JP5586385B2 - Self-excited light emitting device and self-excited sterilization device - Google Patents

Description

The present invention relates to a self- excited light-emitting device that can be used in an alternating magnetic field environment and a self-excited disinfecting device that is a self-excited light-emitting device for sterilization.

  In an electric appliance such as an electromagnetic cooker, which is a kind of induction heating device, light emission using a light source such as a light emitting diode (LED = Light-Emitting Diode) for display to notify the user of the operation state of the appliance in an easy-to-understand manner. A device is provided. In addition, recently, there is an example in which home appliances are provided with a sterilization apparatus using a light source such as an ultraviolet LED that emits ultraviolet rays having a sterilizing action.

  It is desirable to install the light-emitting device and the sterilization device in the optimum position in consideration of the convenience for the user and the function of the electric device. However, the power supply wiring from the electric device to the light-emitting device and the sterilization device is necessary. Therefore, there is a problem that the installation position is limited due to the mechanism of the electric device. In addition, when priority is given to the installation position, there is a problem that the wiring for power supply is necessary and the mechanism of the electric device is complicated due to the wiring, leading to an increase in cost.

  In order to solve these problems, a self-excited power supply device that can supply power to other devices without the need for external power supply wiring, such as an electric device main body, is adopted. A self-excited light emitting device that supplies light to a light source such as a light source has been proposed.

  Patent Document 1 exemplifies an operation display circuit that is a light-emitting device having a self-excited power supply function. In an operation display circuit of an induction heating device that induction-heats an object to be heated by a heating coil fed from a power source, An operation display circuit is disclosed in which a detection coil for detecting generated magnetic flux and a display circuit including at least one set of a display unit in which a resistor, a Zener diode, and an LED are connected in series are connected in parallel.

  The operation display circuit of Patent Document 1 functions in an AC magnetic field environment formed by a heating coil, and supplies an AC voltage generated at both ends of the detection coil to the light source by an AC magnetic flux interlinked with the detection coil. The AC voltage generated at both ends of the detection coil is applied to the LED through a resistor and a Zener diode, and the LED emits light. According to the present invention, the power supply wiring from the induction heating device to the operation display circuit becomes unnecessary.

JP-A-8-298181

  However, in the invention of Patent Document 1, the voltage generated in the detection coil may not reach the voltage necessary for turning on the light source for operation display.

  In an induction heating device such as an electromagnetic cooker, most of the magnetic flux generated by the heating coil is converted to heat by a heating object (such as a pot in the case of an electromagnetic cooker) installed in the induction heating device. The density of magnetic flux that is not converted (leakage magnetic flux) is extremely small. Therefore, in order to supply the voltage necessary for lighting the light source, a detection coil is installed at a position very close to the heating coil where the leakage magnetic flux density is relatively large, or an AC voltage is induced, or the detection coil is heated. It is necessary to install between an object and a heating coil to detect a magnetic flux that is not a leakage magnetic flux and induce an alternating voltage. The leakage magnetic flux refers to a magnetic flux that is not used for the original purpose.

  As a result, in the invention of Patent Document 1, the restriction on the installation position of the operation display circuit including the detection coil becomes large, and the conventional problem that the installation position of the LED is limited cannot be solved.

  As described above, it has been difficult in the prior art to realize a self-excited power supply apparatus having a high degree of freedom of installation in a leakage AC magnetic field environment and a self-excited light-emitting apparatus that combines a self-excited power supply apparatus and a light source. The same applies to a sterilization apparatus that uses the light-emitting device for sterilization.

The present invention has been made to solve the above-described problems, and can be used in a leakage AC magnetic field environment. A power supply wiring is unnecessary and a self- excited light emitting device having a high degree of freedom in installation, and An object of the present invention is to provide a self-excited sterilization apparatus which is a self-excited light-emitting device for sterilization.

To achieve the above object, a self-excited light emitting device according to the present invention includes a self-excited power supply device that operates in a leakage AC magnetic field environment of a predetermined frequency, a light source that receives power from the self-excited power supply device, and emits light. A controller for controlling lighting, and a switch circuit disposed between the self-excited power feeding device and the controller. The self-excited power supply device includes a detection coil arranged so as to interlink with a leakage alternating magnetic field, a resonance capacitor connected in parallel to the detection coil to form a resonance circuit, and a rectifier circuit connected to the resonance circuit. The alternating voltage induced in the detection coil by the leakage alternating magnetic field is resonated and amplified by the resonance circuit. The rectifier circuit resonates with the resonance circuit, boosts the amplified AC voltage without power supply from the outside, converts it to a DC voltage, and outputs it to the controller. An output capacitor is connected to the output terminal of the rectifier circuit. The switch circuit is opened when the output of the rectifier circuit is below a predetermined voltage value, disconnecting the rectifier circuit and the controller, and closed when the output capacitor is charged and the output of the rectifier circuit exceeds the predetermined voltage value. A state is established and the rectifier circuit and the controller are connected. The controller receives power from the self-excited power supply device when the switch circuit is in a closed state, and controls lighting of the light source.

According to the present invention , a self- excited light-emitting device that can be used in a leakage AC magnetic field environment, does not require power supply wiring, and has a high degree of freedom in installation, and a self-excited disinfectant that uses the self-excited light-emitting device for sterilization An apparatus can be provided.

It is a circuit block diagram which shows the example of the self-excitation light-emitting device using the self-excitation electric power feeder which concerns on Embodiment 1 of this invention. 2 is a circuit block diagram illustrating an example of a controller of the self-excited light emitting device according to Embodiment 1. FIG. 6 is a circuit block diagram illustrating a light emitting device including another example of a controller of the self-excited light emitting device according to Embodiment 1. FIG. FIG. 3 is a circuit block diagram illustrating an example of a self-excited light emitting device including the voltage determination circuit according to the first embodiment. 4 is a circuit block diagram illustrating an example of a voltage determination circuit of the self-excited light emitting device according to Embodiment 1. FIG. FIG. 6 is a circuit block diagram illustrating another example of the voltage determination circuit of the self-excited light emitting device according to the first embodiment. 1 is a circuit block diagram illustrating an example of a self-excited light emitting device including a high-side switch circuit according to Embodiment 1. FIG. It is a figure which shows the structural example of the self-excitation sterilization apparatus which concerns on Embodiment 2 of this invention. (A) Perspective view of an electromagnetic rice cooker including a water storage tank according to Embodiment 2, (b) Perspective view showing an example of a self-excited sterilization apparatus installed in the water storage tank of the electromagnetic rice cooker, (c) (b) It is the figure equivalent to the front view and side view of a water storage tank which installed the self-excited sterilization apparatus shown. It is a schematic diagram which shows the other structural example of the self-excitation sterilization apparatus for electromagnetic rice cookers which concerns on Embodiment 2. FIG.

