JP2011090985A - Induction cooking device - Google Patents

Abstract

In an induction heating cooker having a microcomputer that performs sequence control, when an instantaneous power failure occurs, the function of the microcomputer stops due to a drop in power supply, and the sequence control stops halfway.
By detecting the output voltage of the power supply of the microcomputer and when the voltage drops due to an instantaneous power failure, the power supply of the load other than the microcomputer is shut off, the voltage drop is moderated, and the function of the microcomputer is maintained long. Even if an instantaneous power failure occurs in the middle of the sequence control, heating is stopped, and the display is turned off, the sequence control state is maintained. Therefore, the sequence control can be resumed after returning from the instantaneous power failure.
[Selection] Figure 2

Description

  The present invention relates to an induction heating cooker, and particularly to a power failure detection device.

  Conventionally, this type of induction heating cooker converts commercial power to DC power and supplies power to a microcomputer (hereinafter referred to as a microcomputer) or an electronic circuit. When commercial power is momentarily interrupted, supply of commercial power stops. The DC power supply also has a function to detect an instantaneous power failure in order to prevent the voltage from dropping and the microcomputer and the electronic circuit from losing their functions.

  When an instantaneous power failure is detected, the microcomputer suppresses the current used by the electronic circuit, moderates the voltage drop of the DC power supply, and maintains the operation of the microcomputer as long as possible.

  Conventionally, as a detection method of this type of instantaneous power failure, a zero cross point of a commercial power source is detected to generate a zero cross pulse, and the instantaneous power failure is detected based on the presence or absence of the zero cross pulse (see, for example, Patent Document 1).

  FIG. 6 is a diagram showing the relationship between the commercial power supply and the zero cross pulse of the conventional instantaneous power failure detection device described in Patent Document 1.

  As shown in FIG. 6, when the detecting means detects the zero cross point of the commercial power supply 101, a zero cross pulse 102 is generated, the presence or absence of the zero cross pulse 102 is determined every half cycle of the commercial power supply, and an instantaneous power failure occurs when there is no zero cross pulse 102. Is determined to have occurred.

  FIG. 7 is a circuit diagram of a conventional power failure detection device for a DC brushless motor described in Patent Document 2.

  In FIG. 7, the power source from the AC power source 103 is rectified and smoothed, and the voltage of the capacitor 104 is changed to the first DC power source, and converted from the first DC power source to the second DC power source 105.

The three-phase DC brushless motor 106 is driven and controlled by an inverter device 107. The inverter device 107 includes an inverter circuit 108 and a microcomputer 109.
The capacitor 105a is a capacitor connected to the output of the second DC power source 105, and the device 110 is an electronic circuit excluding the microcomputer 109, such as a circuit connected to the input / output of the microcomputer 109 or other load driven by the circuit. All circuits and electric circuits are included.

  The device 110 and the microcomputer 109 are operated by the second DC power source 105. Therefore, when the voltage of the first DC power supply 104 decreases, the output voltage of the second DC power supply 105 cannot operate the microcomputer 109 and the device 110.

The voltage monitoring device 111 divides the DC voltage of the capacitor 104 with a resistor and sends the voltage information to the microcomputer 109.
The microcomputer 109 controls the output terminal of the microcomputer 109 so that the current of the device 110 decreases when the voltage information becomes a predetermined value or less. If the three-phase DC brushless motor 106 is rotating, the microcomputer 109 stops supplying current to the three-phase DC brushless motor 106.

JP 61-129581 A JP 2006-296154 A

  However, the configuration of Patent Document 1 requires detection means for detecting a zero cross point for each of a plurality of microcomputers and control means, which is costly and secures a space for mounting a circuit for the detection means. There is a need to.

  Moreover, since the circuit which detects a zero cross point can detect a zero cross point only for every half cycle of a commercial power supply, it has the subject that there is a time difference after a power failure occurs until a power failure is detected.

