JP2010225427A - Induction heating cooking device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an induction heating cooking device equipped with a heating coil support which can cool a heating coil efficiently. <P>SOLUTION: The induction heating cooking device includes: a cooling room 18 which is provided in a body case 1 and includes an air-cooling fan 26, air intake 5, and exhaust port 6; a jet plate 30 which has a plurality of jet blow off holes 30a arranged at the exhaust port side; and a heating coil support 32 which supports a heating coil 7 arranged above a jet plate. The heating coil support is composed of: a coil inner periphery support 34 which supports the inner periphery of the heating coil; a plurality of ferrite holding parts 35 which extends radically from the coil inner periphery support, supports the heating coil at the front side, and holds a ferrite at the rear side; an annular connection part 36 which is connected with the ends of the plurality of ferrite holding parts and is located outside of the heating coil. A jet guide taper 40 whose reverse side edge is notched is provided into the inside 36a where the outermost periphery of the heating coil is located between the ferrite holding parts adjacent to the annular connection part. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an induction heating cooker, and more particularly to a structure of a heating coil support that supports a heating coil for cooling the heating coil.

  The conventional induction heating cooker cools the heating coil, particularly in cooling the heating coil provided with a donut-shaped space coaxial with the heating coil so as to make the temperature distribution of the cooking container to be heated uniform. The supporting heating coil support base is provided with a hole through which cooling air passes through the donut-shaped space, and the cooling air passing through the hole provided in the heating coil support base and the donut-shaped space collides with the top plate. However, there is a technique for cooling the upper surface of the heating coil (see Patent Document 1).

  Also, as a method for cooling the back surface of the heating coil, a partition wall portion having a plurality of jet blow holes is provided below the base coil, and cooling air passes through the jet blow holes of the partition wall to cool the heating coil. (See Patent Document 2).

JP-A-1-95484 JP 2006-210365 A

However, in the configuration described in Patent Document 1, the cooling air cools the upper surface of the heating coil, and at the same time the top plate is cooled or the temperature detection device is affected. In the configuration described in Patent Document 2, When the doughnut-shaped space portion coaxial with the heating coil is large or plural, the width of the heating coil is reduced, and the number of jet blowout holes formed immediately below the heating coil is reduced. There was also a problem that the air volume of the wind was reduced and the cooling efficiency was deteriorated.
An object of this invention is to obtain the induction heating cooking appliance which has a heating coil support stand which can cool a heating coil efficiently without cooling a top plate.

  An induction heating cooker according to the present invention includes a box-shaped main body case having an upper opening, a top plate covering the opening of the main body case, a heating coil disposed below the top plate in the main body case, A circuit board that is partitioned in the main body case, has an air cooling fan therein, has an air inlet and an air outlet, and a semiconductor circuit device that is disposed in the cooling chamber and drives and controls the heating coil. A jet plate having a plurality of jet blow holes disposed below the heating coil and disposed above the heating coil, and a heating coil support disposed above the jet plate and supporting the heating coil In the induction heating cooker provided with a body, the heating coil support includes a coil inner periphery support part that supports an inner periphery side of the heating coil, and a radial extension from the coil inner periphery support part, Support heating coil A plurality of ferrite holding portions that hold ferrite on the back surface side, and an annular connecting portion that is connected to end portions of the plurality of ferrite holding portions and is located outside the heating coil, and the annular connecting portion A jet guide taper in which a back side edge is notched is provided on the inner side where the outermost periphery of the heating coil is located between adjacent ferrite holding portions.

In the induction heating cooker according to the present invention, the air taken from the air inlet of the cooling chamber by the rotation of the air cooling fan becomes an air flow and flows along the semiconductor circuit device and the circuit board in the cooling chamber, these are air-cooled, When a cooling air jet flows through a plurality of jet blowout holes of the jet plate arranged on the exhaust port side of the cooling chamber, and the jet cools the lower surface of the heating coil through the fan-shaped opening of the adjacent ferrite holding portion, The cooling air jet blown from the jet blow hole provided at the position outside the vertical bottom of the outer periphery of the heating coil is located at the outermost periphery of the heating coil between the adjacent ferrite holding portions of the annular coupling portion of the coil support. The outer periphery of the heating coil that hits the jet guide taper that is notched in the back side edge provided inside, is guided by the jet guide taper, and is usually hard to be hit by the jet of cooling air It can be the surface efficiently cooled.
In addition, the jet of cooling air guided by the jet guide taper efficiently cools the outer peripheral lower surface of the heating coil, and the jet does not hit the top plate, so the top plate never cools, And the influence on the temperature detecting device in contact with the top plate is eliminated.

