EP4401512A1 - Cooking vessel for parking on an induction hob of a cooking system for cooking food, cooking system for cooking food and method for operating a cooking system - Google Patents

Abstract

The invention relates to a cooking utensil (110) for placing on an induction hob (120) of a cooking system (100) for cooking food. The cooking utensil (110) comprises at least one temperature sensor (112, 114) which is arranged in a base of the cooking utensil (110) which can be placed on the induction hob (120). The at least one temperature sensor (112, 114) is designed to provide at least one sensor signal (S) during a cooking operation in a state of the cooking utensil (110) placed on the induction hob (120), which sensor signal represents a detected temperature in the base of the cooking utensil (110). The cooking utensil (110) further comprises a processing device (116) which is connected to the at least one temperature sensor (112, 114) in a signal-transmitting manner. The processing device (116) is designed to evaluate the at least one sensor signal (S) in order to generate a temperature signal. The processing device (116) is designed to generate a data packet (Fx) and to transmit it wirelessly to the induction hob (120) in a secure manner. The data packet (Fx) comprises safety-relevant data which has at least the temperature signal as a safety-relevant data block and a test value determined by means of a safety process for the safety-relevant data block.

Description

The invention relates to a cooking utensil for placing on an induction hob of a cooking system for cooking food, a cooking system for cooking food and a method for operating a cooking system.

Conventionally, a temperature sensor installed under a glass plate of the induction hob can be used to monitor the temperature when cooking food using an induction hob in order to prevent the food from overheating.

The EN 10 2016 108 680 A1 relates to a cooking system with at least one first cooking point and at least one cooking utensil, wherein the first cooking point and the cooking utensil are designed to be able to communicate between them by means of structure-borne sound signals.

The EN 10 2020 109 480 A1 relates to an inductive kitchen system with an inductive hob with at least one cooking area with at least one first induction element and with at least one kitchen utensil with at least one electrical energy storage device which is designed to supply electricity to at least one electronic element of the kitchen utensil. The cooking area comprises at least one second induction element, the kitchen utensil comprises at least one induction element, the inductive hob is designed to operate the first induction element of the cooking area such that the kitchen utensil located on the cooking area can be heated, and the inductive hob is designed to operate the second induction element of the cooking area such that the electrical energy storage device of the kitchen utensil located on the cooking area can be inductively charged by means of its induction element.

The EN 10 2020 109 483 A1 relates to an inductive kitchen system with a kitchen appliance with at least one induction element and with at least one piece of kitchenware with at least one electrical energy storage device, which is designed to supply at least one electronic element of the kitchenware with electricity. The kitchenware comprises at least one induction element and the kitchen appliance is designed to operate the induction element in such a way that the electrical energy storage device of the kitchenware located on the induction element can be inductively charged by means of its induction element.

The EN 10 2020 109 484 A1 relates to an inductive kitchen system with an inductive hob with a support surface which is designed to receive at least one piece of kitchenware from above in a freely positionable manner, with a plurality of first induction elements which are arranged below the support surface and are each designed to heat a piece of kitchenware located on the support surface in a freely positionable manner, and with a plurality of second induction elements which are arranged in a predetermined manner below the support surface and are each designed to detect the presence of a piece of kitchenware on the support surface at least substantially directly above them, and with at least the kitchenware with at least one electrical energy store which is designed to supply at least one electronic element of the kitchenware with electricity. The kitchenware comprises at least one induction element and the inductive hob is designed to operate at least one of its second induction elements in such a way that the electrical energy store of the kitchenware located on the support surface can be inductively charged by means of its induction element.

The EN 10 2021 108 578 A1 relates to a kitchen utensil for placing on an induction hob, comprising an inner shell and an outer shell spaced apart from the inner shell by an intermediate space, wherein the inner shell and the outer shell have mutually corresponding mechanical connecting means for mechanically connecting the inner shell to the outer shell in a mechanical connecting position of the kitchen utensil, and the kitchen utensil is designed such that the inner shell can be heated by means of an induction coil of the induction hob when the kitchen utensil is placed on the induction hob, wherein the inner shell and the outer shell each comprise at least one electrical component, wherein the inner shell and the outer shell have mutually corresponding electrical connecting means for at least partially wirelessly or wired electrically connecting the electrical components of the inner shell and the outer shell in an electrically connecting position of the kitchen utensil.

