JP3436827B2 - Gas meter - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas meter having a safety function of shutting off gas when an abnormality occurs.

[0002]

2. Description of the Related Art FIG. 8 is an explanatory diagram showing the structure of a gas meter with a safety function equipped with a conventional microcomputer. This gas meter has a housing 100,
In this housing 100, from the inlet portion 111 to the outlet portion 11
A gas flow path 110 up to 2 is provided. Gas channel 1
The valve 10 is provided with a shutoff valve 114 for shutting off gas, a flow rate measuring unit 115 for measuring the flow rate, and a pressure switch 116 for outputting a signal when the pressure is equal to or higher than a predetermined value, in order from the inlet section 111 side. . A control unit 117 using a microcomputer for inputting output signals of the flow rate measuring unit 115 and the pressure switch 116 and controlling the shutoff valve 114 is provided in the housing 100.

In the gas meter shown in FIG. 8, when the flow rate measuring unit 115 detects a gas flow rate of a predetermined amount or more, or when the gas flow rate is detected for a predetermined period of time or more, the control unit 117 controls the gas meter. The shutoff valve 114 is driven to shut off the gas. When the gas is shut off in this way, a gas leak test is performed, and if there is a gas leak, recovery work is performed, and when the abnormality is resolved, a shutoff valve 114 is restored by pressing a return button (not shown). As shown in FIG. 9, when the shutoff valve 114 is restored, the control unit 117 causes the pressure switch 116 to operate the gas flow path 110.
It is monitored whether the internal pressure has recovered to, for example, 60 mmH ₂ O. The pressure recovery monitoring period for this monitoring is about 3 minutes at maximum when the pressure recovery cannot be confirmed. Control unit 1
If the pressure recovery can be confirmed within the pressure recovery monitoring period, 17 confirms the presence or absence of gas leakage based on the output of the flow rate measurement unit 115. Then, when there is no leakage, the normal state in which the gas can be used is entered. If there is a leak, the control unit 117 drives the shutoff valve 114 to shut off the gas again.
When the pressure recovery cannot be confirmed within the pressure recovery monitoring period, the control unit 117 drives the shutoff valve 114 to shut off the gas again.

By the way, there is a shut-off valve that electrically shuts off and returns. Further, some of such shut-off valves have a double valve structure in order to reduce the load at the time of return. The shut-off valve having a double-valve structure has a main valve for covering an opening provided in the gas flow path, a hole provided in the main valve, a sub valve capable of closing the hole, and a hole when shutting off. By urging the auxiliary valve in the closing direction, the main valve covers the opening and the auxiliary valve closes the hole, and when returning, it has a drive means for urging the auxiliary valve in the direction of opening the hole. ,
When returning, the main valve is biased in the direction to cover the opening by the pressure difference when the pressure difference between the upstream side and the downstream side of the opening exceeds a certain value, and is opened by the spring when the pressure difference is below a certain value. It is urged in the direction to open the part. Therefore,
In the shutoff valve of this double valve structure, at the time of return, since the differential pressure between the upstream side and the downstream side of the opening is large at first, the main valve covers the opening and the auxiliary valve opens the hole, and When the pressure difference on the downstream side becomes small, the main valve opens the opening.

[0005]

However, when the shutoff valve having the double valve structure described above is used, after the shutoff valve returns,
When the instrument plug is opened or the gas hose is disconnected, only the hole provided in the main valve is opened at the beginning, so the pressure loss in this hole is large, the pressure does not recover, and the maximum is about 3 minutes. There was a problem that the gas would flow out during the pressure recovery monitoring period.

The present invention has been made in view of the above problems, and an object thereof is to prevent gas outflow by promptly determining that pressure does not recover in pressure recovery monitoring after return of the shutoff valve. It is to provide a gas meter that can be used.

