WO2021116186A1 - System for controlling the temperature and/or opacity of electrically activatable glass sheets - Google Patents

Abstract

System for controlling the temperature and/or opacity of one or more electrically activatable glass sheets divided into group(s), comprising: - at least one probe configured to measure at least one physical quantity in each group of glass sheets, the quantity being chosen from a glass sheet surface temperature, a glass sheet electrical resistance or a light intensity, or a combination thereof, - at least one electrical power supply housing connected to each probe and configured to supply each glass sheet with electricity individually, - a control housing connected to each power supply housing, such that the control housing receives the signals corresponding to the measurements carried out by the probe(s) and emits control signals to each electrical power supply housing according to the quantities measured by the probe(s) of the corresponding glass sheet and an electrical power allocated to the control system.

Description

Description

Title: TEMPERATURE AND / OR OPACITY REGULATION SYSTEM OF WINDOWS ACTIVABLE BY ELECTRIC CURRENT

Technical area

The present invention relates to the field of glazing that can be activated by electric current, and in particular of heated glazing and / or of glazing with variable shading.

It may be glazing integrated into a room, such as a veranda, part of a building with glass walls, a public swimming pool, or even a roof.

It can also be insulated glazing, for example glass partitions, for hygienic separation, such as used for interior or exterior reception counters or for cash registers.

The invention aims more particularly to provide a system for regulating the temperature and / or the brightness of a room equipped with one or more exterior glazing that can be activated by electric current.

By "glazing activated by electric current" is meant a glazing of which one or more physical characteristics can be modified by application of an electric current. By "heated glazing" is meant a glazing comprising at least one sheet of glass coated with one or more thin layers capable of producing heat by application of an electric current.

By "variable blackout glazing" is meant a glazing comprising at least one sheet of glass and the degree of opacity of which can be controlled by the application of an electric current. This includes in particular electrochromic glazing and glazing in which at least one glass sheet is coated with at least one liquid crystal film.

Prior art

It is known to use glazing that can be activated by electric current to regulate the brightness of a room. Such a variable occultation glazing can in particular be a so-called electrochromic glazing or a glazing with liquid crystal film (s).

An electrochromic glazing usually comprises an assembly of stacked layers capable of exchanging electrical charges. The degree of opacity of the layers can be controlled by a transfer of electric charges between the different layers, this transfer being generated by the application of an electric field. Another type of variable occultation glazing consists of a glazing comprising at least one liquid crystal film, generally in the form of liquid crystal droplets arranged in a polymer matrix. The opacity of such a film depends on the orientation of the liquid crystals, which is also controlled by the application, or non-application, of an electric field.

It is also known to use glazing that can be activated by electric current to produce heat.

Such heated glazing can be double glazing or triple glazing.

In the case of double glazing, the interior pane, that is to say the sheet of glass which is in contact with the air inside the building, is coated with at least one thin heating layer on its exterior surface. , ie the surface facing the outside of the building. The thin heating layer, generally made up of metallic microparticles deposited on the surface of the glass, is connected to an electrical supply. Under the effect of an electric current, the heating layer reaches a temperature typically between 20 ° C and 55 ° C and produces thermal radiation. The inner pane is usually made of tempered glass.

The outer pane has on its inner surface, that is to say the one facing the inner pane, a thin reflective layer suitable for reflecting the thermal radiation produced by the heating layer.

The space between the two panes can be filled with an inert gas.

In the case of triple glazing, a third pane is arranged between the inner pane and the outer pane, in order to improve thermal insulation.

In terms of comfort and feeling, the heated glazing constitutes a soft and homogeneous source of heat. As it is radiant heating, it provides a feeling of homogeneous heat while avoiding the phenomena of air convection generated by convection heaters. It thus limits the drafts, the movement of dust and the drying out of the air associated with this type of heating.

It advantageously makes it possible to avoid the cold wall effect of a glazing when the outside temperature is lower than the building temperature and to avoid condensation phenomena on the surfaces in contact both with the inside air and 'outside. In addition, a heated glazing system saves space by eliminating the need to install additional heaters, for example on the walls of a room.

Heating by heated glazing is particularly advantageous in the context of heating rooms or buildings with many glazed surfaces, such as verandas, swimming pools, spas, sports halls, certain roofs or even buildings with large glazed surfaces. .

Heated glazing prevents heat dissipation from a heated location through windows or other glass surfaces; it can also perform anti-condensation or snow removal functions.

Furthermore, glazing is likely to contain pathogens on its surface. For example, according to the publication [1], coronaviruses infecting humans are likely to retain their infectious potential on a surface, such as glass, for up to 9 days at room temperature.

However, the temperature of a surface affects the stability of organic or viral elements that may be deposited there. Thus, the publication [2] concludes that the strain of coronavirus SARS CoV-P9 becomes non-infectious after exposure to 56 ° C for 90 minutes, to 67 ° C for 60 minutes or to 75 ° C for 30 minutes.

