JP6719821B2 - Gas stove - Google Patents

Description

The present invention relates to a gas stove, and more particularly to a gas stove including a temperature detection device that detects the temperature of a cooking container such as a pan or a pot.

There is a gas stove that includes a temperature detection device that detects the temperature of a cooking container such as a pot or a kettle, and a control device that controls the heating power of the stove burner based on the detected temperature of the cooking container.

As such a gas stove, Patent Document 1 discloses a heating cooker (gas stove) provided with a temperature detecting means (temperature detecting device) for detecting the temperature of the cooker and a control means for adjusting heat power. The contacting body (heat collecting plate) of the temperature detecting means contacts the lower surface of the cooking container heated by the stove burner as a means to detect the temperature of the lower surface of the cooking container, and controls according to the detected temperature. A heating cooker (gas stove) has been proposed, the means of which controls the heating power of the stove burner.

According to the gas stove of Patent Document 1, it is possible to determine whether or not the first temperature sensor is in contact with the lower surface of the cooking container. For example, when the first temperature sensor is not in contact with the lower surface of the cooking container, Since it is not possible to detect the temperature, control such as stopping combustion is possible, which is significant.

JP, 2013-164257, A

However, in the case of the above-described heating cooker (gas stove) of Patent Document 1, the contact body (heat collecting plate) of the temperature detecting means (temperature detecting device) mounts the cooking container in a state where the cooking container is not mounted. It will be in a state of protruding above the upper end of Gotoku.

In that case, when the cooking container is moved from one of the five virtues to the other one, or the cooking container is once evacuated from the other and then returned to the other virtue. In addition, the temperature detecting means protruding above the upper end of Gotoku sometimes obstructs the movement of the cooking container, which is not convenient.

The present invention is to solve the above problems, and a temperature detecting device for detecting the temperature of a cooking container does not hinder the movement of the cooking container in Gotoku, and is a gas stove that is easy to use. The purpose is to provide.

In order to achieve the above object, the gas stove of the present invention,
A stove burner that heats a cooking container, a virtue on which the cooking container is placed, a temperature detection device that is inserted into a through hole that vertically penetrates the stove to detect the temperature of the cooking container, and the stove A gas stove comprising a control means for controlling the burner heat power,
The temperature detecting device includes (a) a fixed-side support member, one end side of which is fixed to a predetermined fixing portion provided on the gas stove, and the other end side of the one end side is arranged to extend vertically. A movable side support cylinder supported by the fixed side support member and configured to be movable up and down with respect to the fixed side support member; and (c) an upper end of the movable side support cylinder, which is disposed above and below the cooking container. A contact body configured to come into contact with the bottom surface of the cooking container by vertically moving following the movement; and (d) a lower surface side of the contact body, which is thermally coupled with the contact body. And a thermistor arranged in a manner
A permanent magnet having magnetic poles arranged in a predetermined direction is arranged on the moving side support cylinder,
Magnetic sensors for detecting magnetic flux from the permanent magnets are arranged in a plurality of stages at predetermined intervals in the vertical direction of the fixed-side support member,
Electromagnetic coils that generate magnetic force by energization are arranged in a plurality of stages at predetermined intervals in the vertical direction of the fixed-side support member in such a manner that a vertical positional relationship is generated with respect to the magnetic sensor.
The control means, when one magnetic sensor of the plurality of magnetic sensors arranged in the vertical direction detects a predetermined magnetic flux, (a) an upper electromagnetic field adjacent to the one magnetic sensor in the upper direction. The coil is energized so as to have a polarity that causes an attractive force between the permanent magnet and the permanent magnet, and (b) the permanent magnet and the repulsive force are applied to the lower electromagnetic coil adjacent to the lower side of the one magnetic sensor. It is characterized in that it is configured to execute an ascending control for ascending the moving-side support cylinder via the permanent magnets by energizing so as to have a polarity that causes.

In the gas stove of the present invention, a point extinguishing operation unit for instructing point extinguishing to the stove burner is provided, and the control means executes the ascending control by issuing an ignition command by the point extinguishing operation unit, and the point extinguishing operation. It is preferable that the control means is configured to terminate the execution of the ascending control when a fire extinguishing command is issued by the section.

Further, a power switch for switching between energization and de-energization of the control means is provided, and the control means executes the ascending control by energization of the control means by operating the power switch, and the power switch is operated by the operation of the power switch. It is preferable that the control means is configured to terminate the execution of the ascending control by cutting off the power supply to the control means.

Further, it is preferable that the permanent magnet is arranged on a lower end side of the moving side support cylinder, and the magnetic sensor and the electromagnetic coil are arranged on a lower end side of the fixed side support member.

