KR0138635B1 - Detection device of microwave oven - Google Patents

Abstract

The present invention relates to a composite cooker having a combined function of a microwave oven and an induction heating cooker, and more particularly, to a container detecting apparatus for a composite cooker for automatically switching a heating source by sensing a container placed in the composite cooker. In the composite cooker, a control means, a current sensing means for receiving a commercial AC power from the AC power input stage to sense the variation of the current input to the load and outputs the control means, and receives a control signal from the control means A cooking means for performing a cooking operation according to the current sensing signal sensed by the current sensing means, and a voltage sensing means for sensing a driving voltage of the cooking means driven by the control of the control means and outputting the driving voltage to the control means. It features.

Description

Container detection device of compound cooker

1 is a control block diagram of a container detecting device of a composite cooker according to an embodiment of the present invention.

2 is a detailed circuit diagram of a container detecting device of a composite cooker according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: AC power input terminal 10: DC power means

20: current sensing means 21: current transformer

30: control means 40: cooking means

41: induction heating means 42: dielectric heating means

50: voltage detection means 51: driving voltage detection unit

52: reference voltage generator 53: first comparison unit

54: motivation 55: second comparison

The present invention relates to a composite cooker having a combined function of a microwave oven and an induction heating cooker, and more particularly, to a container detecting apparatus for a composite cooker for automatically switching a heating source by sensing a container placed in the composite cooker.

In general, the container detecting device of the conventional cooker detects the amount of change of the current input to the load by the current transformer, and switches the relay to the dielectric heating mode or the induction heating mode by the control means in accordance with the detected current change amount to be heated. Selected by means.

That is, when the cooking vessel mounted on the composite cooker is a magnetic material (ferrous metal), since the amount of change in the current input to the load is large, the current is detected by the current transformer and output to the control means. Induction heating of food by switching.

On the other hand, when the cooking vessel placed in the composite cooker is a non-ferrous metal such as ceramic or glass that can be heated in the dielectric heating mode, there is no variation in the current input to the load, so if the current is detected by the current transformer and output to the control means, the control means In the dielectric heating mode, the relay is switched to dielectric heating food.

By using the current transformer in this manner, the heating source of the composite cooker was switched to the induction heating mode or the dielectric heating mode by sensing the amount of change in the current input to the load, but the non-magnetic / nonferrous metal container (aluminum or copper, etc.) As for the non-conforming material of the complex cooker such as), the automatic switching device is not provided, so the complete container sensing function cannot be realized, and because the overcurrent caused by the use of the non-conforming container flows to the switching element, the switching element is destroyed. There was a problem that it is difficult to ensure the performance and safety of the.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to select the cooking heating mode by sensing the amount of change of the current input to the load by the current sensing means, it is detected by the voltage sensing means According to the driving voltage of the loaded load, it is possible to ensure the performance and safety of the device because the container mounted on the multi-cooker can be discriminated and the cooking operation can be automatically stopped in the case of nonconforming non-ferrous metals. In addition, the present invention provides a container detecting device for a complex cooker having a simple configuration and low manufacturing cost.

In order to achieve the above object, the container detecting apparatus of the complex cooker according to the present invention, in the complex cooker, receives the control means and the commercial AC power from the AC power input terminal and senses the amount of change of the current input to the load to the control means. A current sensing means for outputting, a cooking means receiving a control signal from the control means and performing a cooking operation according to the current sensing signal sensed by the current sensing means, and a cooking means driven by the control of the control means. Characterized in that the voltage sensing means for detecting the driving voltage and output to the control means.

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

1 to 2, the DC power supply unit 10 receives a commercial AC input voltage from the AC power input terminal 1 and converts it into a predetermined constant voltage Vcc necessary for the operation of the control means described later.

