FR3119294A1 - HEATED GLASS DEVICE - Google Patents

Abstract

The invention relates to a heating glass device (1) in particular with a function of separating two spaces, comprising a support structure (3) and a heated glazing (2) carried by said support structure (3). The heated glazing is advantageously heated appropriately to at least 40° C. to remove all traces of virus on its surface without exceeding the temperature of 65° C. and thus avoid the risk of burns. Preferably, the temperature is also adapted to avoid thermal discomfort. Figure to be published with abstract: Fig. 1

Description

HEATED GLASS DEVICE

The invention relates to a heating glass device, in particular for separating two spaces.

The invention will be more particularly described with regard to a heating glass separation device of the protective screen type, preferably able to be mobile and/or removable in order to be easily moved, without however being limited thereto. The invention applies to all glass surfaces of separation (vertical) or support surface (horizontal), mobile or fixed.

Since the appearance of the coronavirus, it has become common to arrange protective screens at counters or checkouts in places open to the public. These screens are often made of plastic material of the acrylic or polycarbonate type, the main drawback of which is its high scratchability. Since glass glazing is generally made transparent, it could also serve as a separating surface. However, whatever the material of the separation surface, it is essential to disinfect it regularly, which requires not only the use of disinfectant products and disposable paper, but also personnel who must be mobilized for these sanitary tasks.

Furthermore, glass glazing is known which is heated by being designed to heat between 20 and 45°C. They serve as heating in a room as radiators, or as an anti-condensation (anti-fog) and anti-frost solution. The current heated windows are not at all suitable for any other use, they require to be fixed in a building or vehicle window frame, or to be fixed to a wall, with an installation implementation specific both in their mechanical attachment and in their electrical connection. It is therefore not possible to use these heated glazings which remain heavy and not very easy to install, in a simple use of sanitary protection screen.

The object of the invention is therefore to propose a glass device which can be for sanitary use, in particular by serving as a separation device without having the aforementioned drawbacks, in particular the glass device being such that manual obligations can be dispensed with disinfection, while being practical to install and not very scratchy.

According to the invention, the heating glass device comprises a support structure, a heating glazing (in glass) carried by said support structure and provided with at least one heating means, electrical power supply means which, on the one hand, are connected to the heating means of the heated glazing by being integrated into the supporting structure (while being masked by the supporting structure), and on the other hand, comprise an electrical connection system which is external to the supporting structure and provided with an electrical connection socket (in order to electrically connect the heated glazing to an electrical power source such as the mains). The heating glass device according to the invention further comprises automated means for regulating and controlling the temperature of the glazing and the heating time, the automated means for regulating and controlling being capable of cutting off the electrical power supply of the heating means when a temperature setpoint value or a maximum temperature threshold value is reached, the temperature setpoint value being at most equal to the maximum temperature threshold value, and the regulation of the temperature being controlled (with a heating duration appropriate) so that the temperature of the glazing in operation is in a range going from 40°C to the maximum threshold temperature value which is at most 65°C.

In particular, the maximum temperature threshold value is at most 60° C., and preferably at most 56° C.

Scientific studies have shown that by heating a surface to 65°C for 5 to 10 minutes, viral loads are destroyed. However, a glass surface that is heated above 65°C, in particular heated to 70°C, risks second degree burns to a person who touches the glass, if only for one second. In addition, the radiation emitted by glazing heated to more than 65° C. can cause thermal discomfort for a user, for example for a counter clerk, who remains for some time in the immediate vicinity of this glazing, and this all the more when the temperature of the room where the device is installed is between 20 and 30°C.

The heating glass device of the invention precisely does not have these drawbacks. By suitably combining the control of the heating duration and the regulation of the heating temperature or temperatures over the range between 40° C. and at most 65° C., the heating glass device of the invention is used to destroy viruses on the outer surface of the glazing (on the outer opposite face(s) of the glazing) in a secure manner, without risk of burns for users.

Furthermore, if the temperature of a heated window were to reach 70° C. for a surface of the order of 1 m ² , the power density necessary for such a heated window would be very high, from 2000 to 2500 W/m ² , implying an impact on the electrical resistance of the electrical system of the device. With such a power density, combined with a voltage supply when it is for example 230 V, an intensity of the order of 10 A would then be reached, which constitutes a safety limit value for the cables and the associated switches. to the device, and would generate a non-negligible risk as to their damage. The heating glass device of the invention precisely does not present this risk.

In addition, the fact that the heated glazing is made of glass provides the advantage of being much less scratchable and therefore more durable over time than a plastic barrier surface.

Preferably, the maximum threshold value is 56° C., or even 50° C. by suitably adapting the heating time, which even better avoids the risk of burning. The heating glass device is thus during its operation, self-disinfected, and totally secure for people who would be nearby or who would touch it.

In addition, this temperature regulation makes it possible to cut off the power supply at the appropriate time to stop the heating, also avoiding any risk of damage to the heated glazing.