The invention has the object of creating an improved cooking utensil for placing on an induction hob of a cooking system for cooking food, an improved cooking system for cooking food and an improved method for operating a cooking system. According to the invention, this object is achieved by a cooking utensil for placing on an induction hob of a cooking system for cooking food, by a cooking system for cooking food and by a method for operating a cooking system with the features of the main claims. Advantageous embodiments and further developments of the invention emerge from the following subclaims.

The advantages that can be achieved with the invention include an evaluation of the pot bottom temperature in the hob, or in other words an evaluation of the recorded temperature of the bottom of the cooking utensil in an induction hob, and in particular a secure data transmission of safety-relevant data packets via various components, in particular between a unit that originally sends the data and a final receiving unit for which the data is intended. The recorded temperature can be securely transmitted from the cooking utensil to the hob or induction hob. It can be ensured that some of the data is safety-relevant and arrives at a safety controller of the induction hob with appropriate security. This makes secure transmission of the data possible, in particular in accordance with standardization, whereby temperature transmission can be used with encryption, for example using various transmission technologies and not necessarily exclusively radio technology. This can lead to increased security relevance of the transmitted data, so that it can be integrated into safety-relevant technology.

• mindestens einen Temperatursensor, der in einem auf das Induktionskochfeld abstellbaren Boden des Gargeschirrs angeordnet ist, wobei der mindestens eine Temperatursensor ausgebildet ist, um in einem Garbetrieb in einem auf dem Induktionskochfeld abgestellten Zustand des Gargeschirrs mindestens ein Sensorsignal bereitzustellen, das eine erfasste Temperatur in dem Boden des Gargeschirrs repräsentiert; und
• eine Verarbeitungseinrichtung, die mit dem mindestens einen Temperatursensor signalübertragungsfähig verbunden ist, wobei die Verarbeitungseinrichtung ausgebildet ist, um das mindestens eine Sensorsignal auszuwerten, um ein Temperatursignal zu erzeugen, wobei die Verarbeitungseinrichtung ausgebildet ist, um ein Datenpaket zu erzeugen und abgesichert drahtlos an das Induktionskochfeld zu übertragen, wobei das Datenpaket sicherheitsrelevante Daten aufweist, die zumindest das Temperatursignal als sicherheitsrelevanten Datenblock und einen mittels eines Sicherheitsprozesses ermittelten Prüfwert über den sicherheitsrelevanten Datenblock aufweisen.

A cooking utensil for placing on an induction hob of a cooking system for cooking food is presented, whereby the cooking utensil has the following features:

• at least one temperature sensor arranged in a base of the cooking utensil that can be placed on the induction hob, wherein the at least one temperature sensor is designed to provide at least one sensor signal that represents a detected temperature in the base of the cooking utensil during a cooking operation in a state in which the cooking utensil is placed on the induction hob; and
• a processing device which is connected to the at least one temperature sensor in a signal-transmitting manner, wherein the processing device is designed to evaluate the at least one sensor signal in order to generate a temperature signal, wherein the processing device is designed to generate a data packet and to transmit it wirelessly to the induction hob in a secure manner, wherein the data packet has safety-relevant data which has at least the temperature signal as a safety-relevant data block and a test value determined by means of a safety process via the safety-relevant data block.

The cooking utensil can be a pot, a pan or the like for holding food to be cooked. In the cooking mode in the state of the cooking utensil placed on the induction hob, the at least one temperature sensor and additionally or alternatively the processing device can be supplied with electrical energy by means of induction from the induction hob. Additionally or alternatively, the cooking utensil can have an electrical energy storage device for supplying the at least a temperature sensor and additionally or alternatively the processing device. The at least one temperature sensor can be integrated into the base of the cooking utensil. The processing device can be integrated in or on a side wall or one or more handles of the cooking utensil. The processing device can be designed to transmit the temperature signal to the induction hob by radio, in particular via Bluetooth or a similar transmission standard. The data packet can also be referred to as a so-called frame. The check value can be a checksum or the like.

