KR102026712B1 - Induction heating cooker - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating cooker, and more particularly, to an induction heating cooker that enables the protection of the switching element and the progress of cooking through an adjustment to reduce the output by a certain amount when an inverter interrupt occurs.
The induction heating cooker of the present invention is provided with a rectifying unit for converting the commercial power supply into a DC power source, a resonant inverter circuit unit for performing the output by the resonance by receiving the DC power, and the output of the resonant inverter circuit unit in response to an output control signal When the inverter interrupt occurs, the inverter control unit for lowering the output of the resonant inverter circuit unit by a set value to perform the output by the resonance, and the main control unit for generating and applying the output control signal to the inverter control unit It is composed.

Description

Induction Heating Cooker {INDUCTION HEATING COOKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating cooker, and more particularly, to an induction heating cooker that enables the protection of the switching element and the progress of cooking through an adjustment to reduce the output by a certain amount when an inverter interrupt occurs.

In general, the electric range is electric power is supplied to the heating plate, the heating plate consumes the power represented by the product of the square of the current and the resistance, the power consumed to heat the heating plate, which is transmitted to the heating element in the form of heat, finally heating the heating element Done. The principle of generating heat in an induction heating cooker is not different from other heaters, but in an induction heating cooker, since electricity is directly generated and consumed by an object blocking magnetic lines, heating is performed.

Therefore, in the case of an induction heating cooker, a high frequency voltage having a certain size must be applied to the working coil in order to generate magnetic lines. At this time, the working coil has a strong thermal power by the high frequency voltage applied. A circuit for applying a high frequency voltage to the working coil is an inverter circuit. Such an inverter circuit performs an operation of shutting off the inverter output in order to protect the switching element when the resonance voltage or the resonance current of the switching element provided therein is higher than a predetermined value (that is, when an inverter interrupt occurs). do.

The switching device protection device of the composite cooker of Korea Patent Publication No. 1996-0020614 detects surge voltage and resonance voltage flowing into the input overvoltage and power input in both the conducting section and the non-conducting section of the switching element so that the switching element is surged. When the voltage generation and the resonant voltage are above a certain voltage, the switching element is immediately cut off to be protected. The pulsating DC voltage is supplied by selecting one of the heating means among the high frequency dielectric heating means and the electromagnetic induction heating means as a microcomputer. And switching means for detecting the presence or absence of a surge voltage in the power input to the high frequency dielectric heating means and the electromagnetic induction heating means in a switching control means including a switching means for heating the food by continuously resonating the selected heating means. Surge detection means for controlling the Resonance voltage detection means for detecting the resonant voltage generated from one of the heating means to stop the operation of the switching means when the predetermined voltage or more.

In this prior art, when the inverter interrupt is generated, the operation of the switching means is stopped, so that the heating is stopped. Due to the interruption of the heating, there is a problem that the continuous cooking is not possible, the temperature of the food in progress is lowered and the desired cooking quality cannot be achieved even if the heating is resumed later.

The present invention provides an induction heating cooker that reduces the output by a certain amount so that heating to the current cooking is continued even when an inverter interrupt is generated, thereby enabling the protection of the switching element and allowing continuous heating to be performed. The purpose.

It is also an object of the present invention to provide an induction heating cooker which, after an inverter interrupt occurs, does not occur again for a certain period of time, increases the reduced output by a certain amount to achieve a desired cooking quality. .

