KR100284547B1 - Resistance laying device of high voltage transformer for microwave oven - Google Patents

Abstract

In the resistance placing apparatus of the high voltage transformer for microwave oven according to the present invention, a commercial AC voltage from the outside is supplied to the first coil of the high voltage transformer through a relay unit, and a high voltage is induced in the second coil of the high voltage transformer. A microwave oven for heating and cooking food by microwaves generated by a high voltage capacitor and a high voltage diode rectified by a high voltage diode and supplied to a magnetron, wherein a plurality of microwaves connected in parallel to a start end of a secondary coil of the high voltage transformer are used. And a control unit for stopping the driving of the magnetron by operating the relay unit when it is determined that the cooking is completed by comparing the output voltage, which is lowered according to the cooking degree and variation of the food while passing through the resistance, and the preset voltage. A terminal terminal attached to one side of the resistor to be connected The present invention compares the output voltage sensed by the high voltage transformer with the reference voltage set according to the cooking degree and variation of the food to control the driving of the magnetron, thereby not only optimally cooking the food, but also the high voltage transformer and The structure of sensing the magnetron's voltage is simple to reduce manufacturing costs.

Description

Resistance laying device of high voltage transformer for microwave oven

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven, and in particular, by installing the magnetron according to a voltage sensed by a high voltage transformer according to a change of food, the resistance laying apparatus of a microwave high voltage transformer for optimally cooking food. It is about.

In general, as shown in FIG. 1, the microwave oven is hinged to a door 3 that opens and closes the cooking chamber 2 on one side of the main body 1 that forms an exterior, and the other side of the door 3. A key input unit 40 for setting and inputting a cooking course (for example, a cooking function, a cooking time and a cooking start / stop, etc.) and a display unit 4 for displaying the cooking course are provided.

Meanwhile, as shown in FIG. 2, the conventional microwave oven includes a relay unit 8, a high voltage transformer 10, a high voltage diode 20, a high voltage capacitor 25, a magnetron 30, and a key input unit 40. And a weight sensor 42, a gas sensor 44, and a control unit 50.

The relay unit 8 is turned on or off by the control signal of the controller 50 to supply or cut off the commercial AC voltage (for example, 220 to 240V) supplied through the input terminals A and B. And a relay, and the high voltage transformer 10 receives a commercial AC voltage and converts the voltage into a high voltage (detailed about 2,200 V) and a low voltage (detailed about 3.4 V) to supply a commercial AC voltage. The first primary coil 12, the second secondary coil 14 transformed to a high voltage, and the filament coil 16 transformed to a low voltage.

In addition, the high voltage diode 20 rectifies a high voltage, and the high voltage capacitor 25 is connected between the high voltage transformer 10 and the magnetron 30 by boosting the high voltage, and the magnetron 30 receives a low voltage. In addition to being heated, a high voltage DC voltage is supplied through the high voltage diode 20 and the high voltage capacitor 25 to generate microwaves.

In addition, when the user sets and inputs a cooking course (for example, a cooking function, a cooking time, and a cooking start / stop, etc.), the key input unit 40 outputs a corresponding key signal, and the weight sensor 42 cooks. It detects the weight of water and outputs the corresponding detection signal.

In addition, the gas sensor 44 detects an amount of gas generated when the food is heated and cooked, and outputs a detection signal corresponding thereto, and the controller 50 controls the magnetron 30 according to the key signal from the key input unit 40. The cooking time is counted and the cooking time is set and the cooking time is set according to the detection signals from the weight sensor 42 and the gas sensor 44. A control signal for stopping the driving of the magnetron 30 is output.

In the conventional microwave oven configured as described above, when a user puts food into the cooking chamber 2 and sets a cooking course through the key input unit 40, and inputs a cooking start, the corresponding key input unit 40 corresponds to the cooking start. The key signal is output to the controller 50, and the controller 50 outputs a control signal for driving the magnetron 30 according to the key signal to the relay unit 8 and counts the cooking time.

Accordingly, the relay unit 8 is turned on by the control signal so that a commercial AC voltage supplied through the input terminals A and B is supplied to the first coil 12 of the high voltage transformer 10. The low voltage is induced in the filament coil 16 of the high voltage transformer 10 and the high voltage is induced in the secondary coil 14.

The low voltage is supplied to the filament of the magnetron 30 to preheat the filament, while the high voltage is double-voltage rectified by the high voltage capacitor 25 and the high voltage diode 20 to be converted into a high voltage DC voltage. When a high voltage DC voltage is supplied to the anode of the magnetron 30 and the magnetron 30 generates microwaves, the food in the cooking chamber 2 is caused by microwaves radiated into the cooking chamber 2 through the waveguide (not shown). It is cooked by heating.

