JP4927790B2 - Cooker - Google Patents

Description

  The present invention relates to, for example, an induction heating cooker that induction-heats an object to be heated, and more particularly to a heating cooker that cools a top plate that is heated during use of the cooker.

  In a conventional induction heating cooker, during cooking, the heat of the object to be heated and the heat of the induction heating coil are transmitted to the top plate, and the top plate becomes high temperature. For this reason, in order to prevent the user from touching the top plate accidentally, the high temperature indicator is turned on when the top plate reaches a high temperature to alert the user (for example, see Patent Document 1).

Japanese Patent Laying-Open No. 2003-217813 (page 3-4, FIG. 2)

  However, some users may inadvertently touch the heating port even when the high temperature warning is displayed.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a safer cooking device that can prevent the top plate from becoming high temperature / cool quickly after use.

The cooking device according to the present invention is stored in the cooking device main body, the induction heating coil that is housed in the cooking device main body, and heats the object to be heated, and is installed on the upper part of the cooking device main body, at a position facing the induction heating coil. A top plate having a placement portion on which the object to be heated is placed; and a heat absorption means for absorbing the heat of the top plate around the placement portion into the liquid refrigerant . The heat absorption means surrounds the outer periphery of the induction heating coil. And a ring-shaped peripheral portion heat absorbing means that contacts the lower surface of the top plate.

According to the present invention, the heat absorbing means has the ring-shaped peripheral heat absorbing means that surrounds the outer periphery of the induction heating coil and contacts the lower surface of the top plate. Can provide a high-heat cooking device.

Embodiment 1 FIG.
FIG. 1 is an external perspective view of an induction heating cooker showing Embodiment 1 of the present invention, FIG. 2 is a block diagram showing a schematic configuration of the induction heating cooker according to Embodiment 1, and FIG. 3 is an induction heating cooker. It is sectional drawing which expands and shows a part of top plate.
In these drawings, a top plate 2 made of heat-resistant tempered glass having heat resistance is installed on the upper portion of the cooker body 1. On the top surface of the top plate 2, heating ports (mounting portions) 3a to 3c formed by printing three ring lines are formed. These heating ports 3a to 3c are opposed to the induction heating coil and indicate positions where heating is possible, in other words, placement positions of the heated object A.

  On the front upper surface of the top plate 2, corresponding to the heating ports 3a to 3c, the thermal power display portions 4a to 4c for displaying the thermal power state, respectively, and the high temperature caution display for prompting attention when the top plate 2 is hot Parts 5a to 5c are provided. Since the top plate 2 is cooled in the present embodiment, these high-temperature caution display portions 5a to 5c are not indispensable configurations, but in the unlikely event that the top plate 2 becomes hot or depending on the heating mode or the cooling mode. As a result of the control, the top plate 2 is provided in case the temperature becomes high. Furthermore, the display part 6 for displaying the operation state of the cooking appliance main body 1 and the setting state of the grill part 8 is provided. For these display units, LEDs (Light Emitting Diodes), liquid crystal display devices, organic EL (Electro Luminescence) elements, and the like are used.

  On the right side of the front surface of the cooker main body 1 is a front operation unit 7 on which a heating power adjustment dial for adjusting the heating power of the induction heating coils 10 to 12 as heating sources, a power switch for turning on / off the power, and the like are arranged. A grill portion 8 is provided on the left side of the front surface of the cooker body 1. This grill part 8 has doors 8a that can slide back and forth, heaters (not shown) are respectively arranged on the upper and lower sides of the chamber, and a temperature sensor 8b that detects the temperature in the chamber due to heating of the heater is installed. ing. The induction heating coils 10 to 12 described above are disposed in the cooker body 1 so as to face the lower surface of the top plate 2 with the central axis of each of the heating ports 3a to 3c as a center, and among them, the induction heating coils 10 and 12 are included. Is larger than the induction heating coil 11. A heater may be installed in place of the induction heating coil 11. In the central space of these induction heating coils 10 to 12, temperature sensors 13 to 15 (for example, a thermistor or an infrared sensor that measures temperature in a non-contact manner) that are in contact with the lower surface of the top plate 2 are installed. In the vicinity, heat absorbing means 16 for absorbing the heat of the top plate 2 are provided.

  When the thermal power is set by the operation unit 7, the control unit (control unit) 20 notifies the refrigerant control unit (refrigerant control unit) 21 of the induction heating coils 10 to 12 in which the thermal power is set, and the thermal power is induced. An inverter (not shown) is controlled to be energized so as to be output from the heating coils 10-12. In addition, when it is determined that the temperature of the heated object A detected by the temperature sensors 13 to 15 exceeds the target temperature, energization to the induction heating coils 10 to 12 is controlled so as to reach the target temperature. In addition, when the start of heating of the grill portion 8 is operated, the heater is energized. When it is determined that the internal temperature exceeds the target temperature, the heater is energized so as to reach the target temperature. To do. In addition, the control unit 20 displays the thermal power set by the operation unit 7 on the thermal power display units 4 a to 4 c and displays the operation state on the display unit 6.

  When the refrigerant control unit 21 receives the notification of the induction heating coils 10 to 12 for which the heating power is set, the refrigerant control unit 21 determines that the cooking is started and opens the corresponding on-off valves 30a to 30c after a predetermined time has elapsed. Moreover, the control part 20 determines whether the detection temperature of the temperature sensors 13-15 exceeded 60 degreeC, for example, and when the temperature exceeding 60 degreeC is detected, the high temperature warning display parts 5a-5c are lighted or blinked. To do. Moreover, the fan motor 22 is driven and the number of rotations is controlled according to the temperature in the cooker body 1 or the output of the induction heating coils 10 to 12. In the refrigerant control unit 21 of the present embodiment, the on-off valves 30a to 30c are opened after a predetermined time has elapsed since the start of cooking. However, the on-off valves 30a to 30c are opened when a predetermined temperature is detected after the start of cooking. It may be opened or may be opened immediately after the start of heating.

  FIG. 3 is a cross-sectional view of the vicinity of the heating port. A plurality of protrusions P formed of heat-resistant paint are applied to substantially the entire upper surface of the top plate 2. The protrusion P reduces the contact area with the heated body A and forms an air layer with a high heat insulating effect, so that the cooling efficiency of the top plate 2 can be increased and the top plate 2 is cooled. It is possible to suppress the rapid deprivation of the heat of the heated object A. Moreover, it is possible to further improve the cooling efficiency by using a paint having a low thermal conductivity (heat insulating member). In addition, you may make it give the protrusion P mentioned above only in a ring line.

Here, the heat absorption means 16 mentioned above is demonstrated using FIG. FIG. 4 is a cross-sectional view and a top view showing the configuration of the heat absorbing means in the first embodiment.
The heat absorbing means 16 has a ring-shaped tank 16a having a substantially quadrangular cross section, and has a sealed and hollow structure so that liquid refrigerant flowing into each tank 16a, for example, water W of waterworks, does not leak. Yes. The upper surface of each tank 16a is fixed in contact with the lower surface of the top plate 2, and the heat of the top plate 2 is absorbed by the water W having a large heat capacity through the tank 16a. A water supply pipe 30 and a drain pipe 31 are connected to each tank 16a. The water supply pipe 30 is equipped with on-off valves 30a to 30c, respectively, and is connected to a water supply pipe. The drain pipe 31 extends to the drain port. The tank 16a is a part of the refrigerant pipe and is a peripheral heat absorbing means (member) provided on the outer periphery of the induction heating coils 10 to 12. Here, although it is a sealed structure in the sense that water does not leak into the cooker body 1, the inside of the tank 16 a and the outside of the cooker body 1 are in communication with each other through a drain port.

Next, the operation of the first embodiment will be described.
For example, when the heating power of the induction heating coil 10 is set by the operation unit 7, the control unit 20 notifies the refrigerant control unit 21 to that effect and controls the inverter so that the setting heating power is output from the induction heating coil 10. To do. On the other hand, the refrigerant control unit 21 determines that the cooking is started when the previous notification is received, opens the on-off valve 30a after a predetermined time, and cools the top plate 2. Moreover, the control part 20 determines whether the temperature of the top plate 2 on the induction heating coil 10 exceeds 60 degreeC, for example. When the temperature sensor 13 installed in the central space of the induction heating coil 10 detects a temperature exceeding 60 ° C., the high temperature caution display 5a is turned on to prompt the user to be aware of the high temperature. At this time, the water W of the water supply flows into the tank 16a and flows out to the drain pipe 31 through the tank 16a. When the water W flows into the tank 16a, the water level in the tank 16a is low, but gradually rises and becomes full. This is because the drain of the tank 16 is provided at the top. The heat conducted radially from the heating port 3a is absorbed by the water W in the tank 16a at the periphery of the heating port. At this time, if the inner wall surface on the top plate side of the tank 16a is provided below by the drain port, the cooling efficiency of the top plate 2 is increased because the inner wall surface comes into contact with water.

  On the other hand, when the control unit 20 determines from the operation input to the operation unit 7 that heating cooking is finished, the control unit 20 stops the output of the induction heating coil 10 and notifies the refrigerant control unit 21 to that effect. Further, the control unit 20 determines whether or not the temperature detected by the temperature sensor 13 is 60 ° C. or less. When the detected temperature is higher than 60 ° C., the cooling by the heat absorbing means 16 is continued, and when the temperature of 60 ° C. or lower is detected, the high temperature caution display unit 5a is turned off and the refrigerant control unit 21 is stopped from cooling. Notice. Based on this notification, the refrigerant control unit 21 closes the corresponding on-off valve 30a of the induction heating coil 10 and stops cooling the peripheral portion of the heating port.