In particular, the power supply is automatically cut off if the maximum temperature threshold value is reached, even if the scheduled heating time (which has been pre-programmed in the factory) is not achieved. Thus, according to one characteristic, the automated regulation and control means are capable of cutting off the electrical power supply when the heating threshold value is reached before the end of the planned heating duration. This has the advantage of not risking damaging the heating glass device, nor burning oneself, in so-called degraded mode. The degraded mode corresponds to an surrounding temperature, that is to say the temperature of the place in which the glass device of the invention is located, which is not that, called the use temperature, for which the temperature combination and heating duration has been pre-programmed in the regulation means; for example, a degraded mode is one for which the actual surrounding temperature, such as 25°C or 30°C, is in fact higher than the operating temperature of the device which was planned at 20°C. In this degraded mode where the surrounding temperature is higher than that intended for use, the heating of the glazing to the temperature setpoint value can actually go much faster than the preprogrammed duration, and exceed the temperature setpoint value or even the maximum temperature threshold value before the end of the scheduled time, mainly causing thermal discomfort for the users, and a risk of burns. For example, by heating the glazing which has an ambient and surface temperature of 30°C, the threshold value of 56°C will be reached very quickly in a period shorter than that preprogrammed, and without the means of regulation and control. , the temperature would continue to increase beyond the threshold value, consuming energy unnecessarily and causing a significant increase in the temperature near the glazing, creating significant thermal discomfort for users.

The purpose of the regulation and temperature control means of the heating glass device of the invention is thus to avoid these problems in degraded mode of the device, that is to say when the temperature of the glazing reaches the setpoint value of temperature or the temperature threshold value pre-recorded in the regulation means (in any case which cannot be greater than 65° C.) in a period of time less than the pre-programmed duration.

Advantageously, the heating glass device is ready to use. The term "ready to use" means the fact that the user does not have to perform any installation procedure, the user only has to arrange the glass heating device in the desired location, connect it electrically via the electrical connection system such as by connecting the connection plug directly to the mains, and to use it. In English, the ready-to-use heating glass device of the invention is referred to as “Plug and Play”. The heating glass device of the invention used as a barrier to viruses is thus very practical to install; it is ready for electrical connection and use, providing quick and easy installation.

In the rest of the description, the qualifiers “external” and “external” with respect to an element of the heating glass device are understood to mean the elements in contact with the external environment of said device.

According to one characteristic, the power density is at most 1000 W/m ² , in particular from 500 to 700 W/m ² . The temperature regulation makes it possible to control the power density which thus remains reasonable (at most 1000 W/m ² ) and avoids any risk of damaging the electrical system of the glass heating device. Preferably, the heating glass device comprises heating glazing with an area of the order of 1 m ² , which allows the use of automated regulation means which are compact because with a power density not exceeding 1000 W/m ² , the intensity in the electrical system will not risk exceeding 10 A, therefore not requiring protection means which would otherwise be cumbersome and remote from the glass heating device, the latter then not being able to be mobile (transportable) and ready to work.

Advantageously, the automated means for regulating and controlling the temperature comprise a switch (preferably an automatic reset circuit breaker) which stops the power supply to the heating means in the event of an overvoltage detected at the input of the means of power supply while the temperature setpoint has been reached and the heating time continues. This advantageously ensures that an overvoltage (which sometimes occurs on the 230V mains supply) does not cause a rise in temperature beyond the temperature set point value; the regulation and control means comprising a temperature sensor, as soon as the temperature increases due to an overvoltage, the power supply is cut off. In addition, by this means of protection, there is no need to employ a transformer in the power supply system, which is a bulky element. The heating glass device of the invention can be directly connected to the mains.

According to another characteristic, the temperature regulation and control means comprise at least one temperature sensor, in particular in the form of a thermocouple, or at least one thermal switch (with lamella or bimetallic strip).

According to yet another characteristic, the means for regulating and controlling the temperature are also means for controlling the duration of heating so as to control the heating intermittently, preferably by periods, or else by heating it continuously, in particular continuously in a temperature range of 40°C to 50°C. The automated means of regulation and control come in the form of an electronic micromodule which is adapted, for example, to be housed in the supporting structure. An example of a micromodule has an input receiving data from the temperature sensor, a relay, a microprocessor to ensure excellent resolution of the temperature reading from the sensor and electronically precisely control the temperature of the heated glazing, an output from the temperature control heated glazing, an inorganic light-emitting diode (LED) display if required, and setting buttons. Such a micromodule is commercially available.

In the embodiment of continuous heating, as soon as the glass heating device is connected, the heating duration control means do not need to provide any regulation (variation in duration), they are for example made up of an on-off switch (external to the support structure and arranged on the support structure or at the level of an electrical connection cable of the electrical system of the glass heating device).

Different combinations of temperature setpoint values or temperature ranges and heating duration can be envisaged, in particular depending on the surface (area) of the glazing and the temperature at which the glass heating device is used (temperature of the environment in which said heating glass device is installed). A programming of the combination of the heating temperature and the heating duration is preferably pre-established and recorded in the factory in the automated regulation and control means. As a variant, mechanical or digital programming of the electronic regulation micromodule can be done on site during the installation of the glass heating device.

In one embodiment, the heated glazing is transparent over at least 50% or at least 80% of a main face of the glazing, or even entirely transparent. The greatest possible transparency of the glazing is used in particular for separation applications requiring vision through the heated glass device (such as vertical protective barrier applications on counters). Of course, the heated glazing may not be transparent (in the sense of a vision through the glazing), but for example translucent (frosted effect) or colored such as for semi-closed partitions in a restaurant or between offices (type space in open tray, also called in English "open space"), or for horizontal support surfaces.

