EP4221459A1 - Method for controlling a cooking area - Google Patents

Abstract

The invention relates to a method for controlling a hotplate (11*) comprising the following steps: specification of a parameter for defining a total energy (E_ges), control of a time profile of an energy emitted by a heating device (2). (E_H), whereby the energy (E_H) emitted by the heating device (2) is recorded, the course of the energy (E< sub>H</sub>) has at least two different heating sections (HA1, HA2), which differ in terms of the power output (P_H) emitted by the heating device (2) and wherein the second heating section (HA2) is started as soon as the detected energy (E_H) emitted by the heating device (2) is in a predetermined ratio to the defined total energy (E_ges) stands.

Description

The invention relates to a method for controlling a hotplate. The invention also relates to a device for heating food. Finally, the invention relates to the use of such a device.

There are numerous different cooking processes in which the heating power supplied has to be changed after a certain state or result has been reached. For example, it can be advantageous or even necessary to turn down the heat output of a hob as soon as the food to be cooked has reached a certain state, for example as soon as the water in a cooking vessel has reached the boiling point. A corresponding power control is usually carried out manually by the user. This is error-prone and can lead to unsatisfactory results or, in the worst case, to damage.

It is an object of the invention to improve a method for controlling a hotplate.

This object is achieved by a method in which the power output of a heating device is controlled as a function of a measured energy output by the heating device.

The object is achieved in particular by a method according to claim 1.

It was recognized that it can be advantageous to change the heating power during a cooking process when a predetermined state is reached, in particular after a certain predetermined amount of energy has been supplied.

For this purpose, the cooking process can be divided into different heating sections.

In particular, the preparation of coffee with an espresso pot can be considerably simplified and improved with the aid of the method according to the invention. However, other applications are also possible.

The entire heating process can have one, two or more heating sections. In the case of a plurality of heating sections, they are arranged sequentially. In particular, they can directly follow one another. In principle, intermediate heating sections are also possible.

In a heating section, the power delivered is positive. In an intermediate heating section, the power output from the heater is zero.

The heating sections differ in terms of the power output from the heater. This can be the mean output power. It can also be the maximum output power. It is also possible to vary a clock rate of the activation of the heating device.

The first heating section is in particular a boil-up section, which is also referred to as the boil-up phase. The first The heating section can in particular be selected in such a way that water in a cooking vessel on the hotplate is brought to a boil or at least heated to just below the boiling point.

According to the invention, it can be provided that the total energy required for this, which has to be delivered by the heating device, is specified. This can be done by specifying a parameter to define the total energy. In particular, provision can be made for specifying the amount of water that is to be brought to the boil. If the temperature of this amount of water is known, the total energy required can be calculated or at least approximately estimated.

Assuming that the other parameters that have an influence on the cooking process can essentially be regarded as constant, it can be sufficient to simply specify the amount of water—directly or indirectly—to control the cooking process.

The term "total energy" is not meant to be limiting. It is primarily used to designate the directly or indirectly specified energy. The total energy can in particular be the amount of energy required to reach the boiling point of a certain amount of water. It can also be a different total amount of energy. It is in particular a predeterminable amount of energy that is required to achieve a specific result. This is particularly advantageous for recurring cooking processes.

The energy emitted by the heating device can be detected by sensors. In particular, a device for detecting the power emitted by the heating device can be used for energy detection. An energy meter can also be used to record energy. In particular, provision is made for the energy actually emitted by the heating device to be recorded. It can also be advantageous to record the energy actually consumed by the food to be cooked. As a result, the control process can be made even more precise.

The energy or power can be recorded in a time-resolved manner, in particular clocked. It can be done, for example, with a clock rate of 1 Hertz. Higher or lower clock rates are also possible.

A subsequent heating section, in particular the second heating section, can be started after, in particular as soon as the detected energy emitted by the heating device is in a predetermined ratio to the defined total energy. This can be an absolute or a relative ratio. For example, the second heating section can be started as soon as a certain percentage, for example 60%, 70%, 80%, 90% or 100%, of the specified total energy has been delivered by the heating device (relative ratio).

The second heating section can also begin as soon as the energy emitted in the first heating section differs by less than 30 Wh, in particular less than 20 Wh, in particular less than 10 Wh, from the specified total energy, or when the energy emitted just corresponds to the specified total energy (absolute ratio).

The heating device can be switched off as soon as a predetermined total energy has been emitted by the heating device. In particular, the heating device can be switched off immediately after the end of the first heating section.

