JPH081409B2 - Gas leak detector - Google Patents

Description

Description: <Industrial field of application> The present invention relates to a gas leakage detection device for detecting gas leakage from a gas flow path.

<Prior Art> In recent years, gas explosion accidents due to gas leakage from gas pipes have frequently occurred. Especially when there is a long distance from the gas storage facility to the gas use facility, such as in hospitals and schools, and there is a gas pipe buried underground between these facilities, corrosion of the buried pipe and uneven settlement of the ground may occur. , There is a risk of cracking the buried pipe and causing gas leakage.

Conventionally, in order to detect a gas leak from such a gas flow path, a pressure sensor is provided in the gas flow path, and a predetermined inspection period, for example, once a year or once every two years is set. , Close both ends of the gas flow path to be inspected and set the pressure in the gas flow path to 850 mmH ₂ O.
Gas leakage is detected by increasing the pressure to a certain degree and inspecting for the presence of pressure drop due to leakage.

There is also a method of arranging a flow rate sensor in a gas flow path and constantly monitoring the gas flow rate, thereby monitoring an abnormal gas flow rate that cannot be attained by normal gas use, and detecting gas leakage.

Gas shutoff device 1 interlocked with the pressure sensor shown in FIG.
Is an example.

The gas shutoff device 1 includes a gas flow path 3 including a shutoff valve 2.
A pressure sensor 4 for detecting the pressure of the gas flow path 3, a flow rate signal transmitter 5 for detecting the gas flow in the gas flow path 3 and transmitting a flow rate signal, and a pressure signal based on the output of the pressure sensor 4. Of the pressure signal from the pressure signal transmitter 6 and the pressure signal from the pressure signal transmitter 6 are stored, and after the pressure signal is stored, the decreasing pressure rises and the flow signal from the flow signal transmitter 5 increases. Is supplied, a shutoff signal 7 for sending a signal to close the shutoff valve 2 is provided.

Then, with this gas shutoff device 1, while using the gas appliance, LP cylinder (container) replacement, for some reason,
If the gas pressure drops and the flame disappears and you forget to close the gas appliance plug, the gas pressure rises again,
The gas flow path 3 is shut off to prevent gas leakage.

<Problems to be Solved by the Invention> However, in the method of detecting a gas leak by a regular inspection, the leak that occurs immediately after the inspection is overlooked until the next inspection, and early detection cannot be performed. That is, if there is no leak during the periodic inspection, or if no leak is found because it is a very small amount of leak, the accumulated gas reaches a dangerous amount due to long-term leak, or the buried pipe corrodes with the passage of time. There is a risk that the amount of leakage will increase and gas explosion will occur.

In addition, in the method of constantly monitoring the gas flow rate with a flow sensor to detect gas leakage, the flow sensor does not function when leakage occurs upstream of the flow sensor, so leakage on the downstream side of the flow sensor can be detected. However, the leak on the upstream side cannot be found.

As explained above, in facilities such as hospitals and schools, the distance from the gas storage facility to the gas use facility is long,
In many cases, gas pipes buried underground are used to connect this space. In such a case, the flow sensor is usually built in the gas meter of the gas use facility or fixed to the wall surface of the gas use facility.

Therefore, even if a leak occurs in the buried pipe, the flow rate sensor does not function and the gas leak cannot be detected.

<Means for Solving the Problems> The present invention has been proposed in view of the above, and a shutoff valve provided in the gas flow passage, and a gas flow passage provided downstream of the shutoff valve in the gas flow passage A flow rate sensor that detects the flow rate of flowing gas, a flow rate signal transmitter that transmits a flow rate signal when the flow rate sensor detects the flow of gas, and a gas flow path upstream of the shutoff valve A pressure sensor that detects the gas pressure, a pressure signal transmitter that sends a pressure fluctuation signal when a gas pressure fluctuation is detected based on the output of the pressure sensor, and a pressure fluctuation signal when the flow rate signal is not supplied. When supplied, it is judged that gas leakage has occurred on the upstream side of the flow sensor, and when the flow rate signal and pressure fluctuation signal are supplied when the gas appliance is not in use, at least on the downstream side of the flow sensor. Gas leaks occur It is characterized by comprising an arithmetic means for judging that there is.