Advantageously, the means for heating the glazing comprises a transparent electroconductive coating, in particular comprising a layer of at least one transparent electroconductive oxide. Alternatively, the heating means could be electrically conductive wires or electrically conductive strips. The electrically conductive wires are for example made of nichrome and have a section between 1.5 and 25 mm ² . The collector conductors of the electroconductive son are for example at least two strips arranged at the edge of the heated glazing (in particular arranged along two opposite edges, for example two lateral edges or two longitudinal edges of the glazing) to connect the heating means to the power supply system are advantageously hidden by the supporting structure of the heating glass device.

The invention also relates to a heated glass device comprising at least one heated glazing which is capable, by suitable heating of at least one of its surfaces, of eliminating all viruses on this surface, and a support structure which carries the heated glazing . The support structure is adapted to the use (in addition to that of removing viruses) which is made of the heating glass device.

The supporting structure is of shape and dimensions adapted to the use of the heating glass device. For example, the load-bearing structure may have a peripheral shape of a square or rectangular frame, but may be of another geometry. The load-bearing structure depends in particular on the self-supporting function of the heating glass device when this self-supporting function is mandatory or not depending on the destination of said heating glass device. The supporting structure may not form a frame, i.e. may not follow the entire periphery of the heated glazing. The supporting structure will at least be designed to make the electrical connection means of the heated glazing invisible. The supporting structure can for example use one or more U-sections whose width is adapted to arrange the edge of the heated glazing. For example, the U-shaped profile allowing the integration of an "88.2" laminated glass (two glass substrates 8 mm thick and two superimposed interlayer films 0.38 mm thick, which corresponds to a total thickness of glazing of 16.8 mm) has the following dimensions according to its section, 18 mm wide inside the U (width of the core between the two flanges of the U) for the integration of the edge of the glazing, 20 mm high (length of each of the wings of the U) for covering the main faces of the glazing along the edge of the periphery, and 2 mm thick of material. Different materials can be used for the load-bearing structure: steel, stainless steel, aluminium, plastic material, composite material. Preferably, the support structure is designed to avoid or at least limit as best as possible any thermal bridge between the heated glazing and the support structure, in order to avoid or at least limit the transfer of heat between the heated glazing and the support structure for that the latter is not too hot if the user touches it when the heating glass device is in operation. Depending on the constituent material of the support structure, in particular if it is particularly thermally conductive, interface means ensuring an insulating barrier can also be integrated between the support structure and the heated glazing; it can be the same material that secures the glass to the profile, for example silicone or polyurethane resistant to high temperatures.

According to yet another characteristic, the heated glazing may comprise on a main face of the glazing at least one marking, in particular a pictogram (rather static) indicating that the glass device is heated and/or a two-dimensional barcode, in particular of the Datamatrix type or QR Code, in particular the marking being visible in the operating mode of the heating and outside the operating mode, and in particular is an enamel on a main face of the glazing (preferably produced by depositing an enamel, in particular black, by screen printing). All types of marking can be considered.

The heated glazing may comprise in particular on a main face of the glazing at least one dynamic marking which is displayed (or becomes even more visible) when said heated glazing is in operation (that is to say when it is in heating mode ).

The dynamic marking is in particular a thermochromic marking (with thermochromic ink) of the organic thermochromic material type having a transition range in the temperature ranges considered in the heating device 1 (from room temperature to approximately 70° C.). Thermochromic materials are, for example, liquid crystals, or leuco-dyes (the leuco-dyes appearing in a known manner in the form of microcapsules).

The dynamic marking can be a diffusing marking (in particular enamel or paint, or varnish) which is luminous via a lighting system.

Thus, the heated glazing may comprise on a main face of the glazing at least one dynamic marking which is luminous when said heated glazing is in operation, in particular a luminous diffusing marking via a lighting system present in the supporting structure, in particular comprising at least a light emitting diode (inorganic, point) arranged at the edge of the glazing (in optical coupling with the edge, in particular in contact with or bonded to or spaced from the edge).

Diffusing marking is a means of extracting light, in particular a diffusing layer (temporary – (sticker, etc.) or permanent, texturing of the glazing (sandblasting, etching, etc.) or by laser engraving within the glazing. This marking diffusing is visible or transparent without lighting.The marking can be in the form of patterns, pictograms, forming a word, etc.

Such a diffusing layer can be in the form of an ink, paint or an enamel, in particular screen-printed or printed in a desired shape. For example, the ink is an ink whose composition is of the organic type (e.g. polymers, monomers, which may include formulation aid agents, deposit aid agents or even color stabilization aid agents depending on the rheology of the composition) or whose composition is sensitive to ultraviolet (UV). An ink of the organic type is an ink which diffuses the light beam which is brought to it. This organic ink is illuminated by a colored light source. A UV ink is an ink made up of a multitude of particles, each reacting differently. Indeed, the particles all react to the wavelength of UV light (405nm) but the reaction is different. It is therefore understood that the light source generates UV light. Indeed, these particles, subjected to the excitation of UV light, will themselves generate photons, that is to say a luminous flux. The wavelength of this flow is variable depending on the particles used. Thus, by mixing the particles according to a particular dosage, it is possible to obtain a multitude of colors.

