JP4940836B2 - Induction heating rice cooker - Google Patents

Description

  The present invention relates to an induction heating rice cooker having a voice notification function.

2. Description of the Related Art Conventionally, there are cookers equipped with voice notification that reduce power consumption and prevent speaker noise by supplying power to a voice output unit including a voice synthesizer only for a specific period (for example, patents). Reference 1).
JP 59-4828

  However, when trying to realize an induction heating rice cooker with the above-described conventional configuration, when a high-frequency current flows through the heating coil, a high-frequency magnetic field from the heating coil propagates to the winding of the speaker. When an induced electromotive voltage is generated and the power of the audio signal output means is off, the induced electromotive voltage exceeds the maximum voltage rating of the audio signal output means, and the audio signal output means is destroyed. When the power of the audio signal output means is on, the output terminal of the audio signal output means is fixed to the intermediate potential of the power supply, or high or low, so that an induced electromotive voltage is generated in the speaker winding. Even if it occurs, the maximum voltage rating of the audio signal output means will not be exceeded. Therefore, in order to prevent the audio signal output means from being broken by the induced electromotive voltage of the speaker, the power supply of the audio signal output means is kept on. There was a need. In this case, power is consumed even when no sound is output, and power cannot be saved, and noise noise is generated from the speaker due to a high-frequency magnetic field generated when a high-frequency current flows through the heating coil. Ended up having.

  Further, in order to turn off the power of the audio signal output means and prevent the audio signal output means from being destroyed, it is necessary to reduce the induced electromotive voltage generated in the winding of the speaker. In order to reduce the induced electromotive voltage, it is necessary to sufficiently separate the speaker from the heating coil. Therefore, the speaker cannot be disposed in the vicinity of the heating coil, the effective space cannot be used, and it is difficult to reduce the size of the device. There was a problem.

  The present invention solves the above-described conventional problems, and provides an induction heating rice cooker that can realize a safe, compact, and power-saving manner in which an audio signal output means is not broken even if a speaker is disposed in the vicinity of a heating coil. It is aimed.

  In order to achieve the above object, the present invention supplies high-frequency power to a heating coil for induction heating of a pan by an inverter circuit, and controls the inverter circuit by a control means. The audio signal is output to the speaker, the signal of the control means is received, the power path to the audio signal output means is cut off or conducted by the switch circuit, and the speaker input terminal is connected to the ground potential by the speaker short-circuit means, When the control means does not output sound, the switch circuit cuts off the power supply path of the sound signal output means, and the speaker short-circuit means connects the speaker input terminal to the ground potential and outputs the sound. To conduct the power supply path of the audio signal output means, and the speaker short-circuit means to connect the speaker input terminal to the ground voltage. Those configured to cut off the connection.

Thus, when the power of the audio signal output means is turned off, the speaker short-circuit means connects the speaker input terminal to the ground potential even if an induced electromotive voltage is generated in the winding of the speaker by the high-frequency magnetic field of the heating coil. Therefore, the input terminal of the speaker is almost the same as the ground potential, the maximum rated voltage of the audio signal output means is not exceeded, and the audio signal output means is not broken even if the speaker is arranged in the vicinity of the heating coil. Thus, an induction heating rice cooker that is compact and can realize power saving can be provided.

  The induction heating type rice cooker of the present invention prevents the destruction of the audio signal output means even if an induction electromotive voltage is generated in the speaker by the high frequency magnetic field of the heating coil when the power supply of the audio signal output means is stopped. It is possible to provide an induction heating rice cooker that is safe, compact, and can realize power saving.

According to a first aspect of the present invention, there is provided a heating coil for induction heating a pan, an inverter circuit for supplying high-frequency power to the heating coil, a control means for controlling the inverter circuit, a speaker, and an audio signal received from the control means. Audio signal output means for outputting a signal to a speaker, a switch circuit for receiving or receiving a signal from the control means and blocking or conducting a power path to the audio signal output means, and a speaker for connecting the input terminal of the speaker to a ground potential Short circuit means, and when the control means does not output sound, the switch circuit cuts off the power supply path of the sound signal output means, and the speaker short circuit means connects the input terminal of the speaker to the ground potential. When outputting audio, the switch circuit conducts the power supply path of the audio signal output means, and Configured to cut off the connection between the input terminal and the ground potential of the loudspeaker in a short circuit means, the audio signal output means, a sound signal storage circuit for outputting audio data stored in advance as a signal, the signal of the audio signal storage circuit A filter circuit for attenuating a predetermined high frequency component and a predetermined low frequency component; and an audio signal amplifying circuit for amplifying the output signal of the filter circuit, wherein the switch circuit has at least a power supply path for the audio signal amplifying circuit. The audio signal amplifying circuit is provided with a first amplifying circuit that inverts and amplifies the output signal of the filter circuit, and a second amplifying circuit that inverts and amplifies the output signal of the first amplifying circuit so as to be cut off or conducted. Has one input terminal connected to the output of the first amplifier circuit, the other input terminal connected to the second amplifier circuit, and the first amplifier circuit and Serial power supply voltage of the second amplifying circuit and the audio signal storage circuit is obtained by the common, even induced electromotive force is generated in the windings of the speaker, it will be fixed to almost the ground potential, the audio signal output means When the power supply voltage is turned off, the maximum rating of the output terminal of the audio signal output means is not exceeded, the destruction of the audio signal output means can be prevented, and power saving can be realized. Moreover, since it can prevent that an induced electromotive voltage destroys an audio | voice signal output means, it becomes possible to arrange | position a speaker to the vicinity of a heating coil, and can provide the induction heating type rice cooker provided with the compact audio | voice function. Further, since the speaker short-circuiting means disconnects the connection between the input terminal of the speaker and the ground potential during the sound output, the signal of the sound signal output means can be input to the speaker and the sound can be output reliably. In addition, the power supply voltage of the audio signal amplifier circuit can be set regardless of the power supply voltage of the control means or the audio signal storage circuit, so that the power input to the speaker can be increased and the volume can be increased so that the user with poor hearing In addition, the voice can be heard even in the noise during cooking. In addition, when no sound is output, the power supply to the sound signal amplifier circuit is stopped. Therefore, even if the high frequency magnetic field of the heating coil is superimposed on the input part of the sound signal amplifier circuit, noise is generated from the speaker. Will not be output. Further, since the power supply paths of the first amplifier circuit, the second amplifier circuit, and the audio signal storage circuit can be cut off at a time, power saving can be realized. Further, since the output of the first amplifier circuit and the output of the second amplifier circuit are inverted, the voltage input to the speaker is almost the same as the power supply voltage supplied to the first amplifier circuit and the second amplifier circuit. Thus, sufficient power can be supplied to the speaker even with a low power supply voltage. Therefore, it is possible to use a single power source for the control means, the audio signal storage circuit, and the audio signal amplifier circuit, so that circuit components can be reduced and the mounting area can be reduced .