<Operation> The flow rate sensor monitors the gas flow rate in the gas flow path, and when the flow rate sensor detects the flow of gas, the flow rate signal transmitter transmits a flow rate signal.

The pressure sensor monitors the gas pressure in the gas flow path, and when a change in gas pressure is detected, the pressure signal transmitter transmits a pressure change signal.

When the pressure fluctuation signal is supplied and the flow rate signal is supplied even though the gas appliance is not used, the calculation means determines that gas leakage has occurred at least on the downstream side of the flow rate sensor. . When the pressure fluctuation signal is supplied and the flow rate signal is not supplied, it is determined that gas leakage has occurred on the upstream side of the flow rate sensor.

<Example> The present invention will be described below based on an example shown in the drawings.

FIG. 1 is a schematic block diagram of an embodiment according to the present invention.

This gas leakage detection device 8 is provided with a shutoff valve 10 in the middle of the gas passage 9, and a pressure sensor 11 for detecting the gas pressure of the gas passage 9 is provided upstream of the shutoff valve 10 and downstream of the shutoff valve 10. Further, a gas meter 12, which is a flow rate sensor for detecting the flow rate of the gas flowing through the gas flow path 9, is provided. Then, the pressure sensor 11 is electrically connected to the microcomputer 14 which is a calculation means via the pressure signal transmitter 13, and the gas meter 12 is also provided.
Through the flow signal transmitter 15 to the microcomputer 14
Electrically connect to. Further, the microcomputer 14 is electrically connected to the display unit 16 for displaying an abnormality and the shutoff valve 10, and is supplied with drive power from the battery 17.
A return safety device 18 for returning the shutoff valve 10 is connected to the shutoff valve 10.

Further, on the upstream side of the gas flow passage 9, a pressure adjuster 19 for adjusting the gas pressure flowing into the gas flow passage 9 constant is provided.

The above-mentioned pressure signal transmitter 13 amplifies the signal from the pressure sensor 11, takes out only the effective signal component by the filter, shapes the waveform with the waveform shaper, and is a pulse signal when the fluctuation of the gas pressure is detected. Sends a pressure fluctuation signal.

In addition, the flow rate signal transmitter 15 changes mechanical movement of the gas meter 12 into an electric signal every time the gas meter 12 makes one revolution. Explaining the case where the flow rate signal transmitter 15 is provided in a membrane gas meter, the flow rate signal transmitter 15 includes a membrane driven by the flow of gas, a magnet rotating in conjunction with the movement of the membrane, and It consists of a reed switch that detects the movement of the magnet and repeats on and off. Then, when the magnet rotates in response to the flow of gas, the magnet approaches or moves away from the reed switch, the reed switch is turned on and off, and the membrane makes one reciprocation, that is, the magnet moves once.
Each time it rotates, it emits a one-pulse flow rate signal.

The pressure adjuster 19 is a device for adjusting the gas pressure flowing into the gas passage 9 to a constant value. For example, in the case of LP gas, the pressure inside the cylinder is limited to 0.7 to 15.6 kg / cm ² , and in order to burn the gas normally with a gas appliance, the gas pressure is reduced to 200 to 330 mmH ₂ O. It is necessary to adjust and supply. Therefore, attach a pressure regulator 19 to the cylinder outlet,
The pressure of the gas flowing into the gas passage 9 is adjusted.

 An example of the pressure regulator 19 is shown in FIG.

The pressure regulator 19 is a single-stage pressure regulator, and the inside of the main body 20 is divided into upper and lower parts by a diaphragm 21, and an upper part is an air chamber 22 and a lower part is a decompression chamber 23. A nozzle 25 is provided on the gas inlet 24 side of the decompression chamber 23, and a valve rod 28 having a closing valve 27 faces the injection port 26 of the nozzle 25.
Is connected to an operator 30 attached to the diaphragm 21 via a lever 29. Further, the diaphragm 21 is pushed down toward the decompression chamber 23 by a spring 31 provided inside the air chamber 22.

