JP7022896B2 - Gas meter - Google Patents

Description

The present invention relates to a straight pipe type gas meter in which a gas inlet and a gas outlet are provided on the same axis.

Conventionally, gas meters operated in the market have gas inlets and outlets provided on the upper surface of the meter housing, and are suspended from gas pipes. Further, in recent years, there is a document that provides a form of a straight tube type gas meter in which a gas inlet and a gas outlet are provided on the same axis (see, for example, Patent Document 1).

FIG. 5 shows a conventional gas meter described in Patent Document 1.

As shown in FIG. 5 , the body body 1 is provided with a gas inflow section 2 and a gas outflow section 3, and a straight gas flow path 4 in which gas flows from the gas inflow section 2 to the gas outflow section 3 inside the body body 1. , Is composed of a display unit 5 arranged on the outer surface of the body body 1. Further, an acceleration sensor (not shown) for detecting the direction of gravity is provided to determine the posture of the body body 1 and the display direction changes according to the posture.

The mounting posture of the gas meter is uniquely determined by the shape of the suspended type, but the gas flow path 4 can be installed in the vertical direction or the horizontal direction in the straight pipe type. Further, even when the gas flow path 4 is installed in the lateral direction, there is a possibility of various installation forms such as installing the display unit 5 in the forward direction or the upward direction. One of the features of the straight tube type gas meter is that the degree of freedom of installation can be expanded in this way.

JP-A-2017-133959

As described above, in the gas meter having a straight tube type configuration, the mounting posture direction is not uniquely determined, so that it is necessary to form the gas meter so that the performance and reliability are not impaired by the mounting posture.

For example, if the meter is installed so that the sealing surface of the valve body of the gas shutoff valve faces upward in the passing gas, dust and dirt in the gas supply pipe easily adhere to the sealing surface, and the airtightness at the time of shutting off. May reduce sex.

As another example, when the meter is installed so that the measuring sensor of the gas measuring section and the measuring circuit section face downward with respect to the gas flow path axis in the passing gas, the moisture in the gas supply pipe is contained in the meter flow path. There is a risk of intrusion or dew condensation in (in the gas atmosphere), moisture accumulates in the flow path, and the electric circuit of the measuring unit is flooded.

As described above, it may be necessary to worry about the deterioration of reliability depending on the installation direction of the gas meter, and it may be necessary to limit the installation posture.

As mentioned above, the challenge is to eliminate anxiety during installation.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a straight tube type gas meter that ensures reliability at the time of installation.

In order to solve the above problems, the gas meter of the present invention has a meter housing having a gas inlet and a gas outlet on the same axis, and an I-shaped gas flowing from the gas inlet to the gas outlet. A gas flow path, a gas measuring unit that measures gas, a gas shutoff valve that shuts off and supplies gas, an acceleration sensor that measures acceleration, and a meter controller that controls gas weighing and gas shutoff and supply. The meter controller is characterized in that the acceleration sensor determines the installation posture of the meter housing and notifies when the installation posture in a predetermined direction is detected.

As a result, the accelerometer determines the direction of gravity to determine the installation posture of the meter housing, and when the restricted direction of the installation posture related to the structure inside the meter that cannot be seen from the outside is detected, the mounting posture is abnormal. Since an alarm is given to the installation worker and the installation worker is notified, the mounting posture can be corrected.

The gas meter of the present invention can prevent deterioration of reliability due to the mounting posture by notifying as an abnormality alarm when the meter housing is mounted in the limiting direction of the mounting posture.

