JP5253902B2 - Heating cooker and power supply method to heating cooker - Google Patents

Description

  The present invention relates to a heating cooker including a power operation unit for starting and stopping power supply to a cooker body, and a power supply method to the heating cooker.

  Heating cookers that heat and cook heated objects such as pans using induction heating or electric heaters have the advantage of being safe and have a temperature control function without using fire, and are quick as IH cooking heaters built into system kitchens. It is becoming popular. In such a heating cooker, a power switch for supplying commercial power to the cooker body is provided, and this power switch is often a mechanical switch.

However, the mechanical power switch is not easy to operate because a certain level of force is required for normal operation. For this reason, it is considered to use a switch that can be operated with a light touch that performs a momentary operation, such as a micro switch (see, for example, Patent Document 1). Moreover, the heating cooker of patent document 1 forcibly performs the heating operation | movement by heating means, such as a heating coil and an electric heater, irrespective of the control state of a control part (microcomputer), when a power-off switch is operated. It is possible to stop. In other words, a fail-safe measure is taken into consideration when an electronic component such as a microcomputer of the control unit fails or runs away.
JP 2007-200767 A

  However, the heating cooker described in Patent Document 1 is configured to form a holding circuit to which commercial power is applied and detect the operation state of the power-off switch according to the holding state of the holding circuit. In order to form this holding circuit, a plurality of relays that can directly cut off the commercial power supply are used. For this reason, the said heating cooker has the problem that a circuit structure becomes complicated and cost becomes high, and there existed room for improvement in this point.

  The present invention has been made in view of the above circumstances, and its purpose is to provide a circuit configuration even when the control unit controls the power supply system supplied to each unit with a light touch power switch configuration. An object of the present invention is to provide a cooking device capable of taking a fail-safe measure without complication and a power supply method for the cooking device.

The cooking device according to the present invention includes a cooking device body, a heating unit that performs heating, a control unit that controls heating by the heating unit, and a power source unit that generates an operation power source from a commercial power source and supplies the operation power source to the control unit. state, and are not to be operated to start the supply of the commercial power supply to the cooker body, the common terminal, and a switch double throw type having a normally open terminal and the normally closed terminal, common to the operating state and turning on the switch to form a first feed path to the power supply unit from the commercial power source by between terminals and normally open terminals are conductive, are connected to the normally closed terminal of the power-on switch, the power on switch and on operation detection unit for detecting an operation state, holds the current state of the second power supply path to the power supply unit from the commercial power supply is controlled is provided in parallel with said first feed path by the control unit Yes A self-holding means having a connected DC relay between the common terminal and the normally open terminals of the power-on switch, the be one that is operated to stop the supply of the commercial power supply to the cooker body An operation signal can be output in an operation state, and a power-off switch provided in a detection energization path to which the operation power is applied, and the power-off switch based on a terminal voltage of the power-off switch An off operation detecting unit for detecting the operation signal; a heating prohibiting unit for prohibiting heating by the heating unit when the operation signal is output from the power off switch; and a cooling fan for cooling the cooker body. comprising comprising a controlled unit, and an operation unit for performing settings relating to cooking, and the controlled unit operates by being controlled by the control unit, the power supply Ofusui The control unit continues to operate even when the operation signal is output from the H, and the control unit operates the operation unit for a predetermined time in a state where the energization state of the second power feeding path is held by the self-holding unit. If not, and if the operation of the power-on switch is not detected for a predetermined time via the on-operation detector, the holding of the energized state by the self-holding means is released .

The power supply method to the heating cooker according to the present invention includes a heating unit that performs heating, a control unit that controls heating by the heating unit, and a power source that generates an operation power source from a commercial power source and supplies the operation power source to the control unit and parts, der those operated to start supplying the commercial power source to the cooking device body is, the common terminal, and a switch double throw type having a normally open terminal and the normally closed terminal, in the operating state A power-on switch that forms a first power supply path from the commercial power supply to the power supply unit by conducting between the common terminal and the normally- open terminal ; and a power-on switch connected to the normally- open terminal of the power-on switch and on operation detection unit for detecting an operation state, holds the current state of the second power supply path to the power supply unit from the commercial power supply is controlled is provided in parallel with said first feed path by the control unit Ah , A self-holding means having a connected DC relay between the common terminal and the normally open terminals of the power-on switch, be one that is operated to stop the supply of the commercial power supply to the cooker body An operation signal can be output in the operation state, and a power off switch provided in a detection energization path to which the operation power is applied, and the power off switch based on the terminal voltage of the power off switch A power supply method to a cooking device comprising an off-operation detecting unit for detecting the operation signal and a heating prohibiting unit for prohibiting or permitting heating by the heating unit, wherein the power-on switch is operated And the power supply unit generates an operation power supply and supplies the operation power supply to the control unit, and the control unit receives the operation power supply and starts operation to place the self-holding unit in a holding state. When the supply of the commercial power source to the cooker body is started and the power-off switch is operated, the heating prohibiting unit prohibits heating by the heating unit, and the control unit sets the holding state of the self-holding unit. It cancels | releases and the supply of the said commercial power supply to the said cooker main body is stopped, It is characterized by the above-mentioned.

  According to the present invention, since the power-on switch and the power-off switch are configured by the light touch switch that performs a predetermined action in the operation state, the operability of the power switch improves. Even when the control unit breaks down or runs out of control, the heating can be forcibly stopped by operating the power-off switch. That is, a fail-safe measure can be taken without complicating the circuit configuration.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 4 is a perspective view showing an external appearance of the cooking device in a state of being incorporated in a kitchen. The heating cooker 1 is made of a heat-resistant glass that is mounted so as to cover the upper surface of the main body 3 and the rectangular box-shaped main body 3 housed in the opening 2 a of the kitchen table 2 and is exposed on the kitchen table 2. And the top plate 4.

  A plurality of heating means including two induction heating coils (indicated by reference numerals 5 and 6 in FIG. 1) and an electric heater (indicated by reference numeral 7 in FIG. 1) are disposed in the main body 3. In addition, an operation panel unit 8 (corresponding to an operation unit) is provided on the right side of the front surface for performing cooking operations and various displays corresponding to the operations. In addition, a power-on switch 9 and a power-off switch 10 configured by momentary type switches are provided at a position located on the upper right side of the operation panel unit 8. The user operates the switches 9 and 10 to start and stop power supply to the heating cooker 1.

