JP5202185B2 - Induction cooking device - Google Patents

Description

  The present invention relates to a cooking device for cooking with an electromagnetic induction heating source having two or more heating action portions. The induction heating type cooking device targeted by the present invention is a so-called stationary type installed on kitchen furniture (not shown) such as a kitchen sink and kitchen furniture. The present invention relates to one or both types of built-in type or built-in type used by being installed in an installation space.

  A conventional cooking device includes an electromagnetic cooking device that heats the upper surface of one main body (housing) with a plurality of electromagnetic induction heating sources (see, for example, Patent Document 1).

Japanese Patent No. 3997895 (see FIGS. 1 and 2)

  However, in the conventional cooking device, a large multi-blade centrifugal fan that constitutes a blower is installed in the right space inside the main body on the vertical axis, so that outside air is introduced and installed in the right space of the main body. The inverter circuit components and the like are cooled, and the resulting wind is guided to a plurality of IH heating coil parts, which are the main parts of the induction heating source, and after the coil parts are cooled, the wind is passed through the power supply board part etc. It was that. Therefore, the cooling air led to the highest temperature IH heating coil part is heated by the heat of the inverter circuit components in the previous stage, and the IH heating coil part that is the original heating target cannot be sufficiently cooled. there were. For this reason, it was considered to use a fan with a large blowing capacity or to increase the driving power to increase the blowing capacity as a countermeasure to solve this, but increased costs, increased operating noise, and used power Another problem such as an increase in the amount occurred, which was not practical. Therefore, there has been a problem that the IH heating coil portion must be effectively cooled without impairing the cooling efficiency of the electrical components of the inverter circuit.

  The present invention has been made to solve the above-described problems, and can effectively cool a plurality of IH heating coil portions that are at high temperatures and improve the cooling effect of the inverter circuit board. An object of the present invention is to provide an induction heating cooking device that can be used.

The induction cooking device according to the present invention includes a main body, a top plate covering a top surface of the body, is disposed below the top plate, the induction heating comprising at least two heating coils which are energized independently of one another and wherein the heating source, and a circuit board inverter circuit for supplying high-frequency power is mounted on the induction heating type heat source, a blower for supplying cooling air to the body interior space, an energization state of the induction heating type heat source and display means for displaying, a grill heating chamber built below the induction heating heat source of the main body is partitioned inside the body, the termination unit is an induction heating which is provided with an exhaust chamber that communicates with the external space, the in cooker, inside of the body, extending in the longitudinal direction in the right or left space of the grill heating chamber, and forming a cooling chamber which is isolated from the internal space of the grill heating chamber, wherein The却室, accommodating the blower therein, the said circuit board housed inside the cooling air from the blower is installed a cooling unit which is to be cooled, the cooling unit, incorporating the blower A fan case and a component case in which cooling air discharged from the exhaust port of the fan case is introduced and the circuit board is accommodated are integrated. The component case includes a first exhaust port, A second exhaust port is provided apart in the front-rear direction, and the two are disposed between the first and second exhaust ports of the component case constituting the cooling unit and the lower space of each heating coil. the cooling duct for communicating arranged, the cooling duct is supplied from the blower, a first ejecting holes for spewing each cooling air exiting from the first outlet to the respective heating coils, before Is supplied from the blower, the cooling air exiting the second exhaust port is provided respectively a second ejecting holes for spewing respectively to the each heating coil, the cooling duct, the first, second exhaust among the mouth, the cooling air from the component case the display unit toward the second exhaust port provided in the, by branching in front of the second ejecting holes provided vents leading to the display means the first of the cooling duct, and air after cooling the heating coil is blown from the second ejecting hole, and the air that has cooled the display unit blown from the vent, the exhaust It flows into the chamber and is discharged to the outside of the main body.

  Since the present invention is configured as described above, it is possible to effectively cool two induction heating sources (6R, 6L) at the same time while cooling the circuit board (41) on which the inverter circuit components are mounted. It has become.

Embodiment 1 FIG.
FIGS. 1-9 shows the heat cooking apparatus which concerns on Embodiment 1 of this invention, Comprising: The induction heating cooking apparatus called a built-in type or a built-in type is shown.
FIG. 1 is a perspective view of the cooking device with the top plate portion removed.
FIG. 2 is a plan view showing the entire main body.
FIG. 3 is a plan view with the top plate portion of FIG. 1 removed.
4 is a vertical sectional view taken along line IV-IV in FIG.
FIG. 5 is a longitudinal sectional view of the right cooling chamber portion of FIG.
6 is a longitudinal sectional view taken along the line VI-VI in FIG.
FIG. 7 is an exploded perspective view of the cooling unit, the cooling duct, and the component case.
FIG. 8 is a block diagram of the control circuit.
FIG. 9 is a longitudinal sectional view showing the upper front part of the main body.
In the drawings, the same or corresponding parts are denoted by the same reference numerals. This also applies to Embodiments 2 and 3 described later.

(Heat cooker body)
The cooking device of the present invention includes a single rectangular main body A. The main body A usually has a top plate B that constitutes the upper surface of the main body A, a casing C that constitutes the periphery (outside) other than the upper surface of the main body A, pots, foods, etc. with electric energy or the like. Heating means D for heating, operating means E operated by a user, control means F for controlling the heating means in response to a signal from the operating means, and display means G for displaying the operating conditions of the heating means are provided. Some of the heating means C include an electric heating means called a grill box or a roaster.

Next, terms used in the embodiments of the present invention are defined respectively.
The operating conditions of the heating means refer to electrical and physical conditions for heating, and collectively refers to energization time, energization amount, heating temperature, energization pattern (continuous energization, intermittent energization, etc.) and the like.

Display means that the user is informed of operating conditions and related information that is useful for cooking (changes in characters, symbols, illustrations, colors, presence / absence of light emission, light emission brightness, etc.) Including the target one, this is simply the operation of visually informing the user of “Cooking related information”.
Unless otherwise specified, the display means is a liquid crystal (LCD), various light emitting elements (an example of a semiconductor light emitting element is LED (Light Emitting Diode), LD (Laser Diode)), organic An electroluminescence (EL) element etc. are included. For this reason, the meaning of the display means includes a display screen such as a liquid crystal screen or an EL screen.

The notification is an operation for notifying the user of the operation conditions of the control means and cooking-related information by display or electrical sound (refers to electrically generated or synthesized sound).
Unless otherwise specified, the notification means includes notification means using audible sounds such as a buzzer and a speaker, and notification means using characters, symbols, illustrations, or visible light.

(Housing C)
In FIG. 1, A is a main body part whose entire upper surface is covered with a top plate part B described later, and this main body part covers an installation port K1 (see FIG. 9) whose outer shape is formed in kitchen furniture such as a sink. It is formed in a substantially square or rectangular shape with a predetermined size that matches the size and space.

  2 is a main body case that forms the outer surface of the casing, and a body 2A formed by bending a single flat metal plate with a press molding machine a plurality of times, and an end of the body, It consists of a front flange plate 2B made of a metal plate joined together by fixing means such as welding or rivets, screws, etc., and in the state where these front flange plates and the body portion 2A are coupled by fixing means, the upper surface is It becomes an open box shape.

  The body case 2 has flanges formed by integrally bending outwardly into an L-shape at the rear end portion, right end portion, and left end portion of the upper surface opening, 3B is a rear flange, and 3L is a left side. The flange 3R is a right flange, and these three flanges and the front flange plate 2B are placed on the upper surface of the installation part (see FIG. 6) of the kitchen furniture KT to support the load of the cooking device.

  In the state where the cooking device is completely accommodated in the kitchen furniture installation opening K1, the front portion of the cooking device is exposed from the opening KTK formed in front of the kitchen furniture KT, and from the front side of the kitchen furniture. The front (left and right) operation unit 60 of the cooking device can be operated, and the front opening of the grill heating chamber 9 can be opened and closed by pulling the door 13 forward.

  2S is an inclined surface connecting the back surface and the bottom surface of the body portion 2A. When the cooking device is installed in the kitchen furniture, it is cut so as not to collide with or interfere with the rear edge of the kitchen furniture installation port K1. It is. That is, when this type of cooking device is installed in kitchen furniture, it is tilted so that the front side of the main body A of the cooking device is down, and in this state, it is dropped into the kitchen furniture installation port K1 from the front side first. . Thereafter, the rear side is dropped into the installation port K1 with a delay, and the installation method is described in detail in, for example, Japanese Patent Application Laid-Open No. 11-121155. Due to such an installation method, the front flange plate 2B has a sufficient space SP between the front edge of the installation opening K1 of the kitchen furniture when the cooking device is installed in the kitchen furniture. It is such a size (see FIG. 8).

  Inside the main body case 2, induction heating type heat sources (hereinafter also referred to as IH heating sources) 6L, 6R for induction heating a heated object N such as a metal pan placed on a top plate 21 described later. An electric heater for heating with electric radiant heat, for example, a heater 7 that generates heat at a high speed called a radiant heater, a control means F that controls cooking conditions of an induction heating type heat source, and the cooking conditions are input to the control means An operation means E to be described later and a display means G for displaying the operating conditions of the heating means input by the operation means are provided. Hereinafter, each will be described in detail.

  The interior of the casing C is roughly divided into a box-shaped grill (or roaster) heating chamber 9, and a cooling chamber 8, an upper component chamber 10, and a rear exhaust chamber 12 that extend long in the front-rear direction on the right side. However, the rooms are not completely isolated from each other. For example, the cooling chamber 8, the upper part chamber 10, and the exhaust chamber 12 are communicated. The cooling chamber 8 is partitioned and formed by further dividing the lower space of the horizontal partition plate 25 that partitions the interior of the housing portion C up and down by the partition plate 24 left and right.

  The grill heating chamber 9 is a substantially independent sealed space when a door 13 to be described later is closed. However, the grill heating chamber 9 is provided in an external space of the casing C via the exhaust duct 14, that is, an indoor space such as a kitchen. Communicate.

(Top plate B)
As will be described below, the top plate portion B is composed of two large parts, an upper frame (also referred to as a frame) 20 and a top plate (also referred to as an upper plate, top glass, or top plate) 21.
The upper frame 20 is formed in a frame shape from a metal plate such as a non-magnetic stainless steel plate or an aluminum plate, and has a size that closes the upper surface opening of the main body case 2.

  The top plate 21 is placed so as to cover a large opening provided in the center of the upper frame 20. The entire top plate is made of a translucent material that transmits infrared rays, such as heat-resistant tempered glass or crystallized glass, and is formed in a rectangular or square shape according to the shape of the opening 20A of the upper frame 20. Furthermore, the top plate 21 is fixed in a watertight state with a rubber packing or a seal material PK interposed between the opening 20A of the upper frame 20 or the upper surface as shown in FIG. Accordingly, water droplets or the like from the upper surface of the top plate 21 are prevented from entering the inside of the main body part A through the gap between the upper frame 20 and the top plate 21.

In FIG. 2, reference numeral 11 denotes a flat lid plate formed entirely from a thin metal plate, and is fixed on the upper frame 20. Reference numeral 20B denotes a right vent hole that is simultaneously punched and formed by a press machine when the cover plate 11 is formed, and serves as an intake passage of the blower 30 described later.
Similarly, 20C is a central vent hole formed by punching when the cover plate 11 is formed, and 20D is a left vent hole similarly punched and formed when the cover plate 11 is formed.

  9E is a through-hole formed in the upper frame 20 as shown in FIG. 9, which is a right heating power setting operation unit 70, a central operation unit 72, and a left heating power setting operation unit 71 of the upper surface operation unit 61 described later. This is for passing 15 push buttons for operating various switch operation keys (for example, operation switches for starting energization of the heaters 22 and 23 of the grill heating chamber 9). In FIG. 9, only one through hole 20E is drawn for the sake of drawing.

  In the actual cooking stage, the top plate 21 receives heat from a heated object N such as a pan heated to a high temperature by the right IH heating source 6R and the left IH heating source 6L, which will be described in detail later, and reaches 300 degrees or more. Sometimes. Further, when a central electric heating source 7 which is a radiation type electric heater described later is provided below the top plate 21, the top plate 21 is directly heated to a high temperature by the heat from the central electric heating source 7, The temperature can reach 350 degrees or more.

  Reference numeral 121 denotes a rear frame formed entirely of a thin metal plate, and is fixed to the upper frame 20 by fixing means such as screws. Reference numeral 123 denotes a front frame formed entirely of a thin metal plate, and is fixed to the upper frame 20 by fixing means such as screws (see FIGS. 6 and 9).

  In FIG. 9, 123A is a through-hole formed in the front frame 123, which is various switches of the right heating power setting operation unit 70, the central operation unit 72, and the left heating power setting operation unit 71 of the upper surface operation unit 61 described later. This is for passing 15 push buttons 254A for operating the operation keys (for example, operation switches for starting energization of the heaters 22 and 23 of the grill heating chamber 9). The through hole 123A is formed at a position corresponding to the through hole 20E of the upper frame 20 described above. In FIG. 9, only one through hole 123A is drawn for the sake of drawing.

  Although not shown, the upper frame 20 is fixed to the main body case 2 with a fixing tool such as a screw.

  On the top surface of the top plate 20, as shown in FIGS. 1 and 2, circular guide marks 6RM indicating the positions of the rough heating zones of the right IH heating source 6R, the left IH heating source 6L, and the central electric heating source 7 which will be described later. , 6LM, and 7M are displayed by a method such as printing.

(Heating means D)
In the present invention, as the heating means, the right IH heating source 6R located at the upper right position of the main body A, the left IH heating source 6L on the left side, and the radiant central electric heating located near the rear on the left and right center line of the main body A. A source 7 and a pair of upper and lower radiant electric heating sources 22 and 23 for the roaster are provided. These heating sources are configured such that energization is controlled independently from each other by the control means F. Details will be described later with reference to FIG.

(Right IH heating source)
The right IH heating source 6 </ b> R is installed inside the upper part chamber 10 that is partitioned and formed inside the main body case 2. A right IH heating coil (induction heating coil) 6RC is disposed on the lower surface side of the top plate 21 at the right side position. The upper end of the coil is close to the lower surface of the top plate 21 with a minute gap, and serves as an electromagnetic induction heating source. In this embodiment, for example, a device having a maximum power consumption (maximum thermal power) of 3 KW is used. The right IH heating coil 6RC is formed by winding a bundle of about 30 thin wires of about 0.1 mm in a spiral shape, and winding this bundle (hereinafter referred to as a collective wire) while twisting one or more wires so that the outer shape becomes circular. Thus, it is finally formed into a disk shape. The diameter (maximum outer diameter dimension) of the right IH heating coil 6RC is about 180 mm.