Embodiment 1. FIG.
FIG. 1 is a circuit block diagram showing an example of a self-excited light emitting device using the self-excited power supply device according to Embodiment 1 of the present invention. The self-excited power supply device 5 and the self-excited light-emitting device 4 are assumed to be used in an alternating magnetic field environment. This AC magnetic field is an AC magnetic field formed by, for example, the heating coil 2 included in the induction heating device 1 and is a leakage AC magnetic field that has not been used for heating. Leakage magnetic flux 3 indicates the magnetic flux of this leakage AC magnetic field. Specific examples of the induction heating device 1 include an electromagnetic cooker (including an electromagnetic rice cooker).

  The self-excited light-emitting device 4 includes a self-excited power supply device 5 and a light-emitting device 6 that includes a light source that receives power from the self-excited power supply device 5 and emits light. The self-excited light emitting device 4 is used as an operation display device such as an electromagnetic cooker or an electromagnetic rice cooker.

  The self-excited power feeding device 5 includes a detection coil 7, a resonance capacitor 8 that is connected in parallel to the detection coil 7 and forms a resonance circuit 9, and a rectifier circuit 10 that is connected to the resonance circuit 9. .

  The detection coil 7 is arranged so as to interlink with the leakage magnetic flux 3, and the leakage magnetic flux 3 generates an AC voltage signal between both ends of the detection coil 7.

  The resonance capacitor 8 has a capacitance value that satisfies the resonance condition at the frequency of the leakage magnetic flux 3 with respect to the inductance of the detection coil 7, and constitutes a resonance circuit 9 together with the detection coil 7. Therefore, the amplitude value of the AC voltage signal generated between both ends of the detection coil 7 is amplified by resonance.

  The rectifier circuit 10 includes n stages of voltage doubler rectifier circuits composed of capacitors 100 and 102 and two diodes (Schottky barrier diodes in the example shown in FIG. 1) 101 (four stages in the example of FIG. 1). A multiple voltage rectifier circuit 103; and a resistor 104 that converts the voltage signal amplified and half-wave rectified by the multiple voltage rectifier circuit 103 together with the capacitor 102 of the multiple voltage rectifier circuit 103 into a direct current by defining a time constant; The AC voltage signal generated by the detection coil 7 is amplified and converted into a DC voltage signal. In the example of FIG. 1, the AC voltage signal between both ends of the detection coil 7 amplified by resonance is further amplified eight times by the multiple voltage rectifier circuit 103 to be converted to DC.

  The operation of the multiple voltage rectifier circuit 103 will be described. The voltage doubler rectifier circuit constituting the multiple voltage rectifier circuit 103 is a circuit that performs half-wave rectification by doubling the input voltage. The reason why the input voltage is doubled is as follows. An AC voltage signal is input to the capacitor 100 from the resonance circuit 9. Now, when the input terminal potential of the AC voltage signal of the capacitor 100 is lower than the ground potential, the capacitor 100 is placed near the peak value of the input AC voltage with the diode side being positive and the input terminal side being negative by the diode 101 which is not installed. Charged. Next, when the input terminal potential of the AC voltage signal of the capacitor 100 becomes higher than the ground potential, the capacitor 102 is charged by the diode 101 that is not provided with the input potential and the charged value of the capacitor 100 in series. As a result, the potential of the capacitor 102 becomes nearly twice the peak voltage of the input AC voltage. The multiple voltage rectifier circuit performs half-wave rectification by stacking n stages of the voltage doubler so that the peak value of the input voltage is 2 * n times.

  Since the self-excited power supply device 5 is configured as described above, even if the leakage magnetic flux 3 is small in an AC magnetic field environment, a DC voltage signal having a predetermined magnitude is applied to the output terminal without power supply from the outside. Can be generated.

  The light-emitting device 6 includes a light source 12, a controller 11 that controls the light emission by controlling energization to the light source 12, a protection circuit for preventing application of overvoltage to the controller 11, a zener diode 13 in the example of FIG. Consists of. The controller 11 and the light source 12 are supplied with power from the self-excited power supply device 5.

  The controller 11 is composed of, for example, a low voltage logic circuit, a microcontroller, or a microcomputer, and controls light emission of the light source 12 by controlling voltage application to the light source 12. FIG. 1 shows an example in which three LEDs connected in parallel to each other are controlled by a controller 11 as a light source 12. The number of the light sources 12 is determined depending on the application, and may be one or plural.

  The light source 12 is composed of a light emitting element such as an LED, for example, and emits light upon receiving a DC voltage signal. Since the self-excited power supply device 5 of the present application supplies a voltage signal induced by the leakage magnetic flux 3, the power that can be supplied is not large. For this reason, it is desirable that the load of the light source 12 to be fed by the self-excited power feeding device 5 has a small power consumption. An LED is suitable as the light source 12 because of its low power consumption. Even if the leakage magnetic flux 3 is small by using the LED, the light source 11 can be turned on.

  The Zener diode 13 is used as a protection circuit for preventing an overvoltage from being applied to a subsequent circuit. That is, even if the voltage supplied from the self-excited power supply device 5 becomes extremely large for some reason, the voltage input from the power supply point of the controller 11 is clamped to the Zener voltage of the Zener diode 13, and therefore the controller 11 Protected against input.

  The operation of the self-excited light emitting device 4 including the self-excited power supply device 5 will be described. In FIG. 1, when an induction heating device 1 (for example, an electromagnetic cooker such as an electromagnetic rice cooker) operates, an AC magnetic flux having a predetermined frequency for heating an object to be heated (for example, a pot) is generated by the heating coil 2. Most of the magnetic flux generated from the heating coil 2 is converted into heat by the object to be heated by the induction heating device 1, but a part of the magnetic flux leaks and a leakage magnetic flux 3 is generated. This leakage magnetic flux 3 also has a predetermined frequency.

