KR19990018721A - Magnetron driving circuit - Google Patents

Abstract

The present invention relates to a magnetron driving circuit for driving two magnetrons.

The configuration includes a microwave oven including two magnetrons and a transformer for supplying power to the magnetron, wherein the transformer includes a booster winding for outputting power boosted to the secondary side and two decompression windings for depressurizing to a predetermined size. One end of the booster winding is connected to the anode of the first magnetron through the high pressure diode, and the other end of the booster winding is connected to the anode of the second magnetron through the high voltage diode, and the decompression winding is of the first magnetron and the second magnetron, respectively. It is characterized in that connected to the negative electrode.

Description

Magnetron driving circuit

The present invention relates to a magnetron driving circuit, and more particularly, to a magnetron driving circuit for driving two magnetrons.

In general, a microwave oven is a cooking appliance equipped with a magnetron as a high frequency generator to irradiate food with high frequency generated from the magnetron to move the molecular arrangement of the food to cook food using heat generated at this time. Therefore, the cooking time of the food is closely related to the amount of high frequency generation in the magnetron.

1 is an electrical connection diagram of a microwave oven having two magnetrons to increase a conventional high frequency generation amount.

The configuration includes a noise filter unit 10 for largely removing noise components included in an input AC power supply, a low pressure unit 20 including all electrical components driven by the input AC power supply, and a high frequency electromagnetic wave generator. And a first magnetron 31 and a second magnetron 35, a high voltage unit 30 including components for driving the magnetrons, and a controller (not shown) for controlling the operation of each of the magnetrons.

Hereinafter, the cooking operation will be described.

When a cooking command is input from the consumer, all electric parts of the low pressure unit 20 are driven by the control of the controller, and the first magnetron 31 and the second magnetron 35 are driven according to the input power. do. That is, the first relay 34 and the second relay 38 are turned on to supply power to the first magnetron 31 and the second magnetron 35 so that the microwave oven performs a cooking operation. At this time, the power supplied to each magnetron (31, 35) is a high-voltage capacitor (31, 36) and a high-voltage diode (33, 37) for backing up and rectifying the secondary boost voltage of the transformer (HVT1) and transformer (HVT2) It is supplied through.

However, the conventional microwave oven has the following problems.

That is, the conventional magnetron driving circuit has two problems in driving two magnetrons, such as a component for driving each magnetron, that is, a high voltage capacitor, a high voltage diode, and a high voltage transformer.

In addition, the installation of parts in the limited space of the electrical equipment room has a lot of restrictions when designing products.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a magnetron driving circuit capable of operating two magnetrons well from one transformer.

Another object of the present invention is to provide a magnetron driving circuit that can operate two magnetrons well from one transformer, thereby overcoming the economical effect of reducing the number of parts and the limitation of design due to limited space in product design. It is to provide a driving circuit of a magnetron.

1 is an electric circuit diagram of a conventional microwave oven,

2 is an electric circuit diagram of a microwave oven according to the present invention;

Figure 3a, b is a circuit diagram showing the operation of the magnetron according to the present invention.

* Explanation of symbols for main parts of the drawings

40: noise filter unit 50: low pressure unit

52: first switch 53: monitor switch

54: main relay 55: output control relay

57: cooking chamber lamp 58: drive motor

59: fan motor 60: high voltage part

61, 65: magnetron 62, 66: high voltage diode

F1, F2: Pressure reducing winding N: Pressure rising winding

In order to achieve the above technical problem, a configuration of the present invention includes a transformer for supplying power to a first magnetron and a second magnetron, and the first magnetron and a second magnetron, wherein the transformer is provided on the secondary side. It has a boost winding for outputting the boosted power and two decompression winding for reducing the pressure to a predetermined size, one end of the boost winding is connected to the anode of the first magnetron through a high voltage diode, the other end of the boost winding It is connected to the anode of the second magnetron through a diode, the decompression winding is characterized in that connected to the cathode portion of the first magnetron and the second magnetron, respectively.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

2 is an electric circuit diagram of a microwave oven according to the present invention, Figures 3a, 3b is a circuit diagram for explaining the operation of the magnetron according to the present invention.

