EP2590475A2 - Induction heating device - Google Patents

Abstract

The device (12) has a control unit (14) defining a set of pulse parameters as a function of a fluctuation of a sensor value of sensing units (40-46), where the sensing units determine temperature of a heating medium or a dish. The control unit is provided in a mode of operation to define the pulse parameters as a function of a curve. The control unit switches the mode of operation between a pulsed operation and a continuous operation as a function of an operator input. Four induction heating units (30-36) are arranged below a cook field plate. An independent claim is also included for a method for operating an induction heating device.

Description

The invention is based on an induction heating device according to the preamble of claim 1.

Induction hobs are known which have an inductor which is operated pulsed in an operating state in which a heating power is requested which can not be supplied continuously.

The object of the invention is in particular to provide a generic device with improved properties in terms of a uniform heating process. The object is achieved by the features of claim 1, while advantageous embodiments and modifications of the invention can be taken from the dependent claims.

The invention is based on an induction heating device, in particular an induction hob device, having at least one heating frequency unit, at least one induction heating unit, which is intended to be operated by the heating frequency unit, and at least one control unit, which is intended to pulse the heating frequency unit in at least one operating mode to operate, and with at least one sensor unit.

It is proposed that the control unit be provided for pulse parameters, in particular at least one pulse power, a pulse phase distance and / or at least one duration of a pulse phase and / or a rest phase, in particular in at least one operating mode in which a low to medium heating power is required, at least as a function of at least one sensor value of the sensor unit. A "heating frequency unit" should in particular be understood to mean an electrical unit which has an oscillating electrical signal, preferably with a switching frequency of at least 1 kHz, in particular of at least 10 kHz, advantageously of at least 20 kHz, and in particular of not more than 100 kHz, for an induction heating unit generated. In particular, the heating frequency unit is intended to be one of which Induktionsheizeinheit required to provide maximum electrical power of at least 1000 W, in particular at least 2000 W, advantageously at least 3000 W, preferably at least 3500 W. The heating frequency unit comprises in particular at least one inverter, which preferably has at least two, preferably series-connected, bidirectional unipolar switches, which are in particular formed by a transistor and a diode connected in parallel, and particularly advantageously at least one damping capacitor connected in parallel to the bidirectional unipolar switches, which is in particular formed by at least one capacitor. As a result, a high-frequency power supply of the induction heating unit can be provided. An "induction heating unit" is to be understood in particular as a unit having at least one induction heating element. In particular, in an operating state in which the induction heating unit is supplied with high-frequency alternating current, all induction heating elements of the induction heating unit, preferably simultaneously, supplied with high-frequency alternating current. An "induction heating element" is to be understood in particular as a wound electrical conductor, preferably in the form of a circular disk through which high-frequency alternating current flows in at least one operating state. The induction heating element is preferably provided to convert electrical energy into an alternating magnetic field, which is intended to cause in a metallic, preferably at least partially ferromagnetic, heating means, in particular cooking utensils, eddy currents and / or remagnetization effects, which are converted into heat. A "control unit" is to be understood in particular to mean an electronic unit which is preferably at least partially integrated in a control and / or regulating unit of an induction heating device and which is preferably provided to control and / or regulate at least the heating frequency unit. The control unit preferably comprises a computing unit and, in particular in addition to the computing unit, a memory unit with a control and / or regulating program stored therein, which is intended to be executed by the computing unit. By "provided" is intended to be understood in particular specially programmed, designed and / or equipped. A "pulsed operation" should in particular be understood as an operating state in which a heating frequency unit alternately, preferably alternately alternately, provides high-frequency alternating current in pulse phases or no current in rest phases. In particular, a duration of the pulse phases at least 0.1 s, in particular at least 0.5 s, advantageously at least 1 s, preferably at least 3 s, in particular a maximum of 15 min, advantageously a maximum of 10 min, preferably a maximum of 5 min. The control unit is provided to select a pulse power, ie heating powers during pulse phases, so that a heating power in the time average corresponds to the requested heating power. In particular, the heating powers in different, in particular successive, preferably immediately successive, pulse phases are at least substantially the same. By saying that two values are "substantially" the same, it should be understood in particular that a difference in the values amounts to a maximum of 10%, in particular a maximum of 5%, preferably a maximum of 1% of a sum of the values. In particular, a duration of a rest phase in at least one operating state is a maximum of 100%, in particular a maximum of 50%, advantageously a maximum of 25%, preferably a maximum of 10%, of a duration of a preceding pulse phase. A "sensor unit" is to be understood in particular a unit which has at least one sensor. In particular, the sensor unit differs from a sensor unit which is provided to determine performance characteristics, in particular a current and / or a voltage of the induction heating unit. A "sensor" should be understood in particular to be an element which is intended to have a preferably physical size, in particular a temperature, a state of cooking, a humidity and / or the like, into another, preferably electrical, parameter of the sensor, for example a voltage, a current and / or an electrical resistance to convert. In particular, the control unit is provided, in particular via an assignment function and / or a characteristic value table, to assign a value of the physical variable to a sensor value. A "low to medium" heating power should be understood in particular to mean a heating power which corresponds to a maximum of 70%, in particular a maximum of 50%, preferably a maximum of 30%, of a maximum heating power, in particular a maximum power of the heating frequency unit. In particular, a low to medium power is a maximum of 1.5 kW, advantageously a maximum of 1.2 kW, preferably a maximum of 1 kW. In particular, a uniform heating process and / or improved comfort can be achieved.

