EP4255117A1 - Method for preparing food to be cooked in a cooking device and cooking device - Google Patents

Abstract

The invention relates to a method for preparing food (6, 106) in a cooking appliance (2, 102) with a cooking space (4, 104), the cooking appliance (2, 102) being equipped with at least one heating element (8, 10, 12, 108, 110, 111, 112, 134, 136, 138) for emitting heat to the cooking chamber (4, 104) and/or the food (6, 106) and with a microwave source (26, 126) for emitting microwave radiation the cooking chamber (4, 104) and/or the food to be cooked (6, 106), and wherein the cooking appliance (2, 102) is equipped with a control device (14, 114) with which the at least one radiator (8, 10 , 12, 108, 110, 111, 112, 134, 136, 138) and the at least one microwave source (26, 126) can be controlled. The method is characterized in that it comprises identifying a parameter of the food to be cooked (6, 106) and at least three steps for preparing the food to be cooked (6, 106), wherein in a first step the cooking space (4, 104) is supplied by Heat is heated to a target temperature and the food to be cooked (6, 106) is additionally heated by emitting microwave radiation to the food to be cooked (6, 106) and/or the cooking space (4, 104), • in a subsequent second step, heat to the cooking space (4, 104) and/or the food to be cooked (6, 106) is delivered in such a way that the heat transfer to the food to be cooked (6, 106) is greater than in the first step, • at least during part of the second step the food to be cooked ( 6, 106) is further dielectrically heated by releasing microwave radiation to the food (6, 106) and/or the cooking chamber (4, 104), • in a subsequent third step, the supply of heat to the cooking chamber (4, 104) and/or the food to be cooked (6, 106) is finished and the food to be cooked (6, 106) is further dielectrically heated by emitting microwave radiation to the food to be cooked (6, 106) and/or the cooking chamber (4, 104).The invention relates to also a cooking appliance (2, 102), the control device (14, 114) of which is suitable and designed to carry out such a method.

Description

The invention relates to a method for preparing food to be cooked in a cooking appliance with a cooking chamber, the cooking appliance having at least one radiator for emitting heat to the cooking chamber and/or the food to be cooked and with a microwave source for emitting microwave radiation to the cooking chamber/and or that Food to be cooked is equipped, and wherein the cooking appliance is equipped with a control device with which the at least one radiator and the at least one microwave source can be controlled. The invention also relates to a cooking appliance with a cooking chamber, wherein the cooking appliance is equipped with at least one radiator for emitting heat to the cooking chamber and with a microwave source for emitting microwave radiation to the cooking chamber, and wherein the cooking appliance is equipped with a control device with which the at least one radiator and the at least one microwave source can be controlled.

Food is often prepared in cooking appliances using simple operating modes and heating methods such as top heat/bottom heat, hot air or microwave radiation. This is done with the aim of achieving the best possible cooking quality. To date, the aspect of energy-saving preparation has been given little or no attention. The most common and therefore avoidable aspects of energy waste are unnecessary preheating and not using the energy stored in the device (residual heat). For ovens or other cooking devices, it is typical that only 10 to 20% of the energy used is used to cook the food.

During preparation, a food usually needs to undergo a change in the core (cooking) and on the surface (browning) in order to achieve the desired end result. These two aspects depend on the type and condition of the food and are achieved by chance, if possible at the same time at the time of removal.

The publication EP 2 608 635 A1 discloses a method for operating a cooking appliance with a thermal heating source and a microwave heating source, wherein at least one thermal heating source is used to heat the cooking chamber and that the microwave heating source is additionally switched on at least during a heating phase.

From the DE 10 2016 114 708 A1 a method for operating a cooking appliance is known in which a food item to be cooked is irradiated with high-frequency radiation in different frequency ranges for cooking and browning. In the first frequency range, the food to be cooked is continuously heated (cooked) due to the frequency-dependent penetration depth of the radiation Radiation in the second frequency range has a lower penetration depth, so that the food to be cooked is only heated on the surface and thus browned. In addition, the food to be cooked can be heated specifically close to the surface using at least one thermal heating source.