Further, the permanent magnet is composed of a plurality of individual permanent magnets arranged at the same vertical position with a central axis extending in the vertical direction of the moving side support cylinder interposed therebetween,
The magnetic sensor is composed of a plurality of individual magnetic sensors arranged at the same vertical position with a central axis extending in the vertical direction of the fixed side support member interposed therebetween,
It is preferable that the electromagnetic coil includes a plurality of individual electromagnetic coils arranged at the same vertical position with a central axis of the fixed-side support member extending in the vertical direction interposed therebetween.

Further, when the control means executes the ascending control, the control means determines whether or not the cooking container is placed on the Gotoku according to the output of the magnetic sensor. When it is determined that the cooking container is not placed on the cooking container, it is preferable that the cooking stove is not ignited.

In the gas stove of the present invention, as described above, when one magnetic sensor (one-stage magnetic sensor) of the magnetic sensors of a plurality of stages arranged in the vertical direction detects a predetermined magnetic flux, (A) Energize the upper electromagnetic coil, which is the electromagnetic coil of the next adjacent stage in the upward direction of the one magnetic sensor (one-stage magnetic sensor), so as to have a polarity that generates an attractive force between the permanent magnet and ( b) The permanent magnet is energized so that the lower electromagnetic coil, which is the electromagnetic coil of the next adjacent stage in the downward direction of the one magnetic sensor (one-stage magnetic sensor), is energized so as to generate a repulsive force with the permanent magnet. It is configured to execute the raising control for raising the moving side support cylinder via the.

Therefore, in the lowered state of the temperature detection device in which the control means does not execute the above-described rise control, the temperature detection device does not interfere when moving the cooking container in Gotoku.

Moreover, in the raised state of the temperature detecting device in which the control means has performed the raising control, when the cooking container is placed on Gotoku, the contact body moves up and down following the vertical position of the lower surface of the cooking container. The temperature of the cooking container can be properly detected by the temperature detection device.

Further, the attraction force and the repulsive force generated between the permanent magnet and the electromagnetic coil due to the energization act as an urging force that urges the moving-side support cylinder upward, so that the moving-side support cylinder moves upward. Since a separate biasing means such as a biasing spring is not required, the structure can be simplified.

Further, the fire extinguisher operation unit for instructing the fire extinguishing to the stove burner is provided, the control means executes the ascending control by the ignition command issued by the fire extinguisher operation unit, and the control means is activated by the extinction command issued by the fire extinguishing operation unit. When configured to terminate the execution of the ascending control, the ascending state and the descending state are switched by the point extinguishing operation of the point extinguishing operation unit, so that it is possible to provide a gas stove with good usability.

Further, a power switch for switching between energization and de-energization of the control means is provided, and the control means executes an ascending control by energization of the control means by operating the power switch, and cuts off energization of the control means by operating the power switch. When the control means is configured to terminate the execution of the ascending control, the power switch is operated to switch between the ascending state and the descending state by energizing and de-energizing the controlling means, thereby providing a gas stove with good usability. It becomes possible to do.

Also, a permanent magnet is arranged on the lower end side of the moving side support cylinder (a position lower than the center), and a magnetic sensor and an electromagnetic coil are arranged on the lower end side of the fixed side support member (a position lower than the center). When it is installed, it is possible to suppress the thermal influence on the permanent magnets and the electromagnetic coil due to the heating of the stove burner, and improve the reliability.

Further, the permanent magnet is composed of a plurality of individual permanent magnets arranged at the same vertical position with the central axis extending in the vertical direction of the moving side support cylinder interposed therebetween, and the magnetic sensor extends in the vertical direction of the fixed side support member. A plurality of individual magnetic sensors are arranged at the same vertical position across the central axis, and a plurality of electromagnetic coils are arranged at the same vertical position across the central axis of the fixed-side support member extending in the vertical direction. In the case of being configured by the individual electromagnetic coil, the moving-side support cylinder can be more smoothly moved and biased upward during execution of the ascending control, and the present invention can be more effectively presented. ..

Also, when the control means executes the ascending control, the control means determines whether or not the cooking container is placed on the Gotoku according to the output of the magnetic sensor, and the cooking container is placed on the Gotoku. If it is determined that the heating is not performed, the user does not ignite the stove burner so that the flame of the stove burner is ignited when the cooking container is not placed on Gotoku. It is possible to provide a gas stove that is easy to use and that can suppress surprises.

It is a perspective view showing the appearance composition of the gas stove concerning one embodiment of the present invention. FIG. 3 is a side view showing a main configuration of a gas stove according to an embodiment of the present invention in a non-execution state of rising control of the temperature detection device (that is, a lowered state of the temperature detection device). It is a side view showing the important section composition of the gas stove concerning one embodiment of the present invention in the installed state which put the cooking container on Gotoku when the rise control of the temperature detecting device was performed. A side view showing a main part configuration of a gas stove according to an embodiment of the present invention in a state in which a cooking container is not placed on the Gotoku (that is, a rising state of the temperature detection device) at the time of execution of rise control of the temperature detection device It is a figure. It is a figure which shows the flowchart of the raising/lowering control subroutine of the temperature detection apparatus of the gas stove concerning one Embodiment of this invention.

