ES2754813A1 - Cooking Appliance Device (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Cooking appliance device. The present invention relates to a cooking appliance device (10), in particular a cooking range device, with a control unit (12) which is intended to activate and supply energy to at least a first objective of induction (14) and at least one second induction target (16). In order to improve activation related properties, it is proposed that, in the event of one or more conditions related to tolerances between the first induction target (14) and the second induction target (16), the unit (12) is intended to enter at least one special operating state, in which the control unit (12) is intended to bring together the first induction target (14) and the second induction target (16) in a common induction target (32) and to match each other a first heating frequency to activate the first induction target (14) and a second heating frequency to activate the second induction target (16). (Machine-translation by Google Translate, not legally binding)

Description

COOKING APPLIANCE DEVICE

The present invention relates to a cooking appliance device according to the preamble of claim 1 and to a method for putting into operation a cooking appliance device according to the preamble of claim 14.

From the state of the art, the cooking fields that have inductors that are operated with heating frequencies adapted to each other to avoid acoustically perceivable coupling noise are already known, where the control schemes to direct the inductors to heat the cooking pans, they are determined in a complex process of determination and calculation as a consequence of the increasing demands of the buyers as regards the quality of control and the functionality of a cooking field, which creates great demands on As for the manufacturing and the incorporated components and, therefore, it has the consequence that the costs are high. The specification EP 1 951 003 B1 discloses in this regard a procedure for the inductive and simultaneous actuation of two inductors of an induction cooking field in order to avoid the generation of coupling noises and the current network to be charged with non-uniformly in time, where, in the process, the inductors are operated in a first time interval with a first heating frequency and, in a second time interval, with a second heating frequency different from the first frequency of heating. On the other hand, the specification US 7,910,865 B2 discloses a method for operating an induction cooking field, in which the inductors are operated during a mode with a common heating frequency and, in another mode, they are actuated in each case with different heating frequencies, the heating frequencies presenting a separation between frequencies between 15 kHz and 25 kHz.

The present invention solves the technical problem of providing a generic cooking appliance device with better properties in terms of its activation. According to the invention, this technical problem is solved by the features of claims 1 and 14, while advantageous embodiments and improvements of the invention can be extracted from the secondary claims.

The invention relates to a cooking appliance device, in particular a cooking range device, with a control unit which is intended for defining at least a first induction target and at least a second induction target and for activating and supplying energy to at least a first induction target, in particular the first mentioned induction target, and at least a second induction target, specifically, to the second induction objective mentioned, where, if there is, specifically, in the event that one or more conditions regarding the tolerances between the first induction objective and the second induction objective are met, the control unit is intended to enter at least a special operating state, in which the control unit is intended to bring together the first induction target and the second induction target into a common induction target and to adapt one to the other a first heating frequency to activate the first induction target and a second heating frequency to activate the second induction target tion, in order to prevent crosstalk from occurring and / or flicker (flicker) and / or the mains is loaded unevenly over time.

By the embodiment according to the invention, a generic cooking appliance device can be provided with better properties in terms of simplified activation and quiet operation. Thanks to this simplified activation, the complexity of determining control schemes can be significantly reduced. In this way, it is possible to use economical and / or lower performance components. With a number of induction targets, the increasing complexity can be exponentially reduced to drive the theoretical heating power desired by the user. Thus, simple power control is made possible. In this way, the user can be prevented from suffering from a disadvantageous acoustic load, so that it is possible to achieve great comfort of use and cause a positive impression on the user about the acoustic quality. Preferably, thanks to the advantageous control of the individual induction targets, flicker can be prevented in accordance with the flicker standard, that is, in accordance with DIN EN 61000-3-3. Also, it is possible to achieve a safe embodiment, preferably with regard to the theoretical heating power requested by the user. In particular, it is possible to simultaneously drive several induction targets together, advantageously quietly and with a low jitter load on the supply network. Furthermore, the control unit can define a third induction target and, advantageously, as many induction targets as desired, which can be brought together by the control unit into one or more common induction targets in the operating state. special. There may be multiple induction targets that are brought together by the control unit into one or more common induction targets. The Induction targets can be simultaneously powered from one or more power sources. The control unit directs the energy supply to the induction targets from the energy source (s). The common induction target can be a combination of two or more induction targets. Also, there can be multiple independent induction targets that can be activated by the control unit in the special operating state with heating frequencies, avoiding the generation of coupling noises.

The term "cooking appliance device", advantageously "cooking range device" and, particularly advantageously, "induction cooking range device" includes the concept of at least one part, namely a constructive subgroup, of a cooking appliance, in particular of a cooking oven, for example of an induction cooking oven and, advantageously, of a cooking range and, particularly advantageously, of a cooking range induction cooking. Advantageously, the household appliance featuring the cooking appliance device is a cooking appliance. The domestic appliance made as a cooking appliance could be, for example, a cooking oven and / or a microwave appliance and / or a grill appliance and / or a steam cooking appliance. Advantageously, the domestic appliance made as a cooking appliance is a cooking range and, preferably, an induction cooking range.

The term "energy source" includes the concept of a unit that provides electrical energy in the form of electrical voltage, electric current and / or an electric and / or electromagnetic field to at least one other unit and / or at least one circuit of electric current. The power source may be a phase of electrical current from a power supply network. The power source can supply a maximum power of 3.7 kW. Advantageously, between the power source and at least one induction target, preferably all induction targets, an inverter may have been arranged to provide a high-frequency supply voltage with the appropriate heating frequency. The power source may have an inverter unit. The inverter unit can have at least one, also several inverters, to provide a high frequency supply voltage with the appropriate heating frequency for the induction purposes.

The term "induction target" includes the concept of at least a part of a cooking battery and at least one inductor or several inductors to heat at least the part of the cooking battery, where the inductors are advantageously driven with a frequency of common heating.

The term "first and / or second induction target” includes the concept of a group of an inductor or several inductors that are operated together with the same heating frequency of the same energy source for the same duration of a period and which they heat in at least one operating state at least a part of the same cooking coil, where, if there are more than two inductors in the group that heat the same cooking coil, they are arranged continuously, and where no other group of Inductors that are powered from the same hot power source by the same part of the cookware The control unit can define and / or redefine the desired induction targets as the first or second induction targets. expression that inductors are arranged "continuously" includes the concept that inductors belong to the same group and border on at least one of the inductors in the group, not having any other inductor in the middle.

The term "common induction objective” includes the concept of an induction objective that comprises at least a first and at least a second induction objective and which is treated by the control unit as a single induction objective when determining at least a control scheme, where the two induction targets can be operated with the same heating frequency, or also with different heating frequencies.

The term "inductor" includes the concept of an element that in at least one operating state supplies energy in the form of an alternating magnetic field to at least one cooking battery in order to heat it, where said alternating magnetic field is intended to cause a metallic heating medium, preferably at least partially ferromagnetic, in particular in a firing coil, eddy currents and / or magnetic reversal effects that transform into heat. The inductor has at least one induction coil and is intended to supply the cooking coil with energy in the form of an alternating magnetic field with a heating frequency The inductor is arranged below and, advantageously, in an area close to at least one support plate of the cooking apparatus device A projection of the inductor can have different shapes, for example a circular, oval or approximate shape or exactly e rectangular. The term "roughly or exactly" includes here the concept that the deviation from a predetermined value amounts to less than 25%, preferably less than 10%, and particularly preferably less 5% of the default value. Inductors can have different dimensions comparing them to each other. Advantageously, the cooking apparatus device has multiple inductors that can be arranged as a matrix, where the inductors arranged as a matrix can form a variable cooking surface.

