JP7108439B2 - cooking device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating cooker such as an induction heating cooker, a hot plate, an electric pan, etc., which is placed on a dining table and used.

2. Description of the Related Art Conventionally, as this type of heat cooking apparatus, there has been known one in which an operation panel is provided on the upper surface of a cooker main body (see, for example, Patent Document 1). In such a heat cooking apparatus, when a pot is placed on the top plate, the pot is heated to heat and cook the food in the pot. Also, such a heat cooking device is placed approximately in the center of the table when in use.

JP-A-9-213469

In such a heat cooking apparatus, when the heat cooking apparatus is connected to a power supply, power is supplied to a microcomputer as a control means to start the microcomputer. Then, by pressing the heating switch, heating is started. However, as described above, the microcomputer is in operation when the cooking apparatus is connected to the power supply. I was afraid I might let it happen.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems and to provide a heat cooking apparatus capable of suppressing malfunction of the heating source when heating is stopped.

A heating cooking apparatus according to claim 1 of the present invention comprises a rectifying circuit connected to an AC power supply, a heating source connected between both electrodes of the rectifying circuit via a heating source driving circuit, and driving the heating source. a power supply circuit provided in parallel with the heat source; a control means provided in parallel with the heat source for controlling the heat source drive circuit; and a self-recovery switch and diode. A cooking device comprising a series circuit, a switching element provided in parallel with the series circuit, and a line branched from between the switch and the diode and connected to an input part of the control means , wherein the switch and a diode and a switching element are arranged between the power supply circuit and the power supply input of the control means, such that current is supplied from the control means to the switching element during operation of the control means. It consists of

According to claim 2 of the present invention, there is provided the heat cooking apparatus according to claim 1, wherein a series circuit is formed by the plurality of switching elements, and the series circuit is connected in parallel with the switch .

Further , according to claim 3 of the present invention, there is provided a heat cooking apparatus according to claim 1 , wherein the current is supplied to the switching element via a capacitor for passing the intermittent current and a smoothing means for smoothing the intermittent current. It consists of

According to the heat cooking apparatus according to claim 1 of the present invention, with the configuration as described above, the control means does not operate unless the switch is operated. It is possible to prevent unintentional current from flowing into the source. Then, the control means can stop the current supply to the switching element to stop the power supply to the control means. That is, the control means can be deactivated by the control means itself. Further, power is supplied from the power supply circuit to the power supply input section of the control means through a switch and a diode. Even if a large amount of power is supplied from an AC power source to the heating source, the switch can be a relatively small capacity switch.

A series circuit is formed by a plurality of the switching elements, and the series circuit is connected in parallel with the switch, so that even if one of the switching elements fails in a short circuit mode, the other switching elements are turned off. , the control means can be reliably stopped.

Further , the current is supplied to the switching element via a capacitor for passing the intermittent current and a smoothing means for smoothing the intermittent current, so that the control means fails and the intermittent current cannot be output. When it runs out, the current cannot be supplied to the switching element. Therefore, it is possible to prevent the control means from being activated in a state where the control means is out of order.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view of the heat cooking apparatus which shows 1st embodiment of this invention. It is a side view of a cooking apparatus main body equally. It is a top view of a cooking apparatus main body equally. Fig. 3 is an enlarged front view of the remote controller of the same; Fig. 3 is an enlarged plan view of the remote controller of the same; It is a schematic diagram of an electric circuit of the same. It is an explanatory view of the state of use of the same. Fig. 2 is a perspective view of a heat cooking device showing a second embodiment of the present invention; It is a side view of a cooking apparatus main body equally. It is a schematic diagram of an electric circuit of the same. It is an explanatory view of the state of use of the same. FIG. 10 is a perspective view of a heat cooking device showing a third embodiment of the present invention; It is an explanatory view of the state of use of the same. FIG. 10 is an explanatory diagram of an electric circuit of a heat cooking device showing a fourth embodiment of the present invention;

A first embodiment of the present invention will be described below with reference to FIGS. 1 to 7. FIG. 1 is the heat cooking apparatus of the present invention. This heat cooking device 1 includes a cooking device main body 2 and a remote control body 3 . In addition, in the present embodiment, the heat cooking device 1 is an induction heating cooker.

The cooking apparatus main body 2 has a short cylindrical upper shell 4 , a dish-shaped lower shell 5 , and a disk-shaped top plate 6 provided on the upper shell 4 . An induction heating coil 7 as a heat source and an LED array 8 as display means are housed below the top plate 6 . Light emitted from this LED array 8 is transmitted through the top plate 6 and is visually recognized. A pot compatible with an induction heating cooker (not shown) can be placed on the top plate 6 . Cutouts 9 and 10 are provided on the side surface of the upper shell 4 and the side surface of the lower shell 5, respectively. . A magnet plug of a power cord (not shown) is detachably connected to the power connection portion 11 . A main switch operation portion 12 and an output control switch operation portion 13 are provided on the side portion of the lower shell body 5 . Further, a plurality of (three in this embodiment) light receiving windows 15 of the infrared signal receiving section 14 are provided on the side portion of the lower shell body. These light receiving windows 15 appear in a side view. Further, these light receiving windows 15 are provided at equal angular intervals (120 degree intervals in this embodiment) around the vertical center line of the cooking apparatus main body 2 .

The remote control body 3 has a short cylindrical shape as a whole. The remote control unit 3 includes a short cylindrical body portion 16 and an operation portion 17 that is put on the body portion 16 . The operating portion 17 is provided so as to be rotatable in the horizontal direction and movable in the vertical direction with respect to the main body portion 16 . Further, the body portion 16 is provided with means (not shown) for detecting the amount of horizontal rotation of the operation portion 17 and the downward pressure. Furthermore, the lower end of the operating portion 17 is higher than the lower end of the main body portion 16 . Accordingly, the lower portion of the body portion 16 is exposed to the outside. A plurality of (three in the present embodiment) emission windows 19 of the infrared signal transmitter 18 are provided on the exposed lower side surface of the main body 16 . These emission windows 19 appear in a side view. Further, these emission windows 19 are provided at equal angular intervals (120° intervals in this embodiment) around the vertical center line of the remote control unit 3 . An infrared LED (not shown) is provided inside each of the emission windows 19 . That is, in the case of this embodiment, the infrared LEDs are provided at three locations, like the emission windows 19 . The number of infrared LEDs per location may be one or plural.