  An AC voltage signal proportional to the leakage magnetic flux 3 is induced in the detection coil 7 interlinking with the leakage magnetic flux 3 by Faraday's law. The resonance frequency of the resonance circuit 9 including the detection coil 7 and the resonance capacitor 8 connected in parallel to the detection coil 7 is set equal to the frequency of the leakage magnetic flux 3.

  Since the resonance frequency is determined by the inductance of the detection coil 7 and the capacitance of the resonance capacitor 8 constituting the resonance circuit 9, the resonance frequency matches the frequency of the leakage magnetic flux 3 by adjusting the inductance of the detection coil 7 and the capacitance of the resonance capacitor 8. Let The AC voltage signal induced in the detection coil 7 is amplified by resonance and input to the rectifier circuit 10.

  When the self-excited light emitting device 4 is used as an operation display device of an electromagnetic cooker, the frequency of the leakage magnetic flux 3 is generally about several tens of kHz, and the detection coil 7 has an inductance of, for example, several hundreds μH to several mH. In this case, the capacity of the resonance capacitor 8 is selected so that the resonance frequency becomes equal to a value of about several tens of kHz.

  The AC voltage signal amplified by resonance is amplified by the rectifier circuit 10 and converted into a DC signal. The multiple voltage rectifier circuit 103 of the rectifier circuit 10 rectifies the AC voltage signal by half-wave rectification and the peak voltage, ideally, a diode constituting the multiple voltage rectifier circuit 103 (Schottky barrier diode in the example of FIG. 1). Is amplified by the number of. In practice, due to the characteristics of the circuit elements, the signal has a voltage slightly smaller than the voltage expected from the amplification for the number of diodes. The voltage signal amplified and converted into direct current by the rectifier circuit 10 is fed to the light source 12 via the controller 11, and the controller 11 controls the light emission of the light source 12 by controlling the voltage applied to the light source 12.

  By introducing the multiple voltage rectifier circuit 103, the output voltage of the rectifier circuit 10 can be increased. By combining the resonance circuit 9 with this, the effect of increasing the output voltage is further increased.

  As the diode 101 constituting the multiple voltage rectifier circuit 103 of the rectifier circuit 10, a Schottky barrier diode is used in FIG. 1, but an ordinary diode may be used. The reason why the Schottky barrier diode is used is that the forward voltage drop of the Schottky barrier diode is smaller than that of a normal diode. Therefore, the efficiency of voltage amplification by the multiple voltage rectifier circuit 103 is improved by using the Schottky barrier diode. It is because it can improve. By using the multiple voltage rectifier circuit 103 having such a configuration, even when the leakage magnetic flux 3 is small and the amplitude of the voltage signal induced in the detection coil 7 is small, the voltage signal can be efficiently amplified. it can. Further, by using a Schottky barrier diode, the inductance of the detection coil 7 or the number of voltage doubler rectifier circuit stages of the multiple voltage rectifier circuit 103 necessary for obtaining a predetermined voltage can be further reduced.

  The controller 11 and the light source 12 of the light emitting device 6 operate by power feeding from the self-excited power feeding device 5. FIG. 2 shows an example of the controller 11 when three LEDs connected in parallel as the light source 12 are used.

  In FIG. 2, the controller 11 is configured by connecting a resistor 110a and a Zener diode 111a, a resistor 110b and a Zener diode 111b, and a resistor 110c and a Zener diode 111c connected in series. The output of the self-excited power feeding device 5 is input to the ends of the resistors 110a, 110b, and 110c opposite to the connection ends of the Zener diodes 111a, 111b, and 111c. The zener diode 13 protects the controller 11 against overvoltage input.

  The controller 11 includes LEDs 12a, 12b as light sources at the ends of the Zener diode 111a, Zener diode 111b, and Zener diode 111c opposite to the connection ends of the resistors 110a, 110b, and 110c, respectively. 12c is connected. The connected LEDs are of the same type.

  Assume that the Zener voltages Vta, Vtb, and Vtc of the Zener diode 111a, Zener diode 111b, and Zener diode 111c are, for example, Vta <Vtb <Vtc. By setting each zener voltage in this way, when the output Vo of the self-excited power supply device 5 input to the controller 11 is Vta or less, none of the LEDs is lit. When Vta <Vo ≦ Vtb, only the LED 12a is turned on. When Vtb <Vo ≦ Vtc, the LED 12a and the LED 12b are turned on. When Vtc <Vo, the LED 12a, the LED 12b, and the LED 12c are turned on. The output Vo of the self-excited power feeding device 5 is proportional to the magnetic flux density of the leakage magnetic flux 3, that is, the magnetic flux density of the heating coil. Therefore, the self-excited light-emitting device 4 can be used as an operation display device that displays the operation status of the induction heating device 1 according to the lighting state of the light sources 12a to 12c, and does not require power supply from the outside.

  In this example, the Zener voltage Vtx of the Zener diode 13 is set to a predetermined value exceeding Vtc. Thereby, the malfunction by overvoltage exceeding Vtx being applied to the controller 11 and the light source 12 can be prevented.

  FIG. 3 shows another example of the controller 11 of the self-excited light emitting device 4 according to this embodiment. In this example, the controller 11 includes a transistor 113 and a base controller 112 that is connected to the base of the transistor 113 and controls the emitter current of the transistor 113 by controlling the base current. Power supply from the self-excited power supply device 5 to the controller 11 is performed at two points: power supply to the base controller 112 and power supply to the collector electrode of the transistor 113. The output terminal of the self-excited power feeding device 5 is connected to the ground via a resistor 14 and a Zener diode 13 connected in series with each other. In addition, a voltage signal extracted from a point between the resistor 14 and the Zener diode 13 is supplied to the base controller 112, and a voltage signal from the output terminal of the self-excited power supply device 5 is connected to the collector electrode of the transistor 113.

