JPH0933311A - Resetting method and device for microcomputer fluidic gas meter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To finish the reset confirming work in a short time when a cutoff valve is again opened after it was closed. SOLUTION: The flow of gas is detected by a fluidic element and a flow sensor 6. When an abnormality is detected on the flow rate, a cutoff valve 9 assembled in a meter is driven to cut off the gas in this micro-computer fluidic gas meter. When the cutoff valve 9 is opened for reset, the flow sensor 6 is driven to measure the flow rate multiple times in a short cycle after the flow rate stabilizing time set in advance or after the flow rate measured by the flow sensor 6 is stabilized, and the average value of the flows rate is obtained. The cutoff valve 9 is kept opened when the average value is within a reset condition value set in advance, otherwise, the cutoff valve 9 is closed by a reset confirming circuit.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a return method in a so-called microcomputer fluidic gas meter, which has a function of automatically shutting off gas when an abnormal flow rate or an earthquake occurs in addition to a flow rate measuring function. Regarding the device.

[0002]

2. Description of the Related Art In a microcomputer fluidic gas meter, when a shutoff valve is actuated for some reason to stop gas, it is necessary to restore the shutoff valve as soon as the cause is resolved. As the resetting means, there are a method of manually operating the reset button and a method of automatically resetting the shutoff valve by an electric signal. However, in the case of the above two restoration methods, if they are unconditionally restored as they are, there is a risk that raw gas may leak from the instrument stopper if it is opened. Conventionally, in order to prevent such a danger, in the N-type microcomputer gas meter (membrane gas meter), once the shutoff valve is opened, the gas flow is monitored for 2 minutes and the metering membrane is activated within 2 minutes. Then, when a signal of one pulse is output (see FIG. 5), it is determined that there is a gas leak and the shutoff valve is shut off again. FIG. 6 is a flow chart of the confirmation work accompanying the return of the shutoff valve.

[0003]

However, the above-mentioned confirmation work has the following problems to be solved. a. Since it is necessary to wait for 2 minutes to confirm the return,
It takes time to confirm the restoration. In particular, when a large number of meters are shut off due to an earthquake or the like, if one meter waits for 2 minutes, the recovery work will be greatly delayed. b. In N type No. 7 meter, the capacity of the measuring chamber is large,
No leaks below 50 l / h can be found.

[0004]

[Means for Solving the Problems] The technical means for solving the above problems are as follows. 1. A microcomputer configured to measure the gas flow rate with a fluidic element and a flow sensor, and to automatically shut off the gas by driving the shut-off valve built into the meter when an abnormality is found in the measured flow rate. In the fluidic gas meter, when returning the shutoff valve, first open the shutoff valve and drive the flow sensor multiple times in a short cycle after a certain period of time until the flow rate stabilizes, and measure the flow rate.
Obtain the average value of this measured flow rate, if this average value is within the return condition value, keep the shutoff valve open as it is, otherwise, close the shutoff valve again to drive the microcomputer fluidic gas meter How to return.

[0005] 2. A microcomputer configured to measure the gas flow rate with a fluidic element and a flow sensor, and to automatically shut off the gas by driving the shut-off valve built into the meter when an abnormality is found in the measured flow rate. In the fluidic gas meter, when returning the shutoff valve, first open the shutoff valve and drive the flow sensor in a short cycle to measure the gas flow to check the gas flow stability and stabilize the gas flow. By the way, again measure the flow rate by driving the flow sensor multiple times in a short cycle, calculate the average value of this measured flow rate, if this average value is within the return condition value, keep the shutoff valve open as it is, In other cases, the reset method of the microcomputer fluidic gas meter that drives the shutoff valve to close again.

[0006] 3. The drive cycle of the flow sensor when obtaining the average value of the gas flow rate is set to 1 second intervals 1 or 2
How to reset the described microcomputer fluidic gas meter. 4. 3. The method of resetting a microcomputer fluidic gas meter according to 2 above, wherein when the flow rate of gas is measured immediately after the valve is opened and the flow rate is stabilized, the flow sensor drive cycle is set to 1 second intervals. 5. The method for returning to the microcomputer fluidic gas meter according to 1 or 2 or 3 or 4, which judges that there is a leak and closes the shutoff valve when the average value exceeds 3 l / h.

