KR870001391Y1 - Electric range - Google Patents

Abstract

No content.

Description

Drive control device of microwave oven

1 is a block diagram of a conventional control device.

2 is a block diagram of the present invention.

3 is a detailed circuit diagram of a relay and a triac controller in the present invention.

* Explanation of symbols for main parts of the drawings

1 control microprocessor 2 first switching circuit

3: second switching circuit 4: third switching circuit

5: relay and triac controller IC1: light receiving energy element

DRSW: Door Switch RYI-RY2: Relay

HVT: High Voltage Transformer L, Ll, L2: Dimming Lamp

TAI, TA2: Triac ACIN: Input Power

STSW: Aperture start switch FM: Fan motor

The present invention relates to a device for controlling the operation of a microwave oven, and more particularly to a drive control device that is capable of safely protecting the device from malfunction or inadvertent use of the control microprocessor.

A conventional apparatus for controlling a magnetron driving high voltage transformer or a dimming lamp and a fan motor of a microwave oven is shown in FIG. 1, where a triac (TA2) is connected in series to the high voltage transformer (HVT) and the gate (G1) is connected to the control microprocessor. In addition, a dimming lamp (Ll) for illuminating the inside of the cooking chamber when the front door is opened and a dimming lamp (L2) for illuminating the inside of the cooking chamber during the cooking operation is provided separately.

In this way, in the control apparatus, when the primary safety switch SW1 forms a contact point to the dimming lamp Ll, that is, when the front door is opened, the input power ACIN is applied to turn on the dimming lamp L1. At this time, the second safety switch SW2 is turned off and the high voltage transformer HVT is turned off.

On the other hand, when the user puts a cooking object into the cooking chamber, inputs a cooking program, and presses the start pad, the gate signal from the microprocessor is applied to the gate Gl of the triac TA2 so that the triac is applied. As TA2 is brought into a conductive state, power is applied to the high voltage transformer HVT, and the magnetron is driven accordingly to achieve a normal cooking function.

However, in the conventional apparatus as described above, since the triac TA2 is directly connected to the high voltage transformer HVT, since the input surge voltage is directly applied, the internal pressure is required to be large, and two dimming lamps Ll are required. (L2) is used to have a disadvantage in that the economic efficiency of the product is lowered in many ways.

In addition, even though the triac (TA2) is directly connected to the microprocessor, no other safety device is installed, so the risks caused by inadvertent use or malfunction of the device cannot be completely eliminated.

The present invention allows the high voltage transformer to be controlled by the power relay instead of the triac designed to complement the conventional control device as described above, so that stable operation is achieved even when the input surge voltage is changed, and when the door is opened or Reliability and stability of the equipment are provided by additionally installing a stabilizer that protects the device and human life from carelessness or malfunction by making the lighting in the cooking room necessary for cooking consist of one lamp. The purpose is to improve the situation.

Hereinafter, the configuration, operation, and effects of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is connected to a fan motor and a lamp control stage of a microprocessor (1) and includes a first switching circuit (2) having a switching transistor (TR5) and a receiving control element (I C1) and the microprocessor ( The second switching circuit 3 and one end of the second switching circuit 3 and the second switching circuit 3 which are connected to the door sense stage and the door switch DRSW of 1) and having the transistors TR3 and TR4. A third switching circuit 4 including an SCR (SCR1) connected to a power level control stage (PWOER LELEL CONTROL) and a star art stage (START) and a transistor (TR1) (TR2), etc. Each output terminal of relay and triac controller 5 To On the input power side, the gate G of the triac TA1 connected in parallel with the fan motor FM, the terminals T1, T2, the relay RY1 connected in parallel with the lamp L and a high voltage. The structure is connected to the power relay RY2 and the like connected in series with the transformer HVT.

Reference numeral STSW is a stop switch.

2 is a block diagram of the present invention having the above-described structure, and the lamp L is configured to illuminate the inside of the cooking chamber when the door is opened and while cooking, according to the operation of the relay RY1.

In addition, since the triac TA1 is connected in parallel with the input power source ACIN to control only the fan motor FM, it is possible to replace the triac TA1 with a small triac that does not require large internal pressure.

On the other hand, the control of the magnetron driving high voltage transformer (HVT) is performed by the power relay (RY2) connected to the microprocessor (1), so that the stable operation against the fluctuation of the input surge voltage.

The operation of the relay and triac control unit 5 in FIG. 3 controlling the relays RY1 and RY2 and the triac TA1 is as follows.

The relay and triac control unit 5 is composed of first, second and third switching circuits 2, 3 and 4 as described in the above structure description. First, the user inputs a cooking program and opens the door. If you press the start art pad (START PAD) in the closed state, the cooking start switch (STSW) turns on, and the cooking signal is resistance (Rl) according to the pre-stored cooking program from the star art stage (START) of the microprocessor (1). And a gate of the SCR SCR1 through the diode Dl to turn on the SCR SCR1. Accordingly, since the current is applied to the base of the transistor TR1 through the resistor Rl6, the SCR SCR1, the lower limit R9, and the resistor R8, the transistor TR1 becomes conductive.