According to one embodiment, the security process can have a cyclic redundancy check. This offers the advantage that errors in data transmission can be reliably detected.

The security-relevant data can also have a continuous packet counter for the data packet. This offers the advantage that all transmitted data packets receive consecutive numbers so that a possible failure or lack of transmission of a data packet can be easily and reliably detected.

Furthermore, the safety-relevant data block can contain identification information for the unique identification of the cooking utensil. This offers the advantage that when using several cooking utensil units on the induction hob, it is easy and precise to determine which cooking utensil delivers which measurement value.

In addition, the data packet can contain additional data that is added outside of the safety-relevant data. This offers the advantage that non-safety-relevant data, such as additional measured values from other sensors or the like, can also be transmitted as additional data in the data packet.

• zumindest ein Exemplar einer Ausführungsform eines hierin genannten Gargeschirrs; und
• das Induktionskochfeld, wobei das Induktionskochfeld ein Schnittstellenmodul, eine Ansteuereinrichtung, ein Bedienmodul und eine elektrische Spule aufweist, wobei das Schnittstellenmodul ausgebildet ist, um das Datenpaket von dem Gargeschirr zu empfangen, wobei die Ansteuereinrichtung und/oder das Bedienmodul ausgebildet ist, um eine Überprüfung des Prüfwerts aus den sicherheitsrelevanten Daten des Datenpakets unter Verwendung des Sicherheitsprozesses durchzuführen, wobei die Ansteuereinrichtung ausgebildet ist, um abhängig von einem Ergebnis der Überprüfung die elektrische Spule unter Verwendung des Temperatursignals aus den sicherheitsrelevanten Daten des Datenpakets anzusteuern.

A cooking system for cooking food is also presented, with the cooking system having the following features:

• at least one example of an embodiment of a cooking utensil mentioned herein; and
• the induction hob, wherein the induction hob has an interface module, a control device, an operating module and an electrical coil, wherein the interface module is designed to receive the data packet from the cooking utensil, wherein the control device and/or the operating module is designed to carry out a check of the test value from the safety-relevant data of the data packet using the safety process, wherein the control device is designed to, depending on a result of the check, control the electrical coil under Using the temperature signal from the safety-relevant data of the data packet.

Such a cooking system offers the advantage that all of the aforementioned advantages can be implemented optimally. The electrical coil can be designed to generate a magnetic field when the power supply is activated, which acts on the cooking utensil when it is placed on the induction hob. The control device can also be referred to as an induction generator or generator controller. The control device can be designed to control or drive the electrical coil by activating and deactivating a supply of electrical current. Only the processing device of the cooking utensil and the control device of the induction hob can be designed to use the safety process.

According to one embodiment, the control device can be designed to deactivate the supply of current to the electrical coil if the temperature signal from the safety-relevant data of the data packet indicates that the temperature in the base of the cooking utensil is above a predefined limit value. This offers the advantage that safe cooking can be ensured, in particular providing reliable protection against overheating of the food being cooked.

The control device can also be designed to deactivate the supply of current to the electrical coil if the test value is incorrect. This offers the advantage that the cooking process can be reliably interrupted or aborted if safety-relevant data is possibly compromised. The evaluation of whether the test value is incorrect can be carried out by the control device and/or by the operating module.

Furthermore, the control device can be designed to deactivate the supply of current to the electrical coil if a continuous packet counter for the data packet is incorrect and, in addition or alternatively, reception of the data packet is interrupted. This offers the advantage that if data transmission is possibly compromised, the cooking operation can be safely interrupted or aborted. The evaluation of whether the data packet is incorrect and/or reception of the data packet is interrupted can be carried out by the control device and/or by the operating module.

• Erzeugen des Datenpakets;
• Übertragen des Datenpakets abgesichert drahtlos an das Induktionskochfeld;
• Empfangen des Datenpakets von dem Gargeschirr;
• Durchführen der Überprüfung des Prüfwerts aus den sicherheitsrelevanten Daten des Datenpakets unter Verwendung des Sicherheitsprozesses; und
• Ansteuern der elektrischen Spule unter Verwendung des Temperatursignals aus den sicherheitsrelevanten Daten des Datenpakets abhängig von einem Ergebnis der Überprüfung.

