JP7274848B2 - heating cooker - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating cooker having a heating coil and a heat sink that dissipates heat from a driving element of an inverter circuit that supplies high-frequency current to the heating coil.

A heating cooker equipped with a heating coil is provided with a structure for cooling built-in parts. As such a cooking device, there has been proposed one provided with a fan device for cooling a heating coil and a fan device for cooling a heat sink of a high heat generating element (see, for example, Patent Document 1). In the heating cooker described in Patent Document 1, a fan device and a heating coil are arranged so as to overlap each other in the vertical direction, and another fan device and a heat sink are arranged so as to overlap each other in the vertical direction.

JP 2013-26169 A

The heating cooker described in Patent Literature 1 cools the heating coil and the heat sink using fan devices provided respectively. However, as disclosed in FIG. 4 of Patent Document 1, the cooling air sent from the fan device toward the heat sink flows not only to the rear of the main body in which the exhaust port is formed, but also to the front. . If there is a flow of cooling air from the rear to the front in this way, the high-temperature air after cooling the object to be cooled cannot be smoothly discharged from the exhaust port, resulting in a decrease in the cooling efficiency of the heating coil and the heat sink.

SUMMARY OF THE INVENTION The present invention has been made against the background of the problems described above, and provides a heating cooker capable of enhancing the cooling efficiency of a heating coil and a heat sink.

A heating cooker according to the present invention includes a top plate, a heating coil provided under the top plate, a first fan, and a first fan housing the first fan and having an inlet and an outlet. A fan case, a second fan provided to the rear of the first fan, a fan housing the second fan, an air intake port and an air outlet formed therein, and at least in the width direction with respect to the first fan case when viewed from the front. a second fan case provided so as to partially overlap; and a first air guide member forming a first air guide passage having an inlet connected to the outlet of the first fan case and a first outlet. a drive element included in an inverter circuit that supplies a high-frequency current to the heating coil; and a heat sink attached to the drive element and arranged in the first air guide path , wherein the heating coil and a second heating coil located farther from the first fan than the first heating coil, wherein the outlet of the second fan case defines a first portion and a second portion. a second air guide member forming a second air guide having an inlet connected to the first portion of the outlet of the second fan case and a first outlet formed below the second heating coil; wherein the second part of the outlet of the second fan case is not connected to the second air guide path and is arranged below the first heating coil, and the first fan case is supplied to the first air guide passage, the cooling air sent from the first portion of the second fan case is supplied to the second air guide passage, and the second Cooling air sent from the second portion of the two-fan case is supplied below the first heating coil .

According to the present invention, the first fan and the second fan are arranged side by side in the front-rear direction, and the first fan case accommodating the first fan and the second fan case accommodating the second fan have a width when viewed from the front. are arranged so that at least a part of them overlaps in the direction. By arranging the first fan and the second fan arranged side by side in the front-rear direction in such a manner that the first fan case and the second fan case overlap in the width direction, the first fan and the second fan in the width direction 2 fans are arranged close to each other. Cooking appliances are generally placed on a kitchen table or installed in a built-in manner. In this installed state, there is a closed space behind the cooking appliance and an open space in front of the cooking appliance. In such an installation state, the first fan, which is placed in front and closer to the open space, can draw air at a lower temperature than the second fan. A heat sink is arranged in the air guide path connected to the outlet of the first fan case of the first fan that sucks relatively low-temperature air. Since the heat sink has a lower temperature than the heating coil, the heat sink can be efficiently cooled by using relatively low-temperature air sucked from the first fan. Further, a first air guide member forming an air guide having an inlet connected to the outlet of the first fan is provided. The trapped air is less likely to contact the heat sink. Therefore, a decrease in cooling efficiency of the heat sink due to the cooling air blown out from the second fan to cool the other components and reach a high temperature is suppressed.

1 is a perspective view of kitchen furniture 200 in which cooking device 100 according to Embodiment 1 is installed. FIG. Fig. 2 is a perspective view of the heating cooker 100 according to Embodiment 1 with the top plate 1 and the exhaust port cover 5 removed. Fig. 2 is a perspective view from below of the heating cooker 100 according to Embodiment 1; FIG. 2 is a diagram illustrating the internal structure of cooking device 100 according to Embodiment 1. FIG. Fig. 2 is a perspective view illustrating the internal structure of cooking device 100 according to Embodiment 1; 4A and 4B are diagrams illustrating the structure of the air guide member 40 according to the first embodiment; FIG. FIG. 3 is a diagram for explaining the flow of cooling air in cooking-by-heating device 100 according to Embodiment 1; Fig. 2 is a vertical cross-sectional view of the cooker 100 according to Embodiment 1 in the front-rear direction passing through the first fan case 20 and the second fan case 30; Fig. 3 is a vertical cross-sectional view in the front-rear direction passing through a second outlet 54 of the heating cooker 100 according to Embodiment 1; Fig. 2 is a vertical cross-sectional view of the heating cooker 100 according to Embodiment 1 in the front-rear direction passing through the first outlet 43 of the first air guide passage 41; FIG. 10 is a perspective view of the cooking device 100 according to Embodiment 2 with the top plate 1 removed. FIG. 11 is a partial perspective view centered on an air guide member 40A, a first heating coil 9A, and a second heating coil 9B according to Embodiment 2; FIG. 11 is a perspective view centering on a wind guide member 40 according to Embodiment 2; FIG. 11 is a perspective view showing a part of the air guiding member 40 according to the second embodiment. FIG. 11 is a transverse cross-sectional view of cooker 100 according to Embodiment 2, taken through third air guide passage 61A. FIG. 11 is a transverse cross-sectional view of the cooker 100 according to Embodiment 2, taken through the first air guide passage 41A. FIG. 10 is a perspective view of kitchen furniture 200 on which cooking device 100 according to Embodiment 3 is installed. FIG. 11 is a perspective view illustrating the internal structure of cooking-by-heating device 100 according to Embodiment 3; Fig. 11 is a bottom perspective view illustrating the internal structure of cooking device 100 according to Embodiment 3; It is a front side perspective view explaining the internal structure of the cooking-by-heating appliance 100 which concerns on Embodiment 3. FIG. FIG. 11 is an exploded perspective view of cooking-by-heating device 100 according to Embodiment 3; It is a figure explaining the structure which supplies a cooling air to the lower side of the drive board|substrate 11 of the heating cooker 100 which concerns on Embodiment 3. FIG. FIG. 11 is a cross-sectional view of the cooking device 100 according to Embodiment 3, passing through the first fan 21 and the second fan 31; FIG. 11 is a plan view of a first front cover 93 and a first intake duct 86 according to Embodiment 3; FIG. 25 is a cross-sectional view taken along line AA of FIG. 24; FIG. 25 is a cross-sectional view taken along the line BB of FIG. 24; FIG. 10 is a perspective view of a cooking chamber 81 and peripheral parts thereof according to Embodiment 3; FIG. 11 is a perspective view of an air guide duct 88 and peripheral parts thereof according to Embodiment 3; FIG. 11 is a vertical cross-sectional view of cooker 100 according to Embodiment 3, passing through third fan case 90 . FIG. 11 is a vertical cross-sectional view passing through a first heating device 821 and a second heating device 822 of the cooking device 100 according to Embodiment 3; FIG. 10 is a vertical cross-sectional view of cooking device 100 according to Embodiment 3 at a position passing through second vent 107 and third vent 108 and at a position outside the width of cooking chamber 81 to the left.

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which a heating cooker according to the present invention is applied to a built-in induction heating cooker will be described below with reference to the drawings. The present invention is not limited to the following embodiments, and various modifications can be made without departing from the gist of the present invention. In addition, the present invention includes all possible combinations of the configurations shown in the following embodiments. Further, the heating cooker shown in the drawings is an example of equipment to which the heating cooker of the present invention is applied, and the applicable equipment of the present invention is not limited to the heating cooker shown in the drawings. . In addition, in the following description, terms representing directions (for example, “up”, “down”, “right”, “left”, “front”, “back”, etc.) are used as appropriate for ease of understanding. They are for illustrative purposes and are not intended to limit the invention. Further, in the following description, "upstream side" and "downstream side" refer to the upstream side and the downstream side in the flow of the cooling air. Also, in each figure, the same reference numerals denote the same or corresponding parts, which are common throughout the specification. In each drawing, the relative dimensional relationship, shape, etc. of each component may differ from the actual one.

Embodiment 1.
FIG. 1 is a perspective view of kitchen furniture 200 on which cooking device 100 according to Embodiment 1 is installed. As shown in FIG. 1, the heating cooker 100 is incorporated in kitchen furniture 200 and used. The kitchen furniture 200 has a flat kitchen top plate 201 used as a workbench, and the top plate 1 of the heating cooker 100 is exposed on the kitchen top plate 201 . The kitchen furniture 200 is provided with a storage 202 below the heating cooker 100 . In this specification, the “front surface” of the heating cooker 100 and the “front surface” of the kitchen furniture 200 refer to the surface facing the user of the heating cooker 100 or the kitchen furniture 200, and in the example of FIG. The door side of 202 is the "front".