  Next, the operation will be described. By detecting the leakage magnetic flux 3 with the detection coil 7, a DC voltage signal is generated at the output end of the self-excited power feeding device 5. If this voltage is equal to or higher than a predetermined value, a predetermined DC voltage signal is applied to the base of the transistor 113 by the base controller 112, the transistor 113 is turned on, the collector / emitter is conducted, and the light source 12 is a self-excited power supply device. Turns on when receiving power from 5.

  As described above, the self-excited power supply device 5 including the resonance circuit 9 including the detection coil 7 and the resonance capacitor 8 and the rectification circuit 10 including the multiple voltage rectification circuit 103 has the magnetic flux density of the leakage magnetic flux 3. Even in a small environment, a necessary voltage signal can be supplied to the others without requiring external power supply.

  The multiple voltage rectifier circuit 103 may be a rectifier having any configuration as long as it can boost and rectify an input AC voltage without being fed from outside.

  Further, in the self-excited light emitting device 4 in which the self-excited power feeding device 5 and the light emitting device 6 configured as described above are combined, even if the leakage magnetic flux density is small under the environment of the AC leakage magnetic flux 3, the self-excited type The light source 12 can emit light without supplying power to the light emitting device 4 from the outside, that is, without a power supply line.

  Therefore, in the self-excited power supply device 5 and the self-excited light emitting device 4 according to the first embodiment, between the heating coil 2 of the induction heating device 1 and the object to be heated (pot pot, etc.) or very close to the heating coil 2. The need to install the detection coil 7 is eliminated, and the degree of freedom of the installation positions of the self-excited power feeding device 5 and the self-excited light-emitting device 4 is increased as compared with the conventional case.

  Since the power supply line is unnecessary and the degree of freedom of the installation position is large, the self-excited power supply device 5 or the self-excited light-emitting device 4 is optimal for the purpose without depending on the mechanism of the induction heating device 1. It becomes possible to install in the position.

  Therefore, when the self-excited light emitting device 4 is used as an operation display device of the induction heating device 1 such as an electromagnetic cooker, for example, the operation display device can be installed at a position free relative to the induction heating device 1 than before. The operation display device can be installed at a position that is easy to see without depending on the mechanism of the induction heating device 1. Therefore, the user can easily visually recognize the operation of the induction heating device 1, and convenience when using the induction heating device 1 is improved.

  Further, since the power supply line is unnecessary and the degree of freedom of the installation position is large, when the self-excited power supply device 5 or the self-excited light-emitting device 4 is installed, the influence on the mechanism and wiring of the induction heating device 1 is affected. As a result, the design and manufacturing processes related to the equipment are simplified compared to the conventional case. Therefore, the manufacturing cost can be reduced.

  As described above, since the self-excited power supply device 5 and the self-excited light-emitting device 4 have a large degree of freedom in installation position, they may be configured to be movable or removable. Since the user can install and remove the self-excited power supply device 5 or the self-excited light-emitting device 4 according to the use situation or preference, the convenience of the user to the self-excited power supply device 5 or the self-excited light-emitting device 4 Will improve. For example, when the self-excited light emitting device 4 is used as an operation display device of an electromagnetic cooker, the operation display device can be arranged at a position that is easy for the user to see.

  The configuration of the controller 11 and the light source 12 (12a to 12c) illustrated in FIG. 2 or FIG. 3 is an example, and the present invention is not limited to such a configuration. The controller 11 may be of any configuration that can control the lighting of the light source 12, and the number of the light sources 12 may be one or more. The controller 11 may set the lighting control of the light source 12 to blink control.

  Further, the self-excited light emitting device 4 may include a voltage determination circuit 15 that determines a power supply voltage level to the controller 11. At this time, the controller 11 gives a width to the operating voltage range. FIG. 4 shows an example of the self-excited light emitting device 4 provided with the voltage discrimination circuit 15. In FIG. 4, the power supply for operation of the voltage determination circuit 15 and the input of the voltage signal to be determined are shown schematically by one line.

  The voltage determination circuit 15 outputs the determined voltage level to the controller 11. The controller 11 performs lighting control for the light source 12 such as increasing or decreasing the number of lighting of the plurality of light sources 12 according to the determined voltage level.

  The voltage determination circuit 15 can be configured by a conversion circuit such as an A / D converter (ADC (Analog-Digital Converter)) or a comparator, and a constant voltage circuit such as a Zener diode or a shunt regulator. By configuring in this way, the user can easily visually recognize the intensity of heating of the induction heating device 1 through the strength of the leakage magnetic flux 3, for example. The controller 11 shown in FIG. 2 may be considered to include a voltage determination circuit 15.

  FIG. 5 shows a specific example of the voltage discrimination circuit 15 using the ADC 150. The voltage determination circuit 15 shown in FIG. 5 includes an ADC 150 and resistors 151a and 151b connected in series to connect the output terminal of the self-excited power feeding device 5 and the ground. The determination target voltage signal is extracted from between the resistors 151 a and 151 b and input to the ADC 150. The voltage signal for the operation of the ADC 150 is extracted from between the resistor 16 and the Zener diode 17 connected in series, which connects the output terminal of the self-excited power feeding device 5 and the ground, and is fed to the ADC 150, for example.

  The controller 11 at this time is composed of, for example, a microcomputer, and calculates the output voltage level of the self-excited power feeding device 5 from the voltage level obtained by the ADC 150 and the resistors 151a and 151b. In addition, it is good also as the voltage determination circuit 15 including the process so far in the controller 11. FIG. The controller 11 performs light emission control of the light source 12 based on the calculated voltage level.

  In FIG. 5, the ADC 150 is a component different from the controller 11, but may be built in the controller 11. When the controller 11 is composed of a microcomputer, an ADC built in the microcomputer can be used as the ADC 150.

  In FIG. 5, the power supply is individually supplied to the ADC 150 and the controller 11, but a common power supply may be used. In particular, when the built-in ADC of the controller 11 is used as the ADC 150, it is convenient to use common power supply.

