JP3744412B2 - Cooker - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a heating cooker that has a high-frequency noise source such as an inverter and requires a filtering circuit that leaks out of a device from a power line.
[0002]
[Prior art]
  Conventionally, as this type of cooking device, for example, there is an induction cooking device as shown in FIG. In FIG. 4, by connecting a connector 2 such as an insertion plug to an outlet (not shown) connected to the commercial power source 1, input terminals A and A 'of the device are connected to the commercial power source. A capacitor 3 and a resistor 4 are connected in parallel to a commercial power line between the input terminals A and A ′ and the power switch 6, and a common mode coil 5 is connected in series.
[0003]
  Reference numeral 7 denotes a full-wave rectifier, one end of which is connected to the load side terminal of the power switch 6 and the other end is connected to the other pole output terminal of the common mode coil 5. The output terminal of the full wave rectifier 7 is connected to the inverter 8. The inverter 8 includes a resonance circuit block 8c having a heating coil 8a, an IGBT 8b, a resonance capacitor, a smoothing capacitor, and the like. A power transformer 12 has a primary winding connected between commercial power lines on the load side of the power switch 6, a secondary winding connected to the control power circuit 10, and the control power circuit 10 supplies control power to the control means 11. Supply. A current transformer 9 outputs an output signal to the control means 11. The control means 11 inputs the voltage of the commercial power line or the voltage generated by the inverter and drives the IGBT 8b.
[0004]
  The operation of the conventional induction heating cooker will be described below. When the power switch 6 is turned on, the commercial power supply 1 is supplied to the input terminal of the full-wave rectifier 7 via the common mode coil 5, and a full-wave rectified DC voltage is output to the inverter 8. Since the commercial power supply 1 is also input to the power transformer 12 in the same manner, the control power supply circuit 10 supplies a DC smoothed control power supply voltage to the control means 11, thereby enabling the control means 11 to operate. In this state, when a heating command is input from an input device (not shown), the control unit 11 drives the IGBT 8b to generate a high-frequency current of about 20 kHz in the resonance circuit block 8c and the heating coil 8a.
[0005]
  When the inverter 8 operates and a high-frequency current is supplied to the heating coil 8a, high-frequency conduction noise leaks from the output terminal of the full-wave rectifier 7 to the input terminal and from the input terminals A and A 'of the equipment to the commercial power supply 1 side. To do. A common mode coil 5 and a capacitor 3 are provided in order to reduce the leaked conduction noise. The common mode coil 5 suppresses common mode noise and the capacitor 3 suppresses normal mode noise leakage. resistance4In this case, the electric charge accumulated in the capacitor 3 is discharged when the connector 2 is disconnected from the commercial power source 1 so that no electric shock is caused when the electrode of the connector 2 is touched.
[0006]
[Problems to be solved by the invention]
  In the heating cooker, when the power switch 6 is opened (turned off), the power supply to the inverter 8, the power transformer 12 and the control means 11 is cut off, but the power supply to the resistor 4 and the capacitor 3 is cut off. The standby power did not become completely zero because it was not done. In order to avoid this, when the common mode coil 5 and the capacitor 3 are provided on the power supply line on the load side of the power switch 6, the wiring portion to which the power switch 6 is connected, that is, the common including the power switch 6 from the input terminals A and A ' The wiring part to the connection point of the mode coil 5 and the capacitor 3 is affected by the radiation noise generated from the inverter 8 and generates high-frequency noise, which may leak to the commercial power source as conduction noise.
[0007]
  This invention solves the said conventional subject, and it aims at providing the heating cooker which can make standby electric power small and can suppress a conduction noise.
