JP4155178B2 - rice cooker - Google Patents

Description

  The present invention relates to an induction heating rice cooker used for home use and business use.

  In a conventional induction heating rice cooker, an example in which an induction heating device (see, for example, Patent Document 1) for reducing a leakage magnetic field from a heating coil will be described. FIG. 9 shows a conventional induction heating apparatus in which the leakage magnetic field of the heating coil is reduced. In this conventional example, an electromagnetic shield ring 2 is arranged on the outer peripheral portion of the heating coil 1 to constitute an induction heating device. In the induction heating apparatus having this configuration, an induction current flows through the electromagnetic shield ring 2 by being induced by the high-frequency magnetic field generated in the heating coil 1, and further, the induction current causes a high-frequency magnetic field generated from the heating coil 1 to be generated in the electromagnetic shield ring 2. Produces a reverse high-frequency magnetic field.

  As a result, the high-frequency magnetic field generated from the electromagnetic shield ring 2 acts so as to cancel the high-frequency magnetic field generated at the outer periphery of the heating coil 1, so that the high-frequency leakage magnetic field of 20 kHz to 50 kHz leaking from the heating coil 1 is reduced. The electromagnetic shield ring 2 is known to have an aluminum plate, a lead wire or the like made into a ring.

  Further, another induction heating device (see, for example, Patent Document 2) that reduces the leakage magnetic field generated from the heating coil will be described. FIG. 10 shows a conventional induction heating apparatus with a reduced leakage magnetic field. The inductor 5 is configured by winding around the outer periphery of the heating coil 1 and arranged in a direction in which components of the high-frequency magnetic field generated by the heating coil 1 and the high-frequency magnetic field generated by the inductor 5 cancel each other.

  FIG. 11 shows a circuit example of a conventional induction heating apparatus. The induction heating apparatus of FIG. 11 includes a power supply unit 3 configured by a commercial power supply, a high-frequency oscillation unit 11 that converts power from the power supply unit 3 into high-frequency power, and a heating coil 1 that converts power from the high-frequency oscillation unit 11 into a high-frequency magnetic field. And an inner pot 15 that generates heat upon receiving a magnetic field from the heating coil 1.

The high-frequency oscillating unit 11 includes a rectifier 4 that rectifies commercial power, an inductor 5 that smoothes the output of the rectifier 4, a semiconductor capacitor 8 that controls power supply to the smoothing capacitor 6, and the heating coil 1, and a semiconductor switch 8. The resonance capacitor 7 smoothes the switching operation. In the conventional example of FIG. 11, the inductor 5 is composed only of windings, and the core material of the inductor 5 is not required, so that the device can be miniaturized and the high frequency noise can be reduced.

  However, in the induction heating apparatus in which the leakage magnetic field from the conventional heating coil as shown in FIG. 9 is reduced, the high-frequency leakage magnetic field can be reduced by the effect of the electromagnetic shield ring 2 but is generated from the heating coil 1. A magnetic field having a power frequency or twice the frequency of the power source (hereinafter referred to as a low-frequency magnetic field) is hardly absorbed by the inner pot 15, and the electromagnetic shield ring 2 cannot sufficiently generate a reverse magnetic field. The magnetic field is released outside without decreasing.

  Further, in the conventional induction heating apparatus of FIG. 10, since the winding is operated as an inductance (about several hundred μH), the number of winding turns increases. At this time, the low-frequency magnetic field emitted from the winding becomes larger than the low-frequency magnetic field emitted from the heating coil, resulting in an increase in the low-frequency magnetic field emitted to the outside.

  These conventional induction heating devices aim to cancel the high-frequency magnetic field, and the winding for reducing the leakage magnetic field is limited to the vicinity of the heating coil and has no freedom of arrangement, and is further arranged in the vicinity of the heating coil. Thus, the magnetic field distribution on a heated object such as a pan changes, and particularly in the case of a rice cooker, there arises a problem of greatly affecting the rice cooking performance.