It is advantageously proposed that the sensor unit is provided to determine a temperature, in particular a temperature of a heating medium and / or a cooking utensil. In particular, a sensor element of the sensor unit is as Infrared sensor and / or designed as a thermal sensor. In particular, a simple control can be achieved. Alternatively, embodiments are also conceivable in which the sensor unit is intended to be determined, for example, by a vibration sensor, in particular a microphone, a cooking state, for example a warm-up phase, cooking and / or overcooking, of a heated cooking utensil.

Furthermore, it is proposed that the control unit be provided to set the pulse parameters at least as a function of a fluctuation of the sensor value of the sensor unit. A "fluctuation" should in particular be understood as a value which indicates how much a sensor value on average deviates from an average value of the sensor value, in particular averaged over a period of time between two starting points of immediately consecutive pulse phases. In particular, the fluctuation is dependent on a maximum value and / or a minimum value of the sensor value.

Furthermore, it is proposed that the control unit is provided to set the pulse parameters at least as a function of an operator input, in particular an input control parameter. In particular, the induction heating device has at least one input means which allows an operator to set a corresponding control parameter. In particular, the control parameter indicates a maximum of a specific parameter, in particular the fluctuation of the sensor value. Alternatively, it is conceivable that an operator input causes the control unit to operate independently of sensor values of the sensor unit. In particular, increased comfort can be achieved.

Advantageously, it is proposed that the control unit is provided for pulsed operation of the heating frequency unit in at least one operating mode in which a heating power is required for the at least one induction heating unit, which is available in a continuous operation from the heating frequency unit to the induction heating unit. A "requested heating power" is to be understood in particular a setting made by an operator via an operating unit. In particular, a value of an electrical power, in particular in watts, and / or a power level, which is preferably assigned by the control unit to an electrical power, can be used. be set. Alternatively, the requested heating power can be set by the control unit as part of a cooking program. A heating power is particularly available in a "continuous operation" when an electrical efficiency of a total used heating electronics, in particular at least the Heizfrequenzeinheit, a rectifier unit, the induction heating unit and / or the control unit is greater than at least 85%, in particular at least 90%, advantageous at least 93%, preferably at least 95%. In particular, a power loss of the heating electronics is not more than 15%, in particular not more than 10%, advantageously not more than 7%, preferably not more than 5%, of a heating power which is output to a heating means via the induction heating unit. In particular, a heating power in a continuous operation is available when a switching frequency of the heating frequency unit, which is necessary to generate the heating power is less than 120 kHz, in particular less than 110 kHz, preferably less than 100 kHz. In particular, an increased electrical efficiency can be achieved because at higher powers can be worked with lower switching frequencies, whereby lower losses occur in the heating frequency unit and other power electronics.

Advantageously, it is proposed that the control unit is provided in at least one operating mode to set pulse parameters at least as a function of at least one characteristic, in particular a characteristic curve which assigns a minimum pulse phase spacing to a power, preferably a flicker characteristic. A "pulse phase distance" is to be understood in particular as a distance between start times of two pulse phases, preferably immediately consecutive pulse phases. Preferably, at least in the one operating mode successive pulse phase intervals are at least substantially equal. A flicker characteristic should in particular be understood to mean a characteristic curve which determines how large a pulse phase spacing as a function of a pulse power should be at least in order to avoid disturbances in a power network and / or comfort restrictions, for example by flickering light. In particular, increased comfort and / or improved network stability can be achieved.