The current sensing means 20 receives the commercial AC voltage from the AC power input terminal 1 and receives the constant voltage signal Vcc from the DC power supply 10 to change the amount of change of the current input to the load. By sensing, the current sensing means 20 receives a commercial AC voltage from the AC power input means 1 and provides a current transformer 21 for sensing the variation of the current input to the load, and the current transformer 21. A capacitor C1 for filtering the noise component included in the current sensed signal detected by the capacitor, and a resistor R1 connected in parallel to the capacitor C1 to convert the current sensed signal filtered by the capacitor C1 into a voltage signal. ), A diode D1 for half-wave rectifying the voltage signal converted by the resistor R1, and a diode D2 for receiving a constant voltage signal from the DC power supply unit 10 through the resistor R2. Wow Resistor R3 and capacitor C2 filtering the pulsation component included in the voltage signal half-wave rectified by the diodes D1 and D2, and the voltage filtered by the resistor R3 and the cache capacitor C2. The divided resistors R4 and R5 received and divided by the signal, the variable resistor VR connected to the divided resistors R4 and R5 so as to vary the threshold value of the current sensing signal sensed by the current transformer 21; A zener diode ZD connected in parallel to the voltage divider resistors R4 and R5 so as to receive a signal divided by the voltage divider resistors R4 and R5 and bypass only a breakdown voltage of a predetermined level, and from the zener diode ZD. And a capacitor C3 for filtering out noise components contained in the voltage signal.

The control means 30 receives a current sensing signal from the current sensing means 20 and at the same time receives a voltage sensing signal from a voltage sensing means described below, and outputs a control signal for controlling the overall operation of the composite cooker. The cooking means 40 receives the constant voltage signal Vcc from the DC power supply 10 and simultaneously receives the control signal from the control means 30 to heat food. Induction heating means 41 for receiving the control signal from the control means 30 and induction heating the food, and the dielectric heating means 42 for receiving the control signal from the control means 30 and the dielectric heating Consists of.

The voltage sensing means 50 detects the driving voltage of the cooking means 40 driven by the control of the control means 30 and outputs the driving voltage to the control means 30. A driving voltage sensing unit 51 for sensing a driving voltage of the cooking means 40 driven by the control of the control means 30, a driving voltage signal from the driving voltage sensing unit 51, and a reference voltage generating unit; A first comparator 53 for receiving the reference voltage signal from the 52 and comparing the same to drive the cooking means 40, and receiving the comparison signal from the first comparator 53; A photocoupler PC for outputting a voltage sensing signal to select a heating source according to the control of the control unit 30 and a comparison signal from the first comparing unit 53 and a synchronizing signal from the synchronizing unit 54. Received as a second comparison unit 55 to compare this to drive control the cooking means 40 It is made.

The driving voltage detecting unit 51 receives the voltage dividing resistors R6 and R8 for dividing the driving voltage signal of the cooking means 40 driven by the control of the control means 30, and the voltage dividing resistors R6 and R8. Capacitor C4 for filtering out the noise component included in the signal divided by < RTI ID = 0.0 >), < / RTI > a diode D3 for half-wave rectifying the voltage signal filtered by the capacitor C4, and the diode D3. Voltage divider resistors R9 and R10 for receiving and dividing the half-wave rectified voltage and capacitor C5 for filtering noise components contained in the signal divided by the voltage divider resistors R9 and R10.

On the other hand, the reference voltage generator 52 receives the voltage signal (Vref) from the reference voltage generator 521 at the non-inverting terminal (+) and amplifies it by the amplification degree determined by the resistor (R7, R11) ( OPA), a voltage divider resistor R12 and R13 that are divided by receiving a voltage Vcc 'applied from the outside, and a capacitor that filters noise components included in a signal divided by the voltage divider resistors R12 and R13. C6).

In addition, the first comparing unit 53 receives the driving voltage signal from the driving voltage detecting unit 51 at the inverting terminal (−) and compares the reference voltage signal from the reference voltage generating unit 52. It is a comparator that receives the inverting terminal (+) and compares them so as to drive control the cooking means 40.

In addition, the photocoupler PC receives a comparison signal from the first comparator 53 at the cathode terminal and simultaneously receives a voltage Vcc 'applied from the outside, and emits light. It consists of a phototransistor RT which receives the constant voltage signal Vcc from the DC power supply means 10 via the resistor R15 when the light emitting diode LED emits light.

On the other hand, the second comparator 55 receives the comparison signal from the first comparator 53 and non-inverts the diode D4 for half-wave rectification and the voltage sensing signal half-wave rectified by the diode D4. The switching signal is applied to the base terminal of the transistor TR1 so as to receive the synchronization signal from the synchronization unit 54 and receive the synchronization signal from the inverse terminal (-) at the same time as input from the terminal (+). It consists of a comparator (COM) to compare them.

Hereinafter, the operation and effect of the container detecting device of the composite cooker configured as described above will be described.

