FR2954662A1 - Autonomous induction removable heating plate for use in cooking assembly for e.g. domestic use, has communication units assuring communication of data with another plate to allow heating plates for exchanging information - Google Patents

Abstract

The plate (1) has inter-burner communication units (17b, 17d, 17g, 17h) i.e. position sensors, assuring wireless bidirectional communication of data with another autonomous induction heating plate (2) to allow the heating plate for exchanging information such as operating states, identifier, positioning of the communication units, cooking setpoints and operating state, between the heating plates. A user interface module defines the cooking setpoints by a user, where the user interface module displays the operating states to the user. An independent claim is also included for a cooking assembly comprising a distribution electric platform intended to provide electric power to each heating plate.

Description

The invention is in the field of induction hobs. More particularly, the invention is in the field of so-called "autonomous" induction foci.

In what follows, it will be understood by the term "independent induction cooking hearth", an induction cooking device consisting of a transportable and easily movable monoblock base, which base allows by induction the heating of a cooking vessel provided for this purpose.

As a reminder, induction heating consists in generating so-called "eddy currents" in an electrically conductive part by means of a magnetic field. The magnetic field is generated by an inductor, adapted to the area of the room to be heated, and which is generally traversed by an alternating current. The alternating current is itself produced by a generator, controlled by a control unit which adjusts the frequency and amplitude of the current to ensure the desired heating. In the case of induction cooking, the object to be heated is an electrically conductive container. Although the invention described below can be applied to non-magnetic materials of copper or aluminum type, we will focus more particularly on the heating of magnetic materials (mild steel, cast iron, magnetic stainless steel). The container generally has a diameter of between 120 and 280 mm and a thickness of between 1 and 4 mm for consumer applications. The diameters can reach 450 mm and the thickness 10 mm for professional applications. With reference to FIG. 1, an independent induction cooking furnace according to the state of the art comprises a base body 60 preferably of parallelepipedal geometry comprising, at its upper face, a receiving surface 600 intended to support an induction cooking vessel (such as a pan or pan comprising magnetic interaction means) disposed on said receiving surface 600.

Generally, such an independent induction cooking furnace has dimensions of between 150 and 300 mm for domestic use and 500 mm for professional use. Such an independent induction cooking furnace comprises means for generating a magnetic field located inside the base body 60 and delivering a generally alternating magnetic field to the receptacle disposed on the receiving surface 600. magnetic field generation is powered by electric current from a source generally connected to the home mains network via a power supply cable 61 provided with a branch plug. Generally the receiving surface 600 comprises a marking 604 for optimum centering of the container on the surface to ensure optimum magnetic interaction between the generated magnetic field and the container.

In addition, this independent induction cooking furnace 6 comprises interface means with the user generally comprising: - input means of a cooking instruction, for example using a rotary knob 601, and a display screen 602 for displaying, to the user, operating states, typically the cooking level corresponding to the set point and / or any reference to an anomaly (for example the fact that the hearth operates "empty", that is to say without a container placed on it, or a warning code to indicate for example that the receiving surface 600 is at a temperature that can cause burns in case of contact with the skin) . The receiving surface 600 is generally ceramic or glass or any other material allowing the passage of the magnetic field therethrough. This independent induction cooking stove according to the state of the art advantageously allows to benefit from induction cooking without having a whole stove. Thus, not only is this device easily movable on a worktop by a user (eg a cook) but it is also possible to seat several cooking stoves of this type on the worktop with a specific positioning for every home. However, one of the drawbacks when using a plurality of autonomous fireplaces is that the access to the user interface of a fireplace can be prevented by the other fireplaces according to the arrangement of the assembly. In addition, access to the input means of a cooking instruction can force the user to bring his arm of cooking receptacles placed on other homes, which can cause the risk of burning. Also known from the state of the art induction hobs arranged on a stove which usually includes an additional oven. Such a stove has the advantage of having a plurality of induction cooking hob whose control is brought to the front of the range, that is to say at the user. Thus, the user can control the plurality of fireplaces arranged on the stove from a single control location, thus avoiding difficult access to the various control means. However, a disadvantage of such a range is that it is difficult to move, especially because of the weight it can represent. In addition, it requires the user to buy a fixed number of induction cookers while the latter may not be beneficial to the use of all homes. Finally, the positioning of each home is fixed and they can not be moved relative to each other. Thus, an object of the present invention is to provide an independent induction cooking furnace for solving the aforementioned problems. More particularly, an object of the present invention is to provide a self-contained induction cooking furnace for having a plurality of displaceable induction furnaces and having access to a control and / or control interface is facilitated for the user. More particularly, an object of the present invention is to provide a cooking assembly comprising a plurality of induction cooking stoves allowing modularity in number and positioning of each home. To this end, the invention relates to a self-contained induction cooking hearth, characterized in that it comprises at least one inter-furnace communication unit able to ensure bidirectional data communication with at least one other induction cooking furnace. autonomous, the homes can thus exchange information of the type of cooking instructions and / or operating conditions. Thus, the user can easily have a cooking assembly composed of several independent induction cooking hobs according to the invention capable of communicating with each other and thus making it possible to have a set of self-contained hearths that can be modulated in number and positioning, each home being remotely controllable from another home.

