JP6851150B2 - Gas stove - Google Patents

Description

The present invention relates to a gas stove that detects the occurrence of an earthquake.

Conventionally, a gas stove having an earthquake detection device and having the supply of fuel gas to the stove burner cut off when an earthquake is detected by the earthquake detection device has been proposed (see, for example, Patent Document 1). ..

The earthquake detection device described in Patent Document 1 includes an XYZ 3-axis acceleration sensor, and captures the output of the acceleration sensor into a microcomputer via a peak hold circuit. Since the peak value of the acceleration detection signal output from the acceleration sensor is held for a certain period by the peak hold circuit, the microcomputer reads and processes the acceleration detection signal with a relatively long sampling period (0.1 seconds). ing.

Then, the microcomputer calculates the fluctuation frequency and amplitude of the acceleration based on the acceleration detection signal, and distinguishes between the seismic wave and the artificial vibration by the fluctuation frequency. Then, when the microcomputer determines that the wave is a seismic wave and the amplitude of the acceleration detection signal is equal to or greater than the amplitude threshold value (when the seismic intensity is assumed to be 4 or higher), the supply of fuel gas is cut off.

Japanese Unexamined Patent Publication No. 2015-145780

When the acceleration detection signal output from the acceleration sensor is read by a microcomputer and the fluctuation frequency of the acceleration is calculated, it is calculated accurately by adopting a high-performance microcomputer and shortening the sampling cycle of the acceleration detection signal. It is possible to raise the upper limit of the fluctuation frequency of the acceleration that is possible. However, when a high-performance microcomputer is adopted, the power consumption of the microcomputer increases.

Therefore, in the earthquake detection device described in Patent Document 1, the peak level of the acceleration detection signal is held for a certain period of time as a configuration in which the acceleration detection signal output from the acceleration sensor is taken into the microcomputer via the peak hold circuit. This makes it possible to read the peak level of an acceleration detection signal having a high fluctuation frequency with a relatively long sampling period using a general-purpose low power consumption microcomputer. However, providing the peak hold circuit in this way has the disadvantage that the power consumption of the earthquake detection device increases.

The present invention has been made in view of this background, and an object of the present invention is to provide a gas stove capable of reducing power consumption while ensuring earthquake detection accuracy.

The first aspect of the present invention is a gas stove having a solenoid valve for a gas burner and a drive circuit for operating the solenoid valve.
An acceleration detection unit that is attached to a predetermined location on the gas stove, detects acceleration in three directions at the predetermined location, and outputs an acceleration detection signal indicating the magnitude of the detected acceleration in the three directions.
With respect to the earthquake judgment frequency range set assuming the fluctuation frequency of the acceleration that occurs at the predetermined location when an earthquake of a predetermined seismic intensity or higher occurs, the sampling cycle set based on the maximum frequency of the earthquake judgment frequency range , The acceleration detection signal reading unit that reads the acceleration detection signal,
A combined acceleration calculation unit that calculates the combined acceleration in the three directions at the predetermined location from the acceleration detection signal read by the acceleration detection signal reading unit.
A seismic intensity determination unit that determines the seismic intensity from the combined acceleration,
An earthquake occurrence determination unit that determines that an earthquake has occurred when the seismic intensity determined by the seismic intensity determination unit is equal to or greater than the seismic intensity threshold set based on the predetermined seismic intensity.
For example Bei and the audio circuit to output the voice, the,
When the earthquake occurrence determination unit determines that an earthquake has occurred, it closes the solenoid valve, shuts off the fuel supply to the gas burner, and emits a voice notifying the occurrence of the earthquake from the voice circuit. It is characterized by executing the output process.