Sectional drawing which shows the structure of the gas meter in embodiment of this invention. A block diagram showing a configuration of an electric system of a gas meter according to an embodiment of the present invention. (1)-(4) Installation diagram showing the installation posture of the gas meter according to the embodiment of the present invention. The flow chart which shows the start operation of the gas meter in embodiment of this invention. External view showing the configuration of a conventional gas meter

The gas meter of the first invention has a meter housing provided with a gas inlet and a gas outlet on the same axis, an I-shaped gas flow path through which gas flows from the gas inlet to the gas outlet, and gas. The meter control is provided with a gas measuring unit for measuring, a gas shutoff valve for shutting off and supplying gas, an acceleration sensor for measuring acceleration, and a meter controller for controlling measuring and shutting off and supplying gas. The device is characterized in that the accelerometer determines the installation posture of the meter housing and notifies when the installation posture in a predetermined direction is detected, so that the accelerometer determines the direction of gravity and the meter housing. When the installation posture of the body is determined and the restriction direction of the installation posture related to the internal structure of the meter that cannot be seen from the outside is detected, the installation operator is notified that the installation posture is abnormal and alerts the user. You can correct your posture.

The second invention, particularly in the first invention, has a structure in which the gas shutoff valve presses the valve body to seal the gas, and detects an installation posture in which the sealing surface of the valve body faces upward. By notifying when the gas is shut, the installation posture can be corrected, the possibility of dust or the like adhering to the sealing surface of the valve body can be reduced, and the deterioration of airtightness at the time of shutting off can be prevented. ..

A third aspect of the invention, particularly in the first invention, is that the gas measuring unit is an electronic type including a measuring sensor and a measuring circuit unit, and the measuring sensor and the measuring circuit unit are of the gas flow path. By notifying when the installation posture that is downward with respect to the shaft is detected, the installation posture is corrected and the electric circuit part is not arranged on the lower side in the gas flow path, so that gas measurement is performed. The possibility that the electric circuit portion of the portion infiltrates into the flow path and is immersed in the accumulated water is reduced, and the deterioration of the water immersion resistance can be prevented.

The fourth invention, particularly in any one of the first to third inventions, is characterized in that the meter controller determines the installation posture according to the operation of putting the gas meter into use, thereby installing the gas meter. After that, the posture can be determined without fail when the use is started, and it is possible to reliably determine whether or not the installation posture is possible.

A fifth aspect of the invention, particularly in any one of the first to fourth aspects, is characterized in that the meter controller fixes the gas shutoff valve in a shutoff state when notified, so that the gas shutoff valve is in an abnormal posture. Gas cannot be used and safety can be ensured.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to this embodiment.

(Embodiment)
FIG. 1 is a cross-sectional view showing the configuration of a gas meter according to the first embodiment of the present invention.

In FIG. 1, the meter housing body 13a has a gas inlet 11 and a gas outlet 12 on the same axis (gas flow path axis 100). The meter housing body 13a is kept airtight with gas between the gas inlet 11 and the gas outlet 12, and forms the meter housing 13 together with the meter housing outer shell 13b that partially covers the meter housing body 13a. ing.

A meter controller 18 composed of a printed wiring board is provided in the outer shell 13b of the meter housing. The meter controller 18 includes an acceleration sensor 19 that measures acceleration in three axis directions, and the acceleration sensor 19 has three axes of X-axis, Y-axis, and Z-axis that are orthogonal to each other, and has three axes of gas flow path axis 100. Is the Z-axis, the meter controller 18 is attached so that the front-rear direction is the X-axis and the remaining one axis is the Y-axis. Assuming that the arrow direction of each acceleration axis shown by the acceleration axis of the acceleration sensor in FIG. 1 is positive acceleration and the opposite direction of each arrow is negative acceleration, a simple acceleration value is used in 3 axes × 2 polarities (positive / negative). You can distinguish 6 directions. In addition, the symbol of × in ○ indicates that the direction from the front to the back of the figure is positive.

In the meter housing body 13a, the gas shutoff portion 17, the gas flow path 14a, the gas measuring unit 15 forming a part of the flow path, and the gas flow path 14b are identical from the gas inlet 11 to the gas outlet 12 in this order. It is arranged in an I shape on the axis.

