JP2009283394A - Heating cooker - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure much amount of suction air of a fan device and to improve a cooling efficiency. <P>SOLUTION: A fan device includes, in addition to a first suction air flow passage from the rear of a body, second suction air flow passages 66 and 76 which suck cooling air from around a first blowing duct 60, so that much amount of suction air by the fan device is secured. Outside air at a plurality of different places is sucked in the first suction air flow passage and the second suction air flow passages 66 and 76, so that, different from a case where outside air is sucked from only one place, the temperatures of air at a plurality of places are averaged to blow cooling air at the averaged temperature, and thereby the efficiency of cooling a heating coil to be cooled and the electric components of a high-frequency current supplying means are improved. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a heating cooker provided with a heating means, a high-frequency current supply means for supplying a high-frequency current to the heating means, and a fan device for cooling electrical components of the high-frequency current supply means.

  Conventionally, in this type of heating cooker (IH cooking heater), both the heating coil as the heating means and the electric parts of the electric circuit unit provided with the high-frequency current supply means for supplying high-frequency current to the heating coil have a large calorific value. For this reason, forced cooling is performed by a cooling fan.

Specifically, a heating coil supported by a support plate is disposed below the top plate, and an electric circuit unit having a plurality of circuit boards on which electric components for an inverter are mounted is provided below the support plate. And a fan device having a cooling fan is provided behind the electric circuit unit, and the electric parts of the electric circuit unit are cooled by the cooling air blown by the cooling fan, and a part of the cooling air is supplied. Is sent to the heating coil side through a hole formed in the support plate, and the heating coil is cooled by the cooling air (see, for example, Patent Document 1).
JP 2002-33184 A (FIG. 1)

  In the configuration of the above-described Patent Document 1, the intake of the cooling fan device is intake from only one intake port at the rear upper part of the main body. With such a structure, since the intake air can be sucked only from one intake port, there is a problem that the amount of air blown by the fan device that cools the electric parts of the electric circuit unit and the heating coil tends to be reduced. In addition, since only the air at the same position is sucked, when the temperature of the air at the sucked position is high, the temperature of the cooling air blown from the fan device becomes high, and the cooling efficiency is deteriorated. was there.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a heating cooker that can secure a large amount of air intake of the fan device and can also improve cooling efficiency. There is.

  In order to achieve the above-described object, a heating cooker according to the present invention includes a main body on which a cooking container is placed, a heating unit disposed in the main body and heating the cooking container, and the main body. A high-frequency current supply means that is arranged to supply a high-frequency current to the heating means; a fan device that is arranged in the main body and that cools electrical components of the high-frequency current supply means; and a fan that blows air from the fan device A ventilation duct for guiding the cooling air, a first intake path through which the cooling air sucked into the fan device passes, and the first air intake path are provided around the air duct separately from the first intake path. And a second intake passage through which the sucked cooling air flows.

  In the configuration described above, since the second intake path for sucking cooling air from the periphery of the air duct is provided in addition to the first intake path, a large amount of intake air by the fan device can be secured. In addition, in the first intake path and the second intake path, outside air from a plurality of different places is sucked in. Therefore, unlike the case of intake from only one place, the temperature of the air at the plurality of places is averaged, Cooling air having an averaged temperature can be blown, and it is possible to improve the cooling efficiency for the electrical parts of the heating means to be cooled and the high-frequency current supply means.

Hereinafter, an embodiment in which the present invention is applied to a stationary heating cooker (IH cooking heater) will be described with reference to the drawings.
First, in FIG. 1, the main body 1 of the heating cooker includes a main body case 2 having a rectangular box shape with an upper surface opened, and a top plate assembly 3 attached to the upper surface of the main body case 2. The top plate assembly 3 includes, for example, a glass top plate 4 and a top plate frame 5 that supports the top plate 4. A cooking container 105 (see FIG. 6) is placed on the top surface of the top plate 4.

  A fan device 6 and an electric circuit unit 7 (see FIGS. 3 to 5), which will be described later, are arranged on one side in the main body case 2 as viewed from the front, and a roaster unit is arranged on the left side which is the other side. 8 is disposed. In the main body case 2, a partition plate 10 extending in the front-rear direction is provided between the right fan device 6 and the electric circuit unit 7 and the left roaster unit 8. It is divided into left and right.

  The roaster unit 8 is provided with a roaster heater 12 (see FIG. 3) disposed in a roaster casing 11 whose front surface is open, and a drawer unit 14 having a door 13 is provided so as to be able to be taken in and out. 14, a tray 14a (see FIG. 3) and a grill net (not shown) are attached. A roaster exhaust port 15 is provided upward at the rear of the roaster casing 11. A roaster exhaust port 5a (indicated by a dotted line in FIG. 1) communicating with the roaster exhaust port 15 is provided at the rear of the top plate frame 5, and the air in the roaster casing 11 is exhausted from the roaster exhaust. The gas is discharged through the mouth portion 15 and the roaster exhaust port 5a. A main body exhaust port 5b (also indicated by a dotted line in FIG. 1) is formed at the rear portion of the top plate frame 5 so as to be positioned on the left side of the roaster exhaust port 5a. The roaster exhaust port 5a and the main body exhaust port 5b are covered with an exhaust port cover 9 having a large number of ventilation holes.

  A partition 16 is disposed in the upper part of the main body case 2 so as to be positioned below the top plate 4. This partition 16 is arranged in a state straddling the right fan device 6 and the electric circuit unit 7 and the left roaster unit 8 (see FIG. 3). The partition 16 is made of a nonmagnetic conductive material, such as aluminum, and has a shallow rectangular container shape with a side wall 16a rising on the outer periphery in a frame shape, and is formed at the upper end of the side wall 16a. It is made to contact | adhere to the lower surface of the top plate 4 via the packing 17 (refer FIG.3 and FIG.4) provided over the perimeter. Here, the partition 16 is provided so as to partition the space below the top plate 4 into an upper space 18 and a lower space 19. Further, the upper space 18 formed between the top plate 4 and the partition 16 is a space in which the space between the top plate 4 and the partition 16 is sealed via the packing 17.

  In the upper space 18 in the partition 16, a plurality, in this case, two heating coils 21 and 22 for induction heating are arranged. These heating coils 21 and 22 constitute a heating means for heating the cooking container 105 placed on the top plate 4. The heating coils 21 and 22 are respectively supported by the coil base 23 and are urged toward the upper top plate 4 by a spring 24 (see FIGS. 3 and 4), so that the heating coils 21 and 22 are separated from the heating coils 21 and 22. A gap is formed between the upper surface of the body 16 and the wind. A temperature sensor 25 is provided at the center of the coil base 23 of each heating coil 21, 22. The temperature sensor 25 is for detecting the temperature of the cooking container 105 placed on the top plate 4.