  In the configuration of Patent Document 2, in the case of a device composed of a plurality of microcomputers, if the power supply to all the microcomputers is continued during a power failure, the output voltage of the first DC power supply decreases rapidly, and the microcomputer cannot operate. End up.

  In addition, when a power failure is detected by a microcomputer and the other power supply is notified by communication to the other microcomputer and the power supply of the load controlled by each microcomputer is cut off, the power supply of the load is cut off after the power failure occurs. Since it takes a long time to communicate, a time difference occurs, and the output voltage of the first DC power source decreases during that time.

  The present invention solves the above-mentioned conventional problem, and when the instantaneous power failure is resolved when the output voltage of the DC power source obtained by rectifying and smoothing the commercial power source is moderated and the microcomputer is prevented from being completely turned off. It is an object of the present invention to provide an induction heating cooker that is easy to use by resuming the continuation of the previous sequence control.

  In order to solve the conventional problems, an induction heating cooker according to the present invention includes a heating unit having a heating coil, a top plate provided above the heating coil and on which an object to be heated is placed, and the heating coil. An inverter for supplying a high frequency current to the first conversion circuit, a first conversion circuit for converting a commercial power supply to a first DC power supply, a second conversion circuit for converting the first DC power supply to a second DC power supply, A third conversion circuit for converting the first DC power source to a third DC power source; a load 1 supplied with power from the first or second DC power source; and a power source from the first or third DC power source. A load 2 to be supplied, a master microcomputer supplied with power from the second DC power supply, a slave microcomputer supplied with power from the third DC power supply, the load 1, the master microcomputer, and the inverter trout A control unit and a slave control unit including the load 2 and the slave microcomputer, the master control unit and the slave control unit include a detection circuit that detects a voltage of the first DC power supply, and the master microcomputer When the voltage drops below level 1, the operation of the inverter is stopped and the power supply to the load 1 is cut off. When the voltage drops below the level 1, the slave microcomputer cuts off the power supply to the load 2. is there. As a result, when the output voltage is input from the detection circuit that detects the output voltage of the first DC power supply to the master microcomputer and the slave microcomputer, and the output voltage falls below a predetermined level, the supply of commercial power is stopped and the power supply is in a power failure state. As a result, the slave microcomputer cuts off the power supply to the load 2, suppresses the power consumption of the first DC power supply, and moderates the decrease in the output voltage of the first DC power supply. This will slow down the voltage and prevent the master microcomputer from turning off completely.

From the above, when the master microcomputer performs sequence control, the master microcomputer continues to operate even if the power supply to the load is cut off due to an instantaneous power failure. You can resume.

  In addition, in the case of an induction heating cooker in which a plurality of microcomputers communicate with each other, if the output voltage of the first DC power supply falls below a predetermined value, the power supply to the microcomputer with the lowest priority among the microcomputers is cut off. Power consumption can be suppressed, and high priority microcomputers can be operated for a long time.

  In the induction heating cooker of the present invention, the detection circuit that detects the output voltage of the first DC power supply has a lower output voltage of the first DC power supply when a power failure occurs, compared to the detection circuit that detects the zero-cross point. Can be detected without time lag, so the power supply to the load can be shut off quickly.

Also, in devices controlled by multiple microcomputers, each microcomputer detects the output voltage of the first DC power supply, so each microcomputer can independently cut off the power supply to the load during a power failure. The load can be disconnected quickly compared to the case where the power supply of the load is cut off by performing communication between the two.
Furthermore, microcomputer functions with high priority are maintained, microcomputers that do not need to maintain the state before a power failure, such as operation switch detection, set a low priority, and when a power failure is detected, the microcomputer function is stopped. As a result, the functions of the high priority microcomputer can be maintained for a long time.