At this time, the weight sensor 42 detects the weight of the food and outputs a corresponding detection signal to the controller 50, and the gas sensor 44 detects the amount of gas generated when the food is heated and cooked accordingly. Outputting a detection signal to the controller 50, and the controller 50 receives the detection signals from the weight sensor 42 and the gas sensor 44, and compares the detected weight and gas amount with a preset weight and gas amount. Set the cooking time.

The controller 50 determines whether the counted cooking time is the set cooking time, and outputs a control signal to the relay unit 8 to stop driving of the magnetron 30 when the cooking time is set. The unit 8 is turned off by the control signal and the commercial AC voltage supplied to the high voltage transformer 10 through the input terminals A and B is cut off, so that the driving of the magnetron 30 is stopped and the whole of the microwave oven is stopped. The cooking operation ends.

On the other hand, if the power (power) of the magnetron 30 is called P _in , and the output for a specific position in the cooking chamber 2 is called P _out , P _out is obtained by the following equations (1) to (3). .

P _in = E _s ²

E _y = E _s sin (x)

P _out = (E _y ) ² = (E _s sin (x)) ² = E _s ² sin (x) ²

In Equation 1 to Equation 3, E _s is electric field energy formed by microwaves generated in the magnetron 30, that is, input electric field energy, and E _y is electric field energy at a specific position inside the cooking chamber 2 , Output field energy.

Therefore, the output of the magnetron 30 is obtained as a squared electric field strength E _s formed by the microwaves generated in the magnetron 30.

At this time, since the microwave generated in the magnetron 30 is a specific phase, that is, a sine wave, the electric field energy E _y at a specific position inside the cooking chamber 2 is equal to the sinus term sin (x) in the electric field energy E _s formed by the microwave. It is a multiplied form, and the value of the electric field energy E _y squared is the output P _out at a specific position inside the cooking chamber 2.

Therefore, the output P _out at a specific position inside the cooking chamber 2 is a form in which the sinusoidal sin (x) is multiplied by the output P _in of the magnetron 30, and the sinusoidal sin (x) is the cooking to be cooked. Since the value, that is, phase, changes depending on the variation (amount, type, state) of the water (load), the output P _out at a specific position inside the cooking chamber 2 also changes according to the variation of the food.

As described above, the impedance characteristic of the waveguide (not shown) according to the variation of the food is as shown in the polar chart shown in FIG. 4, when the load is 2000 cc of water in the state where the microwave frequency range is 2.44 to 2.47 GHz. Voltage standing wave ratio (VSWR), that is, the impedance of the waveguide 6 is reduced, so that the output of the magnetron 30 is large, whereas when the load is 100 cc of water, the standing wave ratio (VSWR), that is, the impedance of the waveguide Becomes large, and the output of the magnetron 30 becomes small.

However, the conventional microwave oven does not adequately respond to variations in the output of the magnetron according to the variation of the food, and simply drives the magnetron by determining the variation of the food through expensive sensors such as a weight sensor or a gas sensor. By controlling, not only the optimum cooking, but also the manufacturing cost increases due to expensive sensors.

Accordingly, the present invention has been made to solve the above problems, by detecting the voltage of the high voltage transformer and the magnetron according to the fluctuation of the food to determine the fluctuation of the food, thereby controlling the cooking of the magnetron, It is an object of the present invention to provide a resistance laying apparatus for microwave oven high voltage transformer which can not only cook water optimally but also detect the voltages of the high voltage transformer and the magnetron to reduce manufacturing costs.

In the resistance laying apparatus of the high voltage transformer for a microwave oven according to the present invention for achieving the above object, the commercial alternating voltage from the outside is supplied to the first coil of the high voltage transformer through a relay unit to the second coil of the high voltage transformer. In a microwave oven in which a high voltage is induced and the high voltage is rectified by a high voltage capacitor and a high voltage diode and supplied to a magnetron, the microwave is heated and cooked at a starting point of a secondary coil of the high voltage transformer. And comparing the plurality of resistors connected in parallel with the plurality of resistors and the output voltage of which the voltage is lowered according to the cooking degree and the predetermined voltage when the cooking is completed, operating the relay unit to stop driving of the magnetron. It includes a terminal terminal provided on one side of the resistor to be connected to the control unit And a gong.

1 is a schematic perspective view of a typical microwave oven,

2 is a circuit diagram of a conventional microwave oven,

3 is an external view of a circuit diagram of FIG. 2 showing a high voltage transformer for a conventional microwave oven;

4 is a circuit diagram of a microwave oven according to the present invention;

5 is a perspective view illustrating a ground structure in which a resistor is attached to a high voltage transformer for a microwave oven according to the present invention.

<Explanation of symbols for main parts of drawing>

8: relay unit 10: high voltage transformer

14: secondary coil 30: magnetron

60: key input unit 62: voltage detection unit

63: terminal terminal 70: control unit

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, about the same part as a conventional structure, the same name is attached | subjected and detailed description of the overlapping code is abbreviate | omitted.

