperature, that is to say at a temperature above 250 C. Of course, this does not exclude local and / or rapid welding operations. for the connection or assembly. Thermal tempering is moreover less expensive and less time consuming than chemical quenching and more effective than simple hardening. The electric heating mirror according to the invention can be used under conditions of high mechanical stress, for example as a partition, facade, wall panel, slab, ceiling lamp. The electric heating mirror can be used indoors or outdoors. The chromium layer is capable of undergoing thermal quenching which allows a manufacturing flexibility. The chromium layer is not altered by a wet atmosphere, unlike the silver layer which requires the addition of an anti-corrosion layer. Thus, the electric heating mirror can be for domestic use, especially in a bathroom, toilets, or industrial, including a swimming pool, sauna, steam room. This chromium layer also has scratch resistance comparable to pyrolized layers, and is resistant to cleaning, to industrial disinfection products. The heating mirror according to the invention can form a partition, a wall panel, a furniture facade, including bathroom cabinet. The heating mirror according to the invention can have an anti-condensation function or, at higher power, can really be used as heating, main or auxiliary, in particular be a wall-mounted or freestanding radiator, a towel radiator with or without towel holder added. The thermal quenching may be carried out on the glass substrate coated with the chromium layer and optionally provided with enamel, in particular opaque masking and / or decorative enamel. The thermal quenching can also be performed on the glass substrate coated with the chromium layer, possibly with a preferably opaque enamel, and already provided with the electric heating element (on the first or second face). In a first embodiment of the invention, said electric heating element is attached, associated with a substrate separate from the substrate with the layer, which element is spaced apart and / or assembled with the substrate. This electric heating element may preferably comprise one of the following means: a heating network in the form of conducting tracks, in particular conducting enamel or aluminum-based, an electroconductive heating layer covering substantially the first or the second face, in particular based on metal oxide or organic conductive paint, - a tubular electrical resistance in particular in a metal enclosure. The aluminum heating network may be on a plastic support such as a polyethylene terephthalate (PET) sheet and an acrylic adhesive film for assembly. The conductive enamel heating network may be in the form of a suspension of metal particles such as silver and glass frit in an organic binder. This enamel can be deposited on a glass support by spraying, by coating with a roller or curtain, or by screen printing and by subjecting the glass thus coated to a firing at a temperature of about 500 to 650 C. This support glass can also be tempered thermally afterwards. To mask the heating network, an opaque enamel may be disposed between the chromium layer and the heating network, on the first face or the second face. The heating conductive layer based on metal oxide may be deposited on a glass support optionally thermally tempered thereafter. The organic conductive paint may be based on a binder of the acrylic, epoxy or urethane type loaded with conductive fillers of the graphite, nickel, copper and / or preferably silver type. The tubular electrical resistance in an enclosure can form a heater body of a radiator. The insert may be assembled to the substrate by any means of assembly. It is possible to choose a mechanical means arranged on the edge of the electric heating mirror such as a surround for example of metal and of straight or U-shaped lateral section, or by a carcass (made of sheet metal ...). It is also possible to choose a chemical assembly means, in particular by one of the faces of the substrate, means covering this assembly face or the edges of this face. The chemical assembly means may be in particular: an adhesive, in particular a casting resin of urethane acrylate type, which is simple to use, a double-sided adhesive, a lamination interlayer of thermoplastic material, in particular polyurethane (PU) , polyvinyl butyral (PVB), ethylene vinyl acetate (EVA). In a second embodiment, the electric heating element may be a heating electroconductive layer deposited on the substrate and above the chromium layer, preferably directly on an intermediate enamel or on the second main face. This layer may be in the form of heating conductive tracks, preferably conducting enamel or this layer may be based on metal oxide or conductive organic paint preferably substantially covering the chromium layer or the second main face. This last layer is a continuous covering layer or several covering strips isolated by thin areas without layers. This layer may be absent on the perimeter for insulation purposes. The electroconductive heating layer mirror according to the invention is compact, easy to install, simple design and implementation. The electroconductive heating layer may be deposited on an enamel - indeed creating a certain roughness - keeping its functionality even when this layer is of a thickness substantially smaller than the thickness of the enamel. For the heating layer the electrical continuity is preserved. Preferably, when the enamel partially covers said face, its thickness may be less than or equal to 50 m, preferably less than or equal to 20 m. The methods for depositing the electroconductive heating layer 30 may be any means known to those skilled in the art, in particular deposits, by coating a paint, by powder, by liquid route, by dip-coating, by spin-coating, flow-coating, PVD or CVD etc. The conductive heating layer may be more preferably transparent to fluorine-doped tin oxide or tin-doped indium oxide, these layers being heatable. Such layers generally obtained by pyrolysis method (powder, liquid or CVD) are chosen for their adhesion, stability, hardness, mechanical strength and / or air. Advantageously, said metal oxide conductive layer may have a thickness (average) less than or equal to 1 m, preferably less than or equal to 500 nm. A layer