First, when the operation switch (not shown) of the composite cooker is turned on, the DC power supply unit 10 receives a commercial AC input voltage supplied from the AC power input unit 1 and converts it into a predetermined constant voltage Vcc to detect the current. 20, output to the control means 30 and the voltage sensing means (50).

At this time, the current transformer 20 of the current sensing means 20 receives a commercial AC voltage from the AC power input terminal 1 and detects a change amount of the current input to the load, and detects the change amount of the current (R1). After converting the voltage variation through the half-wave rectification in the diode (D1).

In addition, the constant voltage signal Vcc from the DC power supply means 10 is input to the diode D2 through the resistor R2 and half-wave rectified.

Accordingly, the current monitoring signal, which is the amount of change of the current input to the load sensed by the current transformer 21, and the constant voltage signal from the DC power supply unit 10 are half-wave rectified by the diodes D1 and D2, and the voltage divider R4, The voltage is divided through R5) and input to the input terminal A / D1 of the control means.

In this case, when the container mounted on the composite cooker is a proper container, since the current sensing signal sensed by the current transformer 21 is smaller than the turn-on voltage of the zener diode ZD, the zener diode ZD is turned off and the current. The detection signal is input to the input terminal A / D1 of the control means 30.

Accordingly, the control means 30 receives the current sensing signal from the current sensing means 20 to determine whether the food is to be induction heated or dielectrically heated to induce heating means 41 of the cooking means 40 or The control signal is output to the dielectric heating means 42.

Therefore, the cooking means 40 receives the control signal from the control means 30, the induction heating means 41 or the dielectric heating means 42 of the relay (not shown) is turned on (ON) while induction heating or food Dielectric heating.

In addition, when the container placed in the composite cooker is a small load (a chopstick, a chopstick, etc.) that is not a proper container, the current sensing signal detected by the current transformer 21 is so small that the diode D1 cannot be conducted.

On the other hand, during the overload operation of the composite cooker according to the overcurrent, since the current sensing signal sensed by the current transformer 21 is greater than the turn-on voltage of the zener diode (ZD), the zener diode (ZD) is turned on at a constant level The signal is input to the input terminal A / D1 of the control means 30.

Accordingly, the control means 30 receives the current sensing signal from the current sensing means 20 and determines the overload operation state of the multicooker according to the overcurrent to output the low level control signal to the output terminals 01 and 02. Output to the induction heating means 41 and the dielectric heating means 42 through.

Therefore, the induction heating means 41 and the dielectric heating means 42 receive a low level control signal output from the control means 30 and stop the cooking operation.

In the voltage sensing means 40, the driving voltage signal of the cooking means 40 driven by the control of the control means 30 is divided through the voltage divider R6 and R8, and the voltage divider signal is divided into the diode D3. Half-wave rectification at

At this time, the voltage half-wave rectified by the diode D3 is divided into voltage through the divided voltage and the resistors R9 and R10, and is input to the inverting terminal (−) of the first comparator 53.

On the other hand, in the operational amplifier OPA of the reference voltage generator 52 receives the voltage signal Vref from the reference voltage generator 521 from the non-inverting terminal (+) and determined by the resistors R7 and R11. Amplify by amplification degree.

In addition, the voltage Vcc 'applied from the outside is divided by the voltage divider R12 and R13, and the noise component included in the divided signal is filtered by the capacitor C6.

Therefore, the reference voltage signal amplified by the operational amplifier OPA and the external voltage signal Vcc 'filtered by the capacitor C6 are input to the non-inverting terminal (+) of the first comparator 53. .

Accordingly, the first comparison unit 53 compares the driving voltage signal from the driving voltage detecting unit 51 with the reference voltage signal from the reference voltage generating unit 52.

As a result of the comparison, when the driving voltage signal from the driving voltage detecting unit 51 is smaller than the reference voltage signal, a high level comparison signal is applied to the cathode terminal of the LED of the photocoupler PC to emit light. The diode LED is off.

Accordingly, when the light emitting diode LED is turned off, the phototransistor receiver PT is also turned off so that the constant voltage signal Vcc from the DC power supply means 10 is connected to the control means 30 through the resistor R15. It is input to the input terminal I1.

Accordingly, the control means 30 receives a high level voltage sensing signal from the voltage sensing means 40 through the input terminal I1 and indicates that the container mounted on the complex cooker is a magnetic material container such as ferrous metal. The high level control signal is discriminated and output to the induction heating means 41 through the output terminal 01.

