Induction cooking apparatus and method

文档序号:174750 发布日期:2021-10-29 浏览:26次 中文

阅读说明:本技术 感应烹饪装置和方法 (Induction cooking apparatus and method ) 是由 梅尔特·塞尔达尔·比尔金 优素福·阿克 于 2019-03-14 设计创作,主要内容包括:本发明提供了一种用于加热烹饪容器(150,250,350)的感应烹饪装置(100,200,300),该感应烹饪装置(100,200,300)包括具有烹饪炉盘(106)的烹饪表面(101,201,301)、感应线圈(102,202,302)、与感应线圈(102,202,302)电耦合的驱动电路(103,203,303)以及设置在烹饪炉盘(106)下方的线圈支架(105),其中感应线圈(102,202,302)设置在线圈支架(105)上并且其中线圈支架(105)被构造为基于感应线圈(102,202,302)和/或驱动电路(103,203,303)的至少一个部件的温度来动态地调整感应线圈(102,202,302)与烹饪表面(101,201,301)之间的距离,其中线圈支架(105)被构造为随着感应线圈(102,202,302)和/或驱动电路(103,203,303)的至少一个部件的温度升高而增加感应线圈(102,202,302)与烹饪表面(101,201,301)之间的距离。此外,本发明提供了一种相应的方法。(The present invention provides an induction cooking device (100, 200, 300) for heating a cooking container (150, 250, 350), the induction cooking device (100, 200, 300) comprising a cooking surface (101, 201, 301) having a cooking hob (106), an induction coil (102, 202, 302), a drive circuit (103, 203, 303) electrically coupled with the induction coil (102, 202, 302), and a coil support (105) arranged below the cooking hob (106), wherein the induction coil (102, 202, 302) is arranged on the coil support (105) and wherein the coil support (105) is configured to dynamically adjust a distance between the induction coil (102, 202, 302) and the cooking surface (101, 201, 301) based on a temperature of the induction coil (102, 202, 302) and/or at least one component of the drive circuit (103, 203, 303), wherein the coil support (105) is configured to move with the induction coil (102, 202, 302) and/or at least one component of the drive circuit (103, 203, 303) increases in temperature to increase the distance between the induction coil (102, 202, 302) and the cooking surface (101, 201, 301). Furthermore, the invention provides a corresponding method.)

1. An induction cooking device (100, 200, 300) for heating a cooking vessel (150, 250, 350), the induction cooking device (100, 200, 300) comprising:

a cooking surface (101, 201, 301) comprising a cooking hob (106);

an induction coil (102, 202, 302);

a drive circuit (103, 203, 303) electrically coupled to the induction coil (102, 202, 302); and

a coil support (105) arranged below the cooking hob (106), wherein the induction coil (102, 202, 302) is arranged on the coil support (105) and wherein the coil support (105) is configured to dynamically adjust a distance between the induction coil (102, 202, 302) and the cooking surface (101, 201, 301) based on a temperature of at least one component of the induction coil (102, 202, 302) and/or the drive circuit (103, 203, 303), wherein the coil support (105) is configured to increase the distance between the induction coil (102, 202, 302) and the cooking surface (101, 201, 301) as the temperature of the at least one component of the induction coil (102, 202, 302) and/or the drive circuit (103, 203, 303) increases.

2. The induction cooking device (100, 200, 300) according to claim 1, wherein the coil support (105) comprises: a movable carrying structure (210, 310) configured to carry the induction coil (102, 202, 302); and a plurality of actuators configured to vary the distance of the movable carrying structure (210, 310) with respect to the cooking surface (101, 201, 301).

3. The induction cooking device (100, 200, 300) according to claim 2, wherein the actuator comprises a flexible body (211, 212) and a phase change material (213, 214) provided in the flexible body (211, 212).

4. The induction cooking device (100, 200, 300) according to claim 3, wherein the phase change material (213, 214) comprises a hydrated salt and/or paraffin and/or a bio-based phase change material (213, 214).

5. The induction cooking device (100, 200, 300) according to claim 2, wherein the actuator comprises an electromechanical actuating element (315) and a corresponding drive circuit (103, 203, 303).

6. The induction cooking device (100, 200, 300) according to claim 5, comprising a distance control unit (316) and a temperature sensor (317) configured to measure a temperature of the induction coil (102, 202, 302) and/or the at least one component of the drive circuit (103, 203, 303) and coupled to the distance control unit (316), wherein the distance control unit (316) is configured to control the actuator based on the temperature measured by the temperature sensor (317).

