KR860001850Y1 - High frequency output control apparatus of magnetron - Google Patents

Abstract

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Description

Magnetron's High Frequency Output Control

1 is a circuit diagram of a high frequency generator of a magnetron to which the present invention is applied.

2 is a detailed circuit diagram of the switching circuit of FIG.

* Explanation of symbols for main parts of the drawings

1: switching circuit part 2: double voltage rectifier circuit

3: magnetron 4: microprocessor

5: photocoupler T: transformer

R ₁ -R ₅ : Resistor Q ₁ : Transistor

The present invention relates to a high frequency output control apparatus of a magnetron that connects a semiconductor switch element to the cathode side of the magnetron to effectively control the high frequency output of the magnetron.

In the conventional magnetron high frequency output control device, since the secondary voltage of the high voltage transformer applied to the cathode side of the magnetron is high voltage, in order to control the cathode side of the magnetron, a capacity having a higher breakdown voltage than the secondary voltage of the high voltage transformer is required. A large and complex switch was required, resulting in a cost increase of the magnetron high frequency output control device.

In view of this, the present invention connects the photo-collar receiver between the secondary winding for low voltage generation of low voltage of the high voltage transformer and the cathode side of the magnetron, and controls the photo coupler with a microprocessor to control the high voltage applied to the cathode side of the magnetron. The present invention will be described in detail with reference to the accompanying drawings as a simple design to control the secondary voltage of the transformer as follows.

1 is a circuit diagram of a high frequency generator of a magnetron to which the present invention is applied, and FIG. 2 is a detailed circuit diagram of the switch circuit unit 1 of FIG. 1, and as shown in FIG. ₁ , 2 of the transformer T connected to the power switch SW ₁ . The secondary winding T ₂ is connected to the cathode 3 _a of the magnetron 3, and the secondary winding T ₃ of the transformer T is a double voltage rectification composed of a capacitor C ₁ and a diode D ₁ . In the high-frequency generator of the magnetron connected to the cathode 3a and the anode 3b of the magnetron 3 via the circuit 2, the output side of the microprocessor 4 is connected to the resistor R via a resistor R ₁ . _2, and a transistor connected to the light emitting portion (5a) of a photo coupler (5) connected to the base of Q ₁₎ to the collector of the transistor (Q ₁₎ through the resistor (R _3), and a photo coupler (5) between the secondary side winding of the light-receiving section (5b), said transformer (T) to node side (1a) and cathode (1b) of the (T ₂₎ and a cathode (3a) of the magnetron (3) Be configured to access, and reference numeral of the description of the drawing R _4, R ₅ is the resistance, and the AC is AC power, V _C is a direct current power source.

Referring to the effects of the present invention configured as described above are as follows.

When the AC power supply AC is applied to the primary winding T ₁ of the transformer T by shorting the power switch SW ₁ , the low voltage is applied to the secondary windings T ₂ and T ₃ of the voltage transformer T. And high voltage are induced respectively. At this time, when the switching circuit unit 1 is ON, the low voltage induced in the secondary winding T ₂ is applied to the cathode 3a of the magnetron 3 to heat the cathode 3a, and further, the secondary winding ( When the organic high voltage to T ₃₎ polarity through the diode (D ₁₎ of the voltage doubler rectifier circuit (2) that a high voltage is a high voltage in the capacitor (C ₁₎ and a diode (condenser flows through the D ₁₎ (C ₁₎ Is charged, and when the polarity of the voltage induced in the secondary winding T ₃ is changed, the diode D ₁ of the double voltage rectifying circuit 2 is turned off, so that the anode 3b and the cathode 3a of the magnetron 3 are turned off. Between the voltage charged in the capacitor (C ₁ ) and the voltage induced in the secondary side winding (T ₃ ) is applied, and if the polarity of the voltage induced in the secondary side winding (T ₃ ) is changed again to the capacitor (C ₁ ). applying the voltage induced in the filled precursor and the secondary side winding (T _3), and, changes the polarity of the voltage induced in the secondary coil again (T3) re- Condenser, so that repeated operation in which the charge on the (C _1), a magnetron (3), and outputs a high frequency by the oscillation.

At this time, the high frequency output is interrupted as the switching circuit unit 1 is turned on and off. That is, when a high potential signal is output to the output side of the microprocessor 4, the high potential signal turns on the transistor Q ₁ through the resistor R ₁ , so that the power supply V _C emits light from the photocoupler 5. The light flows through the portion 5a, the resistor R ₃ , and the transistor Q ₁ to emit light from the light emitting portion 5a of the photocoupler 5.

Accordingly, since the light-receiving portion 5b of the photocoupler 5 conducts in response to the light emitted from its light-emitting portion 5a, the voltage induced in the secondary winding line T ₂ of the transformer T is transferred to the resistor R ₄ and It is applied to the magnetron 3 cathode 3a through the light receiving portion 5b of the photocoupler 5, and high frequency is output from the magnetron 3 as described above.

However, if the output signal of the microprocessor 4 has a low potential, the low potential signal is applied to the base of the transistor Q ₁ through the resistor R ₁ to turn it off so that the light emitting portion 5a of the photocoupler 5 is turned off. ), The flow of power (V _C ) is blocked so that light does not emit from the light emitting portion (5a), and accordingly the light receiving portion (5b) of the photocoupler 5 is turned off, so the secondary winding (T ₂ ) of the transformer (T) The application of the induced voltage to the cathode 3a of the magnetron 3 is interrupted to stop the oscillation operation of the magnetron 3.

As described above, the present invention can easily control the high frequency output of the magnetron because the power is supplied to or cut off the cathode of the magnetron by turning on or off the photocoupler as an output signal of the microprocessor, and the photocoupler for switching is a direct current. Since it is operated by a power source, its size and capacity can be miniaturized, thereby reducing the cost of the product and improving the life of the product.

Claims (1)

The two-side winding T ₂ of the transformer T is connected to the cathode 3a of the magnetron 3, and the secondary winding T ₃ is connected to the cathode of the magnetron ₃ via the double voltage rectifier circuit 2. In the high-frequency generator of the magnetron connected to 3a) and the anode 3b, the collector of the transistor Q ₁ connected to the base of the output of the microprocessor 4 is connected to the photocoupler 5 through the resistor R ₃ . ) Is connected to the light emitting portion 5a of the photocoupler 5, and the anode shaft 1a and the cathode side 1b of the light receiving portion 5b of the photocoupler 5 are connected to the secondary winding T ₂ and the magnetron of the transformer T. High frequency draw out control device for magnetron, characterized in that it is connected between cathodes 3a of (3).