JP3786117B2 - Induction heating cooker - Google Patents

Description

  The present invention relates to an induction heating cooker built in a kitchen or the like equipped with a roaster.

Conventionally, this type of induction heating cooker has a roaster door 2 on the left front surface of the main body 1 and a heater on the ceiling in the back main body as shown in FIG. 3, a saucer 4, and a grill net 5, and a roaster case 6 that is baked on one side. On the opposite side of the roaster door 2, an operation unit 7 that sets the output of the front surface of the main body 1, and a plurality of heating coils 8 and 9. And a plurality of printed circuit boards 10 and 11 constituting a drive circuit corresponding to the heating coils 8 and 9, a radial heater 12, and a plurality of cooling fans 13 and 14 corresponding to the plurality of printed circuit boards 10 and 11. The plurality of cooling fans 13 and 14 blow air to the printed circuit boards 10 and 11, the heating coils 8 and 9, and the entire main body 1. The energization control devices for the roaster heater 3 and the radial heater 12 are included in the printed circuit boards 10 and 11, respectively. And by setting it as such a structure, since the several heating coil is cooled with the separate fan with the printed circuit board which comprises each drive circuit, it can implement | achieve cooling in the main body 1 very efficiently. (For example, see Patent Documents 1 to 5).
JP-A-3-114173 JP-A-3-114190 JP-A-5-190276 JP-A-11-354264 Japanese Patent Laid-Open No. 11-87039

  However, the induction heating cooker having such a configuration requires that the distance between the heating coil 8 and the printed circuit board 10 be a predetermined dimension, and the height dimension of the main body 1 to be incorporated in the kitchen is determined. It is difficult to realize a wide roaster in the cabinet under the restriction of the height of 6, for example, it is difficult to provide a double-sided roaster having heaters above and below the grill.

In order to solve the above problems, the present invention provides a top plate provided on an upper surface of a main body surrounded by an integrated outer shell, and a first heating coil and a second heating coil provided below the top plate. A plurality of printed circuit boards forming a drive circuit for the heating coil, a roaster heating chamber provided so that a gap is formed between the bottom surface of the main body and one of the left and right sides of the main body, and the roaster heating chamber A heat insulating partition at the top of the roaster heating chamber provided to cover the partition plate on the center side of the main body of the roaster heating chamber, an intake port provided on the opposite side of the roaster heating chamber at the rear of the upper surface of the main body, and the An exhaust port provided on the roaster heating chamber side, the second heating coil on the upper side of the heat shield partition, the plurality of printed boards on the side of the roaster heating chamber, and the plurality of print bases. A cooling fan is provided in the vicinity of the back side of each of the plurality of boards, the plurality of printed boards are supported by the board holding base in a multilayer, and a partition is further provided so as to cover the printed board. A ventilation path is formed, the first heating coil is provided above the partition, a vent is formed in the partition, a first ventilation is formed in the lower part of the partition plate, and cooling air from the cooling fan is formed. Is sent from the intake port to the ventilation path, flows from the ventilation path to pass through the ventilation hole and cools the second heating coil, and a part of the cooling air flows from the ventilation path to the ventilation path. It passes through the first vent hole and the induction heating cooker to be discharged from the blown into the gap between the bottom panel and the roaster heating chamber the exhaust port, requiring a wide compartment double-sided baked roaster roaster The induction heating cooker comprising the so easily realized.

As clearly above, according to the invention according to any one of claims 1 to 3, and a second heating coil which is provided through the roaster heating chamber and the heat insulating partition wall on one side of the body, a roaster heating a first pressurization heating coil on the opposite side of the chamber, and the printed circuit board a driving circuit of the first and second heating coils individually configured, since a cooling fan, a height dimension which limited the body at the same time realize a wide user-friendly roaster within duplex baked roaster and refrigerator at medium, the roaster heating chamber opposite the space on the printed circuit board and on the first of the first and second heating coil of a drive circuit Realize efficient cooling with one cooling fan by forming layered cooling while discharging heat from the roaster heating chamber in the heating coil, realizing an induction heating cooker with low noise generated by the cooling fan etc. Can do.

Further, since the built-in main body is surrounded by a single outer shell, the cooling air can be sent to the entire main body with one cooling fan. In addition, since the position of the inlet and exhaust ports are in the top rear portion of the body, even those Haisuru hot air such as an oven under body when embedded in the kitchen, write Mana physician suck the hot air directly. Further, since the exhaust port is located at the rear part of the main body, the exhaust heat of the main body does not directly hit the user, and the flow of the cooling air in the main body flows in a substantially U shape .

Further, since the driving circuit section by the cooling fan for blowing air to the second heating coil after cooling, b and Suta heating chamber, to easily realize an induction heating cooker provided with a plurality of pressurized heat coil. Further, the upper printed circuit board is covered with a partition wall to form a duct-like cooling air passage, so that the cooling effect is enhanced.

