JP5921707B2 - Induction heating cooker - Google Patents

Description

  The present invention relates to an induction heating cooker.

Some conventional induction heating cookers determine the temperature of an object to be heated based on the input current or control amount of an inverter.
For example, it has a control means for controlling the inverter so that the input current of the inverter becomes constant, and when the control amount changes more than a predetermined amount within a predetermined time, it is determined that the temperature change of the object to be heated is large. An induction heating cooker that suppresses the output of an inverter has been proposed (see, for example, Patent Document 1).
Further, for example, a temperature detection device for an induction heating cooker comprising temperature determination processing means for determining a temperature corresponding to the change amount of the input current detected by the input current change amount detection means for detecting only the change amount of the input current Has been proposed (see, for example, Patent Document 2).

JP 2008-181892 A (page 3 to page 5, FIG. 1) JP-A-5-62773 (pages 2 to 3, FIG. 1)

  In the induction heating cooker described in Patent Document 1, the drive frequency of the inverter is controlled so that the input power is constant, and the temperature change of the object to be heated is determined by this control amount change (Δf). However, depending on the material of the object to be heated, there is a problem that the control amount change (Δf) of the driving frequency becomes minute and the temperature change of the object to be heated cannot be detected.

  In the temperature detection device for an induction heating cooker described in Patent Document 2, when the material of the object to be heated changes, the input current may become excessive depending on the drive frequency of the inverter, and the inverter may become hot and break down. There was a problem that there was.

  This invention is made in order to solve the above subjects, and obtains the induction heating cooking appliance which can detect the temperature change of a to-be-heated object irrespective of the material of a to-be-heated object. Moreover, the highly reliable induction heating cooking appliance which suppressed the increase in input current is obtained.

An induction heating cooker according to the present invention includes a heating coil that induction-heats an object to be heated, a DC power supply circuit that converts an AC voltage from an AC power supply into a DC voltage, and a DC voltage from the DC power supply circuit to high-frequency power. converted, the driving circuit for supplying to the heating coil, and controls the drive of the pre-Symbol driving circuit, and a control unit for controlling the high frequency power supplied to the heating coil, wherein, prior SL drive circuit in a state of fixing the driving frequency of the primary voltage value corresponding to the DC voltage of the AC voltage or the DC power supply circuit from the AC power source, at least one of the coil current flowing through the input current and the heating coil to the driving circuit one in accordance with the change amount of the current value and the value based on whether the instruction is an instruction for detecting the temperature change of the heated object.

  The present invention can detect a temperature change of an object to be heated regardless of the material of the object to be heated. Further, an increase in input current can be suppressed, and reliability can be improved.

It is a disassembled perspective view which shows the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is a figure which shows the drive circuit of the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is a load discrimination | determination characteristic view of the to-be-heated object based on the relationship between the heating coil electric current and input current in the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is an interphase figure of the input current with respect to the drive frequency at the time of the temperature change of the to-be-heated material of the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is the figure which expanded the part shown with the broken line of FIG. It is a figure which shows the relationship between the drive frequency of the induction heating cooking appliance which concerns on Embodiment 1, temperature, input current, and time. It is a figure which shows the relationship between the drive frequency of the induction heating cooking appliance which concerns on Embodiment 1, temperature, input current, an input electric current correction value, and time. It is a figure which shows another drive circuit of the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is a figure which shows a part of drive circuit of the induction heating cooking appliance which concerns on Embodiment 2. FIG. 6 is a diagram illustrating an example of a drive signal for a half-bridge circuit according to Embodiment 2. FIG. It is a figure which shows a part of drive circuit of the induction heating cooking appliance which concerns on Embodiment 3. FIG. 6 is a diagram illustrating an example of a drive signal of a full bridge circuit according to a third embodiment. FIG.

Embodiment 1 FIG.
(Constitution)
1 is an exploded perspective view showing an induction heating cooker according to Embodiment 1. FIG.
As shown in FIG. 1, an induction heating cooker 100 has a top plate 4 on which an object to be heated 5 such as a pan is placed. The top plate 4 includes a first heating port 1, a second heating port 2, and a third heating port 3 as heating ports for inductively heating the object to be heated 5, and corresponds to each heating port. The first heating unit 11, the second heating unit 12, and the third heating unit 13 are provided, and the object to be heated 5 can be placed on each heating port to perform induction heating. Is.
In the first embodiment, the first heating means 11 and the second heating means 12 are provided side by side on the front side of the main body, and the third heating means 13 is provided at substantially the center on the back side of the main body. .
In addition, arrangement | positioning of each heating port is not restricted to this. For example, three heating ports may be arranged side by side in a substantially straight line. Moreover, you may arrange | position so that the position of the depth direction of the center of the 1st heating means 11 and the center of the 2nd heating means 12 may differ.

  The top plate 4 is entirely made of a material that transmits infrared rays, such as heat-resistant tempered glass or crystallized glass, and a rubber packing or sealing material is interposed between the upper surface and the outer periphery of the upper surface of the induction heating cooker 100 main body. Fixed in a watertight state. The top plate 4 has a circular pan showing a rough placement position of the pan corresponding to the heating range (heating port) of the first heating unit 11, the second heating unit 12 and the third heating unit 13. The position display is formed by applying paint or printing.

