WO2016087791A1 - Infrared centring system for induction cooking surface - Google Patents

Abstract

The invention relates to a centring system for use with a household appliance (1) or a cooking vessel and an induction cooking surface (2), wherein: a first optical device (4) is positioned in the household appliance (1) or the cooking vessel and the first optical device (4) can generate or receive at least one optical beam; and a second optical device (5) is positioned in the induction cooking surface (2) and the second optical device (5) can generate or receive at least one optical beam. The centring system is used to detect the alignment of the first optical device (4) with the second optical device (5).

Description

 INFRARED CENTERING SYSTEM FOR INDUCTION TABLE

The present invention generally relates to a centering system of a household appliance or cooking vessel on an induction table.

More particularly, the centering system relates to household appliances or cooking vessels that are powered or heated wirelessly energy by an induction table to achieve heating or energy recovery to supply functions related to heating or even a combination of both.

It is known in the prior art circular marking systems on the hobs of generators or induction tables as in particular those disclosed in JP2000323270 or WO2009147664. In these documents the marking is intended to identify the inductor (s) and thus to properly position the appliance or the cooking vessel inside the marking to ensure maximum energy transfer between the various elements.

However, and in the case of energy recovery to supply functions related to heating, for these devices to work properly it is necessary that the inductor of the device to be powered is ideally positioned. For this it must be positioned in front of the inductor of the induction generator. The perfect alignment of these inductors allows to get the most power with the best efficiency of contactless energy transfer. It is an imperative condition to ensure a sufficient energy transfer while having a dimensioning of the induction generator and the household appliance or cooking vessel as optimum as possible.

Tolerance of an offset between the induction generator and the appliance or cooking vessel would reduce the efficiency global application and therefore to sizing the induction generator which would impact the final cost.

In addition, these systems also have the disadvantage that the centering of the appliance or cooking vessel is made at the discretion of the user and generally not very accurate without the user being informed of the proper alignment appliance or cookware on the induction hob.

An object of the present invention is to meet the disadvantages of the prior art mentioned above and in particular first of all to propose a system that can inform the user of the proper alignment of a household appliance or a cooking vessel. with the induction hob for the purpose of transferring as much energy as possible for heating the appliance or cooking vessel or for energy recovery.

For this purpose, a first aspect of the invention concerns a centering system intended to operate with a household appliance or a cooking vessel and an induction table comprising a generator inductor provided to supply energy and positioned in the induction table, the appliance or the cooking vessel are powered and / or heated wirelessly by the energy supplied by the generator inductor characterized in that it comprises:

a first optical device positioned in the appliance or cooking vessel and the first optical device can generate or receive one or more optical rays and

a second optical device positioned in the induction table and the second optical device can generate or receive one or more optical rays; and in that the centering system is arranged to detect the alignment of the first optical device with respect to the second optical device from one or more optical rays emitted by the first optical device and received by the second optical device or one or more optical rays emitted by the second optical device and received by the first optical device.

According to one embodiment, the appliance or cooking vessel comprises a receiver inductor for recovering energy and the first optical device is positioned in the middle of the receiver inductor and the second optical device is positioned in the middle of the receiver inductor. the generator inductor.

Placing the optical devices in the middle of the inductors makes it possible to use only two optical devices and when these are aligned the appliance or the cooking vessel can rotate about the axis formed by the two aligned optical devices without the inductors are shifted relative to each other.

According to one embodiment, the receiver inductor and the generator inductor are aligned when the first optical device receives one or more optical rays emitted by the second optical device or when the second optical device receives one or more optical rays emitted by the first optical device. optical device. Optical rays must be received directly so that the spurious rays are not taken into account by the different optical devices.