[0008]
[Means for Solving the Problems]
  In order to solve the above-described conventional problems, a heating cooker according to the present invention includes a power supply path for supplying power to the heating means, a first switch provided in the middle of the power supply path, and driving of the heating means. Control means for controlling the power supply, first control power supply means connected between the power supply paths on the load side of the first switch to supply control power to the control means, and power supply side of the first switch Between the power supply pathsVia the second switchA second control power supply means connected to supply control power to the control means, and between the power supply side power supply paths of the first switchSaidSecond switch and capacitorTheseriesInConnect andSecond control power supply Means is connected in parallel with said capacitor;After the first switch is changed from open to closed, the second switch is changed from open to closed.
[0009]
  As a result, noise that cannot be sufficiently filtered by the filter provided on the heating means side of the first switch can be reduced by the capacitor, and when it is not necessary, the capacitor can be disconnected to suppress standby power. A cooker is obtained.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
  Since the first aspect of the invention includes the first switch provided in the middle of the power supply path for supplying power to the heating means, the power supply to the heating means can be interrupted by the first switch. it can.
[0011]
  Further, since the second switch and the capacitor are connected in series between the power supply paths having different polarities on the power source side of the first switch, the power supply and the first switch are closed by closing the second switch. The normal noise induced by radiation from a high-frequency generation source inside the device can be reduced by the action of the capacitor in the wiring for connecting to the common mode coil provided on the power supply side of the first switch.
[0012]
  Further, when the noise reduction action by the capacitor is not required, by opening the second switch, it is possible to disconnect the capacitor from the power supply line and eliminate the standby power generated when the capacitor is connected.
[0013]
  In addition, after the first switch is changed from open to closed, the second switch is changed from open to closed so that noise may be generated when the first switch is closed. As long as the second switch is closed, it is possible to stand by, and when the first switch is opened, it is not necessary to reduce noise, so the second switch is opened and the capacitor is disconnected, thereby saving standby power. After both the first and second switches are open, it is possible to prevent the standby power from being generated by the capacitor unless the first switch is closed.
[0014]
  Further, since the second control power supply means is connected in parallel with the capacitor, the control means can be operated by closing the second switch in the control means even after the first switch is opened. For example, a cooling fan can be operated after the power switch is opened, or a function for displaying the high temperature of the heating unit can be provided. Then, the standby power can be reduced by opening the second switch as soon as these functions are no longer required. Further, when the input terminal is disconnected from the commercial power supply while the first switch is open and the second switch is closed, the charge accumulated in the capacitor is discharged by the input impedance of the control power supply means. The risk of electric shock by touching the input terminal can be eliminated.
[0015]
  The invention according to claim 2By connecting a discharge resistor in series with the fourth switch and across the capacitor, standby power consumed after opening the first switch 22 is reduced, the first switch is opened, and the first switch is opened. In the case where the switch 4 is closed, when the input terminal is disconnected from the power source, the charge accumulated in the capacitor can be discharged, so that it is possible to prevent an electric shock by touching the input terminal, It is possible to prevent an electric shock by touching the substrate during repair work such as substrate replacement.
[0016]
  Claim3The invention described in particular is the second switchAlternatively, the third switch and the fourth switch are opened when the heating means is not in a heating state,Heating meansHeatedStatusWhenIf it is closed, noise will increase due to energization of the heating means.TogetherThe normal mode noise leaking to the power supply when closed is reduced, and when the noise is low, the capacitor is disconnected and the standby power can be reduced. The second switchOr third switch and fourth switchReduce the chance to close the second switchOr third switch and fourth switchIt is possible to save the power consumption required for driving.
[0017]
  Claim4In particular, the invention described in the second switch is the second switch after the first switch is opened from the closed state.Or third switch and fourth switchSince the capacitor is connected between the power supply lines unless the first switch is opened, the noise reduction effect by the capacitor can be stably obtained and the first switch can be opened. Since the power supply is cut off, no noise is generated.Or the third switch and the fourth switchBy making it open, it is possible to eliminate generation of standby power by the capacitor.
[0018]
  Claim5In particular, since the second switch is opened after a predetermined time has elapsed since the first switch is opened, the second switch is opened each time the first switch is repeatedly opened and closed in a short time. SwitchOr a third switch and a fourth switchDoes not open or close, so the second switchOr a third switch and a fourth switchThe second switch reduces the chance of opening and closingOr a third switch and a fourth switchThe durability of can be improved.