An outline of the electric circuit of the cooking apparatus main body 2 will be described. In this electric circuit, as shown in FIG. 6, an AC power supply 20 is connected to a rectifier circuit 20A, and the induction heating coil 7 is connected between both electrodes of the rectifier circuit 20A via an induction heating drive circuit 21 as a heat source drive circuit. are connected structures. The induction heating coil 7 is driven and controlled by the induction heating drive circuit 21 . A power supply circuit 22 and a microcomputer 23 as control means are connected in parallel with the induction heating coil 7 . A series circuit of a switch SW1 and a diode D is provided between the power supply circuit 22 and the microcomputer 23. FIG. The switch SW1 is of a self-reset type, and is operated by pressing the main switch operating portion 12. As shown in FIG. A series circuit of the switch SW1 and the diode D is connected to the power supply input PW of the microcomputer 23 . Further, a line branched from between the switch SW1 and the diode D is connected to the input section X of the microcomputer 23. As shown in FIG. Furthermore, a series circuit of field effect transistors (hereinafter referred to as FETs) 24 and 25 as switching elements is connected in parallel with the series circuit of the switch SW1 and the diode D. The output A of the microcomputer 23 is connected through a capacitor C to an integration circuit 26 as a smoothing means, and the integration circuit 26 is connected to the gate of the FET 24 . On the other hand, the microcomputer 23 has its output B connected to the gate of the FET 25 . The microcomputer 23 is connected to the induction heating drive circuit 21 and configured to be able to control the induction heating drive circuit 21 . Further, infrared sensors 27 , 28 and 29 are connected to the microcomputer 23 . The infrared sensor 27 is arranged inside the light receiving window 15A, the infrared sensor 28 is arranged inside the light receiving window 15B, and the infrared sensor 29 is arranged inside the light receiving window 15C. Also, the microcomputer 23 is connected to a switch SW2. The switch SW2 is also of a self-reset type, and is operated by pressing the output adjustment switch operating portion 13. FIG. Furthermore, the LED array 8 is connected to the microcomputer 23 .

With such a circuit configuration, although a large amount of power is supplied from the AC power source 20 to the induction heating coil 7, the switch SW1 can be a switch with a relatively small capacity. This is because the current flowing through the switch SW1 needs only to have a sufficient value to activate the microcomputer 23. FIG.

Next, the operation of this embodiment will be described. First, the user connects the magnet plug of the power cord (not shown) to the power supply connector 11 and connects the power plug to the AC power supply 20 . In this state, no current flows through the induction heating coil 7, and the microcomputer 23 does not start. When the main switch operating portion 12 is pressed, the switch SW1 is turned "on". Thus, when the switch SW1 is turned "on", power is supplied from the power supply circuit 22 to the power input part PW of the microcomputer 23 through the switch SW1 and the diode D, and the microcomputer 23 is activated. At the same time, the microcomputer 23 detects that the current flowing through the switch SW1 is supplied to the input section X. When the microcomputer 23 detects that the current is supplied to the input section X, the microcomputer 23 supplies an intermittent current from the output section A to the integration circuit 26 . Since the current supplied from the output portion A is an intermittent current, it passes through the capacitor C and is supplied to the integrating circuit 26. FIG. This intermittent current is smoothed by the integration circuit 26 to become a DC current, which is supplied to the gate of the FET 24 . At the same time, a DC current is supplied from the output B of the microcomputer 23 to the gate of the FET 25 . By supplying currents to the gates of the FETs 24 and 25 in this way, the FETs 24 and 25 are turned on at the same time, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 and the Power is supplied to the power input unit PW of the microcomputer 23 . Since the switch SW1 is a self-reset type switch as described above, it turns "OFF" when the user releases the main switch operation section 12. FIG. However, current continues to flow to the microcomputer 23 due to current flowing through the series circuit of the FETs 24 and 25 . By continuing to supply the current to the microcomputer 23, the currents continue to be supplied to the gates of the FETs 24 and 25, respectively. Therefore, the microcomputer 23 continues to operate. The current flowing through the series circuit of the FETs 24 and 25 is blocked by the diode D and therefore does not flow to the input X.

Thus, when the microcomputer 23 operates, the microcomputer 23 controls the induction heating drive circuit 21 , and the induction heating drive circuit 21 drives and controls the induction heating coil 7 . That is, an alternating current is supplied to the induction heating coil 7 by the induction heating drive circuit 21 . The set output of the induction heating coil 7 when the microcomputer 23 is activated may be the minimum value or the output value of the previous use. Each time the microcomputer 23 detects that the switch SW2 is turned on by pressing the output adjustment switch operating section 13, the microcomputer 23 controls the induction heating control circuit 21 to turn the induction heating coil 7 on. Control the output in multiple stages. Further, the microcomputer 23 controls the number of LEDs to be emitted in the LED array 8 each time the switch SW2 is turned on. At this time, the number of LEDs to emit light in the LED array 8 corresponds to the output of the induction heating coil 7 . Therefore, the current output of the induction heating coil 7 can be known from the number of LEDs in the LED array 8 emitting light. Light emitted from the LEDs of the LED array 8 passes through the top plate 6 and is visually recognized.

Note that the control of the cooking apparatus main body 2 can also be performed by operating the remote control body 3 . (However, only the operation from activation of the microcomputer 23 to the start of heating is performed by the main switch 12 of the cooking apparatus main body 2.) The remote control unit 3 is operated while placed on the dining table T. . That is, when the remote control unit 3 is placed on the dining table T and the operation part 17 is pushed downward, the current to the induction heating coil 7 is cut off. Even if the operating portion 17 is pushed downward again, the energization of the induction heating coil 7 is not resumed. When the operating portion 17 is rotated clockwise, the output of the induction heating coil 7 increases, and when the operating portion 17 is rotated counterclockwise, the output of the induction heating coil 7 decreases.

A control signal generated by such an operation is transmitted as an infrared signal S from the three infrared LEDs (not shown) of the infrared signal transmission unit 18, and emitted from the emission windows 19, 19, 19. . That is, the infrared signal S is transmitted from the remote controller 3 in three directions. In addition, the infrared LED has a relatively wide irradiation angle (specifically, about 120 degrees). Therefore, the infrared signal S is transmitted over a wide range around the remote control 3 .

On the other hand, the infrared sensors 27, 28, 29 of the cooking apparatus main body 2 also have a relatively wide detection angle (specifically, approximately 140 degrees). Therefore, the infrared sensors 27 , 28 and 29 can receive the infrared signal S from all directions around the cooking apparatus main body 2 . For example, as shown in FIG. 7, the infrared signal S emitted from the light emitting window 19A of the remote control unit 3 placed at the position P1 on the dining table T is received by the light receiving window 15A of the cooking apparatus main body 2. is received by the infrared sensor 27 through . On the other hand, the infrared signal S emitted from the light emitting window 19B of the remote control unit 3 placed at the position P2 on the dining table T passes through the light receiving window 15C of the cooking apparatus main body 2 and reaches the infrared sensor. 29 receives. At the same time, the infrared signal S emitted from the light emitting window 19C is received by the infrared sensor 28 through the light receiving window 15B of the cooking apparatus main body 2. As shown in FIG. That is, in the case of this example, two systems of infrared signals S are exchanged. Depending on the positional relationship between the cooking apparatus main body 2 and the remote controller 3, the infrared signal S transmitted by the infrared LED at one location may be received by two infrared sensors, or The infrared signal S transmitted by the LED may be received by one infrared sensor. That is, by receiving the infrared signal S transmitted by any of the infrared LEDs by any of the infrared sensors 27, 28, 29, the remote control 3 can control the cooking apparatus main body 2. becomes. Since the infrared signals S transmitted in three directions from the remote controller 3 are all the same command signal, even if they are received by a plurality of the infrared sensors 27, 28 and 29, there will be no contradiction in command. Note that FIG. 7 does not provide two remote control units 3 for one cooking apparatus main body 2 . The case where one remote control unit 3 is placed at position P1 on the dining table T and the case where it is placed at position P2 for one cooking apparatus main body 2 are shown simultaneously in one drawing.