Heat cooker 100 of the present embodiment does not include a heating chamber such as a grill or an oven in first housing 10 (see FIG. 2), and first housing 10 is formed on kitchen top plate 201. The heating cooker 100 is installed in the kitchen furniture 200 by being inserted into the opening. It is desirable that the thickness of the portion of the cooking device 100 inserted into the opening of the kitchen top plate 201 be equal to or less than the thickness 203 of the kitchen top plate 201 . Here, the thickness of the portion of the cooking device 100 that is inserted into the opening of the kitchen top plate 201 is the back surface of the top plate frame 105 (see FIG. 2) provided around the top plate 1 in this embodiment. and the outer surface of the bottom of the first housing 10 (see FIG. 2). If the thickness of the portion of the heating cooker 100 inserted into the opening of the kitchen top plate 201 is greater than the thickness 203 of the kitchen top plate 201, the height of the storage compartment 202 is restricted, and the storage capacity of the storage compartment 202 is reduced. This is because the Moreover, there is a possibility that the items stored in the storage compartment 202 and the heating cooker 100 may come into contact with each other. In addition, in the industry standard for kitchen furniture, the thickness of the front end of the kitchen top plate 201 is 40 mm. Therefore, it is desirable that the thickness of the portion of the heating cooker 100 that is inserted into the opening of the kitchen top plate 201 is 40 mm or less. By doing so, it is possible to secure the storage amount of the storage 202 and to suppress the contact between the items stored in the storage 202 and the heating cooker 100 .

A heating cooker 100 has a first housing 10 (see FIG. 2), and a top plate 1 on which a cooking container, which is an object to be heated, is placed is provided on the first housing 10. . The top plate 1 is provided with two heating ports 2 in this embodiment. The number of heating ports 2 is not limited, and one or three or more heating ports 2 may be provided.

An exhaust port cover 5 is provided on the rear side of the heating cooker 100 to cover the housing exhaust port 4 (see FIG. 2) through which the exhaust air from the first housing 10 flows out. The exhaust port cover 5 is provided with an opening through which ventilation is possible. The opening provided in the exhaust port cover 5 can be, for example, a slit-shaped opening having a width equal to or slightly smaller than the width of the exhaust port cover 5 .

FIG. 2 is a perspective view of the cooker 100 according to Embodiment 1 with the top plate 1 and the exhaust port cover 5 removed. The same number of heating coils as the heating ports 2 are provided in the first housing 10 . In this embodiment, a first heating coil 9A and a second heating coil 9B are provided. The first heating coil 9</b>A and the second heating coil 9</b>B have the same basic structure and function, and are arranged side by side in the first housing 10 . The size, shape, and number of turns of the conductor wire of the first heating coil 9A and the second heating coil 9B may be different from each other.

An operation unit 6 is provided on the front side of the heating cooker 100 to receive an operation input from the user. The operation unit 6 may be composed of, for example, push buttons, dial switches, capacitive touch switches, etc. In the present embodiment, the capacitive touch switches are used. When the user touches the top plate 1 (see FIG. 1), the touch switch of the operation unit 6 detects a change in capacitance and accepts it as an operation input. A display unit 7 is provided on the front side of the top plate 1 . The display unit 7 has a device for visually notifying information such as a liquid crystal display and an LED, and indicates the operating state such as the heating power of the heating cooker 100 and the time of the timer, as well as information for the user to input with the operation unit 6. Notification of options, user warnings and alerts. The display contents of the display unit 7 are visually recognized by the user through the top plate 1 (see FIG. 1).

The first housing 10 has a bottom plate 101 . The first housing 10 has a front plate 102, a rear plate 103 (see FIG. 2), and a pair of left and right side plates 104 as four side walls. are doing.

A first fan case 20 and a second fan case 30 are provided in the first housing 10 at positions closer to the first heating coil 9A than the second heating coil 9B in the left-right direction. The first fan case 20 and the second fan case 30 are provided below the first heating coil 9A. The positions of the first fan case 20 and the second fan case 30 in the left-right direction are determined so that the first fan case 20 and the second fan case 30 overlap in the left-right width direction when viewed from the front ( See Figure 7). A wind guide member 40 is connected to the first fan case 20 and the second fan case 30, the details of which will be described later.

A power supply control board 14 is provided above the bottom plate 101 of the first housing 10 and below the second heating coil 9B. The power control board 14 is a board on which a circuit for supplying power to electric components of the heating cooker 100 including the drive board 11 (see FIG. 4) is mounted. The power supply control board 14 is connected to the operation section 6 and the display section 7 and controls the circuits mounted on the display section 7 and the drive board 11 (see FIG. 4) based on the input from the operation section 6 .

The first housing 10 has a top plate frame 105 projecting outward from its upper end. A top plate frame 105 located on the rear side of the first housing 10 is provided with a housing exhaust port 4 that communicates with the inside of the first housing 10 . In this embodiment, the number of housing exhaust ports 4 is the same as that of heating ports 2, that is, two, but this number is not limited. The housing exhaust port 4 of the present embodiment is configured by one rectangular hole elongated in the left-right direction, but the number and shape of the holes constituting the housing exhaust port 4 are not limited to those illustrated. The air in the first housing 10 flowing out from the housing exhaust port 4 is exhausted through an opening provided in the exhaust port cover 5 (see FIG. 1). It is preferable that the widths of the openings provided in the housing exhaust port 4 and the exhaust port cover 5 (see FIG. 1) are nearly equal. More preferably, the width of the opening provided in the exhaust port cover 5 (see FIG. 1) is larger than the width of the housing exhaust port 4 . By doing so, the pressure loss of the exhaust from the housing exhaust port 4 to the opening of the exhaust port cover 5 is reduced.

FIG. 3 is a perspective view from below of the heating cooker 100 according to Embodiment 1. FIG. The bottom plate 101 is provided with a housing air intake port 3 on the same side as the first fan case 20 and the second fan case 30 in the horizontal direction of the bottom plate 101 . In this embodiment, the number of housing air intake ports 3 is the same as the total number of the first fan case 20 and the second fan case 30, namely two. The housing air inlet 3 of the present embodiment is composed of a plurality of holes formed in the bottom plate 101, but the number and shape of the holes forming the housing air inlet 3 are not limited to those illustrated.

A drain port 8 is formed in the rear bottom surface of the first housing 10 . The drain port 8 is an opening for discharging liquid such as a boiled-over liquid that has entered the first housing 10 from the first housing 10 . The drain ports 8 of the present embodiment are provided at the left and right ends of the first housing 10, respectively, but the number and positions of the drain ports 8 are not limited to those illustrated.

FIG. 4 is a diagram illustrating the internal structure of cooking device 100 according to Embodiment 1. As shown in FIG. FIG. 4 shows a rear side perspective view from which the operation part 6, the display part 7, the first heating coil 9A and the second heating coil 9B are removed from FIG. A first coil baffle plate 71 is provided behind the second fan case 30 . The first coil baffle plate 71 is composed of an arc-shaped plate member, and stands on the bottom plate 101 so that its surface is perpendicular to the bottom plate 101 . The first coil baffle plate 71 is arranged along the outline of the first heating coil 9A (see FIG. 2). A second portion 322, which is a part of the outlet of the second fan case 30, is not connected to the second air guide passage 51 and opens in the area surrounded by the arc of the first coil air guide plate 71. ing. Cooling air is blown out from the second portion 322 of the outlet of the second fan case 30 to the area surrounded by the first coil baffle plate 71 , and the first coil baffle plate placed on the first coil baffle plate 71 blows out the cooling air. 1 Cooling air is sent to the bottom surface of the heating coil 9A. By providing the first coil air guide plate 71, diffusion of the cooling air into the first housing 10 is suppressed, so that the cooling air from the second fan case 30 can be efficiently sent to the first heating coil 9A. can be done.

The air guide member 40 forms a space between itself and the bottom plate 101 to accommodate at least a portion of the drive board 11 . Cooling air from the first fan case 20 and the second fan case 30 is sent into the air guide member 40 . The air guide member 40 is provided with a first outlet 43 and a first outlet 53 at two locations. The upper wall 44 of the air guide member 40 is provided with second outlets 54 and 64 . These exits will be described later.

FIG. 5 is a perspective view illustrating the internal structure of cooking device 100 according to Embodiment 1. FIG. FIG. 5 is a front side perspective view of FIG. 4 with the first fan case 20, the second fan case 30 and the air guide member 40 removed. A housing intake port 3 is formed below the first fan case 20 and the second fan case 30 (see FIG. 4).

A drive element 12 is mounted on the drive substrate 11 . The drive element 12 is an element that generates a large amount of heat, such as a switching element, included in an inverter circuit that supplies high-frequency current to the first heating coil 9A and the second heating coil 9B. Drive elements 12 include, for example, IGBTs and diode bridges. The drive element 12 is thermally connected with the heat sink 13 . In the present embodiment, a plurality of drive elements 12 are arranged along the horizontal direction of the first housing 10 . The heat sink 13 is composed of a plurality of horizontally oriented metal flat plates which are vertically spaced apart from each other. The gap between the metal flat plates of the heat sink 13 penetrates to the left and right, and serves as an air passage for cooling air.

FIG. 6 is a diagram illustrating the structure of the air guide member 40 according to the first embodiment. In FIG. 6, the air guide member 40 is seen through. Below the air guide member 40, three air guide paths, a first air guide path 41, a second air guide path 51, and a third air guide path 61, are formed. A first partition plate 45 extending vertically along the horizontal direction divides the space below the upper wall 44 into the first air passage 41 and the second air passage 51 . A second partition plate 46 extending vertically in an arc shape in a plan view divides the space below the upper wall 44 into a second air passage 51 and a third air passage 61 .

The first air guide passage 41 has an inlet 42 and a first outlet 43 . The heat sink 13 (see FIG. 5) and the driving element 12 (see FIG. 5) thermally connected thereto are accommodated in the first air guide passage 41 . The first air guide passage 41 is an air passage for supplying cooling air to the heat sink 13 . The first outlet 43 is provided with a first outlet baffle plate 48 having an inclined surface rising from the front to the rear. The cooling air flowing out of the first outlet 43 is guided by the upper surface of the ascending first outlet baffle plate 48 and flows upward.