7. The induction cooking device (100, 200, 300) according to claim 6, wherein the temperature sensor (317) comprises an indirect temperature sensor (317), in particular a current sensor (318).

8. A method for operating an induction cooking device (100, 200, 300) having an induction coil (102, 202, 302) and a drive circuit (103, 203, 303) for heating a cooking container (150, 250, 350), the method comprising:

operating (S1) the induction coil (102, 202, 302) by the drive circuit (103, 203, 303); and

dynamically adjusting (S2) a distance between the induction coil (102, 202, 302) and a cooking surface (101, 201, 301) based on a temperature of the induction coil (102, 202, 302) and/or at least one component of the drive circuit (103, 203, 303),

wherein the distance increases with increasing temperature of the at least one component of the induction coil (102, 202, 302) and/or the drive circuit (103, 203, 303).

9. The method of claim 8, wherein adjusting comprises moving a movable carrier structure (210, 310) carrying the induction coil (102, 202, 302) by a plurality of actuators.

10. The method according to claim 9, wherein moving the movable carrying structure (210, 310) is performed by a flexible body (211, 212) and a phase change material (213, 214) arranged in the flexible body (211, 212).

11. The method according to claim 10, wherein the phase change material (213, 214) comprises a hydrated salt and/or a paraffin and/or a bio-based phase change material (213, 214).

12. The method according to claim 9, wherein moving the movable carrying structure (210, 310) is performed by an electromechanical actuation element (315) and a corresponding drive circuit (103, 203, 303).

13. The method according to claim 12, comprising measuring a temperature of the at least one component of the induction coil (102, 202, 302) and/or the drive circuit (103, 203, 303), wherein moving comprises controlling the electromechanical actuating element (315) based on the measured temperature.

14. The method of claim 13, wherein the temperature is measured by an indirect temperature sensor (317).

15. The method of claim 14, wherein the indirect temperature sensor (317) comprises a current sensor (318), and wherein the carrier structure (210, 310) is lowered when a current measured by the current sensor (318) exceeds a predetermined current threshold, and wherein the carrier structure (210, 310) is positioned closest to the cooking surface (101, 201, 301) when the measured current is below the current threshold.

Technical Field

The present invention relates to an induction cooking device and a corresponding method.

Background

Although applicable to any induction heating apparatus, the invention will be primarily described in connection with induction stoves.

In modern stoves, energy, and therefore heat, can be transferred to the respective cooking vessel by induction. For this purpose, an induction coil may be arranged below the cooking surface and an alternating field may be generated by the induction coil. The changing magnetic field thus induces a current in the bottom surface of the cooking vessel. The current generates heat at the bottom of the cooking vessel, thereby heating the cooking items in the cooking vessel.

The induction coil and the bottom of the cooking vessel may be considered as a kind of coupling inductor. This means that the magnetic properties of the cooking vessel influence the inductance of the induction coil. It is known that different cooking vessels may comprise different magnetic properties. Therefore, the control of the induction coil is generally adapted to different types of cooking vessels.

For example, the regulation of the current flowing through the induction coil, i.e. the frequency, the amplitude, etc., can be varied in the induction furnace. In addition, an algorithm may be used to detect the type and size of the cookware, and a regulation and switching algorithm may be selected according to the detected type and size of the cookware.

However, these control algorithms require complex operations.

Therefore, there is a need to provide a simplified control of induction cookers.

Disclosure of Invention

The above problems are solved by the features of the independent claims. It is to be understood that independent claims of one claim category may be formed similarly to dependent claims of another claim category.

Thus, there is provided:

an induction cooking device for heating a cooking vessel, the induction cooking device comprising a cooking surface having a cooking hob, an induction coil, a drive circuit electrically coupled with the induction coil and a coil support arranged below the cooking hob, wherein the induction coil is arranged on the coil support and wherein the coil support is configured to dynamically adjust a distance between the induction coil and the cooking surface based on a temperature of at least one component of the induction coil and/or the drive circuit, wherein the coil support is configured to increase the distance between the induction coil and the cooking surface as the temperature of at least one component of the induction coil and/or the drive circuit increases.