However, the installation of a set of heated glazing remains complex. Indeed, each installation is a specific situation due to the great diversity of possible configurations of the glazing concerned: an adaptation specific to each configuration is therefore necessary, which prevents the implementation of standardized solutions that could make the implementation more widely accessible heated glazing.

Typically, the installation of heated glazing requires the installation of an electrical box customized according to the number of glazings and their power consumption. In addition, once the installation has been completed, replacing one type of glazing with another glazing with different characteristics is in practice impossible. This makes maintenance of the glazing potentially difficult.

Furthermore, in the case of heated glazing carried by joinery openings, typically sliding glass doors, the installation and implementation of a heated glazing solution remains a relatively complicated and expensive operation. As regards the regulation of heated glazing, existing regulation systems typically operate solely from a temperature probe and a temperature setpoint, generally determined by a user. The control of the heated windows is then particularly simple: if the measured temperature is lower than the temperature setpoint, an identical electric current is delivered to all the heated windows. Once the temperature setpoint is reached, the current is interrupted. It is therefore a little evolved operation which makes it possible to optimize neither the consumed electric power nor the thermal comfort of the room equipped with the heated windows.

Patent application KR 20170051049A relates to a control system for heated glazing. In a first embodiment, the system aims to prevent the formation of condensation of a given glazing. A power supply box supplies the glazing, depending on the temperature and humidity of the room, so that it heats up sufficiently and thus prevents condensation on it. In a second embodiment, the system aims to use a single power supply box to control a plurality of heated glazing. However, in all cases, it is necessary during the initial implementation of the system that the characteristics of the glazing (dimensions, intrinsic electrical resistance) and of the electrical installation (available power) are pre-recorded. The system described in this application must therefore be configured manually according to the specifics of each room configuration and related electrical installation: it is therefore not a system that can be easily adapted to different configurations.

There is therefore a need for a solution for a system for regulating the temperature and / or the opacity of a room equipped with glazing that can be activated by electric current which makes it possible to simplify the installation of the glazing and to improve its control. whatever the configuration of the room and the related electrical installation.

The aim of the invention is to at least partially meet this need.

Disclosure of the invention

To do this, the invention relates to a system for regulating the temperature and / or opacity of one or more functional glazing, activated by electric current, distributed by group (s) comprising:

- at least one probe configured to measure at least one physical quantity at the level of each group of glazing, the physical quantity being chosen from a temperature glazing area, an electrical resistance of the glazing or a light intensity, or a combination thereof,

- at least one power supply box connected to each probe and configured to supply each glazing individually with electricity according to a current and / or a voltage that can be varied,

- a control unit connected to each power supply unit, so that the control unit receives the signals corresponding to the measurements carried out by the probe (s) connected to each power supply unit, and that it emits signals electrical control signals to each electrical supply box as a function of the quantities measured by the probe (s) of the corresponding glazing and of an electrical power allocated to the regulation system.

By “glazing” is meant here and in the context of the invention, any type of glazed wall, configured with a single sheet of glass (single glazing), with two sheets of glass separated by a gas layer ( double glazing), with three sheets of glass spaced by two blades of gas (triple glazing). It can be a glass door, a glass partition, a fixed bay window, opening, sliding, partition, a window (wall, balcony, roof), a door. window, curtain facade, skylight, bow window ...

The term “glazing group” is understood to mean an assembly comprising one or more glazing, for example electrically connected in series. Thus, the regulation system according to the invention can include a probe for each glazing of the installation, but it can also include a number of probes less than the number of glazings of the installation, for example a probe for two glazings in series. electric.

Preferably, the heated glazing units connected in series of a group whose physical magnitude (s) are measured by means of a single probe, have a close impedance, that is to say that the the difference in impedance between the glazing units of the group is small, preferably less than 20%, or even 10%. This ensures homogeneous thermal behavior between the different panes of the same group.

By “electrical power allocated to the regulation system” is meant an electrical power which can be supplied to the regulation system at a given time. This electric power can be fixed and determined at the time of installation of the system according to the invention, or variable and determined dynamically depending on the source (s). available power supply and the instantaneous power (s) that it can deliver.

Thus, the invention essentially consists of a system for regulating the temperature and / or the opacity of one or more panes that can be activated by electric current as a function of several parameters including an allocated electric power.

To this end, one or more probes provide measurements of suitable physical quantities. One or more power supply boxes individually power the glazing, in order to optimize the regulation of the temperature and / or the brightness of a room. Finally, a control unit controls the regulation system as a function in particular of the measured data.

Advantageously, the regulation system further comprises a power determination means configured to determine an electrical power available on the electrical installation of the building, the control unit being connected to the power determination means, so that the control unit receives the signals corresponding to the measurements performed by the power determination means, the electrical power allocated to the regulation system being the available electrical power.

