KR20200007138A - Induction heater and control method of the induction heater - Google Patents

Abstract

The present disclosure relates to an induction heating device. According to an embodiment of the present disclosure, the induction heating device comprises a rectification part for rectifying an applied alternating current voltage to output a pulse current voltage, a smoothing part for generating a direct current voltage by smoothing the pulse current voltage, an induction heating part connected to an output terminal of the smoothing part and comprising an induction heating coil and a resonance condenser, an inverter part connected to an output terminal of the induction heating part and generating a high frequency resonance voltage in the induction heating part through repeated switching operation, and a control part for generating a switching control signal for controlling a switching operation of the inverter part through a pulse width modulation method. The switching control signal corresponding to one period of the pulse current voltage comprises a first section in which a pulse width decreases and a second section in which a pulse width increases, following the first section. Therefore, the present invention provides the induction heating device which is economical and advantageous for miniaturization.

Description

Induction heating device and induction heating device control method {INDUCTION HEATER AND CONTROL METHOD OF THE INDUCTION HEATER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating apparatus and a control method thereof, and more particularly, to an induction heating apparatus which is economical and advantageous in miniaturization.

Induction heating apparatus is a device that is applied to a cooking utensil such as an electric rice cooker or an electric oven and can be easily encountered in daily life. In the induction heating apparatus, when a commercial AC power is supplied, the commercial AC power is rectified and smoothed to be converted into a DC power source, and the converted DC power is applied to the induction heating coil by a high speed switching operation of the inverter. When a high frequency current flows through the induction heating coil, strong heat is generated in the cooking vessel in proximity to or in contact with the induction heating coil, whereby the food contained in the cooking vessel is cooked.

In the induction heating apparatus according to the related art, a switching control signal having a uniform pulse width is applied to the gate terminal of the inverter unit to control the high speed switching of the inverter unit. At this time, for example, when an AC voltage having a characteristic of 60 Hz is applied, the resonance current flowing in the induction heating coil and the inverter part has the maximum value at the highest point of the rectified 120 Hz characteristic of the pulsating voltage.

When the maximum value of the resonance current is large, noise induced to the outside may be severely generated. The induction heating apparatus may include a filter unit for blocking the noise. The greater the degree of noise, the greater the capacity of the filter unit is required. In this case, manufacturing costs may rise, making it non-economical and difficult to miniaturize the product.

One object of the present disclosure is to provide an induction heating apparatus which is economical and advantageous in miniaturization, and a control method thereof.

One object of the present disclosure is to provide an induction heating apparatus and a method of controlling the same, which can reduce the maximum value of the resonant current while controlling the pulse width of the switching control signal applied to the inverter unit, thereby eliminating a reduction in the amount of power.

An object of the present disclosure is to provide an induction heating device and a control method thereof that can comply with the EMI (Electro Magnetic Interference) standard of the product while reducing the capacity of the filter included therein.

Induction heating apparatus according to an embodiment of the present disclosure is rectified AC voltage applied to the rectifier for outputting a pulse current voltage, smoothing unit for generating a DC voltage by smoothing the pulse voltage, connected to the output terminal of the smoothing portion and the induction heating coil and An induction heating unit including a resonant capacitor, an inverter unit connected to an output terminal of the induction heating unit, and an inverter unit for generating a high frequency resonance voltage in the induction heating unit through a repetitive switching operation, and an inverter unit through a pulse width modulation method. And a control unit configured to generate a switching control signal for controlling the switching operation, wherein the switching control signal corresponding to one period of the pulse voltage includes a first section in which the pulse width decreases and a first section in which the pulse width increases. It includes two sections.

According to an embodiment, the switching control signal corresponding to one period of the pulse voltage may have a pulse having the smallest width at the center thereof.

According to an embodiment, the width of each of the pulses included in the first section may gradually decrease from the zero-crossing point of the AC voltage toward the center of one cycle of the pulse voltage.

According to an embodiment, the width of each of the pulses included in the second section may gradually increase from the center of one period of the pulse voltage to the zero-crossing point of the AC voltage.

According to an embodiment, the width of each of the pulses included in the first section may decrease by 0.1 μm, and the width of each of the pulses included in the second section may increase by 0.1 μm.

According to an embodiment of the present disclosure, the induction heating apparatus may further include a detector configured to detect zero-crossing point information of the AC voltage and provide the detected zero-crossing point information to the controller.

According to one embodiment, the first section and the second section may be symmetrical with respect to the center of the switching control signal corresponding to one period of the pulse voltage.