The DE 10 2019 107 834 A1 discloses a method for operating a cooking appliance for preparing food to be cooked, in which a measurement system is used to determine a measure of browning and a measure of the doneness. For this purpose, a target state can also be set separately. In the process, the food is cooked and browned at a high temperature in a first step and then browned at a low temperature in a second treatment step.

From the publication EP 1 793 300 A1 a cooking method for a cooking appliance is known in which the cooking chamber temperature is regulated depending on the core temperature of the food to be cooked.

Even with one of the DE 10 2016 102 245 A1 Known cooking appliance first carries out a browning step for the food at a high cooking chamber temperature, then low-temperature cooking is carried out. After the browning step, the cooking chamber atmosphere is also cooled down.

In the EP 0 513 721 A2 describes a method for controlling a baking/roasting process in an oven, in which a device is present for ending the baking/roasting process when an adjustable final value is reached. The final value can be a baking/roasting time, but it can also be a core temperature monitored with a temperature sensor skewer. The method also uses a device for switching off the heating energy before the set final value is reached, with a control circuit calculating the switch-off point of the heating energy depending on the size and type of the set final value.

The invention therefore faces the problem of disclosing a method for preparing food to be cooked in a cooking appliance and a cooking appliance for carrying out such a process, in which good preparation quality is achieved using significantly lower energy consumption.

According to the invention, this problem is solved by a method with the features of patent claim 1 and by a cooking appliance with the features of patent claim 15. Advantageous refinements and further developments of the invention result from the following subclaims.

The cooking appliance for carrying out the method is equipped with at least one radiator for emitting heat to the cooking chamber, with a microwave source for emitting microwave radiation to the cooking chamber and with a control device with which radiators and the at least one microwave source can be controlled. The advantages that can be achieved with the invention result from the fact that the method includes identifying a parameter of the food to be cooked and at least three steps for preparing the food to be cooked, wherein in a first step the cooking chamber is heated to a target temperature by supplying heat and the food to be cooked is additionally heated Emission of microwave radiation to the food to be cooked and/or the cooking space is heated, in a subsequent second step heat is released to the cooking space and/or the food to be cooked in such a way that the heat transfer to the food to be cooked is greater than in the first step, at least during one Part of the second step, the food to be cooked is further dielectrically heated by releasing microwave radiation to the food to be cooked and/or the cooking space, and in a subsequent third step the supply of heat to the cooking space and/or the food to be cooked is stopped and the food to be cooked is further released is dielectrically heated by microwave radiation to the food and/or the cooking space.