  On the front side of the top plate 4, there is a heating power and cooking menu (boiling mode, fried food mode when heating the article 5 to be heated by the first heating means 11, the second heating means 12, and the third heating means 13. Etc.) are provided as an input device for setting the operation unit 40a, the operation unit 40b, and the operation unit 40c (hereinafter may be collectively referred to as the operation unit 40). Further, in the vicinity of the operation unit 40, as the notification unit 42, a display unit 41a, a display unit 41b, and a display unit 41c for displaying the operation state of the induction heating cooker 100, the input / operation content from the operation unit 40, and the like. Is provided. Note that the operation units 40a to 40c and the display units 41a to 41c are not particularly limited, for example, when the operation units 40a and 41c are provided for each heating port, or when the operation unit 40 and the display unit 41 are provided collectively.

  A first heating means 11, a second heating means 12, and a third heating means 13 are provided below the top plate 4 and inside the main body, and each heating means is a heating coil (not shown). Z).

Inside the main body of the induction heating cooker 100, there are a drive circuit 50 for supplying high frequency power to the heating coils of the first heating means 11, the second heating means 12, and the third heating means 13, and the drive circuit 50. And a control unit 45 for controlling the overall operation of the induction heating cooker 100.
The control unit 45 in the present embodiment constitutes a “control unit” and a “load determination unit” in the present invention.

  The heating coil has a substantially circular planar shape, and is configured by winding a conductive wire made of an arbitrary metal with an insulating film (for example, copper, aluminum, etc.) in the circumferential direction. Is supplied to each heating coil, whereby an induction heating operation is performed.

FIG. 2 is a diagram illustrating a drive circuit of the induction heating cooker according to the first embodiment. In addition, the drive circuit 50 is provided for every heating means, and the structure is the same. In FIG. 2, only one drive circuit 50 is shown.
As shown in FIG. 2, the drive circuit 50 includes a DC power supply circuit 22, an inverter circuit 23, and a resonance capacitor 24a.

  The input current detection unit 25 a detects a current input from the AC power supply (commercial power supply) 21 to the DC power supply circuit 22 and outputs a voltage signal corresponding to the input current value to the control unit 45.

  The DC power supply circuit 22 includes a diode bridge 22a, a reactor 22b, and a smoothing capacitor 22c, converts an AC voltage input from the AC power supply 21 into a DC voltage, and outputs the DC voltage to the inverter circuit 23.

The primary voltage detection means 35 is configured by connecting a resistor 35a and a resistor 35b in series. The primary voltage detection means 35 detects a primary voltage value (voltage division ratio) corresponding to the DC voltage of the DC power supply circuit 22 from the resistance ratio of the resistors 35 a and 35 b and inputs the detected voltage value to the control unit 45.
In the example shown in FIG. 2, the primary voltage detection means 35 is provided on the output side of the diode bridge 22a. However, the present invention is not limited to this, and the AC voltage from the AC power supply 21 or the DC of the DC power supply circuit 22 is not limited thereto. What is necessary is just to detect the primary voltage value according to the voltage. For example, you may detect the alternating voltage of the alternating current power supply 21 as a primary voltage value. Further, for example, the output of the smoothing capacitor 22c may be detected as the primary voltage value.

  The inverter circuit 23 is a so-called half-bridge type inverter in which IGBTs 23a and 23b as switching elements are connected in series to the output of the DC power supply circuit 22, and diodes 23c and 23d are parallel to the IGBTs 23a and 23b, respectively, as flywheel diodes. It is connected to the. The inverter circuit 23 converts the DC power output from the DC power supply circuit 22 into a high-frequency AC power of about 20 kHz to 50 kHz and supplies the AC power to a resonance circuit including the heating coil 11a and the resonance capacitor 24a.

  With this configuration, a high-frequency current of about several tens of A flows through the heating coil 11a, and the object to be heated placed on the top plate 4 directly above the heating coil 11a by the high-frequency magnetic flux generated by the flowing high-frequency current. 5 is induction heated. The IGBTs 23a and 23b, which are switching elements, are composed of, for example, a silicon-based semiconductor, but may be configured using a wide band gap semiconductor such as silicon carbide or a gallium nitride-based material.

  The coil current detection means 25b is connected between the heating coil 11a and the resonance capacitor 24a. For example, the coil current detection unit 25b detects the peak of the current flowing through the heating coil 11a and outputs a voltage signal corresponding to the peak value of the heating coil current to the control unit 45.

  The temperature detection means 30 is composed of, for example, a thermistor, and detects the temperature by the heat transferred from the article to be heated 5 to the top plate 4. In addition, you may use arbitrary sensors, such as not only a thermistor but an infrared sensor.

(Operation)
Next, operation | movement of the induction heating cooking appliance 100 which concerns on Embodiment 1 is demonstrated.
First, the operation in the case where the object to be heated 5 placed on the heating port of the top plate 4 is induction-heated by the thermal power set by the operation unit 40 will be described.

  When the user places the object to be heated 5 on the heating port and instructs the operation unit 40 to start heating (heating power input), the control unit 45 (load determination unit) performs a load determination process.

FIG. 3 is a load discrimination characteristic diagram of an object to be heated based on the relationship between the heating coil current and the input current in the induction heating cooker according to the first embodiment.
Here, the material of the heated object 5 (pan) serving as a load is largely divided into a magnetic material such as iron or SUS430, a high resistance nonmagnetic material such as SUS304, and a low resistance nonmagnetic material such as aluminum or copper. Separated.