Advantageously, but optionally, the invention comprises at least one of the following features: the inter-focus communication unit provides wireless bidirectional communication; the focus further comprises a user interface module for the definition of instructions for cooking by a user and the display of operating states intended for the user, • the fireplace comprises a control unit configured to ensure the sending by the inter-fireplace communication unit to the another focus, cooking setpoints defined via the interface module, and receiving at least one operating state from the other home for a display of this operating state by the interface module, • the home comprises a base body on the periphery of which are distributed position sensors able to communicate with position sensors of another household, the control unit being further configured In order to determine the relative position of the hearth vis-à-vis the other fireplace on the basis of the information provided by the position sensors, each position sensor has a transmission / reception range of approximately 90 °. in use, the inter-home communication unit transmits and receives at least one of the following information: o an identifier relating to a focus, o a positioning of a communication unit around the perimeter of the basic body of a fireplace, o a cooking instruction, o an operating state of a fireplace, • the interface module comprises a touch screen connected to the control unit, • the fireplace comprises a supply means comprising at least one receiver adapted to receive a flow of energy, the hearth comprises a wireless electric power transmission means. The invention also relates to a cooking assembly comprising a plurality of cooking heaters according to one of the preceding claims. Advantageously but optionally, the set of fireplaces includes an electrical distribution platform intended to supply electrical energy to each cooking zone. Advantageously but optionally, the power distribution platform is also configured to provide bidirectional data communication between homes.

Other features, objects and advantages of the present invention will appear on reading the detailed description which follows, with reference to the appended figures given by way of non-limiting examples and in which: - Figure 1 schematically shows a focus Figure 2 is an exploded view of an inductive induction cooking zone according to a possible embodiment of the present invention, and Figure 3 is a diagrammatic representation of the present invention. of the induction furnace according to FIG. 2 seen from the front, FIG. 4 represents the independent induction cooking furnace of FIG. 2 in a view from above, FIGS. 5A and 5B are representations of a cooking assembly. according to a possible embodiment of the present invention, - Figures 6A and 6B are schematic representations of another possible embodiment of a cooking assembly according to the invention. Referring to FIGS. 2, 3 and 4, and in a possible embodiment of the present invention, an independent induction cooking hearth 1 comprises a base body 10. This base body 10 preferably has a truncated cone shape but can be of any other geometric form. This base body 10 comprises at a lower level a support plate 101 intended to be in contact with the work surface 20 on which the free-standing cooking stove 1 is arranged. This support plate 101 advantageously comprises support pads 1010 allowing better adhesion between the independent cooking stove 1 and the worktop on which it is arranged. The base body 10 also includes an upper receiving surface 100 for receiving a cooking vessel R on its surface. This receiving surface 100 is preferably made of ceramic material but may be of any other material making it possible, on the one hand, to let the magnetic field pass in the direction of the cooking receptacle placed on the receiving surface, and on the other hand to avoid any electrical field leaving outside the base body 10. Preferably, the receiving surface 100 comprises a marking 104 at its surface allowing a centering of the container R on the receiving surface 100.