The second air guide passage 51 has an inlet 52 , a first outlet 53 and a second outlet 54 . The second air passage 51 is an air passage for supplying cooling air to the second heating coil 9B and the first heating coil 9A (see FIG. 2). A first outlet 53 of the second air passage 51 is located below the front portion of the second heating coil 9B (see FIG. 2). The height of the first outlet 53 is approximately the same as the distance between the lower surface of the upper wall 44 and the upper surface of the bottom plate 101 . A second outlet 54 of the second air guide path 51 is an opening formed in the upper wall 44 of the air guide member 40 . The second outlet 54 is positioned below the first heating coil 9A (see FIG. 2) and faces the lower surface of the first heating coil 9A.

The third air guide passage 61 has an inlet 62 , a first outlet 63 and a second outlet 64 . The third air guide passage 61 is an air passage for supplying cooling air to the first heating coil 9A (see FIG. 2). The third air guide passage 61 of the present embodiment is formed generally semicircular in plan view. The first outlet 63 opens only in the upper part of the vertical range of the third air guide passage 61 , and the height dimension of the opening of the first outlet 63 is smaller than the height dimension of the third air guide passage 61 . Furthermore, at least part of the first outlet 63 is open above the upper surface of the second fan case 30 (see FIG. 7). A second outlet 64 is an opening formed in the top wall 44 . A second outlet 64 is located below the first heating coil 9A (see FIG. 2).

The inlet 42 of the first air passage 41 and the inlet 62 of the third air passage 61 are connected to the first fan case 20 (see FIG. 4). In addition, the inlet 52 of the second air guide passage 51 is connected to the second fan case 30 (see FIG. 4).

FIG. 7 is a diagram illustrating the flow of cooling air in cooking-by-heating device 100 according to Embodiment 1. FIG. In FIG. 7 , the cooling air flowing through the air guiding member 40 is conceptually indicated by dashed arrows, and the cooling air flowing out from the air guiding member 40 is conceptually indicated by solid arrows. First, the structures of the first fan case 20 and the second fan case 30 and the structure related to connection between them and the air guide member 40 will be described. The air outlet 22 of the first fan case 20 has a first portion 221 and a second portion 222 . The first portion 221 is a front region of the outlet 22 and is connected to the inlet 42 of the first air guide passage 41 . The second portion 222 is a region located on the rear side of the outlet 22 and is connected to the inlet 62 of the third air guide passage 61 . The first portion 221 and the second portion 222 are arranged horizontally. The air outlet 22 has an opening surface inclined with respect to the front-rear direction. More specifically, in plan view, the first portion 221 and the second portion 222 are positioned with a shift in the left-right direction. The outlet 32 of the second fan case 30 has a first portion 321 and a second portion 322 . The first portion 321 is a region located on the front side of the air outlet 32 and is connected to the inlet 52 of the second air guide passage 51 . The second portion 322 is a region located on the rear side of the outlet 32 , is not connected to the air guide member 40 , and extends toward the space between the air guide member 40 and the first coil air guide plate 71 . It is open.

The cooling air sent out from the first portion 221 of the outlet 22 of the first fan case 20 flows through the first air guide passage 41, contacts the heat sink 13 in the first air guide passage 41, and is heat-transferred. Cool the heat sink 13 . In the present embodiment, a plurality of heat sinks 13 are arranged in two rows in front and behind, and a shielding portion 47 is provided in the gap between the front heat sink 13 and the rear heat sink 13 to block the gap. It's leaking. Therefore, the cooling air does not flow in the gap between the heat sink 13 on the front side and the heat sink 13 on the rear side. Even if the cooling air flows through the gap between the heat sink 13 on the front side and the heat sink 13 on the rear side, the heat sink 13 is not cooled because it does not come into contact with the heat sink 13. Therefore, providing the shielding part 47 does not contribute to the cooling of the heat sink 13. Cooling air volume is suppressed. Further, in the present embodiment, the shielding portion 47 is formed integrally with the air guide member 40, so that the manufacturing cost is suppressed compared to manufacturing these as separate parts.

The cooling air that has flowed through the first air guide passage 41 flows out from the first outlet 43 . The first outlet 43 opens toward the rear, and the first outlet 43 is provided with a first outlet baffle plate 48 (see FIG. 6). Therefore, the cooling air flowing out from the first outlet 43 flows obliquely upward and rearward toward the housing exhaust port 4 arranged in the rear. In the process, the cooling air comes into contact with the second heating coil 9B (see FIG. 2) arranged between the first outlet 43 and the housing exhaust port 4 to cool the second heating coil 9B.

The cooling air sent out from the second portion 222 of the outlet 22 of the first fan case 20 flows into the third air guide passage 61 from the inlet 62 . The cooling air that has flowed into the third air guide passage 61 flows along the arc-shaped second partition plate 46 and is divided into a first outlet 63 and a second outlet 64 to flow out. Since the first outlet 63 opens above the upper surface of the second fan case 30 , the cooling air flowing out from the first outlet 63 flows over the upper surface of the second fan case 30 . Therefore, it is possible to suppress the temperature rise of the second fan case 30, which tends to be heated by the heat from the first heating coil 9A (see FIG. 2). Also, the cooling air flowing out from the first outlet 63 contacts the first heating coil 9A (see FIG. 2) arranged above the first outlet 63 to cool the first heating coil 9A. Also, the cooling air flowing out from the second outlet 64 contacts the first heating coil 9A (see FIG. 2) arranged above the second outlet 64 to cool the first heating coil 9A. Since the first outlet 63 and the second outlet 64 are arranged at different positions in the front-rear direction, the region extending in the front-rear direction of the first heating coil 9A is efficiently cooled. The cooling air that has cooled the first heating coil 9A flows toward the housing exhaust port 4 provided on the rear side.

The air outlet 22 of the first fan case 20 opens toward the right rear portion diagonally to the left front portion of the first housing 10 where the first fan case 20 is arranged. That is, the opening surface of the outlet 22 faces both the right side and the rear side. Therefore, the cooling air sent from the air outlet 22 is directed to the right side of the air outlet 22 where the heat sink 13 is arranged and the rear of the first housing 10 where the second heating coil 9B (see FIG. 2) is arranged. It is easy to be led to both. Therefore, both the heat sink 13 and the second heating coil 9B (see FIG. 2) can be efficiently cooled.

The cooling air sent out from the first portion 321 of the outlet 32 of the second fan case 30 flows into the second air guide passage 51 from the inlet 52 . Part of the cooling air that has flowed into the second air guide passage 51 flows upward from a second outlet 54 formed downstream of the inlet 52 . The cooling air flowing out from the second outlet 54 contacts the first heating coil 9A (see FIG. 2) arranged above the second outlet 54 to cool the first heating coil 9A. The rest of the cooling air that has flowed into the second air guide passage 51 goes straight toward the right side and flows out from the first outlet 53 . The cooling air flowing out from the first outlet 53 joins with the cooling air from the first outlet 43 and flows toward the housing exhaust port 4 arranged in the rear. In the process, the cooling air comes into contact with the second heating coil 9B (see FIG. 2) arranged between the first outlet 53 and the housing exhaust port 4 to cool the second heating coil 9B.

The cooling air sent from the second portion 322 of the outlet 32 of the second fan case 30 flows out to the front side of the first coil baffle plate 71 . This cooling air comes into contact with the first heating coil 9A (see FIG. 2) arranged above the first coil air guide plate 71 to cool the first heating coil 9A.

In the second air guide passage 51 and the third air guide passage 61, there are no components that become hot, such as the driving element 12 and the heat sink 13. As shown in FIG. Therefore, the cooling air supplied to the first heating coil 9A and the second heating coil 9B (see FIG. 2) through the second air passage 51 and the third air passage 61 passes through the first air passage 41. It has a lower temperature than the cooling air that cools the heat sink 13 . Since this low-temperature cooling air is supplied to the first heating coil 9A and the second heating coil 9B, the first heating coil 9A and the second heating coil 9B are efficiently cooled. Therefore, functional deterioration and damage due to the temperature rise of the first heating coil 9A and the second heating coil 9B are suppressed.

In the present embodiment, the cooling air sent from the first fan case 20 and the second fan case 30 passes through the first air passage 41, the second air passage 51, or the third air passage 61. , the first heating coil 9A or the second heating coil 9B. As described above, in the present embodiment, the cooling air from the first fan case 20 and the second fan case 30 is used without waste for cooling the first heating coil 9A or the second heating coil 9B, so the cooling effect is improved. expensive.

FIG. 8 is a vertical cross-sectional view of cooking device 100 according to Embodiment 1 in the front-rear direction through first fan case 20 and second fan case 30 . A first fan 21 is provided in the first fan case 20 . A second fan 31 is provided in the second fan case 30 . When the first fan 21 rotates, a suction force is generated in the housing air inlet 3 . The first fan case 20 is close to the front side of the kitchen top plate 201 in the front-rear direction. Here, the upper side and the lower side of the first housing 10 behind the heating cooker 100 are likely to be heated due to the influence of high temperature exhaust flowing out from the housing exhaust port 4, whereas the front side of the heating cooker 100 are exposed to room air and are relatively cold. The relatively low-temperature air in the room is easily sucked into the first fan 21 through the gap between the kitchen top plate 201 and the storage 202, but is difficult to be sucked into the second fan 31 located on the rear side. . Also, the relatively high-temperature air positioned behind the heating cooker 100 is easily sucked by the second fan 31 positioned on the rear side, but is less likely to be sucked by the first fan 21 positioned on the front side.