According to a further aspect of the invention, provision can be made for the heating device to be switched off automatically directly or after a specified time after the end of a specific heating section, at the latest after a specified period of time. As a result, operational reliability can be increased.

In particular, the heating device can be switched off no later than one hour, in particular no later than half an hour, in particular no later than a quarter of an hour, in particular no more than five minutes, in particular no more than three minutes, in particular no more than two minutes, in particular no more than one minute after the end of the second heating section.

The duration of the second heating section can be specified purely as a duration. The duration of the second heating section can also be determined via the detected energy emitted by the heating device. This makes it possible to achieve cooking results that are particularly reliable and reproducible.

According to a further aspect of the invention, the power (P2) delivered by the heating device in the second heating section is less than the power (P1) delivered by the heating device in the first heating section, P2<P1.

This information relates in particular to the mean output power. It can also be the maximum output power.

In particular, P2:P1<0.7 applies, in particular P2:P1<0.5, in particular P2:P1<0.3.

In particular, P2:P1>0.01, in particular P2:P1>0.1, can apply.

In particular, P2≧10 W, in particular P2≧50 W, in particular P2≧100 W. In particular, P2≦500 W, in particular P2≦300 W, can apply.

Overheating of the food to be cooked can be prevented by reducing the power output by the heating device in the second heating section.

The second heating section can be used, for example, as a warming or simmering phase.

The power P2 emitted by the heating device in the second heating section can also be greater than the power P1, P2 > P1, emitted by the heating device in the first heating section.

If there are more than two heating sections HA _{i ,} the power Pi emitted by the device in the individual heating sections HA _i can decrease successively: Pi>Pj for i>j. This is not mandatory. It can also apply to one or more of the heating sections: Pi < Pj for i < j. According to a further aspect of the invention, the first heating section is terminated after a predetermined energy output by the heating device has been reached, but the second heating section is only started by a user input or in some other way by the user. Between the two heating sections, the heating device can be kept in a waiting mode. This can also be advantageous for some cooking processes.

According to a further aspect of the invention, the power output by the heating device in the second heating section can be controlled to vary over time. In particular, it can increase in the course of the second heating section, in particular increase monotonically, in particular rise linearly.

It can also decrease, in particular decrease monotonically, in particular fall linearly.

In this way, a change in the food to be cooked can be taken into account.

It is also possible to keep the mean and/or maximum power P2 constant in the second heating section.

According to a further aspect of the invention, the power P1 delivered by the heating device in the first heating section is constant. In particular, it can be the maximum output of the heating device. In this way, for example, the time it takes for the boiling point to be reached can be kept as short as possible.

According to a further aspect of the invention, in order to record the energy emitted by the heating device, a voltage present at the heating device and a current intensity flowing through the heating device are measured. This is in particular the voltage applied directly to the heating device or the current strength flowing through it. In this way it is possible to make the control of the heating device dependent on the energy actually emitted by it. Possible fluctuations in the mains voltage are irrelevant.

The heating device can in particular comprise an induction coil. In this case, the voltage applied to the induction coil and the current strength flowing through the induction coil can be measured.

The heating device can also include a radiant heater, in particular be designed as a radiant heater. In this case, the voltage applied to the radiant heater and the current intensity flowing through the radiant heater can be measured.

Appropriate control is also possible with gas cooktops using suitable actuators and/or flow meters.

According to a further aspect of the invention, the profile of the energy and/or power output by the heating device can be selected from a plurality of predefined alternatives.

The alternatives can be stored in a memory. These can be preset presets. Preferably, one or more of the alternatives can be set, in particular programmed.

The alternatives can differ by different values of E _tot , in particular only by different values of E _tot and thus ultimately by the duration of the first heating section.

However, different values of E _tot need not differ in duration. Different amounts of energy can be delivered within the same time due to different power levels.

Different times can also result from the fact that the power fluctuates during the heating sections and, as a result, different durations are required until the specified energy has been delivered.

This enables the user to easily select the right preset for different sizes of an espresso pot, for example.

For example, depending on the size and volume of the cooking vessel, the user can select an alternative that is suitable for this purpose.

In particular, he can choose which size of espresso pot he wants to use at the moment. The control device will then select the curve of the power or the amount of energy delivered that is suitable for the selected variable until the specified amount of energy is reached.

The presettings can be modified, in particular adjusted by the user.