The induction heating cooker of the present invention is provided with a rectifying unit for converting into a DC power supplied with commercial power, a resonant inverter circuit unit receiving the DC power to perform an output by resonance, and an output of the resonant inverter circuit unit in response to an output control signal. When the inverter interrupt occurs, the inverter control unit for lowering the output of the resonant inverter circuit unit by a set value to perform the output by the resonance, and the main control unit for generating and applying the output control signal to the inverter control unit And the inverter control unit further lowers the output of the resonant inverter circuit unit by the set value when the inverter interrupt occurs again within the reference time after the output fall, and outputs the inverter interrupt within the reference time after the output fall. If it doesn't happen again The output of the resonant inverter circuit unit is increased by the set value, and when the output of the resonant inverter circuit unit is lower than or equal to the lower limit output, the output of the resonant inverter circuit unit is cut off, and the inverter controller outputs the output descending or the output rises. Or transmitting a signal corresponding to an output cutoff to the main controller, wherein the signal corresponding to the output dropping or output rising or output cutoff includes an error generating code, and the main control unit stores the error generating code, An upper bit of a generation code means a kind of the inverter interrupt, and a lower bit of the error generating code is output lowered to be lower than an initial output corresponding to the output control signal, or output is raised to correspond to the output control signal. Output stage or output rises lower than the initial output W means that the initial output stage corresponding to the output control signal.

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The inverter controller may transmit a signal indicating that normal output is being performed to the main controller when the output of the resonance inverter circuit part due to the output rise is equal to the initial output in response to the output control signal.

In addition, the inverter control unit transmits a signal corresponding to an output falling or output rising or output blocking to the main control unit to the main control unit, the main control unit to display the output falling or output rising or output blocking through the display unit. desirable.

In addition, when an output initialization condition occurs, the inverter controller preferably initializes the output of the resonant inverter circuit unit to an output corresponding to the output control signal received from the main controller after generation of the output initialization condition.

In addition, the output initialization condition preferably includes at least one of an electrostatic state, a no container state, and a change state of the output control signal.

In addition, the signal corresponding to the output falling or output rising or output blocking preferably comprises a PAN signal.

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According to the present invention, as the protection operation of the switching element, the resonance voltage or the resonance current is high, so that the output voltage is adjusted when the inverter interrupt occurs so that the resonance voltage or the resonance current is lowered. For example, the resonant voltage or resonant current of the switching element (IGBT) increases considerably when the product is driven in a container with poor resonance characteristics, the product is driven in a power distortion area, or the product is eccentric. By lowering and driving the induction heating cooker, the resonance voltage and the resonant current of the switching element (IGBT) can be reduced, thereby stably operating the induction heating cooker and continuing heating.

In addition, when the output is lowered due to the inverter interrupt, the user can see that the output is lower than the normal output (initial output).

In addition, after the inverter interrupt is generated, if it does not occur again for a period of time, there is an effect of increasing the reduced output by a certain amount to achieve a desired cooking quality.

In addition, when an inverter interrupt occurs, the inverter controller terminates the independent output control function when the power is not regulated by the inverter controller, and when the PWM change is detected, the output corresponding to the inverter control signal applied from the main controller. By doing this, there is an effect that the output control by the main control unit is performed.

1 is a block diagram of an induction heating cooker according to the present invention.
FIG. 2 is a flowchart illustrating an output adjustment function of the induction cooker of FIG. 1.
3 is a flowchart illustrating an output initialization of the induction heating cooker of FIG. 1.

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

1 is a block diagram of an induction heating cooker according to the present invention.

The induction heating cooker is supplied with a rectifier 10 for converting the DC power into a commercial power supply, a capacitor C2 for smoothing the DC power from the rectifier 10, and a smoothed DC voltage to receive the output by resonance. It is provided with a resonant inverter circuit portion 15 to perform heating in a cooking vessel (not shown) during cooking. The resonant inverter circuit section 15 includes inverter resonators L1 and C1 for forming electromagnetic force, and a switching element Q1 for supplying and blocking DC voltage smoothed by on / off to the inverter resonators L1 and C1. )

In addition, the induction heating cooker includes an inverter control unit 30 for generating an inverter driving signal for turning on and off the switching element Q1 according to an output control signal of the main control unit 50, an input unit 40 for obtaining an input from a user; , A display unit 50 for displaying information such as a current performing operation of the induction heating cooker, and a main control unit 60 for controlling the above-described components to perform the cooking operation.

