JP3177275U - Temperature control cooking container - Google Patents

Abstract

The present invention provides a temperature-adjustable cooking container capable of finishing cooking by adjusting the distance between a container and a heat source according to temperature using bimetal or the like.
When a temperature adjusting cooking container is heated by a heat source and a temperature adjusting mechanism reaches a predetermined temperature, a metal plate is warped in a bow shape due to the characteristics of the bimetal or shape memory alloy. At this time, the metal plate 124 pushes up the heat receiving bottom surface 140 of the container body 110 upward. That is, the temperature adjustment cooking container 100 moves in a direction away from the heat source. As a result, since a gap as an air layer is formed between the heat receiving plate 122 and the heat receiving bottom surface 140, the heating of the container body 110 is weakened. When the container body 110 is pushed upward with respect to the heat source, the detection arm 131 comes into contact with the switch 132, the switch 132 of the sound generation mechanism 130 is turned on, and a predetermined sound is output from the sound generation mechanism 130. The
[Selection] Figure 1

Description

  The present invention relates to a temperature adjustment cooking container.

  Conventionally, there are pans, kettles, frying pans and the like as cooking containers, and gas utensils, electric heating utensils, electromagnetic cooking utensils and the like as heating cookers (heating heat sources). In recent years, gas utensils and electromagnetic cooking utensils that have a temperature sensor and can automatically adjust the strength of a heat source during heating have been developed. For example, there is a gas appliance equipped with a temperature sensor that comes into direct contact with the bottom of the pan by the expansion and contraction of a spring. In addition, there are electromagnetic cooking utensils that indirectly measure the temperature of the cooking container by measuring the temperature of the top plate or measure the temperature of the pan bottom with infrared rays.

  Moreover, as described in Patent Document 1 and Patent Document 2, a technique for preventing excessive heating has been developed by adjusting components constituting the cooking container. Moreover, as described in Patent Document 3, there is a technique for issuing a warning by measuring the temperature in the pan.

Japanese Patent Laid-Open No. 04-220988 Japanese Patent Laid-Open No. 04-242093 JP 2006-87890 A

  However, in the above technique, it is difficult to accurately measure the temperature of the cooking container, so that there is a problem that cooking of the dish and empty cooking of the pan cannot be prevented.

  Moreover, since the said technique cannot adjust the intensity | strength of a heat source at an appropriate timing, it cannot finish cooking well. That is, the above-described conventional techniques are not suitable for cooking that requires repeated monitoring such as cooking rice, baking pizza, paella, and fish. For example, if you cook rice in a pot of pottery or porcelain, you can cook delicious rice in a shorter time than an electric rice cooker, but the timing to stop the fire is manual. In addition, the current gas appliance (gas stove) has a function to stop the gas after the water is burnt out, such as when cooking, but with such a function, even if safety can be ensured, it will burn There is a problem that it becomes impossible to eat.

  Then, this invention aims at provision of the temperature control cooking container which can finish cooking appropriately by combining with the function of a heating cooker.

  In order to solve the above problems, a temperature-controlled cooking container according to the present invention includes a container body having a heat receiving bottom surface, and a shape that moves the container body in a direction away from the heat source when a predetermined temperature is reached. A temperature adjustment mechanism.

  According to the temperature adjustment cooking container which concerns on this invention, cooking can be finished appropriately by combining with the function of a heating cooker. In addition, inadvertent heating damage of the instrument and unnecessary waste of energy during heating can be prevented, and there is an advantage of being environmentally friendly.

It is the figure which showed the temperature control cooking container which concerns on 1st embodiment of this invention. It is the figure which showed the temperature control cooking container which concerns on 2nd embodiment of this invention. It is the figure which showed the temperature control cooking container which concerns on 3rd embodiment of this invention. It is the figure which showed the temperature control cooking container which concerns on 4th embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings.

<First embodiment>
Fig.1 (a) is the perspective view which showed the whole image of the temperature control cooking container 100 which concerns on 1st embodiment. 1B and 1C are cross-sectional views of the temperature adjustment cooking container 100. FIG. The temperature adjustment cooking container 100 includes a container main body 110, a temperature adjustment mechanism 120, and a sound generation mechanism 130. The container main body 110 has a heat receiving bottom surface 140 that is heated by the action from the heating cooker, and the temperature adjusting mechanism 120 is attached to the heat receiving bottom surface 140. In addition, a foodstuff is cooked in the container main body 110 with the heat transmitted from the heat receiving bottom face 140 heated.

