FR2966689A1 - METHOD FOR DETECTING CONTAINERS DISPOSED ON A COOKTOP AND COOKTOP. - Google Patents

Abstract

A method for detecting the use configuration of a hob (10) comprising heating means distributed in a two-dimensional grid under a hob, comprising an activation step implemented on subsets of means for detecting the presence of a container respectively associated with the heating means (12a, 12b, 12c, 12d), the detection means of each subset (12a, 12b, 12c, 12d) being non-adjacent. The activation step is repeated sequentially on said subsets of detection means (12a, 12b, 12c, 12d) until all of the heating means are at least partially covered by at least one container on the work plan is identified.

Description

The present invention relates to a method for detecting the configuration of use of a hob. It also relates to a hob adapted to implement the detection method according to the invention. It generally relates to a hob in which a container can be placed and heated at any location on a hob of this hob. This type of table comprises heating means arranged in a two-dimensional grid in the hob. Thus, this type of table does not have predefined cooking zones, as described in the document FR 2 863 039 in the name of the Applicant. The heating means are of a sufficiently small size that a conventional size cooking vessel covers a plurality of heating means. In this type of table, a cooking zone is formed case by case, depending on the position and size of the container placed on the hob. Thus, a cooking zone is constituted by a set of heating means covered at least partially by a container placed on the cooking surface. Only the heating means constituting a cooking zone associated with a detected container are activated for heating the container. Therefore, before and during the implementation of the heating of the containers, it is necessary to know the cooking zones present in the hob.

To know the cooking zones, it is necessary to know the configuration of use of the hob, that is to say all the heating means which are covered at least partially by a container, as well as the cooking rate. covering each heating means of this assembly with the container. For this purpose, in some hobs, the heating means are analyzed one by one sequentially. Thus, for each heating means, it is analyzed whether it is covered at least partially by a container placed on the work surface and its recovery rate is determined. This is also described in document FR 2 803 039. Running through the heating means one by one generates a high latency in the detection of the use configuration of the hob. This can cause for example the interruption of the boiling of a liquid in a pan, which can be inconvenient for the user of the hob. EP 2 034 799 discloses a hob in which the detection of the set of inductors covered by a container placed on the hob, is implemented by means of the activation of a subset d inductors, the inductors of the subset being non-adjacent. If it is detected that an inductor belonging to the subset is covered by a container, the inductors surrounding this inductor are then activated. Nevertheless, adjacent inductors activated simultaneously influence each other. Therefore, the recovery rate determined may be unstable over time and cause variations in the time of the heating power of a container for the same desired power demanded by a user of the hob. This can cause for example a variation in the boiling intensity of a liquid of a pan for the same desired power demand, which can be inconvenient for the user of the hob.

The present invention aims to solve the aforementioned drawbacks and to provide a method for detecting the configuration of use of a hob to know the heating means that can be activated for heating a container, in a fast and stable way in time. For this purpose, the present invention aims according to a first aspect, a method of detecting the configuration of use of a hob having heating means distributed in a two-dimensional grid under a hob, comprising a step of activation implemented on subsets of means for detecting the presence of a container associated respectively with the heating means, the detection means of each subset being non-adjacent.

According to the invention, the activation step is repeated sequentially on said subsets of detection means until all the heating means are at least partially covered by at least one container placed on the plane of the sensor. work is identified. Thus, the detection means activated simultaneously during the detection phase, not being adjacent, they have no influence between them, and all of the heating means covered by an identified container is stable over time . In addition, the time used to identify all the heating means covered by at least one container placed on the worktop is reduced compared to the prior art. Thus, the use configuration of the hob is known quickly and stably over time, causing no inconvenience in the use of the hob. Advantageously, the activation step is repeated sequentially on all subsets of detection means of the hob. Thus, the detection means of a single subset are activated simultaneously, the detection means of each subset being activated in turn. According to one characteristic, the subsets of detection means correspond to a partition of all the detection means of the hob.

