KR0151289B1 - Control method for induction heating cooker - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating cooker. In particular, an initial switching operating frequency is set to a frequency for heating an inductive load of a nonmagnetic material, so that zero voltage switching is possible regardless of the material of the induction load. It relates to a control method.

The control method of the induction heating cooker of the present invention comprises the first step of switching the heating coil and the resonance capacitor capacity to the heating mode of the nonmagnetic inductive load and driving at the switching operating frequency of the nonmagnetic inductive load, and the first step. A second step of judging the material of the inductive load by comparing the output when the switching operating frequency of the nonmagnetic inductive load is applied to the reference value in the step state; and if the inductive load is determined to be nonmagnetic in the second step, the output has a reference range. A third step of heating the inductive load at a switching operating frequency of the nonmagnetic inductive load that does not deviate; and if the inductive load is determined to be a magnetic material in the second step, the capacity of the heating coil and the resonance capacitor is changed to the heating mode of the magnetic inductive load. Heats the inductive load with the switching operating frequency of the magnetic inductive load that switches and the output does not deviate from the reference range. 4 composed of a hayeoseo a step and with its features.

Description

Induction Heating Cooker Control Method

1 is a conventional induction heating cooker.

2 is an embodiment of the induction heating cooker of the present invention.

Figure 3 (a) (b) is the output curve versus frequency according to the material of the inductive load.

Figure 4 is a flow chart for explaining the operation of the induction heating cooker of the present invention.

* Explanation of symbols for main parts of the drawings

2: resonator 3: load detector

4: Inverter 5: Inverter driver

7: control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating cooker. In particular, an initial switching operating frequency is set to a frequency for heating an inductive load of a nonmagnetic material, so that zero voltage switching is possible regardless of the material of the induction load. It relates to a control method.

A conventional induction heating cooker is composed of a bridge diode (11), a choke coil (12), a smoothing capacitor (13), and the like, as shown in FIG. DC (DC) power supply unit (1) for switching from the inverter (5) operated by receiving the switching operation frequency of the inverter drive unit 6 to be supplied to the resonator (2) and the first and second heating Working coils L1, L2, first and second resonant capacitors C1, C2, and a switching switch 21. The heating mode is switched to the switching switch 21 according to the material of the inductive load. Switchable resonator 2, load detection unit 3 for detecting the magnitude of the high frequency current and impedance flowing through the resonator 2, and switching the switch 21, transistors Q1 and Q2 The inverter 4 driving the resonator 2, the load detector 3, and the outputs of the phase detector 6 described below are inputted and switched. The frequency was less composed of a variable to the inverter 4, the inverter drive 5 and the resonance unit 6, the phase detection unit 6 receives feedback of the phase of the high-frequency current flowing in the output for a.

The overall operation is briefly described as follows.

The power supply voltage AC from which the noise and the high frequency are removed from the choke coil 12 is rectified by the bridge diode 11, smoothed by the smoothing capacitor 13, and converted into direct current (DC).

The phase detector 6 receives the phase of the high frequency current flowing through the resonator 6.

The load detector 3 switches the switching switch 21 according to the magnitude of the high frequency current from the current transformer CT, and the inverter driver 5 receives the phase of the high frequency current from the phase detector 6 to feed back the inverter ( 4) A switching operating frequency for driving the output is determined and output to the inverter 4.

The load detector 3 detecting the high frequency current and the impedance of the current transformer CT determines the material of the inductive load so that the changeover switch 21 can be changed accordingly.

The overall operation will be described in detail below.

When the first cooking switch (not shown) is turned on, the inverter driver 5 is driven as power is applied.

As the inverter driver 5 is driven, an arbitrary switching operating frequency is applied to the inverter 4 regardless of the material of the inductive load.

As a result, high-frequency current flows from the DC power supply 1 to the resonator 2 while the transistors Q1 and Q2 of the inverter 4 alternately turn on / off.

Thereafter, the load detector 3 determines the material of the inductive load according to the high frequency current and the impedance value detected by the current transformer CT, switches the switching switch 21, and simultaneously induces the switching operation frequency of the inverter driver 5. Is output differently depending on the case of nonmagnetic material or magnetic material.

In other words, the load detection unit 3 determines the material of the inductive load from the magnitude and impedance of the high frequency current detected by the current transformer CT, so that the inductive load is nonmagnetic (high resistance, high permeability) for the switching switch 21. Is connected to contact "ab", and if the inductive load is determined to be a magnetic material (low permeability, low resistance), connect the switching switch 21 to the contact "ac".

