KR200253619Y1 - Oscillation Frequency Control Circuit - Google Patents

Abstract

The present invention relates to an oscillation frequency control circuit, and more particularly, to an oscillation frequency control circuit that can suppress an instantaneous high output that may cause damage to an inverter switching element.

The oscillation frequency control circuit of the present invention is an induction heating cooker including an inverter circuit that is turned on / off by a switching voltage to generate a high frequency voltage, and determines an output level for on-time of the inverter switching element in the inverter circuit. Level determination means for performing; Compensating means for compensating the output of said level determining means; A first muting means for dropping the output potential of the compensation means to a low potential when the product is to be stopped; And second muting means for lowering the output potential of the level determining means to a low potential upon restarting the product.

Description

Oscillation Frequency Control Circuit

The present invention relates to an oscillation frequency control circuit, and more particularly, to an oscillation frequency control circuit that can suppress an instantaneous high output that may cause damage to an inverter switching element.

Electromagnetic induction heating cooker performs the cooking function by the way that the eddy current flows when the magnetic wire generated from the working coil passes through the pot. Looking at the basic heating principle of the electromagnetic induction cooker, when a current is applied to the working coil, the oven is a magnetic material is heated by induction (heating), cooking is done inside the oven.

Therefore, in the case of the electromagnetic induction cooker, a high frequency voltage of a certain magnitude must be applied to the working coil in order to generate magnetic lines. At this time, the working coil has a strong thermal power of about 1300W by the high frequency voltage applied. A circuit for applying a high frequency voltage to the working coil is an inverter circuit.

Therefore, the oscillation frequency control circuit to be described in the present invention is used as the oscillation frequency control circuit for determining the on-time of the switching element in the inverter circuit of the electromagnetic induction heating cooker.

1 is a configuration diagram of an oscillation frequency control circuit according to the prior art.

In the conventional oscillation frequency control circuit, after the initial starting operation of the product is performed, induction heating is performed, the current sensing circuit (not shown) senses the amount of current flowing through the product. The first comparator 10 inputs the voltage signal according to the sensed current to the inverting terminal (-) and inputs the control output of the microcomputer for normal driving of the product to the non-inverting terminal (+).

An integrator consisting of resistors R1 and R2 and a capacitor C1 is connected to an output terminal of the first comparator 10. As a result, the potential determined by the resistors R1 and R2 and the large capacitor C1 becomes an output level that determines the on-time of the switching element in the inverter circuit.

The signal passing through the integrator is input to the OP amplifier 15 for signal compensation through the diode D1. The signal compensated by the OP amplifier 15 is output to the output terminal C through the resistor R3.

The collector terminal of the transistor Q1 is connected to the output terminal C of the oscillation frequency control circuit through the resistor R4, the emitter terminal of the transistor Q1 is connected to the ground potential, and the transistor Q1 The base and emitter terminals are connected via resistors R5 and R13.

The protection circuit 20 is configured to block the output of the oscillation frequency control circuit when an abnormal power supply or a surge voltage is input into the product.

The output C of the oscillation frequency control circuit is applied to an input of an oscillation circuit (not shown) for generating the on-time signal of the switching element in the inverter circuit.

Next, an operation of the oscillation frequency control circuit according to the prior art having the above configuration will be described.

When an initial starting operation of the inverter circuit is performed under the control of a microcomputer (not shown), an oven (not shown), which is a magnetic material, is heated with induction while a current is applied to the working coil (not shown). When induction heating is normally performed between the oven and the working coil, the value of the current supplied to the oven should be higher than a predetermined value. At this time, the detected current value is a feedback signal and is converted into a voltage and input to the inverting terminal of the first comparator 10.

On the other hand, the microcomputer (not shown) outputs an on-time control signal according to the output level that should be generated in the working coil for normal driving of the product, and the first comparator 10 converts the signal into a non-inverting terminal. Enter it.