[Embodiment]
Hereinafter, an embodiment of the present invention will be shown, and features of the embodiment will be described in more detail.

<Basic structure of gas stove>
FIG. 1 is a diagram showing an external configuration of a gas stove (in this embodiment, a gas stove with a grill (drop-in stove)) including a temperature detecting device according to an embodiment of the present invention.

As shown in FIG. 1, a gas stove A (hereinafter, also simply referred to as a gas stove) A equipped with the temperature detecting device of this embodiment has three standard stoves, a standard burner 1a, a high-power burner 1b, and a small burner 1c. It is equipped with a burner (heating unit), and at the upper part of the top plate, there is a Gotoku 51 for receiving and supporting an object to be heated (food) such as a pan for the standard burner 1a, the high thermal power burner 1b, and the small burner 1c. It has been placed.

Then, the standard burner (stove burner) 1a is provided with a temperature detection device (temperature sensor) 9 including a thermistor 14 for detecting the temperature of an object to be heated (for example, the bottom of a pan which is a cooking container). The standard burner 1a is inserted through a through-hole 2 (see FIGS. 2 to 4) that penetrates the standard burner 1a in the vertical direction so as to pass through the center of the standard burner 1a. The standard burner 1a provided with the temperature detecting device 9 can perform temperature controlled cooking such as rice cooking, boiling water, and fried food.

In addition, the grill portion 4 is configured by providing a grill that functions as a placing portion for placing an object to be cooked such as a fish in a box-shaped grill cabinet having an open front surface. .. In addition, one upper burner (not shown) and two lower burners (not shown) are provided as heating units in the grill cabinet.

Further, on the front surface (front side surface) of the gas stove A, there is provided a manual operation unit 34 for instructing ignition and extinction of the above-described stove burner and grill burner, thermal power adjustment and various settings.

The gas stove A also includes control means (not shown) configured to execute various controls. The control means is configured to control the combustion state of the stove burner and the grill burner based on the command information commanded by the manual operation unit 34.
Further, on the front surface of the gas stove A, there are provided a power switch 24 and a power lamp 25 of an automatic resetting type, and each time the power switch 24 is pushed, the control means is switched on and off. It is configured to be.

The manual operation part 34 is a three-point fire extinguishing operation part (heating state) for instructing each of the burners (standard burner 1a, high heat power burner 1b, small burner 1c) to perform ignition/fire suppression and heat power adjustment separately. Control unit 21 (21a, 21b, 21c), standard burner 1a temperature control function (boiling water, fried food, rice cooker) and additional function operation/display unit 32 for standard burner for operating and displaying timer function, grill burner ( In particular, a grill burner operation unit 22 for adjusting the heat power of an upper burner and a lower burner (not shown) and an additional function operation/display unit 33 for the grill for instructing switching of the operating state of the grill burner are provided.

<Characteristic structure>
Next, a characteristic configuration of the gas stove A according to the embodiment of the present invention will be described.

In the gas stove A according to the embodiment of the present invention, the temperature detecting device 9 used for the standard burner (stove burner) 1a is, as shown in FIGS. 2 to 4, (a) one end side 11a is provided on the gas stove A. Fixed side support member 11 fixed to the fixed part 61 and arranged so that the other end side 11b with respect to the one end side 11a extends in the vertical direction, and (b) the fixed side support member 11 supports the fixed side support member 11. The movable side support cylinder 12 configured to be movable up and down with respect to 11 and (c) the movable side support cylinder 12 is disposed at the upper end of the movable side support cylinder 12 and moves up and down in accordance with the vertical movement of the cooking container 40 to perform cooking. An abutting body 13 configured to abut the bottom surface of the container 40, and (d) a thermistor 14 disposed on the lower surface side of the abutting body 13 so as to be thermally coupled to the abutting body 13. I have it.

The thermistor 14 is connected to a control means (not shown) by a lead wire, but the lead wire is not shown in FIGS. 2 to 4.

In this embodiment, the N pole is located in a direction away from a vertically extending central axis (not shown) of the moving-side support cylinder 12, and the S pole is arranged in a direction approaching the central axis (not shown). 15 is arranged in the moving side support cylinder 12. The permanent magnet 15 is composed of a left permanent magnet (individual permanent magnet) 15a, which is an individual permanent magnet, and a right permanent magnet (individual permanent magnet) 15b, as described below.
The left permanent magnet (individual permanent magnet) 15a and the right permanent magnet (individual permanent magnet) 15b are paired with each other with a central axis (not shown) extending in the up-down direction of the moving-side support cylinder 12 interposed therebetween. It is arranged as follows.