According to this embodiment, the control unit receives from the power determination means the electrical power available on the electrical installation of the building integrating the room: this allows active management of the distribution of electrical power according to needs, and in particular simplifies the management of the electrical power to be assigned to the system. Indeed, thanks to the invention, it is not necessary to specifically reserve a predetermined electric power for the glazing. The regulation system can determine and use the power available at a given time and thus allow an automatic adaptation in real time of the regulation system to the power available. If the available power is high, this allows the regulation system to use, if necessary, a high power which can be higher than a predetermined power which would be reserved for the regulation system.

The term “determine”, used in the context of the invention, does not imply human intervention in the determination process: thus, the operations consisting in determining a quantity can be carried out automatically, ie without human intervention. According to another embodiment, the invention relates to a system for regulating the temperature and / or the brightness of a room integrated into a building, such as a veranda, equipped with one or more external, functional glazing. can be activated by electric current, divided by group (s) comprising:

- at least one probe configured to measure at least one physical quantity at the level of each group of glazing, the physical quantity being chosen from a surface temperature of the glazing, an electrical resistance of the glazing or a light intensity, or a combination of these ,

- at least one power supply box connected to each probe and configured to supply each glazing individually with electricity according to a current and / or a voltage that can be varied,

-a control unit connected to each power supply unit, so that the control unit receives the signals corresponding to the measurements carried out by the probe (s) connected to each power supply unit, and that it transmits electrical control signals to each electrical supply box as a function of the quantities measured by the probe (s) of the corresponding glazing and of an electrical power allocated to the regulation system.

Preferably, the regulation system further comprises a power determination means configured to determine an electrical power available on the electrical installation of the building, the control unit being connected to the power determination means, so that the control unit control receives the signals corresponding to the measurements carried out by the power determination means, the electrical power allocated to the regulation system being the available electrical power.

Advantageously, the regulation system according to the invention can be used on any type of configuration of glazing that can be activated by electric current without it being necessary to carry out a specific electrical installation or to configure the regulation system. This results from the control of the system by the control unit which distributes the electrical power available to each window as required. This distribution depends in particular on the electrical power available on the electrical installation of the room, the configuration of the glazing (in particular their number and their individual energy needs), as well as the needs in terms of heating or light shading. Thanks to the dynamic distribution of the electrical power, the regulation system can automatically adapt to a change in the configuration of the glazing. If, for example, a glazing had to be replaced by another glazing of different characteristics, it would not be necessary to modify the regulation system or to reconfigure it.

It is therefore not necessary to configure the control system according to the specificities of each installation: it is a universal control system.

In addition, the glazing is controlled on an individual basis: this makes it possible to optimize the regulation of the temperature and / or the brightness of a room. This is because the temperature inside the room may not be uniform, for example due to varying exposure to the sun. In this case, it may be preferable to activate the heating of the glazing to varying degrees depending on the position of the glazing in the room. This both optimizes the electrical power consumed and minimizes thermal gradients, and therefore improves thermal comfort.

Likewise, the external luminosity which passes through each window may depend on their orientation: it may then be preferable to activate the glazing of the glazing only on part of the glazing with variable shading, or to activate the shading with degrees. variable shading for the different glazing.

Independent control, glazing by glazing, is also advantageous in the event that one of the activatable glazing no longer works.

Preferably, the regulation system according to the invention can be powered both by alternating currents and by direct currents. Likewise, it can supply glazing both with alternating currents and with direct currents. In other words, the electrical sources available for the control system can be an alternating current source from the intrinsic electrical installation of the building and / or a direct current source from one or more renewable energies installed or adjacent to the building.

In particular, it is conceivable that the regulation system is connected both to an alternating current electrical distribution network connected to the building and to a local direct current electricity source directly connected to the regulation system, such as a set of photovoltaic panels mounted on the building or adjacent to it. Thus, according to an advantageous embodiment, the at least one power supply unit comprises an electronic circuit integrating two distinct electrical branches, an intelligent processor connected to each of the two branches, and an alternating current / direct current switch (AC / DC ) connected to the output of each of the two branches and to the processor, the input of one of the two branches being connected to an AC electrical distribution network while the input of the other of the two branches is connected to a source of local electricity in direct current, such as a set of photovoltaic panels, the AC / DC switch being connected to at least one group of glazing to supply it from the distribution network and / or from the source of local electricity according to the commands received by the processor.

According to this mode and a preferred variant embodiment, the branch connected to the local DC electricity source comprises a device for real-time monitoring of the maximum power point of the local electricity source connected to the intelligent processor. Such a device can be the one known by the Anglo-Saxon name "Maximum Power Point Tracking" (MPPT), or even MPP regulator or MPP tracker.

Advantageously, the intelligent processor of the power supply box is configured to supply electric power to the glazing group (s) according to the following conditions:

- if the temperature difference between a temperature setpoint previously determined by a user and the ambient air temperature is moderate, preferably a difference of less than 20% of the setpoint value expressed in degrees Celsius, and if the power provided by the local electricity source is sufficient, then the latter supplies all the glazing;

- if the temperature difference between the setpoint and the ambient air temperature is moderate and if the power supplied by the local electricity source is insufficient to supply all the glazing, then all of the power supplied by the source local electricity supplies one or more glazing and the power from the electrical distribution network supplies the other glazing (s);

- if the temperature difference between the setpoint, the ambient air temperature is high, preferably a difference greater than 20% of the setpoint value expressed in degrees Celsius, and if the power supplied by the electrical distribution network is sufficient to supply all the glazing, then the latter supplies all the glazing.