  In the following description, an electromagnetic cooker using IH (Induction Heater) technology that is induction heating is used as a heating cooker. However, for example, a gas appliance (for example, a gas stove) may be used.

  The container main body 110 has an internal bottom surface 111 facing the inside of the container main body 110, and an internal space 112 in which an adjustment screw 121 described later is attached between the container main body 110 and the heat receiving bottom surface 140.

  The temperature adjustment mechanism 120 includes a heat receiving plate 122, an adjustment screw 121, a compression coil 123, and a metal plate material 124 formed from a bimetal or a shape memory alloy. The heat receiving plate 122 is formed in a tray shape that accommodates the heat receiving bottom surface 140 of the container body 110. Note that heat from the heat source is transmitted to the heat receiving bottom surface 140 via the heat receiving plate 122.

  The adjustment screw 121 is a member for connecting the container main body 110 and the heat receiving plate 122 while adjusting the size of the gap. One end of the adjustment screw 121 is accommodated in the internal space 112 of the container main body 110, and the other end is attached to face the heat source through a through hole formed in the heat receiving bottom surface 140 and the heat receiving plate 122.

  The compression coil 123 is disposed so as to be sandwiched between the bottom surface of the internal space 112 and the head of the adjustment screw 121. That is, when the container main body 110 moves upward, the compression coil 123 plays a role of pushing up the head of the adjustment screw 121 from below.

  The metal plate material 124 formed of bimetal or shape memory alloy has a through hole through which the adjusting screw 121 passes, and is disposed between the heat receiving plate 122 and the heat receiving bottom surface 140. Bimetal is a metal material in which a plurality of metal plates having different coefficients of thermal expansion are bonded to each other. Deformation characteristics in which one surface contracts and the other surface expands at a predetermined temperature (for example, 120 ° C.). Have Further, the shape memory alloy is a metal material having a characteristic of restoring a preset shape when a predetermined temperature (for example, 120 ° C.) is reached.

  The metal plate 124 is attached to the container body 110 in consideration of these deformation characteristics. For example, when a metal plate 124 made of bimetal is used, the heat receiving plate 122 is attached so that the side contracted at a predetermined temperature faces the heat receiving plate 122. Further, in the case of using the metal plate material 124 made of a shape memory alloy, the metal plate material 124 may be attached so that the side that returns to the bow shape at a predetermined temperature faces the heat receiving plate 122. In addition, since the metal plate 124 made of bimetal returns to the original plate shape when cooled (below a predetermined temperature), there is no gap between the heat receiving plate 122 and the heat receiving bottom surface 140, and the two come close again. Further, the metal plate 124 made of shape memory alloy returns to the original plate shape by pressing the container main body 110 downward in a cooled state (below a predetermined temperature), so that there is a gap between the heat receiving plate 122 and the heat receiving bottom surface 140. They disappear and they are close again. Further, it is desirable that a gap is not formed as much as possible between the heat receiving plate 122 and the heat receiving bottom surface 140 so that dirt and dust do not easily enter. Further, since the heat receiving plate 122 can be detached from the heat receiving bottom surface 140 by removing the adjusting screw 121, the heat receiving plate 122 and the heat receiving bottom surface 140 can be cleaned respectively.

  The sound generation mechanism 130 includes a drive detection sensor and a sound generator. The drive detection sensor has a detection arm 131, a switch 132, and a dial 133. The sound generator has a speaker that receives a sound signal (oscillation signal) from a controller (not shown) driven by a battery as a power source and outputs a predetermined sound such as a buzzer sound or a melody. . When the switch 132 is turned on, the controller outputs an audio signal to the speaker.

  The detection arm 131 is attached to the side surface of the heat receiving plate 122. Further, the switch 132 and the dial 133 are attached to the outside of the container main body 110.

  The detection arm 131 extends to a predetermined position near the switch 132. The switch 132 is formed to rotate in accordance with the rotation of the dial 133. The switch 132 is formed so as to be in an ON state or an OFF state when the tip of the detection arm 131 comes into contact. The dial 133 is for adjusting the contact position between the detection arm 131 and the switch 132. Note that the dial 133 may have a function of setting a time from when the detection arm 131 contacts the switch 132 until the sound is output, and has a sound switching function of changing the type of sound. Also good.