  In FIG. 1 and FIG. 2, two communicating portions 26 each having an opening are formed in the right front portion of the partition 16 so as to be positioned in front of the right heating coil 21. In addition, an exhaust port 27 including an opening is formed in the left rear portion of the partition 16 so as to be positioned behind the left heating coil 21, and the right heating coil is formed in the rear of the left and right central portions of the partition 16. An exhaust port 28 is formed on the left rear side of 22.

  A terminal block opening 29 is formed at the center of the partition 16 so as to be positioned between the left and right heating coils 21 and 22. A relay terminal block 30 provided at the upper end portion of the partition plate 10 and positioned at the center portion in the front-rear direction is inserted into the terminal block opening 29. As shown in FIG. 3, the relay terminal block 30 is connected to the first connection portion 32 to which the relay connection wire 31 on the electric circuit unit 7 side is connected and to the lead wire 33 of the heating coils 21 and 22. 2 connecting portions 34. The relay terminal block 30 has a function of electrically connecting the electric circuit unit 7 and the heating coils 21 and 22.

  On the upper surface, which is inside the partition 16, is positioned between the two heating coils 21, 22 adjacent to the left and right, and between the front communication portion 26 and the rear exhaust ports 27, 28, The 1st partition part 36 extended in the left-right direction is provided, and the 2nd partition part 37 which partitions off between the right-and-left adjacent exhaust ports 27 and 28 is provided in the rear part side of this 1st partition part 36. . Further, on the upper surface of the partition 16, between the outer periphery of the coil base 23 of the left heating coil 21 and the left side wall 16 a, and the outer periphery of the coil base 23 of the right heating coil 22 and the right side wall 16 a The 3rd partition part 38 which connects between each is provided.

  An operation panel unit 42 including an operation unit 40 including a switch and a display unit 41 is provided in front of the partition 16. The operation panel unit 42 is covered with a cover portion 42 a provided at the front portion of the top plate frame 5.

  Next, the configuration of the electric circuit unit 7 and the fan device 6 will be described with reference to FIGS. The electric circuit unit 7 and the fan device 6 are provided in the substrate case 45. The substrate case 45 is disposed on the right side of the partition plate 10 in the lower space 19 of the main body case 2. A circuit board 46 made of a single printed circuit board is accommodated at the bottom of the board case 45. The electric circuit unit 7 is configured by mounting electric components to be described later on the circuit board 46.

  A first intake duct 47 is provided on the rear side of the substrate case 45 in the main body case 2. The upper portion of the first intake duct 47 is an intake port 48, and the intake port 48 is a first intake port 49 (shown by a dotted line in FIG. 1) provided on the right side of the rear portion of the top plate frame 5. ). The first intake port 49 also corresponds to the main body intake port. The first intake port 49 is covered with an intake port cover 49a having a large number of ventilation holes. The first intake duct 47 is formed with a vent 50 at the front and a falling wall 51 at the upper part of the inside, and is sucked from the first intake 49 and the intake 48. The configuration is such that air outside the machine (outside air) flows under the falling wall 51 and flows to the vent 50 side so as to be detoured in a U shape. The falling wall 51 has an effect of preventing water or the like from entering the first air intake duct 47 from the first air intake port 49 and the air intake port 48 into the air inlet 50 side. .

  A fan device 6 is attached to the upper part of the rear portion of the substrate case 45 so as to be positioned above the circuit substrate 46. The fan device 6 includes a cooling fan 53 that is a vertical centrifugal fan, a motor 54 that rotationally drives the cooling fan 53, and a fan casing 55 that surrounds the cooling fan 53. The motor 54 is attached to the upper part of the fan casing 55 by screws 55a, and the rotating shaft 54a faces downward. The upper surface of the fan casing 55 and the lower surface of the partition 16 are separated from each other. The discharge port 56 of the fan casing 55 is directed forward, and the top end portion 56 a of the upper portion of the discharge port 56 is directed upward and is in contact with the lower surface of the partition 16. The cooling fan 53 is configured to have a size such that the rotating shaft 54a of the motor 54 serving as the rotating shaft of the cooling fan 53 is positioned in front of the first intake port 49 and faces the lower side of the right heating coil 22. Yes.

  An upper suction port 57 having a shape larger than that of the motor 54 is formed in the upper portion of the fan casing 55. The upper suction port 57 is located between the cooling fan 53 and the partition body 16 and thus the right side heating coil 22 and communicates with the ventilation port 50 of the first intake duct 47. Here, when the cooling fan 53 is driven to rotate by the motor 54, the first path passes through the outside air (cooling air) sucked from the first air inlet 49 through the first air intake duct 47 into the upper air inlet 57. An intake path 58 (see arrow A1 in FIG. 4) is used.

  A lower suction port 59 is formed in a lower portion of the fan casing 55 so as to be positioned at a portion corresponding to the lower portion of the upper suction port 57. In this case, the fan device 6 is attached to the substrate case 45 in a state in which the lower end portion 6a is spaced upward from the bottom portion 45a of the substrate case 45, and the lower end portion 6a of the fan device 6 and the bottom portion 45a of the substrate case 45 are mounted. The circuit board 46 is arranged between the two.

  A first air duct 60 (see FIGS. 4 and 5) extending in the front-rear direction is provided at the center in the left-right direction of the front lower portion of the substrate case 45, and the first upper portion of the substrate case 45 has a first A second air duct 61 (see FIGS. 1 and 4) is provided above the air duct 60. Among these, the rear part of the 1st ventilation duct 60 is connected to the lower part of the discharge outlet 56 of the said fan casing 55, and the front part is opening. A guide plate 62 is provided at the lower part of the rear part of the first air duct 60. The rear end portion of the upper portion of the guide plate 62 is connected to the lower end portion of the discharge port 56 of the fan casing 55, and the lower end portion of the front portion of the guide plate 62 is in contact with the upper surface of the circuit board 46. In this case, part of the cooling air discharged from the discharge port 56 of the fan casing 55 flows forward through the first air duct 60 (see arrow B1 in FIGS. 4 and 5). In the 1st ventilation duct 60, the duct internal partition part 60a which partitions the inside of the said 1st ventilation duct 60 into right and left is provided.