In addition , among the heat shield partitions and partition plates arranged around the roaster heating chamber , a first ventilation port is provided in the lower part of the partition plate on the center side of the main body, and a part of the wind after cooling the drive circuit section is provided in the first Since the air is blown into the gap between the bottom surface of the main body and the roaster heating chamber through the vent hole, the bottom surface side of the roaster heating chamber and the bottom surface of the main body are cooled, and the temperature of the bottom surface of the main body near the roaster heating chamber can be reduced. Thereby, when there is no partition plate in the lower part of the induction heating cooker due to the form of the kitchen incorporating the main body, it is possible to eliminate the fear of burns even if the bottom surface of the induction heating cooker body is touched by mistake.

According to the invention according to any one of claims 4-6, of the thermal barrier septum and a partition plate arranged in the circumference of the roaster heating chamber, a roaster heating chamber above the heat insulating partition wall, sides and the main body of the roaster heating chamber A second ventilation port is provided so that there is a horizontal overlap with the gap with the side surface, and a part of the air after cooling the second heating coil is passed through the second ventilation port and the side surface of the main body and the side surface of the roaster heating chamber. since for blowing air to the gap, blowing around the second heating coil is sufficiently performed above the roaster heating chamber, and at the same time the heat of the roaster heating chamber is reduced from reaching the second heating coil, the roaster heating The temperature of the main body shell adjacent to the chamber can be reduced. Thereby, when the temperature of the 2nd heating coil on a roaster heating chamber is aimed at, and a main body is integrated and used for a kitchen, the temperature reduction of the kitchen adjacent to the induction heating cooking appliance main body side surface can be aimed at.

According to the seventh aspect of the invention, in particular, a plurality of printed circuit boards are individually stacked as a unit on the substrate holder, so that the main body can be easily assembled and disassembled.

The invention according to claim 1, wherein the present invention includes a top plate provided on the upper surface of the main body surrounded by shell that is integral, the first heating coil and a second heating that is provided under the top plate A coil, a plurality of printed circuit boards that form a drive circuit for the heating coil, a roaster heating chamber provided so that a gap is formed between the bottom surface of the main body on one of the left and right sides of the main body, and the roaster heating A heat shield partition at the top of the roaster heating chamber provided to cover the chamber, a partition plate on the main body side of the roaster heating chamber, an intake port provided on the opposite side of the roaster heating chamber at the rear of the upper surface of the main body, and and an exhaust port provided in the roaster heating chamber side, the second heating coil on the upper side of the heat insulating partition wall, a plurality of printed circuit board on the side of the roaster heating chamber, said plurality of printed circuit A cooling fan is provided in the vicinity of the back side of each of the plurality of boards, the plurality of printed boards are supported by the board holding base in a multilayer, and a partition is further provided so as to cover the printed board. A ventilation path is formed, the first heating coil is provided above the partition, a vent is formed in the partition, a first ventilation is formed in the lower part of the partition plate, and cooling air from the cooling fan is formed. Is sent from the intake port to the ventilation path, flows from the ventilation path to pass through the ventilation hole and cools the second heating coil, and a part of the cooling air flows from the ventilation path to the ventilation path. The induction heating cooker passes through the first ventilation port and is blown into the gap between the bottom surface of the main body and the roaster heating chamber and discharged from the exhaust port . By adopting this configuration as an embodiment, the height of the main body is determined because of the built-in type, and at the same time, a roaster heating chamber with a large internal height such as double-sided baking is realized, and at the same time, efficient cooling inside the main body, and consequently cooling An induction heating cooker with low noise generated by a fan or the like can be realized. In addition, an induction heating cooker including a roaster heating chamber and a plurality of heating coils can be easily realized. Moreover, the temperature of the bottom surface of the main body adjacent to the roaster heating chamber can be reduced.

In the invention according to claim 2 of the present invention, in addition to the configuration according to claim 1, the first ventilation port is provided at a position where there is an overlap in the height direction with respect to the gap between the roaster heating chamber and the bottom of the main body. It is what was done. By adopting this configuration as an embodiment, the temperature of the bottom surface of the main body near the roaster heating chamber can be reduced.

In the invention according to claim 3 of the present invention, in addition to the induction heating cooker according to claim 1 or 2, the first ventilation opening is provided in the first half of the depth dimension of the main body. By adopting this configuration as an embodiment, the area through which the cooling air flows through the bottom surface of the roaster heating chamber along the path to the exhaust port can be increased, and the cooling effect can be enhanced.

