EP2811811A1 - Electrical system for managing electrical loads of a household appliance - Google Patents

Abstract

An electrical system for managing the electrical charges of a household appliance comprises a power module (10) comprising: - at least two control modules (11A, 11 B), each control module (11A, 11 B) controlling the operation of at least one electric load and being supplied by a phase (1, 2) of a network of electrical distribution, - an electrical power supply module (14) supplying said at least two control modules (11 A, 11 B) with electrical energy, and - Control means (12) configured to cut off the power supply to said at least two control modules (11 A, 11 B) when the household appliance is in standby state. Use in an induction hob.

Description

The present invention relates to an electrical system for managing the electrical charges of a household appliance.

It also relates to a household appliance, including an induction cooktop, comprising such a system for managing electrical charges.

In general, a household appliance such as an induction hob comprises a plurality of power modules, each power module controlling the operation of at least one electric load, such as an inductor. Each power module is powered by a phase of an electrical distribution network and is connected to a user interface module by means of an exclusive link.

The power modules manage the operation of the electrical loads according to the actions performed by a user on the user interface modules.

Each power module comprises in particular an electric charge control module, a control module managing the operation of the power module and a power supply module supplying the various electrical circuits of the power module, in particular the control module and the module. control.

When the appliance enters the standby state (for example, when a user does not control the operation of the appliance for a certain time), the user interface modules remain energized to react to the manipulations of the appliance. user of the appliance.

Similarly, the power module control, power and control modules also remain powered to put the power module into operation when the user requests it.

Thus, the consumption of the appliance in standby state corresponds at least to the consumption of the power modules and the user interface modules, this energy consumption can be high, particularly in the case of a power table. cooking with a high number of inductors.

The object of the present invention is to propose an electrical system for managing the electrical charges of a household appliance, making it possible to reduce the electrical energy consumption of such a system when the appliance is in a standby state.

For this purpose, the present invention aims, in a first aspect, an electrical system for managing electrical charges of a household appliance.

• deux modules de commande, chaque module de puissance commandant le fonctionnement d'au moins une charge électrique et étant alimenté par une phase d'un réseau de distribution électrique,
• un module d'alimentation électrique alimentant en énergie électrique les modules de commande, et
• des moyens de contrôle configurés pour couper l'alimentation des deux modules de commande lorsque l'appareil électroménager est en état de veille.

According to the invention, the electrical management system comprises a power module comprising:

• two control modules, each power module controlling the operation of at least one electrical load and being powered by a phase of an electrical distribution network,
• a power supply module supplying electrical power to the control modules, and
• control means configured to turn off the power of the two control modules when the appliance is in a standby state.

Thus, the two control modules are turned off when the appliance is in a standby state, which reduces the consumption of the electrical management system and therefore the appliance.

In addition, thanks to the topology of the electrical management system, a power supply module is spared in relation to known topologies, which further reduces the electrical energy consumption of the electrical management system.

In practice, the power module comprises switching means arranged respectively between the phases and the control modules and being controlled by the control means, the means of control being configured to cut power to the control modules by means of the switching means.

Advantageously, the electrical management system comprises user interface modules connected together and to said power module by a communication bus.

The communication bus allows the power module and each user interface module to be aware of the data transmitted by each of these elements.

In addition, the communication bus provides flexible links between the user interface modules and the control modules. Thus, it is not necessary to exclusively associate a user interface module with a control module. With this topology, the same user interface module can be associated with several control modules.

• un module de commande commandant le fonctionnement d'au moins une charge électrique et étant alimenté par une phase d'un réseau de distribution électrique,
• un module d'alimentation électrique alimentant en énergie électrique ledit module de commande, et
• des moyens de contrôle configurés pour couper l'alimentation dudit module d'alimentation lorsque l'appareil électroménager est en état de veille.

According to one characteristic, the electrical management system further comprises at least one additional power module comprising:

• a control module controlling the operation of at least one electrical load and being powered by a phase of an electrical distribution network,
• a power supply module supplying electrical power to said control module, and
• control means configured to cut off power to said power supply module when the appliance is in a standby state.