Alternatively or additionally, inductors can form a cooking surface that has fixedly defined cooking zones. At least one inductor or part of an inductor, and in particular exactly one inductor, can be assigned to fixedly defined cooking zones. The expression "fixedly defined" cooking zone includes the concept of a cooking zone whose position is fixed and / or predetermined by at least one property, for example, by at least one constructive and / or electrical and / or spatial property , and / or by at least one marking, in any operating state invariably and / or irrespective of the setting of the induction targets and / or the setting of the cookware. For example, a zone Defined firing range could be invariably and / or constantly fixed by connecting the inductors assigned to the fixedly defined cooking zone to a common phase of the electric current and / or by the spatial arrangement of the inductors assigned to the fixedly defined cooking zone Inductors are combinable with each other on induction targets of any size and with different contours.

The term "control unit" includes the concept of an electronic unit that is preferably integrated, at least in part, into a control and / or regulating unit of a cooking appliance device, in particular of a cooking field device. cooking and, advantageously, of an induction cooking field device, and which is intended to direct and / or regulate at least one inverter unit of the cooking apparatus device with at least one inverter, in particular, an inverter resonant and / or a double half-bridge inverter The control unit evaluates the signals supplied by a unit, specifically a sensor and / or detection unit, after which the control unit can start a process and / or special operating state if one or more conditions are met Preferably, the control unit comprises a calculation unit and, in addition to the calculation unit, a storage unit with a program of control and / or regulation stored in it, which is intended to be executed by the calculation unit. The cooking appliance device may have a connection unit. The connection unit is driven by the control unit, where the connection unit establishes an electrical connection between at least one energy source and at least one energy consumer, for example the induction target. Connection unit it can have at least one electromechanical or semiconductor-based connection element and is intended to establish at least an electrical connection between the power source and the induction target. The term "connecting element” includes the concept of an element that is intended to establish and / or separate an electrically conductive connection between two points, namely, contacts of the connecting element. Preferably, the connecting element has at least a control contact through which it can be connected. The connection element is realized as a semiconductor connection element, in particular as a transistor, for example as a semiconductor metal-oxide field effect transistor (MOSFET), advantageously , as a bipolar transistor with preferably an isolated gate electrode (IGBT) As an alternative, the connection element is made as a mechanical and / or electromechanical connection element, in particular as a relay.

The term "special operating state” includes the concept of an operating state that differs from a normal operating state in which the control unit directs each induction target separately and drives them separately and independently of each other. The control unit checks whether there is at least one condition regarding tolerances between at least the first induction target and at least the second induction target and, if any, it enters the special operating state. For example, the control unit checks to what extent the respective average output heating power of the first and / or second induction target changes with respect to the theoretical heating power, which is adjustable by a theoretical heating frequency, from the first and / or second induction target by varying the respective heating frequency with respect to the theoretical heating frequency a respective in each frequency interval. In the event that the average output heating power is within a tolerance range, which in this embodiment is the condition related to tolerances, and the respective frequency ranges overlap, that is, that the first and the second induction target can be operated within the tolerance range with a common heating frequency, the control unit initiates the special operating state and / or enters the special operating state.

In the special operating state, several induction targets are brought together by the control unit into a common induction target that is actuated as an individual induction target, that is, autonomous, where the induction targets are activatable by the control unit adapted to each other. In the state of special operation, a specific activation of a unit takes place, specifically, the induction targets, and / or the control unit applies a specific procedure and / or algorithm to the unit and, specifically, to the induction targets, where the control unit operates the induction targets in a manner adapted to each other. In a normal operating state, the control unit operates the different induction targets independently of each other, simultaneously, and with its own heating frequency in each case.

In any operating state, the control unit adjusts at least one output heating power of at least the first and / or the second induction target and / or the common induction target, advantageously at least a large part of the Output heating powers of the first and / or second induction target and / or common induction target and preferably all output heating powers of the first and / or second induction target and / or the common induction, through a heating frequency and / or through a duty cycle. The term "output heating power" of the first and / or second induction target and / or the common induction target includes the concept of the electrical power of the inductors of the first and / or second induction target and / or of the common induction target supply in at least one operating state to a cooker battery of the first and / or second induction target and / or the common induction target to heat it for a time interval.

The term “coupling noise” includes the concept of acoustic intermodulation noise perceivable for humans and pets with a middle ear, which can be produced by the intermodulation of heating frequencies as a consequence of the electrical supply to different targets. induction and present an intermodulation frequency of between 10 Hz and 65 kHz and preferably between 20 Hz and 20 kHz.

The term "flicker" includes the concept of a subjective impression of visually perceived instability, which is caused by a light stimulus whose luminance or spectral distribution fluctuates over time. Flicker can be caused in particular by a decrease in grid voltage .

The term "define an induction target" includes the concept of a process in which one or more inductors are assigned to at least a part of a cookware that is partially or completely arranged above the inductor on a bearing surface of the cooking appliance device, in order to heat it.

The expression that several heating frequencies are "adapted to each other" includes the concept that heating frequencies meet or have a logical condition or functional relationship valid at least for the duration of a period, for example, a reciprocal frequency spacing or a fixed factor between the heating frequency values.

The term "intended" includes the concept of programmed, specifically conceived and / or provided. The expression that an object is intended for a specific function includes the concept that the object satisfies and / or perform this particular function in one or more application and / or operating states.

The condition regarding tolerances could be a condition on the maximum separation between frequencies between the theoretical heating frequencies of the first and second induction targets. Therefore, the control unit could gather those theoretical heating frequencies close to each other that do not exceed the maximum separation between frequencies if the respective power curves of the first and second induction targets have similar characteristic properties, such as, for example, a similar evolution. The condition regarding tolerances could be a condition on a frequency separation between the theoretical heating frequencies of the first and second induction targets of at least 17 kHz, advantageously at least 20 kHz. However, the condition on the maximum separation between frequencies between the theoretical heating frequencies of the first and the second induction target and / or the condition on the separation between frequencies between the theoretical heating frequencies of the first and the second induction target of Advantageously, at least 17 kHz, at least 20 kHz, can cause average output powers which, for cooking operation, have disadvantageous deviations from the theoretical heating powers, which may, for example, result in the cooking time is longer or the cooking product burns, so the condition regarding tolerances presents other criteria along with the conditions mentioned above.

Likewise, it is proposed that the condition related to tolerances be a condition on the maximum deviation of the respective mean output heating power, dependent on the heating frequency, of the two induction targets with respect to the respective theoretical heating power of induction targets in continuous operation with the respective heating frequency, in particular with the first or second frequency of heating. In this way, the user-adjusted heating power can be advantageously controlled and / or accurately provided. The term "average output heating power" includes the concept of the output heating power of an induction target averaged over a period duration. The average output heating power of each particular inductor of the Cooking in continuous operation for a range of heating frequencies in which the inductors are activatable by the control unit in at least one operating state can be stored in at least one table of values in a storage unit of the heating unit. control and can be recoverable by the control unit or determinable from the table of values.Alternatively or additionally, the control unit can start before the start of the special operating state a time-limited test operating state. , which has a duration of several and, advantageously, exactly the duration of a period, with n in order to determine the average output heating power that is generated during continuous operation of each individual inductor of the activated induction targets and / or each induction target. In the test operating state, the control unit can perform a frequency sweep during which the control unit measures for all theoretical heating frequencies over a range of frequencies intended for an operating state, in particular for In all operating states, the theoretical heating power which is generated during continuous operation when an induction target is activated with the theoretical heating frequency and is plotted and stored as a curve of the power itself for each induction target. The term "theoretical heating power" includes the concept of the heating power set and / or requested by the user for a cooking process, where the theoretical heating power is adjustable by means of the theoretical heating frequency.