Food to be cooked in the sense of the application means food that not only needs to be cooked on the inside, but should also be browned on the surface in such a way that a Maillard reaction occurs there. Accordingly, a cooking device in the sense of the registration is a device with which the aforementioned preparation of the food to be cooked can be carried out. A cooking chamber is a part of the cooking appliance that forms a closed area. It holds the food itself or a suitable cooking container in which the food is located and usually has an opening through which the food can be placed in the cooking space and which can be closed by a door. Radiators for emitting heat can be conventional top heat, bottom heat or ring heaters used in cooking appliances such as ovens, with the first two supplying the heat to the cooking space through thermal radiation and thus at least partially giving it off to the food to be cooked, and the latter with the heat in the form of hot air is transported into the cooking chamber and thus also to the food to be cooked using a circulating air fan. However, radiators can also be other devices, described later, with which heat is given off to the cooking space and in particular to the food to be cooked. A microwave source can be a magnetron or a semiconductor-based generator of microwave radiation, preferably in the range of 915 MHz or 2.45 GHz, with which it is possible to emit microwave radiation to the cooking chamber and the food to be cooked therein and thus dielectric heating of the food to be cooked. For the purposes of the application, a distinction is made between heat and microwave radiation in that heat is not generated by a microwave source and microwave radiation is not generated by a radiator. Control device is a device with which programs and program parts are in their process can be influenced. Programs can be simple programs in which the user only sets a type of heating and a cooking chamber temperature, but programs can also be complex processes, in particular automatic programs, in which the individual types of heating and cooking chamber temperatures are varied and the actuators and consumers of the cooking appliance, in particular its heating devices and Microwave sources can be switched on and off and/or the amount of heat and microwave radiation released can be influenced. This influence can occur either as a result of conditions such as reaching a time within a program run and/or the presence of a measured value or as a result of user input. Equipping the cooking appliance with the control device can mean that the control device is structurally integrated into the cooking appliance, but it can also mean that a control device located outside the appliance, for example in a cloud or on a mobile device, is only connected via suitable wired or wireless means communicates with the cooking appliance through data transmission. Mixed forms in which only part of the control device is structurally integrated into the cooking appliance are also conceivable. Identifying a parameter of the food to be cooked is defined in the following paragraphs of the dependent claims. This means that in at least one of the three following steps, one or more parameters, in particular the target temperature, the level of the microwave power causing the microwave radiation, the type and/or amount of heat transfer and/or the duration of the individual steps, are set depending on the parameter can be. The easiest way to increase the heat transfer to the food is to increase the temperature in the cooking chamber. However, it can also be done by directing the transfer of heat to the food to be cooked and therefore at least approximately no increase in the cooking chamber temperature. Suitable means for this are also the subject of the dependent claims. Terminating the supply of heat to the cooking space and/or the food to be cooked in a subsequent third step means that at the beginning of this step, all heating devices with which heat is generated and the associated introduction of heat into the cooking space and/or onto the food to be cooked switched off or reduced to such an extent that they no longer make a significant contribution to the transfer of heat to the food. Stopping the supply of heat to the cooking chamber does not mean that heat already stored in the cooking chamber or adjacent components is used to further warm the food.

As a result of carrying out the method according to the invention, there is a savings potential of up to 50% compared to conventional cooking methods.

In an advantageous embodiment, a parameter of the food to be cooked is the type of food to be cooked and the identification is carried out by a user input or by at least one suitable one Sensor. User input can be made using suitable input means on the cooking appliance or on external devices that communicate with the control device of the device for data transmission. In particular, image-capturing sensors can be used as a sensor, which identify either the food to be cooked itself or a marking arranged on the food to be cooked (which can be removed before the food to be cooked is placed in the cooking space). In this embodiment of the method, the preparation process can be largely automated and the user does not need any knowledge about cooking times or cooking chamber temperatures to be set. This is particularly advantageous because the method according to the invention differs from conventional preparation methods that the user knows or from setting parameters in conventional recipes.

Alternatively or additionally, a parameter of the food to be cooked can be a target temperature, in particular a target core temperature of the food to be cooked, and the identification can take place through a user input or by assigning the target temperature to the identified type of food to be cooked. If it is not a target core temperature, a target temperature can, for example, be a temperature of the surface of the food to be cooked. If the target temperature is not identified through user input, it can be stored in a memory that is assigned to the control device and automatically assigned to the type of food that has already been identified. In this case, it may be possible for the user to influence the target temperature within specified limits by entering a degree of doneness (e.g. rare, medium, well done). The above-described embodiment of the method according to the invention gives the user more freedom to influence the preparation result.

It is also advantageous if at least one of the following parameters depends on at least one of the identified parameters of the food to be cooked: Duration of the first step, target temperature of the cooking chamber in the first step, amount of microwave radiation supplied in the first step, duration of the second step, type and / or amount of energy for heating in the second step, amount of microwave radiation supplied in the second step, duration of the third step, amount of microwave radiation supplied in the third step.