Subsequently, the microprocessor 1 transmits a high level signal from the fan motor and the lamp control terminal. Since the signal is applied to the base of the transistor TR5 through the resistor R11, the transistor TR5 is turned off. On, current flows through the light receiving control element ICT. Therefore, the gate current signal is applied to the gate G of the triac TA1, and the triac TA1 is turned on. In FIG. 2, the input power ACIN passes through the triac TA1 to the fan motor. Is applied to the FM to operate the fan motor FM (the first and second switches SW1 and SW2 are turned on).

In addition, the signal output from the fan motor and the lamp control terminal of the microprocessor 1 is applied to the base side of the transistor TR4 through the diode D4 and the resistor R4, so that the transistor TR4 is turned on and the relay is turned on. RY1 is operated, and the lamp L is turned on to illuminate the inside of the cooking chamber (lighting operation during cooking).

Subsequently, an intermittent signal is output according to the power level selected by the user in the power level control terminal of the microprocessor 1 to focus on the oscillation operation of the magnetron. Therefore, when the output signal of the power level control terminal (POWER LEVEL CONTROL) of the microprocessor 1 is a high level, this signal is applied to the base terminal of the transistor TR2 through the resistor R6, so that the transistor TR2 is applied. The power relay RY2 is turned on (since transistor TR1 is already in the conduction state when the stop switch STSW is turned on), and accordingly. Therefore, the magnetron oscillates to achieve a normal cooking function.

On the contrary, when the output signal of the power level control terminal (POWEL LEVEL CONTROL) of the microprocessor 1 is at the low level, the transistor TR2 is turned off and the relay RY2 is in an inoperative state. When the oscillation output of the magnetron is stopped again, when the oscillation output level of the magnetron is low, the high level control signal is output to resume oscillation of the magnetron, thereby making the overall output level of the magnetron constant.

On the other hand, if the door is opened and the microprocessor 1 is in an abnormal state (ABNORMAL STATE), and the worst case in which even the first and second safety switches SW1 and SW2 are fused, the door is opened. The safety function by the switch (DRSW) is implemented.

The door switch DRSW of FIG. 3 is in series with the door of the microwave oven, and performs a mechanical function of being turned on when the door is opened and turned off when the door is closed. When the door switch DRSW is turned on (door is open), the voltage of Vcc is applied to the base of the transistor TR3 through the diode D2, the resistor R2, and the resistor R5, and is turned on. Since it is turned on, the anode of the SCR SCR1 is cut off and the SCR SCR1 is turned off.

Therefore, since the transistor TR1 is turned off and the power relay RY2 is turned off regardless of the control signal supplied from the power level control stage, the high voltage transformer HVT becomes inoperative. This causes the magnetron to stop oscillating. At this time, since the transistor TR4 is turned on, the relay RY1 operates to light the lamp L.

At this time, when the door is closed, the door switch DRSW is turned off and the Vcc power supply is stopped. Therefore, the relay RY1 is in an inoperative state, and the lamp L is turned off.

After pressing the star art pad, the above-described operation is repeated, and the relay RY1, the power relay RY2, and the triac TA1 are driven to light the lamp L, and the fan motor FM operates to operate the magnetron. This will rash.

As described above, in the basic circuit configuration of the primary side of the microwave oven, the present invention has a simple structure, and a small amount of triac is used only for driving the fan motor, thereby reducing the operation of the input surge voltage. In addition, the microprocessor functions can be precisely implemented by the control operation of the relay and the triac control unit, which has the advantage of protecting the device and the human life from the risk of malfunction.

Claims (1)

Electron consisting of microprocessor (1), relay (RY1) (RY2), triac (TA), fan motor (FM), sushi (SW1 to SW3), lamp (L) and high voltage transformer (HVT) In the drive control apparatus of the range, the first switching circuit (2) which is connected to the fan motor and lamp control stage of the microprocessor (1) and comprises a switching transistor (TR5) and a light receiving control element (I Cl); A second switching circuit 3 and a second switching circuit connected to the door sense stage, the door switch DRSW, and the first switching circuit 2 of the microprocessor 1 and having the transistors TR3 and TR4. Connected to one end of the switching circuit 3, the power level control stage and the star art stage of the microprocessor 1, and a third switching circuit 4 having an SCR (SCR1) and a transistor (TR1) (TR2). A relay and a triac controller 5 are configured to provide a connection between the microprocessor 1 and the respective driving units RY1, RY2, and TA1. Drive control device for a microwave oven, characterized in that installed.