Thus, all the detection means of the hob are

The present invention aims according to a second aspect, a hob having heating means distributed in a two-dimensional grid under a hob. According to the invention, the hob comprises means adapted to implement the method of detecting the configuration of a hob according to the invention. According to one characteristic, the hob comprises means 10 for activating the subsets of detection means associated respectively with the heating means, the detecting means of each subset being non-adjacent, and comprising means able to reiterate sequentially activating said subsets of detection means until all of the heating means covered at least in part by at least one container is placed on the worktop is identified. In one embodiment, the heating means and the detection means are inductors. This hob has similar features and advantages to those described above in connection with the method of detecting the use pattern of a hob. Other features and advantages of the invention will become apparent in the description below. In the accompanying drawings, given by way of non-limiting example: FIG. 1 is a schematic view showing a cooking table according to one embodiment of the invention; and - Figure 2 is a diagram illustrating the heating means distributed in a two-dimensional grid under a hob. First of all, with reference to FIG. 1, a hob according to an embodiment of the invention adapted to implement the method of detecting the use configuration according to an embodiment will be described. of the invention. analyzes.

The hob 10 includes a hob 11 for receiving containers on the hob 10. This hob 10 comprises heating means 12 distributed in a two-dimensional grid under the hob 11 of the hob 10. In one embodiment, the heating means 12 may consist of inductors 12 distributed in the hob 11. These inductors are arranged side by side so as to cover the entire surface of the hob 11 .

In this example, the inductors are arranged in staggered rows as illustrated in FIG. 1 and in FIG. 2 which will be described later. In other embodiments, the inductors may be arranged according to a distribution in rows and columns, that is to say in a matrix arrangement.

Each inductor of the hob is independently controlled and operated only when a container covers at least a portion of the inductor. In this example, the inductors 12 constitute both heating means and means for detecting the presence of a container.

Thus, in the following description, it is considered that the heating means are inductors constituting both heating means and detection means. Of course, the present invention could also be implemented for other types of heating means, for example, for radiant elements also arranged in a two-dimensional grid beneath the hob. In this case, each radiant element must be associated with a system for detecting the presence of a container, such as for example a sensor, or an inductor. By way of non-limiting example, FIG. 1 shows three cooking vessels R1, R2, R3 arranged on the cooking surface 11 of the hob 10.

Thus, in this example, three cooking zones Z1, Z2, Z3 are constituted, each cooking zone Z1, Z2, Z3 respectively corresponding to each container R1, R2, R3. Each cooking zone Z1, Z2, Z3 is constituted by an assembly 5 of heating means 12 at least partially covered by a container R1, R2, R3. Thus, for example, if a user controls the heating of a first container R1, the inductors covered by the first container R1, constituting a first cooking zone Z1, are activated. The cooktop 10 further includes a control and display panel 20 for controlling the cooktop 10 by the user. In this exemplary embodiment, the control and display panel 20 is placed close to a front edge 10a of the hob 15 10, intended to be placed facing the user standing in front of the hob. In one embodiment, when the cooktop is turned on, the containers R1, R2, R3 placed on the cooktop 10 are shown on the control and display panel 20. Thus, the user, recognizing on the control and display panel 20 the container placed on the hob 10, can control the heating of each container R1, R2, R3. The hob 10 also comprises a microprocessor adapted to implement the method of detecting the configuration of use of a hob according to the invention which will be described later with reference to FIG. 2. The microprocessor ( not shown in the figures) comprises, in particular, means for activating the means for detecting the presence of a container associated respectively with the heating means, that is to say that here it can control the activation inductors.

Then, with reference to FIG. 2, the method for detecting the use configuration of a hob according to one embodiment of the invention will be described. Figure 2 illustrates the heating means 12 or inductors 5 distributed in a two-dimensional grid under a hob of the hob. Thus, in this example, the heating means 12 are distributed in lines in a X-axis direction, each line being arranged so that the inductors of the two adjacent lines are arranged in staggered rows. In this example, all of the heating means 12 or inductors of the hob 10 is divided into subsets of heating means or subsets of inductors. In Figure 2, the inductors 12 constituting each subset 15 of heating means are shown with a different pattern or frame. Thus, a first subset of heating means 12a is shown in broken lines, a second subset of heating means 12b is represented by horizontal parallel hatching, a third subset of heating means 12c is represented by hatching. 20 vertical parallels, and a fourth subset of heating means 12d is represented by oblique parallel hatching. Thus, in this example, all the heating means 12 of the hob 10 is divided into four subsets of heating means 12a, 12b, 12c, 12d. Of course, in other embodiments the number of subsets of heating means may be different. As illustrated in Figure 2, the heating means of the same subset are non-adjacent, that is to say, there is at least one inductor 12 disposed between them. In this type of hob 10, a step of detecting the containers R1, R2, R3 placed on the hob 11 is implemented once the hob 10 is put into operation by the user, and that regularly along the operation of the hob 10. As indicated below, the detection of containers R1, R2, R3 is well known in the state of the art and is described in particular in the document FR 2 863 039. As a result of the container detection step, all heating means at least partially covered by a container, as well as the recovery rate of each heating means covered by a container are known.