According to a fourth aspect of the present invention, there is provided a top plate provided on an upper surface of a main body surrounded by an integrated outer shell, a first heating coil and a second heating plate provided below the top plate. A coil, a plurality of printed circuit boards forming a drive circuit for the heating coil, a roaster heating chamber provided on one of the left and right sides in the main body, and the roaster heating chamber provided so as to cover the roaster heating chamber An upper heat shield partition and a partition plate on the center side of the main body of the roaster heating chamber, an intake port provided on the opposite side of the roaster heating chamber at an upper rear portion of the main body, and an exhaust port provided on the roaster heating chamber side The second heating coil on the upper side of the thermal barrier, the plurality of printed boards on the side of the roaster heating chamber, and a cooling fan in the vicinity of the back side of the plurality of printed boards. The The plurality of printed circuit boards are supported by a substrate holding base in a multilayer structure, and a partition is further provided to cover the printed circuit board to form a ventilation path with the substrate holding base and the partition, A first heating coil is provided, a vent is formed in the partition, and a second ventilation is provided in the heat shield partition so that there is a horizontal overlap with a gap between the side surface of the roaster heating chamber and the side surface of the main body. The cooling air from the cooling fan is sent from the intake port to the ventilation path, passes through the ventilation hole from the ventilation path, and flows to cool the second heating coil. A part of the cooling air after cooling the second heating coil is blown into the gap between the main body side surface and the roaster heating chamber side surface from the second ventilation port, and is discharged from the exhaust port. the Than it is. With this arrangement embodiment, it is possible to reduce the temperature of the body shell side heat roaster heating chamber close to the side surface of the same time the roaster heating chamber Reducing reaching the second heating coil.

The invention according to claim 5, wherein the present invention, in addition the induction heating cooker of claim 4 Symbol mounting, the second vent hole are those provided at the end of the body side surface of the thermal barrier septum. With this configuration embodiment, can it to reduce the temperature of the body shell side proximate to the side of the roaster heating chamber.

In the invention according to claim 6 of the present invention, in addition to the induction heating cooker according to claim 5 , the second ventilation opening is provided at the front portion of the heat shield partition . With this configuration embodiment, can it to reduce the temperature of the body shell side proximate to the side of the roaster heating chamber.

According to a seventh aspect of the present invention, in addition to the induction heating cooker according to any one of the first to sixth aspects , a plurality of printed circuit board portions that individually constitute drive circuit portions in the main body are each a substrate holding base. In this case, a plurality of printed circuit boards are stacked in multiple layers. By adopting this configuration as an embodiment, it is possible to efficiently suck in the outside air of the main body cooling and at the same time enhance the cooling effect of the drive circuit unit that is collected and arranged on the opposite side of the roaster and facilitate the assembly and disassembly of the main body. it can.

Example 1
A first embodiment of the present invention will be described below with reference to FIGS.

  In the figure, a heating coil 23, a heating coil 24 as a left heating source, and a radial heater 25 behind the heating coil 23 are provided at the lower front right of the top plate 22 on the upper surface of the main body 21. A roaster door 26 and a roaster heating chamber 27 on the back side thereof are provided on the left side of the front surface of the main body, and the interior of the roaster heating chamber 27 is provided with a saucer, a grill, and heaters on both the upper and lower sides of the grill (see FIG. (Not shown) This constitutes a double-sided roaster. For this reason, the height of the roaster heating chamber 27 is increased, and the upper side of the roaster heating chamber 27 has only a heating coil 24 in a limited space via a heat shield partition 28. It is arranged. An operation unit 29 for setting the output of the main body 21 of the cooking device on the front right side of the main body, and a drive circuit for the first printed circuit board 30 and the left heating coil 24 constituting the driving circuit for the right heating coil 23 at the back thereof. The plurality of printed circuit boards 30 and 31 are supported by the substrate holding bases 32 and 33 in two layers, and the first printed circuit board 30 and the substrate holding base 32 The printed circuit board 31 and the substrate holder 33 are stacked individually as a unit. Further, a sirocco-type cooling fan close to the back side and disposed so that the rotation axis is orthogonal to the printed circuit boards 30, 31, a motor 35 thereabove, an intake duct 36 covering the cooling fan 34 and the motor 35, It has. Further, the drive circuit for the radial heater 25 and the roaster heater is configured in the printed circuit boards 30 and 31. Further, the rear upper surface of the main body 21 is provided with an intake port 37 connected to the intake duct 36 and an exhaust port 38 on the roaster heating chamber 27 side on the opposite side. In addition, the upper end position of the base holder 33 that is united with the second printed circuit board 31 is substantially the same height as the heat shield partition wall 28. As described above, the main body 21 is an integral type that is integrated by the outer shell and is supported by a kitchen or the like by the flange 39 on the upper portion of the outer shell. On the roaster heating chamber 27, a heat insulating partition 28, a support spring (not shown) for the left heating coil 24, and a relay terminal block for electrically connecting the heating coil 24 and the second printed circuit board 31 are provided. Only structures that are loosely temperature-constrained and difficult to thermally break down are disposed. Further, when the main body 21 is viewed from the top, the cooling fan 34, the first printed circuit board 30, and the second printed circuit board 31 are disposed on the side of the body 21 at a position that does not overlap the roaster heating chamber 27.