The block diagram of the induction heating cooking appliance in Embodiment 1 of this invention The figure which shows the state of the detection circuit and microcomputer of the induction heating cooking appliance in Embodiment 1 of this invention The block diagram of the induction heating cooking appliance in Embodiment 2, 3 of this invention The figure which shows the state of the detection circuit and microcomputer of the induction heating cooking appliance in Embodiment 2 of this invention The figure which shows the state of the detection circuit and microcomputer of the induction heating cooking appliance in Embodiment 3 of this invention The figure which shows the relation between the commercial power source and the zero cross pulse of the conventional instantaneous power failure detection device Circuit diagram of conventional DC brushless motor power failure detection device

  An induction heating cooker according to a first aspect of the present invention includes a heating means having a heating coil, a top plate provided above the heating coil and on which an object to be heated is placed, and an inverter for supplying a high-frequency current to the heating coil. A first conversion circuit for converting a commercial power supply into a first DC power supply, a second conversion circuit for converting the first DC power supply into a second DC power supply, and a third DC power supply as a third DC power supply. A third conversion circuit for converting to a DC power source, a load 1 powered from the first or second DC power source, a load 2 powered from the first or third DC power source, A master microcomputer powered from a second DC power supply, a slave microcomputer powered from the third DC power supply, the load 1, the master microcomputer, a master control unit having the inverter, the load 2, and Above A slave control unit having a slave microcomputer, wherein the master control unit and the slave control unit include a detection circuit that detects a voltage of the first DC power supply, and the master microcomputer is configured to detect the inverter when the voltage becomes level 1 or less. And the power supply to the load 1 is cut off, and the slave microcomputer cuts off the power supply to the load 2 when the voltage becomes level 1 or less.

As a result, it is possible to lengthen the time until the functions of the master microcomputer and slave microcomputer are stopped due to a power failure, and to prevent the microcomputer from being reset due to an instantaneous power failure. Thus, even if an instantaneous power failure occurs during sequence control such as automatic cooking, automatic cooking can be continued while maintaining the state before the power failure, and an easy-to-use induction heating cooker can be provided.

  In a second aspect of the invention, in particular, in the first aspect of the invention, the master microcomputer stops the operation of the inverter when the voltage becomes level 1 or less, and when the voltage becomes level 2 or less, which is less than level 1, the power supply to the load 1 The power supply is cut off, and the slave microcomputer cuts off the power supply to the load 2 when the voltage becomes level 1 or lower, so that the load with high priority among the loads maintains the function even during the momentary power failure. Since a low load stops the function, only necessary functions can be operated while suppressing the power consumption of the device.

  In a third aspect of the invention, in particular, in the first or second aspect of the invention, the slave microcomputer cuts off the power supply to the load 2 when the voltage becomes level 1 or less, and when the voltage becomes level 2 or less, which is smaller than level 1. By shutting off the power supply to the slave microcomputer, only the microcomputer with higher priority among the microcomputers will maintain its function during the momentary power failure, and the microcomputer with lower priority will stop functioning. It is possible to prevent the resetting of the microcomputer due to an instantaneous power failure by increasing the time until the function of the microcomputer with high priority is stopped.

  In a fourth aspect of the invention, in particular, in the first to third aspects of the invention, the slave microcomputer is provided with a load 3 that is supplied with power from the first or third DC power source and consumes more power than the load 2, and the slave microcomputer The microcomputer cuts off the power supply to the load 3 when the voltage is lower than level 1, and cuts off the power supply to the load 2 when the voltage is lower than level 2 below the level 1, thereby reducing the power consumption in the load. By stopping the function of a large load immediately after detecting a power failure, the time from the occurrence of a power failure to the stop of the microcomputer function can be lengthened to prevent the microcomputer from being reset by an instantaneous power failure.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the present embodiment.

(Embodiment 1)
FIG. 1 is a block diagram of an induction heating cooker according to the first embodiment of the present invention, and FIG. 2 is a diagram showing a state of a detection circuit and a microcomputer of the induction heating cooker according to the first embodiment of the present invention. .