  As shown in FIG. 3, the relationship between the coil current and the input current differs depending on the material of the pan load placed on the top plate 4. The control unit 45 stores therein in advance a load determination table in which the relationship between the coil current and the input current shown in FIG. 3 is tabulated. By storing the load determination table therein, the load determination means can be configured with an inexpensive configuration.

  In the load determination process, the control unit 45 drives the inverter circuit 23 with a specific drive signal for load determination, and detects the input current from the output signal of the input current detection means 25a. At the same time, the control unit 45 detects the coil current from the output signal of the coil current detection means 25b. The control part 45 determines the material of the to-be-heated material (pan) 5 mounted from the detected coil current and input current, and the load determination table showing the relationship of FIG. Thus, the control part 45 (load determination means) determines the material of the article 5 to be heated placed on the heating coil 11a based on the correlation between the input current and the coil current.

  After performing the above load determination processing, the control unit 45 performs a control operation based on the load determination result.

  When the load determination result is a low-resistance non-magnetic material, the induction heating cooker 100 according to the first embodiment cannot be heated. Encourage people to change the pan.

  Even when the load determination result is no load, the notification means 42 is notified that heating is impossible, and the user is prompted to place the pan.

When the load determination result is a magnetic material or a high-resistance nonmagnetic material, these pans are materials that can be heated by the induction heating cooker 100 of the first embodiment, and thus the control unit 45 has determined. Determine the drive frequency according to the pan material. This drive frequency is set to a frequency higher than the resonance frequency so that the input current does not become excessive. The drive frequency can be determined by referring to a frequency table or the like corresponding to the material of the article 5 to be heated and the set heating power, for example.
The control unit 45 fixes the determined drive frequency and drives the inverter circuit 23 to start the induction heating operation. In the state where the drive frequency is fixed, the on-duty (on / off ratio) of the switching element of the inverter circuit 23 is also fixed.

FIG. 4 is a phase diagram of the input current with respect to the drive frequency when the temperature of the heated object of the induction heating cooker according to Embodiment 1 is changed. In FIG. 4, a thin line is a characteristic when the to-be-heated object 5 (pan) is low temperature, and a thick line is a characteristic when the to-be-heated object 5 is high temperature.
As shown in FIG. 4, the characteristics change depending on the temperature of the object to be heated 5 because the resistivity of the object to be heated 5 increases and the magnetic permeability decreases due to the temperature rise, so that the heating coil 11a and the object to be heated are heated. This is because the magnetic coupling of the object 5 changes.

  In the control unit 45 of the induction heating cooker 100 according to the first embodiment, a frequency higher than the frequency at which the input current shown in FIG. 4 is maximized is determined as the driving frequency, and this driving frequency is fixed and the inverter circuit 23 is controlled.

FIG. 5 is an enlarged view of a portion indicated by a broken line in FIG.
When the inverter circuit 23 is controlled by fixing the drive frequency according to the pan material determined in the load determination process described above, the input current value (operating point) at the drive frequency increases as the heated object 5 changes from low temperature to high temperature. The point A changes from point A to point B, and the input current gradually decreases as the temperature of the article to be heated 5 rises.
At this time, the control unit 45 obtains a change amount (time change) of the input current per predetermined time with the drive frequency of the inverter circuit 23 fixed, and based on the change amount per predetermined time, the object to be heated 5 Detects temperature changes in

  For this reason, the temperature change of the to-be-heated object 5 is detectable irrespective of the material of the to-be-heated object 5. Moreover, since the temperature change of the to-be-heated object 5 can be detected by the change of input current, a temperature change can be detected at high speed compared with a temperature sensor etc.

  Moreover, the material of the to-be-heated object 5 mounted above the heating coil 11a is determined, the drive frequency of the inverter circuit 23 is determined according to the material of the to-be-heated object 5, and the inverter circuit 23 is determined by the drive frequency. Drive. For this reason, the inverter circuit 23 can be fixed and driven by the drive frequency according to the material of the to-be-heated material 5, and the increase in input current can be suppressed. Therefore, the high temperature of the inverter circuit 23 can be suppressed and the reliability can be improved.

(Water heating mode 1)
Next, an operation when the water heating mode for performing the water heating operation of the water charged in the article to be heated 5 is selected as the cooking menu (operation mode) by the operation unit 40 will be described.

  Similarly to the above-described operation, the control unit 45 performs a load determination process, determines a drive frequency corresponding to the determined pan material, drives the inverter circuit 23 with the determined drive frequency fixed, and performs an induction heating operation. carry out. And the control part 45 judges completion of boiling by the time change of input current. Here, the elapsed time and the change of each characteristic when performing water boiling will be described with reference to FIG.

  FIG. 6 is a diagram showing the relationship between the drive frequency, temperature, input current and time of the induction heating cooker according to the first embodiment. In FIG. 6, the elapsed time and the change of each characteristic when water is poured into the article to be heated 5 and the boiling of water are shown, FIG. 6 (a) shows the driving frequency, and FIG. 6 (b) shows the temperature ( Water temperature), FIG. 6 (c) shows the input current.

  As shown in FIG. 6A, the inverter circuit 23 is controlled with the drive frequency fixed. As shown in FIG. 6B, the temperature (water temperature) of the article to be heated 5 gradually rises until it boils, and when it boils, the temperature becomes constant. As shown in FIG. 6C, the input current gradually decreases as the temperature of the article 5 to be heated increases, and when the water boils and the temperature becomes constant, the input current also becomes constant. That is, when the input current becomes constant, the water boils and the boiling is completed.

