JP6445349B2 - Gas stove - Google Patents

Description

  The present invention relates to a gas stove, and more particularly to a technique for improving the ignition performance of a gas stove.

  As the gas stove, there is a gas stove configured such that the upper limit (maximum thermal power) of the thermal power is changed and set depending on use conditions and the like.

  As a conventional gas stove, Patent Document 1 includes a rotary encoder as a pulse generating unit that outputs a pulse signal by operating a thermal power adjusting operation tool, and this output pulse is input to a control unit. A gas stove configured to control the flow rate control valve for the stove that adjusts the amount of gas fuel supplied to the stove to adjust the heating power of the stove burner, and is equipped with an eco mode command switch that commands the eco mode. There has been proposed a gas stove configured such that when the eco mode is commanded by operating the mode command switch, the heating power of the stove burner that is adjusted to five levels before the eco mode command is adjusted to 17 levels.

  And this gas stove can be adjusted by the thermal power control command of the thermal power control command means before the eco mode command, and the maximum value of the stove burner's thermal power is the set maximum thermal power, whereas when the eco mode is commanded, The maximum heat power of the control burner that can be adjusted by the thermal power control command of the control command means is limited to a reduced maximum thermal power that is smaller than the set maximum thermal power, improving safety and ease of use. ing.

  Further, in such a gas stove, normally, when the stove burner is ignited, gas fuel is supplied to the stove burner at a predetermined ignition flow rate.

Although not described in detail in Patent Document 1, generally, the fuel gas supply amount (ignition flow rate) at the time of ignition is a predetermined predetermined flow rate.
The flow rate is set to a necessary and sufficient level so that the burner can be reliably ignited.

  However, in a gas stove in which the fuel gas supply amount at the time of ignition is a predetermined flow rate, depending on conditions such as the temperature of the stove burner, the flame of the stove burner may spread greatly at the time of ignition. In some cases, the user may be surprised, and it is not desirable from the viewpoint of safety, so there is room for improvement.

  On the other hand, it is conceivable to reduce the supply amount of the fuel gas. However, if the supply amount of the fuel gas is merely reduced, the spread of the flame of the burner is suppressed, but ignition is not performed well (ignition performance is low). There is a problem that it decreases).

JP 2013-134047 A

  The present invention solves the above-described problems, and provides a gas stove that can suppress the spread of a flame of a burner at the time of ignition, and that can perform ignition with good ignition performance. For the purpose.

In order to solve the above problems, the gas stove of the present invention is
A stove burner for heating the cooking vessel, a heating power adjusting means for adjusting the heating power of the stove burner, a heating power adjustment command means for commanding a heating power adjustment command, and a point fire extinguishing command for instructing a combustion start command and a combustion stop command for the stove burner Command means, and operation control means for controlling combustion of the stove burner,
Combustion control in which the operation control means starts combustion of the conburner based on the combustion start command of the point fire extinguishing command means, and stops combustion of the conburner based on the combustion stop command. As well as
The operation control means, based on the thermal power adjustment command of the thermal power adjustment command means, to set the thermal power of the combo burner between the set maximum thermal power, the set minimum thermal power, and between the set maximum thermal power and the set minimum thermal power It is configured to execute a thermal power adjustment control that operates the thermal power adjusting means so that it can be adjusted to a set intermediate thermal power,
A gas stove configured to ignite the stove burner with a set ignition heating power at the time of ignition commanded by the combustion start command;
A temperature determination means for determining the temperature of the stove burner, and a setting ignition heating power change setting section for changing and setting the setting ignition heating power,
When the determination temperature determined by the temperature determination unit that determines the temperature of the combustor is equal to or higher than a predetermined temperature, the determination temperature determined by the temperature determination unit is predetermined. Compared to the case where the temperature is lower than the above temperature, it is configured to perform a change setting for reducing the set ignition heating power.

  In the gas stove according to the present invention, the combustor temperature detecting means for detecting the temperature of the stove burner functions as a temperature data detecting means for the temperature determining means to determine the temperature of the stove burner. It is preferable that

  Note that the combustor temperature detecting means for detecting the temperature of the combustor is, for example, a burner cap temperature in which a combustor is formed, a flame cap-formed burner cap, or a fuel to be supplied to the combustor that also constitutes the combustor. It is a concept that means a temperature sensor for detecting the temperature of a mixing tube that mixes gas with air.