Further, there is provided:

a method for operating an induction cooking device having an induction coil and drive circuitry for heating a cooking vessel, the method comprising operating the induction coil by the drive circuitry and dynamically adjusting a distance between the induction coil and the cooking surface based on a temperature of at least one component of the induction coil and/or the drive circuitry, wherein the distance increases as the temperature of the at least one component of the induction coil and/or the drive circuitry increases.

The present invention is based on the discovery that different types of cooking vessels can include ferromagnetic properties that vary widely. Furthermore, the present invention is based on the finding that the distance between the induction coil and the cooking vessel defines the influence of the ferromagnetic properties of the cooking vessel on the induction coil.

Generally, a parallel LC circuit is used to drive an induction coil of an induction cooking device. It should be understood that the term parallel LC circuit may refer to a circuit in which the induction coil is the "L" component and the parallel capacitance is set to the "C" component. If the parallel LC circuit is operating at its resonant frequency, a minimum drive current is required. Furthermore, with a low magnetic coupling between the induction coil and the cooking vessel, the impedance of the parallel LC circuit will be low and the current flowing through the parallel LC circuit will be high. It will be appreciated that the drive circuit may comprise such a parallel LC circuit and corresponding control and switching means, although not explicitly mentioned.

The present invention particularly considers that cooking vessels with poor ferromagnetic properties can lead to non-uniform, irregular and increased currents flowing in the induction coil and the drive circuit. Such irregular current transitions can have significant negative effects in the semiconductor. For example, they can lead to switching irregularities and profile loss. This effect in turn generates losses in the semiconductor and heats the semiconductor up.

The present invention thus provides a coil support that dynamically adjusts the distance between the induction coil and the cooking surface, and thus the cooking vessel. The coil support increases the distance between the induction coil and the cooking surface as the temperature of the induction coil and/or at least one component of the drive circuit increases. The term "at least one component" of the drive circuit may for example refer to one or more switches in the drive unit that drive a current through the induction coil.

Therefore, if a cooking container having poor ferromagnetic characteristics is used, the induction coil and the driving circuit may be heated due to an increase in operating current. This temperature increase causes the coil support to lower the induction coil and increase the distance between the cooking vessel and the induction coil.

An increase in the separation of the cooking vessel from the induction coil results in a decrease in the impedance of the parallel LC circuit and an increase in the current in the parallel LC circuit. However, current irregularities caused by cooking vessels with poor ferromagnetic properties are also reduced. Such cooking vessels with poor ferromagnetic properties cause current irregularities that have a greater effect on the temperature of the induction coil and the drive circuit than the increased current due to the decreased impedance. Therefore, the overall temperature of the induction coil and/or the driving circuit is reduced by increasing the distance between the induction coil and the cooking vessel having poor ferromagnetic properties. After increasing the distance, the current flow is more regular, thus having a positive effect on the semiconductor temperature by spacing the cooking vessel further away from the induction coil.

Thus, by the present invention, the temperature of the induction coil and/or the drive circuit can be adjusted by a simple mechanical configuration (i.e., coil support). The present invention does not require a complicated control algorithm to adapt the induction cooking apparatus to the type of cooking container.

It should be understood that the term induction coil may refer to a single coil or a group or plurality of coils provided for a single cooking hob. Furthermore, it should be understood that the induction cooking device may comprise more than one cooking hob and corresponding induction coils. A single drive circuit may be provided for each induction coil or group of induction coils. Alternatively, a single drive circuit may be provided for all induction coils in the induction cooking apparatus.

Further embodiments of the invention are subject matter of further dependent claims and the following description with reference to the drawings.

In one embodiment, the coil support may include a movable load bearing structure configured to bear the induction coil, and a plurality (i.e., one or more) of actuators configured to change a distance of the movable load bearing structure relative to the cooking surface.

The carrying structure may for example comprise a non-ferromagnetic part, such as a plastic clip or the like that can accommodate the induction coil. It should be understood that the carrying structure may for example be provided in one piece with the induction coil. The carrier structure may for example be injection moulded around the induction coil.

The actuator may be coupled to a structure and a load-bearing structure of the induction cooking apparatus, for example. The structure of the induction cooking device can be considered as a base or support for the actuator.

In another embodiment, an actuator may include a flexible body and a phase change material disposed in the flexible body.