Furthermore, it is proposed that, in accordance with the condition regarding tolerances, the maximum deviation is within a tolerance range of 15% / - 15%. In this way, it is possible to safely provide the heating power requested by the user. Thus, control can be simple for the user, so that buyer satisfaction can be increased. In addition, the danger of the cooking product sticking and / or burning during a cooking process can be further prevented by the lower upper limit of the tolerance range of 5% compared to the lower limit of the range of tolerance of It is also proposed that, in the special operating state and depending on the situation, the control unit choose the first heating frequency and the second heating frequency with a reciprocal frequency separation of 20 Hz maximum and, advantageously, 0 kHz. Advantageously, the control unit drives the first induction target and the second induction target with a common heating frequency. The expression "depending on the situation" includes the concept that there is a condition regarding tolerances, advantageously, that the condition regarding tolerances is fulfilled, between the first induction objective and the second induction objective In this way, it is possible to easily control the average output heating powers The respective average output heating power of the first and second induction targets deviates from the corresponding theoretical heating power within the tolerance range The sum of the respective mean output heating powers of the first and second induction targets has a deviation from the sum of the corresponding theoretical heating powers within the tolerance range.

Alternatively, it is proposed that, in the special operating state and depending on the situation, the control unit chooses the first heating frequency and the second heating frequency with a reciprocal frequency separation of at least 17 kHz. In this way, coupling noises can be avoided during simultaneous operation of the first and second induction targets. Furthermore, it is possible to create a simplified control sequence of inductor heating frequencies and / or induction targets. The respective average output heating power of the first and second induction targets has a deviation from the corresponding theoretical heating power within the tolerance range. The sum of the respective mean output heating powers of the first and second induction targets has a deviation from the sum of the corresponding theoretical heating powers within the tolerance range.

Furthermore, it is proposed that, in the special operating state, the control unit chooses the separation between frequencies depending on the theoretical powers chosen for the two induction objectives. Thus, the output heating power can be more accurately provided. The control unit checks the deviation of the average output heating power respective of the first and second induction objective with respect to the corresponding theoretical heating power and / or the sum of the respective average output heating powers of the first and second induction objective with respect to the sum of the powers of corresponding theoretical heating for the separation between frequencies of 0 Hz and the separation between frequencies of at least 17 kHz, and advantageously chooses the separation between frequencies with the smallest deviation from the theoretical heating power of the first and / or second induction target and / or with respect to the sum of the theoretical heating powers of the first and second induction targets.

Likewise, it is proposed that the control unit be provided in the special operating state to treat the common induction target as a single induction target by determining at least one control scheme to activate the two induction targets, specifically, the first and second induction targets, and at least one other induction target, and specifically several other induction targets. In this way, the number of induction targets is reduced by at least the number of induction targets combined minus one, whereby the control scheme can be advantageously simplified. Thus, the supply of the output heating power can be advantageously controlled. In the special operating state, the control unit is designed to operate the common induction target, that is, the first and second induction targets, with a single heating frequency or with a pair of frequencies having two frequencies of heating that have a frequency separation of at least 17 kHz from each other, and with the same period length. The control scheme presents heating frequencies to activate the induction targets that make it possible to activate the induction targets without coupling noises and that provide an output heating power averaged over a time interval that is equal to the theoretical heating power. The term "other induction target" includes the concept of an induction target that is configured differently with respect to the first and second induction targets and / or the common induction target and / or that is independently operated with with respect to the first and second induction objective and / or with respect to the common induction objective.

Furthermore, it is proposed that the control unit be provided in the special operating state to drive the common induction target periodically with a period duration. Thus, the heating power can be flexibly controlled. The term "period duration” includes the concept of the period of shortest time in a control scheme activation sequence, where the shortest period of time is repeated periodically throughout the running time of a cooking process. The induction target is activated for the duration of the period, where the induction target is supplied with electrical energy, and this electrical energy can tend to zero.

Likewise, it is proposed that the control unit be provided in the special operating state to divide the period duration into a number of partial time sections that correspond to the resulting number of induction targets, specifically, the number of targets common induction and other induction targets. In this way, the complexity of the calculation can be reduced to determine one or more control schemes. Thus, an advantageous control of the output heating power is made possible. Preferably, the induction target is supplied with a constant output electric heating power in each partial time span. The term "partial time span" includes the concept of a time span whose duration is greater than 0 s and less than or equal to the period length. At least one parameter, for example, the duration of the partial time span, and / or An operating parameter for the common induction target and / or the other induction target, for example, the heating frequency and / or the output heating power, is adjustable by the control unit in each partial time span and is different and / or independent of the parameters of other partial time sections.

Furthermore, it is proposed that the control unit be provided in the special operating state to operate in each partial time span at least one of the induction targets, specifically one of the common induction targets and the other induction targets, with an excess power above the respective average output heating power. Thus, it is possible to achieve simplified control of the induction targets. The control unit directs the output heating power of each induction target in each partial time span such that the total output heating power is at least essentially constant during all the partial time stretches. The term "at least essentially" includes the concept that the deviation from a predetermined value is less than 15%, preferably less than 10%, and particularly preferably less than 5% of the Default value. The term "total output heating power" includes the concept of the sum of the output heating powers of all common induction targets and the other induction targets at a time determined of the period length. In the special operating state, the control unit is designed to drive with excess power an induction target other than an induction target operated in a partial time span, in a partial time span that follows in time the time span partial. If there are the same number of induction targets as partial time spans, the control unit is provided in the special operating state to drive each induction target only once with excess power for a period duration. Excess power can be adapted by choosing the appropriate heating frequencies. The term "excess power" includes the concept of a heating power whose mean value referring to a time interval exceeds the average output heating power. Excess power can be achieved by applying an alternating electromagnetic field with a frequency heating power other than a theoretical heating frequency, where, during operation of the induction target with the theoretical heating frequency, a required and / or user-set theoretical heating power is supplied. Excess power can be achieved during operating the cooking range device in a ZVS mode with a heating frequency that is less than the theoretical heating frequency, and during operation of the cooking range device in a ZCS mode with a heating frequency that is greater than the theoretical heating frequency. The term "ZVS mode” incl. Uses the concept of a zero voltage switching mode in which there is a voltage approximately equal to zero during a switch commutation process.

Likewise, it is proposed that, in the special operating state, the control unit constantly chooses the separation between frequencies for all the heating frequencies with which the first and / or the second induction target is operated, at least for the duration of period. The frequency separation is at least 17 kHz. Thus, the complexity of controlling the output heating powers can be reduced. If the first heating frequency is modified for a period duration, the second heating frequency is shifted by the same value, so that the frequency spacing remains constant.