[0007]

A gas meter according to claim 1, wherein a flow rate detecting means for detecting a flow rate of the gas flowing through the gas flow passage, and a shut-off valve for shutting off the gas flow passage in the event of an abnormality are provided.
A pressure sensor provided on the downstream side of the shutoff valve for detecting the pressure of the gas in the gas flow passage, a return means for returning the shutoff valve, and a pressure sensor after the shutoff valve is returned by the return means. It is detected whether the pressure of the gas to be recovered has recovered to a first predetermined value or higher, and the pressure of the gas detected by the pressure sensor does not recover to a second predetermined value which is lower than the first predetermined value. Pressure recovery monitoring means for judging that the gas pressure does not recover when the time continues for a predetermined time or longer, and when the pressure recovery monitoring means detects that the gas pressure has recovered to a first predetermined value or more. In addition, when it is detected that the gas pressure does not recover to the first predetermined value or more by the leak determination means for determining the presence or absence of gas leakage and the pressure recovery monitoring means, the pressure recovery monitoring means determines the gas pressure. When it is determined not recover, and when it is determined that there is gas leakage by leakage determination unit, in which a re-blocking means for blocking the re-gas flow path by driving the shut-off valve.

In this gas meter, after the shut-off valve is restored by the restoring means, the pressure recovery monitoring means detects whether or not the gas pressure has recovered to the first predetermined value or more, and the gas pressure is detected. Second less than first predetermined value
When the time period in which the gas pressure does not recover above the predetermined value continues for the predetermined time period or longer, it is determined that the gas pressure does not recover. When it is detected that the gas pressure has recovered to be equal to or higher than the first predetermined value, the leak determination means determines whether or not there is a gas leak. When the pressure recovery monitoring means detects that the gas pressure does not recover above the first predetermined value, when the pressure recovery monitoring means determines that the gas pressure does not recover, and when there is a gas leak by the leak determining means. When it is determined that the shutoff valve is driven, the shutoff valve is shut off again by the shutoff means. Thus, in the pressure recovery monitoring after the return of the shutoff valve, it is judged that the gas pressure does not recover when the time when the gas pressure does not recover to the second predetermined value or more continues for the predetermined time or longer, thereby determining the double valve structure. Even when the pressure after returning from the shutoff valve is small as in the case of using the shutoff valve, it is possible to quickly determine that the pressure does not recover.

A gas meter according to a second aspect is the gas meter according to the first aspect, wherein the shut-off valve includes a main valve for covering an opening provided in the gas flow passage, and a hole provided in the main valve. , The auxiliary valve that can close this hole and the auxiliary valve in the direction of closing the hole when shut off, so that the main valve covers the opening and the auxiliary valve closes the hole, and when returning, the hole is opened. Drive means for urging the sub-valve in the direction to move the main valve in the direction of covering the opening by the pressure difference when the pressure difference between the upstream side and the downstream side of the opening exceeds a certain value when returning. When the pressure difference is equal to or less than a certain value, the opening is opened.

[0010]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 2 is a sectional view showing the structure of a gas meter according to an embodiment of the present invention. The gas meter comprises a body 10 having an inlet 11 for receiving gas and an outlet 12 for discharging gas. A partition wall 13 is provided in the main body 10.
Is provided, a gas flow path 14 is formed between the partition wall 13 and the inlet portion 11, and a gas flow path 15 is formed between the partition wall 13 and the outlet portion 12. An opening 16 is provided in the partition wall 13, and a shutoff valve 50 that can close the opening 16 is provided on the upstream side of the opening 16.

In the gas passage 15, there is provided a nozzle 21 which allows the gas received from the inlet 11 to pass therethrough to generate a jet flow. A flow sensor 30 which is a thermal type flow velocity sensor is arranged in the passage of the nozzle 21. Although not shown, the flow sensor 30 has a heat generating part and two temperature sensors arranged on the upstream side and the downstream side of the heat generating part, and keeps a constant temperature difference detected by the two temperature sensors. Therefore, the flow rate corresponding to the flow velocity is calculated from the power supplied to the heat generating section, or the heat generating section is heated with a constant current or constant power, and the flow rate is calculated from the temperature difference detected by the two temperature sensors. There is. In addition,
The flow sensor 30 is not limited to the one having the heat generating part and the two temperature sensors as described above, but has, for example, one heat generating part and generates heat required to keep the temperature (resistance) of the heat generating part constant. To obtain the flow velocity from the power supplied to the part,
It is also possible to heat the heat generating portion with a constant current or constant power and obtain the flow velocity from the temperature (resistance) of the heat generating portion.

