KR20000013655A - Emergency breaker of inducted heating type cooker - Google Patents

Abstract

PURPOSE: An emergency breaker of inducted heating type cooker is provided to protect circuit elements from trouble by make error signal active when the first and second switching device are turned-off although emergency condition happened while the first and second switching device are turned-on. CONSTITUTION: The emergency breaker used for an inducted heating type cooker having PWM generator(210), gate pulse generator(220) and switching device comprises: a numbers of sensing means detecting an emergency such as input excessive current, excessive resonance current, overheat, input high voltage or input low voltage, and generating a sensing signal; an AND gate(231) generating an error sensing signal about the sensing signal of the sensing means when one or more emergency is/are generated; and a D-flip flop(D-ff)(232) receiving clock pulse synchronized with a PWM control signal of a PWM generator, receiving the error detecting signal of the AND gate(231), delaying the error detecting signal to edge of the clock pulse, generating the error detecting signal by the gate pulse generator(220), thereby shutting the switching device.

Description

Emergency Breaker of Induction Heating Cooker

The present invention relates to a kitchen cooking appliance, and more particularly, to an emergency breaker of an induction heating cooker for protecting the induction heating cooker from a sudden state.

Since the flameless cabinet-type range was developed for the comfort of the kitchen environment, induction heating cookers of high thermal power and high efficiency have been developed in recent years. Maximize the iron loss of the primary coil, the copper loss of the primary coil is minimized so that all energy is transferred to the iron core core to heat the food.

1 is a block diagram illustrating a general induction heating cooker, which includes a power supply unit 110, first and second switching elements Q1 and Q2, a gate pulse generator 120, and a PWM generator 130. , A microprocessor 140, a resonator 150, and a bowl presence detector 160.

The power supply unit 110 receives the commercial power of 110V, 220V, 60Hz, rectifies through the bridge diode (D1), smoothes through the smoothing capacitor (C3), and then supplies the pulse current to the first and second switching devices (Q1). , Q2). Meanwhile, the first and second switching elements Q1 and Q2 are switched by the gate driving voltage output from the gate pulse generator 120, and the gate pulse generator 120 is PWM (Pulse Width Modulation). The gate driving voltage is output according to the pulse width modulated PWM control signal output from the generator 130.

That is, the microprocessor 140 receives the bowl presence detection signal from the bowl presence detection unit 160 and the PWM generator 130 when the vessel 151 is seated on the second resonance coil L2 of the resonator 150. A synchronous signal is output, and the PWM generator 130 outputs a PWM control signal according to the synchronous signal. In this case, the PWM generator 130 outputs two PWM control signals to the gate pulse generator 120 in order to prevent the frequency of the PWM control signal from being excessively increased.

The gate pulse generator 120 outputs the gate pulses which operate in opposite directions to the first switching element Q1 and the second switching element Q2, respectively, so that the PWM control signal does not become a high level at the same time. The switching element Q1 and the second switching element Q2 may not be turned on at the same time. The resonator 150 includes first and second resonant coils L1 and L2 and first and second resonant capacitors C1 and C2. The first switching element Q1 and the second switching element In the section where Q2) is turned on, the input current is resonated and the resonance current ( i _CT2 ) Is flowed, and at this time, energy is generated through the second resonant coil L2, and the food placed on the bowl 151 is cooked.

On the other hand, the input current flowing to the power supply unit 110 ( i _CT1 ) Is induced to the secondary coil through the primary coil of the sense transformer (T1), so that the input voltage proportional to the input current is filtered through the AC filter 170 is applied to the bowl presence detection unit 160. . The bowl presence detection unit 160 compares the input voltage CT1 applied through the AC filter 170 with a reference voltage, and applies the bowl presence detection signal to the microprocessor 140.

That is, the input voltage CT1 output through the AC filter 170 is applied to the inverting input terminal of the comparator 161, and the reference voltage generated by dividing the driving voltage Vcc by the resistors R1 and R2. Is applied to the non-inverting input terminal of the comparator 161. The comparator 161 compares the input voltage CT1 with the reference voltage, and outputs a low level false detection signal when the input voltage CT1 is greater than the reference voltage, and when the input voltage CT1 is smaller than the reference voltage. Outputs high level bowl presence detection signal.