Furthermore, it is proposed that the control unit be designed to take into account at least the duty cycle when checking the condition regarding tolerances. In this way, the output heating powers can be accurately directed. To achieve a certain output heating power, the The control unit can reduce the duty cycle to be able to drive an induction target with a lower heating frequency and, advantageously, simultaneously achieve the determined output heating power. In order to achieve a determined output heating power of an induction target with a higher heating frequency than the induction target is operated on, the control unit may increase the duty cycle. The heating frequency is a monotonically decreasing function of the duty cycle.

It is conceived that the cooking apparatus device has a position detection unit for detecting the position of the induction target, in particular of the common induction targets and of the other induction targets. In this way, exact temporal and / or spatial activation of the inductors can be achieved, whereby the energy can be supplied in a directed manner. The position detection unit of the control unit provides at least one signal that the control unit evaluates and determines if it is the case that at least one cooking battery is present. The position can be detectable by a camera that can be part of the position detection unit. The position detection unit can determine the absolute and / or relative position of the induction target, in particular of the common induction targets, as well as the dimensions of the induction target in question. The positions can be determinable, for example, by finding out the coordinates and / or finding out the relative position with respect to a point and / or reference surface.

Furthermore, a cooking appliance, in particular a cooking range, with at least one cooking appliance device according to the invention, is proposed so that operation of the induction targets can be achieved with little interference and activation is advantageously simplified thereof.

The invention also relates to a method for operating a cooking appliance device, in particular a cooking field device, according to the invention, in which electrical energy is defined and supplied to at least one first induction target and at least one second induction target, where, in the event of one or more conditions relating to the tolerances between the first induction target and the second induction target, at least one operating state is passed special, in which the first induction target and the second induction target are brought together into a common induction target and a first heating frequency to activate the first induction target and a second heating frequency to activate the second induction target are matched to each other.

The cooking appliance device described is not limited to the application or the embodiment described above, and may in particular have a number of particular elements, components, and units that differs from the amount mentioned herein , as long as it is pursued in order to fulfill the functionality described here.

Other advantages are drawn from the following description of the drawing. Four embodiment examples of the invention are represented in the drawing. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will advantageously consider the features separately as well, and bring them together in other reasonable combinations.

They show:

Fig. 1 a cooking field with a cooking appliance device, Fig. 2 the cooking appliance device with an exemplary first induction target arrangement with three induction targets, where two induction targets are brought together in a common induction target, in schematic top view, Fig. 3 the power curves of the three induction targets, with a plotted common heating frequency fAB of the common induction target,

Fig. 4 a first example of control scheme of the common induction target and another induction target of the first arrangement of induction targets,

Fig. 5 a second example of control scheme of the common induction target and the other induction target of the first arrangement of induction targets,

Fig. 6 the cooking appliance device with an exemplary second induction target arrangement with three induction targets, where two induction targets are brought together into a common induction target, in schematic top view, Fig. 7 the power curves of the three induction targets, with a common heating frequency fAB plotted from the common induction target 32, where the theoretical heating frequencies of the pooled induction targets have a frequency separation of at least 17 kHz,

Fig. 8 a first example of control scheme of the common induction target and another induction target of the second arrangement of induction targets,

Fig. 9 a second example of control scheme of the common induction target and the other induction target of the second arrangement of induction targets,

Fig. 10 another cooking range with a cooking appliance device with an exemplary third induction target arrangement with four induction targets, where two induction targets are brought together in a common induction target, in schematic top view ,

Fig. 11 the power curves of the four induction targets, with a plotted common heating frequency fCD of the common induction target,

Fig. 12 an example of a common induction target control scheme and two other induction targets from the third induction target arrangement,

Fig. 13 another cooking range realized as a classic cooking range, with a cooking appliance device with a fourth arrangement of induction targets with five induction targets, in schematic top view,

Fig. 14 another cooking range realized as a matrix cooking range, with a cooking appliance device with the fourth arrangement of induction targets with five induction targets, in schematic top view,

Fig. 15 the power curves of the five induction targets in the example of the cooking range realized as a matrix cooking range, of which two are combined as a common induction target and three as another common induction target, with a plotted fAB heating frequency of the common induction target and a plotted fCDE heating frequency of the other common induction target,

Fig. 16 a first example of control scheme of the common induction target and the other common induction target of the fourth arrangement of induction targets,

Fig. 17 a second example of control scheme of the common induction target and the other common induction target of the fourth arrangement of induction targets,

Fig. 18 the other cooking range realized as a matrix cooking range, with the cooking apparatus device with a fifth arrangement of induction targets with five induction targets, in schematic top view,

Fig. 19 the power curves of the five induction targets, of which four are assembled as a common induction target, Fig. 20 a first example of control scheme of the common induction target and the other induction target of the fifth provision of induction targets,

Fig. 21 a second example of control scheme of the common induction target and the other induction target of the fifth arrangement of induction targets,

Fig. 22 the power curves of an induction target during three different duty cycles,

Fig. 23 an exemplary representation of an allowable frequency range, in which the selection of suitable heating frequencies is selectable with the frequency spacing of 0 kHz, and

Fig. 24 an exemplary representation of an allowable frequency range, in which the selection of suitable heating frequencies is selectable with the frequency spacing of at least 17 kHz.

Only one of each of the objects present several times is accompanied by a reference symbol in the figures.

Fig. 1 shows a cooking apparatus 26a made as cooking field 38a with a cooking apparatus device 10a. The cooking apparatus 26a is designed as an induction cooking range 40a, in particular as a matrix cooking range 18a. The cooking apparatus device 10a is made as an induction cooking field device.

The cooking apparatus device 10a has a support plate 42a for at least one cooking battery 44a. In this embodiment, the support plate 42a is made as a cooking field plate. The support plate 42a is intended to support at least the cooking battery 44a. The support plate 42a has a first support area 48a and a second support area 50a.

Also, the cooking apparatus device 10a has a control unit 12a. The control unit 12a is provided to execute actions and / or algorithms and / or modify settings depending on the operating parameters entered by the user, such as, for example, the theoretical heating power 78a and / or the cooking time.

The cooking apparatus device 10a also has multiple first and second inductors 20a, 22a. Inductors 20a, 22a are arranged as a matrix. In their incorporated state, the inductors 20a, 22a are arranged below the support plate 42a. The first inductors 20a are arranged below the first bearing area 48a and the second inductors 22a are arranged below the second bearing area 50a. In this exemplary embodiment, the cooking appliance device 10a has twenty-eight first and twenty-eight second inductors 20a, 22a. The inductors 20a, 22a are provided to heat the cookware 44a resting on the support plate 42a above the inductors 20a, 22a. Each inductor 20a, 22a has at least one induction coil.

The first inductors 20a are supplied by the control unit 12a with electrical energy from a first energy source, and the second inductors 22a are supplied by the control unit 12a with electrical energy from a second energy source. The first power source has a first phase of electric current from a power supply network, and the second power source has a second phase of electric current from a power supply network.

The cooking apparatus device 10a has a position detection unit 24a. The position detection unit 24a is made as a position sensor and is intended to detect the respective position of the cookware 44a resting on the support plate 42a above the inductors 20a, 22a.

Fig. 2 shows the cooking appliance device 10a with a first exemplary induction target arrangement with three induction targets A, B, C, where two induction targets A, B are brought together in a common induction target 32a, in schematic top view.