The gas shutoff portion 17 is provided with a gas shutoff valve 16 so as to maintain airtightness with the meter housing body 13a. The gas shutoff valve 16 has a structure in which the valve body 16a is pressed against the flange 17a of the gas shutoff portion 17 to seal the gas, and a compressible rubber material is generally used for the valve body. Further, the gas shutoff valve 16 is attached to the meter housing body 13a so that the sealing surface (sealing direction (arrow A)) of the valve body 16a faces the negative direction of the X axis of the acceleration sensor 19.

The gas measuring section 15 is composed of a measuring channel section 15a that becomes a part of the flow path and through which gas flows, and a measuring electric section 15b that performs electronic weighing. Further, the measuring electric unit 15b is composed of a measuring circuit unit 15b1 and a measuring sensor 15b2, and the measuring sensor 15b2 is connected to the measuring circuit unit 15b1 by an electric wiring (not shown). The weighing sensor 15b2 is a pair of ultrasonic sensors, and transmits and receives ultrasonic waves propagating along the path shown by the dotted line in the figure. That is, ultrasonic waves are transmitted from the measuring sensor 15b2 on the upstream side, and the ultrasonic waves reflected on the inner wall of the measuring flow path portion are received by the measuring sensor 15b2 on the downstream side (in the A direction). In addition, transmission / reception is performed in the opposite direction (referred to as B direction). Since the measuring sensor 15b2 radiates ultrasonic waves toward the measuring flow path portion 15a, an opening 15c is provided between the measuring flow path portion 15a and the measuring electric section portion 15b.

Further, the measuring circuit unit 15b1 drives an ultrasonic sensor, and ultrasonic waves in the A direction (from the upstream with respect to the gas flow) and the B direction (from the downstream with respect to the gas flow) in the gas flow velocity. It is an electronic circuit unit that calculates the flow velocity of gas from the difference in the propagation velocity of the gas, and is formed on the printed wiring board.

As described above, the gas measuring unit 15 is a unit in which a flow path, a sensor, and an electronic circuit are integrated, and is a collection of technical means for ultrasonic measurement. Further, the gas measuring unit 15 is arranged so that the measuring electric unit 15b is on the positive direction side of the X axis of the acceleration sensor with respect to the gas flow path axis 100.

When the meter controller 18 is connected to the measuring circuit unit 15b1 and the gas shutoff valve 16 by an electric wiring (not shown), calculates the gas flow rate from the gas flow rate signal, and detects an abnormal gas flow from the gas flow rate. Controls the entire gas meter, such as shutting off the gas shutoff valve 16.

FIG. 2 is a block diagram showing a configuration of an electric system of a gas meter according to an embodiment of the present invention.

In FIG. 2, the meter controller 18 has a microcomputer 30 (hereinafter referred to as a microcomputer 30), and the microcomputer 30 shuts off a measurement circuit 31 for taking in a signal of a measuring electric unit 15b and a gas shutoff valve 16. A valve drive circuit 32, a pressure detection circuit 33 that captures the signal of the pressure sensor 10, a voltage detection circuit 34 that detects a decrease in battery voltage, an alarm circuit 36 that captures the signal of a gas leak alarm, and a defined signal system. A communication circuit 37 for exchanging wired communication messages by a bus method, a display unit 20 for displaying an operating status, and an operation unit 21 including a contact switch and a magnetic switch for receiving various operations are connected. Further, the acceleration sensor 19 is connected.

The alarm circuit 36 and the communication circuit 37 are connected to the external terminal 7 so that an external device such as an alarm can be connected.

The microcomputer 30 reads the acceleration value of each axis of the acceleration sensor 19, determines the posture of the meter housing from the gravitational acceleration direction, calculates the measured seismic intensity and SI value (building collapse degree index) from the acceleration change value, and causes an earthquake. It has the function of an accelerometer to estimate the scale of.

FIG. 3 is an installation view showing an installation posture of the gas meter according to the embodiment of the present invention. In addition, the arrow of the acceleration axis of the acceleration sensor in the figure indicates the positive direction of each axis, and the symbol of × in ○ indicates that the direction from the front to the back of the figure is positive, and in ○ The symbol of ・ indicates that the direction from the back to the front is positive.