For this reason, the control unit 45 in the present embodiment obtains a change amount (time change) of the input current per predetermined time with the drive frequency of the inverter circuit 23 fixed, and the change amount per predetermined time. When the value becomes equal to or less than the predetermined value, it is determined that the water heater has been completed.
The predetermined value information may be set in the control unit 45 in advance, or may be input from the operation unit 40 or the like.

  And the control part 45 alert | reports that the kettle was completed using the alerting | reporting means 42. FIG. Here, the notification means 42 is not particularly limited, for example, displaying the completion of boiling on the display unit 41 or notifying the user by voice using a speaker (not shown).

As described above, in the water heating mode in which the water boiling operation is set, the amount of change per predetermined time of the input current is obtained with the drive frequency of the inverter circuit 23 being fixed. When the value is less than or equal to the value, the notification means 42 notifies the completion of boiling.
For this reason, it is possible to promptly notify the completion of boiling of water, and an easy-to-use induction heating cooker can be obtained.

(Water heater mode 2)
Next, another control operation when the water heating mode is selected by the operation unit 40 will be described.

The input current depends on the value of the DC voltage (primary voltage) of the DC power supply circuit 22, and even if the temperature of the article to be heated 5 is the same, the input current is high if the primary voltage is high and the primary voltage is low. Input current is also reduced. For this reason, when the AC voltage value of the AC power supply 21 (commercial power supply) changes during the control operation, the DC voltage of the DC power supply circuit 22 also changes, and the input current changes accordingly.
In the water heating mode 1 control operation described above, the completion of the water heating is determined based on the amount of change in the input current per predetermined time. Therefore, if the input current changes due to the change in the AC voltage of the AC power supply 21, the water heating completion is erroneously determined. Or it may not be possible to detect the completion of boiling without the input current being constant.

  In the hot water heating mode 2, the control unit 45 divides the input current detected by the input current detection means 25a by the DC voltage (primary voltage) detected by the primary voltage detection means 35, whereby the ratio of the input current to the primary voltage ( Hereinafter, “input current correction value”) is calculated. Then, the amount of change per predetermined time of the input current correction value is detected, and when the amount of change becomes equal to or less than a predetermined value (substantially constant), it is determined that the water has boiled and boiling is completed. Details of such operation will be described with reference to FIG.

  FIG. 7 is a diagram illustrating the relationship between the drive frequency, temperature, input current, input current correction value, and time of the induction heating cooker according to the first embodiment. In FIG. 7, the elapsed time and the change of each characteristic when water is poured into the article to be heated 5 and the boiling of water are shown, FIG. 7 (a) shows the drive frequency, and FIG. 7 (b) shows the temperature ( Water temperature), FIG. 7C shows the input current, and FIG. 7D shows the input current correction value.

Similar to the operation in the water heating mode 1 described above, when heating is started with the driving frequency fixed (FIG. 7A), the temperature (water temperature) of the article 5 to be heated gradually rises until it boils (FIG. 7 ( b)). As shown in FIG. 7C, the input current gradually decreases as the temperature of the article to be heated 5 rises. When the water boils and the temperature becomes constant, the input current becomes constant. At this time, when the primary voltage V1 increases, the input current also increases, and when the primary current V1 decreases, the input current also decreases.
On the other hand, as shown in FIG. 7 (d), the input current correction value obtained by dividing the input current by the primary DC voltage is not affected by the change in the primary voltage, and depends on the temperature change of the article 5 to be heated. Change.

For this reason, in the hot water heating mode 2, the control unit 45 obtains a change amount (time change) per predetermined time of the input current correction value in a state where the drive frequency of the inverter circuit 23 is fixed. When the amount of change in the temperature becomes equal to or less than a predetermined value, it is determined that the kettle has been completed.
The predetermined value information may be set in the control unit 45 in advance, or may be input from the operation unit 40 or the like.

  And the control part 45 alert | reports that the kettle was completed using the alerting | reporting means 42. FIG. Here, the notification means 42 is not particularly limited, for example, displaying the completion of boiling on the display unit 41 or notifying the user by voice using a speaker (not shown).

As described above, the amount of change per predetermined time of the input current correction value (ratio of the input current to the primary voltage value) is set in a state in which the drive frequency of the inverter circuit 23 is fixed in the water heating mode for setting the water boiling operation. Then, when the amount of change per predetermined time becomes equal to or less than the predetermined value, the notification means 42 notifies the fact that the boiling has been completed.
For this reason, even if the AC voltage value of the AC power supply 21 changes, the completion of boiling of water can be detected with high accuracy, and a highly reliable induction heating cooker can be obtained. In addition, a user-friendly induction heating cooker can be obtained.

(Protection control operation)
Next, the protection control operation during the above-described control operation in the hot water mode 1 or the hot water mode 2 will be described.
When the control unit 45 obtains a change amount (time change) per predetermined time of the DC voltage (primary voltage) detected by the primary voltage detection means 35, and the change amount per predetermined time becomes a predetermined upper limit value or more. That is, when a change (increase or decrease) exceeds a predetermined upper limit value, the hot water heating mode is canceled and the drive of the inverter circuit 23 is controlled to reduce the high frequency power (thermal power) supplied to the heating coil 11a, or The supply of high-frequency power to the heating coil 11a is stopped.
The information on the predetermined upper limit value may be set in the control unit 45 in advance or may be input from the operation unit 40 or the like.

