JP2023093221A - Cooker - Google Patents

Abstract

To provide a cooker that can suitably restrain a temperature rise of objects to be cooled, arranged inside a door, and the door itself.SOLUTION: A microwave oven comprises a main body internally comprising a cooking chamber, and a door 4 for opening/closing an opening of the main body. A first flow passage 47 through which first cooling air for cooling objects to be cooled (a printed circuit board 50, a radio communication device 55, and a fitting plate) flows, and a second flow passage 48 through which second cooling air flows are formed inside the door 4. A temperature rise of the objects to be cooled (the printed circuit board 50, the radio communication device 55, and the fitting plate) arranged inside the door 4, and the door 4 itself is restrained by forming a merging part 56 into which the first flow passage 47 and the second flow passage 48 merge, inside the door 4.SELECTED DRAWING: Figure 5

Description

TECHNICAL FIELD The present invention relates to a heating cooker provided with a passage through which gas flows in a door for opening and closing an opening of a main body.

Conventionally, a heating cooker is known in which a display unit and an operation unit are provided on a door that opens and closes an opening of the main body, and electric parts that constitute the display unit and the operation unit are arranged in the door (for example, See Patent Document 1). In the heating cooker described in Patent Document 1, two flow paths (first flow path (47) and second flow path (48)) are formed in the door, and a blower fan (second flow path) is provided in each flow path. One blower fan (49) and a second blower fan (54) are provided. The blowing fans (49) and (54) cause the air to flow in the flow paths (47) and (48), thereby suppressing the temperature rise of the parts arranged inside the door and the door itself.

Japanese Patent Application Laid-Open No. 2021-167701

However, in the heating cooker described in Patent Document 1, the first flow path (47) is longer than the second flow path (48), so the air blown by the first blower fan (49) There is room for improvement in the cooling effect of the parts arranged inside the door and the door itself.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a heating cooker capable of suitably suppressing temperature rise of an object to be cooled disposed inside a door and the door itself.

A heating cooker according to the present invention includes a main body having a cooking chamber therein, and a door for opening and closing an opening of the main body, and a first cooling air for cooling an object to be cooled is provided inside the door. and a second flow path through which the second cooling air flows are formed. Inside the door, the first flow path and the second flow path join A part is formed.

ADVANTAGE OF THE INVENTION According to the heating cooker of this invention, the cooling object arrange|positioned inside the door and the temperature rise of the door itself can be suppressed suitably.

1 is an upper perspective view of the microwave oven of Embodiment 1. FIG. Fig. 3 is a front view of the microwave oven with the door opened; It is a lower side perspective view of a door same as the above. It is a top view of a door same as the above. It is a figure which shows the inside of a door from a front side same as the above. It is a figure which shows the inside of the door of Embodiment 2 from the front side.

DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a heating cooker according to the present invention will be described below with reference to the accompanying drawings. The embodiments described below do not limit the content of the invention described in the claims. Moreover, not all the configurations described below are essential requirements of the present invention.

1 to 5 show Embodiment 1 of the present invention. FIG. 1 shows an oven range 1 as a heating cooker in this embodiment. An oven range 1 is composed of a rectangular box-shaped main body 2 with an open front surface and a door 4 for opening and closing an opening 3 on the front surface of the main body 2.例文帳に追加

The microwave oven 1 of the present embodiment has a cooking function by oven heating that heats the object S to be cooked by hot air supplied into the cooking chamber 5, and a cooking function by grill heating that heats the object S to be cooked by the heat of the heater. It has a cooking function by microwave heating for irradiating the object S to be cooked with microwaves to heat and cook the object S to be cooked, and a cooking function by steam heating for heating the object S by superheated steam.

As shown in FIG. 2, inside the main body 2, there is provided a cooking chamber 5 in which food S to be cooked is stored and cooked. A ceiling wall 6 of the cooking chamber 5 is provided with an upper heater 7 for performing grill heating. A microwave generator (not shown) having a magnetron or the like is provided below the bottom wall 8 of the cooking chamber 5 in order to supply microwaves, which are radio waves, into the cooking chamber 5 . Microwave heating can be performed by irradiating the object S to be cooked with microwaves. A left side wall 9 of the cooking chamber 5 is provided with a steam ejection hole 10 communicating with a steam supply device (not shown). Steam heating can be performed by the steam jetted into the cooking chamber 5 from the steam jet holes 10 . In addition, a plurality of supply holes 12 for supplying hot air into the cooking chamber 5 are provided in the inner wall 11 of the cooking chamber 5, and a hot air heater for heating the air, A hot-air unit (not shown) having a hot-air fan for sending air heated by a hot-air heater into the cooking chamber 5 for circulation is provided.

