KR200157094Y1 - Magnetron driving circuit - Google Patents

Abstract

The present invention relates to a magnetron driving circuit. In a magnetron driving circuit for transforming and rectifying a commercial AC voltage input from the outside and supplying the same to the magnetron 30, the commercial AC voltage inputted from the outside is short-circuit or open. The triac 45 to be supplied or cut off), the short circuit or open to short-circuit or open the triac 45 to open or close the triac 45, and a commercial AC voltage input from the outside to charge and discharge the die. It further comprises a current limiting portion 40 made up of a triac gate control section 46 including a capacitor (C2) for shorting or opening the evil 43, limiting the primary current of the transformer 10 By suppressing the increase in the anode current flowing through the magnetron 30, the magnetron due to overheating generated in the magnetron 30 in accordance with the increase of the anode current Damage to 30 can be prevented.

Description

Magnetron driving circuit

The present invention relates to a magnetron, and more particularly, to a magnetron driving circuit capable of suppressing an increase in the anode current flowing through the magnetron by limiting a primary current of a transformer.

In general, magnetron is a device in which the hot electrons emitted from the cathode generate microwaves by high frequency oscillation under the influence of the vertical magnetic field generated by the electric field of the anode and a pair of permanent magnets.

The driving circuit using the full-wave rectification circuit of the magnetron includes a transformer 10, a full-wave rectifier 20, and a magnetron 30 as shown in FIG.

The transformer 10 converts the input commercial AC voltage into a predetermined low voltage and a high voltage. The transformer 10 includes a primary coil 13, a low voltage coil 15, and a high voltage coil 17. One side of the coil 15 is connected to one side of the cathode 33 in the magnetron 30, and the other side of the low voltage end coil 15 is contacted with one side of the output terminal of the full wave rectifying unit 20 to allow the cathode 33 to be connected. And the other end of the high voltage end coil 17 are connected to both ends of the input terminal of the full wave rectifying unit 20, respectively.

In addition, the full-wave rectifier 20 rectifies a predetermined high voltage and supplies a predetermined DC voltage, and includes four rectifying diodes D1, D2, D3, and D4, and both ends of the input terminal are high voltage stage coils. (17) is connected to both ends, respectively, one side of the output terminal is connected to the contact of one side of the low voltage stage coil 15 and one side of the cathode 33, the other side of the full wave rectifying section 20 output terminal It is connected to the anode 35 in the magnetron 30.

In addition, the magnetron 30 generates microwaves, and includes a cathode 33 and an anode 35, and one side of the cathode 33 is connected to one side of the low voltage end coil 15 and the other side. Is connected to the other side of the low voltage stage coil 15 and the one side of the output terminal of the full wave rectifier 20, and the anode 35 is connected to the other side of the full wave rectifier output.

In the magnetron driving circuit using the conventional full-wave rectifying circuit configured as described above, when a commercial AC voltage is applied to both ends A and B of the first-stage coil 13 of the transformer 10, the current is applied to the first-stage coil 13. As I1) flows, a low voltage is induced in the low voltage stage coil 15, and the cathode 33 becomes a high temperature due to resistance heat generated by current flowing through the cathode 33 in the magnetron 30 by the induced low voltage. At the same time as the current 11 flows in the primary coil 13, a high voltage is induced in the high voltage stage coil 17, the induced high voltage is full-wave rectified by the full-wave rectifier 20, the full-wave rectification The high voltage is applied to the magnetron 30 to generate an electric field at the anode 35 in the magnetron 30.

However, the magnetron driving circuit using the conventional full-wave rectification circuit as described above generates heat while the magnetron is operated, and the generated heat attenuates the vertical magnetic field generated by the pair of permanent magnets, and generates the pair of permanent magnets. When the perpendicular magnetic field is attenuated, the number of thermoelectrics reaching the positive electrode among the hot electrons emitted from the negative electrode of the magnetron increases, thereby increasing the positive electrode current Ia flowing through the positive electrode.

In addition, when the anode current Ia is increased, heat is generated by the resistance loss as much as the increase of the current, and the vertical magnetic field generated in the pair of permanent magnets by the resistance loss heat is further attenuated so that the anode current Ia is further reduced. Will increase.

Therefore, as described above, when the vicious cycle in which the anode current Ia is increased is repeated, there is a problem that the magnetron is damaged by an excessive amount of the anode current Ia.

Accordingly, the present invention has been made to solve the above problems, to provide a magnetron driving circuit that can prevent damage to the magnetron by limiting the primary current of the transformer to suppress the increase of the anode current flowing through the magnetron. The purpose is.

In order to achieve the above object, the magnetron driving circuit according to the present invention is a magnetron driving circuit for transforming and rectifying a commercial AC voltage input from the outside and supplying the same to the magnetron, by limiting the amount of current of the commercial AC voltage to flow through the magnetron. Characterized in that it comprises a current limiting unit for suppressing the increase of the current.

The current limiting unit may include a triac for controlling the gate of the triac to short-circuit or open the triac and the triac to short-circuit or open the commercial AC voltage supplied from the outside to the magnetron. It is done.

The triac gate control unit may be shorted or opened to short-circuit or open the triac, and a capacitor configured to charge / discharge by a commercial AC voltage input from the outside to short-circuit or open the diaac, and the capacitor Characterized in that it comprises a variable resistor for controlling the charge and discharge time.