The perspective view of the induction heating cooking appliance of Embodiment 1 of this invention. The sectional side view of the induction heating cooking appliance. The top view of the heating coil support body which supported the heating coil of the induction heating cooking appliance. The bottom view of the heating coil support body which supported the heating coil of the induction heating cooking appliance. VV sectional view taken on the line of FIG. The fragmentary sectional view which shows the periphery of the heating coil support body which supported the heating coil of the induction heating cooking appliance in detail. The top view of the heating coil support body which supported the heating coil of the induction heating cooking appliance of Embodiment 2 of this invention. The bottom view of the heating coil support body which supported the heating coil of the induction heating cooking appliance. The fragmentary sectional view which shows the periphery of the heating coil support body which supported the heating coil of the induction heating cooking appliance in detail. Sectional drawing which shows the modification of the heating coil support body which supported the heating coil of the induction heating cooking appliance. The top view of the heating coil support body which supported the heating coil of the induction heating cooking appliance of Embodiment 3 of this invention. The bottom view of the heating coil support body which supported the heating coil of the induction heating cooking appliance. The fragmentary sectional view which shows the periphery of the heating coil support body which supported the heating coil of the induction heating cooking appliance in detail.

Embodiment 1 FIG.
1 is a perspective view of an induction heating cooker according to Embodiment 1 of the present invention, FIG. 2 is a side sectional view of the induction heating cooker, and FIG. 3 is a heating coil support that supports a heating coil of the induction heating cooker. 4 is a bottom view of the heating coil support that supports the heating coil of the induction heating cooker, FIG. 5 is a cross-sectional view taken along line VV of FIG. 3, and FIG. 6 is a heating coil of the induction heating cooker. It is a fragmentary sectional view which shows the periphery of the heating coil support body which supported A in detail.
As shown in FIG. 1, the upper opening of the substantially box-shaped main body case 1 of the heating cooker according to the first embodiment is made of a nonmagnetic material such as heat-resistant glass, and a top support frame 2 is provided on the outer periphery. The flat top plate 3 is detachably mounted. And on the upper surface of the top plate 3, a plurality of placement position display portions 4a to 4c indicating the placement position of the heated cooking container N such as a metal pan are provided by printing. In addition, an intake port 5 is provided on the right side of the rear portion of the top support frame 2, and an exhaust port 6 is provided on the left side of the rear portion.

Two heating coils 7 on the left and right, which are induction heating sources for induction heating of a heated cooking container such as a metal pan placed on the top plate 3, are provided in the front of the main body case 1. A central heating source (not shown) called a radiant heater, for example, a rear center electric heater for heating with electric radiant heat is provided in the center. The attachment of the heating coil 7 will be described later.
In addition, a grill heating chamber 8 is provided in front of the left side inside the main body case 1. The front opening of the grill heating chamber 8 is covered with a grill door 9 so as to be opened and closed, and the opening and closing operation of the grill door 9 can be performed by a handle 9a protruding forward.

A front operation panel 10 is attached to the right front surface of the main body case 1. Above the front operation panel 10, as shown in FIG. 1, the left and right heating coils 7, the operation button 11 of the main power switch capable of simultaneously turning on / off all the power sources of the central heating source, and the left and right heating Left and right operation dials 12L and 12R for controlling energization of the coil 7 and its energization amount (thermal power), and a central operation dial 12C for controlling energization of the central heating source and its energization amount (thermal power) are provided.
Further, three independent timer dials 13L, 13R, and 13C are provided below the front operation panel 10. The timer dials 13L, 13R, and 13C are energized for a desired time (timer set) from the start of energization of the left and right heating coils 7 and the central heating source, respectively, and automatically turn off the power after the set time has elapsed. Is for operating.