According to the present invention, the sampling period when the acceleration detection signal reading unit reads the acceleration detection signal is within the frequency range for earthquake determination set assuming the fluctuation frequency of the acceleration that occurs when an earthquake of a predetermined seismic intensity or higher occurs. Based on the maximum frequency, for example, the fluctuation frequency of the acceleration up to the maximum frequency is set as long as possible within the range of the sampling period in which the fluctuation frequency can be calculated accurately. In this case, in order to accurately calculate the fluctuation frequency of the acceleration exceeding the maximum frequency of the earthquake judgment frequency range, an arithmetic circuit such as a microcomputer with high performance and high power consumption is adopted to detect the acceleration in a short sampling cycle. It is not necessary to read the signal, and a general-purpose arithmetic circuit such as a microcomputer can be adopted. Therefore, the power consumption required for reading the acceleration detection signal can be suppressed.

Further, unlike the earthquake detection device described in Patent Document 1, the gas stove of the present invention does not need to be provided with a peak hold circuit in order to lengthen the sampling period, so that the power consumption due to the provision of the peak hold circuit can be reduced. It is possible to avoid the increase and reduce the power consumption when detecting an earthquake. In addition, when the earthquake occurrence determination unit determines that an earthquake has occurred, the solenoid valve for the gas burner is closed, the fuel supply to the gas burner is cut off, and the voice circuit notifies the occurrence of the earthquake. Is output. As a result, the user can be surely recognized that the fuel supply has been cut off.

Next, the second aspect of the present invention is a gas stove having a solenoid valve for a gas burner and a drive circuit for operating the solenoid valve.
An acceleration detection unit that is attached to a predetermined location on the gas stove, detects acceleration in three directions at the predetermined location, and outputs an acceleration detection signal indicating the magnitude of the detected acceleration in the three directions.
With respect to the earthquake judgment cycle range set assuming the fluctuation cycle of acceleration that occurs at the predetermined location when an earthquake of a predetermined seismic intensity or higher occurs, the sampling cycle set based on the shortest cycle of the earthquake judgment cycle range , The acceleration detection signal reading unit that reads the acceleration detection signal,
A combined acceleration calculation unit that calculates the combined acceleration in the three directions at the predetermined location from the acceleration detection signal read by the acceleration detection signal reading unit.
A seismic intensity determination unit that determines the seismic intensity from the combined acceleration,
When the seismic intensity determined by the seismic intensity determination unit is equal to or greater than the seismic intensity threshold set based on the predetermined seismic intensity, the earthquake occurrence determination unit determines that an earthquake has occurred.
For example Bei and the audio circuit to output the voice, the,

When the earthquake occurrence determination unit determines that an earthquake has occurred, it closes the solenoid valve, shuts off the fuel supply to the gas burner, and emits a voice notifying the occurrence of the earthquake from the voice circuit. It is characterized by executing the output process.

According to the present invention, the sampling cycle when the acceleration detection signal reading unit reads the acceleration detection signal is within the seismic determination cycle range set assuming the fluctuation cycle of the acceleration that occurs when an earthquake of a predetermined seismic intensity or higher occurs. Based on the shortest cycle, for example, it is set as long as possible within the range of the sampling cycle in which the fluctuation cycle of the acceleration up to the shortest cycle can be calculated with high accuracy. In this case, in order to accurately calculate the fluctuation cycle of acceleration shorter than the shortest cycle of the seismic judgment cycle range, an arithmetic circuit such as a microcomputer with high performance and high power consumption is adopted, and acceleration is performed in a short sampling cycle. It is not necessary to read the detection signal, and a general-purpose, low-power consumption microcomputer or other arithmetic circuit can be adopted. Therefore, the power consumption required for reading the acceleration detection signal can be suppressed.

Further, unlike the earthquake detection device described in Patent Document 1, the gas stove of the present invention does not need to be provided with a peak hold circuit in order to lengthen the sampling period, so that the power consumption due to the provision of the peak hold circuit can be reduced. It is possible to avoid the increase and reduce the power consumption when detecting an earthquake. In addition, when the earthquake occurrence determination unit determines that an earthquake has occurred, the solenoid valve for the gas burner is closed, the fuel supply to the gas burner is cut off, and the voice circuit notifies the occurrence of the earthquake. Is output. As a result, the user can be surely recognized that the fuel supply has been cut off.

