JP3527345B2 - Shut-off valve control device for gas meter - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shut-off valve control device for a gas meter for controlling a shut-off valve for shutting off a gas flow path at the time of abnormality or the like. 2. Description of the Related Art Some gas meters have a safety function of shutting off a gas flow path when an abnormality occurs using a microcomputer. In this safety function, the microcomputer calculates the flow rate based on the output of the flow rate detection unit, the output of the pressure sensor for detecting the gas supply pressure, the output of the seismic sensor, etc. When it is determined to be abnormal, a shutoff command signal is output to the shutoff valve drive circuit, and the shutoff valve drive circuit that receives the shutoff command signal applies a pulsed shutoff valve drive signal to the solenoid of the shutoff valve. The shut-off valve is set to a shut-off state. When the shut-off valve is not completely closed due to the application of the one-shot shut-off valve driving signal, or when gas flows out downstream of the gas meter due to cracks in the rubber tube or erroneous opening of the gas plug, etc. Then, gas flows out downstream of the gas meter. Therefore, conventionally, the shut-off valve has been controlled as shown in the flowchart of FIG. That is, when the microcomputer determines that there is an abnormality, first, it outputs a shutoff command signal to the shutoff valve drive circuit, and the shutoff valve drive circuit that receives the shutoff command signal outputs a shutoff valve drive signal to the solenoid of the shutoff valve ( Step S201). The application time of the shutoff valve drive signal, that is, the energization time to the solenoid of the shutoff valve is, for example, 40 to 50 ms. Next, the microcomputer monitors the flow rate pulse output from the flow rate detection unit according to the flow rate, and determines whether or not there is a flow rate pulse, that is, whether or not there is a flow rate (step S20).
2). If there is no flow pulse (N), the microcomputer ends the shut-off valve control operation. If there is a flow pulse (Y), the process returns to step S201, where the microcomputer again outputs a shutoff command signal, and the shutoff valve drive circuit outputs a shutoff valve drive signal to the solenoid of the shutoff valve. [0005] However, in the conventional operation as shown in FIG. 5, if the shut-off valve is not completely closed in the first shut-off operation, the second and subsequent shut-off operations are required. In some cases, the shut-off valve may not be completely closed, so that an investigator must be dispatched to investigate the cause and an urgent response is required. Also, in the past, at low temperatures and at the end of battery consumption,
Since the application time of the shut-off valve drive signal to the shut-off valve is set to be longer, there is a problem that power consumption is wasted. The present invention has been made in view of the above problems, and has as its object to reduce the power consumption while ensuring that the shut-off valve is shut off when the gas flow path needs to be shut off. It is an object of the present invention to provide a gas meter shut-off valve control device capable of performing the above operations. A gas meter shut-off valve control device according to the present invention applies a pulse-shaped shut-off valve drive signal to a shut-off valve for shutting off a gas flow path in a gas meter. A shut-off valve driving means for setting the shut-off valve to a shut-off state, a means for detecting whether or not the shut-off valve is completely shut off, and a shut-off valve driving means for shutting off the gas flow path when necessary. the first-time application time of the cutoff valve driving signal and outputs a first time shutoff of for the cut-off state to shut-off valve Te, when a voltage drop, begin to apply the cutoff valve driving signal
The applied voltage of the shut-off valve drive signal
It is the time required to rise and reach the minimum applied voltage.If the detection means detects that the shut-off valve is not completely shut off after the first shut-off command is output, the shut-off command is output again and Control means is provided for making the application time of the shut-off valve drive signal longer when the shut-off command is output again than when the first shut-off command is output. In the gas valve shut-off valve control device of the present invention,
Starts to apply the shut-off valve drive signal when the voltage drops.
The applied voltage of the shut-off valve drive signal
Over the time it takes to rise to the lowest applied voltage,
Since the first drive voltage is applied to the shut-off valve drive means,
The shut-off valve operates reliably and the gas flow path is shut off. Also,
When the shut-down command is output again, it is longer than when the first shut-off command is output.
Also, by increasing the application time of the shut-off valve drive signal,
The shut-off valve operates more reliably and shuts off the gas flow path.
You. Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a sectional view showing a schematic configuration of a gas meter to which a gas meter shut-off valve control device according to a first embodiment of the present invention is applied. The gas meter 10 includes a main body 11, and a gas pipe 12 as a gas flow path having an inlet 12A for receiving the gas a and an outlet 12B for discharging the gas. The gas pipe 12 includes, in order from the inlet 12A side, a shutoff valve 13 for shutting off a gas flow path at the time of an abnormality, a flow detection unit 14 for detecting a flow rate of gas flowing through the gas flow path, and a gas pipe. A pressure sensor 15 for detecting a gas supply pressure via a pressure guide hole 17 provided in the pressure sensor 12 is provided. The flow rate detector 14 outputs a flow rate pulse whose cycle becomes shorter as the flow rate increases. In the main body 11,
A seismic sensor 18 for detecting an earthquake, a flow detector 14,
A control unit 20 is provided for inputting each output signal of the pressure sensor 15 and the seismic sensor 18 and controlling the shutoff valve 13. The shut-off valve 13 has a solenoid which is held by a permanent magnet in the return state, and shifts to the shut-off state when a pulsed shut-off valve drive signal is applied in the return state. Although not shown, a return button for switching the shutoff valve 13 from the shutoff state to the return state is provided on the front surface of the main body 10. FIG. 2 is a block diagram showing the configuration of the control unit 20 and its periphery in FIG. As shown in the figure, the gas meter further includes a display unit 25, and the control unit 20 is connected to the shut-off valve 13, the flow detection unit 14, the pressure sensor 15, the seismic sensor 18, and the display unit 25. Control unit 2
0 is a flow rate calculating section 21 for calculating a flow rate based on the output of the flow rate detecting section 14, an integrating section 22 for calculating an integrated flow rate by integrating the flow rates calculated by the flow rate calculating section 21, and a flow rate calculating section 21. A safety function unit 23 for detecting an abnormality based on each output signal of the pressure sensor 15 and the seismic sensor 18, and a shut-off valve driving circuit 24 for driving the shut-off valve 13 under the control of the safety function unit 23. ing. The safety function unit 23 and the shut-off valve drive circuit 24 constitute a gas meter shut-off valve control device according to the present embodiment, the shut-off valve drive circuit 24 corresponds to the shut-off valve drive unit in the present invention, and the safety function unit 23 It corresponds to the detection means and the control means in the invention. The flow rate calculation unit 21, the accumulation unit 22, and the safety function unit 23 are configured by, for example, a microcomputer. The integrated flow rate calculated by the integrating section 22 is displayed on the display section 25. The safety function unit 23 detects a gas flow rate of a predetermined amount or more based on the output of the flow rate calculation unit 21 or detects a gas flow rate of a predetermined period or more, or sets the gas supply pressure to a predetermined value based on the output of the pressure sensor 15. When it is detected that the value has dropped below the predetermined value, or when an earthquake is detected based on the output of the seismic sensor 18, it is determined that there is an abnormality, and a shutoff command signal is output to the shutoff valve drive circuit 24. , An alarm display such as blinking of an LED (light emitting diode) is issued.
The shut-off valve drive circuit 24 is configured to apply a pulse-like shut-off valve drive signal to the shut-off valve 13 in response to a shut-off command signal from the safety function unit 23, thereby turning off the shut-off valve 13. . The safety function unit 23 can control the application time of the shut-off valve drive signal applied to the shut-off valve 13 by the shut-off valve drive circuit 24.
Is adapted to switch the application time of the shut-off valve drive signal under the control of the safety function unit 23. After the first shutoff command signal is output, the safety function unit 23 monitors the presence or absence of a flow pulse, that is, the presence or absence of a flow rate. If there is a flow pulse, that is, if there is a flow rate, the shutoff valve 13 is completely shut off. It is determined that it is not in the state, and the shut-off command signal is output again to the shut-off valve drive circuit 24. When the shut-off command signal is output again, the application time of the shut-off valve drive signal is longer than when the first shut-off command signal is output. Is increased by, for example, about 1.5 times.