[0019]
  Claim6In particular, the invention described in the paragraph includes an input device for inputting a control command, and the control command output by the input deviceIs a heating start command,Second switchOr, open the third switch and the fourth switch from open to closed.By changing the open / close state, the opportunity and time to connect the capacitor between the power lines is reduced, and the second switchOr third switch and fourth switchIt is possible to reduce the power required to drive the power and reduce the power consumption when forgetting to turn off the power switch.
[0020]
  Claim7In particular, the second switch includes a phase detection unit that detects a phase of an AC power supply, and the second switch is based on a detection result of the phase detection unit.Or third switch and fourth switchSince the open / close state is changed from open to closed, when the power source is an AC power source, the second switch is closed near the zero voltage of the AC power source so that the inrush current at the time of closing does not become too large. If the switch is a mechanical contact such as a relay, the timing at which the second switch is closed is made random so as not to be biased to the characteristic phase or polarity, so that welding or the like hardly occurs and reliability can be improved.
[0021]
  Claim8In particular, the invention described inPower supply side of the first switchIt has a common mode coil provided in the power supply path, and between the heating part side terminals of the common mode coilSecondConnect the input terminal of the control power supply means, and connect it between the power supply side terminals of the common mode coil.4By connecting a series connection body of switches and capacitors,SecondNoise that leaks from the input terminal of the control power supply means to the commercial power supply is suppressed by the common mode coil, and normal mode noise that increases when the common mode coil is added is more effective by the capacitor connected to the power supply side terminal. Can be reduced.
[0022]
【Example】
  (Example 1)
  An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit block diagram of an induction heating cooker having an induction heating coil for heating a heated pan with a high frequency magnetic field.
[0023]
  The connection terminal 21 such as a plug connects the input terminal 21 a of the induction heating cooker and the other input terminal 21 b to the commercial power source 20. A power supply side terminal 22a of a first switch 22 having a so-called power supply switch function is connected to the input terminal 21a via a common mode coil 31, and an inverter 26 side (load side) terminal 22b includes four diodes 23a to 23d. It is connected to the input terminal (the anode of the diode 23a) of the full-wave rectifier 23 formed by a bridge with a single diode. The other input terminal 21 b is connected to the other input terminal (cathode 23 d cathode) of the full-wave rectifier 23 through the common mode coil 31. An inverter 26 is connected to the output terminals of the full-wave rectifier 23 (the cathode (positive terminal) of the diode 23a and the anode (negative terminal) of the diode 23d). The inverter 26 is composed of a heating coil 26b, a switching element 26c, or a resonant capacitor (see FIG. The high frequency current is supplied to the heating coil 26b when the switching element 26c is turned on / off.
[0024]
  Between the input terminal 21a and another input terminal 21b having a different polarity, a series connection body of the contact of the relay 24 and the capacitor 25 is connected. The control means 27 includes an input device 27a having operation keys, a heating control device 27b for driving the switching element 26c, a phase detection means 27c, and a series connection body of a resistor 27d and a resistor 27e connected between the input terminals of the full-wave rectifier 23. And a cooling fan driving device 27g. Between the connection point of the resistor 27d and the resistor 27e and the negative output terminal of the full-wave rectifier 23, the resistor 27f and the input terminal of the phase detector 27c are connected in parallel. The common potential of the control means 27 is connected to the negative potential of the output of the full-wave rectifier 23 and the emitter (low potential side terminal) of the switching element 26c. The heating control device 27b receives the output signals of the input device 27a and the phase detection means 27c, and outputs the drive signals to the cooling fan drive device 27g, the drive coil (not shown) of the relay 24, and the switching element 26c.