Between the support plate 101 and the receiving surface 100 is arranged an inductor 12 for the creation of a magnetic field to the container R placed on the receiving surface 100. This inductor consists of a wound conductor 120. However, the inductor 12 may consist of any other element known from the state of the art. The base body 10 also comprises a generator 14 associated with the inductor 12 and intended to adjust the electrical power supplied to the inductor 12. Preferably, the generator 14 is placed under the inductor 12 and consists of an electronics power unit for controlling an electrical source for controlling the electric power supplied to the inductor 12. The base body also comprises a control unit 16 for the control of the generator. This control unit 16 is preferably placed under or next to the generator and makes it possible to send control signals to the power electronics of the generator for controlling the electric power supplied to the inductor 12. Such a set inductor, generator and control unit, is known from the state of the art and can be realized in any other form of the skilled person; it will not be more detailed later.

The independent induction cooking hearth 1 also comprises a power supply means 15, for example in the form of an electric cable, intended to be connected to an electrical network (domestic or professional). This supply means 15 makes it possible to supply electrical energy to the generator 14 which, via its power electronics, makes it possible to regulate the electrical power supplied to the inductor 12 from the control signals supplied by the control unit 16. The independent induction cooking hearth 1 also comprises inter-fireplace communication units and positioning units operatively coupled with the control unit 16 respectively for providing the following functionalities: on the one hand, the units inter-furnace communication are able to provide a two-way communication of data with at least one other independent induction cooking furnace, the hearths thus being able to exchange between them information of the type of cooking instructions and / or operating states (thus, control unit 16 ensures the sending by communication units 17d, 17g, 17h and 17b to another foye r cooking instructions, and receiving at least one operating state of the other home for a display of this operating state by the interface module). on the other hand, the positioning units act as position sensors able to communicate with position sensors of another hearth, the control unit 16 being further configured to determine the relative positioning of the hearth with respect to screw the other focus on the basis of the information provided by the position sensors.

Thus, it is possible to be able to control a first home "remotely" from the interface module of another home with which the first focus is in communication. That is, it is possible for a user to be able to provide a setpoint to the first home via the interface module of the other home. In addition, the first focus can send operating states to the user which will then be displayed on the interface module of the other home. These functions can also be provided by one and the same element. Thus the focus 1 may comprise a plurality of communication and positioning units 17d, 17g, 17h and 17b regularly distributed around the periphery of the base body, and more specifically the support plate 101 on which they are arranged. These communication and positioning units are connected to the control unit 16. With reference to FIG. 4, the communication and positioning units 17d, 17g, 17h and 17b are distributed in such a way that the communication unit and positioning 17b is placed "in front", that is to say in the direction of the user. The communication and positioning unit 17h is diametrically opposed to the communication and positioning unit 17b. The communication and positioning units 17d and 17g are diametrically opposed and aligned perpendicularly to the communication and positioning units 17b and 17h so that the communication and positioning unit 17d is on the right and the 17g communication and positioning unit is found on the left. These communication and positioning units are of any type allowing two-way communication between two homes. Preferably, these communication and positioning units are transmission-reception units able to communicate wirelessly and more particularly, using infrared transmission (for example IrDA technology or "Infrared Data Association" in the English terminology). . The base body 10 also comprises an interface module 13, connected to the control unit 16 and preferably comprising a screen 130 whose display is controlled by the control unit 16 (for the display for example of an operating state) and a control means 131 enabling the user to define at least one cooking set point C. According to an advantageous embodiment of the present invention, the interface module 13 comprises a touch screen connected to the control unit 16, this touch screen incorporating the screen functions 130 and set input means 131. The interface module 13 is located on the periphery of the base body 10 as it is located opposite the user. According to another embodiment of the present invention, provision is made for the power supply means 15 to comprise a receiver 150 able to receive a "wireless" energy flow using, for example, "WiTricité" technology. Preferably, the independent induction cooking furnace then comprises four receivers 150b, 150h, 150g, 150d respectively associated with the communication and positioning units 17b, 17h, 17g and 17d and able to receive a flow of electrical energy transmitted by the airs. , that is to say "wireless". Thus, the cooking chamber can receive from one or more of its receivers an electric energy transmitted by the air, this electrical energy being used thereafter for the supply of the inductor 12 via the generator 14. Also , it may be provided according to a possible embodiment of the present invention that the cooking chamber comprises at least one wireless electrical energy transmission means 151 adapted to transmit to a remote receiver, a flow of energy through the air. Preferably, the self-inducing firing furnace comprises four wireless energy transmission means 151b, 151h, 151g and 151d respectively associated with the communication and positioning units 17b, 17h, 17g and 17d. Advantageously, each communication and positioning unit 17b, 17h, 17g and 17d has a data transmission and reception range S of about 90 ° centered on its normal N. With reference to FIGS. 5a and 5b, a cooking assembly comprises a plurality of cooking hobs 1, 2, 3 and 4, distributed in a possible arrangement. The cooking assembly also comprises a power distribution platform 5 (or "hub" in English terms), preferably centrally located with respect to the cooking assembly but which can be arranged at any other location. This electrical distribution platform 5 comprises an electrical energy input 50 connected to a domestic or professional electrical network, and four outlets 51, 52, 53 and 54 each connected to a cooking zone 1, 2, 3 and 4 allowing supply of electrical energy to each induction cooking stove.