According to an embodiment, the first section includes a first-second section and a first-second section including pulses having a width smaller than the first-first section but smaller than the first-first section. The second period may include a second-2 period including pulses that follow the 2-1 period and the 2-1 period and have a width greater than that of the 2-1 period.

According to an embodiment, the widths of the pulses are uniform in each of the first-first section and the second-second section, and the widths of the pulses included in the first-second section are gradually reduced to the second-first section. The width of the pulses involved may increase gradually.

According to an embodiment, the widths of the pulses may be uniform in each of the first-first section, the first-second section, the second-first section, and the second-second section.

According to an embodiment, the first-first period and the second-second period are symmetrical with respect to the center of the switching control signal corresponding to one period of the pulse voltage, and the first-second period and the first-second period. Sections 2-1 may be symmetrical with respect to the center of the switching control signal corresponding to one period of the pulse voltage.

According to one embodiment, the induction heating unit and the inverter unit may have a series connection structure.

According to an embodiment of the present disclosure, the induction heating apparatus may further include a filter unit for blocking noise generated by the high frequency resonance current flowing through the induction heating unit and the inverter unit by the high frequency resonance voltage.

According to an embodiment, the induction heating unit and the smoothing capacitor may have a parallel connection structure when the inverter unit is turned on according to the switching control signal.

According to an embodiment, the induction heating coil and the resonance capacitor may have a structure in which the induction heating unit is connected in parallel.

The induction heating apparatus according to the present disclosure may vary the pulse width of the switching control signal applied to the gate terminal of the inverter unit, thereby reducing the maximum value of the resonance current flowing in the inverter unit while eliminating the reduction of the amount of power. Accordingly, it is possible to reduce the capacity of the filter included therein, and to provide an induction heating apparatus that is economical and advantageous in miniaturization.

1 is a block diagram showing the configuration of an induction heating apparatus according to an embodiment of the present disclosure.
2 illustrates a circuit configuration of an induction heating apparatus corresponding to the block diagram of FIG. 1.
3A illustrates the resonance voltage measured in the inverter unit when a switching control signal having a uniform pulse width is applied.
FIG. 3B illustrates a resonance current corresponding to the resonance voltage of FIG. 3A.
4A illustrates a resonance voltage measured in an inverter unit when a switching control signal having a variable pulse width is applied according to an exemplary embodiment of the present disclosure.
4B illustrates a resonance current corresponding to the resonance voltage of FIG. 4A.

It is an object of the present disclosure to provide an induction heating apparatus and a control method of an induction heating apparatus capable of reducing a maximum value of a resonance voltage or a resonance current while excluding a decrease in the amount of power. Accordingly, the induction heating apparatus according to the present disclosure may have characteristics that are economical and advantageous for miniaturization.

1 is a block diagram showing the configuration of an induction heating apparatus according to an embodiment of the present disclosure. 2 illustrates a circuit configuration of an induction heating apparatus corresponding to the block diagram of FIG. 1.

1 and 2, the induction heating apparatus according to the present embodiment includes a filter unit 10, a rectifying unit 20, a detection unit 30, a smoothing unit 40, an induction heating unit 50, and an inverter unit 60. ) And the controller 70.

Induction heating devices are generally supplied with an alternating voltage V _in (although described as 'voltage', but this substrate may be replaced by 'current').

In the induction heating apparatus, the filter unit 10 may be disposed at an input terminal of the input AC voltage V _in . The filter unit 10 may serve to remove noise. For example, the filter unit 10 may include a low pass filter, a high pass filter, and a band according to characteristics of a frequency band passing or blocking. It can be classified as a pass (or cut off) filter. As illustrated in FIG. 2, the filter unit 10 may include capacitors C ₁ and C ₂ and inductors L ₁ and L ₂ . However, the configuration and structure of the filter unit 10 is not limited to that disclosed in FIG. 2, and may be variously changed within the scope of the present invention.

In designing the filter portion 10, the capacities of the components of the filter portion 10 (e.g., C ₁ , C ₂ , L ₁ , L ₂ ) may be determined according to the amount of noise induced from the induction heating apparatus. Can be. For example, in order to satisfy the EMI (Electro Magnetic Interference) specification of a product (including an induction heating device), the larger the noise level, the more the filter unit 10 components (for example, C ₁ , C ₂ , L ₁ , L ₂ ) must be large. When the capacity of the filter unit 10 components (eg, C ₁ , C ₂ , L ₁ , L ₂ ) is large, this may increase the manufacturing cost of the product and make it difficult to miniaturize the product. In particular, in the induction heating apparatus according to the present invention, when the maximum value of the resonant current (or resonant voltage) flowing in the induction heating unit 50 (or the inverter unit 60) during the heating mode operation as described later, a large capacity The filter unit 10 of may be required. The present invention can reduce the capacity of the filter unit 10 by reducing the maximum value of the resonant current (or resonant voltage) flowing in the induction heating unit 50 or the inverter unit 60 while excluding a decrease in the amount of power. It is an object to provide an induction heating device. Details thereof will be described later.