  The rear part of the second air duct 61 communicates with the upper part of the discharge port 56 of the fan casing 55, and the front part communicates with the communication part 26 of the partition 16. The bottom surface 61 a of the second air duct 61 is an inclined surface that increases from the rear portion toward the communication portion 26. In this case, a part of the cooling air discharged from the discharge port 56 of the fan casing 55 is guided to the communication part 26 through the second air duct 61 (see arrow B2 in FIG. 4). A rear partition portion between the first air duct 60 and the second air duct 61 is used as a flow dividing plate portion 63, and the cooling air discharged from the discharge port 56 of the fan casing 55 is cooled by the flow dividing plate portion 63. The first air duct 60 side and the second air duct 61 side are divided.

  As shown in FIG. 5, a second air intake duct 65 is provided at the lower part of the substrate case 45 so as to be positioned on the right outer side of the first air duct 60, and to the left of the first air duct 60. Another second intake duct 66 is provided on the outer side.

  Among these, the right second air intake duct 65 is surrounded by the right wall of the first air duct 60, the right wall of the substrate case 45, the circuit board 46, and the lower surface of the second air duct 61. The rear portion communicates with the lower suction port 59 of the fan casing 55. On the front wall of the substrate case 45, which is the front portion of the second intake duct 65, a duct intake port 67 made of an opening is formed. A second intake port 68 is formed in the right front portion of the bottom wall portion of the main body case 2 so as to be positioned at a portion corresponding to the lower side of the duct intake port 67. Here, when the cooling fan 53 is rotationally driven by the motor 54, the outside air (cooling air) sucked into the lower suction port 59 of the fan casing 55 through the second suction duct 65 on the right side from the second suction port 68. ) Is a second intake path 69 on the right side (see arrow A2 in FIG. 5).

  As shown in FIG. 1, an auxiliary plate 70 having an L shape as viewed from above is provided between the front portion of the substrate case 45 and the rear surface of the front portion of the main body case 2. An auxiliary duct 71 is formed by the front portion of the substrate case 45, the front wall of the main body case 2, and the front portion of the partition plate 10. The lower portion of the auxiliary duct 71 communicates with the front opening of the first air duct 60, and the cooling air that has passed through the first air duct 60 is discharged to the auxiliary duct 71. As shown in FIG. 4, two vent holes 72 each having a rectangular hole are formed in the front portion of the partition plate 10, and the cooling air passing through the auxiliary duct 71 is guided to the left roaster unit 8 side. (See arrow B3 in FIGS. 2 and 4). As shown in FIG. 5, a partition 70 a is integrally provided at the lower part of the left portion of the auxiliary plate 70, and the partition 70 a provides a space between the left side wall of the substrate case 45 and the partition plate 10. The gap is divided forward and backward. An auxiliary air passage 73 (see FIGS. 1 and 2) extending in the left-right direction is formed between the auxiliary plate 70 and the second air duct 61. The lower right portion of the auxiliary air passage 73 communicates with the second intake port 68.

  The second intake duct 66 on the left side of the first air duct 60 includes a left side wall of the first air duct 60, a left side wall of the substrate case 45, a circuit board 46, and a lower surface of the second air duct 61. The rear portion communicates with the lower suction port 59 of the fan casing 55. A duct intake port 74 formed of an opening is formed at the front portion of the left side wall of the substrate case 45, which is the front portion of the second intake duct 66, and is located behind the partition portion 70a. The duct air inlet 74 communicates with the auxiliary air passage 73 through a gap formed between the left side wall of the substrate case 45 and the partition plate 10.

  Here, when the cooling fan 53 is rotationally driven by the motor 54, a part of the outside air sucked into the main body case 2 from the second air inlet 68 passes through the auxiliary air passage 73 and is a duct air inlet 74. Then, the air is sucked from the duct air inlet 74 through the second air intake duct 66 into the lower air inlet 59 of the fan casing 55. Among these, a route guided from the second intake port 68 through the auxiliary air passage 73 to the duct intake port 74 is referred to as an auxiliary intake route 75 (see arrow A3 in FIGS. The second intake path 76 (see arrow A4 in FIG. 5) on the left side is a path that is sucked into the lower suction port 59 of the fan casing 55 through the intake duct 66.

A decorative cover 77 is attached to the right part of the front surface of the main body case 2.
With reference to FIG. 5, a schematic arrangement of electrical components mounted on the circuit board 46 in the electrical circuit unit 7 will be described. In the circuit board 46, two IGBTs 79 and 80 (indicated by dotted lines in FIG. 5), which are switching elements, are arranged side by side in the front portion corresponding to the right side in the first air duct 60. In addition, a heat radiating member 81 is attached to the upper surface of the front IGBT 79, and a heat radiating member 82 having a longer front and rear length than the heat radiating member 81 is attached to the upper surface of the rear IGBT 80. A single rectifier 83 is disposed on the lower surface of the rear heat dissipation member 82 so as to be positioned on the rear side of the IGBT 80. The two IGBTs 79 and 80, the two heat dissipating members 81 and 82, and the one rectifier 83 arranged on the right side of the first air duct 60 are heated on the right side of the two heating coils 21 and 22, respectively. This corresponds to the coil 22. Each heat radiating member 81 and 82 has many heat radiating fins 81a and 82a, respectively. Each of the radiation fins 81a and 82a is arranged so as to be parallel to the flow of the cooling air flowing in the first air duct 60.

  In the circuit board 46, two IGBTs 79, 80, two heat radiating members 81, 82, and one rectifier 83 are arranged in the portion corresponding to the left side in the first air duct 60, similarly to the right side. Has been. The two IGBTs 79 and 80, the two heat radiation members 81 and 82, and the one rectifier 83 arranged on the left side of the first air duct 60 correspond to the left heating coil 21.

  In the circuit board 46, the portion corresponding to the second intake duct 65 on the right side has two current transformers 84, 85, two resonance capacitors 86, 87, one smoothing capacitor 88, 1 in order from the front. Reactors 89 are arranged. These electrical components correspond to the right heating coil 22. Also, in the circuit board 46, the portion corresponding to the second intake duct 66 on the left side is also provided with two current transformers 84, 85, 2 in order from the front as in the case of the second intake duct 65 on the right side. One resonant capacitor 86, 87, one smoothing capacitor 88, and one reactor 89 are arranged. These electric components correspond to the left heating coil 21.