The first comparator 10 compares the two input signals and compensates the output such that the difference between the two signals becomes zero " 0 ", and the integrators R1, R2, and C1 input the output of the first comparator 10. The potential of the output terminal A of the end) becomes the output level for determining the on-time, that is, the output of the switching element in the inverter circuit.

The on-time control signal of the inverter circuit passing through the integrator passes through the diode D1 and is input to the OP amplifier 15 for signal compensation. After the predetermined amount of signal compensation is performed in the OP amplifier 15, the on-time control signal is output to the output terminal C.

The signal output to the output terminal C is applied as a switching time control signal of a switching element in an inverter circuit (not shown) via an oscillation circuit (not shown), and the loop by the operation is repeated to continue the working coil. Induction heating proceeds.

On the other hand, the protection circuit 20 monitors whether an abnormal power supply or surge voltage is input into the product, and if an abnormal power supply within the product is input, the inverter circuit (not shown) is switched to the low state to the potential of the output terminal C. Do not operate).

At this time, the operation is performed as follows.

First, when the protection circuit 20 is in operation, a high signal is applied to the base terminal of the transistor Q1 in the protection circuit 20. Since the transistor Q1 is an NPN type transistor, the transistor Q1 is turned on when a high signal is applied to the base terminal. In this way, when the protection circuit 20 is operated, the transistor Q1 is turned on.

However, since the transistor Q1 connects the collector terminal to the output terminal C and the emitter terminal to the ground potential, the collector terminal of the transistor Q1 is turned on when the transistor Q1 is turned on. The potential of the output terminal C, which is connected to, is at ground potential. Therefore, the output of the oscillation frequency control circuit is cut off.

On the other hand, when the output of the oscillation frequency control circuit is cut off and the operation of the protection furnace 20 is turned off as the normal power is supplied to the product again, the oscillation frequency control circuit generates instantaneous high output. This occurs when the potential of the output terminal C of the oscillation frequency control circuit is suddenly charged from the low state to the high state.

Looking at this operation, when the oscillation frequency control circuit is turned off under the control of the protection circuit 70, the potential of the output terminal C becomes low. In this way, when the drive of the oscillation frequency control circuit is turned off, the inverter circuit is stopped at the same time, and thus the induction heating operation between the working coil and the oven is also stopped. Therefore, the potential of the inverting terminal of the first comparator 10 which detects and inputs a current value generated during the induction heating becomes also low.

Meanwhile, as the potential of the inverting terminal of the first comparator 10 is lowered, the potential of the integrator output terminal A is relatively higher. Therefore, the potential between the output terminal 4 of the integrator and the output terminal C of the oscillation frequency control circuit is maintained at a very high state when the oscillation frequency control circuit is turned off.

In this state, when the operation of the protection circuit 20 is stopped, the transistor Q1 is turned off, and the potential of the output terminal C of the oscillation frequency control circuit is determined as the potential of the output terminal A of the integrator. Therefore, the oscillation frequency control circuit is to generate a signal according to a high output instantaneously.

The high power generated in this way is applied to the inverter driving circuit through an oscillation circuit (not shown), which eventually causes breakage of the inverter switching element.

Accordingly, an object of the present invention is to provide a circuit capable of suppressing the instantaneous high output of the oscillation frequency control circuit that may be generated when the product is restarted.

1 is a block diagram of an oscillation frequency control circuit according to the prior art.

2 is a block diagram of an oscillation frequency control circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10,30: comparator 15,35: op amp

20, 40: protection circuit 01-03: transistor

Cl, C2: capacitor R1-R13: resistance

Dl, D2: Diode

The oscillation frequency control circuit according to the present invention for achieving the above object, in the induction heating cooker including an inverter circuit that is turned on / off by a switching voltage to generate a high frequency voltage, the on-off of the inverter switching element in the inverter circuit Level determining means for determining an output level for time; Compensating means for compensating the output of said level determining means; A first mute means connected to the output end of the compensation means and dropping the output potential of the compensation means to the ground potential when stopping the operation of the product; And a second mute means connected between the level determining means and the compensation means and dropping the output potential of the level determining means to the ground potential when restarting the product.

