JP6063784B2 - Gas meter - Google Patents

Description

  The present invention relates to a gas meter in which an emergency shut-off valve that has been closed due to a gas supply being shut off due to the occurrence of a large earthquake or the like is manually returned to a valve open state.

  In dry gas meters such as microcomputer meters used to measure gas flow, an emergency shut-off valve is activated to shut off gas supply when an abnormal situation such as a major earthquake occurs. .

  For example, in the large gas meter shown in Patent Document 1, a valve case is provided in the vicinity of a base on the gas inflow side in the meter casing, and an emergency shut-off port is formed on the front wall of the valve case. In a normal state, the gas flowing into the valve case from the base is introduced into the measuring chamber through the emergency shut-off port. Furthermore, an emergency shut-off valve that can be advanced forward is arranged behind the emergency shut-off port. When an abnormality occurs, the emergency shut-off valve advances and the emergency shut-off port is closed to cut off the gas supply. ing.

  In such a gas meter, a manual return device is provided to return the activated emergency shut-off valve to a normal position (valve open position). That is, in the meter casing, an intermediate shaft is provided at the front end of the valve shaft that supports the emergency shutoff valve on an extension line of the valve shaft. On the other hand, a return shaft is disposed in the front wall of the meter casing so as to be slidable back and forth. The return shaft is arranged coaxially with the intermediate shaft, and the rear end of the return shaft is arranged in the meter casing so as to be separated from the front end of the intermediate shaft by the stroke of the emergency shutoff valve. Sometimes, when the valve shaft and the intermediate shaft advance together with the emergency shut-off valve, the front end of the intermediate shaft is arranged in the vicinity of the rear end of the return shaft. When returning from the valve operating state (valve closed state) to the normal state (valve open state), the return shaft is pushed backward from the front of the meter casing, and the emergency shaft is shut off together with the intermediate shaft and the valve shaft by the return shaft. Push the valve backwards. As a result, the emergency shut-off valve returns to the initial position, while the return shaft is pushed back by the urging force of the urging means such as a spring to return to the forward projecting state (initial state). .

JP 2000-97743 A

  By the way, in the conventional gas meter, especially in a large gas meter as shown in the above-mentioned patent document 1, the base and the meter casing are separate members, and the valve case is connected and fixed to the base on the inlet side, while the return shaft is It is fixed to the outer wall of the meter casing. When connecting and fixing the base of such a gas meter to the outer pipe (pipe), if the nut on the outer pipe side is tightened to the base, piping distortion will occur, so the valve shaft and intermediate shaft of the valve case fixed to the base side However, there is a possibility that displacement may occur relative to the return shaft fixed to the front wall of the casing, causing a displacement between the intermediate shaft and the return shaft. Then, for example, when the valve shaft and the intermediate shaft try to advance in the event of an abnormal situation, the intermediate shaft may hit the return shaft and the gas supply cannot be cut off smoothly, or the return shaft may be When pushed in, there is a risk that the return shaft will bump into the intermediate shaft and the shaft will not move smoothly, making the return operation difficult.

  The present invention has been made in view of the above problems, and can prevent displacement between the operating shaft and the return shaft due to piping distortion or the like when the gas meter is installed. An object is to provide a gas meter that can be operated smoothly.

  In order to achieve the above object, the present invention has the following structure.

[1] A valve case arranged in the meter casing is fixed to a base on the gas inflow side, an emergency shut-off port is formed on the front wall of the valve case, and an emergency shut-off valve arranged in the valve case Gas is supplied in the open state that is spaced apart behind the emergency shut-off port, and in the closed state where the emergency shut-off port is closed by the operation shaft of the emergency shut-off valve extending from the open state. While the supply of gas is cut off, a return shaft is slidably disposed along the axis of the operating shaft at a position corresponding to the front of the operating shaft on the front wall of the meter casing, In the gas meter, by pushing the return shaft, the operating shaft is pushed back by the return shaft and retracted together with the emergency shut-off valve to return to the open state.
A first positioning member is fixed in the vicinity of the operating shaft in the valve case, and a second positioning member is fixed in the vicinity of the return shaft in the inner surface of the front wall of the meter casing.
The gas meter according to claim 1, wherein the relative position between the operating shaft and the return shaft is fixed by fitting the one side positioning member into the other side positioning member.