In addition, the induction heating cooker is provided with a DC power supply unit 20 is supplied to the commercial power supply to generate the necessary use DC power supply therein to supply to the inverter control unit 30, the main control unit 60 and the like.

In addition, the induction heating cooker is a current sensing unit 72 connected between the commercial power supply and the rectifier 10 to detect the current applied from the commercial power supply, and the rectifier 10 and the resonant inverter circuit unit 15 to detect the power failure. ) Between the power failure detector 74 connected to the resonance voltage circuit 76 for detecting the resonance voltage in the resonance inverter circuit unit 15, and the resonance current detection unit for detecting the resonance current in the resonance inverter circuit unit 15. 78).

In detail, the rectifier 10 corresponds to a device receiving commercial AC power to generate a DC power having a desired size and applying the same to the resonant inverter circuit 15.

In addition, the inverter resonator includes at least a working coil L1 and a capacitor element C1 connected in parallel to the working coil L1 to generate an output by resonance.

In addition, the switching element Q1 is an element that performs on and off operations by an inverter driving signal from the output terminal O1 of the inverter control unit 30. For example, an IGBT element is applied. A resistor R1 is provided between the emitter terminal and the gate terminal of the switching element Q1, and the gate terminal of the switching element Q1 receives the inverter driving signal. In addition, the resonant current detector 78 is connected to the emitter terminal of the switching element Q1.

The DC power supply unit 20, the input unit 40, the display unit 50, the current sensing unit 72, the electrostatic sensing unit 74, and the resonance voltage sensing unit 76 are elements provided in a general induction heating cooker. Since the present invention is equivalent to those skilled in the art to which the present invention pertains, the detailed description is omitted.

The main controller 60 generates an output control signal corresponding to an output selection input from the input unit 40 or an output according to a pre-stored cooking algorithm, and applies the output control signal to the inverter controller 30.

The inverter controller 30 generates an inverter driving signal corresponding to an output control signal (for example, a PWM signal) applied from the main controller 60, and applies the generated inverter driving signal to the resonance inverter circuit unit 15 to generate an initial output. Here, the initial output corresponds to the output corresponding to the output control signal from the main control unit 60.

In addition, the inverter controller 30 performs an output adjustment function when an inverter interrupt occurs. The inverter controller 30 receives the resonance voltage and the resonance current from the resonance voltage detector 76 and the resonance current detector 78. When the received resonant voltage or resonant current is equal to or greater than the reference voltage or reference current, the inverter controller 30 determines that an inverter interrupt is generated to prevent damage to the switching element Q1. When such an inverter interrupt occurs, the inverter controller 30 generates an inverter drive signal for lowering the initial output corresponding to the output control signal by a set value (for example, one step or 100W) to generate the resonance inverter circuit unit 15. Is applied. In addition, the inverter controller 30 generates an inverter driving signal that raises the current output by a set value (for example, 1 step or 100W) when the inverter interrupt is not generated within the reference time. To the resonant inverter circuit section 15. That is, the inverter controller 30 causes the initial output corresponding to the output control signal from the main controller 60 to be generated in the resonant inverter circuit unit 15, but performs an independent control of the initial output when an inverter interrupt occurs. do. The inverter controller 30 includes a timer element for calculating the elapsed time.

In addition, when the inverter control unit 30 adjusts the output of the resonant inverter circuit unit 15, the falling output lowers only the set lower limit output. When the output of the resonant inverter circuit unit 15 is lower than the lower limit output, it may not only significantly affect the cooking quality of the food, but also the loss voltage of the switching element Q1 may increase, which may cause damage. In addition, when an inverter interrupt occurs below the lower limit output, a problem may occur in another component, and thus the inverter controller 30 may generate a PAN signal (for example, a LOW signal). Is generated and applied to the main control unit 60, and the main control unit 60 generates an output control signal for output blocking in response to the PAN signal and applies it to the inverter control unit 30. Accordingly, the inverter controller 30 generates an inverter driving signal for interrupting the output of the resonance inverter circuit unit 15 and applies it to the switching element Q1.