  FIG.1 (c) is the figure which showed the state in which the temperature adjustment cooking container 100 was heated with the heat source, and the temperature adjustment mechanism 120 reached predetermined temperature. When the temperature adjustment cooking container 100 is heated by the heat source and the temperature adjustment mechanism 120 reaches a predetermined temperature, the metal plate 124 warps into a bow shape due to the characteristics of the bimetal or shape memory alloy. At this time, the metal plate 124 pushes up the heat receiving bottom surface 140 of the container body 110 upward. That is, the temperature adjustment cooking container 100 moves in a direction away from the heat source. As a result, since a gap as an air layer is formed between the heat receiving plate 122 and the heat receiving bottom surface 140, the heating of the container body 110 is weakened.

  When the container body 110 is pushed upward with respect to the heat source, the detection arm 131 comes into contact with the switch 132, and the switch 132 of the sound generation mechanism 130 is turned on. As a result, a predetermined sound is output from the sound generation mechanism 130.

  Thus, according to the temperature control cooking container 100 which concerns on 1st embodiment of this invention, cooking can be finished appropriately by combining with the function of a heating cooker. Furthermore, since the temperature adjustment cooking container 100 according to the present embodiment includes the sound generation mechanism 130 that outputs a predetermined sound at the timing when the temperature adjustment mechanism 120 is operated, the timing at which the adjustment of the fire is automatically adjusted. The user can be notified.

  Next, the temperature adjustment cooking container which concerns on 2nd embodiment of this invention is demonstrated.

<Second embodiment>
Fig.2 (a) is sectional drawing of the temperature control cooking container 200 which concerns on 2nd embodiment. The temperature adjustment cooking container 200 includes a container main body 210, a temperature adjustment mechanism 220, and a sound generation mechanism 130. Since the sound generation mechanism is the same as that of the first embodiment described above, the same reference numerals are given and description thereof is omitted.

  The container body 210 has a heat receiving bottom surface 240 that is heated by the action from the heating cooker, and the temperature adjusting mechanism 220 is attached to the heat receiving bottom surface 240. The container main body 210 has an inner bottom surface 211 facing the inside of the container main body 210, and an inner space 212 in which an adjustment screw 222 described later is attached between the container main body 210 and the heat receiving bottom surface 240.

  The temperature adjustment mechanism 220 includes a heat receiving plate 221, an adjustment screw 222, a metal plate material 223 formed from a bimetal or a shape memory alloy, and a general torsion coil spring 224. The heat receiving plate 221, the adjusting screw 222, and the metal plate material 223 are the same as those in the first embodiment described above, and a description thereof will be omitted.

  The general torsion coil spring 224 has a coil part 225 and an arm part 226, and is a member used by receiving a torsional moment (torque) around the coil part 225. The general torsion coil spring 224 is formed of a predetermined metal material that does not have deformation characteristics such as a shape memory alloy or a bimetal.

  The arm portion 226 of the general torsion coil spring 224 is wound around the outer periphery of the stopper pin 227 provided on the side surface of the container body 210 and the heat receiving plate 221, and there is a gap between the heat receiving bottom surface 240 and the heat receiving plate 221 at low temperatures. Both are connected so that they are not formed. That is, the heat receiving bottom surface 240 and the heat receiving plate 221 are brought into close contact with each other by the torque from the arm portion 226 wound around the stop pin 227.

  FIG.2 (b) is the figure which showed the state which the temperature adjustment cooking container 200 was heated with the heating cooker which is a heat source, and the temperature adjustment mechanism 220 reached predetermined temperature. When the temperature adjustment cooking container 200 is heated by the heat source and the temperature adjustment mechanism 220 reaches a predetermined temperature, the metal plate 223 warps into a bow shape due to the characteristics of the bimetal or shape memory alloy. At this time, the metal plate member 223 pushes up the heat receiving bottom surface 240 of the container body 210 upward. That is, the temperature adjustment cooking container 200 moves in a direction away from the heat source. As a result, since a gap as an air layer is formed between the heat receiving plate 221 and the heat receiving bottom surface 240, the heating of the container body 210 is weakened.

  In addition, when the metal plate 223 warps in a bow shape, the arm portion 226 of the general torsion coil spring 224 is deformed so that the inner angle is greatly opened as the container body 210 moves away from the heat source. Further, when the heating of the container main body 210 is weakened and the distance between the container main body 210 and the heat source is reduced due to the metal plate member 223 being below a predetermined temperature, the inner angle of the general torsion coil spring 224 returns to the original size.

  When the container body 210 is pushed upward with respect to the heat source, the switch of the sound generating mechanism 130 is turned on. As a result, a predetermined sound is output from the sound generation mechanism 130.