On the downstream side of the nozzle 21, a pair of side walls 23 and 24 forming an enlarged flow path are provided. A target 25 is provided on the upstream side and a target 26 is provided on the downstream side with a predetermined gap between the side walls 23 and 24. A return guide 29 is formed outside the side walls 23 and 24 to form a pair of feedback flow paths 27 and 28 for returning the gas passing through the nozzle 21 to the ejection port side of the nozzle 21 along the outer peripheral portions of the side walls 23 and 24. Is provided. A pair of discharge passages 31 and 32 are formed between the outlet portions of the feedback flow passages 27 and 28 and the outlet portion 12 by the back surface of the return guide 29 and the main body 10. A pressure guiding hole 3 is provided in the vicinity of the nozzle 21 ejection port.
3, 34 are provided, and a piezoelectric film sensor 35 (not shown in FIG. 2) for detecting the pressure difference between the pressure guiding hole 33 and the pressure guiding hole 34 is provided outside the bottom portion of the main body 10.

The main body 10 is provided with pressure guiding holes 39 communicating with the gas flow passage 15 on the upstream side of the nozzle 21, and the gas in the gas flow passage 15 is provided outside the main body 10 via the pressure guiding holes 39. A pressure sensor 40 that detects pressure is provided.

FIG. 1 is a block diagram showing the configuration of the circuit portion of the gas meter shown in FIG. As shown in this figure,
The gas meter is an A / D that converts the output signal of the flow sensor 30 from analog to digital (hereinafter referred to as A / D).
A converter 41, an analog amplifier 42 that amplifies the output signal of the piezoelectric film sensor 35, and a waveform shaping circuit 43 that shapes the output of the analog amplifier 42 to generate a pulse.
And a flow rate calculation unit 44 that inputs the output of the A / D converter 41 and the output of the waveform shaping circuit 43 and calculates the flow rate and the integrated flow rate based on at least one of the outputs according to the flow rate, and the flow rate calculation unit 44. And a display unit 45 that displays the integrated flow rate calculated by. The flow rate calculation unit 44 calculates the flow rate and the integrated flow rate based on the output of the flow sensor 30 (the output of the A / D converter 41) in the small flow rate range in which the range is set in advance, and the large flow rate in which the range is set in advance. In the region, the flow rate and the integrated flow rate are calculated based on the output of the piezoelectric film sensor 35 (output of the waveform shaping circuit 43).

The gas meter further determines the presence or absence of gas leakage based on the shutoff valve drive circuit 46 for driving the shutoff valve 50 and the flow rate calculated by the flow rate calculation unit 44, and drives the shutoff valve when it is determined that there is a leak. The circuit 46 is controlled to drive the shutoff valve 50 to shut off the gas, and at the same time, the leakage determination unit 47 that issues an alarm display on the display unit 45 and the shutoff valve drive circuit 46.
A return switch 48 for instructing the return of the shutoff valve 50 and a signal from the return switch 48,
After the shutoff valve 50 is restored, a pressure recovery monitor 49 is provided for monitoring whether or not the gas pressure has recovered to a predetermined value based on the output of the pressure sensor 40. Flow rate calculation unit 44,
The leak determination unit 47 and the pressure recovery monitoring unit 49 are configured by, for example, a microcomputer.

After the shutoff valve 50 is restored, the pressure recovery monitoring unit 49 operates for a maximum pressure recovery monitoring period of, for example, 3 minutes.
It is detected whether the pressure of the gas detected by the pressure sensor 40 has recovered to a _first predetermined value P ₁ , for example, 60 mmH ₂ O or more, and the pressure of the gas detected by the pressure sensor 40 is the first predetermined value. If the time period in which the gas pressure does not recover to the second predetermined value P ₂ which is smaller than the value P ₁ continues for a predetermined time period or more, it is determined that the gas pressure will not recover even before the pressure recovery monitoring period elapses.