The inverter controller 30 adjusts the output within the range of the output of the resonant inverter circuit unit 15 within an initial output or less corresponding to the output control signal applied from the main controller 60.

For example, the output of the induction heating cooker is in the range of 150 to 1500 W (1 to 12 steps), the set lower limit output is 8 steps (950 W), and 8 or more steps are 9 steps (1100 W) and 10 steps (1300 W). , 11 steps (1400W), 12 steps (1500W). When the initial output is 12 steps (1500W), when the inverter interrupt occurs, the inverter control unit 30 lowers the initial output by a set value, and lowers the output in 11 steps (1400W). If the inverter interrupt occurs again within the reference time after the current output falls to 11 steps (1400W) by the output drop, the inverter control unit 30 additionally lowers the current output of 11 steps (1400W) by the set value. In step 10 (1300W), the output is lowered. If the inverter interrupt does not occur within the reference time, the current output is increased by the set value, and the output is increased in 12 (1500W). When the current output and the initial output become the same by this output rise, the inverter controller 30 does not perform additional output rise even if the inverter interrupt does not occur within the reference time.

In addition, when the inverter interrupt occurs, the inverter controller 30 generates an error generation code indicating the generation of the inverter interrupt, and applies the generated error code to the main controller 60. In particular, the inverter control unit 30 includes an error generating code (for example, an IH: F3 code) when the occurrence of the inverter interruption is caused by an abnormality of the resonance voltage and an error generating code (for example due to an error of the resonance current). , IH: F4 code) are generated and transmitted to the main controller 60, respectively. The main control unit 60 stores the error generation code so that a user or a repairer can later confirm the cause of the inverter interrupt (error of resonance voltage and resonance current).

 In addition, the inverter controller 30 checks whether an output initialization condition has occurred while performing the above-described output adjustment function. This output initialization condition includes at least one of a no container state, a power failure, and a change in the output control signal.

First, the no container state is described. Normal cooking may be performed when the cooking vessel is positioned on the cooking region formed above the working coil L1 provided in the inverter resonator. However, when the cooking vessel is eccentric from the cooking region, the distance between the inverter resonator and the cooking vessel may vary. As it moves away, the resonance voltage decreases. Since the output to the cooking vessel is reduced by the reduction of the resonance voltage, unnecessary heating or abnormal heating may occur. To prevent this, it is necessary to cut off the output. Thus, the inverter controller 30 compares the current magnitude from the current sensing unit 72 with the set reference current magnitude, and determines that there is no container when the detected current magnitude is less than or equal to the reference current magnitude. This containerless state includes a case where the cooking vessel is separated from the cooking region by a distance or more (eccentricity), and when the cooking vessel is completely removed from the cooking region (the user lifts the cooking vessel).

Next, in the case of a power failure, the inverter controller 30 and the main controller 60 may confirm that the power failure has occurred by checking the magnitude of the current or voltage from the power failure detection unit 74.

Next, a change in the output control signal means a change in the output control signal received by the inverter controller 30 from the main controller 60. The inverter controller 30 may check the change in the output control signal, that is, the change in the PWM signal (for example, the change in the duty ratio).

When the above-described output initialization condition is confirmed, the inverter control unit 30 initializes (or changes) the current output to an output corresponding to the output control signal received from the main control unit 60 after the output initialization condition occurs. For example, in the case of no container state, the inverter control unit 30 applies a PAN signal (LOW signal) indicating the no container state to the main control unit 60, and the main control unit 60 outputs to the inverter control unit 30. Apply the output control signal corresponding to the cutoff. Accordingly, the inverter control unit 30 stops the output of the resonance inverter circuit unit 15. Subsequently, when the inverter control unit 30 checks the container presence state, the inverter control unit 30 generates a PAN signal (HIGH signal) indicating the container presence state and applies it to the main control unit 60, and the main control unit 60. Generates an output control signal corresponding to an output selection input from the input unit 40 or an output according to a pre-stored cooking algorithm and applies it to the inverter controller 30. Accordingly, the inverter controller 30 does not perform an output according to the output adjustment function that was performed before the output interruption, but performs an output corresponding to the output control signal applied from the main controller 60 after the container no state. do.