In general, when the bowl 151 is seated on the second resonant coil L2 of the resonator 150, the input pulse current is applied toward the resonator 150 so that power is continually consumed. Will flow). At this time, since the input voltage CT1 is higher than the reference voltage, the comparator 161 outputs a low level bowl presence detection signal, and the microprocessor 140 can recognize that the bowl is seated. When the bowl 151 is removed from the second resonance coil L2, since the power is not consumed in the second resonance coil L2, the input voltage CT1 becomes lower than the reference voltage and the bowl presence detection signal is low level to high level. The microprocessor 140 determines that there is no bowl 151 when a high level bowl presence detection signal is applied as described above.

On the other hand, if an unexpected condition occurs while using the induction heating cooker, an error signal (error) applied to the gate pulse generator 120 is activated, and the gate pulse generator 120 cuts the gate driving voltage so that the first pulse is generated. The second switching elements Q1 and Q2 are not driven.

However, if a sudden state occurs while the first and second switching elements Q1 and Q2 are turned on and the gate driving voltage is cut off, the first and second switching elements are shut down by force. There is a problem that a failure occurs in the elements constituting the induction heating cooker.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and even if a sudden state occurs while the first and second switching devices are turned on, the first and second switching devices are turned off. It is an object of the present invention to provide an emergency breaker of an induction heating cooker which protects the circuit elements of the cooker from failure by activating an error signal when it is activated.

1 is a block diagram showing an induction heating cooker according to the prior art,

2 is a circuit diagram illustrating an induction heating cooker having an emergency breaker according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

110: power supply 140: microprocessor

150: resonator 160: bowl presence detection unit

170: AC filter

210: pulse width modulation (PWM) generator

220: gate pulse generator 230: protection circuit

231: AND gate 232: delay flip flop

In order to achieve the above object, the present invention, the PWM generator for outputting a PWM control signal synchronized with the synchronization signal output from the microprocessor, and receives the PWM control signal output from the PWM generator to process the signal gate It is used in an induction heating cooker including a gate pulse generator for outputting a driving voltage and a switching device for switching the input power to the resonator by switching by the gate driving voltage output from the gate pulse generator, the circuit element of the cooker In the emergency circuit breaker

A plurality of sensing means for detecting an abrupt state such as input overcurrent, resonant overcurrent, overheating, input high voltage or input low voltage, and outputting a sensing signal according thereto;

A logical multiplication gate that receives a sensing signal from the plurality of sensing means and outputs an error detection signal when at least one occurrence of a sudden state occurs; And

A clock pulse synchronized with the PWM control signal is input from the PWM generator and an error detection signal output from the logical multiply gate is received. The error detection signal is delayed to the edge of the clock pulse and then output to the gate pulse generator. And a delay flip-flop (D-ff) for shutting down the switching device.

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

2 is a circuit diagram illustrating an induction heating cooker having an emergency breaker according to an embodiment of the present invention.

Referring to FIG. 2, the induction heating cooker according to the present invention includes a power supply unit 110, first and second switching elements Q1 and Q2, a microprocessor 140, a resonator 150, and a PWM generator 210. ), A gate pulse generator 220, a bowl presence detector 160, an AC filter 170, and a protection circuit 230.

The power supply unit 110 is composed of a bridge diode (D1) for receiving the rectified commercial power (AC) and a smoothing capacitor (C3) for outputting the pulsed power by smoothing the rectified input power, resonator 150 Is composed of first and second resonant coils L1 and L2 and first and second resonant capacitors C1 and C2.

The protection circuit 230 detects an abrupt state such as an input overcurrent, resonant overcurrent, overheating, input high voltage and input low voltage, and outputs a sensing signal according to the detection state, and the plurality of sensing means. Receives a sensing signal from the logic signal gate 231 for outputting an error detection signal when at least one or more abrupt state occurs, and receives the clock pulse (CLK) in synchronization with the PWM control signal from the PWM generator 210 The error detection signal output from the logical product gate 231 is input to a data terminal (data), and the error detection signal is delayed to an edge of a clock pulse and then output to the gate pulse generator 220 to output the first, The second switching elements Q1 and Q2 are configured to be delayed flip-flops D-ff: 232 to shut down.