According to a second invention, in the first invention, after the speaker short-circuit means cuts off the connection between the input terminal of the speaker and the ground potential, the control means makes the switch circuit conductive and communicates with the audio signal output means. The output of the audio signal amplifier circuit is short-circuited by turning on the speaker short-circuit means when the power supply voltage of the audio signal amplifier circuit rises, and the short-circuit current flows through the audio signal amplifier circuit and is destroyed. It can be surely prevented.

According to a third aspect of the present invention, in the second aspect of the present invention, the speaker short-circuit means connects the input terminal of the speaker and the ground potential after the control means turns off the switch circuit, and the audio signal output means When the voltage is output from the speaker, the speaker short-circuit means is connected to the ground potential, and an excessive current flows through the audio signal output means and the speaker short-circuit means, thereby preventing the audio signal output means or the speaker short-circuit means from being destroyed. Can do. Further, when the speaker short-circuit means is turned on, a voltage fluctuation occurs at the speaker input terminal, and this voltage fluctuation can be prevented from being heard by the user as a noise sound.

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

(Embodiment 1)
FIG. 1 shows a partially blocked circuit diagram of the main part of the induction heating rice cooker in Embodiment 1 of the present invention, and FIG. 2 shows a cross-sectional view of the induction heating rice cooker. In order to simplify the drawing, lead wires for electrical connection and screws for fixing components are omitted.

  As shown in FIG. 1, the heating coil 1 induction-heats the pan 35 (refer FIG. 2), and is comprised with the litz wire which bundled the copper wire with a small wire diameter. The inverter circuit 2 includes a semiconductor switching element made of IGBT, a diode reversely connected to the semiconductor switching element, a heating coil 1 and a resonance capacitor that forms a resonance circuit, and the semiconductor switching element is switched at a high frequency. By doing so, a high frequency current is supplied to the heating coil 1. The diode bridge 3, the choke coil 4, and the capacitor 5 rectify the commercial power supply 6 and supply power to the inverter circuit 2.

  The input means 7 is comprised with the several momentary switch, and the user can select the rice cooking method, the start or stop of rice cooking, etc. The display means 8 is comprised with the liquid crystal display and LED, and displays the content which the user set, the state of the rice cooker during rice cooking, during reservation, and the elapsed time of rice cooking.

  The control means 9 is composed of a microcomputer, a thermistor for measuring the temperature of the pan, a current transformer for detecting the value of the current supplied from the commercial power source 6, and the like, and an input signal of a switch constituting the input means 7 In response, the set content is displayed on the LCD, or the inverter circuit 2 is controlled to be turned on / off, and the rice cooking sequence and the heat retention sequence set by the input means 7 are operated.

  Here, the speaker 10 uses a type in which a coil and a magnet are used, and the coil is vibrated by a current flowing in the winding and a magnetic field of the magnet. In the present embodiment, the impedance of the speaker 10 is made larger than 8Ω in order to reduce the current flowing through the speaker 10. One input terminal of the speaker 10 is connected to the ground potential.

The audio signal output means 11 receives the output of the control means 9 and outputs the audio signal to the speaker 10. The audio signal output means 11 converts the digital signal output from the memory into an analog signal and stores the audio data as 4-bit data. And a DA converter. In this embodiment, the memory and the DA converter are configured separately, but may be configured by a speech synthesis IC in which the two are combined into one IC. The capacitor 12 is used for cutting a DC component, so that a DC voltage is not applied to the speaker 10.

  The speaker short-circuit means 13 is composed of an NPN transistor having a built-in resistor and a resistor connected in series to the collector terminal of the NPN transistor. When the control unit 9 outputs a high or low signal, the NPN transistor is turned on / off, and the input terminal of the speaker 10 is connected to the ground potential via a resistor or is cut off from the ground potential. In this embodiment, the resistors are connected in series so that the current flowing through the NPN transistor does not exceed the maximum rating. However, if the maximum current rating of the NPN transistor is sufficient, it is particularly necessary to connect the resistor. There is no. Moreover, although the NPN transistor is used for the speaker short-circuit means 13, this is an example and is not limited.

  The driving means 14 is composed of a push-pull circuit composed of a PNP transistor and an NPN transistor, and turns on / off the IGBT constituting the inverter circuit 2 in response to an on / off signal from the control means 9.

  The first DC power supply 15 is constituted by a switching power supply, rectifies the commercial power supply 6, and converts the rectified DC power supply of about 141V into a DC power supply of about 20V. The output voltage 20V of the first DC power supply 15 is a voltage necessary for turning on the IGBT, and is supplied to the IGBT via the driving means 14, and the IGBT is turned on. The second DC power supply 16 has a configuration of an emitter follower circuit including an NPN transistor and a Zener diode. The voltage of the second DC power supply 16 is about 5V, which serves as a power source for the microcomputer constituting the control means 9 and the audio signal output means 11.

  The switch circuit 17 is composed of a PNP transistor and an NPN transistor. The switch circuit 17 is turned on / off in response to a signal from the control means 9, and cuts off or conducts the current path from the first DC power supply 15 to the audio signal output means 11. The audio signal output means 11 is turned on or off.

  When the control means 9 does not output sound, the switch circuit 17 cuts off the power supply path of the sound signal output means 11, and the speaker short-circuit means 13 connects the input terminal of the speaker 10 to the ground potential. Is outputted, the switch circuit 17 conducts the power supply path of the audio signal output means 11, and the speaker short-circuit means 13 cuts off the connection between the input terminal of the speaker 10 and the ground potential.

  Next, as shown in FIG. 2, the rice cooker main body 31 is provided with a lid 32 that covers its upper surface so as to be freely opened and closed. The storage unit 33 of the rice cooker body 31 has the heating coil 1 configured in a spiral shape at the bottom, and the ferrite core 34 is arranged on the outer peripheral side of the heating coil 1. The heating coil 1 is a winding having a center at substantially the center of the bottom of the pan 35.

  The pan 35 is made of a clad steel plate made of a magnetic material such as stainless steel, iron, or copper. The pan 35 has a flange protruding outward at the upper end opening, and is detachably stored in the storage unit 33 by placing the flange in a state of being lifted from the upper end of the storage unit 33. Therefore, the pan 35 has a gap between it and the storage portion 33 when stored.

  A detachable lid heating plate 36 is set on the lid 32. The lid heating plate 36 is made of a metal such as stainless steel. Although the lid heating coil 37 is not illustrated in FIG. 1, the lid heating coil 37 is built in the lid 32, and in the present embodiment, the lid heating plate 36 is induction-heated. However, this is only an example, and the lid heating coil 37 may be a heater.