According to a further aspect of the invention, control data for controlling the course of the energy emitted by the heating device are stored in a memory device, it being possible for the control data to be determined in particular by means of an interactive setting protocol.

In particular, it can be provided that the user can manually specify the course of the energy and/or power delivered by the heating device, with the control data for generating a corresponding course being stored in the storage device and then being retrievable as an individual setting. This makes it possible to store one or more user-specific curves of the energy emitted by the heating device in the memory device. This leads to a particularly high degree of flexibility. In particular, this enables the user to call up personal preferences in a reproducible manner. Once the cooking program has been saved, that is to say the course of the amounts of energy emitted by the heating device, reliably leads to a perfect result for the user.

Provision can also be made to record the actual course of the energy and/or power output by the heating device using a recording device (recorder). The recorded process can be stored in the memory device and can then be called up as an individual cooking program. One or more different profiles can be stored in the memory device.

According to a further aspect of the invention, the course of the power/energy emitted by the heating device can be at least in one of the heating sections, in particular in several, in particular in the first heating section and in the second heating section, in particular in all of the heating/heating sections, are automatically selected on the basis of a sensor-detected parameter for characterizing the cooking item. The parameter detected by sensors can be a parameter for detecting the positioning and/or size of a cooking vessel. It can also be the temperature, quantity or other properties of the food to be cooked.

According to a further aspect of the invention, the profile of the energy and/or power output can be selected as a function of a detected size of a cooking vessel used. The size of the cooking vessel can be recorded automatically. The size of the cooking vessel can be detected by sensors.

It is also possible to select the course of the energy and/or power output according to a combination of an individually specified cooking program, which can be stored in particular in the storage device, and sensor-detected properties of the food and/or the cooking vessel. The control device can have a computing unit for this. This can make it possible to scale the course of the output power, in particular stored cooking programs, i. H. to adapt to different sizes of cookware and/or different amounts of food to be cooked, in particular to adapt in an automated manner.

Different presettings can be preset at the factory. Country-specific features, such as the level and stability of the mains voltage, can be taken into account. It is also possible to take into account the local conditions at the end user's location in the factory settings. For example, the average cold water temperature and/or the average atmospheric pressure can be taken into account when specifying the factory settings.

According to a further aspect, the course of the energy and/or power output at the heating device can be recorded by means of a recording device and stored in a memory device. The recording device can optionally also record further control data and/or user inputs.

Using the recording device, which is also referred to as a recorder, individual cooking programs can be recorded and stored so that they can be called up in a reproducible manner.

Another object of the invention is to improve a device for heating food.

The device can in particular be a hotplate according to the previous description.

This object is achieved by a device with a heating device for delivering energy, a control device for controlling the energy delivered by the heating device and a device for detecting the energy delivered by the heating device, the device for detecting the energy delivered by the heating device being data-transmitting is connected to the control device for controlling the energy and/or power output by the heating device, and wherein the energy and/or power output by the heating device can be controlled by means of the control device in such a way that the course of the energy and/or power output by the heating device has at least two different heating sections, which differ with regard to those output by the heating device differentiate performance.

The device is in particular a device for carrying out the method according to the preceding description. With regard to the advantages and further details, reference is made to the previous description.

According to one aspect of the invention, the device has a memory device in which the course of the energy and/or power output by the heating device or control data corresponding thereto are stored.

In particular, the storage device can have a plurality of storage locations for different curves of the energy emitted by the heating device.

According to a further aspect, the course of the energy and/or power output at the heating device can be recorded by means of a recording device and stored in a memory device. The recording device can optionally also record further control data and/or user inputs.

Using the recording device, which is also referred to as a recorder, individual cooking programs can be recorded and stored so that they can be called up in a reproducible manner.

In particular, different cooking programs can be stored in the memory device. From this, the user can, in particular, very easily select the programs that are suitable for the respective food to be cooked.

The cooking programs can be grouped according to categories. For example, there can be a category for searing meat, a category for parboil programs, a category for steaming vegetables, a category for making coffee, and other categories. This list is not to be understood as exhaustive.

It is possible to provide a graphical input device (GUI, Graphical User Interface) for selecting the cooking programs.

In particular, the memory device can be modified, in particular can be adapted by the user to possible preferences and/or circumstances by means of an input device.

In order to record the energy emitted by the heating device, a device with a measuring element for measuring electrical voltage can be provided. The measuring element can be arranged in such a way that it can measure the voltage applied to the heating device, in particular to an induction coil or a radiant heating element.