Further, in the gas stove A of this embodiment, as shown in FIGS. 2 to 4, the N pole is located on the left side of the left permanent magnet (individual permanent magnet) 15a forming the permanent magnet 15, and the S pole is located on the right side. In addition, the N pole is located on the right side of the right permanent magnet (individual permanent magnet) 15b, and the S pole is located on the left side.
The left permanent magnet 15a and the right permanent magnet 15b are arranged on the lower end side of the moving-side support cylinder 12 (position below the central portion).

Further, the fixed side support member 11 is provided with magnetic sensors 170 (170(I), 170(II)) that detect magnetic flux from the permanent magnets 15 (15a, 15b) at predetermined intervals in the vertical direction. , Are arranged in a plurality of stages (two stages in this embodiment) at predetermined intervals. In this embodiment, Hall elements are used as the individual magnetic sensors 17a and 17b that form the magnetic sensor 170.

Specifically, in the gas stove A of this embodiment, two left magnetic sensors (individual magnetic sensors) are arranged so as to form a pair with the central axis (not shown) of the fixed-side support member 11 extending vertically. Sensor) 17a ₁ and right magnetic sensor (individual magnetic sensor) 17b ₁ and the first-stage magnetic sensor 170(I), and a pair of two magnetic sensors 170(I) sandwiching a central axis (not shown). A second magnetic sensor 170 (II) including a left magnetic sensor (individual magnetic sensor) 17a ₂ and a right magnetic sensor (individual magnetic sensor) 17b ₂ and two magnetic sensors 170 (II) are vertically arranged at a predetermined interval in two steps. Has been done.

Further, the fixed side support member 11 has the electromagnetic coils 160 (160(I), 160(II), 160(III)) that generate a magnetic force when energized by the above-mentioned magnetic sensors 170 (170(I), 170(II). )), the fixed-side support member 11 is arranged in a plurality of stages (three stages in this embodiment) at predetermined intervals in the vertical direction.

Specifically, as the electromagnetic coils 160 (160(I), 160(II), 160(III)), a pair of two is sandwiched with a central axis (not shown) extending in the vertical direction of the fixed-side support member 11 interposed therebetween. A _first- stage electromagnetic coil 160(I) composed of a left electromagnetic coil (individual electromagnetic coil) 16a ₁ and a right electromagnetic coil (individual electromagnetic coil) 16b ₁ arranged in such a manner that a central axis (not shown) is also provided. A second-stage electromagnetic coil 160 (II) consisting of a left electromagnetic coil (individual electromagnetic coil) 16a ₂ and a right electromagnetic coil (individual electromagnetic coil) 16b ₂ which are arranged so as to form a pair, and two A third-stage electromagnetic coil 160 (III) including a left electromagnetic coil (individual electromagnetic coil) 16a ₃ and a right electromagnetic coil (individual electromagnetic coil) 16b ₃ arranged so as to form a pair has a predetermined interval in the vertical direction. It is arranged in three steps.

More specifically, the electromagnetic coil 160(I) of the first stage is arranged below the magnetic sensor 170(I) of the first stage, and the electromagnetic coil 160(II) of the second stage is the magnetic sensor 170(I of the first stage. ) Is arranged above.
The third-stage electromagnetic coil 160(III) is arranged on the second-stage magnetic sensor 170(II) located on the second-stage electromagnetic coil 160(II).

The first-stage electromagnetic coil 160(I), the second-stage electromagnetic coil 160(II), and the third-stage electromagnetic coil 160(III) are located on the lower end side of the fixed-side support member 11 (below the central portion). Position).

In the gas stove according to this embodiment, when one of the magnetic sensors 170(I) and 170(II) arranged in the vertical direction detects a predetermined magnetic flux, (a) The electromagnetic coils (upper electromagnetic coil) that are adjacent to each other in the upward direction of the one magnetic sensor are energized so as to have a polarity that generates an attractive force with the permanent magnet 15, and (b) in the downward direction of the magnetic sensor. By conducting electricity to the adjacent electromagnetic coils (lower electromagnetic coils) so that the permanent magnet 15 and the repulsive force are generated so that the moving-side support cylinder 12 is lifted via the permanent magnets 15, a rising control is executed. Is configured.

In the gas stove A of this embodiment, the control means executes the ascending control by issuing an ignition command by the point extinguishing operation unit 21a that issues an instruction to extinguish the point fire to the standard burner (stove burner) 1a. When the fire extinguishing command is issued by the control means, the control means ends the execution of the rising control.

Then, for example, in the state of FIG. 2, when the control unit executes the ascending control, the control unit faces the first-stage left magnetic sensor (individual magnetic sensor) 17a ₁ forming the first-stage magnetic sensor 170(I), The N pole on the left side of the left permanent magnet 15a is located, and by detecting the magnetic flux of 10 mT or more by the left magnetic sensor 17a ₁ in the first stage, a polarity that repels the N pole on the left side of the left permanent magnet 15a is generated. such that (i.e., as right first stage of the left electromagnetic coil 16a ₁ constituting an electromagnetic coil 160 (I) of the first stage in FIG. 2 is an N pole), it left electromagnetic coil 16a ₁ (under the first stage Side electromagnetic coil), and the right side of the second-stage left electromagnetic coil 16a ₂ constituting the second-stage electromagnetic coil 160(II) becomes the S pole (that is, the left permanent magnet 15a The second-stage left electromagnetic coil (upper electromagnetic coil) 16a ₂ is energized so that the N-pole has a polarity that produces an attractive force.