[2] The operating shaft includes a valve shaft to which the emergency shut-off valve is fixed at a front end, and an intermediate shaft connected to the front end of the valve shaft,
The one side positioning member is formed in a cylindrical shape in which the intermediate shaft is accommodated and disposed so as to protrude forward from the valve case,
The other-side positioning member is formed in a cylindrical shape in which the return shaft is accommodated and arranged so as to protrude rearward from the inner surface of the front wall of the meter casing,
The gas meter according to the preceding item 1, wherein a front end portion of the one side positioning member is fitted into a rear end portion of the other side positioning member.

  [3] The gas meter according to [2], wherein the return shaft is attached to the other positioning member via a bearing.

  According to the gas meter of the invention [1], since the relative position between the operating shaft and the return shaft is fixed by fitting both positioning members, it is possible to prevent the displacement between the operating shaft and the return shaft. . For this reason, the operating shaft and the return shaft can be surely interlocked and smoothly moved, the gas supply can be smoothly cut off without any trouble in an emergency, and the return operation can be smoothly carried out without any trouble.

  According to the gas meter of the invention [2], since both the positioning members are formed in a cylindrical shape arranged on the outer circumference of the intermediate shaft and the return shaft, all of the intermediate shaft and the return shaft are orthogonal to the axial direction. A positional deviation in the direction can be reliably prevented.

  According to the gas meter of the invention [3], since the return shaft is attached to the other side positioning member via the bearing, it is possible to prevent the displacement between the other side positioning member and the return shaft more reliably, and thus return. A positional shift between the shaft and the intermediate shaft can be prevented more reliably.

FIG. 1 is a front view showing a gas meter according to an embodiment of the present invention. FIG. 2 is a side cross-sectional view showing the upper part of the gas meter of the embodiment in a valve open state. Drawing 3 is a side sectional view showing the upper part of the gas meter of an embodiment in the valve closing state. FIG. 4 is a side sectional view showing the vicinity of the return shaft of the gas meter according to the embodiment in a valve-open state. FIG. 5 is a side cross-sectional view showing the vicinity of the return shaft of the gas meter of the embodiment in a closed state. FIG. 6 is an enlarged front view showing the vicinity of the return shaft of the gas meter according to the embodiment. FIG. 6 (a) is a front view showing the valve open state, and FIG. 6 (b) is a front view showing the valve closed state.

  FIG. 1 is a front view showing a gas meter according to an embodiment of the present invention, and FIG. 2 is a side sectional view showing an upper portion of the gas meter according to the embodiment. In the following specification, in order to facilitate understanding of the invention, the vertical direction toward the paper surface of FIG. 1 is “vertical direction (vertical direction)”, and the horizontal direction is “horizontal direction (lateral direction)”. 2, the right side is described as “front side” and the left side as “rear side”.

  As shown in both figures, the gas meter of this embodiment is a large-sized gas meter installed in a facility where a large amount of gas is used. The meter casing 1 of this gas meter includes an upper case 11 that constitutes the upper side portion thereof and a lower case 12 that constitutes the lower side portion thereof.

  A base 13a on the gas inflow side (inlet side) is fixed to one side portion of the upper wall of the upper case 11, and a base 13b on the gas outflow side (outlet side) is fixed to the other side portion.

  A valve case 14 is provided in the upper case 1 corresponding to the inlet-side base 13a. The upper end of the valve case 14 is connected and fixed to the base 13a, and is connected to the inside of the base 13a. Further, a circular opening as an emergency shut-off port 15 is formed in the front wall of the valve case 14, and a valve seat 16 is attached to the opening edge. The emergency shut-off port 15 is formed such that its axis is arranged along the front-rear direction. A forward projecting plate 17 is fixed to the valve case 14 so as to project in front of the emergency shut-off port 15.

  In the present embodiment, the gas flowing in from the inlet side cap 13a is introduced into the valve case 14, flows out of the valve case 14 through the emergency shut-off port 15, and is sent into the measuring chamber of the lower case 12. Further, a gas flow path is formed in which the gas is measured after passing through the measurement chamber and then flows out from the outlet 13b.

  The rear wall of the valve case 14 is constituted by a holder for holding the solenoid 21. That is, the solenoid 21 is fixed to the outer surface of the rear wall of the valve case 14, and the valve shaft 22, which is a plunger of the solenoid 21, is disposed through the rear wall of the valve case 14 in an airtight state. The valve shaft 22 has an axis that coincides with the axis of the emergency shut-off port 15, and can slide and move (advance and retreat) along the front-rear direction (axial direction).