The lighting system is for example one or more light-emitting diodes which are arranged at the edge of the glazing (preferably laminated). The radiation is guided in the glazing (on at least one substrate of the glazing) and is extracted (by diffusion) by the marking.

The light-emitting diodes (inorganic, point) can be ultraviolet (UV) radiation and/or illuminate in the visible. UV diodes convert guided UV light into visible light in the marking. The diffusing marking can be local (to keep transparency as much as possible), such as along the edge or edges of the glazing with lighting by the edge of the glass.

The lighting system of said diffusing marking can for example be integrated inside the supporting structure such as in a profiled frame.

• le long d’un bord longitudinal (notamment supérieur ou inférieur en position verticale) du vitrage et le système d’éclairage le long de ladite tranche dudit bord longitudinal,
• le long d’un bord latéral ou latéral du vitrage et le système d’éclairage le long de ladite tranche dudit bord latéral, notamment dans un coin du vitrage.

The diffusing marking can be:

• along a longitudinal edge (in particular upper or lower in the vertical position) of the glazing and the lighting system along said edge of said longitudinal edge,
• along a lateral or lateral edge of the glazing and the lighting system along said edge of said lateral edge, in particular in a corner of the glazing.

The heated glazing may be laminated glazing and/or insulating glazing of the double or triple glazing type, optionally including at least one tempered glass substrate.

According to yet another characteristic, the supporting structure is a self-supporting structure, which makes it possible to install the heating glass device immediately in any place to be used. In particular, the supporting structure comprises a frame (particularly U-shaped profile), preferably surrounding the whole of the heated glazing (and in which the invisible part of the electrical supply system runs), and feet integral with the frame (which provide stability to the entire device). The electrical connection socket can be integrated into the frame or attached to the end of an electrical cord coming out of the frame. The current supply system to the electrical connection elements may include electrical cables that run inside the supporting structure (in the frame) so as not to be visible.

• (en interne au dispositif verrier et) caché à l’intérieur de la structure porteuse -si la programmation a été faite en usine, et nécessite de ne pas être modifiée par l’utilisateur- ; ou
• fixé sur l’extérieur de la structure porteuse ou intégré à la structure porteuse, et débouchant à l’extérieur de la structure porteuse - le micromodule étant ainsi accessible par l’utilisateur s’il est nécessaire de modifier la programmation -; ou
• installé de manière déportée en étant connecté au système d’alimentation électrique du dispositif verrier chauffant , de manière filaire ou sans fil par des moyens de communication à distance.

In one embodiment, the automated regulation and control means are in the path of the electrical supply to the heated glazing. The automated regulation and control means are in the form of an electronic micromodule which can be arranged as follows:

• (internally to the glass device and) hidden inside the support structure -if the programming was done in the factory, and does not need to be modified by the user-; Where
• attached to the outside of the support structure or integrated into the support structure, and opening outside the support structure - the micromodule thus being accessible by the user if it is necessary to modify the programming -; Where
• installed remotely by being connected to the power supply system of the heating glass device, wired or wirelessly by means of remote communication.

The heating glass device can be mobile, in particular without permanent or temporary fixing to the floor or wall. Mobile means in particular the fact of being movable or transportable or portable, for example for a heating glass device whose glazing is laminated glazing "33.2", the weight of the heating glass device is approximately 20 kg , while it will be 70 kg for “88.2” laminated glazing. Depending on the use of the heated glass device and/or its dimensions, the heated glass device may include rollers fixed to the supporting structure. The heated glass device is ready to use; it only has to be electrically connected and is immediately functional.

The supporting structure may include removable fixing means for temporarily fixing the glass device to a horizontal surface.

Furthermore, the heating glass device may comprise an ultraviolet lighting system, in particular comprising at least one (inorganic) light-emitting diode emitting in the ultraviolet, preferably in the form of strips of light-emitting diodes emitting in the ultraviolet, in particular UVC to provide additional antiviral function. The ultraviolet lighting system can for example be integrated inside the load-bearing structure such as in a profiled frame. The disinfection of the frame can be done by ultraviolet radiation, for example with an (other) integrated lighting system whose angle is adapted to cover the periphery of the glazing and the frame.

In addition, the heated glazing may comprise on all or part of a main face, a surface capable of diffusing and/or reflecting and delivering one or more information, in particular by serving as a projection screen. Lighting is then provided, which may be the ultraviolet lighting provided for additional disinfection.

The heated glass device is according to the invention intended to be used as a barrier to viruses, the heated glazing in operation being destructive of viruses on its surface.

Finally, the heated glass device can be used as an all or part transparent separating device, in particular for a reception counter or store checkout, or as an interior partition or as an office separating device or a separating device tables in a restaurant or a separation device in a place open to the public under shelter.

• comptoir d’accueil type hôtels, bureaux, mairie, EHPAD,
• comptoir d’accueil type caisse haute (magasins type textile),
• caisse de supermarché,
• guichets d’accueil grand public (type en gare ou en kiosque),
• cloisons intérieures (notamment dans hôpitaux, EHPAD, mais aussi bureaux)
• séparateurs de bureaux,
• séparateurs dans les restaurants (entre les tables de clients), en intérieur mais aussi en extérieur en terrasse par temps sec ou dans une zone protégée des intempéries,
• meubles de bureaux type table en verre, tableau blanc en verre, paillasse en verre, surface horizontale d’appui de comptoir.