In order to record the energy emitted by the heating device, a device with a measuring element for measuring the electrical current intensity can be provided. In this case, the measuring element can be arranged in particular in such a way that it measures the current strength flowing through the heating device, in particular through an induction coil or a radiant heating element.

According to a further aspect of the invention, a sensor device can be provided for detecting at least one parameter for characterizing the food to be cooked, which is connected to the control device in a data-transmitting manner in such a way that the course of the energy and/or power output by the heating device is dependent on the at least one parameter detected by the sensor device for characterizing the food to be cooked can be controlled.

This allows the cooking process to be controlled even more reliably.

According to a further aspect, the device can have a recording device for recording a course of the energy and/or power output by the heating device. For further details of the recording device, reference is made to the previous description.

According to a further aspect of the invention, it is provided to use the device described above for the automated preparation of coffee in an espresso pot working according to the percolator principle or in a siphon coffee pot.

Alternative uses are also possible. The control according to the invention of the course of the energy emitted by the heating device is advantageous, for example, in the following cooking processes: searing meat, boiling pasta water, boiling rice, boiling down sauces, boiling jelly. This list is not exhaustive.

Further details, advantages and alternatives of the invention are described below using exemplary embodiments. The corresponding details are not limited to the respective exemplary embodiment, but can be advantageously combined with any selection of the details, features and aspects described above.

Fig. 1

schematisch eine Vorrichtung zum Erhitzen von Kochgut,

Fig. 2

exemplarisch eine Aufsicht auf ein Kochfeld mit einer Vorrichtung zum Erhitzen von Kochgut gemäß Fig. 1,

Fig. 3

exemplarisch einen Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Energie,

Fig. 4

exemplarisch den Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung,

Fig. 5

exemplarisch einen weiteren Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung,

Fig. 6

exemplarisch einen weiteren Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung,

Fig. 7

exemplarisch einen weiteren Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung,

Fig. 8

exemplarisch einen weiteren Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung,

Fig. 9

exemplarisch einen weiteren Verlauf der von einer Heizeinrichtung einer Vorrichtung zum Erhitzen von Kochgut abgegebenen Heizleistung.

The figures show:

1

schematically a device for heating food to be cooked,

2

exemplarily a top view of a hob with a device for heating food to be cooked according to FIG 1 ,

3

an example of a course of the energy emitted by a heating device of a device for heating food to be cooked,

4

exemplarily the course of the heat output emitted by a heating device of a device for heating food to be cooked,

figure 5

exemplarily a further course of the heat output emitted by a heating device of a device for heating food to be cooked,

6

exemplarily a further course of the heat output emitted by a heating device of a device for heating food to be cooked,

7

exemplarily a further course of the heat output emitted by a heating device of a device for heating food to be cooked,

8

exemplarily a further course of the heat output emitted by a heating device of a device for heating food to be cooked,

9

exemplarily a further progression of the heat output emitted by a heating device of a device for heating food to be cooked.

In the following, the structure of a device 1 for heating food to be cooked is first described as an example.

The device 1 for heating food to be cooked comprises a heating device 2 . The heating device 2 has a heating element 3 . An arrangement of one or more induction coils can serve as the heating element 3 . A radiator or a gas burner can also be used as the heating element.

The heating device 2 is connected to a control device 4 in a data-transmitting manner.

The control device 4 is connected to an input device 5 in a data-transmitting manner. The heating device 2 can be controlled by a user by means of the input device 5 . In particular, the heating power emitted by the heating device 2 can be set using the input device 5 .

The control device 4 and/or the input device 5 can be connected to a recording device (not shown) in a data-transmitting manner or can have such a recording device. With the help of the recording device, it is possible to record control data and/or input data and, in particular, to store them as an individual cooking program.

A measuring device 15 is provided for detecting the heating energy emitted by the heating device 2, in particular the heating element 3. The measuring device 15 includes a power meter or an energy meter. The power or energy meter can, as in 1 is shown schematically, a voltmeter 6 and an ammeter 7 have. The voltmeter 6 is connected to the control device 4 in a data-transmitting manner.

The ammeter 7 is connected to the control device 4 in a data-transmitting manner.

The voltage applied to the heating device, in particular to the heating element 3 , can be measured by means of the voltmeter 6 .

The current strength flowing in the same way as the heating device 2 , in particular the heating element 3 , can be measured by means of the ammeter 7 .