The straight tube type gas meter shown in FIG. 1 has more freedom of installation posture than its shape.

FIG. 3 (1) shows the meter posture when the gas inlet is on the upper side and the gas is installed in the direction perpendicular to the ground (hereinafter referred to as vertical installation). Due to gravitational acceleration, the Z axis shows about -980 gal.

Further, FIGS. 3 (2) to 3 (4) show the meter posture when installed in a direction parallel to the ground (hereinafter referred to as horizontal installation). In the horizontal installation, depending on the positional relationship between the gas inlet 11 and the gas outlet 12, it can be installed in any direction 360 ° around the gas flow path axis 100.
FIG. 3 (2) shows a posture in which the sealing surface (that is, the sealing direction (arrow A)) of the valve body 16a of the gas shutoff valve 16 is in the lateral direction (horizontal to the ground), and FIG. 3 (3) shows the posture. , The posture in which the sealing surface faces downward, and FIG. 3 (4) shows the posture in which the display surface faces upward. Due to gravitational acceleration, the Y-axis shows about 980 gal in the posture of FIG. 3 (2), the X-axis shows about -980 gal in the posture of FIG. 3 (3), and the X-axis shows about 980 gal in the posture of FIG. 3 (4). Will be shown.

When the relationship between the valve body 16a, the metering electric unit 15b, and the accelerometer 19 is arranged as shown in FIG. 1, the sealing surface of the valve body 16a faces upward when the installation posture is as shown in FIG. 3 (4). The metering electric unit 15b is located below the gas flow path axis 100, and the acceleration of the X-axis of the accelerometer is about 980 gal.

FIG. 4 is a flow chart showing the activation operation of the gas meter according to the embodiment of the present invention.

The gas meter operates in standby mode (S1) until it is installed and used. In the standby mode operation, in order to suppress the consumption of the battery power supply (not shown), the meter controller 18 stops the operation of, for example, the measurement circuit 31 and the measuring electric unit 15b. After installing the gas meter, if there is a start operation in the operation unit 21 (YES in S2) so that the gas meter can be used normally, the installation posture is first determined (S3).

The installation posture is determined by measuring the acceleration value of each axis detected by the acceleration sensor 19. When the acceleration value of the X-axis becomes about 980 gal (YES in S4), it is determined that the installation state is abnormal, notification (outputs an abnormality alarm) (S5), and the gas shutoff valve is closed (S6). ), And return to the standby mode operation (S1). When the acceleration value of the X-axis is not about 980 gal (NO in S4), the gas is weighed, the measurement mode operation (S7) for executing each function as a gas meter is performed, and the gas shutoff valve is opened (S8).

The operation of the above series of flows can be executed by the program of the microcomputer 30.

As for the notification as an abnormality alarm, for example, the LED as the display unit 20 blinks in a specific pattern, a telegram is transmitted to the external terminal 38 via the communication circuit 37, or the abnormality alarm is stored in the data memory 35. , Responds to a call request message received from the external terminal 38 via the communication circuit 37.

The operation of the gas meter configured as described above will be described below.

Foreign matter such as dust or dust, or moisture or moisture may enter the gas supplied through the gas supply pipe and pass through the flow path of the gas meter, so that the sealing surface of the valve body 16a is formed. If it faces upward, it is susceptible to dust and dirt, and dust and dirt may adhere and remain, and airtightness may be impaired.

Further, there is a possibility that moisture or moisture dew condensation water may remain in the meter housing body 13a, and if the measuring electric part 15b is located on the lower side (ground side), the water will enter the measuring electric part and cause a malfunction. There is a fear.

In the present embodiment, the valve body 16a of the gas shutoff valve 16 faces upward, or the metering electric unit 15b in the meter housing body 13a is on the lower side of the gas flow path (ground) along the gas flow path axis 100. The structure is determined in advance so that the X-axis direction of the acceleration sensor 19 is the gravitational acceleration direction in the installation posture on the side).

