JPH0777445A - Gas meter - Google Patents

Abstract

PURPOSE:To detect gas leakage at an early stage regardless of the magnitude of the leakage quantity by driving a proportional valve provided on a gas passage, and actively changing the pressure of the gas fed downstream a gas meter. CONSTITUTION:A controller 16 sets a proportional valve 12 to the first pressure with a drive circuit, detects the gas feed pressure with a gas pressure sensor 14, and detects the gas flow with a gas flowmeter 15. The detected gas feed pressure and the gas flow are stored in the RAM of the controller 16. When the controller 16 sets the proportional valve 12 to the second pressure, the gas feed pressure is changed. The controller 16 likewise detects the gas pressure with the sensor 14 and detects the gas flow with the flowmeter 15. The detected gas feed pressure and the gas flow are stored in the RAM. The controller 16 obtains the relationship between the gas feed pressure and the gas flow with the gas feed pressures and gas flows stored in the RAM when the first and second pressures are set and judges the presence or absence of a gas leakage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas meter for measuring the flow rate of gas supplied upstream of a gas appliance such as a gas stove, and more particularly to a gas meter capable of detecting gas leakage.

[0002]

2. Description of the Related Art In recent years, as a household gas meter, one having a safety function in addition to the function of measuring the flow rate of passing gas has been put into practical use. The safety function of this gas meter is to drive the gas shutoff valve to open the gas flow path when a flow rate meter detects a gas flow rate higher than a predetermined amount, or when a predetermined gas flow rate is detected for a predetermined time or longer. There is a function to shut off. With these functions, leaks in piping and outflow of unnatural gas can be detected to prevent accidents.
It is designed to guarantee safety.

[0003]

However, there is a problem that the conventional gas leak detecting function as described above cannot detect a gas leak below the set flow rate.

Further, as a function of detecting a slight amount of gas leakage, for example, when a situation in which the gas is not used for a predetermined time, for example, one hour or more, cannot be detected for a predetermined number of days, for example, 30 days, a small amount is provided downstream of the gas meter. There is a gas meter having a function of interrupting the gas by judging that there is a gas leak, but there is a problem that it takes a long period of 30 days to detect a minute amount of gas leak.

The present invention has been made in view of the above problems, and an object thereof is to provide a gas meter capable of detecting a gas leak at an early stage regardless of the amount of leak.

[0006]

The gas meter of the present invention comprises:
A gas passage through which a gas passes, and provided in this gas passage,
Gas pressure detecting means for detecting the pressure of the gas in the gas flow path, a gas flow rate detecting means provided in the gas flow path, for detecting the flow rate of the gas passing through the gas flow path, and provided in the gas flow path , A proportional valve for varying the pressure of the gas supplied to the downstream side of the gas meter, actively driving the proportional valve to vary the gas pressure, and before and after this variation, a gas pressure detecting means and a gas pressure detecting means, respectively. A gas leak detection unit that detects the gas pressure and the gas flow rate using the gas flow rate detection unit and determines the presence or absence of a gas leak from the relationship between the detected gas pressure and the gas flow rate. is there.

In this gas meter, the gas leak detection means actively changes the gas pressure using the proportional valve, and the gas pressure detection means and the gas flow rate detection means are used before and after the change, respectively. And the flow rate of the gas is detected, and the presence or absence of gas leakage is determined from the relationship between the detected gas pressure and the gas flow rate.

[0008]

Embodiments of the present invention will now be described in detail with reference to the drawings. 1 to 3 relate to an embodiment of the present invention.

FIG. 1 is an explanatory view showing a schematic configuration of a gas meter according to this embodiment. As shown in this figure, the gas supply system 1 connects the gas meter 10 and the gas appliance 20 with a pipe 17 to supply the gas a. The pipe 17 is provided with a gas plug 17a.

Inside the gas meter 10, a gas pipe 11 serving as a gas flow path is arranged. In the gas pipe 11, a proportional valve (proportional control valve) 12 for varying the pressure of the gas supplied to the downstream side of the gas meter 10, a gas cutoff valve 13 for shutting off the gas flow path at the time of an abnormality, A gas pressure sensor 14 that detects the pressure of the gas in the gas flow path and a gas flow meter 15 that detects the flow rate of the gas passing through the gas flow path are sequentially arranged.

Further, in the gas meter 10, there is provided a control section 16 for inputting respective outputs of the gas pressure sensor 14 and the gas flow meter 15 and controlling the proportional valve 12 and the gas cutoff valve 13.