  In FIG. 1, a current of a commercial power source 1 is smoothed by a rectifier diode 2 and a capacitor 3 and converted into a first DC power source 5 by a switching transformer 4, and the first DC power source 5 is regulated by a regulator. 7 and a second conversion circuit 9 for converting to a second DC power supply 8.

  In the present embodiment, the voltage of the first DC power supply 5 is 20V, and the voltage of the second DC power supply 18 is 5V. The regulator 7 stably supplies an output voltage of 5 V when the input voltage is 10 V or more. The master microcomputer 10 operates normally when the input voltage is 3V or higher.

  The master microcomputer 10 supplied with power from the second DC power supply 8 controls the inverter 12 that supplies high-frequency current to the heating coil 11.

  The pan 14 placed on the top plate 13 made of heat-resistant tempered glass generates heat due to induction current generated by the high-frequency current flowing through the heating coil 11 below the top plate 13.

In addition, the radial heater 15 that generates heat when an AC current is applied to the nichrome wire is controlled by the master microcomputer 10 through the relay 16 supplied with power from the first DC power supply 5. . The relay 16 is a load 1.

  Next, there is a third conversion circuit 19 that inputs the first DC power supply 5 to the regulator 17 and converts it to the third DC power supply 18. In the present embodiment, the output voltage of the third DC power supply 18 is 5V.

  The regulator 17 stably supplies an output voltage of 5 V when the input voltage is 10 V or more. The slave microcomputer 20 operates normally when the input voltage is 3V or higher.

  The slave microcomputer 20 supplied with power from the third DC power supply 18 energizes a light emitting element 22 such as a buzzer 21 supplied with power from the first DC power supply 5 and an LED supplied with power from the third DC power supply 18. Control. The buzzer 21 is the load 2 and the light emitting element 22 is the load 3.

  In addition to the relay 16, the master microcomputer 10 performs voltage detection of parameters necessary for temperature sensor and fan energization control and switch and inverter control, and loads are supplied from the first DC power supply 5 or the second DC power supply 8. Power is supplied (not shown).

  The master microcomputer 10 performs sequence control such as automatic cooking from information of a temperature sensor and a timer in the microcomputer (not shown).

  In addition to the buzzer 21 and the light emitting element 22, the slave microcomputer 20 detects a speaker for generating sound, an LCD, a high frequency generation circuit for detecting an electrostatic touch switch, and a voltage of the switch. Power is supplied from the fifth or third DC power supply 18 (not shown).

  The master microcomputer 10 and the slave microcomputer 20 transmit and receive each other.

  The rectifier diode 2, the capacitor 3, the switching transformer 4, the first conversion circuit 6, the regulator 7, the second conversion circuit 9, the master microcomputer 10, the inverter 12, and the relay 16 serve as the master control unit 23, and the regulator 17, the third The conversion circuit 19, the slave microcomputer 20, the buzzer 21, and the light emitting element 22 are assumed to be a slave control unit 24.

  The first DC power supply 5 is supplied to the master control unit 23 and the slave control unit 24.

  The master control unit 23 includes a detection circuit 25 that detects the voltage of the first DC power supply 5. The detection circuit 25 includes a Zener diode 25 a having a Zener voltage of 15 V and a transistor 25 b for inputting a detection result to the master microcomputer 10.

  About the induction heating cooking appliance comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

  A zener diode 25 a of the detection circuit 25 is connected between the first DC power supply 5 and the GND 26.

  Since the voltage of the first DC power supply 5 is 20V, a reverse current normally flows through the Zener diode 25a, the transistor 25b is turned on, and a 0V Lo signal is input to the master microcomputer 10. When the Lo signal is input, the master microcomputer 10 determines that the first DC power supply 5 is normal.