- if the temperature difference between the setpoint, the ambient air temperature is high, preferably a difference greater than 20% of the setpoint value expressed in degrees Celsius, and if the power supplied by the electrical distribution network is insufficient to supply all the glazing, then the power supplied by the local electricity source additionally supplies one or more glazing units;

- if no power is supplied by the local electricity source, then the power supplied by the electrical distribution network supplies all the glazing.

According to another of its aspects, the invention relates to a power supply unit comprising:

- an electronic circuit integrating two distinct electrical branches,

- an intelligent processor connected to each of the two branches, and

- an alternating current / direct current (AC / DC) switch connected to the output of each of the two branches and to the processor, the input of one of the two branches being intended to be connected to an AC electrical distribution network while that the input of the other of the two branches is intended to be connected to a local direct current (DC) electricity source, such as a set of photovoltaic panels, the AC / DC switch being intended to be connected to one or more current consumers, such as a group of glazing that can be activated by electric current, to supply them from the distribution network and / or from the local electricity source according to the commands received by the processor.

Advantageously, the regulation system is of the "plug and play" type, that is to say that it does not require any computer installation or manual setting to operate.

According to an advantageous embodiment, each power supply unit is connected to the control unit by wireless transmission, such as by Wifi or Bluetooth®.

Thus, no specific installation is necessary to carry out data transmission between the control unit and the power supply units. This also makes the control box easily movable, only an electrical wire connection being necessary for its correct operation.

Preferably, the regulation system further comprises one or more electrical connection assemblies each configured to electrically connect an opening receiving at least one of the panes and the supply box of said glazing when the opening is in the closed position and to disconnect them. when the sash is in any open position.

Power supplies can be configured to detect any disconnection of any of the electrical connection sets. A power supply unit detecting this disconnection is then capable of transmitting this information to the control unit: the latter can then control all of the power supply units so that the power supply to all the heated glazing is cut off. This makes it possible to cut off the heating if an opening to the outside is detected, which promotes efficient energy management.

Advantageously, the control system further comprises one or more temperature probes configured to measure ambient air temperatures inside the room and optionally a temperature probe for measuring an outside air temperature outside. room, the temperature probes being connected to the control box, so that the latter also receives the signals corresponding to the measurements made by the ambient air temperature probe (s) and, if applicable, the temperature d 'outside air, and that it also emits electrical control signals to each electrical supply box as a function of the temperatures measured by the ambient air temperature probes, of the temperatures measured by the outside air temperature probe where appropriate, and at least one temperature setpoint determined beforehand by a user.

These characteristics make it possible to improve the management of the thermal comfort of the room. Indeed, the regulation system can then take into account at least one interior and exterior temperature, if necessary, to control the heated glazing. Taking into account the outside temperature makes it possible to anticipate the thermal behavior of the room by adapting the type of management and regulation.

Advantageously, the regulation system comprises at least two temperature probes configured to measure the ambient air: this makes it possible to detect a possible temperature gradient of the interior air and consequently to determine which heated windows must be activated as a priority for ensure good thermal comfort, and in particular good homogeneity of the temperature of the interior air.

According to an advantageous characteristic, the control unit is configured to distribute the electric power available between several of the glazing units which are heated as a function of the available electric power, of the glazing temperatures, of the ambient air temperatures, optionally of a temperature of reference previously determined by a user and optionally an air temperature outside the room. Thanks to this characteristic, the thermal comfort of the room is further optimized. Advantageously, the control unit comprises an interface configured to allow a user to choose a reference temperature.

Preferably, a user can change the reference temperature, which is an indoor air temperature target, either by physical interaction with the control box or a separate interface connected to the control box, or through the intermediary of the control box. a smartphone application.

According to an advantageous embodiment, the system comprises one or more heated glazing and is configured to bring the surface temperature of at least one heated glazing to a temperature greater than or equal to a decontamination temperature for a period greater than or equal to a period. decontamination.

The decontamination temperature and the decontamination duration are chosen so as to allow the decontamination of the heated glazing under the effect of heat. The duration of decontamination depends in particular on the decontamination temperature. In the case of the SARS CoV-P9 coronavirus, the decontamination time can be 90 minutes for a decontamination temperature of 56 ° C, 60 minutes at 67 ° C or 30 minutes at 75 ° C: [2]

To ensure effective decontamination without limitation to a particular pathogen, the temperature and duration of decontamination can be 70 ° C and 45 minutes or even 80 ° C and 30 minutes.

By significantly increasing the surface temperature of a heated glazing for a limited period of time, the invention advantageously makes it possible to eliminate or render non-infectious pathogens present on the surface. This ensures decontamination of the glazing without having to regularly apply a disinfectant product to the glazing.