Further, an integrated liquid crystal display unit 15 is provided in the center of the front side 3 in the left-right direction, and liquid crystal display units 16 </ b> L and 16 </ b> R are provided on the left and right sides of the integrated liquid crystal display unit 15.
The integrated liquid crystal display unit 15 displays energization states (thermal power, time, etc.) of the left and right IH coils, the central heating source, and the heater of the grill heating chamber 8.
Further, when the left and right liquid crystal display units 16L and 16R operate the timer switches in the left and right heating coils 7 for timer cooking, the elapsed time from the start time is measured and displayed in numbers. Reference numerals 17L and 17R denote heating power display units for the left and right heating coils 7, and reference numeral 17C denotes a thermal power display unit for the central heating source.

As shown in FIG. 2, a cooling chamber 18 extending in the front-rear direction is formed on the right side in the main body case 1. In the cooling chamber 18, two air paths of an upper air path 21 and a lower air path 22 are formed by a partition plate 19 that extends vertically downward from the rear portion of the top plate 3 and extends horizontally forward. .
The rear portion of the lower air passage 22 is communicated with the intake port 5 provided on the right side of the rear portion of the top support frame 2, and the front portion of the lower air passage 22 is communicated with the front portion of the upper air passage 21. . The rear portion of the upper air passage 21 is communicated with the exhaust port 6 provided on the left side of the rear portion of the top plate support frame 2.

The lower air passage 22 is provided with two drive circuit boards 25 on which the semiconductor drive circuit device 24 such as a series of power modules for supplying a large current to the left and right heating coils 7 and the central heating source is mounted up and down. Yes. A cooling fan 26 for air-cooling the heating coil 7 and the semiconductor circuit device 24 is provided on the rear side of the lower air passage 22.
The cooling fan 26 is designed to be driven according to heat generated by the heating coil 7 and the semiconductor circuit device 24.

A jet plate support member 28 extending horizontally from the middle of the partition plate 19 toward the front is provided in the upper air passage 21. The jet plate support member 28 is provided with an opening 29 having a diameter substantially the same as the diameter of the heating coil 7.
A wind guide tube 31 attached to the periphery of the lower surface of the circular jet plate 30 is fixed to the peripheral portion of the opening 29 of the jet plate support member 28.
Further, a leg 33 provided on the periphery of a circular heating coil support 32 formed of a heat resistant resin such as PET or PBT is fixed to the outer periphery of the jet plate 30.

The circular heating coil support 32 has a disk-shaped coil inner periphery support portion 34 that supports the inner periphery side of the heating coil 7, and extends radially from the coil inner periphery support portion 34. A plurality of ferrite holding portions 35 that support and hold the ferrite 38 on the back surface side, and are connected to end portions of the plurality of ferrite holding portions 35 and an annular connecting portion 36 that is located outside the heating coil 7. Are united.
The surfaces of the coil inner periphery support part 34, the ferrite holding part 35, and the annular connection part 36 are formed flush with each other. Moreover, the ferrite holding part 35 has the recessed part 35a which fits and holds the ferrite 38 on the back surface side.

In the first embodiment, as shown in FIG. 6, the back side edge is notched in the inner side 36 a where the outermost periphery of the heating coil 7 is located between the adjacent ferrite holding portions 35 of the annular coupling portion 36 of the heating coil support 32. A concave arc-shaped jet guide taper 40 is provided.
Further, as shown in FIG. 5, the circular jet plate 30 positioned immediately below the circular heating coil support 32 is annularly formed from the position immediately below the coil inner peripheral support portion 34 and the outer edge 40 a of the arc-shaped jet guide taper 40. A plurality of jet blowout holes 30a are provided except for a position immediately below the portion S reaching the outer peripheral edge of the connecting portion 36. In other words, the jet plate 30 is also provided with jet jet holes 30 a at positions away from the vertical bottom of the outer periphery of the heating coil 7.
In addition, each of the jet blowout holes 30a is curved so that the diameter of the inlet side becomes wider so that the wind can easily enter.

Then, when the air cooling fan 26 rotates, the air taken in from the intake port 5 becomes an air flow and flows along the semiconductor circuit device 24 and the circuit board 25 in the lower air passage 22 as indicated by arrows, Air-cool.
This air flow further enters the upper air passage 21 from the lower air passage 22 and becomes a jet of cooling air from the upper air passage 21 through the plurality of jet outlet holes 30a of the jet plate 30 through the wind guide tube 31. The lower surface of the heating coil 7 is cooled through the fan-shaped openings of the ferrite holding portions 35 adjacent to each other.