According to one embodiment, the one or more optical rays emitted by the first optical device or by the second optical device comprise:

- status data of the appliance or cookware or induction hob so as to know the state of the appliance or cookware or induction hob or

- Control data of the appliance or cooking vessel or induction hob so as to control the operation of the appliance or cooking vessel or induction hob; and the status or control data can be bidirectionally exchanged between the appliance or cooking vessel and the induction table via the first optical device and the second optical device only when the first optical device and the second optical device are aligned. The appliance or the cooking vessel and the induction table can thus communicate with each other via the optical rays and this only when the optical devices are aligned which allows to evacuate the possibility of have spurious information that could come from other sources.

In other words, the proposed solution makes it possible, via one and the same means, to provide bidirectional communication between the appliance and the induction hob and a centering indicator of the appliance in relation to the appliance. at the induction table.

According to one embodiment, the appliance or cooking vessel or induction table comprises a display for viewing the alignment of the first optical device with the second optical device. The advantage of such a display is to have a device for rendering the centering information visible to a user.

According to one embodiment, the display comprises one or more light-emitting diodes which are in a first ignition state if the first optical device is aligned with the second optical device and which are in a second ignition state if the first device optic is not aligned with the second optical device. The advantage of having such an indication of the centering is to be able to quickly know the status of the alignment of the optical devices between them.

According to one embodiment, the induction table comprises a device for viewing the presence of a household appliance or a cooking vessel, connected to the second optical device. Such a device can detect whether a household appliance or a cooking vessel is present on the induction table and inform a user.

According to one embodiment, the appliance or the cooking vessel or the induction hob comprises a device for measuring the decentering the first optical device with respect to the second optical device or the second optical device with respect to the first optical device. Such a device makes it possible to know the relative position of the two optical devices with each other. According to one embodiment, the decentering measuring device comprises a photosensitive slab with optical rays, positioned on the induction table or on the bottom of the appliance or cooking vessel, and which allows to know the position on the photosensitive slab of an incident optical ray. The photosensitive slab makes it easy to integrate within the scope of the invention and makes it possible to capture optical rays reliably.

According to one embodiment, the appliance or cooking vessel or induction table comprises a device for displaying the position of the ray incident on the photosensitive slab relative to the position of the first optical device or the second optical device . In this way, it is possible to visualize the relative positions of the two optical systems with respect to one another in real time and from this visualization the alignment of the two optical devices can be corrected in order to align them.

According to one embodiment, the first optical device is a transmitter and / or infrared receiver connected to a microcontroller and the second optical device is a transmitter and / or infrared receiver connected to a microcontroller. Infrared transmitters and / or receivers operate in wavelengths in which there is little interference.

According to one embodiment, the appliance or cooking vessel or induction table comprises a user interface adapted to receive input control data to be transmitted by the first optical device or by the second optical device, in order to control at least one function of the appliance or cooking vessel from the induction hob or to control at least one function of the hob from the appliance or cooking vessel. A second aspect of the invention relates to a home appliance system which operates by induction and which comprises at least one appliance or a cooking vessel and at least one induction hob and wherein the appliance or cooking vessel comprises a first optical device.

According to one embodiment of the electrical appliance system, the induction table comprises a second optical device.

The aims, aspects and advantages of the present invention will be better understood from the description given below of a particular embodiment of the invention presented by way of non-limiting example, with reference to the accompanying drawings in which :

- Figure 1 is a general sectional view of the home appliance system in a first position;

- Figure 2 is a general sectional view of the home appliance system in a second position;

FIG. 3 is a view from above of a variant of the electrical appliance system in the position of FIG. 1;

FIG. 4 is a detailed view from above of the variant of the electrical appliance system of FIG. 3 in the position of FIG. 2. FIG. 1 represents a sectional view of an electrical appliance system which comprises a centering system, a table induction 2 and an appliance 1 or a cooking vessel.

By appliance 1 is meant all appliances that may include heating functions but also functions related to heating. As auxiliary functions to the heater can include a power supply for chopping, mixing or for supplying lighting devices, communications or visualizations.

By heating function of a household appliance 1 is meant that part of the household appliance 1 may rise in temperature either by means of electric heating resistors or currents induced in a metal part of the appliance 1.