  As described above, according to the first embodiment, water W is supplied into the tank 16a disposed on the outer periphery of the induction heating coils 10 to 12 during cooking, and is thus conducted radially from the heating ports 3a to 3c. Heat is absorbed in the peripheral part of the heating port, and therefore, the temperature rise in the peripheral part of the heating port 3a to 3c is suppressed even during or immediately after use of the cooker, and the user accidentally touches the peripheral part or the like. Even safer cookers can be provided. In addition, when the temperature of the heating ports 3a to 3c exceeds a predetermined temperature, the high temperature caution display portions 5a to 5c are turned on to prompt the user to be aware of the high temperature. There is an effect.

Embodiment 2. FIG.
In the first embodiment, it has been described that the heat absorption means 16 is provided on the outer periphery of the induction heating coils 10 to 12, but in the second embodiment, the heat absorption means is provided between the top plate 2 and the induction heating coils 10 to 12. This will be described below with reference to FIG. FIG. 5 is a cross-sectional view and a top view showing the configuration of the heat absorbing means in the second embodiment. In the second embodiment, the configuration and operation are the same as those of the first embodiment except for the heat absorption means, and therefore, different parts will be mainly described below.

  In FIG. 5, the heat absorbing means 40 of the present embodiment is a planar circular tank 40a disposed between the top plate 2 and the induction heating coils 10 to 12, respectively, and the water of the waterworks flowing into each tank 40a. Let W absorb the heat of the top plate 2. The tank 40a is provided with a hole for inserting temperature sensors 13 to 15 for detecting the temperature of the top plate 2 at the center, and a water supply pipe 30 and a drain pipe 31 are connected to the outer peripheral part. In addition, two guide plates 40b are provided in the inside so that the tip end faces each other with the hole as a center. By this guide plate 40b, the water W that has flowed into the tank 40a becomes full and flows as indicated by arrows, so that the heat of the heating ports 3a to 3c and its peripheral part is efficiently absorbed. In addition, about the operation | movement regarding cooling during use of this cooking appliance, it is the same as that of Embodiment 1. FIG. Moreover, while providing the electromagnetic valve which can adjust an opening degree to the drain pipe 31, a drain outlet can also be provided in the tank 40a lowermost part so that the water in the tank 40a may flow out when this solenoid valve is opened. The heating of the top plate 2 is improved by heating the tank 40a during heating by controlling the solenoid valves and the on-off valves 3a to 30c of the water supply pipe 30 so that the tank 40 becomes full after heating. It is also possible to balance the effect.

  As described above, according to the second embodiment, since the heat absorbing means 40 is disposed between the top plate 2 and the induction heating coils 10 to 12, in addition to the heat absorption around the heating port, the heating ports 3 a to 3 c Heat is also absorbed, so that heat conducted radially from the periphery of the heating port can be further suppressed, and safe cooking even if the heating ports 3a to 3c are touched even during or immediately after use of the cooker. Can be provided. Moreover, since the high temperature caution display part 5a is turned on when the temperature of the top plate 2 exceeds 60 ° C., there is an effect that safety is further improved.

Embodiment 3 FIG.
In the first and second embodiments, the high temperature caution display is performed through the temperature detected by the temperature sensors 13 to 15 provided in the central space of the induction heating coils 10 to 12, but the third embodiment is the induction heating coil. A temperature sensor is provided outside the outermost periphery of 10 to 12, and when the detected temperature of the temperature sensor exceeds 60 ° C., a high temperature caution display is performed. FIG. 6 is a top view showing the configuration of the heat absorbing means in the third embodiment. Since the basic configuration and operation are the same as those in the first and second embodiments, the following description will focus on the different parts.

In FIG. 6, the ring-shaped high temperature caution display unit 43 is disposed between the induction heating coils 10 to 12 and the tank 16 a (peripheral part heat absorption means 16) provided on the outer periphery of each induction heating coil 10 to 12. As shown in FIG. The temperature sensor 42 arranged outside the outermost periphery of the induction heating coils 10 to 12 is in contact with the lower surface of the top plate 2. The temperature sensor 42 is provided for detecting heat (temperature) transmitted from the heating ports 3a to 3c to the peripheral portion. The top plate 2 is conductive heat from the heated object A and / or the induction heating coil 10 to 12, heated by radiant heat, this heat is spread to the peripheral portion radially from the heating opening 3 A～3c, temperature sensor 42 is provided in the vicinity of the outermost periphery of the induction heating coils 10 to 12 and in the vicinity of the boundary with the portion that is normally hidden by the heated object A, so that a temperature rise (propagation) is quickly detected in the process of heat propagation to the peripheral portion. be able to. Furthermore, compared with the case where the temperature sensor is arranged in the central portion of the induction heating coils 10 to 12, the temperature of the top plate 2 spreading in the peripheral portion is more appropriately measured because it is less affected by the heat of the heated object A. be able to.

  Next, the operation will be described. As described in the first embodiment, the control unit 20 adjusts the output of the induction heating coils 10 to 12 with the temperature sensors 13 to 15 provided in the heating ports 3 a to 3 c, while others provided in the vicinity of the outer periphery thereof. On the basis of the temperature sensor 42, the necessity of cooling the top plate 2 is determined, and when the detected temperature exceeds a predetermined value, the refrigerant control unit 21 is notified of the start of cooling. And the refrigerant | coolant control part 21 which received this notification opens the on-off valve 30a-30c, makes water W flow in in the tank 16a, and cools the heat | fever of the top plate 2 of the heating port 3a-3c peripheral part. When the temperature sensor 42 detects a temperature exceeding 60 ° C., the control unit 20 lights the ring-shaped high-temperature caution display unit 43 to alert the user. When the temperature detected by the temperature sensor 42 becomes 60 ° C. or lower after the cooking is finished, the high temperature caution display unit 43 is turned off, and the refrigerant control unit 21 closes the on-off valves 30a to 30c and finishes cooling the top plate 2. On the other hand, the control unit 20 controls the inverter according to the temperature detected by the temperature sensors 13 to 15 arranged at the center of the induction heating coils 10 to 12 and adjusts the output of the induction heating coils 10 to 12.

  In addition, the refrigerant | coolant control part 21 can also be made to adjust a refrigerant | coolant flow volume continuously or in multiple steps of two steps or more based on the detected temperature of the temperature sensor 42 like embodiment mentioned later. is there. That is, when the detected temperature rises so that the temperature of the top plate 2 (particularly the peripheral portion) is as low as possible or less, it can be controlled to increase the refrigerant flow rate. When this refrigerant flow rate control is performed, the temperature sensor 42 is provided between the induction heating coils 10 to 12 and the heat absorption means 16, so that not only the heating state of the top plate 2 but also the heat absorption effect of the heat absorption means 16 is obtained. Since the applied temperature can be measured, it is possible to obtain an appropriate feedback control of the cooling effect and control the refrigerant flow rate appropriately.

  As described above, according to the third embodiment, the temperature sensors 42 are provided outside the outermost circumferences of the induction heating coils 10 to 12, respectively, and when the temperature sensor 42 detects a temperature exceeding a predetermined value, the temperature is high. Since the caution display unit 43 is turned on, it is possible to quickly display a high-temperature caution display before heat is transmitted from the heating ports 3a to 3c to the peripheral portion, and this has the effect of increasing safety. is there.

The start of cooling may be started after a predetermined time from the start of cooking without depending on the temperature of the temperature sensor 42, or may be started immediately after the start of cooking.
Moreover, since the temperature sensor 42 is independent of the output control of the induction heating coils 10 to 12, a signal line may be directly connected to the refrigerant control unit 21 instead of the control unit 20.

Embodiment 4 FIG.
In the fourth embodiment, heat absorption means are provided in the outer periphery and central space of the induction heating coils 10 and 12 having a large diameter, and the configuration will be described below with reference to FIGS. 7 and 8. FIG. 7 is a cross-sectional view showing the configuration of the heat absorbing means in the fourth embodiment, and FIG. 8 is a block diagram showing the overall configuration of the induction heating cooker according to the fourth embodiment. In addition, in Embodiment 4, since it is the structure and operation | movement similar to the induction heating cooking appliance of Embodiment mentioned above except heat absorption means, below, it demonstrates centering on a different part.

  7 and 8, heat absorption means (peripheral heat absorption means) 16 are provided on the outer circumferences of the induction heating coils 10 and 12 arranged below the top plate 2, respectively, and the central space portions of the induction heating coils 10 and 12 are respectively provided. Heat absorption means (mounting part heat absorption means) 17 is provided. The heat absorbing means 16 is the tank 16a having the same shape as that of the first embodiment described above, and the heat absorbing means 17 has a planar circular tank 17a in which a concave portion is formed at the center of the upper surface. A water supply pipe 30 and a drain pipe 31 fitted with on-off valves 30d and 30e are connected to the bottom of the tank 17a.

In this heating cooker, as shown in FIG. 7, the heat absorbing means 17 is also disposed in the central space portion of the induction heating coils 10 and 12 (that is, the central portion of the heating port / mounting portion). A high cooling effect can be obtained. The refrigerant control unit 21 not only opens the on-off valves 30a and 30b of the peripheral tank 16a after the elapse of a predetermined time from the start of cooking, but also opens the on-off valves 30d and 30e on the side of the central tank 17a to enter the tank 17a. Supply water W. However, since the on-off valves 30a to 30e are provided independently at the peripheral part and the central part, the supply timing and supply amount of the refrigerant do not need to be the same. For example, during heating, water W is supplied only to the peripheral tank 16a, and control is performed so that the water W is stopped / reduced to a small flow rate in the central tank 17a. May be increased. When the flow rate is adjusted, the on-off valves 30a to 30e are not valves that can take only two states of fully open and fully closed, and electromagnetic valves that can adjust the opening according to the request of the refrigerant control unit 21 may be used.
When the detected temperature reaches 60 ° C. or less after the end of cooking, the refrigerant control unit 21 closes the on-off valves 30a and 30b on the tank 16a side, and closes the on-off valves 30d and 30e on the tank 17a side, thereby heating the heating port 3a. 3b and its periphery are stopped.