With the help of the voltmeter 6 and the ammeter 7, the heating output emitted by the heating device 2, in particular the heating element 3, can thus be measured. About the heating power can be that of the heating device 2 amount of energy actually emitted, in particular the amount of energy actually emitted by the heating element 3, can be measured.

Optionally, the device 1 for heating food to be cooked can have one or more sensors 8 for detecting a parameter for characterizing the food to be cooked. The sensor 8 or the sensors 8 are each connected to the control device 4 in a data-transmitting manner.

A cooking vessel, in particular a pot or a pan, for example, serves as the cooking material. When cooking can in particular one in the 1 schematically shown espresso pot 9 or a siphon coffee pot are used. This is primarily exemplary, in particular not to be understood as limiting.

In the 2 a hob 10 with four hotplates 11 is shown as an example. At least one of the hotplates 11 in which 2 characterized as a hotplate 11 ^∗ , can be operated by means of the device 1 for heating food to be cooked, in particular can be controlled in accordance with the method described in this application.

The hob 10 also includes an integrated device 12 for removing cooking fumes. From the device 12 for removing cooking vapors is in the 2 only the intake opening 14 provided with an inflow nozzle 13 is visible. For further details of the hob 10 and in particular the device 12 for extracting cooking vapors is on DE 10 2019 202 088 A1 referred, which is hereby fully integrated into the present application.

In the following, an operating mode for operating the device 1 for heating food to be cooked is initially described in general terms. The operating mode generally forms an example of a method for heating food to be cooked or a method for controlling the hotplate 11*.

Like in the 3 is shown as an example, the time course of the energy E _H emitted by the heating device 2 is controlled by means of the control device 4 in such a way that there are two different heating sections HA1, HA2, which differ with regard to the energy emitted by the heating device 2 Power P _H differ.

At the in the 3 In the variant shown, the first heating section HA1 lasts from t=0 to t=t ₁ . The heating section HA2 lasts from t=t ₁ to t=t ₂ . In this case, t ₁ and t ₂ are not fixed, but can vary depending on the energy actually delivered, ie the times can still change when the heating sections are already running and "being processed".

The power P _H delivered by the heating device 2 in the first heating section HA1 is shown in FIG 3 drawn as P _H1 . The power P _H delivered by the heating device 2 in the second heating section HA2 is shown in FIG 3 drawn as P _H2 .

In particular, P _H1 >P _H2 applies, for example P _H1 :P _H2 =2.

According to the invention, a total amount of energy E _Ges to be emitted by means of the heating device 2 or the amount of energy E* to be emitted by the heating device 2 in the first heating section HA1 is specified.

The energy E* can in particular be the amount of energy required to bring a specific amount of water to the boiling point at a specified temperature. A slight deviation, for example by up to 5% or up to 10%, is possible here. In particular, E* may be slightly higher or slightly lower than the amount of energy required to boil the given amount of water at a given temperature.

E* can be determined as a function of E _tot . Conversely, it is also possible to determine E _Ges from a specified value of E*.

The boiling point is thus reached at time t ₁ to a good approximation. Subsequently, the heating power emitted by the heating device 2 is reduced in the second heating section HA2. The second heating section HA2 can in particular be a warm-keeping phase.

If a slower approach to the boiling point is desired, E _Ges can also be determined in such a way that this value corresponds to the energy required to reach the boiling point. In this case, the boiling point is only reached at time t ₂ .

After the end of the heating section 2 HA2, the heating device 2 can be switched off. This can take place immediately upon completion of the heating section 2 HA2, ie at time t ₂ . The shutdown can also take place at a later point in time t ₃ >t ₂ . Here, 1 min≦t ₃ ≦10 min can apply.

The control device 4 can be designed in particular such that the output of the heating device 2 heat output at the latest Time t ₃ > t ₂ is reduced to 0. Here, 1 min≦t ₃ ≦10 min can apply.

The device 1 for heating food to be cooked can in particular have a safety shutdown.

In the Figures 4 to 9 different curves of the heating power P _H emitted by the heating device 2 are shown as examples. The different alternatives are not to be understood as exhaustive. Other alternatives are also possible.

4 _{FIG _} 3 is equivalent to. In this example, the heating device 2 has two non-zero power levels P _H1 , P _H2 . The heating power P _H delivered by the heating device 2 is constant within the different heating sections HA1, HA2, at least on average. P _H1 : P _H2 = 2 applies.

