JP3375452B2 - Abnormality detection device in 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 abnormality detecting device for detecting abnormality such as gas leakage in a gas meter.

[0002]

2. Description of the Related Art A conventional gas leak detection method for a gas meter with a safety function equipped with a microcomputer is to judge a gas leak when it is detected that gas is flowing continuously for 30 days or more, and an alarm is displayed. Was to do. However, when the gas is flowing continuously for 30 days or more, in addition to the gas leakage, the gas appliance may be left ignited. Therefore, in order to distinguish between gas leakage and igniting, the flow rate of igniting can be registered in the microcomputer. After registering the pilot flame is gas meter as shown in FIG. 7, if the flow rate of the registered pilot flame was Q _E, determines that pilot flame flow in the range of Q _E ± Delta] Q, the flow rate of this range for more than 30 days No alarm is displayed even if the flow is continuous.

[0003]

However, in the above-mentioned gas leakage detection method, it is necessary to detect gas leakage in 30
There is a problem that it takes days and it is not possible to detect gas leakage at a flow rate within a range determined to be igniting.

The present invention has been made in view of the above problems, and an object thereof is to provide an abnormality detecting device in a gas meter capable of detecting an abnormality such as gas leakage in a short time.

[0005]

An abnormality detecting device for a gas meter according to claim 1 is provided in the gas meter,
Flow rate detection means for detecting the flow rate of gas, ignition sound detection means provided in the gas meter for detecting the ignition sound of the gas appliance connected to the gas meter, and flow rate without the ignition sound being detected by the ignition sound detection means. An abnormality determining means for determining an abnormality when the flow rate is detected by the detecting means is provided.

In the abnormality detecting device for the gas meter, the flow rate detecting means detects the flow rate of the gas, and the ignition sound detecting means detects the ignition sound of the gas appliance connected to the gas meter. The abnormality determining means determines that there is an abnormality when the flow rate detecting means detects the flow rate without detecting the ignition sound by the ignition sound detecting means.

An abnormality detecting device for a gas meter according to a second aspect of the present invention is provided in the gas meter, and detects a flow rate detecting means for detecting a gas flow rate and an ignition sound of a gas appliance provided in the gas meter and connected to the gas meter. Ignition sound detecting means for detecting, and for each gas appliance connected to the gas meter, a storage means for storing the ignition sound detected by the ignition sound detecting means and the flow rate detected by the flow rate detecting means after ignition in association with each other. When the ignition sound is not detected by the ignition sound detecting means and the flow rate is detected by the flow rate detecting means, and after the ignition sound is detected by the ignition sound detecting means, it is stored in the storage means as a flow rate corresponding to the ignition sound. And an abnormality determining means for determining an abnormality when a flow rate other than the specified flow rate is detected by the flow rate detecting means.

In this abnormality detecting device in the gas meter, the flow rate detecting means detects the flow rate of the gas, the ignition sound detecting means detects the ignition sound of the gas appliance connected to the gas meter, and the storing means connects the gas meter to the gas meter. The ignition sound detected by the ignition sound detector and the flow rate detected by the flow rate detector after ignition are stored in association with each other for each gas appliance. The abnormality determining means determines the flow rate corresponding to the ignition sound when the flow rate detecting means detects the flow rate without detecting the ignition sound and after the ignition sound detecting means detects the ignition sound. When a flow rate other than the flow rate stored in the storage means is detected by the flow rate detection means, it is determined to be abnormal.

The abnormality detecting device in the gas meter according to claim 3 is the abnormality detecting device in the gas meter according to claim 2, wherein the abnormality determining means does not detect the ignition sound by the ignition sound detecting means and detects the flow rate by the flow rate detecting means. When it is detected, it is judged as a gas leak, and after the ignition sound is detected by the ignition sound detection means, a flow rate other than the flow rate stored in the storage means as the flow rate corresponding to the ignition sound is detected by the flow rate detection means. It is sometimes configured to judge that the gas appliance is abnormal.

An abnormality detecting device for a gas meter according to a fourth aspect is the abnormality detecting device for a gas meter according to the third aspect, wherein the abnormality determining means further determines that the gas appliance is being used without being determined to be abnormal, When the ignition sound is not detected by the ignition sound detecting means and a flow rate other than the flow rate stored in the storage means as the flow rate corresponding to the gas appliance being used is detected by the flow rate detecting means, it is determined that there is a gas leak. It is configured as follows.