Thus, when the appliance is in a standby state, the power supply module is de-energized and does not consume electrical energy.

With the power module turned off, the power module is not powered and does not consume electrical energy either.

Therefore, the consumption of the appliance in standby state is not incremented by the addition of additional electrical charges.

In practice, the additional power module comprises switching means arranged between the phase and the power supply module and being controlled by said control means, the control means being configured to cut off power to the power supply module. by means of switching means.

Advantageously, the control means of the additional power module are powered by a power signal from the power module of the power module.

Thus, although the power supply module in the additional power module is off, the control means remain available to respond to the manipulations of a user of the appliance.

In practice, the control means of the additional power module receive the supply signal via the communication bus.

The use of the communication bus to supply power to the control means of the additional power module makes it possible to reduce the number of conducting wires in the electrical management system.

Advantageously, the power module comprises second switching means controlled by the control means, the control means being configured to cut off the supply of the power supply module and control means of the additional power module by means of the second means. of commutation.

Thus, the second switching means are used to cut off the power supply of the control means of the additional power module.

With this feature, the control means of the additional power module are reset by themselves after a power failure.

Therefore, the reinitialization or reset of the additional power module control means by the control means of the power module is not necessary.

Thus, the communication between the power module and the additional power module via the communication bus is simplified.

The assembly of the electrical circuits in the electrical management system is thus simplified and the cost of the electrical management system is reduced.

According to a second aspect, the present invention also relates to an appliance, comprising a set of electrical charges.

According to the invention, the appliance comprises an electric electrical charge management system according to the invention.

The invention is particularly applicable to an induction hob comprising a set of inductors and an electrical system for managing electrical charges according to the invention, the electrical charges being the inductors.

This appliance has similar characteristics and advantages to those described above in connection with the electrical system for managing electrical charges.

Other features and advantages of the invention will become apparent in the description below.

• la figure 1 est un schéma représentant un système de gestion de charges électriques conforme à un mode de réalisation de l'invention.

In the only appended drawing, given by way of non-limiting example:

• the figure 1 is a diagram showing an electric charge management system according to an embodiment of the invention.

We will describe with reference to the figure 1 an electrical charge management system according to the invention.

For example, the electric charge management system can be used in an induction hob in which the electric charges are inductors, each inductor forming a cooking hearth.

Of course, the present invention is not limited to an induction hob but can be applied to any type of household appliance, and in particular another type of hob, a stove, a washing machine and / or or tumble dryer, dishwasher, oven.

The electrical charge management system represented at figure 1 comprises a power module 10 and an additional power module 20.

In the embodiment described, the power module 10 comprises two control modules 11 A, 11 B. Each module of control 11 A, 11 B is supplied by a phase 1, 2 of an electrical distribution network and comprises components of the power electronics necessary for controlling the operation of at least one electrical load (not shown in the figure) . These control modules are known to those skilled in the art and will not be described here.

Thus, for example in the case of an induction hob, the electrical charges can be inductors.

Each control module 11 A, 11 B controls the operation of at least one inductor.

In the case of an induction hob, each control module 11A, 11B generally controls the operation of two inductors, each inductor forming a cooking chamber.

Thus, for example, in an induction hob, the power module 10 controls and controls the operation of four inductors.

Of course, it is possible that a cooking hearth is formed by more than one inductor, for example a cooking hearth may be formed by two concentric inductors.

In another example, the power module 10 controls and controls the operation of three inductors, each inductor forming a cooking zone.

In another embodiment, the power module 10 has more than two control modules.

For example for an induction hob with six inductors forming respectively six hobs, the power module 10 has three control modules, each control module controlling the operation of two inductors.

In the embodiment described with reference to the figure 1 , the power module 10 comprises two control modules 11 A, 11 B.

The operation of a power module 10 comprising two switching modules 11 A, 11 B is similar to that of a power module comprising a greater number of control modules.

As described above, in another example (the one shown on the figure 1 ), an induction cooktop has a power module 10 and an additional power module 20, the power modules 10, 20 controlling and controlling a larger number of inductors, for example five or six inductors.

The power module 10 further comprises control means 12 configured to manage the operation of the power module 10. The control means 12 are for example a microcontroller 12.