A method for operating an embodiment of a cooking system mentioned herein is also presented, the method comprising the following steps:

• Creating the data packet;
• Transfer of the data packet securely wirelessly to the induction hob;
• Receiving the data packet from the cooking utensil;
• Performing the verification of the check value from the security-relevant data of the data packet using the security process; and
• Controlling the electrical coil using the temperature signal from the safety-relevant data of the data packet depending on a result of the check.

By carrying out the method, a safe operation of an embodiment of a cooking system mentioned herein, and thus a safe cooking of food, can be achieved, in particular also in so-called remote operation.

Figur 1

eine schematische Darstellung eines Garsystems gemäß einem Ausführungsbeispiel; und

Figur 2

ein Ablaufdiagramm eines Ausführungsbeispiels eines Verfahrens zum Betreiben eines Garsystems; und

Figur 3

eine schematische Darstellung eines Datenpakets gemäß einem Ausführungsbeispiel.

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. It shows

Figure 1

a schematic representation of a cooking system according to an embodiment; and

Figure 2

a flow chart of an embodiment of a method for operating a cooking system; and

Figure 3

a schematic representation of a data packet according to an embodiment.

Before an embodiment of the invention is described in more detail below, the background and principles are first briefly explained.

It can be assumed that the IEC 60335-2-6 standard, relating to the safety of electrical appliances for domestic and similar purposes, will be updated. This will have an impact on future hobs and cookware. In this case, requirements for a temperature limit for cookware in remote operation, for example in assistance or automatic mode, could be tightened. The current version of the standard requires that when the maximum temperature change (+270K) of the food being cooked is reached, the hob is switched off in order to avoid the risk of overheating (risk of fire, spontaneous combustion of oil). According to the current version of the standard, temperature can be recorded using a temperature sensor in the hob, with the generator controller evaluating the temperature and switching off the induction coil if the temperature is too high, with the operating module, for example with an on/off switch, guaranteeing safe switching off. If the current version of the standard still assumes a relatively large amount of food to be cooked (e.g. 3 liters of oil), in the future remote operation could also be used for Smaller quantities (a few millilitres) must ensure compliance with the maximum temperature.

To monitor the pot temperature, for example, a temperature sensor (e.g. NTC) is installed underneath the glass plate in current hobs to measure the temperature. However, due to its design, the sensor measures the temperature of the glass plate. This is not a problem with large fill quantities; the food being cooked (e.g. 3 liters of oil) heats up slowly and the glass plate has almost the same temperature as the pot or the food being cooked. However, the situation is completely different with small fill quantities. Especially with induction cookers, the cooking utensils (pot, pan) heat up very quickly. With small fill quantities, the food being cooked is also heated up quickly. However, the temperature of the glass plate or the temperature sensor can only follow this rapid increase with a delay. This can mean that the switch-off temperature in the sensor is detected too late and temperatures above the switch-off temperature can therefore be reached in the food being cooked. Another point is that the sensors built into the hob are usually placed in several places. It can therefore happen that the cooking utensils are not placed optimally in relation to the temperature sensor and the temperature measurement can also be distorted.

It is therefore proposed here to measure the pot temperature directly in the pot or cooking utensil and to securely transmit the data to a monitoring unit for temperature evaluation.

Figure 1 shows a schematic representation of a cooking system 100 according to an embodiment. The cooking system 100 is designed to cook food or to carry out a cooking operation for cooking food. The cooking system 100 comprises at least one cooking utensil 110 and an induction hob 120. The at least one cooking utensil 110 can be placed on the induction hob 120.

The cooking utensil 110 can also be referred to as cookware. The cooking utensil 110 is, for example, a pot, a pan or the like. The cooking utensil 110 is shaped to hold the food to be cooked. In the illustration of Figure 1 only a cooking utensil 110 is shown, which is placed on the induction hob 120. The cooking utensil 110 comprises at least one temperature sensor 112, 114 and a processing device 116. The at least one temperature sensor 112, 114 is connected to the processing device 116 in a signal-transmitting manner, for example by means of an electrical line, via a radio connection or the like.

