KR0152836B1 - Frequency band conversion circuit of induction cooker - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frequency band converting circuit of an induction heating cooker. Conventionally, when a ferromagnetic container is mounted on a working coil, a reactance value (L) is fixed and a resonance frequency is formed according to the value of the resonance capacitor. In order to supply power with electric current, the current detector detects the current and generates the frequency accordingly. However, when a container with paramagnetic body is mounted, the reactance value is considerably lower than the reactance value of the container with ferromagnetic material. Since there is no frequency band, there was a problem that the frequency band should be changed. Accordingly, the present invention detects the amount of current flowing through the load to determine whether the load is ferromagnetic or paramagnetic, and then converts the capacitor value according to the control output of the microprocessor to change the frequency band so that the desired power is independent of the type of container. Enable output.

Description

Frequency band conversion circuit of induction cooker

1 is a circuit diagram of a heating apparatus of a conventional induction heating cooker.

2 is a frequency band conversion circuit diagram of the induction heating cooker of the present invention.

* Explanation of symbols for main parts of the drawings

11 rectifier 12 inverter section

13: cooking vessel 14: walking coil

15: drive circuit portion 16: load detection and voltage conversion unit

17 frequency generator 18 microprocessor

19: frequency band conversion unit 20: voltage control unit

The present invention is to change the frequency band as the reactance value changes according to the material of the container in the induction heating cooker and the resonant frequency band is changed, in particular, it is determined whether the container mounted on the working coil is ferromagnetic or paramagnetic and outputs the desired power accordingly. It relates to a frequency band conversion circuit of an induction heating cooker to change the frequency band so that it can. As shown in FIG. 1, the circuit arrangement of the heating apparatus of the conventional induction heating cooker resonates the AC power inputted to rectify and converts the AC power into a DC voltage, and resonates the voltage output from the rectifier 11. And a working coil 14 to induce an eddy current in the cooking vessel 13 to be heated by the electric induction effect due to the magnetic field generated by the resonance voltage to heat the food in the cooking vessel 13 to a desired heating temperature. In order to control the inverter unit 12 and the switching element of the inverter unit 12 to provide a resonant voltage to the working coil 14 by switching the DC voltage supplied from the rectifying unit 11 according to a switching control signal. A driving circuit unit 15 for outputting a switching control signal, a current detector CT for detecting a current from the input AC power source AC, and whether a load is present depending on the amount of current detected by the current detector CT. To Load detection and voltage conversion unit 16 for converting and outputting a current value according to the presence or absence of the detected load into a voltage, and reducing the output current according to the position change of the load in the load detection and voltage conversion unit 16. And a voltage controller 20 for maintaining a constant output power according to the increase, a frequency generator 17 for outputting a frequency by varying a frequency according to the voltage variation of the voltage controller 20, and the frequency generator. It consists of a driving circuit section 15 that receives the frequency of (17) so that the switching element can be switched alternately in accordance with the frequency.