At this time, the jet of the cooling air blown from the jet blow hole 30a provided at a position off the vertical periphery of the outer periphery of the heating coil 7 is between the adjacent ferrite holding portions 35 of the annular coupling portion 36 of the heating coil support 32. In the inner side 36a where the outermost periphery of the heating coil 7 is located, it hits an arc-shaped jet guide taper 40 with a notch on the back side edge, and is guided and aggregated by the jet guide taper 40, and usually a jet of cooling air hits it. It is possible to efficiently cool the lower outer peripheral surface of the heating coil 7 which is difficult.
Moreover, the jet of cooling air guided and gathered by the jet guide taper 40 efficiently cools the outer peripheral lower surface of the heating coil 7, and the jet does not hit the top plate 3. In addition, there is no influence on the top plate 3 or the temperature detecting device in contact with the top plate 3.

Embodiment 2. FIG.
7 is a top view of a heating coil support that supports the heating coil of the induction heating cooker according to Embodiment 2 of the present invention, and FIG. 8 is a bottom view of the heating coil support that supports the heating coil of the induction heating cooker. FIG. 9 is a partial sectional view showing in detail the periphery of the heating coil support that supports the heating coil of the induction heating cooker, and FIG. 10 shows a modification of the heating coil support that supports the heating coil of the induction heating cooker. FIG.
In the second embodiment, the same configurations as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, and the description of the overlapping configurations is omitted.
In the first embodiment, the heating coil 7 is single, whereas in the second embodiment, the heating coil 7 is double, and the inner heating coil 7a and the outer heating coil 7a are spaced apart from each other. The outer heating coil 7b is provided on a concentric circle.
Therefore, the configuration of the heating coil support 32 is also different from that of the first embodiment.

The heating coil support 42 according to the second embodiment includes a circular coil inner periphery support portion 44 that supports the inner periphery side of the inner heating coil 7a, a radial extension from the coil inner periphery support portion 44, and inner heating on the surface side. The outer peripheral side of the coil 7a and the outer heating coil 7b are supported, and a plurality of ferrite holding portions 45 holding the ferrite 38 on the back side are connected to the ends of the plurality of ferrite holding portions 45, and outside the outer heating coil 7b. An annular connecting portion 46 that is positioned, and an intermediate connecting portion 47 that is located between the outer periphery of the inner heating coil 7a and the inner periphery of the outer heating coil 7b and connects the intermediate portions of the plurality of ferrite holding portions 45, These are united.
The surfaces of the coil inner periphery support portion 44, the ferrite holding portion 45, the annular connecting portion 46, and the intermediate connecting portion 47 are formed flush with each other. Moreover, the ferrite holding part 45 has the recessed part 45a which fits and holds the ferrite 38 on the back surface side.

In the second embodiment, as shown in FIG. 9, the back side of the intermediate connecting portion 47 has an arc-shaped inner jet guide taper 41a that is recessed by notching the back-side inner edge portion and an arc-shaped shape that is notched and recessed at the back-side outer edge portion. , And a jet guide taper 41b on the outer side.
Further, as shown in FIG. 9, the circular jet plate 30 positioned immediately below the circular heating coil support 32 includes a plurality of jet blowouts except for the positions directly below the coil inner peripheral support portion 34 and the annular coupling portion 46. A hole 30a is provided.
Also in the second embodiment, the jet of cooling air that has passed through the plurality of jet outlets 30a of the jet plate 30 cools the lower surface of the heating coil 7 through the fan-shaped openings of the ferrite holding portions 45 adjacent to each other.

At this time, it is provided on the back side of the intermediate connecting portion 47 and is a jet of cooling air that hits the arc-shaped inner jet guide taper 41a with the inner edge cut out and the arc-shaped outer jet guide taper 41b with the outer edge cut out. The jet hitting the jet guide taper 41a is guided by the inner jet guide taper 41a to cool the lower surface on the outer peripheral side of the inner heating coil 7a, which is usually difficult to cool, and the jet hitting the outer jet guide taper 41b is outside. It is possible to efficiently cool the lower surface on the inner peripheral side of the outer heating coil 7b by being guided by the jet guide taper 41b.
In the second embodiment, the top plate 3 is not jetted, so that the top plate 3 is not cooled, and there is no influence on the top plate 3 or the temperature detecting device in contact with the top plate 3.