Rectifying section 20 outputs a ripple voltage by rectifying the AC voltage (V _in), receiving force receiving an AC voltage (V _in), input. For example, the rectifier 20 receives a commercial AC voltage V _in of 220V. The rectifier 20 may rectify this to output a pulse voltage. To this end, the rectifying unit 20 may include a bridge-diode (BD).

The detector 30 is connected in parallel to the input terminal of the rectifier 20 (or the input terminal of the filter unit 10), and has a zero crossing point at an AC voltage V _in applied to the induction heating apparatus. ZC) can be detected. That is, when a commercial AC voltage V _{in of a} sine waveform (or cosine waveform) is applied to the induction heating apparatus, the detector 30 may detect zero-crossing points ZC in the waveform. have. Meanwhile, the detector 30 may transmit the detected zero-crossing point information to the controller 70 for the purpose of generating a switching control signal, as will be described later. However, according to another embodiment, the detector 30 may be omitted in the induction heating apparatus, and in this case, the controller 70 may detect zero crossing points (ZCs) at the AC voltage V _in . Can be.

The smoothing unit 40 is connected to the output terminal of the rectifying unit 20, and smoothes the pulsed voltage output from the rectifying unit 20 to generate a DC voltage. For this purpose, referring to FIG. 2, the smoothing unit 40 includes an inductor L ₃ connected to the output terminal of the rectifying unit 20, and a smoothing capacitor connected between one end of the inductor L ₃ and ground. C ₃ ). However, the configuration and connection structure of the smoothing part 40 is not limited to that disclosed in FIG. 2, and may be variously changed within the scope of the present invention. The DC voltage generated by the smoothing part 40 may be provided at an input terminal of the induction heating part 50, and may also be provided to other components of the induction heating device according to the present embodiment. For example, the DC voltage generated by the smoother 40 may be provided to the detector 30, the controller 70, or the like.

On the other hand, in view of the purpose, the rectifying unit 20 and the smoothing unit 40 may be referred to as a smoothing circuit. In addition, the smoothing part 40 composed of the inductor L ₃ and the smoothing capacitor C ₃ may serve as a filter. As a non-limiting example, referring to the disclosure of FIG. 2, the smoothing portion 40 can serve as a low pass filter.

Induction heating unit 50 includes an induction heating coil (L ₄ ) and a resonant capacitor (C ₄ ). Referring to FIG. 2, one end of the induction heating unit 50 may be connected to a node between the inductor L ₃ and the smoothing capacitor C ₃ , and the other end thereof may be connected to one end of the inverter unit 60. In addition, in the induction heating unit 50, the induction heating coil L ₄ and the resonant capacitor C ₄ may be connected in parallel with each other. However, the configuration and connection structure of the induction heating unit 50 is not limited to that disclosed in FIG. 2, and may be variously changed within the scope of the present invention.

Meanwhile, the induction heating coil L ₄ , the resonant capacitor C ₄ , and the resistance component R (not shown) of the induction heating unit 50 may be caused by the resistance of the conducting wire itself or the counter electromotive force generated by the coil. Resistors, etc.) form an RLC resonant circuit, and the RLC resonant circuit is oscillated by a high frequency resonant voltage that may be generated by the switching operation of the inverter unit 60, thereby causing an induction heating phenomenon.

The inverter unit 60 may be connected between the output terminal of the induction heating unit 50 and the ground. In the present embodiment, the inverter unit 60 may be a one-seat voltage resonant inverter having one switch element. The inverter unit 60 may be represented by a single switch element, as shown in FIG. 2. Here, the inverter unit 60 may be, for example, an insulated gate bipolar transistor (IGBT). However, the present invention is not limited thereto, and the inverter unit 60 may be one of BJT, FET, and GTO. In the induction heating apparatus, the DC voltage of the smoother 40 may be converted into a high frequency resonance voltage through on / off control of the inverter unit 60.

Referring to FIG. 2, the induction heating unit 50 has a parallel connection structure with the smoothing capacitor C ₃ when the switch of the inverter unit 60 is turned on (ie, shorted). Can be achieved. The inverter unit 60 may receive a switching control signal from the control unit 70 as described later, and may switch the DC voltage rectified and output from the rectifying unit 20 and the smoothing unit 40 at high speed, thereby inducing it. The high frequency resonant voltage may be applied to the heating unit 50 (that is, the induction heating coil L ₄ ). As a result, a high frequency magnetic field for induction heating can be generated.