In a non-exhaustive way, the uses can be the following:

• reception desk such as hotels, offices, town hall, EHPAD,
• high cash desk type reception counter (textile type stores),
• supermarket checkout,
• reception counters for the general public (in the station or at a kiosk),
• interior partitions (especially in hospitals, nursing homes, but also offices)
• office dividers,
• separators in restaurants (between customer tables), indoors but also outdoors on the terrace in dry weather or in an area protected from bad weather,
• glass table-type office furniture, glass whiteboard, glass bench top, horizontal counter support surface.

Characteristics and other advantages of the invention will appear on reading the following description, given solely by way of non-limiting example, and made with reference to the accompanying drawings and in which

• ou représente une vue en perspective d’un exemple de réalisation du dispositif verrier chauffant selon l’invention intégrant une surface verrière à fonction auto-désinfectante.
• ou est une variante de la quant au raccordement électrique du dispositif verrier chauffant.
• ou est une vue en perspective d’une variante de la , le dispositif verrier chauffant étant sur roulettes.
• ou est une vue schématique en coupe partielle du vitrage chauffant du dispositif verrier chauffant de la , montrant son alimentation électrique.
• ou montre un autre exemple encore du dispositif verrier chauffant en position d’utilisation sur un comptoir et doté de fonctionnalités supplémentaires que sont au moins une zone de marquage et une zone dédiée à une projection d’images, lesdites zones étant ici invisibles et schématisées par des pointillés et ne s’affichant que sous éclairage ultraviolet.
• ou correspond à la en mode éclairé et faisant par conséquent apparaître les zones de marquage et de projection d’images.
• ou illustre une vue en perspective d’un autre exemple de réalisation de dispositif verrier chauffant de l’invention, comprenant un premier dispositif verrier chauffant en tant qu’écran transparent de protection et doté de trois surfaces verrières selon un design en U, la surface verrière centrale du U étant au moins un vitrage chauffant à fonction auto-désinfectante, et un second dispositif verrier chauffant formant une partie de la surface d’appui horizontale sur laquelle est agencé le premier dispositif.

The present invention is now described using only illustrative examples and in no way limiting the scope of the invention, and from the accompanying illustrations, in which:

• Where shows a perspective view of an embodiment of the heating glass device according to the invention integrating a glass surface with a self-disinfecting function.
• Where is a variant of regarding the electrical connection of the glass heating device.
• Where is a perspective view of a variant of the , the heating glass device being on wheels.
• Where is a partial sectional schematic view of the heated glazing of the heated glass device of the , showing its power supply.
• Where shows yet another example of the heated glass device in the position of use on a counter and provided with additional functionalities which are at least one marking area and one area dedicated to projecting images, said areas here being invisible and schematized by dotted lines and displaying only under ultraviolet light.
• Where corresponds to the in lit mode and therefore revealing the marking and image projection zones.
• Where illustrates a perspective view of another exemplary embodiment of a heated glass device of the invention, comprising a first heated glass device as a transparent protective screen and provided with three glass surfaces in a U-shaped design, the glass surface central U being at least one heating glazing with self-disinfecting function, and a second heating glass device forming part of the horizontal bearing surface on which the first device is arranged.

The heating glass device of the invention is intended to provide a vertical barrier surface, such as a protective pane illustrated in FIGS. 1 to 6, or else a horizontal support surface such as a work surface or a counter part as shown in the , the vertical or horizontal surface being disinfected in an automated manner (self-disinfected), that is to say without human intervention. The heated glass device is able to eliminate any virus that would be deposited on its surface, without manual cleaning intervention.

The heated glass devices 1 illustrated in FIGS. 1 to 6 are examples of the embodiment of a vertical barrier surface aimed at separating two spaces and protecting the people intended to be placed on each side. Depending on the intended use, its height is adapted and its installation method may be different.

The heating glass device 1 of Figures 1, 5a and 6 is more particularly intended to be installed on a counter 7 for example of a store, as a transparent glazed surface to see through, while constituting a protective screen for each of the people placed on each side. People will be able to talk without necessarily being masked, the glass surface acting as a protective barrier for users and being self-disinfected. The counter 7 on which the users can lean can also constitute, optionally only in part, a heated glass device of the invention, the heated glazing 2 being arranged in a horizontal plane to disinfect the support surface.

As shown in Figures 1 to 4, the heated glass device 1 comprises a heated glazing 2, a support structure 3 which makes the device self-supporting, electrical supply means 4 for the heated glazing 2, the electrical supply means 4 comprising an electrical connection system 5 external to the heated glass device for electrically connecting said device, for example to the mains, and an internal current supply system 40 from the electrical connection system 5 to the heated glazing 2. In addition, the device heated glass 1 comprises automated means 6 for regulating and controlling the temperature of the heated glazing 2 and controlling the heating time. The automated regulation and control means 6 are on the electrical path between the heated glazing and the exterior electrical connection system 5 .

The supporting structure 3 comprises a peripheral frame 30 which carries the heated glazing 2 and supporting means 31 of the heating glass device 1 to make said device self-supporting and install it in the desired location depending on its destination.