With the remote control unit 3 placed on the dining table T, when the operation unit 17 is pushed downward or the main switch operation unit 12 is pushed to turn on the switch SW1, the microcomputer 23 is turned on. cuts off the energization of the induction heating coil 7 and then stops its own operation. When the induction heating coil 7 is de-energized by operating the remote controller 3, when the infrared sensors 27, 28 and 29 receive the infrared signal S of the stop instruction, the microcomputer 23 detects the induction heating coil 7. After the power supply to the induction heating coil 7 is stopped by the drive circuit 21, the current supply from the output portions A and B is stopped. On the other hand, when the induction heating coil 7 is deenergized by operating the main switch operation section 12, when it is detected that the current is supplied from the power supply circuit 22 to the input section X through the switch SW1, the micro The computer 23 stops the current supply from the output portions A and B after stopping the energization of the induction heating coil 7 by the induction heating drive circuit 21 . As a result, the current supply to the gates of the FETs 24 and 25 is cut off, so that both of these FETs 24 and 25 are turned off, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 to the microcomputer 23 . is also cut off. This causes the microcomputer 23 to stop. Thus, when the microcomputer 23 stops, it becomes impossible to control the induction heating drive circuit 21 and supply current to the induction heating coil 7 . Therefore, it is possible to reduce the possibility that current is unintentionally supplied to the induction heating coil 7 due to malfunction of the microcomputer 23 when not in use. Thereby, the safety of the heat cooking device 1 can be enhanced. When the microcomputer 23 determines that there is no operation for a predetermined time (for example, 30 minutes) during heating by the induction heating coil 7, the induction heating drive circuit 21 stops energizing the induction heating coil 7. After that, the current supply from the output sections A and B is stopped. This causes the microcomputer 23 to stop.

By connecting the FETs 24 and 25 in series, even if one of the FETs 24 or 25 fails in a short-circuit mode, by stopping the power supply to the gate of the other FET 25 or 24, the microcomputer 23 can be stopped. Therefore, the possibility that the microcomputer 23 cannot be stopped can be reduced. Further, if the microcomputer 23 fails, the intermittent current cannot be output from the output section A of the microcomputer 23 . If no current can be supplied from the output section A, no current is supplied to the gate of the FET 24 . Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Conversely, if the current supplied from the output section A becomes a DC current, this DC current cannot pass through the capacitor C, so that no current is supplied to the gate of the FET 24 as well. Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Therefore, it is possible to prevent current from being supplied to the induction heating coil 7 when the microcomputer 23 fails.

As described above, the present invention includes an induction heating coil 7 as a heat source, an induction heating drive circuit 21 as a heat source drive circuit for driving the induction heating coil 7, a power supply circuit 22, and the induction heating drive circuit 21. and a switch SW1, wherein the switch SW1 is arranged between the power supply circuit 22 and the microcomputer 23 so that the switch SW1 Since the microcomputer 23 does not operate unless the .

Further, according to the present invention, the switch SW1 is of a self-recovery type, and FETs 24 and 25 as switching elements are connected in parallel with the switch SW1. is supplied, the microcomputer 23 can stop the current supply to the FETs 24 and 25 and the power supply to the microcomputer 23 itself. That is, the microcomputer 23 can be stopped by the microcomputer 23 itself.

Further, according to the present invention, a series circuit is formed by a plurality of the FETs 24 and 25, and the series circuit is connected in parallel with the switch SW1. By turning off the FET 25 or 24, the microcomputer 23 can be reliably stopped.

Further, according to the present invention, a current is supplied to the gate of the FET 24 via a capacitor C for passing the intermittent current and an integration circuit 26 as smoothing means for smoothing the intermittent current. If the computer 23 breaks down and cannot output the intermittent current, the current cannot be supplied to the FET 24, so that the microcomputer 23 can be prevented from being started when the microcomputer 23 is broken. .

Next, a second embodiment of the invention will be described with reference to FIGS. 8 to 11. FIG. In addition, the common code|symbol is attached|subjected about the part which is common in the said 1st embodiment. 31 is a heat cooking device of the present invention. This heat cooking device 31 comprises a cooking device main body 32, a remote control unit 33, and a signal line 34 connecting them. In addition, in the present embodiment, the heat cooking device 31 is an induction heating cooker.

The cooking apparatus main body 32 has a short cylindrical upper shell 4 , a dish-shaped lower shell 35 , and a disk-shaped top plate 6 provided on the upper shell 4 . An induction heating coil 7 as a heat source and an LED array 8 as display means are housed below the top plate 6 . Light emitted from this LED array 8 is transmitted through the top plate 6 and is visually recognized. A pot compatible with an induction heating cooker (not shown) can be placed on the top plate 6 . Cutouts 9 and 10 are provided on the side surface of the upper shell 4 and the side surface of the lower shell 5, respectively. . A magnet plug of a power cord (not shown) is detachably connected to the power connection portion 11 . A main switch operation portion 12 and an output control switch operation portion 13 are provided on the side portion of the lower shell body 5 .

The remote control body 33 has a short cylindrical shape as a whole. The remote control unit 3 includes a short cylindrical body portion 36 and an operation portion 17 that is put on the body portion 36 . The operating portion 17 is provided so as to be rotatable in the horizontal direction and movable in the vertical direction with respect to the main body portion 36 . Further, the body portion 36 is provided with means (not shown) for detecting the amount of rotation of the operation portion 17 in the horizontal direction and the downward pressure. Furthermore, the lower end of the operating portion 17 is higher than the lower end of the main body portion 36 . Accordingly, the lower portion of the body portion 36 is exposed to the outside.