[0025]
  One end of the primary side (input side) terminal of the first transformer 28 a is connected to the load side terminal 22 b of the first switch 22, and the other end is connected to the output end of the common mode coil 31. The output terminal of the first transformer 28a is connected to the first power supply circuit 28b. Primary terminals of the second transformer 29 a are connected to both ends of the capacitor 25. The output terminal of the second transformer 29a is connected to the second power supply circuit 29b. Output voltages of the first power supply circuit 28 b and the second power supply circuit 29 b are supplied to the control power supply circuit 30, and DC control power is supplied from the control power supply circuit 30 to each circuit of the control means 27.
[0026]
  The operation of the cooking device configured as described above will be described. Even if the connector 21 is connected to a power supply outlet and the input terminal 21a and the input terminal 21b are connected to the commercial power supply 20, if the first switch 22 and the relay 24 are both open, the first No power is supplied to the power circuit 28b, the second power circuit 29b, and the inverter 26.
[0027]
  When the power switch 22 is closed, the power supply voltage is applied to the primary winding of the first power supply transformer 28 a, so that the first power supply circuit 28 b supplies the control power supply voltage to the control power supply 30. Since the control power supply 30 supplies the control power supply (DC power supply) voltage necessary for the control means 27, the control means 30 becomes operable.
[0028]
  When the power switch 22 is closed, the phase detection circuit 27c inputs the voltage at the connection point between the resistor 27d and the resistor 27e, and the common potential is set to the negative output terminal of the full-wave rectifier 23. The voltage is rectified by each diode of the full-wave rectifier 23 and a resistance-divided voltage of the resistor 27d and the resistor 27f or the resistor 27e and the resistor 27f is input. Therefore, if the resistance 27d and the resistance 27e are substantially equal, a waveform obtained by resistance-dividing the waveform obtained by full-wave rectification of the commercial power supply voltage as shown in FIG. 2A is input to the phase detection means 27c. When this waveform is input, the phase detection means 27c performs waveform shaping as shown in FIG. 2B to the heating control device 27b and outputs it.
[0029]
  When the heating control device 27b inputs the heating start command from the input device 27a in a state where the signal of FIG. 2B is input, the driving coil of the relay 24 is driven and the contact is closed. And after the contact of the relay 24 is closed, the drive signal of the switching element 26c is output, the inverter 26 is driven, the high frequency current is supplied to the heating coil 26b, and the object to be heated is heated.
[0030]
  When the contact of the relay 24 is closed, the capacitor 25 is connected between the power supply paths having different potentials connected to the input terminal 21a and the input terminal 21b, and therefore leaks from the inverter 26 to the power supply path or the power supply path. It is possible to reduce normal mode noise (noise having different phases) generated in the power supply path due to the influence of radiation noise generated by the inverter 26. Further, since a voltage is applied to the primary winding of the second transformer 29a, power can be supplied from the second power supply circuit 29b.
[0031]
  When the first switch 22 is opened during the operation of the inverter 26, the input voltage of the phase detector 27 becomes a half-wave rectified waveform as shown in FIG. 2C, and the phase detector 27 to the heating controller 27b. And the waveform is shaped and output as shown in FIG. 2D, so that the heating control means 27b recognizes the difference from the waveform of FIG. 2B and recognizes that the first switch 22 is opened. Then, the operation of the inverter 26 is stopped.
[0032]
  Since the control means 27 can receive the control power supply from the path of the second power supply circuit 29b even when the first switch 22 is opened, the cooling fan drive device 27g discharges the remaining heat of the inverter 26. If necessary, a cooling fan (not shown) can be operated. When it is determined that the operation of the cooling fan or the operation of the control means 27 after the first switch 22 is opened is necessary, the heating control device 27b opens the contact of the relay 24.
[0033]
  At this time, since the capacitor 25 is released from the input terminal 21a, standby power consumed by the combined impedance of the capacitor and the resistance component connected in parallel to the capacitor can be eliminated.