The at least one temperature sensor 112, 114 is arranged in a base of the cooking utensil 110 that can be placed on the induction hob 120. The at least one temperature sensor 112, 114 is designed to measure the cooking temperature in a Induction hob 120 to provide at least one sensor signal S that represents a detected temperature in the base of the cooking utensil 110. The processing device 116 is designed to evaluate the at least one sensor signal S in order to generate a temperature signal. The processing device 116 is arranged, for example, in or on a side wall of the cooking utensil 110. The processing device 116 is also designed to generate a data packet Fx and to transmit it wirelessly to the induction hob 120 in a secure manner. The data packet Fx includes safety-relevant data that has at least the temperature signal as a safety-relevant data block and a test value determined by means of a safety process for the safety-relevant data block.

In particular, the processing device 116 is designed to determine the test value for the safety-relevant data block using the security process and to include it in the data packet Fx. According to one embodiment, the security process comprises a cyclic redundancy check. According to a further embodiment, the safety-relevant data also comprises a continuous packet counter for the data packet Fx. In this case, the processing device 116 is designed to add the continuous packet counter to the data packet Fx. According to yet another embodiment, the safety-relevant data block comprises identification information for uniquely identifying the cooking utensil 110. The processing device 116 is designed to include the identification information in the safety-relevant data block. According to one embodiment, the data packet Fx also has additional data that is added outside of the safety-relevant data. In this case, the processing device 116 is designed to add the additional data outside of the safety-relevant data to the data packet Fx.

According to one embodiment, the at least one temperature sensor 112, 114 is designed to be capable of being diagnosed. The processing device 116 is designed to carry out a diagnosis of the at least one temperature sensor 112, 114. The processing device is also designed to generate the temperature signal depending on a result of the diagnosis. In particular, the temperature signal indicates an error state of the at least one temperature sensor 112, 114 if the result of the diagnosis indicates an error of the at least one temperature sensor 112, 114.

Additionally or alternatively, according to one embodiment, the cooking utensil 110 comprises a first temperature sensor 112 and a second temperature sensor 114, which are arranged in the Bottom of the cooking utensil 110. The first temperature sensor 112 is designed to provide a first sensor signal, wherein the second temperature sensor 114 is designed to provide a second sensor signal. For example, the processing device 116 is designed to evaluate the first sensor signal and the second sensor signal in order to generate the temperature signal using the first sensor signal and/or the second sensor signal. In particular, the processing device 116 is designed to compare the first sensor signal and the second sensor signal with one another. In this case, the processing device 116 is further designed to generate the temperature signal depending on a result of the comparison. Advantageously, the temperature signal indicates an error state of the at least one temperature sensor 112, 114 if the result of the comparison represents a difference between the temperatures represented by the sensor signals that is above a predefined threshold value.

The induction hob 120 comprises, merely by way of example, a glass plate 122 or glass ceramic for placing the cooking utensils 110 on. Furthermore, the induction hob 120 comprises an interface module 130 and a hob control device 140, which are connected to one another in a way that is capable of transmitting signals.

In particular, the interface module 130 comprises a communication device 132 and an application device 134. The communication device 132, which can also be referred to as a radio module or transceiver, is designed to receive the data packet Fx from the cooking utensil 110. The application device 134 or application device is designed to output the data packet Fx to the hob control device 140 and optionally also evaluate it.

The hob control device 140 comprises, by way of example only, an operating module 142, a control device 144, an electrical coil 146 and a further temperature sensor 148. The glass plate 122 is arranged between the hob control device 140 and the cooking utensil 110 placed thereon.

The control device 144 and/or the operating module 142 is designed to carry out a check of the test value from the safety-relevant data of the data packet Fx using the safety process. The safety process can only be used by the processing device 116 and by the control device 144 and/or by the operating module 142, in particular because only the latter have knowledge of the safety process. The control device 144 is also designed to carry out a check of the test value from the safety-relevant data of the data packet Fx using the safety process. to control the electrical coil 146 using the evaluated temperature signal from the safety-relevant data of the data packet Fx.