The induction hobs of this set are distributed in such a way that the foci 1 and 2 are aligned in front of the user O, the foci 3 and 4 being aligned parallel to (and behind) the line formed by the foci 1 and 2. Thus, the foci 1, 2, 3 and 4 form substantially a square with each focus at a vertex of the square. Of course, any other arrangement is also possible and that presented in Figures 5a and 5b is given by way of example. For proper operation of the communication and positioning units between them, it is important that the cooking hobs are arranged relative to the user so that the communication and positioning units whose index is b (17b , 27b, 37b and 47b) are located "in front", that is, substantially facing the user.

Thus, from this arrangement, the cooking zone 1 can interact with its communication and positioning unit 17d with the communication and positioning unit 27g of the cooking zone 2 and with the unit. communication and positioning 37b of the cooking chamber 3. This communication allows the focus 1 to know on the one hand that the fireplace 2 is located on the right because it is in communication with the communication unit and positioning 27g, c that is to say the one located on the left of the hearth 2 and on the other hand that the hearth 3 is disposed offset backwards and to the right relative to the hearth 1 because it is in communication with the communication unit and positioning 37b.

Thus, the communication and positioning units 17d, 17g, 17h, 17b are also used as position sensors able to communicate with position sensors of another household, the control unit being further configured to determine the positioning relative to the other household based on the information provided by the position sensors. In the same way, the communication and positioning unit 17h is in communication with the communication and positioning unit 47b of the hearth 4 and 37g of the hearth 3, which makes it possible to know, on the one hand, that the hearth 4 is situated "behind The hearth 1 because the communication and positioning unit 17h is in communication with the communication and positioning unit 47b of the hearth 4 and the hearth 3 is located shifted behind and to the right of the hearth 1 because the Communication and positioning unit 17h is in communication with the communication and positioning unit 37g of the hearth 3. Thus, with the aid of the set of established connections, each home transmits to the homes with which it is in communication the relative positioning of other homes of which he has knowledge. Each control unit in each household is ultimately aware of the relative positioning of all households with respect to the user. Each communication and positioning unit of each home is confirmed to transmit at least one of the following information: an ID identifier making it possible to identify the home to which the transmitted information corresponds. Thus each household can transmit either information related to its own identifier, that is to say concerning him; information about another household at his disposal. The position P of the communication and positioning unit, ie whether the communication and positioning unit is a communication and positioning unit located at the bottom, top, right or on the left as described in Figure 4. This positioning corresponds to the relative positioning with respect to the user. 15 - The cooking instruction C linked to a focus. This cooking instruction is the cooking instruction given by the user to a given home. an operating state E which can take at least two possible forms: a feedback of information from a given focus. Generally this information corresponds to the state of cooking of the current hearth, particularly with respect to the cooking instruction given by the user, • an anomaly report A of a given focus. This abnormality report is intended to inform the user of a predetermined abnormal situation such as empty operation of the hearth. Thus, the control unit 16 (for example the focus 1) can ensure the sending by the communication and positioning units 17b, 17h, 17g and 17d, used as inter-home communication units, to another hearth (for example the hearth 4), cooking instructions