In the first step, the target temperature of the cooking chamber is preferably 0 Kelvin to 40 Kelvin above the entered or assigned target core temperature of the food to be cooked; ideally it is 20 Kelvin above the target core temperature. In this way, a sufficient cooking chamber temperature is specified in order to heat the food effectively and at the same time in an energy-saving manner. The target temperature of the cooking chamber is therefore below a temperature at which a Maillard reaction of the food to be cooked occurs. The amount of microwave radiation supplied can be determined by both the duration and the power of the supplied Microwave radiation can be influenced. Here it is advantageous to supply microwave radiation to the cooking chamber during the entire duration of the first, second and third step with a transmission power of 50 to 500 watts, preferably greater than 100 watts, in particular 100 to 200 watts. In the simplest case, the transmission power is the same in all three steps, but it can also vary. For example, you can start with a higher transmission power in the first step and then reduce it in the second step or in the following two steps. It is also possible that the transmission power in the third step is higher than in the second step, in particular equal to or greater than in the first step. The duration of the second step can depend either on the food to be cooked or, in a particularly advantageous manner, on a sensory-determined property of the surface of the food to be cooked, in particular the browning and/or surface temperature of the food to be cooked. Suitable sensors for determining these properties are cameras, infrared sensors or thermometers. For this purpose, the heat transfer to the food in the second step should be large enough to cause a Maillard reaction in the food. In particular, the surface temperature of the food to be cooked in the second step is above 160°C. Particularly energy-saving types of surface browning are the release of heat in the form of near-infrared waves with a wavelength of approx. 1.2 micrometers, in particular through a quartz or quartz-tungsten radiator, the release of heat through hot air concentrated on the food to be cooked (the so-called impingement method) or the release of heat through a combination of a circulating air fan and a grill heater.

One aspect is that the microwave radiation is supplied to the cooking chamber during all three steps with a transmission power that is the same.

One aspect is that the transmission power during a step is understood to mean the average transmission power of the step.

It is particularly advantageous if the second step is ended when the food to be cooked has a target browning determined by sensors. The target browning can be below the desired final browning, which means that the food can continue to brown in the third step. This measure ensures that the food is only heated with high energy for as long as is necessary to achieve the desired browning.

It is particularly advantageous if the heat supply to the cooking space only begins when the food to be cooked is in the cooking space. This can be ensured in particular by suitable sensors such as weight sensors or a camera. This avoids a heating process, which is usually not necessary, but already uses energy that would be better used to warm the food.

It can be advantageous to support the cooking of the food to be cooked by introducing heated steam in at least one of the steps for additional heating of the cooking space. This means that cooking takes place gently and without the food drying out.

In an advantageous embodiment of the method, the third step is followed by a fourth step, in which heat is supplied to the cooking chamber again after the cooking chamber temperature has fallen below the target temperature. This ensures that the food is cooked to its desired state of doneness.

Fig. 1

eine erste Ausführungsform eines Gargeräts 2 zur Durchführung des erfindungsgemäßen Verfahrens;

Fig. 2

ein Blockschaltbild einer zweiten Ausführungsform eines Gargeräts 102;

Fig. 3

ein Diagramm, in dem der zeitabhängige Energieverbrauch in einem erfindungsgemäßen Verfahren und einem konventionellen Verfahren zur Zubereitung eines Kartoffelauflaufs dargestellt sind.

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

Fig. 1

a first embodiment of a cooking appliance 2 for carrying out the method according to the invention;

Fig. 2

a block diagram of a second embodiment of a cooking appliance 102;

Fig. 3

a diagram in which the time-dependent energy consumption in a method according to the invention and a conventional method for preparing a potato casserole are shown.

Fig. 1 shows a cooking appliance 2 in a first embodiment, which is suitable and designed for carrying out the method according to the invention for preparing food 6. The cooking appliance 2 comprises a cooking space 4 which can be closed by a cooking space door 20 and in which the food to be cooked is placed on a food support 18 suitable for this purpose and selected by the operator. For cooking and browning the food 6, the cooking appliance 2 is equipped with radiators, in the exemplary embodiment shown with a top heat radiator 10 arranged in the cooking space 4, a bottom heat radiator 12 below the cooking space floor and a circulating air heater in the form of a ring heater and a fan, both symbolized by the dashed ring 8. These radiators/heaters 8, 10 and 12 give off heat to both the food 6 and the cooking chamber 4 and its other components (18 and 20). The cooking appliance 2 is also equipped with a microwave source 26, via which microwave radiation from a microwave generator (not shown in the figures (magnetron or semiconductor microwave generator)) can be sent into the cooking chamber 4, whereby the food to be cooked, and only to a small extent also the cooking chamber, are dielectric be heated. Microwaves in the range of 915 MHz or 2.45 GHz are preferably used.