The cooking vessel is a container adapted to be placed on an induction table 2 and heated by it at the bottom. The cooking vessel may also include functions related to the heating. We find in a nonlimiting way the additional functions mentioned above.

The induction table 2 comprises one or more inductors 3 generators intended to provide energy. The one or more inductors 3 generators are positioned in the induction table 2.

The centering system comprises a first optical device 4. This first optical device 4 is composed of an optical sensor connected to a microcontroller 12. This optical sensor is either an infrared transmitter, an infrared receiver or a combined transceiver. Thus it can generate or receive one or more optical rays in the infrared wavelengths. This optical sensor is positioned in the appliance 1 or in the cooking vessel. It is positioned perpendicular to the bottom of the appliance 1 or the bottom of the cooking vessel so that the one or more optical rays 10 emitted are emitted perpendicularly to the bottom of the appliance 1 or the bottom of the cooking vessel .

The appliance 1 or the cooking vessel, in addition to being heated, comprises a receiver inductor 6 for recovering energy in order to supply functions related to heating. The first optical device 4 is positioned in the middle of the inductor 6 receiver. By "positioned in the middle" is meant that the first optical device 4 is positioned in the center of the circle when, for example, the receiver inductor 6 has the shape of a circle. In general, if the receiver inductor 6 is of any shape or comprises a plurality of receiver inductors 6, the first optical device 4 will be placed on an axis of revolution of the total magnetic field formed by the one or more inductor 6 receivers. . The centering system also comprises a second optical device 5. This second optical device 5 is composed of an optical sensor connected to a microcontroller 13. This optical sensor is either an infrared transmitter, an infrared receiver or a combined transceiver. Thus it can generate or receive one or more optical rays in the infrared wavelengths. This second optical device 5 is positioned in the induction table 2. This second optical device 5 is more particularly positioned in the middle of the generator inductor 3 and perpendicular to the plane of the induction table 2 so that the one or more 1 1 emitted optical beams are perpendicular to the plane of the induction table 2.

The definition of "milieu" is here the same as that stated above.

In general, the invention is not limited to wavelengths of the infrared and other wavelengths are possible when the first or the second optical device (4, 5) is adapted to detect these wavelengths.

In FIG. 1, the first optical device 4 and the second optical device 5 are shifted, which implies that the generator inductor 3 and the receiver inductor 6 are not in opposite relation and that the energy efficiency transmitted from the induction table 2 to the appliance 1 is not optimal. In order to inform a user, the appliance 1, or the cooking vessel or the induction table 2, comprises a display 7 making it possible to display the alignment of the first optical device 4 with the second optical device 5.

The display 7 comprises one or more light-emitting diodes which are in a first state of ignition if the first optical device 4 is aligned with the second optical device 5 and which are in a second state of ignition if the first optical device 4 n is not aligned with the second optical device 5.

It is also possible to have a sound device (not shown) to inform a user of the alignment of the optical devices (4, 5). As shown in Figures 1 to 4, the induction table 2 comprises a display device 8 of the presence of an appliance 1 or a cooking vessel on the induction table 2. This display device 8 is connected the second optical device 5 and it can detect whether a household appliance 1 or a cooking vessel is present on the induction table 2 and inform a user. Indeed if the second optical device 5 does not detect optical rays then the display device 8 indicates that a household appliance 1 or a cooking vessel is not present on the induction table 2. Figure 2 shows the system appliance in the case where the first optical device 4 is centered with the second optical device 5. In this way the first optical device 4 directly receives the one or more optical rays 1 1 emitted by the second optical device 5 and the second optical device 5 directly receives one or more optical rays 10 emitted by the first optical device 4. In this way the induction table 2 is informed that an appliance 1 or a cooking vessel is positioned on the induction table 2 but the apparatus appliance 1 or the cooking vessel is also informed that an induction table 2 is positioned under the appliance 1 or the cooking vessel. The one or more optical rays (10.1 1) emitted by the first optical device 4 or by the second optical device 5 comprise state data of the domestic appliance 1 or the cooking vessel or the induction table 2 in order to know the state of the domestic appliance 1 or the cooking vessel or the induction table 2. These optical radii (10, 1 1) emitted also include control data of the appliance 1 or the appliance. cooking vessel or induction hob 2.