  FIG. 6 shows another specific example of the voltage determination circuit 15. The voltage determination circuit 15 illustrated in FIG. 6 includes comparators 152a to 152c. The number of comparators is determined according to the number of voltage levels to be determined. In the example of FIG. 6, since the number of voltage levels to be determined is set to 3 in correspondence with the configuration of the light source 12 by three LEDs, the voltage determination circuit 15 is configured by three comparators 152a to 152c. ing. Each of the comparators 152 a to 152 c receives a reference voltage corresponding to each of the comparators 152 a to 152 c and also receives a voltage signal corresponding to the output voltage of the self-excited power supply device 5. The comparators 152 a to 152 c compare the input output voltage of the self-excited power feeding device 5 with each reference voltage, and output 0 or 1 to the controller 11 according to the magnitude relationship. The controller 11 grasps the output voltage level of the self-excited power feeding device 5 from the 0 or 1 output obtained from the comparators 152a to 152c, and controls the lighting of the light source 12, that is, the three LEDs.

  In FIG. 6, power supply to the comparators 152a to 152c is the same as that in FIG. That is, the output terminal of the self-excited power feeding device 5 is connected to the ground through the resistor 16 and the Zener diode 17 connected in series with each other, and a voltage signal is taken out between the resistor 16 and the Zener diode 17 to compare the comparators 152a to 152a. Power is supplied to 152c.

  The input of the reference voltage signal to the comparators 152a to 152c is as follows. The output terminal of the self-excited power feeding device 5 is connected to the ground via a resistor 153 and a Zener diode 154 connected in series. At this time, the Zener diode 154 is connected to the ground side. Further, the point between the resistor 153 and the Zener diode 154 and the ground are connected by resistors 155a, 155b, and 155c connected in series.

  A voltage signal is extracted and input from between the resistor 153 and the Zener diode 154 to the input terminal of the reference voltage signal of the comparator 152a. A voltage signal is extracted from between the resistors 155a and 155b and input to the input terminal of the reference voltage signal of the comparator 152b. A voltage signal is extracted and input from between the resistors 155b and 155c to the input terminal of the reference voltage signal of the comparator 152c. Therefore, the magnitude of the reference voltage input to the comparators 152a to 152c is: comparator 152a> comparator 152b> comparator 152c.

  The input of the discrimination target voltage signal to the comparators 152a to 152c is as follows. The output terminal of the self-excited power feeding device 5 is connected to the ground via resistors 151a and 151b connected in series. A voltage signal is extracted and input from between the resistors 151a and 151b to the input terminals of the discrimination target voltage signals of the comparators 152a to 152c. Since this voltage is different from the output voltage of the self-excited power supply device 5, the output voltage level of the self-excited power supply device 5 can be determined by determining the reference voltage in consideration of the resistors 151a and 151b.

  For example, the comparators 152a to 152c output 1 when the voltage of the discrimination target voltage signal exceeds each reference voltage, and outputs 0 when the voltage does not exceed the reference voltage. Therefore, when the voltage level of the discrimination target voltage signal is small, the outputs of the comparators 152a to 152c are all 0, and as the discrimination target voltage signal increases, the outputs of the comparators 152a to 152c are (0, 0, 1). ), (0, 1, 1), (1, 1, 1).

  The controller 11 inputs this output through, for example, a GPIO (General Purpose Input / Output) port. When the output is (0, 0, 0), for example, three LED light sources according to the output levels of the comparators 152a to 152c. All 12 are not lit, 1 is (0, 0, 1), 2 is (0, 1, 1), and 3 is (1, 1, 1). Take control.

  The controller 11 may perform lighting control such that the blinking cycle of the light source 12 is changed according to the voltage level determined by the voltage determination circuit 15. At this time, the number of the light sources 12 is not necessarily plural, and may be one. The blinking period can be changed by, for example, configuring the controller 11 with a microcomputer and using a built-in timer to change the set value of the timer according to the voltage level. You may perform lighting control of changing the lighting number of the several light sources 12 according to a voltage level, and the blinking period of the light source which lighted.

  As described above, the self-excited light-emitting device 4 can control the lighting of the light source 12 in accordance with the output voltage level of the self-excited power supply device 5 by introducing the voltage discrimination circuit 15, so that an induction heating device such as an electromagnetic cooker is used. It can be used as an operation display device that displays the operation state of one heating coil 2 and has a high degree of freedom in the installation position and does not require a feeder line.

  In the self-excited light emitting device 4, a high-side switch circuit may be provided between the self-excited power supply device 5 and the controller 11. The high-side switch circuit is in an open state when the output voltage of the rectifier circuit 10 is equal to or lower than a predetermined voltage level, and is closed when it is equal to or higher than a predetermined voltage level. Accordingly, no voltage is applied to the controller 11 (and the light source 12 via the controller 11) until the output voltage of the self-excited power supply device 5 becomes equal to or higher than a predetermined voltage.

  FIG. 7 shows an example of a self-excited light emitting device provided with a high-side switch circuit. In the high-side switch circuit 18 shown in FIG. 7, a P-channel MOS FET (Metal-Oxide-Semiconductor Field-Effect Transistor) 180 is used, the source of the P-channel MOS FET 180 is at the output terminal of the self-excited power supply device 5, and the drain is The gate of the controller 11 is connected to the ground of the self-excited light emitting device 4 through a resistor 182. A resistor 181 is connected between the source and the gate.

  In the high-side switch circuit 18 configured as described above, the voltage between the source and the gate changes according to the output voltage of the self-excited power feeding device 5, and the source / drain until the output voltage of the self-excited power feeding device 5 exceeds a predetermined value. The controller 11 is in an open state, and the controller 11 is not supplied with power from the self-excited power supply device 5 and does not operate. When the predetermined value is exceeded, the source / drain space is closed, and the controller 11 is powered by the self-excited power feeding device 5 and operates.

  That is, due to the installation of the high-side switch circuit 18, the controller 11 causes the output of the self-excited power supply device 5 to become a predetermined voltage or higher, that is, the output of the rectifier circuit 10 of the self-excited power supply device 5 becomes a predetermined voltage or higher. Power is supplied after charging. Since the operation of the controller 11 becomes unstable when the power supply voltage is smaller than the operating voltage, the high side switch circuit 18 has an effect of stabilizing the operation of the controller 11.

  In addition, when the load power (power consumption of the light source device 6 in this example) is larger than the power fed from the self-excited power feeding device 5, the capacitor 102 of the rectifier circuit 10 is installed by installing the high side switch circuit 18. By charging (with n stages) over a predetermined time, the rectifier circuit 10 can output a voltage exceeding the operating voltage of the light source device 6 for a short time. Therefore, the light source device 6 can be operated intermittently by installing the high-side switch circuit 18.