Further, when the control means executes the ascending control in the state of FIG. 2, the right permanent magnet is arranged so as to face the _first- stage right magnetic sensor (individual magnetic sensor) 17b ₁ that constitutes the first-stage magnetic sensor 170(I). Since the N pole on the right side of the magnet 15b is located and the right magnetic sensor 17b ₁ of the first stage detects a magnetic flux of 10 mT or more, the polarity is such that a repulsive force is generated with respect to the N pole on the right side of the right permanent magnet 15b. (That is, so that the left side of the first-stage right electromagnetic coil 16b ₁ configuring the first-stage electromagnetic coil 160(I) in FIG. 2 becomes the N pole), the first-stage right electromagnetic coil (lower electromagnetic coil) 16b ₁ is energized, and the left side of the second-stage right electromagnetic coil 16b ₂ forming the second-stage electromagnetic coil 160(II) becomes the S pole (that is, the N pole on the right side of the right permanent magnet 15b). The second right electromagnetic coil (upper electromagnetic coil) 16b ₂ is energized so that it has a polarity that produces a suction force.

As a result, the moving-side support cylinder 12 is urged upward, and the moving-side support cylinder 12 rises.

Further, in the case where the cooking container 40 is placed on the Gotoku 51, as shown in FIG. 3, when the control means performs the ascending control, the abutment body 13 at the upper end of the moving-side support cylinder 12 is attached to the cooking container 40. The moving-side support cylinder 12 moves up to a position where it abuts on the bottom surface.

Even in the state of FIG. 3, the control means continues the execution of the ascending control so as to face the second-stage left magnetic sensor 17a ₂ forming the second-stage magnetic sensor 170(II) so as to face the left permanent magnet 15a. The N pole on the left side of is located, and the second-stage left magnetic sensor 17a ₂ detects a magnetic flux of 10 mT or more, so that the N pole on the left side of the left permanent magnet 15a has a polarity that produces a repulsive force. (That is, the right side of the second-stage left electromagnetic coil 16a ₂ forming the second-stage electromagnetic coil 160(II) in FIG. 2 has the N pole), and the second-stage left electromagnetic coil 16a ₂ is energized. In addition, the right side of the third-stage left electromagnetic (lower electromagnetic coil) coil 16a ₃ forming the third-stage electromagnetic coil 160(III) becomes the S pole (that is, the left permanent magnet 15a has the left side of the left permanent magnet 15a). The left-side electromagnetic coil (upper-side electromagnetic coil) 16a ₃ in the third stage is energized so that the N-pole has a polarity that produces an attractive force.

Further, in the state of FIG. 3, the N pole on the right side of the right permanent magnet 15b is located so as to face the second-stage right magnetic sensor 17a ₂ that constitutes the second-stage magnetic sensor 170(II). The right magnetic sensor 17b ₂ detects the magnetic flux of 10 mT or more so that the right magnetic sensor 17b ₂ has a polarity that produces a repulsive force to the N pole on the right side of the right permanent magnet 15b (that is, the second-stage electromagnetic coil in FIG. 3). 160 (II) so that the left side of the second-stage right electromagnetic coil 16b ₂ becomes the N pole), the second-stage right electromagnetic coil (lower electromagnetic coil) 16b ₂ is energized, and the third-stage So that the left side of the third-stage right electromagnetic coil 16b ₃ constituting the electromagnetic coil 160(III) of FIG. 3 has an S pole (that is, has a polarity that produces an attractive force to the N pole of the right side of the right permanent magnet 15b). As described above), the third stage right electromagnetic coil (upper electromagnetic coil) 16b ₃ is energized.

As a result, the moving-side support cylinder 12 is biased in the upward direction, and proper contact between the contact body 13 and the bottom surface of the cooking container 40 is maintained.

The gas stove A of this embodiment is configured as described above, and when the temperature detecting device 9 in which the control means does not perform the raising control is in the lowered state, the temperature detecting device is moved when the cooking container 40 is moved on the Gotoku 51. 9 will not get in the way.

Moreover, in the raised state of the temperature detecting device 9 in which the control means has performed the raising control, the contact body 13 follows the vertical position of the lower surface of the cooking container 40 when the cooking container 40 is placed on the Gotoku 51. The temperature of the cooking container 40 can be properly detected by the temperature detecting device 9.