That is, the resonator 2 includes a first heating coil L1, a second heating coil L2, a first resonance capacitor C1, a second resonance capacitor C2, It is composed of a switching switch 21 controlled by the load detection unit 3, if it is determined that the inductive load is low magnetic permeability and low resistance characteristics of the non-magnetic material, the switching switch 21 is controlled by the load detection unit 3 The first heating working coil L1, the second heating working coil L2, the first resonant capacitor C1, and the second resonant capacitor C2 are connected in series, and the inductive load is a magnetic material. In the case of high permeability and high resistance, which are the characteristics of the first heating coil L1 and the first resonant capacitor C1, the switching switch 21 is connected in series.

The phase detection unit 6 feeds back the phase of the high frequency current flowing through the resonator unit 2 to the inverter driver 5.

However, the control method of the conventional induction heating cooker as described above has the following problems.

Initially, the induction heating cooker has a loss due to the failure of zero voltage switching to the switching transistor constituting the inverter because any switching operating frequency is output from the inverter driver to the inverter regardless of whether the inductive load is nonmagnetic or magnetic. There was a lot of concern.

Therefore, the present invention has been devised to solve the above problems, the switching operation when the inductive load is a non-magnetic material and the switching operation when the inductive load is a non-magnetic material at the same time regardless of the material of the inductive load The inverter drive unit is driven at a frequency to compare the output power with a predetermined value to determine the material of the inductive load, and the switching operation frequency of the inverter drive unit for driving the inverter while switching the switch according to the material of the determined inductive load. Induction heating cooker capable of zero voltage switching irrespective of the material of the inductive load that can prevent the switching transistor of the inverter from being damaged by the initial switching operating frequency applied regardless of the material of the inductive load. To provide a control method of .

The control method of the induction heating cooker of the present invention for achieving the above object is the first to switch the heating coil and the resonance capacitor capacity to the heating mode of the nonmagnetic inductive load and to drive at the switching operating frequency of the nonmagnetic inductive load And a second step of judging the material of the inductive load by comparing the output when the switching operating frequency of the nonmagnetic inductive load is applied in the first step state with a reference value, and determining that the inductive load is nonmagnetic in the second step. The third step of heating the inductive load at a switching operating frequency of the nonmagnetic inductive load whose output does not deviate from the reference range, and if the inductive load is determined to be a magnetic material in the second step, the capacity of the heating coil and the resonance capacitor Switching operating frequency of magnetic inductive loads that switch to the heating mode of the inductive loads and whose output does not exceed the reference Hayeoseo configured to include a fourth step of heating the inductive load can have its features.

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

2 is a circuit diagram of an embodiment of the induction heating cooker according to the present invention, in which a full-wave rectified bridge diode 11, a choke coil 12, and a smoothing capacitor 13 are inputted. Heating for heating the inductive load with the energy generated by the rectification and smoothing unit (1) for smoothing the DC and removing noise and high frequency, and the DC power output of the rectifying and smoothing unit (1). Selectively switching the coil L and the first resonance capacitor, the second resonance capacitor C1 and C2 and the first and second resonance capacitors C1 and C2 with the heating working coil L A resonator 2 capable of switching the heating mode according to the material of the inductive load, and a load detector 3 for detecting a high frequency current and impedance flowing through the resonator 2; And the transistors Q1 and Q2 to direct the resonator 2 to a specific frequency. Inverter (4) for resonating in a row, an inverter driver (5) for outputting a switching operating frequency of a specific frequency to the inverter (4), the switching switch 21 and the inverter by receiving the output of the load detector (3) The control unit 7 controls the driving unit 5.

If an inductive load is a non-magnetic material which is the resonance frequency of the resonance point ₁ / 2π (LC 1) ^1/2 condenser for the heated working coil (L) for the first resonator such that (C ₁₎ in series with which is connected a non-magnetic inductive load The switching switch 21 is switched to the heating mode of the switching switch 21. At this time, in order to enable zero voltage switching of the switching transistors Q1 and Q2 constituting the inverter 4, the resonance from the inverter driver 5 is controlled. A first switching operating frequency of frequency higher than frequency 1 / 2π (LC ₁ ) ^1/2 should be output to the inverter 4.

When the inductive load is a magnetic material, heating of the magnetic induction load in which the heating working coil L is connected in series with the second resonance capacitor C ₂ so that the resonance frequency of the resonance point is 1 / 2π (LC ₂ ) ^1/2. The switching switch 21 is switched to the mode, in which case the switching transistors Q1 and Q2 constituting the inverter 4 are capable of zero voltage switching. A second switching operating frequency of frequency higher than 2π (LC ₂ ) ^1/2 should be output to the inverter 4.

The operation of the changeover switch 21 is controlled by the control unit 7 which receives the output of the load detection unit 4.

