KR890001602Y1 - Control circuit of microwave oven - Google Patents

Abstract

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Description

Heating output control circuit of the electronic cooker

1 is a basic structural diagram of an electronic cooker.

2 is a waveform diagram of a base side voltage and resonant current of each stage in a power transistor;

3 is a waveform diagram of current flowing through a heating coil according to the base voltage of each power transistor and each container.

4 is a state diagram showing a relationship between a conduction time of a power transistor and power consumption.

5 is a diagram illustrating voltage induced by an input current and a current detector.

6 is a circuit diagram of the present invention.

7 is a diagram illustrating a relationship between input current and one side (−) side of a comparator CP ₃ .

8 is a relationship diagram between the input current and the one-side input voltage of the comparator CP ₄ .

9 is an output state diagram of the heating vessel and each comparator.

10 is a voltage increase relationship between the heating vessel and the comparator (CP ₃ ).

11 is a diagram showing the voltage rise between the heating vessel and the comparator CP ₄ .

* Explanation of symbols for main parts of the drawings

1: drive part of power transistor 2: sawtooth wave generator

3: Output setting part 4: Object detection part

5: display unit 7: container detection unit

6: output control unit CP ₁ , CP ₂ , CP ₃ , CP ₄ : comparator

CT: current sensor R ₁ , R ₂ , R ₃ : resistance

D ₁ , D ₂ , D ₃ : Diodes ZD ₁ , ZD ₂ : Zener Diodes

LED: Light emitting diode Q ₁ , Q ₂ , Q _3, Q ₄ : Transistor

VR ₁ , VR ₂ : Variable resistor

The present invention relates to a heating output control circuit of an electronic cooker. Since an electronic cooker uses high frequency as a cooker using dielectric heating by microwaves, it is necessary to construct various apparatuses and circuits in terms of stability.

In power supply circuits, primary, secondary, and monitor are required because high voltage must be maintained on the transformer secondary side. Each switch is configured to drive stably.

In addition, a stabilizer is required for the container inside the electronic cooker cavity, so in the case of an improper container such as an aluminum container and a small load such as a fork or a spoon, the heating operation must be stopped to prevent burns. Unlike ordinary steel or enamel containers, the output is excessively increased and the parts are exerted on each part, so proper prevention measures are required.

An object of the present invention is to provide an electronic cooker capable of detecting an unsuitable container or a small load applied to a container in an electronic cooker cavity and displaying a label on the label, and controlling heating output according to heating of general steel products and stainless steel containers. In order to provide a heating output control circuit, the conduction time of a power transistor is proportional to the power consumption and the induced voltage of the current detector is proportional to the input current. According to the accompanying drawings, the heating output is stably configured to be controlled in detail.

FIG. 1 is a basic circuit diagram of a microwave oven, in which an AC power source is full-wave rectified through a rectifier (REC), and then smoothed with a choke coil (L ₁ ) and a smoothing capacitor (Ca), followed by a heating coil (L ₂ ) and a resonance. Since the capacitor (cb) and the power transistor (Q) damper diode (D) are supplied to the resonant circuit (15) connected, the power transistor (Q) is resonated in accordance with the conduction and non-conduction.

Therefore, as shown in FIG. 2, when the fixed-phase state signal is applied (H level) according to the state signal of the square wave applied to the base side of the power transistor Q, the rising current flows through the heating coil L ₂ and the power transistor Q. When the low potential state signal L level is applied to the base side, the transistor Q is turned off, and thus the resonance capacitor Cb is charged.

A heating coil (L ₂₎ to be charged after finishing the flow a little through a damper diode (D) does not stop because of the inductance of the heating coil (L ₂₎ after the discharge is discharged through the heating coil (L ₂₎ back to the high-frequency alternating current is When the heating coil (L ₂ ) is flowing to generate a magnet in a vertical direction, the eddy current is generated in the container by the magnetism, the eddy current is heated while the joule heat is generated by the resistance component of the container.

In this case, when the period of conduction and non-conduction of the power transistor Q is constant, the current is rapidly increased and the value is increased in comparison with the steel container which is a suitable container as shown in FIG. If the output is constant, the conduction time of the power transistor Q is shorter than that of the steel container, and the current flowing through the heating coil L ₂ increases rapidly. The critical point is reached in time.

Therefore, if the output is set at the highest point, overcurrent flows in the case of stainless steel container, which causes excessive force on parts such as power transistor (Q) and damper diode (D), which causes the cause of failure and reliability to deteriorate.

However, in the present invention, the conduction time of the power transistor Q is proportional to the power consumption as shown in FIG. 4 and the induced voltage of the current detector CT installed in the input power supply as shown in FIG. The purpose of the present invention is to provide an apparatus capable of effective load detection and stable stainless steel heating using points proportional to and.