Therefore, the induction heating means 41 receives the high level control signal output from the control means 30 to induction heating the food.

Meanwhile, as a result of the comparison, when the driving voltage signal from the driving voltage detecting unit 51 is larger than the reference voltage signal Vref, the low level comparison signal is the cathode terminal of the light emitting diode LED of the photocoupler PC. Is applied to the light emitting diodes (LEDs) to emit light.

Accordingly, when the light emitting diode LED emits light, the phototransistor PT is turned on and the constant voltage signal Vcc from the DC power supply unit 10 is applied to the ground terminal through the resistor R15 and the phototransistor PT. do.

Accordingly, the control means 30 receives a low-level voltage sensing signal from the voltage sensing means 40 through the input terminal I1, and a container mounted on the multi-cooker is made of a nonmagnetic material such as aluminum or copper. It is determined that the container and outputs a low-level control signal to the induction heating means 41 and the dielectric heating means 42 through the output terminals (01, 02).

Therefore, the induction heating means 41 and the dielectric heating means 42 receive a low level control signal output from the control means 30 to stop the cooking operation.

In addition, the low level control signal output from the first comparator 53 is applied to the inverting terminal (+) of the comparator COM of the second comparator 55 to relate to the synchronization signal of the synchronizer 54. A low level comparison signal is always applied to the base terminal of the transistor TR so that the transistor TR is turned off to stop the cooking operation of the induction heating means 41 and the dielectric heating means 42.

According to the container sensing apparatus of the composite cooker according to the present invention as described above, by detecting the amount of change of the current input to the load by the current sensing means to select the cooking heating mode, the cooking means sensed by the voltage sensing means According to the drive voltage of the cooker can be determined by determining the container mounted in the non-ferrous metals, such as non-ferrous metals can be stopped automatically because the cooking operation can not only ensure the performance and safety of the device, This simple but low cost is excellent.

Claims (4)

In the multi-cooker, the control means, the current sensing means for receiving the commercial AC power from the AC power input stage and senses the amount of change in the current input to the load and outputs to the control means, and receiving the control signal from the control means A cooking means for performing a cooking operation according to the current sensing signal sensed by the current sensing means, and a voltage sensing means for sensing a driving voltage of the cooking means driven by the control of the control means and outputting the driving voltage to the control means. Container detecting device of a composite cooker characterized in that. According to claim 1, wherein the current sensing means for receiving a commercial AC voltage from the AC power supply means and a current transformer for sensing the amount of change of the current input to the load, and converts the current sense signal detected by the current transformer into a voltage signal A resistor R1, a diode D1 for half-wave rectifying the voltage signal converted by the resistor R1, and a resistor for filtering pulse components contained in the voltage signal half-wave rectified by the diode D1. (R3) and capacitor (C2), voltage divider (R4, R5) for dividing the voltage signal filtered by the resistor (R3) and capacitor (C2), and the threshold value of the current sensing signal sensed by the current transformer. A variable resistor VR for varying the voltage; Included in the signal A container detecting device for a composite cooker, characterized in that it comprises a capacitor (C3) for filtering the noise component. 2. The voltage sensing means according to claim 1, wherein the voltage sensing means comprises: a driving voltage sensing portion for sensing a driving voltage of the cooking means driven by the control of the control means, and a driving voltage signal from the driving voltage sensing and a reference voltage generating portion; A first comparator for receiving a reference voltage signal and comparing the same to drive control of the cooking means, and outputting a voltage sensing signal to receive a comparison signal from the first comparator and select a heating source according to the control of the control means; And a photocoupler (PC) and a second comparator for receiving the comparison signal from the first comparator and the synchronous signal from the synchronizer to compare and drive the cooking means. Sensing device. 4. The driving voltage sensing unit is divided by the voltage dividing resistors R6 and R8 for dividing the driving voltage signal of the cooking means driven by the control of the control means. A capacitor C4 for filtering a noise component included in the signal, a diode D3 for half-wave rectifying the voltage signal filtered by the capacitor C4, and a voltage for half-wave rectified voltage by the diode D3. Dividing resistance (R9, R10) and the capacitor sensing device of the composite cooker characterized in that it comprises a capacitor (C5) for filtering the noise component contained in the signal divided by the voltage divider (R9, R10). .