  The left and right IH heating coils 6LC, 6RC are provided with a high permeability material, for example, a plate or rod made of ferrite, as a magnetic flux leakage prevention material from the coils. In the form, the illustration is omitted. The magnetic flux leakage prevention material does not need to cover the entire lower surfaces of the left and right IH heating coils 6LC and 6RC, and the magnetic flux leakage prevention material formed in a rod shape with a cross section of, for example, a square or a rectangle is predetermined so as to intersect the right IH heating coil 6RC. A plurality may be provided at intervals. A plurality of radials may be provided from the center of each coil.

  The position of the guide mark RM which is a circle (shown by a broken line in FIG. 1) displayed on the top plate 21 is not completely coincident with the outermost peripheral position of the right IH heating coil 6RC of the right IH heating source 6R. . The guide mark indicates a proper induction heating area. A circle indicated by a dashed line in FIG. 3 is an outer peripheral edge position of the left and right IH heating coils 6LC and 6RC.

  The right IH heating coil 6RC may be divided into a plurality of parts so as to be energized independently. For example, an IH heating coil is wound inside in a spiral shape, and another large-diameter spiral IH heating coil is placed on the outer peripheral side of the IH heating coil on the same concentric circle and substantially on the same plane. The object to be heated may be heated in three energization patterns: energization of the heating coil, energization of the outer IH heating coil, and energization of the inner and outer IH heating coils. Thus, from at least one of the output level, duty ratio, and output time interval of the high-frequency power flowing through the two IH heating coils, or a combination thereof, it is efficient from a small pan to a large (large diameter) pan. Heating may be performed (Japanese Patent No. 2978069 is known as a typical technique using such a plurality of coils that can be independently energized).

  31R is an infrared type temperature detection element installed in the central space (CK) of the right IH heating coil 6RC (see FIG. 7).

  An infrared temperature detection element (hereinafter referred to as an infrared sensor) is configured by a photodiode or the like that can measure the temperature by detecting the amount of infrared rays emitted from an object to be heated N such as a pan. The temperature detection element may be a heat transfer type detection element, for example, a thermistor type temperature sensor.

  For example, Japanese Patent Application Laid-Open No. 2004-95144 (Patent No. 3975865) and Japanese Patent Application Laid-Open No. 3975865 disclose that infrared rays emitted from an object to be heated according to the temperature thereof are quickly detected from below the top plate 21 by an infrared sensor. No. 2006-310115 and JP-A No. 2007-18787 are known.

  When the temperature detection element 31R is an infrared sensor, the infrared rays emitted from the object to be heated can be collected and received in real time (with little time difference) to detect the temperature from the amount of infrared rays (thermistor type) Better than). This temperature sensor can be heated regardless of whether the temperature of the top plate 21 made of heat-resistant glass or ceramics in front of the object to be heated and the temperature of the object to be heated are the same. The temperature of the object can be detected. That is, the infrared rays radiated from the object to be heated are devised so that they are not absorbed or blocked by the top plate 21. For example, the top plate 21 is selected from a material that transmits infrared rays having a wavelength range of 4.0 μm or 2.5 μm or less, while the temperature sensor 31R detects infrared rays having a wavelength range of 4.0 μm or 2.5 μm or less. The one is selected.

  On the other hand, when the temperature detection element 31R is of a heat transfer type such as a thermistor, it is inferior in capturing a rapid temperature change in real time as compared with the above-described infrared temperature sensor, but the top plate 21 and the object to be heated The temperature of the bottom plate of the object to be heated and the top plate 21 immediately below it can be detected reliably. Further, the temperature of the top plate 21 can be detected even when there is no object to be heated. In the case where the temperature detection element is a heat transfer type such as a thermistor, the temperature detection unit is brought into direct contact with the lower surface of the top plate 21 or a member such as a heat transfer resin is interposed to place the temperature detection element on the top plate 21 itself. The temperature may be grasped as accurately as possible. This is because if there is an air gap between the temperature sensing unit and the lower surface of the top plate 21, a temperature transmission is delayed.

(Left IH heating source)
The left IH heating source 6L is installed at a position contrasting with the right IH heating source 6R across the left and right center line of the main body A, and has the same configuration as the right IH heating source 6R. That is, the temperature detection element 31L is also installed. In this embodiment, for example, one having a maximum power consumption (maximum thermal power) of 3 KW or 2.5 KW is used. Further, the diameter (maximum outer diameter dimension) of the left IH heating coil 6LC is about 180 mm when the maximum heating power is 3 KW, and about 170 mm when the maximum heating power is 2.5 KW.

  Similarly to the right IH heating coil 6RC, the left IH heating source 6L is provided with an infrared temperature detection element (hereinafter referred to as an infrared sensor) 31L in the center space (see FIG. 8). The forefront positions of the right IH heating coil 6RC and the left IH heating coil 6LC are arranged so as to be aligned with a substantially horizontal line (reference numeral LF in FIG. 2). In the following description, the description of “left, right” in the name and “L, R” in the reference may be omitted for the contents shared for the members arranged in common on the left and right.

(Radiation type central electric heating source)
7 is a radiant central electric heating source (hereinafter referred to as “central heating source”) (see FIGS. 1 and 2), inside the main body A, on the left and right center lines of the top plate 21, and It is arranged at a position near the rear part of the top plate 21.

  The central electric heating source 7 uses an electric heater (for example, a nichrome wire, a halogen heater, or a radiant heater) that is heated by radiation, and heats an object to be heated such as a pan through the top plate 21 from below. And, for example, one having a maximum power consumption (maximum heating power) of 1.2 kW is used.

The central electric heating source 7 has a circular container shape with the entire upper surface opened, and the container-like cover 50 made of heat insulating material constituting the outermost peripheral portion has a maximum outer diameter of about 180 mm and a thickness of 5 mm. It has become.
The position of the guide mark 7M, which is a circle (solid line in FIG. 1) displayed on the top plate 21, does not completely coincide with the outermost peripheral position of the central electric heating source 7. The guide mark indicates a proper induction heating area. The circle of the case 50 in FIG. 3 is the outermost peripheral position of the central electric heating source 7.

(Radiation type electric heating source)
24R is a vertical partition plate on the right side that is installed vertically (see FIG. 3), and serves as a partition wall that separates the cooling chamber 8 and the grill heating chamber 9 from each other inside the casing C. Yes. Although not shown, the upper and lower partition plates 24L may be provided on the left side as well. The upper and lower partition plates 24R and 24L are installed with a gap 116 of about several millimeters from the outer wall surface of the grill heating chamber 9 (see FIG. 4).
Reference numeral 25 denotes a horizontal partition plate (see FIGS. 1 and 4), and has a size that divides the entire main body A into two upper and lower spaces above the grill heating chamber 9. Is the upper part chamber 10. The horizontal partition plate 25 is installed with a predetermined gap 26 of about several millimeters to 1 cm from the ceiling surface of the grill heating chamber 9 (see FIG. 6).

  The grill heating chamber 9 formed in the shape of a rectangular box has wall surfaces on the left, right, top, bottom, and back sides made of a metal plate such as stainless steel or steel plate, and the top and bottom 1 near the top ceiling and bottom as a radiant electric heating source. The pair of sheathed heaters 22 and 23 (see FIGS. 4 and 6) are installed so as to spread substantially horizontally.

  These two heaters are energized simultaneously or individually to prepare roast cooking (for example, grilled fish), grill cooking (for example, pizza or gratin), or oven cooking (for example, cake or grilling) that sets the ambient temperature in the grill heating chamber 9 for cooking. Vegetables). For example, the sheathed heater 22 near the top ceiling has a maximum power consumption (maximum thermal power) of 1200 W, and the sheathed heater 23 near the bottom has a maximum power consumption of 800 W.

  As described above, the air gap 26 is formed between the horizontal partition plate 25 and the ceiling wall surface of the grill heating chamber 9, and is finally communicated with the exhaust chamber 12. Is drawn out of the main body A through the exhaust chamber 12.

  In FIG. 1, reference numeral 28 denotes a rear partition plate that partitions the upper component chamber 10 and the exhaust chamber 12. The lower end portion has a height that reaches the horizontal partition plate 25 and the upper end portion reaches a height of the upper frame 20. 28 </ b> A is an exhaust hole formed in two places in the rear partition plate 28 for exhausting the cooling air that has entered the upper part chamber 10.

  In FIG. 3, 58 is a power supply board A at the right back corner of the upper part chamber 10, and a part of the power supply board A projects over the cooling chamber 8. A commercial power supply of 100V or 200V is drawn from the lower back. For example, various electric component groups for a rectifying bridge circuit 221 (see FIG. 8) for rectifying a commercial power supply are mounted on the power supply board A58.

  A power supply board B59 (not shown; however, refer to FIG. 16 of the second embodiment) is installed on the horizontal partition plate 25 at the left rear corner of the upper part chamber 10, and this board is located in the center. Electric power is supplied to the electric heating source 7 and the heaters 22 and 23 of the grill heating chamber 9, electric power is supplied from the power supply board A58, and various electric components for heating capacity (thermal power) control are mounted. Yes. Further, these two power supply boards are attached to the horizontal partition plate 25 with fixing means such as screws so as to maintain a certain gap 119 (see FIG. 5) from the upper surface of the horizontal partition plate 25. The gap 119 is for facilitating passage of cooling air from a cooling unit CU described later.

(Cooling fan)
As shown in FIGS. 5 and 7, the blower 30 of the cooling unit CU in this embodiment uses a centrifugal multi-blade blower (typically, there is a sirocco fan). A rotating shaft 32 having a wing 30F fixed to the tip thereof is used. The blower 30 is installed in the cooling chamber 8 to cool the left and right circuit boards for the IH heating coils 6LC and 6RC and the coils themselves, which will be described in detail below.

  When the centrifugal blower is used, the discharge capacity (blow-out capacity) is not uniform over the entire discharge port, and there is the highest part of the discharge capacity. This part is a circuit board for the left and right IH heating coils 6LC and 6RC. If it is located at a specific part of the air, the specific part is cooled by the strongest wind. However, be aware that if the air from indoor spaces such as kitchens contains oily smoke or dust, they are more likely to adhere to and accumulate on the surface of parts on specific parts of the circuit board. is necessary. This is because, over many years of use, oil deposits accumulate on the circuit board, which leads to a decrease in electrical insulation of the circuit board by absorbing moisture.

  The cooling unit CU is a cooling unit that is inserted into the cooling chamber 8 from above and is fixed. The cooling unit CU is connected to the component case 34 that houses the circuit board 41 that constitutes the inverter circuit. And a fan case 37 forming a chamber 39.

  The blower 30 is a so-called horizontal shaft type in which the rotation shaft 32 of the drive motor 31 is horizontal, and is accommodated in a fan case 37 installed in a cooling chamber (FIGS. 5 and 5). 7). A circular air space is formed in the fan case 37 so as to surround a large number of rotor blades 30F of the air blower 30, and a air chamber 39 is formed. 37 </ b> A is a suction cylinder of the fan case 37, and a suction port 37 </ b> B approaching the right ventilation port 20 </ b> B of the cover plate 11 is formed at the uppermost position. Reference numeral 37 </ b> C denotes an exhaust port (outlet) formed at one end of the fan case 37.

  The fan case 37 is formed as an integral structure (incorporating the blower 30) by combining the cases 37D and 37E, which are two plastic molded parts, and connecting them with a fixing tool such as a screw.

Reference numeral 34 denotes a component case that is connected to the fan case 37 by a fixing means such as a screw so that cooling air discharged from the air discharge outlet 37C of the fan case 37 is introduced (FIG. 5). , Refer to FIG. 7), and the whole has a horizontally-long rectangular shape, and includes an introduction port (not shown) communicating with the exhaust port 37 </ b> C, a first exhaust port 34 </ b> A and a second exhaust port 34 </ b> B described later. The entire other part except for only is sealed.
The fan case 37 containing the blower 30 as described above can be transported as an integral structure, inserted into the cooling chamber 8 from above, and fixed so as not to move by an appropriate fixing means such as a screw. The In FIG. 5, there is a gap between the exhaust port 37 </ b> C and the component case 34, but in reality, this part is connected so that the wind does not leak through a seal packing or the like.

  Reference numeral 41 denotes one printed wiring board (hereinafter referred to as a circuit board) on which inverter circuits for supplying predetermined high-frequency power to each of the right IH heating source 6R and the left IH heating source 6L are mounted (see FIG. 4). ), Having an outer dimension substantially comparable to the shape of the internal space of the component case 34, on the side farther from the grill heating chamber 9 in the component case 34, on the contrary, the main body case 2 constituting the outline of the main body portion A, It is installed on the side that is close to a few millimeters or less. The circuit board 41 is mounted with a drive power source and a control circuit unit (motor drive circuit) 33 for the drive motor 31 of the blower 30 apart from the inverter circuit portion.

  On the upper surface of the component case 34, two first exhaust ports 34A and two second exhaust ports 34B are formed along the direction in which the cooling air from the blower 30 flows. The second exhaust port 34B is located at the most downstream side of the flow of the cooling air in the component case 34, and has an opening area several times larger than that of the first exhaust port 34A. 5, Y1 to Y5 indicate the flow of the air sucked and discharged by the blower 30, and the cooling air flows in sequence Y1, Y2,... Y5.

  42 is a cooling duct formed entirely of plastic (see FIGS. 3 to 7), and an upper case 42A, which is an integrally molded product of plastic, and a lower case 42B, which is also an integrally molded product of plastic, are overlapped with screws. By fixing, three ventilation spaces 42F, 42G, and 42H, which will be described later, are formed between the two. Although the lower case 42B is not shown in FIG. 4, the lower case 42B is disposed horizontally with close contact with the upper surface of the horizontal partition plate 25 or with a gap of several mm.

  As shown in FIGS. 3 and 4, the cooling duct 42 has a length extending from the left IH heating coil 6LC to the side of the right IH heating coil 6RC. 42CB is a plurality of second ejection holes formed so as to penetrate the wall surface over the entire upper surface of the upper case 42A, and is formed to eject cooling air from the blower 30, and the diameter of each ejection hole 42CB is the same. For example, it is a perfect circle with a diameter of 10 mm.