  Although FIG. 7 shows an example in which the high-side switch circuit 18 is configured using the P-channel MOS FET 180, it may be an N-channel MOS FET or a normal FET instead of the MOS FET.

  The detection coil 7 of the self-excited power feeding device 5 may be detachable. If the detection coil 7 of the self-excited power feeding device 5 can be selected from coils of various inductances, the resonance frequency of the resonance circuit 9 can be changed.

  Further, the resonant capacitor 8 of the self-excited power feeding device 5 may be a variable capacitor. The resonance frequency of the resonance circuit 9 can also be changed by changing the capacitance value of the variable capacitor.

  Even when the application target is changed and the frequency of the leakage magnetic flux 3 is changed by at least one of the replacement by attaching and detaching the detection coil 7 and the adjustment of the capacitance value of the variable capacitor, the detection coil 7 and the resonance capacitor 8 are changed. The resonance frequency of the resonance circuit 9 configured as follows can be easily matched to the frequency of the leakage magnetic flux 3. Therefore, the application range of the self-excited power supply device 5 and the self-excited light-emitting device 4 can be expanded.

Embodiment 2. FIG.
The self-excited sterilization apparatus 4a according to Embodiment 2 of the present invention is obtained by replacing the light source 12 of the self-excited light-emitting apparatus 4 described in Embodiment 1 with an ultraviolet light source (for example, an ultraviolet LED) 12v that generates ultraviolet light.

  Ultraviolet light is light having a wavelength of 400 nm or less, and ultraviolet light having a wavelength in the vicinity of the peak region (265 nm, 185 nm) of a DNA (Deoxyribonucleic acid) absorption spectrum has a particularly high bactericidal effect and is used for sterilization.

  FIG. 8 shows a configuration example of the self-excited sterilization apparatus. A self-excited sterilization apparatus 4a shown in FIG. 8 is obtained by replacing the light source 12 of the self-excited light source apparatus 4 shown in FIG. 3 with an ultraviolet LED 12v. FIG. 8 shows, together with the self-excited sterilization apparatus 4a, a sterilization target 20 that is irradiated with the ultraviolet light 120 generated by the ultraviolet LED 12v, and a target storage unit 19 that stores the sterilization target 20.

  Examples of the ultraviolet LED 12v include InAlGaN quaternary mixed crystals and InGaN / GaN / AlGaN.

  The object storage unit 19 prevents leakage of the ultraviolet light 120 to the general environment when the sterilization target object 20 is irradiated with the ultraviolet light 120, and stores or removes the sterilization target object 20 when it is a fluid such as a liquid. It is used for the purpose of holding the bacteria target 20 or the like.

  The operation of the self-excited sterilization apparatus 4a shown in FIG. 8 will be described. The operation up to the emission of the ultraviolet LED 12v is as described in the first embodiment. The sterilization target 20 is stored in the target storage unit 19, and the ultraviolet light 120 generated by the ultraviolet LED 12v is stored in the inner wall surface of the target storage unit 19 and the target storage unit 19 of the sterilization target 20. And the irradiated surface is sterilized.

  The self-excited sterilization apparatus 4a may include an object storage unit 19 in addition to the self-excited power supply apparatus 5 and the light emitting apparatus 6 including the ultraviolet LED 12v.

  The self-excited sterilization apparatus 4a can be combined with an electromagnetic cooker that is a kind of the induction heating apparatus 1. Since the electromagnetic cooker handles food, it is convenient if various parts can be sterilized. An example in which the self-excited sterilization apparatus 4a is applied to an electromagnetic rice cooker that is an electromagnetic cooker is shown in FIGS.

  FIG. 9 shows an example in which a self-excited sterilizer is installed in a water storage tank of an electromagnetic rice cooker. Fig.9 (a) shows the perspective view of the electromagnetic rice cooker containing a water storage tank. The electromagnetic rice cooker 30 includes a water storage tank 40, and collects steam generated when cooking rice in the water storage tank 40 as stored water. The water storage tank 40 has a detachable structure. In order to show the rough arrangement relationship of the heating coil 2 incorporated in the electromagnetic rice cooker 30, the heating coil 2 is schematically shown by a solid line. The water storage tank 40 is indicated by a broken line. FIG.9 (b) is a perspective view which shows the example of the self-excitation type | mold sanitization apparatus installed in the water storage tank of the electromagnetic rice cooker. A perspective view is used for convenience of understanding. The self-excited sterilization apparatus 4 a is arranged outside the water storage tank 40 except for the ultraviolet LED 12 v, and the ultraviolet LED 12 v is installed in the water storage tank 40. FIG.9 (c) is a figure equivalent to the front view and side view of a water storage tank which installed the self-excited sterilization apparatus shown in FIG.9 (b). The figure on the left side of FIG. 9 (c) is a figure corresponding to the front view, and the water tank 40 to which the self-excited sterilization apparatus 4a is applied is viewed from the direction of arrow A in FIG. In the figure corresponding to the figure, the water storage tank 40 in which the self-excited sterilization apparatus 4a is installed is viewed from the direction of the arrow B in FIG. The electromagnetic rice cooker 30 and the built-in heating coil 2 are indicated by broken lines.

  In this example, the electromagnetic rice cooker 30 is stored in the water storage tank 40 by the induction heating device 1, the water storage tank 40 is stored in the object storage unit 19, and the sterilization target 20 is stored in the water storage tank 40 by steam collected during rice cooking. It corresponds to 41. The arrangement position of the ultraviolet LED 12v in the storage tank 40 may be anywhere as long as the ultraviolet light 120 can be irradiated to the stored water 41. FIG. 9 shows an example of arrangement on the bottom surface of the water storage tank 40. Since the heating coil 2 is disposed in the vicinity of the bottom surface of the electromagnetic rice cooker 30, in order to dispose the detection coil 7 so as to interlink with the leakage magnetic flux 3, the self-excited sterilization device and the ultraviolet LED 12v are disposed on the bottom surface. The arrangement is convenient.