Next, in the case of power failure, the inverter control unit 30 and the main control unit 60 respectively check the power failure state, and when the main control unit 60 ends the power failure state and becomes an energized state, the main control unit 60 enters the input unit ( An output control signal corresponding to the output selection input from 40) or the output according to the pre-stored cooking algorithm is generated and applied to the inverter controller 30. Accordingly, the inverter controller 30 does not output the output control function performed before the power failure state, but performs an output corresponding to the output control signal applied from the main control unit 60 after the power failure state. .

As another example, when the change of the output control signal is confirmed, the inverter controller 30 initializes the current output to an output corresponding to the changed output control signal.

Next, the main control unit 60 basically performs control according to an output selection input input by the user through the input unit 40 or a cooking algorithm stored in a storage unit provided therein, and the cooking state and error of the induction heating cooker. Information such as status is displayed via the display unit 50. That is, the main controller 60 generates an output control signal corresponding to the output selection input or the cooking algorithm and applies it to the inverter controller 30 so that a process such as heating is performed.

In addition, the main control unit 60 may receive an error generation code from the inverter control unit 30 to confirm that an inverter interrupt has occurred in the induction heating cooker. In addition, the main control unit 60 stores the error occurrence code in the storage unit, and then allows a user or a repairer to read and confirm the error occurrence code.

In addition, the main controller 60 checks the output drop, the output rise, the output cutoff, the normal output, etc. by the inverter controller 30 using the error generation code and the PAN signal, and displays corresponding information. Mark on. The main controller 60 may check the output adjustment state of the inverter controller 30 based on the PAN signal generated by the inverter controller 30 and the error occurrence code. Table 1 shows the states according to the PAN signal and the error generation code.

Kinds PAN signal Error code Output regulation state Output display
(example) Upper bits Lower bits One HIGH 0011 0010 Lowered output, output 2 steps lower than initial output

2 LOW 0011 0100 4 levels lower than the initial output (output cut off)

3 HIGH 0000 0010 Output rises and outputs 2 levels lower than initial output

4 HIGH 0000 0000 Initial output by rising output

The lower bits of Table 1 contain only a few examples. In Table 1, the upper bits of the error occurrence codes indicate the type of inverter interrupts (0011-IH: F3, 0100-IH: F4), and the lower bits are output stages lower than the initial output by falling output or initial output by rising output. Lower output stage or output rise means the initial output stage. For example, the lower bits are 0000 (current output is equal to initial output), 0001 (output step one step lower than initial output), 0010 (output step two steps lower than initial output), 0011 (three steps lower than initial output) Low output stage), 0100 (four stages lower than the initial output stage), and the like. The inverter controller 30 generates an error generation code corresponding to the output stage as described above and transmits the generated error code to the main controller 60 while performing an independent output adjustment function, thereby performing a corresponding display.

For example, the initial output is 12 steps (1500 W), the inverter control unit 30 generates a PAN signal and an error generation code corresponding to the type 1, and transmits the generated PAN signal to the main control unit 60. It is possible to visually or audibly display to the user through the display unit 50 that the output down adjustment is being performed (output information) at an output two levels lower than the initial output. For example, two red lights may be displayed or may be displayed in letters such as "output two-stage falling".

Next, when the current output is less than the lower limit output, the inverter controller 30 generates a PAN signal and an error generation code corresponding to the type 2, and transmits the generated error code to the main controller 60, and the main controller 60 performs more than the initial output. The output drop is adjusted to the four-stage low output to output to the user through the display unit 50 that the output is being blocked (output information). For example, four red lights may be displayed, or may be displayed in letters such as "output blocking".