  Here, on the circuit board 46 in the first air duct 60, IGBTs 79 and 80 that are switching elements corresponding to the left and right heating coils 21 and 22, their heat radiation members 81 and 82, and a rectifier 83 are provided. Two current transformers 84, 85, which are electrical components other than IGBTs 79, 80, are arranged in parallel on the circuit board 46 in the right second intake duct 65 and the left second intake duct 66. Two resonant capacitors 86, 87, one smoothing capacitor 88, and one reactor 89 are arranged in parallel across the first air duct 60.

  In the circuit board 46, a control unit 92 including two noise filter coils 90 and a control microcomputer 91 is provided at a rear portion of the guide plate 62 below the lower suction port 59 of the fan casing 55. Electrical components, three relays 94 for the roaster, electrical components of the power supply circuit 95 for the microcomputer 91, and the like are arranged. The power supply circuit 95 for the microcomputer 91 includes an AC-DC converter that converts AC 100V to DC 5V. Of the electrical components on the circuit board 46, electrical components other than the electrical components given names and symbols are denoted by reference numerals 103 as other electrical components.

  In this case, the heat dissipating members 81 and 82 having a large height in the circuit board 46 are arranged in the front portion, and the fan device 6 (cooling fan 53) is located at a position different from the heat dissipating members 81 and 82 in plan view. Arranged at the rear. And as shown in FIG. 4, the lower end part 6a of the fan apparatus 6 is arrange | positioned so that it may become lower than the upper end parts 81b and 82b of the thermal radiation members 81 and 82. As shown in FIG.

FIG. 6 shows an electrical configuration of a portion related to the gist of the present invention, which will be briefly described. In FIG. 6, the electrical configuration of the roaster unit 8, the fan device 6, and the operation panel unit 42 side is omitted.
First, the electrical configuration for the left heating coil 21 will be described. The AC input terminal of the rectifier 83 is connected to both ends of the noise filter capacitor 96 and is connected to the commercial AC power source 97 via the noise filter coil 90. The DC output terminals of the rectifier 83 are connected to both ends of the smoothing capacitor 88 through the reactor 89.

  Both ends of the smoothing capacitor 88 are connected to arms composed of IGBTs 79 and 80 as switching elements on the positive side and the negative side via DC buses 98 and 99, thereby forming a half-bridge type inverter circuit 100. ing. Free wheel diodes 101 and 102 are connected between the collectors and emitters of the IGBTs 79 and 80, respectively. One end of the heating coil 21 is connected to the output terminal of the inverter circuit 100, and two resonant capacitors 86 and 87 are connected in parallel between the other end of the heating coil 21 and the DC bus 99. . The inverter circuit 100 constitutes a high frequency current supply unit that supplies a high frequency current to the heating coil 21.

  A current transformer 84 is inserted on the AC input side of the rectifier 83, and a secondary output voltage of the current transformer 84 is supplied to the control unit 92. Further, a current transformer 85 is inserted on the output side of the inverter circuit 100, and a secondary output voltage of the current transformer 85 is also supplied to the control unit 92. The temperature sensor 25 detects the temperature of the cooking container 105 via the top plate 4 and gives a detection signal to the control unit 92.

  The electrical configuration for the right heating coil 22 is the same as the electrical configuration for the left heating coil 21 described above, and a description thereof will be omitted. The noise filter coil 90 and the noise filter capacitor 96 are shared by the left heating coil 21 and the right heating coil 22.

  Next, the operation of the above configuration will be described. Here, the explanation will be made mainly on the flow of the cooling air by the fan device 6 in particular. When cooking by using one or both of the heating coils 21 and 22, the user operates the operation unit 40 of the operation panel unit 42 with the cooking container 105 placed at a predetermined position on the top plate 4. Manipulate. Then, the control unit 92 controls the IGBTs 79 and 80 of the inverter circuit 100 to control the heating coils 21 and 22 and the motor 54 of the fan device 6 based on the operation and a control program prepared in advance. Of these, a high frequency current is supplied to the heating coils 21 and 22 by controlling the IGBTs 79 and 80 to generate a high frequency magnetic field, and a current is induced in the cooking vessel 105 to perform heating cooking by Joule heat. At this time, the heating coils 21 and 22 to be used generate heat, and the electric parts of the circuit board 46 in the electric circuit unit 7 also generate heat. Therefore, it is necessary to cool them. Is called.

  When the cooling fan 53 is rotationally driven by the motor 54 of the fan device 6, air (outside air) outside the main body 1 is supplied from the first intake port 49 at the rear upper part of the main body 1 by the air blowing action of the cooling fan 53. 1 is sucked into the air intake duct 47 and is sucked into the main body case 2 from the second air inlet 68 in the bottom wall portion of the front portion of the main body case 2.

  Among these, the outside air (cooling air) sucked into the first intake duct 47 from the first intake port 49 mainly passes through the first intake path 58 as shown by an arrow A1 in FIG. Then, the air is sucked into the fan casing 55 from the upper suction port 57 of 55.

  On the other hand, a part of the outside air (cooling air) sucked into the main body case 2 from the second intake port 68 is supplied from the right duct intake port 67 to the second intake duct 65 as shown by an arrow A2 in FIG. The air enters the fan casing 55 through the second intake passage 69 and is sucked into the fan casing 55 from the lower suction port 59 of the fan casing 55. Further, a part of the outside air (cooling air) sucked into the main body case 2 from the second air inlet 68 flows upward on the right side of the auxiliary plate 70, and then is indicated by an arrow A3 in FIGS. As shown, the auxiliary intake passage 75 flows from right to left and then flows downward through the gap between the left side wall of the substrate case 45 and the partition plate 10. Thereafter, as indicated by an arrow A4 in FIG. 5, the air enters the second intake duct 66 on the left side from the duct inlet 74 at the front side of the left side wall of the board case 45, passes through the second intake path 76, and passes through the second intake path 76. The air is sucked into the fan casing 55 from the lower suction port 59 of the casing 55.

  At this time, the right side current transformers 84 and 85, the resonance capacitors 86 and 87, the smoothing capacitor 88, the reactor disposed in the second intake duct 65 are cooled by the cooling air passing through the second intake duct 65 on the right side. 89 is cooled. The left current transformers 84 and 85, the resonant capacitors 86 and 87, the smoothing capacitors 88, and the reactor 89 are disposed in the second intake duct 66 by cooling air passing through the left second intake duct 66. Is cooled. Then, the cooling air that has passed through the second intake duct 65 on the right side and the cooling air that has passed through the second intake duct 66 on the left side merge below the fan device 6. The noise filter coil 90 disposed below the apparatus 6, the electrical components of the control unit 92 including the microcomputer 91, the relay 94 for the roaster, the electrical components of the power supply circuit 95 for the microcomputer 91, and the like are cooled.

