KR940002503Y1 - Automatic inverter of induction heating cooker - Google Patents

Abstract

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Description

Automatic switching inverter output of induction cooker

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

2 is a block diagram of a conventional heating coil.

FIG. 3 is a sub waveform diagram of FIGS. 1 and 2.

4 is a circuit diagram of the output automatic switching inverter of the induction heating cooker according to the present invention.

5 is a block diagram of a heating coil according to the present invention.

* Explanation of symbols for main parts of the drawings

1: phase detector 2: power transistor driver

10: heating section 11: current detection section

12: micom 13: power control unit

14: relay driver C.T: current transistor

The present invention relates to an inverter of an induction heating cooker, and more particularly, to an automatic switching inverter output of the induction heating cooker to solve the problems of output and uniform heating according to the size of the heating vessel.

As a driving circuit of the conventional heating cooker of FIG. 1, as shown therein, an AC power source AC is applied to both ends of the brazed diode BD1, and the outputs of the bridge diode BD1 are connected in parallel to each other to perform a resonance action. The voltage is applied from the collector of the transistor Q1 through the choke coil L1 and the condenser C1, and the voltage across the heating coil L10 is applied to the phase detector 1, and the phase detector 1 It is comprised so that it may be driven by the output by transistor Q1.

The operation and problems with respect to the conventional circuit as described above are as follows.

First, when the power transistor Q1 is turned on, the current flows to the collector while it is turned off. When the power transistor Q1 is turned off, resonance occurs between the heating coil L10 and the condenser C1 to exchange energy with each other.

In this section, when a high voltage is generated at both ends of the heating coil L10 and the energy exchange is completed once in the resonant circuit, the discharge current flows through the reverse conducting diode D1 in the capacitor C1 and the flow of the discharge current flows. When the zero point is reached, the power transistor Q1 is forcibly turned on to repeat the above operation.

When the power transistor Q1 is switched on / off at a high frequency, a heating current 13, such as a third degree, is generated and flows in the heating coil L10, and a magnetic field is formed around the coil L10 to heat the heating. Magnetic lines caused by the large current flowing through the coil (L10) are combined with the heating vessel to generate Joule heat to heat food.

However, the circuit described above uses a single heating coil (L10) as shown in FIG. 2, and therefore, when used for a business that requires a large output, the heating area of the heating container is not detected because the container having a large heating area is not detected. There is a problem in the uniform heating because it can not control the output according to the size and the heating area of the container is large and heats a certain part regardless of the size.

Therefore, the present invention can be used to combine the high power and low power output according to the size of the heating area of the container by using two heating coils separately in consideration of the deficiencies of the conventional circuit as described above. When used as a high-power output is designed to perform a uniform heating, which will be described in detail as follows.

4 is a circuit diagram of the present invention, when a large vessel is used by receiving an AC power source AC input through the bridge diode BD1 and the high frequency choke coil L1 as shown therein, according to the contact point of the relay RY1. The resonant circuit is formed by the heating coils L10 and L11 and the condenser C11, and when the heating vessel is small, the heating unit 10 constituting the resonant circuit by the heating coil L10 and the condenser C10, and the heating The current detecting unit 11 for detecting the resonant current flowing through the resonant circuit of the unit 10 and the current of the current detecting unit 11 are compared with the predetermined data, and the relay driver 14 is controlled according to the value to control the relay ( The control signal from the microcomputer 12 which converts the contact of RY1, the phase detection part 1 which detects a phase by detecting the voltage of the both ends of the heating coils L10, L11, and the power transistor drive part 2, Flow current to heating coils L10 and L11 It is composed of a power control unit 13.

The present invention configured as described above will be described in detail the operation and effect.

First, the container is placed on the heating coils L10 and L11 as shown in FIG. 5, and when the heating area of the container is large, the container is heated by the heating coils L10 and L11, and only by one coil L10 when the heating area is small. Heat the vessel.

That is, when the initial induction heating cooking is initially driven in FIG. 4 of the present invention, the two-contact relay RY1 operates in a state in which it is connected to the contact point 1. At this time, two heating coils L10 and L11 and a condenser are operated. Resonance occurs due to the high frequency switching of the transistor Q10 by C11, and the high frequency current due to the resonance flows to the collector of the power transistor Q10 as an emitter. The current transformer CT senses the high frequency current. During normal resonance by the heating coils L10 and L11 and the condenser C11, that is, when heating a large vessel that couples with the magnetic force lines caused by the high frequency current flowing through the heating coils L10 and L11, a current transformer for each power level ( Compared with the data of the microcomputer 12 set based on the current value detected by CT), the 2-contact relay RY1 is kept at the initial contact 2 state, and the heating is continued. If the value is less than the value, the area of the heat container is small, and it is determined that the magnetic force lines by the external heating coils L10 and L11 do not combine with the container. The resonance state is turned off once, and the relay RY1 is connected to the contact 1 state, and the power transistor ( Q10) is driven by resonance by a single heating coil L10 and a condenser C10 to heat the container, which is advantageous in terms of uniform heating when heating a container having a large output and area suitable for the container area.

The reason why the resonance state is turned off and the relay RY1 is connected to the contact 1 state is because the on-off time of the power transistor Q10 for high frequency switching cannot be set because the relay RY1 is a mechanical contact.

Therefore, if the power transistor Q10 moves the relay RY1 contact during high frequency switching, that is, during resonance, there is a risk of breakage because a large high voltage is exceeded between the collector and the emitter of the power transistor Q10 due to a high voltage. .

As described above, the present invention separates and uses two heating coils, and according to the size of the heating area of the container, high power and low power output can be used in combination. It is also advantageous in terms of heat.

Claims (2)

In the induction heater for operating the heating coil (L10) by detecting the phase difference of the voltage appearing in the heating coil (L10) through the phase detection unit (1) and control the power transistor driver (2) accordingly, the heating coil ( Another heating coil L11 is connected in series with L10 to operate a resonant circuit by a single heating coil L10 or two heating coils L10 and L11 according to the contact of the relay RY1 to heat the container. The control unit outputs a control signal by comparing the heating unit 10, the current detection unit 11 for detecting the resonance current flowing into the heating unit 10, and the resonance current detected by the current detection unit 11 with reference data. An output automatic switching inverter of the induction heating cooker comprising a relay driving unit (14) for converting the contact of the relay switch (SW1) according to the control signal of the microcomputer (12) and the microcomputer (12). The power transistor (Q10) is turned off by the control signal of the microcomputer 12 when the relay driver 14 converts the contact point of the relay switch Sw1. Q10) output switching inverter of the induction heating cooker comprising a power transistor drive unit for controlling the drive.