Further, in the first aspect or the second aspect described above,
The detection target level setting unit that sets the detection target level that indicates the level of the earthquake to be detected, and the detection target level setting unit.
An acceleration detection cycle that sets an acceleration detection cycle, which is a cycle in which the acceleration detection unit detects acceleration in the three directions and outputs the acceleration detection signal according to the detection target level set by the detection target level setting unit. It is characterized by having a setting unit.

According to this configuration, gas stove user walking maintenance or the like of the present invention, the detection target level setting section, the detection target level (e.g., level can not be a person is standing, level buildings are damaged, etc. ) Can be set. Then, the acceleration detection cycle setting unit sets, for example, the acceleration detection cycle required to detect the fluctuation frequency of the acceleration and the earthquake that causes the seismic intensity according to the detection target level as long as possible, and reduces the power consumption of the acceleration detection unit. Can be reduced.

Configuration diagram of the earthquake detection device. Explanatory drawing of fluctuation period and fluctuation amplitude of acceleration in the X direction. Flowchart of earthquake detection processing. The block diagram of the earthquake detection apparatus provided with the low-pass filter circuit and the high-pass filter circuit.

An embodiment of the present invention will be described with reference to FIGS. 1 to 4.

[1. Configuration of earthquake detection device]
With reference to FIG. 1, the earthquake detection device 1a of the present embodiment sets the microcomputer 10a, the acceleration sensor 20a (corresponding to the acceleration detection unit of the present invention), and the level (strength) of the earthquake to be detected. A detection target level setting switch 25 (corresponding to the detection target level setting unit of the present invention) is provided. The earthquake detection device 1a is mounted on a gas stove, and the microcomputer 10a is a load drive that operates an electric load (a solenoid valve that opens and closes a gas supply pipe, an igniter that applies a high voltage to an ignition electrode of a gas burner, etc.) provided in the gas stove. It also has a function of controlling the operation of the circuit 32, the voice circuit 30, and the buzzer circuit 31.

The earthquake detection device 1a can be used by being mounted on a gas stove powered by a battery or a gas stove powered by a commercial power source, but when mounted on a gas stove powered by a battery, the effect of reducing power consumption described later will be effective. Will be higher.

Further, from the various sensor circuits 22 to which various sensors provided in the gas stove (thermocouple for detecting the burning state of the burner, thermistor for detecting the temperature of the object to be cooked, etc.) are connected to the microcomputer 10a, each sensor is connected. The detection signal is input.

The acceleration sensor 20a is mounted on a control board arranged in the housing of the gas stove, and the magnitude of the acceleration (acceleration in three directions of XYZ orthogonal to each other) generated at the mounting location (corresponding to a predetermined location of the present invention). Is output as an acceleration detection signal. The acceleration sensor 20a is arranged so that X is in the north-south (NS) direction, Y is in the east-west (EW) direction, and Z is in the up-down (UD) direction.

The microcomputer 10a operates in synchronization with the clock signal input from the oscillation circuit 33, and executes an earthquake detection program (included in the gas stove control program) held in a memory (not shown). It functions as an acceleration detection signal reading unit 11a, a combined acceleration calculation unit 12, a seismic intensity determination unit 13, an earthquake occurrence determination unit 14, and an acceleration detection cycle setting unit 15.

The acceleration detection signal reading unit 11a reads the acceleration detection signals in the three directions of X, Y, and Z output from the acceleration sensor 20a in a sampling period Ps of 16 msec. Then, high-pass (removal of low-frequency components) and low-pass (removal of high-frequency components) processing is performed to acquire accelerations Ax, Ay, and Az in the three directions of X, Y, and Z.