  Next, the operation of this embodiment will be described. Since the roaster heating chamber 27 is a double-sided baking provided with heaters on both the upper and lower sides of the inside of the roaster heating chamber 27, at least the height dimension of the heater below the roasting net becomes high, and the other is between the heating coil 24 on the left side. The second printed circuit board 31 constituting the driving circuit of the heating coil 24 cannot be disposed under the heating coil 24, and is not provided on the right side of the roaster heating chamber 27. The first printed circuit board 30 and two layers are disposed in a space behind the operation unit 29. As a result, only one cooling fan 34 behind the two-layer printed circuit boards 30 and 31 can efficiently cool the plurality of printed circuit boards 30 and 31 directly and cool the printed circuit boards 30 and 31 at the same time. Since the fan 34 is disposed separately from the roaster in the planar direction, the heat effect of the roaster can be reduced and the fan 34 can be cooled. Further, since the right heating coil 23 is disposed on the first printed circuit board 30, a part of the blowing air from the cooling fan 34 directly cools the right heating coil 23. Since the cooling fan 34 is a sirocco type whose rotation axis is orthogonal to the printed circuit boards 30 and 31, the cooling balance can be easily made equal by adjusting the vertical positions of the printed circuit boards 30 and 31.

  As a result, it is possible to provide a roaster that needs to increase the internal height of double-sided baking, and by arranging the printed circuit boards 30 and 31 of the heating coil driving circuit in two layers in the main body 21 with one cooling fan. In addition to concentrating the cooling required parts, mainly the large current parts in the printed circuit boards 30 and 31, in positions where they are not easily affected by the heat of the roaster, the upper heating coil 23 can be cooled at the same time, thereby realizing efficient cooling. . Furthermore, since the cooling fan is composed of one piece, an induction heating cooker with low noise is realized. Moreover, if it is set as the structure of a present Example, since the height of the roaster heating chamber 27 can be enlarged until it adjoins to the left heating coil 24, since the main body 21 is a built-in type to a kitchen, the height of the main body 21 Even if it is determined from the kitchen dimensions, it can be raised as much as possible, and a wide roaster that is easy to use can be provided.

  In the present embodiment, the built-in main body 21 is surrounded by a single outer shell, so that the cooling air can be sent to the entire inside of the main body 21 with a single cooling fan. In addition, since the position of the intake port 37 and the exhaust port 38 is the rear upper surface of the main body 21, even when there is something that exhausts hot air such as an oven under the main body 21 when it is installed in the kitchen, the hot air is not directly sucked in. Therefore, it is possible to prevent the intake air temperature sucked into the main body 21 from rising by about 20K, and the internal cooling of the main body 21 can be sufficiently achieved, and the protection device does not operate due to the temperature rise due to hot air. Further, since the exhaust port 38 is located at the rear portion of the main body 21, the exhaust heat of the main body 21 does not directly hit the user, and the flow of the cooling air in the main body becomes a high temperature as shown by an arrow in FIG. Since it flows in a substantially U shape so as to avoid the radiator heater 25, it is possible to prevent the heat from being removed from the heater 25 which does not require cooling. Moreover, since the printed circuit boards 30 and 31 are united with the board holding bases 32 and 33, the main body 21 can be easily assembled and disassembled. Further, since the upper end of the upper substrate holding base 33 and the heat shielding partition 28 are substantially the same height, the printed circuit boards 30 and 31 that are driving circuits for the heating coils 23 and 24 and the cooling fan 34 are placed in the space on the right side of the roaster. With this, it can be cooled intensively to dissipate the heat of the roaster. In addition, since the printed circuit boards 30 and 31 overlap the layers, the space between them can be blown in a duct shape, and the cooling efficiency is improved. Further, the ventilation resistance around the two heating coils 23 and 24 can be made equal, and the temperatures of the two heating coils 23 and 24 can be easily made equal, and the members that hold the heating coils 23 and 24 are shared. Can be.

  In this embodiment, there are two heating coils and two layers of the printed circuit board. However, the present invention is not limited to this, and there are three heating coils and three layers of printed circuit boards, or one heating coil on the right front. However, the other heat source may be an electric heating type radial heater or the like, and the same effect can be obtained even if the printed circuit board has a plurality of layers for heating coil driving circuit and other heat source driving.

(Example 2)
Hereinafter, a second embodiment 2 of the present invention will be described with reference to FIGS. 4, 5 and 6.

  In the figure, a main body 41, a top plate 42, a first heating coil 43, a second heating coil 44, a radiant heater 45, a roaster door 46, a roaster heating chamber 47, a saucer provided inside the roaster heating chamber 47, The grille and both the upper and lower heaters (not shown) of the grille are the same as those in the first embodiment. Therefore, the height of the roaster heating chamber 47 is increased, and the upper side of the roaster heating chamber 47 is insulated. Only the heating coil 44 is disposed in a limited space through the partition wall. Further, the operation unit 48, the first printed circuit board 49 constituting the drive circuit for the first heating coil 43, the second printed circuit board 50 constituting the drive circuit for the second heating coil 44, and the substrate holders 51 and 52. The cooling fan 53, the motor 54, the intake duct 55, the intake port 56, and the exhaust port 57 have the same configuration as in the first embodiment.