When the pressure recovery monitoring unit 49 detects that the gas pressure has recovered to a predetermined value P ₁ or higher, the leakage determination unit 47 determines whether or not there is a gas leak based on the presence or absence of the flow rate calculated by the flow rate calculation unit 44. It is designed to judge. In the leakage determination unit 47, when the pressure recovery monitoring period has elapsed, the pressure recovery monitoring unit 49 causes the gas pressure to reach a predetermined value P ₁
When it is detected that the recovery does not occur, the pressure recovery monitoring unit 49 determines that the gas pressure will not recover before the pressure recovery monitoring period elapses, and the pressure recovery monitoring unit 4
When the recovery of the gas pressure is detected by 9 and it is determined that there is a gas leak, the shut-off valve drive circuit 46 is controlled to drive the shut-off valve 50 to shut off the gas again, and an alarm is displayed on the display unit 45. It is designed to output. After the shutoff valve 50 returns, when the pressure recovery monitoring unit 49 detects that the gas pressure has recovered and the leakage determination unit 47 determines that there is no gas leakage, the gas is in a normal state in which it can be used. The leak determination unit 47 corresponds to the leak determination means and the re-cutoff means in the present invention.

3 to 5 show the structure and operation of the shutoff valve 50. As shown in FIG. As shown in these drawings, the shutoff valve 50 includes a housing 51 fixed to the outside of the main body 10 of the gas meter. The housing 51 has a hollow portion, and the permanent magnet 5 is provided at the rear end in the hollow portion.
2 is provided, and further, a core piece 53 joined to the front end of the permanent magnet 52 is provided. Housing 5
In the hollow part of No. 1, a plunger 54 made of a magnetic material
Has been inserted. Inside the housing 51, a coil 55 serving as an electromagnet is provided. The plunger 54 has three parts having a diameter smaller toward the tip side, that is, a small diameter part 54a on the tip side, a middle diameter part 54b in the center, and a large diameter part 54c on the rear end side. . Between the small diameter portion 54a and the medium diameter portion 54b, and between the medium diameter portion 54b and the large diameter portion 54c, tapered surfaces having gradually changing diameters are formed. The taper surface between the small diameter portion 54a and the medium diameter portion 54b constitutes a sub valve 56.

The shutoff valve 50 further includes a main valve 57 that abuts on a valve seat 16a formed around the opening 16 and covers the opening 16. The main valve 57 has a ring-shaped support member 57a and a rubber valve body 57b fixed to the front end surface of the support member 57a. Rubber valve body 57b
A hole 58 having an inner diameter larger than the outer diameter of the small-diameter portion 54a and smaller than the outer diameter of the medium-diameter portion 54b is provided in the central portion of the. The small diameter portion 54a of the plunger 54 is inserted into the hole 58. On the rear end side of the rubber valve body 57b, a tapered surface whose inner diameter is gradually increased is formed continuously with the hole 58, and the auxiliary valve 56 formed on the plunger 54 abuts on this tapered surface, Sub valve 56
The hole 58 is closed by the. A spring 59 that biases the main valve 57 toward the opening 16 is provided around the middle diameter portion 54b between the rear end surface of the support member 57a and the inner wall of the main body 10. A flange member 61 is fixed to the tip of the small diameter portion 54a, and the small diameter portion 54a is surrounded by the flange member 61 and the rubber valve body 57b.
A spring 62 that biases the main valve 57 toward the side opposite to the opening 16 is provided.

This shut-off valve 50 is normally used for the coil 5
5, the plunger 54 moves the core piece 5 into the core piece 5 due to the magnetic force of the permanent magnet 52, as shown in FIG.
Adsorbed on 3. Further, the force of the spring 62 is stronger than the force of the spring 59, and the balance of the spring load allows the main valve 57 to open the opening 56 and allow the gas to pass through the opening 16. To shut off the gas from this state,
A current is passed through the coil 55 so as to cancel the magnetic force of the permanent magnet 52, and the force of the spring 59 causes the plunger 54 to project, as shown in FIG. As a result, the main valve 57 covers the opening 56, the auxiliary valve 56 closes the hole 58, and the gas is shut off. When the shutoff valve 50 is returned from this state, an electric current is applied to the coil 55 in the direction opposite to that at the time of shutoff, and the plunger 54 is attracted to the core piece 53 side as shown in FIG. At the time of this restoration, the opening 1 is initially
Since the pressure on the upstream side of 6 is larger than the pressure on the downstream side and the pressure difference between the two is large, the pressure difference urges the main valve 57 in the direction to cover the opening 16. Therefore, at the beginning, the main valve 5
7 covers the opening 16 and the auxiliary valve 56 opens the hole 58, and the gas flows through the hole 58 to the downstream side of the opening 16. When the pressure difference between the upstream side and the downstream side of the opening 16 becomes smaller, the spring 62 becomes stronger than the biasing force due to the pressure difference.
The urging force of the main valve 57 becomes larger than the opening 1
6 and the main valve 57 is in the state shown in FIG. 3 in which the opening 56 is opened.