Using an operating and display device 13, programs can be selected and parameters associated with the programs, such as types of heating, temperatures or times, as well as those necessary for carrying out the program can be set Information, for example parameters of the food to be cooked 6 such as the type of food to be cooked or a degree of doneness are identified. A control device 14 controls the programs depending on programs and parameters entered with the operating and display device 13 and / or depending on sensor data that are measured with sensors described below. In particular, the radiators 8, 10 and 12 and the microwave source 26 are controlled or regulated.

The cooking appliance 2 is also equipped with a sensor in the form of a camera 16, with which parameters of the food 6 can be identified. The type of food being cooked and the browning of the food being cooked are of particular interest here. The camera 16 is arranged outside an insulation (not shown) of the cooking space 4 and takes images of the cooking space 4 through a transparent window (not shown). A further sensor in the exemplary embodiment shown is a core temperature measuring probe 24, which can be inserted into the food 6 and determines the core temperature there and passes it on to the control device. As in the exemplary embodiment of the cooking appliance 2 shown, this can be done by radio, but also via a cable, not shown.

Figure 2 shows a second embodiment of a cooking appliance 102 with a cooking chamber 104 and a food support 118, which is suitable and designed for carrying out the method according to the invention for preparing food 106, using a block diagram. Compared to the first embodiment, this cooking appliance not only has a top heat radiator 110, a bottom heat radiator 112 and a circulating air heater 108, but also with a device for generating and introducing hot steam into the cooking space 104 (steam generator 132). Quartz or quartz-tungsten radiator 134, a panel heater 136 and a device 138 for generating and specifically directing hot air to the food to be cooked in an impingement process. The cooking appliance 102 is also equipped with a microwave source 126, via which microwave radiation from a microwave generator 127 can be sent into the cooking chamber 104. The top heat radiator can also be operated at maximum power and/or by connecting another radiator as a grill radiator 111.

Here, too, as in the previous exemplary embodiment, there is an operating and display device 113 with which programs can be selected and parameters associated with the programs such as heating types, temperatures or times can be set, as well as information necessary for carrying out the program, for example parameters of the food to be cooked 106 how the type of food to be cooked can be identified. A control device 114 is also present, which functions in a similar manner to the control device 14.

In addition to the sensors camera 116 and core temperature measuring probe 124 already known from the first exemplary embodiment, a sensor 128 for measuring the surface temperature of the food to be cooked is present in the second exemplary embodiment. This sensor 128 can be an infrared camera, but also a temperature measuring probe 124 with an additional temperature sensor in the handle area. In addition, a temperature sensor 130 is shown in this figure, with the help of which the cooking chamber temperature can be regulated.