Further, the attractive force and the repulsive force generated between the permanent magnet 15 and the electromagnetic coil 160 (160(I), 160(II), 160(III)) by energization cause the moving-side support cylinder 12 to face upward. Since it acts as an urging force for urging, a separate urging means such as a spring for urging the moving-side support cylinder 12 upward is not required, and the structure is simplified.

Further, in the gas stove A according to this embodiment, as described above, the control unit executes the ascending control by the ignition command issued by the point extinguishing operation unit 21a, and the control unit operates by the extinguishment command issued by the point extinguishing operation unit 21a. Since the execution of the rising control is terminated, a gas stove with good usability in which the temperature detecting device can be reliably switched between the raised state and the lowered state by the point fire extinguishing operation of the point fire extinguishing operation part 21a. You can

Next, the operation when the temperature detecting device 9 is switched between the lowered state and the raised state will be described in detail with reference to the flowchart of the temperature control device raising/lowering control subroutine shown in FIG.

First, in step #001, it is determined whether or not an ignition operation by the fire extinguishing operation unit 21a is performed.

When it is determined in step #001 that the ignition operation by the fire extinguishing operation part 21a has been performed (the state has changed from the extinguishing state to the ignition state), the process proceeds to step #002, and the control means performs the above-described raising control. And then return.

On the other hand, if it is determined in step #001 that the ignition operation by the fire extinguishing operation unit 21a is not performed (the state does not change from the fire extinguishing state to the ignition state), the process proceeds to step #003 and the point extinguishing operation unit is performed. The presence or absence of the fire extinguishing operation (change of the state from the ignition state to the fire extinguishing state) by 21a is determined.

Then, if it is determined in step #003 that the fire extinguishing operation by the point fire extinguishing operation unit 21a has been performed (the state has changed from the ignition state to the fire extinguishing state), the execution of the rising control is stopped in step #004. Then, the electromagnetic coil 160 (160(I), 160(II), 160(III)) is deenergized, and the routine is repeated.

On the other hand, when it is determined in step #003 that the fire extinguishing operation by the point fire extinguishing operation unit 21a is not performed (the state does not change from the ignition state to the fire extinguishing state), the process directly returns.

As described above, in the gas stove A of this embodiment, the control means executes the rising control in response to the ignition command issued by the point extinguishing operation part 21a, and the temperature detecting device 9 is switched to the rising state which is the rising state. When the fire extinguishing command is issued by the fire extinguishing operation unit 21a, the execution of the ascending control is terminated, and the temperature detecting device 9 is switched to the descending state, which is the descending state. When the execution of the rising control is completed, the moving-side support cylinder 12 is lowered by its own weight, and the temperature detection device 9 is in the lowered state. As described above, in the gas stove A of this embodiment, the temperature detecting device 9 is configured to be switched between the raised state and the lowered state by the point fire extinguishing operation of the point fire extinguishing operation unit 21a, so that a gas stove with good usability can be obtained. Can be realized.

Further, in the case of the gas stove A of this embodiment, as described above, the left permanent magnet 15a and the right permanent magnet 15b are arranged on the lower end side of the moving-side support cylinder 12 (position lower than the central portion), Further, the first-stage magnetic sensor 170(I), the second-stage magnetic sensor 170(II), the first-stage electromagnetic coil 160(I), the second-stage electromagnetic coil 160(II), and the third-stage magnetic coil 170(II). Since the electromagnetic coil 160 (III) is disposed on the lower end side (position lower than the central portion) of the fixed-side support member 11 (FIGS. 2, 3 and 4), the standard burner (stove burner) 1a is provided. The permanent magnet 15 (15a, 15b) by heating, the first-stage magnetic sensor 170(I), the second-stage magnetic sensor 170(II), the first-stage electromagnetic coil 160(I), the second-stage electromagnetic coil 160. (II) It is possible to improve the reliability by avoiding the thermal influence on the electromagnetic coil 160(III) of the third stage.

However, the permanent magnet is arranged on the lower end side of the moving side support cylinder, and the magnetic sensor and the electromagnetic electromagnetic coil are arranged on the lower end side of the fixed side support member, and the permanent magnet is on the moving side. The magnetic sensor and the electromagnetic coil may be disposed at positions other than the lower portion of the support cylinder, and may be disposed at positions other than the lower portion of the fixed-side support member.

Further, in the gas stove A of this embodiment, the left permanent magnet 15a and the right permanent magnet 15b forming the permanent magnet 15 are arranged with a central axis (not shown) extending in the up-down direction of the moving side support cylinder 12 interposed therebetween. Further, a pair of left and right electromagnetic sensors 170(I) and 170(II) of the first and second stages are arranged at the same vertical position with the central axis of the fixed-side support member extending vertically. Each of the first-stage, second-stage, and third-stage electromagnetic coils 160(I), 160(II), and 160(III), which are formed of (individual electromagnetic sensors), are attached to the fixed-side support member 11. A configuration in which a pair of left and right electromagnetic coils (individual electromagnetic coils) arranged with a central axis (not shown) extending in the vertical direction sandwiched therebetween is formed, and the electromagnetic coils are arranged in three stages in the vertical direction. Therefore, it is possible to smoothly move the moving-side support cylinder 12 and urge the moving-side support cylinder 12 upward during the execution of the rising control, and perform the rising control with high reliability. be able to.