At this time, the capacitances of the first and second resonance capacitors C ₁ and C ₂ are C ₁ <C ₂ .

When the inverter 4 is operated by the switching operating frequency output from the inverter driver 5, the DC power, which is the output of the rectification and smoothing unit 1, is applied to the resonator 2 to start charging and discharging of energy. .

At this time, the load detector 3 detects the magnitude and impedance of the high frequency current flowing through the resonator 2 and the control unit 7 which receives the output thereof switches the switching switch 21 and switches the inverter driver 5. Control the operating frequency.

4 is a flowchart according to a control method of an induction heating cooker according to the present invention, and the resonance curves of the case where the inductive loads of the second and third FIGS. The operation is described as follows.

As the initial cooking switch (not shown) is turned on (step 100), the control unit 7 controls the selector switch 21 to turn the selected number of turns of the working coil L ₁ for heating and the selected _first of small capacity. The resonance capacitor C1 is connected in series to set the heating mode of the nonmagnetic inductive load (step 101).

The output frequency of the inverter driver 5 is set to a first switching operating frequency f ₁ , which is a zero voltage switching operating frequency for heating of the nonmagnetic inductive load (step 102).

The high frequency current flowing through the resonator 6 by the inverter 4 operated at the first switching operating frequency of the inverter driver 5 is detected by the load detector 4 and the magnitude of power multiplied by the high frequency current and impedance. the first switching an operating frequency band (f ₁ ^- f ~ ⁺ _1), it is determined whether of the frequency exceeds a reference power (P _ref1) on the (f ⁺ ₁₎ (step 103).

When it exceeds the reference power (P _ref1) is a frequency (f ₁ ^-) a first switching operation frequency does not exceed the reference power (P _ref2) on the f ₁ ^- maintains a ~ f ₂ ⁺ (step 104).

When the reference power P _ref1 for the frequency f ₁ ⁺ is not exceeded, the control unit 7 controls the switching switch 21 of the resonator unit 2 for the selected second resonance having a large capacity. The capacitor C2 is connected in series with the heating working coil L to switch to the heating mode of the magnetic induction load (step 105).

The control unit 7 then controls the inverter driver 5 to set its output frequency to the second switching operating frequency f ₂ (step 106).

The size of the high-frequency gopin power of the current and the impedance passing through the resonator portion (2) which is detected in the load detecting unit (3) a second switching operation frequency band (f ₂ ^- ~ f ₂ ⁺⁾ for one frequency (f ₂ ⁺⁾ It is determined whether the reference power P _ref1 is exceeded (step 107).

Reference power if it exceeds (P _ref1) is the reference power and the second switching operation frequency so as not to exceed (P _ref2) (f ⁺ ₂₎ f ₂ ^- maintains a ~ f ₂ ⁺ (step 108).

If the reference power P _ref1 is not exceeded, it is determined as a small load (step 109).

As described above, the present invention is the first case in which the inductive load is a nonmagnetic material in a state in which a resonance capacitor initially connected in series with the heating working coil is set to the nonmagnetic material regardless of the material of the inductive load. The resonator is driven at a switching operating frequency. When the power calculated from the high frequency current flowing through the resonator is greater than or equal to the reference power, the first switching frequency band is maintained. If less than or equal to the reference power, the resonator is connected in series with the heating working coil. When the resonant capacitor is set to the case where the inductive load is a magnetic material, the resonator is driven at the second switching operating frequency when the inductive load is a nonmagnetic material, and the power calculated from the high frequency current flowing through the resonator is greater than or equal to the reference power. Maintaining the second switching operation frequency band, and less than the reference power The zero voltage switching operation of the switching transistors constituting the inverter was made possible by judging as below.

As described above, the present invention has an effect of initially preventing the switching transistor constituting the inverter from being damaged by initially setting the switching operating frequency of the inverter to enable zero voltage switching regardless of the material of the inductive load.

Claims (1)

A first step of switching the heating coil and the resonance capacitor capacity to a heating mode of the nonmagnetic inductive load, and driving the inverter at a switching operating frequency of the nonmagnetic inductive load; and switching of the nonmagnetic inductive load in the first step state. The second step of determining the material of the inductive load by comparing the output when the operating frequency is applied to the reference value, and the switching operation of the nonmagnetic inductive load whose output does not deviate from the reference range when the inductive load is determined to be nonmagnetic in the second step The third step of heating the inductive load at a frequency, and if the inductive load is determined to be a magnetic material in the second step, the capacities of the heating coil and the resonance capacitor are switched to the heating mode of the magnetic inductive load, and the output does not deviate from the reference range. And a fourth step of heating the inductive load at a switching operating frequency of the magnetic inductive load. The control method of induction heating cooker.