  And the control part 45 alert | reports that the protection control operation | movement was performed using the alerting | reporting means 42. FIG. Here, the notification means 42 is not particularly limited, for example, displaying on the display unit 41 or notifying the user by voice using a speaker (not shown).

  Thus, when the amount of change per predetermined time of the DC voltage (primary voltage) detected by the primary voltage detection means 35 is equal to or greater than a predetermined upper limit value, the high-frequency power (thermal power) supplied to the heating coil 11a is reduced. Therefore, an induction heating cooker with high safety (reliability) can be obtained.

When the controller 45 determines that the kettle has been completed, the fixed driving frequency is released, the driving frequency of the inverter circuit 23 is increased, the input current is decreased, and the high-frequency power supplied to the heating coil 11a. You may make it reduce (thermal power). In the case of boiling water (boiling water), even if the heating power is increased more than necessary, the water temperature does not become 100 ° C. or higher, so that the water temperature can be maintained even if the driving frequency is increased to lower the heating power.
Thus, when the amount of change per predetermined time of the input current correction value is equal to or less than the predetermined value, the drive of the inverter circuit 23 is controlled to reduce the high frequency power supplied to the heating coil 11a. Energy can be saved by reducing power.

(Configuration example of another drive circuit)
Next, an example using another drive circuit will be described.
FIG. 8 is a diagram illustrating another drive circuit of the induction heating cooker according to the first embodiment.
The drive circuit 50 shown in FIG. 8 is obtained by adding a resonance capacitor 24b to the configuration shown in FIG. Other configurations are the same as those in FIG. 2, and the same parts are denoted by the same reference numerals.

  As described above, since the resonance circuit is configured by the heating coil 11a and the resonance capacitor, the capacity of the resonance capacitor is determined by the maximum heating power (maximum input power) required for the induction heating cooker. In the drive circuit 50 shown in FIG. 8, by connecting the resonant capacitors 24a and 24b in parallel, the respective capacities can be halved, and an inexpensive control circuit can be obtained even when two resonant capacitors are used. .

  Further, by arranging the coil current detection means 25b on the resonance capacitor 24a side of the resonance capacitors connected in parallel, the current flowing through the coil current detection means 25b becomes half of the current flowing through the heating coil 11a. The capacity coil current detection means 25b can be used, a small and inexpensive control circuit can be obtained, and an inexpensive induction heating cooker can be obtained.

  In the above description, the method for controlling the thermal power by changing the drive frequency is described. However, the method for controlling the thermal power by changing the on-duty (on / off ratio) of the switching element of the inverter circuit 23 is used. Also good.

  In the first embodiment, the input current correction value is calculated by dividing the input current detected by the input current detection means 25a by the DC voltage (primary voltage) detected by the primary voltage detection means 35. As described above, the present invention is not limited to this, and the system is not particularly limited as long as the system corrects the input current with the primary voltage (for example, a system using a coefficient or a calculation formula).

  In the first embodiment, the example in which the change amount of the input current detected by the input current detection unit 25a is detected has been described. However, the change amount of the coil current detected by the coil current detection unit 25b instead of the input current. May be detected, or the amount of change in both the input current and the coil current may be detected.

  In the first embodiment, the half-bridge inverter circuit 23 has been described. However, a configuration using a full-bridge inverter or a single-voltage resonance inverter may be used.

  Furthermore, although the method of using the relationship between the coil current and the primary current in the load determination of the pot material has been described, a method of determining the load by detecting the resonance voltage at both ends of the resonance capacitor may be used. It doesn't matter.

Embodiment 2. FIG.
In the second embodiment, details of the drive circuit 50 in the first embodiment will be described.

FIG. 9 is a diagram illustrating a part of the drive circuit of the induction heating cooker according to the second embodiment. In FIG. 9, only a part of the configuration of the drive circuit 50 of the first embodiment is illustrated.
As shown in FIG. 9, the inverter circuit 23 includes two switching elements (IGBTs 23a and 23b) connected in series between the positive and negative buses, and diodes 23c and 23d connected in antiparallel to the switching elements, respectively. One set of arms is provided.

The IGBT 23 a and the IGBT 23 b are driven on and off by a drive signal output from the control unit 45.
The control unit 45 turns off the IGBT 23b while turning on the IGBT 23a, turns on the IGBT 23b while turning off the IGBT 23a, and outputs a drive signal that turns on and off alternately.
Thereby, the half bridge inverter which drives the heating coil 11a is comprised by IGBT23a and IGBT23b.

  The IGBT 23a and the IGBT 23b constitute a “half-bridge inverter circuit” in the present invention.

  The control unit 45 inputs a high-frequency drive signal to the IGBT 23a and the IGBT 23b according to the input power (thermal power), and adjusts the heating output. The drive signal output to the IGBT 23a and the IGBT 23b is variable in a drive frequency range higher than the resonance frequency of the load circuit constituted by the heating coil 11a and the resonance capacitor 24a, and the current flowing through the load circuit is applied to the load circuit. It is controlled to flow with a lagging phase compared to the voltage to be transmitted.

  Next, the operation of controlling the input power (thermal power) based on the drive frequency and on-duty ratio of the inverter circuit 23 will be described.

FIG. 10 is a diagram illustrating an example of a drive signal of the half bridge circuit according to the second embodiment. FIG. 10A shows an example of a drive signal for each switch in the high thermal power state. FIG. 10B is an example of the drive signal of each switch in the low thermal power state.
The control unit 45 outputs a high-frequency drive signal higher than the resonance frequency of the load circuit to the IGBT 23 a and the IGBT 23 b of the inverter circuit 23.
By varying the frequency of the drive signal, the output of the inverter circuit 23 increases or decreases.