[0034]
  Even when the first switch 22 is open and the relay 24 is closed and the input terminals 21a and 21b are released from the commercial power supply 20, the charge accumulated in the capacitor is the primary winding of the second transformer 29a. Since the battery is quickly discharged through the wire, there is no risk of electric shock even if the input terminals 21a and 21b are touched.
[0035]
  Further, since the phase detection means 27c outputs the waveforms shown in FIGS. 2B and 2C, the heating control device 27b detects the phase of the power source from the output waveform and sets the switching timing of the contact of the relay 24 to zero phase or The reliability can be improved by making the relay 24 difficult to weld by performing the random phase.
[0036]
  As described above, according to this embodiment, the power supply path for supplying the power supply current or voltage to the inverter 26 (the power supply path from the input terminal 21a to the anode of the diode 23a serving as the input terminal of the full-wave rectifier 23) is in the middle. In addition, the first switch 22 is provided, and the series connection body of the relay 24 and the capacitor 25 is connected between the power supply paths having different polarities on the power source side than the first switch 22, so that the first switch 22 is opened. By doing so, the heating operation by the heating coil 26a can be stopped reliably. Further, since the capacitor 25 and the series connection body of the relay 24 are provided between the power supply paths, the normal noise leaking from the inverter 26 to the power source side and the first switch 22 are connected by closing the relay 24. The common mode coil 31 is provided between the input terminal and the first switch 22, or high-frequency normal noise generated between the input terminals 21a and 21b can be reduced. Further, when a capacitor is not required, that is, when there is no possibility of generating high-frequency noise, the relay 24 is opened, so that commercial power is not applied to the capacitor 25, and standby power is suppressed. it can.
[0037]
  Further, since the control means 27 is closed when the inverter 26 is heated, the standby power can be further reduced by reducing the time during which the relay 24 is closed.
[0038]
  Moreover, since the relay 24 opens the relay 24 after the first switch 22 is opened, noise can be reliably reduced and standby power can be suppressed.
[0039]
  Further, by changing the open / close state of the relay 24 in accordance with the control command output from the input device 27a that inputs the control command, the timing for connecting or disconnecting the capacitor 25 to the power supply path can be determined efficiently, and the standby power can be reduced. It can be reduced efficiently.
[0040]
  Further, since the control unit 27 changes the open / close state of the relay 24 from open to closed or from closed to open based on the detection result of the phase detection unit 27c that detects the phase of the AC power supply, the switching timing of the contact of the relay 24 The reliability of the relay 24 can be improved by making the relay 24 difficult to be welded by performing it with a zero phase or a random phase of the commercial power cycle.
[0041]
  Further, since the primary winding of the second transformer 29a for supplying control power to the control means 27 is connected between both ends of the capacitor 25, the first switch 22 is in the open state and the relay 24 is in the closed state. Sometimes, even when the input terminal 21a and the input terminal 21b are released from the power supply 20, since the capacitor 25 is quickly discharged by the primary winding of the second transformer 29a, there is no risk of electric shock due to the charge remaining in the capacitor 25.
[0042]
  (Example 2)
  FIG. 3 shows a circuit block of the second embodiment. In this figure, the parts having the same configuration as in FIG. 1, that is, the connector 21, the first switch 22, the full-wave rectifier 23, the relay 24, the capacitor 25, the inverter 26, the first transformer 28a, the first power source. The circuit 28b, the control power supply circuit 30, and the common mode coil 31 are denoted by the same reference numerals as those in FIG.
[0043]
  3 differs from FIG. 1 in that a resistor 35 is connected to both ends of the capacitor 25, and the primary winding of the third transformer 32a is connected to the first switch 22 and the full-wave rectifier 23 of the common mode coil 31. When the control means 33 detects that the first switch 22 is closed, the relay 24 is connected to the terminal connected to the inverter 26 via the relay (third switch) 34. And outputting a drive signal for the relay 34, and opening the relay 24 and the relay 34 after a predetermined time when the control means 33 detects the opening of the first switch 22.