  On the upper surface of the top plate 4, circular mounting frames 11, 12, and 13 that indicate positions for heating a cooking utensil (not shown) such as a pan are printed with heat-resistant ink. It is displayed by the method. Among them, the inside of the mounting frames 11 and 12 at two places on the left and right sides are a left IH heating port 14 and a right IH heating port 15 for induction heating of the cooked utensils by the induction heating coils 5 and 6. On the other hand, the inside of the mounting frame 13 located at the rear center is a central heater heating port 16 for heat transfer heating of the cooking utensil by the electric heater 7. The user operates the operation panel unit 8 described above to set heating start, heating stop, and heating power (input power) of the heating ports 14 to 16.

  In front of the left IH heating port 14 and the right IH heating port 15, thermal power display units 17 and 18 for displaying the thermal power of the heating ports 14 and 15 are provided, respectively. The thermal display units 17 and 18 include a large number of LEDs provided in the main body 3 and a transmission part of the top plate 4 that transmits light emitted from these LEDs. Between the left IH heating port 14 and the right IH heating port 15, a high temperature caution display unit 19 is provided to notify the user that the heating port is hot. The high-temperature caution display section 19 includes an LED provided in the main body 3 and a transmission section of the top plate 4 that transmits light emitted from the LED. In addition, an intake port 20 and an exhaust port 21 are formed on the left and right sides behind the top plate 4 for intake and exhaust of air that cools electrical components such as the induction heating coils 5 and 6 and the electric heater 7.

  FIG. 1 is a block diagram schematically showing an electrical configuration of a cooking device. The heating cooker 1 includes a left inverter circuit 30 and a right inverter circuit for performing induction heating by supplying a high frequency current to induction heating coils 5 and 6 disposed below the left IH heating port 14 and the right IH heating port 15. 31, a control circuit for controlling the electric heater 7 (corresponding to the heater) and the inverter circuits 30 and 31 (corresponding to the induction heating inverter) disposed below the central heater heating port 16, energizing control to the electric heater 7 32 or the like. The control circuit 32 includes a control microcomputer 33 (corresponding to the control unit), a power supply circuit 34 (corresponding to the power supply unit) that supplies operation power to the control microcomputer 33, and an on operation for detecting the operation state of the power on switch 9. An off operation detection unit 36 that detects the operation state of the detection unit 35 and the power off switch 10 is provided.

  The pair of power supply buses 37 and 38 are connected to a commercial power supply 39 that supplies AC power to the cooking device 1 via a noise filter 40 for noise removal. The power-on switch 9 is a double-throw (three-point contact type) micro switch having a common terminal COM, a normally open terminal NO, and a normally closed terminal NC. The power-on switch 9 is electrically connected between the common terminal COM and the normally open terminal NO while being pressed by the user, and is connected to the common terminal COM and the normally closed terminal NC while the pressing operation is not being performed. Conducts between. The normally open terminal NO of the power on switch 9 is connected to the power bus 37.

  The power-off switch 10 is a momentary type tact switch, and is configured to be closed only while being pressed. One terminal of the power-off switch 10 is connected to the ground (the ground on the control circuit 32 side), and the other terminal is connected to the off operation detection unit 36.

  The common terminal COM of the power-on switch 9 is connected to the power bus 41 and the normally closed terminal NC is connected to the power bus 42. An on operation detection unit 35 is connected between the power supply bus 42 and the power supply bus 38. A DC relay 43 is connected between the power bus 37 and the power bus 41. Accordingly, an AC voltage is applied to the on-operation detecting unit 35 in a state where the contact of the DC relay 43 is closed and the power-on switch 9 is not operated.

  In the present embodiment, the path from the commercial power supply 39 to the power supply circuit 34 via the power supply bus 37, the power ON switch 9, and the power supply bus 41 corresponds to the first power supply path, and the commercial power supply 39 to the power supply bus 37 and the DC relay 43. The path reaching the power supply circuit 34 via the power supply bus 41 corresponds to the second power supply path. The DC relay 43 corresponds to a self-holding unit that holds the energized state of the second power feeding path.

  Between the power supply bus 41 and the power supply bus 38, a series circuit of a cooling fan 44 (corresponding to a controlled portion) and a photocoupler 45 and a power supply circuit 34 are connected in parallel to each other. Therefore, in the state where the power-on switch 9 is operated or the contact of the DC relay 43 is closed, an AC voltage is applied to the power supply circuit 34 and the series circuit of the cooling fan 44 and the photocoupler 45 and the control. The microcomputer 33 operates. In this state, the cooling fan 44 starts operating when the photocoupler 45 is turned on by a fan drive signal output from the control microcomputer 33. The opening and closing of the contact of the DC relay 43 is controlled by a relay drive signal from the control microcomputer 33 and is performed via the relay drive circuit 46.

  Power supply buses 37 and 38 are connected to the right inverter circuit 31. Among these, a DC relay 47 is connected to one power supply bus 37, and the DC relay 47 is controlled by a drive signal from the control microcomputer 33 and is driven via a relay drive circuit 48. That is, the control microcomputer 33 controls the power supply to the right inverter circuit 31 by controlling the opening and closing of the DC relay 47.

  The oscillation operation of the right inverter circuit 31 is controlled by an inverter drive signal input from the control microcomputer 33 via the oscillation permission circuit 49. The oscillation permission circuit 49 is supplied with an off operation signal Sa that changes in accordance with the operation state of the power off switch 10 output from the off operation detector 36. The oscillation permission circuit 49 enables the inverter drive signal to be output to the right inverter circuit 31 when the off operation signal Sa becomes an active level corresponding to “permitted”.