An outline of an electric circuit of the heat cooking device 31 will be described. In this electric circuit, as shown in FIG. 10, an AC power supply 20 is connected to a rectifier circuit 20A, and the induction heating coil 7 is connected between both electrodes of the rectifier circuit 20A via an induction heating drive circuit 21 as a heat source drive circuit. are connected structures. The induction heating coil 7 is driven and controlled by the induction heating drive circuit 21 . A power supply circuit 22 and a microcomputer 23 as control means are connected in parallel with the induction heating coil 7 . A series circuit of a switch SW1 and a diode D is provided between the power supply circuit 22 and the microcomputer 23. FIG. The switch SW1 is of a self-reset type, and is operated by pressing the main switch operating portion 12. As shown in FIG. A series circuit of the switch SW1 and the diode D is connected to the power supply input PW of the microcomputer 23 . Further, a line branched from between the switch SW1 and the diode D is connected to the input section X of the microcomputer 23. As shown in FIG. Furthermore, a series circuit of field effect transistors (hereinafter referred to as FETs) 24 and 25 as switching elements is connected in parallel with the series circuit of the switch SW1 and the diode D. The output A of the microcomputer 23 is connected through a capacitor C to an integration circuit 26 as a smoothing means, and the integration circuit 26 is connected to the gate of the FET 24 . On the other hand, the microcomputer 23 has its output B connected to the gate of the FET 25 . The microcomputer 23 is connected to the induction heating drive circuit 21 and configured to be able to control the induction heating drive circuit 21 . Further, the remote controller 33 is connected to the microcomputer 23 via the signal line 34 . Also, the microcomputer 23 is connected to a switch SW2. The switch SW2 is also of a self-reset type, and is operated by pressing the output adjustment switch operating portion 13. FIG. Furthermore, the LED array 8 is connected to the microcomputer 23 .

With such a circuit configuration, although a large amount of power is supplied from the AC power supply 20 to the induction heating coil 7, the switch SW1 can be a switch with a relatively small capacity. This is because the current flowing through the switch SW1 needs only to have a sufficient value to activate the microcomputer 23. FIG.

Next, the operation of this embodiment will be described. First, the user connects the magnet plug of the power cord (not shown) to the power supply connector 11 and connects the power plug to the AC power supply 20 . In this state, no current flows through the induction heating coil 7, and the microcomputer 23 does not start. When the main switch operating portion 12 is pressed, the switch SW1 is turned "on". Thus, when the switch SW1 is turned "on", power is supplied from the power supply circuit 22 to the power input part PW of the microcomputer 23 through the switch SW1 and the diode D, and the microcomputer 23 is activated. At the same time, the microcomputer 23 detects that the current flowing through the switch SW1 is supplied to the input section X. When the microcomputer 23 detects that the current is supplied to the input section X, the microcomputer 23 supplies an intermittent current from the output section A to the integration circuit 26 . Since the current supplied from the output portion A is an intermittent current, it passes through the capacitor C and is supplied to the integrating circuit 26. FIG. This intermittent current is smoothed by the integration circuit 26 to become a DC current, which is supplied to the gate of the FET 24 . At the same time, a DC current is supplied from the output B of the microcomputer 23 to the gate of the FET 25 . By supplying currents to the gates of the FETs 24 and 25 in this way, the FETs 24 and 25 are turned on at the same time, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 and the Power is supplied to the power input unit PW of the microcomputer 23 . Since the switch SW1 is a self-reset type switch as described above, it turns "OFF" when the user releases the main switch operation section 12. FIG. However, current continues to flow to the microcomputer 23 due to current flowing through the series circuit of the FETs 24 and 25 . By continuing to supply the current to the microcomputer 23, the currents continue to be supplied to the gates of the FETs 24 and 25, respectively. Therefore, the microcomputer 23 continues to operate. The current flowing through the series circuit of the FETs 24 and 25 is blocked by the diode D and therefore does not flow to the input X.

Thus, when the microcomputer 23 operates, the microcomputer 23 controls the induction heating drive circuit 21 , and the induction heating drive circuit 21 drives and controls the induction heating coil 7 . That is, an alternating current is supplied to the induction heating coil 7 by the induction heating drive circuit 21 . The set output of the induction heating coil 7 when the microcomputer 23 is activated may be the minimum value or the output value of the previous use. Each time the microcomputer 23 detects that the switch SW2 is turned on by pressing the output adjustment switch operating section 13, the microcomputer 23 controls the induction heating control circuit 21 to turn the induction heating coil 7 on. Control the output in multiple stages. Further, the microcomputer 23 controls the number of LEDs to be emitted in the LED array 8 each time the switch SW2 is turned on. At this time, the number of LEDs to emit light in the LED array 8 corresponds to the output of the induction heating coil 7 . Therefore, the current output of the induction heating coil 7 can be known from the number of LEDs in the LED array 8 emitting light. Light emitted from the LEDs of the LED array 8 passes through the top plate 6 and is visually recognized.

The control of the cooking apparatus main body 32 can also be performed by operating the remote control body 33 . (However, only the operation from activation of the microcomputer 23 to the start of heating is performed by the main switch 12 of the cooking apparatus main body 2.) The remote control unit 33 is operated while placed on the dining table T. . That is, when the remote control unit 33 is placed on the dining table T and the operation unit 17 is pushed downward, the electric current to the induction heating coil 7 is cut off. Even if the operating portion 17 is pushed downward again, the energization of the induction heating coil 7 is not resumed. When the operating portion 17 is rotated clockwise, the output of the induction heating coil 7 increases, and when the operating portion 17 is rotated counterclockwise, the output of the induction heating coil 7 decreases. A control signal generated by operating the remote controller 33 is sent to the microcomputer 23 via the signal line 34 . Then, as shown at positions P1 and P2 in FIG. 11, the remote controller 33 can be placed at any position on the dining table T and operated within the length of the signal line 34 . It should be noted that FIG. 11 does not provide two remote control units 33 for one cooking apparatus main body 32 . The case where one remote control unit 33 is placed on one cooking apparatus main body 32 at position P1 and the case where it is placed at position P2 on the dining table T are shown in one drawing at the same time.

With the remote control unit 33 placed on the dining table T, when the operation unit 17 is pushed downward or the main switch operation unit 12 is pushed to turn on the switch SW1, the microcomputer 23 is turned on. cuts off the energization of the induction heating coil 7 and then stops its own operation. When the induction heating coil 7 is de-energized by operating the remote controller 33, when the microcomputer 23 detects a stop command signal from the signal line 34, the microcomputer 23 controls the induction heating drive circuit. After energization of the induction heating coil 7 is stopped by 21, current supply from the output portions A and B is stopped. On the other hand, when the induction heating coil 7 is deenergized by operating the main switch operation section 12, when it is detected that the current is supplied from the power supply circuit 22 to the input section X through the switch SW1, the micro The computer 23 stops the current supply from the output portions A and B after stopping the energization of the induction heating coil 7 by the induction heating drive circuit 21 . As a result, the current supply to the gates of the FETs 24 and 25 is cut off, so that both of these FETs 24 and 25 are turned off, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 to the microcomputer 23 . is also cut off. This causes the microcomputer 23 to stop. Thus, when the microcomputer 23 stops, it becomes impossible to control the induction heating drive circuit 21 and supply current to the induction heating coil 7 . Therefore, it is possible to reduce the possibility that current is unintentionally supplied to the induction heating coil 7 due to malfunction of the microcomputer 23 when not in use. Thereby, the safety of the heat cooking device 31 can be enhanced. When the microcomputer 23 determines that there is no operation for a predetermined time (for example, 30 minutes) during heating by the induction heating coil 7, the induction heating drive circuit 21 stops energizing the induction heating coil 7. After that, the current supply from the output sections A and B is stopped. This causes the microcomputer 23 to stop.