Referring to the prior art configured in this way in detail as follows. When the user wants to cook in the electromagnetic induction cooker, the AC voltage input by rectifying the input AC power to the rectifier 11 supplies the inverter unit 12. At this time, when the user puts the food of the dish to be performed in the cooking vessel 13 and selects the corresponding key not shown, cooking starts. On the other hand, since the current flowing to the switching element of the inverter unit 13 is driven in response to the switching control signal generated from the driving circuit unit 15, the working coil 14 and the resonant capacitor C2 are input from the inverter unit 12 Continuous LC resonance is caused by the applied DC voltage. Therefore, a large resonance current flows through the working coil 14. The magnetic field is generated in the working coil 14 by the resonance current, and an eddy current is induced in the cooking vessel 13 to be heated due to the electromagnetic induction effect by the magnetic field, thereby heating the cooking vessel 14 and the cooking vessel. Food in (13) is heated. In this case, when the current detector CT operates after the cooking vessel 13 is placed on the working coil 14, the current detector CT detects an amount of current supplied to the load and provides the current to the load detection and voltage change unit 16. The load detecting unit and the voltage converting unit determine whether the load is a small load or a magnetic container according to the amount of current provided from the current detector CT, and discriminates whether a proper current flows in the load so that a proper current flows in the voltage control unit 20. Voltage control is performed to generate an appropriate frequency and output to the frequency generator 17. Therefore, the voltage control unit 20 which receives the voltage output from the load detection and voltage conversion unit 16 outputs the frequency according to the control voltage to the frequency generating unit 17, and this output is output to the driving circuit unit 15. In the case of the small load, the driving circuit unit 15 is controlled so as not to generate a frequency, and if the magnetic circuit is judged as a magnetic container, the driving circuit unit 15 generates an appropriate frequency for cooking. To control the switching element of the inverter unit 12. In this manner, the switching element of the inverter unit 14 is turned on or off to effectively drive the working coil 14 to heat the food in the cooking vessel 14 to perform a desired dish. However, in the conventional circuit as described above, when the ferromagnetic container is mounted on the working coil, the reactance value L is fixed, and a resonance frequency is formed according to this and the value of the resonance capacitor, and power is supplied at a desired power. The current detector detects the current and generates a frequency accordingly. However, when a container with paramagnetic body is mounted, the reactance value is considerably lower than the reactance value of the container with ferromagnetic material. There is a problem of changing the frequency band. Accordingly, the present invention for solving the conventional problem is to detect the amount of current flowing in the load to determine whether the load is a ferromagnetic or paramagnetic, induction heating to change the frequency band by converting the capacitor value according to the control output of the microprocessor It is to provide a frequency band conversion circuit of the cooker. Another object of the present invention is to provide a frequency band conversion circuit of an induction heating cooker to lower the frequency band when the load is a ferromagnetic material and to raise the frequency band when the load is a paramagnetic material. The circuit of the present invention for achieving the above object is based on the rectifying means for rectifying the input AC power to a DC voltage, and the magnetic field generated by the resonance voltage resonating the rectified DC voltage through the rectifying means A working coil which induces an eddy current in the cooking vessel to be heated by the electric induction effect and heats the food in the cooking vessel to a desired heating temperature, and switches the DC voltage supplied from the rectifying means according to a switching control signal to the working coil. Inverter means for providing a resonance voltage, drive means for outputting a switching control signal for controlling the switching element of said inverter means, current detecting means for detecting a current from said input AC power source AC, and said current detecting means Detects the presence or absence of a load according to the amount of current detected through the output, and outputs the voltage value according to the presence or absence of the detected load. A load detection and voltage conversion means, a microprocessor for outputting an appropriate control signal according to the type of load detected through the load detection and voltage change means, a control output of a saik microprocessor and the load detection and voltage conversion unit 16 It converts the capacitor value in accordance with the voltage output of the) to change the frequency band and constitutes a frequency conversion means for output to the drive means. Referring to the operation and effect of the present invention configured as described in detail as follows. When the user wants to cook in the electromagnetic induction cooker, the AC voltage input by rectifying the input AC power to the rectifier 11 supplies the inverter unit 12. In this case, since the current flowing to the switching element of the inverter unit 13 is driven in response to the switching control signal generated from the driving circuit unit 15, the working coil 14 and the resonant capacitor C2 are driven by the inverter unit 12. The input DC voltage leads to continuous resonance. Therefore, a large resonance current flows in the working coil 14. The magnetic field is generated in the working coil 14 by the resonance current, and an eddy current is induced in the cooking vessel 13 to be heated due to the electromagnetic induction effect by the magnetic field, thereby heating the cooking vessel 14 and the cooking vessel. The food in (13) is heated to a heating temperature. In this case, when the current detector CT operates after the cooking vessel 13 is placed on the working coil 14, the current detector CT detects the amount of current supplied to the load and provides the load detection and voltage converter 16. The load detection and voltage conversion unit 16 determines whether the cooking vessel is a ferromagnetic vessel or a paramagnetic vessel according to the amount of current provided from the current detector CT. In the case of starting by turning on, in the case of ferromagnetic material, the current is not sensed by the current detector CT. In this case, when the transistor Q1 is turned on and starts to operate again, the electric power is sensed while the current is sensed. It outputs to the frequency band conversion part 19 as much as possible.

In addition, when the transistor Q1 is turned off, the paramagnetic is operated while the current is detected by the current detector C.T.

In the case of the small load, the microprocessor 18 recognizes the small load because the current is not detected in the current detector C.T even when the transistor Q1 is turned on or off.