When a power failure occurs and the supply of the commercial power supply 1 is stopped, the voltage of the first DC power supply 5 decreases and 15V
Below. Then, since the Zener diode 25a does not pass a reverse current, the transistor 25b is turned off, and a 5V Hi signal is input to the master microcomputer 10. When the Hi signal is input, the master microcomputer 10 determines that the first DC power supply 5 is a power failure.

  The slave control unit 24 also has a similar detection circuit 27, and includes a Zener diode 27a having a Zener voltage of 15V and a transistor 27b for inputting the detection result to the slave microcomputer 20. The operation is the same as that of the detection circuit 25.

  The operation of the device when the supply of the commercial power supply 1 is stopped will be described below.

  When the supply of the commercial power supply 1 is stopped and no reverse current flows through the Zener diode 27a, the diode 27b is turned off and the Hi signal is input to the slave microcomputer 20. The slave microcomputer 20 determines that a power failure has occurred, and cuts off the power supply to the buzzer 21 and the light emitting element 22.

  FIG. 2 shows an operation when the supply of the commercial power supply 1 is stopped between T11 and T14. T21 to T24 are the same time as T11 to T14.

  As shown in FIG. 2A, without the detection circuit, when the detection circuit 27 is not provided, when the supply of the commercial power supply 1 is stopped at T11, the voltage of the first DC power supply 5 starts to decrease. The second DC power supply 8 maintains 5 V until it reaches 10 V at T12, but the voltage of the second DC power supply 8 starts to decrease when the voltage drops below 10 V.

  The master microcomputer 10 is turned off when the second DC power supply 8 is 3V or less, and the slave microcomputer 20 is turned off when the third DC power supply 18 is 3V or less. Therefore, the two microcomputers are turned off at T13 and turned off. The inverter controlled by 10, the buzzer 21 that controls energization by the slave microcomputer 20 turned off, and the light emitting element 22 are also turned off.

  When the commercial power supply 1 resumes supply at T14, the voltages of the first DC power supply 5, the second DC power supply 8, and the third DC power supply 18 rise, and at T16, the second DC power supply 8 and the third DC power supply are increased. When the voltage of the power supply 18 exceeds 3V, the master microcomputer 10 and the slave microcomputer 20 are turned on.

  However, since the master microcomputer 10 is once turned off and reset, the sequence control before turning off is not continued.

  On the other hand, when the detection circuit 27 is present as shown in FIG. 2B, with the detection circuit 27, the supply of the commercial power supply 1 is stopped at T21, and the voltage of the first DC power supply 5 is reduced, but the voltage is 15V. When a power failure is detected, the slave microcomputer 20 cuts off the energization of the buzzer 21 and the light emitting element 22. The master microcomputer 10 turns off the inverter 12.

  Since the load to which the first DC power supply 5 supplies power is turned off, the power consumption is reduced and the voltage drop of the first DC power supply 5 is moderated.

  As in the case without the detection circuit in FIG. 2A, when the voltage of the first DC power supply 5 falls below 10 V at T23, the voltage of the second DC power supply 8 starts to decrease. Since the decrease is gradual, the time from T21 to T23 is longer than the time from T11 to T12.

  Thereafter, since the voltage of the second DC power supply 8 does not fall below 3 V until the supply of the commercial power supply 1 is resumed at T24, the master microcomputer 10 is not turned off, and the sequence control information is continued.

  When the voltage of the first DC power supply exceeds 15 V at T25, the master microcomputer 10 determines that the power failure has been resolved, turns on the inverter, and resumes the sequence control before the power failure. When the slave microcomputer 20 determines that the power failure has been resolved, the energization of the buzzer 21 and the light emitting element 22 is resumed.

  When the detection circuit 27 is present, the load is cut off and the power consumption is reduced, so that the time from when the power failure starts until the master microcomputer 10 is turned off can be extended, and a short power failure occurs during the sequence control. When this happens, the sequence control state before the power failure is maintained without disappearing in the middle, so that the sequence control can be resumed after the power failure is restored.