  42D is a rib (projection) -shaped partition wall formed in a straight line on the rear side in the upper case 42A, and thereby a ventilation space 42F having one end communicating with the exhaust port 34A of the component case 34 is defined. It is formed.

  The cooling duct 42 is installed so that one side portion of the ventilation space 42H (the side close to the component case 34 in FIG. 7) is directly above the second exhaust port 34B of the component case 34. Thus, the cooling air discharged from the component case 34 enters the ventilation space 42H of the cooling duct 42, expands from here to the ventilation space 42G, and is ejected from the second ejection hole 42CB. Reference numeral 42K denotes a rectangular ventilation opening formed corresponding to the ventilation space 42H of the upper case 42A, which emits air for cooling liquid crystal display portions (liquid crystal display screens) 45R and 45L described later.

  42CA are provided on the rear of the upper surface of the upper case 42A with respect to the right IH heating coil 6RC and the left IH heating coil 6LC, respectively, and on the back surface of the upper case 42A constituting the back wall surface of the ventilation space 42F. It is a first ejection hole formed two by two, and is formed for ejecting the cooling air from the blower 30 upward. The diameter of each ejection hole 42CA is the same, for example, a circle having a diameter of 8 to 10 mm, Or it is an ellipse of about 10 mm × 8 mm.

  The two first ejection holes 42CA formed on the back side of the upper case 42A are formed so as to face the power supply substrate A58 or the power supply substrate B59, and are ventilated from the first exhaust port 34A of the cooling unit CU. The fresh (low temperature) cooling air sent to 42F is ejected toward the left and right side spaces of the power supply board A58, the power supply board B59, or the central electric heating source 7.

  43A and 43B are power control semiconductor switching elements such as an IGBT 225 in a circuit board 41 on which inverter circuits (described in detail in FIG. 8) 210R and 210L for the right IH heating source 6R and the left IH heating source 6L are mounted. And other heat-generating parts mounted on aluminum (see FIG. 5), and a large number of thin fins are regularly arranged over the entire surface. As shown in FIG. 5, the heat dissipating fins are installed on the side close to the ceiling in the component case 34, and a sufficient space SY is secured below, so that the cooling air Y4 flows through the space. Yes. That is, due to the characteristics of the blower, the discharge capacity (blowing capacity) is not uniform over the entire area of the discharge port (exhaust port 37C), and the highest part of the discharge capacity is below the vertical center point of the exhaust port 37C. The positions of the radiating fins 43A and 43B are set upward so as not to be positioned on the extended line. Further, the cooling air is not blown toward various small electronic components and printed wiring pattern portions mounted on the surface of the circuit board 41.

  The grill heating chamber 9 is built below the induction heating type heat source of the main body, and a predetermined space SX (see FIG. 3) is formed between the inner rear wall surface of the main body. That is, the grill heating chamber 9 is provided with a space SX of, for example, 10 cm or more between the body case 2 and the trunk rear wall 2U in order to install an exhaust duct 14 to be described later and to form the exhaust chamber 12.

  When the cooling unit CU is inserted and fixed in the cooling chamber 8 from above, the component case 34 housing the circuit board 41 forms a predetermined gap 118 of several mm or less on the right side wall surface of the main body case 2. (See FIG. 3). A large gap 117 is also secured between the component case 34 and the upper and lower partition plates 24R (see FIG. 4).

(Operating means E)
The operation means E of the cooking device in this embodiment includes a front operation unit 60 and an upper operation unit 61 (see FIGS. 1 to 3).
(Front operation unit)
A plastic front operation frame 62 is attached to the right front surface of the main body case 2, and the front surface of the operation frame is a front operation unit 60. The front operation unit includes a main power switch 63 for turning on / off all the power sources of the left IH heating source 6L, the right IH heating source 6R, the central electric heating source 7 and the electric heaters 22 and 23 of the roaster heating chamber 9 at the same time. The operation button 63A (see FIG. 2), the right operation dial 64R that opens and closes the electrical contacts of the right power switch (not shown) that controls the energization of the right IH heating source 6R and the energization amount (thermal power), and the left A left operation dial 64L of a left control switch (not shown) for controlling energization of the IH heating source 6L and its energization amount (thermal power), and a control switch for controlling energization of the central electric heating source 7 and its energization amount (thermal power) A central operation dial 65 (not shown) is provided.

  The front operation unit 60 is energized to the left IH heating source 6R by the left operation dial 64R and the left indicator lamp 66L that is lit only when the left IH heating source 6L is energized by the left operation dial 64L. And a right indicator lamp 66R that is lit only when it is in the closed state.

  In addition, the left operation dial 64L, the right operation dial 64R, and the central operation dial 65 are pushed inward so as not to protrude from the front surface of the front operation unit 60 as shown in FIG. In use, when the user presses the finger once and then releases it, it protrudes by the force of a spring (not shown) built in the front operation frame 62 (see FIG. 3), and the user grasps the surroundings. It will be ready to turn. And if it turns to the left or right by one stage at this stage, the left IH heating source 6L and the right IH heating source 6R are energized for the first time (with a minimum setting heating power of 120 W).

  Therefore, if either the protruding left operation dial 64L or right operation dial 64R is further rotated in the same direction, a predetermined electrical pulse generated from a built-in rotary encoder (not shown) according to the amount of rotation. Is read by the control means F, the energization amount of the heating source is determined, and the heating power can be set.

  Note that the left operation dial 64L and the right operation dial 64R are both in the initial state or are turned to the left and right in the middle, and the user presses once with a finger from the front surface of the front operation unit 60. When pushed into a predetermined position that does not protrude, both the left IH heating source 6L and the right IH heating source 6R can be de-energized (even during cooking, if the right operation dial 64R is pushed in, the right IH heating source 6R Is immediately de-energized). Further, the heating power of the central electric heating source 7 can be similarly adjusted according to the rotation amount of the dial 65.

  Further, if the operation button 63A of the main power switch 63 (see FIG. 1) is opened (OFF), then the operations of the right operation dial 64R and the left operation dial 64L are invalidated simultaneously. Similarly, the energization of the central electric heating source 7 and the built-in heaters 22 and 23 of the grill heating chamber 9 are all cut off.

  Three independent timer dials 66, 67, 68 are provided at the lower front of the front operation frame 62. These timer dials 66, 67, 68 energize the left IH heating source 6L, the right IH heating source 6R, and the central electric heating source 7 for a desired time (timer set time) from the start of energization, and the set time has elapsed. After that, the timer switch (not shown) for automatically turning off the power is operated.

(Top operation section)
The upper surface operation unit 61 includes a right heating power setting operation unit 70, a left heating power setting operation unit 71, and a central operation unit 72.
An upper surface operation unit 61 is disposed on the upper surface of the top plate 21, specifically, on the front portion of the upper frame 20. The right heating power setting operation unit 70 of the right IH heating source 6R is arranged on the right side of the left and right center line of the main body A, and the electric heater 22 installed in the central electric heating source 7 and the grill heating chamber 9 is arranged in the center. , 23, and a left heating power setting operation unit 71 of the left IH heating source 6L are arranged on the left side, respectively.

(Right heating power setting operation section)
In FIG. 1, the right heating power setting operation unit 70 is provided with a one-touch setting key unit for each heating power that can easily set the heating power of the right IH heating source 6 </ b> R with a single press by the user. Yes. For example, it has three one-touch keys, a low thermal power key, a medium thermal power key, and a strong thermal power key. The low thermal power key sets the thermal power of the right IH heating source 6R to 300 W, the medium thermal power key sets to 750 W, The strong firepower key is set to 2.5 kW. Furthermore, when the right thermal power key is provided at the right end portion of the right one-touch key portion and it is desired to set the thermal power of the right IH heating source 6R to 3 KW, this is pressed.

(Left thermal power setting operation section)
Similarly, the left heating power setting operation unit 71 for setting the heating power of the left IH heating source 6L is provided with a one-touch key group similar to the right heating power setting operation unit 70.

(Central control unit)
In FIG. 1, an operation button of an operation switch (not shown) for starting energization of heaters 22 and 23 of the grill heating chamber 9 used for grill (roast) cooking and oven cooking is provided in the central operation unit 72, and the energization thereof. An operation button (not shown) for stopping the operation is provided side by side.
Further, the central operation unit 72 has a temperature adjustment switch for setting the control temperature in grill cooking by the heaters 22 and 23 and electromagnetic cooking by the left IH heating source 6L and the right IH heating source 6R one by one in an additive or subtractive manner. Operation buttons (not shown) are provided in a horizontal row. Also, although not shown, a power on / off switch button dedicated to the central electric heating source 7 is also provided here.

  Further, the central operation unit 72 is provided with a convenient menu key (not shown). When it is operated, deep-fried food cooking (using left IH heating source 6L and right IH heating source 6R), fried food preheating status display (using left IH heating source 6L and right IH heating source 6R, heating oil to a predetermined preheating temperature ) Timer cooking (the left IH heating source 6L, the right IH heating source 6R, the central electric heating source 7 and the heaters 22 and 23 provided in the grill heating chamber 9 are energized only during the time set by the timer switch. If it is pressed when setting (cooking), a desired input screen or status display screen can be easily read on the integrated display means 100 described later. That is, the integrated display means 100 can know the operating conditions of the various heating means 6R, 6L, 7, 22, and 23 by characters.

  When the start switch key (97R in FIG. 1) for operating / starting the timer counter (not shown) is operated, the elapsed time from the start point is measured on the liquid crystal display units 45R and 45L, and the numbers are displayed. Is displayed. The display light of the liquid crystal display units 45R and 45L is transmitted through the top plate 21, and the elapsed time is clearly displayed to the user in units of “minutes” and “seconds”.

  99R is a right fried food selection switch that is also provided at the right end of the upper surface operation unit 61. When the user presses this switch once, the oil temperature in the fried food (tempura) pan by the right IH heating source 6R is set to 180 ° C. The initial setting can be made, and then the user can adjust the heating power of the right IH heating source 6R by operating the right operation dial 64R and set it to any appropriate temperature suitable for fried food, for example, 200 ° C. Similarly, the left heating power setting operation unit 71 on the left side is also provided with a left timer switch (not shown), a left liquid crystal display unit 45L, and a left fried food selection switch (not shown). Each of these switches and the liquid crystal display units 45R and 45L are provided at right and left target positions with the left and right center line of the main body A interposed therebetween.

(Thermal power indicator lamp)
On the right front side of the top plate 21, a right heating power display lamp 101R for displaying the magnitude of the heating power of the right IH heating source 6R is provided at a position between the right IH heating source 6R and the right heating power setting operation unit 70. Yes. The right thermal power display lamp 101R is provided in the vicinity of the lower surface of the top plate 21 so that display light is emitted from the lower surface thereof through the top plate 21 (transmitted).
Similarly, a left heating power display lamp 101L that displays the magnitude of the heating power of the left IH heating source 6L is located at a position between the left IH heating source 6L and the left heating power setting operation unit 71 on the left front side of the top plate 21. It is provided in the vicinity of the lower surface of the top plate 21 so that display light is emitted from the lower surface thereof through the top plate 21 (transmitted).

(Display means)
The integrated display means 100 is provided on the front side in the front-rear direction at the center of the top plate 21 in the left-right direction. This integrated display means is mainly composed of a liquid crystal panel, and is provided in the vicinity of the lower surface of the top plate 21 so that display light is emitted from the lower surface thereof through the top plate 21 (transmitted).

The integrated display means 100 inputs or confirms the energization states (heating power, time, etc.) of the left IH heating source 6L, the right IH heating source 6R, the central electric heating source 7, the heaters 22 and 23 of the grill heating chamber 9, and the like. It is something that can be done. That is,
(1) Functions of left and right IH heating sources 6L and 6R (whether cooking operation is in progress, etc.)
(2) Function of central electric heating source 7 (whether cooking is in progress, etc.)
(3) In the case of cooking in the grill heating chamber 9, operating procedures and functions for performing the cooking (for example, whether roaster, grill, or oven cooking is currently being performed)
Corresponding to the above three scenes, the heating conditions such as the operation status and the thermal power are clearly displayed by characters, illustrations, graphs and the like. A specific structure and display operation will be omitted.

  The liquid crystal screen used in the integrated display means 100 is a known dot matrix type liquid crystal screen. In addition, a high-definition screen (QVGA with a resolution of 320 × 240 pixels or 640 × 480 dots, equivalent to VGA capable of displaying 16 colors) can be realized, and a large number of characters can be displayed even when characters are displayed. Can do. The liquid crystal screen is not limited to a single layer, but may be one that displays in two or more layers in order to increase display information. The size of the display area of the liquid crystal screen is a rectangle having a length (front-rear direction) of about 4 cm and a width of about 10 cm.

Further, the screen area for displaying information may be divided into a plurality for each heating source. For example, the screen may be assigned to a total of 10 areas and defined as follows.
(1) Corresponding area of the left IH heating source 6L (one each for thermal power and time).
(2) Corresponding area of the central electric heating source 7 (one each for thermal power and time).
(3) Corresponding area of the right IH heating source 6R (one each for thermal power and time).
(4) For cooking the grill heating chamber 9 (one each for heating power and time).
(5) A guide area (one piece) for displaying reference information for various cooking as needed or by user operation.
(6) A display area (1) for notifying the user when abnormal driving is detected or improper operation is used.

  Each of the above 10 areas (display areas) is realized on the liquid crystal screen of the integrated display means 100, but is not physically formed or partitioned on the screen itself. Absent. In other words, since it is established by screen display software (microcomputer program), the area, shape, and position can be changed each time by that software. The heating source 6L, the central electric heating source 7, the right IH heating source 6R and the like are always arranged in the same order in accordance with the left and right order of the respective heating sources. That is, on the screen, information on the left IH heating source 6L on the left side, the central electric heating source 7 on the middle, and the right IH heating source 6R on the right side are displayed.

  When there are two corresponding areas for the left and right IH heating sources 6L and 6R, the first display area for displaying the normal state of the “first condition” setting such as the thermal power (heating amount), the cooking time, and the set temperature Etc. (there are more types than the first condition) and the second display area that displays the setting state of the “second condition” and the “physical quantities such as temperature, current, voltage, etc.” It may be divided into two areas.