  The operation of the self-excited sterilization apparatus 4a shown in FIG. 9 will be described. When the electromagnetic rice cooker 30 is operated, a magnetic flux for heating the pot from the heating coil 2 is generated. As shown in FIG. 9B, the leakage magnetic flux 3 from the heating coil 2 causes the ultraviolet LED 12v to emit light, as in FIG. 3 of the first embodiment (assuming that the light source 12 is replaced with the ultraviolet LED 12v). Ultraviolet light 120 is emitted. The stored water 41 stored in the water storage tank 40 by the recovered steam and the inner wall surface of the water storage tank are irradiated with ultraviolet rays 120 to be sterilized. By sterilizing the stored water 41 and the water storage tank 40, mold and bad odor in the water storage tank 14 are prevented.

  FIG. 10 shows an example of a self-excited sterilization apparatus installed in a rice paddle receiver of an electromagnetic rice cooker. In the example shown in FIG. 10, the electromagnetic rice cooker 30 is separately provided with a rice paddle receiver 50 in the vicinity thereof. The rice paddle receiver 50 has an opening 51 through which the rice paddle 52 can be inserted. The self-excited sterilization apparatus 4 a is installed outside or inside the rice paddle receiver 50 except for the ultraviolet LED 12 v, and the ultraviolet LED 12 v is installed inside the rice paddle receiver 50.

  The operation of the self-excited sterilization apparatus 4a shown in FIG. 10 is the same as the operation of the self-excited sterilization apparatus 4a shown in FIG. The difference is that the sterilization target 20 is not the stored water 41 but the rice scoop 52, and the fact that the sterilization target 20 is different makes the target object storage unit 19 not the water storage tank 40 but the rice scoop receiver 50. is there.

  Since the rice paddle 52 does not transmit the ultraviolet ray 120, in order to sterilize both sides, the ultraviolet ray 120 must be irradiated on each side. Therefore, in FIG. 10, two ultraviolet LEDs 12v are installed and arranged so that each surface of the paddle 52 is irradiated with the ultraviolet rays 120. The two ultraviolet LEDs 12v may be installed not on the bottom surface but on the side surface of the scoop holder 50 facing each surface of the scoop 52. Further, even if one ultraviolet LED 12v is used, the inner wall surface of the rice paddle receiver 50 is covered with an ultraviolet reflector, and both sides of the rice paddle 52 inserted into the rice paddle receiver 50 are sterilized by the ultraviolet light 120 reflected by the inner wall surface. good.

  FIG. 8 shows an example in which the portion held by the hand of the rice paddle 52 is to be sterilized, but the portion of the rice paddle 52 that is turned upside down may be stored in the rice paddle receiver 50 and sterilized. . Further, the opening 51 of the rice paddle receiver 50 may be provided on the side surface, and the rice paddle 52 may be inserted into the rice paddle receiver 50 from the side surface direction for sterilization. The entire rice paddle 52 may be inserted for sterilization.

  The rice paddle 52 is an item that is always used when the electromagnetic rice cooker 30 is used, and sterilization of a portion gripped by hand or a portion pretending to have rice is highly effective in terms of hygiene.

  The self-excited sterilization apparatus 4a is not limited to the example shown in FIG. Any light source device 6 including the ultraviolet light source 12v that receives the power supply from the self-excited power supply device 5 described in the first embodiment and generates the ultraviolet light 120 may be used.

  Since the ultraviolet light source 12a of the self-excited sterilization apparatus 4a according to the second embodiment is supplied with power from the self-excited power supply apparatus 5 described in the first embodiment and generates ultraviolet light 120, from the main body of the induction heating apparatus 1 such as an electromagnetic cooker. Not only is the wiring for power supply to the self-excited sterilizer 4a unnecessary, but also the position between the heating coil 2 and the pot in the induction heating device 1 or in the vicinity of the heating coil 2 for the generation of the ultraviolet rays 120. Thus, it is not necessary to install the detection coil 7 at a very limited position, and the operating voltage of the self-excited sterilization apparatus 4a can be supplied by the weak leakage magnetic flux 3 around the heating coil 2.

  Therefore, the self-excited sterilization apparatus 4 a can be installed at a free position with respect to the induction heating apparatus 1 without depending on the mechanism of the induction heating apparatus 1. Moreover, the function of the induction heating apparatus 1 is improved by being able to install the self-excited sterilization apparatus 4a at an optimum position with respect to the induction heating apparatus 1 without depending on the mechanism of the induction heating apparatus 1. Further, when the self-excited sterilization apparatus 4a is applied to the induction heating apparatus 1, since the influence on the mechanism of the induction heating apparatus 1 and its internal wiring is small, it is possible to reduce the cost associated with the application.

  Moreover, since the self-excited sterilization apparatus 4a does not require an external power supply line and has a high degree of freedom in the installation position, it can be a sterilization apparatus that can be moved and removed according to the state of use. Thereby, the convenience of the self-excited sterilization apparatus 4a for the user is improved. When the self-excited sterilizer 4a is installed in the form shown in FIG. 9 or FIG. 10, it is necessary to move the water storage tank 40 and the rice paddle receiver 50. It is important that it is possible.

  The voltage discriminating circuit 15 shown in FIGS. 4, 5, and 6 and the high-side switch circuit 18 shown in FIG. 7 can be installed in the self-excited sterilization apparatus 4a as in the first embodiment. With each installation, the self-excited sterilization apparatus 4a can achieve the same effects as those described in the corresponding part of the first embodiment.

  The self-excited sterilization apparatus 4 a needs to use an ultraviolet light source 12 v as the light source 12. When the light source is an LED, since the ultraviolet LED 12v consumes more power than a normal LED, the effect when the high-side switch circuit 18 is used in the self-excited sterilization apparatus 4a becomes more remarkable.

  In the case of the self-excited sterilization apparatus 4 a shown in FIG. 8, the high-side switch circuit 18 may be installed at one of the two feeding points to the controller 11.

  In the above description, the induction heating device 1 is illustrated as a magnetic field source that generates the leakage magnetic flux 3, but a leakage magnetic field from a microwave heating device such as a microwave oven may be used in addition to the induction heating device 1.