That is, according to the present invention, the driving unit 1 of the power transistor Q is configured to be controlled by the output of the comparator CP ₁ as shown in FIG. 6, but the output setting unit 3 is connected to one terminal (+) of the comparator CP ₁ . The output voltage of the structure is configured to be distributed and applied to the resistor (R ₂ ) (R ₃ ) and the output of the sawtooth wave generator 2 is not provided to the other terminal (-).

The output setting unit 3 is configured such that the voltage divided by the variable resistor VR ₁ and the resistor R ₄ is applied to one terminal (+) of the comparator CP ₂ and the output of the current detector CT is condenser. (C ₃ ) (C ₄ ), diode (D ₁ ), resistor (R ₇ ) (R ₈ ) through the filter divided into resistor (R ₅ ) (R ₆ ) and then the other terminal of comparator (CP ₂ ) It is configured to be applied to (-), and R ₉ is a resistance for giving hysteretic characteristics.

Here, the stable output can be obtained by the variable resistor VR ₁ .

In addition, the output of the comparator CP ₁ is configured to be applied to the small object detecting unit 4, and the small object detecting unit 4 is configured such that the output of the current detector CT is applied to the container detecting unit 7. (4) is configured so that the sawtooth wave is generated from the variable resistor (VR ₂ ) resistor (R ₁₁ ), the capacitor (C ₅ ) through the diode (D ₂ ) is applied to one terminal (+) of the comparator (CP ₃ ) and the other side The output of the current detector CT is applied to the terminal (-), and the capacitor C ₇ is configured to be charged through the diode D ₄ to which the power supply V _CC is applied. The output of CT is distributed to resistor R ₁₂ (R ₁₃ ) and applied to the other terminal (-) of comparator CP ₄ through zener diode ZD ₂ , and the output of comparator CP ₄ is diode (D ₃₎ and capacitor (C ₆₎ is applied through the output of the comparator (CP ₄₎ charged in the capacitor (C ₈₎ configured to thereby drive the output control unit 6 The. The display unit 5 is configured so that the collector side of the transistor Q ₁ is connected to the diode D ₅ and D ₆ to drive the transistor Q ₂ connected in parallel with the light emitting diode LED to light up when the object is detected. Thus, the output control unit 6 is configured to control the voltage applied to one terminal (+) of the comparator CP ₁ by configuring the transistors Q ₃ and Q ₄ in multiple stages.

In this configuration, the sawtooth wave of the sawtooth generator 2 is applied to one terminal (-) of the voltage comparator CP ₁ connected to the base of the power transistor Q, and the resistor R ₂ is applied to the other terminal (+). The division voltage by (R ₃ ) is applied, and the output of the voltage comparator CP ₁ generates a square wave, which turns the power transistor Q on and off. After this time in the distribution voltage of the resistor (R ₄₎ by an output variable resistor (VR ₁₎ it is set to output a set current detector (CT) there is a voltage of the organic detects the power line a current the voltage of resistor (R ₅ ) And the resistor (R ₆ ) to become the input terminal (-) voltage of one side of the comparator (CP ₃ ) as shown in FIG. In addition, the voltage is applied to the comparator CP ₂ to be compared with the voltage set by the output variable resistor VR ₁ to stabilize the voltage of one terminal (+) of the voltage comparator CP ₁ to give a constant output. Therefore, the user can obtain the desired stable output at all times by the output setting 3 changing the output resistance VR ₁ .

In this way, when the output is set by the output variable resistor VR ₁ , since the current flows less as shown in FIG. 3, the voltage induced in the current detector CT is low, and the output of the comparator CP ₂ becomes H level and the voltage comparator ( One input terminal (+) of CP ₁ ) is supplied with the divided voltage of resistors R ₂ and R ₃ , which are maximum values, so that the output pulse width of the voltage comparator CP ₁ is maximized.

In other words, where a variable resistance of the current sensor (CT) voltage and a voltage comparator (CP ₁₎ somul detection unit (4) there is the comparison with the output voltage an output voltage of the voltage comparator (CP ₁₎ through the diode (D ₂₎ of the ( VR ₂ ) and the resistor R ₁₁ generate the sawtooth wave as shown in FIG. 9 in the capacitor C ₅ .

The maximum value of the sawtooth wave is related to the square wave pulse width. In the current detector CT, a low voltage is applied to one input terminal (-) of the voltage comparator CP ₃ and the other input terminal (+) is applied to the two sawtooth waves. In comparison with FIG. 10, a portion having one terminal (+) higher than the other terminal (−) of the voltage comparator CP ₃ of the object sensing unit 4 when the object is loaded is generated.