Here, the 16 msec sampling period Ps is an earthquake determination frequency set with the fluctuation frequency of acceleration assumed to occur when an earthquake with a seismic intensity of 5 (corresponding to a predetermined seismic intensity of the present invention) or higher occurs as the upper limit (maximum frequency). It is set based on the highest frequency in the range (eg 0.1-10 Hz).

The inventors of the present application have determined whether or not an earthquake with a seismic intensity of 5 having an acceleration fluctuation frequency of 10 Hz can be detected accurately (without erroneous detection) by changing the sampling period, such as an experiment or a computer simulation. Was examined by. Then, 16 msec, which is the longest sampling cycle capable of accurately detecting an earthquake with a seismic intensity of 5 having an acceleration fluctuation frequency of 10 Hz, is set as the sampling cycle Ps when the acceleration detection signal reading unit 11a reads the acceleration detection signal. Were determined.

The sampling period when reading the acceleration detection signal does not have to be exactly 16 msec, for example, a range longer than 10 msec and shorter than 32 msec (higher than 3.1 times the maximum frequency of the seismic determination frequency range). It may be set within a period range corresponding to a frequency range lower than 10 times).

The combined acceleration calculation unit 12 calculates the combined acceleration Axyz of the accelerations Ax, Ay, and Az in the X, Y, and Z directions acquired by the acceleration detection signal reading unit 11a. The seismic intensity determination unit 13 detects the seismic intensity Ed corresponding to the combined acceleration Axyz calculated by the combined acceleration calculation unit 12.

Earthquake determination unit 14, when seismic intensity Ed detected by seismic intensity determining unit 13 is seismic intensity threshold (e.g., intensity 5) or more, it is determined that the earthquake that has occurred. When the earthquake occurrence determination unit 14 determines that an earthquake has occurred, the gas on-off valve is closed to shut off the supply of fuel gas to the gas burner, and the voice circuit 30 notifies the occurrence of the earthquake. Is executed (earthquake occurrence response process).

The acceleration detection cycle setting unit 15 acquires the acceleration detection cycle St corresponding to the detection target level Lv set by the detection target level setting switch 25. Then, the acceleration detection cycle setting unit 15 outputs the acquired data indicating the acceleration detection cycle St to the acceleration sensor 20a.

The acceleration sensor 20a detects acceleration in the X, Y, and Z directions by the acceleration detection cycle St recognized from the data output from the acceleration detection cycle setting unit 15, and outputs the acceleration detection signal to the acceleration detection signal reading unit 11a. ..

Here, the detection target level is, for example, a setting of a plurality of levels of risk of an event (such as collapse of a building) caused by an earthquake. In the memory of the microcomputer 10a, a correlation map for setting an acceleration detection cycle indicating an acceleration detection cycle corresponding to the detection target level of each stage with respect to a plurality of stages of detection target levels set by the detection target level setting switch 25. Data is retained.

Then, the acceleration detection cycle setting unit 15 applies the detection target level Lv set by the detection target level setting switch 25 to the correlation map for determining the acceleration detection cycle, and acquires the corresponding acceleration detection cycle St.

The correlation map for determining the acceleration detection cycle is the acceleration detection required to accurately detect the fluctuation frequency (or fluctuation cycle) and seismic intensity of the acceleration that occurs when an earthquake occurs, which is assumed by the detection target level at each stage. It was created by setting the cycle (preferably the shortest cycle) by experiment or computer simulation.

Users of the earthquake detection device 1a, maintenance workers, etc. operate the detection target level setting switch 25 to set the detection target level, which is expected to cause some damage to the house where the gas stove is installed. Only when an earthquake occurs, the earthquake occurrence response process by the earthquake detection device 1a can be executed.