That is, the first fan 21 can suck in air with a lower temperature than the second fan 31 and send it out as cooling air. By using the air sent out by the first fan 21 to cool the heat sink 13 of the drive element 12 whose temperature is around 100° C., the heat sink 13 of the drive element 12 can be efficiently cooled. In addition, the second fan 31 draws in air that is hotter than the first fan 21 and sends it out as cooling air. The cooling air generated by the second fan 31 is sent out from the second fan case 30, but as described with reference to FIG. Or it is used for cooling the second heating coil 9B. Since the temperature of the first heating coil 9A and the second heating coil 9B increases to about 180° C. when driven, the temperature of the cooling air sent from the second fan 31 is higher than the temperature of the cooling air from the first fan 21. No, it is possible to cool the first heating coil 9A and the second heating coil 9B. If an attempt is made to cool the heat sink 13 of the driving element 12 with cooling air from the second fan 31 that draws relatively high-temperature air, the temperature difference between the cooling air from the second fan 31 and the heat sink 13 is small. Cooling efficiency of the heat sink 13 may be reduced. However, according to the present embodiment, the heat sink 13 and the first heating coil 9A and the second heating coil 9B utilize the temperature difference between the air sucked by the first fan 21 and the second fan 31 arranged in front of and behind the heat sink 13. can be efficiently cooled.

As described above, according to the present embodiment, the first fan 21 and the second fan 31 are arranged side by side in the front-rear direction as shown in FIGS. In addition, the first fan case 20 that houses the first fan 21 and the second fan case 30 that houses the second fan 31 are arranged so as to at least partially overlap in the left-right width direction when viewed from the front. By arranging the first fan 21 and the second fan 31 arranged side by side in the front-rear direction so that the first fan case 20 and the second fan case 30 overlap in the left-right width direction, , the first fan 21 and the second fan 31 are arranged close to each other. The heating cooker 100 is installed by being placed on or incorporated in the kitchen furniture 200, and in this installed state, there is a closed space behind the heating cooker 100 and an open space in front. In such an installation state, the first fan 21 arranged in front near the open space can draw air with a lower temperature than the second fan 31 . A heat sink 13 is arranged in the first air guide passage 41 connected to the outlet 22 of the first fan case 20 of the first fan 21 that draws in relatively low-temperature air. Since the heat sink 13 has a lower temperature than the heat sink 13 and the first heating coil 9A and the second heating coil 9B, the heat sink 13 is efficiently cooled by using the relatively low temperature air sucked from the first fan 21. can do. Further, an air guide member 40 forming a first air guide passage 41 having an inlet 42 connected to the outlet 22 of the first fan 21 is provided, and the heat sink 13 is arranged in the first air guide passage 41. It is Therefore, the air sent from the second fan 31 is less likely to come into contact with the heat sink 13 . Therefore, a decrease in cooling efficiency of the heat sink 13 due to the cooling air sent from the second fan 31 to cool the other components and reach a high temperature is suppressed. Moreover, the heat sink 13, the first fan case 20, and the second fan case 30 are arranged so as not to overlap each other vertically, and the height dimension of the first housing 10 is suppressed.

Also, the top surface of the first fan case 20 is positioned higher than the top surface of the second fan case 30 . That is, the cooling air blown from the first fan 21 flows at a higher position than the cooling air blown from the second fan 31 . Therefore, the position of the upper surface of the first fan case 20 and the first position of the third air guide passage 61 opening above the upper surface of the second fan case 30 , which is one of the outlets of the cooling air from the first fan 21 . The height position is close to that of the exit 63 . By reducing the height difference between the first fan 21 and the first outlet 63 in this manner, the cooling air from the first fan 21 can be guided to the first outlet 63 in a state of less turbulence. In addition, since the upper surface of the second fan case 30 is positioned lower than the upper surface of the first fan case 20, the height of the space above the second fan case 30 is ensured, and the cooling air flows through this space. Cheap. Therefore, the cooling efficiency of the first heating coil 9A arranged on the second fan case 30 can be enhanced.

FIG. 9 is a vertical cross-sectional view in the front-rear direction passing through the second outlet 54 of the heating cooker 100 according to Embodiment 1. FIG. The heat sink 13 is arranged in the first air guide passage 41 positioned in front of the first partition plate 45 , and the heat sink 13 is cooled by the cooling air flowing through the first air guide passage 41 . A second outlet 54 is provided above the second air guide passage 51 located behind the first partition plate 45 , and the first heating coil 9A is provided above the second outlet 54 . The cooling air flowing out from the second outlet 54 contacts the first heating coil 9A from below the first heating coil 9A. Also, the first heating coil 9A is arranged above the space between the first coil baffle plate 71 and the baffle member 40 . The first heating coil 9</b>A is cooled by the cooling air flowing into the space between the first coil air guide plate 71 and the air guide member 40 .

FIG. 10 is a vertical cross-sectional view of the cooker 100 according to Embodiment 1 in the front-rear direction passing through the first outlet 43 of the first air guide passage 41 . The upper surface of the first outlet baffle plate 48 provided at the first outlet 43 rises from the front to the rear. Therefore, the cooling air flowing out from the first outlet 43 flows obliquely upward. Therefore, the directivity of the cooling air directed toward the second heating coil 9B positioned above the upper end of the first outlet baffle plate 48 is enhanced, and the cooling air is efficiently supplied to the second heating coil 9B.

In this embodiment, an example in which the first air guide passage 41, the second air guide passage 51, and the third air guide passage 61 are configured by the integrally molded air guide member 40 has been described. By doing so, the number of parts is reduced, and an increase in manufacturing cost of the heating cooker 100 is suppressed. However, the specific members constituting the first air passage 41, the second air passage 51 and the third air passage 61 are not limited to the above examples, and the first air passage 41 and the second air passage 51 and part of the third air guide passage 61 may be composed of individual members. That is, a first air guide member, a second air guide member, and a third air guide member that configure the first air guide 41, the second air guide 51, and the third air guide 61, respectively, may be provided.

Embodiment 2.
In the present embodiment, a mode in which an air guide member having a structure different from that of the air guide member 40 of the first embodiment will be described. In this embodiment, differences from the first embodiment will be mainly described, and the same reference numerals will be given to the same configurations as in the first embodiment.

FIG. 11 is a perspective view of cooker 100 according to Embodiment 2 with top plate 1 removed. FIG. 12 is a partial perspective view centering on the air guide member 40A, the first heating coil 9A, and the second heating coil 9B according to the second embodiment. FIG. 13 is a perspective view centering on the air guide member 40 according to the second embodiment. FIG. 14 is a perspective view showing through a part of the air guide member 40 according to the second embodiment. FIG. 15 is a cross-sectional view of cooker 100 according to Embodiment 2, passing through third air guide passage 61A. FIG. 16 is a transverse cross-sectional view of cooker 100 according to Embodiment 2, passing through first air guide passage 41A.

The basic functions of the first air passage 41A, the second air passage 51A, and the third air passage 61A formed by the air guide member 40A are the same as those of the first air passage 41 and the second air passage 41 of the first embodiment. It is the same as the air guide passage 51 and the third air guide passage 61 . That is, the first air guide path 41A guides the cooling air from the first fan case 20 to the heat sink 13. As shown in FIG. The second air guide path 51A guides the cooling air from the second fan case 30 to the first heating coil 9A and the second heating coil 9B. The third air guide passage 61A guides the cooling air from the first fan case 20 to the first heating coil 9A.

As shown in FIG. 13, the air guide member 40A forms an inlet 62A of the third air guide 61A and an inlet 42A of the first air guide 41A which are aligned vertically. Both the inlet 42A and the inlet 62A are connected to the outlet 22 of the first fan case 20. As shown in FIG. The baffle member 40A is provided with a baffle plate 49 standing vertically side by side on the right side of the inlet 42A and the inlet 62A. The baffle plate 49 functions as a wall that partitions a portion of the interior of the first housing 10 into front and rear and guides the cooling air to the rear side. A second coil baffle plate 72 that stands up and down is provided on the right side of the baffle member 40A. The second coil baffle plate 72 has a wall extending in the front-rear direction and a wall extending leftward from the rear end of the wall to form an overall L shape in plan view. The second coil air guide plate 72 has a function of guiding the cooling air flowing out from the air guide member 40 to the second heating coil 9B.

Next, each of the first air passage 41A, the second air passage 51A, and the third air passage 61A will be described in detail.

As shown in FIG. 16, the first air guide path 41A is connected to the lower portion of the outlet 22 of the first fan case 20 that opens rearward. The lower portion of blower port 22 corresponds to first portion 221 in the first embodiment. The first air guide passage 41A extends rearward from the inlet 42A and then extends forward right. A first outlet 43A of the first air guide passage 41A is located downstream of the heat sink 13 as in the first embodiment. Further, as shown in FIG. 13, the first outlet 43A is provided with a first outlet baffle plate 48A having an inclined surface rising from the front to the rear.

Part of the cooling air sent from the first fan 21 flows out from a part of the lower side of the blowout port 22 of the first fan case 20, and passes through the inlet 42A shown in FIGS. It flows into path 41A. The cooling air that has flowed into the first air guide passage 41A contacts the heat sink 13 and cools the heat sink 13 through heat transfer. After cooling the heat sink 13, the cooling air exits from the first air guide passage 41A through the first outlet 43A and cools the second heating coil 9B arranged behind.

The second air guide passage 51A is connected to the front first portion 321 of the outlet 32 of the second fan case 30, as shown in FIG. The second air guide passage 51A extends forward right from a first portion 321 of the outlet 32 that opens forward right. The opening surface of the air outlet 32 is not parallel to the side plate 104 of the first housing 10, but is inclined toward the front right. A region connected to the inlet 52A of the second air guide passage 51A extends so as to be perpendicular to the opening surface of the blower outlet 32. As shown in FIG. A first outlet 53A of the second air guide passage 51A is positioned below the second heating coil 9B (see FIG. 12). The second air guide passage 51A of the present embodiment does not have a configuration corresponding to the second outlet 54 of the first embodiment.