As described above, the conventional induction heating apparatus reduces the high-frequency leakage magnetic field, and has not paid attention to the reduction of the low-frequency leakage magnetic field. By reducing this low-frequency leakage magnetic field, it is possible to remove the anxiety of the device user about the influence of the low-frequency magnetic field on the human body, which is not clear in the causal relationship but is concerned in some investigations. It is also possible to eliminate the risk of malfunction of electronic devices in the immediate vicinity.
JP-A-57-115795 Japanese Patent Publication No. 63-7672

  In view of the above problems of the background art, the problem to be solved by the present invention is to focus on the low-frequency leakage magnetic field that has not been recognized by the conventional induction heating rice cooker, and the low-frequency magnetic field is heated. Reduces unnecessary electromagnetic waves generated from the equipment by reducing the radiation from the coil, and improves the rice cooking performance by taking measures against low-frequency leakage magnetic fields without significantly changing the magnetic field distribution of conventional induction heating rice cookers An object of the present invention is to provide a rice cooker that can take measures against a leakage magnetic field at a low frequency without adverse effects.

In order to solve the above problems, the present invention provides an inner pot, an inner frame for holding the inner pot, a bottom surface heating coil that is disposed on the outer surface of the inner frame and induction-heats the bottom of the inner pot, Arranged on the outer surface of the frame, the side heating coil that induction-heats the side surface of the inner frame, and connected to the power supply unit to rectify the power of the commercial frequency and convert it into power with a low frequency component of twice the commercial frequency Rectifying means, a series connection circuit of an inductor and a smoothing capacitor connected in series with the rectifying means, and converting the power having the low frequency component into high frequency power to the bottom surface heating coil and the side surface heating coil. and a high-frequency oscillation section for supplying a high-frequency current low frequency component and high frequency component is superimposed, the wire of the series connection circuit low-frequency current flows having the low frequency component is in the high frequency oscillation portion, generated from the wiring A low-frequency magnetic field canceling means configured to be wound a plurality of times so that the low-frequency magnetic field generated by the heating coil and the low-frequency magnetic field generated by the heating coil cancel each other, and the low-frequency canceling means contributes to induction heating. In order to reduce the influence on the rice cooker, the rice cooker is arranged on the side surface of the inner frame and above the side surface heating coil.

  As a result, the magnetic field generated from the low-frequency magnetic field canceling means arranged in the high-frequency oscillating unit so that the current flows in the opposite direction to the side heating coil with the same frequency component as the low frequency component of the current flowing in the side heating coil is reduced. The leakage magnetic field from the side heating coil that generates a lot of leakage magnetic field cancels each other to greatly reduce the low frequency leakage magnetic field, and the low frequency magnetic field cancellation means is arranged on the side surface of the inner frame, thereby heating the bottom surface and the side surface. Since the distance from the coil can be taken, the influence on the high frequency magnetic field used for induction heating can be reduced, and the influence on the rice cooking performance can be suppressed.

  The rice cooker of this invention can suppress the influence on rice cooking performance, and can reduce the low frequency leakage magnetic field which generate | occur | produces from a heating coil.

1st invention is arrange | positioned on the outer surface of the inner pot, the inner frame holding the said inner pot, the bottom surface heating coil which arrange | positions on the outer surface of the said inner frame, and induction-heats the bottom part of the said inner pot, and the said inner frame A side heating coil that induction-heats the side of the inner frame, and a rectifying unit that is connected to the power supply unit to rectify the power of the commercial frequency and convert the power into a power having a low frequency component of twice the commercial frequency; A series connection circuit of an inductor and a smoothing capacitor connected in series with the rectifying means, and power having the low frequency component is converted into high frequency power, and the low frequency component and high frequency are applied to the bottom surface heating coil and the side surface heating coil. A high-frequency oscillating unit for supplying a high-frequency current with superimposed components, and a low-frequency magnetic field generated from the wiring by the wiring of the series connection circuit in which the low-frequency current having the low-frequency component flows in the high-frequency oscillating unit; Above The low-frequency magnetic field canceling means is constituted by winding a plurality of times so that the low-frequency magnetic field generated from the thermal coil is in a direction to cancel each other, and the low-frequency canceling means reduces the influence on the high-frequency magnetic field contributing to induction heating. Therefore, it is set as the rice cooker arrange | positioned above the said inner frame side surface and the said side surface heating coil.