The heated glazing may be a heated laminated glazing, for example of the e-glas® 44-4 or 33-4 type. In this case, both sides of the glazing heat up. This is particularly advantageous for implementing a health protection device separating at least two people, for example in places open to the public or to a large number of people. The regulation system can in this case include a single glazing, for example a window protection partition, but the system can also include several glazings.

The heated glazing can also be a heated double glazing with a single heating face, for example of composition 6 XN / 16 argon / 6 k-glass®, 33-2 / 16 argon / 6 k- glass® or 4 XN / 16 argon / 44-4 e-glas®. This is particularly suitable for living rooms with large glass surfaces such as a veranda.

The heated glazing can also be a heated double glazing with two heating faces, for example of composition 44-4 e-glas® / 16 argon / 44-4 e-glass® or 6 k-glass® / 16 argon / 6 k- glass®. This is particularly suitable for premises comprising glazed partitions.

The invention also relates to a building, in particular a residential building, comprising a regulation system according to the invention, and the room of which is equipped with heated exterior glazing and / or with variable blackout.

According to an advantageous embodiment, the electrical installation of the building comprises a dedicated circuit breaker connected directly to the power supply boxes of the glazing. The invention also relates to a method for controlling a regulation system according to the invention, the room being equipped with at least internal or external heating glazing, the method comprising the steps of: a) allocating electrical power to the system ; b) determining a glazing surface temperature for each glazing in the room; c) determine at least one ambient air temperature inside the room; d) compare the ambient air temperature with a reference temperature; e) optionally, determine an outside air temperature outside the room, and compare the outside temperature to the ambient air temperature and to the reference temperature; f) if the ambient air temperature is lower than the reference temperature, determine the electric power to be applied to each heating glazing according to the allocated electric power, the ambient air temperature, the glazing temperatures and optionally d 'an orientation of the building.

It is advantageous to take into account the temperature of the indoor and / or outdoor air. For example, the temperature of the outside air in fact determines the temperature of the glazing before the heating is started. However, if the temperature of the glazing is low, the time necessary to bring the glazing to a temperature sufficient to produce adequate heating by radiation will be longer. The regulation system can therefore allocate more power and / or a longer heating glazing activation time to optimize the thermal comfort of the room as quickly as possible. According to another of its aspects, the invention relates to a method for controlling a regulation system according to the invention, the room being equipped with interior or exterior glazing with variable shading, the method comprising the steps consisting in: al) allocate electrical power to the system; bl) determining a received light intensity for each glazing in the room; cl) determine the electrical power to be applied to each variable blackout glazing as a function of the light intensities and / or the available electrical power.

Finally, the invention relates to a use of the regulation system according to the invention, the room being equipped at least with heated external glazing, for the emission of an anti-intrusion alarm in the event of a variation in the electrical resistance of at least minus one of the heated windows.

Indeed, the regulation system can continuously measure the characteristics of the glazing, in particular their electrical resistance. If one of the glazing thus monitored is damaged or even broken, the electrical resistance of this glazing would undergo a sudden variation that the control system can detect in order to trigger an anti-intrusion alarm.

The invention also relates to a method for controlling a system according to the invention, comprising the steps of: a2) determining a glazing surface temperature of one or more heated glazing units; b2) comparing the surface temperature with a decontamination temperature; c2) if the surface temperature is lower than the decontamination temperature, apply electrical power to the heated glazing until the surface temperature exceeds the decontamination temperature; d2) maintaining a surface temperature greater than or equal to the decontamination temperature for a duration greater than or equal to a decontamination duration. Thus, in this operating mode, the system acts according to the values communicated by the probe measuring the surface temperature of the glazing.

Monitoring the surface temperature of the glazing makes it possible, on the one hand, to ensure the effectiveness of the heat treatment to obtain the desired effect of decontamination, and on the other hand to ensure that the surface temperature of the glazing does not exceed not an imposed limit. This is for example advantageous for ensuring compliance with normative constraints. This also makes it possible to choose a decontamination temperature according to the environment and / or the sanitary constraints imposed, that is to say an adaptable temperature, which is not definitively fixed during the installation of the glazing.

Also, depending on the constraints of the surrounding room, control can be carried out to minimize the duration of the related decontamination treatment. For example, in the case of glass partitions in a shared meeting office within a building, it may be advantageous to carry out the fastest possible processing to allow participants in successive meetings to occupy the room. as quickly as possible. In other words, it is possible to carry out a "booster" type control of the heated glazing (s).

Advantageously, the process can be triggered according to an operating time setpoint determined by a user.

Depending on the objective pursued when starting the decontamination process, the decontamination temperature and the decontamination time may vary. Advantageously, the decontamination process can be triggered in a unique manner by a user either immediately or at a time determined by the latter, or even triggered recurrently according to a schedule and times determined by G user.

Brief description of the drawings

[Fig 1] Figure 1 shows a perspective view of a veranda equipped with a regulation system according to the invention.