  As described above, according to the fourth embodiment, since the central space of the induction heating coils 10 and 12 is also cooled, the heating ports 3a and 3b can be cooled more quickly. Even if the heating ports 3a and 3b themselves and the periphery thereof are touched after use, a safer cooking device can be provided.

Embodiment 5 FIG.
In the first embodiment, the tank 16a is arranged so as to be in direct contact with the lower surface of the top plate 2. However, in this embodiment, the top plate 2 and the tank are connected so that heat is conducted indirectly instead of directly. An induction heating cooker provided with a heat transfer member in between will be described. Since other configurations and operations are the same as those in the above-described embodiment, the following description will focus on different parts.
FIG. 9 is a top view and a cross-sectional view showing the configuration of the heat absorbing means in the fifth embodiment. FIG. 4B shows an embodiment using a heat transfer member for cooling the peripheral portion and the heating port 3, and FIG. 5C shows an embodiment using a heat transfer member in the gap portion of the split coil.

  In FIG. 9, the two divided coils 50 are each composed of an inner coil 51 and an outer coil 52 that are substantially centered on the central axes of the heating ports 3 a and 3 b, respectively, and are arranged in the width direction in the cooker body 1 below the top plate 2. It is arranged. Temperature sensors 13 and 15 are respectively installed in the central space of the inner coil 51. The heat absorption means 60 is installed so as to contact the lower surface of the two divided coils 50 and the lower surface of the top plate 2 between the two divided coils 50.

  The heat absorption means 60 has a tank 61 and a heat transfer member 62 as shown in (b), and has a structure in which the water W absorbs heat through the heat transfer member 62. The tank 61 has a rectangular shape with a flat surface extending in the width direction of the cooker main body 1, and a cross section of the tank 61 has a convex shape so as to contact the lower surface of the top plate 2 between the two divided coils 50. Although not shown, the tank 61 is provided with a partition plate in the center in the longitudinal direction, and the water supply pipe 30 and the drain pipe 31 are connected to each of them. The upper surface of the tank 61 on the split coil 50 side is in contact with the split coil 50, whereby heat generated in the split coil 50 is absorbed by the water in the tank 61.

  The heat transfer member 62 described above includes a ring-shaped external heat transfer member 62 a provided on the outer periphery of the outer coil 52 of the split coil 50, and a ring-shaped intermediate heat transfer member inserted between the inner coil 51 and the outer coil 52. 62b and a ring-shaped internal heat transfer member 62c provided on the inner periphery of the inner coil 51 (mounting portion heat absorption means). Each of the heat transfer members 62a to 62c has an upper surface in contact with the lower surface of the top plate 2, and each lower surface in contact with the tank 61. The heat at the periphery of the top plate passes through the heat transfer members 62a to 62c. It is absorbed into the water W inside. On the other hand, the heat of the heating ports 3 a and 3 b of the top plate 2 is conducted to the heat transfer members 62 b and c and absorbed by the water W of the tank 61. Any of these conductive members 62a to 62c may be used as long as they have high thermal conductivity. For example, metals such as iron, aluminum, and stainless steel can be used. Further, even if the thermal conductivity is slightly lowered, it is possible to use a resin in consideration of advantages such as ease of manufacture.

  Further, in the heat transfer member 62 illustrated in FIG. 9B, the width of the heat transfer member 62c for the heating ports 3a and 3b in the coil radial direction is wider than the width of the heat transfer member 62a for the peripheral portion. Yes. With this structure, the cooling capacity between the heating ports 3a and 3b and the peripheral portion can be adjusted, and the cooling capacity of the heating ports 3a and 3b can be sufficiently secured. In addition, when the importance of preventing the deterioration of the heating efficiency due to the supercooling of the heating port 3 during cooking is more important than the cooling of the top plate after the heating is finished, the above-mentioned width is wide at the peripheral portion and narrowed at the heating portion. May be.

FIG. 9C shows an embodiment in which direct heat absorption in which the tank 64 is brought into contact with the top plate and indirect heat absorption in which heat is absorbed through the heat transfer member.
The heat absorbing means 63 shown in FIG. 9C includes a tank 64 provided so as to come into contact with the lower surface of the top plate in the peripheral portion, and an intermediate heat transfer member 62d inserted between the inner coil 51 and the outer coil 52. Have. The tank 64 is housed so as to surround each divided coil 50, and has a convex portion that is inserted into the central space portion of the inner coil 51 in the central portion. The ring-shaped intermediate heat transfer member 62d is inserted between the inner coil 51 and the outer coil 52, and heat of the heating ports 3a and 3b is transferred to the tank 64 by the heat transfer member 62d. Absorbed by water W.

  As described above, according to the fifth embodiment, the tanks 61 and 64 can be configured with a relatively simple structure / shape, and the refrigerant is drawn around the top plate 2 such as a gap between two divided coils. Even when it is difficult, the top plate 2 can be cooled. In particular, since the shapes of the tanks 61 and 64, which are refrigerant pipes, can be prevented from becoming very complicated, the flow of the refrigerant is leveled so that the refrigerant does not stay as much as possible in a portion where the shape is too complicated or a portion which is too narrow. 64 can be designed, and the cooling efficiency can be increased. Therefore, since the heating ports 3a and 3b and their peripheral parts can be cooled even during use or immediately after use of the cooker, a safer cooker can be provided.

Embodiment 6 FIG.
In the sixth embodiment, a heat absorbing means 65 is provided between the top plate 2 and the split coil 50 as shown in FIG.
The basic operation and configuration are the same as those of the above-described embodiment. In particular, the only difference from Embodiment 2 is whether the induction heating coils 10 to 12 are the split coils 51 and 52. The tank 66 is the same as the tank 40a of the second embodiment shown in FIG.

Embodiment 7 FIG.
The seventh embodiment is an application example of the sixth embodiment, in which the cooling of the inner coil 51 side of the split coil 50 is suppressed more than the outer coil 52 side during use of the cooker. FIG. 11 is a top view showing the configuration of the heat absorbing means in the seventh embodiment. In addition, in Embodiment 7, since it is the structure and operation | movement similar to the induction heating cooking appliance of embodiment mentioned above except a division | segmentation coil and a heat absorption means, it demonstrates below centering on a different point.

  The heat absorbing means 67 in the seventh embodiment is installed between the top plate 2 and the split coil 50, for example, and has a tank 67a formed in a planar circular shape as shown in FIG. 11, and flows into the tank 67a. The water W to be absorbed absorbs the heat of the top plate 2. The tank 67a has a water supply pipe 30 and a drain pipe 31 connected to the outer periphery thereof, and has a central axis substantially the same as that of the split coil 50 and provided approximately corresponding to the outer diameter of the outer coil 52. A ring-shaped partition plate 67b is installed. The partition plate 67b forms a ring-shaped outer flow path 67d and a circular inner flow path 67e. Further, a plate-like partition plate 67c that is closed in the circumferential direction of the outer flow path 67d and intersects the central axis except for a part of the inner flow path 67e is provided. An inflow port 67f and an outflow port 67g are provided in the inner flow path 67e with the partition plate 67c as a boundary. Although not shown, the inlet 67 f is connected to the water supply pipe 30 piped between the inner coil 51 and the outer coil 52 of the split coil 50, and the outlet 67 g is piped between the inner coil 51 and the outer coil 52. Connected to the drainage pipe 30. A flow rate control valve (not shown) is inserted between the inflow port 67f and the water supply pipe 30.

  Next, an example of the cooling operation using the heat absorbing means 67 will be described. The refrigerant control unit 21 opens the on-off valves 30a and 30b after a predetermined time has elapsed from the start of cooking to supply water W so that the inside of the outer flow path 67d of the tank 67 is full, and the amount of water in the inner flow path 67e. The opening degree of the flow control valve is adjusted so that less water W is supplied. In this case, the heat around the heating port is cooled by the water W flowing in the outer flow path 67d, and the heat at the center of the heating ports 3a and 3b is cooled with a cooling amount lower than that of the outer periphery. When the cooking is finished, the refrigerant control unit 21 opens the valve of the flow rate control valve until the temperature becomes 60 ° C. or lower (or the opening degree is larger than that during heating), and the inside of the inner flow path 67e. The water W is supplied so that the water becomes full, and the amount of cooling of the heating ports 3a and 3b is increased by securing a larger flow rate than during heating.

As described above, according to the seventh embodiment, since the flow path inside the tank 67 is divided into the cooling for the heating port (mounting portion) and the cooling for the peripheral portion, the heating ports 3a and 3b. And the amount of cooling of the peripheral part can be controlled independently.
Moreover, since it is made for the heat of heating opening 3a, 3b not to fall much until cooking is complete | finished, sufficient temperature rise of the to-be-heated body A is securable.

  In the seventh embodiment, the amount of water in the inner flow path 67e of the tank 67 is decreased until cooking is completed, but water is not supplied into the inner flow path 67e instead. Anyway.

  In addition, it has been described that the tank 67a having the inner flow path 67e and the outer flow path 67d inside is disposed between the top plate 2 and the split coil 50. However, as shown in FIG. ˜12 and the top plate 2 may be provided. Also in this case, since the water with a small amount of water flows through the inner flow path 67e until the cooking is completed, the heat cooling amount of the heating ports 3a and 3b can be kept lower than that of the peripheral portion.