(Grill heating chamber 9)
The front opening 9A of the grill heating chamber 9 is covered by a door 13 so as to be opened and closed, and the door 13 is held in the heating chamber 9 by a support mechanism (not shown) so as to be movable in the front-rear direction. Further, a heat-resistant glass window plate 106 is installed in the central opening of the door 13 so that the inside of the grill heating chamber 9 can be seen from the outside.

  A handle 13 </ b> B protrudes forward to open and close the door 13. The grill heating chamber 9 is formed with a predetermined space SX (see FIG. 3) between the inner rear wall surface of the main body as described above, and an exhaust duct 14 to be described later is installed using this space. An exhaust chamber 12 is formed.

  A front end portion of a metal tray 108 is connected to the door 13, and when cooking with a lot of oil, a metal grill 109 is usually placed on the tray 108 for use. Thus, when the door is pulled forward, the tray 108 (or the grill when the grill 109 is placed) is also pulled out to the front of the grill heating chamber 9 along with the drawer operation. Note that the tray 108 is detachably supported by the left and right ends on a pair of left and right metal rails DL connected to the normal door 13, so that the tray 108 can be detached from the rail DL alone. It is like that.

Further, the shape of the grill 109 and the position and shape of the tray 108 are devised so that they cannot be pulled out by hitting the lower heater 23 when the tray 108 is pulled forward. In this manner, in the grill heating chamber 9, if meat, fish, or other food is placed on the grill 109 and the heaters 22 and 23 are energized (simultaneously or in time division or the like), the food is heated from both the upper and lower surfaces. It has a “double-sided baking function”.
The grill heating chamber 9 is provided with a temperature sensor (not shown) for detecting the room temperature, and cooking can be performed while maintaining the internal temperature at a desired temperature.

  As shown in FIG. 6, the grill heating chamber 9 includes a cylindrical metal inner frame 9 </ b> C having an opening 9 </ b> B on the rear (back) side and an opening 9 </ b> A on the front side, and the entire outside of the inner frame. The outer frame 9D covers a predetermined (upper) gap 114, a lower gap 113, and left and right side gaps (115, not shown). A gap 307 is formed between the outer frame 9D of the grill heating chamber 9 and the bottom wall surface of the main body case 2.

  The outer frame 9D has five surfaces, that is, left and right side wall surfaces, an upper surface, a lower surface, and a back surface, and is entirely formed of a steel plate or the like. The inner surfaces of the inner frame 9C and the outer frame 9D form a coating with good cleanability such as enamel, or a heat-resistant coating film or an infrared radiation film. When an infrared radiation film is formed, the amount of infrared radiation with respect to an object to be heated such as food is increased, heating efficiency is improved, and uneven burning is also improved.

9E is an exhaust port formed in the upper part of the back wall surface of the outer frame 9D.
14 is a metal exhaust duct installed continuously outside the exhaust port 9E (see FIGS. 1, 3, and 6), and this exhaust duct 14 has a square or rectangular cross section. As shown in FIG. 6, as it goes downstream, it inclines obliquely upward, then bends in the vertical direction, and finally the upper end opening 14 </ b> A communicates with the vicinity of the central vent 20 </ b> C formed in the cover plate 11.
Reference numeral 120 denotes a deodorizing catalyst installed in the exhaust duct 14 at a position downstream of the exhaust port 9E (see FIG. 6). The catalyst 120 is activated by being heated by the catalyst heater 120H and passes through the exhaust duct 14. It functions to remove odor components from the hot air inside the heating chamber 9.

(Exhaust structure / intake structure)
As described above, the lid plate 11 placed in a fixed state at the rear portion of the upper frame 20 has a long sideways right vent (to be an inlet) 20B, a central vent (to be an exhaust port) 20C, and a left vent. 20D is formed (see FIG. 2). On these three rear vents, a metal plate-like cover 130 (see FIG. 1) in which countless small communication holes are formed so as to cover the entire upper part is detachably mounted. The cover 130 may be a metal mesh or a fine lattice shape in addition to a metal plate formed with small holes for communication holes by press working (also referred to as punching metal). In any case, it is only necessary that the user's finger or a foreign object does not enter the ventilation openings 20B, 20C, 20D from above.

  A suction port 37B at the uppermost position of the suction cylinder 37A of the fan case 37 faces directly below the right end of the cover 130, that is, the right ventilation port 20B, and passes through the communication hole of the cover 130 and the right ventilation port 20B. External room air can be introduced into the cooling chamber 8 in the main body A.

  In the rear exhaust chamber 12, as shown in FIG. 3, the upper end portion of the exhaust duct 14 is located. In other words, on both the left and right sides of the exhaust duct 14, the exhaust chamber 12 communicating with the gap 116 formed on both sides of the grill heating chamber 9 and the upper gap 26 is secured. In other words, the ceiling surface of the grill heating chamber 9 is installed with a predetermined gap 26 between the ceiling surface of the grill heating chamber 9 and the horizontal partition plate 25, and this gap finally communicates with the exhaust chamber 12. As described above, the interior of the upper part chamber 10 communicates with the exhaust chamber 12 through the pair of exhaust ports 28A formed in the rear partition plate 28, so that the cooling air flowing in the upper part chamber 10 (the arrow in FIG. 5). Y5) is discharged to the outside of the main part A. At this time, the air inside the gap 26 is also discharged by being attracted by this.

  The circuit board (circuit board on which an inverter circuit or the like is formed) 41 includes a rectifier bridge circuit 221 connected to a 100V or 200V commercial power source, a coil 222 connected to a DC output terminal of the rectifier bridge circuit, and a smoothing circuit. Capacitor 224, resonant capacitor 224 connected to the coil and capacitor, power control element 225 such as IGBT serving as a semiconductor switching means connected to these components, and other main electric / electronic circuit components necessary for induction heating drive It is installed. The power control element 225 generates heat because a large amount of electric power flows in accordance with the induction heating drive operation. Therefore, the power control element 225 is attached to the heat radiating fins 43A and 43B by heat transfer in order to cool the air, thereby cooling air from the blower 30. I'm trying to cool it down. In the case of this embodiment, since there are two IH heating sources 6R and 6L on the left and right, there are two inverter circuits and two or more power control elements 225. Therefore, each of the two radiating fins 43A and 43B It is attached.

(Auxiliary cooling structure)
3, 5, and 7, reference numeral 46 denotes an interior of various electric / electronic components 56 of the upper surface operation unit 61, and a light emitting element (LED) 57 that displays the heating power during induction heating cooking with light. A transparent plastic lower duct 46A whose upper surface is opened and a transparent plastic upper duct 46B which serves as a lid for sealing the upper surface opening of the lower duct. It is configured.

Ventilation holes 46R and 46L are opened at the right end and the left end of the lower duct 46A, respectively, and a notch 46C that allows ventilation is formed at the center rear.
46H is a leg portion formed integrally with the lower surface of the lower duct 46A, and has a function of supporting the lower duct 46A on the upper surface of the horizontal partition plate 25.
The legs may be formed long and continuously on the lower surface of the lower duct 46A so as to serve as a cooling air guide plate. In this embodiment, however, the leg portion is provided between the lower duct 46A and the horizontal partition plate 25. In addition, since the cooling air is not actively flown, the leg portions 46H (see FIG. 9) are only scattered in several places.

  On the ceiling surface of the upper duct 46B, the integrated display means 100 is installed in the center, and the liquid crystal display units 45R and 45L are installed on the left and right, respectively. The cooling air of the blower 30 enters the ventilation space 42H of the cooling duct 42 from the second exhaust port 34B of the component case 34, and from there through the ventilation port 42K formed corresponding to the ventilation space 42H, the right liquid crystal display screen (Liquid crystal display part) It enters into the front part case 46 from the lower side of 45R, and is discharged | emitted from the notch 46C to the upper part chamber 10. FIG. Thus, both the right liquid crystal display unit 45R and the integrated display unit 100 are always cooled by the cooling air from the blower 30. In particular, the cooling air from the second exhaust port 34B of the component case 34 is not the air that has cooled the left and right IH heating coils 6LC and 6RC that become high during the induction heating operation, so the temperature is low, and the liquid crystal display unit 45R and the integrated air are integrated. Both the display means 100 can effectively suppress the temperature rise while the amount of cooling air is small.

  On the other hand, the liquid crystal display unit 45L on the left side cannot sufficiently receive the air introduced from the ventilation port 46R. Therefore, a small axial fan 15 is installed inside the front part case 46 as shown in FIG. The cooling air pushed in from 46R is sucked to sequentially cool the space below the integrated display means 100 and the space below the left liquid crystal display portion 45L, and exhaust the air from the air vent 46L. Of course, part of the cooling air from the axial fan 15 is also discharged from the notch 46C.

  In the present embodiment, the rear positions of the left and right IH heating coils 6LC and 6RC that are located downstream in the flow of cooling air (indicated by arrow Y5 in FIG. 5) are difficult to cool down. The low-temperature wind from one exhaust port 34A is directly supplied, and this portion is cooled by this wind.

  In FIG. 4, reference numeral 102 denotes a cover installed at the lower part of the cooling chamber 8, in which an independent intake space is formed. Reference numeral 103 denotes a driving motor for the axial fan 104 installed in the intake space, which sucks outside air from an intake hole 105 formed in the bottom surface of the main body A and is formed on the upper and lower partition plates 24 as indicated by arrows YSS. The air gap 116 formed between the grill heating chamber 9 and the upper and lower partition plates 24 is guided through the communication port 24A. Since this gap communicates with the rear exhaust chamber 12 at the rear part of the main body part A, it is exhausted from the rear of the rear partition plate 28.

(Auxiliary exhaust structure)
As shown in FIG. 6, a cylindrical bottom portion 14 </ b> B having a shape recessed downward by one step is formed downstream of the deodorizing catalyst 120 in the exhaust duct 14.
14C is a vent formed in the bottom. During cooking in the grill heating chamber 9, since the heating chamber 9 becomes hot, the internal atmospheric pressure naturally rises, and accordingly, the high-temperature atmosphere is discharged and the exhaust duct 14 rises. As shown, the air inside the main part A is attracted and exhausted.

Reference numeral 172 denotes a guide plate installed at a position directly below 14C. The guide plate 172 is fixed to the inner wall surface of the main body case 2.
173 is a corrosion-resistant metal container having an open top surface having a volume of about 800 to 1000 CC. The corrosion-resistant metal container 173 receives water when water or the like intrudes from the upper end opening 118 of the upper end exhaust duct 1 by mistake. Accordingly, even if water or the like flows erroneously above the top plate 21 and water or the like enters from the upper end opening 118, entry to the roaster heating chamber 9 side can be suppressed.

  Reference numeral 174 denotes a support base on which the corrosion-resistant metal container 173 is placed. The support base 174 is formed of a metal plate and is fixed to the rear (back) wall surface of the roaster heating chamber 9. Water or the like accumulated in the corrosion-resistant metal container 173 receives heat transferred from the wall surface of the roaster heating chamber 9 and is naturally dried.

Note that a structure such as the bottom 170 of the exhaust duct 14 is provided so that all of the water or the like that has entered the exhaust chamber 12 from a portion other than the upper end opening 118 of the exhaust duct 14 is concentrated in the corrosion-resistant metal container 173. Or a structure such as a guide plate 172 may be provided.
1 is a space defined in the main body case 2 by the upper and lower partition plates 24 and the rear partition plate 28, and the cooling unit CU is positioned so that the suction cylinder 37A of the fan case 37 is positioned therein. Is installed inside the cooling chamber 8.

(Control means F)
(Control circuit)
FIG. 8 is a component diagram showing the entire control circuit of this cooking apparatus, and the control circuit is formed by an energization control circuit 200 configured by incorporating one or a plurality of microcomputers. The energization control circuit 200 includes four parts, that is, an input unit 201, an output unit 202, a storage unit 203, and an arithmetic control unit 204, and is supplied with DC power via a constant voltage circuit (not shown). Thus, it serves as a central control means for controlling all the heating sources and the display means G.
In FIG. 8, an inverter circuit 210R for the right IH heating source 6R is connected to a commercial power supply having a voltage of 100V or 200V through a rectifier circuit (also referred to as a rectifier bridge circuit) 221.

  Similarly, an inverter circuit 210L of the left IH heating source is connected to the commercial power source via the rectification bridge circuit 221 in parallel with the inverter circuit 210R of the right IH heating source. Reference numeral 211 denotes a heater drive circuit for the central electric heating source 7, and 212 denotes a heater drive circuit for driving the internal heating heater 22 of the grill heating chamber 9. Reference numeral 213 denotes a heater driving circuit for driving the internal heating heater 23 of the grill heating chamber 9, 214 denotes a heater driving circuit for driving the catalyst heater 121 provided in the middle of the exhaust duct 14, and 215 denotes a liquid crystal of the integrated display means 100. A driving circuit 107 for driving the screen is a driving circuit for the motor 103 of the axial fan 104.

  The inverter circuit 210R of the right IH heating source 6R includes a right IH heating coil (induction heating coil) 6RC shown in FIG. 8, a rectifier bridge circuit 221 whose input side is connected to a bus of a commercial power source, and a DC side output terminal. A DC circuit composed of a connected coil 222 and a smoothing capacitor 223, a resonance circuit composed of a parallel circuit of a heating coil 6RC and a resonance capacitor 224, one end of which is connected to a connection point between the coil 222 and the capacitor 223, and the resonance circuit IGBT225 which becomes a switching means with the collector side connected to the other end of.

  The emitter of the IGBT 225 is connected to a common connection point between the smoothing capacitor 223 and the rectifying bridge circuit 221. The flywheel diode 226 is connected between the emitter and collector of the IGBT 225 so that the anode is on the emitter side. N indicates a metal pan to be heated.

Reference numeral 227 denotes a current detection sensor 227 that detects a current flowing in a resonance circuit including a parallel circuit of the heating coil 6RC and the resonance capacitor 224R. The detection output of the current detection sensor 227 is supplied to the input part of the energization control circuit 200, and when a pot that is inappropriate for induction heating is used, or because of some accident or the like, it exceeds a predetermined current value by a predetermined value or more. When a difference undercurrent or overcurrent is detected, the energization control circuit 200 controls the IGBT 225 via the drive circuit 228, and the energization of the induction heating coil 220 is instantaneously stopped.
Similarly, the inverter circuit 210L of the left IH heating source 6L has a circuit configuration equivalent to that of the right heating source circuit 206R, and thus description thereof will be omitted. However, 6LC is a heating coil, and 224L is a resonance capacitor.

