WO2019024970A1 - INDUCTION HEATER - Google Patents

Abstract

An induction heater (eg, induction cooker) includes a DC power source (10), an inverter circuit (12) for converting a DC power from the DC power source (10) into an AC power (B), and an inductor (18) for inducing electric power in a heater to be heated Heating element (20) (eg cooking vessel) by the alternating current (B) flowing through the inductor (18). The inductor (18) is connected to the output of the inverter circuit (12) so that the alternating current (B) generated by the inverter circuit (12) is provided to the inductor (18). The inverter circuit (12) preferably has a switching device (14) connected to the DC voltage source (10) for generating a square wave signal (A) and a low-pass filter (16) for generating a sinusoidal alternating current (B) with a constant oscillation frequency from the square wave signal (A) ,

Description

 induction heater

The present invention relates to an induction heating apparatus, such as a induction cooker, with an inductor for inducing eddy currents in a heating element to be heated, such as a cooking vessel, by an alternating current flowing through the inductor.

Conventional induction cookers, as described for example in DE 197 08 335 B4, have an induction coil for inducing electrical energy in a cooking vessel to be heated, wherein the induction coil is installed in an electrical resonant circuit, which is excited by a switching device, so that the induction coil flows an alternating current with an oscillation frequency of, for example, 20 kHz. Since the cooking vessel or its magnetic properties affect the resonant frequency of the resonant circuit, the switching frequency of the switching device usually has to be variably adjusted.

It is the object of the invention to provide an induction heater, with which independent of the heating element to be heated, an improved mode of action can be achieved.

This object is achieved by an induction heater with the features of claim 1. Particularly preferred embodiments and modifications of the invention are the subject of the dependent claims. The induction heater has a DC voltage source and an inductor for inducing electrical energy in a heating element to be heated by an AC current flowing through the inductor. The induction heater according to the invention further comprises an inverter circuit for converting a direct current from the DC voltage source into an alternating current. The inductor is connected to the output of the inverter circuit so that the alternating current generated by the inverter circuit is provided to the inductor. In contrast to conventional induction heaters, the inductor is not part of a resonant circuit. Instead, the inductor is traversed by an alternating current, which is generated separately from an upstream inverter circuit. That is, an alternating current is generated by the inverter circuit, which then flows through the inductor, wherein this alternating current and in particular its oscillation frequency are not or at most slightly influenced by the heating element to be heated by means of the inductor. This has several advantages. Thus, regardless of the heating element to be heated, the inductor can be traversed by an alternating current generated by the inverter circuit at a constant oscillation frequency and, accordingly, the switching frequency of the inverter circuit need not be changed. The control of the inverter circuit can be simplified accordingly. The inductor is not part of a resonant circuit, so that no capacity of such a resonant circuit must be adapted to the inductor. For the inductor there is greater flexibility in terms of shape and size, since it is not part of a resonant circuit, so it can be better adapted to the particular application or the heating elements to be heated. On the other hand, the same inverter circuit can be used for different inductors used for various applications.

In addition, the electromagnetic compatibility (EMC) of the induction heater can be improved, since the inverter circuit, which is uninfluenced by the heating element to be heated, generates a sinusoidal alternating current and the inductor can be traversed by a stable sinusoidal alternating current. Furthermore, higher switching frequencies of the inverter circuit and thus higher frequencies of oscillation (eg up to 200 kHz and more) of the alternating current generated by the inverter circuit may be generated than with conventional induction heaters, so that more electrical energy can be induced in the heating element to be heated by the inductor. As a result, the induction heater according to the present invention is not limited to the use of heating elements made of a ferromagnetic material, but also heating elements of a paramagnetic material (eg, aluminum) or a diamagnetic material (eg, copper) can be heated by means of the inductor. The induction heater is preferably an induction cooker, without the invention being restricted to this application. Accordingly, the heating element to be heated is preferably a cooking vessel, without the invention being restricted to this application.

The term inductor in this context is intended to include any type of device capable of inducing electrical energy (e.g., in the form of eddy currents) in the vicinity of the inductor based on an alternating current in a heating element to be heated. The inductor preferably has at least one induction coil.