Therefore, the voltage control unit 20 which receives the voltage output from the load detection and voltage conversion unit 16 outputs the frequency according to the control voltage to the frequency generating unit 17, and this output is output to the driving circuit unit 15. In the case of the small load, the driving circuit unit 15 is controlled so as not to generate a frequency, and if the magnetic container is judged, the driving circuit unit 15 generates a frequency at which the cooking can proceed, and the driving circuit unit 15 is operated. To control the switching element of the inverter unit 12. At this time, when it is determined that the cooking vessel 13 determined by the load detecting and voltage converting unit 16 is a ferromagnetic material, the microprocessor 18 outputs a control signal in a low state to its output terminal P1 to produce a transistor Q1. ), The frequency band is set to a low frequency band, and in the case of a paramagnetic body, a control signal in a high state is output and the transistor Q1 is turned on to control the frequency band high. That is, when the cooking vessel 13 is a ferromagnetic material, the transistor Q1 of the frequency band converter 19 is in a conductive state, and the capacitor value C is C = C11, and the load detection and voltage converter 16 The output voltage is input to the voltage controller 20, and the voltage controller 20 controls the voltage to generate a proper frequency compared with the reference voltage, and this voltage is divided by the resistors R1 and R2 to comparator COMP1. ) Is input to the inverting terminal (-) of the (), divided by the resistors (R1) (R2) (R3) and input to the non-inverting terminal (+) of the comparator (COMP2). At this time, the capacitor value C is input to the inverting terminal (+) of the comparator COMP1 and the non-inverting terminal (-) of the comparator COMP2, respectively. Accordingly, the value compared by the comparator COMP1 while being initially charged becomes a low state and the value compared by the comparator COMP2 becomes a high state and is input to the RS flip flop F / F1. As a high signal is input to the S input terminal of the RS flip flop F / F1 and a low signal is input to the R input terminal, a low state signal is output to the inverting output terminal Q thereof so that the field effect transistor FET It is turned off as it is applied to the base. Accordingly, as the charge of T1 = K (R3 + R4 + C) is made, the transistor Q1 is kept in the on state. Where C is C = C1 + C2. The value compared by the comparator COMP1 goes high and the value compared by the comparator COMP2 goes low and is input to the RS flip flop F / F1. As the high signal is input to the S input terminal of the RS flip flop F / F1, a high state signal is output to its inverting output terminal Q and is turned on as it is applied to the base of the field effect transistor FET. As the capacitor C discharges through the resistor R5, T2 = K R5 C is established, and the transistor Q1 is turned off during this period. Where C is C = C11.

As described in detail above, the present invention is to determine whether the cooking vessel is a ferromagnetic or paramagnetic body to lower the frequency band when the cooking vessel is ferromagnetic, and to raise the frequency band when the cooking vessel is paramagnetic is mounted on the working coil There is an effect that can output the desired power regardless of the type of container.

Claims (3)

A rectifying means for rectifying the input AC power to a DC voltage and resonating the DC voltage rectified through the rectifying means and applying an eddy current to the cooking vessel to be heated by an electric induction effect due to the magnetic field generated by the resonance voltage. A working coil for inducing and heating the food in the cooking vessel to a desired heating temperature, an inverter means for switching a DC voltage supplied from the rectifying means according to a switching control signal to provide a resonance voltage to the working coil, and the inverter Driving means for outputting a switching control signal for controlling the switching element of the means, current detecting means for detecting a current from the input AC power source, and load of the load according to the amount of current detected through the current detecting means. Induction cooker having a load detection and voltage conversion means for determining the presence and absence of the cooking vessel material and output the voltage accordingly A microprocessor for recognizing a cooking vessel material determined by the load detection and voltage conversion means and outputting a control signal according thereto, and converting a capacitor value according to the output of the load detection and voltage conversion means, the frequency of the frequency generating means. A frequency band converting circuit of an induction heating cooker comprising a frequency band converting means for changing a band and allowing heating of either a paramagnetic or a ferromagnetic material. The frequency band conversion circuit of an induction heating cooker according to claim 1, wherein the microprocessor outputs a high signal to its output terminal when the ferromagnetic material and a low signal when the paramagnetic material is used. The frequency band converting circuit of an induction heating cooker according to claim 1, wherein the frequency converting means lowers the frequency band in the case of a ferromagnetic material and increases the frequency band in the case of a paramagnetic material.