First, the electrical circuit diagram of the present invention with reference to FIG. 2 as follows.

The configuration includes a noise filter unit 40 for removing a noise component included in an input AC power applied from a power supply stage, a low voltage unit 50 including all electrical components driven by the input AC power, and a high frequency electromagnetic wave. It consists of two magnetrons (61) for generating a high voltage unit (60) including a component for driving the two magnetrons 61 and a control unit (not shown) for controlling the operation of the respective parts.

In the above-described components, the high voltage unit 60 includes two magnetrons 61 and 62 for oscillating ultra-high frequency, one transformer HVT for supplying power to each of the magnetrons 61 and 62, and a transformer HVT. It includes a high-voltage diode (62, 66) for rectifying the AC power boosted by) to supply power to the magnetron (61, 62).

That is, the secondary side of the transformer HVT consists of one boost winding N and two pressure reducing windings F1 and F2, so that the AC power boosted from the boost winding N is a high voltage diode 62 at every cycle change. (66) alternately supplies current to the magnetrons (61, 65). Each of the decompression windings F1 and F2 supplies power to the negative portion of the magnetron.

3 is a circuit diagram showing the operation of each of these magnetrons.

First, FIG. 3A illustrates the operation of the magnetron 61 when the power supply is a negative cycle. That is, when a negative cycle is supplied to the supply power, the flow of the magnetic field of the boost winding N is changed so that the direction of the current flows in the opposite direction to that of the positive cycle. Therefore, the current flows in the direction I1 of the illustrated current and is supplied to the magnetron 61 through the high voltage diode 62, thereby making it possible to oscillate the magnetron 61.

3B illustrates the operation of the magnetron 65 when the supply power source is a positive cycle. That is, when the positive cycle power is supplied to the supply power, the flow of the magnetic field of the boost winding N is changed so that the direction of the current flows in the opposite direction to the case of the negative cycle. Therefore, the high voltage flows in the direction I2 of the illustrated current and is supplied to the magnetron 65 through the high voltage diode 66, thereby making it possible to oscillate the magnetron 65.

Hereinafter, an operation of the microwave oven according to the present invention will be described with reference to the above-described components.

First, when the user puts food into the cooking chamber and closes the door of the microwave oven, the first switch 52 and the monitor switch 53 are closed in conjunction with this, and when a cooking command is input by the consumer, the controller (not shown) The relay 54 is turned on to enter the cooking operation preparation step. Thereafter, when the door is closed from the door detection switch (not shown), the controller performs the cooking operation by controlling the output control relay 55 on / off in accordance with the cooking order set by the consumer. That is, the lamp 57 is turned on to check the cooking state, the fan motor 59 is driven to cool the high-pressure unit 60 and to ventilate the smell in the cooking chamber, and the food is supplied so that the microwave can be irradiated evenly. The drive motor 58 to rotate is driven. The magnetrons 61 and 65 receive power for oscillation from the high voltage transformer HVT of the high voltage unit 60 and the magnetrons 61 through the pressure reducing coils F1 and F2 of the high voltage transformer HVT. Power is applied to the negative electrode of, 65 so that each of the magnetrons 61 and 65 oscillates an ultra high frequency of 2,450 MHz to perform a cooking operation.

Thereafter, when the cooking is finished, the output control relay 55 is turned off. When the door is opened, the first switch 52 is opened in association with the door, and the power of the microwave is completely cut off.

As described in detail above, according to the present invention, two magnetrons can be operated well from one transformer, so that the economic effect due to the reduction of the number of parts and the limitation of design due to limited space in product design can be overcome. Has the effect of.

Claims (1)

A microwave oven including a first magnetron and a second magnetron, and a transformer for supplying power to the first magnetron and the second magnetron, wherein the transformer has a boost winding for outputting power boosted to the secondary side and a predetermined size. It has two decompression windings for decompression, one end of the boosting winding is connected to the anode of the first magnetron through a high voltage diode, the other end of the boosting winding is connected to the anode of the second magnetron through a high voltage diode, The decompression winding is a magnetron drive circuit, characterized in that connected to the cathode portion of the first magnetron and the second magnetron, respectively.