KR900005049Y1 - Fan motor control circuit of convection range - Google Patents

Abstract

No content.

Description

Fan motor function selection circuit of convection microwave oven

1 is a block diagram according to the present invention.

2 is a detailed circuit diagram of an embodiment of FIG.

* Explanation of symbols for main parts of the drawings

10: door switching unit 20: voltage supply unit

30: signal input unit 40: microcomputer

50: fan function selection circuit 60: energy discharge unit

70: Function notation

The present invention relates to a convection microwave oven, and more particularly, to a circuit for selecting a function of a fan motor of a convection microwave oven according to a use state.

In general, a convection oven circulates heat energy generated from a heater to a convection fan to cook food using convection heat, and a microwave oven is a magnetron. Ultra-high frequency (approximately 2450MHz) generated by the Stirrer Fan (Stirrer Fan) to the food to cook food.

In the conventional convection range that meets these two functions, a heater and a convection fan are installed at the rear of the cooking chamber to circulate the heat energy generated by the heater to a convection fan (rotational speed of about 1700-2000 RPM) which is rotated at high speed and supplied into the cooking chamber. A hot air circulation system is used, and when it is used as a microwave oven, microwaves generated from the magnetic plate are supplied to the inside of the cooking chamber, and the turntable is rotated to rotate food or to rotate the fan at a low speed in the upper part of the cooking chamber. More than about 60 RPM) is used to disperse ultra-high frequency to cook food.

However, the convection microwave oven operated as described above has a problem in that the circuit is complicated by selecting and rotating the convection fan or the battery fan according to the function of the convection or microwave oven, but also causes the cost increase due to the increase in the number of man-hours.

Accordingly, an object of the present invention is to provide a fan motor function selection circuit that adjusts the rotational speed of the fan motor to perform two functions of the convection microwave oven as one fan motor.

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

1 is a block diagram according to the present invention is a door switching unit 10 for outputting a power voltage according to the open and closed state of the lazy door, and a DC voltage rectified power voltage input to the door switching unit 10 According to the output state of the voltage supply unit 20 for outputting to the operating power of each circuit to be input and operated, the signal input unit 30 for outputting a function selection signal for selecting a function of the microwave oven, and the signal input unit 30 The microcomputer 40 outputs a fan function selection signal and a range function selection signal by a built-in program, and outputs a power voltage output from the door switching unit 10 and simultaneously outputs a phase of the power voltage from the microcomputer 30. A fan selection circuit 50 for controlling the fan rotation speed by controlling the fan function selection signal and a range selection scene for outputting the power voltage output from the fan function selection circuit 50 from the microcomputer 40; According to the call is configured to drive a heater or magnetron to generate heat energy and ultra-high frequency energy emitting unit 60, and the function display unit 70 for displaying the current operating state by the output of the microcomputer 40.

Therefore, when the door of the current range is in the closed state, the door switching unit 10 outputs the power of the power voltage (AC110V) to the fan function selection circuit 50, and the voltage supply unit 20 rectifies the power supply voltage to the DC voltage Through the terminal 100 and outputs to each circuit requiring a DC power.

In this state, when the convection cooking selection signal is output from the signal input unit 30 to the microcomputer 40, the microcomputer 40 outputs a high speed rotation signal for rotating the fan motor at high speed to the fan function selection circuit 50. At the same time, the heater driving signal is output to the energy discharging unit 60 so as to perform the function of the convection range to the energy discharging unit 60, and the current execution state signal is output to the function display unit 70.

At this time, the fan function selection circuit 50 controls the phase of the power supply voltage output from the door switching unit 10 to rotate the rotational speed of the fan motor at high speed, and the energy discharging unit 60 drives the heater to generate thermal energy. Generate.

Therefore, the heat generated from the energy discharging unit 60 circulates the heat in the cooking chamber by the high speed rotation of the fan by the function selection of the fan function selection circuit 50.