1 is a magnetron driving circuit diagram using a conventional full-wave rectification circuit.

2 is a magnetron driving circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10: transformer 20: full wave rectifier

30: magnetron 40: current limiting part

43: diaak 45: triac

46: triac gate control unit

Hereinafter, with reference to the accompanying drawings an embodiment of the present invention will be described in detail.

In FIG. 2, the same components as the conventional components are denoted by the same reference numerals and the same names, and detailed description thereof will be omitted.

The magnetron drive circuit according to the present invention includes a transformer 10, a full-wave rectifier 20, a magnetron 30, and a current limiter 40, as shown in FIG.

The current limiting unit 40 is configured to limit the primary breaking current of the transformer 10, and includes a triac 45, a triac gate controller 46, and an impact preventing unit 49.

The triac 45 is short-circuited when a gate signal is applied from the triac gate controller 46 to the gate G of the triac 45 so that a commercial AC voltage input from the outside is supplied to the magnetron 30. On the other hand, if the gate signal from the triac gate control unit 46 is not applied to the gate (G) of the triac 45 is opened to block the commercial AC voltage input from the outside to supply to the magnetron 30 will be.

In addition, the triac gate controller 46 outputs and controls a gate signal to the gate of the triac 45 so that the triac 45 is shorted or opened, and is shorted or opened to control the triac 45. Charge / discharge time of the capacitor (C2) and the capacitor (C2) which short-circuit or open the capacitor, and the capacitor (C2) and the capacitor (C2) short-circuit or open by the commercial AC voltage input from the outside. It comprises a variable resistor 47, resistors (R1, R2, R3, R4) and diodes (D5, D6, D7, D8) to adjust the voltage.

In addition, the impact preventing unit 49 absorbs an abnormal voltage having high impact resistance, and a resistor R5 and a capacitor C1 are formed in series to be connected in parallel to both ends of an anode of the triac 45. have.

Hereinafter, the operation of the magnetron driving circuit configured as described above will be described.

First, when a commercial AC voltage is supplied to the input terminals A and B from the outside in the initial state in which the triac 45 is opened, the capacitor of the triac gate controller 46 is provided through the resistor R3 and the variable resistor 47. As the C2 is charged, the voltage Vc across the capacitor C2 increases, and when the Vc voltage increases to a predetermined voltage (for example, 35V), the diaak 43 is short-circuited and the triac gate control unit The gate signal is applied from 46 to the gate G of the triac 45.

Therefore, the triac 45 is short-circuited by the gate signal of the triac gate controller 46, and a commercial AC voltage is applied to the primary coil 13 of the transformer 10, and the low voltage stage coil 15 and The voltage is induced in the high voltage stage coil 17 to supply the voltage to the magnetron 30.

At this time, the Vc voltage of the capacitor C2 of the triac gate controller 46 begins to be discharged, and when the Vc voltage is completely discharged, the diac 43 is opened to release the triac 45 from the triac gate controller 46. Since the gate signal is not applied to the gate G of the gate, the triac 45 is opened.

Therefore, due to the opening of the triac 45, a commercial AC voltage is not applied to the primary coil 13 of the transformer 10, and no voltage is induced to the low voltage coil 15 and the high voltage coil 17. Therefore, no voltage is supplied to the magnetron 30.

On the other hand, if the Vc voltage of the capacitor C2 of the triac gate controller 46 continues to decrease and decreases below a certain voltage (-35V), the diaak 43 is short-circuited again, and the triac gate controller 46 A gate signal is applied to the gate G of the triac 45 to short-circuit the triac 45.

Therefore, the commercial AC voltage is applied to the primary coil 13 of the transformer 10 by the short circuit of the triac 45, and the voltage is induced to the low voltage coil 15 and the high voltage coil 17 to magnetron. The voltage is supplied to 30.

As such, the time when the commercial AC voltage input from the outside is supplied to the magnetron 30 is until the triac 45 is shorted and opened, and the adjustment of the time is adjusted according to the size of the variable resistor 47. Depending on the resistance value of the variable resistor 47, the charging / discharging time of the capacitor C2 varies (for example, if the resistance value is increased, the charging / discharging time is delayed and the duty is reduced. In general, the primary current of the transformer 10 is limited to suppress an increase in the anode current Ia flowing through the magnetron 30.

As described above, the magnetron driving circuit of the present invention restricts the primary current of the transformer to suppress the increase of the anode current flowing through the magnetron, thereby preventing the damage of the magnetron due to the overheat generated in the magnetron with the increase of the anode current. It has an effect.

Claims (1)

In a magnetron drive circuit having a transformer for converting a commercial AC voltage into a predetermined low voltage and a high voltage, and a magnetron for generating a high frequency in response to the voltage transformed by the transformer, the commercial AC voltage is applied to the primary side of the transformer. A triac which is shorted or opened to be supplied to or cut off from the magnetron, a diac which short-circuits or opens the triac by controlling the gate signal of the triac, a capacitor which is charged and discharged by a commercial AC voltage to short-circuit or open the diaac And a current limiting unit including a variable resistor for controlling charge and discharge times of the capacitors to suppress an increase in the anode current flowing through the magnetron.