  The difference from the first embodiment is that a substrate cover 58 is provided so as to cover the first printed circuit board 49 on the upper side, and a ventilation path is formed by the substrate holding base 51 and the substrate cover 58, and at the outlet side of the ventilation path A first rear wall 48a is provided that serves as a deflecting plate for cooling air, and serves as a main vent at a position in front of the rear end of the left second heating coil 44 on the left side, which is near the roaster. The opening 59 is provided with a second opening 60 that follows the right side.

  The operation in this configuration is as follows. The cooling air sent from the cooling fan 53 is cooled while passing through the printed circuit boards 49 and 50 each having a ventilation passage, and then the flow path is changed at the operation unit rear wall 48a, most of which is the first of the substrate cover 58. The cooling air that has passed through the opening 59 and the second opening 60 and has exited from the first opening 59 passes through the left second heating coil 44, and the cooling air that has exited from the second opening 60 passes through the right first heating coil. 43 flows to cool down. The left heating coil 44 is located away from the first opening 59, and is also affected by the heat of the roaster heating chamber 47 below it, so that it is necessary to improve the cooling performance of the right first heating coil 43. One opening 59 is made larger than the second opening 60 to be a main opening. Thereby, the cooling performance of the left second heating coil 44 far from the cooling fan 53 is ensured. Further, since the position of the first opening 59 is in front of the rear end of the left second heating coil 44, most of the cooling air from the first opening 59 is the left second heating coil. Therefore, the cooling efficiency of the left second heating coil 44 can be increased.

  As described above, the effect of the present embodiment is as follows.

  With the configuration of this embodiment, as in the previous embodiment, the height of the roaster heating chamber 47 can be maximized, and a wide and convenient roaster can be provided in the cabinet, and at the same time, a cooling fan can be provided above the roaster. The cooling of the second heating coil 44 can be sufficiently achieved even at a position far from 53 and susceptible to the thermal effects of the roaster. Further, the cooling air can be effectively sent to the second heating coil 44 on the roaster side, and the cooling efficiency can be improved. In this way, the restriction of the arrangement position of the heating coil is eliminated, and an induction heating cooker including a plurality of heating coils can be easily realized. In addition, the first printed circuit board 49 is covered with a substrate cover 58 to form a duct-like cooling air passage, and the cooling effect of the upper first printed circuit board is enhanced.

Example 3
A third embodiment of the present invention will be described below with reference to FIGS.

  In the figure, there are shown a main body 61, a top plate 62, heating coils 63 and 64, a radiant heater 65, a roaster door 66, a roaster heating chamber 67, a tray 67a, a grill 67b and a grill 67b provided in the roaster heating chamber 67. Both the upper heater 67c and the lower heater 67d have the same configuration as that of the first embodiment. Therefore, the height dimension of the roaster heating chamber 67 is a space (H shown in FIG. 7) necessary for placing the food. Only the heating coil 64 is disposed in the space above the roaster heating chamber 67 through the heat shielding case 68. In addition, the operation unit 69, the first printed circuit board 70 that constitutes the drive circuit for the heating coil 63, the second printed circuit board 71 that constitutes the drive circuit for the heating coil 64, the substrate holders 72, 73, and cooling fans (not shown). ), A motor (not shown), an intake duct 74, a heat insulating partition 75, an intake port 76, and an exhaust port 77 have the same configuration as in the first embodiment.

  The difference from the first embodiment is that, among the heat shield partition wall 75 and the partition plate 79 provided so as to cover the roaster heating chamber 67 above the roaster heating chamber 67 and on the center side of the main body, a ventilation port 80, 81 is provided. The positions of the ventilation openings 80 and 81 are provided such that the gap between the bottom surface of the heat shielding case 68 and the bottom surface of the main body 61 overlaps in the height direction.

  With such a configuration, a part of the cooling air blown from the cooling fan and cooled down the first printed circuit board 70 and the second printed circuit board 71 is indicated by an arrow in FIG. 7 due to the pressure generated by the cooling fan. As described above, the air is blown from the ventilation openings 80 and 81 at the lower part of the partition plate 79 to the gap between the heat shielding case 68 of the roaster and the bottom surface of the main body 61, and is discharged from the exhaust port after cooling the bottom side of the roaster and the bottom surface of the main body 61. As a result, the temperature of the bottom surface of the outer shell of the main body close to the roaster can be reduced. As a result, when the main body 61 is incorporated into a kitchen and used, there is no partition plate in the kitchen when the lower door of the induction heating cooker incorporated according to the form of the kitchen is opened, and therefore the portion where the bottom surface of the induction heating cooker body is exposed Although there are many, even if it touches the bottom face of an induction heating cooking appliance main body accidentally in such a case, the worry of a burn can be eliminated. The number of ventilation openings of the partition plate 79 may be one, or three or more. Further, by providing it in the first half of the depth dimension of the main body 61, the area flowing through the bottom surface of the heat shield case 68 of the roaster can be increased along the path to the exhaust port 77, and the cooling effect can be enhanced.

(Example 4)
A fourth embodiment of the present invention will be described below with reference to FIGS.

