KR20200100473A - Cooker improving operation stability and operating method thereof - Google Patents

Abstract

Disclosed are a cooking utensil with improved operation stability and an operation method thereof. According to one aspect of the technical idea of the present disclosure, the cooking utensil comprises: a heating unit including a working coil; a DC power generation unit providing a rectified voltage by performing rectification for commercial power provided from the outside through an input alternating current (AC) line; a switching circuit connected to the rectified voltage and performing a switching operation in response to a switch driving signal so that a resonance current is applied to the working coil of the heating unit; and a control circuit performing initial driving of the switching circuit in a soft start section as a cooking operation of the cooking utensil starts and outputting the switch driving signal with an on time set for predetermined heat output in a normal cooking operation after the soft start section ends. The control circuit is characterized in that the on time of the switch driving signal is set smaller than an on time set for the predetermined heat output in the soft start section.

Description

Cooking apparatus with improved operation stability and its operating method TECHNICAL FIELD

The technical idea of the present disclosure relates to a cooking device and a method of operation thereof, and more particularly, to a cooking device and a method of operating the same, which improves operation stability by preventing noise caused by inrush current and preventing damage to circuit elements. .

As a cooking appliance, an electric range is a device that heats an object to be heated placed on a cooking area by driving the heating unit of the cooking area using electricity as an energy source. The electric range operates on the principle of generating a high-frequency magnetic field by flowing a high-frequency current through the working coil of the crater on which the container is placed, and generating an eddy current in the container magnetically coupled with the working coil to heat the container.

The electric range may rectify a commercial power supply to generate a rectified voltage, and drive the heating unit through switching control for the generated rectified voltage. As an example, a switching element (e.g., an inverter) provided in the electric range switches the rectified voltage in response to the switch driving signal, and based on the switching operation, the working coil of the heating unit and the magnetic Eddy current may be generated in the combined container.

At this time, inrush current may be generated in the working coil when the inverter is initially driven as the cooking operation is started or the inverter is stopped as the cooking operation is finished, which increases the noise of the cooking appliance. There is a problem that may cause damage or damage to circuit elements.

The technical idea of the present disclosure is to provide a cooking device and an operating method thereof capable of reducing an inrush current that may be generated in the cooking device, thereby reducing noise and preventing damage to circuit elements.

In order to achieve the above object, a cooking appliance according to an aspect of the technical idea of the present disclosure includes a heating unit including a working coil and a rectification process for commercial power provided from the outside through an input alternating current (AC) line. A DC power generation unit that provides a rectified voltage by performing, and a switching circuit connected to the rectified voltage and performing a switching operation in response to a switch driving signal so that a resonance current is applied to the working coil of the heating unit, and the cooking appliance Performing initial driving of the switching circuit in a soft start section as the cooking operation starts, and outputting a switch driving signal having an on time set for a predetermined heating output in a normal cooking operation after the soft start section is finished. A control circuit is provided, and the control circuit is characterized in that, in the soft start period, an on time of the switch driving signal is set smaller than an on time set for the predetermined heating output.

Meanwhile, a method of operating a cooking appliance according to an aspect of the technical idea of the present disclosure includes the steps of entering a soft start section as the cooking operation of the cooking appliance starts, and an on time of the switch driving signal in the soft start section. Gradually increasing and outputting, and outputting a switch driving signal having an on time set for a predetermined heating output in a normal cooking operation of the cooking appliance, and in the soft start period, a gate of the switching circuit The voltage level applied to the gate electrode of the switching circuit is gradually increased by the switch driving signal provided to the electrode.

According to the cooking appliance and its operating method according to an exemplary embodiment of the present disclosure, when the inverter is initially driven as the cooking operation starts, by applying a soft start section and adjusting the on time of the switch driving signal in the section. , There is an effect of reducing the possibility of noise and damage to circuit elements caused by inrush current.

In addition, according to the cooking appliance and its operating method according to an exemplary embodiment of the present disclosure, when the driving of the inverter is stopped when the cooking operation is finished, the driving of the inverter is performed at a timing when the energy of the LC resonance circuit is relatively small. By stopping, there is an effect of reducing the possibility of damage to the circuit element and noise caused by the inrush current that may be generated at the end of the cooking operation.