It is also proposed that the control unit be provided, at least in response to an operator input, preferably from a Heating power requirement and / or adjustment differs in the at least one operating mode between a pulsed operation and a continuous operation switch. In particular, the induction heating device has at least one operating element, in particular a touch-sensitive operating surface and / or a menu item in a control menu, which is provided to provide the control unit with a signal for switching over. In particular, increased comfort can be achieved.

Furthermore, it is proposed that the control unit be provided to dispense with an adjustment of the pulse parameters as a function of sensor values of the sensor unit in at least one operating mode during a start phase of a heating process. In particular, a start phase is to be understood as meaning a time range between a heating power requirement and a point in time at which a preset sensor value and / or a preset time duration has been reached.

Such a device is particularly advantageously arranged in an induction hob and / or in an oven with induction heating.

Further advantages emerge from the following description of the drawing. In the drawings, embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Fig. 1

ein erfindungsgemäßes Kochfeld in einer schematischen Ansicht von oben,

Fig. 2

einen gepulsten Betrieb in einem schematischen Diagramm der Heizheizleistung in Abhängigkeit von der Zeit,

Fig. 3

ein schematischer, zeitlicher Temperaturverlauf bei gepulstem Betrieb,

Fig. 4

Temperaturschwankungen in Abhängigkeit von verwendeter Pulsleistung und zu erhitzender Menge in einem schematischen Diagramm,

Fig. 5

eine schematische Flickerkennlinie und

Fig. 6

eine von einer Heizleistung abhängige Effizienz in einem schematischen Diagramm.

Show it:

Fig. 1

an inventive hob in a schematic view from above,

Fig. 2

a pulsed operation in a schematic diagram of the heating heating power as a function of time,

Fig. 3

a schematic, temporal temperature profile with pulsed operation,

Fig. 4

Temperature fluctuations as a function of the pulse power used and the quantity to be heated in a schematic diagram,

Fig. 5

a schematic Flickerkennlinie and

Fig. 6

a dependent on a heating efficiency in a schematic diagram.

FIG. 1 shows a designed as an induction hob home appliance 10 with an induction heater designed as an induction heating 12. The induction heating 12 has four formed as an inverter Heizfrequenzeinheiten 20, 22, 24, 26 on. Furthermore, the induction heating device 12 has four induction heating units 30, 32, 34, 36 formed as inductors, which are each intended to be operated by different heating frequency units 20, 22, 24, 26. The induction heating units 30, 32, 34, 36 are disposed below a cooktop panel and are intended to heat cooking dishes placed on the cooktop panel positioned above the induction heating units 30, 32, 34, 36. Furthermore, the hob device sensor units 40, 42, 44, 46, which are arranged in centers of the induction heating units 30, 32, 34, 36. The sensor units 40, 42, 44, 46 have sensor elements designed as infrared sensors. Furthermore, the induction heating device 12 has a control unit 14 and an operator interface 16. The operator interface 16 is intended to enable an operator to request heating powers for the induction heating units 30, 32, 34, 36 via control elements and to output currently set power levels to display units. The control unit 14 is provided to process inputs of the user interface 16, to control displays of the display units of the user interface 16 and to control the heating frequency units 20, 22, 24, 26 such that the induction heating units 30, 32, 34, 36 deliver powers on average that correspond to heating powers that are requested via the operator interface 16.

The control unit 14 is provided for pulsing the heating-frequency units 20, 22, 24, 26 in each case in an operating mode ( FIG. 2 ). The induction heating unit 30, 32, 34, 36 is provided to generate in the operating mode periodically alternately during pulse phases 60, 62 with a pulse phase duration t _ON high-frequency alternating current, which leads to a pulse power P _pulse , and during rest periods 61, 63 with a rest phase duration t _off to produce no high-frequency alternating current. An average heating power corresponds to the requested heating power P _mean . The control unit 14 is further provided for setting pulse parameters, ie a pulse phase distance t _flicker , the pulse phase duration t _ON and the pulse power P _{pulse in} each case as a function of sensor values T of the sensor unit 40, 42, 44, 46. The sensor units 40, 42, 44, 46 are each intended to determine temperatures of cooking utensils placed on the hob plate.