The following procedure is carried out with one of the two cooking devices 2 or 102:
In a first step, the food to be cooked is ideally placed in a cold, not preheated cooking chamber. A parameter of the food to be cooked is identified beforehand (then through a user input) or at the same time (then possibly with the help of the camera). This can either be a target temperature of the food to be cooked, in particular the target core temperature, or the type of food to be cooked. After identifying the type of food to be cooked, the control device assigns a target core temperature to the food to be cooked. Additional user input, particularly regarding the degree of doneness or the quantity of food being cooked, can help. The aim of this identification step is for the control device to know at its end a target temperature and/or a target core temperature, which it monitors on the one hand with the help of the core temperature measuring probe and/or the sensor for measuring the surface temperature of the food to be cooked and, depending on which, on the other hand, it determines parameters of the further steps to prepare the food. The cooking space is then heated up using the top heat radiator, the bottom heat radiator, the circulating air heater or a combination thereof. The selection of the radiator can either be set by the user via the operating and display device, or it can be done automatically by the control device depending on the food being cooked. When the cooking space is heated up, the heating energy is already used to warm the food. Heating is preferably carried out via temperature control of the cooking chamber with suitable temperature sensors. The target cooking chamber temperature in this step is 0 Kelvin to 40 Kelvin, ideally 20 Kelvin above the target core temperature of the food to be cooked. This is necessary so that the ambient air is warm enough that the food to be cooked does not cool down on the surface and thus the cooking space air is heated over the food in a very energy-inefficient manner. An excessively high ambient temperature of around 160-200°C, which is the case in the classic combination operation of microwaves and conventional heating, is disadvantageous because the high ambient temperatures heat up the cooking space and its components rather than the food itself and thus unnecessary energy consumption increases. In addition to the heat generated by the aforementioned radiators, microwave radiation with an output of approximately 150 watts is radiated into the cooking space via the microwave source, thereby dielectrically heating the food. The level of performance can be fixed. Alternatively, it depends on the type of food being cooked Target temperature or the target core temperature possible. The dielectric heating in particular results in heating and the associated cooking inside the food to be cooked. The duration of the first step is set by the control device depending on the food to be cooked, the target temperature or the target core temperature.

In the second step, further cooking and browning takes place with a higher heat transfer to the food. The aim is to cause a Maillard reaction on the surface of the food, which causes the food to brown. The heat transfer can be increased in the simplest way by increasing the target cooking space temperature and continuing to use the radiators used in the first step. However, higher heating outputs or other or additional radiators such as the quartz or quartz-tungsten radiator, the panel heater, the device for generating and directing hot air to the food in an impingement process or a combination in which the top heat Radiators are operated with higher power than grill radiators and only the fan of the circulating air heating without the ring heating element. This step is deliberately not done at the beginning of the cooking process because, for example, in the case of casseroles sprinkled with cheese, the browning process is first waited until the cheese has melted in order to achieve an optimal browning result. Furthermore, the first step warms the surface of the food slightly and, if necessary, dries it so that the browning step can then take place faster and more energy-efficiently. It makes sense to continue cooking using microwave radiation during this browning step, since for large-volume foods such as meat and casseroles, cooking in volume is the time-limiting process and separating cooking and browning would be disadvantageous for both time and energy efficiency reasons. The control device sets the duration of the second step, the radiators used, their heating output, the target cooking chamber temperature, and/or the power of the microwave radiation depending on the food to be cooked, the target temperature or the target core temperature. As an alternative to specifying the duration of the second step by the control device, it is particularly advantageous if the second step is ended after the food to be cooked has reached a target browning that is dependent on the food to be cooked or other user input and determined with the camera. It is particularly advantageous if the target browning is below a desired final browning, since the food can continue to brown in a subsequent third step.

In the third step, the target cooking chamber temperature is reduced again to 0 Kelvin to 40 Kelvin, ideally 20 Kelvin above the target core temperature of the food to be cooked. This means that in this step the supply of heat to the cooking space and/or the food to be cooked is initially stopped. The microwave source remains switched on and dielectrically heats the food. The power of the microwave radiation can again depend on the type of food being cooked, depending on the target temperature or the target core temperature or be permanently set to approx. 150 watts. The residual heat from the radiators used for browning is also used to continue cooking the food, browning it further and protecting the surface from cooling down. Only when the target cooking chamber temperature falls below are the top heat, bottom heat and/or circulating air heating switched on again in a fourth step.

Since the duration of cooking in volume and browning of the surface are usually not identical, a sensible sequence of times is necessary as to when cooking and when browning should take place and with what intensity. In the simplest case, the cooking process steps can be time-controlled. However, it is even better if, ideally, sensors (such as core temperature sensors, cooking chamber cameras, moisture sensors) are used, which can provide information about the condition of the surface and the core/volume during the cooking process and thus enable dynamic control of the individual cooking steps. In addition to the heating methods described here, support with heated steam from the steam generator is also conceivable, especially in the first and/or second step.