  The first circuit board 38 includes a switch constituting the input means 7, an LCD constituting the display means 8, an LED, a microcomputer constituting the control means 9, a voice synthesis IC constituting the voice signal output means 11, and a capacitor 12. Etc. are implemented. On the second circuit board 39, components constituting the inverter circuit 2, the diode bridge 3, the choke coil 4, the capacitor 5, and the like are mounted. The wind-up type power cord storage unit 40 is electrically connected to the second circuit board 39 via a lead wire. The power cord storage unit 40 can wind up the power cord using a stopper and a spring.

  Although not shown in FIG. 1, the temperature detection means 41 is composed of a thermistor and is arranged at the approximate center of the bottom of the pan 35. Since the resistance value of the thermistor changes with temperature, a voltage dividing circuit is configured with this thermistor and a resistor having a predetermined resistance value, and the resistance value of the thermistor is analogized by supplying a predetermined voltage to both ends of the voltage dividing circuit. Can be converted to voltage. The microcomputer constituting the control means 9 shown in FIG. 1 estimates the temperature from this analog voltage using a built-in AD converter.

  The first circuit board 38 and the second circuit board 39 are electrically connected by lead wires to realize the circuit configuration shown in FIG. In addition, as shown in FIG. 2, the speaker 10 is disposed using a gap formed between the rice cooker body 31 and the heating coil 1, and the output surface of the speaker 10 is disposed below the heating coil 1. . Note that the direction and location of the speaker 10 are not particularly limited, and the output surface of the speaker 10 may be upward, or may be placed on the lid 32 if there is a space.

  The operation of the above configuration will be described with reference to FIGS. FIG. 3 shows a timing chart of the main part at the time of voice output in the induction heating rice cooker of the present embodiment. (1) is a voltage waveform of the commercial power source 6, and (2) is synchronized with 0 V of the commercial power source 6. (3) is an on (conducting) and off (cutting) state of the switch circuit 17, and (4) is a power supply voltage of the audio signal output means 11. Waveform, (5) is a transmission signal waveform from the control means 9 to the audio signal output means 11, (6) is an on (conduction) and off (cutoff) state of the speaker short-circuit means 13, and (7) is an input voltage of the speaker 10. , (8) respectively show the on / off state of the IGBT constituting the inverter circuit 2 (on / off state of the driving means 14). Moreover, FIG. 4 shows the operation waveform of each part when the high frequency current is flowing through the heating coil 1 in the induction heating rice cooker of the present embodiment, and (1) is the envelope of the high frequency current flowing through the heating coil 1. (2) is an induced electromotive voltage waveform generated in the speaker 10 when a high-frequency current flows through the heating coil 1 (when the speaker short-circuit means 13 is turned on), and (3) is a case where a high-frequency current flows through the heating coil 1. An induced electromotive voltage waveform generated when the speaker 10 is generated (when the speaker short-circuit means 13 is turned off) is shown.

  First, when the user operates a switch (input means 7) provided in the first circuit board 39 of FIG. 2, the control means 9 detects a signal from the input means 7. Then, at time T0 in FIG. 3, the control means 9 turns on the switch circuit 17 in synchronization with the zero voltage of the commercial power supply 6 and supplies a DC voltage to the audio signal output means 11. At the same time, the control means 9 outputs an off signal to the speaker short-circuit means 13 in synchronism with the zero voltage of the commercial power supply 6, and the speaker short-circuit means 13 is turned off so that a signal can be inputted to the speaker 10. . Note that the amount of change at the time of rising of the DC voltage to the audio signal output means 11 may be applied to the speaker 10 via the capacitor 12 and output as noise noise.

Thereafter, at time T2 in FIG. 3, the control unit 9 transmits the volume setting data to the audio signal output unit 11 in synchronization with the zero voltage of the commercial power source 6. After that, at time T3 in FIG. 3, the control unit 9 transmits address data indicating predetermined audio data to the audio signal output unit 11 in synchronization with the zero voltage of the commercial power supply 6. Then, at time T4 in FIG. 3, the memory constituting the audio signal output unit 11 outputs predetermined audio digital data to the DA converter based on the transmission data from the control unit 9, and the DA converter An audio signal converted into a voltage is output, and the audio signal is input to the speaker 10 via the capacitor 12. When an audio signal is input, the speaker 10 vibrates, and this vibration becomes sound and notifies the user of the sound. At this time, the DC component of the audio signal output from the DA converter is removed by the capacitor 12.

  At time T5 in FIG. 3, according to the menu set by the input means 7, the control means 9 starts on / off control of the IGBT constituting the inverter circuit 2 via the drive means 14, and supplies high frequency power to the heating coil 1. The pan 35 is heated.

  At time T6 in FIG. 3, the audio output ends, and the output voltage of the second DC power supply 16 returns to the original value. Thereafter, at time T8 in FIG. 3, the control means 9 shuts off the switch circuit 17, stops the power supply to the audio signal output means 11, turns on the speaker short-circuit means 13, turns on the input terminal of the speaker 10 and the ground potential. Connect. At this time, since the power supply voltage of the audio signal output means 11 fluctuates, this voltage fluctuation may be applied to the speaker 10 via the capacitor 12 and a slight noise may be output.

  Thereafter, the heating coil 1 continues to operate according to a rice cooking sequence determined to heat the pan 35 and cook rice. In the absence of the speaker short-circuit means 13, when the power supply to the audio signal output means 11 becomes 0V, the induced electromotive voltage generated in the speaker 10 when the high-frequency current flows through the heating coil 1 exceeds the power supply voltage of the audio signal output means 11. Then, a current flows through the protection diode of the DA converter constituting the audio signal output means 11, and a voltage waveform in which the induced electromotive voltage of the speaker 10 is clamped is output to the speaker 10 terminal as shown in FIG. However, if the input terminal of the speaker 10 is connected to the ground potential by using the speaker short-circuit means 13, the induced electromotive voltage is short-circuited, so that it is possible to prevent the induced electromotive voltage from being applied to the audio signal output means 11. Further, since the power supply to the audio signal output means 11 is also stopped, the power consumption is reduced, and the heat generation of the first DC power supply 15 and the second DC power supply 16 can be suppressed.

  In this embodiment, since the control means 9 stores the time of the audio data in advance, the switch circuit 17 is shut off when a predetermined time has elapsed from that time. The reason why the interruption timing of the switch circuit 17 is made sufficiently later than the time of the sound data is that the speed of the sound signal output from the sound signal output means 11 varies.

  As described above, in this embodiment, when sound is not output, the speaker short-circuit means 13 that connects the input terminal of the speaker 10 to the ground potential is provided, so that when the high-frequency current flows through the heating coil 1, the speaker 10 can be prevented from being applied to the audio signal output means 11. Therefore, even if the power supply voltage of the audio signal output means 11 is turned off, the induced electromotive voltage of the speaker 10 becomes the audio signal output means. Therefore, the rice cooker can be provided which does not exceed the maximum rating of 11 and has no failure, and which saves power. Moreover, since the induced electromotive voltage generated in the speaker 10 can be prevented, the speaker 10 can be disposed in the vicinity of the heating coil 1, and a compact rice cooker can be realized.