By connecting the FETs 24 and 25 in series, even if one of the FETs 24 or 25 fails in a short-circuit mode, by stopping the power supply to the gate of the other FET 25 or 24, the microcomputer 23 can be stopped. Therefore, the possibility that the microcomputer 23 cannot be stopped can be reduced. Further, if the microcomputer 23 fails, the intermittent current cannot be output from the output section A of the microcomputer 23 . If no current can be supplied from the output section A, no current is supplied to the gate of the FET 24 . Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Conversely, if the current supplied from the output section A becomes a DC current, this DC current cannot pass through the capacitor C, so that no current is supplied to the gate of the FET 24 as well. Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Therefore, it is possible to prevent current from being supplied to the induction heating coil 7 when the microcomputer 23 fails.

Compared to the first embodiment, this embodiment is inconvenient when many tableware and the like are placed on the dining table T due to the lack of wireless connection. The effect of being able to operate the heat cooking device 31 is common.

As described above, the present invention includes an induction heating coil 7 as a heat source, an induction heating drive circuit 21 as a heat source drive circuit for driving the induction heating coil 7, a power supply circuit 22, and the induction heating drive circuit 21. and a switch SW1, wherein the switch SW1 is arranged between the power supply circuit 22 and the microcomputer 23 so that the switch SW1 Since the microcomputer 23 does not operate unless the .

Further, according to the present invention, the switch SW1 is of a self-recovery type, and FETs 24 and 25 as switching elements are connected in parallel with the switch SW1. is supplied, the microcomputer 23 can stop the current supply to the FETs 24 and 25 and the power supply to the microcomputer 23 itself. That is, the microcomputer 23 can be stopped by the microcomputer 23 itself.

Further, according to the present invention, a series circuit is formed by a plurality of the FETs 24 and 25, and the series circuit is connected in parallel with the switch SW1. By turning off the FET 25 or 24, the microcomputer 23 can be reliably stopped.

Further, according to the present invention, a current is supplied to the gate of the FET 24 via a capacitor C for passing the intermittent current and an integration circuit 26 as smoothing means for smoothing the intermittent current. If the computer 23 breaks down and cannot output the intermittent current, the current cannot be supplied to the FET 24, so that the microcomputer 23 can be prevented from being started when the microcomputer 23 is broken. .

Next, a third embodiment of the present invention will be described with reference to FIGS. 2, 3, 6, 12 and 13. FIG. In addition, in this embodiment, the cooking apparatus main body 2 is the same as that of the first embodiment. That is, FIGS. 2, 3 and 6 of the first embodiment are also applied to this embodiment. 41 is the heat cooking device of the present invention. This heat cooking device 41 comprises a cooking device main body 2 and a remote control body 43 . In addition, in the present embodiment, the heat cooking device 41 is an induction heating cooker.

The cooking apparatus main body 2 has a short cylindrical upper shell 4 , a dish-shaped lower shell 5 , and a disk-shaped top plate 6 provided on the upper shell 4 . An induction heating coil 7 as a heat source and an LED array 8 as display means are housed below the top plate 6 . Light emitted from this LED array 8 is transmitted through the top plate 6 and is visually recognized. A pot compatible with an induction heating cooker (not shown) can be placed on the top plate 6 . Cutouts 9 and 10 are provided on the side surface of the upper shell 4 and the side surface of the lower shell 5, respectively. . A magnet plug of a power cord (not shown) is detachably connected to the power connection portion 11 . A main switch operation portion 12 and an output control switch operation portion 13 are provided on the side portion of the lower shell body 5 . Further, a plurality of (three in this embodiment) light receiving windows 15 of the infrared signal receiving section 14 are provided on the side portion of the lower shell body. These light receiving windows 15 appear in a side view. Further, these light receiving windows 15 are provided at equal angular intervals (120 degree intervals in this embodiment) around the vertical center line of the cooking apparatus main body 2 .

The remote control body 43 has an elongated rectangular parallelepiped shape as a whole. The remote control unit 43 includes an outer shell 44 , operating units 45 , 46 and 47 appearing on the upper surface of the outer shell 44 , and an infrared signal transmitter 48 . The operation part 45 is a main operation part for supplying/stopping current to the induction heating coil 7 . Further, the operation portions 46 and 47 are adjustment switches for adjusting the output of the induction heating coil 7 . The infrared signal transmitter 48 is provided at the tip of the outer shell 44 . An infrared LED (not shown) is provided inside the infrared signal transmission unit 48 .

An outline of the electric circuit of the cooking apparatus main body 2 will be described. In this electric circuit, as shown in FIG. 6, an AC power supply 20 is connected to a rectifier circuit 20A, and the induction heating coil 7 is connected between both electrodes of the rectifier circuit 20A via an induction heating drive circuit 21 as a heat source drive circuit. are connected structures. The induction heating coil 7 is driven and controlled by the induction heating drive circuit 21 . A power supply circuit 22 and a microcomputer 23 as control means are connected in parallel with the induction heating coil 7 . A series circuit of a switch SW1 and a diode D is provided between the power supply circuit 22 and the microcomputer 23. FIG. The switch SW1 is of a self-reset type, and is operated by pressing the main switch operating portion 12. As shown in FIG. A series circuit of the switch SW1 and the diode D is connected to the power supply input PW of the microcomputer 23 . Further, a line branched from between the switch SW1 and the diode D is connected to the input section X of the microcomputer 23. As shown in FIG. Furthermore, a series circuit of field effect transistors (hereinafter referred to as FETs) 24 and 25 as switching elements is connected in parallel with the series circuit of the switch SW1 and the diode D. The output A of the microcomputer 23 is connected through a capacitor C to an integration circuit 26 as a smoothing means, and the integration circuit 26 is connected to the gate of the FET 24 . On the other hand, the microcomputer 23 has its output B connected to the gate of the FET 25 . The microcomputer 23 is connected to the induction heating drive circuit 21 and configured to be able to control the induction heating drive circuit 21 . Further, infrared sensors 27 , 28 and 29 are connected to the microcomputer 23 . The infrared sensor 27 is arranged inside the light receiving window 15A, the infrared sensor 28 is arranged inside the light receiving window 15B, and the infrared sensor 29 is arranged inside the light receiving window 15C. Also, the microcomputer 23 is connected to a switch SW2. The switch SW2 is also of a self-reset type, and is operated by pressing the output adjustment switch operating portion 13. FIG. Furthermore, the LED array 8 is connected to the microcomputer 23 .

With such a circuit configuration, although a large amount of power is supplied from the AC power supply 20 to the induction heating coil 7, the switch SW1 can be a switch with a relatively small capacity. This is because the current flowing through the switch SW1 needs only to have a sufficient value to activate the microcomputer 23. FIG.