containing a metal oxide such as fluorine doped tin oxide has a specific resistance or square resistance R1 typically of 5 to 500 ohms. One can also choose other transparent layers of the family of TCO (transparent conductive oxide in English). In particular, several means are known which make it possible to pyrolyze organic salts on a hot glass which are converted into conductive oxides. Among these, that of patent EP 0 125 153 makes it possible to deposit a thin film based on fluorine-doped tin oxide on flat glass continuously between the exit of a "float" bath and the entry into a "float" bath. the lehring lehr. This method makes it possible to have glass plates with a transparent and conductive layer of infinite dimensions for a reduced cost price. This glass plate is then assembled cold as already seen. The deposition of the electroconductive heating layer can also be carried out on the substrate with the mirror layer or on the second glass, this for more flexibility (choice of glass type, choice of thickness, or possible layer thickness) ...). This electroconductive heating layer is connected to electrical connection elements to the power supply cables, these elements being called connecting pieces or lugs of the current supply or distribution strips or bus bars, which are generally arranged on two opposite sides 30. of the layer. These elements are hereinafter referred to simply by distributors. These distributors are for example in the form of metal strips (for example in the form of tinned copper foils) fixed for example by welding or gluing on the substrate or in the form of 2903563 6 silver screen printed metal strips, copper, organic paint conductive. The mirror-forming chromium layer can be (essentially) visible via the first face and the second face, in particular with a transparent electroconductive heating layer. The electric heating mirror according to the invention can benefit from the oriented emissivity of the fluorinated doped tin oxide (flow directed towards the workpiece) for example in the case of a radiator facade. The chromium layer can be obtained by magnetron sputtering. The chromium layer may be a multilayer, for example the layer used in the Mirastar product sold by SAINT GOBAIN GLASS. The chromium layer is not necessarily completely opaque. The chromium layer of Mirastar type typically has a light reflection of the order of 60% and a light transmission of about 3%. The mirror can thus be used to preserve privacy or even as a spy mirror in certain lighting conditions. Indeed, a person is not visible on the side of the mirror less illuminated or dark, for example a first room, but can however observe the opposite side, for example a second room. For example, this mirror may be a door, a part of a door, a part of a window, a partition. An opaque uniform bottom may be provided if this transmission is not desired, for example, an opaque enamel - black, white, optionally colored - disposed between the chromium layer and the electric heating element. The chromium layer may completely cover the first face, be in a zone or in a plurality of zones separated from each other for example by sandblasting. The mirror may for example be in the form of parallel strips, constant spacings or possibly variable, then possibly used to preserve privacy. The glass substrate may be of any shape, including rectangular, square and of any size. The mirror may comprise an electrical insulator above the electric heating element, in particular a plastic film or a glass, optionally carrying the electric heating element or glued to the electric heating element. Further details and advantageous features of the invention appear on reading the examples of heating mirrors illustrated by the following figures: FIGS. 1 to 4 show schematically sectional or face views of electric heating mirrors in different modes embodiment of the invention. For the sake of clarity, the elements are not represented at scale. Example 1 Figure 1 shows schematically a sectional view of an electric heating mirror in a first embodiment of the invention. This first electric heating mirror 100 is for example intended to garnish a wall, a wall. This first electric heating mirror 100 is particularly suitable in a humid environment, such as for example a bathroom or a swimming pool, in which a slight heating is provided to remove the fog that forms on the front face 11 of the mirror (front side). oriented towards the room). This first electric heating mirror 100 is monolithic. It comprises a glass sheet 1, for example rectangular, for example of silicosodocalcic glass and 4 or 6 mm thick. The front face 11 of the sheet 1 comprises a chromium-based layer 2, such as the (multi) layer of the Saint Gobain Glass Mirastar product, covering all or almost all of this front face 11. The back face 12 of the sheet 1 comprises, in this order: a heating electroconductive layer 3 made of fluorine-doped tin oxide deposited by steam pyrolysis (known as CVD) on the rear face 12, covering all or almost all of this face rear 12, two strips 4 in silver paste and serigraphed forming distributors, deposited on the heating layer 3 along the side edges of the glass sheet 1. For its manufacture, after passing through a baking oven, the mirror Electric heater has been thermally quenched. After quenching, the distributors are conventionally connected to electric cables. To completely mask the dispensers, an entourage can be provided. Alternatively, it is possible to provide for the deposition of an enamel under the electroconductive layer 3, in the form of two strips identical to the collectors. The circulation of the electric current in the conductive layer develops heat by Joule effect. This heat is distributed over the entire surface of the mirror so that each point of the surface accessible to the touch is at a temperature not too high to avoid any risk of burning. In its anti-condensation function, the heating mirror is powered at very low voltage, for example 24 V. It presents virtually no danger for people and in particular no danger of electrocution. The surface temperature can be between 25 C and 50 C, typically of the order of 35 C. The pfd can be between 300 and 800 W / m2. The electric heating mirror 100 can be integrated with a bathroom element, especially over a sink. Alternatively, the