4 and 5, in the microwave oven according to the present invention, a relay unit 8, a high voltage transformer 10, a high voltage diode 20, a high voltage capacitor 25, a magnetron 30, The key input section 60, the voltage sensing section 62, and the control section 70.

The voltage detecting unit 62 includes a plurality of resistors R connected in parallel to a start end of the secondary coil 14 of the high voltage transformer 10 and a voltage depending on the cooking degree while passing through the resistors R. FIG. When it is determined that cooking is completed by comparing the dropped output voltage with a preset voltage, the resistor R may be connected to a controller 70 for stopping the driving of the magnetron 30 by operating the relay unit 8. It includes a terminal terminal 63 attached to one side.

The terminal terminal 63 is connected between the start end of the secondary coil 14 of the high voltage transformer 10 and the resistor R, and the other end of the resistor R is connected to the high voltage transformer 10. Ground to bobbin.

That is, the controller 70 outputs a control signal for driving the magnetron 30 according to the key signal from the key input unit 60, while the high voltage transformer 10 sensed by the voltage sensing unit 62. It is determined whether the cooking is completed by comparing the voltage (in detail, the voltage detection unit output voltage with respect to the time according to the change of the food) and the preset voltage (in detail, the reference voltage set according to the cooking degree and variation of the food) When it is determined that the cooking is completed, a control signal for stopping driving of the magnetron 30 is output.

Next, the operation of the present invention configured as described above will be described.

First, when a user puts food into a cooking chamber, sets a cooking course through the key input unit 60, and then inputs a cooking start, a corresponding key signal is output from the key input unit 60 to the controller 70. If the control unit 70 receives the key signal to determine whether to start cooking and determines that the cooking is not started, the control unit 70 repeatedly determines whether the cooking is started, and when it is determined that the cooking is started, the magnetron 30 is determined. A control signal for driving is outputted to the relay unit 8.

Accordingly, the relay unit 8 is turned on by the control signal so that a commercial AC voltage supplied through the input terminals A and B is supplied to the first coil 12 of the high voltage transformer 10. The low voltage is induced in the filament coil 16 of the high voltage transformer 10 and the high voltage is induced in the secondary coil 14.

The low voltage is supplied to the filament of the magnetron 30 to preheat the filament, while the high voltage is double-voltage rectified by the high voltage capacitor 25 and the high voltage diode 20 to be converted into a high voltage DC voltage. A high voltage DC voltage is supplied to the anode of the magnetron 30 so that the magnetron 30 generates microwaves, whereby the food in the cooking chamber 2 is heated and cooked by the microwaves.

At this time, the voltage of the second coil 14 of the high voltage transformer 10 is detected through the voltage sensing unit 62 and output to the control unit 70, the control unit 70 is the voltage sensing unit 62 ) By comparing the detected voltage (in detail, the voltage detection unit output voltage with respect to the time according to the change of the food) and the preset voltage (in detail, the reference voltage set according to the change in cooking degree and change of the food) Determine if cooking is complete.

If it is determined that the cooking is not completed, the magnetron 30 is driven while sensing the voltages of the high voltage transformer 10 and the magnetron 30 to repeatedly determine whether the cooking is completed. A control signal for stopping the driving of the magnetron 30 is output to the relay unit 8.

Accordingly, the relay unit 8 is turned off by the control signal, so that the commercial AC voltage supplied through the input terminals A and B is interrupted, so that the driving of the magnetron 30 is stopped to cook the entire microwave. The operation ends.

Therefore, according to the resistance laying apparatus of the high voltage transformer for a microwave oven according to the present invention, by controlling the driving of the magnetron by comparing the output voltage detected by the high voltage transformer with the reference voltage set according to the cooking degree and variation of the food, In addition to being able to cook optimally, the structure for sensing the voltage of the high voltage transformer and the magnetron is simple to reduce the manufacturing cost.

Claims (2)

The commercial AC voltage from the outside is supplied to the primary coil of the high voltage transformer through the relay unit to induce high voltage in the secondary coil of the high voltage transformer, and the high voltage is rectified by the high voltage capacitor and the high voltage diode to the magnetron. In a microwave oven for cooking food by the microwave generated by the supply, Comparing the plurality of resistors connected in parallel to the start of the secondary coil of the high voltage transformer, and the output voltage is lowered in accordance with the degree of cooking and fluctuation of the food while passing through the resistor and the predetermined voltage is completed cooking And a terminal terminal disposed on one side of the resistor to be connected to a control unit for stopping the driving of the magnetron by determining that the relay unit is operated. The method of claim 1, And the terminal terminal is connected between the start end of the secondary coil of the high voltage transformer and the resistor.