This control data makes it possible to control the operation of the household appliance 1 or the cooking vessel or the induction table 2. The status or control data can be bidirectionally exchanged between the appliance 1 or the cooking vessel and the induction hob 2.

Figures 3 and 4 show a variant of the household appliance system in which the appliance 1 or the cooking vessel or the induction table 2 comprises a device for measuring the decentering of the first optical device 4 with respect to the second optical device 5 or the second optical device 5 with respect to the first optical device 4. The decentering measuring device comprises a plate 9 photosensitive to optical radiation. It is positioned on the induction table 2 or on the bottom of the appliance 1 or the cooking vessel and it makes it possible to locate the position of an optical ray incident thereon.

The decentering measuring device is connected to a display device 16 of the position of the incident ray on the photosensitive plate 9 which makes it possible to visualize the relative positions of the two optical devices (4, 5) relative to one another. another in real time, the second optical device 5 being fixed relative to the induction table 2 and the first optical device 4 being movable relative to the induction table 2.

From this visualization, a user can correct the alignment of the two optical devices (4, 5) with each other.

In general, and as shown in Figures 1 to 4, the appliance 1 or the cooking vessel or the induction table 2 comprises a user interface 14. This user interface 14 is adapted to receive input control data. This user interface 14 includes tactile or electromechanical keys. The information entered on the user interface 14 can directly control the functions of the element of the electrical household system on which the user interface 14 is located or can be transmitted by the first optical device 4 or by the second optical device 5 to the other element of the household electrical system. Several situations can be encountered when using the appliance 1 or the cooking vessel with the induction cooker 2. Firstly, no appliance 1 or cooking vessel is positioned on the cooking table. In this case, the optical sensor of the second optical device 5 does not detect optical rays. The microcontroller 13 interprets the information and the result is viewable on the display device 8.

Once a household appliance 1 or a cooking vessel positioned on the induction table 2, the two optical devices (4, 5) can be either aligned or non-aligned.

If the two optical devices (4, 5) are not aligned, the second optical device 5 of the induction table 2 will receive optical radiation mainly from the reflection of its own optical radiation emitted on the bottom of the appliance. 1 or cooking vessel. The second optical device 5 is adapted to recognize the power of the optical rays received and to deduce that below a certain power threshold of the optical rays received, the first optical device 4 of the appliance 1 or cooking vessel is offset from the second optical device 5 of the induction table 2. The display of this shift will be via the display device 16 mentioned above or via the display 7 or both at once.

When the two optical devices (4, 5) are opposite each other, the one or more optical rays 10 emitted by the first optical device 4 are directly received by the second optical device 5. In this way the threshold necessary power to the second optical device 5 to detect the proper alignment of the first optical device 4 is achieved. The display 7 now indicates by a change of state of the diodes that the two optical devices (4, 5) are aligned and the display device 16 indicates the proper alignment, for example, by the superposition of a luminous point in the center of a cross-shaped reference frame. Once the alignment is completed, a two-way data exchange can be done and the control of the induction table 2 is possible either via the appliance 1 or the cooking vessel, or directly via the induction table 2 and in a case as in the other via the user interface 14 which allows to enter control data.

For example in this case, a user can control the heating power of the induction table 2 through the appliance 1 or the cooking vessel

It will be understood that various modifications and / or improvements obvious to those skilled in the art can be made to the embodiment of the invention described in the present description without departing from the scope of the invention defined by the appended claims.