(Embodiment 2)
FIG. 5 shows a partially blocked circuit diagram of the main part of the induction heating rice cooker in Embodiment 2 of the present invention.

As shown in FIG. 5, the audio signal output means 51 includes a memory (audio signal storage circuit) 52 that stores audio data as 4-bit data, and a DA converter 53 that converts a digital signal output from the memory 52 into an analog signal. A filter circuit 56 composed of a high-pass filter 54 for attenuating the low-frequency component of the output signal of the DA converter 53 and a low-pass filter 55 for attenuating the high-frequency component, and a sound for amplifying the output voltage of the filter circuit 56 at a predetermined magnification. The signal amplifying circuit 57 is used. In this embodiment, the high-pass filter 54 is configured by a series circuit of a resistor and a capacitor, and the low-pass filter 55 is configured by a parallel circuit of a resistor and a capacitor. However, this is an example. It may be used to form a digital filter. Further, in the present embodiment, the memory 52 and the DA converter 53 are configured separately, but may be configured by a speech synthesis IC in which the two are combined into one IC. The audio signal amplifying circuit 57 includes an operational amplifier IC integrated into a circuit and a plurality of resistors.

  The second DC power supply 58 is configured by an emitter follower circuit using an NPN transistor, and supplies approximately 5 V DC power to the memory 52 and the DA converter 53. The third DC power source 59 has the same emitter follower circuit configuration as the second DC power source 58, and the output voltage is about 10V. When the switch circuit 60 becomes conductive, the third DC power supply 59 is supplied with power from the first DC power supply 15 and outputs a DC voltage of about 10V. In the present embodiment, the third DC power supply 59 supplies a DC voltage to the operational amplifier constituting the audio signal amplifier circuit 57.

  The switch circuit 60 receives a signal from the control means 9 and conducts or cuts off the current path from the first DC power supply 15 to the third DC power supply 59. Since the circuit configuration of the switch circuit 60 is the same as that of the switch circuit 17 of FIG. 1, the description thereof is omitted here. Other configurations are the same as those of the first embodiment, and the same reference numerals are given and description thereof is omitted.

  As described above, in the present embodiment, the audio signal output means 51 includes the memory 52, the DA converter 53, the filter circuit 56, and the audio signal amplifier circuit 57, thereby increasing the power supply voltage of the audio signal amplifier circuit 57. In addition, the voltage input to the speaker 10 can be increased. Further, by providing the filter circuit 56, noise noise at the time of DA conversion and noise noise included in the audio data are reduced, so that it is possible to output a voice that is easy to hear. Further, when no sound is output, the switch circuit 60 turns off the current path from the first DC power supply 15 to the third DC power supply 59, so that a current flows through the third DC power supply 59 and the audio signal amplifier circuit 57. Power consumption can be saved. In addition, since no power is supplied to the speaker 10, noise noise can be prevented.

  As in the first embodiment of the present invention, since the speaker short-circuit means 13 connects the input terminal of the speaker 10 to the ground potential, even if a high-frequency current flows through the heating coil 1 and a high-frequency magnetic field is generated, the speaker The induced electromotive voltage generated in the 10 windings does not exceed the maximum rating of the audio signal amplification circuit 57. Therefore, it is possible to provide a highly reliable rice cooker that can output an easy-to-listen sound with less noise sound at a large volume and can save power.

(Embodiment 3)
The speaker short-circuit means 13 shown in FIG. 5 is configured to cut off the connection between the input terminal of the speaker 10 and the ground potential after the control means 9 makes the switch circuit 60 conductive. Other configurations are the same as those of the second embodiment.

The operation and action of the above configuration will be described with reference to FIG. FIG. 6 shows a timing chart of the main part at the time of voice output in the induction heating rice cooker of the present embodiment. (1) is a voltage waveform of the commercial power source 6, and (2) is synchronized with 0 V of the commercial power source 6. Waveform (not shown in FIG. 1), (3) is the on (conducting) and off (cutting) state of the switch circuit 60, and (4) is the output of the third DC power supply 59. Voltage waveform, (5) is a transmission signal waveform from the control means 9 to the audio signal output means 51, (6) is an on (conduction) and off (cutoff) state of the speaker short-circuit means 13, and (7) is an input of the speaker 10. Voltage, (8) is I constituting the inverter circuit 2
The on / off state of the GBT (the on / off state of the driving means 14) is shown.

  First, when the user operates a switch (input means 7) provided on the first circuit board 39, the control means 9 detects a signal from the input means 7. Then, at time T0 in FIG. 6, the control means 9 turns on the switch circuit 60 in synchronization with the zero voltage of the commercial power supply 6, activates the third DC power supply 59, and supplies the DC voltage to the audio signal amplifier circuit 57. Supply. The fluctuation at the rising of the DC voltage is applied to the speaker 10 via the capacitor 18 and may be output as a noise sound. However, in the present embodiment, when the speaker short-circuit means 13 is turned on, signal input to the speaker 10 is prevented, and noise noise is reduced.

  Thereafter, at time T1 in FIG. 6, the control means 9 outputs an off signal to the speaker short-circuit means 13 in synchronization with the zero voltage of the commercial power supply 6, and the speaker short-circuit means 13 is turned off and inputs a signal to the speaker 10. Will be able to. Thereafter, at time T2 in FIG. 6, the control unit 9 transmits the volume setting data to the audio signal output unit 51 in synchronization with the zero voltage of the commercial power source 6. Thereafter, at time T3 in FIG. 6, the control unit 9 transmits address data indicating predetermined audio data to the audio signal output unit 51 in synchronization with the zero voltage of the commercial power supply 6.

  Then, at time T4 in FIG. 6, the memory 52 outputs digital data of a predetermined sound to the DA converter 53 based on the transmission data from the control means 9, and the DA converter 53 converts the sound into an analog voltage. The signal is output, and the audio signal is input to the speaker 10 via the filter circuit 56, the audio signal amplifier circuit 57, and the capacitor 12. When an audio signal is input, the speaker 10 vibrates, and this vibration becomes sound and notifies the user of the sound. At this time, the low frequency component of the audio signal is attenuated by the high pass filter 54, and the high frequency component is attenuated by the low pass filter 55. The attenuated audio signal is amplified by the audio signal amplification circuit 57, and the DC component of the amplified audio signal is removed by the capacitor 12.

  When the audio signal is output, the voltage of the third DC power supply 59 drops by about 0.2V, but the voltage of the second DC power supply 58 does not change, so that the reference voltage of the AD converter constituting the control means 9 Does not fluctuate. Therefore, it is possible to prevent the detection means using the AD converter, such as temperature detection of the pot 35, detection of the input current, voltage detection of the commercial power source 6, and the like.

  At time T <b> 5 in FIG. 6, according to the menu set by the input unit 7, the control unit 9 starts on / off control of the IGBT configuring the inverter circuit 2 via the driving unit 14 and supplies high-frequency power to the heating coil 1. The pan 35 is heated.