  The air sucked into the fan casing 55 is discharged forward from the discharge port 56. The cooling air discharged from the discharge port 56 is divided into the lower first air duct 60 side and the upper second air duct 61 side by the flow dividing plate 63. Among these, the cooling air sent to the 1st ventilation duct 60 side flows toward the front inside the 1st ventilation duct 60, as shown by arrow B1 in FIG.4 and FIG.5. With the cooling air flowing in the first air duct 60, the IGBTs 79 and 80, the heat dissipating members 81 and 82, and the rectifier 83 disposed on the left and right sides are cooled.

  At this time, the flow direction of the cooling air flowing forward in the first air duct 60 (see arrow B1) and the second intake ducts 65 and 66 located on the left and right sides of the first air duct 60 are arranged. The flow direction of the cooling air flowing toward the rear (see arrows A2 and A4) is opposite and opposite to each other.

  The cooling air that has passed through the first air duct 61 exits to the auxiliary duct 71 side. The cooling air that has flowed out to the auxiliary duct 71 flows from the front vent 72 of the partition plate 10 toward the left roaster unit 8 (see arrow B3 in FIGS. 2 and 4). The front portion of the upper surface of the roaster casing 11 is slightly lower than the other portions, and the cooling air that has flowed to the roaster unit 8 side is operated with the front portion of the upper surface of the roaster casing 11 as shown by arrow B4 in FIG. After flowing between the panel unit 42 from right to left, it flows backward between the left side surface of the casing 11 for the roaster and the inner surface of the left side wall of the main body case 2, and finally the top plate frame 5 It is discharged out of the machine from the rear main body exhaust port 5b (see arrow B5 in FIG. 2). At this time, when the cooling air flows around the roaster casing 11, the roaster casing 11 can be cooled. Moreover, it is possible to prevent the heat of the roaster casing 11 from adversely affecting the operation panel unit 42 as much as possible by passing the cooling air between the operation panel unit 42 and the roaster casing 11.

  Further, the cooling air discharged from the discharge port 56 of the fan casing 55 to the second air duct 61 side flows toward the upper communication portion 26 as indicated by an arrow B2 in FIG. In the upper space 18 between the partition 16 and the top plate 4. The cooling air entering the upper space 18 hits the lower surface of the top plate 4 and spreads in the upper space 18.

  At this time, on the upper surface of the partition 16, it is positioned between the two heating coils 21, 22 adjacent to the left and right, and between the front communication portion 26 and the rear exhaust ports 27, 28. A first partition 36 extending in the direction is provided, and on the rear side of the first partition 36, a second partition 37 that partitions the left and right adjacent exhaust ports 27 and 28 is provided. A third partition 38 that connects between the outer periphery of the coil base 23 of the left heating coil 21 and the left side wall 16a and between the outer periphery of the coil base 23 of the right heating coil 22 and the right side wall 16a. Are provided.

  Since the first partition portion 36, the second partition portion 37, and the third partition portion 38 are in contact with the top plate 4 and the partition body 16, respectively, the wind is the first, second, and third partition portions 36. , 37, 38, and the cooling air that has flowed to the left among the cooling air that has hit the lower surface of the top plate 4 and spread in the upper space 18 is the left heating coil 21 portion as shown by arrow B6 in FIG. After flowing intensively (especially, the space between the coil base 23 and the partition 16 separated from the spring 24), it is discharged from the left rear exhaust port 27 to the lower side of the partition 16. In addition, among the cooling air that has spread on the lower surface of the top plate 4 and spread in the upper space 18, the cooling air that has flowed to the right side is, as shown by the arrow B 7 in FIG. After intensively flowing in the space between the coil base 23 and the partition 16 separated from the spring 24, it is discharged to the lower side of the partition 16 from the exhaust port 28 at the rear part of the center. Thereby, both the left side heating coil 21 and the right side heating coil 22 are efficiently cooled. At this time, since the upper space 18 in which the heating coils 21 and 22 are accommodated is configured to be a space in which the space between the top plate 4 and the partition 16 is sealed, the heating coils 21 and 22 should be cooled. The leakage of the cooling air that has entered the upper space 18 can be prevented as much as possible, and the cooling air can be effectively applied to the cooling of the heating coils 21 and 22. Further, it is possible to prevent as much as possible the wind that has cooled and heated the electrical components of the lower electrical circuit unit 7 from entering the upper space 18.

  The cooling air discharged to the lower side of the partition 16 from the exhaust outlets 27 and 28 at the rear part of the partition 16 together with the cooling air that has cooled the electric parts of the electric circuit unit 7 from the main body exhaust 5b at the rear of the main body 1. (See arrow B5).

According to the above-described embodiment, the following operational effects can be obtained.
A space below the top plate 4 is partitioned into an upper space 18 and a lower space 19 by a partition 16, and heating coils 21 and 22 for induction heating are disposed in the upper space 18. The upper space 18 provided with the heating coils 21 and 22 is configured to be a space in which the space between the top plate 4 and the partition 16 is sealed by the partition 16. The cooling air discharged from the cooling fan 53 is divided into cooling air that cools the electrical components (IGBTs 79 and 80, heat radiation members 81 and 82, etc.) of the electric circuit unit 7 and cooling air that cools the heating coils 21 and 22. The cooling air that cools the heating coils 21 and 22 flows through the second air duct 61 (cooling path) toward the communication portion 26 of the partition 16 and enters the upper space 18 from the communication portion 26. The heating coils 21 and 22 are cooled by the cooling air.

  According to such a configuration, since the heating coils 21 and 22 are arranged in the upper space 18 whose periphery is sealed, the leakage of the cooling air supplied into the upper space 18 can be prevented as much as possible. , 22 can effectively act on the cooling of the heating coils 21, 22, and the lower electrical components (IGBTs 79, 80, heat radiation members 81, 82, etc.) are cooled and become hot. Wind can also be prevented from entering the upper space 18, and the cooling efficiency for the heating coils 21 and 22 can be improved. Note that the degree of sealing between the top plate 4 and the partition 16 does not have to be perfect, and may be as long as it can prevent the cooling air entering the upper space 18 from leaking as much as possible.

The communication part 26 exists in the front part of the partition 16, and exhaust ports 27 and 28 for discharging cooling air flowing into the upper space 18 from the communication part 26 from the upper space 18 are provided at the rear part of the partition 16. It was set as the structure provided in. According to this configuration, the cooling air flowing in the upper space 18 can flow as smoothly as possible from the front to the rear, and the heating coils 21 and 22 can be cooled more efficiently.
By forming the partition 16 in the shape of a container having a side wall 16a in the shape of a frame on the outer peripheral portion, it is possible to easily form a configuration that seals between the top plate 4 that forms the upper space 18 and the partition 16. it can.