At the in the figure 5 variant shown, the heating power P _H emitted by the heating device 2 is constant only in the heating section 1 . The heating power P _H2 emitted by the heating device 2 in the second heating section is decreasing, in particular decreasing monotonically, in particular decreasing strictly monotonically, in particular decreasing linearly.

The heating output _PH2 emitted by the heating device 2 in the second heating section HA2 increases linearly, in particular starting from a value that is smaller than the heating output _PH1 emitted in the first heating section HA1, for example _PH2 ^max = _PH1 : 2 zero off.

At the in the 6 variant shown, the heating power P _H2 in the second heating section HA2, starting from the heating power P _H1 in the first heating section HA1, decreases to zero. An example is in the 6 a mean value P _H2 ^medium is drawn.

At the in the 7 In the variant shown as an example, a pause of length Δt is provided between the first heating section HA1 and the second heating section HA2, during which no heating power is emitted by the heating device 2 ( _{PH(t1,t1+Δt)} =0).

The duration Δt of the interruption can be fixed. It is preferably possible to have the user initiate the second heating section HA2. For example, a warming phase, which is implemented by the second heating section HA2, can be started manually by the user by actuating an input device.

In 8 shows an example of a profile of the heating power P _H emitted by the heating device 2, in which the heating power P _H2 emitted in the second heating section HA2 increases, in particular increases monotonically, in particular increases strictly monotonically, in particular increases linearly.

Other curves of the output heating power P _H , in particular the heating output P _H2 output in the second heating section HA2, in particular non-linear curves, are also possible.

In the 9 is an example of a profile of the heating power P _H emitted by the heating device 2 with three heating sections HA1, HA2, HA3 shown. A larger number of different heating sections HAi is also possible.

The heating power P _H emitted by the heating device 2 in the different heating sections HAi, in particular in the heating sections HAi, i≧2, can in particular also be non-constant, in particular according to one of the previously described variants.

The device 1 described above for heating food to be cooked, in particular the multi-stage method described above for controlling the energy E _H or heating output P _H emitted by the heating device 2, can be used in particular for brewing coffee with an espresso pot, such as those used in EP 0 932 355 B1 is known, or a siphon jug can be used. Particulars, details and advantages are described once more in keywords below.

The method described above for controlling the heating power P _H emitted by the heating device 2 facilitates in particular an automatic brewing of coffee with an espresso pot.

The voltage present at the heating device 2, in particular at the heating element 3, and the current flowing through it are measured at the hotplate 11 ^∗ . The power output can be calculated from this. From this, the emitted energy E _H can be determined, in particular recorded.

The control of the heat output P _H emitted by the heating device 2 enables a predetermined volume of water to be boiled up quickly in the espresso pot. The boiling phase, ie the energy required for the heating phase, can be predicted relatively well from the given volume of water to be boiled. A substantially constant water temperature at the beginning of the brewing process is assumed here. The amount of energy required for a specific volume of water can preferably be determined at a temperature which is lower than the water temperature to be expected in the espresso pot. In this way it can be ensured that the water in the espresso pot actually reaches the boiling point.

After the boiling-up phase, which is also referred to as the heating-up phase, the second heating section HA2 follows. In the second heating section HA2, a lower heating power P _H is emitted by the heating device 2. This can prevent the espresso pot from overheating. The power P _H emitted by the heating device 2 in the second heating section HA2 can in particular be selected in such a way that the water running through the coffee powder has a sufficiently long contact time with the coffee powder.

After the end of the second heating section HA2, most of the water from the espresso pot's boiling container should have flowed through the coffee powder into the espresso pot's collecting vessel.

This can be followed by a warming phase. Finally, the controller 4 switches off the hotplate 11 ^* .

The user can select the automatic function via the input device 5 . It can be started, for example, by actuating the input device 5 twice in quick succession.

The multi-stage control of the hob can be designed in such a way that a predetermined proportion of the required amount of energy, for example 67% of the calculated amount of energy, is emitted by the heating device 2 at maximum heating power P _H ^max . The heating power P _H emitted by the heating device 2 can then be reduced, for example to 50%.

Through the multi-level control of the heating power P _H delivered by the heating device 2, the taste quality of a coffee prepared using an espresso pot can be improved, in particular improved in a reproducible manner, in particular optimized.

The safety shutdown prevents the cooking vessel, especially the espresso pot, from overheating. This also prevents the coffee from becoming bitter.