As shown in FIG. 1, a water supply cassette 13 and a water receiver 14 that can be attached and detached from the front surface of the main body 2 are arranged at the lower portion of the main body 2, respectively. The water supply cassette 13 is a bottomed container containing liquid water as a supply source of steam generated from the steam supply device. The water receiver 14 is a container with a bottom that receives food waste, water droplets, steam water, and the like from the main body 2 . The water supply cassette 13 and the water receiver 14 can be removed by pulling them out toward you, and can be installed by pushing them back.

The lower portion of the door 4 is rotatably connected to the main body 2 so that the opening 3 of the main body 2 can be opened and closed vertically. The door 4 has a rectangular window 21 through which the inside of the cooking chamber 5 can be viewed, and a frame 22 surrounding the window 21 . The window portion 21 is arranged substantially in the center of the door 4 . The frame portion 22 includes a plate-like front portion 22A, a plate-like back portion 22B (see FIG. 4), a plate-like outer peripheral surface portion 22C, and an inner peripheral surface portion 22D (see FIG. 5) in contact with the window portion 21. )have. The frame portion 22 includes an upper side portion 23 positioned above the window portion 21, a lower side portion 24 positioned below the window portion 21, a left side portion 25 positioned to the left of the window portion 21, and the window portion 21. has a right side portion 26 positioned to the right of the . An upper left corner portion 27 of the frame portion 22 is a portion where the upper side portion 23 and the left side portion 25 overlap. Similarly, the lower left corner 28 of the frame 22 is part of the lower side 24 and the left side 25, and the upper right corner 29 of the frame 22 is part of the upper side 23. Also part of right side 26 , lower right corner 30 of frame 22 is part of lower side 24 and part of right side 26 .

As shown in FIGS. 1, 3, and 4, of the front portion 22A of the frame portion 22, the front portion 23A of the upper side portion 23 is provided with a user's hand when opening and closing the door 4 that opens vertically. A handle 31 is provided for. The handle 31 includes a grip portion 32 extending in the horizontal direction, and fixing portions 33A and 33B provided at both left and right ends of the grip portion 32 and fixed to the door 4 .

A front portion 26A of the right side portion 26 of the front portion 22A of the frame portion 22 is provided with an operation panel 34 for display, notification and operation. The operation panel 34 is provided with display means 35 for displaying setting contents and progress of cooking, and operation means 36 for enabling various operation inputs related to heat cooking. The display means 35 has an electrostatic touch panel 37 that enables touch operations on the screen.

As shown in FIG. 3, the bottom surface portion 38 of the frame portion 22, which is the lower portion of the door 4, has a first air intake port 41 as an air intake port composed of a plurality of through holes, and an exhaust port 42 composed of a plurality of through holes. A second air intake port 43 is formed as an air intake port composed of a plurality of through holes. The first intake port 41, the second intake port 43, and the exhaust port 42 are arranged in this order from the right side. Outside air is taken into the frame portion 22 through the first intake port 41 and the second intake port 43 , and air inside the frame portion 22 is discharged outside through the exhaust port 42 . In this embodiment, the first intake port 41, the exhaust port 42, and the second intake port 43 are composed of four through holes, four through holes, and five through holes, respectively. The number, shape and position of the through-holes can be any number, shape and position as desired.

The first intake port 41, the exhaust port 42, and the second intake port 43 are positioned forward of the front surface 13A of the water supply cassette 13 and the front surface 14A of the water receiver 14 in the attached state. Therefore, when the water supply cassette 13 and the water receiver 14 are attached to the main body 2, the first intake port 41, the exhaust port 42, and the second intake port 43 are not blocked by the water supply cassette 13 and the water receiver 14. , intake and exhaust are not obstructed by the water supply cassette 13 and the water receiver 14. - 特許庁

As shown in FIG. 5, the inside of the frame portion 22 is a range surrounded by a front portion 22A, a rear portion 22B, an outer peripheral surface portion 22C, and an inner peripheral surface portion 22D. The interior of the frame portion 22 is partitioned by a partition wall 45 to form two spaces, a first channel 47 and a second channel 48, which are channels. The partition wall 45 is arranged inside 24B of the lower side portion 24 . A space (path) from the right side of the partition wall 45 through the right side portion 26, the upper side portion 23, and the left side portion 25 to reach the exhaust port 42 is the first flow path 47, and the lower side portion 24 is provided from the left side of the partition wall 45. The space (path) through which the exhaust port 42 is reached is the second flow path 48 . The first intake port 41 and the exhaust port 42 communicate the first channel 47 with the outside, and the second intake port 43 and the exhaust port 42 communicate the second channel 48 with the outside.