Part of the cooling air sent out from the second fan 31 flows into the second air guide passage 51A from the first portion 321 of the outlet 32 . Since the wall that forms the area connected to the inlet 52A of the second air guide passage 51A extends so as to be perpendicular to the opening surface of the blower outlet 32, a flow parallel to this wall is formed. Therefore, the pressure loss of the cooling air in the second air guide passage 51A is reduced, the air volume of the cooling air flowing through the second air guide passage 51A is increased, and the cooling efficiency of the object to be cooled is enhanced. The cooling air that has flowed into the second air passage 51A flows rightward and flows out of the second air passage 51A through the first outlet 53A. The cooling air flowing out from the first outlet 53A contacts the second heating coil 9B (see FIG. 12) arranged above the first outlet 53A and cools the second heating coil 9B.

Another part of the cooling air sent from the second fan 31 flows out from the second portion 322 of the blower port 32 to the space in front of the first coil baffle plate 71 . Then, the cooling air from the second portion 322 of the outlet 32 cools the first heating coil 9A (see FIG. 12) located above the space.

As shown in FIGS. 14 and 15, the third air guide passage 61A is connected to the upper portion of the outlet 22 of the first fan case 20 that opens rearward. The upper portion of the outlet 22 corresponds to the second portion 222 in the first embodiment. The third air guide path 61A is arranged at a position that overlaps a portion of the first air guide path 41A (see FIG. 16) before reaching the drive board 11. As shown in FIG. A first flow dividing plate 65A that divides the flow path into left and right is provided in the third air guide path 61A. One side of the third air guide passage 61A divided by the first flow dividing plate 65A and the other side guide the cooling air in different directions. As shown in FIGS. 13 and 15, the third air guide passage 61A on the left side of the first flow dividing plate 65A faces substantially rearward, and the third air guide passage 61A on the right side of the first flow dividing plate 65A faces right rearward. It is arc-shaped. Further, there is no wall above the third air passage 61A, and the upper surface of the third air passage 61A is open and functions as an outlet for the cooling air. More preferably, the member forming the bottom surface of the third air guide passage 61A is inclined upward from the inlet 62A toward the downstream.

Part of the cooling air sent out from the first fan 21 flows out from the upper part of the blowout port 22 of the first fan case 20 and flows into the third air guide passage 61A through the inlet 62A. The cooling air flowing into the third air guide passage 61A travels rearward through the third air guide passage 61A divided into left and right by the first flow dividing plate 65A. The cooling air flowing through the third air passage 61A, which is located on the left side of the first flow dividing plate 65A and has an open upper surface, contacts the first heating coil 9A arranged above the third air passage 61A, Cool the heating coil 9A. By inclining the member forming the bottom of the third air guide passage 61A upward from the front to the rear, it is possible to direct the flow of the cooling air upward. By doing so, it becomes easier for the cooling air to come into contact with the first heating coil 9A, and the cooling effect of the first heating coil 9A is enhanced. In addition, the cooling air flowing through the third air guide passage 61A located on the right side of the first flow dividing plate 65A cools the first heating coil 9A while flowing toward the rear right, and also cools the second heating coil 9B. Since the left and right walls forming the third air guide passage 61A are curved in an arc shape in a plan view, the pressure loss of the cooling air flowing through the third air guide passage 61A is suppressed.

In addition, the same configuration as in the first embodiment produces the same effects as in the first embodiment in this embodiment as well.

Embodiment 3.
This embodiment differs from Embodiments 1 and 2 in that a cooking chamber 81 is provided. In this embodiment, differences from the first and second embodiments will be mainly described. Further, this embodiment can be combined with each of the first and second embodiments.

FIG. 17 is a perspective view of kitchen furniture 200 on which cooker 100 according to Embodiment 3 is installed. As shown in FIG. 17 , cooker 100 includes cooking chamber 81 at a position below kitchen top plate 201 when incorporated into kitchen furniture 200 . The cooking chamber 81 has a door 811 and a heating device for heating the inside of the cooking chamber 81 . A first front cover 93 is provided on the left side of the cooking chamber 81, and a second front cover 94 is provided on the right side.

FIG. 18 is a perspective view illustrating the internal structure of cooker 100 according to Embodiment 3. FIG. FIG. 18 shows the cooking device 100 with the top plate 1 and the exhaust port cover 5 removed. Cooking device 100 of the present embodiment includes second housing 80 that accommodates first housing 10B and cooking chamber 81 . A first front cover 93 and a second front cover 94 provided on the front portion of the second housing 80 function as design plates on the front side of the cooker 100 . An intake port 931 is formed in the first front cover 93 . A space is formed inside the first front cover 93 to serve as an air path for air flowing in through the intake port 931 .

Two second vents 107 are formed in the bottom plate 101B of the first housing 10B. The second vent 107 allows the upper side of the bottom plate 101B and the inside of the second housing 80 to communicate with each other.

An exhaust duct 85 is provided in the second housing 80 below the housing exhaust port 4 on the left side. The exhaust duct 85 has therein an air passage for guiding the air inside the second housing 80 and the cooking chamber 81 to the housing exhaust port 4 . FIG. 18 illustrates how the exhaust duct 85 can be visually recognized through the housing exhaust port 4 and the second vent 107 .

A wind guide member 40B is arranged below the first heating coil 9A and the second heating coil 9B. As will be described later, the air guide member 40B of the present embodiment differs in structure from the air guide member 40 of the first embodiment and the air guide member 40A of the second embodiment.

FIG. 19 is a bottom perspective view illustrating the internal structure of cooker 100 according to Embodiment 3. FIG. FIG. 19 is a bottom view of the heating cooker 100 with the second housing 80 and the door 811 of the cooking chamber 81 removed. An intake port 931 is also provided on the lower surface of the first front cover 93 . The air intake port 931 on the lower surface of the first front cover 93 of the present embodiment is not provided on the entire lower surface of the first front cover 93, but only on the left side, that is, part of the direction away from the cooking chamber 81. is provided.

A first intake duct 86 is provided behind the first front cover 93 and on the left side of the cooking chamber 81 . The first intake duct 86 guides the air sucked from the intake port 931 of the first front cover 93 into the first housing 10B. The first front cover 93 and the first air intake duct 86 are connected, and airtightness is ensured at the connection point.

Intake ports 941 are formed in the right and lower surfaces of the second front cover 94 . A space is formed inside the second front cover 94 to serve as an air passage for air flowing in through the intake port 941 .

The intake port 931 and the intake port 941 are inlets of cooling air for cooling the inside of the second housing 80 as will be described later. By providing the air inlet 931 and the air inlet 941 at a place other than the front surface of the heating cooker 100, the air inlet 931 and the air inlet 941 are less visible to the user during use. Since the intake port 931 and the intake port 941 do not impair the appearance of the cooker 100, deterioration of the design of the cooker 100 is suppressed. Further, when the air intake port 931 and the air intake port 941 are provided on the front surface of the heating cooker 100, dust tends to adhere to the air intake port 931 and the air intake port 941 because they are exposed to the room air. However, according to the present embodiment, dust is less likely to adhere to the intake port 931 and the intake port 941 that are arranged at positions that are less likely to be exposed to the indoor air.

A second intake duct 87 and a third fan case 90 are provided behind the second front cover 94 and on the right side of the cooking chamber 81 . The second intake duct 87 guides the air sucked from the intake port 941 of the second front cover 94 to the third fan case 90 . An air guide duct 88 is provided behind the third fan case 90 . A first outlet 881 is formed on the right side of the air guide duct 88 . The second front cover 94, the second air intake duct 87, the third fan case 90 and the air guide duct 88 form a series of air passages.

An exhaust airflow passage inlet 109 is formed in the rear portion of the bottom plate 101B of the first housing 10B. The exhaust airflow path inlet 109 is provided below the housing exhaust port 4 (see FIGS. 18 and 20).

FIG. 20 is a front side perspective view for explaining the internal structure of cooking device 100 according to Embodiment 3. FIG. FIG. 20 shows a state in which the first heating coil 9A, the second heating coil 9B, the door 811, the second front cover 94 and the top plate frame 105 are removed from FIG. A connection port 95 is formed on the right front surface of the second housing 80 . The connection port 95 is connected to the second front cover 94 (see FIG. 19), and airtightness is ensured at the connection location. The second front cover 94 and the second housing 80 communicate with each other through the connection port 95 . Although not shown in FIG. 20, the second housing 80 is provided with an opening corresponding to the connection port 95 that allows the inside of the second housing 80 and the inside of the first front cover 93 to communicate with each other. The first front cover 93 and the second front cover 94 are detachably attached to the second housing 80 . Therefore, even if dust adheres to the intake port 931 and the intake port 941, the user can easily remove the dust. Therefore, an increase in pressure loss at the air inlets 931 and 941 due to dust adhering to the air inlets 931 and 941 is suppressed, and a decrease in cooling airflow and cooling efficiency is also suppressed.

FIG. 21 is an exploded perspective view of cooking-by-heating device 100 according to Embodiment 3. FIG. In FIG. 21, the first housing 10B is shown in a lower perspective view, and the second housing 80 is shown in an upper perspective view. A first intake duct 86 is provided inside the second housing 80 . The first intake duct 86 has a first air passage 861 and a second air passage 862, which are independent of each other. The first intake duct 86 communicates with the intake port 931 via an air passage formed inside the first front cover 93 . Above the first air passage 861, the housing air intake port 3 communicating with the inside of the first fan case 20 (see FIG. 20) is arranged. Above the second air passage 862, the housing air intake port 3 communicating with the inside of the second fan case 30 (see FIG. 20) is arranged. The upper end of the first air intake duct 86 that constitutes the outlet of the first air passage 861 is connected to the bottom plate 101B in a state where airtightness is ensured with the bottom plate 101B. The upper end of the first air intake duct 86 that constitutes the outlet of the second air passage 862 is connected to the bottom plate 101B in a state where airtightness is ensured with the bottom plate 101B.