  When the master microcomputer 10 is turned off due to a power failure, it is impossible to remember how far the automatic cooking sequence such as rice cooking has progressed, and even if the power failure is resolved, the sequence cannot be resumed from the state before the power failure, so wasted food However, if the master microcomputer 10 is not turned off even if a short-time power failure occurs, the waste of the cooked product does not come out, and an easy-to-use induction heating cooker can be provided.

(Embodiment 2)
FIG. 3 is a block diagram of the induction heating cooker in the second embodiment of the present invention, and FIG. 4 is a diagram showing the state of the detection circuit and microcomputer of the induction heating cooker in the second embodiment of the present invention. .

  The same parts as those of the first embodiment are denoted by the same reference numerals, description thereof is omitted, and only different parts will be described below.

  The master control unit 23 includes a detection circuit 28 that detects the voltage of the first DC power supply 5. The detection circuit 28 includes a Zener diode 28 a having a Zener voltage of 17 V and a transistor 28 b for inputting a detection result to the master microcomputer 10.

  The slave control unit 24 includes a detection circuit 29 that detects the voltage of the first DC power supply 5. The detection circuit 29 includes a Zener diode 29a having a Zener voltage of 17V and a transistor 29b for inputting the detection result to the slave microcomputer 20.

  The operation when the supply of the commercial power source 1 is stopped during T31 to T35 is shown.

  At T31, the supply of the commercial power supply 1 is stopped, and the voltage of the first DC power supply 5 decreases. However, when the voltage becomes 17V and a power failure is detected at T32, the master microcomputer 10 turns off the inverter. In addition, the slave microcomputer 20 first cuts off the energization of the buzzer 21 that consumes more power than the light emitting element 22.

  Thereafter, at T33, when the voltage becomes 15V and a power failure is detected, the slave microcomputer 20 cuts off the power supply to the light emitting element 22. Since the load to which the first DC power supply 5 supplies power is turned off, the power consumption is reduced and the voltage drop of the first DC power supply 5 is moderated. Further, when the load with large power consumption is turned off first, the voltage drop of the first DC power supply 5 becomes more gradual.

  When the voltage of the first DC power supply 5 falls below 10V at T34, the voltage of the second DC power supply 8 also starts to drop, but since the voltage drop of the first DC power supply 5 is gradual, supply of the commercial power supply 1 at T35. The voltage of the second DC power supply 8 does not fall below 3V until the restart is resumed, the master microcomputer 10 is not turned off, and the sequence control is continued.

When the voltage of the first DC power supply 5 exceeds 10V at T36, the slave microcomputer 20 resumes energization of the light emitting element 22, and when it exceeds 17V at T37, energization of the buzzer 21 resumes.

  As described above, the load with higher priority among the loads maintains the function even during the momentary power failure, and the function with lower priority stops the function, so that only necessary functions can be operated while suppressing the power consumption of the equipment. it can.

(Embodiment 3)
FIG. 3 is a block diagram of an induction heating cooker according to the third embodiment of the present invention.

  FIG. 5 is a diagram showing states of the detection circuit and the microcomputer of the induction heating cooker according to the third embodiment of the present invention. The same parts as those in the first and second embodiments are denoted by the same reference numerals, description thereof is omitted, and only different parts will be described below.

  The operation when the supply of the commercial power supply 1 is stopped during T41 to T44 is shown.

At T41, the supply of the commercial power supply 1 is stopped, and the voltage of the first DC power supply 5 decreases. However, when the voltage becomes 17V and a power failure is detected, the master microcomputer 10 turns off the inverter.
Further, when the voltage becomes 15 V and a power failure is detected, the slave microcomputer 20 cuts off the power supply by itself and turns off all the loads of the slave control unit 24.
Since the load supplied by the third DC power supply 18 is turned off, the power consumption of the first DC power supply 5 is also reduced, and the voltage drop of the first DC power supply 5 is moderated.