  Thus, according to the temperature control cooking container 200 which concerns on 2nd embodiment of this invention, cooking can be finished appropriately by combining with the function of a heating cooker. Furthermore, in the temperature adjustment cooking container 200 according to the present embodiment, since a predetermined sound can be output at the timing when the temperature adjustment mechanism 220 is operated, the user is notified of the timing at which the heating / discharging is automatically adjusted. Can do.

  Next, the temperature control cooking container which concerns on 3rd embodiment of this invention is demonstrated.

<Third embodiment>
Fig.3 (a) is sectional drawing of the temperature control cooking container 300 which concerns on 3rd embodiment. The temperature adjustment cooking container 300 includes a container main body 310, a temperature adjustment mechanism 320, and a sound generation mechanism 130. The container main body 310 has a heat receiving bottom surface 330 that is heated by the action from the heating cooker. Since the sound generation mechanism is the same as that of the first embodiment described above, the same reference numerals are given and description thereof is omitted.

  The temperature adjustment mechanism 320 includes a heat receiving plate 321, a metal plate member 322, and a stop rivet 323 for attaching the metal plate member 322 to the container body 310 and the heat receiving plate 321. In addition, since it is the same as that of the heat receiving plate 321 and the above-mentioned 1st embodiment, description is abbreviate | omitted.

  The metal plate member 322 is a rectangular metal material formed from a bimetal or a shape memory alloy. The metal plate material 322 has a shape that is partially bent in a state below a predetermined temperature. One end of the metal plate material 322 is fixed to the container main body 310 by a stop rivet 323 and the other end is fixed to the heat receiving plate 321. At this time, the metal plate member 322 is attached to the container body 310 and the heat receiving plate 321 so that no gap is formed between the heat receiving bottom surface 330 and the heat receiving plate 321. The metal plate material 322 may be screwed to the container body 310 and the heat receiving plate 321 instead of the retaining rivet 323, or may be fitted and fixed to the container body 310 and the heat receiving plate 321. Moreover, since the heat receiving plate 321 can be detached from the heat receiving bottom surface 330 by removing the screwing or releasing the fitting, each of the heat receiving plate 320 and the heat receiving bottom surface 330 can be cleaned.

  FIG. 3B is a diagram showing a state in which the temperature adjustment cooking container 300 is heated by a heating cooker that is a heat source, and the temperature adjustment mechanism 320 has reached a predetermined temperature. When the temperature adjustment cooking container 300 is heated by the heat source and the temperature adjustment mechanism 320 reaches a predetermined temperature, the metal plate material 322 is deformed so that the flexure extends straight. At this time, since the container main body 310 is pushed upward by the deformed metal plate material 322, the heat receiving bottom surface 330 moves away from the heat receiving plate 321. As a result, since a gap as an air layer is formed between the heat receiving plate 321 and the heat receiving bottom surface 330, the heating of the container body 310 is weakened.

  In addition, when it becomes less than predetermined temperature, the metal plate material 322 will return to the original shape by the deformation | transformation specification of bimetal or a shape memory alloy. That is, it is deformed into a shape having some deflection. As a result, the heat receiving bottom surface 330 is again in close contact with the heat receiving plate 321 and the gap formed between the two is eliminated.

  When the container body 310 is pushed upward with respect to the heat source, the switch of the sound generating mechanism 130 is turned on. As a result, a predetermined sound is output from the sound generation mechanism 130.

  Thus, according to the temperature control cooking container 300 which concerns on 3rd embodiment of this invention, cooking can be finished appropriately by combining with the function of a heating cooker. Furthermore, in the temperature adjustment cooking container 300 according to the present embodiment, since a predetermined sound can be output at the timing when the temperature adjustment mechanism 320 is operated, the user is notified of the timing at which the heating / discharging is automatically adjusted. Can do.

  Next, the temperature adjustment cooking container which concerns on 4th embodiment of this invention is demonstrated.

<Fourth embodiment>
Fig.4 (a) is sectional drawing of the temperature control cooking container 400 which concerns on 4th embodiment. The temperature adjustment cooking container 400 includes a container main body 410, a temperature adjustment mechanism 420, and a sound generation mechanism 130. Note that the sound generation mechanism 130 is the same as that of the first embodiment described above, and thus the same reference numerals are given and description thereof is omitted.

  The container body 410 has a heat receiving bottom surface 440 that is heated by the action from the heating cooker. In addition, the container body 410 has an inner bottom surface 411 facing the inside of the container body 410, and has an inner space 412 in which an adjustment screw 412 described later is attached between the container body 410 and the heat receiving bottom surface 440.