[Fig 2] Figure 2 is a detail view of part of a control system according to the invention.

[Fig 3] Figure 3 illustrates another aspect of a control system according to the invention.

[Fig 4] Figure 4 is a block diagram of a power supply box according to the invention in the most complex and efficient form for electrically supplying a control system according to the invention.

[Fig 5] Figure 5 is a graph showing the change in the surface temperature of a glazing during the activation of a method according to the invention according to different configurations.

[Fig 6] Figure 6 is a graph showing the change in the surface temperature of a glazing during the activation of a method according to the invention.

detailed description There is illustrated in Figure 1 a veranda 1 equipped with a temperature and / or brightness regulation system according to the invention. The veranda 1 comprises a plurality of glazing 3 which can be activated by electric current.

Each glazing 3 is individually powered by an electrical supply box 5, as shown in Figure 2.

In the illustrated embodiment, each power supply box 5 electrically supplies two glazing 3 by a separate electrical connection for each glazing. Depending on the constraints of integrating the power supply units into the room, a single power supply unit could also power a single glazing, or three or more glazing units. When the glazing 3 is carried by an opening of a joinery, for example are sliding, the regulation system comprises for each glazing 3, an electrical connection assembly 7.

Each electrical connection assembly 7 is configured to electrically connect a glazing 3 to the power supply box 5 which supplies it, when the sash carrying the glazing 3 is in the closed position. On the contrary, when the sash is in the open position, that is to say in any position other than closed, the connection assembly 7 is configured to electrically disconnect the glazing from its power supply box. This advantageously makes it possible to cut off the power supply to a glazing, in particular a heated glazing, when an opening of the sash is made.

FIG. 2 also illustrates two temperature probes 9 each configured to measure a surface temperature of a given glazing 3. Each probe is connected to a power supply unit 5 via an electrical connection assembly 7, in order to transmitting the temperature measurements to the control unit 11, shown in FIG. 3. As illustrated in FIG. 3, the connection between the power supply units 5 and the control unit 11 is of the wireless type. Data transmission between the power supply units and the control unit then advantageously does not require any physical installation. In addition to simplifying the installation of the control system, it also allows the location of the control box in the conservatory to be changed without significant constraints.

The regulation system can include one or more interior temperature sensors 15 to improve the management of the thermal comfort of the room. The control unit 11 is configured to determine the electrical power available on the electrical installation of the room. Using this information and the data recorded by the surface temperature probes 9 and the interior temperature probe 15, the control unit 11 can manage the activation of the glazing to optimally regulate thermal and / or light comfort. of the local. Preferably, the regulation system comprises at least two internal temperature probes 15, for example located at two opposite ends of the room. This makes it possible to measure a possible temperature gradient of the air inside the room and, using this information, to optimize the heating of the room.

So, if for example one side of the room is exposed to the sun and another side is in the shade, there may be one or more significant temperature differences within the room. In this case, on the basis of the information obtained by the temperature sensors, the control box can automatically determine that the heated glazing installed on the coldest side of the room have priority in the allocation of the available electrical power. To facilitate the control of the regulation system by a user, a man-machine interface device such as the touch screen 13 can be provided. In the example illustrated, this device 13 is integrated into the control unit 11.

The regulation system comprises a power determination means 19 which is connected to the electric meter 17 of the electrical installation of the room. The means 19 is in the embodiment shown a box connected to the control box 11 by a wireless connection. Alternatively, the power determination means 19 could also be integrated into the control unit.

The power determination means 19 dialogues with the electric meter 17 in order to determine the electric power available at a given instant. The control of the glazing by the control unit 11 takes this information into account in order to use and distribute the available electrical power as best as possible.

The regulation system according to the invention can use in addition to or instead of the alternating current source (AC) 6 of the intrinsic electrical installation of the building, a direct current source (DC) 8 coming from one or more energies. renewables installed or adjacent to the building.

The block diagram of FIG. 4 represents a power supply unit 5 according to an advantageous embodiment of the invention which makes it possible to mix these two sources for the power supply of the heating glazing of the system. The box 5 firstly comprises an electronic circuit incorporating two distinct electrical branches 20, 21, an intelligent processor 22 connected to each of the two branches, and an alternating current / direct current (AC / DC) switch 23 connected to the output of each of the two branches 20, 21 and to the processor 22.

The input of branch 20 is connected to an alternating current electrical distribution network 6 while the input of branch 21 is connected to a local direct current electricity source 8, such as a set of photovoltaic panels. mounted on the roof of the building or one or more wind turbines mounted on the roof of the building.

The AC / DC switch 23 is connected to the heated windows.

Thus, the regulation system according to the invention can supply the heated glazing from the distribution network and / or from the local electricity source according to the commands received by the intelligent processor 22 of the box 5.