defined via the interface module 13 of the hearth 1, and the reception of at least one operating state received from the hearth 4 for a display of this operating state by the interface module 13. With the help of this relative positioning of all the foci that the latter share among themselves, it is possible to know which foci are placed in front, that is, say those whose interface is accessible to the user O. In the example shown in FIGS. 5A and 5B, these are the foci 1 and 2. Thus, all the modules interfacing with the user of the all the fireplaces 1, 2, 3 and 4 are returned to at least one of the two interface modules located at most close to the user, that is to say the interface modules 13 and 23 respectively of the fireplaces 1 and 2. For example, according to a possible embodiment of the present invention, the control of the fireplace 4 can be reduced to the interface 13 of the hearth 1 and the control of the hearth 3 can be returned to the interface module of the hearth 2. According to another possible embodiment, all the controls of the hearths 3 and 4 can be brought exclusively to the hearth 1 or on the hearth 2. Thus the user, through interfaces modules 13 and 23 of the hearths 1 and 2, can control all the homes. Also, feedback from each household is returned to the interface level as close as possible to the user O. For example, assuming control of focus 4 is returned to the home interface 1, the user then has the possibility on the interface 1 to enter a cooking instruction for the hearth 1 or for the hearth 4. In the case where the user O chooses to enter a cooking instruction for the hearth 4, the control unit 16 of the hearth 1 stores this information and sends it to the hearth 4 via its communication and positioning unit 17h which communicates with the communication and positioning unit 47b of the hearth 4. control of the hearth 4 receiving this information command 30 then the generator associated with the inductor of the focus 4 to generate the associated magnetic field. The furnace 4 then sends the information return I for cooking to the furnace 1 (or the anomaly report A for example in the case where the furnace is running empty) to the furnace 1 via its communication and positioning unit 47b in communication with the communication and positioning unit 17h of the focus 1. Thus, the focus 1 can display the feedback of the focus 4 at its interface to the user O. The communication unit and positioning 17h providing the controls to the focus 4, the focus 3 at its interface 37g also receives them; however, using the identifier provided for each command transmitted by the focus 1, the focus 3 can then discern the commands that are to its destination or not. This example, given for illustrative purposes only, can be generalized to other provisions and for quite a different number of households in communication with one another. With reference to FIGS. 6A and 6B showing a cooking assembly comprising self-contained induction cooking hobs 1, 2, 3, 4 arranged in another possible arrangement, the hearth 1, 2 and 4 are arranged in front of (relative to O), substantially aligned. The hearth 3, meanwhile, is arranged behind, globally on the mediator of the fireplaces 2 and 4. In the same way as presented above, households communicating with each other using communication and positioning units, they know ultimately the relative positioning of the other homes with respect to the user. Thus, the hearth 4, knowing that the communication and positioning units 37b and 37d of the hearth 3, are in communication respectively with its communication and positioning units 47g and 47h can deduce that the hearth 3 is located behind and on the left (and therefore substantially diagonal) of the hearth 4. In another example, the hearth 1 is in communication with the hearth 2 through the communication and positioning units 17d and 27g, it is deduced that the foci 1 and 2 are aligned so that fireplace 1 is on the left and fireplace 2 on the right. From the positioning described above, it is possible for the user to choose for example to bring all the controls of the fireplaces 1, 2, 3 and 4 to the level of the single interface of the fireplace 4.