Since food items differ greatly in how quickly they cook and how quickly they brown and what their desired target state is, in order to ensure the most energy-efficient cooking process possible, it makes sense to adapt the process to the food being cooked and therefore, in the best case scenario, to know the type of food being cooked. This is possible either by manually entering the type of food to be cooked or by automatic food recognition, for example via a camera. By knowing the food being cooked, the sensors can then be used specifically to recognize characteristics typical of the food being cooked and thus start/finish individual cooking steps. For example, a camera can be used to detect when cheese has melted on a casserole so that the energy-efficient step of browning the food can then be started. For a piece of meat, for example, this step could take place when a certain core temperature (for example 20 Kelvin below the target core temperature) has been reached.

In Figure 3 and in the following text, for further explanation, an example is given using a potato casserole in which real measured values were collected and compared with the energy consumption in a conventional cooking process. For this purpose, the potato casserole was placed in the cold cooking space (step 0). It was then cooked in volume in a first step (I) with circulating air heating at 120 ° C and with microwave radiation (150 W). After 15 minutes, the melting of the cheese was complete (measurable via the camera sensor) and the second step (II) for energy-efficient browning was started. For this purpose, the top heat radiator was at maximum power operated. The volume cooking using microwaves continued in parallel. Tanning was then stopped when a certain target tanning was achieved (recognizable via the sensor camera or via time control). In the following third step (III), the target cooking chamber temperature was reduced again to 120°C and the residual heat from the device and cooking using microwaves were used to achieve the target core temperature of 99°C (measurable via a core temperature sensor). to reach.

Compared to conventional cooking, which also took place without preheating and therefore used the warm-up energy, an energy saving of 15% could be achieved in the example shown here.

Reference symbol list First embodiment

2

cooking device

4

cooking space

6

Food to be cooked

8th

Circulating air heating

10

Top heat radiator

12

Bottom heat radiator

13

Operating and display device

14

Control device

16

camera

18

Food carrier

20

cooking compartment door

24

Core temperature measuring probe

26

Microwave source

Second embodiment

102

cooking device

104

cooking space

106

Food to be cooked

108

Circulating air heating

110

Top heat radiator

111

Grill radiator

112

Bottom heat radiator

113

Operating and display device

114

Control device

116

camera

118

Food carrier

120

cooking compartment door

124

Core temperature measuring probe

126

Microwave source

127

Microwave generator

128

Sensor for measuring the surface temperature of the food being cooked

130

Temperature sensor (for measuring the cooking chamber temperature)

132

Steam generator

134

Quartz or quartz-tungsten emitters

136

Panel radiators

138

Device for generating and directing hot air in a targeted manner

Claims (15)