Embodiment 8 FIG.
In the first to seventh embodiments, it is described that a tank is used as one part of the heat absorbing means. However, the eighth embodiment uses a pipe instead of the tank, and hereinafter, FIG. Details will be described. FIG. 12 is a top view and a cross-sectional view showing the configuration of the heat absorbing means in the eighth embodiment. The eighth embodiment is the same as the above-described embodiment except for the heat absorption means, and therefore, different parts will be mainly described below.

  In FIG. 12, the heat absorbing means 68 includes a spiral inner pipe 68 a and an outer pipe 68 b, a ring-shaped intermediate heat transfer member 62 b inserted between the inner coil 51 and the outer coil 52, and a central space portion of the inner coil 51. And a heat transfer member 62 made of a ring-shaped internal heat transfer member 62c provided in the pipe, and adopting a structure in which the water W flowing into the pipes 68a and 68b absorbs the heat of the top plate 2. Yes. The inner pipe 68a is disposed on the lower surface of the coil support plate 69 on which the split coil 50 is placed, and the outer pipe 68b is disposed on the outer periphery of the outer coil 52, that is, immediately below the peripheral portion. The outer pipe 68 b is in contact with the lower surface of the top plate 2 and the upper surface of the coil support plate 69. Although not shown, the inlet side of the inner pipe 68a and the outer pipe 68b is connected to the water supply pipe 30 to which the on-off valves 30a and 30b are attached, and the outlet side is connected to the drain pipe 31.

  In the eighth embodiment, the heat around the heating port is absorbed by the water W in the outer pipe 68b, and the heat of the heating ports 3a and 3b passes through the heat transfer members 62b and 62c via the coil support plate 69. And absorbed by the water W in the inner pipe 68a. Further, heat generated from the split coil 50 is conducted through the heat transfer members 62 b and 62 c and absorbed by the water W in the inner pipe 68 a through the coil support plate 69.

As described above, according to the eighth embodiment, the internal heat transfer member 62 c is provided in the central space portion of the inner coil 51 of the split coil 50, and the intermediate heat transfer member 62 b is provided between the inner coil 51 and the outer coil 52. Furthermore, a spiral inner pipe 68a is provided on the lower surface of the coil support plate 69, a spiral outer pipe 68b is provided on the outer periphery of the outer coil 52, and water W is applied to the inner pipe 68a and the outer pipe 68b when the top plate 2 is cooled. In addition to the heat absorption at the periphery of the heating port, the heat at the heating ports 3a and 3b is also absorbed, and thus the heat conducted radially from the periphery of the heating port on the outer pipe 68b is further suppressed. be able to. Therefore, since the heating ports 3a and 3b and their peripheral parts can be cooled even during use or immediately after use of the cooker, a safer cooker can be provided.
The inner pipe 68a and the outer pipe 68b do not have to be spiral as described above, and may be formed by connecting a plurality of concentric pipes, or the inner pipe 68a and the outer pipe 68b may be connected in series. Good.

  In the heat absorption means of FIG. 12, the outer pipe 68 b is provided on the coil support plate 69, but it may be disposed so as to contact the lower surface of the coil support plate 69. In this case, the coil support plate 69 can have a large heat transfer area so as to be in surface contact with the peripheral portion of the top plate 2. The inner pipe 68a and the outer pipe 68b are not limited to hollow pipes having a circular cross section, and may have a shape in which the contact area with the coil support plate 69 is increased in order to increase the thermal conductivity with the coil support plate 69. is there. It is also possible to adopt an integrated shape of the coil support plate 69, the inner pipe 68a and the outer pipe 68b by a combination of resin / resin and metal.

  The coil support plate 69 and the heat transfer members 62b and 62c do not have to be separate and can be integrated. For example, by pressing one disk, one or more convex portions and concave portions are formed concentrically with the center of the induction heating coil, and the convex portions are brought into contact with the top plate 2 and divided into concave portions. The heat absorbing means may be configured using the coil support plate 69 so as to house the coils 51 and 52.

  Further, the refrigerant (water) gradually increases in temperature while moving through the pipes 68a and 68b. Therefore, by forming the refrigerant flow path so as to vortex as in this embodiment, temperature unevenness of the top plate 2 can be suppressed at the left / right / up / down of the induction heating coil and at the left / right / up / down of the peripheral portion. It becomes possible. In particular, when the temperature unevenness of the heating ports 3a and 3b becomes large, for example, when a frying pan is used, the cooking is affected. Therefore, such a spiral shape is useful. Furthermore, in order to suppress temperature unevenness, the flow direction of the refrigerant can be reversed between the inner pipe 68a and the outer pipe 68b. For example, the inner pipe 68a is clockwise and the outer pipe 68b is counterclockwise or vice versa.

  In addition, each pipe 68a, 68b is configured such that the refrigerant flows from the outer circumference to the inner circumference direction (that is, inward), so that a lower temperature refrigerant can be supplied to the outer circumference portion, and the peripheral portion is radiated radially. The conducted heat can be suppressed to a lower temperature. Further, the top plate 2 has a high temperature near the induction heating coil, and the temperature decreases toward the outside of the peripheral portion. Therefore, by allowing the refrigerant to flow through the outer pipe 68b from the outer circumference to the inner circumference as described above, the temperature difference between the top plate 2 and the refrigerant is reduced, and the heat exchange efficiency is improved. Therefore, there is an advantage that more efficient cooling can be performed with a small refrigerant flow rate.

Embodiment 9 FIG.
In the first to eighth embodiments, water is supplied to the tanks and pipes to cool the surroundings of the heating ports 3a to 3c. However, the ninth embodiment uses a refrigeration cycle that absorbs heat by refrigerant circulation. The periphery of the heating ports 3a to 3c is cooled. Since the configuration and operation other than the refrigerant circuit are the same as those in the above-described embodiment, the following description will focus on differences.
FIG. 13 is a block diagram showing a schematic configuration of the induction heating cooker according to the ninth embodiment.

In FIG. 13, the heat absorption means 16 is an evaporator, and expansion valves 32a to 32c are provided on the refrigerant inflow side. The expansion valves 32a to 32c are connected to the refrigerant pipe 35, respectively. The refrigerant pipe 35 is connected to each tank 16 via a heat exchanger 34 having a fan motor 34 a and a compressor 33. As the refrigerant flowing through the refrigerant pipe 35, natural refrigerants such as non-fluorocarbon refrigerant (HFC-134a), CO ₂ , and water are used. In the unlikely event that the refrigerant leaks, a nonflammable or flame retardant refrigerant may be used so that the refrigerant does not ignite. Also, even if the refrigerant leaks, the refrigerant will not burn unless the concentration required for ignition is reached, so assuming that the refrigerant leaks into the cooker body, the cooker body is provided with an exhaust port, The interior of the cooker body may be ventilated by the fan 22.

  When cooling the top plate 2 around the heating port, the refrigerant control unit 21 drives the compressor 33 and drives the fan motor 34a to adjust the opening / closing / opening degree of the expansion valves 32a to 32c. The expansion valves 32 a to 32 c may not be provided for each heat absorbing means 16, but may be attached to the refrigerant pipe 35 near the outlet of the heat exchanger 34. When the flow rate is not adjusted, an expander (a decompression device) such as a capillary tube may be used, or the capillary tube may be combined with an on-off valve whose opening degree cannot be adjusted.

  When the compressor 33 is driven, high-temperature and high-pressure refrigerant gas is discharged from the compressor 33 and flows into the heat exchanger (condenser) 34. In the heat exchanger 34, cooling air is blown by the fan motor 34 a, and the cooling air exchanges heat with a high-temperature refrigerant gas, whereby the refrigerant is condensed to become liquid refrigerant and sent to the expansion valves 32 a to 32 c. The expansion valves 32 a to 32 c reduce the pressure of the high-pressure refrigerant, and cool liquid refrigerant is discharged to the heat absorption means 16. The liquid refrigerant flowing into the heat absorbing means 16 is gradually vaporized while taking the heat of the top plate 2. Then, the compressor 33 is reached. Control of the compressor 33, the heat exchanger 34, and the expansion valves 32a to 32c on the refrigerant pipe 35 is performed by a known control method by the refrigerant control unit 21, for example, a temperature sensor provided in the outlet side pipe of the heat absorbing means 16 Thus, the degree of superheat of the refrigerant is measured, and each device is controlled so that the degree of superheat becomes a predetermined small value (0 degree or more).

The refrigerant control unit 21 controls the expansion valves 32a to 32c corresponding to the coils other than the heating based on the information about the driving status (whether heating is performed) of the induction heating coils 10 to 12 notified from the control unit 20. Fully closed.
The heat absorbing means 16 may be anything as long as it can withstand the pressure condition of the refrigerant (including the case of negative pressure) and has sufficient heat exchange efficiency. Can be used. In particular, when a refrigerant that changes from a liquid phase to a gas phase is used in the heat absorbing means 16, the energy of the absorbed heat is used for the phase change of the refrigerant, so that the temperature of the refrigerant from the inlet to the outlet of the pipe is substantially constant. . Therefore, a more leveled cooling capacity can be obtained, and temperature unevenness that affects cooking can be sufficiently suppressed.
Further, a refrigeration cycle using a supercritical state such as a CO ₂ refrigerant can be adopted, and the condenser is used as a gas cooler.

  As described above, according to the ninth embodiment, since the top plate 2 in the vicinity of the heating port is cooled using the refrigerant circuit in the cooker, the heat transmitted radially from the heating ports 3a to 3c is reduced. Therefore, heat conduction from the heating ports 3a to 3c to the peripheral portion can be suppressed, and even if the cooker is used or immediately after use, it can be heated safely even if it touches any part other than the heating ports 3a to 3c. A cooker can be provided.