  A circular emergency shut-off valve 23 is fixed to the front end of the valve shaft 22 corresponding to the circular emergency shut-off port 15, and the valve shaft 22 is interposed between the emergency shut-off valve 23 and the rear wall of the valve case 14. The compression coil spring 24 is disposed so as to be fitted on the outer side.

  In the present embodiment, the solenoid 21 is of a self-holding type, and in the non-energized state, the valve shaft 22 is magnetically attracted, so that the retracted state (normal state) shown in FIG. Is held in. In this state, the emergency shut-off valve 23 is disposed at a position spaced rearward from the emergency shut-off port 15 and is in a valve open state. In this state, when the solenoid 21 is energized instantaneously based on a command from an abnormality detector (not shown) in an emergency (when an abnormality occurs), the magnetic adsorption of the valve shaft 22 is released, and the spring The emergency shut-off valve 23 advances forward together with the valve shaft 22 by the urging force of 24 and presses against the valve seat 16. As a result, as shown in FIG. 3, the emergency shut-off port 15 is closed and the valve is closed, the gas flow path is shut off, and the gas supply is stopped.

  In the present embodiment, an emergency cutoff device is configured by the solenoid 21, the valve shaft 22, the emergency cutoff valve 23, the compression coil spring 24, and the like.

  The front projecting plate 17 fixed to the valve case 14 has an intermediate shaft 32 slidably disposed in the axial direction so that the valve shaft 22 and the shaft center coincide with each other. Is connected and fixed to the front end of the valve shaft 22. Accordingly, the intermediate shaft 32 is integrated with the valve shaft 22 so as to be slidable along the longitudinal direction on the shaft center.

  Here, in the present embodiment, the valve shaft 22 and the intermediate shaft 32 constitute an operating shaft.

  A rear end of a cylindrical rear positioning member 35 is fixed to the front surface of the front projecting plate 17 of the valve case 14 so as to accommodate and arrange the intermediate shaft 32 therein. The rear positioning member 35 is arranged so that its axis coincides with the axis of the valve shaft 22 and the intermediate shaft 32 and protrudes forward from the front projecting plate 17 of the valve case 14.

  In this embodiment, the rear positioning member 35 constitutes one side positioning member, and the front side positioning member 45 described later constitutes the other side positioning member.

  As shown in FIG. 4, a return shaft mounting hole 40 is formed in the front wall of the upper case 11 so as to correspond to the emergency shutoff valve 23. The return shaft mounting hole 40 is formed in a circular shape, and its axis coincides with the axis of the valve shaft 22.

  An annular mounting ring 41 is fixed to the peripheral edge of the return shaft mounting hole 40 on the inner wall surface of the upper case 11 by screwing. A front positioning member 45 is disposed through the ring hole of the attachment ring 41. The front positioning member 45 is formed in a substantially cylindrical shape, and a mounting flange 46 is formed on the outer periphery of the front end. The mounting flange 46 is fixed to the front side of the mounting ring 41 with screws, and the front positioning member 45 is disposed so as to protrude rearward (inward) from the inner wall surface of the upper case 1. The outer diameter of the cylindrical portion of the front positioning member 45 substantially corresponds to the inner diameter of the rear positioning member 35, and the rear end portion of the front positioning member 45 is fitted into the front end portion of the rear positioning member 35 in a conforming state. ing. By being fitted in this way, the front positioning member 45 is positioned with respect to the rear positioning member 35, and the axis of the front positioning member 45 is arranged so as to coincide with the axis of the valve shaft 22.

  The front end side of the front positioning member 45 is closed, and the return shaft 42 is attached to the front blocking wall through a bearing 48 in a penetrating state. The area of the return shaft 42 excluding its front end is accommodated and disposed inside the front positioning member 45. The return shaft 42 has an axis that coincides with the axes of the front positioning member 45, the valve shaft 22, and the intermediate shaft 32, and can slide along the axis along the front-rear direction. A rear end tool 43 is attached to the rear end of the return shaft 42, and the front end is configured as a large operation button 44.

  Needless to say, in the vicinity of the return shaft mounting hole 40, seal members are appropriately interposed between the respective members, and airtightness between the inside and outside of the gas meter is ensured.