FIG. 2 is a block diagram showing the configuration of the control unit 16 and its peripherals in the gas meter 10 of this embodiment.
As shown in this figure, the control unit 16 includes a CPU (central processing unit) 30, a ROM (read only memory) 31,
RAM (random access memory) 32, and I
/ O (input / output) ports 33 and 34 are connected to each other by a bus. A gas pressure sensor 14 and a gas flow meter 15 are connected to the input / output port 33, and a drive circuit 3 for driving the gas cutoff valve 13 is connected to the input / output port 34.
5 and a drive circuit 36 for driving the proportional valve 12 are connected. The proportional valve 12 can arbitrarily change the open state in proportion to the drive signal from the drive circuit 36 to arbitrarily change the gas supply pressure.

In the control unit 16, the CPU 30 controls the RA
By executing a program stored in the ROM 31 with M32 as a working area, functions such as gas leak detection are realized.

The control section 16 drives the proportional valve 12 to actively fluctuate the gas pressure as a function related to gas leakage detection, and before and after this fluctuation, respectively.
The gas pressure sensor 14 and the gas flow meter 15 are used to detect the gas pressure and the gas flow rate, and gas leak detection means for determining the presence or absence of gas leakage from the relationship between the detected gas pressure and the gas flow rate is provided. Have

The control unit 16 also includes a gas pressure sensor 14
The gas supply pressure is set to a predetermined value by controlling the proportional valve 12 by feeding back the output of.

Next, the operation relating to the detection of gas leakage in the gas meter of this embodiment will be described with reference to the flow chart of FIG.

In this operation, first, the control section 16 sets the proportional valve 12 to the first pressure by using the drive circuit 36 (step S101). Next, the gas pressure sensor 14 is used to detect the gas supply pressure (step S102), and the gas flow meter 15 is used to detect the gas flow rate (step S1).
03). The detected gas supply pressure and gas flow rate are stored in the RAM 32 in the control unit 16.

Next, the control unit 16 uses the drive circuit 36 to set the proportional valve 12 to a second pressure different from the first pressure (step S104). As a result, the gas supply pressure is changed. Then, the gas supply pressure is detected using the gas pressure sensor 14 in the same manner as above (step S10).
5) The gas flow rate is detected using the gas flow meter 15 (step S106). The detected gas supply pressure and gas flow rate are stored in the RAM 32 in the control unit 16.

Next, the control unit 16 uses the gas supply pressure and the gas flow rate when the first pressure is set and the gas supply pressure and the gas flow rate when the second pressure is set, which are stored in the RAM 32. Obtain the relationship between the gas supply pressure and the gas flow rate, and from this relationship determine the presence or absence of gas leakage, and determine the gas appliances (determination of the presence or absence of gas governor) that are required when determining the presence or absence of gas leakage. (Step S107), the operation ends.

Here, a method of determining the presence / absence of gas leakage and determining a gas appliance in this embodiment will be described.

When the gas supply pressure is actively changed,
If the gas appliance 20 side does not have the function of correcting the change in gas flow rate due to the change in gas supply pressure, the change in gas supply pressure causes the change in gas flow rate as it is. In such a case, a gas leak may occur during use of the gas appliance 20 having no gas governor or regardless of the presence or absence of the gas governor. Therefore, when a gas leak occurs, there is a correlation between the gas supply pressure and the gas flow rate.

On the other hand, the gas water heater, the bath kettle, etc. have a built-in gas governor in the equipment, and the fluctuation of the gas supply pressure is absorbed by the gas governor. Therefore, if no gas leakage occurs,
Even if the gas supply pressure fluctuates, it does not affect the gas flow rate. Therefore, there is no correlation between the gas supply pressure and the gas flow rate.

Utilizing the above, the determination of the presence or absence of gas leakage and the determination of gas appliances are performed as follows, for example.

First, if there is no correlation between the gas supply pressure and the gas flow rate, it is determined that the gas equipment having the gas governor is used or the gas is not used. If the gas leak detection operation is performed when the gas appliance is used, unless there is a correlation between the gas supply pressure and the gas flow rate, it is a gas appliance having a gas governor, and no gas leak has occurred. Is determined.