  In the ninth embodiment, the top plate 2 around the heating ports 3a to 3c is cooled using the refrigerant circuit. However, the cooling is performed using the pump 37 and the heat exchanger 34 as shown in FIG. Water may be circulated. The pump 37 may be a pump using natural convection using heat such as an induction heating coil as well as a drive unit that uses a motor. When using water, the pressure in the refrigerant circuit is set to a lower pressure than the outside air, so that bubbles are generated at a low temperature and the convection force can be enhanced by using the rising force of the bubbles. Is possible. In other words, the heat of the induction heating coil etc. is transmitted to the pipe extending in the vertical direction, and by warming the water, the expanded and lightened specific gravity gives rise to the force to circulate, and bubbles are generated in the pipe. As a result, the bubbles rise to accelerate the water and circulate the water. In this case, the natural convection pump 37 may be provided in the vicinity of the heat absorbing means 16 or integrally with the heat absorbing means 16. Further, the valves 30a to 30c may be omitted.

Embodiment 10 FIG.
In the tenth embodiment, there are two top plates 2 and water is flowed between them to cool them. Except for the heat absorption means, this embodiment is the same as the above-described embodiment. Explained. FIG. 15 is a sectional view of the top plate side of the induction heating cooker showing the tenth embodiment.

  In FIG. 15, the upper top plate 2a is detachably fixed to the upper portion of the cooker body 1 by a locking portion 2c. The lower top plate 2b is installed with a gap below the upper top plate 2a, and this gap communicates with a water supply pipe 30 and a drain pipe 31 described later to form a water channel. A frame (not shown) that contacts the lower surface of the upper top plate 2a is formed on the outer periphery of the lower top plate 2b so as not to leak water. Moreover, the induction heating coils 10-12 are arrange | positioned under the lower top plate 2b, and the temperature sensors 13-15 are each installed in the center space part of each induction heating coil 10-12. The end of the water supply pipe 30 to which the on-off valve 30a is attached is inserted between the upper top plate 2a and the lower top plate 2b, and the end of the drain pipe 31 is inserted on the opposite side.

  In the tenth embodiment, the on-off valve 30a is kept closed during cooking, and the on-off valve 30a is opened at the end of cooking to cause water W to flow over the lower top plate 2b to absorb heat from the upper top plate 2a. This state is performed for a predetermined time after the heating is completed, or until the temperature detected by the temperature sensors 13 to 15 is 60 ° C. or lower.

  Thus, the cooker main body, the lower top plate 2b installed on the upper portion of the cooker main body, the upper top plate 2b, and facing the lower top plate 2b with a space therebetween, and An upper top plate 2a that can be opened and closed, coils 10 to 12 that are installed below the lower top plate 2b and that inductively heat the heated body A via the lower top plate 2b and the upper top plate 2a, and the upper top plate 2a And a water supply pipe 30 in which a water supply opening is inserted between the lower top plate 2b and an on-off valve 30a, a drain pipe 31 in which a water discharge port is inserted between the upper top plate 2a and the lower top plate 2b, and cooking Since the on-off valve 30a is opened after completion and the refrigerant control part 21 which flows water to the lower top plate 2b is provided, the upper top plate 2a can be cooled quickly. Moreover, since the upper top plate 2a is configured to be openable and closable, cleaning such as removal of chalk attached to the lower top plate 2b can be facilitated.

Embodiment 11 FIG.
In the eleventh embodiment, a cover that covers the top plate 2 is provided, the cover is closed during cooling, water is cooled between the top plate 2 and cooled, and the top plate can be washed. This will be described with reference to FIGS. 16 and 17. FIG. 16 is an external perspective view of the induction heating cooker showing Embodiment 11, and FIG. 17 is a schematic side view showing the side of the induction heating cooker.

  In these drawings, the top plate 2c installed on the upper part of the cooker body 1 is formed to be recessed / sinked downward. An end portion of the water supply pipe 30 is fixed to the front side of the top plate 2c, and water spraying means having a plurality of discharge ports is provided at this end portion. This sprinkling means is installed in the width direction of the top plate 2c so as to have a length substantially close to the width of the top plate 2c, and when the valve 30a is opened by the refrigerant control unit 21, the area of the ejection port is limited by the discharge port. Therefore, water is sprayed like a shower with a strong momentum. A drain port 1b is provided at the rear part of the top plate 2c, and the water discharged from the watering means can be collected and allowed to flow to the sewer through the drain pipe 31. An exhaust port 8c is provided on the left side of the rear portion of the cooker body 1, and is used for exhausting the grill 8 and cooling air from the fan 22 in the body. An intake port 1a of the fan 22 is provided on the rear right side. In addition, a cover 70 is provided on the top plate 2c so as to face the top surface of the top plate 2c and is pivotally supported by the rear portion of the cooker body 1 so as to be opened and closed. On the front side of the cover 70, a locking portion 72 that locks the surface 1 c on which the thermal power display portions 4 a to 4 c and the like of the cooker body 1 are arranged and prevents water from being ejected is formed. . A plurality of protrusions 71 having a triangular side surface formed extending in the width direction are arranged on the surface of the cover 70 on the top plate 2c side. A drain pipe 31 is connected to the drain port 1b described above.

  In the induction heating cooker configured as described above, when the cooking is finished, the on-off valve 30a is opened to allow water W to flow on the top plate 2c and to be discharged from the drain port 1b. When the refrigerant control unit 21 detects from the notification of the control unit 20 that the heating of all the induction heating coils 10 to 12 has been completed, the refrigerant control unit 21 determines whether the cover 70 is closed. Any means can be used for this determination as long as it can be confirmed that the cover 70 is closed. For example, the upper surface 1c on the main body side is locked when the cover 70 is closed. By providing a contact sensor or a non-contact sensor at a position facing the portion 72, the opening and closing of the cover 70 can be detected. In addition, it is possible to provide a similar sensor near the rear end of the main body or at the shaft stop, and when a non-contact sensor such as an infrared sensor is provided in the heating ports 3a to 3c, It may be determined that the cover 70 is closed when a state different from the open state of the cover 70 is detected.

  When it is detected that the cover 70 is closed, the refrigerant control unit 21 determines whether running water is permitted / instructed to immediately run by the user's setting input through the operation unit 7. The operation of the operation unit 7 by the user is a processing item of the control unit 20, and the control unit 20 monitors the input of the operation unit 7, and in the same manner as when there is an instruction to start thermal power, etc. If there is, the refrigerant control unit 21 is notified. When the refrigerant control unit 21 receives this notification, the refrigerant control unit 21 sets a flag indicating that the instruction has been given in the internal memory, and checks the presence or absence of this flag when the cover 70 is closed. Determine whether to start.

  When running water permission / instruction is issued, the refrigerant control unit 21 opens the on-off valve 30a and starts watering by the watering means. The water spouted from the sprinkling means cools the top plate 2c, and collides with or peels off dirt adhered to the top plate 2c and the cover 70 using a gap between the top plate 2c and the cover 70 as a water channel. However, it flows to the drain port 1b. At this time, if the cover 70 has protrusions (as described above, it may not have a triangular section as described above), the flow of water becomes complicated and the force applied to dirt becomes stronger. improves. During cooking, it often happens that food drops or spilled juice etc. adhere to the top plate 2, but as mentioned above, this cooking device causes dirt to flow with water, so the top plate 2 c Can reduce the trouble of cleaning. Further, food, oil, etc. scattered during cooking adhere to the cover 70, but this can also be made to flow at the same time. Since the cover 70 is erected on the rear end side from the exhaust port 8c in the open state, the effect of suppressing the diffusion of smoke emitted from the grill 8 and guiding the smoke to be sucked into the ventilation fan smoothly is also obtained. I can expect.

  This outflow of water W is performed for a predetermined time suitable for cleaning. The refrigerant control unit 21 measures the time from the start of running water using a timer, and closes the on-off valve 30a after counting a predetermined time. In addition, if washing is unnecessary and only cooling the top plate 2 is sufficient, running water in a shorter time than washing is sufficient, and the temperature detected by the temperature sensors 13 to 15 becomes a predetermined temperature (60 ° C. or less). You may make it continue flowing water until. Thereby, the heat of the top plate 2c is absorbed and quickly cooled. Further, even when there is an overflow from the heated body A, the dirt can be washed by flowing it to the drain port 1b. In addition, when the top plate 2c is covered with the cover 70 when the water W flows out on the top plate 2c, the water W does not scatter to the periphery but flows into the drain port 10 while hitting the protrusion 71, and thus has more cleaning power. Goes up.

  As described above, the heating sources 10 to 12 that are housed in the cooking device main body 1 and heat the heated object A and the upper surface of the cooking device main body 1 are provided, and the heated object A is placed corresponding to the heating source. A top plate 2c, a cover 70 which is provided so as to be openable and closable with respect to the cooker body 1 and covers the top surface of the top plate 2c with a space therebetween, and forms a water channel between the top plate 2c, and the top plate 2c And a cover 70 and a water supply pipe 30 for flowing water, and a drain port 1b for draining water on the top plate 2c. When cooking is completed, the on-off valve 30a is opened to flow water W on the top plate 2c. Therefore, the top plate 2c can be quickly cooled, and overflow can also be washed by flowing into the drain port 1b at the same time.

  In addition, when not only cold water but also hot water water pipes are installed at the installation location of the heating cooker, a switching valve is connected to the water supply pipe 30 so that the cold water pipe and hot water pipe at the installation location can be switched. If hot water is sprinkled at the beginning of washing and cold water is sprinkled after a predetermined time, the detergency of oil stains and the like is increased. In addition, even when hot water is not supplied, it is also possible to arrange a water storage tank inside or outside the heating cooker and provide a heater in the water storage tank to warm the water in the water storage tank and supply hot water. .