A heat insulating case 96 is provided above the cooking chamber 81 . The heat insulating case 96 covers the upper side of the cooking chamber 81 with a gap between it and the upper wall of the cooking chamber 81 . A second outlet 882 of the air guide duct 88 is connected to the gap between the heat insulating case 96 and the upper wall of the cooking chamber 81 . The gap between the heat insulating case 96 and the cooking chamber 81 functions as an air insulation layer and also functions as an air passage through which the cooling air flows from the air guide duct 88 as indicated by the dashed arrow.

Exhaust duct 85 has an inlet 851 and an outlet 852 . The exhaust duct 85 extends rearward from the front and then upward, and has an L-shaped flow path inside when viewed from the side. An inlet 851 of the exhaust duct 85 communicates with the cooking chamber 81 as well as with the gap between the heat insulating case 96 and the upper wall of the cooking chamber 81 .

21, the cooling air that has flowed from the second outlet 882 of the air guide duct 88 into the gap below the heat shield case 96 flows below the heat shield case 96. 96 to cool it. The cooling air that has flowed under the heat shield case 96 flows through the exhaust duct 85 via the inlet 851 and flows out from the outlet 852 . When the first housing 10B and the second housing 80 are assembled, the outlet 852 of the exhaust duct 85 is connected to the first housing 10B via the exhaust airflow passage inlet 109 formed in the bottom plate 101B of the first housing 10B. It is located inside the housing 10B (see FIG. 20). By cooling the heat shielding case 96, heat transfer from the cooking chamber 81 to the first housing 10B arranged above the heat shielding case 96 is suppressed. By suppressing the heat transfer to the first housing 10B, the cooling efficiency of the components accommodated in the first housing 10B can be improved.

Two second vents 107 are formed in the bottom plate 101B of the first housing 10B at positions that do not overlap the exhaust duct 85 in plan view. A third vent 108 is formed on the front left of the bottom plate 101B, and a first vent 106 is formed on the front right of the bottom plate 101B. The third ventilation port 108 is arranged on the front side of the housing intake port 3 . The first ventilation port 106 is arranged at the right end of the bottom plate 101B and in front of the heat sink 13 arranged on the first housing 10B.

FIG. 22 is a diagram illustrating a structure for supplying cooling air to the lower side of drive board 11 of cooking device 100 according to Embodiment 3. As shown in FIG. Between the end of the drive board 11 and the left side plate 104, a board-down air guide member 73 is provided. The under-board air guide member 73 is a member for guiding the cooling air sent from the second fan case 30 (see FIG. 20) to the lower side of the drive board 11 . The board lower air guide member 73 has a vertically standing wall, and a part of the wall is formed with a first recess 731 and a second recess 732 whose upper end is recessed more than the other part. The outlet 22 (see FIG. 23) of the first fan case 20 is connected to the first concave portion 731 . The outlet 32 (see FIG. 23) of the second fan case 30 is connected to the second recess 732 .

A substrate lower shielding member 74 is provided between the first concave portion 731 and the driving substrate 11 . The under-substrate shielding member 74 is a member for blocking the vertical gap between the drive substrate 11 and the bottom plate 101B and preventing the cooling air from flowing under the drive substrate 11 . The under-substrate shielding member 74 is a wall extending vertically, and stands on the bottom plate 101B so as to be in contact with the side end of the drive substrate 11 .

On the other hand, no member corresponding to the under-substrate shielding member 74 is provided between the second concave portion 732 and the drive substrate 11 . Therefore, the space below the drive substrate 11 is open at the position facing the second recess 732 . A space below the drive board 11 is called a fourth air guide passage 75 . The space above the second recessed portion 732 connected to the outlet 32 (see FIG. 23) of the second fan case 30 functions as an inlet for the cooling air to the fourth air guide passage 75 .

FIG. 23 is a cross-sectional view of cooker 100 according to Embodiment 3, passing through first fan 21 and second fan 31. FIG. In FIG. 23, the flow of cooling air passing through the first air passage 41B or the second air passage 51B is indicated by solid arrows, and cooling through the fourth air passage 75 (see FIG. 22) on the lower side of the drive board 11 is shown. The flow of wind is conceptually indicated by dashed arrows.

Inside the air guide member 40B, a first partition plate 45B partitions a part of the space inside the air guide member 40B into front and rear, forming a first air guide passage 41B on one side and a second air guide passage 51B on the other side. It is In this embodiment, a configuration corresponding to the third air guide passage in the first and second embodiments is not provided.

The first air guide passage 41B has an inlet 42B and a first outlet 43B. The heat sink 13 and the drive element 12 (see FIG. 22) thermally connected thereto are accommodated in the first air guide passage 41B. The first air guide passage 41B is an air passage for supplying cooling air to the heat sink 13 . The inlet 42B is connected to the outlet 22 of the first fan case 20. As shown in FIG. The first outlet 43B is provided at the end of the air guide member 40B farthest from the first fan case 20 in the flow direction of the cooling air from the first fan case 20 . The first outlet 43B is a gap formed between the right end of the upper wall of the air guide member 40B and the drive substrate 11 .

The second air guide passage 51B has an inlet 52B and a first outlet 53B. The second air guide path 51B is an air path for supplying cooling air to the second heating coil 9B (see FIG. 18). The inlet 52B is connected to the outlet 32 of the first fan case 20. As shown in FIG. The first outlet 53B is located below the front portion of the second heating coil 9B (see FIG. 18). The first outlet 53B is a gap formed between the right end of the upper wall of the air guide member 40B and the drive board 11 .

The first fan case 20 is installed such that the opening surface of the air outlet 22 is substantially parallel to the side plate 104 . In the flow direction of the cooling air from the first fan case 20, the first partition plate 45B, which constitutes the side wall of the first air passage 41B, extends from the outlet 22 toward the downstream side of the first air passage 41B. It slopes backwards to increase its width. As indicated by the solid line arrows in FIG. 23, the cooling air blown out from the air outlet 22 flows while diffusing in the air passage expanding along the first partition plate 45B, cools the heat sink 13, and cools the first outlet 43B. exits the first air guide passage 41B. The cooling air coming out of the first outlet 43B is guided to the right side plate 104 of the first housing 10B and cools the second heating coil 9B (see FIG. 18) arranged in the rear.

As indicated by solid line arrows in FIG. 23, the cooling air blown out from the outlet 32 flows through the second air guide passage 51B. Since the second air passage 51B does not have a heat-generating component such as the heat sink 13, the temperature rise of the cooling air flowing through the second air passage 51B is equal to the temperature rise of the cooling air flowing through the first air passage 41B. less than The low-temperature cooling air flowing through the second air guide path 51B exits the first outlet 53B and cools the second heating coil 9B (see FIG. 18) installed behind.

23, part of the cooling air from the air outlet 32 flows into the fourth air guide passage 75 formed below the drive board 11. As shown in FIG. Via the second concave portion 732 shown in FIG. 22, the outlet 32 and the fourth air guide passage 75 communicate with each other. The cooling air that has flowed into the fourth air guide passage 75 flows below the drive board 11 . The second fan case 30 is installed such that the opening surface of the air outlet 32 is slanted with respect to the side plate 104 . Specifically, the opening surface of the air outlet 32 faces the corner closest to the air outlet 32 among the four corners of the drive board 11 . Therefore, the cooling air can easily spread over the entire lower surface of the drive board 11 . The air in the fourth air guide passage 75 functions as a heat insulating layer that suppresses heat transfer from the cooking chamber 81 on the lower side of the first housing 10B to the drive board 11 . By suppressing the heat transfer from the cooking chamber 81 to the drive board 11, the cooling efficiency of the heat sink 13 mounted on the drive board 11 can be enhanced.

The cooling air that has flowed through the fourth air passage 75 exits the fourth air passage 75 from the right end of the drive board 11 and flows through the second heating coil 9B (with the cooling air that has flowed through the second air passage 51B). 18) is cooled. In this way, the cooling air from the second fan case 30 is divided into the second air guide passage 51B above the drive board 11 and the fourth air guide passage 75 below the drive board 11, and then joins. It is used for cooling the second heating coil 9B (see FIG. 18). Therefore, the pressure loss of the second fan 31 is reduced compared to the case where the cooling air is sent from the second fan case 30 only to the second air guide path 51B. As the pressure loss decreases, the amount of cooling air used for cooling the second heating coil 9B increases, and the cooling efficiency of the second heating coil 9B can be improved.

24 is a plan view of the first front cover 93 and the first intake duct 86 according to Embodiment 3. FIG. A first air passage 861 and a second air passage 862 are provided in the first intake duct 86 connected to the rear side of the first front cover 93 . The first air passage 861 guides the air sucked from the intake port 931 to the first fan 21 (see FIG. 23) of the first fan case 20 . The upper end of the first air intake duct 86 serving as the outlet of the first air passage 861 is attached to the lower surface of the first housing 10B so as to surround the housing air intake 3 (see FIG. 21). The second intake duct 87 guides the air sucked from the intake port 931 to the second fan 31 (see FIG. 23) of the second fan case 30 . The upper end of the first intake duct 86 serving as the outlet of the second air passage 862 is attached to the lower surface of the first housing 10B so as to surround the housing intake port 3 (see FIG. 21).