1 is a block diagram illustrating a cooking device according to an exemplary embodiment of the present disclosure.
FIG. 2 is a block diagram illustrating an example implementation of the control circuit of FIG. 1.
3 is a diagram illustrating an example of an operation of a cooking device.
4 is a graph showing various examples of adjustment of on time according to an exemplary embodiment of the present invention.
5 is a flowchart illustrating an example of an operation of a cooking appliance that reduces inrush current when an inverter is initially driven.
Fig. 6 is a block diagram showing a cooking device according to another exemplary embodiment of the present disclosure.
7 is a circuit diagram showing an example of implementation of a cooking appliance according to an exemplary embodiment of the present invention.
8 is a diagram illustrating an example of an operation of the cooking appliance of the circuit diagram shown in FIG. 7.
9 is a flowchart illustrating an example of an operation of a cooking appliance for reducing an inrush current when the cooking operation is finished.

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

1 is a block diagram illustrating a cooking device according to an exemplary embodiment of the present disclosure. Referring to FIG. 1, the cooking appliance 100 may include a DC power generation unit 110, a switching circuit 120, a heating unit 130, and a control circuit 140. In addition, according to an exemplary embodiment, the control circuit 140 may include a soft start management module 141, and the soft start management module 141 may initially drive the switching circuit 120 as a cooking operation starts. At this time, various management operations for controlling the switching circuit 120 may be performed. In addition, although not shown in FIG. 1, additional components may be further provided in the cooking device 100 for various other operations that may be performed in the cooking device 100. As an example, an object to be heated ( 101) may be further provided with a device that performs various functions such as a user interface unit and a communication unit.

According to an embodiment, the cooking appliance 100 may be an electric range that includes one or more cooking units (not shown), and heats the object to be heated 101 placed on the cooking area using an electrical principle. The term crater may be defined in various ways, and in embodiments of the present invention, the crater may be defined as including a heating unit 130 disposed corresponding to a position where an object to be heated such as a container is placed. When the cooking appliance 100 includes a plurality of cooking units, some of the cooking units may correspond to induction heating the object to be heated 101 through electromagnetic induction including a working coil, and other parts of the cooking unit are heated wires. Other types of craters, such as a hot plate for generating heat by heating the included metal plate, and a highlight for generating heat by heating a ceramic plate by distributing heat rays, may be used.

The object to be heated 101 may represent an object heated by the heating device 100. The body to be heated 101 may include at least one of containers to be heated such as a pot, a frying pan, a steam pot, a kettle, and a tea pot.

Meanwhile, the cooking appliance 100 according to the exemplary embodiment of the present invention may correspond to various types of appliances other than the electric range. For example, the cooking appliance 100 according to an embodiment of the present invention may be various types of heating devices that generate AC power (eg, AC voltage or AC current) using a switching element to drive a heating unit.

The DC power generator 110 may be implemented in various forms, and may include, for example, a diode bridge or a bridge rectifier. The DC power generator 110 may be referred to as a rectifier, receives commercial power supplied from the outside, and generates and outputs a rectified voltage (or DC link voltage) through a rectification operation therefor. Commercial power may correspond to 110V AC power, 220V AC power, 380V AC power, or any other voltage level with a predetermined frequency (e.g., 60 Hz) depending on the country and/or region of use. have.

The heating unit 130 is provided with an LC resonance circuit including a working coil and a capacitor, and the switching circuit 120 is a high-frequency AC power source to the working coil of the heating unit 130 through a high-frequency switching operation for the generated rectified voltage. For example, a switching operation may be performed so that an alternating current) flows. As an alternating current is applied to the working coil, the working coil makes a current resonance with the container 101 placed on the cooking zone, whereby the container 101 heats up to perform a cooking function.

The switching circuit 120 may include one or more inverters, and the inverter may control its switching operation in response to the switch driving signal Ctrl_SW. As an example, the inverter may include an insulated gate bipolar transistor (IGBT). However, this is only an embodiment, and the inverter may include various types of switching elements such as a Silicon Controlled Rectifier (SCR), an MOS-FET, or an Integrated Gate-Commutated Thyristor (IGCT). In addition, the switching circuit 120 may be driven by a single-ended method as it includes one inverter, or the switching circuit 120 is driven by a half-bridge method or a full bridge method as it includes two or more inverters. It could be. Hereinafter, in describing exemplary embodiments of the present invention, for convenience of description, the switching circuit 120 may be referred to as an inverter or terms thereof may be used interchangeably.

When a cooking operation starts at at least one cooking zone of the cooking appliance 100, when the inverter is initially driven while a large level voltage (eg, a rectified voltage) is applied to a node in the cooking appliance 100, an inrush ) Current flows through the working coil of the heating unit 130, which may cause various problems such as an increase in noise and damage to circuit elements. As an example, when a switch driving signal (Ctrl_SW) is provided to the gate electrode of the inverter and the inverter suddenly switches a voltage of a large level by the switch driving signal (Ctrl_SW), a large inrush current is generated, causing damage to circuit elements. can do.