  In the figure, a main body 91, a top plate 92, heating coils 93 and 94, a radiant heater 95, a roaster door 96, a roaster heating chamber 97, a tray 97a, a grill 97b and a grill 97b provided in the roaster heating chamber 97 are shown. The heaters of both the upper heater 97c and the lower heater 97d have the same configuration as that of the above-described embodiment. Therefore, the height of the roaster heating chamber 97 is a space (J shown in FIG. 9) necessary for placing the food. Only the heating coil 94 is disposed in the space above the roaster heating chamber 97 through the heat insulating partition wall 98. In addition, the operation unit 99, the first printed circuit board 100 constituting the drive circuit for the heating coil 93, the second printed circuit board 101 constituting the drive circuit for the heating coil 94, the board holding base 102, 103 cooling fans (not shown). ), A motor (not shown), an intake duct 104, an intake port 105, and an exhaust port 106 have the same configuration as in the above-described embodiment.

  The difference from the above-described embodiment is the main body side of the heat insulating partition wall 98 among the heat insulating partition wall 98 and the partition plate 107 provided so as to cover the roaster heating chamber 97 above the roaster heating chamber 97 and on the center side of the main body. The vent hole 108 is provided in the left end front part. The position of the ventilation hole 108 is provided so that there is a horizontal overlap in the gap between the left side surface of the heat shield case 109 and the left outer wall of the main body 91.

  With such a configuration, most of the cooling air after being blown from the cooling fan and cooling the printed circuit boards 100 and 101 is blown around the left heating coil 94 by the pressure generated by the cooling fan. As shown by the arrows, the air is blown from the ventilation port 108 at the front left end of the heat shield partition wall 98 to the gap between the heat shield case 109 of the roaster and the front left front wall of the main body 91, and the left side of the roaster and the left outer side of the main body 91 are The wall is cooled from front to back and discharged from the rear exhaust port. By this action, air is sufficiently blown around the heating coil 94 above the roaster heating chamber 97 to reduce the heat of the roaster from reaching the heating coil 94, and at the same time, the temperature of the left outer surface of the main body near the roaster is reduced. Can be reduced. As a result, the temperature of the heating coil 94 on the roaster heating chamber 97 can be reduced, and at the same time, when the main body 91 is incorporated in a kitchen, the temperature of the kitchen adjacent to the side surface of the induction heating cooker main body is reduced, The heat influence by the induction heating cooker main body that the temperature of the member which comprises a kitchen rises and durability falls can be reduced.

(Example 5)
A fifth embodiment of the present invention will be described below with reference to FIGS.

  In the figure, a main body 121, a top plate 122, heating coils 123 and 124, a radiant heater 125, a roaster door 126, a roaster heating chamber 127, a tray (not shown) provided in the roaster heating chamber 127, a grill (see FIG. A first printed circuit board 129 that constitutes a drive circuit for the heaters of both the upper heater (not shown) and the lower heater (not shown) of the grill, the lower heater (not shown), the operation unit 128, and the heating coil 123, and the heating The second printed circuit board (not shown), the board holding bases 130 and 131, the cooling fan 132, the motor (not shown), and the intake duct 133 constituting the drive circuit of the coil 124 have the same configuration as that of the first embodiment. is there.

  The difference from the first embodiment is that, in addition to the intake port 134 and the exhaust port 135 provided at the rear part of the main body 121, the air flow narrower than that of the exhaust port 135 on the front surface of the main body 121 on the left front of the left heating coil 124 and above the roaster door 126. The point is that a mouth 136 is provided.

  With this configuration, when the cooling air after cooling the heating coil 124 is discharged only from the exhaust port 135 at the rear of the main body, it is difficult for the cooling air to reach the left front corner portion of the main body away from the exhaust port 135. Although 124 was difficult to be cooled, the stagnation of the cooling air at the left front corner in the main body is eliminated by exhausting the air through the vent hole 136 on the left front side of the main body. This is to reduce the temperature rise and increase the cooling effect of the entire body. Further, since the cooling air is warmed while passing through the main body 121 and expands in volume, a large area of the exhaust port is required. However, the ventilation port 136 serves as an auxiliary exhaust port to reduce an increase in exhaust resistance and reduce the increase in exhaust resistance. The cooling effect is enhanced.

(Example 6)
A sixth embodiment of the present invention will be described below with reference to FIGS.

  In the figure, the main body 141 is provided with heating coils 143 and 144 on the top and bottom of the top plate 142 on the upper surface and on the left and on the lower side, and on the rear side with a heating heater 145. A roaster door 146 and a roaster heating chamber 147 at the back of the roaster door 146 are provided on the left side of the front surface of the main body, and the inside of the roaster heating chamber 147 is provided with a tray, a grill, and heaters on both the upper and lower sides of the grill ( It constitutes a double-sided roaster. For this reason, the height dimension of the roaster heating chamber 147 is increased, and only the heating coil 144 is disposed in a limited space on the upper side of the roaster heating chamber 147 via a heat insulating partition. On the right side opposite to the roaster side of the main body is an operation unit 148 for setting the output of the cooker main body 141 on the front surface, and a first printed circuit board 149 that constitutes a drive circuit for the right heating coil 143 and the left side heating. The second printed board 150 constituting the drive circuit of the coil 144 is supported by the board holding bases 151 and 152 so as to form two horizontal layers. A sirocco-type cooling fan 153, a motor 154 thereabove, and an intake duct 155 that covers the cooling fan 153 and the motor 154 are provided near the rear. Driving circuits for the radiant heater 145 and the roaster heater are formed in the printed circuit boards 149 and 150. Further, the rear portion of the main body is provided with an intake port 156 connected by an intake duct 155 and an exhaust port 157 on the opposite side.