The supporting means 31 are feet which ensure the stability of the heating glass device 1 on a vertical, flat surface. The feet 31 are fixed in this example. The heating glass device 1 has dimensions of the order of 1 m ² , which allows it to be handled and moved easily in order to place it via its feet 31 on any surface. The feet 31 can if necessary include fixing holes for screwing the feet onto a surface. On the , the carrying means 31 consist of two here glazed returns which are perpendicular to the heated glazing 2.

The heating glass device 1 of the is rather intended to be installed on the floor, while preferably being mobile via rollers 32 which are integrated into its carrying means 31. In this example, the glazed surface of the heated glazing 2 is not necessarily transparent because the device glass heater 1 aims above all to provide a protective barrier between people located on each side, without necessarily that people see each other. Such a glass heating device 1 can for example be used in a restaurant to separate two tables side by side.

As shown on the , the heated glazing 2 of the heating glass device 1 comprises at least two external glass substrates 20 and 21, and at least one heating means 22 which is arranged inside the glazing, between the two external substrates 20 and 21. heater 2 has two opposite main faces 2A and 2B forming the outer faces of the glazing and in contact with the outside environment. The main faces 2A and 2B constitute the external faces of the glass substrates 20 and 21.

Preferably, the heating means 22 is at least one electroconductive transparent coating such as an electroconductive layer consisting of at least one transparent electroconductive oxide, for example fluorine-doped tin oxide or another mixed oxide of indium and tin, preferably deposited on the internal face of at least one of the glass substrates.

The heated glazing 2 can be laminated glazing and/or insulating glazing of the double or triple glazing type. One or more glass substrates constituting the glazing may be made of tempered glass.

The heated glazing 2 preferably provides heating of the two outer surfaces 2A and 2B, the heating being adapted as will be seen later to remove all viruses, while avoiding the risk of thermal discomfort. When the glazing is laminated, even if the heating means coats the inside of only one of the two glass substrates, the result is that the two outer faces 2A and 2B of the glazing are heated.

Nevertheless, depending on the intended application, it may be envisaged to heat only one external face of the glazing (at least to ensure the removal of viruses on this face) while the other external face is either unheated because the infrared energy does not manage to pass through the glass, as for example for insulating glazing of the triple glazing type, or less heated (in any case insufficiently heated to eliminate viruses) as when the insulating glazing is double glazing and/or when the glass substrate opposite the glass substrate provided with the heating means, is provided with a so-called low emissive (transparent) layer which, by reflecting the infrared energy of the facing heating means, greatly reduces the heating of the external face of the glass substrate provided with said low emissive layer. The low emissive (transparent) layer is for example a silver stack or other functional metallic layer (on an internal face of the laminated glazing or of a double glazing) in particular between layers of dielectric material of the metal oxide or nitride type. silicon. A low emissive layer is for example a stack of conductive transparent oxide on one or each external face of the laminated glazing.

The heated glazing 2 of the is laminated glazing which comprises, in a known manner, between the two glass substrates 20 and 21, an intermediate bonding film 23 made of plastic material such as polyvinyl butyral (PVB). The heated laminated glazing is for example a glazing whose constitution corresponds to that of the EGLAS® glazing marketed by SAINT-GOBAIN. The heated laminated glazing may include other functionalities, linked for example to the nature of the interlayer film, for example to also provide laminated safety glazing such as STADIP PROTECT® glazing or acoustic laminated glazing such as STADIP SILENCE® glazing, both marketed by SAINT-GOBAIN

The electrically conductive heating layer 22 is arranged between one of the glass substrates and the PVB film 23. It is preferably deposited directly on the internal face of one of the glass substrates such as the first glass substrate 20. Preferably, the electrically conductive heating layer 22 covers partially or all of the surface of the glass substrate 20. Although the heating means 22 is associated with the first substrate 20, the second substrate 21 immediately bonded to the first also benefits from the heating, the two opposite faces 2A and 2B of the glazing being thus heated.

The heating means 22 comprises electrical connection elements 22'. For a heating electroconductive layer 22, the electrical connection elements are collector conductors of the bus bar type, in particular in strips, which are arranged along two opposite edges of the layer and hidden by a layer (such as an enamel) of masking and/or the carrier frame 30 of the carrier structure 3.

The electrical power supply means 4 of the heating means 22 comprise the electrical connection system 5 which is external to the support structure 3 and the internal current supply system 40 from the electrical connection system 5 to the connection elements electric 22' of the heating means 22.

The electrical connection system 5 is provided with an electrical connection socket 50 which can be integrated into the frame 30 ( ) or integral with the end of an electric cord coming out of the frame 30 ( ).

The current supply system 40 ( ) to the electrical connection elements 22 'comprises electrical cables which run inside the supporting structure 3 (in the frame 30) so as not to be visible.

The operation of the glass heating device 1 is done by directly connecting the electrical connection socket 50 to the mains (FIGS. 1 and 2), an on-off switch 51 being able to be provided as an interface on the electrical supply path.