  The temperature adjustment mechanism 420 includes a heat receiving plate 422, a stopper 430, an adjustment screw 421, and a compression coil 423. Note that the heat receiving plate 422, the adjusting screw 421, and the compression coil 423 are the same as those in the first embodiment described above, and thus the description thereof is omitted.

  The stopper 430 includes a hook member 431 and a hook member 432. The hook member 431 is a metal plate material formed from a bimetal or a shape memory alloy, and a hook 433 is formed on one end side thereof. Further, the hanging member 432 is a metal member having a concave portion 434 on one end side of which hooks are caught.

  The other end of the hook member 431 opposite to the one end on which the flange 433 is formed is fixed to the side surface of the container body 410. In addition, the other end of the hanging member 432 opposite to the one end where the recess is formed is fixed to the heat receiving plate 422.

  The hook member 431 and the hanging member 432 are attached to the container body 410 and the heat receiving plate 422 so that the heat receiving bottom surface 440 and the heat receiving plate 422 are in close contact with each other. That is, the stopper 430 is attached to the container body 410 and the heat receiving plate 422 so that no gap is formed between the heat receiving bottom surface 440 and the heat receiving plate 422 in a state where the flange 433 and the recess 434 are engaged with each other.

  The hook member 431 is attached to the container body 410 in consideration of the deformation characteristics of the bimetal or shape memory alloy. Specifically, when the temperature reaches a predetermined temperature, the hook member 431 is attached to the container main body 410 so as to move away from the concave portion 434 of the hanging member 432 by warping. Note that the hook 433 of the hook member 431 may be formed on the surface of the hook member 432 facing the recess 434.

  FIG. 4B is a view showing a state in which the temperature adjustment cooking container 400 is heated by a heating cooker that is a heat source, and the temperature adjustment mechanism 420 reaches a predetermined temperature. When the temperature adjustment cooking container 400 is heated by the heat source and the temperature adjustment mechanism 420 reaches a predetermined temperature, the hook member 431 warps away from the hanging member 432. Then, the flange 433 is removed from the concave portion 434, and the stopper 430 that has brought the container body 410 and the heat receiving plate 422 into close contact with each other without a gap is removed. At this time, the container main body 410 moves away from the heat receiving plate 422 by the elastic force of the compression coil 423. That is, when the stopper 430 is removed by heating, the heat receiving bottom surface 440 of the container body 410 moves in a direction away from the heat receiving plate 422 and the heat source. As a result, a gap as an air layer is formed between the heat receiving plate 422 and the heat receiving bottom surface 440, so that the heating of the container body 410 is weakened.

  When the temperature is lower than the predetermined temperature, the hook member 431 of the stopper 430 returns to the original shape by specifying the deformation of the bimetal or shape memory alloy. That is, the hook member 431 that has warped by heating returns to the original plate shape when the temperature becomes lower than a predetermined temperature. It should be noted that the force for again engaging the trough 433 with the recess 434 may be applied manually.

  When the container body 410 is pushed upward with respect to the heat source, the switch 132 of the sound generation mechanism 130 is turned on. As a result, a predetermined sound is output from the sound generation mechanism 130.

  Thus, according to the temperature control cooking container 400 which concerns on 4th embodiment of this invention, cooking can be finished appropriately by combining with the function of a heating cooker. Furthermore, in the temperature adjustment cooking container 400 according to the present embodiment, since a predetermined sound can be output at the timing when the temperature adjustment mechanism 420 is activated, the user is notified of the timing at which the heating is automatically adjusted. Can do.

  In the above-described embodiments and modifications, the switch 132 is turned on or off by the contact of the detection arm 131 when the container body is pushed upward. However, the present invention is not limited to these embodiments and modifications. It is not limited to examples. For example, the sound generation mechanism 130 may switch between an ON state and an OFF state of the switch according to the temperature in the container body detected using a temperature detection sensor or a thermocouple.

  Specifically, when the temperature in the container body detected by the temperature detection sensor or the thermocouple is equal to or higher than a predetermined temperature (for example, 120 ° C.) set with a dial, the sound generation mechanism 130 switches the switch 132. Is turned on, otherwise it is switched to the off state. According to such a sound generation mechanism 130, when the temperature in the container body reaches a predetermined temperature, the switch 132 is turned on and a predetermined sound or the like is output from the speaker. Further, when the temperature inside the container body becomes lower than the predetermined temperature, the switch 132 is turned off, and the sound output from the speaker stops sounding.