  As a result, the magnetic field generated from the low-frequency magnetic field canceling means arranged in the high-frequency oscillating unit so that the current flows in the opposite direction to the side heating coil with the same frequency component as the low frequency component of the current flowing in the side heating coil is reduced. The leakage magnetic field from the side heating coil that generates a lot of leakage magnetic field cancels each other to greatly reduce the low frequency leakage magnetic field, and the low frequency magnetic field cancellation means is arranged on the side surface of the inner frame, thereby heating the bottom surface and the side surface. Since the distance from the coil can be taken, the influence on the high frequency magnetic field used for induction heating can be reduced, and the influence on the rice cooking performance can be suppressed.

  In the second invention, the low-frequency magnetic field generated from the low-frequency leakage magnetic field canceling means and the bottom heating coil are obtained by winding the wire constituting the bottom heating coil and the side heating coil of the first invention in the same direction. Since the low frequency leakage magnetic field generated from the side and the low frequency leakage magnetic field generated from the side surface heating coil cancel each other, more low frequency leakage magnetic fields can be reduced.

  According to a third aspect of the invention, in particular, the low frequency magnetic field canceling means of the first or second aspect of the invention is provided with a wire having the same frequency component as the low frequency component of the current flowing in the side surface heating coil in a plurality of annular shapes and the wires are arranged in cascade. Since the low frequency magnetic field canceling means can be formed into a cylindrical shape by being stacked on top of each other, it can be arranged simply by fitting into the outer periphery of the inner frame on the side surface of the rice cooker. Assembling workability at the time can be improved.

  The fourth invention is the low frequency magnetic field canceling means of the third invention in particular, the self-bonding wire is used as the constituent wire material, and the wirings stacked in a column in a ring are fused together to fix the shape. By doing so, since it is difficult for the shape to change during the work, the handling becomes easy and the assembling workability when taking countermeasures against the leakage magnetic field can be improved.

  According to a fifth aspect of the invention, in particular, the low-frequency magnetic field canceling means of the third or fourth aspect of the present invention is configured by using a wire formed by twisting a plurality of thin wires insulated from each other, thereby canceling the low-frequency magnetic field. Loss due to the skin effect of the electric wire due to the high-frequency component of the current flowing in the means can be suppressed, and heat generation as a countermeasure against leakage magnetic field is less and cooling arrangement can be facilitated.

  In the sixth aspect of the invention, the low frequency magnetic field canceling means according to any one of the third to fifth aspects is formed integrally with the inner frame, thereby improving workability and fixing the low frequency magnetic field canceling means. Since a fixing device for doing so is not required, the leakage magnetic field countermeasure can be made inexpensive.

  In a seventh aspect of the invention, in particular, in any one of the first to sixth aspects of the invention, the electromagnetic shield ring made of an annular conductor is located near the outer periphery of the side surface heating coil and more than the center position of the low-frequency magnetic field canceling means. By adopting a configuration in which the center position of the electromagnetic seal ring is disposed below, it is possible to adopt a configuration that can reduce both the low-frequency magnetic field and the high-frequency magnetic field.

  In an eighth aspect of the invention, in particular, in any one of the first to fifth aspects of the invention, an electromagnetic shield ring made of an annular conductor is disposed in the vicinity of the outer periphery of the side surface heating coil, and the outer periphery of the electromagnetic shield ring is arranged. Since the low frequency magnetic field canceling means is arranged, low frequency and high frequency leakage magnetic field reduction measures can be incorporated simply by determining the position of the electromagnetic shield ring. In addition, the assembly workability when taking countermeasures against leakage magnetic fields can be improved.

  In the ninth aspect of the invention, the low frequency magnetic field canceling means can be directly wound around the electromagnetic shield ring by providing the electromagnetic shield ring of the eighth invention with an uneven portion for determining the position of the low frequency magnetic field canceling means. Therefore, a leakage magnetic field countermeasure can be easily taken without using a jig for making the low frequency magnetic field canceling means annular.