  Two heating coils 21 and 22 are arranged in the upper space 18, and the partition 16 has exhaust ports 27 and 28 for discharging the cooling air flowing into the upper space 18 from the upper space 18, Two heating coils 21 and 22 were provided in correspondence with each other. With this configuration, the cooling air that has cooled the left heating coil 21 and the cooling air that has cooled the right heating coil 22 can be prevented from interfering as much as possible, and the flow of the cooling air can be made smoother. The cooling efficiency with respect to 22 can be further improved.

  The electric circuit unit 7 and the fan device 6 are arranged on the right side in the lower space 19 in the main body 1, and the roaster unit 8 is arranged on the left side, and a partition plate is provided between the electric circuit unit 7 and the fan device 6 and the roaster unit 8. 10 is divided into left and right, and a vent 72 is provided at the front of the partition plate 10 to guide the cooling air that cools the electrical components of the electrical circuit unit 7 to the roaster unit 8 side. With this configuration, the roaster unit 8 side can be efficiently cooled.

  A first partition part 36 is provided on the upper space 18 side of the partition 16 between the adjacent heating coils 21 and 22 and between the communication part 26 and the exhaust ports 27 and 28. The cooling air that has flowed into the air 18 is divided into two heating coils 21 and 22 by the first partition 36 and flows. With this configuration, interference between the cooling air that cools the left heating coil 21 and the cooling air that cools the right heating coil 22 can be prevented more reliably, and the cooling efficiency for the two heating coils 21 and 22 can be improved. It can be further improved.

  A second partition portion 37 that partitions between the two adjacent exhaust ports 27 and 28 is provided on the upper space 18 side of the partition body 16. Thereby, it can prevent more reliably that the cooling air which cooled the left side heating coil 21 and the cooling air which cooled the right side heating coil 22 interfere.

  On the side of the upper space 18 in the partition 16, a third partition 38 that connects the outer peripheral portions of the heating coils 21 and 22 and the side wall 16 a of the partition 16 is provided. Thereby, it is possible to prevent the cooling air from passing through the gap between the outer peripheral portion of each heating coil 21, 22 and the side wall 16 a of the partition 16, so that the cooling air passes through each heating coil 21, 22 as much as possible. The cooling efficiency for the heating coils 21 and 22 can be further improved.

  Since the partition 16 is made of a nonmagnetic conductive material, in this case, aluminum, when leakage magnetic flux of the heating coils 21 and 22 passes through the partition 16, an eddy current is generated in the partition 16 and the magnetism makes it difficult to pass the magnetic flux. There is a shielding effect. Accordingly, it is possible to eliminate the need to provide a magnetic shielding ring or the like on the coil base 23 side of the heating coils 21 and 22.

  The cooling fan 53 of the fan device 6 is constituted by a vertical centrifugal fan, and is positioned above the circuit board 46 in the electric circuit unit 7. With this configuration, the dimension (diameter dimension) of the cooling fan 53 in the radial direction can be increased without being restricted by the circuit board 46, and the air flow rate of the cooling fan 53 can be secured at a low rotational speed. Rotational noise (noise) generated with the rotation of the cooling fan 53 can be reduced.

  The reason for this is that the rotation sound of the cooling fan increases in proportion to the speed of the outer periphery of the fan, and by increasing the diameter of the fan, it is possible to secure the fan air flow rate at a low rotation speed. This is because the speed of the outer peripheral portion of the fan can be reduced and the rotational noise can be lowered.

  The circuit board 46 of the electric circuit unit 7 is constituted by one piece. This makes it possible to secure a larger space for disposing the fan device 6 above the circuit board 46 than when the circuit boards are provided in a plurality of stages in the vertical direction, and the upper and lower suction ports 57 and 59 of the fan device 6. Etc. can be secured easily.

  A first intake port 49 (main unit intake port) for sucking air by the cooling fan 53 of the fan device 6 is provided at the rear of the upper portion of the main body 1, and the rotation shaft 54 a of the cooling fan 53 has the first rotating shaft 54 a. The size is such that it is located in front of the air inlet 49 and faces the lower side of the heating coil 22. With such a configuration, the diameter of the cooling fan 53 can be increased, and the rotational noise can be reduced.

  Incidentally, conventionally, a plurality of circuit boards are provided below the heating coil, and a circuit board duct for covering the circuit boards and blowing air to the inside is provided. It could only be provided between the main body intake port located behind and the circuit board duct, and a cooling fan having a diameter so as to face the lower part of the heating coil could not be provided.

  In this respect, in the present embodiment, the circuit board 46 is expanded to the lower side of the fan device 6 and is not formed in a plurality of stages, but is constituted by one sheet, whereby the volume of the circuit board 46 in the height direction can be reduced. Therefore, the fan device 6 can be arranged using the space that is free above the circuit board 46. Thereby, it is possible to install the cooling fan 53 having a large diameter at a position in front of the first intake port 49 and facing the lower side of the heating coil 22, and it is possible to reduce the rotational noise. .

  The fan device 6 has an upper suction port 57 for sucking cooling air from the first suction port 49 at the rear of the main body 1, and the upper suction port 57 is positioned between the heating coil 22 and the cooling fan 53. Yes. According to this structure, the space below the heating coil 22 can be effectively cooled by the cooling air sucked into the upper suction port 57, and the heat of the heating coil 22 is affected to the lower circuit board 46 side. Can be difficult. In particular, since the heating coil 22, the fan device 6, and the circuit board 46 are arranged in the vertical direction in this order, the heating coil 22 and the circuit board 46 are positioned so as to be farthest from each other. The influence of heat can be effectively reduced.

  The circuit board 46 is provided with IGBTs 79 and 80 as switching elements and heat radiating members 81 and 82 for radiating them, and the heat radiating members 81 and 82 having a large height and the fan device 6 are viewed in plan view. It arrange | positioned in a different position and arrange | positioned the lower end part 6a of the fan apparatus 6 so that it might become lower than the upper end parts 81b and 82b of the thermal radiation members 81 and 82. FIG. The IGBTs 79 and 80 generate a large amount of heat and require the heat dissipating members 81 and 82. However, since the fan device 6 is disposed avoiding the heat dissipating members 81 and 82 having a large height, the space in the main body 1 is effectively utilized. In addition, the cooling fan 53 can be enlarged in the vertical direction, and the amount of blown air can be increased. For this reason, the number of rotations of the cooling fan 53 can be lowered, and noise can be suppressed also by this.