Next, the operation of the gas meter of this embodiment will be described.

The gas received from the inlet 11 of the gas meter is supplied to the gas passage 14, the opening 16 and the gas passage 1.
After going through 5 in order, it enters the nozzle 21. The output signal of the flow sensor 30 arranged in the passage of the nozzle 21 is converted into digital data by the A / D converter 41 and the flow rate calculation unit 4
4 is input. The flow rate calculation unit 44 is A /
The flow rate and the integrated flow rate are calculated based on the output of the D converter 41. The display unit 45 displays the integrated flow rate calculated by the flow rate calculation unit 44.

The gas passing through the nozzle 21 becomes a jet stream and is jetted from the jet outlet. The gas ejected from the ejection port flows along one side wall due to the Coanda effect. Here, it shall first flow along the side wall 23. The gas flowing along the side wall 23 is further returned to the ejection port side of the nozzle 21 via the feedback flow path 27.
It is discharged from the outlet 12 via the discharge passage 31. At this time, the gas ejected from the nozzle 21 is changed in direction by the gas flowing through the feedback flow path 27, and now flows along the other side wall 24. This gas further passes through the feedback flow path 28, and the nozzle 21
Is discharged to the jet outlet side of the nozzle, and is discharged from the outlet portion 12 via the discharge passage 32. Then, the direction of the gas ejected from the nozzle 21 is changed by the gas flowing through the feedback flow path 28, and the gas flows again along the side wall 23 and the feedback flow path 27. By repeating the above operation, the gas passing through the nozzle 21 performs fluidic oscillation which alternately flows through the pair of feedback flow paths 27 and 28. The frequency of this fluidic oscillation,
The cycle has a relationship with the flow rate.

The fluidic oscillation is detected by the piezoelectric film sensor 35, the output of the piezoelectric film sensor 35 is amplified by the analog amplifier 42, pulsed by the waveform shaping circuit 43, and input to the flow rate calculation unit 44. The flow rate calculation unit 44 calculates the flow rate and the integrated flow rate based on the output of the waveform shaping circuit 43 in the large flow rate range.

The leakage determination unit 47 controls the shut-off valve drive circuit 46 in the event of an abnormality such as when the flow rate calculation unit 44 detects a gas flow rate of a predetermined amount or more, or when the gas flow rate is detected for a predetermined period or more. Then, the shutoff valve 50 is changed from the state shown in FIG. 3 to the state shown in FIG. 4 to shut off the gas, and an alarm display is displayed on the display unit 45. When the gas is shut off in this way, a gas leak test is performed, and if there is a gas leak, recovery work is performed. When the abnormality is resolved, the return switch 48 is pressed to turn off the shut-off valve 5 to the shut-off valve drive circuit 46.
Instruct to return 0. In response to this instruction, the shutoff valve drive circuit 46 changes the shutoff valve 50 from the state shown in FIG. 4 to the state shown in FIG. 5, and restores the shutoff valve 50.

As shown in FIG. 6, when the shutoff valve 50 is restored, the pressure recovery monitoring unit 49 controls the gas pressure detected by the pressure sensor 40 during the pressure recovery monitoring period of, for example, 3 minutes at maximum. A predetermined time P ₁ is detected, for example, 60 mmH ₂ O or more, and the gas pressure detected by the pressure sensor 40 is less than the predetermined value P ₁ and is not recovered to a predetermined value P ₂ or more for a predetermined time. If it continues for more than time, it is judged that the gas pressure does not recover even before the pressure recovery monitoring period has elapsed. The leak determination unit 47 determines that the pressure recovery monitoring unit 49 determines that the gas pressure does not recover before the pressure recovery monitoring period elapses, and that the pressure recovery monitoring period elapses and the pressure recovery monitoring unit 49 determines that the gas pressure does not recover. When it is detected that the predetermined value P ₁ or more is not recovered,
The shutoff valve drive circuit 46 is controlled to drive the shutoff valve 50 to shut off the gas again, and at the same time, an alarm display is displayed on the display unit 45.