Meanwhile, when the microwave function selection signal is output from the signal input unit 30 to the microcomputer 40 while the door switching unit 10 and the voltage supply unit 10 are operated as described above, the microcomputer 40 operates the fan motor. It outputs a low speed rotation signal to rotate at a low speed to the fan function selection circuit 50 and at the same time transmits the magnetron drive signal to the energy discharge unit 60 to perform the function of the microwave oven to the energy discharge unit 60. And outputs the current execution status signal to the function display unit 70.

At this time, the fan function selection circuit 50 controls the phase of the power supply voltage output from the door switching unit 10 to rotate the rotational speed of the fan motor at a low speed, and the energy discharging unit 60 drives the magnetron tube to generate ultra-high frequency. Generate.

Therefore, the ultra-high frequency generated by the energy discharge unit 60 is irradiated into the cooking chamber by the low speed rotation of the fan by the function selection of the fan function selection circuit 50.

Therefore, it can be seen that the fan speed is controlled by the fan function selection circuit according to the function selection signal of the signal input unit 30.

FIG. 2 is a detailed circuit diagram of one embodiment of the block diagram of FIG. 1, and includes a fuse FS, a thermal start switch TH S / W, and a primary switch PS _1. ), A door switch 10 consisting of a relay (RY ₁ ), a contact switch (S ₀ ), a second switch (SS ₂ ) and a monitor switch (MS ₃ ), and a power supply unit ( 20, the signal input unit 30, the microcomputer 40, the capacitors C ₁ -C ₂ , the resistors R ₁ -R ₆ , the trigger diodes TD ₁ -TD ₃ , and the triac T ₁ ), A fan motor function selection circuit 50 consisting of a relay (RY ₂ ), a transistor (Q ₁ ) and a fan motor (FM), a resistor (R ₇ -R ₈ ), a transistor (Q ₂ -Q ₃ ), and a relay (RY ₂ -RY ₃ ), a heater (HT), a high voltage transformer (HVT), a high voltage capacitor (HVE), a diode (HVD) and a magnet tube (MGT) consisting of an energy discharge unit 60 and a function display unit 70 do.

When the door of the range is closed now, the primary switch PS ₁ and the secondary switch SS ₂ are "on" and the monitor switch MS ₃ is turned off.

In the above state, when a predetermined current flows in the relay RY ₁ , the switch contact point S ₀ is “on” so that the power supply voltage flows in the line A and B, and the constant current is supplied by the power supply unit 20. It is rectified to voltage and input to each circuit part operating under DC voltage.

At this time, when the signal of the convection function is output from the signal input unit 30 to the microcomputer 40, the microcomputer 40 outputs a logic "low"-"high"-"low" signal to the output terminals OUT ₁ -OUT ₃ . At the same time, the convection function selection display data is output to the function selection display unit 70.

Therefore function selection display section 70 is to indicate that the current state is Con beksyeon function, due to a "turn-off" of the transistor (Q ₁₎ relay jeomjeop (RS) is becomes connected to a normal closed port (b), the transistor ( Q ₂ ) is “turned on” and heater HT starts to heat up.

Since the contact point RS of the relay RY ₂ is connected to the normal close terminal b, the voltage inputted to the line AB is the capacitor C ₂ through the resistor R ₂ and the fast selection resistor R ₄ . As the voltage starts to be charged at, the voltage at both ends of the capacitor C ₂ changes the phase difference between the voltages due to the time constants of the fast selection resistor R ₄ and the capacitor C ₂ .

Thus, when the voltage charged in the capacitor (C ₂₎ pre-going diode (TD ₃₎ of which leads to break-over voltage, the electric charge charged in the capacitor (C ₂₎ is discharged through the gate of the triac (T ₁₎ Triac (T ₁ ) is triggered.