Next, when the inverter control unit 30 performs a one-step output increase in the output state three steps lower than the initial output, generates a PAN signal and an error generation code corresponding to the type 3, and transmits to the main control unit 60. The main controller 60 may transmit the output ascending to the output 2 levels lower than the initial output (output information) to the user through the display unit 50. For example, two red lights may be displayed or may be displayed in letters such as "output two-stage falling".

In addition, the main controller 60 displays previously when the current output becomes the same as the initial output after the output falls, that is, when the PAN signal corresponding to the type 4 and the error occurrence code are received from the inverter controller 30. One output information (output falling state) may be removed from the display unit 50, or it may indicate that normal output is being performed. For example, one green light may be displayed, or may be displayed in text such as "normal output" or the like.

FIG. 2 is a flowchart illustrating an output adjustment function of the induction cooker of FIG. 1.

In step S11, the main controller 60 generates and applies an output control signal corresponding to the output selection input or cooking algorithm to the inverter controller 30, and the inverter controller 30 receives the output control signal.

In step S13, the inverter controller 30 generates and applies an inverter drive signal to the switching element Q1 such that an initial output corresponding to the received output control signal is generated by the resonance inverter circuit unit 15.

In operation S15, the inverter controller 30 receives the resonance voltage detector 76 and the resonance voltage and the resonance current from the resonance current detector 78 to check whether the inverter interrupt occurs. If an inverter interrupt has occurred, the process proceeds to step S17, otherwise the process proceeds to step S11.

In step S17, the inverter controller 30 determines whether the current output is greater than the lower limit output. If the current output is greater than the lower limit output, the process proceeds to step S21. If the current output is less than the lower limit output, the process proceeds to step S19.

In step S19, since the inverter control unit 30 can no longer lower the current output, the inverter control unit 30 generates a PAN signal and an error generation code as in Type 2 of Table 1 and applies it to the main control unit 60. In addition, the inverter controller 30 generates an inverter driving signal corresponding to the output cutoff and applies it to the switching element Q1. At this time, the main control unit 60 confirms that the output is blocked, and informs the output blocking through the display unit 50.

In step S21, the inverter controller 30 generates an inverter driving signal for lowering the current output by a set value (for example, step 1) and applies it to the resonance inverter circuit unit 15. In addition, the inverter controller 30 generates a PAN signal and an error generation code and transmits the generated PAN signal to the main controller 60. The main controller 60 provides the user with visual or auditory output information indicating the output drop through the display unit 50.

In step S23, the inverter controller 30 determines whether an inverter interrupt occurs additionally. If an inverter interrupt occurs additionally, the process proceeds to step S17, otherwise the process proceeds to step S25.

In step S25, the inverter control unit 30 calculates the elapsed time since the output fall by using the timer element, and if the elapsed time passes the reference time, proceeds to step S27, otherwise, step S23. Proceed to).

Steps S23 and S25 described above are processes for checking whether an inverter interrupt occurs within a reference time after the output fall.

In step S27, the inverter controller 30 increases the current output by the set value because no inverter interrupt occurs additionally within the reference time after the output fall. In addition, the inverter controller 30 generates a PAN signal and an error generation signal, and transmits the generated PAN signal to the main controller 60. The main controller 60 provides the output information to the user through the display unit 50 based on the received PAN signal and the error occurrence signal.

In step S29, the inverter controller 30 determines whether the current output and the initial output are the same. If the current output and the initial output are the same, the inverter controller 30 determines that the current output corresponds to the normal output corresponding to the output control signal, and proceeds to step S31. If the current output is lower than the initial output, the flow proceeds to step S23.

In step S31, the inverter controller 30 notifies the main controller 60 that the current output is the initial output. That is, the inverter controller 30 generates a PAN signal and an error occurrence code as shown in Type 4 of Table 1 and transmits them to the main controller 60, and the main controller 60 performs normal output through the display unit 50. It is displayed.

After step S31, the process proceeds to step S15 again, whereby the output adjustment function is performed.