  At time T6 in FIG. 6, the audio output ends, and the output voltage of the third DC power supply 59 returns to the original value. At time T7 in FIG. 6, the control means 9 outputs an ON signal to the speaker short-circuit means 13, and the speaker short-circuit means 13 brings the input terminal of the speaker 10 into the ground potential. Thereafter, at T time 8 in FIG. 6, the control means 9 turns off the switch circuit 60 and cuts off the current path from the first DC power supply 15 to the third DC power supply 59, thereby allowing the third DC power supply. 59, power supply is stopped. The output voltage of the third DC power supply 59 gradually decreases. This voltage change may be applied to the speaker 10 via the capacitor 12 to generate a noise sound. However, in the present embodiment, since the speaker short-circuit means 13 connects the input terminal of the speaker 10 and the ground potential, no signal is input to the speaker 10 and no noise sound is generated. Therefore, no noise sound is generated when the power of the audio signal amplification circuit 57 is turned on and off, and the user can be prevented from feeling uncomfortable due to the noise sound.

At this time, in the absence of the speaker short-circuit means 13, when the power supply to the audio signal amplification circuit 57 becomes 0 V, the induced electromotive voltage generated in the speaker 10 when a high-frequency current flows through the heating coil 1 is the power supply of the audio signal amplification circuit 57. When the voltage exceeds the voltage, a current flows through the protection diode of the operational amplifier IC constituting the audio signal amplification circuit 57, and the voltage waveform obtained by clamping the induced electromotive voltage of the speaker 10 is applied to the terminal of the speaker 10 as shown in FIG. However, when the input terminal of the speaker 10 is connected to the ground potential using the speaker short-circuiting means 13, the induced electromotive voltage is short-circuited, so that the induced electromotive voltage can be prevented from being applied to the audio signal amplifying circuit 57.

  In addition, since the third DC power supply 59 is stopped, the power supply to the audio signal amplifier circuit 57 is also stopped, power consumption is reduced, and the first DC power supply 15 and the third DC power supply 59 are not connected. Heat generation can be suppressed.

  In the present embodiment, since the control means 9 stores the time of the audio data in advance, the switch circuit 60 is shut off when a predetermined time has elapsed from that time. The reason why the interruption timing of the switch circuit 60 is made sufficiently later than the time of the audio data is because the speed of the audio signal output from the audio signal output means 51 varies.

  As described above, in the present embodiment, when the power supply of the audio signal amplifier circuit 57 is turned on / off, the speaker short-circuit means 13 is turned on, so that the fluctuation voltage of the power supply voltage is supplied to the speaker via the capacitor 12. 10 can be prevented and noise sound can be prevented from being emitted from the speaker 10.

  When no sound is output, the speaker short-circuit means 13 for connecting the input terminal of the speaker 10 to the ground potential is provided, so that the induced electromotive voltage generated in the speaker 10 when the high-frequency current flows through the heating coil 1 is amplified as an audio signal. Since it can be prevented from being applied to the circuit 17, even if the power supply voltage of the audio signal amplification circuit 17 is turned off, the induced electromotive voltage of the speaker 10 does not exceed the maximum rating of the audio signal amplification circuit 17 and a failure occurs. There can be no power saving rice cooker.

  Moreover, since the induced electromotive voltage generated in the speaker 10 can be prevented, the speaker 10 can be disposed in the vicinity of the heating coil 1 and a compact rice cooker can be realized.

(Embodiment 4)
FIG. 7 shows a partial block circuit diagram of the main part of the induction heating rice cooker according to Embodiment 4 of the present invention.

  As shown in FIG. 7, a high-pass filter 93 that attenuates a low-frequency component is configured by a resistor 81 and a capacitor 82, and a low-pass filter 94 that attenuates a high-frequency component is configured by a resistor 83 and a capacitor 84. The first amplifier circuit includes an operational amplifier 85, a high-pass filter 93, and a low-pass filter 94, attenuates the low frequency component and high frequency component of the output of the DA converter 53, and inverts and amplifies signals in other frequency bands. ing. Note that the amplification factor of the first amplifier circuit is determined by the ratio of the resistor 83 to the resistor 81. The second amplifier circuit includes an operational amplifier 86, a resistor 87, and a resistor 88, and inverts and amplifies the output of the first amplifier circuit. The amplification factor of the second amplifier circuit is determined by the ratio of the resistors 87 and 88. In this embodiment, the ratio between the resistor 87 and the resistor 88 is 1, and the purpose is to invert the output of the first amplifier circuit.

  The output terminal of the operational amplifier 85 is connected to one terminal of the speaker 10, and the output terminal of the operational amplifier 86 is connected to the other terminal of the speaker 10.

  The first speaker short-circuiting unit 89 is connected to one input terminal of the speaker 10 to connect or block the input terminal of the speaker 10 and the ground potential. The second speaker short-circuit means 90 is connected to the other input terminal of the speaker 10 to connect or block the speaker input terminal and the ground potential.

  The power of the memory (voice storage circuit) 52 and the DA converter 53 constituting the audio signal output means 92 is supplied from a third DC power supply 95. The third DC power supply 95 has a configuration of an emitter follower circuit similar to the third DC power supply 59 of the rice cooker of FIG. 5, but the output voltage is about 5V. Other configurations are the same as those of the second embodiment, and the same reference numerals are given and description thereof is omitted.

  The operation and action of the above configuration will be described. As shown in FIG. 7, by performing inverting amplification using two operational amplifiers 85 and 86, it is possible to apply almost the same voltage as the power supply voltage of the operational amplifiers 85 and 86 to the speaker 10, so that the operational amplifier 85, The power supply voltage of 86 can be lowered to be the same as the power supply voltage of the memory (audio signal storage circuit) 52 and the DA converter 53. Therefore, since all the power sources of the components constituting the audio signal output unit 92 can be turned off, power saving can be realized. In addition, since the rise of the output voltage of the two operational amplifiers 85 and 86 is almost the same, the noise sound is not applied to the speaker 10 when the power of the operational amplifiers 85 and 86 is turned on, which makes the user uncomfortable. Never give.

  Further, since the high-pass filter 93, the low-pass filter 94, and the operational amplifier 85 constitute the first amplifier circuit, it is possible to reduce the parts for the filter circuit and to implement a compact audio signal output means.

  As described above, in this embodiment, by using the two operational amplifiers 85 and 86 so that almost the same voltage as the power supply voltage can be output, one power source for the components constituting the audio signal output means 92 is provided. It can be turned on and off. Thereby, it is possible to realize power saving when no sound is output.

  Also, when the power of the audio signal output means 92 is off, the first speaker short-circuit means 89 and the second speaker short-circuit means 90 are turned on, and both input terminals of the speaker 10 are connected to the ground potential. Therefore, the induced electromotive voltage generated in the winding of the speaker 10 can be reduced, and the audio signal output means 92 is not destroyed even when the power is turned off, so that high reliability can be obtained.