According to one embodiment, the control device 144 is designed to deactivate the energization of the electrical coil 146 if the temperature signal from the safety-relevant data of the data packet Fx indicates that the temperature in the base of the cooking utensil 110 is above a predefined limit value. Additionally or alternatively, the control device 144 is designed to deactivate the energization of the electrical coil 146 if the test value from the safety-relevant data of the data packet Fx is incorrect. Additionally or alternatively, the control device 144 is designed to deactivate the energization of the electrical coil 146 if the continuous packet counter for the data packet Fx is incorrect and/or reception of the data packet Fx is interrupted.

Incorrect data etc. can be detected, for example, by the operating module 142, which then instructs the control device 144 to control the electrical coil 146 accordingly.

Even if it is in the representation of Figure 1 not explicitly shown, for example, protocol-specific and non-safety-relevant data of the data packet Fx can be remotely replaced or changed at at least one intermediate station of the transmission from the processing device 116 to the control device 144.

Safety-relevant components and/or features of the cooking system 100 are Figure 1 highlighted with dashed lines. In particular, the at least one temperature sensor 112, 114, the processing device 116, the secure data transmission or data connection, the operating module 142, the control device 144 and the further temperature sensor 148 are shown as safety-relevant components.

The cooking utensil 110 can have additional sensors, for example temperature sensors or the like, at least one operating element, an electrical energy storage device and/or the like, even if this is not shown in the illustration of Figure 1 is not explicitly shown or merely implied.

Figure 2 shows a flow chart of an embodiment of a method 200 for operating a cooking system. The method 200 for operating is executable to operate the cooking system from Figure 1 or a similar cooking system. Thus, the method 200 is for operating in conjunction with the cooking system of Figure 1 or a similar cooking system. The method 200 for operating comprises a step 201 of generating, a step 203 of transmitting, a step 205 of receiving, a step 207 of executing and a step 209 of controlling.

In the step 201 of generating, the data packet is generated. In the step 203 of transmitting, the data packet is securely transmitted wirelessly to the induction hob. In the step 205 of receiving, the data packet transmitted by the cooking utensil is received. In the step 207 of executing, the check value from the safety-relevant data of the data packet is carried out using the safety process. In addition, the packet counter can be evaluated here. In the step 209 of controlling, the electrical coil is controlled using the temperature signal from the safety-relevant data of the data packet depending on a result of the check carried out in the step 207 of executing. If expected data is not received, for example during a connection interruption, the hob is put into an emergency mode or alternatively switched off.

Figure 3 shows a schematic representation of a data packet Fx according to an embodiment. The data packet Fx can also be referred to as a so-called frame. The data packet Fx corresponds to or is similar to the data packet described in one of the figures described above. In the schematic representation of Figure 3 Subunits of the data packet Fx are shown explicitly.

According to the exemplary embodiment shown here, the data packet Fx comprises the safety-relevant data SR and additional data NSR or non-safety-relevant data. According to the exemplary embodiment shown here, the safety-relevant data SR comprises the safety-relevant data block SRDB, which comprises the temperature signal T and the identification information ID, and also the check value CRC and the continuous packet counter #F. The additional data NSR comprises at least one data block NSR1, NSRn with non-safety-relevant data, such as measured values from other sensors, status information and/or the like.

With reference to the figures described above, embodiments and advantages of embodiments are summarized again below and, in other words, briefly explained.

In the processing device 116 of the cooking utensil 110, data is determined for transmission to other modules of the cooking system 100. This involves safety-relevant data SR and non-safety-relevant data or additional data NSR. The safety-relevant data SR includes, for example, at least the identification information ID for the unique identification of the cooking utensil 110, the Temperature signal T and optionally additional safety-relevant data, such as temperatures, button states (ON/OFF), etc., the continuous packet counter #F and the check value CRC via the safety-relevant data block SRDB. The generation of the checksum or the check value CRC is only known to the transmitter, here the processing device 116 of the cooking utensil 110, and the receiver, here the control device 144 and/or the operating module 142 of the hob 120. The control device 144 and/or the operating module 142 evaluates the received data. If the data is incorrect or, for example, the temperature is too high, the control device 144 switches the generator off or deactivates the current supply to the electrical coil 146. The data is incorrect if the packet counter #F jumps, the check value CRC is incorrect and/or the data reception is interrupted.