The controller 70 may control the on / off of the inverter unit 60 through a pulse width modulation (PWM) scheme. To this end, the controller 70 may generate a switching control signal. For example, the controller 70 may generate a switching control signal having a pulse waveform as shown in the third graph of FIG. 3A or the third graph of FIG. 4A. The switching control signal generated by the controller 70 has a predetermined duration T ₂ , and a plurality of pulses (ie, a voltage control waveform) may be generated during the duration T ₂ . The plurality of pulses may be applied to the gate terminal of the inverter unit 60 so that the inverter unit 60 may be turned on / off at a high speed, and thus a high frequency oscillation voltage may be applied to the induction heating unit 50.

The controller 70 may generate a switching control signal at a specific cycle. For example, for the purpose of providing a warming function of an electronic device such as a rice cooker, the controller 70 may generate a switching control signal every 10 minutes. As the switching control signal is periodically generated, the mode of the induction heating apparatus may be divided into a standby mode in which the switching control signal is not generated and a heating mode in which the switching control signal is generated. For example, when the warm function is activated, this standby mode and heating mode may be repeated.

Figure 3 shows the general correlation of voltage, current and switching control signals in the standby mode and heating mode of the induction heating apparatus. 3A illustrates the voltage V _ce measured at the collector and emitter terminals of the inverter unit 60 when a switching control signal having a uniform pulse width is applied according to the related art. 3B shows a waveform of a current I _ce corresponding to the voltage V _ce .

Referring to FIG. 3A, a commercial AC voltage V _in is supplied to an induction heating apparatus. As described above, the commercial AC voltage V _in may be converted into a DC voltage through the rectifying unit 20 and the smoothing unit 40 (that is, the smoothing circuit). The voltage V _ce of the inverter unit 60 is kept constant (ie, V _ce1 ) during the standby mode time T ₁ in which the switching control signal is not generated by the controller 70. That is, in the standby mode, the inverter unit 60 is turned off to operate as an open circuit, and the collector of the inverter unit 60 (i.e., the output end of the induction heating unit 50) and the emitter terminal (i.e., ground). The voltage V _ce1 between) remains constant. On the other hand, in the standby mode, as the inverter unit 60 operates in an open circuit, no current is applied to the induction heating unit 50 (in other words, I _ce becomes zero).

When the standby mode time T ₁ ends, the controller 70 may generate a switching control signal and provide the switching control signal to the gate terminal of the inverter unit 60. The time point at which the controller 70 generates the switching control signal may be synchronized with the zero-crossing point ZC of the commercial AC voltage V _in that is input. That is, referring to FIGS. 3A and 4A, the first pulse of the switching control signal generated by the controller 70 is one of zero-crossing points (eg, ZC ₁ to ZC ₅ ) of the commercial AC voltage V _in . It can be seen that it is synchronized with one (ZC ₂ ). For such synchronization, the controller 70 may obtain zero-crossing point ZC information of the input AC voltage V _in from the detector 30. Meanwhile, according to another exemplary embodiment, the detector 30 may be omitted. In this case, the controller 70 may be directly connected to an input terminal of the rectifier 20 to obtain zero-crossing point ZC information of the input voltage V _in . Can be.

The third graph of FIG. 3A shows the pulse waveform of the switching control signal corresponding to the 'one period' of the pulsed voltage (generated through the rectification of the input AC voltage V _in ). As the inverter part 60 is turned on and off at high speed by the switching control signal, the resonance voltage V _ce oscillates as shown in the second graph of FIG. 3A (after the zero-crossing point ZC ₂ ). In this case, the maximum value V _ce2 of the oscillation voltage may be observed at the center of one period of the pulse voltage.

Referring to FIG. 3B, the waveform of the switching control signal corresponding to one period of the pulse voltage and the current I _ce flowing through the inverter unit 60 (or induction heating unit 50) (or induction heating unit 50). The current flowing in the wave form is shown. The one periodic current I _ce waveform of FIG. 3B corresponds to the one periodic resonance voltage V _ce waveform that oscillates when the switching control signal is applied in FIG. 3A.

According to the prior art, the control unit 70 generates a switching control signal having a uniform pulse width. That is, referring to FIG. 3B, the widths of the pulses p ₁ ,?, P _c , and? P _n are all uniform in the switching control signal period α corresponding to one period of the pulse voltage. However, although FIG. 3B illustrates that 13 pulses exist in the switching control signal section α corresponding to one period of the pulse voltage, this is merely for convenience of description and should not be understood as a limitation. Therefore, it is apparent that any number of pulses may be included in the switching control signal section α corresponding to one period of the pulse voltage.