Thus, the user returning a setpoint to the focus 1 through the interface of the fireplace 4, the latter, through its control unit, sends via its communication unit and positioning 47g to the home 2 ( by its communication and positioning unit 27d) the information to the focus 1, the focus 2 then sends the information via the communication and positioning unit 27g to the focus 1 by the communication unit and 17d positioning. In the same way, following the opposite path, the focus 1 can return to the interface of the focus 4 all the information to the user. It can be expected that the platform 5 for the distribution of electrical energy to each of the hearths 1, 2, 3 and 4 comprises an additional function of inter-home communication, each home then transmitting the information to another focus via the platform 5. It can also be expected to connect the 17b communication units and 17b, 17h, 17g and 17d homes to the distribution platform 5 wired, arranging the son for the transmission of information between the platform and the hearth in the same sheath as that used for the feeding of the different feeding foci.

Alternatively, this inter-focus communication is carried out by carrier current transmitted by the power supply cables feeding the homes from the platform 5. According to another possible embodiment of the present invention, it is possible that only one of the homes, for example the one that is furthest back from the user O (in the case shown in Figure 6, it is the focus 3), or connected to the power source. The hearth 3 then supplies the other hearths via the electrical energy transmission means on air 351. Thus, in the case shown in FIGS. 6a and 6b, the hearth 3 supplies via the transmission means 351d and 351b the hearth 4 through the receiving means 450h and 450d and also feeds the firebox 2 by its transmission means 351b and 351g through the receiving means 250h and 250d of the firebox 2. The firebox 2 in turn supplies the firebox

Claims (13)

REVENDICATIONS1. Independent induction cooking hearth, characterized in that it comprises at least one inter-furnace communication unit (17d, 17g, 17h, 17b) capable of ensuring bidirectional communication of data with at least one other induction cooking furnace autonomous, the homes can thus exchange information of the type of cooking instructions and / or operating conditions. The cooking hearth according to claim 1, wherein the inter-focus communication unit (17d, 17g, 17h, 17b) provides bidirectional wireless communication. 3. Cooking hearth according to one of claims 1 or 2, which further comprises a user interface module (13) for the definition of cooking instructions by a user and the display of operating states to the user. 4. Cooking hearth according to one of the preceding claims, which comprises a control unit (16) configured to ensure the sending by the inter-home communication unit (17d, 17g, 17h, 17b), to the other focus, cooking setpoints defined via the interface module (13), and receiving at least one operating state from the other home for a display of this operating state by the interface module (13). 5. Cooking hearth according to one of the preceding claims, which comprises a base body (10) on the periphery of which are distributed position sensors (17d, 17g, 17h, 17b) adapted to communicate with position sensors d another focus, the control unit being further configured to determine the relative positioning of the focus with respect to the other focus based on the information provided by the position sensors (17d, 17g, 17h, 17b ). 6. Induction cooking hearth according to one of the preceding claims, wherein each position sensor (17d, 17g, 17h, 17b) has a transmission / reception range of about 90 °. Induction cooking hearth according to one of the preceding claims, wherein, in use, the inter-focus communication unit (17d, 17g, 17h, 17b) transmits and receives at least one of the following information: an identifier relative to a focus (ID), a positioning (P) of a communication unit on the periphery of the base body (10) of a focus, a cooking instruction (C), a state operating (I, A) of a fireplace, 8. induction cooking hearth according to one of the preceding claims, wherein the interface module (13) comprises a touch screen (130, 131) connected to the control unit (16). 9. induction cooking hearth according to one of the preceding claims, which comprises a supply means (15) comprising at least one receiver (150) adapted to receive a flow of energy. An induction cooking hearth according to one of the preceding claims, which comprises a wireless electric power transmission means (151). 11. Cooking assembly (E) comprising a plurality of cooking heaters (1, 2, 3, 4) according to one of the preceding claims. Cooking assembly (E) according to claim 11, which comprises an electrical distribution platform (5) for supplying electrical energy to each cooking zone (1, 2, 3, 4). 30 The cooking assembly (E) of claim 12, wherein the electrical distribution platform (5) is also configured to provide bidirectional data communication between the homes.