According to one embodiment, the data transmission within the cooking system 100 is secured as follows: The data packet Fx sent by the cooking utensil 110, or more precisely by the processing device 116 thereof, includes the safety-relevant data SR and the additional data NSR or non-safety-relevant data. The safety-relevant data SR includes the safety-relevant data block SRDB with the identification information ID and the temperature signal T or the dish base temperature, expanded by the packet counter #F and the check value CRC (cyclic redundancy check), whereby the check value CRC (cyclic redundancy check) is only formed via the safety-relevant data block SRDB. The additional data NSR includes, for example, data from other sensors, e.g. temperature, vibration, position sensors, various status data, such as battery, display, etc.

Claims (10)

Cooking utensils (110) for placing on an induction hob (120) of a cooking system (100) for cooking food, the cooking utensils (110) having the following features: at least one temperature sensor (112, 114) which is arranged in a base of the cooking utensil (110) which can be placed on the induction hob (120), wherein the at least one temperature sensor (112, 114) is designed to provide at least one sensor signal (S) during a cooking operation in a state of the cooking utensil (110) placed on the induction hob (120), which sensor signal represents a detected temperature in the base of the cooking utensil (110); and a processing device (116) which is connected to the at least one temperature sensor (112, 114) in a signal-transmitting manner, wherein the processing device (116) is designed to evaluate the at least one sensor signal (S) in order to generate a temperature signal (T), wherein the processing device (116) is designed to generate a data packet (Fx) and to transmit it wirelessly to the induction hob (120) in a secure manner, wherein the data packet (Fx) has safety-relevant data (SR) which has at least the temperature signal (T) as a safety-relevant data block (SRDB) and a check value (CRC) determined by means of a safety process via the safety-relevant data block (SRDB). Cooking utensil (110) according to claim 1, wherein the safety process comprises a cyclic redundancy check. Cooking utensils (110) according to one of the preceding claims, wherein the safety-relevant data (SR) comprises a continuous packet counter (#F) for the data packet (Fx). Cooking utensil (110) according to one of the preceding claims, wherein the safety-relevant data block (SRDB) has identification information (ID) for uniquely identifying the cooking utensil (110). Cooking utensils (110) according to one of the preceding claims, wherein the data packet (Fx) comprises additional data (NSR) added outside of the safety-relevant data (SR). Cooking system (100) for cooking food, the cooking system (100) having the following features: at least one cooking utensil (110) according to one of the preceding claims; and the induction hob (120), wherein the induction hob (120) has an interface module (130), a control device (144), an operating module (142) and an electrical coil (146), wherein the interface module (130) is designed to receive the data packet (Fx) from the cooking utensil (110), wherein the control device (144) and/or the operating module (142) is designed to carry out a check of the check value (CRC) from the safety-relevant data (SR) of the data packet (Fx) using the safety process, wherein the control device (144) is designed to control the electrical coil (146) using the temperature signal (T) from the safety-relevant data (SR) of the data packet (Fx) depending on a result of the check. Cooking system (100) according to claim 6, wherein the control device (144) is designed to deactivate a current supply to the electrical coil (146) if the temperature signal (T) from the safety-relevant data (SR) of the data packet (Fx) indicates that the temperature in the bottom of the cooking utensil (110) is above a predefined limit value. Cooking system (100) according to one of claims 6 to 7, wherein the control device (144) is designed to deactivate a current supply to the electrical coil (146) if the check value (CRC) is incorrect. Cooking system (100) according to one of claims 6 to 8, wherein the control device (144) is designed to deactivate a current supply to the electrical coil (146) if a continuous packet counter (#F) for the data packet (Fx) is incorrect and/or reception of the data packet (Fx) is interrupted. Method (200) for operating a cooking system (100) according to one of claims 6 to 9, wherein the method (200) comprises the following steps: Generating (201) the data packet (Fx); Transmitting (203) the data packet (Fx) securely wirelessly to the induction hob (120); Receiving (205) the data packet (Fx) from the cooking utensil (110); Performing (207) the verification of the check value (CRC) from the security-relevant data (SR) of the data packet (Fx) using the security process; and Controlling (209) the electrical coil (146) using the temperature signal (T) from the safety-relevant data (SR) of the data packet (Fx) depending on a result of the check.

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