  In the tenth aspect of the invention, the low frequency magnetic field low canceling means can be easily arranged on the annular ring by providing the supporting means for supporting the low frequency magnetic field canceling means in the electromagnetic shield ring of the ninth invention. The leakage magnetic field countermeasure can be made inexpensive.

  Since the object of the present invention can be achieved by using the first to tenth aspects of the present invention as the main part of the embodiments, details of the embodiments corresponding to the respective claims will be described below with reference to the drawings. It will be described and the best mode for carrying out the present invention will be described. The present invention is not limited to the present embodiment. Further, in the description of the present embodiment, the same reference numerals are given to the same configurations and the effects and the same description is not repeated.

(Embodiment 1)
FIG. 1 shows a configuration diagram of a rice cooker according to Embodiment 1 of the present invention. In FIG. 1, a power supply unit 3 including a commercial power supply is connected to a high-frequency oscillation unit 11, and the high-frequency oscillation unit 11 is connected to a bottom surface heating coil 1a and a side surface heating coil 1b. The bottom surface heating coil 1 a and the side surface heating coil 1 b are disposed on the bottom surface and the side surface of the inner frame 16, and are installed so as to be magnetically coupled to the inner pot 15 that is an inner pot placed on the upper surface of the inner frame 16.

Under the bottom heating coil 1a and the side heating coil 1b, a magnetic shield ferrite 13 that enhances magnetic coupling with the inner pot 15 is disposed. The high-frequency oscillation unit 11 includes a rectifying unit 4 connected to the power source unit 3, a series connection circuit of an inductor 5 and a smoothing capacitor 6 connected in series with the rectifying unit 4, and a resonance connected in parallel to the smoothing capacitor 6. The resonant capacitor 7 is connected in parallel with the bottom surface heating coil 1a and the side surface heating coil 1b.

  The bottom surface heating coil 1a and the side surface heating coil 1b are connected in series when simultaneous energization is performed (hereinafter referred to as the heating coil 1), and the bottom surface heating coil 1a and the side surface heating coil 1b are wound in the same direction. desirable. On the other hand, the wiring of the inductor 5 is wound a plurality of times near the center of the side surface of the inner pot near the center of the side surface of the inner pot, opposite to the winding direction of the side surface heating coil 1b, thereby constituting the low-frequency magnetic field canceling means 12.

  In this embodiment, a general circuit configuration used for the induction heating apparatus is shown, but there is no particular limitation as long as the circuit configuration is such that a low-frequency magnetic field component is superimposed on the heating coil 1.

About the rice cooker comprised as mentioned above, the operation | movement and an effect | action are demonstrated below. FIG. 2 is a diagram showing a current path in each section of the inverter circuit. I ₃ is an input current, I ₅ is a current flowing through the inductor 5 and the low-frequency magnetic field canceling means 12, and I ₁ is a current flowing through the heating coil 1. The power supply unit 3 is composed of a commercial power source or the like, and supplies commercial frequency power to the high-frequency oscillation unit 11.

Therefore, the input current I ₃ will current having a commercial frequency component. In the high frequency oscillating unit 11, commercial power is rectified by the rectifying means 4 to be converted into power having a frequency component twice that of the commercial power supply, and further converted to high frequency power of about 20 kHz to 50 kHz using the semiconductor switch 8. . And this high frequency electric power is supplied to the heating coil 1, and is supplied to the inner pot 15 from the heating coil 1 in the form of a high frequency magnetic field. In the inner pot 15, an eddy current is generated in the surface layer portion according to the high frequency magnetic field, and as a result, heat is generated.

For this reason, the current I ₅ having a frequency twice the commercial frequency flows through the inductor 5 and the low-frequency magnetic field canceling means 12, and the power source 3 when the semiconductor switch 8 becomes conductive in the side surface heating coil 1 b. A current I ₁₁ (a superposition of a low-frequency current having a component twice the commercial frequency generated in the loop of the rectifying means 4 → the heating coil 1 → the semiconductor switch 8 and a high-frequency component flowing in the heating coil 1 according to the frequency of the semiconductor switch 8. Flows as shown in FIG.