[0011]

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

FIG. 1 is a sectional view showing the structure of a gas meter to which an abnormality detecting device for a gas meter according to an embodiment of the present invention is applied. 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, a gas flow channel 14 is formed between the partition wall 13 and the inlet portion 11, and a gas flow channel 15 is disposed between the partition wall 13 and the outlet portion 12.
Are formed. In the gas flow path 14, a microphone 40 is provided as an ignition sound detecting means for detecting an ignition sound of a gas appliance connected to the gas meter. An opening 16 is provided in the partition wall 13, and a cutoff valve 17 capable of closing the opening 16 is provided in the gas flow path 14. Body 1
A solenoid 18 is fixed to the outside of 0, and a plunger 19 of the solenoid 18 penetrates a side wall of the main body 10 and is joined to a shutoff valve 17. A spring 20 is provided around the plunger 19 between the shutoff valve 17 and the main body 10, and the spring 20 biases the shutoff valve 17 toward the opening 16.

In the gas passage 15, there is provided a nozzle 21 for passing the gas received from the inlet portion 11 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.

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. 1) for detecting a 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.

FIG. 2 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 gas meter further inputs the shutoff valve drive circuit 47 for driving the solenoid 18, the output of the microphone 40 and the output of the flow rate calculation unit 44, detects an abnormality based on these outputs, and turns off the shutoff valve drive circuit 47. An abnormality detection unit 46 that controls and displays an alarm on the display unit 45 is provided. Flow rate calculation unit 44 and abnormality detection unit 4
Part of 6 is composed of, for example, a microcomputer. The flow rate calculation unit 44 calculates the flow rate and the integrated flow rate based on the output of the A / D converter 41 in the small flow rate range in which the range is set in advance, and the waveform shaping circuit 43 in the large flow rate range in which the range is set in advance. Calculate the flow rate and integrated flow rate based on the output.

FIG. 3 is a block diagram showing the structure of the abnormality detecting section 46 in FIG. The abnormality detection unit 46 includes a filter 51 such as a multi-channel bandpass filter that extracts a plurality of frequency components from the output signal of the microphone 40, and an ignition sound detected by the microphone 40 based on the output signal of the filter 51. Is input to the frequency conversion unit 52 for converting the frequency characteristic to the frequency characteristic, and the output of the frequency conversion unit 52 and the flow rate calculated by the flow rate calculation unit 44. Register /
The determination control unit 53 and a storage unit 54 that stores the frequency characteristics and the flow rate of the ignition sound registered by the registration / determination control unit 53 are provided. The registration / judgment control unit 53 registers the frequency characteristic of the ignition sound detected by the microphone 40 and the flow rate after ignition in the storage unit 54 in association with each other for each gas appliance connected to the gas meter. There is.
The frequency conversion unit 52, the registration / judgment control unit 53, and the storage unit 54 are composed of, for example, a microcomputer. The microphone 40, the flow rate calculation unit 44, and the abnormality detection unit 46 illustrated in FIG. 3 configure an abnormality detection device in the gas meter according to the present embodiment.

FIG. 4 conceptually shows the contents stored in the storage unit 54. In this way, the storage unit 54 stores
Gas appliances (A, B, C ...) connected to the gas meter
Frequency characteristics of ignition sound (F _A , F _B , F _C …) and flow rates after ignition (Q _A1 , Q _B1 , Q _B2 , Q _C1 , Q _C2 , Q _C3 …)
Are stored in association with each other. For gas appliances with a substantially constant flow rate after ignition, such as a water heater, only one flow rate after ignition is stored, but for gas appliances with proportional control that perform control according to the load, such as heating appliances. In this case, since the flow rate after ignition changes, a plurality of flow rates are stored.

The abnormality detecting section 46 controls the shutoff valve drive circuit 47 to close the shutoff valve 17 to shut off the gas when it is judged that there is a gas leak, and the display section 45 when the gas appliance is judged to be abnormal. It is designed to give an alarm display.

An outline of the operation of the gas meter shown in FIGS. 1 and 2 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.

Next, the operation of the abnormality detecting device in the gas meter according to this embodiment will be described.

The microphone 40 detects the ignition sound of the gas appliance connected to the gas meter, the filter 51 of the abnormality detecting section 46 extracts a plurality of frequency components from the output signal of the microphone 40, and the output signal of the filter 51. Based on the above, the frequency converter 52 converts the ignition sound detected by the microphone 40 into its frequency characteristic.

The registration / judgment control unit 53 of the abnormality detection unit 46 is maintained for a predetermined period, for example, one month after the gas meter is attached.
The storage unit 54 correlates the frequency characteristic of the ignition sound with the flow rate after ignition for each gas appliance connected to the gas meter.
Perform the operation to register to. That is, the registration / determination control unit 5
When the frequency conversion unit 52 outputs the frequency characteristic of the ignition sound that is not registered in the storage unit 54, a new gas appliance item is provided in the storage unit 54, and the frequency characteristic of the ignition sound is stored in the item 3. Register the flow rate after ignition. In the case of a proportionally controlled gas appliance, since the flow rate after ignition changes, the registration / determination control unit 53 monitors the flow rate even after registering the flow rate immediately after ignition in the storage unit 54, and the flow rate changes by a predetermined amount or more. Each time, the changed flow rate is registered.