As shown in FIG. 5 , a first blower fan 49 as a blower is provided in the first flow path 47 and near the first intake port 41 . By driving the first blower fan 49 , outside air is taken in from the first intake port 41 , the air flows counterclockwise in the first flow path 47 , and exits from the exhaust port 42 . Ejected. Hereinafter, the air flowing through the first flow path 47 is indicated by the white arrow Y1 and is referred to as the first cooling air.

A printed circuit board (PCB) 50 as control means for controlling the display means 35 and the operation means 36 is arranged in the upper portion of the inside 26B of the right side portion 26 (the rear portion of the operation panel 34). The printed circuit board 50 is an object to be cooled, is disposed in the first flow path 47, and is cooled by contact with the first cooling air, thereby suppressing temperature rise. Further, the flow of the first cooling air in the first flow path 47 cools the right side portion 26 itself of the door 4, and the temperature rise of the front portion 26A of the right side portion 26 is also suppressed.

A mounting plate (not shown) to which the fixing portions 33A and 33B of the handle 31 are attached by fixing members 51 such as screws is arranged in the first flow path 47 formed in the inside 23B of the upper side portion 23 . The mounting plate, which is an object to be cooled, is cooled by being brought into contact with the first cooling air, and a temperature rise is suppressed. As a result, high-temperature heat is less likely to be conducted to the handle 31, and an increase in the temperature of the handle 31 is suppressed. The mounting plate extends to the inside 23B of the upper side portion 23 and the inside 25B of the left side portion 25, and when the mounting plate comes into contact with the first cooling air, the upper side portion 23 and the left side portion 25 themselves are This cools the front portion 23A of the upper side portion 23 and the temperature rise of the front portion 25A of the left side portion 25 is suppressed.

As shown in FIG. 5, a rib 53 is provided in the first flow path 47 and in the vicinity of the exhaust port 42 as a path extension portion for increasing the length of the first flow path 47. ing. The ribs 53 are connected to the front portion 22A and the rear portion 22B of the frame portion 22 . The first cooling air taken in from the first intake port 41 absorbs heat from the door 4 and the printed circuit board 50 in the process of flowing through the first flow path 47, and is disposed on the cooking chamber 5 side. Since heat is absorbed from a contacting object such as the back surface portion 22B of the frame portion 22, the temperature of the air has risen when it reaches the vicinity of the exhaust port . Therefore, by providing the ribs 53 and increasing the length of the first flow path 47, the time in which the air contacts the frame portion 22 in the vicinity of the exhaust port 42 is increased, and the heat of the first cooling air is dissipated. The heat is transmitted to the frame portion 22 to dissipate the heat, and after the temperature of the first cooling air is lowered to a certain extent, it is discharged from the exhaust port 42 .

Although the rib 53 of this embodiment is formed of a linear plate member, it may have another shape as long as the length of the first flow path 47 is increased. Further, the positions at which the ribs 53 are arranged and the number of the ribs 53 provided may be changed as appropriate.

In this embodiment, the printed circuit board 50, which is the object to be cooled, is disposed in the interior 26B of the right side portion 26. Therefore, the first intake port 41 is located on the right side portion 26 side of the bottom portion 38 of the frame portion 22. is provided so that the printed circuit board 50 can be efficiently cooled by the low-temperature air taken inside the frame portion 22. In this case, the first intake port 41 is provided on the left side portion 25 side of the bottom portion 38 , the exhaust port 42 is provided on the right side portion 26 side of the bottom portion 38 , and the air flows through the first flow path 47 . You may make it flow to the right (clockwise) inside.

A second blower fan 54 as a blower is provided in the second flow path 48 and near the second intake port 43 . By driving the second blower fan 54 , outside air is taken in through the second intake port 43 , the air flows through the second flow path 48 , and is discharged from the exhaust port 42 . Hereinafter, the air flowing through the second flow path 48 is indicated by an outline arrow Y2, and is referred to as the second cooling air. The partition wall 45 is arranged between the first blower fan 49 and the second blower fan 54 .