The oscillation frequency control circuit of the present invention is characterized by suppressing the high output that can be applied to the switching element in the inverter circuit at the moment when the driving of the product is stopped and restarted due to a power failure or an abnormal power supply.

Therefore, the present invention is characterized in that when the product is stopped, the high potential state existing in the oscillation frequency control circuit is dropped to the low potential state.

The state transition in the oscillation frequency control circuit of the present invention is characterized by the control of a protection circuit operated when an abnormal power supply or surge voltage of a product is input.

Hereinafter, an oscillation frequency control circuit according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram of an oscillation frequency control circuit according to the present invention.

In the oscillation frequency control circuit according to the present invention, the initial starting operation of the product is made, and after induction heating is performed, the amount of current flowing in the product is sensed by a current sensing circuit (not shown). The first comparator 30 inputs the voltage signal according to the sensed current to the inverting terminal (-) and inputs the control output of the microcomputer for normal driving of the product to the non-inverting terminal (+).

An output terminal of the first comparator 30 is connected to one side of the resistor R6, and the other side of the resistor R6 is connected to the anode terminal of the diode D2 through a connection point A 'and simultaneously connected in parallel. It is connected to one side of the R7 and the capacitor C2. The other side of the resistor R7 and the capacitor C2 is connected to the ground potential, that is, the resistor and the capacitor constitute an integrator. Thus, the potential determined by the resistor and the capacitor becomes an output level that determines the on-time of the switching element in the inverter circuit.

The collector terminal of the transistor Q2 is connected to the connection point A 'through the resistor R12, the emitter terminal of the transistor Q2 is connected to the ground potential, and the base terminal of the transistor Q2 is connected to the connection point A'. It is connected to the output terminal of the protection circuit (40). The base terminal and the emitter terminal of the transistor Q2 are connected through the resistor R10.

The transistor Q2 is under the control of the protection circuit 40 and operates in conjunction with the operation of the protection circuit 40 to lower the potential of the connection point A '.

In addition, the cathode terminal of the diode D2 is connected to the input terminal of the OP amplifier 35 for signal compensation, and the output terminal of the OP amplifier 35 is connected to one side of the resistor R8 while being fed back to the OP amplifier. do. The other side of the resistor R8 is connected to the output terminal C 'of the oscillation frequency control circuit, and is connected to the collector terminal of the transistor Q3 through the resistor R9, and the emitter terminal of the transistor Q3. It is connected to the ground potential, and the base terminal of the transistor Q3 is connected to the third output terminal of the protection circuit 40. The base terminal and the emitter terminal of the transistor Q3 are connected through a resistor R11.

The transistor Q3 is controlled by the second output of the protection circuit 40, and is operated in conjunction with the operation of the protection circuit 40 to lower the potential of the connection point C ′.

The protection circuit 40 is configured to block the output of the oscillation frequency control circuit when an abnormal power source or a surge voltage is input into the product.

The output C 'of the oscillation frequency control circuit is applied to an input of an oscillation circuit (not shown) for generating an on-time signal of the switching element in the inverter circuit.

The following describes the operation of the oscillation frequency control circuit according to the present invention made of the above configuration.

When an initial starting operation of the inverter circuit is performed under the control of a microcomputer (not shown), an oven (not shown), which is a magnetic material, is heated with induction while a current is applied to the working coil (not shown). When induction heating is normally performed between the oven and the working coil, the value of the current supplied to the oven should be higher than a predetermined value. At this time, the detected current value is a feedback signal and is converted into a voltage and input to the inverting terminal of the first comparator 30.

On the other hand, the microcomputer (not shown) outputs an on-time control signal according to the output level that should be generated in the working coil for normal driving of the product, and the first comparator 30 converts the signal into a non-inverting terminal. Reform.