  Next, the operation of this embodiment will be described.

  Below the left heating coil 144, the height of the roaster heating chamber 147 is required, so that the space is fitted and the drive circuit cannot be provided. Therefore, the printed circuit boards 149 and 150 are arranged in two layers in the main body space on the side opposite to the roaster so as to overlap with the drive circuit of the right heating coil 143. In this way, since a plurality of printed circuit boards 149 and 150 including power semiconductors such as switching elements and rectifiers can be integrated into one place, a single cooling fan 153 is disposed so as to span both printed circuit boards 149 and 150. By doing so, the cooling air is diverted to the plurality of printed circuit boards and can be efficiently cooled. In this embodiment, the cooling fan 153 is a sirocco type, but other types such as an axial flow type have the same effect. In this embodiment, the motor 154 is disposed on the sirocco-type cooling fan 153 so as not to be exposed to the inlet side from the inlet wall of the inlet duct 155 connected to the inlet 156. At the same time as efficient suction, even if water or foreign matter enters from the air inlet 156, it can easily reach the bottom of the air intake duct 155 without hitting the motor 154, and the reliability of the cooker body can be improved against malfunctions, etc. . Since the cooling fan 153 sucks in from both upper and lower surfaces, the air blown from the outlet of the cooling fan 153 is not biased upward or downward, so that the cooling air can be evenly distributed to the plurality of printed circuit boards 149 and 150, and the motor 154 is sufficiently cooled. The In this embodiment, the printed circuit boards 149 and 150 are arranged in two layers horizontally, but the present invention is not limited to this, and the same effect can be obtained by arranging two layers substantially vertically.

( Reference Example 1 )
Hereinafter, Reference Example 1 of the present invention will be described with reference to FIGS. 16, 17 and 18.

  In the figure, a main body 161, a top plate 162, two heating coils 163 and 164, a radiant heater 165, a roaster door 166 on the left side of the main body, a roaster heating chamber 167, a saucer, a grill net, and a grill net inside the roaster heating chamber 167. Both upper and lower heaters (not shown), the operation portion 168 on the anti-roaster side of the main body, the first printed circuit board 169, the second printed circuit board 170, the substrate holding bases 171 and 172, and the intake air at the rear of the main body 161 The port 173 and the exhaust port 174 have the same configuration as in the above embodiment.

  A difference from the above embodiment is that a sirocco-type cooling fan 175, a motor 176, and a fan duct 177, which are a centrifugal type, are placed in front of a plurality of printed circuit boards 169 and 170 arranged in two layers. This is that the shaft of the fan duct 177 is disposed sideways, and the blowout port of the fan duct 177 is disposed on the upper side of the main body so as to face the roaster or to the rear of the roaster.

Next, the operation of this reference example will be described. The flow of cooling air when the cooling fan 175 is operated passes through the cooling ducts of the printed circuit boards 169 and 170 formed by the substrate holders 171 and 172 from the air inlet 173 and is sucked into the cooling fan 175. Further, the fan duct 177 is mainly discharged from the blowout port in the direction of the roaster, and is exhausted from the exhaust port 174 to the outside of the main body 161. Since the cooling fan 175 is a sirocco type in this path, it is easy to change the direction of the cooling air passing through the printed circuit boards 169 and 170 from the air inlet 173 into an L shape or a U shape. As shown in the figure, there is an effect that the cooling air is easily sent also to the left heating coil 164 side above the roaster, and air is efficiently blown from the left side of the main body to the exhaust port. In this reference example, the cooling fan 175 is a sirocco type. However, the present invention is not limited to this, and the same effect can be obtained even with other types of centrifugal fans such as a turbo type.