• en interne au dispositif verrier 1 et caché à l’intérieur de la structure porteuse 3 (ce qui est par exemple le cas de la ) lorsque la programmation a été faite en usine, et nécessite de ne pas être modifiée par l’utilisateur ; ou
• fixé sur l’extérieur de la structure porteuse 3 ou intégré à la structure porteuse 3, et débouchant en son extérieur (comme illustré sur les figures 1 et 4), le micromodule 6 étant ainsi accessible par l’utilisateur s’il est nécessaire de modifier la programmation ; ou
• installé de manière déportée en étant connecté au système d’alimentation électrique 4 du dispositif verrier chauffant 1, de manière filaire ou sans fil par des moyens de communication à distance.

The heating glass device 1 of the invention makes it possible to eliminate viruses at a heating temperature which according to the invention does not exceed 65° C., thanks to the automated means of regulation and control 6, which are coupled to the heated glazing 2. The automated regulation and control means 6 are in the path of the electrical supply to the heated glazing 2. The automated regulation and control means 6 are in the form of an electronic micromodule which can be arranged as follows :

• internally to the glass device 1 and hidden inside the support structure 3 (which is for example the case of the ) when the programming has been done in the factory, and does not need to be modified by the user; Where
• fixed to the outside of the supporting structure 3 or integrated into the supporting structure 3, and emerging on its exterior (as illustrated in FIGS. 1 and 4), the micromodule 6 thus being accessible by the user if it is necessary to change the schedule; Where
• installed remotely by being connected to the power supply system 4 of the heating glass device 1, wired or wirelessly by means of remote communication.

The automated regulation and control means 6 ensure that the heating temperature is appropriately combined with a heating time in order to remove, when the heating glass device 1 is in operation, any virus on preferably the two faces 2A and 2B of the glazing. heater 2. The automated regulation and control means 6 are able to cut off the power supply to the electrically conductive heating layer 22 when a temperature setpoint value or a maximum temperature threshold value is reached, the setpoint value temperature being at most equal to the threshold value.

The temperature of the heated electro-conductive layer 22 which corresponds to the temperature of the heated glazing 2 in operation is between 40° C. and the threshold value of at most 65° C., avoiding any risk of burns for the user if the -it touches the heated glass for more than 2 seconds. Preferably, the threshold value does not exceed 56°C.

The heating glass device 1 further comprises at least one temperature sensor 60 ( ) attached to the heating means 22 and connected to the automated means of regulation and control 6. Depending on the temperature information received (for example every minute, but the frequency could be less) by the automated means of regulation and control 6, the latter adapt the temperature and the heating time according to the pre-recorded heating program.

Furthermore, the automated means for regulating the temperature 6 comprise a switch 61 such as an automatic reset circuit breaker, which stops the power supply to the electrically conductive heating layer 22 in the event of an overvoltage detected at the input power supply means 5 when the temperature setpoint value has been reached but the heating time continues to ensure that the temperature setpoint value is maintained for a determined (pre-recorded) duration. Overvoltage detection is done by monitoring the temperature of the electrically conductive heating layer 22, and when the temperature rises suddenly, the circuit breaker 61 opens. The aim is to avoid a temperature rise above the temperature set point. Indeed, depending on the heating protocol imposed on the heated glazing, it is advisable not to reach a temperature above 65° C. which would risk burning a user who touches the glazing.

In an exemplary embodiment of the heated glass device 1 for which the heated glass glazing 2 is an "88.2" heated laminated glazing whose function is to remove any trace of the human Coronavirus 229E on the surface of the heated glass glazing 2, the setpoint value of temperature is 45°C. Once the electrically conductive heating layer 22 reaches the temperature of 45°C, the temperature of 45°C is maintained continuously at least for one hour to ensure the removal of the virus. The inventors have demonstrated that such a heating protocol was sufficient to disinfect the two surfaces 2A and 2B of the heating glass device 1, without risk of burning for the user.

At 45°C, thermal discomfort is thus minimized.

In addition, the automated temperature regulation means 6 make it possible to control the power density which does not exceed 1000 W/m ² , thus avoiding any risk of damage to the electrical system of the heating glass device.

On the , the heating glass device 1 is provided with a static marking 8 such as a pictogram warning of the heating aspect of the device. The static warning marking 8 is permanently visible. As a variant, the warning marking can be a dynamic marking 80, that is to say appearing only when the heated glazing 2 heats up, like the written indication which is made visible on the heated glazing 2 in operation of the , whereas it is (almost) invisible when the heated glazing 2 is switched off ( ). The dynamic marking 80 is for example a marking with thermochromic ink (including for example micro-capsules of leuco-dyes) or even a diffusing and luminous marking by light extraction.

Depending on the use that will be made of the glass heating device 1, in addition to its protective barrier function against the projection of droplets and particles in the air, and its function of self-disinfection of its glass surface against viruses, the device heated glass 1 can integrate other functionalities, such as that of a projection screen 9 ( ) which is capable of displaying an image 90 ( ) when the area of the projection screen 9 is illuminated ( ) by a remote projection system (front projection or rear projection or by the integration of a dynamic or active screen within the glazing). All conventional screen technologies can be used (liquid crystals called 'LCD', electroluminescent thin film called 'TFEL', active matrix with organic light-emitting diodes called 'AMOLED', etc.).

To form a dynamic luminous diffusing marking, a diffusing layer 80' is used on the glass 21 as shown schematically in the (just at the desired location of the marking) (or a surface texturing of the glass), forming a guided light extractor. A lighting system is for example obtained by light-emitting diodes 10 which are arranged at the level of the edge of the heated glazing 2 ( ) to be in optical coupling with the heated glazing forming a light guide before extraction via the diffusing layer 80'.