The branch 20 may comprise in series one or more electrical protection filters 24, electrical safety means 25 and a specific control 26. The filters 24 preferably comprise a set of electronic components making it possible to provide electrical protection of the electrical installation. downstream, in particular by the use of fuses, and electromagnetic protection. The security means 25 can include galvanic isolation. Preferably, the control 26 is static: this advantageously makes it possible not to generate noise pollution.

The branch 21 may comprise in series electrical safety means 27, one or more device 28 for measuring the DC current and a device 29 for real-time monitoring of the maximum power point of the local electricity source connected to the intelligent processor 22. , known under the Anglo-Saxon name "Maximum Power Point Tracking (MPPT)". The electrical safety means 27 advantageously make it possible to limit the voltage of the direct current, for example to a value of 45 V. The use of a low voltage current makes it possible in particular to minimize energy losses.

The measuring devices 28 notably measure the voltage and the intensity of the current taken from the local electricity source. Preferably, they are connected to probes arranged on the local electricity source to also measure other parameters such as a temperature of solar panels if the local source is constituted by solar panels or an alternator frequency if the local source is wind turbines. Measuring the temperature of solar panels is useful in determining the maximum point of power. Advantageously, the comparison between an expected value of the power of a set of solar panels at the maximum power point and a measured value of the power at the maximum power point makes it possible to inform a user that the efficiency of the solar panels is less than the expected value. This is the case, for example, when the transparency of the surfaces of solar panels is affected by external elements such as dust.

FIG. 5 represents the change in the surface temperature of a heated glazing during the implementation of a method for decontaminating the glazing. The three curves illustrate three configurations which differ by the initial temperature of the glazing.

First, the surface temperature of the glazing is lower than the decontamination temperature T _cv . The regulation system then applies electrical power to the glazing until the surface temperature of the latter exceeds T _cv .

The regulation system then maintains the surface temperature of the glazing above Tcv for a period greater than or equal to the decontamination period T _tv .

The surface temperature of the glazing then drops freely.

FIG. 6 illustrates more precisely the change in the surface temperature of a heated glazing during the implementation of a method for decontaminating the glazing.

The surface temperature of the glazing is controlled so as to remain constantly greater than a value T _minreg which is itself greater than the decontamination temperature Tcv for a period Tréeireg greater than the decontamination duration T _tv .

T _minreg and T _réeireg are chosen so as to create a safety margin and thus guarantee the application of the minimum decontamination temperature at any point on the surface to be treated.

The decontamination time T _{tv as} well as the Tréeireg time do not depend on the ambient temperature or other variables such as the supply voltage or the characteristics of the glazing.

The invention is not limited to the examples which have just been described; characteristics of the examples illustrated can in particular be combined with one another within variants not illustrated.

Other variations and improvements can be envisioned without departing from the scope of the invention.

List of references cited [1] Kampf G, Todt D, Pfaender S, Steinmann E. Persistence of coronaviruses on inanimate surfaces and their inactivation with biocidal agents [published correction appears in J Hosp Infect. 2020 Jun 8 ;:]. J Hosp Infect. 2020; 104 (3): 246-251. doi: 10.1016 / d.jhin.2020.01.022

[2] Duan SM, Zhao XS, Wen RF, et al. Stability of SARS coronavirus in human specimens and environment and its sensitivity to heating and UV irradiation. Biomed Environ Sci.

2003; 16 (3): 246-255.

Claims

Claims

1. Temperature and / or opacity regulation system of one or more functional glazing (3), activated by electric current, divided (s) by group (s) comprising:

- at least one probe (9) configured to measure at least one physical quantity at the level of each group of glazing, the physical quantity being chosen from a surface temperature of the glazing, an electrical resistance of the glazing or a light intensity, or a combination of these,

- at least one power supply box (5) connected to each probe and configured to supply each glazing unit with power individually according to a current and / or a voltage that can be varied,

-a control unit (11) connected to each power supply unit (5), so that the control unit receives the signals corresponding to the measurements carried out by the probe (s) connected to each unit d power supply, and that it emits electrical control signals to each electrical supply box as a function of the quantities measured by the probe (s) of the corresponding glazing and of an electrical power allocated to the regulation system.

2. System according to claim 1, further comprising a power determination means (19) configured to determine an electrical power available on an electrical installation connected to the system, the control unit being connected to the power determination means, so that the control unit receives the signals corresponding to the measurements carried out by the power determination means, the electrical power allocated to the regulation system being the available electrical power.

3. System according to one of the preceding claims, each power supply unit being connected to the control unit by wireless transmission, such as by Wifi or Bluetooth®.

4. System according to one of the preceding claims, further comprising one or more electrical connection sets each configured to electrically connect an opening receiving at least one of the glazing and the power supply of said glazing when the opening is in the closed position. and to disconnect them when the sash is in any open position.

5. System according to one of the preceding claims configured to regulate the temperature and / or the brightness of a room, the system further comprising one or more temperature probes (15) configured to measure ambient air temperatures at l. 'inside the room and optionally a temperature probe for measuring an outside air temperature outside the room, the temperature probes being connected to the control box so that the control box also receives the signals corresponding to the measurements carried out by the ambient air temperature sensor (s) and, if applicable, the outside air temperature, and that it also sends electrical control signals to each electrical supply unit as a function of the temperatures measured by the ambient air temperature probes, temperatures measured by the outside air temperature probe, if applicable, and at least one previously determined temperature setpoint created by a user.