[0007] 6. Along with detecting the flow rate of gas with a fluidic element and a flow sensor, if an abnormality is found in this flow rate, in a microcomputer fluidic gas meter configured to drive the shutoff valve incorporated in the meter to shut off the gas, When the shut-off valve is opened for restoration, the flow sensor drive circuit is provided to wait for a preset time for stabilizing the flow rate and to drive the flow sensor multiple times in a short cycle after this time elapses. That is, an average value of the flow rates detected by the flow sensor is obtained, and when the average value is within a value set as a return condition value in advance, the shutoff valve is maintained open, and in other cases, the shutoff valve is controlled to be closed. A reset device for a microcomputer fluidic gas meter, which is provided with a reset confirmation circuit.

[0008] 7. Along with detecting the flow rate of gas with a fluidic element and a flow sensor, if an abnormality is found in this flow rate, in a microcomputer fluidic gas meter configured to drive the shutoff valve incorporated in the meter to shut off the gas, When the shutoff valve is opened for recovery, the flow sensor is driven in a short cycle to measure the gas flow rate, and when the measured flow rate is stable, the flow sensor is driven again multiple times in a short cycle. A circuit is provided, the average value of the flow rate detected by the flow sensor is obtained, and when this average value is within the value set as the return condition value in advance, the shutoff valve is kept open, and in other cases, the shutoff valve is opened. A reset device for a microcomputer fluidic gas meter, which is provided with a reset confirmation circuit for controlling to be closed.

8. 8. The recovery device in the microcomputer fluidic gas meter according to 6 or 7 above, wherein the flow sensor drive circuit sets the drive cycle of the flow sensor at the time of obtaining the average value of the flow rate of the gas at an interval of 1 second. 9. 8. The reset device in the microcomputer fluidic gas meter according to 7, wherein the flow sensor drive circuit sets a drive cycle of the flow sensor for monitoring the gas flow to be stable at an interval of 1 second. 10. In the recovery confirmation circuit, the average value of the flow rate is 3 l / h
The recovery device in the microcomputer fluidic gas meter according to 6 or 7 or 8 or 9, which is configured to close the shut-off valve when it is determined that there is leakage.

[0010]

When the reset button is pressed or a reset signal is input to restore the shutoff valve, the shutoff valve opens. After a certain waiting time has passed since the shutoff valve was opened (Claim 1 or Claim 6) or the flow sensor drive circuit drives the flow sensor, for example, at 1 second intervals to measure the flow rate, and this flow rate is stable. When it is recognized that the flow sensor is driven (Claim 2 or Claim 7), the flow sensor driving circuit drives the flow sensor, for example, 3 to 4 times at intervals of 1 second to measure the gas flow rate, and confirms that the measured value is restored. Output to the circuit side. The recovery confirmation circuit is
Obtain the average value of the measured flow rate input from the flow sensor,
When the average value is, for example, 3 l / h or more, the re-shutoff valve is closed, and when it is within the range, the opening operation is maintained as it is, and the return operation is completed.

[0011]

FIG. 1 shows a microcomputer fluidic gas meter embodying the present invention. In FIG. 1, 1 is a fluidic gas meter main body, 2 is a gas inlet, 3 is a metered gas outlet, 4 is a fluidic element, 5 is a nozzle, 6
Is a flow sensor incorporated in the nozzle 5 portion, 7 is a gas flow path from the gas inlet 2 to the nozzle 5, 8 is a valve seat provided in the gas flow path 7, 9 is a shutoff valve, and a shutoff signal is When input, the shut-off valve 9 operates and the valve 10 comes into close contact with the valve seat 8 to shut off gas. Reference numeral 11 denotes a reset button, and when the button 11 is pushed when manually resetting after the shutoff valve 9 is operated, the reset mechanism in the shutoff valve 9 is actuated, the valve 10 is returned to the original state, and the valve seat Open 8 to resume gas flow.