According to an exemplary embodiment of the present invention, the cooking device 100 may enter the soft start section before performing the normal cooking operation as the cooking operation starts, and the soft start management module 141 is in the soft start section. Various management operations for reducing inrush current can be performed. As an example, the control circuit 140 may include a driving signal generator (not shown) that generates a switch driving signal (Ctrl_SW) provided to the gate electrode of the inverter, and the soft start management module 141 is a soft start period A management operation for adjusting the frequency and/or duty of the switch driving signal Ctrl_SW may be performed. Based on the control of the soft start management module 141, the voltage level of the gate electrode of the inverter to which the switch driving signal (Ctrl_SW) is provided may be gradually increased, and through this, the inrush caused by the inverter suddenly switching the voltage of a large level Current can be reduced or eliminated.

As an example of operation, the control circuit 140 receives start information (Info_S) indicating the start of the cooking operation, and the soft start management module 141 is the soft start corresponding to a predetermined time after the start of the cooking operation. During the period, the frequency and/or duty of the switch driving signal Ctrl_SW may be adjusted. The cooking operation may be started under various conditions such as user selection or reservation cooking, and in the example of FIG. 1, an example in which the start information (Info_S) is provided to the control circuit 140 by the user's selection is illustrated, but the start information (Info_S) May be generated in an arbitrary component in the control circuit 140 and provided to the soft start management module 141.

As an example of operation, the soft start management module 141 may generate control information for adjusting the on time (or duty ratio) of the switch driving signal (Ctrl_SW) in the soft start period, and within the control circuit 140 The driving signal generator that generates the switch driving signal Ctrl_SW in may adjust the on time of the switch driving signal Ctrl_SW based on the control information. For example, in the soft start period, the switch driving signal Ctrl_SW may have a predetermined frequency, and the on time in any one period may be adjusted based on control information from the soft start management module 141. As an example, in order to reduce the inrush current (or to gradually increase the voltage level of the gate electrode of the inverter), the ON time of the switch driving signal (Ctrl_SW) in the soft start period generates a heating output in the actual normal cooking operation. It may have a value smaller than the on time set for this.

According to an exemplary embodiment, the on time of the switch driving signal Ctrl_SW in the soft start period can be varied in various ways within a range in which the inrush current is reduced (or in a range in which the voltage level of the gate electrode of the inverter is gradually increased). Can be adjusted accordingly. As an example, the on time of the switch driving signal Ctrl_SW may be set relatively small at the beginning of the soft start period, and the on time of the switch driving signal Ctrl_SW may gradually increase in the soft start period. Alternatively, the soft start section includes at least two sections, and in one section, the on time of the switch drive signal (Ctrl_SW) may be gradually increased, and in the other section, the on time of the switch drive signal (Ctrl_SW) is constant. It may be maintained.

As an example of operation, in a normal cooking operation, the on time of the switch driving signal Ctrl_SW may be set to a first value, and in the soft start period, the on time of the switch driving signal Ctrl_SW may be set below the first value. have. That is, in the soft start period, the on time of the switch driving signal Ctrl_SW initially has a small value and may be gradually increased to the first value. If, in the normal cooking operation, when the on time of the switch driving signal (Ctrl_SW) has half the period (cycle/2), the on time of the switch driving signal (Ctrl_SW) in the soft start period is half of the period (cycle/2) Can be gradually increased to

In forming various electrodes of the inverter, a predetermined capacitance component may exist in the gate electrode, and the voltage of the gate electrode may be adjusted according to the waveform of a signal (e.g., a switch driving signal (Ctrl_SW)) provided to the gate electrode of the inverter. have. In this case, by adjusting the on time of the switch driving signal Ctrl_SW according to the above-described embodiment, the voltage of the gate electrode of the switch driving signal Ctrl_SW may be linearly increased, through which the working coil and/or Inrush current that may flow to the switching circuit 120 may be suppressed.

FIG. 2 is a block diagram illustrating an example implementation of the control circuit of FIG. 1.

1 and 2, the control circuit 150 includes a driving signal generator 142, a heating output controller 143, a driving start determiner 144, a time information generator 145, and an on-time controller 146. It may include. The soft start management module 141 shown in FIG. 1 may be defined as a configuration including various functions. As an example, the soft start management module 141 is a driving start determiner 144 and a time information generator 145 And an on-time adjuster 146.