Here, FIG. 2 illustrates how the acceleration in the X direction indicated by the acceleration detection signal output from the acceleration sensor 20a fluctuates, the horizontal axis is set to time t (msec), and the vertical axis is. The acceleration in the X direction (gal, cm / s ² ) is set. Further, each black dot indicates the reading timing of the acceleration detection signal by the acceleration detection signal reading unit 11a, and Ps is the sampling period. In FIG. 2, for example, in the period of t = 220 msec to 380 msec, the fluctuation frequency of the acceleration in the X direction is fa_x (fluctuation cycle Ta_x = 1 / fa_x), and the fluctuation amplitude is Aw_x.

The detection target level Lv set by the detection target level setting switch 25 is also input to the earthquake occurrence determination unit 14. The earthquake occurrence determination unit 14 sets the seismic intensity threshold value for determining the occurrence of an earthquake according to the detection target level Lv.

[2. Earthquake detection processing]
Next, a series of processes executed by the acceleration detection signal reading unit 11a, the combined acceleration calculation unit 12, the seismic intensity determination unit 13, and the earthquake occurrence determination unit 14 will be described according to the flowchart shown in FIG.

When the power is turned on (power on the gas stove is turned on) in STEP 1 of FIG. 3, the process proceeds to STEP 2 and the earthquake detection process is started. STEP2 is a process by the acceleration detection signal reading unit 11a, and the acceleration detection signal reading unit 11a collects an acceleration detection signal indicating acceleration in three directions of X, Y, and Z output from the acceleration sensor 20a in a sampling period Ps of 16 msec. Read sequentially with and keep in memory.

Subsequent STEP 3 is processing by the combined acceleration calculation unit 12. The combined acceleration calculation unit 12 calculates the combined acceleration Axyz of the accelerations Ax, Ay, and Az in the three directions of X, Y, and Z held in the memory in STEP2.

The next STEP 4 is a process by the seismic intensity determination unit 13. The seismic intensity determination unit 13 applies the combined acceleration Axyz calculated by the combined acceleration calculation unit 12 in STEP 3 to the correlation map for seismic intensity determination showing the correspondence between the seismic intensity held in the memory and the combined acceleration, and the corresponding seismic intensity. Determine Ed.

Subsequent STEP 5 is processing by the earthquake occurrence determination unit 14. The earthquake occurrence determination unit 14 determines whether or not the seismic intensity Ed determined by the seismic intensity determination unit 13 is 5 or more. Then, when the seismic intensity Ed is 5 or more (when it can be determined that an earthquake has occurred), the process proceeds to STEP 6, and the earthquake occurrence determination unit 14 closes the gas solenoid valve to shut off the fuel supply to the gas burner. Execute the process of "device error stop". On the other hand, when the seismic intensity Ed is smaller than 5, it branches to STEP 1, and in this case, the earthquake detection process is executed again.

Here, the seismic intensity 5, which is the determination threshold for the occurrence of an earthquake in STEP 5, corresponds to the seismic intensity threshold set based on the predetermined seismic intensity of the present invention. In STEP 5, the seismic intensity threshold value is set to a predetermined seismic intensity (seismic intensity 5), but the seismic intensity threshold value may be set to a value different from the predetermined seismic intensity (for example, seismic intensity 4.8 or the like). As described above, the seismic intensity threshold value is set according to the detection target level Lv set by the detection target level setting switch 25.

The earthquake detection device 1a limits the detection target of the fluctuation frequency of the acceleration for detecting an earthquake to the frequency range for earthquake determination (0.1 Hz to 10 Hz in the above embodiment), and the maximum frequency in the frequency range for earthquake determination. Acceleration detection signals with fluctuation frequencies exceeding the above are excluded from earthquake detection. As a result, the following effects (1) and (2) are obtained.