Thus, the configuration of the hob 10 is known. In this embodiment, in order to detect the configuration of use of the hob 10, an activation step is implemented on the subsets of means. 12a, 12b, 12c, 12d or inductor subassemblies 12a, 12b, 12c, 12d.

The activation step is repeated sequentially on the inductor subassemblies 12a, 12b, 12c, 12d until all the inductors 12 are covered at least in part by at least one container R1, R2, R3 laid on the worktop 11 is identified. In this example, the activation step is reiterated sequentially on the four inductor subassemblies 12a, 12b, 12c, 12d of the hob 10. Thus, the inductors belonging to the first subset of inductors 12a are activated simultaneously, then the inductors belonging to the second subset 12b are activated simultaneously, followed by the sequential activation of the inductors 12c, 12d of the third and fourth subset in turn. The result of this activation step is the identification of the inductors 12 covered at least in part by the containers R1, R2, R3, placed on the hob 10. Thus, when the user of the hob 10 , control the heating of one of the containers R1, R2, R3, the heating means 12, here inductors, identified as being covered by the container R1, R2, R3 corresponding, are activated. Since the inductors activated at the same time (inductors belonging to the subset of inductors) are not adjacent, there is no influence between them. Thus, the recovery rate determined for the inductors covered by a container is reliable, and stable over time. The detection time of the use configuration of the hob 10 is particularly reduced compared to the time used in the prior art. The time required for the detection of the use configuration of the hob 10 is given by the following equation: Ttotal = NgX Tind Ng being the number of inductor subsets, and Tind the time necessary for the detection the presence of a container on an inductor 12. By way of non-limiting example, if the number of inductors is 36, the number of inductor subsets is 4, and the time required for detection the presence of a container on a inductor Tind is 60 ms, the time required to know the configuration of use of the hob 10 is 240 ms. Therefore, the time is notably reduced compared to the prior art where the detection of the inductors 12 is performed on all the inductor means of the hob 10 sequentially, the time required for the detection of the configuration of the hob. use of the hob being 2.16 s. Thus, thanks to the invention, the configuration of use of a hob, that is to say all the heating means which are covered by a container, and the recovery rate of each means heating this set by the container, is known quickly and stably in time.

Therefore, the detection of the cooktop usage pattern does not cause any inconvenience when using the cooktop. Of course, the present invention is not limited to the embodiments described above. In particular, heating means may be radiant elements associated with a system for detecting the presence of a container.

Claims (6)

REVENDICATIONS1. Method for detecting the use configuration of a hob (10) comprising heating means (12) distributed in a two-dimensional grid under a hob (11), comprising an activation step implemented on subsets of means for detecting the presence of a container associated respectively with the heating means (12a, 12b, 12c, 12d), the detection means of each subassembly (12a, 12b, 12c, 12d) being non-adjacent, characterized in that the activation step is repeated sequentially on said subsets of detection means (12a, 12b, 12c, 12d) until all the heating means (12) covered at least in part by at least one container (R1, R2, R3) placed on the worktop (11) is identified. 2. Detection method according to claim 1, characterized in that the activation step is repeated sequentially on all subsets of detection means (12a, 12b, 12c, 12d) of the hob (10). ). 3. Detection method according to one of claims 1 or 2, characterized in that said subsets of detection means (12a, 12b, 12c, 12d) correspond to a partition of all the detection means of the cooktop (10). 4. Detection method according to one of claims 1 to 3, characterized in that the heating means (12) and the detection means are inductors. 5. Hobs having heating means distributed in a two-dimensional grid under a cooking surface (11), means for activating the subsystems of means for detecting the presence of a container associated with the heating means ( 12a, 12b, 12c, 12d), the detection means (12) of each subassembly (12a, 12b, 12c, 12d) being non-adjacent, the hob being characterized in that it comprises means capable of sequentially reiterating the activation of said subsets of detection means (12a, 12b, 12c, 12d) until all of the heating means (12) are at least partially covered by at least one container (R1, R2, R3) placed on the worktop (11) is identified. Cooktop (10) according to claim 5, characterized in that the heating means (12) and the detecting means are inductors.