[0044]
  The cooking device configured as described above will be described below. When the first switch 22 is closed, the control means 33 sees the change in the voltage waveform input from the load side terminal of the first switch 22 and inputs the drive command for the inverter 26 immediately, after a predetermined time, or after Then, the relay 24 and the relay 34 are closed. As a result, the capacitor 25 is connected between the input terminal 21a and the input terminal 21b or between the power supply lines connected to these terminals, and the control power supply from the third power supply circuit 32b to the control means 33 is performed. It becomes possible.
[0045]
  When a control command (heating command) from the user is input to the control means 33, the inverter 26 operates and a high-frequency current is supplied to a heating coil (not shown) to heat the heated pan (not shown). At this time, normal mode noise is generated between the power supply lines due to high frequency noise conducted from the inverter 26 via the power supply line and radiation noise from the inverter 26 on the common mode coil 31 and the distribution line. Bypassing and noise leaking to the commercial power supply 20 are reduced.
[0046]
  When the first switch 22 is opened, control power is not supplied from the first power supply circuit 28b, but control power is supplied from the third power supply circuit 32b, so that the operation of the control means 33 continues. It becomes possible. The control means 33 opens both the relay 24 and the relay 34 when it is not necessary to perform other control operations such as driving, displaying, or monitoring the cooling fan after the first switch 22 is opened. Thereafter, unless the first switch 22 is closed, power consumption by the control means 33 or the capacitor 25 and the resistor 35 can be eliminated.
[0047]
  As described above, according to the present embodiment, the power supply path for supplying power to the inverter 26 and the first switch 22 provided on one side of the power supply path are provided, and the power supply side is more than the first switch 22. The relay 24 and the capacitor 25 are connected in series between the power supply lines, and the relay 24 opens and closes according to the open / closed state of the first switch 22, thereby waiting for consumption after the first switch 22 is opened. Electric power can be reduced.
[0048]
  Further, by connecting the input terminal of the third transformer 32a between the heating part side terminals of the common mode coil 31, and connecting the series connection body of the relay 24 and the capacitor 25 between the power source side terminals of the common mode coil 31, Noise that leaks from the primary winding of the third transformer 32a or the power supply line connected to the primary winding to the commercial power supply 20 can be attenuated by the common mode coil 31 to prevent the noise from increasing.
[0049]
  In the first embodiment, one terminal of the first transformer 28 is connected to the heating unit side terminal of the common mode coil 31 via the first switch, but directly without using the first switch. Even if it is connected to the heating part side terminal of the common mode coil 31, the series connection body of the relay 24 and the capacitor 25 is connected between the power lines on the power source side than the first switch, and the first and second relays 24 are opened and closed. It goes without saying that an equivalent effect is obtained in that standby power consumed after the switch 22 is opened is reduced.
[0050]
  In the first embodiment, the first power supply circuit 28b is connected between both ends of the heating unit side terminal of the common mode coil 31 via the first transformer 28a. Even if the input terminal is connected to either the heating unit side terminal of the common mode coil 31 or the heating unit side terminal of the first switch instead of the switching power source, the power line on the power source side than the first switch It goes without saying that an equivalent effect of reducing standby power consumed after the first switch 22 is opened by connecting the series connection body of the relay 24 and the capacitor 25 between them and opening and closing the relay 24 is obtained.
[0051]
  Similarly, in the first embodiment, the second power supply circuit 29b is configured to connect the primary winding of the second transformer 29a between both ends of the capacitor 25. However, the second power supply circuit 29b is connected to the switching power supply. Even if the input terminal is connected to the terminal of the capacitor 25 to which the relay 24 is connected, the series connection body of the relay 24 and the capacitor 25 is connected between the power lines on the power source side than the first switch, Needless to say, the opening and closing of the relay 24 can provide an equivalent effect of reducing standby power consumed after the first switch 22 is opened.