A wireless communication device 55 that enables wireless communication between the microwave oven 1 and another communication device (not shown) is arranged in the second flow path 48 . The second cooling air taken in from the second air intake port 43 contacts the wireless communication device 55, which is an object to be cooled, in the course of flowing through the second flow path 48, absorbs heat from the wireless communication device 55, It joins the first cooling air at a junction 56 formed near the exhaust port 42 and is discharged to the outside from the exhaust port 42 . In this embodiment, the wireless communication device 55 is cooled by the second cooling air, and the lower side portion 24 itself is cooled, so that the temperature rise of the front portion 24A of the lower side portion 24 is suppressed. Part of the lower side portion 24 is also cooled by the first cooling air.

In the present embodiment, since the first air intake port 41 and the second air intake port 43 are provided at positions separated from the air exhaust port 42, the air discharged from the air exhaust port 42 and having a raised temperature is transferred to the first The structure is such that it is difficult to take in the inside of the frame portion 22 from the intake port 41 and the second intake port 43 .

In this embodiment, since the window portion 21 is connected to the frame portion 22, the temperature of the inner peripheral surface portion 22D of the frame portion 22 is lowered by the first cooling air and the second cooling air. Heat is conducted to the frame portion 22 from the window portion 21, so that the temperature rise of the window portion 21 is suppressed.

The first flow path 47 and the second flow path 48 join before (near) the exhaust port 42 . This confluence portion 56 is formed by a regulation wall portion 57 that regulates the flow of air. The restriction wall portion 57 is connected to the front portion 22A of the frame portion 22, the rear portion 22B of the frame portion 22, and the inner upper surface portion 24C of the lower side portion 24. As shown in FIG. The restricting wall portion 57 partially partitions the first flow path 47 and the second flow path 48 . Therefore, the regulation wall portion 57 prevents the first cooling air from flowing into the second flow path 48 .

The regulating wall portion 57 includes a right inclined plate portion 58 inclined so as to be lowered from the inner upper surface portion 24C toward the confluence portion 56 side (exhaust port 42 side), and a lower end portion of the right inclined plate portion 58 extending toward the confluence portion 56 direction. a lower plate portion 59 extending horizontally from the inner surface portion 24C, a vertical plate portion 60 extending vertically downward from the inner upper surface portion 24C, a lower end portion of the vertical plate portion 60, and a junction portion 56 connected to the lower plate portion 59. and a left inclined plate portion 61 inclined so as to become lower toward the side.

The second flow path 48 narrows downstream due to the restriction wall portion 57 . Since the first cooling air blown out from the first blower fan 49 has a longer flow distance than the second cooling air blown out from the second blower fan 54, the flow velocity when reaching the confluence portion 56 is It is slower than the flow velocity when the second cooling air reaches the confluence portion 56 . Also, the shortest distance D2 between the inner lower surface portion 24D of the lower side portion 24 and the lower plate portion 59 is formed shorter than the shortest distance D1 between the rib 53 and the regulation wall portion 57 . Therefore, the flow velocity of the second cooling air that merges at the confluence portion 56 becomes even faster than the flow velocity of the first cooling air. When the pressure of the second cooling air becomes lower than the pressure of the first cooling air, the first cooling air is accelerated while joining the first cooling air and the second cooling air, and the joining portion From 56 , it flows integrally to the exhaust port 42 . A black arrow Y3 shown in FIG. 5 indicates the confluence of the first cooling air and the second cooling air.

After flowing downward along the vertical plate portion 60 , the first cooling air is guided along the left inclined plate portion 61 toward the exhaust port 42 . Since the left inclined plate portion 61 is inclined toward the merging portion 56, the first cooling air and the second cooling air are prevented from colliding and joining at right angles, so that they can be joined smoothly. there is

The area of the opening K2 leading to the confluence 56 of the second flow path 48 of the present embodiment is formed smaller than the area of the opening K1 leading to the confluence 56 of the first flow path 47. The flow velocity of the second cooling air that joins at 56 is made even faster than the flow velocity of the first cooling air. The area of the opening K1 connected to the confluence 56 of the first flow path 47, the area of the opening K2 connected to the confluence 56 of the second flow path 48, and the lengths of the shortest distance D1 and the shortest distance D2 are , the flow velocity of the second cooling air can be changed as appropriate so that the flow velocity of the first cooling air is higher than that of the first cooling air.

