EP2214454A1 - Induction hob with multiple inductors - Google Patents

Abstract

The cooker has a control unit for activating and deactivating inductors (10a, 10b), and a switching element (68) for earthing one of the inductors. The control unit closes the switching element, and earths the inductors when the inductors are deactivated. The switching element is designed as a semiconductor switch having inverters (32a) that are connected with the inductors. The inductors are identically constructed and arranged on a two-dimensional grid. The switching element includes a transistor (64) and a diode (60) that is arranged parallel to the transistor. An independent claim is also included for a method for operating an induction cooker.

Description

The invention relates to an induction hob with a plurality of inductors according to the preamble of claim 1 and a method for operating an induction hob according to the preamble of claim 9.

From the EP 1 951 003 A1 For example, an induction hob with multiple inductors and a control unit for activating and deactivating the inductors is known. A half-bridge inverter generates a heating current for driving the inductors, and includes two semiconductor switching elements that can connect and disconnect a connection between one of the inductors and a positive pole of a rectifier or ground potential. The two semiconductor switching elements are alternately opened and closed by the control unit with the frequency of the heating current. One of the semiconductor switching elements can therefore be used for grounding at least one of the inductors, but this only happens during the active phases of the inductor in order to generate the alternating voltage. The semiconductor switches consist of a transistor with a parallel freewheeling diode.

The input lines of the half-bridge inverters and the output lines of the rectifier are connected via a damping capacitor. For example, when an alternating magnetic field is induced in an inactive inductor by the operation of an adjacent inductor, a current may be induced to flow through the freewheeling diode into the bus line of the inverter connected to the positive pole of the rectifier. A discharge of the charge is prevented by the freewheeling diode, so that the charge can accumulate in the damping capacitor. This can lead to uncontrolled discharge upon reactivation of the inductor. This uncontrolled discharge can eventually lead to damage in electronic components of the induction hob.

The object of the invention is, in particular, to provide an induction hob, in which uncontrolled charge accumulations in the bus line can be avoided.

The object is achieved by the features of the independent claims, while advantageous embodiments and modifications of the invention can be taken from the dependent claims.

The invention is based in particular on an induction hob with a plurality of inductors, a control unit for activating and deactivating the inductors and a switching element for grounding at least one of the inductors.

It is proposed that the control unit close the switching element and ground the inductor when the inductor is deactivated. As a result, charge accumulation in the bus line and uncontrolled discharges can be avoided, which ultimately damage of electronic components are unlikely and the life of the induction hob can be increased.

A separate switching element can be avoided if the switching element is a semiconductor switch of an inverter connected to the inductor, which may be in particular a transistor with insulated gate electrode.

An interaction between adjacent inductors is particularly strong in so-called matrix induction cooktops, in which the inductors are identical in construction and arranged in a two-dimensional grid. Therefore, the advantages of the invention in such induction cooktops come especially to fruition.

The risk of uncontrolled accumulation of charge exists in particular when the induction hob comprises a plurality of power electronics modules, each with at least one rectifier and at least one inverter, since then individual supply lines can be inactive, although adjacent inductors are in operation.

Since the closing of the switching element requires the application of a gate voltage and thus a certain power consumption, an unnecessary expense can be avoided, when the control unit closes the switching element and grounds the inductor only when an inductor adjacent to the grounded inductor is active. Only in this case is there the danger of the occurrence of a significant induced voltage in the inactive inductor. This is especially true when at least one inductor adjacent to the grounded inductor is associated with a different rectifier and inverter than the grounded inductor.

The risk of an accumulation of charges exists in particular when the switching element comprises a transistor and a diode arranged parallel to the transistor. When using a MOSFET, the body diode can act in this sense. An inexpensive switching element can be realized by an IGBT transistor in which the transistor has an insulated gate electrode.

A further aspect of the invention relates to a method for operating an induction hob with a plurality of inductors and a control unit for activating and deactivating the inductors and a switching element for grounding at least one of the inductors.

To improve the method according to the invention, it is proposed that the switching element is closed and the inductor is grounded when the inductor is deactivated. Thereby, as described above, the accumulation of charge in the supply line of an inverter can be avoided.

In a development of the method, it is proposed that the inductor is grounded only if at least one inductor adjacent to the grounded inductor is active.

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.

Show it:

Fig. 1

an induction hob with a plurality of inductors and a control unit in a schematic representation,

Fig. 2

a circuit diagram for the connection of two rectifiers, each with two inverters and inductors,

Fig. 3

the bus line voltage in an inactive inductor according to the prior art,

Fig. 4a and Fig. 4b

a schematic representation of the charging of the bus line according to the prior art,

Fig. 5

a schematic representation of the grounding of inactive inductors and

Fig. 6

the bus line voltage in an inactive inductor in an induction hob according to the invention.

FIG. 1 shows an induction hob with a plurality of inductors 10 and a control unit 18. The inductors 10 are distributed in a regular two-dimensional grid over the entire surface of the induction hob.