The flexible body may for example be a body that easily expands and contracts. Such a body may be made of rubber or other plastic, for example. The flexible body may be filled with a phase change material. The term "phase change material" refers to a material that at least softens with increasing temperature.

It will be appreciated that the actuator may be thermally coupled to the induction coil and/or corresponding component(s) of the drive circuit. To this end, the mechanical configuration and position of the actuator in the induction cooking device may bring the actuator into direct contact with the induction coil and/or corresponding component(s) of the drive circuit. Additionally or alternatively, heat transfer elements, such as copper sheets or heat pipes or the like, may also be provided between the respective component(s) of the induction coil and/or the drive circuit.

Thus, if the induction coil and/or the corresponding component(s) of the drive circuit heats up, heat will be transferred to the actuator and the phase change material in the actuator will change its phase or at least soften with respect to the lower temperature. If the phase change material becomes soft, the weight of the induction coil will push the actuator downwards and the induction coil will decrease.

With the help of the phase change material, a fully passive or mechanical configuration may be provided to dynamically control the distance of the induction coil from the cooking surface.

In yet another embodiment, the phase change material may include a hydrated salt and/or a paraffin and/or a bio-based phase change material.

The hydrated salt consists of an inorganic salt and water. Their melting point temperature ranges between 15 ℃ and 80 ℃. Hydrated salts have the advantages of low material cost, high latent heat storage capacity, precise melting point, high thermal conductivity and flammability.

Paraffin waxes are generally derived from petroleum and have a waxy consistency at room temperature. Their melting point temperature ranges between-8 ℃ and 40 ℃. They have good heat storage capacity and have been shown to freeze without undercooling.

Bio-based Phase Change Materials (PCMs) are organic compounds derived from animal fats and vegetable oils. Their melting point temperature ranges between-40 ℃ and 151 ℃. The most common bio-based PCMs are derived from fatty acids and are more efficient than hydrated salts and petroleum-based phase change materials.

In another embodiment, the actuator may include an electro-mechanical actuation element and a corresponding drive circuit.

As an alternative to passive control as described above, electromechanical actuating elements may be used to allow fine control of the distance of the induction coil from the cooking surface.

The electromechanical actuating element may for example comprise a linear actuator or any other type of electric motor and mechanical device that allows positioning of the induction coil or the movable carrying structure relative to the cooking surface.

In another embodiment, the induction cooking device may comprise a distance control unit and a temperature sensor configured to measure a temperature of at least one component of the induction coil and/or the drive circuit and coupled to the distance control unit. The distance control unit may be configured to control the actuator based on the temperature measured by the temperature sensor.

It should be understood that the distance control unit may be, for example, a dedicated distance control unit. Such a dedicated control unit may for example comprise a microcontroller or the like with corresponding drivers (e.g. switches or transistors) for the actuators. Furthermore, a position sensor may be provided which indicates to the control unit the distance of the carrying structure from the cooking surface.

Alternatively, the distance control unit may also be integrated into another control unit in the induction cooking surface, for example. The distance control unit may for example be integrated into a control unit or controller of the drive circuit.

The temperature sensor may be a single temperature sensor, for example, provided at a switch or an induction coil of the driving circuit. Furthermore, a plurality of temperature sensors may be provided, for example, at the drive circuit and the induction coil.

Furthermore, additional switches, such as end switches, may be provided at the minimum and maximum ranges or positions of movement of the movable load bearing structure.

In another embodiment, the temperature sensor may comprise an indirect temperature sensor, in particular a current sensor.

As an alternative to the above, the temperature can be derived, for example, from other system values (e.g., the current flowing through the induction coil). This current can be measured, for example, in any case by a current sensor in the drive circuit.

For example, a particular current threshold may be determined, and the load bearing structure may be lowered when the measured current exceeds the current threshold. The distance between the load bearing structure and the cooking surface may be set to a minimum value when the measured current is below the current threshold.

Drawings

For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings. The invention is explained in more detail below using exemplary embodiments specified in the schematic drawings of the figures, in which:

fig. 1 shows a block diagram of an embodiment of an induction cooking device according to the present invention;

fig. 2 shows a block diagram of another embodiment of an induction cooking device according to the present invention;

fig. 3 shows a block diagram of another embodiment of an induction cooking device according to the present invention; and is

Fig. 4 shows a flow chart of an embodiment of the method according to the invention.