Next, the operation of this embodiment will be described. First, the user connects the magnet plug of the power cord (not shown) to the power supply connector 11 and connects the power plug to the AC power supply 20 . In this state, no current flows through the induction heating coil 7, and the microcomputer 23 does not start. When the main switch operating portion 12 is pressed, the switch SW1 is turned "on". Thus, when the switch SW1 is turned "on", power is supplied from the power supply circuit 22 to the power input part PW of the microcomputer 23 through the switch SW1 and the diode D, and the microcomputer 23 is activated. At the same time, the microcomputer 23 detects that the current flowing through the switch SW1 is supplied to the input section X. When the microcomputer 23 detects that the current is supplied to the input section X, the microcomputer 23 supplies an intermittent current from the output section A to the integration circuit 26 . Since the current supplied from the output portion A is an intermittent current, it passes through the capacitor C and is supplied to the integrating circuit 26. FIG. This intermittent current is smoothed by the integration circuit 26 to become a DC current, which is supplied to the gate of the FET 24 . At the same time, a DC current is supplied from the output B of the microcomputer 23 to the gate of the FET 25 . By supplying currents to the gates of the FETs 24 and 25 in this way, the FETs 24 and 25 are turned on at the same time, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 and the Power is supplied to the power input unit PW of the microcomputer 23 . Since the switch SW1 is a self-reset type switch as described above, it turns "OFF" when the user releases the main switch operation section 12. FIG. However, current continues to flow to the microcomputer 23 due to current flowing through the series circuit of the FETs 24 and 25 . By continuing to supply the current to the microcomputer 23, the currents continue to be supplied to the gates of the FETs 24 and 25, respectively. Therefore, the microcomputer 23 continues to operate. The current flowing through the series circuit of the FETs 24 and 25 is blocked by the diode D and therefore does not flow to the input X.

Thus, when the microcomputer 23 operates, the microcomputer 23 controls the induction heating drive circuit 21 , and the induction heating drive circuit 21 drives and controls the induction heating coil 7 . That is, an alternating current is supplied to the induction heating coil 7 by the induction heating drive circuit 21 . The set output of the induction heating coil 7 when the microcomputer 23 is activated may be the minimum value or the output value of the previous use. Each time the microcomputer 23 detects that the switch SW2 is turned on by pressing the output adjustment switch operating section 13, the microcomputer 23 controls the induction heating control circuit 21 to turn the induction heating coil 7 on. Control the output in multiple stages. Further, the microcomputer 23 controls the number of LEDs to be emitted in the LED array 8 each time the switch SW2 is turned on. At this time, the number of LEDs to emit light in the LED array 8 corresponds to the output of the induction heating coil 7 . Therefore, the current output of the induction heating coil 7 can be known from the number of LEDs in the LED array 8 emitting light. Light emitted from the LEDs of the LED array 8 passes through the top plate 6 and is visually recognized.

The control of the cooking apparatus main body 2 can also be performed by operating the remote control body 43 . (However, only the operation from activation of the microcomputer 23 to the start of heating is performed by the main switch 12 of the cooking apparatus main body 2.) It can be operated even when When the remote control unit 43 is placed on the dining table T and used, the operation units 45, 46, and 47 are set to face upward, and the infrared signal transmission unit 48 is directed toward the cooking apparatus main body 2. turn. By pressing the operating portion 45, the induction heating coil 7 is de-energized. Even if the operation part 45 is pressed again, the induction heating coil 7 is not energized. Further, by pressing the operation part 46, the output of the induction heating coil 7 is decreased stepwise, and by pressing the operation part 47, the output of the induction heating coil 7 is increased step by step. When using the remote control unit 43 by holding it, the user can easily operate the remote control unit 43 by pointing the infrared signal transmission unit 48 toward the cooking apparatus main body 2 and similarly operating the operation units 45 and 45. 46 and 47 should be operated.

A control signal generated by such an operation is transmitted as an infrared signal S from the infrared LED (not shown) of the infrared signal transmission unit 48 . That is, the infrared signal S is transmitted forward from the remote controller 43 .

On the other hand, the infrared sensors 27, 28, 29 of the cooking apparatus main body 2 have a relatively wide detection angle (specifically, approximately 140 degrees). Therefore, the infrared sensors 27 , 28 and 29 can receive the infrared signal S from all directions around the cooking apparatus main body 2 . For example, as shown in FIG. 13, the infrared signal S emitted from the infrared signal transmitting section 48 of the remote control unit 43 placed at the position P1 on the dining table T is received by the cooking apparatus main body 2. The infrared sensor 27 receives through the window 15A. On the other hand, the infrared signal S emitted from the infrared signal transmitting section 48 of the remote control 43 placed at the position P2 on the dining table T passes through the light receiving window 15C of the cooking apparatus main body 2 and passes through the infrared signal. External sensor 29 receives. At the same time, the infrared signal S emitted from the infrared signal transmitter 48 is received by the infrared sensor 28 through the light receiving window 15B of the cooking apparatus main body 2 . Thus, depending on the positional relationship between the cooking apparatus body 2 and the remote control body 43, the infrared signal S transmitted by the infrared LED is received by one infrared sensor or by two infrared sensors. will do. That is, by receiving the infrared signal S transmitted by the infrared LED by any of the infrared sensors 27 , 28 , 29 , the remote control 43 can control the cooking apparatus body 2 . Even if the infrared signal S is received by a plurality of the infrared sensors 27, 28, and 29, the received command signals are all the same, so there is no contradiction in the commands. It should be noted that FIG. 13 does not provide two remote control bodies 43 for one cooking apparatus main body 2 . The case where one remote control unit 43 is placed at position P1 on the dining table T and the case where it is placed at position P2 for one cooking apparatus main body 2 are shown in one drawing at the same time.

When the operation unit 45 of the remote control unit 43 is operated or the main switch operation unit 12 is pressed to turn on the switch SW1, the microcomputer 23 cuts off the energization of the induction heating coil 7. and then stop its own movement. When the induction heating coil 7 is deenergized by operating the remote controller 43, when the infrared sensors 27, 28 and 29 receive the infrared signal S of the stop command, the microcomputer 23 detects the induction heating. After the power supply to the induction heating coil 7 is stopped by the drive circuit 21, the current supply from the output portions A and B is stopped. On the other hand, when the induction heating coil 7 is deenergized by operating the main switch operation section 12, when it is detected that the current is supplied from the power supply circuit 22 to the input section X through the switch SW1, the micro The computer 23 stops the current supply from the output portions A and B after stopping the energization of the induction heating coil 7 by the induction heating drive circuit 21 . As a result, the current supply to the gates of the FETs 24 and 25 is cut off, so that both of these FETs 24 and 25 are turned off, and the power supply circuit 22 passes through the series circuit of the FETs 24 and 25 to the microcomputer 23 . is also cut off. This causes the microcomputer 23 to stop. Thus, when the microcomputer 23 stops, it becomes impossible to control the induction heating drive circuit 21 and supply current to the induction heating coil 7 . Therefore, it is possible to reduce the possibility that current is unintentionally supplied to the induction heating coil 7 due to malfunction of the microcomputer 23 when not in use. As a result, the safety of the heat cooking device 41 can be enhanced. When the microcomputer 23 determines that there is no operation for a predetermined time (for example, 30 minutes) during heating by the induction heating coil 7, the induction heating drive circuit 21 stops energizing the induction heating coil 7. After that, the current supply from the output sections A and B is stopped. This causes the microcomputer 23 to stop.