  Therefore, the low frequency magnetic field generated from the heating coil 1 can be canceled by arranging the heating coil 1 and the low frequency magnetic field canceling means 12 so that the low frequency magnetic fields cancel each other. At this time, the side surface heating coil 1b has a larger coil diameter than the bottom surface heating coil 1a, and the leakage magnetic field is large because it is difficult to be coupled with the inner pot. For this reason, it is desirable that at least the side surface heating coil 1b and the low frequency magnetic field canceling means 12 are arranged so as to cancel each other. Further, the bottom surface heating coil 1a and the side surface heating coil 1b are wound in the same direction, so that the low frequency magnetic field canceling unit is The magnetic field canceling effect of 12 can be further increased.

  On the other hand, the low-frequency magnetic field canceling means 12 is disposed near the side surface of the inner pot 15. Therefore, as shown in FIG. 3, the low-frequency magnetic field canceling means 12 are stacked in a column and formed into a ring shape, so that the low-frequency magnetic field canceling means can be formed into a cylindrical shape and can be easily arranged on the side surface of the inner frame 16. It is possible to improve the workability, and further, the self-bonding wire is wound and used several times, and fixing the wire itself further simplifies the handling and improves the workability. it can.

Further, by using an electric wire (Litz wire) formed by twisting a plurality of thin wires insulated from each other in the low frequency magnetic field canceling means 12, an electric wire caused by a high frequency component of the current flowing in the low frequency magnetic field canceling means It is possible to suppress the loss due to the skin effect, and it is possible to reduce the heat generation of the electric wire, so that the arrangement for cooling is not complicated.

As described above, in the present embodiment, the low-frequency magnetic field cancellation in which the wiring having the same frequency component as the low-frequency component of the current flowing in the side surface heating coil 1b is arranged so that the currents flowing in the opposite directions to the side surface heating coil 1b flows. By disposing the means 12 on the side surface of the inner frame 16 and above the side surface heating coil 1b, the magnetic field generated from the low frequency canceling means 12 and the low frequency magnetic field generated from the side surface heating coil 1b cancel each other. Combined with this, the low frequency leakage magnetic field is greatly reduced and the distance between the bottom surface heating coil 1a and the side surface heating coil 1b is reduced, so that the influence on the high frequency magnetic field contributing to induction heating is small , thereby reducing the influence on the rice cooking performance. the can be, moreover integration into the inner frame 16 by a ring-like configuration stacking a low-frequency magnetic field cancellation means 12 in tandem It can be easy.

(Embodiment 2)
FIG. 4 is a configuration diagram of a main part of the rice cooker according to Embodiment 2 of the present invention. The present embodiment is different from the first embodiment in that the low-frequency magnetic field canceling means 12 is integrally formed with the inner frame 16 and the outer surface thereof.

  About the rice cooker comprised as mentioned above, the operation | movement and an effect | action are demonstrated below. The inner frame 16 is made of a resin having a heat resistance of 100 ° C. or higher, such as PPS, and a shape in which the bottom surface heating coil 1a, the side surface heating coil 1b, the magnetic shield ferrite 13 and the like are integrally formed is also seen. Here, by forming the lead wire of the low frequency magnetic field canceling means 12 integrally with the inner frame 16, it is not necessary to set the low frequency magnetic field canceling means 12 to the inner frame 16, and it is possible to adopt a compact configuration. Become.

  As described above, in the present embodiment, the low frequency magnetic field canceling means 12 is integrally formed with the inner frame 16 to improve the workability during product assembly and to fix the low frequency magnetic field canceling means 12. Since a fixing device for doing so is not required, the leakage magnetic field countermeasure can be made inexpensive.

(Embodiment 3)
FIG. 5 is a configuration diagram of a rice cooker according to Embodiment 3 of the present invention. The present embodiment is different from the invention of the first embodiment in that the electromagnetic shield ring 2 is disposed below the low frequency magnetic field canceling means 12 in the vicinity of the side surface heating coil 1b.