  Although not shown, the current detection sensor 227 is similarly provided in the inverter circuit 210L of the left IH heating source 6L. The current detection sensor 227 includes a shunt that measures current using a resistor and a method that uses a current transformer.

In the cooking apparatus that heats the object N to be heated by the induction heating method as in the present invention, a power control circuit for flowing high-frequency power to the heating coils 6RC and 6LC is called a so-called resonance inverter. A switching circuit element (IGBT 225 in FIG. 9) is about 20 to 40 KHz to a circuit in which the inductance of the IH heating coils 6RC and 6LC including the object to be heated N (metal object) and the resonance capacitor (224 in FIG. 9) are connected. The on / off control is performed at the drive frequency. The resonance type inverter includes a current resonance type that is said to be suitable for a 200 V power supply and a voltage resonance type that is said to be suitable for a 100 V power supply.
Such a resonant inverter circuit has a configuration called a so-called half-bridge circuit and a full-bridge circuit depending on how the connection destination of the IH heating coils 6RC, 6LC and the resonant capacitor 224 is switched by a relay circuit. Divided. The inverter circuits 210R and 210L of the present invention may be configured as a half bridge circuit or a full bridge circuit.

As described above, when the object to be heated N (metal object) is induction-heated by energizing the IH heating coils 6RC and 6LC, in the case of the object to be heated N of a magnetic material such as iron, a resonance capacitor (224 in FIG. 8) is used. A switching circuit element (IGBT 225 in FIG. 8) is controlled to be turned on and off at a driving frequency of about 20 to 40 KHz, and a current of about 20 to 40 KHz is supplied to the connected circuit.
On the other hand, when the object to be heated N is made of a material having a high electric conductivity such as aluminum or copper, a large current is passed through the IH heating coils 6RC and 6LC in order to obtain a desired heating output. It is necessary to induce a large current on the bottom surface of N. For this reason, in the case of an object to be heated N made of a material having a high electrical conductivity, on / off control is performed at a driving frequency of 60 to 70 KHz.

  Reference numeral 33 denotes a power source / drive circuit for the motor 31 of the blower 30 for keeping the internal space of the main body A in a certain temperature range.

(Temperature detection circuit)
In FIG. 8, reference numeral 240 denotes a temperature detection circuit, to which temperature detection information from the following temperature detection elements is input.
(1) The temperature detection element 31R provided at the center of the right IH heating coil 6RC
(2) The temperature detection element 31L provided at the center of the left IH heating coil 6LC
(3) Temperature detection element 241 provided in the vicinity of the electric heater of the central electric heating source 7
(4) Temperature detecting element 242 for detecting the internal temperature of the grill heating chamber 9
(5) Temperature detection element 243 (not shown) installed in the vicinity of the integrated display means 100
(6) Temperature detecting elements 244 and 245 which are attached in close contact with the two radiating fins 43A and 43B inside the component case 34 and detect the temperatures of the two radiating fins individually.

  Two or more temperature detection elements may be provided for the temperature detection object. For example, the temperature sensor 31R of the right IH heating source 6R may be provided in the central portion and the outer peripheral portion of the IH heating coil 6RC to achieve more accurate temperature control. Further, the temperature detection element may be configured by using a different principle. For example, the temperature detecting element at the center of the IH heating coil 6RC may be an infrared type, and the one provided at the outer peripheral part may be a thermistor type.

  The drive circuit 33 of the motor 31 of the blower 30 always operates the blower 30 and cools it with wind according to the temperature measurement state from the temperature detection circuit 240 so that each temperature measurement portion does not become higher than a predetermined temperature.

(Top operation structure)
As shown in FIG. 9, the upper surface operation unit 61 is positioned above the flange 2T of the front flange plate 2B made of a metal plate that is fixed to the front end portion of the upper surface opening 2a of the main body case 2. Further, as shown in FIG. 9, the upper surface operation unit 61 is a substrate on which a resin-made substrate case 250, a number of pressing operation switches 251 attached to the upper surface of the substrate case, electronic component elements 252 and the like are mounted. 253 and a push button case 254 having a push button 254A provided so as to cover above the switch 251 and an outer peripheral edge attached to the front frame 123 so as to cover the push button case. And a membrane sheet 255.

  The push button case 254 is attached to the frame of the substrate case 250 so as to cover the substrate 253. Reference numeral 254B denotes an elastic push button support piece, whereby the push button case 254 supports the push button 254A. That is, when the push button 254A is pushed down by the user, the push button 254A is moved downward by a predetermined dimension of about 1 mm to several mm, the push operation type switch 251 is closed, and the push button 254A is pushed from that state. When the button is stopped, the push button support piece returns to its original upper position due to its elasticity, and the push-type switch 251 is opened.

A pair of left and right support pieces 256R and 256L projecting rearward are integrally formed on the vertical wall portion of the front flange plate 2B.
The substrate case 250 is formed long in the horizontal width direction of the top plate 21, and a flat plate-like hanging portion 259 is integrally formed along the rear edge of the substrate case. The hanging portion is inserted between the support pieces 256R and 256L and supported so as to be movable up and down.

  Reference numeral 257 denotes a rectangular bar-shaped elastic body interposed between the lower surface of the substrate case 250 and the upper surface of the flange 2T of the front flange plate 2B, and is formed of, for example, a silicon rubber material. This elastic body may be provided in such a length as to cover the entire width of the lower surface of the substrate case 250, or may be provided only at the left and right ends of the lower surface of the substrate case 250, or may be scattered at predetermined intervals. The above may be provided.

  As shown in FIG. 9, the elastic body 257 is abnormal when the push button 254 </ b> A exceeds a predetermined allowable dimension with respect to a pressing force from below when the front side of the cooking device hits the front frame 142 </ b> A of the kitchen furniture. It has a repulsive force that cannot be pushed up so much. That is, when the front side of the cooking apparatus hits the frame 142A of the kitchen furniture and the flange 2T of the front flange plate 2B bends upward, the bending is absorbed by the elastic body 257 and further supported so as to be movable up and down. Is absorbed by. Reference numeral 142B denotes a frame on the back side of the kitchen furniture that supports the rear portion of the main body A.

(Operation of cooking device)
Next, the outline | summary of operation | movement of the heat cooking apparatus which consists of said structure is demonstrated.
When the power is turned on, a basic operation program from the turning on to the start of cooking preparation is stored in the storage unit 203 inside the energization control circuit 200.
First, the power plug is connected to a 200V commercial power source, and the operation button 63A (see FIG. 1) of the main power switch 63 is pressed to turn on the power.

  Then, a predetermined low power supply voltage is supplied to the energization control circuit 200 via a constant voltage circuit (not shown), and the energization control circuit 200 is activated. A self-diagnosis is performed by the control program of the energization control circuit 200 itself, and if there is no abnormality, a motor drive circuit 33 for driving the drive motor 31 of the blower 30 is preliminarily driven. Further, the left IH heating source 6L, the right IH heating source 6R, and the driving circuit 215 of the liquid crystal display unit of the integrated display means 100 are also preliminarily activated.

The temperature detection circuit 240 reads temperature data from each of the temperature sensors 31R, 31L, 241, 242, 244, 245 and sends the data to the energization control circuit 200.
As described above, the energization control circuit 200 collects data such as circuit currents, voltages, temperatures, and the like of main components, and therefore abnormal heating determination is performed as abnormality monitoring control before cooking. For example, when the temperature around the liquid crystal substrate of the integrated display means 100 is higher than the heat-resistant temperature of the liquid crystal display substrate (for example, 70 ° C.), it is determined that the temperature is abnormally high.

  The current detection sensor 227 detects a current flowing through the resonance circuit 225 including a parallel circuit of the right IH heating coil 6RC and the resonance capacitor 224, and this detection output is supplied to the input unit 201 of the energization control circuit 200, and the storage unit 203 When an undercurrent or an overcurrent is detected as compared with the regular current value of the determination reference data stored in the current control circuit 200, the energization control circuit 200 determines that there is some kind of accident or poor conduction, and determines that there is an abnormality. .

  When there is no abnormality determination by the above self-diagnosis steps, “cooking start preparation is completed”. However, if an abnormality determination is made, a predetermined abnormality process is performed and cooking cannot be started.

(Cooking mode)
Next, a case where the right IH heating source 6R is used will be described as an example of the case where the cooking mode is shifted to after the pre-cooking abnormality monitoring process is completed.
First, the right operation dial 64R of the front operation unit 60 is turned right or left (the heating power is set according to the amount of rotation).

An operation signal from the front operation unit 60 is input to the energization control circuit 200, and operation signals of various input keys from the upper surface operation unit 61 are input to the energization control circuit 200, and cooking conditions such as a heating power level and a heating time are set. Is done.
Next, the energization control circuit 200 drives the drive circuit 228 to drive the right IH heating source circuit 206R. Since the integrated display means 100 is driven by the drive circuit 215, cooking conditions such as heating power and cooking time are displayed in the display area.
Since the drive circuit 228 applies a drive voltage to the gate of the IGBT 225, a high frequency current flows through the right IH heating coil 6RC. As a result, the pan of the object to be heated N becomes hot due to the high frequency magnetic flux from the right IH heating coil 6RC, and the electromagnetic induction heating cooking operation (cooking mode) is started.

  The direct current obtained by the rectifier bridge circuit 221 and the smoothing capacitor 223 is input to the collector of the IGBT 225 that is a switching element. When the drive signal from the drive circuit 228 is input to the base of the IGBT 225, the on / off control of the IGBT 225 is performed. A combination of the on / off control of the IGBT 225 and the resonant capacitor 224 generates a high-frequency current in the right heating coil 6RC, and a pan placed on the top plate above the heating coil 6RC by electromagnetic induction caused by this high-frequency current An eddy current is generated in the object N to be heated. Thus, the eddy current generated in the object to be heated N becomes Joule heat, the object to be heated generates heat, and can be used for cooking.

  The drive circuit 228 has an oscillation circuit, and a drive signal generated by the oscillation circuit is supplied to the base of the IGBT 225 to control the IGBT 225 on / off. By adjusting the oscillation frequency and oscillation timing of the oscillation circuit of the drive circuit 228, the conduction ratio, conduction timing, current frequency, etc. of the right IH heating coil 6RC are adjusted, and the heating power of the right IH heating coil 6RC can be adjusted. .

In addition, when the energization stop command of the right IH heating source 6R is issued, the energization of the right IH heating source 6R is stopped, but the blower 30 continues to operate for 2 minutes to 5 minutes even after the energization stop. Thereby, the hot air stays in the vicinity of the heating coil 6RC of the right IH heating source 6R immediately after the air blow from the blower 30 is stopped, and the overshoot problem that the temperature rapidly increases can be prevented. Further, it is possible to prevent the adverse effect that the temperature of the integrated display unit 100 becomes high.
This operation continuation time is determined from a formula or numerical table that is determined in advance by the energization control circuit 200 in accordance with conditions such as the temperature rise until the energization is stopped, the room temperature, and the operating heat power level of the heating source.

  However, when it is determined that the cooling fan itself is out of order, such as when an abnormal current is detected from the blower 30 (for example, when only the temperature of the cooling fins 43A and 43B is increased), the blower 30 At the same time, the energization of is stopped.

The liquid crystal display substrate of the integrated display means 100 is heated by reflected heat from the bottom of the object to be heated N heated during cooking by the IH heating sources 6R and 6L or radiant heat from the top plate 21.
Further, when the used hot tempura pan is placed on the central portion of the top plate 21 as it is, it receives heat from the hot pan (near 200 ° C.).
Therefore, in the first embodiment, the air is cooled from both the left and right sides by the blower 30 and the axial fan 15 in order to suppress the temperature rise of the integrated display means 100.

  When the blower 30 is driven under such a normal operating environment, air outside the main body A is sucked into the fan case 37 from the suction port 37B of the suction cylinder 37A of the fan case 37. The sucked air is discharged forward in the horizontal direction from the exhaust port (exit) 37C by the blade portion 30F rotating at high speed inside the fan case 37.

  There is a component case 34 connected in close contact with the fan case 37 at the front position of the exhaust port 37C, and the air introduction port communicates with the exhaust port 37C in close contact with the exhaust case 37C. Inside, air is sent from the blower 30 so as to increase its internal pressure (static pressure). A part of the sent cooling air is discharged from the first exhaust port 34 </ b> A on the side near the exhaust port 37 </ b> C on the upper surface of the component case 34.

The temperature of the released air is almost the same as the temperature immediately after exiting from the exhaust port 37C because it does not cool a high-temperature heating element or a heat-generating electrical component on the way, and remains fresh air. .
Then, the cooling air sent from the first exhaust port 34A to the ventilation space 42F of the cooling duct is ejected upward from the first ejection hole 42CA as shown by an arrow Y3 in FIG. It collides with the lower surface of the heating coil 6RC and effectively cools the coil. In addition, when the shape of the right IH heating coil 6RC has a gap through which the air-cooling air partially penetrates as described above or a central space CK having a through hole shape, the first exhaust port 34A is also provided there. The cooling air from the air enters and flows upward so as to pass through it and cools it.

  In addition, fresh (low temperature equivalent to room temperature) cooling air is simultaneously ejected rearward from the rear upper surface of the upper case 42A constituting the peripheral wall surface of the ventilation space 42F and the first ejection hole 2CA formed on the rear surface side. Since it flows toward the side of the power supply board A58 and the central electric heating source 7, the ambient temperature of the power supply board A58 can be lowered. Since the gap 119 exists, the temperature rise of the power supply substrate A58 is suppressed from both the upper surface and the lower surface. Further, the flow toward the side of the central electric heating source 7 facilitates the backward flow of the cooling air blown from the first blow-out hole 42CA, and the central electric heating source 7 is energized. When it is done, it becomes very hot, so that hot air does not stay around it.

  On the other hand, the cooling air sent into the component case 34 with pressure from the blower 30 is not directed to the surface of the circuit board 41 and does not flow near the surface. Since the cooling air passes between a large number of heat exchange fin elements centering on the heat radiation fins 43A and 43B that are structured to protrude from the surface (one side surface) of the circuit board 41, the heat radiation fins 43A and 43B are mainly used. To be cooled.