Embodiment 12 FIG.
In the twelfth embodiment, cooling of the heating ports 3a and 3b is controlled according to the heating mode, and a detailed example of the refrigerant control in the above-described embodiment is also shown. Hereinafter, with reference to FIG. 18 and FIG. 19, a description will be given focusing on differences from the above-described embodiment and more detailed control points. FIG. 18 is a flowchart showing the operation of the induction heating cooker according to the twelfth embodiment, and FIG. 19 is a graph showing the difference in the temperature change and the cooling amount of the heated object and the top plate depending on the heating mode, such as the normal mode and the fried food mode It is. The flowchart of FIG. 18 controls the cooling of the heating unit and the peripheral part, and therefore the hardware configuration will be described by taking the heating cooker of FIGS. 7 and 8 as an example. If attention is paid to this, it can be applied to any of the above-described first to tenth embodiments. Moreover, the on-off valves 30a-30e which control a refrigerant | coolant flow use the flow volume adjustment valve which can adjust opening degree.

Hereinafter, based on FIG. 18, processes, such as a heating port and cooling control of a peripheral part, a high temperature warning display, are demonstrated.
First, after the power is turned on, the control unit 20 enters a standby state until a heating operation by the user is input to the operation unit 7 and monitors the operation of the operation unit 7. Then, it is determined whether or not a heating operation has been performed from the output signal of the operation unit 7 (S1). For example, when it is determined that a heating operation (thermal power setting) has been performed on the induction heating coil 10, this thermal power setting and heating The inverter is controlled according to the heating target temperature T1 based on the mode to start heating the induction heating coil 10 (S2). The heating mode (stir fry mode / fried food mode / boiled food, automatic water heating mode, etc.) is an inverter control mode set by the user according to cooking by the operation unit 7, that is, a heating pattern of the object A to be heated. When it is performed, it is recorded as data in the built-in memory of the control unit 20.

  After a predetermined time has elapsed from the start of heating or when the temperature of the temperature sensor 13 reaches a predetermined value (for example, 60 ° C.) or more (S3), the control unit 20 starts heating the refrigerant control unit 21 or the temperature sensor 13 A cooling command is transmitted to the refrigerant control unit 21 together with the identifier of the induction heating coil 10 corresponding to and information on the heating mode of the coil. The reason why the cooling is not performed immediately after the start of heating in step S3 is to make the temperature rise of the heated object A as fast as possible. When receiving the cooling command, the refrigerant control unit 21 selects a cooling amount based on the heating mode as described below, and cools the heating port 3a.

-Stir fry mode The stir-fry mode is a heating mode in which the fried food is cooked in a frying pan, etc., the allowable range of the heating target temperature T1 is 200 ° C or higher, and the default value (default value) of the induction heating coil output is normal ( This is a mode in which the value of the coil assigned rating value is set.
When it is determined that the stir-fry mode is selected, the refrigerant control unit 21 closes / closes the corresponding on-off valve 30d so as not to cool the heating port 3a (S5). As described above, the reason why the top plate of the heating port 3a is not actively cooled in the stir-fried food mode is that when cooking the fried food, the surface of the food is solidified / burned at a high temperature so that the taste of the food such as gravy is obtained. This is because it is necessary not to escape outside or to give a crisp texture. By not cooling, the temperature of the non-heating body such as a frying pan can be sufficiently increased by cooling the top plate 2. Further, even if the temperature of the heated object A is likely to drop suddenly due to the input of food, the temperature drop can be quickly stopped by increasing the output of the induction heating coil 10, and the heating target temperature T1 is reached. It becomes possible to approach.
As described with reference to FIG. 3, there is an air layer between the heated object A and the top plate 2 due to the projection P of the heat-resistant paint, and even if the top plate 2 is cooled, the heated object immediately. This control is particularly effective when A is not cooled but the effect of cooling cannot be ignored.

-Deep-fried food mode The deep-fried food mode (also called tempura mode) is set so that the target heating temperature T1 is about 160-200 ° C, and the default value of the temperature rise rate (coil output) is also set within the normal rated value. Is.
When it is determined that the fried food mode is selected, the refrigerant control unit 21 controls the opening degree of the corresponding on-off valve 30d to be small in order to cool with a small cooling amount (S6). By this control, it is possible to control the temperature of the top plate 2 so as not to be excessively high, and the top plate temperature after use can be lowered, so that it is safer. In the fried food, the temperature control of the heated object A is moderate as compared with the fried food, but temperature control is important. Therefore, the amount of cooling is conserved to facilitate temperature control.

-Boiled food / boiling mode In the automatic boiling mode, the heating target temperature T1 is about 100 ° C., but in order to shorten the boiling time, the temperature rise rate (coil output) is set to a maximum setting exceeding the normal use. In the case of the maximum setting, the induction heating coil 10 consumes power exceeding the rated power pre-assigned to each coil, so that water can be rapidly heated. However, when the other induction heating coils 11 and 12 are heated, cooking is performed. Since the power of the entire unit exceeds the allowable value (overall rated value), the maximum output cannot be achieved. In that case, an output within the rated value assigned to the induction heating coil 10 is set.
When it is determined that the hot water heating mode is selected, the refrigerant control unit 21 controls the opening degree of the on-off valve 30d to be larger than that in step S6 in order to cool the heating port 3a with a cooling amount larger than that in the deep-fried food mode (S7). ). In this mode, since the amount of cooling is large, the temperature of the top plate 2 is lower than that in the deep-fried food mode, and the top plate temperature after use can be further lowered.
The boiled food mode is the same, but the coil output is lower than the automatic water heating mode and is set within the normal setting range (rated value of each induction heating coil). In the hot water heating mode, since the heating time may be about 1 to 3 minutes, it is conceivable that the temperature of the top 2 is not so high. Therefore, control may be performed such that the cooling is not performed in the hot water boiling mode or the cooling amount is not reduced, and the cooling amount is increased in the boiled food mode used for a long time.

  Next, the refrigerant control unit 21 controls the opening degree of the on-off valve 30a to be large in order to start cooling the peripheral part (S8). In addition, when there is no cooling of the peripheral part of the heating port 3a, the temperature of the top plate 2 rises as shown by a one-dot chain line. Note that the refrigerant supply to each of the heat absorbing means 15 to 17 in steps S6 to S8 need not be continuous, and can be performed intermittently by repeatedly opening and closing the valve according to the required cooling amount. is there.

  After starting the cooling of the peripheral part of the heating port 3a, the control unit 20 determines whether or not the temperature of the top plate 2 exceeds the high temperature caution temperature T (60 ° C.) (S9), and the temperature is equal to or lower than T. When the high temperature caution display portion 5a is turned off (S10), it is determined whether or not the cooking is finished (S12). When the temperature of the top 2 exceeds the high temperature caution temperature T, the high temperature caution display portion 5a is turned on to prompt the user to be aware of the high temperature (S11).

Next, the control part 20 determines whether heat cooking is complete | finished (S12). When a heating end instruction is input from the user to the operation unit 7, the control unit 20 identifies this instruction and proceeds to an end process. On the other hand, if it is determined that the process is not finished, the control unit 20 returns to the above-described determination of the top board temperature (S9), and continues the high temperature caution display process.
In the case of ending, the control unit 20 stops energization of the induction heating coil 10, and transmits a cooling instruction after heating together with the identifier of the induction heating coil 10 to the refrigerant control unit 21. Upon receiving this command, the refrigerant control unit 21 opens the respective on-off valves 30a and 30d in order to cool the heating port 3a and the peripheral portion corresponding to this command. Here, the opening degree of each on-off valve is made larger than the opening degree when the cooling amount is reduced as in the deep-fried food mode (S6), and cooling is performed so that a larger refrigerant flow rate is secured and the target temperature is rapidly reached. (S13).

Next, the control unit 20 determines whether the temperature detected by the temperature sensor 13 has become lower than the high temperature caution temperature T (S15). When the temperature is higher than the high temperature caution temperature T, the control unit 20 turns on the high temperature caution display unit 5a (S14), while the refrigerant control unit 21 continues cooling (S15).
Further, when the temperature of the top plate 2 is sufficiently lowered, the control unit 20 stops the power supply to the high temperature caution display unit 5a and turns off the light (S16). And the control part 20 transmits the cooling stop command after a heating with the identifier of the induction heating coil 10 to the refrigerant | coolant control part 21, and the refrigerant | coolant control part 21 which received this instruction | command fully closes the on-off valves 30a and 30d. Then, supply of the refrigerant to the heat absorbing means 16, 17 is stopped.

In addition, since the to-be-heated body A may cool quickly if the heating port 3a is cooled too much after completion | finish of a heating, it is good to adjust the stop temperature of cooling suitably.
In addition, when the presence or absence of the heated object A on the heating port is detected and the heated object A is present, the cooling stop temperature in step S15 is set to be higher or the cooling is stopped, and there is no heated object A In addition, the heating port 3a may be cooled as in step S13 described above. The presence or absence of the object to be heated A can be determined by passing an extremely short current through the induction heating coil 10 and measuring the impedance at this time. That is, when the impedance is high, it can be determined that there is an object to be heated A, and when it is lower than a predetermined value, there is no object to be heated A. As a method for determining this side, a known technique known as pan detection can be used, and when the temperature sensor 13 is an infrared sensor, it can also be determined by another optical sensor provided under the heating port 3a. Is also possible. In addition, while cooling of the heating port 3a is controlled by the presence or absence of the article A to be heated, safety is enhanced if cooling of the peripheral portion is performed regardless of this.