  About the rice cooker comprised as mentioned above, the operation | movement and an effect | action are demonstrated below. In general, a gap of about 10 mm usually exists between the heating coil 1 and the inner pot 15. Therefore, among the high-frequency magnetic field generated from the heating coil 1, there is a leakage magnetic field that is released to the outside without being absorbed by the inner pot 15. Since the leakage magnetic field increases toward the outer periphery, a method of reducing the high frequency magnetic field in the opposite direction around the outermost part is effective. However, the magnetic field generated from the low-frequency magnetic field canceling means 12, which is a low-frequency magnetic field reducing means, is mostly low frequency and has little effect on reducing the high-frequency leakage magnetic field.

  Therefore, by disposing the electromagnetic shield ring 2 on the outer peripheral portion of the heating coil 1, particularly on the outer peripheral portion of the side surface heating coil 1b, a cancellation magnetic field for the heating coil 1 is generated in the electromagnetic shield ring 2 and the high-frequency leakage magnetic field is reduced. Can do. At this time, since the low frequency magnetic field canceling means 12 and the electromagnetic shield ring 2 are arranged separately, it is only necessary to fit both of them in order, so that workability at the time of product assembly can be improved.

  Here, since the low frequency magnetic field canceling means 12 is located in the vicinity of the inner frame 16, the diameter of the electromagnetic shield ring 2 is larger than the diameter of the low frequency magnetic field canceling means 12. Therefore, there is no problem even if a positional overlap occurs between the electromagnetic shield ring 2 and the low-frequency magnetic field canceling means 12. In addition, the electromagnetic shield ring 2 includes an aluminum plate formed in an annular shape and joined at an end thereof, and an electromagnetic shield ring formed by short-circuiting an electric wire.

  However, it goes without saying that the casing of the rice cooker can be made compact if the electromagnetic shield ring 2 and the low-frequency magnetic field canceling means 12 do not overlap.

  As described above, in the present embodiment, the electromagnetic shield ring 2 made of an annular conductor is arranged in the vicinity of the outer periphery of the side surface heating coil 1b and below the low frequency magnetic field canceling means 12, thereby reducing the low frequency. In addition, high-frequency leakage magnetic fields can be reduced.

(Embodiment 4)
FIG. 6 is a configuration diagram of a rice cooker according to Embodiment 6 of the present invention. The present embodiment is different from the first embodiment in that the low-frequency magnetic field canceling means 12 is located on the outer periphery of the electromagnetic shield ring 2.

  About the rice cooker comprised as mentioned above, the operation | movement and an effect | action are demonstrated below. The low frequency magnetic field canceling means 12 generates more canceling magnetic fields as the number of windings is larger and the diameter is larger. Therefore, it is desirable to arrange in a place where the diameter can be increased. On the other hand, if the diameter of the low-frequency magnetic field canceling means 12 is increased, the size of the rice cooker increases, so that the installation location is limited.

  Therefore, by providing the low frequency magnetic field canceling means 12 on the outer peripheral portion of the electromagnetic shield ring 2 as shown in FIG. 6, the diameter can be increased and the low frequency magnetic field canceling means 12 can be accommodated compactly. Moreover, the low-frequency magnetic field canceling means 12 can be positioned above the side surface heating coil 1b, so that the distance from the side surface heating coil 1b can be increased and the influence on the rice cooking performance can be reduced.

  On the other hand, as shown in FIG. 7 showing the main part of the rice cooker, the electromagnetic shield ring 2 is provided with an uneven portion 18 in which the wiring of the low frequency magnetic field canceling means 12 is accommodated, and the low frequency magnetic field canceling means 12 is wound around the electromagnetic shield. Since the ring 2 can also serve as a winding jig and can be housed in the case of the rice cooker as it is, workability at the time of product assembly is improved.

  Further, as shown in FIG. 8, by providing a plurality of support means 17 for fixing the low-frequency magnetic field canceling means 12 in a part of the electromagnetic shield ring 2, it is not necessary to prepare a fixing device again, and the magnetic shield can be inexpensively provided. A structure can be realized. As a support means, there is a method such as a structure in which a part of the electromagnetic shield ring 2 is taken out into a key shape and sandwiched between the electromagnetic shield rings 2.