Since the first cooling air flows over a longer distance and receives more heat than the second cooling air, the temperature when it reaches the junction 56 is higher than temperature. However, the heat of the first cooling air is radiated by the ribs 53 and is transferred to the second cooling air having a lower temperature by joining with the second cooling air. Therefore, the temperature of the merged air discharged from the exhaust port 42 is lower than or equal to the predetermined temperature.

As described above, the microwave oven 1 of the present embodiment includes the main body 2 having the cooking chamber 5 therein, and the door 4 for opening and closing the opening 3 of the main body 2. Inside the door 4, there is an object to be cooled. A first flow path 47 through which the first cooling air for cooling (the printed circuit board 50, the wireless communication device 55, and the mounting plate) flows and a second flow path 48 through which the second cooling air flows are formed. Inside the door 4, a confluence portion 56 where the first flow path 47 and the second flow path 48 merge is formed, so that the slow first cooling air is diverted to the fast second cooling air. The first cooling air can be accelerated by joining the first cooling air. In addition, the temperature of the first cooling air can be lowered by merging the first cooling air with a high temperature with the second cooling air with a low temperature.

Further, in the microwave oven 1 of the present embodiment, the first flow path 47 is formed longer than the second flow path 48, so that the amount of heat received by the first cooling air is equal to that of the second cooling air. Although the amount of heat is greater than the amount of heat, the merging of the first cooling air and the second cooling air at the confluence portion 56 transfers the heat of the first cooling air to the second cooling air, resulting in the temperature of the confluence being less than a predetermined temperature. It becomes wind and is discharged from the exhaust port 42 . Therefore, it is possible to prevent high-temperature hot air from blowing out from the exhaust port 42 .

Further, the microwave oven 1 of the present embodiment has an exhaust port 42 in the door 4 for discharging the first cooling air and the second cooling air to the outside of the door 4, and the confluence portion 56 is near the exhaust port 42. , the first cooling air having a high temperature and the second cooling air having a low temperature are merged before being discharged from the exhaust port 42, and discharged from the exhaust port 42 as a combined air having a temperature equal to or lower than a predetermined temperature. can do.

Moreover, since the air outlet 42 is formed in the lower part of the door 4, the microwave oven 1 of the present embodiment can discharge the merged air from a portion that is difficult for the user to touch.

In addition, the microwave oven 1 of the present embodiment has a restriction wall portion 57 that controls the wind direction of the first cooling air and the wind direction of the second cooling air toward the confluence portion 56. and the second cooling air can be smoothly merged.

In addition, in the microwave oven 1 of the present embodiment, the opening area of the second flow path 48 leading to the confluence portion 56 is smaller than the opening area of the first flow path 47 leading to the confluence portion 56, so that the confluence portion 56 The first cooling wind and the second cooling wind join together in a state in which the wind speed of the second cooling wind is faster than the wind speed of the first cooling wind at the confluence portion 56, so that the first cooling wind in the confluence portion 56 is changed to It is possible to accelerate the first cooling air flowing through the first flow path 47, thereby increasing the cooling efficiency of the first cooling air.

A second embodiment of the present invention will be described below. It should be noted that common reference numerals are given to portions that are common to the first embodiment described above, and description of common portions will be omitted as much as possible to avoid duplication.

FIG. 6 shows a second embodiment. In this embodiment, a restriction wall portion 66 having a shape different from that of the restriction wall portion of the first embodiment is formed. The restriction wall portion 66 of the present embodiment is connected to the front portion 22A of the frame portion 22, the rear portion 22B of the frame portion 22, and the inner upper surface portion 24C of the lower side portion 24. As shown in FIG. The restricting wall portion 66 is connected to an upper plate portion 67 arranged above the wireless communication device 55 and an end portion of the upper plate portion 67 on the confluence portion 56 side (exhaust port 42 side). A right inclined plate portion 68 inclined downward, a vertical plate portion 69 vertically extending downward from the inner upper surface portion 24C, and a lower end portion of the vertical plate portion 69 and the right inclined plate portion 68 are connected and merged. and a lower plate portion 70 extending horizontally on the portion 56 side. A connection portion between the vertical plate portion 69 and the lower plate portion 70 is curved. A tip portion 70A of the lower plate portion 70 extends below the tip portion 53A of the rib 53 . The restricting wall portion 66 partially partitions the first flow path 47 and the second flow path 48 . Therefore, the regulation wall portion 66 prevents the first cooling air from flowing into the second flow path 48 .