The inductors 10 are covered by a cover plate 12 made of glass or glass ceramic, on which cookware elements 14, 16 as cooking pots or pans can be placed. In order to detect the cookware elements 14, 16, the control unit 18 generates low-voltage measuring currents which flow through the inductors 10 or the oscillators comprising the inductors 10. When a cookware element 14, 16 completely or partially covers one of the inductors 10, this affects the inductance of this inductor 10. A degree of change in the inductance is related to the degree of coverage. Furthermore, the eddy current losses in the bottom of the cookware elements 14, 16 also influence the damping of the resonant circuit. The control unit 18 can therefore from the vibration characteristics of the resonant circuit, the presence and the degree of coverage of the respective inductor 10 through the cookware element Determine 14, 16 and also draw conclusions on the material properties of the cooking utensil 14, 16 and on the material properties of the bottom.

After detection of a cookware element 14, 16, the control unit 18 sums those inducers 10 which are covered with at least a certain degree of coverage from the bottom of the cookware element 14, 16 to a heating zone adapted in size, shape and position to the cookware element 14, 16 20, 22 together.

The induction hob comprises a user interface 26 with a plurality of control elements 28 and a display 24. The heating zone 20, 22 determined in the manner described above is shown as a pictogram, depending on the shape of the cooking utensil 14, 16, for example as a circle, oval or rectangle on the display 24, so that the user has an overview of the active heating zones 20, 22.

By way of the adjusting elements 28 of the user interface 26, the user can finally set a heating power for each of the heating zones 20, 22. For this purpose, the user sets a performance level that can assume, for example, integer and half-integer values between 0 and 9. The control unit 18 converts the power stage into a heating power and operates the inductors 10 so that in the inductors 10 of the respective heating zone 20, 22 a total of the desired heating power is generated.

For this purpose, the control unit 18 connects the inductors 10 of the heating zone 20, 22 with one or more inverters 32 of two power electronics modules 44, 46 of the induction hob by actuating a switching arrangement 30. The inverters 32 comprise unipolar semiconductor switches 34, which in the exemplary embodiment are formed as transistors 64, 66 with insulated-gate insulated-gate electrodes (IGBTs) (see also FIGS Fig. 2 ).

The semiconductor switches 34 arranged in a half-bridge configuration are each connected via a bus line 48, 50 (FIG. Fig. 2 ) is connected to a pole of a rectifier 36 of one of the power electronics assemblies 44, 46, which communicates via a filter circuit 38 with a phase 40, 42 of a household power network. The two power electronics modules 44, 46 are fed by two phases 40, 42 of the three-phase network.

At the output of the rectifier 36 of both power electronics modules between the bus line 48, 50 and a ground 52, 54 a damping capacitor 56, 58 is arranged in each case.

The heating current generated by the inverters 32 having a frequency which is approximately in the range of between 75 kHz and 100 kHz generates, in operation in the inductors 10, a rapidly changing magnetic field which causes eddy currents in the ferromagnetic bottom of the cookware element 14, 16. The eddy currents eventually generate heat in this soil. The frequency of the heating current is above a resonant frequency of the inductor 10, a resonant capacitor, not shown here, and the bottom of the cookware element 14, 16 comprehensive overall system. With increasing frequency, fewer and fewer white areas in the ferromagnetic bottom of the cookware element 14, 16 can follow the alternating magnetic field, so that the power dissipation and thus the heating power decreases. By varying the frequency of the heating current, therefore, the heat output coupled by the inductors 10 into the bottom of the cookware element 14, 16 can be adjusted by the control unit 18. Furthermore, the control unit 18, the inductors 10 on and off periodically to achieve a certain desired heating power in the time average.

FIG. 2 2 shows a circuit diagram for the connection of two rectifiers 36a, 36b, each with two inverters 32a, 32a ', 32b, 32b' and inductors 10a, 10b, wherein the switching arrangement 30 (FIG. Fig. 1 ) between the inverters 32a, 32a ', 32b, 32b' and the inductors 10a, 10b is not shown for reasons of clarity. In the induction hob, groups of inductors 10a, 10b are respectively associated with one of the rectifiers 36a, 36b and are typically powered by this rectifier 36a, 36b. The inductors 10a, 10b of both groups are distributed over the entire surface of the hob and arranged alternately, so that each inductor 10a, 10b in its immediate vicinity typically has a plurality of inductors 10a, 10b from the other group, respectively, due to the nested structure in FIG. 2 is shown. If one of the inductors 10b is operated or charged with the heating current, this induces Inductor 10b therefore always an alternating field in the adjacent inductors 10a of the other group.

FIG. 3 Figure 3 shows the bus line voltage in an inactive inductor 10a, 10b in an arrangement similar to the prior art when one of the inductors 10a is inactive and an adjacent inductor 10b is active. The lower bold curve shows the output voltage of the active rectifier 36b and the upper dashed curve shows the voltage in the bus line 48 of the inactive rectifier 36a. It can be seen that charge accumulates in the bus line 48.