Claims

Centering system designed to work with a household appliance (1) or a cooking container and an induction hob

(2), the induction table (2) comprising a generator inductor (3) which is intended to provide energy and which is positioned in the induction table (2), the household appliance (1) or the container cooking are powered and/or heated wirelessly by the energy supplied by the generator inductor (3), characterized in that it comprises:

- a first optical device (4) positioned in the household appliance (1) or the cooking container and the first optical device (4) can generate or receive one or more optical rays and

- a second optical device (5) positioned in the induction table (2) and the second optical device (5) can generate or receive one or more optical rays; and in that the centering system is provided to detect the alignment of the first optical device (4) relative to the second optical device (5) from one or more optical rays (10) emitted by the first optical device (4 ) and received by the second optical device (5) or one or more optical rays (1 1) emitted by the second optical device (5) and received by the first optical device (4).

Centering system according to the preceding claim characterized in that the household appliance (1) or the cooking container comprises a receiving inductor (6) intended to recover energy and the first optical device (4) is positioned in the middle of the receiving inductor (6) and the second optical device (5) is positioned in the middle of the inductor

(3) generator. 3. Centering system according to the preceding claim characterized in that that the receiving inductor (6) and the generating inductor (3) are aligned when the first optical device (4) receives one or more optical rays (1 1) emitted by the second optical device (5) or when the second device optical (5) receives one or more optical rays (10) emitted by the first optical device (4) and the optical rays (10, 1 1) are received directly.

Centering system according to one of claims 1 to 3 characterized in that the one or more optical rays (10, 1 1) emitted by the first optical device (4) or by the second optical device (5) comprise:

- status data of the household appliance (1) or of the cooking vessel or of the induction hob (2) so as to know the state of the household appliance (1) or of the cooking vessel or of the induction hob (2) the induction hob (2) or

- control data for the household appliance (1) or the cooking vessel or the induction hob (2) so as to control the operation of the household appliance (1) or the cooking vessel or the table induction (2); and in that the status or control data can be exchanged bidirectionally between the household appliance (1) or the cooking vessel and the induction hob (2) via the first optical device (4) and the second optical device (5) only when the first optical device (4) and the second optical device (5) are aligned.

Centering system according to one of claims 1 to 4 characterized in that the household appliance (1) or the cooking container or the induction hob (2) comprises a display (7) making it possible to visualize the alignment of the first optical device (4) with the second optical device (5).

Centering system according to the preceding claim characterized in that the display (7) comprises one or more diodes electroluminescents which are in a first ignition state if the first optical device (4) is aligned with the second optical device (5) and which are in a second ignition state if the first optical device (4) is not aligned with the second optical device (5).

Centering system according to one of the preceding claims characterized in that the induction hob (2) comprises a display device (8) of the presence of a household appliance (1) or a cooking container, connected to the second optical device (5).

Centering system according to one of the preceding claims characterized in that the household appliance (1) or the cooking container or the induction hob (2) comprises a device for measuring the off-centering of the first optical device (4) relative to to the second optical device (5) or of the second optical device (5) relative to the first optical device (4).

Centering system according to the preceding claim characterized in that the off-centering measuring device comprises a panel (9) photosensitive to optical rays, positioned on the induction table (2) or on the bottom of the household appliance (1) or the cooking container, and which makes it possible to know the position on the photosensitive panel 9 of an incident optical ray.

Centering system according to one of claims 8 or 9 characterized in that the household appliance (1) or the cooking container or the induction hob (2) comprises a display device (16) for the position of the radius incident on the photosensitive panel (9) relative to the position of the first optical device (4) or the second optical device (5).

Centering system according to one of the preceding claims characterized in that the first optical device (4) is an infrared transmitter and/or receiver connected to a microcontroller (12) and the second optical device (5) is a transmitter and/or infrared receiver connected to a microcontroller (13). Centering system according to one of the preceding claims characterized in that the household appliance (1) or the cooking container or the induction hob (2) comprises a user interface (14) adapted to receive control data as input intended to be transmitted by the first optical device (4) or by the second optical device (5), so as to control at least one function of the household appliance (1) or the cooking container from the induction hob (2) or to control at least one function of the induction hob (2) from the household appliance (1) or the cooking container.