The upper plate portion 67 extends in the horizontal direction, narrows the vertical width of the second flow path 48 formed in the inner portion 24B of the lower side portion 24, and reduces the air supplied from the second blower fan 54. This is for efficiently contacting the wireless communication device 55 . A windward end portion 71, which is an end portion on the second blower fan 54 side (upstream side) of the upper plate portion 67, is not connected to the inner upper surface portion 24C. The upper plate portion 67 is positioned slightly above the upper end portion 72 of the second blower fan 54, so that the air blown out from the second blower fan 54 easily flows below the upper plate portion 67. ing. A space P is formed between the upper plate portion 67 and the inner upper surface portion 24C, and the windward side end portion 71 is not connected to the inner upper surface portion 24C. Air blown from the blower fan 54 may flow in, but as shown in FIG. Very little compared to the amount of air.

The first flow path 47 is narrowed toward the downstream side by the rib 53 and the restricting wall portion 66 . Also, the second flow path 48 is narrowed toward the downstream side by the inner lower surface portion 24</b>D and the restricting wall portion 66 . The shortest distance D3 between the inner lower surface portion 24D and the lower plate portion 70 is substantially the same as the shortest distance D4 between the rib 53 and the regulating wall portion 66. As shown in FIG. In addition, the area of the opening leading to the confluence 56 of the second flow path 48 and the area of the opening leading to the confluence 56 of the first flow path 47 are formed to be substantially the same. However, since the flow distance of the first cooling air is longer than that of the second cooling air, the flow velocity when reaching the confluence portion 56 is slower than the flow velocity when reaching the confluence portion 56 of the second cooling air. Therefore, since the pressure of the second cooling air becomes lower than the pressure of the first cooling air, the first cooling air is accelerated while joining the first cooling air and the second cooling air, and the joining portion From 56 , it flows integrally to the exhaust port 42 . A black arrow Y3 shown in FIG. 6 indicates the confluence of the first cooling air and the second cooling air.

After flowing downward along the vertical plate portion 69 , the first cooling air is guided along the lower plate portion 70 toward the confluence portion 56 . Since the lower plate portion 70 extends horizontally, the first cooling air and the second cooling air smoothly merge while flowing in parallel.

As described above, the microwave oven 1 of the present embodiment has the restriction wall portion 66 that controls the direction of the first cooling air and the direction of the second cooling air toward the confluence portion 56, thereby cooling air and the second cooling air can be smoothly merged.

It should be noted that the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the present invention. For example, the object to be cooled may be something other than the printed circuit board 50 and the wireless communication device 55 . In addition, the object to be cooled need not be disposed inside the first flow path 47 and the second flow path 48, and is disposed so as to be in contact with the first flow path 47 and the second flow path 48. For example, it may be arranged at a position where heat can be absorbed by the gas flowing inside the first flow path 47 and the second flow path 48 .

1 Microwave oven (heating cooker)
2 main body 3 opening 4 door 5 cooking chamber 42 exhaust port 47 first channel 48 second channel 50 printed circuit board (object to be cooled)
55 wireless communication device (object to be cooled)
56 confluence portion 57 regulation wall portion 66 regulation wall portion

Claims (6)

a main body having a cooking chamber inside;
a door that opens and closes the opening of the main body,
A first flow path through which a first cooling air for cooling an object to be cooled flows and a second flow path through which a second cooling air flows are formed inside the door,
A heating cooker, wherein a confluence portion where the first flow path and the second flow path join is formed inside the door. 2. The heating cooker according to claim 1, wherein said first flow path is formed longer than said second flow path. The door has an exhaust port for exhausting the first cooling air and the second cooling air to the outside of the door,
3. The heating cooker according to claim 1, wherein said confluence is formed in the vicinity of said exhaust port. 4. The heating cooker according to claim 3, wherein said exhaust port is formed in a lower portion of said door. 5. The cooling device according to claim 1, further comprising a regulating wall portion for controlling the direction of the first cooling air and the direction of the second cooling air toward the confluence portion. heating cooker. The opening area of the second flow path leading to the junction is smaller than the opening area of the first flow path leading to the junction. heating cooker.

Images