  Note that the left inverter circuit 30 including the DC relay 50 and the relay drive circuit 51 has the same configuration as the right inverter circuit 31. The oscillation permission circuit 49 permits or prohibits the oscillation operation of the inverter circuits 30 and 31 by controlling whether or not the inverter drive signal is transmitted to the inverter circuits 30 and 31, and the heating prohibition referred to in the present invention. Corresponds to means. Each of the inverter circuits 30 and 31 is configured as a half bridge inverter including an upper arm switching element and a lower arm switching element (both not shown).

  One end of the electric heater 7 is connected to the power supply bus 37 via the DC relay 52. The other end of the electric heater 7 is connected to the power supply bus 38 via a DC relay 53 (corresponding to a heater energizing relay). The DC relay 52 is controlled by a drive signal from the control microcomputer 33 and is driven through a relay drive circuit 54. That is, the control microcomputer 33 controls the power supply to the electric heater 7 by controlling the opening and closing of the DC relay 52.

  Opening and closing of the DC relay 53 is controlled by a heater drive signal input from the control microcomputer 33 via the heater heating permission circuit 55 and the relay drive circuit 56. The heater heating permission circuit 55 is provided with an off operation signal Sa output from the off operation detecting unit 36. The heater heating permission circuit 55 enables the heater driving signal to be output to the relay driving circuit 56 when the OFF operation signal Sa becomes an active level corresponding to “permitted”. The control microcomputer 33 controls the energization amount to the electric heater 7 by controlling the opening and closing of the DC relay 53. The heater heating permission circuit 55 permits or prohibits heating by the electric heater 7 by controlling whether or not to transmit a heater driving signal to the relay driving circuit 56, and corresponds to the heating prohibiting means referred to in the present invention. To do.

  The control microcomputer 33 receives signals indicating instructions (settings) related to heating cooking such as heating start, heating stop, and heating power setting from the operation panel unit 8, and the left IH heating port 14, the right IH heating port 15, the center Temperature detection signals from temperature sensors 57, 58 and 59 provided in the heater heating port 16 are input.

  The control microcomputer 33 outputs a power supply display drive signal for controlling the lighting thereof to the power supply display unit 97 indicating that a heating operation such as induction heating or heater heating can be started. The power display unit 97 is composed of, for example, a lamp, an LED, and the like. When cooking by heating, the control microcomputer 33 outputs an LED drive signal for displaying the thermal power corresponding to the input power of the heating port in use to the thermal power display units 17 and 18. When any of the heating ports 14 to 16 is at a high temperature, the control microcomputer 33 outputs an LED drive signal for performing a high temperature warning display on the high temperature warning display unit 19.

  Then, the structure relevant to the induction heating operation | movement of the heating cooker 1 is demonstrated. FIG. 2 is a diagram showing the above configuration in detail. The on-operation detecting unit 35 is mainly configured by a bidirectional input type photocoupler 60, and one input terminal of the photocoupler 60 is connected to the power supply bus 37 through a current limiting resistor 61, and the other Are connected to the power supply bus 38. The emitter of the output-side transistor of the photocoupler 60 is connected to a ground line 62 serving as a reference potential (ground potential) on the control circuit 32 side, and the collector is connected to a power supply line 65 via a resistor 63 and a resistor 64. An operation power supply Vcc generated by the power supply circuit 34 is applied to the power supply line 65. In the present embodiment, the voltage of the operating power supply Vcc is, for example, + 5V.

  A capacitor 66 is connected between the interconnection node N 1 of the resistors 63 and 64 and the ground line 62. The interconnection node N1 is connected to the SWON terminal of the control microcomputer 33 as an output terminal of an on operation signal Sb indicating the operation state of the power on switch 9. The control microcomputer 33 detects the operation state of the power-on switch 9 based on the level of the on operation signal Sb. The resistance value of the resistor 64 is set very high compared to the resistance value of the resistor 63. With such a configuration, in a state where an AC voltage is applied between the input terminals of the photocoupler 60 (power-on switch 9 = non-operation state), the photocoupler 60 is turned on, so the on operation signal Sb is at the L level. . On the other hand, in a state where an AC voltage is not applied between the input terminals of the photocoupler 60 (power-on switch 9 = operating state), the photocoupler 60 is turned off, and the on operation signal Sb is at the H level.

  The capacitor 66 is provided to maintain the ON operation signal Sb at the L level even when the AC voltage is near zero cross. That is, when the photocoupler 60 changes from the on state to the off state, the capacitor 66 is charged, and the on operation signal Sb is maintained at the L level for a predetermined time corresponding to the charging time. The In the present embodiment, the capacitance of the capacitor 66 and the resistance value of the resistor 64 are set so that the ON operation signal Sb does not change to the H level when the AC voltage is in the vicinity of the zero cross.

  The off operation detection unit 36 includes a transistor 67 including a resistor, resistors 68 to 70, and a capacitor 71. One terminal of the power-off switch 10 is connected to the ground line 62, and the other terminal is connected to the power line 65 via a resistor 68. That is, the power supply off switch 10 is provided so as to be interposed in an energization path (corresponding to a detection energization path) to which the operation power supply Vcc is applied. Further, the other terminal of the power-off switch 10 is connected to the base of the transistor 67.

  The emitter of the transistor 67 is connected to the ground line 62, and the collector is connected to the power supply line 65 via the resistor 69 and the resistor 70. A capacitor 71 is connected between the interconnection node N2 of the resistors 69 and 70 and the ground line 62. The interconnection node N <b> 2 is connected to the SWOFF terminal of the control microcomputer 33 and the oscillation permission circuit 49 as an output terminal of an off operation signal Sa indicating the operation state of the power supply off switch 10. The control microcomputer 33 detects the operation state of the power-off switch 10 based on the level of the off operation signal Sa. The resistance value of the resistor 70 is set very high compared to the resistance value of the resistor 69.

  With such a configuration, when the power-off switch 10 is being operated, the transistor 67 is turned off, so that the off operation signal Sa output to the control microcomputer 33 and the oscillation permission circuit 49 is at the H level. On the other hand, since the transistor 67 is turned on when the power supply off switch 10 is not operated, the off operation signal Sa output to the control microcomputer 33 and the oscillation permission circuit 49 becomes L level.