(1) In order to accurately detect the fluctuation frequency of the acceleration detection signal that exceeds the maximum frequency of the earthquake judgment frequency range, a high-performance microcomputer with high power consumption is adopted, and the acceleration detection signal is used in a short sampling cycle. There is no need to read. Therefore, it is sufficient to adopt a general-purpose microcomputer having low power consumption and read the acceleration detection signal in a relatively long sampling cycle, whereby the power consumption required for reading the acceleration detection signal can be suppressed. When the frequency range for earthquake judgment is set to a lower range (for example, 1 Hz to 2 Hz) where damage to buildings due to an earthquake is expected to increase, the sampling cycle is further lengthened to further reduce power consumption. be able to.

(2) It is not necessary to provide a peak hold circuit that holds the peak level of the acceleration detection signal for a certain period of time in order to accurately calculate a high frequency exceeding the maximum frequency in the seismic determination frequency range due to a long sampling period. Therefore, it is possible to avoid an increase in power consumption due to the provision of the peak hold circuit and reduce the power consumption of the earthquake detection device 1a.

[3. Other embodiments]
In the above embodiment, as shown in FIG. 1, the acceleration detection signal reading unit 11a uses the acceleration sensor 20a that outputs the detected acceleration detection signals in the three directions of X, Y, and Z as digital signals. High-pass and low-pass processing was performed by software processing, but as shown in FIG. 4, even if an acceleration sensor 20b that outputs acceleration detection signals sx, sy, and sz in three directions of X, Y, and Z as analog signals is used. Good.

In the earthquake detection device 1b shown in FIG. 4, the microcomputer 10b includes an A / D input (analog / digital conversion input) port. Then, the acceleration detection signals sx, sy, and sz in the three directions of X, Y, and Z output from the acceleration sensor 20b are A / D input via the low-pass & high-pass filter (bandpass filter) circuits 21a, 21b, and 21c. Input to the port.

As a result, the acceleration detection signal reading unit 11b converts the analog acceleration detection signals in the three directions of X, Y, and Z from which the high-frequency component and the low-frequency component are removed by the low-pass & high-pass filter circuits 21a, 21b, and 21c into digital values. It can be converted and read. The same as the earthquake detection device 1a shown in FIG. 1 except for the configuration in which the acceleration detection signal read by the acceleration sensor 20b is input by the acceleration detection signal reading unit 11b via the low-pass & high-pass filter circuits 21a, 21b, 21c. is there.

In the above embodiment, the sampling period for reading the acceleration detection signal is set based on the maximum frequency of the acceleration fluctuation frequency range (earthquake determination frequency range) caused by the earthquake to be detected. The sampling period Ps when reading the acceleration detection signal may be set based on the shortest period of the range of the acceleration fluctuation period (earthquake determination cycle range) caused by the target earthquake.

In this case, the seismic determination cycle range (for example, 0.1 to 10 seconds) is set with the fluctuation cycle of acceleration assumed to occur when an earthquake of seismic intensity 5 (corresponding to the predetermined seismic intensity of the present invention) occurs as the minimum cycle. As with the earthquake detection device 1a, the 16 msec sampling period Ps is accurate for earthquakes with an acceleration fluctuation period of the shortest period in the earthquake determination period range and a seismic intensity of 5 by experiments or computer simulations. The sampling period is set to be as long as possible within the range of the sampling period that can be calculated.

Even in the earthquake detection device 1b, the sampling period Ps when reading the acceleration detection signal does not have to be exactly 16 msec, for example, a range longer than 10 msec and shorter than 32 msec (the shortest period of the earthquake determination cycle range). It may be set within a range (a range longer than 0.1 times 0.1 seconds and shorter than 0.32 times).

Although FIGS. 1 and 4 show a configuration in which the high-pass & low-pass filtering process is performed, the effect of the present invention can be obtained even when the high-pass & low-pass filtering process is not performed.