  In this way, it is possible to prevent problems such as no sound due to poor contact between the detection arm 131 and the switch 132 or the like.

  In addition, the sound generation mechanism 130 detects the temperature in the container body by using a bimetal or a shape memory alloy without using a temperature detection sensor or a thermocouple, and releases the spring that has been previously wound by the shape change. It may be configured.

  Specifically, a music box spring that plays a predetermined music is wound in advance, and the release of the spring is stopped by a latch formed of bimetal or shape memory alloy. Thereafter, the temperature-controlled cooking container is heated, so that the latch of the bimetal or shape memory alloy is deformed, the spring is released, and the music of the music box is played.

  Note that the temperature at which the mainspring is released may be set as appropriate, such as the temperature transmitted from the container main body 136 at the timing when the temperature adjusting mechanism operates.

  In the above-described embodiment and modification, the heating intensity is adjusted by the function of the temperature adjustment mechanism, but the present invention is not limited to these embodiment and modification. For example, the cooking temperature may be adjusted more appropriately using a temperature-adjusted cooking container (including a container body and a heat receiving plate) formed from a magnetic metal material having a predetermined Curie temperature (for example, 120 ° C.). . The components of the magnetic metal material and the blending ratio thereof may be appropriately designed so as to achieve a desired Curie temperature.

  According to such a temperature control cooking container, cooking can be finished more appropriately by combining with the function of the heating cooker. In particular, when a temperature-controlled cooking container having such a Curie temperature is used, more delicate temperature adjustment can be made, and accidents caused by malfunctions or design errors can be prevented. Safety in the area can be ensured.

100 ... Temperature-controlled cooking container according to the first embodiment,
110 ... Container body according to the first embodiment, 120 ... Temperature adjustment mechanism,
130 ... sound generating mechanism, 140 ... heat receiving bottom surface

Claims (10)

A container body having a heat receiving plate heated on the heat source and a heat receiving bottom surface disposed on the heat receiving plate;
When a predetermined temperature is reached, a temperature adjustment mechanism having a shape that forms a gap between the heat receiving plate and the container body;
A temperature-regulated cooking container comprising: It is the temperature control cooking container of Claim 1, Comprising:
The temperature adjustment mechanism is
A temperature-controlled cooking container comprising a shape that moves the container body by a restoring force of a leaf spring, a coil spring, or a torsion spring. It is the temperature control cooking container of Claim 1, Comprising:
The temperature adjustment mechanism is
A temperature-controlled cooking container comprising a shape for moving the container body by a shape memory alloy or bimetal shape change. The temperature-controlled cooking container according to claim 2,
The temperature adjustment mechanism is
A temperature-controlled cooking container comprising a shape in which the return of the leaf spring, the coil spring, or the torsion spring is started when the shape memory alloy or bimetal changes in form. It is the temperature control cooking container as described in any one of Claims 1-4,
A temperature detection sensor or thermocouple for detecting the temperature in the container body;
A switch that switches between on and off in the temperature detection by the temperature detection sensor or thermocouple;
A temperature-regulating cooking container, comprising: a sound generating mechanism having a sound generator that outputs a predetermined sound or sound when the switch is turned on. It is the temperature control cooking container as described in any one of Claims 1-4,
A drive detection sensor for detecting the drive of the temperature adjustment mechanism;
A temperature-regulating cooking container, comprising: a sound generation mechanism having a sound generator that outputs a predetermined sound or sound by driving the drive detection sensor. It is the temperature control cooking container of Claim 6, Comprising:
The drive detection sensor is
A detection arm attached to the heat receiving plate;
A switch that is attached to the container body and that is switched on and off by contact of the detection arm;
The sound generator is
A voice-controlled cooking container that outputs a predetermined sound or voice when the switch is turned on. It is the temperature control cooking container as described in any one of Claims 5-7,
The temperature-controlled cooking container, wherein the sound generator is a speaker. It is the temperature control cooking container as described in any one of Claims 1-4,
It has a sound generation mechanism composed of a music box that plays predetermined music by driving the mainspring.
The spring is
The release is stopped by a latch formed of shape memory alloy or bimetal in a state below a predetermined temperature,
A temperature-controlled cooking container, wherein the latch is released when the latch reaches a predetermined temperature. It is the temperature control cooking container as described in any one of Claims 1-9,
At least one of the container main body and the heat receiving plate is formed of a magnetic metal material having a predetermined Curie temperature.

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