FIG. 10 shows a modification of the heating coil support that supports the heating coil of the induction heating cooker according to the second embodiment of the present invention.
In this modified example, an arc-shaped jet guide taper 41 c that is notched and recessed so as to reach from the inner edge portion to the outer edge portion is provided on the back side of the intermediate connecting portion 47.
In this modification, the jet of cooling air that hits the arc-shaped jet guide taper 41c provided on the back side of the intermediate connecting portion 47 and cut out from the inner edge to the outer edge is guided by the jet guide taper 41c. Usually, the outer peripheral side of the inner heating coil 7a, which is difficult to cool, is gathered and cooled.
Further, the lower surface of the outer heating coil 7b cools the lower surface of the outer heating coil 7b through an opening formed by the intermediate connecting portion 47, the annular connecting portion 46 and the adjacent ferrite holding portion 45.

Embodiment 3 FIG.
11 is a top view of a heating coil support that supports the heating coil of the induction heating cooker according to Embodiment 3 of the present invention, and FIG. 12 is a bottom view of the heating coil support that supports the heating coil of the induction heating cooker. FIG. 13 is a partial cross-sectional view showing in detail the periphery of the heating coil support that supports the heating coil of the induction heating cooker.
The third embodiment is configured by combining the configurations of the first embodiment and the second embodiment. The heating coil 7 is a double one, and an interval is provided between the inner heating coil 7a and the outer heating coil 7a. The outer heating coil 7b is provided on a concentric circle.
The heating coil support 42 according to the third embodiment includes a circular coil inner periphery support portion 44 that supports the inner periphery side of the inner heating coil 7a, a radial extension from the coil inner periphery support portion 44, and inner heating on the surface side. A plurality of ferrite holding portions 45 that support the outer peripheral side of the coil 7a and the outer heating coil 7b and hold the ferrite 38 on the back surface side are connected to the end portions of the plurality of ferrite holding portions 45, and are positioned outside the heating coil 7. And an intermediate connecting portion 47 that is located between the outer periphery of the inner heating coil 7a and the inner periphery of the outer heating coil 7b and connects the intermediate portions of the plurality of ferrite holding portions 45, and Are united.

On the back side of the intermediate connecting portion 47, an arc-shaped inner jet guide taper 41a with an inner edge cut out and an arc-shaped outer jet guide taper 41a with an outer edge cut out are provided.
Further, an arc-shaped jet guide taper 40 with a back side edge notched is provided on the inner side 46a where the outermost periphery of the outer heating coil 7a is located between the adjacent ferrite holding portions 35 of the annular coupling portion 46 of the heating coil support 42. Yes.
Further, as shown in FIG. 13, the circular jet plate 30 positioned immediately below the circular coil support 42 has an annular connecting portion from the position directly below the coil inner peripheral support portion 44 and the outer edge of the arc-shaped jet guide taper 41. Except for the position immediately below the portion S reaching the outer peripheral edge 36, a plurality of jet blowout holes 30a are provided. In other words, the jet plate 30 is provided with jet blow holes 30a at positions outside the vertical periphery of the outer periphery of the outer heating coil 7b.

In the third embodiment as well, the jet of cooling air that has passed through the plurality of jet outlets 30a of the jet plate 30 cools the lower surface of the heating coil 7 through the fan-shaped openings of the ferrite holding portions 45 adjacent to each other.
At this time, a jet of cooling air is provided on the back side of the intermediate connecting portion 47 and hits the arc-shaped inner jet guide taper 41a with the inner edge cut out and the arc-shaped outer jet guide taper 41a with the outer edge cut out. The jet that hits the guide taper 41a is guided by the inner guide taper 41a to cool the lower surface on the outer peripheral side of the inner heating coil 7a, which is normally difficult to cool, and the jet that hits the outer jet guide taper 41b Guided by the guide taper 41b, the inner peripheral lower surface of the outer heating coil 7b can be efficiently cooled.