However, the permanent magnet, the magnetic sensor, and the electromagnetic coil may be configured by a single permanent magnet, a magnetic sensor, and an electromagnetic coil, instead of the pair of two permanent magnets, the magnetic sensor, and the electromagnetic coil. It is also possible to employ a configuration including a plurality of permanent magnets, one or more, a magnetic sensor, and an electromagnetic coil.
Further, there is no particular limitation on the number of steps of disposing the electromagnetic coil 160 and the magnetic sensor 170, and the number of steps different from this embodiment can be adopted.

Further, when the cooking container 40 is placed on the Gotoku 51, as shown in FIG. 3, when the control means performs the raising control, the contact body 13 moves to the position where it comes into contact with the bottom surface of the cooking container 40. When the support cylinder 12 rises, but the cooking container 40 is not placed on the Gotoku 51, as shown in FIG. 4, when the control means performs the raising control, the contact body 13 moves beyond the upper end of the Gotoku 51. The moving-side support cylinder 12 moves up.

At this time, the N pole of the left permanent magnet 15a is located in front of the left magnetic sensor 17a ₂ of the second-stage magnetic sensor 170(II), and the N pole of the right permanent magnet 15b is the second-stage magnetic sensor 170(II). ) Located right in front of the right magnetic sensor 17b ₂ .

Therefore, the magnetic flux detected by the second-stage left magnetic sensor 17a ₂ and the second-stage right magnetic sensor 17b ₂ of the second-stage magnetic sensor 170(II) is 50 mT or more.

Then, in the gas stove A of this embodiment, when the magnetic flux detected by the second-stage left magnetic sensor 17a ₂ and the second-stage right magnetic sensor 17b ₂ is 50 mT or more when the control means executes the ascending control, The left burner 1a is configured not to ignite even when it is determined that the cooking container 40 is not placed on the Gotoku 51 and an ignition command is issued by the point extinguishing operation unit 21a.

As a result, it becomes possible to suppress and prevent the user from being surprised by the flame of the left burner 1a ignited when the cooking container 40 is not placed on the Gotoku 51.

In the present embodiment, when the magnetic flux detected by the left magnetic sensor 17a ₂ and the second right magnetic sensor 17b ₂ is less than 50 mT when the control means executes the ascending control, the cooking container 40 is placed in the Gotoku 51. It is configured that the left burner 1a is ignited when it is determined that it is placed and an ignition command is issued by the fire extinguishing operation unit 21a.

However, when the control means executes the ascending control, the control means determines whether or not the cooking container is placed on Gotoku according to the output of the magnetic sensor, and the cooking container is not placed. If it is determined that the ignition is not performed on the stove burner, the gas stove of the present invention may not have such a configuration.

[Other embodiment]
In the above embodiment, the case where the fire extinguishing operation unit 21a for instructing the fire extinguishing to the standard burner (stove burner) 1a and the control means (not shown) constitutes a switching means has been described. The control means may constitute a switching means. In that case, the control means is switched to the rising state by energizing the control means by operating the power switch 24, and when the power supply to the control means is cut off by operating the power switch 24, the control means ends the execution of the rising control. It may be configured to switch to the configuration lowering state.
It should be noted that the switching means may have another configuration.

Even when the power switch 24 and the control means constitute the switching means in this way, the operating state of the power switch 24 allows the control means to be energized and de-energized to switch between the raised state and the lowered state, which is convenient. It is possible to realize a gas stove equipped with a good temperature detecting device.

In the above embodiment, the drop-in stove has been described as an example, but the present invention can be applied to the table stove.

Further, in the above embodiment, the standard burner is provided with the temperature detection device for detecting the temperature, and the case where the standard burner is provided with the switching means for switching between the lowered state and the raised state of the temperature detection device has been described as an example. Not only the standard burner but also a high thermal power burner or a small burner may be provided with a temperature detecting device and a switching means.

The present invention is not limited to the above embodiment in other respects, and various modifications can be made within the scope of the present invention.