The driving signal generator 142 may generate a switch driving signal (Ctrl_SW) for controlling switching of an inverter (eg, IGBT) provided in the switching circuit 120, and control information from the heating output controller 143 ( In accordance with Ctrl_P), a switch driving signal Ctrl_SW having a frequency and an ON time for generating a predetermined heating output may be generated. In addition, when the cooking operation starts based on a user's manipulation or other various control methods, the driving start determiner 144 may determine that the inverter starts to be driven according to the start information Info_S.

According to an exemplary embodiment of the present invention, the on-time controller 146 is based on the information from the driving start determiner 144 and the time information generator 145, the on-time of the switch driving signal (Ctrl_SW) in the soft start period. On-time control information (Ctrl_ON) for adjusting the time can be output. For example, as a predetermined heating output is set for a cooking operation, in a normal cooking operation, the switch driving signal (Ctrl_SW) may have a predetermined on time. In the soft start period, the on time of the switch driving signal (Ctrl_SW) is It can be adjusted to reduce the inrush current regardless of the on time of normal operation.

According to an embodiment, as described above, the on time of the switch driving signal Ctrl_SW in the soft start period may be set smaller than the on time in the normal cooking operation. For example, the on time of the switch driving signal Ctrl_SW at the beginning of the soft start period may have the smallest value, and the on time of the switch driving signal Ctrl_SW may gradually increase during the soft start period. In addition, as an example, the soft start period may include two or more periods, and the on time of the switch driving signal (Ctrl_SW) gradually increases in one period, while the switch driving signal ( Ctrl_SW) may be kept constant.

The soft start period may be fixedly set as a predetermined time. The on-time adjuster 146 starts the on-time adjustment operation in the soft start section based on information from the driving start determiner 144, and based on the time information from the time information generator 145, the above-described The on-time adjustment operation may be performed for a certain period of time. In addition, after the above-described predetermined time has elapsed, the driving signal generator 142 may generate a switch driving signal (Ctrl_SW) for generating a predetermined heating output in a normal cooking operation. As an example, the heating output controller 143 A switch driving signal Ctrl_SW having a frequency and an ON time according to the control information Ctrl_P from) may be generated.

Meanwhile, the components of the present invention shown in FIGS. 1 and 2 may be implemented in various forms. According to an embodiment, the operation of the soft start management module 141 for adjusting the on time of the switch driving signal Ctrl_SW in the soft start period may be implemented in hardware, or a function thereof by a processor executing a program. It could also be implemented in software to achieve this. Alternatively, the soft start management module 141 may be implemented as a combination of hardware and software.

Meanwhile, components of the control circuit 140 shown in FIG. 2 are shown separately for each function to implement an embodiment of the present invention, and the control circuit 140 according to the embodiment of the present invention must be shown in FIG. It need not be limited by the components shown in. For example, the on-time controller 146 may be configured to include components for determining the start and end of the soft start, or the components provided in the soft start management module 141 are switches according to an embodiment of the present invention. It may be classified and defined as various other functions within the range of reducing the inrush current by adjusting the frequency and/or the on time of the driving signal Ctrl_SW.

Hereinafter, a specific example of the operation of the cooking appliance according to embodiments of the present invention will be described.

3 is a diagram illustrating an example of an operation of a cooking device. As an example, a commercial power source having a predetermined frequency is exemplified as an example of power applied to a node of a cooking appliance, and a voltage level applied to a gate electrode of a switching circuit (eg, an inverter) provided in the cooking appliance is It is shown in Figure 3.

Referring to Figure 3 (a), a commercial power having a predetermined frequency is provided to the inside of the cooking appliance (for example, a DC power generator), and the hatched portion in each cycle of the commercial power is the switch driving signal (Ctrl_SW). It can be proportional to the amount of heating output in each cycle of the commercial power supply depending on the on time. As shown in (a) of FIG. 3, when the inverter is initially driven as the cooking operation starts, the on time of the switch driving signal Ctrl_SW has a small value at the beginning of the soft start period, and thereafter, the switch As the on time of the driving signal Ctrl_SW gradually increases, the amount of heating output may increase in the next cycle of the commercial power supply. As an example of operation, when the on time and the off time are set to 1:1 during normal cooking operation, the on time may have a value of 1/2 of the period of the switch driving signal (Ctrl_SW), and the switch is driven in the soft start section. The on time of the signal Ctrl_SW gradually increases and may increase to a value of 1/2 of the period of the switch driving signal Ctrl_SW.