The control means 12 control and control the operation of a power microcontroller 13. The power microcontroller 13 is a microcontroller dedicated solely to controlling the operation of the control modules 11A, 11B.

Thus, the execution by the power microcontroller 13 of the software controlling the control modules 11A, 11B do not interact on the execution of the software by the control means 12 and vice versa.

In another embodiment, the functions of the power microcontroller 13 and the control means 12 can be grouped together at the same microcontroller.

The power module 10 further comprises a power supply module 14 generating a low voltage internal power supply V from the power supply received from the phase 1 of the electrical distribution network.

This internal power supply V is used to power the various electrical circuits of the power module 10, in particular the control means 12, the power microcontroller 13 and the control modules 11 A, 11 B.

For example, the internal power supply V is a DC voltage of 5V or 12V.

In another example, the power supply module 14 generates more than one low-voltage internal power supply, for example DC voltages of 5V and 12V.

The voltage of the electrical distribution network or mains voltage has for example a value of 230 VRMS (325V peak value) for the French power grid.

Of course, the mains voltage may have different values, depending on the power grid of the country in which we are located.

The control modules 11A, 11B receive power from phase 1, 2 of the power distribution network.

Switching means 15A, 15B are arranged respectively between the phases 1, 2 and the control modules 11A, 11B.

In the embodiment described, the switching means 15A, 15B may have an open state in which the control modules 11A, 11B are not powered by the phases 1, 2 respectively, and a closed state in which the modules of FIG. control 11A, 11B are powered by phases 1, 2 respectively.

In one embodiment, the switching means 15A, 15B are power relays.

The control means 12 are configured to cut power to the power modules 11A, 11B by means of the switching means 15A, 15B when the appliance is in a standby state.

Thus, the control means 12 are configured to put the switching means 15A, 15B in the open state or the closed state.

The electrical management system further includes user interface modules 30A, 30B, 30C through which a user controls the operation of the appliance. In particular, in the case of an induction hob, the user can configure the power to be delivered by inductors forming cooking hobs.

The interface modules 30A, 30B, 30C are connected to each other and to the power module 10 via a communication bus 31.

Thus, when a user performs an action on one of the interface modules 30A, 30B, 30C, signals are generated and transmitted to the power module 10 through the communication bus 31.

An electric electrical charge management system comprising a power module 10 and at least one user interface module 30A, 30B, 30C can be used, for example, in an induction hob with four cooking hobs, each cooking zone. being generated by an inductor (representing an electric charge).

In one embodiment, when the management system manages additional electrical charges, it comprises at least one additional power module 20. For example, the electric charge management system shown in FIG. figure 1 comprises a power module 10 and a single additional power module 20.

Of course, the number of additional power modules could be higher.

In the embodiment described, the additional power module 20 comprises a control module 21 comprising the power electronics components for controlling the operation of at least one electrical load (of an inductor in the case of a table induction cooking).

As described below, in the case of an induction hob, a control module 21 generally manages two inductors.

Thus, the electrical management system represented at figure 1 can be used in an induction hob with six inductors, each inductor forming a cooking zone.

As indicated below, in another example, a cooking zone is formed by more than one inductor, for example two concentric inductors.

In other embodiments, the additional power module 20 may comprise a greater number of control modules 21.

The additional power module 20 further comprises control means 22 configured to manage the operation of the additional power module 20.

The operation of the control module 21 is controlled by a power microcontroller 23.

The additional power module 20 further comprises a power supply module 24 supplying electrical power to the control module 21 and the microcontroller 23.

It will be noted that the control means 22 are powered by a supply signal coming from the power supply module 14 of the power module 10.

The control module 21 is powered by a phase 3 of the electrical distribution network.

Switching means 25 are arranged between phase 3 and the control module 21.

The control module 21, the control means 22, the power microcontroller 23, the power supply module 24 and the switching means 25 of the additional power module 20 are respectively similar to the control modules 11A, 11B, module 12, microcontroller 13, power supply module 14 and switching means 15A, 15B of the power module 10.