The perspective view of the induction heating cooking appliance in Example 1 of this invention Broken plan view of the induction heating cooker Vertical side sectional view of the induction heating cooker The perspective view of the induction heating cooking appliance in Example 2 of this invention Broken plan view of the induction heating cooker Vertical side sectional view of the induction heating cooker Vertical front sectional drawing of the induction heating cooking appliance in Example 3 of this invention Perspective view of the induction heating cooker Vertical front sectional drawing of the induction heating cooking appliance in Example 4 of this invention Perspective view of the induction heating cooker The perspective view of the induction heating cooking appliance in Example 5 of this invention Broken plan view of the induction heating cooker The perspective view of the induction heating cooking appliance in Example 6 of this invention Broken plan view of the induction heating cooker Vertical side sectional view of the induction heating cooker The perspective view of the induction heating cooking appliance in the reference example 1 of this invention Broken plan view of the induction heating cooker Vertical side sectional view of the induction heating cooker Perspective view of a conventional induction heating cooker Vertical front sectional view of the induction heating cooker

Explanation of symbols

21, 41, 61, 91, 121, 141, 161 Main body 22, 42, 62, 92, 142, 162 Top plate 23, 24, 63, 64, 93, 94, 123, 124, 143, 144, 163, 164 Heating coil 27, 47, 67, 97, 127, 147, 167 Roaster heating chamber 29, 48, 69, 99, 148, 168 Operation unit 48a Operation unit rear wall (deflection plate)
30, 49, 70, 100, 169 First printed circuit board (drive circuit unit)
31, 50, 71, 101, 170 Second printed circuit board (drive circuit section)
34, 53, 132, 153, 175 Cooling fan 28, 75, 98 Thermal barrier 37, 56, 76, 105 Inlet port 38, 57, 77, 106 Exhaust port 43 First heating coil 44 Second heating coil 51 , 52, 72, 102, 103 Substrate holder 58 Substrate cover 59 First opening 60 Second opening 79, 107 Partition plate 80, 81, 108 Ventilation opening

Claims (7)

Forming a top plate provided on the upper surface of the main body surrounded by shell that is integral, a first heating coil and a second heating coil provided below the top plate, the driving circuit of the heating coil A plurality of printed circuit boards, a roaster heating chamber provided so that a gap is formed between the bottom surface of the main body on one of the left and right sides in the main body, and an upper portion of the roaster heating chamber provided so as to cover the roaster heating chamber A partition wall on the center side of the main body of the roaster heating chamber, an intake port provided on the opposite side of the roaster heating chamber at the rear of the upper surface of the main body, and an exhaust port provided on the roaster heating chamber side the provided, the second heating coil on the upper side of the heat insulating partition wall, a plurality of printed circuit board on the side of the roaster heating chamber, it cooling fan in close proximity to the rear side of the plurality of printed circuit board The plurality of printed circuit boards are supported by a substrate holding table in a multilayer structure, and a partition is further provided to cover the printed circuit board to form a ventilation path between the substrate holding table and the partition, and above the partition The first heating coil is provided, a ventilation hole is formed in the partition, a first ventilation port is formed at a lower portion of the partition plate, and cooling air from the cooling fan is sent from the intake port to the ventilation path. And flows from the ventilation path through the ventilation hole to cool the second heating coil, and a part of the cooling air passes from the ventilation path through the first ventilation hole to the main body. An induction heating cooker that is blown into a gap between a bottom surface and the roaster heating chamber and is discharged from the exhaust port . The induction heating cooker according to claim 1, wherein the first ventilation opening is provided at a position where there is an overlap in a height direction with respect to a gap between the roaster heating chamber and the bottom surface of the main body . The induction heating cooker according to claim 1 or 2, wherein the first ventilation opening is provided in the first half of the depth dimension of the main body . Forming a top plate provided on the upper surface of the main body surrounded by shell that is integral, a first heating coil and a second heating coil provided below the top plate, the driving circuit of the heating coil A plurality of printed circuit boards, a roaster heating chamber provided to form a gap with the side surface of the main body on one of the left and right sides of the main body, and an upper portion of the roaster heating chamber provided to cover the roaster heating chamber A partition wall on the center side of the main body of the roaster heating chamber, an intake port provided on the opposite side of the roaster heating chamber at the rear of the upper surface of the main body, and an exhaust port provided on the roaster heating chamber side the provided, the second heating coil on the upper side of the heat insulating partition wall, a plurality of printed circuit board on the side of the roaster heating chamber, it cooling fan in close proximity to the rear side of the plurality of printed circuit board The plurality of printed circuit boards are supported by a substrate holding table in a multilayer structure, and a partition is further provided to cover the printed circuit board to form a ventilation path between the substrate holding table and the partition, and above the partition The first heat coil is provided, a vent is formed in the partition, and a second overlap is formed in the heat shield partition so that there is a horizontal overlap with a gap between the side surface of the roaster heating chamber and the side surface of the main body. While forming the ventilation port, the cooling air by the cooling fan is sent from the intake port to the ventilation path, flows from the ventilation path through the ventilation hole, and flows to cool the second heating coil, A part of the cooling air after cooling the second heating coil is blown from the second ventilation port to the gap between the side surface of the main body and the side surface of the roaster heating chamber and is discharged from the exhaust port . . 5. The induction heating cooker according to claim 4 , wherein the second ventilation opening is provided at an end of the heat shield partition on the side surface of the main body . The induction heating cooker according to claim 4 or 5 , wherein the second ventilation opening is provided at a front portion of the heat shielding partition . The induction heating cooker according to any one of claims 1 to 6, wherein a plurality of printed boards are individually stacked as a unit on a board holding table .

Images