  Further, in the cooling air pushed from the exhaust port 37C, the main flow, which is the fastest part, flows straight from the exhaust port 37C as indicated by an arrow Y4 in FIG. Is ejected from the second exhaust port 34B located at the most downstream position in the flow. Since the second exhaust port 34B has an opening area several times larger than the first exhaust port 34A, most of the cooling air pushed into the component case 34 from the exhaust port 37C is the second exhaust gas. It is ejected from the mouth 34B.

  The blown cooling air is guided into the space 42G and 42H of the cooling duct, and most of the cooling air is blown out from a large number of blow holes 42C formed on the upper surface of the upper case 42A, and the right IH heating just above it. It collides with the lower surface of the coil 6RC and effectively cools the coil.

  A part of the cooling air guided into the space 42H of the cooling duct is a front part in which various electric / electronic parts 56 and a light emitting element (LED) 57 for displaying the heating power at the time of induction heating cooking are stored. Guided into the case 46. Specifically, the cooling air of the blower 30 enters the ventilation space 42H of the cooling duct 42 from the second exhaust port 34B of the component case 34, and from here the cooling duct 42 formed corresponding to the ventilation space 42H. The air passes through the vent 42K and enters the vent 46R of the lower duct 46A that is positioned so as to be in close contact with the vent 42K.

  As a result, the right side liquid crystal display screen (liquid crystal display unit) 45R is first cooled from below by the cooling air that has entered the front part case 46, and then the axial fan that is in the middle of flowing through the front part case 46 15, the flow is accelerated and finally the built-in components and the like are cooled in the process of being discharged from the notch 46C to the upper component chamber 10. As a result, the right side liquid crystal display unit 45R, the integrated display means 100, the various electric / electronic components 56, the light emitting element 57 that displays the heating power during induction heating cooking with light, and the like are sequentially cooled with cooling air.

In particular, the cooling air guided into the front part case 46 is not a wind that has cooled the left and right IH heating coils 6LC and 6RC that are heated at the time of the induction heating operation. Therefore, the temperature is low, and the liquid crystal display unit 45R and the integrated display are provided. The means 100 and the like continue to be cooled so that the temperature rise is effectively suppressed while the amount of cooling air is small.
The wind delayed by the axial fan 15 also flows below the left liquid crystal display unit 45L, and cools the liquid crystal display unit 45L and its surrounding electrical components in the process of being discharged from the ventilation port 46L.

The cooling air jetted from the second jet holes 42CB and the first jet holes 42CA formed in a large number in the cooling duct 42 moves the upper part chamber 10 rearward as shown in FIGS. It flows like an arrow. The cooling air guided to the gaps 26 and 116 also merges with the cooling air flow in the exhaust chamber 12 and is discharged to the outside of the main body A.
When the left IH heating source 6L is energized, the remaining cooling air that has cooled the right IH heating source 6R is sent to the left as shown by the arrow in FIG. 6LC is cooled similarly. In addition, the cooling air blown out to cool the left IH heating coil 6LC cools the power supply substrate 59 in the process of flowing in the direction of the exhaust chamber 12. In particular, the cooling air jetted from the two first jet holes 42CA provided on the back side of the cooling duct 42 flows between the periphery of the power supply substrate 59 and the central electric heating source 7 as indicated by an arrow Y5 in FIG. Therefore, the power supply board 59 is effectively cooled.

Embodiment 2. FIG.
10 to 16 show a cooking apparatus according to Embodiment 2 of the present invention. FIG. 10 is a longitudinal sectional view of the cooling unit, FIG. 11 is a transverse sectional view thereof, and FIG. FIG. 13 is a sectional view taken along the line XII-XII, FIG. 13 is a side view of the cooling unit component case and the fan case, FIG. 14 is a longitudinal sectional view showing the cooling unit installation state, and FIG. FIG. 16 is an overall longitudinal sectional view of the main part. In the drawings, the same or corresponding parts as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described.

In the second embodiment, a grill heating chamber 9 is provided inside the main body A, and a cooling chamber 8 extending in the front-rear direction and isolated from the grill heating chamber is provided in the right side space of the grill heating chamber in the main body. In this cooling chamber, a component case 34 containing a circuit board constituting an inverter circuit and a fan case 37 which is coupled to the component case and forms a blower chamber of the blower 30 therebetween are formed. The cooling unit CU provided is arranged.
Then, the rotor blade portion of the blower 30 is built in the air blowing chamber between the fan case 37 and the component case 34, and the cooling air generated in the rotor blade portion is introduced into the component case. The cooling air is branched at the component case 34 and is blown out toward the IH heating coils 6RC and 6LC of the induction heating type heat sources at two places on the left and right.

14 and 16, a box-shaped grill heating chamber 9 is provided in the center of the main body case 2, and a gap 116 of about several millimeters from the outer wall surface of the grill heating chamber 9 is provided on the right side of the grill heating chamber. The upper and lower partition plates 24 made of metal or a heat insulating material are installed so as to face each other.
The space between the right side surface of the upper and lower partition plates 24 and the inner wall surface (right wall surface) of the main body case 2 is the cooling chamber 8. That is, the cooling chamber 8 is isolated from the grill heating chamber 9 by the upper and lower partition plates 24. This is to prevent heat from the grill heating chamber 9 from reaching the cooling chamber 8 as much as possible.

A cooling unit CU as shown in FIG. 12 is inserted into the cooling chamber 8 from above. In the installed state, a large gap (space) 117 is secured between the side surface of the cooling unit CU and the outer wall surface of the grill heating chamber 9, and the side surface on the opposite side of the cooling unit CU and the inner side of the main body case 2. An air gap 118 having a facing distance of several millimeters or narrower than that between the wall surfaces is secured.
The cooling unit CU has a length L3 (see FIG. 11) close to the depth dimension of the cooling chamber 8R, and is installed in a close-contact state so as to cover the effective space in the front-rear direction of the cooling chamber 8. . Note that the gaps 116 and 117 are one of the structures designed to reduce the thermal influence on the cooling chamber 8 on the assumption that the heat of the grill heating chamber 9 that becomes high temperature is radiated from the wall surface. is there.

The cooling unit CU is integrally coupled with a component case 34 that houses a circuit board constituting an inverter circuit, and a fan case 37 that is coupled to the component case and forms a blower chamber of the blower 30 therebetween. Thus, it can be transported as a single structure or installed in the main body A.
The right IH heating coil 6RC and the left IH heating coil 6LC are spaced apart from each other as much as possible so that even a pan with a large diameter can be heated, and the position of the right IH heating coil 6RC is located above the cooling chamber 8. The positional relationship is such that a part of the outer peripheral edge protrudes.

  As shown in FIGS. 10 to 12, the cooling unit CU includes a fan case 37 made of a transparent plastic in which ribs 38 are integrally formed in a circular shape at a constant height on one side surface of the rear side, and the other side surface side of the fan case. Between the plastic box-shaped part case opened on one side and joined to one side of the fan case 37, and the space surrounded by the ribs 38 in the joined state. The chamber 39 is composed of three large parts, ie, a fan case 40 in which a compartment 39 is formed.

  The fan case 40 has a suction port 37B having a sufficient opening area formed at the upper end, and a suction tube 37A extending vertically downward therefrom, and rotating the flow of wind sucked continuously at the end of the suction tube. A guide tube portion 40A for conversion into the wing portion 30F, and four arm portions 40B project from the surrounding wall surface toward the center portion at the center portion of the guide tube portion. A motor 31 is fixed to the front end portion.

  Reference numeral 38A denotes a throat portion formed by the rib 38 of the fan case 37, and the fan case 40 also includes a wall which is in close contact with the rib 38 including the throat portion and is continuously formed on the opposing surface. The actual opening dimension (effective inner dimension) at the upper end of the suction port 37B is 17 mm in the front-rear direction (depth dimension M2 in FIG. 11) and 80 mm in width (M1 in FIG. 11). Is 13.6 square centimeters.

The component case 34 has recesses 34 </ b> C that respectively accommodate one circuit board 41 on which components constituting the inverter circuits 210 </ b> R and 210 </ b> L are mounted. As shown in FIG. 11, the recessed portion 34C partially extends to the back side of the air blowing chamber 39, and the size when viewed from the side has dimensions of vertical H1 and horizontal width W1 as shown in FIG. ing. The circuit board 41 has a size substantially comparable to the recess 34C, and a large number of components constituting inverter circuits 210R and 210L for supplying high-frequency power using this large area are mounted.
In this embodiment, the circuit board 41 corresponds to both the left and right IH heating coils 6LC and 6RC. However, the circuit board 41 may be arranged one by one with a space between the left and right IH heating coils. A layer (overlapping) structure may be used.

The peripheral edge of the fan case 37 is superimposed on the outside of the peripheral edge of the opening of the component case 34, and the screw SC1 is tightened to the tongue 37F and the side portion 37G formed on the fan case 37 so as to be integrated with the component case 34. It has become.
The fan case 40 is also formed with a tongue 40F and a mounting portion 40G, which are fastened to the fan case 37 with screws SC2 to couple the two fan cases 37 and 40 together.

  Between the integrated component case 34 and the fan case 37, a horizontally long rectangular-shaped sealed space communicating with the blower chamber 39 through the exhaust port 37C is formed. However, only the three locations of the first exhaust port 34A and the second exhaust port 34B exceptionally function as communication portions with the outside, and cooling air is forced from these exhaust ports 34A and 34B (pressure higher than atmospheric pressure). Discharged).

  Note that the size of the first exhaust port 34A in this embodiment is a projection area viewed from the side, and in FIG. 10, the height HA is 11 mm, the width WA is 20 mm, and the second exhaust port 34B. In FIG. 10, the height HA is 11 mm and the width WA is 110 mm in FIG. That is, in terms of the projected area viewed from the side, the total of the two exhaust ports 34A, 34B is 14.3 square centimeters, which is slightly larger than the opening area of the suction port 37 of 13.6 square centimeters.

  Further, when the pressure of the air discharged from the first exhaust port 34A and the second exhaust port 34B is not increased compared to the atmospheric pressure, the first exhaust port 34A as in this embodiment. In addition, although the opening area of the suction port 37 may be made equal to the total opening area of the second exhaust port 34B, in order to secure a sufficient pressure air, the first exhaust port 34A If the opening area of the suction port 37B is sufficiently larger than the total opening area of the second exhaust port 34B, the internal pressure (static pressure) of the cooling unit CU can be further increased.

Reference numeral 40 </ b> C denotes an inclined guide portion formed in the fan case 40 corresponding to the exhaust port 37 </ b> C of the fan case 37, and guides the wind generated in the air blowing chamber 39 to the inside of the component case 34.
Since the suction port 37B needs to secure an opening area in order to secure a constant air volume, the thickness (width dimension) of the portion of the air blowing chamber 39 becomes large as shown in FIG. Further, since it is necessary to secure the diameter and thickness of the wing portion 30F and to secure the installation space for the motor 31, both the width and the depth dimension must be increased when viewed in the fan case 37 and the fan case 40 as a whole. However, since the thickness of the component case 34 can be made smaller than the thickness of the air blowing chamber 39 and the like, the inclined guide portion 40C guides the air flow smoothly through the inlet portion where the wind enters the component case 34 from the exhaust port 37C. Yes. That is, as shown in FIG. 12, the width of the passage must be H5 at the beginning of the exhaust port 37C, but there is an inclined guide portion 40C so that the dimension H5 decreases as it goes downstream.

  In the fan case 37, as shown in FIG. 10, the blowing direction of the cooling air is inclined upward by a certain angle Θ1 (for example, 10 degrees) with respect to the horizontal line. Further, since the radiation fins 43A and 43B are installed at positions separated from the inner bottom surface of the component case 34 by the predetermined dimensions H2 and H3, the central portion of the flow of cooling air from the blower 30 is the lower end of the radiation fins 43A and 43B. Become a part. If the radiating fins 43A and 43B are installed in front of the cooling air in the blowing direction, the cooling effect of the radiating fins 43A and 43B is enhanced, but with pressure loss when passing through the fine fin elements of the radiating fins 43A and 43B, The air pressure of the cooling air is lowered, and there is a possibility that the air cannot be sent with a sufficient air volume and pressure to the second exhaust port 34B.

Also, the leeward side corner of the fan case 37 has a large curved surface 37K so that the central portion of the flow of cooling air from the blower 30 is easily directed toward the second exhaust port 34B.
223 is a smoothing capacitor as shown in the circuit diagram of FIG. 8, 224 is a resonance capacitor, and such a tall electric component has a height dimension S3 from the circuit board 41 as shown in FIG. In the component case 34 made as thin as possible, there is a possibility that the gap S2 with the inner wall surface may be reduced. Therefore, as shown in FIG. 10, all these components are inclined by an angle Θ2 in the direction of guiding the wind. Thus, the air flows smoothly to the second exhaust port 34B. Incidentally, in this embodiment, S3 is 45 mm and S2 is 25 mm.

  Although no circuit component is mounted on the back surface of the circuit board 41, the circuit board 41 is installed so that a gap 119 of several mm or less is secured between the inner surface of the component case 34. In FIG. 10, 260 is an electrical component such as a capacitor.

  In FIG. 10, reference numeral 262 denotes a dent formed on the upper wall surface of the component case 34, and a metal terminal 263 is fixed to the inner bottom surface 265. The inverter terminals 210R and 210L are connected to the fixed terminal. The generated high frequency power is supplied from a metal terminal 150 provided in front of the circuit board 41 through a jumper wire 151 (floating so as not to contact the surface of the circuit board 41). After installing the cooling unit CU in the cooling chamber 8 and connecting a predetermined cord 264 to the terminal 263, the high-frequency power connection to the left and right IH heating coils 6RC, 6LC can be simplified. Note that the code A that draws high-frequency power from the inverter circuits 210R and 210L is not exposed to the outside of the component case 34 as long as it reaches the terminal. Further, if a connector is provided at the other end of the cord 264, the connection with the left and right IH heating coils 6RC and 6LC can be made easier.

  In FIG. 10, reference numeral 152 denotes a power cord for the drive circuit 33 of the blower 30, and through a through hole 154 formed between a recess formed in the wall surface of the component case 34 and a recess formed in the edge of the fan case 37. The circuit board 41 is pulled in and connected to a drive circuit 33 formed on the circuit board 41. A connector 155 is attached to the other end of the power cord 152. After the cooling unit CU is installed in the cooling chamber 8, a test current of a predetermined voltage (for example, 24V) of the drive circuit 33 is supplied to the connector 155. The operating state of the blower 30 can be checked.