  Further, in the case of including an ignition detection means for detecting the temperature of the flame formed in the cono burner and detecting the ignition of the cono burner, the ignition detection means, the temperature determination means, the temperature determination means, the temperature of the cono burner It may be configured to function as temperature data detection means for determining the above.

In addition, a combustion time timer for measuring the combustion time of the burner after the combustion start command is commanded,
A post-combustion combustion stop time timer that measures an elapsed time after the combustion stop command is commanded as a post-combustion combustion stop time when the combustion time measured by the combustion time timer is a predetermined time or more;
When a combustion start command is commanded in a state where the post-combustion combustion stop time measured by the post-combustion combustion stop time timer is equal to or shorter than a predetermined time, the post-combustion post-combustion time measured by the post-combustion combustion stop time timer It is also possible to configure so that the determination temperature is higher than when the combustion start command is issued in a state where the combustion stop time exceeds a predetermined time.

  As described above, the gas stove of the present invention includes the temperature determination means for determining the temperature of the stove burner, and the setting ignition heating power change setting unit that changes and sets the setting ignition heating power, and the setting ignition heating power change setting unit includes: When the determination temperature determined by the temperature determination unit that determines the temperature of the combustor is equal to or higher than a predetermined temperature, the set ignition heating power is higher than that when the determination temperature determined by the temperature determination unit is lower than the predetermined temperature. Because it is configured to make a change setting that reduces the size of the gas stove, it prevents a fire transfer failure at the time of ignition, while suppressing the flame of the stove burner from spreading too much at the time of ignition, a safe and easy to use gas stove It becomes possible to provide.

  In addition, when the determination temperature determined by the temperature determination means for determining the temperature of the cono burner is equal to or higher than a predetermined temperature (when the temperature of the cono burner is high), the ignitability to the fuel gas becomes high. Even if the thermal power is reduced, it is possible to ensure sufficient fire transfer, and the ignition performance is not impaired.

  In addition, when the temperature detector is configured so that the temperature determination means functions as a temperature data detection means for determining the temperature of the combo burner, the temperature of the combo burner is directly detected. Therefore, the set ignition heating power can be changed and set accurately.

  In addition, in the case of including an ignition detection means for detecting the temperature of the flame formed in the stove burner to detect the ignition of the stove burner, the temperature judgment means is used for the temperature judgment means to judge the temperature of the combo burner. When used as a means for detecting temperature data, the constituent elements inherently included in the combustor can also be used as a means for detecting temperature data for the temperature determining means to determine the temperature of the combustor. Cost can be reduced.

  In addition, a combustion time timer that measures the combustion time of the burner after the combustion start command is commanded is provided, and a combustion stop command is commanded when the combustion time measured by the combustion time timer is equal to or longer than a predetermined time. A post-combustion combustion stop time timer that measures the elapsed time after combustion as a post-combustion combustion stop time. When commanded, it is determined that the determination temperature is higher than when the combustion start command is commanded in a state where the post-combustion combustion stop time measured by the post-combustion combustion stop time timer exceeds a predetermined time. In this configuration, it is not necessary to provide a sensor such as a temperature sensor for detecting the temperature of the combustor. It is possible to perform, it is possible to reduce the manufacturing cost.

  In other words, when the combustion stop time after a predetermined time of combustion is short, it is possible to determine that the temperature of the combo burner is small and the judgment temperature is high, so a sensor such as a combo burner temperature detecting means is provided. It is possible to determine the temperature of the stove burner only with software (only by comparing the time).

It is a figure which shows the external appearance structure of the gas stove concerning embodiment of this invention. It is a figure which shows the pulse waveform for demonstrating operation | movement of the rotary encoder (thermal-power adjustment command means) used in the gas stove concerning embodiment of this invention, (a) at the time of forward rotation, (b) at the time of reverse rotation It is a figure which shows the pulse waveform of. It is a figure which shows the burner operation part (thermal power adjustment command means) of the gas stove concerning embodiment of this invention, (a) shows the state where the burner operation part is not used, (b) shows the burner operation part protruding. It is a figure which shows the state which became usable. It is a figure which shows the structure of the gas stove concerning embodiment of this invention. It is a figure which shows the principal part structure of the gas stove concerning 1st Embodiment of this invention. It is a figure which shows the principal part structure of the gas stove concerning 2nd Embodiment of this invention.