The operation and effects of the present invention configured as described above are as follows.

The power supply unit 110 receives the commercial power (AC) of 110V to 220V, 60Hz, rectifies through the bridge diode (D1), smoothes the smoothing capacitor (C3), and then supplies the pulse current to the first and second switching devices ( Supply to Q1, Q2). The microprocessor 140 detects whether the vessel is seated according to the vessel presence detection signal output from the vessel presence detection unit 160, and outputs a synchronization signal to the PWM generator 210 when the vessel 151 is seated. do. The PWM generator 210 outputs two PWM control signals, and the gate pulse generator 220 processes the PWM control signals to signal first and second switching devices Q1 and Q2. Is applied.

Generally, when the bowl 151 is seated on the second resonance coil L2, the input current ( i _CT1 ) Is continuously supplied to maintain a normal state, but when the vessel 151 is removed from the second resonance coil L2, the input current ( i _CT1 ) Gradually decreases. Therefore, the comparator 161 of the bowl presence detection unit 160 has an input current ( i _CT1 By comparing the input voltage and the reference voltage according to), it is recognized that the bowl 151 is seated if the input voltage is greater than the reference voltage, and that the bowl 151 is removed if the input voltage is smaller than the reference voltage.

When the bowl 151 is seated on the second resonance coil L2, a low level bowl presence detection signal is applied to the microprocessor 140, and the microprocessor 140 outputs a synchronization signal to the PWM generator 210. The PWM generator 210 outputs a PWM control signal to the gate pulse generator 220 and a clock pulse (Synchronized with the PWM control signal) to the delay flip flop 232 of the protection circuit 230. CLK).

As described above, while the clock pulse CLK is applied to the delay flip flop 232, the first switching element Q1 and the second switching element Q2 repeat the switching operation to transmit the resonance current to the resonator 150. i _CT2 Bar to flow, thereby cooking the food while the bowl 151 is heated.

At this time, when a sudden state is detected from the sensing means when the first switching element Q1 or the second switching element Q2 is turned on, the logical multiplication gate 231 outputs an error detection signal of an active low level. At this time, the delay flip-flop 232 receiving the error detection signal is delayed within the clock period of the clock pulse CLK and is activated at the rising edge or the falling edge. In other words, the error detection signal is the gate pulse generator (at the edge of the clock pulse CLK) at the moment when one of the first switching element Q1 or the second switching element Q2 is turned on and turned off. 220).

Therefore, even if a sudden state occurs while the first and second switching elements Q1 and Q2 are turned on and the error detection signal is activated, the error detection signal is the edge portion of the clock pulse CLK, that is, the first and second switching elements. When the two switching elements Q1 and Q2 are turned off, the gate pulse generator 220 is applied to the gate pulse generator 220 to enable zero current switching (ZCS) or zero voltage switching (ZVS), and the switching elements Q1 and Q2. The circuits are protected because they are shut down with all of them turned off.

As described above, in the present invention, when an unexpected condition occurs while the first and second switching devices are turned on and a voltage is applied to the circuit device, the error detection signal is delayed so that the first and second switching devices are turned on. By shutting down in the off state, there is an effect of protecting circuit elements from failure.

Claims (1)

A PWM generator for outputting a PWM control signal synchronized with a synchronization signal output from a microprocessor, a gate pulse generator for receiving a PWM control signal output from the PWM generator and processing the signal to output a gate driving voltage; In an induction heating cooker including a switching element that is switched by a gate driving voltage output from the gate pulse generator to apply an input power to the resonator, the emergency breaker for protecting the circuit elements of the cooker, A plurality of sensing means for detecting an abrupt state such as input overcurrent, resonant overcurrent, overheating, input high voltage or input low voltage, and outputting a sensing signal according thereto; A logical multiplication gate that receives a sensing signal from the plurality of sensing means and outputs an error detection signal when at least one occurrence of a sudden state occurs; And A clock pulse synchronized with the PWM control signal is input from the PWM generator and an error detection signal output from the logical multiply gate is received. The error detection signal is delayed to the edge of the clock pulse and then output to the gate pulse generator. And a delayed flip-flop (D-ff) for shutting down the switching device.