Meanwhile, referring to the graph of FIG. 3B, the horizontal axis represents time and the vertical axis represents the voltage of the gate electrode of the inverter (eg, the gate voltage Vg). Also, along the time axis, a time point m may represent the start of a soft start section and a time point n may represent the end of the soft start section.

When the on time of the switch driving signal Ctrl_SW is kept small or gradually increases in the soft start period, the level of the gate voltage Vg of the gate electrode having a predetermined capacitance component of the inverter may gradually increase. In addition, when the level of the gate voltage Vg during normal operation is defined as the normal voltage Vs, the level of the gate voltage Vg may gradually increase to the normal voltage Vs in the soft start period. 3B shows an example in which the level of the gate voltage Vg increases linearly, but the embodiment of the present invention need not be limited thereto. For example, the level of the gate voltage Vg can be variously changed by adjusting the frequency and/or the on time of the switch driving signal Ctrl_SW, and as an example, the level of the gate voltage Vg increases in the form of a curve. Alternatively, the level of the gate voltage Vg may have various types of waveforms within a range not to increase rapidly to the normal voltage Vs.

In addition, in the example of FIG. 3(b), the soft start period is ended when the level of the gate voltage Vg reaches the normal voltage Vs, and in the embodiment of the present invention, the gate voltage Vg The cooking device may be implemented in such a way that the soft start section ends based on detecting the level of. That is, in the present invention, the soft start section may be set to a certain time, or the start and end times of the soft start section may be determined by various other methods.

In addition, in the example of FIG. 3(b), it is shown that the soft start period ends when the level of the gate voltage Vg reaches the normal voltage Vs, but the embodiment of the present invention needs to be limited thereto. none. As an example, the soft start period may be defined as further including a time after the level of the gate voltage Vg reaches the normal voltage Vs. For example, in the example of FIG. 3B, the soft start section may be defined as a section between the time point m and the time point k.

4 is a graph showing various examples of adjustment of on time according to an exemplary embodiment of the present invention.

Referring to FIG. 4A, when the inverter is initially driven according to the start of the cooking operation, the soft start period is performed according to exemplary embodiments of the present invention, and the on time of the switch driving signal during the soft start period is Can be adjusted. As an example, in (a) of FIG. 4, regardless of the on time for the heating output set for the actual cooking operation, the on time of the switch driving signal is set to the smallest at the beginning of the soft start section, and the switch is driven during the soft start section. An example in which the on time of the signal is gradually increased is shown. In addition, when the soft start section ends, the on time of the switch drive signal has a value for a predetermined heating output, and as an example implementation, the maximum value of the on time in the soft start section corresponds to the on time in the normal cooking operation. Can be increased to

Meanwhile, in FIG. 4B, an example in which the soft start section includes at least two sections is shown, and as an example, the soft start section may include a first section (A) and a second section (B). In addition, the on time of the switch driving signal in the first period A and the second period B may be adjusted differently. In addition, as an example, the on time of the switch driving signal in the second period B may have a value equal to or smaller than the on time in the normal cooking operation.

As an example, the on time of the switch driving signal in the first period A may gradually increase, while the on time of the switch driving signal in the second period B may be maintained at a constant value. The voltage level of the gate electrode of the switching circuit may be gradually increased based on the on-time adjustment as shown in FIG. 4B, and accordingly, the inrush current may be reduced or eliminated during initial driving of the cooking operation.

Meanwhile, in FIG. 4B, an example in which the on time of the switch driving signal is gradually increased and then maintained at a constant value is shown, but the embodiment of the present invention need not be limited thereto. As an example of operation, the on time of the switch driving signal may be maintained at a constant small value at the beginning of the soft start period, and then the on time may be adjusted to gradually increase thereafter. In addition, although two sections A and B are illustrated in (b) of FIG. 4, the soft start section may include a larger number of sections, and the ON time of the switch driving signal in each section is various types. May be adjusted to

Meanwhile, in the above-described embodiments, an example of adjusting the on time of the switch driving signal in order to reduce or eliminate the inrush current that may occur during the initial driving of the cooking operation has been described, but by adjusting the frequency of the switch driving signal, the inrush current May be reduced or eliminated. As an example, at the beginning of the soft start period, the frequency of the switch driving signal is set higher than the resonance frequency to reduce the heating output, and during the soft start period, the frequency of the switch driving signal may be gradually decreased so that the frequency is close to the resonance frequency. There will be.