  The capacitor 71 (corresponding to a noise filter unit) is provided to prevent erroneous detection of an operation state due to external noise or the like entering the off operation detection unit 36. That is, the capacitor 71 is charged when the transistor 67 changes from the on state to the off state, and the off operation signal Sa output to the oscillation permission circuit 49 is a predetermined value corresponding to the charge time. It is maintained at the L level for the time. In the present embodiment, the capacitance of the capacitor 71 and the resistance value of the resistor 70 are set so that the off operation signal Sa does not change to H level due to noise not related to the operation of the power supply off switch 10.

  When the on operation signal Sb output from the on operation detection unit 35 is at the H level and the off operation signal Sa output from the off operation detection unit 36 is at the H level, the control microcomputer 33 performs the off operation signal. Priority is given to the recognition of Sa. That is, for example, when the power-on switch 9 and the power-off switch 10 are pressed simultaneously, the control microcomputer 33 is configured to recognize with priority that the power-off switch 10 has been pressed.

  The operation panel unit 8 is configured to output a signal indicating the start of heating to the control microcomputer 33 and the oscillation permission circuit 49 in accordance with the operation of the right IH heating start switch 72 and the left IH heating start switch 73. Also, these IH heating start switches 72 and 73 (corresponding to induction heating start switches) are configured as normally open switches capable of momentary operation, similar to the power-off switch 10.

  One end of each of the IH heating start switches 72 and 73 is connected to the power line 65, and the other end is connected to the ground line 62 via the resistors 74 and 75, respectively, and to the RSB terminal and the LSB terminal of the control microcomputer 33. It is connected. Therefore, for example, when the right IH heating start switch 72 is pressed, the heating start signal input to the RSB terminal changes from the L level to the H level. The control microcomputer 33 detects that the right IH heating start switch 72 has been operated by such a change in signal level. Note that the control microcomputer 33 detects the operation of the left IH heating start switch 73 in the same manner as described above.

  The other ends of the IH heating start switches 72 and 73 are also connected to the base of an NPN transistor 78 with resistance via diodes 76 and 77, respectively. The emitter of the transistor 78 is connected to the ground, and the collector is connected to the oscillation permission circuit 49. Accordingly, when any one of the IH heating start switches 72 and 73 is pressed, the transistor 78 is turned on, so that the collector connected to the oscillation permission circuit 49 becomes L level. Each of the following transistors is of the “with resistance” type like the transistor 78.

  Inverter drive signals RU and RD for generating a waveform by the control microcomputer 33 and driving the right inverter circuit 31 are output from the RU terminal and the RD terminal of the control microcomputer 33, and are respectively connected through current limiting resistors 79 and 80. This is applied to the bases of NPN transistors 81 and 82 of the right inverter circuit 31. These transistors 81 and 82 are controlled by inverter drive signals RU and RD, and alternately turn on and off the upper arm switching element and the lower arm switching element via a drive circuit (not shown) made of a photocoupler. Thus, a high-frequency current to be supplied to the induction heating coil 6 is generated.

  Similarly to the inverter drive signals RU and RD, the inverter drive signals LU and LD for driving the left inverter circuit 30 are also current limiting resistors 83 from the LU terminal and LD terminal of the control microcomputer 33, respectively. , 84 to the bases of the NPN transistors 85, 86 of the left inverter circuit 30.

  The control microcomputer 33 outputs an ENB signal for permitting or prohibiting the oscillation of the inverter circuits 30 and 31 from the ENB terminal in response to the heating start signal input to the RSB terminal or the LSB terminal. The ENB terminal is connected to the base of the NPN transistor 88 through the resistor 87 and is connected to the ground line 62 through the NPN transistor 89. The base of the transistor 89 is supplied with the off operation signal Sa from the off operation detecting unit 36 described above.

  Therefore, if the off operation signal Sa is at the L level, the transistor 89 is turned off, and the transistor 88 is on / off controlled by the ENB signal. On the other hand, when the off operation signal Sa is at the H level, the transistor 89 is turned on, and the transistor 88 is turned off regardless of the level of the ENB signal.

  The emitter of the transistor 88 is connected to the ground line 62, and the collector is connected to the power supply line 65 via a thyristor 90 (corresponding to oscillation state maintaining means) and a resistor 91. The gate of the thyristor 90 is connected to the power supply line 65 through the resistor 92 and the PNP transistor 93. The base of the transistor 93 is connected to the collector of the transistor 78 of the operation panel unit 8 described above. When either of the IH heating start switches 72 and 73 is pressed and the transistor 78 is turned on, the transistor 93 is also turned on. Thus, a trigger signal is applied to the gate of the thyristor 90.

  The bases of the transistors 81 and 85 in each inverter circuit 30 and 31 are connected to the ground line 62 via diodes 94 and 95 and an NPN transistor 96, respectively. The base of the transistor 96 is connected to the anode of the thyristor 90. Therefore, ON / OFF of the transistor 96 is controlled by the conduction state of the thyristor 90 and the transistor 88.

  With the above configuration, when the transistor 89 is turned off and the level of the ENB signal becomes H level, the transistor 88 is turned on. When the transistor 93 is turned on with the transistor 88 turned on and a trigger signal is applied to the gate of the thyristor 90, the thyristor 90 becomes conductive. Then, the transistor 96 is turned off, and the inverter drive signals RU and LU are transmitted to the inverter circuits 30 and 31. In other words, the oscillation permission circuit 49 permits or prohibits the oscillation operation of the inverter circuits 30 and 31 by controlling whether or not to transmit the inverter drive signals RU and LU to the inverter circuits 30 and 31. .

  Then, the structure relevant to the heater heating operation | movement of the heating cooker 1 is demonstrated. FIG. 3 is a diagram showing the above configuration in detail. Note that the same parts as those in FIG. The off operation signal Sa output from the off operation detection unit 36 is also given to the heater heating permission circuit 55.

  The operation panel unit 8 is provided with a heater heating start switch 103 composed of a normally open switch that can perform a momentary operation, similar to the power-off switch 10. The operation panel unit 8 outputs a signal indicating the start of heating to the CSB terminal of the control microcomputer 33 and the heater heating permission circuit 55 according to the operation of the heater heating start switch 103. The circuit for outputting the signal is similarly configured by the resistor 104, the diode 105, and the NPN transistor 106 corresponding to the resistor 74, the diode 76, and the NPN transistor 78 in FIG.