By connecting the FETs 24 and 25 in series, even if one of the FETs 24 or 25 fails in a short-circuit mode, by stopping the power supply to the gate of the other FET 25 or 24, the microcomputer 23 can be stopped. Therefore, the possibility that the microcomputer 23 cannot be stopped can be reduced. Further, if the microcomputer 23 fails, the intermittent current cannot be output from the output section A of the microcomputer 23 . If no current can be supplied from the output section A, no current is supplied to the gate of the FET 24 . Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Conversely, if the current supplied from the output section A becomes a DC current, this DC current cannot pass through the capacitor C, so that no current is supplied to the gate of the FET 24 as well. Therefore, the FET 24 remains "off" and the microcomputer 23 also stops when the switch SW1 is turned off. Therefore, it is possible to prevent current from being supplied to the induction heating coil 7 when the microcomputer 23 fails.

As described above, the present invention includes an induction heating coil 7 as a heat source, an induction heating drive circuit 21 as a heat source drive circuit for driving the induction heating coil 7, a power supply circuit 22, and the induction heating drive circuit 21. and a switch SW1, wherein the switch SW1 is arranged between the power supply circuit 22 and the microcomputer 23 so that the switch SW1 Since the microcomputer 23 does not operate unless the .

Further, according to the present invention, the switch SW1 is of a self-recovery type, and FETs 24 and 25 as switching elements are connected in parallel with the switch SW1. is supplied, the microcomputer 23 can stop the current supply to the FETs 24 and 25 and the power supply to the microcomputer 23 itself. That is, the microcomputer 23 can be stopped by the microcomputer 23 itself.

Further, according to the present invention, a series circuit is formed by a plurality of the FETs 24 and 25, and the series circuit is connected in parallel with the switch SW1. By turning off the FET 25 or 24, the microcomputer 23 can be reliably stopped.

Further, according to the present invention, a current is supplied to the gate of the FET 24 via a capacitor C for passing the intermittent current and an integration circuit 26 as smoothing means for smoothing the intermittent current. If the computer 23 breaks down and cannot output the intermittent current, the current cannot be supplied to the FET 24, so that the microcomputer 23 can be prevented from being started when the microcomputer 23 is broken. .

Next, a fourth embodiment of the invention will be described with reference to FIG. It should be noted that this embodiment differs from the other embodiments only in the electric circuit, and the structure is the same as that of the first embodiment. Therefore, only the electric circuit will be described, and the reference numerals of the first embodiment will be used for common parts. In addition, in the present embodiment, the heat cooking device 1 is an induction heating cooker.

As shown in FIG. 14, the electric circuit of this embodiment has an AC power supply 20 connected to a rectifier circuit 20A, and an induction heating drive circuit 21 as a heat source drive circuit between the electrodes of the rectifier circuit 20A. It is a structure in which a heating coil 7 is connected. The induction heating coil 7 is driven and controlled by the induction heating drive circuit 21 . A power supply circuit 22 and a microcomputer 23 as control means are connected in parallel with the induction heating coil 7 . A series circuit of a switch SW1 and a diode D is provided between the power supply circuit 22 and the microcomputer 23. FIG. The switch SW1 is of a self-reset type and is operated by pressing the main switch operating section 12. FIG. A series circuit of the switch SW1 and the diode D is connected to the power supply input PW of the microcomputer 23 . Further, a line branched from between the switch SW1 and the diode D is connected to the input section X of the microcomputer 23. As shown in FIG. Further, a field effect transistor (hereinafter referred to as FET) 51 as a switching element is connected in parallel with the series circuit of the switch SW1 and the diode D. The output B' of the microcomputer 23 is connected to the gate of the FET 51 . The microcomputer 23 is connected to the induction heating drive circuit 21 and configured to be able to control the induction heating drive circuit 21 . Further, infrared sensors 27 , 28 and 29 are connected to the microcomputer 23 . The infrared sensor 27 is arranged inside the light receiving window 15A, the infrared sensor 28 is arranged inside the light receiving window 15B, and the infrared sensor 29 is arranged inside the light receiving window 15C. Also, the microcomputer 23 is connected to a switch SW2. The switch SW2 is also of a self-reset type, and is operated by pressing the output adjustment switch operating section 13. FIG. Furthermore, an LED array 8 is connected to the microcomputer 23 .

With such a circuit configuration, although a large amount of power is supplied from the AC power source 20 to the induction heating coil 7, the switch SW1 can be a switch with a relatively small capacity. This is because the current flowing through the switch SW1 needs only to have a sufficient value to activate the microcomputer 23. FIG.

Next, the operation of this embodiment will be described. First, the user connects the magnet plug of the power cord (not shown) to the power supply connector 11 and connects the power plug to the AC power supply 20 . In this state, no current flows through the induction heating coil 7, and the microcomputer 23 does not start. When the main switch operating portion 12 is pressed, the switch SW1 is turned "on". Thus, when the switch SW1 is turned "on", power is supplied from the power supply circuit 22 to the power input part PW of the microcomputer 23 through the switch SW1 and the diode D, and the microcomputer 23 is activated. At the same time, the microcomputer 23 detects that the current flowing through the switch SW1 is supplied to the input section X. When the microcomputer 23 detects that a current is supplied to the input section X, it supplies a DC current to the gate of the FET 51 from the output section B'. By supplying a current to the gate of the FET 51 in this manner, the FET 51 is turned on, and a current is supplied from the power supply circuit 22 to the power input part PW of the microcomputer 23 via the FET 51. be. Since the switch SW1 is a self-reset type switch as described above, it turns "OFF" when the user releases the main switch operation section 12. FIG. However, the flow of current through the FET 51 continues to supply the microcomputer 23 with current. As the current continues to be supplied to the microcomputer 23 , the current continues to be supplied to the gate of the FET 51 . Therefore, the microcomputer 23 continues to operate. It should be noted that the current flowing through the FET 51 is blocked by the diode D and therefore does not flow to the input X.

Thus, when the microcomputer 23 operates, the microcomputer 23 controls the induction heating drive circuit 21 , and the induction heating drive circuit 21 drives and controls the induction heating coil 7 . That is, an alternating current is supplied to the induction heating coil 7 by the induction heating drive circuit 21 . The set output of the induction heating coil 7 when the microcomputer 23 is activated may be the minimum value or the output value of the previous use. Each time the microcomputer 23 detects that the switch SW2 is turned on by pressing the output adjustment switch operating section 13, the microcomputer 23 controls the induction heating control circuit 21 to turn the induction heating coil 7 on. Control the output in multiple stages. Further, the microcomputer 23 controls the number of LEDs to be emitted in the LED array 8 each time the switch SW2 is turned on. At this time, the number of LEDs to emit light in the LED array 8 corresponds to the output of the induction heating coil 7 . Therefore, the current output of the induction heating coil 7 can be known from the number of LEDs in the LED array 8 emitting light. Light emitted from the LEDs of the LED array 8 passes through the top plate 6 and is visually recognized.