The term DC source in this context is intended to include any type of device or unit that provides a DC electrical voltage between two poles. The DC voltage source preferably has a rectifier. In one embodiment, the DC voltage source is preferably configured as a power supply.

In a preferred embodiment of the invention, the inverter circuit has a switching device connected to the DC voltage source for generating a square-wave signal and a low-pass filter for generating the alternating current from the square-wave signal. That the alternating current for the inductor is provided by the inverter circuit through the interaction of a switching device which generates a square wave signal from the direct current and the low pass filter which generates the desired alternating current from this square wave signal and provides it at the output of the inverter circuit.

The term switching device is intended in this context to include any type of device which is suitable for selectively connecting a device or circuit connected to the switching device to one or the other pole of the DC voltage source. The switching device preferably has at least one transistor as a switching element. The switching device preferably has two transistors in a half-bridge circuit. The switching device or its switching element (s) are preferably controlled by a control device. The switching device or its switching element (s) are preferably operated pulse width modulated (PWM), ie the Switching device generates from the direct current from the DC voltage source, a pulse width modulated .Rechtscksignal.

The low pass filter preferably comprises an LC element, i. preferably has at least one coil and at least one capacity. The alternating current generated by the inverter circuit is preferably a sinusoidal alternating current having a constant oscillation frequency.

In an advantageous embodiment, the inductor is connected between the output of the inverter circuit and a DC decoupling coupling.

In a preferred embodiment of the invention, the inductor is connected between the output of the inverter circuit and a capacitive voltage divider. The capacitive voltage divider preferably has two capacitances, the inductor being connected to a center lab grip between the two capacitances. The two capacitances may optionally have substantially equal or different capacitance values. The capacitances of the capacitive voltage divider do not form a resonant circuit together with the inductor in the induction heater according to the invention, but in particular are intended to block only a DC component of the alternating current through the inductor. Thus, the DC losses of the induction heater can be reduced.

In one embodiment of the invention, the inductor may comprise a plurality of induction coils for inducing electrical energy in various heating elements to be heated, which are connected to the output of the common inverter circuit. Since the heating elements to be heated do not or only slightly influence the alternating current and in particular its oscillation frequency through the induction coils, a common inverter circuit can provide an alternating current with a constant oscillation frequency for all induction coils of the inductor. The various inductors of the inductor are preferably connected via additional switching elements and / or current regulator to the common inverter circuit in order to operate the different induction coils independently and to be able to adjust the induction powers of the various induction coils independently. The above and other features and advantages of the invention will become more apparent from the following description of a preferred, non-limiting embodiment thereof with reference to the accompanying drawings. In it show, mostly schematically:

Fig. 1 is a circuit of an induction heater according to the present invention;

 and

FIG. 2 is a voltage-time diagram for two waveforms in the circuit of FIG.

 1.

FIG. 1 shows an exemplary embodiment of an induction cooker according to the invention as an example of an induction heater. The induction cooker has a DC voltage source 10, which in this example has a DC link capacitor C1, which is connected downstream of a rectifier (not shown) connected to an AC voltage source. Connected to the poles (VCC, GND) of the DC voltage source 10 is an inverter circuit 12 which converts the DC current from the DC voltage source 10 into an AC current.

This inverter circuit 12 includes a switching device 14 and a low-pass filter 16. The switching device 14 includes two transistors T1 and T2 as switching elements in a half-bridge circuit, which are each connected to a pole VCC or GND of the DC voltage source 10. The two transistors T1, T2 are driven by a controller 22, i. switched on and off. the low-pass filter 16 includes an LC element having a coil L2 and a capacitor C2. The low-pass filter 16 is on the one hand connected to the center tap between the two transistors T1, T2 of the switching device 14 and on the other hand connected to a pole (here: GND) of the DC voltage source 10.