Finally, an ultraviolet UVC "lighting" system to provide an additional antiviral function can be integrated inside the supporting structure 3 in the profiled frame 30 and at the level of the edge of the heated glazing 2. This lighting corresponds for example to all or part of the light-emitting diodes 10 which then emit in the ultraviolet UVC.

Thus, the heating glass device 1 of the invention can serve as a separation surface or as a support surface, and is capable, by being heated in an appropriate manner and without exceeding 65° C., of destroying the viruses which would be present on its surface. canopy, while avoiding the risk of burns or thermal discomfort, the glass device being easy to install and simple to use.

The general shape of the glazing can be variable, with or without through openings, etc.

Claims (19)

Heated glass device (1) comprising a support structure (3), a heated glazing (2) carried by said support structure (3) and provided with at least one heating means (22), electric power supply means (4 ) which, on the one hand, are connected to the heating means (22) of the heated glazing by being integrated into the support structure (3), and on the other hand, comprise an electrical connection system (5) which is external to the support structure and provided with an electrical connection socket (50), characterized in that it comprises automated means for regulating and controlling (6) the temperature of the glazing and the heating time, the automated means for regulating and control (6) being capable of cutting off the electrical power supply to the heating means (22) when a temperature setpoint value or a maximum temperature threshold value is reached, the temperature setpoint value being at most equal to the maximum temperature threshold value, the regulation on of the temperature being controlled so that the temperature of the glazing in operation is in a range going from 40°C to the maximum threshold temperature value which is at most 65°C. Glass heating device according to Claim 1, characterized in that the maximum temperature threshold value is at most 60°C, and preferably at most 56°C. Glass heating device according to any one of the preceding claims, characterized in that the power density is at most 1000 W/m ² , in particular from 500 to 700 W/m ² . Heating glass device according to any one of the preceding claims, characterized in that the automated means (6) for regulating and controlling the temperature comprise a switch (61), preferably a circuit breaker with automatic resetting, stopping the electrical supply of the heating means in the event of an overvoltage detected at the input of the electrical power supply means when the temperature setpoint value has been reached and the heating time continues. Device according to any one of the preceding claims, characterized in that the temperature regulation and control means (6) comprise at least one temperature sensor (60) in particular in the form of a thermocouple, or at least one thermal switch. Device according to any one of the preceding claims, characterized in that the temperature regulation and control means (6) are also means for controlling the duration of heating so as to control the heating intermittently, preferably by periods , or else by heating it continuously, in particular continuously in a range of temperatures ranging from 40° C. to 50° C. Device according to any one of the preceding claims, characterized in that the heated glazing (2) is transparent over at least 50% or at least 80% of a main face of the glazing. Device according to any one of the preceding claims, characterized in that the heating means (22) of the glazing comprises a transparent electroconductive coating, in particular comprising a layer of at least one transparent electroconductive oxide. Device according to any one of the preceding claims, characterized in that the heated glazing (2) comprises on a main face of the glazing at least one marking (8) in particular a pictogram indicating that the glass device is heated and/or a code- two-dimensional bars, in particular of the Datamatrix or QR Code type, in particular the marking being visible in heating operating mode and out of operating mode, and in particular is an enamel on a main face of the glazing. Device according to any one of the preceding claims, characterized in that the heated glazing (2) comprises in particular on a main face of the glazing at least one dynamic marking (80) which is displayed when the said heated glazing is in operation, in particular the dynamic marking is a thermochromic marking or is a diffusing marking, in particular of enamel or paint or varnish, which is luminous via a lighting system. Device according to any one of the preceding claims, characterized in that the heated glazing (2) comprises on a main face of the glazing at least one dynamic marking (80) which is luminous when the said heated glazing is in operation, in particular a diffusing marking light via a lighting system (10) present in the support structure (3), in particular comprising at least one light-emitting diode arranged at the edge of the glazing. Device according to any one of the preceding claims, characterized in that the heated glazing (2) is laminated glazing and/or insulating glazing of the double or triple glazing type, optionally including at least one tempered glass substrate. Device according to any one of the preceding claims, characterized in that the supporting structure (3) is a self-supporting structure. Device according to any one of the preceding claims, characterized in that the support structure (3) comprises a frame (30), preferably surrounding the whole of the heated glazing (2), and feet (31) integral with the frame. Device according to any one of the preceding claims, characterized in that it is mobile. Device according to any one of the preceding claims, characterized in that it comprises an ultraviolet lighting system (10), in particular comprising at least one light-emitting diode emitting in the ultraviolet. Device according to any one of the preceding claims, characterized in that the heated glazing (2) comprises, on all or part of a main face, a surface (9) capable of diffusing and/or reflecting and delivering one or more information (90), in particular by serving as a projection screen. Use of the device according to any one of the preceding claims, as a barrier to viruses, the heated glazing in operation being destructive of viruses on its surface. Use of the device according to any one of the preceding claims as a fully or partially transparent separation device, in particular for a reception counter or store checkout, or as an interior partition or as a desk separation device or a device separation of tables in a restaurant or separation device in a place open to the public under shelter.