3 is a flowchart illustrating an output initialization of the induction heating cooker of FIG. 1. FIG. 3 shows that the above-described output initialization condition is generated while the inverter controller 30 performs an independent output adjustment function, and performs the output rising, output falling, and normal output. Output corresponding to the output control signal received from 60).

In detail, in step S41, the inverter controller 30 determines whether the current output adjustment function is performed. If the current output adjustment function is being performed, the flow advances to step S43, otherwise, the process ends.

In step S43, the inverter controller 30 determines whether an output initialization condition is generated while performing an output adjustment function. If the output initialization condition occurs, the process proceeds to step S45, otherwise, the process proceeds to step S41.

In step S45, the inverter controller 30 generates a PAN signal and an error occurrence code as in Type 4 of Table 1 and applies it to the main controller 60 in response to the output initialization condition. The inverter controller 30 does not perform an output before the output initialization condition occurs, but initializes (or converts) the output control signal to an output corresponding to the output control signal received from the main controller 60 after the output initialization condition occurs. An inverter driving signal is generated and applied to the switching element Q1. In addition, the main controller 60 notifies the normal output through the display unit 50. For example, one green light is displayed.

However, in the step S45, when the output initialization condition is the no container state and the power failure state, the main control unit 60 generates an output control signal when the output initializing condition is changed to the container present state and the energized state after the output initialization condition is generated. After the application to the inverter controller 30, the display unit 50 indicates that the normal output is being performed.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person having ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. It is to be understood that such changes may be made, and such changes will fall within the scope of the claims.

10: rectifier 15: resonance inverter circuit
20: DC power supply unit 30: inverter control unit
40: input unit 50: display unit
60: main control unit 72: current detection unit
74: power failure detection unit 76: resonance voltage detection unit
78: resonance current detection unit

Claims (10)

A rectifying unit receiving commercial power and converting the power into DC power;
A resonant inverter circuit unit configured to receive the DC power and perform output by resonance;
An inverter control unit configured to perform an output of the resonance inverter circuit unit in response to an output control signal, and to output the resonance unit by lowering the output of the resonance inverter circuit unit by a set value when an inverter interrupt occurs;
It is composed of a main control unit for generating the output control signal applied to the inverter control unit,
When the inverter interrupt occurs again within the reference time after the output fall, the inverter controller further lowers the output of the resonance inverter circuit unit by the set value, and does not regenerate the inverter interrupt within the reference time after the output fall. When the output of the resonance inverter circuit unit is increased by the set value, and the output of the resonance inverter circuit unit is lower than the lower limit output, the output of the resonance inverter circuit unit is cut off,
The inverter control unit transmits a signal corresponding to an output falling or an output rising or an output interruption to the main control unit to the main control unit,
The signal corresponding to the output falling or output rising or output blocking includes an error generating code, the main control unit stores the error generating code,
An upper bit of the error generating code means a kind of the inverter interrupt, and a lower bit of the error generating code is output lowered and lower than an initial output corresponding to the output control signal, or output is raised and the output control signal Induction heating cooker, characterized in that the output stage is lower than the initial output corresponding to the output stage or the output rises corresponding to the output control signal. delete delete delete The method of claim 1,
The inverter control unit transmits a signal indicating that normal output is being performed to the main control unit when the output of the resonance inverter circuit unit due to the output rise is equal to the initial output in response to the output control signal. Cooker. The method of claim 1,
The main control unit is characterized by displaying the output falling or output rising or output blocking through the display unit. The method of claim 1,
When the output initialization condition is generated, the inverter control unit initializes the output of the resonance inverter circuit unit to an output corresponding to the output control signal received from the main control unit after the generation of the output initialization condition. . The method of claim 7, wherein
And the output initialization condition includes at least one of an electrostatic state, a vessel free state, and a change state of the output control signal. The method of claim 1,
The signal corresponding to the output falling or output rising or output blocking comprises a PAN signal. delete

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