25 is a cross-sectional view taken along the line AA of FIG. 24. FIG. In FIG. 25, arrows conceptually indicate the flow of the cooling air. The second air passage 862 is an L-shaped passage extending rearward and further upward when viewed from the side. The second air passage 862 is connected to the air intake port 931 formed on the upper side of the air intake port 931 of the first front cover 93 . The cooling air sucked in from the air intake port 931 flows rearward through the air passage in the first front cover 93 and the second air passage 862 of the first air intake duct 86 and then rises to the second air passage. 862 flows upward.

26 is a cross-sectional view taken along the line BB of FIG. 24. FIG. In FIG. 26, arrows conceptually indicate the flow of the cooling air. The first air passage 861 is an L-shaped passage extending rearward and further upward when viewed from the side. The first air passage 861 is connected to the air intake ports 931 formed in the side lower portion and the bottom surface of the first front cover 93 among the air intake ports 931 of the first front cover 93 . The cooling air sucked in from the air intake port 931 flows rearward through the air passage in the first front cover 93 and the first air passage 861 in the first air intake duct 86, and then rises to become the first wind. It flows upward from the channel 861 . The cooling air flowing out from the first air passage 861 is sucked into the first fan 21 and sent out from the first fan case 20, and used to cool the heat sink 13 in the first air guide passage 41B. Here, since high-temperature air moves upward due to buoyancy, the temperature of the air around first front cover 93 is lower on the lower side than on the upper side when cooker 100 is installed. Therefore, by supplying the heat sink 13 with the air sucked from the air inlets 931 provided on the side wall and the bottom surface of the first front cover 93, the temperature of the first heating coil 9A and the second heating coil 9B is reduced. The low heat sink 13 can be efficiently cooled.

Further, as shown in FIGS. 21 and 24 to 26, a second air passage 862 is arranged between the first air passage 861 through which the cooling air supplied to the heat sink 13 flows and the cooking chamber 81. . The second air passage 862 functions as a heat insulator that prevents heat from the cooking chamber 81 from being transferred to the first air passage 861 . Therefore, the temperature of the cooling air flowing through the first air passage 861 is suppressed, and the cooling air having a lower temperature is supplied to the heat sink 13, so that the cooling efficiency of the heat sink 13 can be improved.

As can be seen by comparing FIGS. 25 and 26, the air passage from the air intake port 931 on the upper side of the first front cover 93 to the outlet of the second air passage 862 extends from the lower side of the first front cover 93 and the bottom surface of the first front cover 93 . is longer than the air passage from the air intake port 931 to the outlet of the first air passage 861 . Therefore, the pressure loss in the second air passage 862 is greater than the pressure loss in the first air passage 861 . Therefore, it is preferable to make the opening area of the intake port 931 connected to the second air passage 862 larger than the opening area of the intake port 931 connected to the first air passage 861 . By doing so, the difference in the suction air volume between the first fan 21 and the second fan 31 is suppressed, and the increase in the noise of the second fan 31 is suppressed.

FIG. 27 is a perspective view of a cooking chamber 81 and peripheral parts thereof according to Embodiment 3. FIG. A first heating device 821 for heating the inside of the cooking chamber 81 is provided on the upper wall of the cooking chamber 81 . The first heating device 821 is, for example, a resistance heating element. A second heating device 822 that heats the interior of the cooking chamber 81 is provided in the lower portion of the cooking chamber 81 . The second heating device 822 is, for example, a heating coil, and heats the cooking plate placed in the cooking chamber 81 by high-frequency magnetic flux to heat the ingredients placed on the cooking plate. Note that the specific configurations of the first heating device 821 and the second heating device 822 are not limited to those described above, and may be any device that heats the interior of the cooking chamber 81 . Specific examples of the first heating device 821 and the second heating device 822 include resistance heating elements, induction heating coils, microwave heating devices, and superheated steam. Cooking chamber 81 can be used as, for example, a grill, a microwave oven, or a rice cooker.

FIG. 28 is a perspective view of the air guide duct 88 and peripheral parts thereof according to the third embodiment. An air guide duct 88 is provided behind the third fan case 90 . The air guide duct 88 constitutes an air path for guiding the cooling air sent from the third fan case 90 to the object to be cooled. An object to be cooled in this embodiment is the drive circuit 83 that drives the first heating device 821 and the second heating device 822, and the drive circuit 83 has heat generating components 831, 832, 833, and 834 mounted thereon. The heat-generating component 831 is, for example, a drive element forming an inverter circuit, and the heat-generating component 832 is a heat sink thermally connected to the drive element. The heat-generating component 833 is, for example, a transformer, and the heat-generating component 834 is, for example, a heat sink. A first outlet 881 is provided downstream of the air guide duct 88 in the flow direction of the cooling air from the third fan case 90 .

FIG. 29 is a vertical cross-sectional view of cooker 100 according to Embodiment 3, taken through third fan case 90 . In FIG. 29, arrows conceptually indicate the flow of the cooling air. A blowout port 92 of the third fan case 90 is connected to the air guide duct 88 . The lower end of the outlet of the third fan case 90 is located below the lower end of the drive circuit 83 on which the heat generating components 831-834 are mounted. That is, the cooling air blown rearward from the air outlet 92 flows below the drive circuit 83 . The cooling air sent from the third fan 91 in the third fan case 90 flows into the air guide duct 88 via the blowout port 92 . The air guide duct 88 is provided with flow dividing plates 891 and 892 that are arranged so that their flat surfaces face forward and backward and extend vertically. The flow dividing plate 891 is provided at a position facing a portion of the air outlet 92 and guides the cooling air from the air outlet 92 upward. A heat-generating component 832 is accommodated between the flow dividing plate 891 and the front wall of the air guide duct 88 , and the heat-generating component 832 is cooled by the cooling air guided by the flow dividing plate 891 . The flow dividing plate 892 is located downstream of the flow dividing plate 891 in the flow of the cooling air, and guides the cooling air from the outlet 92 upward. A heat-generating component 833 is arranged between a flow dividing plate 891 and a flow dividing plate 892 which are arranged with a gap in the front and rear direction. cooled.

Of the cooling air flowing through the air guide duct 88, the cooling air that has flowed upward along the flow division plates 891 and 892 flows out through the second outlet 882 of the air guide duct 88 as shown in FIG. Then, it flows through the gap formed between the heat insulating case 96 and the upper wall of the cooking chamber 81 .

The flow dividing plate 893 is a plate-shaped member that is arranged such that its flat plate surface faces up and down and extends in the front-rear direction. The flow dividing plate 893 is arranged with a gap between it and the bottom plate of the air guide duct 88 . A gap between the flow dividing plate 893 and the bottom plate of the air guide duct 88 serves as an air path through which the cooling air flows. The cooling air blown out from the blowout port 92 flows rearward along the upper surface of the flow dividing plate 893 and is guided upward by the vertically extending rear wall of the air guide duct 88 . During this process, the heat generating component 834 is cooled by the cooling air. The cooling air that has cooled the heat generating component 834 flows out into the second housing 80 through the first outlet 881 (see FIG. 28).

The flow of cooling air from the third fan case 90 is generated in the second housing 80, and the first ventilation port 106 provided on the front side of the first housing 10B accommodated in the second housing 80 is cooled. , an attractive force toward the lower side of the first housing 10B is generated. As a result, the air inside the first housing 10B flows downward through the first ventilation port 106 and moves backward inside the second housing 80 along the bottom plate 101B of the first housing 10B. flow to At least part of the cooking chamber 81 is arranged below the straight line connecting the first vent 106 and the exhaust airflow inlet 109 . Therefore, the cooling air flowing inside the second housing 80 contacts and cools the cooking chamber 81 in the process of flowing toward the exhaust airflow passage inlet 109 . High-temperature air tends to stay above the second housing 80, that is, around the first housing 10B. However, by forming the flow of cooling air from the first ventilation port 106 to the exhaust air passage inlet 109 around the bottom plate 101B of the first housing 10B, the high temperature air around the first housing 10B can be discharged. can be encouraged.

FIG. 30 is a longitudinal sectional view through the first heating device 821 and the second heating device 822 of the cooking device 100 according to Embodiment 3. FIG. In FIG. 30, arrows conceptually indicate the flow of the cooling air. A second vent 107 is formed at a position behind the cooking chamber 81 in the bottom plate 101B of the first housing 10B. The cooling air that cools the heat sink 13 and flows out through the first air guide passage 41B of the air guide member 40B flows rearward and passes through the second air vent 107 formed in the bottom plate 101B to the first housing 10B. flow downwards. The cooling air that has flowed into the second housing 80 on the lower side of the first housing 10B flows through the second housing 80 and flows out from the housing exhaust port 4 . Heating cooker 100 of the present embodiment has a space formed between the rear wall of second housing 80 and cooking chamber 81 . Here, the air warmed around the cooking chamber 81 tends to stay in this space. However, as in the present embodiment, by providing the second ventilation port 107 on the downstream side of the first air guide passage 41B and the upstream side of the housing exhaust port 4 of the bottom plate 101B, the first air guide passage The cooling air flowing out of the second housing 80 flows toward the housing exhaust port 4 to promote the discharge of the air inside the second housing 80 . Therefore, an increase in temperature inside the second housing 80 is suppressed.

In addition, as shown in FIG. 21 , the second vent 107 is not formed above the exhaust duct 85 . Therefore, the air flowing into the lower side of the first housing 10B from the second vent 107 is less likely to come into contact with the exhaust duct 85 . Therefore, the temperature of the exhaust air from the cooking chamber 81 flowing through the exhaust duct 85 is less likely to be lowered. In other words, the exhaust air from the cooking chamber 81 is exhausted through the exhaust duct 85 while maintaining a high temperature. As a result, the exhaust of heat in the cooking chamber 81 is promoted, and the cooling effect in the second housing 80 is enhanced. By suppressing the temperature rise in the second housing 80, the cooling effect of the heat-generating components 831 to 834 shown in FIG. 29 can be enhanced.