  The circuit board 46 and the fan device 6 are provided in a board case 45 that accommodates the circuit board 46, and the fan device 6 is in a state in which the lower end portion 6 a of the fan device 6 is spaced upward from the bottom portion 45 a of the board case 45. The circuit board 46 is disposed between the lower end portion 6 a of the fan device 6 and the bottom portion 45 a of the substrate case 45. According to such a configuration, a space can be easily secured below the fan device 6, and the circuit board 46 can be easily disposed in the space.

  A lower suction port 59 through which the cooling fan 53 sucks cooling air is provided between the circuit board 46 and the lower end portion 6 a of the fan device 6, and a portion of the circuit board 46 corresponding to the lower side of the cooling fan 53 is provided. In addition, electrical components other than the switching elements (such as the microcomputer 91 and the noise filter coil 90) are arranged. The fan device 6 is disposed above the circuit board 46 by disposing electrical components such as the microcomputer 91 and the noise filter coil 90 that do not need to have a large heat radiation member below the cooling fan 53. Therefore, it is possible to arrange the electrical components without being affected by the limited space, and to cool the electrical components.

  The substrate case 45 has a first air duct 60 that extends outward (forward) from the fan device 6 and guides the cooling air blown from the cooling fan 53, and inside the first air duct 60, IGBTs 79 and 80 and heat dissipation members 81 and 82 are arranged. Thereby, IGBT79,80 and the thermal radiation member 81,82 can be cooled more efficiently.

  Heating coils 21 and 22 are disposed above the fan device 6, and cooling air is supplied from the fan device 6 to the heating coils 21 and 22, above the first air duct 60 and below the heating coils 21 and 22. A second air duct 61 for blowing air is provided. Since the circuit board 46 is constituted by one piece, the air ducts 60 and 61 can be constituted in a plurality of stages in this way. And by providing the 2nd ventilation duct 61, the wind which cooled electrical components, such as IGBT79,80 and the heat radiating member 81,82, is used as the cooling wind which cools the heating coils 21 and 22 to the heating coils 21 and 22 side. The air from the cooling fan 53 can be sent directly without the need to send, and the cooling efficiency of the heating coils 21 and 22 can be improved.

  Electrical components other than the switching elements (current transformers 84 and 85, resonant capacitors 86 and 87, etc.) are arranged on the circuit board 46 located outside the first air duct 60, and are arranged on the outer periphery of the first air duct 60. The second air intake ducts 65 and 66 are provided, through which the cooling air flowing in the direction opposite to the flow direction of the cooling air flowing through the first air blowing duct 60 and passing through the lower air inlet 59 of the fan device 6 passes. Electric components (current transformers 84 and 85, resonant capacitors 86 and 87, etc.) other than the switching element are cooled by cooling air flowing through the second intake ducts 65 and 66. According to such a configuration, the electric component of the electric circuit unit 7 can be cooled using the intake path sucked into the fan device 6, so that the electric component can be efficiently cooled. In addition, second intake ducts 65 and 66 are disposed on the left and right sides of the first air duct 60, and the flow direction of the cooling air flowing in the second air intake ducts 65 and 66 is changed in the first air duct 60. Since it is configured to face the flow direction of the flowing cooling air, the narrow space in the main body 1 can be used effectively.

  On the circuit board 46 in the first air duct 60, switching elements (IGBTs 79 and 80, heat radiation members 81 and 82) corresponding to the two heating coils 21 and 22 are arranged in parallel, and the second air intake duct 65. , 66, electrical components other than the switching elements corresponding to the heating coils 21, 22 (current transformers 84, 85, resonant capacitors 86, 87, etc.) are separated by the first air duct 60. Arranged in parallel. With such an arrangement, the arrangement of electrical components on the circuit board 46 can be optimized.

  The fan device 6 is attached to a board case 45 that houses the circuit board 46 of the electric circuit unit 7, and the board case 45 integrates the electric circuit unit 7 (circuit board 46) and the fan device 6 with respect to the main body case 2. It can be detachably attached. According to this configuration, the electric circuit unit 7 and the fan device 6 can be removed together from the main body case 2, and there is an advantage that the maintainability is excellent.

  The first air intake path 58 (see the first air intake duct 47) on the rear side of the main body 1 through which the cooling air sucked into the fan device 6 passes and the first air intake duct 58 are separated from the first air intake duct 58. Second intake passages 69 and 76 (see second intake ducts 65 and 66) provided around and through which cooling air sucked into the fan device 6 passes are provided. According to such a configuration, in addition to the first intake passage 58, the second intake passages 69 and 76 for sucking cooling air also from the periphery of the first air duct 60 are provided. A large amount of air can be secured. Moreover, in the first intake path 58 and the second intake paths 69 and 76, the outside air from a plurality of different places is sucked, so that the temperature of the air at the plurality of places is different from the case of taking in air from only one place. Thus, the cooling air with the averaged temperature can be blown, and it becomes possible to improve the cooling efficiency for the electric components of the heating coils 21 and 22 and the electric circuit unit 7 to be cooled.

  Incidentally, when the air is sucked from only one place at the rear of the main body, there is a problem that the temperature of the cooling air blown by the fan device becomes high if the temperature of the air in the sucked portion is high. In this respect, according to the present embodiment, as described above, the fan device 6 sucks in the outside air at a plurality of different locations, so the temperature of the air at the plurality of locations is averaged, and the cooling air with the averaged temperature is cooled. Can be blown.

  The cooling air passing through the second intake passages 69 and 76 is sucked into the lower suction port 59 of the fan device 6 located upstream of the first air duct 60. According to this configuration, the flow direction of the cooling air flowing through the first air duct 60 and the flow direction of the cooling air flowing through the second intake passages 69 and 76 are opposite to each other and face each other. Therefore, the narrow space in the main body 1 can be used effectively.

  The fan device 6 has an upper suction port 57 and a lower suction port 59, the first intake passage 58 is connected to the upper suction port 57, and the second intake passages 69 and 76 are lower portions different from the upper suction port 57. It is connected to the suction port 59. By differentiating the suction port (upper suction port 57) of the first intake passage 58 and the suction ports (lower suction port 59) of the second intake passages 69 and 76, the first intake passage 58 and the second intake passage. Cooling air can be sucked smoothly through the paths 69 and 76, respectively.