Three cookware 44a, 60a, 62a are placed on the support plate 42a. The position detection unit 24a detects the position of the three cookware 44a, 60a, 62a. Position detection unit 24a detects extension from the base of the three cookware 44a, 60a, 62a, which are in contact with the support plate 42a. The position detection unit 24a provides a signal with information on the respective position of the cookware 44a, 60a, 62a for the control unit 12a. The control unit 12a evaluates the signal provided by the position detection unit 24a.

One or more first and / or second inductors 20a, 22a are conceived to be (n) part of the position detection unit 24a. The inductor 20a, 22a could detect in a known way the absence and / or presence of a cookware 44a, 60a, 62a above the inductor 20a, 22a in question and provide a signal to the control unit 12a.

The control unit 12a defines an induction target based on a cookware 44a, 60a, 62a supported on the support plate 42a. Control unit 12a can define multiple induction targets. Each induction target comprises at least one inductor and at least a part of the cookware. Each induction target can have one or more inductors.

The control unit 12a defines three induction targets A, B and C. The control unit 12a defines the induction target A based on the first cookware 44a, resting on the support plate 42a in the first support area 48a , which covers several first inductors 20a. Control unit 12a supplies electrical power from a first power source to induction target A.

The control unit 12a defines the induction target B based on the second cooking battery 60a, supported on the support plate 42a in the first and the second support area 48a, 50a, which covers several first and second inductors 20a, 22a. Control unit 12a supplies electrical power from the first and from a second power source to induction target B.

The control unit 12a defines the induction target C based on the third cookware 62a, supported on the support plate 42a in the second support area 50a, which covers at least several second inductors 22a. Control unit 12a supplies electrical power from the second power source to induction target C.

Control unit 12a is assumed to define induction target A as the first induction target 14a, induction target B as the second induction target 16a, and induction target C as another induction target 34a.

The first power source has a first phase of electric current from a power supply network. The second power source has a second phase of electrical current from a power supply network. The cooking apparatus device 10a has a first inverter unit that is part of the first power source. The first phase of electrical current in the power supply network supplies electrical energy to the first inverter unit. The cooking apparatus device 10a has a second inverter unit that is part of the second power source. The second phase of electrical current from the power supply network supplies electrical energy to the second inverter unit. The first and / or the second inverter unit each have at least one inverter to provide the corresponding heating frequency for the first and / or the second and / or other induction targets 14a, 16a, 34a.

Figure 3 shows the power curves of the three induction targets A, B, C, with a plotted common heating frequency fAB of the common induction target 32a, where the theoretical heating power 78a is plotted with respect to the frequency heating. The corresponding theoretical heating power 78a P ^ta , P ^tb , P ^tc is user adjustable.

In a normal operating state, the control unit 12a activates the induction target 14a, 16a, 32a corresponding to the respective theoretical heating frequency fTA, fTB, fTc. The corresponding theoretical heating frequency frA, frB, fTc provides the respective theoretical heating power 78a P ^ta , P ^tb , P ^tc .

The control unit 12a checks whether there is a condition regarding the tolerances between the first induction target 14a and the second induction target 16a. The control unit 12a checks whether, during operation with a common heating frequency, two or more induction targets provide an average output heating power 36a in continuous operation, which has a maximum deviation from the power of Corresponding theoretical heat 78a within a tolerance range. The tolerance margin allows a maximum deviation from the average output heating power 36a in continuous operation of 5% above the theoretical heating power 78a. The tolerance margin allows a maximum deviation of 10% below the theoretical heating power 78a.

When checking the condition regarding tolerances, the control unit 12a takes into account a duty cycle 56a. In the event that an induction target is activated by the control unit 12a with a heating frequency fi unable to provide the required heating power P * without breaching the condition regarding tolerances, the control unit 12a modifies the duty cycle 56a (see figure 22). By reducing the duty cycle 56a D1, which has a value of 0.5, to another duty cycle 56a D2, D3 with a value lower than below 0.5, a new heating frequency f2, f3 with a value f3 <2 <f lower compared to the heating frequency can provide the required heating power P *. Therefore, the result is that the appropriate heating frequencies can be chosen flexibly, while taking into account the condition related to tolerances.

The control unit 12a selects a common heating frequency frA for the first induction target 14a and the second induction target 16a.

The control unit 12a checks what is the amplitude of a first frequency range 52a in which the first heating frequency provides the average output heating power 36a during continuous operation of the first induction target 14a within the tolerance range of 15% / - 15% (see figure 23). Also, the control unit 12a checks what is the amplitude of a second frequency range 54a in which the second heating frequency provides the average output heating power 36a during continuous operation of the second induction target 16a within the range of tolerance of 15% / - 15%, preferably 5% / - 10%. Control unit 12a also checks whether the first frequency range 52a and the second frequency range 54a overlap.

In the event that the frequency ranges 52a, 54a overlap and the mean output heating power deviation 36a of the first and second induction targets 14a, 16a is in continuous operation within the tolerance range, the control unit 12a enters a special operating state.

In the special operating state, the control unit 12a brings together the first induction target 14a and the second induction target 16a into a common induction target 32a. Also in the special operating state, the control unit 12a adapts to each other a first heating frequency to activate the first induction target 14a and a second heating frequency to activate the second induction target 16a. The control unit 12a selects in the special operating state the first heating frequency to activate the first induction target 14a and the second heating frequency to activating the second induction target 16a with a reciprocal frequency separation 46a of 0 kHz. In the special operating state, the control unit 12a chooses the common heating frequency frAB to activate the first induction target 14a and the second heating frequency to activate the second induction target 16a.

The common heating frequency frAB is between the theoretical heating frequency frA and the theoretical heating frequency frB.

The control unit 12a is intended to perform a procedure in which electrical energy is defined and supplied to the first induction target 14a and the second induction target 16a and, in the event that one or more conditions exist regarding tolerances between the first induction target 14a and the second induction target 16a, the special operating state is entered, in which the first induction target 14a and the second induction target 16a are brought together into a common induction target 32a and a first heating frequency to activate the first induction target 14a and a second heating frequency to activate the second induction target 16a are matched to each other.

In the special operating state, the control unit 12a determines a control scheme to activate the two induction targets 14a, 16a and the other induction target 34a.

Fig. 4 shows a first example of control scheme of the common induction target 32a and another induction target 34a of the first arrangement of induction targets.

This first control scheme example shows the output heating power 68a plotted over time for the common induction target 32a and the other induction target 34a.

It is assumed that the control unit 12a defines the first induction target 14a and the second induction target 16a as an induction target, that is, as the common induction target 32a. In the special operating state, the control unit 12a treats the common induction target 32a as a single induction target when determining the control scheme.

The control unit 12a is provided to periodically feed the common induction target 32a and the other induction target 34a.

The control unit 12a drives each of the induction targets 32a, 34a periodically over a period duration 28a for a full cook time. The cooking time is divided in each case into the period length 28a (see FIG. 4). During the period duration 28a, the control unit 12a supplies the induction targets 32a, 34a with the corresponding average output heating power 36a.

In a special operating state, the control unit 12a drives the common induction target 32a and the other induction target 34a avoiding flickering. In order to avoid flickering, the control unit 12a maintains in the special operating state essentially constant the total output heating power of the common induction target 32a and the other induction target 34a for at least a large part of the period duration 28a .

In the special operating state, the control unit 12a drives the common induction target 32a and the other induction target 34a avoiding coupling noises. The control unit 12a reduces coupling noises in the special operating state by specific activation of the common induction target 32a.