  The rear end tool 43 of the return shaft 42 is disposed so as to be close to the front end tool 33 provided at the front end of the intermediate shaft 32. When the solenoid 21 is actuated, as shown in FIGS. The valve shaft 22, the intermediate shaft 32, and the return shaft 42 integrally move forward, and the front end portion of the return shaft 42 moves in a direction protruding forward from the outer wall surface of the upper case 11. Conversely, when the operation button 44 of the return shaft 42 in the forward projecting state is pushed backward, these shafts 42, 32, and 22 are integrally pushed backward as shown in FIGS. ing.

  The return shaft 42 is held in the pushed state when the valve is returned to the open state by the pushing operation to the rear, and is projected forward when the emergency shut-off valve 23 is closed. Is supposed to be retained.

  As described above, since the positioning between the rear positioning member 35 fixed to the valve case 14 and the front positioning member 45 fixed to the meter front wall is achieved, the positioning is supported by the valve case 14. Positioning between the intermediate shaft 32 and the return shaft 42 supported by the front positioning member 45 is also achieved. That is, the relative position between the intermediate shaft 32 and the return shaft 42 is fixed.

  A cover member 5 is provided around the return shaft 42 on the outer wall surface of the upper case 11. The cover member 5 has an annular nut portion 51 at the rear end portion, and the nut portion 51 is screwed into a male screw portion provided at a front projecting portion of the bearing 48, whereby the cover member 5. Is fixed to the outer wall surface of the upper case 11.

  The cover member 5 is provided with both side covers 52, 52 that cover both sides of the operation button 44 of the return shaft 42 in the valve open state shown in FIGS. Further, the cover member 5 includes a front lid 53 disposed between the front ends of the both side covers 52, 52, and the upper end portion of the front lid 53 is pivoted to the upper end portion of the both side covers 52, 52 in the left-right direction (lateral direction). It is attached to be freely rotatable. Thereby, the front lid 53 can swing in the front-rear direction with the upper end as a fulcrum, and the front end opening portion between the side covers 52, 52 can be opened and closed by the swing.

  2 and 4, the front lid 53 is arranged vertically by its own weight, closes the front end opening between the two side covers 52, 52, and forwards and both sides of the operation button 44 of the return shaft 42. It is in the state which covered. When the return shaft 42 slides forward to the valve closing state shown in FIG. 3, the front lid 53 is pushed open to the front end portion of the return shaft 42, so that the operation button 44 of the return shaft 52 is pressed. It protrudes forward from the cover member 5 and is exposed.

  Here, as shown in FIG. 5, in the present embodiment, on the front surface (front surface) of the front lid 53, characters “open”, which is a symbol indicating a valve open state, are displayed, and the front lid 53 is closed. In the opened valve state, the letters “open” can be visually recognized, so that the valve opened state can be easily grasped. In the closed state in which the front lid 53 is pushed open by the return shaft 42 as shown in FIG. 6, the front face of the front lid 53 is disposed upward, making it difficult to see the letters “open” from the front. That is, in the valve closed state, the word “open” is not visible, so that it is not mistaken for the valve opened state.

  In this embodiment, the front surface of the front lid 53 of the cover member 5 is colored light gray, while the operation button 44 of the return shaft 42 is colored bright red. Therefore, when the return shaft 42 protrudes and the operation button 44 is exposed, the red color of the operation button 44 is clearly visually recognized, so that the valve closing state can be easily grasped.

  For reference, in this embodiment, in the valve open state shown in FIGS. 2 and 4, the amount of protrusion from the outer surface of the upper case 11 on the front end surface of the return shaft 42 (the front end surface of the operation button 44) is 11 mm. On the other hand, in the conventional gas meter, the protruding amount is about 43 mm. Therefore, in the gas meter of the present embodiment, the protruding amount of the return shaft 42 in the valve open state is remarkably reduced.

  In the gas meter of the present embodiment configured as described above, when an abnormal situation such as a large earthquake occurs, the solenoid 21 operates as described above, and the valve shaft 22, the intermediate shaft 32, and the return shaft 42 are integrated. As shown in FIGS. 3, 5, and 6 (b), the emergency shut-off valve 23 closes the emergency shut-off port 15 to shut off the gas supply and the front end of the return shaft 42. The part is arranged in a state of protruding forward.

  In order to resume the gas supply from this closed state, the operation button 44 of the return shaft 42 protruding forward may be pushed backward. Then, as shown in FIGS. 2 and 4, the return shaft 42, the intermediate shaft 32, and the valve shaft 22 move together to move backward, the valve shaft 22 returns to the initial position, and the emergency shut-off valve 23 The emergency shutoff port 15 is opened away from the valve seat 16 and gas can be supplied. When the return shaft 42 is pushed in this way, the return shaft 42 is held in the pushed state as described above.