  The flow of the cooling air flowing in the first air duct 60 and the flow of the cooling air flowing in the second intake passages 69 and 76 located on the left and right sides of the first air duct 60 are opposite to each other and face each other. It is configured as follows. According to this structure, the narrow space in the main body 1 can be used effectively.

  The second intake passages 69 and 76 are configured by the second intake ducts 65 and 66 that are arranged in parallel with at least a part of the first air duct 60, so that the second intake passages 69 and 76 can be easily made. Can be formed.

  The first air duct 60 and the second air intake ducts 65, 66 are configured in a single board case 45, and outside the board case 45 and on the rear upper part of the main body 1, a first air intake path 58. Has a first intake port 49 for sucking outside air, and a second intake port 68 for sucking outside air into the second intake ducts 65 and 66 on the bottom wall portion of the front portion of the main body case 2. And the fan device 6 is arranged between the first intake port 49 and the second intake port 68. According to such a configuration, the first air intake port 49 exists behind the fan device 6 and the second air intake port 68 exists ahead, and the fan device 6 is different in the front and rear in the main body 1. The air in the place can be taken in. For this reason, even when the temperature of the air at the position where the first air inlet 49 sucks and the temperature of the air at the position where the second air inlet 68 sucks are different, the fan device 6 is relatively low in average. A cooling air having a low temperature can be blown, and a problem that the cooling effect is lowered by taking in only a relatively high temperature of air at only one place can be prevented.

  In the circuit board 46 located below the fan device 6, an electrical component other than a switching element that does not have a heat radiating member (microcomputer) is provided in a portion corresponding to the lower side of the fan device 6 in the second intake passages 69 and 76. 91, noise filter coil 90, etc.), and switching elements (IGBTs 79, 80) that require heat dissipating members 81, 82 are arranged at positions different from those below the fan device 6. According to this, since the electrical components other than the switching elements that do not require the heat radiating member are disposed in the space below the fan device 6 and narrow in the height direction, the cooling fan 53 in the fan device 6 is arranged in the vertical direction. It is possible to increase the air flow rate.

  The second intake passages 69 and 76 are formed between the circuit board 46 and the fan device 6. Also by this, electric parts other than the switching elements that do not require the heat dissipation member are arranged in the space below the fan device 6 and narrow in the height direction, so that the cooling fan 53 in the fan device 6 is arranged in the vertical direction. It can be increased and the amount of blown air can be increased.

The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
In the above-described embodiment, the case where the present invention is applied to a stationary type cooking device is illustrated, but the present invention can also be applied to a built-in type cooking device incorporated in a kitchen.

The disassembled perspective view of the heating cooker which shows one Embodiment of this invention Top view showing top plate assembly and operation panel unit removed Longitudinal front view along line X1-X1 in FIG. Vertical side view along line X2-X2 in FIG. Transverse plan view along line X3-X3 in FIG. Electrical configuration diagram

Explanation of symbols

  In the drawings, 1 is a main body, 2 is a main body case, 3 is a top plate assembly, 4 is a top plate, 6 is a fan device, 7 is an electric circuit unit, 8 is a roaster unit, 10 is a partition plate, 16 is a partition, 18 Is an upper space, 19 is a lower space, 21 and 22 are heating coils (heating means), 26 is a communication portion, 42 is an operation panel unit, 45 is a board case, 46 is a circuit board, 47 is a first intake duct, 49 Is a first intake port (main body intake port) 53 is a cooling fan, 55 is a fan casing, 56 is a discharge port, 57 is an upper intake port, 58 is a first intake path, 59 is a lower intake port, and 60 is a first intake port. , 61 is a second air duct, 63 is a flow dividing plate portion, 65 and 66 are second air intake ducts, 68 is a second air inlet, 69 is a second air intake path, and 76 is a second air intake. Path 79, 80 is IGBT (switching , 81 and 82 are heat dissipation members (electric parts), 83 is a rectifier (electric parts), 84 and 85 are current transformers (electric parts), 86 and 87 are resonance capacitors (electric parts), and 88 is smooth. Capacitors (electric parts), 89 reactors (electric parts), 90 noise coil coils (electric parts), 91 microcomputers (electric parts), 94 relays (electric parts), 100 inverter circuits (high-frequency current supply) Means), 103 indicates an electrical component, and 105 indicates a cooking container.

Claims (10)

A main body on which the cooking container is placed;
A heating means disposed in the main body for heating the cooking container;
A high-frequency current supply means disposed in the main body and supplying a high-frequency current to the heating means;
A fan device having a cooling fan disposed in the main body and configured to cool electrical components of the high-frequency current supply means;
A blower duct for guiding cooling air blown from the fan device;
A first intake path through which cooling air sucked into the fan device passes;
A cooking device comprising a second air intake path provided around the air duct separately from the first air intake path and through which cooling air sucked into the fan device passes.   The heating cooker according to claim 1, wherein the cooling air passing through the second intake path is sucked into a suction port of the fan device located upstream of the blower duct.   The cooking device according to claim 1 or 2, wherein the fan device has a plurality of inlets, and the first intake path and the second intake path are connected to different inlets.   The flow of the cooling air flowing through the air duct and the flow of the cooling air flowing through the second intake passage are configured to face each other. Cooking cooker.   The cooking device according to any one of claims 1 to 4, wherein the second intake path is configured by a second intake duct that is parallel to at least a part of the air duct.   The air duct and the second air intake duct are configured in a single case, and a first air for sucking outside air into the first air intake path outside the case and at the rear upper part of the main body. A second intake port for sucking outside air into the second intake duct at the bottom of the front portion of the main body; the first intake port and the second intake port; The cooking device according to claim 5, wherein the fan device is disposed between the two.   The switching element of the high-frequency current supply means is disposed in the air duct, and an electrical component other than the switching element is disposed in the second intake path. Cooking device.   The switching element has a heat radiating member and is provided on a circuit board. The circuit board is located below the fan device and is located in the second air intake path and below the fan device. 8. The cooking device according to claim 7, wherein an electrical component other than the switching element having no heat radiating member is disposed, and the switching element is disposed at a position different from the lower side of the fan device.   The cooking device according to claim 8, wherein the second intake path is formed between the circuit board and the fan device. A plurality of the heating means are provided in the main body,
The second intake path is located on the left and right outside of the air duct,
On the circuit board in the air duct, switching elements corresponding to the plurality of heating means are arranged in parallel,
The electrical component other than the switching element corresponding to each switching element is arranged in parallel in the second air intake path with the air duct therebetween. The cooking device described.

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