3A and 3B, when the width of each of the pulses p ₁ ,?, P _c ,?, P _n of the switching control signal applied to the inverter unit 60 during one period of the pulse voltage is constant, The maximum value of the resonant voltage V _ce2 and the maximum value of the resonant current I _ce2 may be observed at the center of one period of the pulse current voltage. For example, when the input AC voltage has a characteristic of 60 Hz, one period of the pulse voltage is 8.33 ms, wherein the maximum values of the resonant voltage and the resonance current (V _ce2 , I _ce2 ) are the centers of one period of the pulse current voltage. Observed at about 4.16 ms.

The magnitude of the maximum value I _ce2 of the resonance current (or the maximum value V _ce2 of the resonance voltage) may affect the design of the filter unit 10. If the maximum value I _ce2 of the resonant current is large, since the current value flowing through the inverter unit 60 is large, noise induced to the outside may be severely generated. In this case, the design of the filter unit 10 having a large capacity is required to satisfy the EMI specification of the product (including the induction heating device). In this case, a large capacity of the components of the filter unit 10 (that is, C ₁ , C ₂ , L ₁ , L ₂ ) is required, and thus, the manufacturing cost of the induction heating apparatus can be increased, while miniaturization is difficult. have.

Accordingly, an object of the present invention is to provide an induction heating apparatus capable of maintaining the amount of power while enabling the design of the filter unit 10 having a smaller capacity than the prior art.

Figure 4 shows the correlation of the voltage, current and switching control signal in the standby mode and heating mode of the induction heating apparatus according to the present invention. 4A shows the voltage V _ce measured at the collector and emitter terminals of the inverter unit 60 when a switching control signal having a varying pulse width is applied. 4B shows the waveform of the current I _ce corresponding to the voltage V _ce when a switching control signal having a varying pulse width is applied.

Referring to FIG. 4A, a commercial AC voltage V _in is supplied to an induction heating apparatus. As described above, the commercial AC voltage V _in may be converted into a DC voltage through the rectifying unit 20 and the smoothing unit 40 (that is, the smoothing circuit). The voltage V _ce of the inverter unit 60 is kept constant (ie, V _ce1 ) during the standby mode time T ₁ in which the switching control signal is not generated by the controller 70. That is, in the standby mode, the inverter unit 60 is turned off to operate as an open circuit, and the collector of the inverter unit 60 (i.e., the output end of the induction heating unit 50) and the emitter terminal (i.e., ground). The voltage V _ce1 between) remains constant. On the other hand, in the standby mode, as the inverter unit 60 operates in an open circuit, no current is applied to the induction heating unit 50 (in other words, I _ce becomes zero).

When the standby mode time T ₁ ends, the controller 70 may generate a switching control signal and provide the switching control signal to the gate terminal of the inverter unit 60. The time point at which the controller 70 generates the switching control signal may be synchronized with the zero-crossing point ZC of the commercial AC voltage V _in that is input. That is, referring to FIG. 4A, the first pulse of the switching control signal generated by the controller 70 is one of the zero-crossing points (eg, ZC ₁ to ZC ₅ ) of the commercial AC voltage V _in (ZC). ₂ ) is synchronized with.

The third graph of FIG. 4A shows the pulse waveform of the switching control signal corresponding to the 'one period' of the pulsed voltage (generated through the rectification of the input AC voltage V _in ). As the inverter 60 is turned on and off at a high speed by the switching control signal, the resonance voltage V _ce is oscillated as shown in the second graph of FIG. 4A.

Referring to FIG. 4B, the waveform of the switching control signal corresponding to one period of the pulse voltage and the resonance current I _ce flowing through the inverter unit 60 (or the induction heating unit 50) are illustrated. The one periodic resonance current I _ce waveform of FIG. 4B corresponds to the one periodic resonance voltage V _ce waveform that oscillates when the switching control signal is applied in FIG. 4A.

According to an embodiment of the present invention, the control unit 70 generates a switching control signal in which the pulse width changes. Referring to FIG. 4B, the widths of the pulses p ₁ ,?, P _c ,?, And p _n in the switching control signal period α corresponding to one period of the pulse voltage are not constant.