In the drawings, like reference numerals refer to like elements unless otherwise specified.

Detailed Description

Fig. 1 shows a block diagram of an induction cooking apparatus 100. Induction cooking device 100 includes a cooking surface 101 having a cooking hob 106. A cooking container 150 may be provided on the cooking hob 106 to heat the cooking items. Further, an induction coil 102 is provided below the cooking surface 101. The induction coil 102 is electrically coupled with a drive circuit 103. In addition, in the induction cooking apparatus 100, the coil support 105 is disposed below the cooking hob 106 and carries the induction coil 102.

During operation of the induction cooking device 100, the coil support 105 dynamically adjusts the distance between the induction coil 102 and the cooking surface 101 based on the temperature of the induction coil 102 and/or at least one component of the drive circuit 103 (e.g., the switching element 104). If the temperature of the induction coil 102 and/or at least one component of the drive circuit 103 rises, for example, above a predetermined threshold, the coil support 105 increases the distance between the induction coil 102 and the cooking surface 101, and vice versa.

This means that if a certain temperature is exceeded in the drive circuit 103 or the induction coil 102, the induction coil 102 is lowered. It will be appreciated that the coil support 105 may be configured to begin to drop at temperatures that are not reached in normal operating conditions, but only for cooking vessels having poor ferromagnetic properties. The temperature may be determined experimentally, for example, during development or design of induction cooking device 100.

Fig. 2 shows a block diagram of another induction cooking apparatus 200. Induction cooking device 200 is based on induction cooking device 100. Accordingly, the induction cooking device 200 comprises a cooking surface 201 having a cooking hob 206. A cooking container 250 is provided on the cooking hob 206 to heat the cooking items. Further, an induction coil 202 is provided below the cooking surface 201. The induction coil 202 is electrically coupled to a drive circuit 203. An exemplary switching element 204 is shown in the driving circuit 203. In the induction cooking apparatus 200, the coil support is not explicitly shown. Instead, a carrier structure 210 and an actuator are provided, the actuator comprising a flexible body 211, 212 filled with a phase change material 213, 214.

The carrier structure 210 carries the induction coil 202 and is mechanically coupled with flexible bodies 211, 212 located below the carrier structure 210. As described above, the phase change materials 213, 214 may soften or become liquid when they are heated to a particular temperature. If the phase change material 213, 214 becomes soft, the flexible body 211, 212 may be compressed by the weight of the load bearing structure 210 and the induction coil 202. Alternatively, the phase change materials 213, 214 may expand upon liquefaction, thus allowing the flexible bodies 211, 212 to expand laterally, thereby causing them to contract vertically. To this end, the top and bottom of the flexible bodies 211, 212 may be inflexible.

The embodiment of fig. 2 thus provides a very simple construction which does not require dedicated electrical control.

Fig. 3 shows a block diagram of another induction cooking apparatus 300. Induction cooking device 300 is based on induction cooking device 200. Accordingly, induction cooking device 300 includes a cooking surface 301 having a cooking hob 306. A cooking container 350 is provided on the cooking hob 306 to heat the cooking item. Further, an induction coil 302 is provided below the cooking surface 301. The induction coil 302 is electrically coupled to a drive circuit 303. An exemplary switching element 304 is shown in the driver circuit 303. In the induction cooking apparatus 300, the coil support is not explicitly shown. Instead of the flexible bodies 211, 212, the induction cooking device 300 comprises an electromechanical actuating element 315 arranged below the carrying structure 310. Further, a distance control unit 316 is provided in the drive circuit 303. The distance control unit 316 is coupled to the electromechanical actuating element 315 to control the electromechanical actuating element 315. Further, a temperature sensor 317 is provided at the switching element 304 and coupled with the distance control unit 316, and a current sensor 318 is provided on a power line from the induction coil 302 to the drive circuit 303. The current sensor 318 is also coupled to the distance control unit 316. It should be understood that the current sensor 318 may be used as a substitute for the temperature sensor 317 and that only one of the two sensors 317, 318 may be provided.

The distance control unit 316 controls the electromechanical actuating element 315 based on the temperature measured by the temperature sensor 317 or based on the current measured by the current sensor 318 or both. If the temperature or the current or both exceed predetermined thresholds, the distance control unit 316 may control the electromechanical actuator 315 to lower the induction coil 302 relative to the cooking surface 301.