The period length 28a is divided into partial time sections 30a. In the special operating state, the control unit 12a divides the period duration 28a into two partial time sections 30a t1, t2. The number of partial time sections 30a corresponds to the amount resulting from the sum of the other induction targets 34a and the common induction targets 32a. The sum of the duration of each of the partial time sections 30a t1, t2 coincides with the duration of period 28a.

In the special operating state, the control unit 12a drives the common induction target 32a and the other induction target 34a with the same heating frequency in the first partial time section 30a t1 and drives the other induction target 34a with a excess power above the average output heating power 36a of the other induction target 34a.

In the second partial time section 30a fe, the control unit 12a drives the common induction target 32a and the other induction target 34a simultaneously with heating frequencies differing by at least 17 kHz. In the special operating state, the control unit 12a drives the common induction target 32a in the second partial time section 30a fe with excess power above the average output heating power 36a of the common induction target 32a.

To avoid coupling noises, the control unit 12a can additionally select an activation possibility from a catalog of activation possibilities in the special operating state. By way of example, the control unit 12a could drive the common induction target 32a and the other induction target 34a at least with essentially the same heating frequency in the special operating state to prevent coupling noises from occurring. This is indicated in Figures 4, 5, 7, 8, 11, 15, 16, 18 and 19 by oblique and perpendicular dashed and dotted lines.

Alternatively or additionally, the control unit 12a could drive the common induction target 32a and the other induction target 34a with heating frequencies differing by at least 17 kHz in the special operating state in order to avoid noise coupling. This is indicated in Figures 4, 7, 11, 15 and 18 by an oblique dashed line.

Alternatively or additionally, in order to avoid coupling noises, the control unit 12a could, for example, deactivate in the special operating state at least a part of the common induction target 32a and the other induction target 34a and actuating at least a part of the common induction target 32a and the other induction target 34a with a given heating frequency. This is indicated in Figures 5, 8, 16 and 19 by cross hatching.

The control scheme represented by way of example in FIG. 4 fulfills the condition of the standard regarding flicker and the avoidance of coupling noises.

On average over the period duration 28a, the common induction target 32a and the other induction target 34a each provide an average output heating power 36a P ^tab , P ^tc .

Figure 5 shows a second example of control scheme of the common induction target 32a and the other induction target 34a of the first arrangement of induction targets. The following description is essentially limited to the differences between the control schemes, where, in relation to characteristics and functions that remain the same, one can refer to the description of the control scheme of Figure 4.

In the special operating state, the control unit 12a drives the common induction target 32a and the other induction target 34a with the same heating frequency in the first partial time section 30a ti and drives the other induction target 34a with a excess power above the average output heating power 36a of the other induction target 34a.

In the second partial time section 30a t2, the control unit 12a drives the common induction target 32a with excess power and deactivates the other induction target 34a.

Fig. 6 shows the cooking appliance device 10a with a second exemplary induction target arrangement with three induction targets A, B, C, where two induction targets A, C are brought together in a common induction target 32a, in schematic top view.

Figure 7 shows the power curves of the three induction targets A, B, C with a plotted common heating frequency fAB of the common induction target 32a, where the theoretical heating frequencies of the combined induction targets A, C They have a separation between frequencies 46a of at least 17 kHz.

Control unit 12a defines three induction targets A, B and C. It is assumed that control unit 12a defines induction target A as the first induction target 14a, induction target C as the second induction target 16a, and induction target B as another induction target 34a.

In case the theoretical heating frequencies of the first and second induction targets 14a, 16a differ by more than 17 kHz and the theoretical heating power 78a fTA of the first induction target 14a and the theoretical heating power 78a fTB of the third induction target 16a have a large percentage distance, where the frequency ranges 52a, 54a do not overlap, the control unit 12a enters a special operating state. In the special operating state, the control unit 12a brings together the first induction target 14a and the second induction target 16a into a common induction target 32a. Also in the special operating state, the control unit 12a adapts to each other a first heating frequency to activate the first induction target 14a and a second heating frequency to activate the second induction target 16a. The control unit 12a sets the reciprocal frequency spacing 46a between the first heating frequency in the special operating state to activate the first induction target 14a and the second heating frequency to activate the second induction target 16a. The spacing between frequencies 46a is constant for the duration of period 28a. The second heating frequency is automatically set by choosing the first heating frequency.

The control unit 12a checks what is the amplitude of the first frequency range 52a in which the first heating frequency provides the average output heating power 36a during continuous operation of the first induction target 14a within the tolerance interval of 15 % / - 15% (see figure 24). Also, the control unit 12a checks what is the amplitude of a second frequency range 54a in which the second heating frequency provides the average output heating power 36a during continuous operation of the second induction target 16a within the range of tolerance of 15% / - 15%, preferably 5% / - 10%.

The control unit 12a can vary the first the first and / or the second heating frequency with the constant frequency separation 46a, as long as they meet the condition regarding tolerances (see figure 21).

The first heating frequency can take a maximum value f ^{+ TA} from which the average output heating power 36a of the first induction target 14a exceeds the corresponding theoretical heating power 78a of the first induction target 14a by 5%. The second heating frequency can take a maximum value f ^{+ TB} from which the average output heating power 36a of the second induction target 16a exceeds the corresponding theoretical heating power 78a of the second induction target 16a by 5%.

The first heating frequency can take a minimum value f ^- ta from which the average output heating power 36a of the first induction target 14a falls below the corresponding theoretical heating power 78a of the first induction target 14a by 10%. The second heating frequency can take a minimum value f ^{- TB} from which the average output heating power 36a of the second induction target 16a falls below the corresponding theoretical heating power 78a of the second induction target 16a by 10%.

Figures 8 and 9 show in each case a first and a second control scheme example of the common induction target 32a and of the other induction target 34a of the second induction target arrangement, where the first heating frequency of the first target induction 14a and the second frequency of Heating of the second induction target 16a has a constant frequency separation 46a.

The following description is essentially limited to the differences between the control schemes, where, in relation to characteristics and functions that remain the same, one can refer to the descriptions of the control schemes of Figures 4 and 5.

It is assumed that the control unit 12a defines the induction target A as the first induction target 14a and the induction target C as the second induction target 16a together as the induction target, that is, as the common induction target 32a. In the special operating state, the control unit 12a treats the common induction target 32a as a single induction target when determining the control scheme.

In the special operating state, the control unit 12a drives in the first partial time section 30a t1 of Figures 8 and 9 the common induction target 32a and the other induction target 34a with the same heating frequency and drives the other induction target 34a with excess power above the average output heating power 36a of the other induction target 34a.

In the second partial time span 30a t2 of the first control scheme depicted in Figure 8, the control unit 12a drives the common induction target 32a and the other induction target 34a simultaneously with heating frequencies differing by at least 17 kHz . In the special operating state, the control unit 12a drives the common induction target 32a in the second partial time section 30a t2 with an excess power above the average output heating power 36a of the common induction target 32a.

In the second partial time section 30a t2 of the second control scheme shown in FIG. 9, the control unit 12a drives the common induction target 32a with excess power and deactivates the other induction target 34a.

The heating frequencies of the first and second induction targets 14a, 16a have a constant frequency separation 46a set by the control unit 12a in each partial time segment 30a of the period duration 28a.