When a predetermined period of time has passed after the gas meter was attached, the registration / judgment control section 53 carries out the operations shown in FIGS. When the flow rate is 0 (zero), the registration / determination control unit 53 operates in the flow rate 0 mode shown in FIG. In this flow rate 0 mode, the registration / determination control unit 53
First, it is determined whether or not there is an ignition sound (step S10).
1) If there is no ignition sound (N), it is determined whether there is a flow rate (step S102). If there is no flow rate (N), the process returns to step S101. If there is a flow rate (step S
102; Y) determines that the gas has leaked, closes the shutoff valve 17 to shut off the gas (step S103), and ends the operation. When there is an ignition sound (step S101; Y), it is determined whether the detected frequency characteristic of the ignition sound is the frequency characteristic of the ignition sound registered in the storage unit 54 (step S).
104). Specifically, the frequency characteristics of the detected ignition sound and the frequency characteristics of each ignition sound registered in the storage unit 54 are collated by pattern matching to determine whether or not they match. When the detected frequency characteristic of the ignition sound is not the frequency characteristic of the ignition sound registered in the storage unit 54 (N), it is determined to be a new appliance, and a new gas appliance item is provided in the storage unit 54. The frequency characteristic of the ignition sound is registered there (step S105), the flow rate after ignition is further registered (step S106), and the flow rate monitoring mode shown in FIG. 6 is entered.

The frequency characteristic of the detected ignition sound is stored in the storage unit 5.
In the case of the frequency characteristic of the ignition sound registered in No. 4 (step S104; Y), the subsequent flow rate is monitored (step S107), and whether the detected flow rate is the flow rate registered in the storage unit 54 or not. Is determined (step S108). If the detected flow rate is the flow rate registered in the storage unit 54 (Y), it is determined that the flow rate is in the steady use state (step S10).
9) and shifts to the flow rate monitoring mode shown in FIG. When the detected flow rate is not the flow rate registered in the storage unit 54 (step S109; N), it is determined that the gas appliance is abnormal, and an alarm display is displayed on the display unit 45 (step S11).
0), the operation ends.

In the flow rate monitoring mode shown in FIG.
The determination control unit 53 first determines whether or not there is a flow rate (step S111), and when there is no flow rate (N), shifts to the flow rate 0 mode shown in FIG. When there is a flow rate (Y)
Determines whether there is an ignition sound (step S11).
2). If there is no ignition sound (N), it is determined whether or not there is a flow rate change other than the flow rate registered in the storage unit 54 (step S113). When there is no flow rate change other than the flow rate registered in the storage unit 54 (N), step S11
Return to 1. When there is a change in the flow rate other than the flow rate registered in the storage unit 54 (step S113; Y), it is determined that there is a gas leak, the shutoff valve 17 is closed and the gas is shut off (step S114), and the operation ends. . When there is an ignition sound (step S112; Y), it is determined whether the detected frequency characteristic of the ignition sound is the frequency characteristic of the ignition sound registered in the storage unit 54 (step S115). When the detected frequency characteristic of the ignition sound is not the frequency characteristic of the ignition sound registered in the storage unit 54 (N), it is determined to be a new appliance, and a new gas appliance item is provided in the storage unit 54. The frequency characteristic of the ignition sound is registered there (step S116), and the flow rate obtained by subtracting the flow rate before the current ignition from the flow rate of the current ignition is registered (step S117), and the step S117 is performed.
Return to 111.

The frequency characteristic of the detected ignition sound is stored in the storage unit 5.
If it is the frequency characteristic of the ignition sound registered in No. 4 (step S115; Y), the subsequent flow rate is monitored (step S118), and the flow rate before the current ignition is subtracted from the current ignition flow rate. (Step S119),
It is determined whether the calculated flow rate is the flow rate registered in the storage unit 54 (step S120). If the calculated flow rate is the flow rate registered in the storage unit 54 (Y), it is determined to be in the steady use state (step S121), and step S11 is performed.
Return to 1. If the calculated flow rate is not the flow rate registered in the storage unit 54 (step S120; N), it is determined that the gas appliance is abnormal, an alarm is displayed on the display unit 45 (step S122), and the operation ends. To do.

In the above operation, it is determined whether or not the frequency characteristic of the detected ignition sound and the frequency characteristic of the ignition sound registered in the storage unit 54 match, and the detected flow rate and the storage unit 54. Whether or not the registered flow rates match is determined by having a predetermined width.