5 is a flowchart illustrating an example of an operation of a cooking appliance that reduces inrush current when an inverter is initially driven.

Referring to FIG. 5, the cooking appliance may start a cooking operation by an operation such as a user's selection, and accordingly, a switching circuit (eg, an inverter) in the cooking appliance may be initially driven (S11). As an example, the control circuit in the cooking appliance may receive start information indicating that the cooking operation has started, and through this, the timing at which the inverter is initially driven may be determined. The control circuit may enter the soft start section for a predetermined time before performing the heating operation according to the heating output set in the normal cooking operation, and perform a control operation to reduce or remove the inrush current in the soft start section. . As an example, irrespective of the setting for the heating output in the normal cooking operation, the on time of the switch driving signal in the soft start section may be set to be small (S12).

In addition, the control circuit gradually increases the on time of the switch driving signal in the soft start period, and the on time of the switch driving signal can be increased within a predetermined reference value (for example, the on time set in a normal cooking operation). Yes (S13).

Thereafter, it is determined whether the soft start period has ended (S14), and when the soft start period has not ended, an output of a switch driving signal having a relatively small ON time compared to the normal operation may be maintained. On the other hand, when it is determined that the soft start section has ended, a switch driving signal having an on time corresponding to heating output information set for a normal cooking operation may be generated (S15).

Fig. 6 is a block diagram showing a cooking device according to another exemplary embodiment. In FIG. 6, an example of reducing the possibility of damage to circuit elements and noise caused by the rush current in the process of terminating the cooking operation, together with the application of the soft start function in the above-described embodiment, is described. In describing the configuration and operation example of the cooking appliance 200 illustrated in FIG. 6, detailed descriptions of the same components described in the above-described embodiments are omitted.

Referring to FIG. 6, the cooking appliance 200 may include a DC power generator 210, a switching circuit (or inverter 220), a heating unit 230 and a control circuit 240, and also cook A voltage detector 250 for detecting a voltage level applied to a node in the device 200 may be further included. In addition, the control circuit 240 may include a soft start management module 241 and a zero voltage stop control module 242.

When the cooking operation of the cooking appliance 200 is completed, the driving of the inverter 220 may be stopped. In this case, when the driving of the inverter 220 is stopped while a large rectified voltage is applied to the inverter 220 In this case, the energy stored in the LC resonant circuit may generate an inrush current in the working coil, which may increase noise and cause damage to circuit elements. In order to reduce or eliminate noise and circuit damage due to inrush current in a situation in which the cooking operation is terminated, the voltage detector 250 detects a voltage of a node in the cooking device 200 and calculates the detection result (Det_V). It may be provided to the control circuit 240, and the zero voltage stop control module 242 may perform a control operation for reducing or removing the inrush current when the cooking operation is terminated. As an example, FIG. 6 shows an example in which the voltage detector 250 is connected to the output terminal of the DC power generator 210 to detect the level of the rectified voltage. However, the embodiment of the present invention does not need to be limited thereto. The level of the voltage applied to other nodes within 200 may be detected.

The soft start management module 241 of the control circuit 240 responds to receiving the start information (Info_S) indicating the start of the cooking operation according to the above-described embodiments, the frequency and the frequency of the switch driving signal Ctrl_SW in the soft start section. /Or the duty may be adjusted, and as an example, the duty of the switch driving signal Ctrl_SW in the soft start period may be set smaller than the duty of the switch driving signal Ctrl_SW in normal operation.

Meanwhile, the zero voltage stop control module 242 of the control circuit 240 minimizes the voltage level of one node in the cooking device 200 according to the end information (Info_F) indicating that the cooking operation of the cooking device 200 is finished. The control operation may be performed so that the driving of the inverter 220 is stopped at a point in time (for example, a point in time when the voltage level becomes 0). As an example, based on the control of the zero voltage stop control module 242, the control circuit 240 is in synchronization with the timing at which the level of the rectified voltage becomes 0 (or in synchronization with the zero voltage timing of the rectified voltage) The switch driving signal Ctrl_SW may be output so that the 220 is turned off.

An example of an operation of stopping driving of the inverter according to the embodiment illustrated in FIG. 6 will be described as follows. 7 is a circuit diagram showing an example of implementation of a cooking appliance according to an exemplary embodiment of the present invention.