Therefore, when the high pressure gas flows from the gas inlet 24, the gas passes through the nozzle 25 and enters the decompression chamber 23. Here, when the inflow of gas continues, the pressure in the decompression chamber 23 rises,
Diaphragm 21 resists the bias of spring 31 and
Pushed up to side 22. Therefore, the operator 30 attached to the diaphragm 21 also rises, and the lever connected to the operator 30
29 rotates around the fulcrum 32 as an axis, the valve rod 28 moves to the gas inflow port 24 side, and the closing valve 27 reduces the injection amount of gas from the nozzle 25, or the injection port 26 when the pressure is high. To close. On the other hand, when the gas in the decompression chamber 23 flows out from the gas outlet 33, the pressure in the decompression chamber 23 decreases, and the diaphragm 21 is urged by the spring 31 to descend to the decompression chamber 23 side. Therefore, the lever 29 connected to the operator 30 rotates about the fulcrum 32, the valve rod 28 moves to the gas outlet 33 side, the closing valve 27 separates from the injection port 26 of the nozzle 25, and the high pressure gas is discharged. Inflow increases again.

In this way, the diaphragm 21 moves up and down as the pressure inside the decompression chamber 23 rises and falls, and the gas inflow amount from the nozzle 25 is adjusted to keep the gas pressure flowing into the gas flow passage 9 substantially constant.
In this case, the gas pressure flowing into the gas passage 9 pulsates.

In addition, in this embodiment, the mechanism of the pressure adjustment is explained by the single-stage pressure adjuster, but the same applies when this is changed to another pressure adjuster, for example, an automatic switching type pressure adjuster. .

As described above, when the gas pressure flowing into the gas passage 9 is adjusted by using the pressure adjuster 19, the gas pressure changes periodically. This pressure fluctuation shows different patterns when a gas appliance is normally used and when a slight gas leak occurs due to cracks or the like in the gas flow passage 9. In other words, the pressure fluctuation pattern in the case of a minute gas leak changes from several seconds to several tens of seconds, and is slower than the pressure fluctuation pattern in the case where the gas appliance is normally used.

The pressure fluctuation pattern when a slight gas leakage occurs is shown in FIGS. 4 and 5. FIG. 4 is a fluctuation pattern when the single-stage pressure regulator 19 is used, and four patterns are shown. Further, FIG. 5 shows a variation pattern when the automatic switching type pressure regulator 19 is used. The time interval at which this pressure fluctuation pattern occurs is not constant, but varies depending on the amount of leakage. The pressure fluctuation pattern also differs depending on the components of the flow path system, but if the leak amount does not change when the flow path system is specified, it shows a substantially constant pressure fluctuation pattern. The time interval in which the pressure fluctuation pattern occurs is about 1 minute to 20 minutes in the case of the single-stage pressure regulator, and about 1 to 10 minutes in the case of the automatic switching type pressure regulator.

The gas leak determination process by the gas leak detection device 8 described above will be described below.

 FIG. 6 shows the criteria for judging gas leakage.

Gas leakage is judged by the presence / absence of a flow rate signal and the presence / absence of a pressure fluctuation signal when the parts other than the igniter mechanism of the gas appliance are not used.

That is, when the pressure fluctuation signal is detected and the flow rate signal is detected, it is determined that gas leakage has occurred at least on the downstream side of the gas meter 12.

When the pressure fluctuation signal is detected and the flow rate signal is not detected, it is determined that gas leakage has occurred on the upstream side of the gas meter 12.

If the flow rate signal is detected without the pressure fluctuation signal being detected, it is determined that the pressure sensor 11 is abnormal.

When the pressure fluctuation signal is not detected and the flow rate signal is not detected, it is determined that there is no gas leakage, that is, normal.