In figures 10 to 21, other embodiment examples of the invention are shown. The following descriptions are essentially limited to the differences between the embodiment examples, where, in relation to components, characteristics and functions that remain the same, one can refer to the description of the first example of embodiment of figures 1 to 9. For the differentiation of the embodiment examples, the letter "a" of the reference symbols of the embodiment example of figures 1 to 8 has been replaced by the letters "b", "c" and "d" in the following embodiment examples.

Fig. 10 shows another cooking field 38b with a cooking appliance device 10b with a third exemplary induction target arrangement with four induction targets A, B, C, D, where two induction targets C, D they are assembled on a common induction target 32b, in schematic top view.

The first support area 48b features five first inductors 20b. The second support area 50b has five second inductors 22b. Inductors 20b, 22b have a rectangular contour.

By placing a cookware 44b, 60b, 62b, 64b on top of one or more inductors 20b, 22b or a part of the inductor 20b, 22b, where the part amounts to at least 10% of the total extension of the inductor 20b, 22b, inductors 20b, 22b are covered by cookware 44b, 60b, 62b, 64b. Control unit 12b activates covered inductors 20b, 22b.

The control unit 12b defines as an induction target the inductor (s) 20b, 22b covered by the cookware 44b, 60b, 62b, 64b together with the respective cookware 44b, 60b, 62b, 64b. In total, four induction targets A, B, C, D are defined by control unit 12b.

Induction targets A, B and D each have two inductors 20b, 22b and a first, second and fourth cookware 44b, 60b, 64b placed on top of the corresponding inductors 20b, 22b. Induction target C features four inductors 20b, 22b and a third cookware 62b placed on top of inductors 20b, 22b.

It is assumed that the control unit 12b examines the power curves of the induction targets A, B, C, D for the existence of the condition related to tolerances, and then defines the induction target C as the first induction target 14b, the induction target D as the second induction target 16b, and the induction targets A, B as other induction targets 34b, 58b.

The control unit 12b adapts a first heating frequency to each other to activate the first induction target 14b and a second frequency of heating to activate the second induction target 16b such that a reciprocal frequency separation 46b of 0 kHz is generated.

The control unit 12b defines the first induction target 14b and the second induction target 16b as an induction target, that is, as a common induction target 32b. In the special operating state, the control unit 12b treats the common induction target 32b as a single induction target when determining the control scheme.

Control unit 12b activates the first induction target 14b and the second induction target 16b, and thus the common induction target 32b, with the same heating frequency fCD (see Figure 11).

Fig. 12 shows an example of control scheme of the common induction target 32b and two other induction targets 34b, 58b of the third arrangement of induction targets. The control unit 12b divides the period duration 28b into three partial time sections 30b t1, t2, t3. In the first partial time span 30b t1, the control unit 12b drives the common induction target 32b and the other induction targets 34b, 58b together with the same heating frequency.

In the second partial time section 30b t2, the control unit 12b drives all the induction targets 32b, 34b, 58b simultaneously, where the control unit 12b drives the other induction target 34b and the common induction target 32b with the same heating frequency and the other 58b induction target with another heating frequency differing by at least 17 kHz.

In the third partial time span 30b t3, the control unit 12b drives the other induction target 34b and the common induction target 32b simultaneously with heating frequencies differing by at least 17 kHz, and deactivates the other induction target 58b.

Averaged over the period duration 28b, the common induction target 32b and the other induction targets 34b, 58b each provide a mean output heating power 36b PT ^cd , P ^ta , P ^tb .

Figure 13 shows another cooking range 38c, made as a classic cooking range, with a cooking appliance device 10c with a fourth induction target arrangement with five induction targets A, B, C, D, E, in view schematic top.

Fig. 14 shows another cooking field 38d, made as matrix cooking field 18d, with a cooking appliance device 10d with the fourth induction target arrangement with five induction targets A, B, C, D, E, in schematic top view.

The following description applies both to the classic cooking range with fixedly defined cooking zones and to the 18d matrix cooking range shown in figure 14. The invention is explained below by means of the cooking range example of matrix 18d.

The control unit 12d each time defines as an induction target the inductor (s) 20d, 22d covered by the cookware 44d, 60d, 62d, 64d, 66d together with the cookware 44d, 60d, 62d, 64d, 66d respective. In total, five induction targets A, B, C, D, E are defined by control unit 12d.

It is assumed that the control unit 12d examines the power curves of the induction targets A, B, C, D, E for the existence of the condition related to tolerances, and then defines the target of induction A as the first induction target 14d, induction target B as the second induction target 16d, and induction target C as another first induction target 72d, induction target D as another second induction target 74d, and the induction target E as third induction target 70d.

The control unit 12d adapts to each other a first heating frequency to activate the first induction target 14d and a second heating frequency to activate the second induction target 16d in such a way that a reciprocal frequency separation 46d of 0 kHz.

The control unit 12d defines the first induction target 14d and the second induction target 16d as an induction target, that is, as a common induction target 32d. In the special operating state, the control unit 12d treats the common induction target 32d as a single induction target when determining the control scheme.

The control unit 12d activates the first induction target 14d and the second induction target 16d, and therefore the common induction target 32d, with the same heating frequency fAB (see Figure 15).

The control unit 12d adapts another first heating frequency to each other to activate the other first induction target 72d, another second frequency of heating to activate the other second induction target 74d, and a third heating frequency to activate the third induction target 70d, such that a reciprocal frequency spacing 46d of 0 kHz results.

The control unit 12d defines the other first induction target 72d, the other second induction target 74d, and the third induction target 70d as an induction target, that is, as another common induction target 76d. In the special operating state, the control unit 12d treats the other common induction target 76d as a single induction target when determining the control scheme.

The control unit 12d activates the other first induction target 72d, the other second induction target 74d, and the third induction target 70d, and therefore the other common induction target 76d, with the same heating frequency f ^CDE (see figure 15).

Figures 16 and 17 show in each case a first and a second control scheme example of the common induction target 32d and the other common induction target 76d of the fourth arrangement of induction targets.

The control unit 12d divides the period duration 28d into two partial time sections 30d t ¹ , t ² . In the first partial time span 30d t ¹ of the first and second control scheme, the control unit 12d drives the common induction target 32d and the other common induction target 76d together with the same heating frequency. In the first partial time span 30d t ¹ , the control unit 12d drives the common induction target 32d with an excess power above the average output heating power 36d of the common induction target 32d.

In the second partial time span 30d t ² of the first control scheme, the control unit 12d drives the common induction target 32d and the other common induction target 76d simultaneously with heating frequencies differing by at least 17 kHz.

In the second partial time span 30d t ² of the second control scheme, the control unit 12d drives the common induction target 32d with excess power and deactivates the other common induction target 76d.

P rimed through the 28 d period, the common induction target 32 d and the other common induction target 76 d provide each medium output heat 36 d P tab , P tcde .

L f i g u r 18 m or e s t r e l c a m p o r c o c c i n d e e t r i z 18 d c o n e l d i s p o s i t i v o r a p a r a t o r c or c t i o n 10 d c o n u n to q u in t a d i s p o s i t i o n d e o b j e t i v or s d e i n d u c t i o n c o n c i n c o o b je t i v or s d e i n d u c t i o n A, B, C, D, E, and n v i s t a s u p e r i o r e s q u e m a t i c a.

L a u n id a d e c o n t r o l 12 d d e f i n e e l o b j e t i v o d e i n d u c c i o n B c o m o o r t o o b j e t i v o d e i n d u c c i n 34 d.