  Therefore, when the heater heating start switch 103 is pressed, the control microcomputer 33 detects that the heater heating start switch 103 has been operated based on a change in the signal level input to the CSB terminal. Further, when the transistor 106 is turned on, the collector of the transistor 106 connected to the heater heating permission circuit 55 becomes L level.

  A heater drive signal for driving the DC relay 53 output from the control microcomputer 33 is output from the HEAT terminal of the control microcomputer 33, and the base of the NPN transistor constituting the relay drive circuit 56 via the current limiting resistor 107. Is given to. The emitter of this transistor is connected to the ground line 62, and the collector is connected to the power supply line 65 via the relay coil 53 b of the DC relay 53. One end of the relay contact 53 a of the DC relay 53 is connected to the power supply bus 37 through the electric heater 7 and the DC relay 52, and the other end is connected to the power supply bus 38.

  The control microcomputer 33 controls the opening and closing of the DC relay 53 by turning on and off the transistor of the relay drive circuit 56 according to the heater drive signal. The ENB terminal of the control microcomputer 33 is connected to the heater heating permission circuit 55, and outputs an ENB signal for permitting or prohibiting energization of the electric heater 7 in accordance with a heating start signal input to the CSB terminal.

  The heater heating permission circuit 55 includes resistors 87, 91, 92 of the oscillation permission circuit 49, NPN transistors 88, 89, 96, thyristors 90, PNP transistors 93, and resistors 94, 109, 110 corresponding to the diode 94, NPN transistors 111, 112 and 113, a thyristor 114, a PNP transistor 115, and a diode 116 are configured similarly to the oscillation permission circuit 49.

  The base of the transistor of the relay drive circuit 56 is connected to the ground line 62 through the diode 116 and the NPN transistor 113, similarly to the base of the transistor 81 in FIG. 2. The transistor 113 is turned on and off by the thyristor 114 and the transistor 111. It is controlled by the conduction state.

  With the above-described configuration, when the transistor 112 is turned off and the ENB signal becomes H level, the transistor 111 is turned on. When the transistor 115 is turned on and a trigger signal is applied to the gate of the thyristor 114 with the transistor 111 turned on, the thyristor 114 becomes conductive. Then, the transistor 113 is turned off, and the heater drive signal is transmitted to the relay drive circuit 56. That is, the heater heating permission circuit 55 is configured to permit or prohibit heating by the electric heater 7 by controlling whether or not to transmit a heater driving signal to the relay driving circuit 56.

Next, the operation of this embodiment will be described.
[1] Induction heating operation When the power-on switch 9 is pressed to start supplying power to the heating cooker 1, the common terminal COM and the normally-open terminal NO of the power-on switch 9 are connected, and the power circuit An AC voltage is applied to 34. As a result, the control microcomputer 33 is activated by being supplied with the operating power supply Vcc (+5 V). Then, the control microcomputer 33 immediately closes the self-holding DC relay 43 via the relay drive circuit 46. As a result, even after the power-on switch 9 is not pressed, the operating power supply Vcc continues to be supplied to the control microcomputer 33, and the control microcomputer 33 can cut off the operating power supply Vcc as needed. . At this time, the control microcomputer 33 turns on the power display unit 97.

  In the standby state where the power supply is just turned on, the off operation signal Sa output from the off operation detecting unit 36 to the oscillation permission circuit 49 is at the L level and the transistor 89 is off. Since the ENB signal output from 33 is at L level, the transistor 96 of the oscillation enable circuit 49 is on. Therefore, even when the control microcomputer 33 erroneously sends the inverter drive signals RU, RD, LU, and LD, the inverter circuits 31 and 30 are in an oscillation prohibited state in which the oscillation operation cannot be performed. Further, the control microcomputer 33 determines that the power-off switch 10 is not operated because the off operation signal Sa is at the L level.

  Subsequently, for example, when the right IH heating start switch 72 is pressed to start cooking using the right IH heating port 15, a signal indicating the heating start input to the RSB terminal of the control microcomputer 33 is H level. To change. At this time, since the transistor 78 is turned on while the right IH heating start switch 72 is being pressed, the transistor 93 is also turned on, and a trigger signal is given to the gate terminal of the thyristor 90. In addition, when the control microcomputer 33 detects a heating start command for the right IH heating port 15 by a change in the signal level input to the RSB terminal, the control microcomputer 33 changes the ENB signal to the H level to turn on the transistor 88. The time until the transistor 88 is turned on is sufficiently shorter than the time until the user presses the right IH start switch 72 and releases it, for example.

  That is, by turning on the transistor 88 while the trigger signal is applied to the gate terminal of the thyristor 90, the thyristor 90 becomes conductive. When the thyristor 90 becomes conductive, the thyristor 90 maintains that state as long as the transistor 88 is turned on even if the right IH heating start switch 72 is turned off. When the thyristor 90 becomes conductive, the transistor 96 is turned off. As a result, the right inverter drive signals RU and RD are not forcibly dropped to the L level, and the right inverter circuit 31 enters an oscillation permission state in which an oscillation operation can be performed.

  In the above state, the control microcomputer 33 closes the DC relay 47 via the relay drive circuit 48 to supply AC power to the right inverter circuit 31 and send out inverter drive signals RU and RD. Then, the control microcomputer 33 controls the inverter drive signals RU and RD so that the input power (thermal power) to the induction heating coil 6 becomes a value set by the user. At the same time as the induction heating is started in this way, the control microcomputer 33 turns on the photocoupler 45 to drive the cooling fan 44.

  Subsequently, when a right IH heating stop switch (not shown) is operated in order to end cooking, the control microcomputer 33 detects that the right IH heating stop switch is operated, and an inverter drive signal RU, The transmission of RD is stopped, and then the ENB signal is changed to the L level to turn off the transistor 88. As a result, the thyristor 90 is turned off and the transistor 96 is turned on to return to the standby state. In addition, the heating cooker 1 performs the same operation | movement as the case of the right IH heating port 15 mentioned above also about the case where it cooks using the left IH heating port 14. FIG.