  According to the gas meter of the present embodiment, the return shaft 42 is brought into contact with the intermediate shaft 32 without forming a gap between the return shaft 42 and the intermediate shaft 32, and is interlocked with the valve shaft 22 and the intermediate shaft 32 when an abnormality occurs. Since the return shaft 42 is advanced, the amount of protrusion of the return shaft 42 from the outer surface of the meter can be reduced in the valve-open state where the return shaft 42 has not advanced and moved in the protruding direction. For this reason, the return shaft 42 can be prevented from being troubled by the surrounding person's clothes and body being caught, and the return shaft 42 can be prevented from being bent due to the collision of the equipment or the like with the return shaft 42. Can do.

  Furthermore, in the present embodiment, the amount of protrusion of the return shaft 42 is small in the valve-open state, and the amount of protrusion is large in the valve-closed state. Can be easily determined.

  In particular, in the present embodiment, in a normal state (valve open state), the protruding portion (front end portion) of the return shaft 42 such as the operation button 44 is covered by the cover member 5 and becomes an abnormal state (valve closed state). In this case, since the operation button 44 pushes open the front lid 53 of the cover member 5 and jumps forward, the difference between the normal state and the abnormal state can be easily distinguished at a glance. It is possible to more easily and accurately determine whether or not it is in a state.

  In the normal state, since the protruding portion (operation button 44) of the return shaft 42 is covered with the cover member 5, the operation button 44 is hidden from the outside, so that the appearance is improved and a good aesthetic appearance is obtained. be able to.

  Further, in the present embodiment, the rear positioning member 35 is attached to the valve case 14 side so as to project forward, and the front positioning member 45 is attached to the inner surface of the front wall of the upper case 11 so as to project rearward. The relative positions between the intermediate shaft 32 supported by the valve case 14 on the side of the base 13a and the return shaft 42 supported on the front side of the meter casing are fixed by fitting the 45s in an adapted state. I am doing so. Therefore, when connecting the gas meter base 13a to the outer pipe (pipe) in the gas meter installation work, even if piping distortion occurs by tightening the nut on the outer pipe side to the base 13a, the intermediate shaft 32 on the side of the base 13a remains. There is no displacement relative to the return shaft 42 on the front wall side of the casing 1, and a positional deviation between the return shaft 42 and the intermediate shaft 32, particularly a positional deviation (center deviation) in a direction orthogonal to the axial direction. It can be surely prevented.

  In particular, in the present embodiment, since both positioning members 35 and 45 are formed in a cylindrical shape arranged on the outer periphery of the intermediate shaft 32 and the return shaft 42, the intermediate shaft 32 and the return shaft 42 are arranged in the axial direction. Misalignment in all orthogonal directions can be reliably prevented.

  Furthermore, in the present embodiment, since the return shaft 42 is attached to the other side positioning member 45 via the bearing 48, it is possible to reliably prevent the displacement between the other side positioning member 45 and the return shaft 42, As a result, the position shift between the return shaft 42 and the intermediate shaft 32 can be prevented more reliably.

  As described above, in the present embodiment, since the displacement between the return shaft 42 and the intermediate shaft 32 can be prevented, the valve shaft 22, the intermediate shaft 32, and the return shaft 42 are integrated when the valve shaft 22 is operated. Move reliably. Therefore, problems due to misalignment, for example, problems such as the valve shaft 22 and the intermediate shaft 32 not moving smoothly due to the intermediate shaft 32 striking the return shaft 42 can be reliably prevented, and the gas supply can be cut off when an abnormal situation occurs. It can be done reliably. Further, when the return shaft 42 is pushed in during the return operation, the return shaft 42, the intermediate shaft 32, and the valve shaft 22 move together as a unit, so that the return shaft 42 strikes the intermediate shaft 32 and the shafts 42, 32. , 22 can be reliably prevented, and the return operation can be performed smoothly without any trouble.

  In the above embodiment, the letter “open” is displayed on the front lid 53 of the cover member 5 as a symbol indicating that the valve is open. However, the present invention is not limited to this. Characters other than "" or symbols other than characters may be displayed.