Similarly, in FIG. 10, reference numeral 156 denotes a power cord for supplying power to the circuit board 41, and a through hole formed between a recess formed in the wall surface of the component case 34 and a recess formed in the edge of the fan case 37. 158 is drawn to the circuit board 41 side and connected to a predetermined terminal on the circuit board 41.
A connector 157 is attached to the other end of the power cord 156, and a test current having a predetermined voltage can be supplied to the connector 157 after the cooling unit CU is installed in the cooling chamber 8.

The difference from Embodiment 1 is that a large plate 25A (see FIG. 16) is formed at the rear of the horizontal partition plate 25, that is, a plate-like member that partitions the upper side of the grill heating chamber 9 up and down.
The two power supply boards 58 and 59 (only 58 is shown in FIG. 15 and only 59 is shown in FIG. 16) have their lower surfaces separated from the upper surface of the horizontal partition plate 25 by a certain distance HC (see FIG. 15). Of course, the cooling unit CU is also set apart from the upper surface by a certain distance.

  The horizontal partition plate 25 is installed at a position that secures a predetermined gap 26 between the grill heating chamber 9 and the ceiling surface of the grill heating chamber 9, and cooling air passes through the lower case 42B as shown in FIG. It flows from the hole 306 to the gap 26.

  Reference numeral 305 denotes a through hole formed in the lower case corresponding to the space 42H of the cooling duct 42. The through hole 305 corresponds to the position of the through hole 306 and has the same diameter. 309 is a plurality of legs that support and fix the power supply board A58 to the horizontal partition plate 25, 310 is a large electric part fixed on the power supply board 58, 311 is also a small electronic part, and such legs 309, Those similar to the electrical component 310 and the small electronic component 311 are similarly provided with a power supply board B59 on the left side. Reference numeral 312 denotes a ring-shaped sealing material installed in a compressed state from above and below in order to increase the airtightness between the through holes 305 and 306.

42J are ventilation holes formed on the rear wall surface of the cooling duct 42, and one to several holes are formed on the side facing the two power supply boards 58 and 59, respectively. Thereby, a part of fresh air from the cooling unit CU is branched and can be used as cooling air for the two power supply boards 58 and 59.
42L (see FIG. 15) is a step portion in which the outer case 42 of the cooling duct 42 has an outer shape formed in a semicircular portion (arc portion) 42M, and is formed in a semicircular shape with a predetermined width WL. This step portion creates a wide space between the left and right IH heating coils 6LC and 6RC, so that the cooling air from the first ejection holes 42CA and the second ejection holes 42CB hitting the IH heating coils 6RC and 6LC. Has the effect of smoothing the flow of

  All the first ejection holes 42CA and the second ejection holes 42CB formed on the upper surface (not including the side surfaces) of the cooling duct 42 are arranged along the direction in which the cooling air flows, that is, below An inclined surface that reduces the diameter as it goes upward from the top is formed on the entire circumference, and a guide wall (wind direction guide) 48 that protrudes backward in a bowl shape is formed integrally with a part of the hole edge. Has been. The diameter 42N of the first ejection hole 42CA based on the tip of the wind direction guide is about 8 mm. That is, since the aperture is originally 12 mm, the wind direction guide 48 protrudes by 4 mm.

  The wind direction guide 48 is integrally formed so as to face the direction of the power bases 59 and 58, that is, directly behind the center points X3 and X2 of the left and right IH heating coils 6LC and 6RC.

(Operation)
A case where the blower 30 is driven in such a configuration will be described. In this case, it is assumed that the right IH heating coil 6RC is in induction heating.
First, air outside the main body A is sucked into the fan case 37 from the suction port 37 </ b> B of the suction cylinder 37 </ b> A of the fan case 37 of the cooling chamber 8. The sucked air is sent out vigorously from the exhaust port (exit) 37C toward the predetermined angle from the horizontal direction by the blade portion 30F rotating at high speed inside the fan case 37. There is a component case 34 connected in close contact with the fan case 37 at the front position as viewed from the exhaust port 37C, and the air introduction port communicates with the exhaust port 37C, so that it is sent from the exhaust port 37C by the blower 30. Due to the air, the internal pressure (static pressure) of the component case 34 increases.

  Further, since the radiation fins 43A and 43B are installed at positions separated from the inner bottom surface of the component case 34 by the predetermined dimensions H2 and H3, the central portion of the flow of cooling air from the blower 30 is the lower end of the radiation fins 43A and 43B. Become a part. In other words, the cooling air is not directly blown to the surface of the circuit board 41 and to a large number of small electronic components and printed wiring patterns mounted on the circuit board 41.

  In the second embodiment, as described above, the central portion of the cooling air discharge flow is not close to or near the surface of the circuit board 41, and the central portion of the cooling air discharge flow is the radiating fin 43A, 43B is located at the end of the non-mounting portion side of 43B (see FIG. 10), so that oil smoke and dust contained in the air from the indoor space such as the kitchen after long-term use together with the cooling air and the surface of the circuit board 41 and mounting The possibility of adhering to and depositing on the periphery of small electronic parts and terminals and the terminal portion can be kept low, and over many years of use, deposits such as oily smoke and dust accumulate on the circuit board 41, which absorbs moisture. Thus, it is possible to prevent the electrical insulation of the circuit board from being lowered.

  A part of the sent cooling air is discharged from the first exhaust port 34A on the side close to the exhaust port 37C on the upper surface of the component case 34 as indicated by an arrow Y3 in FIG. The temperature of the released air is almost the same as the temperature immediately after exiting from the exhaust port 37C because it does not cool a high-temperature heating element or a heat-generating electrical component on the way, and remains fresh air. . At this stage, the air flow is not positive but positive.

  Then, the cooling air sent from the first exhaust port 34A to the cooling duct 42 is ejected upward from the first ejection hole 42CA as shown by the arrows in FIGS. 10 and 14, and the right IH heating coil located directly above. Collides with the bottom surface of the 6RC to effectively cool the coil.

  On the other hand, the cooling air sent with pressure from the blower 30 to the inside of the component case 34 has a structure projecting on the surface (one side surface) of the circuit board 41 in the process of flowing through the circuit board 41. Since it passes between many heat exchange fin elements of the radiation fins 43A and 43B, the radiation fins 43A and 43B are cooled.

  Further, in the cooling air pushed in from the exhaust port 37C, the main flow, which is the fastest part, flows straight from the exhaust port 37C as indicated by an arrow Y4A in FIG. Is ejected from the second exhaust port 34B located at the most downstream position in the flow. Since the second exhaust port 34B has an opening area several times larger than the first exhaust port 34A, most of the cooling air pushed into the component case 34 from the exhaust port 37C is the second exhaust gas. It is ejected from the mouth 34B.

The blown cooling air is guided into the space 42G and 42H of the cooling duct, and most of the cooling air is blown out from the second blow holes 42CB formed in the upper surface of the upper case 42A and right above the right. Colliding with the lower surface of the IH heating coil 6RC, the coil is effectively cooled.
A part of the cooling air guided into the space 42H of the cooling duct is stored before various electric / electronic components 56, a light emitting element (LED) 57 for displaying the heating power at the time of induction heating cooking, and the like. Guided into the part case 46.

  Since the cooling air discharged from the cooling unit CU maintains a positive pressure state until reaching the cooling duct 42, the heat of the grill heating chamber 9 is hardly drawn by itself, and a predetermined low temperature wind is supplied to the right iH. The lower surface of the heating coil 6RC can be supplied through the second ejection hole 42CB.

  The cooling air ejected from the first ejection holes 42CA of the cooling duct 42 and the numerous second ejection holes 42CB flows rearward in the upper component chamber 10 as shown in FIG. The cooling air discharged into the upper part chamber 10 joins the flow of the cooling air, and finally flows from the rear exhaust chamber 12 by flowing into the rear exhaust chamber 12 communicating (opening) to the outside of the main body A. Discharged.

  Further, the cooling air sent into the cooling duct is ejected upward as shown by the arrow in FIG. 15 from the first ejection hole 42CA, and collides with the lower surface of the right IH heating coil 6RC located directly above the coil. At this time, since the direction of the guide wall (wind direction guide) 48 is unified so as to face directly behind, the direction of the cooling air to be blown out is unified and flows smoothly backward.

  Further, since the cooling air is blown out from the first blow-out hole 42CA formed in the back wall surface of the upper case 42A constituting the peripheral wall surface of the ventilation space 42F of the cooling duct 42, the air flowing toward the power supply board 58 Can flow.

  On the other hand, the cooling air blown from the second exhaust port 34B at the most downstream position of the cooling air flow in the cooling unit CU is guided into the spaces 42G and 42H of the cooling duct 42, and most of the cooling air is cooled. The wind is ejected from a large number of second ejection holes 42CB formed on the upper surface of the upper case 42A, and collides with the lower surface of the left iH heating coil 6LC just above it to cool the coil effectively. At this time as well, the direction of the wind direction guide 48 at the rim of the second ejection hole 42CB is unified so as to face directly behind, so the direction of the cooling air to be ejected is unified and flows smoothly backward.

  On the other hand, a part of the cooling air guided into the space 42H of the cooling duct passes through the through hole 306 of the horizontal partition plate 25 from the through hole 305, and between the horizontal partition plate 25 and the grill heating chamber 9 ceiling surface. It flows into the formed gap 26. As shown in FIG. 6, the air thus flowed flows backward in the gap 26, the cooling air flowing upward from the front of the horizontal partition plate 25, that is, the interior of the upper part chamber 10, and the horizontal partition. After passing through the vent 25A of the plate 25, they merge.

  That is, as shown in FIGS. 10 and 14, the cooling air sent from the second exhaust port 34B of the component case 34 of the cooling unit CU is sent to the cooling duct 42, and then, through the second ejection hole 42CB. To the right IH heating coil 6RC side. Then, after cooling the right IH heating coil 6RC portion, it will eventually flow to the exhaust chamber 12 behind the rear partition plate 28 via the vent hole 25A. The cooling air blown out from the first blowout hole 42CA of 42 also merges, and finally suppresses an increase in the ambient temperature of the power supply boards 58 and 59, and finally passes through the air vent 25A as shown in FIG. It flows into the exhaust chamber 12 and is discharged outside the apparatus.

  In each of the above embodiments, the case where the right IH heating coil 6RC is inductively heated has been described. However, the cooking apparatus is being used (for example, when the left and right IH heating coils 6LC and 6LC are driven simultaneously, or the center When the electric heating source 7 and the grill heating chamber are used at the same time, the operating speed (air blowing capacity) of the blower 30 may be appropriately changed depending on the environment such as the temperature of the upper part chamber 10.

Embodiment 3 FIG.
FIG. 17 shows a cooking device according to Embodiment 3 of the present invention, and is a simplified plan view of a cooling unit and a cooling duct. In FIG. 17, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and different points will be mainly described.

  In the third embodiment, the air passage in the cooling duct 42 is divided into the air passage 42F into which relatively low temperature air supplied from the first exhaust port 34A of the component case 34 is introduced, and the first exhaust. The right IH heating coil 6RC is the same as that of the first embodiment described above, except that it is divided into the air passage 42G into which the air supplied from the second exhaust port 34B on the downstream side of the port 34A is introduced. The air volume adjusting valve 80 is provided in the middle of the air passage 42G through which the main flow of the air to cool the left IH heating coil 6LC flows.

  The air volume control valve 80 is rotated by a driving means (not shown) such as a motor or a solenoid between a position indicated by a solid line (closed position) and a position indicated by a broken line (open position) with the central portion as a fulcrum. It may be either fixed at two points of a closed position and an open position, or one that can be stopped in several steps or multiple steps at an appropriate position between the two points. 81 is a partition wall formed integrally with the wall surface over the entire width of the cooling duct 42 in the same manner as the partition wall 42D in the first embodiment, and the two air passages 42F and 42G are formed with this as a boundary. Is done. Reference numeral 82 denotes a throttle portion protruding into the air passage 42G so as to come into contact with one end portion of the air flow control valve 80 at its closed position, and the flow passage cross-sectional area of the air passage 42G is narrow in this portion. Note that the air volume control valve 80 does not completely block the air passage 42G in the closed position, and a minimum flow path is secured to a certain limit.

(Operation)
A case where the blower 30 is driven in such a configuration will be described. In this case, it is assumed that the induction heating is first performed using the right IH heating coil 6RC.
First, air outside the main body A is sucked into the fan case 37 from the suction port 37B. The sucked air is continuously formed integrally with the fan case 37, or is formed in a sealed container-like component case 34 used by connecting a separately formed member in a close contact state. It is fed by the blower 30 with pressure.

  The cooling air pushed in from the fan case 37 is ejected from the first exhaust port 34A at the upstream position to the air passage 42F and from the second exhaust port 34B to the air passage 42G. At this time, since the air volume control valve 80 is in the closed position and can reduce the air volume to the left IH heating coil 6LC through the air path YY, the air volume adjusting valve 80 is accordingly reduced from the second ejection hole 42CB of the right IH heating coil 6RC portion. The amount of air blown out increases. For this reason, it is possible to reduce the operating speed of the blower 30 of the cooling unit CU so that excessive blowout is not performed from the second blow-out hole 42CB, thereby reducing the power consumption of the blower 30 (naturally the operation sound). Is also preferable).

  In this state, when high-frequency power is newly supplied to the left IH heating coil 6LC and cooking is performed by both the left and right IH heating sources 6L and 6R, the air volume control valve 80 is in response to a command from the energization control device 200. Since the drive circuit (not shown) connected thereto is controlled so as to be in the open position, the cooling air is sufficiently supplied also to the left side of the air passage 42G, and the left and right IH heating coils 6LC and 6RC are blown out from below. Each is cooled by wind.

  In the third embodiment, the right IH heating source 6R can be used by selecting the most numerous heating powers in a wide range of about 3 KW to 100 W so that the right IH heating source 6R is most frequently used by general users. It has become. For example, in the range of low thermal power, fine thermal power settings such as 100 W, 150 W, 250 W, 500 W,. Therefore, cooling air is always preferentially supplied to the right IH heating source 6R. However, the top plate 21 may remain at a high temperature for a while after cooking during cooking, and it is desirable to cool it quickly. Therefore, even when only the right IH heating coil 6RC is operated, no cooling air is supplied to the left IH heating coil 6LC, and the air passage 42G is not completely cut off even when the air volume control valve 80 is in the closed position. A part of the cooling air is also sent to the left IH heating source 6L side.