  Subsequently, when the power-off switch 10 is pressed to stop the power supply to the cooking device 1 after the cooking is finished, the off-operation signal Sa changes to the H level. The control microcomputer 33 determines that the power-off switch 10 has been operated due to the level change of the off operation signal Sa. Then, the control microcomputer 33 turns off the power source display unit 97 and maintains the ENB signal at the L level regardless of changes in the signal levels input to the RSB terminal and the LSB terminal (each IH heating start switch 72, 73). The state of not accepting the operation. The control microcomputer 33 detects the temperature of the used right IH heating port 15 by the temperature sensor 58. Further, since the off operation signal Sa becomes H level, the transistor 89 is turned on, and the oscillation permission circuit 49 is in a heating prohibited state (even if heating is continued, it is forcibly stopped).

  When the detected temperature is higher than the predetermined temperature, the control microcomputer 33 continues the ON state of the DC relay 43 and sends an LED drive signal to the high temperature caution display unit 19 to alert the user and The cooling fan 44 is continuously driven while the coupler 45 is kept on. The control microcomputer 33 opens the DC relay 43 after confirming that the detected temperature is equal to or lower than the predetermined temperature. As a result, the supply of the operating power source Vcc to the control microcomputer 33 is stopped, and the power source of the entire heating cooker 1 is shut off. In the present embodiment, the predetermined temperature is a temperature that is safe when the user touches the heating port.

  By the way, in the above operation, even if the power-on switch 9 is operated while the detected temperature is higher than the predetermined temperature and the cooling fan 44 is continuously operated, the operation can be detected with the conventional configuration. There wasn't. For this reason, for example, after the user operates the power-off switch 10 once, the cooking is resumed even if the cooking is performed again before the temperature of the cooking device 1 falls below a predetermined temperature. I could not.

  On the other hand, in the present embodiment, when the power ON switch 9 is operated during the period when the DC relay 43 is ON, the control microcomputer 33 causes the level of the ON operation signal Sb output from the ON operation detection unit 35. The operation can be detected by the change. When the control microcomputer 33 detects the operation of the power-on switch 9, the power supply display unit 97 is turned on again, and the ENB signal is changed according to the change in the signal level input to the RSB terminal and the LSB terminal ( Each IH heating start switch 72, 73 is ready to be operated). That is, since the control microcomputer 33 returns to the standby state described above, cooking can be resumed even after the power-off switch 10 is operated and before the temperature of the heating cooker 1 becomes equal to or lower than the predetermined temperature.

  In addition, after cooking, for example, even when the user forgets to operate the power-off switch 10, the cooking device 1 performs the power supply stop operation as follows. That is, after the cooking is completed, the control microcomputer 33 confirms that the temperature of the used heating port has become sufficiently low in the same manner as when the power-off switch 10 is operated. After that, when the operation such as the heating start in the operation panel unit 8 or the operation of the power-on switch 9 is not performed for a predetermined time (for example, 1 hour), the control microcomputer 33 turns off the power display unit 97 and the DC relay 43. Is opened, and the power supply of the whole heating cooker 1 is cut off.

[2] Heater heating operation When the power-on switch 9 is pressed to start supplying power to the heating cooker 1, a standby state is entered in the same manner as in the induction heating operation. In this standby state, since the transistor 113 of the heater heating permission circuit 55 is turned on as in the case of the induction heating operation, even if the control microcomputer 33 erroneously sends a heater drive signal, the electric heater 7 It is in an energization prohibition state in which heating cannot be performed.

  Subsequently, when the heater heating start switch 103 is pressed to perform cooking using the central heater heating port 16, the signal input to the CSB terminal of the control microcomputer 33 changes to H level. At this time, since the transistor 106 is turned on while the heater heating start switch 103 is being pressed, the transistor 115 is also turned on, and a trigger signal is applied to the gate terminal of the thyristor 114. Further, when the control microcomputer 33 detects a heating start command for the central heater heating port 16 by a change in the signal level input to the CSB terminal, the control microcomputer 33 changes the ENB signal to the H level to turn on the transistor 111. The time until the transistor 111 is turned on is sufficiently shorter than, for example, the time from when the user depresses the heater heating start switch 103 until it is released.

  That is, by turning on the transistor 111 while the trigger signal is applied to the gate terminal of the thyristor 114, the thyristor 114 becomes conductive. If the thyristor 114 becomes conductive, the thyristor 114 maintains that state as long as the transistor 111 is turned on even if the heater heating start switch 103 is turned off. Thus, since the transistor 113 is turned off when the thyristor 114 becomes conductive, the heater drive signal is not forcibly dropped to the L level, and the energization permitted state in which heating by the electric heater 7 can be performed. .

  In the above state, the control microcomputer 33 closes the DC relay 52 via the relay drive circuit 54 to connect one end of the electric heater 7 to the power supply bus 37 and sends a heater drive signal. Then, the control microcomputer 33 performs on / off control of the heater driving signal so that the input power (thermal power) to the electric heater 7 becomes a value set by the user. Further, at the same time when the heater heating is started in this way, the control microcomputer 33 turns on the photocoupler 45 to drive the cooling fan 44.

Subsequently, when a heater heating stop switch (not shown) is operated in order to end cooking, the control microcomputer 33 detects the operation state and stops sending the heater driving signal. Thereafter, the control microcomputer 33 changes the ENB signal to L level to turn off the transistor 111. As a result, the thyristor 114 is turned off, so that the transistor 113 is turned on to return to the standby state.
The operation of the heating cooker 1 when the power-off switch 10 is pressed after the cooking is completed and when the user forgets to operate the power-off switch 10 is the case of the induction heating operation. The same is done.