  In the following, embodiments of the present invention will be shown to describe the features of the present invention in more detail.

<Basic Configuration of Gas Stove according to Embodiment of the Present Invention>
The gas stove according to the embodiment of the present invention is
As shown in FIGS. 1, 3, and 4, a stove burner 1 (three burners of a standard burner 1 a, a high burner 1 b, and a small burner 1 c) that heats the cooking container and a heating power adjustment that regulates the heating power of the stove burner 1 Means (in the gas stove according to this embodiment, the flow rate control valve 3) (FIG. 4), and a thermal power adjustment command means (burner operation unit) 21 (standard burner operation unit 21a, high thermal power burner operation unit 21b) for instructing a thermal power control command , Small burner operation unit 21c) (FIGS. 1 and 3).

Further, the gas stove includes point-extinguishing command means for commanding a combustion start command and a combustion stop command for the stove burner 1. In the gas stove according to this embodiment, the heating power adjustment command means (burner operation unit) 21 is configured to function also as a point fire extinguishing command means for instructing a combustion start command and a combustion stop command for the stove burner 1. .
Moreover, this gas stove is provided with the control part (operation control means) (FIG. 4) which controls the combustion of the stove burner 1. FIG.

  Moreover, this gas stove is provided with the grill part 4 for mounting to-be-cooked objects, such as a fish, and the grill burner 2 (refer FIG. 4) is arrange | positioned in the grill part 4. As shown in FIG.

  The standard burner 1 (1a) is provided with a temperature sensor (pan bottom temperature sensor) 9 for contacting the cooking container and detecting its temperature. In addition, it is also possible to similarly provide the high thermal power burner 1b and the small burner 1c with temperature sensors.

  On the front side of the gas stove, a heating power adjustment command means (burner) for manually instructing ignition and extinguishing, heating power adjustment and various settings of the above-described stove burner 1 and the grill burner 2 provided in the grill portion 4. (Operation unit) 21 (standard burner operation unit 21a, high thermal power burner operation unit 21b, small burner operation unit 21c), grill burner operation unit for manually instructing ignition and extinguishing of the grill burner 2, thermal power adjustment and various settings 22 (FIG. 1) is provided.

  Further, as shown in FIG. 4, each of the stove burner 1 (standard burner 1a, high thermal power burner 1b, small burner 1c) detects an ignition plug 7 as an ignition device for performing an ignition operation and an ignition state. The thermocouple 8 is provided for each of the grill burners 2 (upper burner 2a, lower burners 2b, 2c), and an ignition plug 7 as an ignition device for performing an ignition operation and a thermocouple 8 for detecting an ignition state. Is provided.

In addition, the structure regarding the gas supply to the stove burner 1 and the grill burner 2 is as follows.
As shown in FIG. 4, a source gas solenoid valve 12 is provided in a source gas supply path (main gas pipe) 11, and the source gas supply path 11 includes a standard burner branch path 13a and a high thermal power burner branch path 13b. The small burner branch 13c and the grill burner branch 13d are branched.

  Each of these branch paths has a flow rate control valve (gas amount control valve driven by a stepping motor) 3 for adjusting the amount of heating of each burner by adjusting the amount of gas, and a position for detecting the opening position thereof. A sensor 19 is provided. In addition, in the gas stove concerning this embodiment, the said flow control valve 3 is comprised so that it may function as a thermal power adjustment means in this invention.

Further, in the gas stove of this embodiment, the above-described heating power adjustment command means (burner operation units) 21 and 22 also function as point fire extinguishing command means for commanding the combustion start command and the combustion stop command of the stove burner 1. It is configured.
Note that a power switch 24 and a power lamp 25 for notifying that the power switch 24 is turned on are provided on the front side of the gas stove.

  In addition, five combustion displays are provided as thermal power display means 23 in the vicinity of the periphery of each thermal power adjustment command means (burner operation section) 21 (21 standard burner operation section 21a, high thermal power burner operation section 21b, small burner operation section 21c). Lamps L1, L2, L3, L4, and L5 are disposed (see FIG. 3). In the gas stove of this embodiment, an LED is used as the combustion display lamp.