two sides of the mirror are accessible, the electric heating mirror 100 being for example integrated in a partition wall. Since the heating layer 3 is transparent, the mirror 3 can be visible via the front face 11 and the rear face 12. In a variant, the electric heating layer is an organic conductive paint or a silver enamel grating and the we remove the two collectors. Example 2 Figure 2 schematically shows a sectional view of an electric heating mirror 200 in a second embodiment of the invention. This second electric heating mirror 200 differs from the first mirror 100 by the following characteristics: the heating layer is replaced by a self-adhesive heating film composed of: a plastic sheet 7 made of PET, for example of thickness 0.05 to 0 , 2 mm, coated with an aluminum heating network 30, - an acrylic adhesive film 32, thickness 0.05 to 0.2 mm, the self-adhesive heating film is stuck on an opaque enamel 5 forming a uniform background. Example 3 Figure 3a schematically shows a sectional view of an electric heating mirror 300 in a third embodiment of the invention. This third mirror 300 is distinguished from the first mirror 100 by the elements described below. The mirror layer 2 is deposited on the rear face 12 and an opaque enamel 5 is placed between the mirror layer and the heating layer 3, for example to form a uniform masking background. This third heating mirror 300 is designed to release enough heat to form a backup or main radiator. Typically, the surface power is between 1200 W / m2 and 1500 W / m2. This third heating mirror 300 is a wall radiator or is movable. It can be on feet, intended to be arranged in height on a bathroom plan or bathroom furniture. This third electric heating mirror 300 can also serve as a towel radiator. The napkin straddles the two main faces of the mirror 200 or is spread on a towel rail (not shown) for example in the form of a horizontal bar preferably fixed at mid-height by its ends in two projecting wall-mounting elements. provided for this purpose. For a high power application, electrical insulation is provided for an insulator 6 at the rear, for example a plastic film or another glass. In another napkin configuration, shown in front view in FIG. 3b, the mirror 300 forms the upper part of a towel dryer 310, the lower part being for example in the form of heated glass slides 300 '. Two vertical uprights 80, on either side of the vertical opposite edges 30 of the towel rail 310, hold the mirror 300 and the blades 300 '. FIG. 4 schematically represents a sectional view of an electric heating mirror 400 in a fourth embodiment of the invention. It is a radiator provided with an electric heating element in the form of a tubular resistor 30 'embedded in a metal plate 7', typically made of aluminum. This plate 7 'serves to distribute the heat more evenly. The face of the plate 7 'facing the part to be heated (front face) is coated with a high emissivity black paint to guide the heat flow 10 (not shown). The chromium layer 2, Mirastar type, is facing the front face of the plate 7 '. The substrate 1 with the mirror layer 2 and the plate 7 'are assembled by means of a carcass 70, covering the rear face of the plate 7'.

  The first and second electric heating mirrors 100 and 200 can also serve as radiators (towel rail) with, for electrical safety preferably, an insulator at the rear, for example a plastic film or another glass stuck on the element electric heater. 20

Claims (9)

  An electric heating mirror (100 to 400) comprising: - a glass substrate (1) having first (12) and second (5) main faces (11); - a mirror reflecting layer (2) on the first major face; an electric heating element (3, 30, 30 ') facing one of the first or second main faces, characterized in that the reflective layer is based on chromium and in that the glass substrate is hardened thermally.   Electric heating mirror (200, 400) according to claim 1 characterized in that said electric heating element (30, 30 ') is attached, spaced and / or assembled with the substrate, and in that the heating element electrical 15 preferably comprises one of the following means: - a heating network (3 ') in the form of conductive tracks, in particular conducting enamel or aluminum-based, - an electroconductive heating layer substantially covering the first or the second face , in particular based on metal oxide 20 or organic conductive paint, - a tubular electrical resistance (30 ') in particular in a metal enclosure (7').   Electric heating mirror (100, 300) according to claim 1, characterized in that the electric heating element (3) is a heating electroconductive layer deposited on the substrate above the chromium layer (2) or on the second main face (11), the layer being discontinuous thus forming conductive tracks, preferably conducting enamel or the layer (3) is based on metal oxide or conductive organic paint and preferably substantially covers the chromium layer or the second main face. 30   4. Electric heating mirror (100) according to one of the preceding claims characterized in that the chromium layer forming a mirror (2) is visible via the first face and the second face. 2903563 12   5. electric heating mirror (100) according to one of the preceding claims characterized in that the chromium layer (2) has a light reflection of about 60% and a light transmission of about 3%.   6. electric heating mirror (200, 300) according to one of the preceding claims characterized in that an enamel (5), preferably opaque, is disposed between the chromium layer (2) and the electric heating element (3). ', 3).   7. electric heating mirror (100 to 200) according to one of the preceding claims characterized in that it is anti-condensation function for domestic use, especially for bathrooms, toilets, or industrial, io including swimming pool , sauna, and / or forms a partition, a wall panel, a furniture facade.   8. electric heating mirror (300 to 400) according to one of the preceding claims characterized in that it serves as heating, in particular form a radiator wall or feet, a towel radiator with or without towel holder.   9. electric heating mirror (200, 300) according to one of the preceding claims characterized in that it comprises an electrical insulator (6, 7) above the electric heating element (3 '), including a film plastic or a glass. 20