As described above, according to the present embodiment, the following effects can be obtained.
In the cooking device 1, the power-on switch 9 and the power-off switch 10 are composed of switches that can be operated momentarily, so that the user can turn on and off the power with a light touch, and is operated in comparison with a conventional mechanical power switch. The characteristics are greatly improved.
The inverter drive signal output from the control microcomputer 33 is applied to the inverter circuits 30 and 31 via the oscillation permission circuit 49, and the oscillation permission circuit 49 permits transmission of the inverter drive signal according to the operation state of the power-off switch 10. It was banned. The heater drive signal output from the control microcomputer 33 is applied to the relay drive circuit 56 via the heater heating permission circuit 55, and the heater heating permission circuit 55 transmits the heater driving signal according to the operating state of the power-off switch 10. Was allowed or prohibited. Therefore, for example, even when a runaway or failure occurs in the control microcomputer 33 and the inverter drive signal continues to be sent to the inverter circuits 30 and 31 or the heater drive signal continues to be sent to the relay drive circuit 56, the user can If the power-off switch 10 is operated, the transmission of the inverter drive signal and the heater drive signal is prohibited, so that the induction heating operation and the heater heating operation can be forcibly terminated.

  An on operation detection unit 35 for detecting the operation state of the power on switch 9 is provided. As described above, since the power-on switch 9 can be operated with a light touch, the operation time is usually short. Therefore, when the on-operation signal Sb output from the on-operation detection unit 35 is maintained at the H level for an extremely longer time than the normal operation time, it is determined that an abnormality has occurred in the power-on switch 9. be able to. That is, for example, it is possible to detect a failure state in which the power-on switch 9 continues to be pressed due to a failure of a switch operation part.

  Even if the power-off switch 10 is pressed, the power supply to the control microcomputer 33 is held via the DC relay 43, and the control microcomputer 33 then shuts off the power supply by opening the DC relay 43 as necessary. I did it. Therefore, when cooking is finished and the power-off switch 10 is pressed by the user, the control microcomputer 33 alerts the high-temperature caution display unit 19 while the temperature of the used heating ports 14 to 16 is high. Thus, it is possible to prevent the user from touching the heating ports 14 to 16. Further, by driving the cooling fan 44 until the temperature of the heating port becomes sufficiently low, the heated heating port can be cooled in a short time.

  When the power-on switch 9 is operated while the DC relay 43 is on, the control microcomputer 33 detects the operation based on the level change of the on-operation signal Sb output from the on-operation detector 35. Can do. For this reason, for example, even after the user operates the power-off switch 10 and before the temperature of the heating cooker 1 falls below a predetermined temperature, the cooking can be resumed by operating the power-on switch 9. It becomes. Therefore, cooking can be resumed without waiting for the temperature of the heating cooker 1 to become equal to or lower than the predetermined temperature, and convenience is improved. In addition, since the power display unit 97 is turned on again according to the operation of the power-on switch 9 at this time, the user can visually recognize that the cooking can be resumed.

  When the user forgets to operate the power-off switch 10 after cooking, when the user forgets to operate the power-off switch 10 or when the operation of the power-on switch 9 is not performed for a while, for example, for one hour. Since the DC relay 43 is opened and the power supply to the entire cooking device 1 is cut off, wasteful power consumption can be suppressed as much as possible.

  The power supply off switch 10 is provided so as to be interposed in the energization path to which the operating power supply Vcc of +5 V, for example, is applied. Therefore, the power-off switch 10 can use a switch having a low withstand voltage and a low current capacity, such as a tact switch, and the cost can be reduced as compared with a conventional configuration using a micro switch.

In the off operation detection unit 36, a capacitor 71 is provided for maintaining the off operation signal Sa when the transistor 67 is switched from on to off at an L level for a predetermined time. Thereby, it is possible to suppress the influence of noise superimposed on the path from the power-off switch 10 to the node N2 on the off operation signal Sa. For example, when the power-off switch 10 is arranged on the operation panel unit 8, the wiring for connecting the terminal to the on-operation detection unit 35 becomes long, and it is necessary to take measures against noise in this wiring. Even in such a case, the on-operation detection unit 35 has improved noise resistance as described above, and thus can prevent erroneous output of the off-operation signal Sa.
When the power-on switch 9 and the power-off switch 10 are pressed at the same time, the control microcomputer 33 recognizes that the power-off switch 10 has been pressed with priority, so that safety can be improved.

  When the IH heating start switch 72 or 73 is pressed, the thyristor 90 of the oscillation permission circuit 49 is turned on to allow the inverter circuits 30 and 31 to oscillate. In addition, when the heater heating start switch 103 is pressed, the thyristor 114 of the heater heating permission circuit 55 is turned on so that the electric heater 7 is allowed to be energized. Therefore, even if the IH heating start switches 72 and 73 or the heater heating start switch 103 are operated instantaneously, the oscillation operation permission state or the energization permission state is continued, so the IH heating start switches 72 and 73 and the heater heating start switch The operability can be improved by configuring 103 with a light touch switch.

  An on-operation detecting unit that gives a signal indicating an operation state of the power-on switch 9 constituting the input side to which the commercial power is applied to the control microcomputer 33 and the oscillation permission circuit 49 on the control circuit 32 side to which the operating voltage Vcc is applied. 35 is configured using the photocoupler 60, the input side ground and the control circuit 32 side ground can be separated.

The present invention is not limited to the embodiment described above and illustrated in the drawings, and the following modifications or expansions are possible.
The IH heating start switches 72 and 73 and the heater heating start switch 103 for performing the heating start operation are composed of switches that can be operated momentarily, but these are composed of a rotary encoder type switch that can be pushed in. A function for adjusting the heating power may be added. In this way, it is not necessary to provide a separate dial for adjusting the thermal power, and the configuration of the operation panel unit 8 can be simplified.
The on-operation detecting unit 35 is configured mainly by the photocoupler 60. However, when it is not necessary to separate the ground on the input side and the ground on the control circuit 32 side, a semiconductor switching element such as a transistor may be mainly configured. . Further, the on-operation detecting unit 35 and the off-operation detecting unit 36 are not limited to the circuit configuration shown in the above embodiment, and may be any configuration that can detect the operation states of the power-on switch 9 and the power-off switch 10. The capacitor 71 of the off operation detection unit 36 may be provided according to the degree of influence of noise on the off operation signal Sa.