FIG. 31 is a vertical cross-sectional view of the cooker 100 according to Embodiment 3 at a position passing through the second vent 107 and the third vent 108 and at a position outside the width of the cooking chamber 81 to the left. be. In FIG. 31, arrows conceptually indicate the flow of the cooling air. At least part of the third vent 108 is formed outside the width of the cooking chamber 81 to the left. Therefore, the cooling air flowing into the lower side of the first housing 10B from the third vent 108 flows rearward along the left side of the cooking chamber 81 and flows out through the housing exhaust port 4 . High-temperature air tends to stay around the cooking chamber 81 , but the discharge of this high-temperature air is facilitated in the course of the cooling air flowing from the third vent 108 to the housing exhaust port 4 . As shown in FIG. 31, the first intake duct 86 is arranged on the left side of the second housing 80, and the cooling air flowing from the third vent 108 to the housing exhaust port 4 prevents the high temperature air from stagnation. By suppressing, the temperature increase in the first intake duct 86 is suppressed. Therefore, the temperature of the cooling air sent from the first fan case 20 and the second fan case 30 is suppressed, so that the cooling effect of the object to be cooled is also enhanced.

In Embodiments 1 to 3, the first centrifugal fan 21 and the second fan 31 that rotate clockwise (right) were described as examples, but a blower that rotates counterclockwise (counterclockwise) is used. can also be adopted. In that case, the first fan 21, the second fan 31, and the members connected thereto can be arranged in the left-right opposite direction to those in the first to third embodiments.

Reference Signs List 1 top plate, 2 heating port, 3 housing intake port, 4 housing exhaust port, 5 exhaust port cover, 6 operation unit, 7 display unit, 8 drainage port, 9A first heating coil, 9B second heating coil, 10 First housing 10B First housing 11 Drive board 12 Drive element 13 Heat sink 14 Power supply control board 20 First fan case 21 First fan 22 Air outlet 30 Second fan case 31 Second 2 fans 32 outlet 40 air guide member 40A air guide member 40B air guide member 41 first air guide 41A first air guide 41B first air guide 42 inlet 42A inlet 42B entrance, 43 first outlet, 43A first outlet, 43B first outlet, 44 upper wall, 45 first partition plate, 45B first partition plate, 46 second partition plate, 47 shielding part, 48 first outlet baffle plate , 48A first outlet air guide plate, 49 air guide plate, 51 second air guide plate, 51A second air guide plate, 51B second air guide plate, 52 inlet, 52A inlet, 52B inlet, 53 first outlet, 53A 1st outlet, 53B 1st outlet, 54 2nd outlet, 61 3rd air guide, 61A 3rd air guide, 62 inlet, 62A inlet, 63 1st outlet, 64 2nd outlet, 65A 1st flow dividing plate, 71 first coil air guide plate, 72 second coil air guide plate, 73 board lower air guide member, 74 board lower shielding member, 75 fourth air guide passage, 80 second housing, 81 cooking chamber, 83 drive circuit, 85 exhaust duct, 86 first intake duct, 87 second intake duct, 88 air guide duct, 90 third fan case, 91 third fan, 92 outlet, 93 first front cover, 94 second front cover, 95 connection Mouth, 96 Heat shielding case, 100 Heating cooker, 101 Bottom plate, 101B Bottom plate, 102 Front plate, 103 Rear plate, 104 Side plate, 105 Top plate frame, 106 First vent, 107 Second vent, 108 Third vent Mouth, 109 Exhaust air duct inlet, 200 Kitchen furniture, 201 Kitchen top plate, 202 Storage, 203 Thickness, 221 First part, 222 Second part, 321 First part, 322 Second part, 731 First concave part, 732 second recess 811 door 821 first heating device 822 second heating device 831 heat generating component 832 heat generating component 833 heat generating component 834 heat generating component 851 inlet 852 outlet 861 first air passage 862 second 2 air passages, 881 first outlet, 882 second outlet, 891 flow dividing plate, 892 flow dividing plate, 893 flow dividing plate, 931 intake port, 941 intake port.

Claims (21)

a top plate;
a heating coil under the top plate;
a first fan;
a first fan case housing the first fan and having an air inlet and an air outlet;
a second fan provided behind the first fan;
a second fan case that accommodates the second fan, has an air inlet and an air outlet, and is provided so as to at least partially overlap the first fan case in the width direction when viewed from the front;
a first air guide member forming a first air guide passage having an inlet connected to the air outlet of the first fan case and a first outlet;
a drive element included in an inverter circuit that supplies a high-frequency current to the heating coil;
a heat sink attached to the driving element and arranged in the first air guide passage;
The heating coil includes a first heating coil and a second heating coil located farther from the first fan than the first heating coil,
the outlet of the second fan case includes a first portion and a second portion;
a second air guide member forming a second air guide passage having an inlet connected to the first part of the outlet of the second fan case and a first outlet formed below the second heating coil; ,
the second portion of the outlet of the second fan case is not connected to the second air guide path and is arranged below the first heating coil;
cooling air sent out from the outlet of the first fan case is supplied to the first air guide passage;
cooling air sent from the first portion of the second fan case is supplied to the second air guide path;
A heating cooker in which cooling air sent from the second portion of the second fan case is supplied below the first heating coil. 2. The heating cooker according to claim 1, wherein the upper wall of the second air guiding member is formed with a second outlet facing the lower surface of the first heating coil. the outlet of the first fan case includes a first portion and a second portion;
a third airflow guide member forming a third airflow passage having an inlet connected to the second portion of the air outlet of the first fan case and a first outlet formed below the first heating coil; with
The heating cooker according to claim 1 or 2, wherein the first portion of the outlet of the first fan case is connected to the inlet of the first air guide passage. 4. The heating cooker according to claim 3, wherein the upper wall of the third air guiding member is formed with a second outlet facing the lower surface of the first heating coil. The heating cooker according to claim 3 or 4, wherein the first portion and the second portion of the outlet of the first fan case are arranged horizontally. The heating cooker according to claim 3, wherein the first portion and the second portion of the outlet of the first fan case are arranged vertically. The third air guide member is provided with a first flow dividing plate that stands up and down and divides the third air guide path into left and right,
7. The heating cooker according to claim 6, wherein the one air passage and the other air passage divided by the first diverter plate flow out the cooling air in different directions. On the downstream side of the second portion of the outlet of the second fan case, there is a first coil baffle plate which stands vertically and has a planar shape along at least part of the outer shape of the first heating coil. The heating cooker according to claim 1, further comprising: Downstream of the first outlet of the first air guide, a second coil guides the cooling air from the first outlet of the first air guide to the second heating coil. The heating cooker according to any one of claims 1 to 6, further comprising a plate. 10. The first outlet air guide plate according to any one of claims 1 to 9, wherein the first outlet of the first air guide path is provided with a first outlet air guide plate having an inclined surface rising toward the rear. heating cooker. A substrate on which the inverter circuit is mounted,
11. The method according to any one of claims 1 to 10, wherein an under-substrate shielding member for blocking inflow of cooling air to the underside of the substrate is provided on the downstream side of the air outlet of the first fan case. The heating cooker described. 12. The heating cooker according to claim 11, wherein a fourth air guide passage through which cooling air from the outlet of the second fan case flows is formed on the lower side of the substrate. a first housing that houses the heating coil, the first fan case, the second fan case, the first air guide member, the drive element, and the heat sink;
a second housing connected under the first housing;
a cooking chamber housed in the second housing;
A first air passage communicating with the suction port of the first fan case and a second air passage not communicating with the first air passage but communicating with the suction port of the second fan case are formed inside. 13. The heating cooker according to any one of claims 1 to 12, further comprising a first air intake duct. A housing exhaust port is formed in the first housing,
14. The heating cooker according to claim 13, wherein an exhaust duct that communicates between the housing exhaust port and the inside of the second housing is provided in the second housing. A first vent communicating with the inside of the second housing is formed in the bottom of the first housing,
15. The heating cooker according to claim 14, wherein at least part of the cooking chamber is arranged below a line connecting the first vent and the housing exhaust port. At the bottom of the first housing, on the downstream side of the first air guide passage and on the upstream side of the housing exhaust port, a second housing that communicates the inside of the first housing with the inside of the second housing is provided. The heating cooker according to claim 14 or 15, wherein a vent is formed. At the bottom of the first housing, outside the width of the cooking chamber, there is formed a third vent that communicates the inside of the first housing with the inside of the second housing. 17. The heating cooker according to any one of 16. a third fan case that is housed in the second housing and houses a third fan;
a heating device that is housed in the second housing and heats the inside of the cooking chamber;
A drive circuit that is housed in the second housing and drives the heating device,
A ventilable gap is formed between the upper wall of the cooking chamber and the bottom of the first housing,
The heating cooker according to any one of claims 13 to 17, wherein the gap is positioned downstream of the drive circuit in the air flow direction from the outlet of the third fan. 19. The heating cooker according to claim 18, further comprising an air guide duct that communicates between the outlet of the third fan case and the gap and accommodates at least part of the drive circuit. The drive circuit includes a plurality of heat-generating components,
20. The heating cooker according to claim 19, wherein a flow dividing plate that separates the plurality of heat-generating components is provided in the air guide duct. The heating cooker according to any one of claims 18 to 20, wherein the lower end of the outlet of the third fan case is located below the lower end of the drive circuit.

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