  In addition, the light emitting device 6 has been exemplified as the power supply destination from the self-excited power feeding device 5, but in addition to the light emitting device 6, a sounding device that notifies the operation state of a device that generates a leakage magnetic field with a sound such as a buzzer, and a leakage magnetic field. A self-excited ringing device, a self-excited communication device, and a self-excited display device in combination with a communication device that transmits the operating state of the generated device to other devices by communication and a display device that displays the operating state of the device that generates a leakage magnetic field. Can be used as etc. Furthermore, the self-excited power supply device 5 can also be used as a charging device that charges a device that generates a leakage magnetic field or a built-in battery of another device.

1 Induction heating device (electromagnetic cooker)
2 Heating coil 3 Leakage magnetic flux 4 Self-excited light-emitting device 4a Self-excited sterilizer 5 Self-excited power supply device 6 Light-emitting device 7 Detection coil 8 Resonant capacitor 9 Resonant circuit 10 Rectifier circuit 11 Controller 12, 12a-12c Light source (LED)
12v UV light source (UV LED)
13 Zener diode 14 Resistor 15 Voltage discriminating circuit 16 Resistor 17 Zener diode 18 High-side switch circuit 19 Object storage part 20 Sterilization object 30 Electromagnetic rice cooker 40 Water storage tank 41 Water storage 50 Rice scoop receptacle 51 Opening 52 Rice scoop 100a to 100d Input capacitors 101a to 101d Schottky barrier diodes 102a to 102d Output capacitor 103 Multiple voltage rectifier circuit 104 Resistors 110a to 110c Resistors 111a to 111c Zener diode 112 Base controller 113 Transistor 120 Ultraviolet light 150 ADC
151a, 151b Resistors 152a to 152c Comparator 153 Resistor 154 Zener diodes 155a to 155c Resistor 180 P-channel MOS FET
181 Resistance 182 Resistance

Claims (13)

A self-excited power feeding device that operates in a leakage AC magnetic field environment of a predetermined frequency;
A light source that receives power from the self-excited power feeding device and emits light;
A controller for controlling lighting of the light source;
A switch circuit disposed between the self-excited power feeding device and the controller,
The self-excited power supply device is
A detection coil arranged to interlink with the leakage alternating magnetic field;
A resonant capacitor connected in parallel to the detection coil to resonate an alternating voltage induced in the detection coil by the leakage alternating magnetic field at the predetermined frequency;
A rectifier circuit that resonates and amplifies the AC voltage amplified by the resonance circuit without power supply from the outside, converts the voltage into a DC voltage, and outputs the DC voltage to the controller.
An output capacitor is connected to the output terminal of the rectifier circuit,
The switch circuit is opened when the output of the rectifier circuit is less than or equal to a predetermined voltage value, disconnects the controller and the rectifier circuit, the output capacitor is charged, and the output of the rectifier circuit is a predetermined voltage value When it exceeds, it becomes a closed state and connects the controller and the rectifier circuit,
The controller receives power from the self-excited power supply device when the switch circuit is in a closed state and controls lighting of the light source;
A self-excited light-emitting device. The light source is an LED.
The self-excited light-emitting device according to claim 1 . It operates by receiving power from the self-excited power supply device, and includes a voltage determination circuit that determines the level of the received voltage,
The controller performs control to change the lighting state of the light source according to the voltage level determined by the voltage determination circuit.
The self-excited light-emitting device according to claim 1 or 2 . The leakage AC magnetic field is a leakage magnetic field from an induction heating device,
The self-excited light emitting device is an operation display device for displaying the operation of the induction heating device.
The self-excited light emitting device according to any one of claims 1 to 3 . The rectifier circuit includes a multiple voltage rectifier circuit as a part for boosting the alternating voltage,
The self-excited light emitting device according to any one of claims 1 to 4 . The diode constituting the multiple voltage rectifier circuit is a Schottky barrier diode.
The self-excited light emitting device according to claim 5 . The resonant capacitor is a variable capacitor.
The self-excited light - emitting device according to any one of claims 1 to 6 . The detection coil is replaceable.
The self-excited light - emitting device according to any one of claims 1 to 7 . A self-excited power feeding device that operates in a leakage AC magnetic field environment of a predetermined frequency;
A light source that receives power from the self-excited power feeding device and emits ultraviolet light;
A controller for controlling lighting of the light source;
A switch circuit disposed between the self-excited power feeding device and the controller,
The self-excited power supply device is
A detection coil arranged to interlink with the leakage alternating magnetic field;
A resonant capacitor connected in parallel to the detection coil to resonate an alternating voltage induced in the detection coil by the leakage alternating magnetic field at the predetermined frequency;
A rectifier circuit that resonates and amplifies the AC voltage amplified by the resonance circuit without power supply from the outside, converts the voltage into a DC voltage, and outputs the DC voltage to the controller.
An output capacitor is connected to the output terminal of the rectifier circuit,
The switch circuit is opened when the output of the rectifier circuit is less than or equal to a predetermined voltage value, disconnects the controller and the rectifier circuit, the output capacitor is charged, and the output of the rectifier circuit is a predetermined voltage value When it exceeds, it becomes a closed state and connects the controller and the rectifier circuit,
The controller receives power from the self-excited power supply device when the switch circuit is in a closed state and controls lighting of the light source;
A self-exciting sterilization apparatus characterized by that.   The light source is an ultraviolet LED.
  The self-excited sterilization apparatus according to claim 9. It has an object storage unit that can store sterilized objects,
The light source is installed at a position where the sterilization target stored in the target storage unit can be irradiated with ultraviolet rays from the light source.
The self-excited sterilization apparatus according to claim 9 or 10 . The leakage AC magnetic field is a leakage magnetic field from an electromagnetic rice cooker,
The sterilization object is water generated by collecting steam generated during rice cooking in the electromagnetic rice cooker,
The object storage unit is a water storage tank that can store the generated water as stored water,
The light source is disposed at a position in the object storage unit where the stored water can be irradiated with ultraviolet rays.
The self-excited sterilization apparatus according to claim 11 . The leakage AC magnetic field is a leakage magnetic field from an electromagnetic rice cooker,
The sterilization object is rice scoop used in the electromagnetic rice cooker,
The object storage unit is a rice paddle receiver that can store the rice paddle,
The light source is disposed at a position in the rice paddle receiver that can irradiate ultraviolet light on the rice paddle stored in the rice paddle receiver.
The self-excited sterilization apparatus according to claim 11 .

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