FIG. 7 shows a change in gas pressure after the shutoff valve 50 returns. Reference numeral 71 indicates a gas flow downstream of the gas meter, and 72 indicates a gas flow downstream of the gas meter. It shows the case where there is an outflow. As shown in this figure, after the shutoff valve 50 returns, if there is no gas outflow on the downstream side of the gas meter, the gas pressure increases with the passage of time and recovers to a predetermined value P ₁ or more. When there is a gas outflow on the downstream side, the gas pressure increases slightly at the beginning, but does not increase thereafter. Therefore, the predetermined value P ₂ is set to a value smaller than the predetermined value P ₁ and larger than the gas pressure when there is gas outflow on the downstream side of the gas meter, and after the shutoff valve 50 returns, the gas pressure is set to a predetermined value. If the time for which the gas pressure does not recover to the value P ₂ or more continues, it can be determined that the gas pressure does not recover. Therefore, in the present embodiment, when the pressure recovery monitoring unit 49 does not recover the gas pressure detected by the pressure sensor 40 to the predetermined value P ₂ or higher for a predetermined time T or longer as shown in FIG. It is determined that the gas pressure does not recover even before the pressure recovery monitoring period elapses. Specifically, the predetermined time T
The gas pressure detected by the pressure sensor 40 may be sampled every time, and it may be determined that the gas pressure does not recover when the pressure at the time of the first sampling is less than the predetermined value P ₂ , or at each sampling. It may be determined that the pressure of the gas is not recovered when the state in which the pressure is less than the predetermined value P ₂ continues for a plurality of times. Here, the predetermined time T is set to 5 seconds, for example. Further, the predetermined value P ₂ is set when the gas pressure is sufficiently higher than the gas pressure within a predetermined time T when there is no outflow of gas on the downstream side of the gas meter, and when there is outflow of gas on the downstream side of the gas meter. The gas pressure is set to a value that does not exceed this.

When the pressure recovery monitoring unit 49 detects that the gas pressure has recovered to the predetermined value P ₁ or higher, the leakage determination unit 47 determines the flow rate during the next leakage confirmation period as shown in FIG. The presence / absence of gas leakage is determined based on the presence / absence of the flow rate calculated by the calculation unit 44. If it is determined that there is a gas leak, the shut-off valve drive circuit 46 is controlled to drive the shut-off valve 50 to shut off the gas again, and an alarm display is displayed on the display unit 45. When it is determined that there is no gas leakage, the gas is in a normal state in which it can be used.

As described above, in the present embodiment, after the shutoff valve 50 returns, the pressure recovery monitoring unit 49 sets a predetermined time period during which the gas pressure detected by the pressure sensor 40 does not recover to the predetermined value P ₂ or more. If you continue for more than an hour,
It is determined that the gas pressure will not recover even before the pressure recovery monitoring period has elapsed, and the gas is shut off. After the shutoff valve 50 returns, when the gas does not flow out on the downstream side of the gas meter, the time required for the gas pressure to recover to the predetermined value P ₂ or more is:
Since it is shorter than the time for the gas pressure to recover to the predetermined value P ₁ or higher, it is possible to quickly determine that the gas pressure will not recover. Therefore, according to the present embodiment, even when the pressure after the return of the shutoff valve 50 is small as in the case of using the shutoff valve 50 of the double valve structure as shown in FIGS. In the pressure recovery monitoring after the recovery, it is possible to quickly judge that the pressure is not recovered and prevent the gas from flowing out.