For example, as shown in FIG. 10A, when the drive frequency is lowered, the frequency of the high-frequency current supplied to the heating coil 11a approaches the resonance frequency of the load circuit, and the input power to the heating coil 11a increases. .
Further, as shown in FIG. 10B, when the drive frequency is increased, the frequency of the high-frequency current supplied to the heating coil 11a is separated from the resonance frequency of the load circuit, and the input power to the heating coil 11a is reduced. .

Furthermore, the control unit 45 controls the application time of the output voltage of the inverter circuit 23 by changing the on-duty ratio of the IGBT 23a and the IGBT 23b of the inverter circuit 23, along with the control of the input power by changing the drive frequency described above, It is also possible to control the input power to the heating coil 11a.
When increasing the thermal power, the ratio (on duty ratio) of the on-time of the IGBT 23a (the off-time of the IGBT 23b) in one cycle of the drive signal is increased to increase the voltage application time width in one cycle.
When reducing the thermal power, the ratio (on duty ratio) of the on-time of the IGBT 23a (the off-time of the IGBT 23b) in one cycle of the drive signal is reduced to reduce the voltage application time width in one cycle.

In the example of FIG. 10A, the ratio between the ON time T11a of the IGBT 23a (the OFF time of the IGBT 23b) and the OFF time T11b of the IGBT 23a (the ON time of the IGBT 23b) in one cycle T11 of the drive signal is the same (on duty ratio). Is 50%).
In the example of FIG. 10B, the ratio between the ON time T12a of the IGBT 23a (the OFF time of the IGBT 23b) and the OFF time T12b of the IGBT 23a (the ON time of the IGBT 23b) in one cycle T12 of the drive signal is the same (ON The case where the duty ratio is 50%) is illustrated.

When determining the amount of change per predetermined time of the input current correction value described in the first embodiment, the control unit 45 performs the IGBT 23a and IGBT 23b of the inverter circuit 23 in a state where the drive frequency of the inverter circuit 23 is fixed. The on-duty ratio is fixed.
Thereby, the amount of change per predetermined time of the input current correction value can be obtained in a state where the input power to the heating coil 11a is constant.

Embodiment 3 FIG.
In the third embodiment, an inverter circuit 23 using a full bridge circuit will be described.
FIG. 11 is a diagram illustrating a part of the drive circuit of the induction heating cooker according to the third embodiment. In FIG. 11, only the differences from the drive circuit 50 of the first and second embodiments are illustrated.
In the third embodiment, two heating coils are provided for one heating port. For example, the two heating coils have different diameters and are arranged concentrically. Here, the heating coil having a small diameter is referred to as an inner coil 11b, and the heating coil having a large diameter is referred to as an outer coil 11c.
In addition, the number and arrangement | positioning of a heating coil are not limited to this. For example, the structure which arrange | positions a some heating coil around the heating coil arrange | positioned in the center of a heating port may be sufficient.

  The inverter circuit 23 includes three arms each composed of two switching elements (IGBT) connected in series between the positive and negative buses and diodes connected to the switching elements in antiparallel. Hereinafter, one of the three sets of arms is called a common arm, and the other two sets are called an inner coil arm and an outer coil arm.

The common arm is an arm connected to the inner coil 11b and the outer coil 11c, and includes an IGBT 232a, an IGBT 232b, a diode 232c, and a diode 232d.
The inner coil arm is an arm to which the inner coil 11b is connected, and includes an IGBT 231a, an IGBT 231b, a diode 231c, and a diode 231d.
The outer coil arm is an arm to which the outer coil 11c is connected, and includes an IGBT 233a, an IGBT 233b, a diode 233c, and a diode 233d.

  The common arm IGBT 232a and IGBT 232b, the inner coil arm IGBT 231a and IGBT 231b, and the outer coil arm IGBT 233a and IGBT 233b are driven on and off by a drive signal output from the control unit 45.

The controller 45 turns off the IGBT 232b while turning on the IGBT 232a of the common arm, turns on the IGBT 232b while turning off the IGBT 232a, and outputs a drive signal that turns on and off alternately.
Similarly, the control unit 45 outputs drive signals for alternately turning on and off the IGBTs 231a and IGBT 231b for the inner coil arms and the IGBTs 233a and IGBT 233b for the outer coil arms.
As a result, the common arm and the inner coil arm constitute a full bridge inverter that drives the inner coil 11b. The common arm and the outer coil arm constitute a full bridge inverter that drives the outer coil 11c.

  The common arm and the inner coil arm constitute a “full bridge inverter circuit” in the present invention. The common arm and the outer coil arm constitute a “full bridge inverter circuit” in the present invention.

The load circuit constituted by the inner coil 11b and the resonance capacitor 24c is connected between the output point of the common arm (the connection point of the IGBT 232a and the IGBT 232b) and the output point of the arm for the inner coil (the connection point of the IGBT 231a and the IGBT 231b). Is done.
The load circuit constituted by the outer coil 11c and the resonance capacitor 24d is connected between the output point of the common arm and the output point of the outer coil arm (the connection point between the IGBT 233a and the IGBT 233b).