(Embodiment 5)
The control means 9 shown in FIG. 7 makes the switch circuit 60 conductive after the first speaker short-circuit means 89 and the second speaker short-circuit means 90 have disconnected the connection between the input terminal of the speaker 10 and the ground potential. Communication is performed with the output means 92. Other configurations are the same as those of the fourth embodiment.

  The operation of the above configuration will be described with reference to FIG. FIG. 8 shows a timing chart of the main part at the time of voice output in the induction heating rice cooker of the present embodiment. (1) is a voltage waveform of the commercial power source 6 and (2) is synchronized with 0 V of the commercial power source 6. Waveform (not shown in FIG. 7), (3) is the on (conductive) and off (cut off) state of the switch circuit 60, and (4) is the output of the third DC power supply 95. Voltage waveform, (5) is a transmission signal waveform from the control means 9 to the audio signal output means 92, and (6) is ON (conduction) and OFF (cut off) of the first speaker short-circuit means 89 and the second speaker short-circuit means 90. ) State, (7) is the output voltage waveform of the operational amplifier 85, (8) is the output voltage waveform of the operational amplifier 86, (9) is the voltage waveform across the speaker 10, and (10) is the on / off state of the IGBT constituting the inverter circuit 2. (On / off of driving means 14 It shows state), respectively.

First, when the user operates a switch (input means 7) provided on the first circuit board 39, the control means 9 detects a signal from the input means 7. Then, at time T0 in FIG. 8, the control means 9 synchronizes with the zero voltage of the commercial power supply 6 and the first speaker short-circuit means 89 and the second short-circuit means 90.
An off signal is output to the input terminal of the speaker 10 and the connection between the input terminal of the speaker 10 and the ground potential is cut off so that the signal can be input to the speaker 10. Thereafter, at time T 1 in FIG. 8, the switch circuit 60 is turned on, the third DC power supply 95 is activated, and a DC voltage is supplied to the audio signal output means 92. Although the output voltages of the operational amplifier 85 and the operational amplifier 86 fluctuate when the DC voltage rises, since the output voltages of the two operational amplifiers 85 and 86 are the same, the voltage across the speaker 10 becomes 0V, and no sound is output from the speaker 10.

  If the power supply voltage is input to the operational amplifier 85 and the operational amplifier 86 with the first speaker short-circuiting means 89 and the second speaker short-circuiting means 90 turned on, the output terminals of the operational amplifier 85 and the operational amplifier 86 are short-circuited. A short-circuit current flows, the rated current of the operational amplifier 85 and the operational amplifier 86 is exceeded, and there is a risk of destruction. However, in this embodiment, the first speaker short-circuit means 89 and the second speaker short-circuit means 90 are turned off before the power supply voltages of the operational amplifier 85 and the operational amplifier 86 are input. There is no destruction.

  Thereafter, at time T2 in FIG. 8, the control unit 9 transmits the volume setting data to the audio signal output unit 92 in synchronization with the zero voltage of the commercial power supply 6. Thereafter, at time T3 in FIG. 8, the control unit 9 transmits address data indicating predetermined audio data to the audio signal output unit 92 in synchronization with the zero voltage of the commercial power supply 6. Then, at time T4 in FIG. 8, the memory 52 outputs digital data of a predetermined sound to the DA converter 53 based on the transmission data from the control means 9, and the DA converter 53 converts the sound into an analog voltage. A signal is output, and an audio signal is input to the speaker 10 via the first amplifier circuit and the second amplifier circuit. As a sound signal input to the speaker 10, a voltage difference between the output voltages of the operational amplifier 85 and the operational amplifier 86 is input. When an audio signal is input, the speaker 10 vibrates, and this vibration becomes sound and notifies the user of the sound.

  When the audio signal is output, the voltage of the third DC power supply 95 decreases by about 0.2 V, but the voltage of the second DC power supply 58 does not change, so that the reference voltage of the AD converter that constitutes the control means 9 Does not fluctuate. Therefore, it is possible to prevent influences on detection means using the AD converter, such as temperature detection of the pot 35, detection of input current, voltage detection of commercial power supply, and the like.

  At time T5 in FIG. 8, according to the menu set by the input means 7, the control means 9 starts on / off control of the IGBTs constituting the inverter circuit 2 via the drive means 14, and supplies high frequency power to the heating coil 1. The pan 35 is heated.

  At time T6 in FIG. 8, the audio output ends, and the output voltage of the third DC power supply 95 returns to the original value. At time T7 in FIG. 8, the control means 9 turns off the switch circuit 60, cuts off the current path from the first DC power supply 15 to the third DC power supply 95, and supplies power to the third DC power supply 95. To stop. The output voltage of the third DC power supply 95 gradually decreases. This voltage change may be applied to the speaker 10 via the operational amplifier, resulting in noise. However, in this embodiment, since the output voltages of the two operational amplifiers 85 and 86 are the same, the voltage across the speaker 10 does not fluctuate, and no noise sound is generated from the speaker 10. Therefore, no noise sound is generated when the power of the audio signal output means 92 is turned on and off, and the user can be prevented from feeling uncomfortable due to the noise sound.

If the first speaker short circuit 89 and the second speaker short circuit 90 are turned on while the power supply voltages of the operational amplifier 85 and the operational amplifier 86 are input, the output terminals of the operational amplifier 85 and the operational amplifier 86 are short-circuited. A short-circuit current flows, the rated current of the operational amplifier 85 and the operational amplifier 86 is exceeded, and there is a risk of destruction. However, in the present embodiment, the power supply voltage of the operational amplifier 85 and the operational amplifier 86 is turned off while the first speaker short-circuiting means 89 and the second speaker short-circuiting means 90 are turned off, so that the operational amplifier 85 and the operational amplifier 86 are destroyed. Never do.

  Thereafter, at time T8 in FIG. 8, the control means 9 outputs an ON signal to the first speaker short-circuit means 89 and the second speaker short-circuit means 90, and the first speaker short-circuit means 89 is one input terminal of the speaker 10. And the second speaker short-circuit means 90 and the other input terminal of the speaker 10 are connected to the ground potential.

  In the case where the first speaker short-circuiting means 89 and the second speaker short-circuiting means 90 are not provided, when the power supply to the audio signal output means 92 becomes 0 V, induction that occurs in the speaker 10 when a high-frequency current flows through the heating coil 1. The electromotive voltage exceeds the power supply voltage of the operational amplifier 85 and the operational amplifier 86, current flows through the protective diodes of the operational amplifiers 85 and 86, and the voltage waveform obtained by clamping the induced electromotive voltage of the speaker 10 as shown in FIG. However, if the input terminal of the speaker 10 is connected to the ground potential using the first speaker short-circuit means 89 and the second speaker short-circuit means 90, the induced electromotive voltage is short-circuited. It is possible to prevent an excessive induced electromotive voltage from being applied to the operational amplifier 86.