Further, in the above embodiment, the detection target level setting switch 25 is shown as the detection target level setting unit of the present invention, but the earthquake detection devices 1a and 1b are provided with a communication function and a communication terminal (smartphone, mobile phone, tablet, etc.) ) May be transmitted from the communication terminal to the seismic detection devices 1a and 1b to set the detection target level. In this case, the configuration in which the detection target level data is received from the communication terminal and output to the acceleration detection cycle setting unit 15 corresponds to the detection target level setting unit of the present invention.

1a, 1b ... Earthquake detection device, 10a, 10b ... Microcomputer, 11a, 11b ... Accelerometer detection signal reading unit, 12 ... Synthetic acceleration calculation unit, 13 ... Seismic intensity determination unit, 14 ... Earthquake occurrence determination unit, 15 ... Acceleration detection cycle Setting unit, 20a, 20b ... Accelerometer, 25 ... Detection target level setting switch (detection target level setting unit).

Claims (3)

A gas stove having a solenoid valve for a gas burner and a drive circuit for operating the solenoid valve.
An acceleration detection unit that is attached to a predetermined location on the gas stove, detects acceleration in three directions at the predetermined location, and outputs an acceleration detection signal indicating the magnitude of the detected acceleration in the three directions.
With respect to the earthquake judgment frequency range set assuming the fluctuation frequency of the acceleration that occurs at the predetermined location when an earthquake of a predetermined seismic intensity or higher occurs, the sampling cycle set based on the maximum frequency of the earthquake judgment frequency range , The acceleration detection signal reading unit that reads the acceleration detection signal,
A combined acceleration calculation unit that calculates the combined acceleration in the three directions at the predetermined location from the acceleration detection signal read by the acceleration detection signal reading unit.
A seismic intensity determination unit that determines the seismic intensity from the combined acceleration,
An earthquake occurrence determination unit that determines that an earthquake has occurred when the seismic intensity determined by the seismic intensity determination unit is equal to or greater than the seismic intensity threshold set based on the predetermined seismic intensity.
An audio circuit that outputs audio and
Bei to give a,
When the earthquake occurrence determination unit determines that an earthquake has occurred, it closes the solenoid valve, shuts off the fuel supply to the gas burner, and emits a voice notifying the occurrence of the earthquake from the voice circuit. A gas stove characterized by executing an output process . A gas stove having a solenoid valve for a gas burner and a drive circuit for operating the solenoid valve.
An acceleration detection unit that is attached to a predetermined location on the gas stove, detects acceleration in three directions at the predetermined location, and outputs an acceleration detection signal indicating the magnitude of the detected acceleration in the three directions.
With respect to the earthquake judgment cycle range set assuming the fluctuation cycle of acceleration that occurs at the predetermined location when an earthquake of a predetermined seismic intensity or higher occurs, the sampling cycle set based on the shortest cycle of the earthquake judgment cycle range , The acceleration detection signal reading unit that reads the acceleration detection signal,
A combined acceleration calculation unit that calculates the combined acceleration in the three directions at the predetermined location from the acceleration detection signal read by the acceleration detection signal reading unit.
A seismic intensity determination unit that determines the seismic intensity from the combined acceleration,
When the seismic intensity determined by the seismic intensity determination unit is equal to or greater than the seismic intensity threshold set based on the predetermined seismic intensity, the earthquake occurrence determination unit determines that an earthquake has occurred.
An audio circuit that outputs audio and
Bei to give a,
When the earthquake occurrence determination unit determines that an earthquake has occurred, it closes the solenoid valve, shuts off the fuel supply to the gas burner, and emits a voice notifying the occurrence of the earthquake from the voice circuit. A gas stove characterized by executing an output process . In the gas stove according to claim 1 or 2.
The detection target level setting unit that sets the detection target level that indicates the level of the earthquake to be detected, and the detection target level setting unit.
An acceleration detection cycle that sets an acceleration detection cycle, which is a cycle in which the acceleration detection unit detects acceleration in the three directions and outputs the acceleration detection signal according to the detection target level set by the detection target level setting unit. A gas stove characterized by having a setting unit.

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