Referring to FIG. 7, the cooking appliance 300 includes a DC power generation unit 310, a switching circuit (or inverter 320), a heating unit 330, a control circuit 340, and a voltage detector 350. can do. In FIG. 7, a single-ended method in which the switching circuit 320 includes one Insulated Gate Bipolar Transistor (IGBT) as an inverter is illustrated, but as described above, in the embodiment of the present invention, the switching circuit 320 includes two or more inverters. It could also be applied in other ways, including those. The control circuit 340 may include a soft start management module 341 and a zero voltage stop control module 342, and receives start information (Info_S) indicating the start of the cooking operation and end information (Info_F) indicating the end of the cooking operation. can do. In addition, the voltage detector 350 may be connected to a node a in the cooking appliance 300, for example, an output terminal of the DC power generation unit 310 to output a detection result Dev_V of detecting the level of the rectified voltage. .

Meanwhile, in FIG. 7, an example in which start information (Info_S) and end information (Info_F) are provided to the control circuit 340 is illustrated, but as described in the above-described embodiment, the start information (Info_S) and the end information (Info_F) are It may also be created within the control circuit 340.

An operation example of the cooking appliance of the circuit diagram shown in FIG. 7 will be described with reference to FIG. 8.

The commercial power supply has a sine wave form having a predetermined frequency, and the rectified voltage from the DC power generator 310 may have a waveform as shown in FIG. 8. That is, the rectified voltage may have a positive (+) value and may have a waveform whose level fluctuates according to a predetermined period.

The termination of the cooking operation may be selected based on various factors. For example, the cooking operation may be terminated according to a cooking stop command or the cooking operation may be terminated as a time of the cooking operation set to a predetermined time elapses. The end information (Info_F) may include information indicating whether the cooking operation is generally stopped or stopped in an emergency situation, and the end information (Info_F) may be provided to the control circuit 340 at an arbitrary point in time. have.

As shown in (a) of FIG. 8, the cooking operation of the cooking device 300 may generally be terminated in a state where the level of the rectified voltage is high, and the working coil may be caused by relatively large energy stored in the LC resonance circuit. Inrush current may flow, which increases noise and may also cause damage to circuit elements. The zero voltage stop control module 342 may adjust the driving stop timing (eg, turn-off timing) of the inverter 320 based on the detection result (Det_V) indicating the level of the rectified voltage together with the termination information (Info_F). As an example, a control operation may be performed such that the inverter is turned off in synchronization with a timing when the level of the rectified voltage (or commercial power) becomes 0. As an example of operation, as the end information (Info_F) indicates a general stop of the cooking operation, a time point at which the level of the rectified voltage becomes 0 is determined based on the detection result (Det_V), and the zero voltage stop control module 342 Control information for controlling the inverter to be turned off in synchronization with a time point of 0 may be provided to a driving signal generator (not shown) in the control circuit 340.

On the other hand, as shown in (b) of FIG. 8, the cooking device 300 may cause a situation in which the cooking operation is urgently stopped due to various causes, and as an example, the level of the resonance voltage or the resonance current is predetermined. In order to prevent damage to the circuit elements in the cooking appliance 300 as the threshold value is exceeded, the driving of the inverter 320 may be stopped. When the end information Info_F indicates an emergency stop situation, the control circuit 340 may immediately stop driving the inverter 320 regardless of the level of the rectified voltage.

For example, during an emergency stop of the cooking appliance 300, circuit elements therein may be damaged. In particular, when the emergency stop timing occurs when the level of the rectified voltage is rising, the level of the rectified voltage is 0. The level of the rectified voltage may increase further in the process of waiting for the timing to become, and in this case, the possibility of damage to the circuit element increases. That is, the cooking appliance 300 according to an exemplary embodiment of the present invention stops the inverter 320 in synchronization with the timing when the level of the rectified voltage becomes 0 based on the stopping method of the cooking operation, or the level of the rectified voltage Regardless of this, the operation of stopping the inverter 320 may be selectively performed.

9 is a flowchart illustrating an example of an operation of a cooking appliance for reducing an inrush current when the cooking operation is finished.

Referring to FIG. 9, the cooking appliance performs a normal cooking operation, and a control circuit in the cooking appliance may receive or internally generate a driving stop request indicating that the cooking operation is terminated (S21). As in the above-described embodiment, the termination of the cooking operation may occur due to various causes, and due to reasons such as the completion of a normal cooking operation or an emergency stop of the cooking appliance to prevent damage to circuit elements. It can be terminated.

Based on the control of the control circuit, it may be determined whether the end of the cooking operation corresponds to a general stop (S22). If the cooking operation is urgently terminated rather than a normal stop, the driving of the inverter may be immediately stopped regardless of the level of the voltage (eg, rectified voltage) of one node in the cooking appliance (S23).