  Further, since the third DC power supply 95 is stopped, the power supply to the audio signal output means 92 is also stopped, power consumption is reduced, and the first DC power supply 15 and the third DC power supply 95 are connected. Heat generation can be suppressed. In the present embodiment, since the control means 9 stores the time of the audio data in advance, the switch circuit 60 is turned off when the predetermined time has elapsed from that time, and the first DC power supply 15 supplies the first time. The current path to the third DC power source 95 is cut off. The reason why the OFF timing of the switch circuit 60 is made sufficiently later than the time of the sound data is that the speed of the sound signal output from the sound signal output means 92 varies.

  As described above, in the present embodiment, when the audio signal amplifier circuit is configured using the first amplifier circuit and the second amplifier circuit, the first signal is input while power is being input to the audio signal amplifier circuit. The speaker short-circuiting means 89 and the second speaker short-circuiting means 90 are turned off, and the first speaker short-circuiting means 89 and the second speaker short-circuiting means 90 are turned on while the power of the audio signal amplifier circuit is turned off. As a result, it is possible to prevent the output voltage of the operational amplifier 85 and the operational amplifier 86 from being short-circuited, so that the failure of the operational amplifier 85 and the operational amplifier 86 can be prevented.

  Further, when no sound is output, by providing the first speaker short-circuit means 89 and the second speaker short-circuit means 90 for connecting the input terminal of the speaker 10 to the ground potential, a high-frequency current flows through the heating coil 1. Since the induced electromotive voltage generated in the speaker 10 can be reduced from being applied to the output terminals of the operational amplifier 85 and the operational amplifier 86, the induced electromotive voltage of the speaker 10 becomes the audio signal even when the power supply voltage of the audio signal amplifier circuit is turned off. It is possible to provide a rice cooker that does not exceed the maximum rating of the amplifier circuit and saves power without causing a failure.

(Embodiment 6)
FIG. 9 shows a partial block circuit diagram of the main part of the induction heating rice cooker according to the sixth embodiment of the present invention.

  As shown in FIG. 9, the electronic switch 101 is configured as an NPN transistor or a relay, and is turned on (conducted) or turned off (cut off) in response to an on / off signal from the control means 9. The resistors 102 and 103 are connected in series, and one terminal of each of the resistors 102 and 103 is connected to the input terminal of the speaker 10. That is, in the present embodiment, the speaker short-circuiting means 104 is constituted by the resistor 102, the resistor 103, and the electronic switch 101. Other configurations are the same as those in the fourth embodiment, and the same reference numerals are given and description thereof is omitted.

As described above, one switch can be connected to the input terminal of the speaker 10 and the ground potential through the two resistors 102 and 103. Further, since the input terminal of the speaker 10 is connected to the ground potential via the resistors 102 and 103, the speaker short-circuit means 104 connects the input terminal of the speaker 10 to the ground when the power supply voltage of the operational amplifier 85 and the operational amplifier 86 is turned on. Even if the potential is connected, overcurrent is prevented from flowing through the operational amplifier 85 and the operational amplifier 86. Therefore, the speaker short-circuit means 104 can be turned on / off regardless of whether the operational amplifier 85 and the operational amplifier 86 are powered on or off.

(Embodiment 7)
Communication between the control means 9 and the audio signal output means 92 shown in FIG. 9 is performed when the inverter circuit 2 is stopped. Other configurations are the same as those of the sixth embodiment.

  The operation of the above configuration will be described with reference to FIG. FIG. 10 shows a timing chart of the main part at the time of voice output in the induction heating rice cooker of the present embodiment. (1) is a voltage waveform of the commercial power source 6, and (2) is synchronized with 0 V of the commercial power source 6. Waveform (not shown in FIG. 9), (3) is the on (conducting) and off (cutting) state of the switch circuit 60, and (4) is the output of the third DC power supply 95. Voltage waveform, (5) is a transmission signal waveform from the control means 9 to the audio signal output means 92, (6) is an on (conduction) and off (cutoff) state of the speaker short-circuit means 104, and (7) is an output of the operational amplifier 85. Voltage waveform, (8) is an output voltage waveform of the operational amplifier 86, (9) is a voltage waveform across the speaker 10, and (10) is an on / off state of the IGBT constituting the inverter circuit 2 (on / off state of the driving means 14). ing.

  First, in FIG. 10, the user has already operated a switch (input means 7) provided on the first circuit board 39 to perform a predetermined rice cooking operation. That is, the control means 9 controls the inverter circuit 2 via the drive means 14, supplies a high frequency current to the heating coil 1, and heats the pot 35 by induction. In the above state, it is assumed that the user has pressed a switch constituting the input means 7.

  Then, at time T0 in FIG. 10, the control means 9 outputs an OFF signal to the speaker short-circuit means 104 in synchronization with the zero voltage of the commercial power supply 6 to cut off the connection between the input terminal of the speaker 10 and the ground potential. The signal can be input to the speaker 10. Thereafter, at time T1 in FIG. 10, the switch circuit 60 is turned on, the third DC power supply 95 is activated, and a DC voltage is supplied to the audio signal output means 92. Although the output voltages of the operational amplifier 85 and the operational amplifier 86 fluctuate when the DC voltage rises, the output voltages of the two operational amplifiers are the same. Therefore, the voltage across the speaker 10 becomes 0 V, and no sound is output from the speaker 10.

  Thereafter, at time T2 in FIG. 10, the control unit 9 transmits volume setting data to the audio signal output unit 92 in synchronization with the zero voltage of the commercial power supply 6. At this time, the control means 9 outputs an off signal to the drive means 14 and stops the operation of the inverter circuit 2. When the control unit 9 finishes transmitting the volume setting data to the audio signal output unit 92, the control unit 9 outputs an on / off signal to the drive unit 14 in synchronization with the zero voltage of the commercial power supply 6 at time T3 in FIG. The operation of the inverter circuit 2 is started again.

Thereafter, at time T4 in FIG. 10, the control unit 9 transmits address data indicating predetermined audio data to the audio signal output unit 92 in synchronization with the zero voltage of the commercial power supply 6. At this time, the control means 9 outputs an off signal to the drive means 14 and stops the operation of the inverter circuit 2. Then, at time T5 in FIG. 10, the memory 52 outputs digital data of a predetermined sound to the DA converter 53 based on the transmission data from the control means 9, and the DA converter 53 converts the sound into an analog voltage. A signal is output, and an audio signal is input to the speaker 10 via the first amplifier circuit and the second amplifier circuit. As a sound signal input to the speaker 10, a voltage difference between the output voltages of the operational amplifier 85 and the operational amplifier 86 is input. When an audio signal is input, the speaker 10 vibrates, and this vibration becomes sound and notifies the user of the sound.