As described above, according to this embodiment,
For each gas appliance connected to the gas meter, the frequency characteristics of the ignition sound and the flow rate after ignition are associated and registered, and when the flow rate is detected without detecting the ignition sound, and during steady use, ignition is performed. When a change to a flow rate other than the registered flow rate is detected without sound being detected, it is judged as a gas leak, and after the ignition sound is detected, the flow rate registered as the flow rate corresponding to the ignition sound. Since it is determined that the gas appliance is abnormal when a flow rate other than the above is detected, it is possible to detect an abnormality such as gas leakage in a short time. Further, it is possible to detect a gas leak having the same flow rate as that of the spark. In addition, it is possible to determine an abnormal usage state due to a failure of the gas appliance, and it is possible to improve safety. Also, since the gas usage pattern for each gas appliance can be determined,
It is possible to discriminate abnormal use of gas appliances (such as disconnection of rubber tube).

The present invention is not limited to the above embodiment,
For example, when a flow rate is detected without an ignition sound being detected, and when a change to a flow rate other than the registered flow rate is detected without an ignition sound being detected during steady use, the ignition sound is output. After detection, in any case when a flow rate other than the flow rate registered as the flow rate corresponding to the ignition sound is detected, the gas may be shut off and an alarm display may be issued.

[0033]

As described above, according to the abnormality detecting device in the gas meter of the first aspect, it is determined that the abnormality is detected when the flow rate is detected without the ignition sound being detected. There is an effect that an abnormality such as a gas leak can be detected.

According to the abnormality detecting device in the gas meter according to any one of claims 2 to 4, the ignition sound and the flow rate after ignition are stored in association with each other for each gas appliance connected to the gas meter. However, it is judged to be abnormal when the flow rate is detected without detecting the ignition sound and when a flow rate other than the flow rate stored as the flow rate corresponding to the ignition sound is detected after the ignition sound is detected. As a result, in addition to the above effects, there is an effect that not only gas leakage but also an abnormality due to a gas appliance failure can be detected.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a configuration of a gas meter to which an abnormality detection device in a gas meter according to an embodiment of the present invention is applied.

FIG. 2 is a block diagram showing a circuit configuration of the gas meter shown in FIG.

3 is a block diagram showing a configuration of an abnormality detection unit in FIG.

FIG. 4 is an explanatory diagram conceptually showing the storage contents of a storage unit in FIG.

5 is a flowchart showing an operation of a registration / judgment control unit in FIG.

FIG. 6 is a flowchart showing the operation of the registration / judgment control unit in FIG.

FIG. 7 is an explanatory diagram for explaining a gas leakage detection method in a conventional gas meter.

[Explanation of symbols]

40 microphone 44 Flow rate calculator 45 Display 46 Abnormality detector 47 Shut-off valve drive circuit 51 filters 52 Frequency converter 53 Registration / judgment control unit 53 storage

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-5-166439 (JP, A) JP-A-5-20568 (JP, A) JP-A-64-30618 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) G01F 1/00-9/02

Claims (4)

(57) [Claims] 1. A flow rate detecting means provided in a gas meter for detecting a flow rate of gas; an ignition sound detecting means provided in the gas meter for detecting an ignition sound of a gas appliance connected to the gas meter; and the ignition. An abnormality detecting device for a gas meter, comprising: abnormality determining means for determining an abnormality when the flow rate is detected by the flow rate detecting means without detecting an ignition sound by the sound detecting means. 2. A flow rate detecting means provided in the gas meter for detecting a flow rate of gas, an ignition sound detecting means provided in the gas meter for detecting an ignition sound of a gas appliance connected to the gas meter, and the gas meter. For each connected gas appliance, a storage unit that stores the ignition sound detected by the ignition sound detection unit and the flow rate detected by the flow rate detection unit after ignition in association with each other, and ignition by the ignition sound detection unit A flow rate stored in the storage means as a flow rate corresponding to the ignition sound when the flow rate is detected by the flow rate detection means without detecting sound and after the ignition sound is detected by the ignition sound detection means. An abnormality determining means for determining an abnormality when a flow rate other than the above is detected by the flow rate detecting means. Always detection device. 3. The abnormality determining means determines that there is a gas leak when the flow rate detecting means detects a flow rate without detecting an ignition sound by the ignition sound detecting means, and the ignition sound detecting means detects an ignition sound. The gas appliance is determined to be abnormal when a flow rate other than the flow rate stored in the storage means as the flow rate corresponding to the ignition sound is detected by the flow rate detection means after being detected. An abnormality detection device in the gas meter described. 4. The abnormality determining means further determines whether or not the gas appliance is being used without the ignition sound being detected by the ignition sound detecting means when the gas appliance is being used without being determined to be abnormal. 4. The abnormality detecting device in a gas meter according to claim 3, wherein when the flow rate detecting means detects a flow rate other than the flow rate stored in the storage means as a corresponding flow rate, the gas leak is determined.