Specifically, referring to the switching control signal illustrated in the middle of FIG. 4B, the pulses (p ₁ ,?, P _c ,?, P _n ) are zero in the switching control signal period α corresponding to one period of the pulse voltage. The width gradually decreases from the intersection point ZC ₂ near the center, and increases in width toward the zero-crossing point ZC ₃ near the center again. That is, in the switching control signal period α corresponding to one period of the pulse voltage, the widths of the pulses (eg, p ₁ , p _n ) generated adjacent to the zero-crossing points ZC ₂ and ZC _{3 are} shown. Is large and the pulse generated at the center (eg, p _c ) may be relatively small in width.

)(제1 구간으로 지칭될 수 있다)에서 펄스들 각각의 폭은 제로-교차점(ZC₂)에서 중심으로 갈수록(또는 시간 경과에 따라) 0.1㎛씩 감소할 수 있고, 스위칭 제어 신호의 구간(

)(제2 구간으로 지칭될 수 있다)에서 펄스들 각각의 폭은 중심에서 제로-교차점(ZC₃)으로 갈수록(또는 시간 경과에 따라) 0.1㎛씩 증가할 수 있다. 한편, 그에 따라 펄스(p₁, p_n)의 폭은 펄스(p_c)의 폭보다 클 수 있다. 또한 펄스(p₁) 및 펄스(p_n)의 폭은 동일할 수 있다. 즉, 스위칭 제어 신호의 구간(

)에서 펄스들(p₁, ?, p_c, ?, p_n)의 폭은 중심을 기준으로 대칭되는 특징을 가질 수 있다. 특히, 도 3에 개시된 종래 기술과 대비하였을 때, 제로-교차점들(ZC₂, ZC₃)에 인접한 펄스들(p₁, p_n)의 폭은 3~5㎛ 더 클 수 있다.As a specific example, the section of the switching control signal (

(Which may be referred to as the first interval), the width of each of the pulses may decrease by 0.1 μm toward the center (or over time) at the zero-crossing point ZC ₂ , and the interval of the switching control signal (

The width of each of the pulses (which may be referred to as the second interval) may increase by 0.1 μm from the center to the zero-crossing point ZC ₃ (or over time). Meanwhile, the widths of the pulses p ₁ and p _n may be larger than the widths of the pulses p _c . In addition, the widths of the pulses p ₁ and the pulses p _n may be the same. That is, the interval of the switching control signal (

), The widths of the pulses p ₁ ,?, P _c ,?, P _n may be symmetric about the center. In particular, in contrast to the prior art disclosed in FIG. 3, the widths of the pulses p ₁ , p _n adjacent to the zero-crossing points ZC ₂ , ZC ₃ may be 3 to 5 μm larger.

This control scheme, although the amount of power at the center of the signal of one cycle is reduced, as the amount of power at both sides is increased, the overall amount of power in one cycle can remain the same (i.e. no degradation in heating performance), At the same time, it is possible to lower the value of the resonant voltage V _ce3 and the value of the resonant current I _{ce3 at} the center of one period of the pulse current voltage (for example, the highest point of 120 Hz). That is, referring to the second graph of FIG. 4A, when the switching control signal having the uniform pulse width is supplied, the switching control having the pulse width increasing and decreasing according to the present embodiment, rather than the value V _ce2 of the highest resonant voltage. It can be seen that the value V _ce3 of the peak voltage is smaller when the signal is supplied. In addition, referring to the first graph of FIG. 4B, when the switching control signal having the uniform pulse width is supplied, the switching control having the pulse width increasing or decreasing according to the present embodiment, rather than the value I _ce2 of the highest resonant current. It can be seen that the value I _ce3 of the highest resonant current is smaller when the signal is supplied.

As the maximum value of the resonant voltage V _ce3 and the maximum value of the resonant current I _ce3 are smaller than those of the related art disclosed in FIG. 3, the maximum value of the induced noise may be reduced. This may provide flexibility in the design of the filter unit 10. That is, even if the capacity of the components of the filter unit 10 (for example, C ₁ , C ₂ , L ₁ , L ₂ ) is reduced, the EMI standard of the product (including the induction heating device) can be satisfied. It can be miniaturized, there is an advantage that the manufacturing cost can also be lowered. Meanwhile, as the maximum value V _ce3 of the resonance voltage and the maximum value I _ce3 of the resonance current become smaller, the reliability of the rectifying unit 20 and the inverter unit 60 may be improved.