  When the audio signal is output, the voltage of the third DC power supply 95 decreases by about 0.2 V, but the voltage of the second DC power supply 58 does not change, so that the reference voltage of the AD converter that constitutes the control means 9 Does not fluctuate. Therefore, it is possible to prevent influences on detection means using the AD converter, such as temperature detection of the pot 35, detection of input current, voltage detection of commercial power supply, and the like.

  At time T6 in FIG. 10, the control means 9 outputs an on / off signal to the drive means 14 in synchronization with the zero voltage of the commercial power supply 6, and starts the operation of the inverter circuit 2 again. At time T7 in FIG. 10, the audio output ends, and the output voltage of the third DC power supply 95 returns to the original value.

  At time T8 in FIG. 10, the control means 9 turns off the switch circuit 60, cuts off the current path from the first DC power supply 15 to the third DC power supply 95, and supplies power to the third DC power supply 95. To stop. The output voltage of the third DC power supply 95 gradually decreases. This voltage change may be applied to the speaker 10 via the operational amplifier, resulting in noise. However, in this embodiment, since the output voltages of the two operational amplifiers 85 and 86 are the same, the voltage across the speaker 10 does not fluctuate, and no noise sound is generated from the speaker 10. Therefore, no noise sound is generated when the power of the audio signal output means 92 is turned on and off, and the user can be prevented from feeling uncomfortable due to the noise sound.

  Thereafter, at time T9 in FIG. 10, the control means 9 outputs an ON signal to the speaker short-circuit means 104, and the speaker short-circuit means 104 makes the input terminal of the speaker 10 and the ground potential conductive.

  In the absence of the speaker short-circuit means 104, when the power supply to the audio signal output means 92 becomes 0 V, the induced electromotive voltage generated in the speaker 10 when a high-frequency current flows through the heating coil 1 is the power supply voltage of the operational amplifier 85 and the operational amplifier 86. As shown in FIG. 4 (3), a voltage waveform in which the induced electromotive voltage of the speaker 10 is clamped is output to the terminal of the speaker 10, but the speaker is short-circuited. When the input terminal of the speaker 10 is connected to the ground potential using the means 104, the induced electromotive voltage is reduced by the resistors 102 and 103, so that it is possible to prevent an excessive induced electromotive voltage from being applied to the operational amplifier 85 and the operational amplifier 86.

  Further, since the third DC power supply 95 is stopped, the power supply to the audio signal output means 92 is also stopped, power consumption is reduced, and the first DC power supply 15 and the third DC power supply 95 are connected. Heat generation can be suppressed. In the present embodiment, the control means 9 stores the time of the audio data in advance, so when a predetermined time has elapsed from that time, the switch circuit 60 is turned off and the first DC power supply 15 supplies the first time. The current path to the third DC power source 95 is cut off. The reason why the OFF timing of the switch circuit 60 is made sufficiently later than the time of the sound data is that the speed of the sound signal output from the sound signal output means 92 varies.

  As described above, in the present embodiment, since the operation of the inverter circuit 2 is stopped when the control means 9 transmits a signal to the audio signal output means 92, the noise when the inverter circuit 2 is operated becomes a transmission signal. Can be prevented from being superimposed, and a predetermined sound can be reliably output.

As described above, the induction heating rice cooker according to the present invention has the audio signal output means even when the induction electromotive force is generated in the speaker by the high frequency magnetic field of the heating coil when the power supply of the audio signal output means is stopped. Can be prevented, and it is safe, compact, and can provide an induction heating rice cooker that can realize power saving. Therefore, it is useful as an induction heating rice cooker having a voice notification function.

The circuit diagram which made the main part of the induction heating type rice cooker in Embodiment 1 of this invention a part block configuration Cross section of the induction heating rice cooker Timing chart for voice output of the induction heating rice cooker (1) Envelope waveform diagram of high-frequency current flowing through the heating coil of the induction heating rice cooker (2) When the high-frequency current flows through the heating coil when the speaker short-circuit means of the induction heating rice cooker is turned on Inductive electromotive voltage waveform diagram (3) Inductive electromotive voltage waveform diagram generated in the speaker when a high-frequency current flows through the heating coil when the speaker short-circuiting means of the induction heating rice cooker is turned off The circuit diagram which made the main part of the induction heating type rice cooker in Embodiment 2 of this invention partially block-ized Timing chart at the time of sound output of induction heating type rice cooker in Embodiment 3 of the present invention The circuit diagram which made the main part of the induction heating type rice cooker in Embodiment 4 of this invention partially block-ized. Timing chart at the time of sound output of induction heating rice cooker in Embodiment 5 of the present invention The circuit diagram which made the main part of the induction heating type rice cooker in Embodiment 6 of this invention into the partial block form Timing chart at the time of voice output of induction heating rice cooker in Embodiment 7 of the present invention

DESCRIPTION OF SYMBOLS 1 Heating coil 2 Inverter circuit 9 Control means 10 Speaker 11 Audio | voice signal output means 13 Speaker short-circuit means 17 Switch circuit 35 Pan

Claims (3)

A heating coil that induction-heats the pan, an inverter circuit that supplies high-frequency power to the heating coil, a control unit that controls the inverter circuit, a speaker, and an output of the control unit that outputs an audio signal to the speaker Audio signal output means, a switch circuit that receives or outputs a signal from the control means to cut off or conduct a power path to the audio signal output means, and speaker short-circuit means that connects the input terminal of the speaker to a ground potential, When the control means does not output sound, the switch circuit cuts off the power supply path of the sound signal output means, and the speaker short-circuit means connects the input terminal of the speaker to a ground potential to output sound. When the power supply path of the audio signal output means is conducted by the switch circuit, the speaker short-circuit means Configured to cut off the connection between the input terminal and the ground potential of the speaker, the audio signal output means, stored in advance and an audio signal storage circuit for outputting audio data as signals, the audio signal more than a predetermined frequency of the memory circuit of the signal A filter circuit for attenuating a component and a low frequency component equal to or lower than a predetermined value, and an audio signal amplifier circuit for amplifying the output signal of the filter circuit, and the switch circuit cuts off or conducts at least a power supply path of the audio signal amplifier circuit The audio signal amplifier circuit includes a first amplifier circuit that inverts and amplifies the output signal of the filter circuit, and a second amplifier circuit that inverts and amplifies the output signal of the first amplifier circuit. The input terminal is connected to the output of the first amplifier circuit, the other input terminal is connected to the second amplifier circuit, and the first amplifier circuit and the second amplifier circuit are connected. Induction heating cooker in which the power supply voltage of the circuit and the audio signal storage circuit in common. After speaker short-circuit device has disconnected the input terminal and the ground potential of the loudspeaker, the control means is a switching circuit in a conductive state, induction heating cooker according to claim 1 wherein to perform the communication to the audio signal output means. The induction heating rice cooker according to claim 2 , wherein the speaker short-circuit means connects the input terminal of the speaker and the ground potential after the control means turns off the switch circuit.

Images