In the present embodiment, in particular, the application time of the shut-off valve drive signal at the time of the first output of the shut-off command signal is set to 50 ms, and the application time of the shut-off valve drive signal at the time of outputting the shut-off command signal again is set to 70 ms. I have. Next, the operation of the gas valve shut-off valve control device according to the present embodiment will be described with reference to the flowchart shown in FIG. The safety function unit 23 outputs a shutoff command signal to the shutoff valve drive circuit 24 when it determines that there is an abnormality based on the outputs of the flow rate calculation unit 21, the pressure sensor 15, and the seismic sensor 18. In response, the shutoff valve drive circuit 24 applies a pulsed shutoff valve drive signal to the shutoff valve 13 (step S101). At this time, the application time of the shutoff valve drive signal to the shutoff valve 13 is 50 msec. Next, the safety function unit 23 monitors the presence or absence of the flow pulse, and determines whether or not there is a flow pulse (step S102). If there is no flow pulse (N), the safety function unit 23
Ends the control operation. If there is a flow pulse (step S102; Y), the safety function unit 23 determines that the shut-off valve 13 is not completely shut off, and sends a shut-off command signal to the shut-off valve driving circuit 24 again. Is output, and the shut-off valve drive circuit 24 again applies the shut-off valve drive signal to the shut-off valve 13 in response to the shut-off command signal (step S103). At this time, the application time of the shut-off valve drive signal to the shut-off valve 13 is 70 msec. Next, the safety function unit 23 monitors the presence / absence of a flow pulse and determines whether or not there is a flow pulse (Step S).
104). When there is no flow pulse (N), the safety function unit 23 ends the operation of controlling the shutoff valve 13. If there is a flow pulse (Y), the safety function unit 23 determines whether or not the output of the cutoff command signal is n or less again (step S105). If the output of the cutoff command signal is n or less (Y), the safety function unit 23 proceeds to step S103.
And outputs the shutoff command signal to the shutoff valve drive circuit 24 again. At this time, the application time of the shut-off valve drive signal to the shut-off valve 13 is 70 msec. The safety function unit 23
When the output of the shutoff valve drive signal is not n times or less again (step S105; N), the display unit 25 is used to
An alarm for notifying the abnormality of the shutoff valve 13 is output (step S106), and the operation of controlling the shutoff valve 13 is terminated. Referring now to FIG. 4, the relationship between the application time of the shut-off valve drive signal to the shut-off valve 13 and the applied voltage will be described. In this figure, reference numeral 31 indicates the relationship between the applied time and the applied voltage under an environment of 20 ° C. when the voltage is normal, for example, when the battery in the gas meter is not at the end of consumption, and reference numeral 32 indicates when the voltage drops. For example, -10 ° C
2 shows the relationship between the application time and the applied voltage in the environment of FIG. Further, V ₀ is the shut-off valve 13
5 shows the minimum applied voltage of the shut-off valve drive signal required to cause the reset state from the return state to the shut-off state. As can be seen from this figure, the applied voltage of the shut-off valve drive signal to the shut-off valve 13 increases with the application time of the shut-off valve drive signal. Also, when the voltage drops, the applied voltage of the shut-off valve drive signal decreases as a whole compared to when the voltage is normal. In the present embodiment, in order to prevent malfunction of the shut-off valve 13 at the time of voltage drop, the application time of the shut-off valve drive signal at the time of the first output of the shut-off command signal is set to the minimum applied voltage even at the time of voltage drop. The time t ₂ (= 50 ms) to reach V ₀ is set. Also, the application time of the cutoff valve driving signal when cut-off command signal output again, is set to t ₂ (= 50 m sec) longer t ₃ than (= 70m sec). As described above, in the gas valve shut-off valve control device according to the present embodiment, the safety function unit 23
After outputting the first shut-off command signal to the shut-off valve drive circuit 24, if the presence or absence of the flow rate is monitored and it is detected that the shut-off valve 13 is not completely shut off, the shut-off valve drive circuit The shut-off valve drive circuit 24 outputs the shut-off command signal to the shut-off valve 13 again and outputs the shut-off command signal again.
, The application time of the shut-off valve drive signal is extended. Thus, when the shutoff command signal is output again, the shutoff valve 13
And the application time of the shut-off valve drive signal to
The applied voltage increases. Therefore, when the shutoff command signal is output again, the shutoff valve 13 can be more reliably set to the shutoff state. Further, since the number of failures due to malfunction of the shut-off valve 13 is reduced, the number of dispatched investigators is reduced. Further, when the first shutoff command signal is output, the shutoff valve 13 is turned off.