A first embodiment of the gas leakage determination processing will be described with reference to the flowchart of FIG. In this first embodiment, when a gas leak is detected, the display section 16 shows the location of the gas leak.

When the determination process is started and the flow rate signal Q is not detected, the presence or absence of the pressure fluctuation signal P is determined.

Here, if the pressure fluctuation signal P is not detected, since no gas leakage has occurred, it is displayed on the display unit 16 that it is normal, and the process ends. On the other hand, when the pressure fluctuation signal P is detected, since gas leakage has occurred on the upstream side of the gas meter 12, the display unit 16 displays that gas leakage has occurred on the upstream side, and the processing ends. To do.

Next, when the flow rate signal Q is detected, the presence or absence of the pressure fluctuation signal P is determined.

Here, if the pressure fluctuation signal P is not detected, it means that the pressure sensor 11 is abnormal.
A message indicating that an abnormality has occurred is displayed and the processing ends. On the other hand, when the pressure fluctuation signal P is detected, gas leakage has occurred at least on the downstream side of the gas meter 12, so
After operating the shutoff valve 10 to close the gas flow path 9, it is determined whether or not the pressure fluctuation signal P is present.

When the pressure fluctuation signal P is detected, the shutoff valve
Since gas leakage has occurred on the upstream side of 10, the display unit 16 displays that gas leakage has occurred on the upstream side, and the process ends. On the other hand, when the pressure fluctuation signal P is not detected, gas leakage has occurred on the downstream side of the shutoff valve 10, so
The display unit 16 displays that gas leakage has occurred on the downstream side, and the process ends.

As described above, according to the first embodiment, the gas meter 12 is provided in the gas flow passage 9 downstream of the shutoff valve 10, and the pressure sensor 11 is provided in the gas flow passage 9 upstream of the shutoff valve 10. The gas leak is detected by the microcomputer 14 based on the flow rate signal Q transmitted by the flow rate signal transmitter 15 with the output of the pressure sensor 11 and the pressure fluctuation signal P transmitted by the pressure signal transmitter 13 with the output of the pressure sensor 11 as the input. Since it was configured to do so, even though gas appliances are not used,
When the pressure fluctuation signal P is supplied and the flow rate signal Q is supplied, it can be detected that gas leakage has occurred at least on the downstream side of the gas meter 12, and the pressure fluctuation signal P is supplied. When the flow rate signal Q is not supplied, it is possible to detect that gas leakage has occurred on the upstream side of the gas meter 12.

Therefore, in facilities such as hospitals and schools, the distance from the gas storage facility to the gas use facility is long, and the gap is connected by a gas pipe buried underground, and the flow rate sensor is built in the gas meter of the gas use facility or Even if it is fixed on the wall of the facility being used, upstream of the flow sensor,
For example, a gas leak in the buried pipe can be reliably detected.

Further, since the gas leakage can be easily determined, it is possible to detect the gas leakage at an early stage and prevent a serious accident from occurring.

Further, since one set of the pressure sensor 11 and the gas meter 12 may be arranged upstream and downstream of the shutoff valve 10, the intended purpose can be achieved with a simple and inexpensive structure.

Further, when the gas leakage occurs at least on the downstream side of the gas meter 12, the shutoff valve 10 is operated to operate the gas flow path 9
Whether the gas leakage has occurred on the upstream side or the gas leakage has occurred on the downstream side with reference to the shutoff valve 10 depending on the presence or absence of the pressure fluctuation signal P even after closing the
Therefore, by disposing the shutoff valve 10 close to the gas meter 12, it is possible to detect gas leakage between the upstream side and the downstream side with respect to the gas meter 12 as a reference.

A second embodiment of the gas leakage determination process will be described with reference to the time chart of FIG. 8 and the flowchart of FIG.
This second embodiment also determines the use of igniting.