  As described above, in the present embodiment, by adopting a configuration in which the low-frequency magnetic field canceling means 12 is arranged on the outer periphery of the electromagnetic shield ring 2, the low-frequency leakage magnetic field can be reduced and the low-frequency magnetic field can be easily obtained. Since the annular structure of the canceling means 12 can be made, it is possible to improve the assembling workability when taking measures against the leakage magnetic field.

  As described above, the rice cooker according to the present invention can reduce the low-frequency leakage magnetic field generated from the heating coil without greatly affecting the rice-cooking performance. Applicable.

The block diagram of the rice cooker in Embodiment 1 of this invention The figure which shows the operation | movement waveform of the rice cooker in Embodiment 1 of this invention. The perspective view of the low frequency magnetic field cancellation means of the rice cooker in Embodiment 1 of this invention The block diagram of the principal part of the rice cooker in Embodiment 2 of this invention. The block diagram of the rice cooker in Embodiment 3 of this invention The block diagram of the rice cooker in Embodiment 4 of this invention The block diagram of the principal part of the rice cooker in Embodiment 4 of this invention. The block diagram of the principal part of the rice cooker in Embodiment 4 of this invention. Configuration diagram of conventional induction heating device Configuration diagram of conventional induction heating device Circuit diagram of a conventional induction heating and heating device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Heating coil 1a Bottom surface heating coil 1b Side surface heating coil 2 Electromagnetic shield ring 11 High frequency oscillation part 12 Low frequency magnetic field cancellation means 15 Inner pan 16 Inner frame 17 Support means 18 Uneven part

Claims (10)

An inner pot, an inner frame holding the inner pot, an outer surface of the inner frame, a bottom heating coil for induction heating the bottom of the inner pot, an outer surface of the inner frame, Side heating coil for induction heating the side, rectifying means connected to the power supply unit for rectifying the power of the commercial frequency and converting it into power having a low frequency component twice the commercial frequency, and in series with the rectifying means A series connection circuit of an inductor and a smoothing capacitor to be connected, and a high frequency current in which the low frequency component and the high frequency component are superimposed on the bottom surface heating coil and the side surface heating coil by converting the power having the low frequency component into high frequency power. and a high-frequency oscillation unit for supplying the wire of the high frequency is in the oscillation portion the series connection circuit low-frequency current flows having the low frequency components, from the heating coil and the low-frequency magnetic field generated from the wiring In addition to having a low frequency magnetic field canceling means constituted by winding a plurality of times so that the generated low frequency magnetic field is in the direction of canceling each other, the low frequency canceling means reduces the influence on the high frequency magnetic field contributing to induction heating. A rice cooker arranged on the side of the inner frame and above the side surface heating coil. The rice cooker according to claim 1, wherein the wire constituting the bottom surface heating coil and the side surface heating coil is wound in the same direction. 3. The rice cooker according to claim 1 or 2, wherein the low-frequency canceling means is configured by applying a component having the same frequency as the low-frequency component of the current flowing in the side surface heating coil in a ring shape and stacking the wirings in tandem. . 4. The rice cooker according to claim 3, wherein the low-frequency magnetic field canceling means fixes the shape using a self-bonding wire. 5. The rice cooker according to claim 3, wherein the low-frequency canceling means uses an electric wire formed by twisting a plurality of thin wires insulated from each other. The rice cooker according to claim 4 or 5, wherein the low-frequency canceling means is formed integrally with the inner frame. The electromagnetic shield ring made of an annular conductor is disposed in the vicinity of the outer periphery of the side surface heating coil so that the center position of the electromagnetic shield ring is below the center position of the low-frequency magnetic field canceling means. The rice cooker of any one of 6. The rice cooker according to any one of claims 1 to 7, wherein the electromagnetic shield ring made of an annular conductor is disposed in the vicinity of the outer periphery of the side surface heating coil, and a low-frequency magnetic field canceling means is disposed on the outer periphery thereof. The rice cooker according to claim 8, wherein the electromagnetic shield ring is provided with an uneven portion for determining the position of the low-frequency canceling means. The rice cooker according to claim 8 or 9, wherein the electromagnetic shield ring is provided with support means for supporting low-frequency canceling means in part.

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