The inner coil 11b is a heating coil with a small outer shape wound in a substantially circular shape, and an outer coil 11c is disposed on the outer periphery thereof.
The coil current flowing through the inner coil 11b is detected by the coil current detection means 25c. For example, the coil current detection means 25c detects the peak of the current flowing through the inner coil 11b and outputs a voltage signal corresponding to the peak value of the heating coil current to the control unit 45.
The coil current flowing through the outer coil 11c is detected by the coil current detection means 25d. The peak of the current flowing through the coil current detection means 25d, for example, the outer coil 11c, is detected, and a voltage signal corresponding to the peak value of the heating coil current is output to the control unit 45.

The control unit 45 inputs a high-frequency drive signal to the switching element (IGBT) of each arm according to the input power (thermal power), and adjusts the heating output.
The drive signal output to the switching elements of the common arm and the inner coil arm varies in a drive frequency range higher than the resonance frequency of the load circuit constituted by the inner coil 11b and the resonance capacitor 24c, and flows to the load circuit. Control is performed so that the current flows in a delayed phase compared to the voltage applied to the load circuit.
Further, the drive signal output to the switching elements of the common arm and the outer coil arm can be varied within a drive frequency range higher than the resonance frequency of the load circuit constituted by the outer coil 11c and the resonance capacitor 24d, and the load circuit Control is performed so that the current flowing in the current flows in a delayed phase compared to the voltage applied to the load circuit.

  Next, the control operation of the input power (thermal power) due to the phase difference between the arms of the inverter circuit 23 will be described.

FIG. 12 is a diagram illustrating an example of a drive signal of the full bridge circuit according to the third embodiment.
FIG. 12A is an example of the drive signal of each switch and the energization timing of each heating coil in the high thermal power state.
FIG. 12B is an example of the drive signal of each switch and the energization timing of each heating coil in the low thermal power state.
The energization timings shown in FIGS. 12A and 12B are related to the potential difference between the output points of each arm (connection point between IGBT and IGBT). A state where the output point of the common arm is lower than the output point of the arm is indicated by “ON”. Further, the state where the output point of the common arm is higher than the output point of the inner coil arm and the output point of the outer coil arm and the state of the same potential are indicated by “OFF”.

As shown in FIG. 12, the control unit 45 outputs a high-frequency drive signal higher than the resonance frequency of the load circuit to the IGBT 232a and the IGBT 232b of the common arm.
Further, the control unit 45 outputs a drive signal having a phase advanced from the drive signal of the common arm to the IGBT 231a and IGBT 231b of the inner coil arm and the IGBT 233a and IGBT 233b of the outer coil arm. In addition, the frequency of the drive signal of each arm is the same frequency, and the on-duty ratio is also the same.

The positive bus potential or the negative bus potential, which is the output of the DC power supply circuit, is switched at a high frequency and output at the output point of each arm (the connection point between the IGBT and IGBT) in accordance with the on / off state of the IGBT and IGBT. As a result, a potential difference between the output point of the common arm and the output point of the inner coil arm is applied to the inner coil 11b. Further, a potential difference between the output point of the common arm and the output point of the outer coil arm is applied to the outer coil 11c.
Therefore, the high frequency voltage applied to the inner coil 11b and the outer coil 11c can be adjusted by increasing / decreasing the phase difference between the driving signal to the common arm and the driving signals to the inner coil arm and the outer coil arm. The high frequency output current and the input current flowing through the inner coil 11b and the outer coil 11c can be controlled.

When increasing the thermal power, the phase α between the arms is increased to increase the voltage application time width in one cycle. The upper limit of the phase α between the arms is in the case of reverse phase (phase difference 180 °), and the output voltage waveform at this time is almost a rectangular wave.
In the example of FIG. 12A, the case where the phase α between the arms is 180 ° is illustrated. Further, the case where the on-duty ratio of the drive signal of each arm is 50%, that is, the case where the ratio of the on-time T13a and the off-time T13b in one cycle T13 is the same is illustrated.
In this case, the energization on time width T14a and the energization off time width T14b of the inner coil 11b and the outer coil 11c in one cycle T14 of the drive signal have the same ratio.

When lowering the thermal power, the phase α between the arms is made smaller than in the high thermal power state to reduce the voltage application time width in one cycle. Note that the lower limit of the phase α between the arms is set to a level at which an excessive current does not flow into the switching element and breaks due to the phase of the current flowing in the load circuit at the time of turn-on, for example.
In the example of FIG. 12B, the case where the phase α between the arms is made smaller than that in FIG. The frequency and on-duty ratio of the drive signal for each arm are the same as in FIG.
In this case, the energization on time width T14a of the inner coil 11b and the outer coil 11c in one cycle T14 of the drive signal is a time corresponding to the phase α between the arms.
Thus, the input power (thermal power) to the inner coil 11b and the outer coil 11c can be controlled by the phase difference between the arms.

  In the above description, the case where both the inner coil 11b and the outer coil 11c are heated is described. However, the driving of the inner coil arm or the outer coil arm is stopped, and either the inner coil 11b or the outer coil 11c is stopped. Only one of them may be heated.

When the controller 45 determines the amount of change per predetermined time of the input current correction value described in the first embodiment, in a state where the drive frequency of the inverter circuit 23 is fixed, the phase α between the arms, The on-duty ratio of the switching element of each arm is fixed. Other operations are the same as those in the first embodiment.
Thereby, the change amount per predetermined time of the input current correction value can be obtained in a state where the input power to the inner coil 11b and the outer coil 11c is constant.