 As similar to the third embodiment, two second exhaust ports 34B are provided, and the air passage in the cooling duct 42 is dedicated to the right IH heating coil 6RC and the left IH heating coil 6LC. The two second exhaust ports 34B may be communicated with the two air passages. In this case, the first exhaust port 34A may be eliminated. Then, cooling air is supplied to the left and right IH heating coils 6LC and 6RC from only one exhaust port 34B. Further, according to the high frequency driving of the left and right IH heating coils 6LC, 6RC, the exhaust outlet 34B which is not driven or the valve cross section of the air passage is adjusted, or a valve body which is completely shut off / opened is provided, The cooling air from the cooling unit CU may be intensively supplied to the IH heating coil on the side used for cooking.

  In carrying out the present invention, the upper and lower partition plates 24R and 24L and the horizontal partition plate 25 are not necessarily required. For example, when the outer wall surface of the grill heating chamber 9 is covered with a heat insulating material, when a sufficient gap can be secured between the outer wall surface of the grill heating chamber 9, or when the temperature of the gap can be kept low (for example, air For natural convection or forced convection). Further, a heat shield panel may be attached to the side facing the outer wall surface of the grill heating chamber 9 among the outer wall surfaces of the cooling unit CU itself, or a heat insulating film may be formed. In this way, the facing distance from the outer wall surface of the grill heating chamber 9 can be minimized, and if the horizontal width of the main body A is formed to be the same size as in the built-in type cooking apparatus, the grill heating chamber 9 is correspondingly increased. There is an advantage that the width dimension can be increased and cooking can be performed with a larger object to be cooked.

  The induction heating cooking apparatus of the present invention can effectively cool the IH heating coil portion simultaneously with cooling the inverter circuit components and the like, so that the cooker dedicated to stationary type or built-in type induction heating type heating source can be used. And it can be widely used in a combined heating cooker with other radiant heating sources.

The perspective view in the state which removed the top plate part of the whole heat cooking apparatus. The top view which shows the whole main-body part. The top view in the state which removed the top plate part of FIG. FIG. 4 is a vertical sectional view taken along line IV-IV in FIG. 3. The longitudinal cross-sectional view of the right side cooling chamber part of FIG. The VI-VI line longitudinal cross-sectional view of FIG. The disassembled perspective view of a cooling unit, a cooling duct, and a component case. FIG. The longitudinal cross-sectional view which shows the front upper part of a main-body part. The longitudinal cross-sectional view of the cooling unit of the heat cooking apparatus which concerns on Embodiment 2 of this invention. FIG. 11 is a cross-sectional view of FIG. 10. Sectional drawing in the XII-XII line | wire of FIG. The side view in the combined state of the component case and fan case of a cooling unit. The longitudinal cross-sectional view which shows the installation state of a cooling unit. Sectional drawing of the principal part which shows a cooling duct part in a cross section. FIG. The simplified top view of the cooling unit and cooling duct of the heat cooking apparatus which concerns on Embodiment 3 of this invention.

Explanation of symbols

A body part, B top plate part, C casing part, D heating means, E operation means, control means for controlling the heating means in response to signals from the operation means, G display means for displaying the operating conditions of the heating means CK central space, CU cooling unit, DL door rail, FR protection member, FL protection member, K1 installation port, KTS installation space, KTK installation space, N heated object, M1 depth dimension, M2 width dimension, SC1 screw, SC2 Screw, SP space, SX space, SY space, PK seal material, WA Opening width dimension of the first exhaust port, W2 Opening width dimension of the second exhaust port, WL width.
2 Body case, 2A body, 2B flange plate, 2S inclined surface, 2T flange of front flange plate 2B, 2U body rear wall, 2V body side wall, 3B flange, 3L flange, 3R flange, 6L left IH heating Source, 6LC left IH heating coil, 6LM guide mark, 6R right IH heating source, 6RC right IH heating coil, 6RM guide mark, 7 radiant central electric heating source (heater), 7M guide mark, 8R right cooling chamber, 8L left side Cooling chamber, 9 grill heating chamber, 9A front opening, 9B rear opening, 9C inner frame, 9D outer frame, 9E exhaust port, 10 upper parts chamber, 11 lid plate, 12 rear exhaust chamber, 13 door, 13B handle, 14 exhaust Duct, 14A Upper end opening, 14B Cylindrical bottom, 14C Vent hole, 15 Axial fan, 20 Upper frame, 20A Opening, 20B Right vent, 20C Central vent 20D Left vent, 20E Through hole, 21 Top plate, 22 Radiation type electric heating source (heater), 23 Radiation type electric heating source (heater), 24 Vertical partition plate, 25 Horizontal partition plate, 25A Ventilation port, 25B cut Notch, 26 gap, 28 rear partition plate, 28A exhaust hole, 30 blower, 30F wing, 31R infrared sensor, 31L infrared sensor, 32 rotating shaft, 33 power supply / drive circuit, 34 component case, 34A first exhaust port , 34B Second exhaust port, 34C recess, 37 fan case, 37A suction cylinder, 37B suction port, 37C exhaust port, 37D case, 37E case, 37F tongue, 37G side, 37K curved surface, 38 rib, 39 Blower chamber, 40 fan case, 40A guide tube, 40B arm, 40C tilt guide, 40F tongue, 41 circuit board, 2 cooling duct, 42A upper case, 42B lower case, 42L stepped part, 42M semicircular part (arc part), 42CA first ejection hole, 42CB second ejection hole, 42D partition wall, 42F ventilation space (air path) , 42G Ventilation space (air passage), 42H Ventilation space (air passage), 42J hole, 42L stepped portion, 42M semicircular portion (arc portion), 42N diameter, 43A heat radiation fin, 43B heat radiation fin, 45R liquid crystal display portion (liquid crystal Display screen), 45L liquid crystal display (liquid crystal display screen), 46 parts case, 46A lower duct, 46B upper duct, 46C notch, 46H leg, 46R vent, 46L vent, 47 inclined surface, 48 guide wall ( Wind direction guide), 50 cover, 56 electrical / electronic components, 57 light emitting element (LED), 58 power supply board, 59 power supply board, 60 front operation section, 61 top operation section, 62 Front operation frame, 63 Main power switch, 64R Right operation dial, 64L Left operation dial, 66R Right indicator, 66L Left indicator, 70 Right heating power setting operation unit, 71 Left heating power setting operation unit, 72 Central operation unit , 80 Air volume control valve, 81 Partition wall, 82 Restriction part, 97 Start switch key, 98 Deep-fried food selection switch.
100 integrated display means, 101R right thermal power display lamp, 101L left thermal power display lamp, 102 cover, 103 drive motor, 104 axial fan, 105 air intake hole, 106 window plate, 107 motor drive circuit, 108 saucer, 109 grill, 110 space, 113 gap, 114 gap, 115 gap, 116 gap, 118 gap, 119 gap, 120 deodorizing catalyst, 120H heater, 121 rear frame body, 123 front frame body, 123A through hole, 130 cover, 142A frame, 142B Frame, 150 terminals, 151 jumper wire, 152 power cord, 153 connector, 154 through hole, 155 connector, 156 power cord, 157 connector, 158 through hole, 172 guide plate, 173 container, 174 support base, 175 opening.
200 energization control circuit, 201 input unit, 202 output unit, 203 storage unit, 204 arithmetic control unit, 205 rectification circuit (rectification bridge circuit), 210R inverter circuit for right IH heating source, 210L inverter circuit for left IH heating source, 211 Heater drive circuit for central electric heating source 7, 212 Heater drive circuit for driving the internal heating heater 22 of the roaster heating chamber 9, 213 Heater drive circuit for driving the internal heating heater 23 of the roaster heating chamber 9, 214 Catalyst Heater drive circuit for driving heater 121, 215 Liquid crystal screen drive circuit of integrated display means 100, 221 Rectifier bridge circuit, 222 coil, 223 smoothing capacitor, 224 resonance capacitor, 225 switching means (IGBT), 226 flywheel diode, 227 Current detection sensor, 228 drive Road, 240 Temperature detection circuit, 241 Temperature detection element (temperature sensor), 242 Temperature detection element (temperature sensor), 243 Temperature detection element (temperature sensor), 244 Temperature detection element (temperature sensor), 245 Temperature detection element (temperature sensor) ), 250 substrate case, 251 switch, 252 electronic component element, 253 substrate, 254 push button case, 254A push button, 254B push button support piece, 255 membrane sheet, 256L support piece, 256R support piece, 257 elastic body, 259 drooping , 260 parts, 262 terminal recess, 263 terminal, 264 cord, 265 connector, 266 bottom.
301 upper partition wall, 302 lower partition wall, 304 partition wall, 305 through-hole, 306 through-hole, 307 gap, 308 notch, 309 leg, 310 electrical component, 311 small electronic component, 312 sealing material, 340 cover plate.

Claims (16)

The body,
A top plate covering the upper surface of the main body;
An induction heating type heat source including at least two heating coils disposed below the top plate and energized independently of each other;
A circuit board on which an inverter circuit for supplying high-frequency power to the induction heating source is mounted;
A blower for supplying cooling air to the internal space of the main body;
Display means for displaying an energization state of the induction heating type heat source;
A grill heating chamber built under the induction heating source of the main body;
An exhaust chamber partitioned into the main body and having a terminal portion communicating with the external space;
In an induction heating cooker equipped with
Inside the main body, a cooling chamber is formed that extends in the front-rear direction in the right or left space of the grill heating chamber and is isolated from the inner space of the grill heating chamber,
The cooling chamber is provided with a cooling unit that houses the blower therein and that is configured to cool the circuit board housed therein with cooling air from the blower.
The cooling unit is one in which a fan case incorporating the blower and a component case in which cooling air discharged from an exhaust port of the fan case is introduced and the circuit board is accommodated are integrated.
The component case is provided with a first exhaust port and a second exhaust port separated in the front-rear direction,
Between the first and second exhaust ports of the component case constituting the cooling unit and the lower space of each heating coil, a cooling duct is disposed to communicate both of them.
The cooling duct is supplied from the blower and supplied from the blower, and the first blowout holes for blowing the cooling air from the first exhaust port to the respective heating coils . It provided the cooling air exiting from the outlet and a second ejection holes for spewing the respective heating coils, respectively,
In the cooling duct, cooling air from the second exhaust port provided near the display means of the component case, of the first and second exhaust ports, is placed in front of the second ejection hole. in is branched, providing a vent hole leading to said display means,
The air after being blown out from the first and second blowout holes of the cooling duct to cool the heating coil and the air after being blown out from the ventilation port and after cooling the display means are in the exhaust chamber. An induction heating cooking apparatus, wherein the induction heating cooking apparatus is discharged to the outside of the main body.   2. The induction heating cooking apparatus according to claim 1, wherein the blower is a centrifugal multi-blade blower having a horizontal rotation axis. The component case has a first exhaust port and a second exhaust port on the downstream side of the exhaust port, and the cooling air that does not cool the power switching element of the inverter circuit is supplied to the first exhaust port. The induction heating cooking apparatus according to claim 1 , wherein the induction heating cooking apparatus is further evacuated.   The cooling duct is provided with a first ejection hole and a second ejection hole located at a downstream side in the flow of the ejected cooling air, and the exhaust port provided in the cooling unit has a first An exhaust port and a second exhaust port are provided, cooling air is supplied from the first exhaust port to the first ejection hole, and cooling air is supplied from the second exhaust port to the second ejection hole. The induction heating cooking apparatus according to claim 1, wherein: The induction heating cooking apparatus according to claim 4 , wherein the cooling duct is partitioned into a plurality of passages, and the first ejection hole and the second ejection hole are formed for each section.   The induction heating cooking apparatus according to claim 1, wherein the air after cooling the heating coil cools a power circuit board installed in a space above the grill heating chamber in the main body.   The induction heating cooking apparatus according to claim 1, wherein an outside air suction port of the cooling unit extends to the vicinity of a rear upper surface of the main body 1.   The induction heating cooking apparatus according to claim 1, wherein the grill heating chamber and the cooling chamber are separated by a partition plate made of metal or a heat insulating material.   The induction heating cooking apparatus according to claim 1, wherein the grill heating chamber and the cooling duct are separated by an upper and lower partition plate made of metal or a heat insulating material. The circuit board housed in the component case includes a semiconductor switching element to which a high-voltage current for the inverter circuit is supplied, and a radiation fin to which the switching element is attached, The cooling air from the blower is configured to flow, and the cooling air sent from the blower is discharged from the first exhaust port of the component case before reaching the radiation fin. The induction heating cooking apparatus according to claim 3 , wherein the induction heating cooking apparatus is provided. The component case is formed in a box shape, the induction heating cooking apparatus according to claim 1, wherein the outlet port of the fan case to the lower side surface of the component case is characterized in that it is connected. The circuit board is installed vertically within the component case, and the heat dissipating fins are installed so as to protrude horizontally from the circuit board, and a space below the heat dissipating fins is provided for cooling air supplied from the blower. induction cooking apparatus of claim 10 Symbol mounting, characterized in that as the center of the flow.   The cooling duct is installed in a face-to-face state below the bottom surface of the heating coil, and a stepped portion is formed on the outer peripheral edge of the cooling duct to increase the facing distance from the heating coil. The induction heating cooking apparatus of claim | item 1. The cooling unit is a unit in which a fan case incorporating a blower and a component case in which cooling air discharged from an exhaust port of the fan case is introduced and the circuit board is accommodated are integrated. structure induction cooking apparatus of claim 1 Symbol mounting, characterized in that it is inserted placed from above into the interior state of the cooling chamber of the main body of the.   The cooling unit includes power connection means for supplying power to the circuit board, connection means for one end connected to the circuit board to supply high frequency power to the heating coil, and power connection to the drive circuit for the blower The induction heating cooking apparatus according to claim 1, wherein the means are exposed to the outside. Wherein the cooling duct, induction cooking apparatus of claim 1 Symbol mounting is characterized by providing the air volume adjusting means for automatically changing the rate of the cooling air flowing from the cooling unit into two heating coils.

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