Reference numeral 12 is a measuring unit, which is shown in FIG. 2 together with the function of calculating the flow rate from the fluid vibration (pulse) generated in the fluidic element 4 and the electric signal output from the flow sensor 6. A configuration recovery confirmation circuit 13 is incorporated. In FIG. 2, 14 is a flow sensor drive circuit (flow sensor drive interval control circuit),
When the reset signal of the shutoff valve 9 is input, the flow sensor 6 is first driven at intervals of 1 second, and when the flow rate is stable, the flow sensor 6 is driven 3 to 4 times at intervals of 1 second to measure the flow rate. The drive interval of the flow sensor 6 during normal flow rate measurement is 6 seconds.

Reference numeral 15 denotes a flow rate determination circuit, which calculates an average value of the measured flow rate output from the flow sensor 6 after the flow rate is stabilized, and when this average value is 3 l / h or more, it is determined that there is a gas leak, A signal is sent to the shutoff valve drive circuit 16 to close the shutoff valve 9, and if it does not reach 3 l / h, it is determined that there is no gas leakage, and the shutoff valve 9 is kept open. The above action is
The flow sensor 6 measures the gas flow immediately after opening the valve and confirms that it stabilizes. However, the unstable gas flow immediately after opening the valve is just after opening the valve as shown in FIG. Alternatively, the time until the stabilization may be set in advance as a standby time in a timer, and then the flow sensor 6 may be driven to shift to the gas leak confirmation operation (claim 1 or 6). FIG. 3 is a flow chart of the above-mentioned return leakage confirmation work.

[0014]

As described above, according to the present invention, after the gas flow rate is stabilized at the time of restoration, the flow sensor is driven at an interval shorter than the normal drive interval, for example, 3 to 4 times at an interval of 1 second, and the average thereof is obtained. Since the value is calculated and the presence or absence of leakage is confirmed by this, the time required for recovery confirmation is 6 in total as compared with the conventional method of confirming leakage over 2 minutes.
It takes about 8 seconds, and therefore the leak confirmation work time can be greatly shortened. Therefore, for example, in the event of an earthquake, when the restoration work is performed on a large number of meters, the work time can be greatly shortened, and there is an effect that the restoration is accelerated by this amount.

Further, according to the present invention, since the leak confirmation measurement is performed after the flow rate after opening the valve is stabilized, the accuracy is high. Further, in the present invention, since the flow rate is measured by the flow sensor, it is possible to confirm the leakage in the minute flow rate range.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a microcomputer fluidic gas meter embodying the present invention.

FIG. 2 is an explanatory diagram of a recovery confirmation circuit.

FIG. 3 is a return confirmation flowchart.

FIG. 4 is an explanatory diagram of a gas flow immediately after opening the valve.

FIG. 5 is a recovery confirmation time chart in the membrane gas meter.

FIG. 6 is a flowchart for confirming return in the membrane gas meter.

[Explanation of symbols]

 1 Fluidic Gas Meter Main Body 2 Gas Inlet 3 Gas Outlet 4 Fluidic Element 5 Nozzle 6 Flow Sensor 7 Gas Flow Path 8 Valve Seat 9 Shutoff Valve 10 Valve 11 Reset Button 12 Measuring Section 13 Return Confirmation Circuit 14 Flow Sensor Drive Circuit 15 Flow Rate Judgment Circuit 16 Shut-off valve drive circuit

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Katsuto Sakai 3-2-7-123 Takasago, Katsushika-ku, Tokyo (72) Inventor Shinichi Sato 543-15 Kitano-cho, Hachioji-shi, Tokyo (72) Inventor Toshihiko Ito Aichi Clock Electric Co., Ltd. 1-270, Chitose 1-chome, Atsuta-ku, Nagoya, Aichi Prefecture (72) Inventor Koichi Ueki 1006 Kadoma, Kadoma-shi, Osaka Prefecture Matsushita Electric Industrial Co., Ltd.