[0052]
【The invention's effect】
  As described above, claims 1 to8According to the invention described in (2), since noise may be generated when the first switch is closed, the second switch is used to reduce the noise.Or 4thThe first switch is closed, and when the first switch is opened, it is not necessary to reduce noise.Or 4thAnd the capacitor is disconnected to save standby power, and the first and,SecondOr 4thAfter both of the switches are opened, it is possible to eliminate the generation of standby power by the capacitor unless the first switch is closed.
[Brief description of the drawings]
FIG. 1 is a circuit block diagram of a heating cooker in Embodiment 1 of the present invention.
FIG. 2A is a diagram showing an input waveform to phase detection means when the first switch of the cooking device according to the first embodiment of the present invention is closed.
  (B) The figure which shows the output waveform of a phase detection means in case the said 1st switch is closed.
  (C) The figure which shows the input waveform to a phase detection means when the same 1st switch is open
  (D) The figure which shows the output waveform of a phase detection means in case the said 1st switch is open
FIG. 3 is a circuit block diagram of a heating cooker in Embodiment 2 of the present invention.
FIG. 4 is a circuit block diagram of a conventional cooking device.
[Explanation of symbols]
  21 connector
  22 First switch
  23 Full-wave rectifier (heating means)
  24 relay (second switch)
  25 capacitors
  26 Inverter (heating means)
  27 Control means
  27a Input device (control means)
  27b Heating control device (control means)
  27c Phase detection means
  29a Second transformer (control power supply means)
  29b Second power supply circuit (control power supply means)
  30 Control power circuit
  31 Common mode coil
  32a Second power transformer (control power supply means)
  32b Second power supply circuit (control power supply means)
  33 Control means

Claims (8)

A power supply path for supplying power to the heating means; a first switch provided in the middle of the power supply path; a control means for controlling driving of the heating means; and the power supply on the load side of the first switch A first control power supply means connected between supply paths for supplying control power to the control means, and a control switch connected between the power supply paths on the power supply side of the first switch via a second switch. and a second control power supply means for supplying control power to the unit, along with connecting the second switch and the capacitor in series between the power supply side power supply path of the first switch, the second control The power supply means is connected to the capacitor in parallel, and after the first switch is opened to closed, the second switch is opened to closed. A power supply path for supplying power to the heating means; a first switch provided in the middle of the power supply path; a control means for controlling driving of the heating means; and the power supply on the load side of the first switch A first control power supply means connected between supply paths for supplying control power to the control means, and a control switch connected between the power supply paths on the power supply side of the first switch via a third switch. and a second control power supply means for supplying control power to the unit, along with connecting the fourth switch and the capacitor in series between the power supply side power supply path of said first switch, said fourth switch A heating cooker in which a discharge resistor is connected in series and in parallel with the capacitor, and the third switch and the fourth switch are closed from the open after the first switch is closed from the open. The heating according to claim 1 or 2 , wherein the second switch or the third switch and the fourth switch are opened when the heating means is not in a heating state , and are closed when the heating means is in a heating state. Cooking device. The cooking device according to claim 1 or 2 , wherein after the first switch is opened from the closed state, the second switch or the third switch and the fourth switch are opened from the closed state. The cooking device according to claim 4 , wherein the first switch is opened from the closed state, and the second switch or the third switch and the fourth switch are opened from the closed state after a predetermined time has elapsed. When the control command output by the input device is a heating start command, the second switch or the third switch and the fourth switch are changed from open to closed. The cooking device according to any one of claims 1 to 5 , wherein the open / close state is changed. Phase detection means for detecting the phase of the power supply is provided, and the second switch or the third switch and the fourth switch are opened / closed from open to closed or from closed to open based on the detection result of the phase detection means The cooking device according to any one of claims 1 to 6, wherein the cooking device is changed. Comprising a common mode coil provided on the power supply side power supply path of a first switch, the input terminal of the second control power supply means connected between the heating unit side terminal of the common mode coil, the common mode coil The cooking device according to claim 2 , wherein a fourth switch and a series connection body of capacitors are connected between the power supply side terminals.

Images