Next, when there is a correlation between the gas supply pressure and the gas flow rate, it can be seen that gas leakage has occurred in the case of a gas appliance having a gas governor, but a gas appliance having no gas governor. In the case of 1, the presence or absence of gas leakage cannot be determined only by the correlation between the gas supply pressure and the gas flow rate. Therefore, the presence or absence of the gas governor and the presence or absence of the gas leak are determined by adding other conditions to the presence or absence of the correlation.

For example, when the rate of fluctuation of the gas flow rate with respect to the fluctuation of the gas supply pressure is less than or equal to a predetermined value, it is determined that gas leakage has occurred. When the gas leak detection operation is performed when the gas appliance is used, it is determined that the gas appliance has a gas governor and that a gas leak has occurred. On the other hand, if the rate of fluctuation of the gas flow rate with respect to the fluctuation of the gas supply pressure exceeds a predetermined value, it is determined that a gas appliance without a gas governor is in use, but it is unknown whether or not there is a gas leak. The presence or absence of gas leakage is determined by adding other conditions. For example, after the use of gas is completed, the correlation between the gas supply pressure and the gas flow rate is checked again, and if there is a correlation, it is determined that a gas leak has occurred. If there is no correlation, no gas leak has occurred. Can be determined.

When it is determined that a gas leak has occurred, the control unit 16 shuts off the gas flow path by the gas shutoff valve 13.

As described above, by adding the information on whether the gas appliance is in use or not, it becomes easy to determine the presence or absence of the gas governor and the gas leak.
Whether 0 is in use can be known by detecting ignition by a sensor such as a flame rod or by detecting a rapid increase in gas flow rate by using the gas flow meter 15.

As described above, in this embodiment, the gas supply pressure is actively changed by using the proportional valve 12, and the gas pressure and the gas flow rate before and after this change are detected to detect the gas pressure and the gas pressure. Since the presence or absence of gas leakage is determined from the relationship with the flow rate, gas leakage can be detected early regardless of the amount of leakage.

When determining the presence or absence of a gas leak or the gas appliance (presence or absence of a gas governor) from the relationship between the gas pressure and the gas flow rate, a passive gas caused by the surrounding households using the gas Although it is possible to use the pressure fluctuation, it is impossible to predict the gas pressure fluctuation pattern, the fluctuation timing, and the like.

On the other hand, in this embodiment, since the gas supply pressure is actively changed by using the proportional valve 12 capable of setting the pressure to a predetermined value, the gas supply pressure on the upstream side of the gas meter 10 is changed. It is possible to suppress the influence of the above and to cause the pressure fluctuation with the same fluctuation pattern whenever necessary, which not only improves the accuracy of gas leak determination and gas appliance determination, but also reduces the calculation amount and power consumption. Can be expected.

The present invention is not limited to the above embodiment,
For example, the proportional valve 12 may double as this without providing the gas cutoff valve 13.

[0033]

As described above, according to the gas meter of the present invention, the gas supply pressure is actively changed using the proportional valve, and the gas pressure and the gas flow rate before and after this change are detected, Since the presence / absence of gas leakage is determined based on the relationship between the gas pressure and the gas flow rate, the gas leakage can be detected early regardless of the amount of leakage.

Further, since the proportional valve is used as a means for actively fluctuating the gas supply pressure, the influence of the fluctuation of the gas supply pressure on the upstream side of the gas meter is suppressed, and the pressure is changed with the same fluctuation pattern whenever necessary. There is an effect that it is possible to cause fluctuation.

[Brief description of drawings]

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

FIG. 2 is a block diagram showing a configuration of a control unit in FIG. 1 and its peripherals.

FIG. 3 is a flowchart showing an operation relating to detection of gas leakage in the gas meter of FIG.

[Explanation of symbols]

 10 Gas Meter 12 Proportional Valve 13 Gas Cutoff Valve 14 Gas Pressure Sensor 15 Gas Flow Meter 16 Controller

Claims (1)

[Claims] 1. A gas passage through which a gas passes, gas pressure detection means provided in the gas passage to detect the pressure of the gas in the gas passage, and the gas passage provided in the gas passage. Gas flow rate detection means for detecting the flow rate of gas passing through the flow path, a proportional valve provided in the gas flow path for varying the pressure of the gas supplied to the downstream side of the gas meter, and driving this proportional valve. The gas pressure is actively changed, and before and after this change, the gas pressure and the gas flow rate are detected using the gas pressure detection means and the gas flow rate detection means, respectively. A gas meter, comprising: a gas leak detection means for determining the presence or absence of a gas leak based on the relationship with the flow rate of the gas.