The control unit 14 is provided to set the pulse parameters as a function of a fluctuation S, S 'of the sensor value T of the sensor units 40, 42, 44, 46 ( FIG. 3 ). The fluctuation S, S 'is calculated according to S = ΔT / t _ON × t _flicker . Wherein a temperature difference .DELTA.T, .DELTA.T 'is a difference of a last measured local maximum value T _max , T _max ' and a last measured local minimum value T _min , T _min '. If the control unit 14 determines a fluctuation S, S 'having a value greater than a predetermined maximum fluctuation S _max , the control unit 14 reduces the pulse phase interval t _flicker . If the control unit 14 determines a fluctuation S, S 'having a value less than a predetermined minimum fluctuation S _min , the control unit 14 increases the pulse phase distance t _flicker . The pulse phase distance t _flicker is thereby changed by 5% of its value. The maximum fluctuation S _max and the minimum fluctuation S _min are determined by an operator input via the operator interface 16. The control unit 14 provides an operator with different cooking modes, such as "milk", "cooking", "frying", for selection, to which specific maximum fluctuations S _max , eg 2 K, 7 K, 20 K, are assigned. A minimum variation S _min is set at 70% of S _max .

Alternatively, the fluctuation S may also be set as S = ΔT. Alternatively, the pulse phase spacing t _{flicker can be changed} by arbitrary proportions between 0% and 50% of its value. Alternatively, an operator via the operator interface 16 also directly set a value, in the form of a number, the maximum fluctuation S _max .

FIG. 4 shows by way of example how the fluctuation S behaves in dependence on the pulse power P _pulse for different quantities to be heated. The left curve stands for 1 kg of water and the right curve for 6 kg of water.

The control unit 14 is provided to the heating frequency units 20, 22, 24, 26 in an operating mode in which for the corresponding induction heating unit 30, 32, 34, 36 a heating power P _{mean is} requested, in a continuous operation of the heating frequency unit 20, 22 , 24, 26 to the induction heating unit 30, 32, 34, 36 is available to operate pulsed. A permanently deliverable power is determined by an efficiency η of electronics of the induction heating device 12 ( FIG. 6 ). In this case, for average cooking utensils, heating powers P, which are above a minimum heating power P _min , permanently available, since for them the efficiency ηder electronics is greater than a minimum efficiency η _min . The minimum efficiency η _min is 95%. This results in a minimum heating power P _min of 500 W.

The control unit 14 is provided in the one operating mode to set a pulse phase spacing t _flicker and a pulse power P _puls as a function of a flicker characteristic f _flicker . In FIG. 5 For example, a flicker characteristic f _{Flicker is} shown, as defined by national standards. The following information refers to the Spanish Flickernorm. For example, the control unit 14 assigns to a pulse power P ₁ of 500 W a pulse phase distance t ₁ of 6 s, a pulse power P ₂ of 2200 W a pulse phase distance t ₂ of 32 s and a pulse power P ₃ of 3300 W a pulse phase distance t ₃ of 170 s to. On the other hand, the control unit 14 can _assign a pulse power P _pulse via the patch characteristic f _{Flicker to} a pulse phase _distance tp _hcker . A requested heating power P _mean is assigned by the control unit 14, a pulse power P _pulse and a pulse phase distance t _flicker . If an adjustment of the pulse phase spacing t _{flicker occurs} due to the fluctuation S being too small or too high due to the control unit 14, the control unit 14 uses the new pulse phase spacing t _{flicker to determine} a new pulse power P _puls as a function of the flicker characteristic f _flicker . In order to set the requested heating power P _mean , the control unit selects a pulse phase duration t _ON after t _ON = P _mean / P _pulse × t _flicker .

Furthermore, the control unit 14 is provided to switch between a pulsed operation and a continuous operation in the one operating mode depending on an operator input via the operator interface 16. This allows an operator to flexibly switch between a power saving mode and a conventional mode. For example, the control unit 14 may be provided, when a maximum fluctuation S _max of 0 K is entered via the operator interface 16, to switch to continuous operation. Alternatively, the operator interface 16 may include a control provided to send a pulsed mode on / off signal to the control unit 14.