The reason for this charge accumulation is in the FIGS. 4a and 4b shown schematically. There is shown an inactive inductor 10a with an inverter 32a, the current carrying lines being shown in bold and the directions of the currents being illustrated by arrows. FIG. 4a shows a phase in which a positive voltage is induced in the inductor 10a. The induced current may flow through the upper diode 60 of the inverter 32a into the bus line 48 and accumulate in the snubber capacitor 56.

FIG. 4a shows a phase in which a negative voltage is induced in the inductor 10a, 10b. The charge accumulated in the bus line 48 can not drain away, so that a cumulative charge accumulates in the bus line 48 or in the snubber capacitor 56 connected to this bus line.

FIG. 5 shows a schematic representation of the grounding of an inactive inductor 10a. The upper inductor 10b is operated by the first rectifier 36b and generates a magnetic field that is a voltage in the in FIG. 5 Inductor 10a shown below is induced.

In the prior art, the insulated gate transistors 64 of the inverter 32a associated with the lower inductor 10a would both be disabled in the inactive state of the inverter so that no current could flow through the transistors 64.

According to the invention, however, it is proposed that the control unit close the switching element 68 by switching the lower transistor 64 of the lower inverter 32a to ON, thereby grounding the inductor 10a, although the lower inductor 10a is deactivated. The inductor 10a then forms a closed resonant circuit with the capacitor 72 connected in series with the inductor 10a, and the voltage induced in the inductor 10a can easily drain off. Since the diode 60 in the upper switching element 70 of the inverter 32a has a greater intrinsic resistance than the on-pass transistor 64 of the lower switching element 68, the current can not flow into the bus line 48.

FIG. 6 shows the bus line voltage in an inactive inductor 10a, 10b in an induction hob according to the invention. The comparison to FIG. 3 shows that the voltage in the bus line 48 does not rise above the voltage generated by the rectifier, so that uncontrolled discharges of the bus line 48 and the snubber capacitor 56 can be avoided.

The control unit 18 is a universally programmable arithmetic unit into which a method for operating an induction cooktop with a plurality of inductors 10a, 10b is implemented. The control unit 18 activates and deactivates inductors 10a, 10b of the induction hob and actuates by control signals by means of control lines (not shown here) various switching elements, in particular switching elements of the switching arrangement 30 and the inverters 32.

reference numeral

10

inductor

10a

inductor

10b

inductor

12

cover

14

Cookware element

16

Cookware element

18

control unit

20

heating zone

22

heating zone

24

display

26

User interface

28

actuator

30

switching arrangement

32

inverter

32a

inverter

32a '

inverter

32b

inverter

32b '

inverter

34

Semiconductor switches

36

rectifier

36a

rectifier

36b

rectifier

38

Filter circuit

40

phase

42

phase

44

Power electronics module

46

Power electronics module

48

Bus line

50

Bus line

52

grounding

54

grounding

56

snubber capacitor

58

snubber capacitor

60

diode

62

diode

64

transistor

66

transistor

68

switching element

70

switching element

Claims (10)

Induction hob with a plurality of inductors (10, 10a, 10b) and a control unit (18) for activating and deactivating the inductors (10, 10a, 10b) and a switching element (68) for grounding at least one of the inductors (10, 10a, 10b), characterized in that the control unit (18) closes the switching element (68) and grounds the inductor (10, 10a, 10b) when the inductor (10, 10a, 10b) is deactivated. Induction hob according to Claim 1, characterized in that the switching element (68) is a semiconductor switch of an inverter (32, 32a, 32b) connected to the inductor (10, 10a, 10b). Induction hob according to one of the preceding claims, characterized in that the inductors (10, 10a, 10b) are of identical construction and are arranged in a two-dimensional grid. Induction hob according to one of the preceding claims, characterized by a plurality of power electronics modules (44, 46) each having at least one rectifier (36, 36a, 36b) and at least one inverter (32, 32a, 32b). Induction hob according to one of the preceding claims, characterized in that the control unit (18) only closes the switching element (68) and grounds the inductor (10, 10a, 10b) when one adjacent to the grounded inductor (10, 10a, 10b) Inductor (10, 10a, 10b) is active. Induction hob according to one of the preceding claims, characterized in that at least one of the grounded inductor (10, 10a, 10b) adjacent inductor (10, 10a, 10b) to another rectifier and another inverter (32, 32a, 32b) is assigned as the grounded inductor (10, 10a, 10b). Induction hob according to one of the preceding claims, characterized in that the switching element (68) comprises a transistor (64) and a parallel to the transistor (64) arranged diode (60). Induction hob according to claim 6, characterized in that the transistor (64, 66) has an insulated gate electrode. Method for operating an induction hob with a plurality of inductors (10, 10a, 10b) and a control unit (18) for activating and deactivating the inductors (10, 10a, 10b) and a switching element (68) for grounding at least one of the inductors (10, 10a , 10b), characterized in that the switching element (68) is closed and the inductor (10, 10a, 10b) is grounded when the inductor (10, 10a, 10b) is deactivated. A method according to claim 9, characterized in that the inductor (10, 10a, 10b) is grounded only when at least one to the grounded inductor (10, 10a, 10b) adjacent inductor (10, 10a, 10b) is active.

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