,

,

,

)로 구분 될 수 있다. 즉, 도 4b의 중간에 도시된 스위칭 제어 신호와 비교하면, 펄스들의 폭이 감소하는 제1 구간(

)은 제1-1 구간(

,) 및 제1-1 구간(

,)을 뒤따르는 제1-2 구간(

)을 포함하고, 펄스들의 폭이 증가하는 제2 구간(

)은 제2-1 구간(

) 및 제2-1 구간(

)을 뒤따르는 제2-2 구간(

)을 포함할 수 있다. 여기서, 제로-교차점(ZC₂)에 인접하는 제1-1 구간(

)에 포함된 펄스들 각각의 폭은 구간(α)의 중심에 인접한 제1-2 구간(

)에 포함된 펄스들 각각의 폭보다 클 수 있다. 또한, 제로-교차점(ZC₃)에 인접하는 제2-2 구간(

)에 포함된 펄스들 각각의 폭은 구간(α)의 중심에 인접한 제2-1 구간(

)에 포함된 펄스들 각각의 폭보다 클 수 있다. According to another embodiment of the present disclosure, referring to the switching control signal shown at the bottom of FIG. 4B, when one period of the pulse current voltage (for example, the input AC voltage V _in has a characteristic of 60 Hz), 1 The interval α of the switching control signal corresponding to /120=8.33 ms is divided into four intervals (

,

,

,

) Can be separated. That is, compared to the switching control signal shown in the middle of Figure 4b, the first interval (the width of the pulse is reduced)

) Section 1-1 (

,) And section 1-1 (

Section 1-2 followed by,)

And a second period (in which the width of the pulses increases)

) Is the 2-1 interval (

) And 2-1 interval (

Followed by section 2-2 (

) May be included. Here, the _first-first section adjacent to the zero-crossing point ZC ₂ (

The width of each of the pulses included in the first to second intervals adjacent to the center of the interval (α) (

) May be greater than the width of each of the pulses included in. In addition, the second-second section adjacent to the zero-crossing point ZC ₃ (

The width of each of the pulses included in the?

) May be greater than the width of each of the pulses included in.

,

) 각각에서 펄스들 각각의 폭은 균일하게 유지될 수 있는 반면, 구간들(

,

) 각각에서 펄스들의 폭은 변화할 수 있다. 예를 들어, 제1-2 구간(

)에서 펄스들의 폭은 점진적으로 감소할 수 있는 반면, 제2-1 구간(

)에서 펄스들의 폭은 점진적으로 증가할 수 있다. Meanwhile, according to an embodiment, the sections (

,

The width of each of the pulses in each can be kept uniform while the intervals (

,

In each case the width of the pulses can vary. For example, the first to second intervals (

The width of the pulses can be gradually decreased in the 2-1 period ().

The width of the pulses may increase gradually.

,

,

,

) 각각에서 펄스들 각각의 폭은 균일하게 유지될 수 있다. 다만, 이 경우에도 앞서 언급된 것처럼 제1-1 구간(

) 보다 제1-2 구간(

,)에 포함된 펄스들의 폭이 더 작고, 제2-1 구간(

)보다 제2-2 구간(

)에 포함된 펄스들의 폭이 더 클 수 있다.Or intervals according to another embodiment (

,

,

,

In each case the width of each of the pulses can be kept uniform. In this case, however, as described above, the first-first section (

) From section 1-2

, The width of the pulses included in the smaller, and the 2-1 period (

) From 2-2 section (

) May have a larger width.

)에 포함된 펄스들 각각의 폭은 제2-2 구간(

)에 포함된 펄스들 각각의 폭과 동일할 수 있고, 제1-2 구간(

)에 포함된 펄스들 각각의 폭은 제2-1 구간(

)에 포함된 펄스들 각각의 폭과 동일할 수 있다. 즉, 제1-1 구간(

)과 제2-2 구간(

)은 맥류 전압의 한 주기의 중심을 기준으로 서로 대칭될 수 있고, 제1-2 구간(

)과 제2-1 구간(

)은 맥류 전압의 한 주기의 중심을 기준으로 서로 대칭될 수 있다.Meanwhile, section 1-1 (

Width of each of the pulses included in

May be equal to the width of each of the pulses included in

Width of each of the pulses included in

It may be equal to the width of each of the pulses included in). That is, the 1-1 section (

) And section 2-2 (

) May be symmetrical with respect to the center of one cycle of the pulse voltage,

) And section 2-1

) May be symmetrical with respect to the center of one period of the pulse voltage.

,

,

,

)로 구분되는 것으로 개시되어 있지만, 이에 제한되는 것은 아니며, 구간(α)은 본 발명의 목적 범위 내에서 임의의 수의 구간들로 구분될 수 있다.In the present embodiment, the section α of the switching control signal corresponding to one period of the pulse voltage is divided into four sections (

,

,

,

It is disclosed that but is not limited to this, interval (α) may be divided into any number of intervals within the scope of the present invention.