Further, according to this embodiment, when the gas pressure detected by the pressure sensor 40 recovers to a predetermined value P ₂ or more within a predetermined time after the shutoff valve 50 returns, the pressure recovery monitoring unit It is configured to detect whether or not the gas pressure has recovered to a predetermined value P ₁ or more by 49, and to judge the presence or absence of gas leakage when the gas pressure has recovered to a predetermined value P ₁ or more. The presence / absence can be accurately determined.

[0032]

As described above, according to the gas meter of the present invention, in the pressure recovery monitoring after the return of the shut-off valve, it is detected whether or not the pressure of the gas has recovered to the first predetermined value or more, and If the pressure of is not recovered to the second predetermined value which is smaller than the first predetermined value continues for a predetermined time or more, it is determined that the gas pressure is not recovered and the gas flow path is shut off. Even when the pressure after returning to the shutoff valve is small, such as when a shutoff valve with a double valve structure is used, it is possible to quickly judge that the pressure will not recover and prevent the gas from flowing out. .

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a gas meter according to an embodiment of the present invention.

FIG. 2 is a sectional view showing a configuration of a gas meter according to an embodiment of the present invention.

3 is a cross-sectional view showing a normal state of the shutoff valve in FIG.

FIG. 4 is a cross-sectional view showing a state when the shutoff valve in FIG. 1 is shut off.

5 is a cross-sectional view showing a state immediately after the cutoff valve in FIG. 1 is restored.

FIG. 6 is an explanatory diagram showing an operation of the gas meter according to the embodiment of the present invention after the shutoff valve is returned.

FIG. 7 is a characteristic diagram showing a change in gas pressure after the shutoff valve is restored in the gas meter according to the embodiment of the present invention.

FIG. 8 is an explanatory diagram showing a configuration of a conventional gas meter.

FIG. 9 is an explanatory diagram showing an operation of the conventional gas meter after returning from the shutoff valve.

[Explanation of symbols]

30 flow sensor 35 Piezoelectric film sensor 40 pressure sensor 44 Flow rate calculator 45 Display 46 Shut-off valve drive circuit 47 Leakage judgment part 48 Return switch 49 Pressure recovery monitor 50 shutoff valve

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-6-117955 (JP, A) JP-A-5-240216 (JP, A) JP-A-51-118133 (JP, A) Patent 3051577 (JP, B2) Patent 2837082 (JP, B2) (58) Fields investigated (Int.Cl. ⁷ , DB name) G01F 3/22 G01F 1/00 G01F 1/20

Claims (2)

(57) [Claims] 1. A flow rate detecting means for detecting a flow rate of gas flowing through a gas flow path, a shut-off valve for shutting off the gas flow path in the event of an abnormality, and a shut-off valve provided downstream of the shut-off valve, A pressure sensor for detecting the pressure of gas, a return means for returning the shutoff valve, and a pressure of the gas detected by the pressure sensor after the shutoff valve is returned by the return means is equal to or higher than a first predetermined value. If the gas pressure detected by the pressure sensor is not recovered to a second predetermined value smaller than the first predetermined value and continues for a predetermined time or more, the gas is detected. Pressure recovery monitoring means for determining that the pressure of the gas does not recover, and leakage determination for determining the presence or absence of gas leakage when the pressure recovery monitoring means detects that the gas pressure has recovered to a first predetermined value or higher. hand When the pressure recovery monitoring means detects that the gas pressure does not recover to a first predetermined value or more, when the pressure recovery monitoring means determines that the gas pressure does not recover, and the leakage determination A gas meter, comprising: a re-shutoff means for driving the shut-off valve to shut off the gas flow path again when the means determines that there is a gas leak. 2. The shutoff valve includes a main valve for covering an opening provided in a gas flow path, a hole provided in the main valve, a sub valve capable of closing the hole, and a shutoff valve when shutting off. By urging the auxiliary valve in the direction of closing the hole, the main valve covers the opening and the auxiliary valve closes the hole, and at the time of return, the drive means for urging the auxiliary valve in the direction of opening the hole. The main valve is urged in a direction to cover the opening by the differential pressure when the differential pressure between the upstream side and the downstream side of the opening exceeds a certain value at the time of return, and the differential pressure is below a certain value. 2. The gas meter according to claim 1, wherein the gas meter is biased in a direction to open the opening.