6. System according to one of the preceding claims configured to regulate the temperature and / or the brightness of a room, the control unit being configured to distribute the electric power available between several of the glazings which are heated as a function of the electric power. available, glazing temperatures, optionally ambient air temperatures, optionally a reference temperature previously determined by a user and optionally an air temperature outside the room.

7. System according to one of the preceding claims, the control unit comprising an interface configured to allow a user to choose a reference temperature.

8. System according to one of the preceding claims, the at least one power supply unit comprising an electronic circuit incorporating two distinct electrical branches (20, 21), an intelligent processor (22) connected to each of the two branches, and a alternating current / direct current (AC / DC) switch (23) connected to the output of each of the two branches and to the processor, the input of one of the two branches being connected to an AC power distribution network (6) while the input of the other of the two branches is connected to a local direct current electricity source (8), such as a set of photovoltaic panels, the AC / DC switch being connected to at least one group of glazing to supply it from the distribution network and / or from the local electricity source according to the commands received by the processor.

9. The system of claim 8, the branch connected to the local DC power source comprising a device (29) for real-time monitoring of the maximum power point of the local power source connected to the intelligent processor.

10. System according to claim 8 or 9, the intelligent processor of the power supply unit being configured to supply electric power to the glazing group (s) according to the following conditions:

- if the temperature difference between a temperature setpoint previously determined by a user and the ambient air temperature is moderate, preferably a difference of less than 20% of the setpoint value expressed in degrees Celsius, and if the power provided by the local electricity source is sufficient, then the latter supplies all the glazing;

- if the temperature difference between the setpoint and the ambient air temperature is moderate and if the power supplied by the local electricity source is insufficient to supply all the glazing, then all of the power supplied by the source local electricity supplies one or more glazing and the power from the electrical distribution network supplies the other glazing (s);

- if the temperature difference between the setpoint, the ambient air temperature is high, preferably a difference greater than 20% of the setpoint value expressed in degrees Celsius, and if the power supplied by the electrical distribution network is sufficient to supply all the glazing, then the latter supplies all the glazing;

- if the temperature difference between the setpoint, the ambient air temperature is high, preferably a difference greater than 20% of the setpoint value expressed in degrees Celsius, and if the power supplied by the electrical distribution network is insufficient to supply all the glazing, then the power supplied by the local electricity source supplies one or more glazing units in addition;

- if no power is supplied by the local electricity source, then the power supplied by the electrical distribution network supplies all the glazing.

11. System according to one of the preceding claims comprising one or more heated glazing, the system being configured to bring the surface temperature of at least one heated glazing to a temperature greater than or equal to a decontamination temperature for a period greater than or equal. to a decontamination period.

12. Building, in particular residential, comprising a system according to one of the preceding claims, and the room of which is equipped with heated interior or exterior glazing and / or variable blackout.

13. Building according to claim 12, the electrical installation of which comprises a dedicated circuit breaker connected directly to the power supply boxes of the glazing.

14. A method of controlling a system according to one of claims 5 to 9 configured to regulate the temperature of a room, the room being equipped with at least internal or external heating glazing, the method comprising the steps of: a ) allocate electrical power to the system; b) determining a glazing surface temperature for each glazing in the room; c) determine at least one ambient temperature inside the room; d) compare the ambient air temperature with a reference temperature; e) optionally, determine an outside air temperature outside the room, and compare the outside temperature to the ambient air temperature and to the reference temperature; f) if the ambient air temperature is lower than the reference temperature, determine the electric power to be applied to each heated glazing according to the allocated electric power, the ambient air temperature, the glazing temperatures, optionally of the outside air temperature and optionally a building orientation.

15. A method of controlling a system according to one of claims 5 to 9 configured to regulate the brightness of a room, the room being equipped with interior or exterior glazing with variable shading, the method comprising the steps of: al ) allocate electrical power to the system; bl) determining a received light intensity for each glazing in the room; cl) determine the electrical power to be applied to each variable blackout glazing as a function of the light intensities and / or, where appropriate, of the allocated electrical power.

16. A method of controlling a system according to claim 11, comprising the steps of: a2) determining a glazing surface temperature of one or more heated glazing units; b2) comparing the surface temperature with a decontamination temperature; c2) if the surface temperature is lower than the decontamination temperature, apply electrical power to the heated glazing until the surface temperature exceeds the decontamination temperature; d2) maintaining a surface temperature greater than or equal to the decontamination temperature for a duration greater than or equal to a decontamination duration.

17. Use of a system according to one of claims 1 to 7, the room being equipped at least with heated external glazing, for the emission of an anti-intrusion alarm in the event of a variation in the electrical resistance of at least one. minus one of the heated windows.