The control unit 14 is provided to dispense with an adaptation of the pulse parameters as a function of sensor values T of the sensor unit 40, 42, 44, 46 in the operating mode during a start phase of a heating operation. The starting phase is characterized by large changes in temperature, which leads to a regulation of the pulse phase spacing t _flicker and the variables associated therewith, pulse power P _puls and pulse phase duration t _ON . If a temperature of 70 ° C. is reached, an adaptation of the pulse parameters as a function of sensor values T of the sensor unit 40, 42, 44, 46 starts. If a cooking mode is selected, depending on the cooking mode, an adjustment of the pulse parameters is made only from a higher temperature, for example 90 ° C. for "cooking", 200 ° C. for "frying".

Furthermore, embodiments are conceivable in which the control unit 14 is provided to operate the heating frequency unit 20, 22, 24, 26 at heating powers P _mean , which are greater than low to medium heat outputs, ie, for example, greater than 1000 W, to operate continuously.

Furthermore, embodiments with more than one temperature sensor per induction heating unit and / or configurations in which the temperature sensor is arranged in a decentralized manner are conceivable.

Embodiments of the invention are also conceivable in which a heating frequency unit is provided to operate a plurality of induction heating units alternately.

reference numeral

10

household appliance

12

induction heating

14

control unit

16

Operator Interface

20

Heizfrequenzeinheit

22

Heizfrequenzeinheit

24

Heizfrequenzeinheit

26

Heizfrequenzeinheit

30

induction heating

32

induction heating

34

induction heating

36

induction heating

40

sensor unit

42

sensor unit

44

sensor unit

46

sensor unit

60

pulse phase

61

dormancy

62

pulse phase

63

dormancy

t _ON

Pulse phase duration

t _off

Dormancy period

P _mean

requested heating power

P

heating capacity

P _min

minimum heating power

_Pulse

pulse power

P ₁

pulse power

P ₂

pulse power

P ₃

pulse power

f _Flicker

Flickerkennlinie

t _Flicker

Pulse phase distance

t ₁

Pulse phase distance

t ₂

Pulse phase spacing

t ₃

Pulse phase distance

S

fluctuation

S _min

minimal fluctuation

S _max

maximum fluctuation

T

sensor value

.DELTA.T

temperature difference

T _max

maximum value

T _min

minimum value

η

efficiency

η _min

minimum efficiency

Claims (9)

Induction heating device, in particular induction hob device, having at least one heating frequency unit (20, 22, 24, 26), at least one induction heating unit (30, 32, 34, 36), which is operated by the heating frequency unit (20, 22, 24, 26) and at least one control unit (14), which is intended to operate the heating frequency unit (20, 22, 24, 26) pulsed in at least one operating mode, and at least one sensor unit (40, 42, 44, 46), characterized in that the control unit (14) is provided to set pulse parameters at least as a function of at least one sensor value (T) of the sensor unit (40, 42, 44, 46). Induction heater according to claim 1, characterized in that the sensor unit (40, 42, 44, 46) is provided to determine a temperature. Induction heating device according to one of the preceding claims, characterized in that the control unit (14) is provided, the pulse parameters at least in response to a variation (S, S ') of the sensor value (T) of the sensor unit (40, 42, 44, 46) set. Induction heating device according to one of the preceding claims, characterized in that the control unit (14) is provided for the heating frequency unit (20, 22, 24, 26) in at least one operating mode, in which for the at least one induction heating unit (30, 32, 34, 36) a heating power (P _mean ) is required, which in a continuous operation of the Heizfrequenteinheit (20, 22, 24, 26) to the induction heating unit (30, 32, 34, 36) is available to operate pulsed. Induction heater according to one of the preceding claims, characterized in that the control unit (14) is provided in at least one operating mode to set pulse parameters at least in dependence on at least one characteristic (f _flicker ). Induction heater according to one of the preceding claims, characterized in that the control unit (14) is provided to switch at least in response to an operator input, at least in the at least one operating mode between a pulsed operation and a continuous operation. Induktionsheizvorrichtung according to any one of the preceding claims, characterized in that the control unit (14) is provided, in at least one operating mode during a start phase of a heating process to an adjustment of the pulse parameters in dependence on sensor values (T) of the sensor unit (40, 42, 44, 46). Domestic appliance with an induction heating device (12) according to one of the preceding claims. Method for operating an induction heating device (12) according to one of the preceding claims 1 to 7.

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