  When the voltage of the first DC power supply 5 falls below 10V at T43, the voltage of the second DC power supply 8 also starts to drop, but since the voltage drop of the first DC power supply 5 is gradual, supply of the commercial power supply 1 at T44 Since the voltage of the second DC power supply 8 does not fall below 3V until the restart is resumed, the master microcomputer 10 is not turned off and the sequence control is continued.

  When the supply of the commercial power supply 1 is resumed at T44 and it is detected that the voltage of the first DC power supply 5 exceeds 15V, the master microcomputer 10 starts supplying power to the slave microcomputer 20, and the slave microcomputer 20 is turned on.

  If the power supply to the slave microcomputer 20 is cut off during a power failure, the power consumption is further reduced, and even if the power failure time becomes longer, the master microcomputer 10 does not turn off. Automatic cooking can continue after returning.

  The present invention is not limited to the embodiments described above and illustrated in the drawings, and the following modifications or expansions are possible.

  The voltage and detection voltage of each power source are not limited to the numerical values shown in the present embodiment. The load supplied to each power supply is not limited to that shown in this embodiment. One detection circuit 25, 27, 28, and 29 may be provided for either the master control unit or the slave control unit, and the detection result input line may be wired to the other microcomputer.

  As described above, the induction cooking device according to the present invention can maintain the sequence control when recovering from a power failure even if an instantaneous power failure occurs and can store the state before the power failure. Since it can be provided, it can be applied to uses such as washing machines equipped with microcomputers, rice cookers, and electronic devices that perform sequence control.

1 Commercial Power Supply 5 First DC Power Supply 6 First Conversion Circuit 8 Second DC Power Supply 9 Second Conversion Circuit 10 Master Microcomputer 12 Inverter 16 Relay (Load 1)
18 Third DC power supply 19 Third conversion circuit 20 Slave microcomputer 21 Buzzer (load 2)
22 Light Emitting Element (Load 3)
23 Master control unit 24 Slave control unit 25 Detection circuit

Claims (4)

A heating means having a heating coil, a top plate provided above the heating coil and on which an object to be heated is placed, an inverter for supplying a high-frequency current to the heating coil, and a commercial power source converted into a first DC power source A first converter circuit that converts the first DC power source into a second DC power source, and a third converter circuit that converts the first DC power source into a third DC power source. A load 1 supplied with power from the first or second DC power supply, a load 2 supplied with power from the first or third DC power supply, and a master supplied with power from the second DC power supply A microcomputer, a slave microcomputer supplied with power from the third DC power source, the load 1, the master microcomputer, a master controller having the inverter, a load 2 and a slave microcomputer having the slave microcomputer A control unit, and the master control unit and the slave control unit include a detection circuit that detects a voltage of the first DC power supply, and the master microcomputer stops the operation of the inverter when the voltage becomes level 1 or less. In addition, an induction heating cooker that cuts off the power supply to the load 1 and the slave microcomputer cuts off the power supply to the load 2 when the voltage becomes level 1 or less. The master microcomputer stops the operation of the inverter when the voltage becomes level 1 or lower, and cuts off the power supply to the load 1 when the voltage becomes lower than level 2 lower than the level 1, and the slave microcomputer stops the voltage at level 1 The induction heating cooker according to claim 1, wherein the power supply to the load 2 is cut off when it becomes below. 3. The slave microcomputer cuts off power supply to the load 2 when the voltage falls below level 1, and cuts off power supply to the slave microcomputer when the voltage falls below level 2 below the level 1. Induction heating cooker. The slave microcomputer is provided with a load 3 that is supplied with power from the first or third DC power source and consumes more power than the load 2, and the slave microcomputer supplies power to the load 3 when the voltage falls below level 1. The induction heating cooker according to any one of claims 1 to 3, wherein the supply is cut off and the power supply to the load 2 is cut off when the level is lower than the level 1 and below the level 2.

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