FIG. 19 is a graph showing changes in the top plate temperature and the heated object temperature depending on the heating mode. The top plate temperatures in the fried food mode and the boiled food mode are compared, and the heating target temperature in each mode is the same for comparison.
The dotted line indicates the temperature of the object A to be heated in both modes, and is controlled so that the temperature suddenly rises from the start of heating and converges near the heating target temperature. Since the temperature of the object A to be heated varies depending on the amount, type, or timing of food to be put in the object A to be heated, it may not actually be as shown in FIG. ing.
The solid line indicates the top plate temperature of the heating port 3a in the boiled food mode, and the temperature rises more slowly than the heated object A, which is a heating element, at the initial stage of heating. At this time, the heating port 3a is not cooled. When the heating reaches a predetermined time or when the top plate temperature reaches a predetermined temperature, cooling is started and the temperature of the top plate 2 is suppressed to the vicinity of the predetermined temperature.
The alternate long and short dash line indicates the top plate temperature of the heating port 3 when in the stir-fried mode, and cooling is not performed as described above in the initial stage of heating, The state which is not cooled continues. Therefore, the temperature of the heating port 3a rises so as to approach the temperature of the heated object A. How much the temperature of the heating port 3a approaches the temperature of the heated body A depends on the thickness of the air layer provided between the heated body A and the heating port 3a and the heat insulation performance, and the induction heating coil. When 10 becomes high temperature, it is influenced also by the temperature. As described above, since the cooling of the heating port 3a is suppressed in the fried food mode, the influence of the cooling of the heated object A can be suppressed as described above. In FIG. 19, comparison was made in the temperature range used even in the boiled mode, but the stir-fried food may use a high temperature of 250 ° C. or higher, and the heating efficiency improvement effect in such a high temperature range is high.
After the heating is completed, the amount of cooling is increased in both modes, so that the temperature of the heating port 3a is rapidly decreased, and a safe cooking device can be provided even if the user touches the top plate 2. In FIG. 19, the temperature of the heated object A after the heating is not displayed (because the frying pan and the like are removed after cooking).

  As described above, according to the twelfth embodiment, the cooling of the heating ports 3a to 3c is controlled in accordance with the heating mode, and then the cooling of the periphery of the heating port is performed. Temperature rise can be secured and temperature controllability can be improved. The amount of cooling during heating is adjusted according to the level of the heating target temperature. If the target temperature is high, the cooling amount is low or no cooling. If the target temperature is low, the cooling amount is high. Can be taken.

  In the above-described twelfth embodiment, the cooling of the peripheral portion and the heating port 3a is individually controlled, but it is also possible to cool only the peripheral portion. Further, even when the cooling amount control of the peripheral portion and the heating port 3a cannot be individually controlled using the on-off valve as in the heat absorbing means shown in FIG. 9, the heating port 3a in steps S5 to S7 in FIG. The cooling of the top plate 2 and the high-temperature warning display can be changed to the heating control by selecting whether to perform the cooling control of the peripheral portion of step S8 without performing these processes. It is possible to implement together.

Embodiment 13 FIG.
Next, cooling control for simultaneously controlling the induction heating coil output and the heating port cooling amount according to the temperature of the heated object will be described. In the thirteenth embodiment, particularly when the temperature of the object to be heated A does not rise sufficiently even if the output of the induction heating coil is increased, adaptive control for reducing the amount of cooling by the heat absorbing means is performed.
The control of the thirteenth embodiment can be applied to the heating cooker (hardware) of the first to tenth embodiments similarly to the twelfth embodiment, but as a typical example, the heating cooker of FIG. The following will be described with reference to FIG.

FIG. 20 is a flowchart showing the cooling control and the like of this embodiment.
First, the control unit 20 determines whether or not a heating operation has been performed by operating the operation unit 7 (S21). For example, when a heating operation (heating power setting) is performed on the induction heating coil 10, the control unit 20 controls the inverter. Then, current is supplied to the induction heating coil 10 to start heating (S22). Thereafter, the control unit 20 stands by until a predetermined time (for example, every several tens of milliseconds or every second) that is a control interval of the thermal power adjustment elapses (S23).
Next, the control unit 20 reads the temperature detected by the temperature sensor 13, that is, the heated object temperature t1, and determines which of the following corresponds to the heated object temperature t1 (S24).

-Coil output increase In the case of t1 <(target heating temperature T1-α), since the heated object temperature t1 has not reached the target heating temperature T1, the control unit 20 can further increase the output of the induction heating coil 10 or not. Is determined (S25). Here, α is a temperature margin, and a predetermined value (for example, 3 ° C.) is set. This temperature margin α is set to reduce the switching frequency so that the switching process in step S24 does not occur frequently. When the current induction heating coil output is not changed to a large value and is a small value, or when the maximum value of the multistage coil outputs has not been reached, the control unit 20 supplies the induction heating coil 10 to the induction heating coil 10. The power is increased to a value larger by one of the large value / multi-stage output (S26). On the other hand, when a large value has already been set, or when the current output has reached the maximum value among the multi-stage coil outputs, the control unit 20 does not increase the coil output and the refrigerant control unit 21. In order to instruct a decrease in the cooling amount, a heating port cooling amount decrease command is transmitted together with the identifier of the induction heating coil 10. When the refrigerant control unit 21 receives this command, the refrigerant control unit 21 reduces the opening of the on-off valve 30d corresponding to the induction heating coil 10 indicated by the identifier by one step, and reduces the refrigerant inflow amount (S27).

Coil output maintenance When (T1-α) ≦ t1 <T1, the temperature of the heated object A is substantially controlled to the heating target temperature, so the control unit 20 maintains the output of the induction heating coil 10 while Then, the detected temperature t2 of the top plate 2 is acquired from the temperature sensor 13, and the cooling process according to the temperature t2 of the top plate is determined (S30).
When the top plate temperature t2 <(upper limit temperature T2-β), the heating port 3a is sufficiently cooled, so the control unit 20 sends a heating port refrigerant amount reduction command to the refrigerant control unit 21 together with the identifier of the induction heating coil 10. The refrigerant control unit 21 that outputs the command and controls the on-off valve 30d so that the cooling amount is decreased by one more stage. The temperature margin β is the same as α, and a value larger than α is set in order to make the sensitivity more dull.
When (T2-β) ≦ t2 <T2, it is determined that the temperature of the heating port 3a is appropriately controlled, and the control unit 20 does not instruct the refrigerant control unit 21 to change the cooling amount.
When upper limit temperature T2 <top plate temperature t2, since temperature of heating port 3a is too high, control unit 20 transmits a heating port cooling amount increase command to refrigerant control unit 21 together with the identifier of induction heating coil 10. Receiving this command, the refrigerant control unit 21 controls the on-off valve 30d corresponding to the induction heating coil 10 indicated by the identifier, and increases the cooling amount by one step. That is, the opening degree of the on-off valve 30d is increased by one step.

Coil output reduction When it is determined in step S24 that the target heating temperature T1 is equal to or lower than the heated object temperature t1, the heated part A is heated too much. It is determined whether the output needs to be lowered (S28). If the output of the induction heating coil 10 has already been reduced, or if the current output has reached the lower limit value of the multistage induction heating coil output, the output has been sufficiently reduced, so that the output is maintained as it is. Then, it is determined that the temperature gradually decreases, and the process proceeds to the refrigerant amount processing in step S30 as it is. On the other hand, when that is not right, the control part 20 changes the output of the induction heating coil 10 from a large value to a small value, or reduces it to the output one step smaller among multistage outputs (S29). When this process ends, the control unit 20 proceeds to the above-described cooling amount process (S30).
In addition, when the temperature t1 of the to-be-heated body A is too high, unlike the case where it is too low, the heating port cooling amount is not controlled. This is because the temperature control by the output of the induction heating coil 10 is simplified by cooling the heating port 3a, and the temperature is prevented from fluctuating by cooling. However, this cooling process is not denied, and when YES is determined in step S28, the process can be performed in the reverse manner of step S27 to actively lower the temperature. In this case, the processes in steps S30 to S32 are skipped in the same manner as in step S27 and subsequent steps.

  When the above process ends, the control unit 20 determines whether or not there is an instruction to end the cooking (S33), and if not, returns to step S23. On the other hand, in the case of termination, the control unit 20 stops (supply of power to the induction heating coil 10) (S34), and transmits a post-heating cooling command to the refrigerant control unit 21 together with the identifier of the induction heating coil 10. Receiving this command, the refrigerant control unit 21 controls the on-off valve 30d so that the cooling amount of the heating port 3a is maximized or increased (S35). Then, it is determined whether or not the temperature t2 of the top plate 2 is t2 <(T2-β) (S36). When the temperature t2 is high, the high temperature warning display portion 5a is turned on to prompt the user to be aware of the high temperature ( S37) This operation is repeated until the temperature t2 of the top plate 2 becomes t2 <(T2-β). When the temperature t2 of the top plate 2 becomes t2 <(T2-β), the high temperature caution display portion 5a is turned off (S38), the on-off valve 30d is closed, and the cooling of the heating port 3a is stopped (S39). ).

  As described above, the cooling of the top plate 2 and the output of the induction heating coils 10 to 12 are controlled according to the temperatures of the heating ports 3a to 3c of the top plate 2 and the heated object A. In addition to the effect that heat conduction from the part can be suppressed, a sufficient temperature rise of the heated object A can be secured.