In the third embodiment, the coil current flowing through the inner coil 11b and the coil current flowing through the outer coil 11c are detected by the coil current detecting means 25c and the coil current detecting means 25d, respectively.
Therefore, when both the inner coil 11b and the outer coil 11c are heated, even if either the coil current detection means 25c or the coil current detection means 25d cannot detect the coil current value due to a failure or the like. The amount of change per predetermined time in the correction value of the coil current can be detected by the other detection value.
In addition, the control unit 45 changes the amount of change in the correction value of the coil current detected by the coil current detection unit 25c per predetermined time and the change in the correction value of the coil current detected by the coil current detection unit 25d per predetermined time. Each determination operation described in the first embodiment may be performed using the larger one of the change amounts. In addition, each determination operation described in the first embodiment may be performed using an average value of each change amount.
By performing such control, even if the detection accuracy of either the coil current detection means 25c or the coil current detection means 25d is low, the amount of change per predetermined time of the correction value of the coil current can be more accurately determined. Can be sought.

  In Embodiments 1 to 3, the IH cooking heater has been described as an example of the induction heating cooker of the present invention, but the present invention is not limited to this. The present invention can be applied to any induction heating cooker that employs an induction heating method, such as a rice cooker that performs cooking by induction heating.

  DESCRIPTION OF SYMBOLS 1 1st heating port, 2nd heating port, 3rd heating port, 4 Top plate, 5 To-be-heated object, 11 1st heating means, 11a Heating coil, 12 2nd heating means, 13 1st heating port Three heating means, 21 AC power supply, 22 DC power supply circuit, 22a diode bridge, 22b reactor, 22c smoothing capacitor, 23 inverter circuit, 23a, 23b IGBT, 23c, 23d diode, 24a, 24b resonance capacitor, 25a input current detection means , 25b Coil current detection means, 30 Temperature detection means, 35 Primary voltage detection means, 35a, 35b Resistance, 40a-40c Operation part, 41a-41c Display part, 42 Notification means, 45 Control part, 50 Drive circuit, 100 Induction heating Cooker, 11b inner coil, 11c outer coil, 24c, 24d resonant capacitor, 25 c, 25d Coil current detection means, 231a, 231b, 232a, 232b, 233a, 233b IGBT, 231c, 231d, 232c, 232d, 233c, 233d diode.

Claims (11)

A heating coil for inductively heating an object to be heated;
A DC power circuit that converts AC voltage from the AC power source into DC voltage;
A drive circuit that converts a DC voltage from the DC power supply circuit into high-frequency power and supplies the power to the heating coil;
A controller that controls driving of the driving circuit and controls high-frequency power supplied to the heating coil;
The controller is
The primary voltage value corresponding to the AC voltage from the AC power supply or the DC voltage of the DC power supply circuit, the input current to the drive circuit, and the coil current flowing through the heating coil in a state where the drive frequency of the drive circuit is fixed An induction heating cooker that detects a temperature change of the object to be heated in accordance with a change amount of a value based on at least one of the current values. Load determining means for performing load determination processing of the heating coil,
The controller is
The induction heating cooker according to claim 1, wherein the drive circuit is driven in accordance with a determination result of the load determination means. The controller is
The temperature change of the object to be heated is detected according to the amount of change in the ratio of the current value of at least one of the input current and the coil current to the primary voltage value. The induction heating cooker described in 1. The controller is
When the amount of change in the primary voltage value is equal to or greater than an upper limit value,
The drive of the said drive circuit is controlled, the high frequency electric power supplied to the said heating coil is reduced, or the supply of the high frequency electric power to the said heating coil is stopped. The induction heating cooker according to one item. The controller is
When the amount of change in a state where the drive frequency of the drive circuit is fixed is equal to or less than a threshold value,
The induction heating cooker according to any one of claims 1 to 4, wherein driving of the drive circuit is controlled to vary high-frequency power supplied to the heating coil. The controller is
The induction heating cooker according to claim 4 or 5, wherein the high frequency power supplied to the heating coil is varied by varying a driving frequency of the driving circuit or an on-duty ratio of the switching element. An operation unit for selecting an operation mode;
An informing means,
The controller is
When the water heating mode for setting the water heating operation of water is selected as the operation mode, the driving circuit is driven,
The notification means that the boiling is completed when the amount of change in a state where the drive frequency of the drive circuit is fixed is equal to or less than a threshold value. The induction heating cooker described in 1. The load determination means includes
The induction heating cooker according to claim 2 , wherein a load determination process of the object to be heated is performed based on a correlation between the input current and the coil current. The controller is
The induction heating cooker according to any one of claims 1 to 8, wherein an on-duty ratio of a switching element of the drive circuit is fixed in a state where the drive frequency of the drive circuit is fixed. . The drive circuit is
A full-bridge inverter circuit having at least two arms in which two switching elements are connected in series;
The controller is
In the state where the driving frequency of the switching element of the full bridge inverter circuit is fixed, the driving phase difference of the switching element between the two arms and the on-duty ratio of the switching element are fixed. The induction heating cooker according to any one of claims 1 to 8, wherein The drive circuit is
It is composed of a half-bridge inverter circuit having an arm in which two switching elements are connected in series,
The controller is
The state which fixed the on-duty ratio of the said switching element in the state which fixed the drive frequency of the said switching element of the said half-bridge inverter circuit, It is any one of Claims 1-8 characterized by the above-mentioned. Induction heating cooker.

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