This has been described in the figure with figures 12 and 13, the control id 1 2 dre u with the induction objectives C, D, E in another objective of induc tion with the other 76 see figure 19).

T he control id 12 defines the goal of induction A in a first goal of induction 14 d. The high temperature heating frequency of the first induction target 14 d and the fCDE heating frequency of the other common induction target 76 show a minimum frequency spacing 46 of 17 kHz. L apotenciadecalentamie ntote or rich 78 d fta delprimerobjetivodein duction 14 d and 78 tote potenciadecalentamien or rich TCDE delotroobjetivodeindu d ^í ú n ction NCOM 76 dpresentanunagrandist anciaporcentualmente, dondelosintervalosdef recuencias 52 d, 54 dnosesolapan (v é ase Figure 21).

L u n ity d e c o n t r o l 12 d d e f i n e e l o t r o b j e t i v o r i n d u c t i o n c o m u n 76 d c o m o n u and v or s e c o n d o o b j e t i v o r i n d u c t i o n 16 d and r and u n e e l p r i m e r o b j e t i v o r i n d u c t i o n 14 d and b e u and v or s e c o n d o o b j e t i v o r i n d u c t i o n 16 d and n u o b j e t i v o r i n d u c t i o n c o m u n 32 d.

L a s f i g u r e s 20 and 21 m u e s t r a n e n c a d a c a s o u n p r i m e r and u n s e c o n d e j e m p l o d e e s q u e e d e c o n t r o l d and l or b j e t i v o r i n d u c t i o n c o m u n 32 d and d and l or t r o b j e t i v o r i n d u c t i o n 34 d th e q u in t a d i s p o s i t i o n d e o b j e t i v or s d e i n d u c t i o n.

T he control id 12 divides the duration of the period 28 time sparcial spans 30 dt 1, t 2 in the first and second squemadecontrol. In the first part-time 30 dt 1 timeframe of the first and second control, the one control id 12 gives the common induction goal 32 and the other induction goal 34 d along with the same heating frequency. In the first partial timeframe 30 dt 1, the one control id 12 gives the other goal of induction 34 d with an excess power boost overheating power at average output 36 d from the other induction target 34 d.

E n e l s e c o n d t r m o t e m p o r a l p r c i a l 30 d t 2 d e l p r i m e r e s q u e e d e c o n t r o l u n ity d e c o n t r o l 12 d a c c i o n e l o b j e t i v o r i n d u c t i o n c o m u n 32 d and e l o t r o b j e t i v o r i n d u c t i o n 34 d s i m u l t to n e a m e n t e c o n f r e q u e n c i a s d e c a l e n t a m i e n t or q u e d i f i e r e n e n 17 k H z c o m o m i n i m o.

E n e l s e c o n d t r m o t e m p o r a l p r c i a l 30 d t 2 d e l s e c o n d e s q u e e d e c o n t r o l u n ity d e c o n t r o l 12 d a c c i o n e l o b j e t i v o r i n d u c t i o n c o m u n 32 d c o n u n e x c e s o f p o t e n c i a and d e s a c t i v e l o t r o b j e t i v o r i n d u c t i o n 34 d.

P rimed through the 28 d period, the common induction target 32 d and the other 34 d induction target provide each medium output power 36 d P tacde , P tb .

Reference symbols

Cooking appliance device

Control unit

First induction objective

Second induction objective

Matrix cooking range

First inductor

Second inductor

Position detection unit

Cooking appliance

Period length

Partial time section

Common induction target

Another induction goal

Average output heating power Cooking range

Induction cooking range

Support plaque

First firing coil

Frequency separation

First support area

Second support area

First frequency range

Second frequency range

Duty cycle

Another induction goal

Second firing coil

Third firing coil

Fourth firing coil

Fifth firing battery

Output heating power

Third induction objective

Another first induction goal

Another second induction goal

Another common induction objective

Theoretical heating power

Claims (14)

1. Cooking appliance device (10), in particular, cooking range device, with a control unit (12) which is intended to activate and supply power to at least a first induction target (14) and to at least a second induction target (16), characterized in that , in the event of one or more conditions related to tolerances between the first induction target (14) and the second induction target (16), the control unit (12 ) is intended to enter at least one special operating state, in which the control unit (12) is intended to bring together the first induction target (14) and the second induction target (16) into an induction target common (32) and to adapt to each other a first heating frequency to activate the first induction target (14) and a second heating frequency to activate the second induction target (16). Cooking appliance device (10) according to claim 1, characterized in that the condition relating to tolerances is a condition on the maximum deviation of the respective mean output heating power (36) of the two induction targets (14 , 16) with respect to the respective theoretical heating power of the induction targets (14, 16) in continuous operation with the respective heating frequency. Cooking appliance device (10) according to claim 2, characterized in that , in accordance with the condition regarding tolerances, the maximum deviation is within a tolerance range of 15% / - 15%. Cooking appliance device (10) according to one of the preceding claims, characterized in that , in the special operating state and depending on the situation, the control unit (12) chooses the first heating frequency and the second heating frequency with a reciprocal frequency separation (46) of 0 kHz. Cooking appliance device (10) according to one of the preceding claims, characterized in that , in the special operating state and depending on the situation, the control unit (12) chooses the first heating frequency and the second frequency of heating with reciprocal frequency spacing (46) of at least 17 kHz. Cooking appliance device (10) according to claims 4 and 5, characterized in that , in the special operating state, the control unit (12) chooses the separation between frequencies (46) depending on the theoretical powers chosen for the two induction targets (14, 16). Cooking appliance device (10) according to one of the preceding claims, characterized in that the control unit (12) is provided in the special operating state to treat the common induction target (32) as a single induction by determining at least one control scheme to activate the two induction targets (14, 16) and at least one other induction target (34). Cooking appliance device (10) according to one of the preceding claims, characterized in that the control unit (12) is provided in the special operating state to periodically drive the common induction target (32) with a duration of period (28). Cooking appliance device (10) according to claims 7 and 8, characterized in that the control unit (12) is provided in the special operating state to divide the period duration (28) into a number of partial time sections (30) which corresponds to the resulting number of induction targets, specifically, the number of common induction targets and other induction targets. Cooking appliance device (10) according to claim 9, characterized in that the control unit (12) is provided in the special operating state to drive at least one of the induction targets in each partial time section (30) of the number of common induction targets and other induction targets with excess power above the respective mean output heating power (36). Cooking appliance device (10) according to at least claims 4, 5 and 8, characterized in that , in the special operating state, the control unit (12) constantly chooses the frequency spacing (46) at least during the length of the period (28). Cooking appliance device (10) according to one of the preceding claims, characterized in that the control unit (12) is designed to take into account at least the duty cycle when checking the condition related to tolerances. Cooking appliance (26), in particular, cooking range (38), with at least one cooking appliance device (10) according to one of the preceding claims. Method for starting up a cooking appliance device (10), in particular a cooking range device, according to one of claims 1 to 12, in which electric power is supplied to at least one first induction target (14) and at least one second induction target (16), characterized in that , in the event of one or more conditions relating to tolerances between the first induction target (14) and the second induction target (16), at least one special operating state is entered, in which the first induction target (14) and the second induction target (16) are brought together into a common induction target (32) and a first frequency Heating frequencies to activate the first induction target (14) and a second heating frequency to activate the second induction target (16) are matched to each other.