  The gas stove also includes a thermal power adjusting means (not shown) that adjusts the thermal power of the stove burner 1 based on the command from the above-described thermal power adjustment command means (burner operation unit) 21.

  The gas stove also includes a control unit (operation control means) that controls the combustion of the stove burner 1. The operation control means starts the combustion of the stove burner 1 based on the combustion start command, and the combustion Combustion control for stopping the combustion of the stove burner 1 based on the stop command is executed.

  Further, the control unit (operation control unit) sets the heating power of the stove burner 1 based on the heating power adjustment command of the heating power adjustment command unit (burner operation unit) 21 to the set maximum heating power (3610 kcal / h in the present embodiment), The heating power adjusting means is operated so that the setting minimum heating power (330 kcal / h in this embodiment) and a plurality of intermediate heating powers set between the setting maximum heating power and the setting minimum heating power can be adjusted. Perform thermal power control.

  And in this gas stove, the above-mentioned thermal power adjustment command means (burner operation part) 21 is constituted using the rotary encoder which can command the thermal power adjustment command of the stove burner 1 by rotation operation.

Then, based on the thermal power adjustment command of the thermal power adjustment command means (burner operation unit) 21 using the rotary encoder, the thermal power of the stove burner 1 is set to the set maximum thermal power, the set minimum thermal power, and the set maximum thermal power and the set minimum thermal power. The thermal power adjustment control is performed to operate the thermal power adjusting means (not shown) so as to be adjusted to a plurality of intermediate thermal powers set during the period.
Note that the number of stages of the intermediate thermal power is configured to be set to a plurality of types of stages.

<About thermal power control command means (rotary encoder)>
In the gas stove according to this embodiment, a rotary encoder is used as the thermal power adjustment command means, and the thermal power adjustment command means (rotary encoder) is in the positive direction (as shown in FIGS. 2A and 2B). Along with the rotation operation in the clockwise direction, one (A phase) of the two-phase pulse signals advances in phase from the other (B phase) pulse signal, and the rotation is in the reverse direction (counterclockwise). In a state where the other (B-phase) pulse signal advances in phase with the one (A-phase) pulse signal in accordance with the operation, the two-phase pulse signals having different phases are output in accordance with the rotary operation of the rotary encoder. It is configured.

  In the gas stove according to this embodiment, the rotary encoder is configured to generate 24 pulses in each of the A phase and the B phase when rotated once (360 degrees).

In this embodiment, the rotation operation amount of the rotary encoder is determined by the number of times the rising edge st of the pulse output from the A phase is detected in the control unit (operation control means).
For example, when detecting the rising edge st of the pulse output from the A phase n times, the control unit determines that an instruction to change the heating power of the standard burner by n stages has been made.

  In this embodiment, the control unit detects whether the B phase is at a high level or a low level when the rising edge st of the pulse output from the A phase is detected. Is the heating power increase command of the standard burner rotated in the forward direction (clockwise) or the heating power increase command of the standard burner rotated in the reverse direction (counterclockwise).

  More specifically, as shown in FIG. 2A, when the B phase is low when the rising edge st of the pulse output from the A phase is detected, the control unit moves the rotary encoder in the forward direction. It is determined that the command is for increasing the heating power of the standard burner rotated clockwise (clockwise), and the B phase when the rising edge st of the pulse output from the A phase is detected as shown in FIG. When it is at the high level, it is determined that the command is a fire power reduction command for the standard burner in which the rotary encoder is rotated in the reverse direction (counterclockwise).

  Further, the gas stove according to this embodiment, like the conventional gas stove, ignites the stove burner at the set ignition heating power (in this embodiment, 2600 kcal / h) at the time of ignition when the combustion start command is commanded. It is configured. Further, as will be described later, the set ignition heating power is changed and set.

<Characteristic configuration>
The gas stove of this embodiment includes a setting ignition heating power change setting unit for changing and setting the setting ignition heating power (see FIGS. 5 and 6), and can change the setting ignition heating power depending on conditions. It is configured as follows.