In the microcomputer 14, a predetermined constant signal reception start time, for example, 30 minutes, when the gas appliance is not used and the flow signal from the flow signal transmitter 15 is not detected, the pressure fluctuation from the pressure signal transmitter 13 Start accepting signals. When a pressure fluctuation signal is detected, a timer is started and a predetermined fixed signal interval time, for example,
If the pressure fluctuation signal is continuously detected within 30 minutes, the counting is continued, and when the signal interval time is reached, a leak signal is transmitted. On the other hand, when the pressure fluctuation signal is not detected within the signal interval time, the count is cleared,
The timer is reset and the above processing is repeated. When the gas appliance is restarted within the signal interval time and the flow signal from the flow signal transmitter 15 is detected, the previous count value is cleared, the count is stopped, and the initial stage of the process is started. Return to.

The above-mentioned signal interval time is set in order to prevent a leak signal from being generated due to pressure fluctuations not based on gas leakage, for example, pressure fluctuations due to expansion of the gas pipe due to sunlight or temperature changes. Such pressure fluctuations that are not based on gas leakage occur in a longer cycle than pressure fluctuations that occur due to gas leakage. Therefore, by setting a certain signal interval time, it is assumed that pressure fluctuations that occur continuously within the signal interval time are due to gas leakage, and pressure fluctuations that occur beyond the signal interval time period are caused by factors other than gas leakage. It is judged that it is a pressure fluctuation caused by.

Note that both the signal reception start time and the signal interval time can be appropriately changed and implemented.

When the determination process is started and the flow rate signal Q is not detected, the presence or absence of the pressure fluctuation signal P is determined.

Here, when the pressure fluctuation signal P is not detected, since no gas leakage has occurred, the display unit 16 displays that the state is normal, and then returns to the determination of the presence or absence of the flow rate signal Q. on the other hand,
When the pressure fluctuation signal P is detected, since gas leakage has occurred on the upstream side of the gas meter 12, the display unit 16 displays that gas leakage has occurred on the upstream side, and the process ends.

Next, when the flow rate signal Q is detected, the presence or absence of the pressure fluctuation signal P is determined.

Here, if the pressure fluctuation signal P is not detected, it means that the pressure sensor 11 is abnormal.
A message indicating that an abnormality has occurred is displayed and the processing ends. On the other hand, when the pressure fluctuation signal P is detected, the flow rate signal Q
Determine if is less than 21 liters / h.

Here, it is determined whether or not the flow rate signal Q is less than 21 liters / h, when the gas appliance is using igniting, the gas flow passage 9 normally has a gas flow rate of about 21 liters / h. This is to distinguish the gas flow due to the use of igniting from the gas flow due to the gas leakage.

Then, when the flow rate signal Q is 21 liters / h or more, it is determined that there is no minute leak of gas, and the display unit 16 displays that it is normal. On the other hand, when the flow rate signal Q is less than 21 liters / h, it is determined whether or not the fire is in use based on the registration of the fire.

Here, when the igniting fire is registered, it is assumed that there is no minute leak of gas, and the display unit 16 displays that it is normal. On the other hand, when the igniting is not registered, the determination of the minute leak of gas is made based on the igniting pattern.

Then, when the minute leak matches the spark pattern, the display unit 16 displays that it is normal. On the other hand, if the minute leak does not match the spark pattern, the display unit 16
Since gas leakage has occurred at least in the downstream side of the gas meter 12, the shutoff valve 10 is operated to close the gas flow path 9, and then the presence or absence of the pressure fluctuation signal P is determined.

Here, when the pressure fluctuation signal P is detected, the shutoff valve
Since gas leakage has occurred on the upstream side of 10, the display unit 16 displays that gas leakage has occurred on the upstream side, and the process ends. On the other hand, when the pressure fluctuation signal P is not detected, gas leakage has occurred on the downstream side of the shutoff valve 10, so
The display unit 16 displays that gas leakage has occurred on the downstream side, and the process ends.

As described above, according to the second embodiment, the effect of the first embodiment described above is obtained, and the microcomputer 14 is also configured to determine whether to use the fire.
It is possible to detect a gas leak that also takes into account a spark.