1a Standard burner 1b High thermal power burner 1c Small burner 2 Stove burner through hole 4 Grill section 9 Temperature detection device (temperature sensor)
11 Fixed Side Support Member 11a One End Side of Fixed Side Support Member 11b Other End Side of Fixed Side Support Member 12 Moving Side Support Tube 13 Contact Body 14 Thermistor 15 Permanent Magnet 15a Right Permanent Magnet (Individual Permanent Magnet)
15b Left permanent magnet (individual permanent magnet)
16a ₁ First stage left electromagnetic coil (individual electromagnetic coil)
16a ₂ Second stage left electromagnetic coil (individual electromagnetic coil)
16a ₃ Third stage left electromagnetic coil (individual electromagnetic coil)
16b ₁ First stage right electromagnetic coil (individual electromagnetic coil)
16b ₂ Second stage right electromagnetic coil (individual electromagnetic coil)
16b ₃ Third stage right electromagnetic coil (individual electromagnetic coil)
17a ₁ First stage left magnetic sensor (individual magnetic sensor)
17a ₂ Second stage left magnetic sensor (individual magnetic sensor)
17b ₁ First stage right magnetic sensor (individual magnetic sensor)
17b ₂ Second stage right magnetic sensor (individual magnetic sensor)
21 (21a, 21b, 21c) Point extinguishing operation section (heating state adjustment section)
22 Grill Burner Operation Section 24 Power Switch 25 Power Lamp 32 Additional Function Operation/Display Section for Standard Burner 33 Additional Function Operation/Display Section for Grill 34 Manual Operation Section 40 Cooking Vessel 51 Gokutoku 61 Fixed Section 160 Electromagnetic Coil 160(I) First stage electromagnetic coil 160(II) Second stage electromagnetic coil 160(III) Third stage electromagnetic coil 170 Magnetic sensor 170(I) First stage magnetic sensor 170(II) Second stage magnetic sensor A Gas stove

Claims (6)

A stove burner that heats a cooking container, a virtue on which the cooking container is placed, a temperature detection device that is inserted into a through hole that vertically penetrates the stove to detect the temperature of the cooking container, and the stove A gas stove comprising a control means for controlling the burner heat power,
The temperature detecting device includes (a) a fixed-side support member, one end side of which is fixed to a predetermined fixing portion provided on the gas stove, and the other end side of the one end side is arranged to extend vertically. A movable side support cylinder supported by the fixed side support member and configured to be movable up and down with respect to the fixed side support member; and (c) an upper end of the movable side support cylinder, which is disposed above and below the cooking container. A contact body configured to come into contact with the bottom surface of the cooking container by vertically moving following the movement; and (d) a lower surface side of the contact body, which is thermally coupled with the contact body. And a thermistor arranged in a manner
A permanent magnet having magnetic poles arranged in a predetermined direction is arranged on the moving side support cylinder,
Magnetic sensors for detecting magnetic flux from the permanent magnets are arranged in a plurality of stages at predetermined intervals in the vertical direction of the fixed-side support member,
Electromagnetic coils that generate magnetic force by energization are arranged in a plurality of stages at predetermined intervals in the vertical direction of the fixed-side support member in such a manner that a vertical positional relationship is generated with respect to the magnetic sensor.
The control means, when one magnetic sensor of the plurality of magnetic sensors arranged in the vertical direction detects a predetermined magnetic flux, (a) an upper electromagnetic field adjacent to the one magnetic sensor in the upper direction. The coil is energized so as to have a polarity that causes an attractive force between the permanent magnet and the permanent magnet, and (b) the permanent magnet and the repulsive force are applied to the lower electromagnetic coil adjacent to the lower side of the one magnetic sensor. By energizing so that it has a polarity that produces
A gas stove configured to perform an ascending control for ascending the moving-side support cylinder via the permanent magnet. The fire extinguishing operation unit for instructing the fire extinguishing to the stove burner is provided, the control means executes the ascending control by issuing the ignition instruction by the point extinguishing operation unit, and by issuing the fire extinguishing instruction by the point extinction operation unit. The gas stove according to claim 1, wherein the control means is configured to terminate the execution of the rising control. A power switch for switching between energization and de-energization of the control means is provided, and the control means executes the rising control by energization of the control means by operating the power switch, and the control means by operating the power switch. The gas stove according to claim 1, wherein the control means is configured to terminate the execution of the ascending control by cutting off the power supply to the gas stove. 4. The permanent magnet according to claim 1, wherein the permanent magnet is arranged on a lower end side of the moving side support cylinder, and the magnetic sensor and the electromagnetic coil are arranged on a lower end side of the fixed side support member. Gas stove according to any one. The permanent magnet is composed of a plurality of individual permanent magnets arranged at the same vertical position with a central axis extending in the vertical direction of the moving side support cylinder interposed therebetween,
The magnetic sensor is composed of a plurality of individual magnetic sensors arranged at the same vertical position with a central axis extending in the vertical direction of the fixed side support member interposed therebetween, and the electromagnetic coil of the fixed side support member. The gas stove according to any one of claims 1 to 4, comprising a plurality of individual electromagnetic coils arranged at the same vertical position with a central axis extending in the vertical direction interposed therebetween. When the control means executes the ascending control, the control means determines whether or not the cooking container is placed on the Gotoku according to the output of the magnetic sensor. The gas stove according to any one of claims 1 to 5, which is configured not to ignite the stove burner when it is determined that the cooking container is not placed.

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