Method for preparing food (6, 106) in a cooking appliance (2, 102) with a cooking chamber (4, 104), the cooking appliance (2, 102) being equipped with at least one heating element (8, 10, 12, 108, 110, 111, 112, 134, 136, 138) for emitting heat to the cooking chamber (4, 104) and/or the food to be cooked (6, 106) and with a microwave source (26, 126) for emitting microwave radiation to the cooking chamber (4 , 104) and/or the food to be cooked (6, 106), and wherein the cooking device (2, 102) is equipped with a control device (14, 114) with which the at least one radiator (8, 10, 12, 108 , 110, 111, 112, 134, 136, 138) and the at least one microwave source (26, 126) can be controlled, characterized in that
in that the method includes identifying a characteristic of the food to be cooked (6, 106) and at least three steps for preparing the food to be cooked (6, 106), wherein • In a first step, the cooking space (4, 104) is heated to a target temperature by supplying heat and the food (6, 106) is additionally heated by emitting microwave radiation to the food (6, 106) and/or the cooking space (4, 104) is heated, • In a subsequent second step, heat is given off to the cooking chamber (4, 104) and/or the food to be cooked (6, 106) in such a way that the heat transfer to the food to be cooked (6, 106) is greater than in the first step, whereby at least during part of the second step the food (6, 106) is further dielectrically heated by emitting microwave radiation to the food (6, 106) and/or the cooking space (4, 104), • In a subsequent third step, the supply of heat to the cooking chamber (4, 104) and/or the food to be cooked (6, 106) is stopped and the food to be cooked (6, 106) continues by releasing microwave radiation to the food to be cooked (6, 106 ) and/or the cooking space (4, 104) is dielectrically heated. Method according to claim 1, characterized in that the microwave radiation is supplied to the cooking space during the entire duration of the first, second and third step with a transmission power of 50 to 500 watts, preferably 100 to 500 watts, in particular 100 to 200 watts. Method according to one of the preceding claims, wherein the microwave radiation is supplied to the cooking chamber during the first step and during the second step with a transmission power which is greater than or equal to the transmission power in the second step. Method according to one of the preceding claims, wherein the microwave radiation is supplied to the cooking chamber during all three steps with a transmission power which is the same. Method according to one of the preceding claims, wherein a parameter of the food to be cooked (6, 106) is the type of food to be cooked and the identification is carried out by a user input or by at least one suitable sensor (16, 116). Method according to one of the preceding claims, wherein a parameter of the food to be cooked (6, 106) is a target temperature, in particular a target core temperature of the food to be cooked (6, 106), and the identification is carried out by a user input or by assigning the target temperature to the identified type of food to be cooked. Method according to at least one of the preceding claims, wherein at least one of the following parameters depends on at least one of the identified parameters of the food to be cooked (6, 106): duration of the first step, target temperature of the cooking space (4, 104) in the first step, quantity of food supplied Microwave radiation in the first step, duration of the second step, type and/or amount of energy of heating in the second step, amount of microwave radiation supplied in the second step, duration of the third step, amount of microwave radiation supplied in the third step. Method according to at least one of the preceding claims, wherein the target temperature of the cooking chamber (4, 104) in the first step is below a temperature at which a Maillard reaction of the food to be cooked occurs, and that the heat transfer to the food to be cooked (6, 106) in the second step is large enough to produce a Maillard -Reaction of the food to be cooked (6, 106).
and or the target temperature of the cooking space (4, 104) in the first step is approximately at a temperature that is 0 to 40 Kelvin, preferably about 20 Kelvin, above the target core temperature defined as a parameter of the food (6, 106) to be cooked in the cooking space and that the surface temperature of the Food (6, 106) in the second step is above 160°C. Method according to at least one of the preceding claims, wherein the heat supply to the cooking space (4, 104) only begins when the food (6, 106) is in the cooking space (4, 104). Method according to at least one of the preceding claims, wherein in at least one of the steps, preferably in the first and/or second step, heated steam is introduced for additional heating of the cooking space (4, 104). Method according to at least one of the preceding claims, wherein the third step is followed by a fourth step, in which heat is supplied to the cooking chamber (4, 104) again after the cooking chamber temperature has fallen below the target temperature. Method according to at least one of the preceding claims, wherein in the second step heat is emitted in the form of near-infrared waves with a wavelength of approximately 1.2 micrometers, in particular by a quartz or quartz-tungsten radiator (134). Method according to at least one of the preceding claims, wherein in the second step heat is released by hot air concentrated on the food (6, 106). Method according to at least one of the preceding claims, wherein in the second step heat is given off by a combination of a circulating air fan and a grill heater (111). Cooking appliance (2, 102) with a cooking space (4, 104), the cooking appliance having at least one radiator (8, 10, 12, 108, 110, 111, 112, 134, 136, 138) for emitting heat to the cooking space (4, 104) and is equipped with a microwave source (26, 126) for emitting microwave radiation to the cooking chamber (4, 104), and wherein the cooking appliance (2, 102) is equipped with a control device (14, 114), with which of the at least one radiator (8, 10, 12, 108, 110, 111, 112, 134, 136, 138) and the at least one microwave source (26, 126) can be controlled,
characterized,
that the control device (14, 114) is suitable and designed and set up to carry out a method according to at least one of the preceding claims.

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