  In the above embodiment, the intermediate shaft 32 is connected to the valve shaft 22 to form the operating shaft. However, the present invention is not limited to this, and in the present invention, the intermediate shaft can be omitted. For example, by adopting a long return shaft 42 and disposing the rear end of the return shaft 42 in proximity to the front end of the valve shaft 22, the intermediate shaft can be omitted. In this case, the operating shaft is constituted only by the valve shaft.

  In the above embodiment, the intermediate shaft 32 is brought into contact with the return shaft 42. However, the present invention is not limited to this. In the present invention, a small gap is formed between the intermediate shaft 32 and the return shaft 42. May be. However, in the present invention, the gap between the intermediate shaft and the return shaft needs to be smaller than the stroke amount of the emergency shutoff valve (valve shaft).

  In the above embodiment, the front positioning member 45 is fitted inside the rear positioning member 35. However, the present invention is not limited to this. In the present invention, the rear positioning member 45 may be fitted inside the front positioning member. good.

  The positioning members 35 and 45 are not limited to a circular cross section, and may be formed in other cross sectional shapes, for example, a polygonal cross section such as a triangle or a quadrangle, an elliptical shape, an oval shape, or a deformed cross section. Further, the positioning members 35 and 45 are not necessarily formed in the same cross-sectional shape, but may be formed in different cross-sectional shapes, for example, a circular cross section on one side and a polygonal cross section on the other side.

  Further, in the present invention, the positioning member is not necessarily formed in a cylindrical shape. For example, the one side positioning member is a holed member having an insertion hole, and the other side positioning member can be slidably inserted into the insertion hole. An insertion member may be used, and the insertion member may be fitted into a holed member so as to be positioned between them.

  Furthermore, in the present invention, the positioning member does not necessarily have to be formed in a cylindrical shape so as to be disposed on the entire outer periphery of the intermediate shaft 32 and the return shaft 42. For example, the positioning member may be arranged parallel to the intermediate shaft and the return shaft 42 with an interval in the vertical direction or the horizontal direction.

  In short, the relative positioning between the operating shaft (the valve shaft 22 and the intermediate shaft 32) and the return shaft 42 can be achieved by fitting the one side positioning member and the other side positioning member together. If so, the configuration (shape and the like) and the mounting position of the positioning member are not particularly limited.

  In the above embodiment, the case where the present invention is applied to a large gas meter has been described as an example. However, the present invention is not limited thereto, and the present invention can also be applied to a normal size gas meter used in general households. it can.

  The gas meter of this invention can be used as a gas flow rate measuring device for measuring the flow rate of gas.

1: Meter casing 13a: Inlet 14: Valve case 15: Emergency shut-off port 22: Valve shaft (working shaft)
23: Emergency shut-off valve 32: Intermediate shaft (working shaft)
35: Rear positioning member (one positioning member)
42: Return shaft 45: Front positioning member (the other positioning member)
48: Bearing 5: Cover member 53: Front lid

Claims (3)

A valve case arranged in the meter casing is fixed to the base on the gas inflow side, an emergency shut-off port is formed on the front wall of the valve case, and an emergency shut-off valve arranged in the valve case is the emergency shut-off Gas is supplied in the open valve state spaced apart from the mouth, and gas is supplied in the closed state in which the emergency shut-off valve closes the emergency shut-off port when the operating shaft advances from the open state. In the closed state, the return shaft is slidably disposed along the axis of the operating shaft at a position corresponding to the front of the operating shaft on the front wall of the meter casing. In the gas meter in which the operating shaft is pushed back by the return shaft and moved back together with the emergency shut-off valve to return to the valve open state by pushing the shaft.
A first positioning member is fixed in the vicinity of the operating shaft in the valve case, and a second positioning member is fixed in the vicinity of the return shaft in the inner surface of the front wall of the meter casing.
The gas meter according to claim 1, wherein the relative position between the operating shaft and the return shaft is fixed by fitting the one side positioning member into the other side positioning member. The operating shaft includes a valve shaft to which the emergency shut-off valve is fixed at a front end, and an intermediate shaft connected to the front end of the valve shaft,
The one side positioning member is formed in a cylindrical shape in which the intermediate shaft is accommodated and disposed so as to protrude forward from the valve case,
The other-side positioning member is formed in a cylindrical shape in which the return shaft is accommodated and arranged so as to protrude rearward from the inner surface of the front wall of the meter casing,
The gas meter according to claim 1, wherein a front end portion of the one side positioning member is fitted into a rear end portion of the other side positioning member. The gas meter according to claim 2, wherein the return shaft is attached to the other positioning member via a bearing.

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