  That is, in the gas stove of this embodiment, the determination temperature (the temperature of the gas stove 1) determined by the temperature determination means (described later) for determining the temperature of the stove burner 1 by the setting ignition heating power change setting unit is higher than a predetermined temperature. In this case, a change setting for reducing the set ignition heating power compared to a case where the determination temperature is lower than a predetermined temperature (for example, a setting for reducing the set ignition heating power that was 2600 kcal / h to 1800 kcal / h) is performed. It is configured to be able to.

less than,
(1) The temperature sensor 10 (FIG. 5) that detects the temperature of the burner cap 31 in which the flame hole 31a is formed in the stove burner 1 detects temperature data for the temperature determining means to determine the temperature of the burner 1 When used as a means to perform (first embodiment) (see FIG. 5), and
(2) A temperature sensor 10a (FIG. 6) for detecting the temperature of the mixing pipe 41 that mixes the fuel gas supplied to the conoburner 1 with air, and temperature data for the temperature judging means to judge the temperature of the conoburner 1. When used as a detection means (second embodiment) (see FIG. 6),
The configuration will be described separately.

  In the first embodiment and the second embodiment, the temperature sensor 10 or the temperature sensor 10a, which is a means for detecting the temperature of the combo burner, is used, and the temperature judging means judges the temperature of the combo burner. It is an example of a structure at the time of using as a means to detect the temperature data required for this.

  In the following first embodiment and second embodiment, the control unit (operation control means) (FIGS. 4 and 5) functions as a temperature determination means for determining the temperature of the burner 1. It is configured.

(1) For the first embodiment (when the temperature sensor for detecting the temperature of the burner cap is used as means for detecting temperature data for the temperature determining means to determine the temperature of the stove burner).
As shown in FIG. 5, the gas stove according to the first embodiment includes a temperature sensor (thermistor) 10 for detecting the temperature of the burner cap 31 provided around the flame hole 31 a of the stove burner 1. As a means. And this temperature sensor 10 is comprised so that a temperature determination means may function as a detection means of the temperature data for determining the temperature of the burner 1. FIG.

  In the first embodiment, the control unit (operation control means) (FIGS. 4 and 5) is configured to function as a temperature determination means for determining the temperature of the stove burner 1.

  In the gas stove according to the first embodiment, when the detected temperature of the temperature sensor 10 for determining the temperature of the burner cap 31 is less than 180 ° C., the temperature determining means has the temperature of the stove burner 1 lower than a predetermined temperature. And the set ignition heating power is maintained at 2600 kcal / h.

  On the other hand, when the detected temperature of the temperature sensor 10 that detects the temperature of the burner cap 31 is 180 ° C. or higher, the temperature determination means determines that the temperature of the stove burner 1 is higher than a predetermined value and A change setting is made to reduce the heating power from 2600 cal / h to 1800 cal / h.

  The “predetermined temperature” in the case where the temperature determining means determines whether the temperature of the stove burner 1 is lower or higher than the predetermined temperature enables a reliable fire transfer when actually igniting, It is a concept that separates whether or not the temperature can cause a highly reliable ignition, but the structure of the burner, the type of fuel gas, the supply mode of fuel gas, primary air, secondary air, etc. The temperature is determined in consideration of the above relationship, and is not specified as a fixed value.

(2) Second embodiment (a temperature sensor for detecting the temperature of a mixing tube for mixing the fuel gas supplied to the cono burner with air, and a temperature data detecting unit for the temperature judging means to judge the temperature of the combo burner. The gas stove according to the second embodiment, unlike the configuration of the first embodiment described above, mixes the fuel gas supplied to the stove burner 1 with air, as shown in FIG. A temperature sensor (thermistor) 10 a that detects the temperature of the mixing tube 41 is configured to function as temperature data detection means for the temperature determination means to determine the temperature of the stove burner 1.
In the second embodiment as well, the control unit (operation control means) (FIGS. 4 and 6) is configured to function as a temperature determination means for determining the temperature of the stove burner 1.

  When the temperature detected by the temperature sensor 10a is less than 60 ° C., the temperature determination means determines that the temperature of the conburner 1 is lower than the predetermined temperature, and maintains the set ignition heating power at 2600 kcal / h. To do.