The present invention is not limited to the case of using LP gas,
It can also be applied when using city gas or simple gas.

Further, in the first embodiment, when the flow rate signal Q is detected, the presence or absence of the pressure fluctuation signal P is determined, and when the pressure fluctuation signal P is detected, gas leakage has occurred at least on the downstream side of the gas meter 12. Although the shut-off valve 10 is operated to close the gas passage 9 and then the presence or absence of the pressure fluctuation signal P is determined, the display is made regardless of whether the shut-off valve 10 closes the gas passage 9 or not. The process may be terminated by displaying in the section 16 that gas leakage has occurred at least on the downstream side of the gas meter 12.

<Effects of the Invention> As described above, according to the first aspect of the invention, a flow sensor is provided in a gas flow passage downstream of a shutoff valve, and a pressure sensor is provided in a gas flow passage upstream of a shutoff valve. Since the gas leak is detected by the calculation means based on the flow rate signal transmitted by the flow rate signal transmitter with the output as the input and the pressure fluctuation signal transmitted by the pressure signal transmitter with the output of the pressure sensor as the input, the gas leakage is detected. When the pressure fluctuation signal is supplied and the flow rate signal is supplied even though the device is not used, it is possible to detect that gas leakage has occurred at least on the downstream side of the flow rate sensor. When the pressure fluctuation signal is supplied and the flow rate signal is not supplied, it is possible to detect that gas leakage has occurred on the upstream side of the flow rate sensor.

Therefore, in facilities such as hospitals and schools, the distance from the gas storage facility to the gas use facility is long, and the gap is connected by a gas pipe buried underground, and the flow rate sensor is built in the gas meter of the gas use facility or Even if it is fixed on the wall of the facility being used, upstream of the flow sensor,
For example, a gas leak in the buried pipe can be reliably detected.

Further, since the gas leakage can be easily determined, it is possible to detect the gas leakage at an early stage and prevent a serious accident from occurring.

Also, since one set of pressure sensor and one set of flow rate sensor may be provided upstream and downstream of the shutoff valve, the intended purpose can be achieved with a simple and inexpensive configuration.

[Brief description of drawings]

FIG. 1 is a schematic block diagram showing a gas leakage detection device of the present invention, FIG. 2 is a schematic block diagram showing a conventional gas shutoff device, and FIG. 3 is a side sectional view showing an internal structure of a pressure regulator. The figure shows the pressure fluctuation pattern when a slight leak occurs when a single-stage pressure regulator is used, the figure 5 shows the pressure fluctuation pattern when a slight leak occurs when an automatic switching type pressure regulator is used, and the figure 6 shows a gas leak. 7 is a flow chart of the first embodiment, FIG. 8 is a time chart of the second embodiment,
FIG. 9 is a flowchart of the second embodiment. In the figure, 8 ... Gas leak detection device, 9 ... Gas flow path, 10 ... Shut-off valve, 11 ... Pressure sensor, 12 ... Gas meter, 13 ... Pressure signal transmitter, 14 ... Microcomputer, 15 ... Flow signal transmitter.

Claims (1)

[Claims] 1. A cutoff valve provided in a gas flow path, a flow rate sensor provided in a gas flow path downstream of the cutoff valve for detecting a flow rate of gas flowing in the gas flow path, and the flow rate sensor Flow rate signal transmitter that sends a flow rate signal when a gas flow is detected, a pressure sensor installed in the gas flow path upstream of the shutoff valve to detect the gas pressure in the gas flow path, and a gas sensor based on the output of the pressure sensor. If a pressure signal transmitter that sends a pressure fluctuation signal when a pressure fluctuation is detected and a pressure fluctuation signal is supplied when the flow rate signal is not supplied, gas leakage will occur on the upstream side of the flow sensor. When the flow rate signal and the pressure fluctuation signal are supplied while the gas appliance is not in use, it is determined that at least the gas leakage has occurred at the downstream side of the flow rate sensor. Characterized by Leakage detection device.