Then, when the meter is started, the acceleration sensor 19 detects the gravitational acceleration direction, determines the installation posture of the meter housing, and determines that the X-axis is 980 gal (the arrow direction of the X-axis is the gravitational acceleration direction). It is determined that the abnormality is notified, the gas shutoff valve 16 is shut off, and the process returns to the standby mode.

In the present embodiment, since the gas meter determines that the installation posture impairs reliability and notifies (outputs an abnormality alarm), the installation worker can be alerted and the installation posture is corrected. Therefore, it is possible to prevent the reliability from being lowered due to the installation and to give the installation worker a sense of security.

Further, since it is possible to avoid the installation posture in which the sealing surface of the valve body 16a faces upward with respect to the ground, it is possible to prevent a decrease in airtightness when the gas is shut off.

Further, since it is possible to prevent the measuring circuit unit 15b1 and the measuring sensor 15b2 from being installed so as to be positioned downward with respect to the gas flow path, it is possible to avoid the infiltration of water due to moisture in the gas or condensation of moisture. , The possibility of malfunction can be reduced.

Further, since the installation posture is determined by the operation of starting the gas meter, the operator can reliably and efficiently perform the determination without forgetting the determination work.

Further, at the time of an abnormality alarm, the gas is shut off and the standby mode is set, so that the shutoff state is maintained until the installation posture is corrected, and safety can be ensured.

It should be noted that the accelerometer 19 does not have to have a three-axis direction, as long as it has a necessary axial direction according to the internal structure, and in the present embodiment, the object can be realized even as a one-axis accelerometer. be able to.

As described above, the gas meter according to the present invention can determine the installation posture and correct the installation posture that impairs the performance and reliability of the meter, and thus can be used as a gas flow meter installed in factory equipment. Applicable.

11 Gas inlet 12 Gas outlet 13 Meter housing 13a Meter housing body 13b Meter housing outer shell 14a, 14b Gas flow path 15 Gas measuring part 15a Measuring flow part (gas flow path)
15b Weighing electricity part 15b1 Measuring circuit part 15b2 Weighing sensor 16 Gas shutoff valve 16a Valve body 17 Gas shutoff part 17a Flange 18 Meter controller 19 Accelerometer 20 Display part 30 Microcomputer 100 Gas flow path axis

Claims (4)

A meter housing equipped with a gas inlet and a gas outlet on the same axis,
An I-shaped gas flow path through which gas flows from the gas inlet to the gas outlet, and
The gas measuring unit that measures gas and
A gas shutoff valve that shuts off and supplies gas,
An accelerometer that measures acceleration and
A meter controller that controls gas measurement and gas shutoff and supply,
Equipped with
The gas shutoff valve has a structure in which a valve body is pressed against the gas to seal the gas.
The meter controller is a gas meter characterized in that the accelerometer determines the installation posture of the meter housing and notifies the installation posture when the sealing surface of the valve body faces upward. A meter housing equipped with a gas inlet and a gas outlet on the same axis,
An I-shaped gas flow path through which gas flows from the gas inlet to the gas outlet, and
The gas measuring unit that measures gas and
A gas shutoff valve that shuts off and supplies gas,
An accelerometer that measures acceleration and
A meter controller that controls gas measurement and gas shutoff and supply,
Equipped with
The gas measuring unit is an electronic type equipped with a measuring sensor and a measuring circuit unit.
The meter controller notifies when the acceleration sensor determines the installation posture of the meter housing and the measurement sensor and the measurement circuit unit detect an installation posture downward with respect to the axis of the gas flow path. Gas meter to do . The gas meter according to claim 1 or 2 , wherein the meter controller determines an installation posture according to an operation of putting the gas meter into a used state. The gas meter according to any one of claims 1 to 3 , wherein the meter controller fixes the gas shutoff valve in a shutoff state when notified.

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