  On the other hand, when the temperature detected by the temperature sensor 10a that detects the temperature of the mixing tube 41 is 60 ° C. or higher, the temperature determination means determines that the temperature of the combustor 1 is higher than a predetermined value, Change setting is made to reduce the thermal power from 2600 kcal / h to 1800 kcal / h.

  The mixing tube 41 is a tube in which the fuel gas ejected from the nozzle 42 and the primary air sucked by the ejector effect from the periphery of the nozzle 42 are mixed, and the temperature sensor 10a in contact with the mixing tube 41 is subjected to temperature determination. When the means is used as a temperature data detecting means for determining the temperature of the combo burner, the temperature determining means for judging the temperature of the combustor 1 detects the temperature data necessary for judging the temperature of the combo burner 1. Is done.

  Although the temperature of the mixing pipe 41 is far from the vicinity of the flame hole, which is directly related to the ignitability of the burner 1 to the fuel gas, the temperature of the mixing pipe 41 has a close correlation with the temperature near the flame hole. Therefore, the temperature determination means uses the temperature of the mixing tube 41 (the temperature closely correlated with the temperature in the vicinity of the flame hole) as temperature data for the temperature determination means to determine the temperature of the combo burner. It becomes possible to accurately determine the temperature of the stove burner, and the set ignition heating power can be changed and set accurately.

As described above, in the first embodiment, the temperature sensor 10 is used to detect the temperature of the burner cap 31, and in the second embodiment, the temperature sensor 10a is used to detect the temperature of the mixing tube 41. Since the temperature determination means is configured to be able to determine the temperature of the combustor 1 from the temperature data obtained by doing so, in both cases of the first embodiment and the second embodiment, the combo burner The temperature of 1 can be accurately determined.

  Then, when the temperature of the cono burner 1 determined by the temperature determining unit is high, the set ignition heating power is suppressed, so that the spread of the flame of the cono burner at the time of ignition is reduced.

Further, when the temperature of the burner is high, the ignitability to the fuel gas is high, and even if the set ignition heating power is suppressed, the fire transfer at the time of ignition is good and no ignition failure is caused.
Further, when the temperature of the burner 1 is low, the set ignition heating power is maintained in a large state, so that it is possible to prevent the occurrence of fire transfer failure and to ensure sufficient ignition performance.

  Therefore, by providing the configurations of the first embodiment and the second embodiment described above, it is possible to suppress the spread of the flame of the burner at the time of ignition, and without causing a fire transfer failure and the like. It becomes possible to provide a gas stove with high performance.

<Modification>
In the first embodiment, the temperature of the burner cap 31 is detected using the temperature sensor 10, and in the second embodiment, the temperature obtained by detecting the temperature of the mixing tube 41 using the temperature sensor 10a. Although the temperature determination means is configured to determine the temperature of the combustor 1 using the data, it is also possible to adopt a configuration as in the following modifications 1 and 2.

(Modification 1)
In the first embodiment, the temperature sensor 10 that detects the temperature of the burner cap 31 is used, and in the second embodiment, the temperature sensor 10a that detects the temperature of the mixing tube 41 is used, and the temperature determination means is a combo burner. The temperature data for determining the temperature is obtained, but the temperature detection means (thermocouple in this embodiment) 8 is configured to obtain the temperature data necessary for the temperature determination means to determine the combo burner. can do.

  In the case of such a configuration, the constituent elements originally provided in the stove burner 1 can be used for the temperature judgment of the stove burner, so that the temperature sensor 10 for detecting the temperature of the burner cap 31 and the mixing of the stove burner 1 It is not necessary to provide the temperature sensor 10a in contact with the pipe 41, the manufacturing cost can be reduced, and a gas stove excellent in economy can be provided.

(Modification 2)
Although not particularly shown, when a combustion time timer for measuring the combustion time is provided after the combustion start command is commanded, and when the combustion time measured by the combustion time timer is equal to or longer than a predetermined time (for example, 100 seconds) When a post-combustion combustion stop time timer that measures an elapsed time after the combustion stop command is commanded is measured as a post-combustion combustion stop time, the value of the post-combustion combustion stop time timer is a predetermined time (for example, 1 second). When the combustion start command is commanded in the following state, the determination temperature is higher than when the combustion start command is commanded when the value of the post-combustion combustion stop time timer is larger than a predetermined time (for example, 1 second). It can also be configured to determine that it is high. In addition, when the combustion stop time after the predetermined time of combustion is short, since the conburner maintains a high temperature, the level of the temperature (determination temperature) of the combo burner is determined based on the length of the combustion stop time. Is reasonable and can ensure reliability with no practical problems.