The control means 22 are configured to cut off the supply of the power supply module 24 when the appliance is in the standby state. Thus, the control module 22 is configured to put the switching means 25 in an open state that does not allow the supply coming from phase 3 to go to the control module 21, or in a closed state allowing the supply coming from the phase 3 to the control module 21.

We will then describe the operation of an electrical management system like the one shown in figure 1 , in particular operation when the appliance is in a standby state.

In the case of an electrical management system comprising at least one additional power module 20, the power module 10 is considered as a master power module 10 and the at least one additional power module 20 as a slave power module 20.

Thus, in the remainder of the description, the power module 10 is called the master power module 10 and the additional power module 20 is called the slave power module 20.

When the appliance enters the standby state, for example when a predetermined period of time elapses without any operation of the appliance being requested by the user, the control modules 12, 22 the switching means 15A, 15B, 25 in the open state.

Thus, in the master power module 10, the control modules 11A, 11B are disconnected from the phases 1, 2 by means of the switching means 15A, 15B and are therefore de-energized.

The power supply module 14 remains in operation in order to supply power to the control module 12 of the master power module 10, the control module 22 of the slave power module 20, the power microcontroller 13 and the user interface modules. 30A, 30B, 30C.

The power microcontroller 13 is kept energized in a reset state or reset state in which the power microcontroller 13 is inactive. When the power microcontroller 13 is in this reset state, its consumption is substantially zero.

Of course, when the control means 12 and the power microcontroller 13 are implemented by the same microcontroller, the reset function of the power microcontroller 13 is not implemented.

The control means 12 are in the standby state in order to remain available for the reception of an alarm signal coming from the communication bus 31. The control means 12 leave the waking state when they receive a wake-up signal .

In the slave power module 20, the power supply module 24, the control module 21 and the power microcontroller 23 are disconnected from the phase 3 by means of the switching means 25 and are therefore de-energized.

As for the control means 12 of the master power module 10, the control means 22 of the slave power module 20 are in the standby state in order to remain available for receiving an alarm signal from the communication bus 31.

It will be noted that the control means 22 of the slave power module 20 are powered by a supply signal coming from the power supply module 14 of the master power module 10.

Thus, in the slave power module 20, only the control means 22 remain energized. The power supply module 24, the control module 21 and the power microcontroller 23 remain de-energized. The power consumption when the hob is in standby state is thus reduced compared to a conventional induction hob.

By way of non-limiting example, the standby power consumption for an induction hob with six cooking hobs comprising an electric charge management system according to the invention is about 400 mW. This power consumption value is significantly lower than the consumption of an equivalent induction hob but using a conventional electric charge management system, this hob having an electrical consumption of about 700mW.

The supply signal from the power supply module 14 of the master power module 10 is received by the slave power module 20 via the communication bus 31.

The power modules 10, 20 and the user interface modules 30A, 30B, 30C are interconnected by the communication bus 31.

In one embodiment, the communication bus 31 is of the mono-master multi-slave type. With this type of communication bus 31, the control means 12 of the master power module 10 are configured to manage the exchanges between the different power modules connected to the communication bus 31.

For example, the control means 12 control the operation of the second switching means 16 in the master power module 10 which controls the supply of all the electronic circuits connected to the communication bus 31.

In one embodiment, the second switching means 16 comprise a switch 16.

Thus, the control means 12 control the supply of the supply module 24 of the slave power module 20 by means of the switch 16.

In one embodiment, the control means 12 of the master power module 10 can cut off the power supply of the control means 22 of the slave power module by means of the switch 16.

In this embodiment, the elements of the slave power module 20, and in particular the control means 22 and the power microcontroller 23 of the slave power module 24 are reset after a power failure for a predetermined time.

It is thus avoided the control of the reset or reset of the elements of the slave power module 20 by the control means 12 of the master power module 10.

Of course, in another embodiment, reset signals may be generated by the control means 12 of the master power module 10 and sent to the slave power module 20 via the communication bus 31.

In one embodiment, the communication bus 31 has three lines, a first line corresponding to a supply signal, for example a DC voltage of 5V, a second line corresponding to the reference potential, and a third line corresponding to a communication line.