Claims (10)

[Claims] 1. A gas flow rate is measured by a fluidic element and a flow sensor, and when an abnormality is found in the measured flow rate, a shut-off valve incorporated in the meter is driven to automatically shut off the gas. In the microcomputer fluidic gas meter configured as above, when returning the shutoff valve, first open the shutoff valve and after a certain period of time until the flow rate stabilizes, measure the flow rate by driving the flow sensor multiple times in a short cycle. Obtain the average value of the measured flow rate, if the average value is within the reset condition value, keep the shutoff valve open, otherwise, close the shutoff valve again.Return the microcomputer fluidic gas meter. Method. 2. The gas flow rate is measured by a fluidic element and a flow sensor, and when an abnormality is found in the measured flow rate, a shut-off valve incorporated in the meter is driven to automatically shut off the gas. In the microcomputer fluidic gas meter configured as described above, when returning the shutoff valve, first open the shutoff valve and drive the flow sensor at a short cycle to measure the gas flow and check the gas flow stability. When the flow is stable, the flow sensor is again driven multiple times in a short cycle to measure the flow rate, and the average value of the measured flow rates is calculated.If this average value is within the reset condition value, the shutoff valve is directly operated. A method of resetting the microcomputer fluidic gas meter that keeps the valve open and otherwise drives the shutoff valve to close again. 3. The driving cycle of the flow sensor when obtaining the average value of the gas flow rate is set to an interval of 1 second.
How to reset the described microcomputer fluidic gas meter. 4. The method of resetting a microcomputer fluidic gas meter according to claim 2, wherein when the gas flow is measured immediately after the valve is opened and the flow rate is stabilized, the drive period of the flow sensor is set to 1 second intervals. 5. The method of resetting a microcomputer fluidic gas meter according to claim 1, 2 or 3 or 4, wherein when the average value exceeds 3 l / h, it is judged that there is a leak and the shutoff valve is closed. 6. A microcomputer configured to detect the flow rate of gas with a fluidic element and a flow sensor, and to drive the shut-off valve incorporated in the meter to shut off the gas when an abnormality is found in this flow rate. In a fluidic gas meter, when the shut-off valve is opened for restoration, the flow sensor waits for the time set in advance as the time for the flow rate to stabilize, and after this time has elapsed, the flow sensor drives the flow sensor multiple times in a short cycle. A drive circuit is provided, the average value of the flow rate detected by the flow sensor is obtained, and when the average value is within a value set as a return condition value in advance, the shutoff valve is kept open, and in other cases, the shutoff valve is opened. A reset device for a microcomputer fluidic gas meter, characterized in that a reset confirmation circuit for controlling the closing of the switch is provided. 7. A microcomputer configured to detect the flow rate of gas by a fluidic element and a flow sensor and, when an abnormality is detected in this flow rate, shut off the gas by driving a shut-off valve incorporated in the meter. In the fluidic gas meter, when the shut-off valve is opened for restoration, the flow sensor is driven in a short cycle to measure the gas flow rate, and when the measured flow rate stabilizes, the flow sensor is re-shot multiple times in a short cycle. A flow sensor drive circuit for driving is provided, the average value of the flow rate detected by the flow sensor is obtained, and when the average value is within a value set as a return condition value in advance, the shutoff valve is maintained open, In the case of, a reset confirmation circuit that controls the shutoff valve to close is provided, and a reset device in a microcomputer fluidic gas meter. 8. The flow sensor drive circuit sets a drive cycle of the flow sensor to 1 when obtaining the average value of the gas flow rate.
The resetting device for a microcomputer fluidic gas meter according to claim 6 or 7, wherein the resetting device is set at an interval of seconds. 9. The reset device for a microcomputer fluidic gas meter according to claim 7, wherein in the flow sensor drive circuit, the drive cycle of the flow sensor for monitoring the stabilization of the gas flow is set at an interval of 1 second. 10. The recovery confirmation circuit is configured to close the shutoff valve by determining that there is a leak when the average value of the flow rate exceeds 3 l / h.
Returning device in the described microcomputer fluidic gas meter.