The first comparator 30 compares the two input signals and compensates the output so that the difference between the two signals becomes zero " 0 ". The first comparator 30 includes an integrator composed of a resistor and a capacitor input to the output of the first comparator 30. The potential of the output stage .1 'eventually becomes the output level for determining the on-time, that is, the output, of the switching element in the inverter circuit.

The on-time control signal of the inverter circuit passing through the integrator passes through the diode D2 and is input to the OP amplifier 35 for signal compensation. After the predetermined amount of signal compensation is performed in the OP amplifier 35, the on-time control signal is output to the output terminal C '.

The signal output to the output terminal C 'is applied as a switching time control signal of a switching element in an inverter circuit (not shown) via an oscillation circuit (not shown), and the loop by the operation is repeated to continue walking. Induction heating of the coil proceeds.

On the other hand, the protection circuit 40 monitors whether an abnormal power supply or surge voltage is input into the product, and when the abnormal power supply is input into the product, the inverter circuit (S) is switched to the low state to the potential of the output terminal C '. Stop driving).

At this time, the operation is performed as follows.

First, when the protection circuit 40 is operated, a high signal is applied to the base terminal of the transistor Q3 at the second output terminal of the protection circuit 40. Since the transistor Q3 is an NPN type transistor, a high signal is applied to the base terminal, and thus becomes a turn-on phase. In this way, when the protection circuit 40 is operated, the transistor Q3 is turned on.

However, since the transistor Q3 connects the collector terminal to the output terminal C 'and the emitter terminal to the ground potential, the collector of the transistor Q3 is turned on when the transistor Q3 is turned on. The potential of the output terminal C 'connected to the terminal becomes equal to the ground potential state. Therefore, the output of the oscillation frequency control circuit is cut off.

In this way, the drive of the oscillation frequency control circuit is turned off and the inverter circuit is stopped. Accordingly, the induction heating operation between the working coil and the oven is also stopped.

In addition, the protection circuit 40 also outputs a high signal to the first output terminal when performing the control for stopping the inverter circuit. At this time, the output high signal is applied to the base terminal of the transistor Q2 located between the output terminal A 'of the integrator and the OP amplifier 35, thereby turning on the transistor Q2.

Since the transistor 72 connects the collector terminal to the output terminal A 'of the integrator and the emitter terminal to the ground potential, when the transistor Q2 is turned on, The potential of the output terminal A 'becomes equal to the ground potential.

That is, when the protection circuit 40 is operated, the transistor Q3 is turned on to turn off the output of the oscillation frequency control circuit, and the transistor Q2 is used to lower the potential of the integrator in the oscillation frequency control circuit. ) Is turned on. In this manner, when the protection circuit 40 is operated, the potential of the connection point A1 in the oscillation frequency control circuit and the potential of the output terminal C 'of the oscillation frequency control circuit can be controlled to be lowered.

Therefore, when the normal power is input back to the product and the operation of the product is restarted, the potential of the connection point A 'in the oscillation frequency control circuit has a low potential state, thereby preventing an instantaneous high output to the inverter circuit. You can do it.

As described above, the oscillation frequency control circuit according to the present invention suppresses the high output that can be applied to the inverter switching element at the moment when the driving of the product is temporarily stopped and restarted, such as during abnormal power supply or power failure. Damage to the device can be prevented, and the reliability of the product can be increased.

Claims (3)

An induction heating cooker comprising an inverter circuit which is controlled on / off by a switching voltage to generate a high frequency voltage, comprising: level determining means for determining an output level for on-time of an inverter switching element in the inverter circuit; Compensation means for compensating the output of said level determining means, said first muting means being connected to an output end of said compensation means and dropping the output potential of said compensation means to ground potential when stopping the operation of a product; And a second muting means connected between the level determining means and the compensation means and dropping the output potential of the level determining means to the ground potential upon restarting the product. The oscillation frequency control circuit according to claim 1, further comprising a protection circuit for sensing an input of an abnormal power supply or a surge power supply and controlling the operation of the first and second mute means. The oscillation frequency control circuit according to claim 2, wherein the first and second mute means use a switching element operated under the control of the protection circuit.