In addition, the cooling air jet blown from the jet blow hole 30 a provided at a position outside the vertical bottom of the outer periphery of the heating coil 7 is transferred between the ferrite holding portions 45 adjacent to the annular coupling portion 46 of the coil support 42. The heating coil 7b hits an arc-shaped jet guide taper 40 provided in the inner side 46a where the outermost periphery is located, and is guided and aggregated by the jet guide taper 40 to cool the lower surface of the outer heating coil 7. be able to.
Therefore, the lower surface of the outer heating coil 7 is efficiently cooled by the jet stream guided and aggregated by the jet taper 40 and the jet stream guided and aggregated by the outer jet guide taper 41b.
In the third embodiment, since the jet does not hit the top plate 3, the top plate 3 is not cooled, and there is no influence on the top plate 3, the temperature detecting device in contact with the top plate 3, or the like.

  DESCRIPTION OF SYMBOLS 1 Main body case, 2 Top plate support frame, 3 Top plate, 5 Intake port, 6 Exhaust port, 7 Heating coil, 8 Grill heating chamber, 9 Grill door, 10 Front operation panel, 18 Cooling chamber, 19 Partition plate, 21 Top Air path, 22 Lower air path, 24 Semiconductor circuit device, 25 Circuit board, 26 Air cooling fan, 28 Jet plate support member, 29 Opening, 30 Jet plate, 30a Jet blow hole, 31 Wind guide tube, 32 Heating coil support, 33 Leg part, 34 Coil inner periphery support part, 35 Ferrite holding part, 36 Annular connection part, 36a Inner side, 38 Ferrite, 40 Jet guide taper, 40a Outer edge.

Claims (5)

A box-shaped body case with an open top;
A top plate covering the upper opening of the main body case;
A heating coil disposed below the top plate in the main body case;
A cooling chamber that is partitioned in the main body case, includes an air cooling fan therein, and has an intake port and an exhaust port;
A circuit board disposed in the cooling chamber and mounted with a semiconductor circuit device for driving and controlling the heating coil;
A jet plate having a plurality of jet blow holes arranged on the exhaust port side of the cooling chamber and positioned below the heating coil;
In an induction heating cooker that is disposed above the jet plate and includes a heating coil support that supports the heating coil,
The heating coil support body includes a coil inner periphery support portion that supports the inner periphery side of the heating coil, a radial extension from the coil inner periphery support portion, supports the heating coil on the front surface side, and ferrite on the back surface side. A plurality of ferrite holding portions to be held, and connected to end portions of the plurality of ferrite holding portions, are configured integrally with an annular connecting portion located outside the heating coil,
An induction heating cooker, characterized in that a jet guide taper with a back side edge notched is provided on the inner side where the outermost periphery of the heating coil is located between adjacent ferrite holding portions of the annular coupling portion. A box-shaped body case with an open top;
A top plate covering the upper opening of the main body case;
An induction heating source comprising an inner coil disposed below the top plate in the main body case and an outer coil disposed concentrically with the inner coil;
A cooling chamber that is partitioned in the main body case, includes an air cooling fan therein, and has an intake port and an exhaust port;
A circuit board that is disposed in the cooling chamber and on which a semiconductor circuit device that drives and controls the induction heating source is mounted;
A jet plate having a plurality of jet outlets disposed on the exhaust port side of the cooling chamber and positioned below the induction heating type heating source;
In an induction heating cooker that is disposed above the jet plate and includes a heating coil support that supports the induction heating source.
The heating coil support includes a circular coil inner periphery support portion that supports an inner periphery side of the inner heating coil, a radial extension from the coil inner periphery support portion, and an outer periphery side of the inner heating coil and the outer surface on the surface side. A plurality of ferrite holding portions that support the heating coil and hold the ferrite on the back surface side, are connected to end portions of the plurality of ferrite holding portions, and are located outside the outer heating coil, and the inner heating coil Between the outer periphery of the outer heating coil and the inner periphery of the outer heating coil are integrally formed with an intermediate connection portion connecting intermediate portions of the plurality of ferrite holding portions,
An induction heating cooker characterized in that an inner jet guide taper with an inner edge cut out is provided on the back side of the intermediate connecting portion.   The induction heating cooker according to claim 2, wherein an outer jet guide taper having an outer edge cut out is provided on the back side of the intermediate connecting portion.   4. The induction heating according to claim 2, wherein a jet guide taper in which a back side edge is notched is provided on an inner side where an outermost periphery of the outer heating coil is located between adjacent ferrite holding portions of the annular coupling portion. Cooking device.   The induction heating cooker according to any one of claims 1 to 4, wherein the jet guide taper is formed in a concave arc shape.

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