Therefore, it can be seen that the triac T ₁ is "turned on", and the phase of the trigger signal of the triac T ₁ is the time constant of the resistor R ₂ , the select resistor R ₄ , and the capacitor C ₂ . By changing the value of, the triac T ₁ controls the phase of the power supply voltage at high speed.

(At this time, the relationship between the selection resistors R ₄ and R ₅ is R ₄ <R ₅ ) Therefore, the fan motor FM rotates at high speed to perform the convection function, thereby circulating the heat heated by the heater HT.

On the other hand, when the signal input unit 30 outputs the microwave function selection signal to the microcomputer 40, the microcomputer 40 outputs a logic "high"-"low"-"high" signal to the output terminals OUT _{1 to} OUT ₃ . At the same time, the microwave selection display data is output to the function selection display unit 70.

Therefore, the function selection display unit 70 indicates that the current state is a microwave function, and the relay contact RS is connected to the terminal C due to the "turn-on" of the transistor Q ₁ , and the transistor Q ₃ . Is " turned on " so that relay RY ₄ is driven so that contact S ₂ is " on &quot;.

Therefore, a power supply voltage flows through the high voltage transformer (HVT), and thus generates an ultra-high frequency in the magnet tube (MGT).

At this time, the contact RS of the relay RY ₂ is connected to the terminal C so that the voltage inputted to the line AB is applied to the capacitor C ₂ through the resistor R ₂ and the low speed selection resistor R ₅ . As the charge starts, the voltage at both ends of the capacitor C ₂ changes the phase difference with the power supply voltage at low speed due to the time constant of the low speed selection resistor R ₅ and the capacitor C ₂ .

Therefore, the time when the voltage charged in the capacitor C ₂ reaches the brake voltage of the trigger diode TD ₃ is delayed, so the triac T ₁ controls the power supply voltage at low speed to rotate the fan motor FM at low speed. As a result, the ultra-high frequency generated from the magnetron tube (MGT) is irradiated into the cooking chamber to cook food.

On the other hand, the capacitor C ₁ and the resistor R ₁ which are not described are elements for preventing the hysteresis caused by the trigger diode TD ₃ , and the trigger diodes TD ₂ -TD ₃ are line A ) Is a device to protect the circuit when the voltage input to (B) is overvoltage.

As described above, the present invention can be used as a fan motor of two functions, a convection and a microwave oven as a single fan motor, which can lead to a reduction in man-hours.

Claims (2)

As the operating power of each circuit operated by inputting a DC voltage by rectifying the power supply voltage input to the door switching unit 10 and the door switching unit 10 according to the open and closed state of the range door Convection comprising a power supply unit 20 for outputting, a signal input unit 30 for outputting a function selection signal for selecting a function of a range, and a function display unit 70 for inputting a predetermined state signal to display a current operation state In the fan motor function selection circuit of a microwave oven, a microcomputer 40 for outputting a fan function selection signal and a range function selection signal by a built-in program according to the output state of the signal input unit 30, and the door switching unit ( Fan function line for controlling fan rotation speed Energy discharge unit 60 for generating a thermal energy and ultra-high frequency by driving the heater or magnetron according to the circuit 50 and the range selection signal output from the microcomputer 40 to the power supply voltage output from the fan function selection circuit 50 Circuit characterized in that the configuration. 2. The fan function selection circuit 50 of claim 1, wherein the fan function selection circuit 50 connects the resistor R ₂ and the low and high speed selection resistors R ₄ -R _{5 in} parallel to each other in order to control the phase across the input line AB. And the fan function selection relay RY ₂ to a capacitor C ₂ for controlling the phase by the RC time constant, and the low and high speed selection resistors R ₄ -R ₅ by the driving state of the relay RY ₂ . ) To trigger the trigger diode (TD ₃ ) and control the rotation speed of the fan motor (FM) by controlling the triac (T ₁ ) connected in series with the fan motor (FM) according to the RC time constant value. The circuit characterized by the above-mentioned.