After completion of pressing heat cooking, while the temperature of the heating ports 14 to 16 used is high it is configured so as to drive the cooling fan 44 until the temperature of the heating port with attention by the high temperature warning display unit 19 is low enough These may be provided as necessary.
In the above embodiment, the control related to the power supply when induction heating cooking using the induction heating coils 5 and 6 is performed or when the heater heating cooking is performed using the central electric heater 7 has been described, but one of the other heating means The same effect can be obtained by applying the same configuration to the roaster. Moreover, the heating cooker does not need to be provided with all the heating means described above, and it is sufficient that only one of them is provided.
In the present embodiment, the built-in type heating cooker 1 incorporated in the kitchen table 2 has been described as an example. However, the present invention is not limited to this, and is applied to a stationary type heating cooker used on a table. Is also applicable.

The block diagram which shows the electric constitution of the heating cooker which shows one Embodiment of this invention. The figure which shows the configuration related to the induction heating operation in detail The figure which shows the configuration related to the heater heating operation in detail External perspective view of cooking device

Explanation of symbols

  In the drawings, 1 is a heating cooker (cooker body), 5 and 6 are induction heating coils (heating means), 7 is an electric heater (heating means), 8 is an operation panel section (operation section), and 9 is a power on switch. 10 is a power supply off switch, 33 is a control microcomputer (control unit), 34 is a power supply circuit (power supply unit), 35 is an on operation detection unit, 36 is an off operation detection unit, 43 is a DC relay (self-holding means), 44 Is a cooling fan (controlled part), 49 is an oscillation permission circuit (heating prohibiting means), 55 is a heater heating permission circuit (heating prohibiting means), 60 is a photocoupler, and 71 is a capacitor (noise filter part).

Claims (6)

The cooker body,
Heating means for heating;
A control unit for controlling heating by the heating means;
A power supply unit that generates an operation power supply from a commercial power supply and supplies the operation power supply to the control unit;
The Der those operated to start supplying the commercial power source to the cooking device body is, the common terminal, and a switch double throw type having a normally open terminal and the normally closed terminal, the common terminal in the operating state and turning on the switch to form a first feed path to the power supply unit from the commercial power source by and the between normally open terminal conducts,
An on-operation detecting unit connected to a normally-closed terminal of the power-on switch and detecting an operation state of the power-on switch;
Is intended to hold the current state of the second power supply path to the power supply unit from the commercial power supply is controlled is provided in parallel with said first feed path by the control unit, the common terminal and the normally of the power-on switch Self-holding means having a DC relay connected between the open terminals ;
It is operated to stop the supply of the commercial power supply to the cooker body , and can output an operation signal in the operation state, and is interposed in a detection energization path to which the operation power supply is applied. A power-off switch provided
An off operation detector that detects the operation signal of the power off switch based on a terminal voltage of the power off switch;
Heating prohibiting means for prohibiting heating by the heating means when the operation signal is output from the power-off switch ;
A controlled part including a cooling fan for cooling the cooker body;
An operation unit for making settings related to cooking;
With
The controlled part operates by being controlled by the control part, and continues to operate even when the operation signal is output from the power-off switch,
The control unit operates the power-on switch when the operation unit is not operated for a predetermined time in a state where the energization state of the second power supply path is held by the self-holding unit and when the power-on switch is operated through the on-operation detection unit. When not detected for a predetermined time, the cooker characterized by releasing the holding of the energized state by the self-holding means . The heating cooker according to claim 1, wherein
The cooking device according to claim 1, wherein the off operation detection unit includes a noise filter unit that receives a terminal voltage of the power off switch, and detects the operation signal based on an output of the noise filter unit . The heating cooker according to claim 1 or 2,
The said cooking part gives priority to the detection by the said off operation detection part in the state by which the said power-on switch and the said power-off switch were operated simultaneously, The heating cooker characterized by the above-mentioned . The heating cooker according to any one of claims 1 to 3,
The cooking device according to claim 1, wherein the on-operation detecting unit includes a photocoupler that outputs a signal indicating an operation state of the power-on switch to the control unit . Heating means for heating, a control section for controlling heating by the heating means, a power supply section for generating an operation power supply from a commercial power supply and supplying it to the control section, and starting supply of the commercial power supply to the cooker body der those operated to is, the common terminal, a normally open terminal and the switch of the double-throw type having a normally closed, the commercial by between the common terminal and the normally open terminal at its operating state conducts A power-on switch that forms a first power supply path from a power source to the power source unit, an on-operation detection unit that is connected to a normally open terminal of the power-on switch and detects an operation state of the power-on switch, and the control unit is from controlled the commercial power supply provided in parallel with said first feed path to hold the current state of the second power supply path to the power supply unit, the common terminal and the normally open of the power-on switch A self-holding means having a connected DC relay between the child, is capable of outputting an operation signal in the operation state be one that is operated to stop the supply of the commercial power supply to the cooker body A power-off switch provided in a detection energization path to which the operation power is applied, and an off-operation detection unit that detects the operation signal of the power-off switch based on a terminal voltage of the power-off switch And a power supply method to a heating cooker comprising a heating prohibiting means for prohibiting or permitting heating by the heating means,
When the power-on switch is operated, the power supply unit generates an operation power supply and supplies the operation power supply to the control unit, and the control unit receives the operation power supply and starts an operation to perform the self holding unit. And start supplying the commercial power to the cooker body as a holding state,
When the power-off switch is operated, the heating prohibiting unit prohibits heating by the heating unit, and the control unit releases the holding state of the self-holding unit and supplies the commercial power to the cooker body The power supply method to the heating cooker characterized by stopping. A method for supplying power to a heating cooker according to claim 5,
An operation unit for making settings related to cooking;
A controlled part including a cooling fan for cooling the cooker body,
The control unit controls heating by the heating unit based on an operation of the operation unit,
When the power-off switch is operated, the control unit enters a state where it does not accept the operation of the operation unit, and continuously operates the controlled unit,
When the operation of the power-on switch is detected via the on operation detection unit during a period in which the controlled unit is continuously operated, the control unit is in a state of accepting the operation of the operation unit. To supply power to the cooking device.

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