However, in many cases, the shut-off valve 13 can be set to the shut-off state when the second shut-off command signal is output, so that the shut-off valve drive signal is repeatedly transmitted to the shut-off valve 13 many times. No voltage is applied, and power consumption can be reduced. Next, a second embodiment of the present invention will be described. In this embodiment, as shown in FIG. 4, the application time of the shut-off valve drive signal at the time of the first output of the shut-off command signal is set to a time t ₁ (for example, when the applied voltage reaches the minimum applied voltage V ₀ when the voltage is normal). 30 ms). Thus, in the present embodiment, the application time of the shutoff valve drive signal at the time of the first shutoff command signal output is shorter when the voltage is normal than in the first embodiment.
In the present embodiment, when the voltage drops, a situation occurs in which the shut-off valve 13 is not completely shut off when the first shut-off command signal is output. However, in many cases, the shut-off valve 13 is reliably turned off when the shut-off command signal is output again. So there is no problem. As described above, according to the present embodiment, it is possible to reduce the power consumption when the voltage is normal, and the effect of reducing the power consumption is increased particularly in a situation where most of the time is normal voltage. Other configurations, operations and effects in the present embodiment are the same as those in the first embodiment. The present invention is not limited to the above embodiments. For example, the detecting means for detecting whether or not the shutoff valve 13 is completely shut off includes a valve body of the shutoff valve 13 and a solenoid. May be used. Further, the application time of the shut-off valve drive signal can be appropriately set according to the specifications of the shut-off valve 13, the environment in which the gas meter is used, and the like. As described above, according to the shut-off valve control device for a gas meter of the present invention, when the voltage drops, the shut- off valve is shut off.
After applying the valve drive signal,
Pressure rises over time to reach the minimum applied voltage
For the first time the shut-off valve drive means
Since the voltage is applied, the shutoff valve is surely shut off
And shut off the gas flow path when necessary.
There is an effect that the cutoff state can be achieved.
When the shut-off valve is not completely shut off after the first shut-off command is output to the shut-off valve driving means , the shut-off command is output again, and when the shut-off command is output again, the first shut-off command is output. By making the application time of the shut-off valve drive signal to the shut-off valve longer than at the time of output ,
Applying a voltage exceeding the minimum applied voltage to the shut-off valve
Since is to allow, it is possible to completely shut off condition the shutoff valve to the second time shutoff time of output often even when the shutoff valve at first time cutoff command output does not become completely blocked state, gas When the flow path needs to be shut off, the shut-off valve can be more reliably set to the shut-off state. Furthermore, since the number of times of application of the shut-off valve drive signal can be reduced and the application time of the shut-off valve drive signal at the time of the first shut-off command output can be shortened, power consumption can be reduced. It has the effect of becoming.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing a schematic configuration of a gas meter to which a gas meter shut-off valve control device according to a first embodiment of the present invention is applied. FIG. 2 is a block diagram showing a configuration of a control unit and its periphery in FIG. 1; FIG. 3 is a flowchart showing an operation of the gas meter cutoff valve control device according to the first embodiment of the present invention. 4 is a characteristic diagram showing a relationship between an application time and an applied voltage of a shutoff valve drive signal to the shutoff valve in FIG. 1; FIG. 5 is a flowchart showing an operation relating to control of a shutoff valve in a conventional gas meter. [Description of Signs] 10 Gas meter 12 Gas pipe 13 Shut-off valve 14 Flow rate detection unit 20 Control unit 21 Flow rate calculation unit 23 Safety function unit 24 Shut-off valve drive circuit

Claims (1)

(57) [Claim 1] A pulse-shaped shut-off valve drive signal is applied to a shut-off valve for shutting off a gas flow path in a gas meter, so that the shut-off valve is turned off. Shut-off valve driving means, means for detecting whether or not the shut-off valve is completely shut off, and setting the shut-off valve to the shut-off valve driving means when the gas flow path needs to be shut off. Output the first shut-off command for the first time and the first application time of the shut-off valve drive signal to start applying the shut-off valve drive signal when the voltage drops.
The applied voltage of the shut-off valve drive signal
It is the time required to rise and reach the minimum applied voltage. If the detection means detects that the shut-off valve is not completely shut off after the first shut-off command is output, the shut-off command is output again. And a control means for making the application time of the shut-off valve drive signal longer at the time of outputting the shut-off command again than at the time of outputting the first shut-off command.