This control scheme, as mentioned above, can keep the total amount of power in one cycle the same (ie, no deterioration in heating performance), while the maximum value of the resonant voltage (V _ce3 ) and the maximum value of the resonant current (I _ce3 ). Can be lowered. Accordingly, the maximum value of noise induced outside the product can be reduced, so that the capacity of the components in the design of the filter unit 10 can be reduced. Meanwhile, as the maximum value V _ce3 of the resonance voltage and the maximum value I _ce3 of the resonance current become smaller, the reliability of the rectifying unit 20 and the inverter unit 60 may be improved.

The term "about" as used in this disclosure includes the degree of error associated with a particular amount of measurement based on the equipment available at the time of filing. For example, “about (or approximately)” may include a range of ± 8% or ± 5% or ± 2% of a given value.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. As used herein, the terms "comprises" and / or "comprising" refer to the presence of a feature, integer, step, operation, element, and / or component that is mentioned, but one or more other features, integers, steps, operations , Does not exclude the presence or addition of elemental elements and / or groups thereof.

Although the present disclosure has been described with reference to exemplary embodiments or embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for such elements without departing from the scope of the present disclosure. In addition, many modifications may be made to adapt a particular situation or configuration to the teachings of the present disclosure without departing from the essential scope thereof. Accordingly, the present disclosure is not limited to the specific embodiments disclosed as the best mode contemplated for carrying out the present disclosure, and the present disclosure will include all embodiments falling within the scope of the claims.

Claims (15)

In induction heating apparatus,
A rectifier for rectifying the applied AC voltage to output a pulse voltage;
A smoothing unit for generating a DC voltage by smoothing the pulse voltage;
An induction heating unit connected to an output end of the smoothing unit and including an induction heating coil and a resonance capacitor;
An inverter unit connected to an output terminal of the induction heating unit and configured to generate a high frequency resonance voltage in the induction heating unit through a repetitive switching operation; And
And a controller configured to generate a switching control signal for controlling the switching operation of the inverter unit through a pulse width modulation method.
And a switching control signal corresponding to one period of the pulse voltage includes a first section in which a pulse width decreases and a second section following the first section and in which the pulse width increases. The induction heating apparatus according to claim 1, wherein the switching control signal corresponding to one period of the pulse voltage has the smallest pulse at its center. The induction heating apparatus of claim 1, wherein a width of each of the pulses included in the first section gradually decreases from the zero-crossing point of the AC voltage toward the center of one period of the pulse voltage. The induction heating apparatus of claim 3, wherein a width of each of the pulses included in the second section gradually increases from the center of one period of the pulse voltage to the zero-crossing point of the AC voltage. The induction heating apparatus of claim 4, wherein a width of each of the pulses included in the first section decreases by 0.1 µm, and a width of each of the pulses included in the second section increases by 0.1 µm. The induction heating apparatus according to claim 1, further comprising a detector for detecting zero-crossing point information of an alternating voltage and providing the detected zero-crossing point information to the control unit. The induction heating apparatus of claim 1, wherein the first section and the second section are symmetrical with respect to a center of a switching control signal corresponding to one period of the pulse voltage. The method of claim 1, wherein the first section includes a first-second section and a first-second section including pulses having a width smaller than the first-first section, but smaller than the first-first section, The second section includes a second section 2-2 including pulses that follow a section 2-1 and the section 2-1 but having a width greater than that of the section 2-1. The method of claim 8, wherein the widths of the pulses in each of the first-first section and the second-second section are uniform, and the width of the pulses included in the first-second section is gradually decreased and included in the second-first section. The width of the pulsed pulses gradually increases. The induction heating apparatus of claim 8, wherein a width of pulses is uniform in each of the first-first, first-second, second-first, and second-second sections. The method of claim 8, wherein the first-first section and the second-second section are symmetrical with respect to the center of the switching control signal corresponding to one period of the pulse current voltage, and the first-second section and the second section. The -1 sections are symmetrical with respect to the center of the switching control signal corresponding to one period of the pulse voltage, induction heating apparatus. The induction heating apparatus according to claim 1, wherein the induction heating unit and the inverter unit have a series connection structure. The induction heating apparatus according to claim 12, further comprising a filter unit for blocking noise generated by the high frequency resonance current flowing through the induction heating unit and the inverter unit by the high frequency resonance voltage. The induction heating apparatus according to claim 1, wherein the induction heating unit and the smoothing capacitor have a parallel connection structure when the inverter unit is turned on in accordance with the switching control signal. The induction heating apparatus of claim 1, wherein the induction heating coil and the resonance capacitor are connected in parallel in the induction heating unit.

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