In another embodiment, the communication bus 31 comprises an additional line corresponding to a second supply signal, for example a DC voltage of 12V.

Through the use of such a communication bus 31, each of the power modules 10, 20 and user interface modules 30A, 30B, 30C is aware of the data transmitted by the other power modules.

In addition, it is not necessary to assign a user interface module to each control module 11A, 11B, 21 as in the prior art. Thanks to the electrical charge management system according to the invention, it is possible to produce, during the manufacture of the appliance, a single display module controlling several control modules 11 A, 11 B, 21.

When the appliance is in a standby state, the user interface modules 30A, 30B, 30C are in operation to receive and process user actions.

Thus, when the user performs an action on one of the user interface modules 30A, 30B, 30C, the user interface module 30A, 30B, 30C emits an alarm signal on the communication bus 31. This signal The alarm clock is received by the master power module 10 and the slave power module 20. The control means 12, 22 of the master and slave power modules 10, 20 come out of the standby state on receipt of this signal.

When the control means 12, 22 of the master and slave power modules 10, come out of the standby state, they control the closing of the switching means 15A, 15B, 25 of the master and slave power modules 10, respectively .

Thus, the modules which were de-energized are reconnected to the phases 1, 2, 3 and the control means 12 of the master power module 10 control the output of the reset state of the power microcontroller 13.

In addition, power supply of the power supply module 24 of the slave power module 20 is restored.

The appliance is thus ready for use.

The operation of an electrical charge management system comprising a single power module 10 is similar to that described for an electrical charge management system comprising a power module 10 and an additional power module 20 and can be understood from the above description.

Claims (11)

Electrical system for managing the electrical charges of a household appliance, characterized in that it comprises a power module (10) comprising: at least two control modules (11A, 11B), each control module (11A, 11B) controlling the operation of at least one electrical load and being powered by a phase (1, 2) of a control network; electrical distribution, - a power supply module (14) supplying electrical energy to said at least two control modules (11A, 11B), and - control means (12) configured to cut off the power of said at least two control modules (11A, 11B) when the appliance is in a standby state. Electrical management system according to claim 1, characterized in that the power module (10) has switching means (15A, 15B) respectively between the phases (1, 2) and the control modules (11A, 11B). ) and being controlled by the control means (12), the control means (12) being configured to cut the power of the control modules (11A, 11B) by means of said switching means (15A, 15B). Electrical management system according to one of claims 1 or 2, characterized in that it comprises user interface modules (30A, 30B, 30C) connected to each other and to said power module (10) via a bus of communication (31). Power management system according to any one of claims 1 to 3, characterized in that it further comprises at least one additional power unit (20) comprising: at least one control module (21) controlling the operation of at least one electrical load and being powered by a phase (3) of an electrical distribution network, - a power supply module (24) supplying electrical energy to said at least one control module (21), and - control means (22) configured to cut the power supply of said power supply module (24) when the appliance is in a standby state. Electrical management system according to claim 4, characterized in that the additional power module (20) has switching means (25) arranged between the phase (3) and the power supply module (24) and being controlled by said control means (22), the control means (22) being configured to cut power to the power supply module (24) by means of said switching means (25). Electrical management system according to claims 3 and 4 or 5, characterized in that the user interface modules (30A, 30B, 30C) are further connected to the additional power module (20) via said communication bus (31). ). Electrical management system according to one of claims 4 to 6, characterized in that the control means (22) of said additional power module (20) are powered by a power supply signal from said power supply module ( 14) of the power module (10). Electrical management system according to claim 7, characterized in that the control means (22) of said additional power module (20) receive the supply signal via said communication bus (31). Electrical management system according to one of Claims 4 to 8, characterized in that the power module (10) comprises second switching means (16) controlled by said control means (12), the control means ( 12) of the power module (10) being configured to cut power to the power supply module (24) and control means (22) of said additional power module (20) by means of said second switching means (16) . Domestic appliance, in particular a hob, comprising a set of electric charges, and characterized in that it comprises an electric electrical charge management system according to one of the preceding claims. Domestic appliance according to the preceding claim characterized in that the electrical charges are heating means, including inductors.

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