The required energy can be determined interactively. In particular, it is possible for the user to manually control the heating output P _H or energy E _H emitted by the heating device 2 by means of the input device 5 the first time. The course of the heating power P _H emitted by the heating device 2 can be stored in the memory device of the device 1 . The saved history can be called up for the same filling quantity. This makes brewing coffee with an espresso pot noticeably easier.

For different sizes of the espresso pot, for example two cups, four cups, six cups, eight cups, twelve cups, the energy to be emitted by the heating device 2 can vary E _H or heating power P _H stored, in particular stored.

With the aid of the method according to the invention, the user no longer needs to monitor the brewing process manually.

The automatic limit switch prevents damage to the coffee pot.

Because the energy E _H actually emitted by the heating device 2, in particular in the heating element 3, is detected, the method is independent of disturbances such as a fluctuating supply voltage.

Claims (13)

Method for controlling a hotplate (11*) comprising the following steps: 1.1. Specification of a parameter to define a total energy (E-ges), 1.2. Control of a time profile of a heating device (2) emitted energy (E _H ), wherein 1.2.1. the energy (E _H ) emitted by the heating device (2) is recorded, 1.2.2. the course of the energy (E _H ) emitted by the heating device (2) has at least two different heating sections (HA1, HA2), which differ in terms of the power (P _H ) emitted by the heating device (2), 1.3. wherein a subsequent heating section (HA2, HA3...) is started after the detected energy (E _H ) emitted by the heating device (2) is in a predetermined ratio to the defined total energy (E _tot ). Method according to Claim 1, characterized in that the power (P2) emitted by the heating device (2) in the second heating section (HA2) is less than the power (P2) emitted by the heating device (2) in the first heating section (HA1). P1): P2 < P1. Method according to one of the preceding claims, characterized in that the power (P2) delivered by the heating device (2) in the second heating section (HA2) is controlled to vary over time. Method according to one of the preceding claims, characterized in that to detect the energy (E _H ) emitted by the heating device (2), a voltage present at the heating device (2) and a current intensity flowing through the heating device (2) are measured. Method according to one of the preceding claims, characterized in that the profile of the energy (E _H ) emitted by the heating device (2) can be selected from a plurality of predetermined alternatives. Method according to one of the preceding claims, characterized in that control data are stored in a storage device to control the course of the energy (E _H ) emitted by the heating device (2), it being possible for the control data to be determined using an interactive setting protocol. Method according to one of the preceding claims, characterized in that the progression of the energy (E _H ) emitted by the heating device (2) is automatically selected in at least one heating section (HA) on the basis of a sensor-detected parameter for characterizing the food to be cooked. Method according to one of the preceding claims, characterized in that the course of the energy (E _H ) emitted by the heating device (2) is recorded by means of a recording device and stored in a memory device. Having device (1) for heating food to be cooked 9.1. a heating device (2) for delivering energy (E _H ), 9.2. a control device (4) for controlling the energy (E _H ) emitted by the heating device (2) and 9.3. a device (6, 7) for detecting the energy (E _H ) emitted by the heating device (2), 9.4. wherein the device (6, 7) for detecting the energy (E _H ) emitted by the heating device (2) is connected in a data-transmitting manner to the control device (4) for controlling the energy (E _H ) emitted by the heating device (2), and 9.5. wherein the energy (EH) emitted by the heating device (2) can be controlled by the control device (4) in such a way that
9.5.1. the progression of the energy (EH) emitted by the heating device (2) has at least two different heating sections (HA1, HA2) which differ in terms of the power (PH) emitted by the heating device (2). Device according to Claim 9, characterized in that it has a memory device in which the course of the energy (E _H ) emitted by the heating device (2) or control data corresponding thereto are stored. Device according to one of Claims 9 to 10, characterized in that it has a sensor device (8) for detecting at least one parameter for characterizing the food to be cooked, which is connected to the control device in a data-transmitting manner in this way (4) that the progression of the energy (E _H ) emitted by the heating device (2) can be controlled as a function of the at least one parameter recorded by the sensor device (8) for characterizing the food to be cooked. Device according to one of Claims 9 to 11, characterized in that it has a recording device for recording a profile of the energy (E _H ) and/or power output by the heating device (2). Use of a device according to one of Claims 9 to 12 for preparing coffee in an espresso pot working according to the percolator principle or in a siphon coffee pot.

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