At this time, when a high voltage is applied to one terminal (+), the voltage comparator (CP ₃ ) outputs the H level and the current is charged in the capacitor (C ₇ ) through the resistor (R ₆ ) and the diode (D ₄ ). (Q ₁ ) is turned on and the voltage of one terminal (+) of the voltage comparator CP ₁ falls to the ground voltage through the diode D ₅ to stop the operation.

In addition, the transistor Q ₂ also has a base potential lowered through the diode D ₆ , thereby turning off the light emitting diode LED that is turned on by the transistor Q ₂ being turned on.

At this time, when the discharge of the capacitor (C ₅ ) of the object detection unit (4) is finished, the voltage comparator (CP ₃ ) is output to the L level, but the capacitor (C ₇ ) flows slowly through the discharge resistor (R ₁₇ ) for some time the transistor Keep (Q ₁ ) in conduction state.

After the discharge of the capacitor C ₇ is completed, the transistor Q ₁ is turned off, and the voltage of one terminal (+) of the voltage comparator CP ₁ is also gradually increased by the capacitor C ₁ , and the output becomes H level. The light emitting diode LED of the display portion becomes large again. At this time, the voltage comparator CP ₃ compares the induced voltage of the current detector with the square wave pulse width, sets the output to H level, conducts the transistor Q ₁ , increases the light emitting diode (LED), and repeats the operation of stopping the output. This will reduce power consumption while informing the user that the container is inappropriate.

In addition, when the stainless steel vessel is heated with the output variable resistor VR ₁ set to the high output section, the output is stabilized by the current detector CT, and the pulse width of the square wave is higher than that of the steel vessel. As a result, the waveform is charged and discharged as shown in FIG. 9 by the capacitor C ₆ through the diode D ₃ .

That is, the input voltage of the positive side of the voltage comparator CP ₄ of the vessel sensing unit 7 is lowered when the stainless vessel is heated than the steel vessel. On the other hand, when the output becomes larger, the other terminal (-) voltage of the voltage comparator CP ₄ is applied proportionally from the moment of obtaining the zener voltage of the zener diode ZD ₂ as shown in FIG.

As a result, the voltages at both ends are compared with each other as shown in FIG. 11. In the case of the steel container, the portion of the high voltage of one terminal (+) is increased, and the H-level output is sent to the voltage comparator (CP ₄ ) to supply the diode (D ₇ ). Through charging the capacitor (C ₈ ) through the transistor (Q ₃ ) and the transistor (Q ₄ ) is always kept off.

However, in the case of stainless steel, the voltage at both ends of the voltage comparator CP ₄ of the container sensing unit 7 is lowered as shown in Fig. 11 so that the output becomes L level and the capacitor C ₅ is charged. In this case, the transistor Q ₃ is turned off and the transistor Q ₄ is turned on so that the voltage of one terminal (+) of the voltage comparator CP ₁ is divided between the resistors R ₂ and R ₃ so that the resistance ( Drop through R ₂₄ ).

Thus, when the stainless steel container is heated, the output control unit 6 stabilizes the maximum output at a certain limit, so that the operating characteristics of the product can be improved and the reliability can be increased even if the output is somewhat reduced.

As described above, according to the present invention, when the power transistor is driven based on a constant container, the induced voltage of the output setting unit 3 and the sawtooth wave generator 2 are generated by using a point in which the power consumption is proportional to the induced current of the input side current sensor. At the same time, the power transistor is driven by the output voltage of the power supply and the output voltage of the comparator is compared between the induced voltage and the power transistor drive to drive the display unit 5 and the output control unit 6 in the small object detector 4 and the container detector 7. It is possible to provide an electronic cooker capable of driving stably at all times by controlling the heating output in accordance with an inappropriate container or a stainless container.

Claims (1)

Sawtooth wave is applied to the induction voltage of the current sensor (CT) via a filter to a comparator (CP ₁₎ to be applied as compared with the reference voltage of the comparator (CP ₂₎ connected to the variable resistor constituting the output setting section (3) generating portion ( 2) the comparator output is via a respective distribution resistor and a capacitor (C ₆₎ via a respective diode (D ₂₎ (D ₃₎ of the configuration as compared to the voltage and current detectors (CT), and a comparator (CP ₁₎ of the (CP ₃ After the condensation detector 4 and the container detector 7 are configured to be charged in the rear end capacitor C ₇ (C ₈ ) of (CP ₄ ), the transistors (Q ₁ -Q ₄ ) and the light emitting diodes (LEDs) are used. A heating output control circuit of an electronic cooker configured to control the configured display unit (5) and the output control unit (6).