On the other hand, when it is determined that the end of the cooking operation corresponds to a normal stop, the inverter is rectified so that the driving of the inverter can be stopped at the timing when the energy of the LC resonance circuit is reduced (or when the level of the resonance current is decreased). The timing at which the voltage level becomes 0 may be detected, and this may be described as an operation of detecting the zero voltage of the rectified voltage (S24). As a result of detecting the level of the rectified voltage, it is determined whether the voltage corresponds to the zero voltage (S25), and driving of the inverter may be stopped in synchronization with the timing when the level of the rectified voltage corresponds to the zero voltage (S26).

As described above, exemplary embodiments have been disclosed in the drawings and specifications. In the present specification, embodiments have been described using specific terms, but these are only used for the purpose of describing the technical idea of the present disclosure, and are not used to limit the meaning or the scope of the present disclosure described in the claims. . Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of the present disclosure should be determined by the technical spirit of the appended claims.

Claims (11)

In the cooking appliance,
A heating unit including a working coil;
A direct current power generation unit that provides a rectified voltage by performing a rectification process on commercial power provided from the outside through an input alternating current (AC) line;
A switching circuit connected to the rectified voltage and performing a switching operation in response to a switch driving signal such that a resonance current is applied to the working coil of the heating unit; And
As the cooking operation of the cooking appliance starts, the switching circuit is initially driven in a soft start section, and after the soft start section is finished, a switch having an on time set for a predetermined heating output in a normal cooking operation is driven. It has a control circuit for outputting a signal,
Wherein the control circuit sets an on time of the switch driving signal to be smaller than an on time set for the predetermined heating output in the soft start period. The method of claim 1,
The cooking appliance, characterized in that the soft start section is performed for a preset time as the cooking operation of the cooking appliance starts. The method of claim 1,
The cooking appliance, wherein the on time of the switch driving signal is set to the smallest at the beginning of the soft start period, and the on time of the switch driving signal is gradually increased in the soft start period. The method of claim 1,
The soft start section has a first section and a second section, the on time of the switch driving signal is gradually increased in any one of the first section and the second section, and the switch driving signal is in the other section. Cooking appliance, characterized in that the on time of the constant is maintained. The method of claim 1,
The control circuit includes a soft start management module that generates control information for adjusting an on time of the switch driving signal in the soft start period, and a driving signal generator that generates the switch driving signal based on the control information. and,
The soft start management module,
A driving start determiner for determining a driving start of the switching circuit based on start information indicating the start of a cooking operation;
A time information generator for generating time information indicating the soft start period; And
And an on-time adjuster that generates the control information during the soft start period. The method of claim 1,
The switch driving signal whose on time is adjusted in the soft start period is provided to the gate electrode of the switching circuit,
The cooking appliance, characterized in that the level of the voltage of the gate electrode linearly increases according to the switch driving signal. The method of claim 1,
Further comprising a voltage detector that detects the level of the rectified voltage and outputs a voltage detection result,
Wherein the control circuit performs a control operation such that the switching circuit is turned off at a timing when the level of the rectified voltage becomes 0 according to end information indicating the end of the cooking operation. The method of claim 7, wherein the control circuit,
A zero voltage stop control module for generating control information indicating a zero voltage timing of the rectified voltage after receiving end information indicating the end of the cooking operation,
And outputting the switch driving signal for turning off the switching circuit in synchronization with a timing at which the level of the rectified voltage becomes 0 based on the control information. In the method of operating a cooking appliance, the cooking appliance includes a switching circuit for performing a switching operation in response to a switching driving signal so that a resonance current is applied to the working coil,
Entering a soft start section as the cooking operation of the cooking appliance starts;
Gradually increasing and outputting an on time of the switch driving signal in the soft start period; And
And outputting a switch driving signal having an on time set for a predetermined heating output in a normal cooking operation of the cooking appliance,
In the soft start period, the voltage level applied to the gate electrode of the switching circuit is gradually increased by the switch driving signal provided to the gate electrode of the switching circuit. The method of claim 9,
The on time set for a predetermined heating output in a normal cooking operation of the cooking appliance has a first value,
The operation of the cooking appliance, wherein the on time of the switch driving signal has the smallest value at the beginning of the soft start period, and the on time of the switch driving signal is gradually increased to the first value during the soft start period Way. The method of claim 9,
And entering the normal cooking operation section after the voltage level of the gate electrode of the switching circuit exceeds a predetermined reference level.

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