Although the cooling amount control of the heating port 3a has been described in the present embodiment, it is preferable to cool the peripheral portion at the same time. Cooling of the peripheral part is a method of supplying a substantially constant amount of cooling during heating and after heating, a method of increasing the amount of cooling after heating compared to during heating, or the amount of cooling during heating compared to the amount of cooling after heating The method of increasing the number can be adopted. Further, it is possible to control the cooling of the peripheral portion in the same manner as the cooling of the heating port 3a in steps S27, S31, S32, S35, and S39 of FIG.
The cooling amount of the heating port 3a and the peripheral part may be substantially the same, either heating port> peripheral part or heating part <peripheral part. Here, the cooling amount is a cooling amount per unit area on the top plate.

1 to 20, the same reference numerals represent the same or corresponding parts.
In the first to thirteenth embodiments described above, a single coil is used as an induction heating coil or a split coil is used as an example. In each embodiment, which type of induction heating coil is used. Needless to say.
Furthermore, although the temperature sensors 13 to 15 are also arranged below the heating ports 3a to 3c or below the peripheral part, either type of temperature sensor is controlled by controlling the cooling amount. The detected temperature may be used. However, the temperature sensors 13 to 15 below the heating port are mainly used for the output control of the induction heating coil.
Further, by cooling the heating ports 3a to 3c that become the hottest with the heat absorbing means (mounting part heat absorbing means), the peripheral part can be cooled even if the heat absorbing means in the peripheral part is omitted.
As the refrigerant, not only water but any liquid refrigerant may be used.
Further, the on-off valves 30a to 30e may be provided in the drain pipe 31 so that the refrigerant always accumulates in the heat absorption means 16 and 17 instead of the water supply pipe 30.
The control unit 20 and the refrigerant control unit 21 do not need to be provided independently, and one microprocessor can be used.

  The above-described embodiments show examples of the present invention, and the present invention is not limited to these embodiments. Therefore, various modifications can be made based on these embodiments without departing from the spirit of the present invention. Also, in the above-described embodiment, the constituent elements of various aspects and the combinations thereof have been described. However, these combinations are also examples, and different constituent elements of different embodiments can be combined.

In the above-described first to thirteenth embodiments, a liquid refrigerant is used to cool the top plate 2. for that reason,
・ High heat capacity and small volume of refrigerant enables quick cooling in a short time. ・ Even when the power is turned off, the liquid refrigerant can absorb heat and the temperature can be lowered relatively quickly. ・ The refrigerant speed is faster than when blowing air. Low speed and excellent quietness ・ Refrigerant drive energy required for cooling can be reduced ・ Refrigerant does not diffuse and dissipate, so local cooling is possible ・ Effective difference in cooling amount at multiple locations・ If the drain pipe is connected to the sewer, the heat is discharged to the outside of the room.

It is an external appearance perspective view of the induction heating cooking appliance which shows Embodiment 1 of this invention. It is a block diagram which shows schematic structure of the induction heating cooking appliance which concerns on Embodiment 1. FIG. It is sectional drawing which expands and shows a part of top plate of an induction heating cooking appliance. FIG. 3 is a cross-sectional view and a top view showing the configuration of the heat absorbing means in the first embodiment. FIG. 6 is a cross-sectional view and a top view showing a configuration of a heat absorbing means in a second embodiment. FIG. 9 is a top view showing a configuration of heat absorption means in Embodiment 3. FIG. 6 is a cross-sectional view showing a configuration of heat absorbing means in a fourth embodiment. It is a block diagram which shows schematic structure of the induction heating cooking appliance which concerns on Embodiment 4. FIG. FIG. 10 is a top view and a cross-sectional view showing a configuration of a heat absorbing means in a fifth embodiment. FIG. 10 is a cross-sectional view showing a configuration of heat absorbing means in a sixth embodiment. FIG. 10 is a top view showing a configuration of heat absorbing means in a seventh embodiment. FIG. 10 is a top view and a cross-sectional view showing a configuration of a heat absorbing means in an eighth embodiment. It is a block diagram which shows schematic structure of the induction heating cooking appliance which concerns on Embodiment 9. FIG. It is a block diagram of the induction heating cooking appliance which shows the other form of Embodiment 9. FIG. It is sectional drawing by the side of the top plate of the induction heating cooking appliance which shows Embodiment 10. FIG. It is an external appearance perspective view of the induction heating cooking appliance which shows Embodiment 11. FIG. It is a schematic side view which permeate | transmits and shows the side surface of an induction heating cooking appliance. It is a flowchart which shows the operation | movement of the induction heating cooking appliance in Embodiment 12. It is a figure which shows the temperature change of the to-be-heated body at the time of stir-fry / boiled food mode, and the temperature change of a top plate. It is a flowchart which shows the operation | movement of the induction heating cooking appliance in Embodiment 13.

Explanation of symbols

1 cooker body, 2 top plate, 2a upper top plate, 2b lower top plate, 2c concave top plate, P protrusion (heat-resistant paint), 3a-3c heating port, 4a-4c thermal power display, 5a-5c Display unit, 6 display unit, 7 front operation unit, 8 grill unit, 10-12 induction heating coil,
13 to 15 temperature sensor, 16 heat absorption means, 17 heat absorption means, 20 control section, 21 refrigerant control section, 22 fan motor, 30 water supply pipe, 30a to 30e on-off valve, 31 drain pipe, 32a to 32c expansion valve, 33 compressor , 34 heat exchanger, 37 pump, 40 heat absorption means, 43 ring-shaped high temperature caution display section, 42 temperature sensor, 50 divided coils, 60 heat absorption means, 62 heat transfer member, 63 heat absorption means, 65 heat absorption means, 67 heat absorption means , 68 heat absorption means, 69 coil support plate, 70 cover, 71 protrusion, 72 locking part.

Claims (15)

The cooker body,
An induction heating coil that is housed in the cooker body and heats the object to be heated;
A top plate that is installed on the upper part of the cooker main body and has a placement portion on which the heated object is placed at a position facing the induction heating coil;
Heat absorption means for absorbing the heat of the top plate around the mounting portion into the liquid refrigerant ,
The said heat absorption means has a ring-shaped periphery part heat absorption means which surrounds the outer periphery of the said induction heating coil, and contacts the lower surface of the said top plate, The cooking device characterized by the above-mentioned. The endothermic device, the centrally located space of the induction heating coil, No placement claim 1 Symbol and having a mounting portion heat absorbing means for absorbing the heat of the top plate of the mounting table by the liquid coolant Cooking cooker. The cooking device according to claim 1 or 2 , wherein the heat absorption means is provided as a part of a refrigerant pipe through which a liquid refrigerant flows . The heat absorbing means, the heating cooker of claim 3 Symbol mounting characterized by comprising the placed heat transfer member to contact the top plate and the refrigerant pipe. The heat absorption means has a spiral inner pipe installed at the lower part of the induction heating coil ,
It said peripheral portion endothermic device is No placement claim 1 Symbol, wherein the induction surrounds the outer periphery of the heating coil is in thermal contact with the spiral outer pipe you the lower surface of the top plate <br/> Cooking cooker. The cooking device according to claim 2, wherein the refrigerant flow rate of the placement part heat absorption means is smaller than the refrigerant flow rate of the peripheral heat absorption means. To the endothermic device, a water supply pipe valve is mounted, and the drainage pipe is connected,
The cooking device according to any one of claims 1 to 6 , further comprising refrigerant control means for controlling the valve and supplying liquid refrigerant to the heat absorption means. The cooking device according to claim 7 , wherein the refrigerant control means controls the valve of the water supply pipe according to the temperature of the top plate. The refrigerant control means is configured such that the cooling amount during heating of the placement part heat absorption means is less than the cooling amount after completion of heating, or during the heating, the supply of liquid refrigerant to the placement part heat absorption means is stopped and the heating is finished. The cooking device according to claim 7 or 8 , wherein the valve is controlled so as to start the supply of the liquid refrigerant. The said refrigerant | coolant control means controls the valve of the said water supply pipe | tube according to the heating mode of the said induction heating coil, and increases / decreases or stops the cooling amount of a liquid refrigerant | coolant , The any one of Claim 7 thru | or 9 characterized by the above-mentioned. Cooking device. The refrigerant control means determines whether or not the temperature of the top plate is equal to or lower than a predetermined temperature after the end of cooking, and closes the valve of the water supply pipe when the temperature is equal to or lower than the predetermined temperature. The cooking device according to any one of claims 7 to 10 . The refrigerant control means reduces the cooling amount of the liquid refrigerant flowing into the placement part heat absorption means by reducing the opening degree of the valve of the water supply pipe when the temperature of the heated object is lower than the heating target temperature. The cooking device according to any one of claims 7 to 11 , wherein when the temperature of the heating body is equal to or higher than the heating target temperature, the opening degree of the valve of the water supply pipe is controlled according to the temperature of the top plate . . A temperature sensor is provided outside the outermost periphery of the induction heating coil,
The said refrigerant | coolant control means opens the valve of the said water supply pipe when the detection temperature of the said temperature sensor exceeds the preset value , A liquid refrigerant | coolant is made to flow in into the said peripheral part heat absorption means. The cooking device according to any one of 7 to 12 . A compressor,
A heat exchanger for cooling the refrigerant compressed by the compressor;
Provided with an expansion valve for expanding the refrigerant cooled by the said heat exchanger,
The heat absorbing means causes the refrigerant decompressed by the expansion valve to absorb the heat of the top plate,
The cooking device according to any one of claims 1 to 13 , wherein the compressor, the heat exchanger, the expansion valve, and the heat absorption means constitute a refrigeration cycle connected by piping. A pump for circulating a liquid refrigerant;
And a heat exchanger for cooling the liquid refrigerant pushed out by the pump,
The heat absorption means causes the liquid refrigerant cooled by the heat exchanger to absorb the heat of the top plate,
The cooking device according to any one of claims 1 to 13 , wherein the pump, the heat exchanger, and the heat absorbing means constitute a circulation circuit connected by piping.

Images