Note that the control of the cooking apparatus body 2 can also be performed by operating the remote control body 3 . (However, only the operation from activation of the microcomputer 23 to the start of heating is performed by the main switch 12 of the cooking apparatus main body 2.) The remote control unit 3 is operated while placed on the dining table T. . That is, when the remote control unit 3 is placed on the dining table T and the operation part 17 is pushed downward, the current to the induction heating coil 7 is cut off. Even if the operating portion 17 is pushed downward again, the energization of the induction heating coil 7 is not resumed. When the operating portion 17 is rotated clockwise, the output of the induction heating coil 7 increases, and when the operating portion 17 is rotated counterclockwise, the output of the induction heating coil 7 decreases.

A control signal by such an operation is transmitted as an infrared signal S from three infrared LEDs (not shown) of the infrared signal transmission unit 18 and emitted from the emission windows 19 , 19 , 19 . That is, the infrared signal S is transmitted from the remote controller 3 in three directions. In addition, the infrared LED has a relatively wide irradiation angle (specifically, about 120 degrees). Therefore, the infrared signal S is transmitted over a wide range around the remote control 3 .

On the other hand, the infrared sensors 27, 28, 29 of the cooking apparatus main body 2 also have a relatively wide detection angle (specifically, approximately 140 degrees). Therefore, the infrared sensors 27 , 28 and 29 can receive the infrared signal S from all directions around the cooking apparatus main body 2 . By receiving the infrared signal S transmitted by any of the infrared LEDs by any of the infrared sensors 27, 28, and 29, the remote controller 3 can control the cooking apparatus main body 2. becomes. Since the infrared signals S transmitted in three directions from the remote controller 3 are all the same command signal, even if they are received by a plurality of the infrared sensors 27, 28 and 29, there will be no contradiction in command.

With the remote control unit 3 placed on the dining table T, when the operation unit 17 is pushed downward or the main switch operation unit 12 is pushed to turn on the switch SW1, the microcomputer 23 is turned on. cuts off the energization of the induction heating coil 7 and then stops its own operation. When the induction heating coil 7 is de-energized by operating the remote controller 3, when the infrared sensors 27, 28 and 29 receive the infrared signal S of the stop instruction, the microcomputer 23 detects the induction heating coil 7. After the power supply to the induction heating coil 7 is stopped by the drive circuit 21, the current supply from the output section B' is stopped. On the other hand, when the induction heating coil 7 is deenergized by operating the main switch operation section 12, when it is detected that the current is supplied from the power supply circuit 22 to the input section X through the switch SW1, the micro After the induction heating drive circuit 21 stops the energization of the induction heating coil 7, the computer 23 stops the current supply from the output section B'. As a result, the current supply to the gate of the FET 51 is cut off, so that the FET 51 is turned off, and the power supplied from the power supply circuit 22 to the power input section PW of the microcomputer 23 via the FET 51 is also cut off. be done. This causes the microcomputer 23 to stop. Thus, when the microcomputer 23 stops, it becomes impossible to control the induction heating drive circuit 21 and supply current to the induction heating coil 7 . Therefore, it is possible to reduce the possibility that current is unintentionally supplied to the induction heating coil 7 due to malfunction of the microcomputer 23 when not in use. Thereby, the safety of the heat cooking device 1 can be enhanced. When the microcomputer 23 determines that there is no operation for a predetermined time (for example, 30 minutes) during heating by the induction heating coil 7, the induction heating drive circuit 21 stops energizing the induction heating coil 7. After that, the current supply from the output section B' is stopped. This causes the microcomputer 23 to stop.

In the case of this embodiment, the safety is inferior to that of the electric circuits of the above-described embodiments, but if the reliability of the microcomputer 23 and the FET 51 is sufficiently high, it can be constructed at a low cost.

As described above, the present invention includes an induction heating coil 7 as a heat source, an induction heating drive circuit 21 as a heat source drive circuit for driving the induction heating coil 7, a power supply circuit 22, and the induction heating drive circuit 21. and a switch SW1, wherein the switch SW1 is arranged between the power supply circuit 22 and the microcomputer 23 so that the switch SW1 Since the microcomputer 23 does not operate unless the .

Further, according to the present invention, the switch SW1 is of a self-recovery type, an FET 51 as a switching element is connected in parallel with the switch SW1, and a current is supplied to the gate of the FET 51 while the microcomputer 23 is operating. With this configuration, the microcomputer 23 can stop the current supply to the FET 51 and stop the power supply to the microcomputer 23 itself. That is, the microcomputer 23 can be stopped by the microcomputer 23 itself.

It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the invention. For example, in each of the above embodiments, a field effect transistor (FET) is used as a switching element, but a transistor may be used. Moreover, although two FETs are connected in series in the first to third embodiments, three or more FETs may be connected in series. In addition, in the fourth embodiment, the direct current is supplied to the gate of the FET, but the current obtained by smoothing the intermittent current through a capacitor and a smoothing circuit may be supplied to the gate of the FET. Furthermore, in each of the above embodiments, the heating cooking apparatus is an induction heating cooker using an induction heating coil as a heating source, but an electric pot, hot plate, or deep fat fryer using a heater as a heating source. good.

1, 31, 41 Cooking device 7 Induction heating coil (heating source)
20 AC power supply
20A rectifier circuit
21 induction heating drive circuit (heat source drive circuit)
22 power supply circuit 23 microcomputer (control means)
24, 25, 51 Field effect transistor (switching element )
2 6 integration circuit (smoothing means)
C capacitor
D diode
PW Power supply input
SW1 switch
X input section

Claims (3)

a rectifying circuit connected to an AC power supply; a heating source connected between the electrodes of the rectifying circuit via a heating source driving circuit; the heating source driving circuit driving the heating source; A power supply circuit provided , a control means provided in parallel with the heating source for controlling the heating source driving circuit, a series circuit of a self-recovery switch and a diode, and a switching element provided in parallel with the series circuit. and a line branched from between the switch and the diode and connected to the input part of the control means , wherein the series circuit of the switch and the diode and the switching element are connected to the power supply circuit A cooking apparatus, characterized in that it is disposed between a control means and a power supply input section, and is constructed such that a current is supplied from the control means to the switching element during operation of the control means . 2. The cooking apparatus according to claim 1 , wherein a series circuit is formed by a plurality of said switching elements, and said series circuit is connected in parallel with said switch. 2. The cooking device according to claim 1 , wherein current is supplied to said switching element via a capacitor for passing intermittent current and smoothing means for smoothing said intermittent current.

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