The current flowing through the switching element 304 and the induction coil 302 affects the temperature of the switching element 304 and the induction coil 302. Thus, the current sensor 318 in this embodiment may be considered an indirect temperature sensor.

For clarity, in the following description of method-based fig. 4, the reference numerals used in the above description of apparatus-based fig. 1 to 3 will be retained. Fig. 4 shows a flow chart of a method of operating an induction cooking device 100, 200, 300 having an induction coil 102, 202, 302 and a drive circuit 103, 203, 303 for heating a cooking vessel 150, 250, 350.

The method comprises operating S1 the induction coil 102, 202, 302 by the drive circuit 103, 203, 303 and dynamically adjusting S2 a distance between the induction coil 102, 202, 302 and the cooking surface 101, 201, 301 based on a temperature of the induction coil 102, 202, 302 and/or at least one component of the drive circuit 103, 203, 303, wherein the distance increases as a temperature of the induction coil 102, 202, 302 and/or at least one component of the drive circuit 103, 203, 303 increases.

The step of adjusting S2 may include moving the movable carrier structure 210, 310 carrying the induction coil 102, 202, 302 by a plurality of actuators.

Moving the movable carrying structure 210, 310 may in particular be performed by two different schemes.

For example, the flexible body 211, 212 and the phase change material 213, 214 arranged in the flexible body 211, 212 may be arranged to deform the flexible body 211, 212 and lower the load bearing structure 210, 310 when the phase change material 213, 214 heats up. The phase change material 213, 214 may comprise hydrated salts and/or paraffin and/or bio-based phase change material 213, 214.

As an alternative, moving the movable carrying structure 210, 310 may be performed by an electromechanical actuation element 315 and a respective drive circuit 103, 203, 303. To this end, the temperature of at least one component of the induction coil 102, 202, 302 and/or the drive circuit 103, 203, 303 may be measured, and moving may include controlling the electromechanical actuating element 315 based on the measured temperature. The temperature may be measured by a dedicated temperature sensor or an indirect temperature sensor 317. The indirect temperature sensor 317 may include, for example, a current sensor 318. The load bearing structure 210, 310 may be lowered when the current measured by the current sensor 318 exceeds a predetermined current threshold. When the measured current is below the current threshold, the carrying structure 210, 310 may be positioned closest to the cooking surface 101, 201, 301, for example. Alternatively, a linear relationship may be established between temperature/current and distance.

Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that a variety of alternate and/or equivalent implementations exist. It should be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration in any way. Rather, the foregoing summary and detailed description will provide those skilled in the art with a convenient road map for implementing at least one exemplary embodiment, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope as set forth in the appended claims and their legal equivalents. In general, this application is intended to cover any adaptations or variations of the specific embodiments discussed herein.

The present invention provides an induction cooking device 100, 200, 300 for heating a cooking vessel 150, 250, 350, the induction cooking device 100, 200, 300 comprising a cooking surface 101, 201, 301 with a cooking hob 106, an induction coil 102, 202, 302, a drive circuit 103, 203, 303 electrically coupled with the induction coil 102, 202, 302 and a coil support 105 arranged below the cooking hob 106, wherein the induction coil 102, 202, 302 is arranged on the coil support 105 and wherein the coil support 105 is configured to dynamically adjust a distance between the induction coil 102, 202, 302 and the cooking surface 101, 201, 301 based on a temperature of the induction coil 102, 202, 302 and/or at least one component of the drive circuit 103, 203, 303, wherein the coil support 105 is configured to increase a temperature of the induction coil 102, 202, 302 and/or at least one component of the drive circuit 103, 203, 303, wherein the coil support 102, 202, 302, and the drive circuit 103, 203, 303 are configured to increase a temperature of the induction coil 102, 202, 302 and/or at least one component of the drive circuit 103, 203, 303 202. 302 from the cooking surface 101, 201, 301.

List of reference numerals

100, 200, 300 induction cooking device

101, 201, 301 cooking surface

102, 202, 302 induction coil

103, 203, 303 drive circuit

104, 204, 205 switching element

105 coil support

106 cooking hob

210, 310 load bearing structure

211, 212 Flexible body

213, 214 phase change material

315 electromechanical actuating element

316 distance control unit

317 temperature sensor

318 current sensor

Method steps S1, S2

150, 250, 350 cooking vessel

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