  When configured as in the second modification, it is not necessary to provide a temperature sensor that detects the temperature of the burner cap or a temperature sensor that comes into contact with the mixing tube of the stove burner, and temperature determination can be performed only by software. This is possible, and the cost can be reduced.

  In addition, this invention is not limited to the said embodiment and modification, A various application and deformation | transformation are possible within the scope of the invention.

1 Combustor 1a Standard burner 1b High-power burner 1c Small burner 2 Grill burner 2a Upper burner 2b Lower burner 2c Lower burner 3 Flow control valve (gas amount control valve)
4 Grill part 7 Spark plug 8 Thermocouple 9 Temperature sensor (pan sensor)
10 Temperature sensor for detecting the temperature of the burner cap 10a Temperature sensor for detecting the temperature of the mixing pipe 11 Original gas supply path (main gas pipe)
12 original gas solenoid valve 13a branch for standard burner 13b branch for high thermal power burner 13c branch for small burner 13d branch for grill burner 19 position sensor 21 thermal power control command means (burner operation section)
21a Standard burner operation section 21b High-heat power burner operation section 21c Small burner operation section 22 Grill burner operation section 23 Combustion display lamp, thermal power display section 24 Power switch 25 Power lamp 31 Burner cap 31a Flame hole 41 Mixing tube 42 Nozzle L1 to L5 Combustion display Lamp (heating amount display means)

Claims (4)

A stove burner for heating the cooking vessel, a heating power adjusting means for adjusting the heating power of the stove burner, a heating power adjustment command means for commanding a heating power adjustment command, and a point fire extinguishing command for instructing a combustion start command and a combustion stop command for the stove burner Command means, and operation control means for controlling combustion of the stove burner,
Combustion control in which the operation control means starts combustion of the conburner based on the combustion start command of the point fire extinguishing command means, and stops combustion of the conburner based on the combustion stop command. As well as
The operation control means, based on the thermal power adjustment command of the thermal power adjustment command means, to set the thermal power of the combo burner between the set maximum thermal power, the set minimum thermal power, and between the set maximum thermal power and the set minimum thermal power It is configured to execute a thermal power adjustment control that operates the thermal power adjusting means so that it can be adjusted to a set intermediate thermal power,
A gas stove configured to ignite the stove burner with a set ignition heating power at the time of ignition commanded by the combustion start command;
A temperature determination means for determining the temperature of the stove burner, and a setting ignition heating power change setting section for changing and setting the setting ignition heating power,
When the determination temperature determined by the temperature determination unit that determines the temperature of the combustor is equal to or higher than a predetermined temperature, the determination temperature determined by the temperature determination unit is predetermined. A gas stove configured to perform a change setting that reduces the set ignition heating power as compared with a case where the temperature is lower than the temperature of the gas stove.   The combo burner temperature detecting means for detecting the temperature of the cono burner is configured to function as a temperature data detecting means for the temperature judging means to judge the temperature of the cono burner. Item 1. A gas stove according to item 1.   In the case where there is provided an ignition detection means for detecting the temperature of the flame formed in the cono burner and detecting the ignition of the cono burner, the ignition detection means determines the temperature of the cono burner. The gas stove according to claim 1, wherein the gas stove is configured to function as temperature data detection means for performing the operation. A combustion time timer for measuring the combustion time of the combustor after the combustion start command is commanded;
A post-combustion combustion stop time timer that measures an elapsed time after the combustion stop command is commanded as a post-combustion combustion stop time when the combustion time measured by the combustion time timer is a predetermined time or more;
When a combustion start command is commanded in a state where the post-combustion combustion stop time measured by the post-combustion combustion stop time timer is equal to or shorter than a predetermined time, the post-combustion post-combustion time measured by the post-combustion combustion stop time timer The gas stove according to claim 1, wherein the determination temperature is determined to be higher than a case where a combustion start command is commanded in a state where the combustion stop time exceeds a predetermined time.

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