The control device 22 controls the transistors T1, T2 of the switching device 14 in pulse width modulation (PWM) so that the center tap between the two transistors alternately with the one or the other pole of the DC voltage source 10th connected is. The PWM control of the transistors T1, T2 of the switching device 14 is preferably carried out in a technique that allows elimination of the high-frequency harmonics. As a result, a pulse-width-modulated rectangular signal A is generated by the switching device 14. From this square wave signal A, the low-pass filter B then generates a sinusoidal alternating current B having a constant oscillation frequency, which is provided at the output of the inverter circuit 12.

FIG. 2 shows, in a voltage-time diagram, the signal curve of the pulse width modulated square wave signal A at the center tap between the two transistors T1, T2 of the switching device 14 and the sinusoidal alternating current signal B at the output of the low-pass filter 16 or the inverter circuit 12.

The induction cooker further includes an inductor 18 having an inductor L1. The inductor 18 is connected on the one hand to the output of the inverter circuit 12, and on the other hand connected to a center tap between two capacitances C3, C4 of a capacitive voltage divider 24.

By means of the alternating current B generated by the inverter circuit 12, which flows through the inductor 18, the inductor 18 induces electrical energy in the form of eddy currents in a cooking vessel 20 placed in its vicinity as an example of a heating element to be heated. As a result, the cooking vessel 20 heats up.

The capacitive voltage divider 24 allows AC through the inductor 18, but blocks a DC component, so that DC losses can be reduced. In the induction cooker according to the invention, the inverter circuit 12 independently of the respective cooking vessel 20 via switching frequencies of the switching device 14 of a few hundred kHz, a sinusoidal alternating current B with a constant oscillation frequency of up to 200 kHz and more ready. In this way, with the inductor 18 not only cooking vessels 20 made of a ferromagnetic material (eg iron), but also cooking vessels 20 made of a paramagnetic material (eg Aluminum) or a diamagnetic material (eg copper). The switching frequency of the transistors T1, T2 of the switching device 14 need not be adapted to the particular cooking vessels 20 used. In addition, the stable sinusoidal oscillation of the alternating current B generated by the inverter circuit 12 improves the electromagnetic compatibility (EMC) of the induction cooker.

REFERENCE NUMBER LIST

10 DC voltage source

 12 inverter circuit

 14 switching device

 16 low pass filters

 18 inductor

 20 heating element to be heated, e.g. cooking vessel

22 control device

 24 capacitive voltage divider

Claims

An induction heating apparatus comprising a DC voltage source (10) and an inductor (18) for inducing electrical energy in a heating element (20) to be heated by an alternating current flowing through the inductor (18), characterized in that  the induction heater further comprises an inverter circuit (12) for converting a direct current from the DC power source (10) to an AC power (B); and  the inductor (18) is connected to the output of the inverter circuit (12), and the alternating current (B) produced by the inverter circuit (12) is provided to the inductor (18). An induction heater according to claim 1, wherein  the inverter circuit (12) has a switching device (14) connected to the DC voltage source (10) for generating a square wave signal (A) and a low-pass filter (16) for generating the AC current (B) from the square wave signal (A). An induction heater according to claim 2, wherein  the low-pass filter (16) contains an LC element (L2, C2). An induction heater according to any one of the preceding claims, wherein the alternating current (B) generated by the inverter circuit (12) is a sinusoidal alternating current having a constant oscillation frequency. 5. Induction heater according to one of the preceding claims, wherein the inductor (18) is connected between the output of the inverter circuit (12) and a DC decoupling circuit (24). An induction heater according to any one of the preceding claims, wherein the inductor (18) is connected between the output of the inverter circuit (12) and a capacitive voltage divider (24). An induction heater according to any one of the preceding claims, wherein the switching means (14) of the inverter circuit (12) comprises two half-bridge transistors (T1, T2). Induction heater according to one of the preceding claims, wherein the switching means (14) of the inverter circuit (12) comprises at least one switching element (T1, T2), which is switched pulse width modulated. An induction heater according to any one of the preceding claims, wherein the inductor (18) comprises a plurality of induction coils (L1) for inducing electrical energy in various heating elements (20) to be heated connected to the output of the common inverter circuit (12).