JP6630169B2 - Gas meter - Google Patents

Description

  The present invention relates to a gas meter.

  2. Description of the Related Art Conventionally, a gas meter provided with a flow rate sensor such as an ultrasonic type and a microcomputer has been known. The microcomputer calculates the gas flow rate (instantaneous flow rate) from the gas flow rate measured by the flow rate sensor, and calculates the integrated gas flow rate from this instantaneous flow rate. The calculated integrated flow rate is presented to a user or a meter reader via a display panel provided in the gas meter, for example.

  For example, as shown in Patent Literature 1, a gas meter includes a robust housing (body main body), and the body main body includes a gas inlet connected to a gas supply source and a gas connected to a gas supply destination combustor or the like. An outlet is provided. The gas inlet and the gas outlet are formed at an upper portion of the body main body, and a gas flow path from the gas inlet to the gas outlet is formed in a substantially U shape inside the body main body. I have.

  Note that, for example, Patent Document 2 discloses a flow meter having a configuration in which a flow tube (flow tube) for flowing a fluid to be measured is linearly arranged in the hollow cylindrical outer cylinder along the axial direction of the outer cylinder. It has been disclosed. Further, for example, Patent Literature 3 discloses an apparatus including a straight measuring pipe body through which a measuring fluid flows, and a pair of vibrators arranged at predetermined intervals in an axial direction on the outer circumference of the measuring pipe body. Is disclosed. This device measures the flow rate of a fluid for measurement by determining the flow velocity of a fluid for measurement from the ultrasonic propagation time difference in both directions detected between separated transducers. Here, a measurement space is formed inside the lower housing, and a measurement tube is horizontally arranged in the measurement space.

JP 2015-148525 A JP 2005-274251 A JP 2012-42243 A

  By the way, the conventional gas meter has a bulky shape due to the shape of a gas flow path formed inside the body main body and the like. Therefore, there are inconveniences such as low space efficiency and poor appearance.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a gas meter having a novel configuration.

In order to solve such a problem, a gas meter according to the present invention includes a body main body having a gas inlet and a gas outlet, and a straight gas formed inside the body main body, the gas flowing from the gas inlet to the gas outlet. A flow path, and a display portion disposed on a front portion of the body main body , wherein the body main body continuously extends a central region outward along a longitudinal direction of one of the right side surface portion and the left side surface portion. A bulging portion that bulges in an arc shape, and a concave portion in which the central region is continuously concaved in an arc shape inward along the longitudinal direction of the other side surface portion of the right side surface portion and the left side surface portion. The bulging portion and the concave portion are characterized in that they are set in a shape corresponding to each other such that each side portion contacts the entire surface when the right side portion and the left side portion are brought into contact with each other.

  Here, in the present invention, it is preferable that the display section has a shape that is long in the axial direction of the gas flow path.

  Further, the present invention preferably further includes an acceleration sensor for detecting the direction of gravity and a control unit for controlling information displayed on the display unit. In this case, the control unit determines the posture of the body main body based on the direction of gravity detected by the acceleration sensor, and controls the display direction of the information displayed on the display unit according to the determined posture of the body main body. Is preferred.

  Further, in the present invention, it is preferable that the body main body includes, at a position corresponding to the gas inflow port or the gas outflow port, a plug portion connectable to a socket portion connected to an end of the gas pipe. In this case, it is preferable that the socket portion and the plug portion have a joint structure that can be disconnected by a one-touch operation.

  According to the present invention, a gas meter having a novel configuration can be provided. As a result, it is possible to suppress a decrease in space efficiency, poor appearance, and the like.

Perspective view showing the configuration of the gas meter according to the present embodiment. Explanatory drawing showing the configuration of the gas meter shown in FIG. FIG. 2 is a block diagram schematically showing the configuration of the gas meter according to the embodiment. Explanatory diagram showing the relationship between the posture of the body body and the display direction Illustration of pipe fittings Explanatory drawing showing the parallel arrangement structure of gas meters The perspective view which shows the structure of the gas meter which concerns on the modification of this embodiment. Explanatory drawing showing the configuration of the gas meter shown in FIG. The perspective view which shows the structure of the gas meter which concerns on the modification of this embodiment. Explanatory drawing showing the configuration of the gas meter shown in FIG. The perspective view which shows the structure of the gas meter which concerns on the modification of this embodiment. Explanatory drawing showing the configuration of the gas meter shown in FIG.

  FIG. 1 is a perspective view illustrating a configuration of a gas meter 1 according to the present embodiment. 2A and 2B are explanatory diagrams showing the configuration of the gas meter 1 shown in FIG. 1, wherein FIG. 2A is a front view and FIG. 2B is a top view. FIG. 3 is a block diagram schematically illustrating the configuration of the gas meter 1 according to the present embodiment. The gas meter 1 according to the present embodiment is disposed on a supply path (gas pipe) that supplies gas from a gas supply source to a gas supply destination, calculates a flow rate of gas used at the gas supply destination, and calculates an integrated flow rate and the like. Is displayed.

  The gas meter 1 includes a body main body 10 which is a housing formed of a metal material such as aluminum or an aluminum alloy. The body main body 10 has a substantially quadrangular prism shape, and has a shape that is long in the height direction of the quadrangular prism. In the example shown in FIG. 1, the body main body 10 is installed so that its longitudinal direction coincides with the vertical direction (the direction of gravity).

  The body main body 10 has one gas inlet 11 on its upper surface 10a and one gas outlet 12 on its lower surface 10b. The gas inlet 11 is connected to a gas supply source via an upstream pipe (gas pipe) 200, and the gas outlet 12 is connected to a gas supply destination via a downstream pipe (gas pipe) 201. For the connection between the gas inlet 11 and the upstream pipe 200 and the connection between the gas outlet 12 and the downstream pipe 201, a pipe joint 15 (joint structure) that can be disconnected by one-touch operation is used.

  One gas passage 13 extending from the gas inlet 11 to the gas outlet 12 is formed inside the body 10. In the present embodiment, the gas passage 13 has a straight shape that extends linearly in the vertical direction from the gas inlet side (gas inlet 11) to the gas outlet side (gas outlet 12).

  Note that the gas inlet 11 and the gas outlet 12 may be set to have a relationship facing each other so that the gas passage 13 has a straight shape. However, since the flow velocity sensor 5 for measuring the gas flow is disposed in the gas flow path 13, the gas flow path 13 corresponds to the longitudinal direction of the body main body 10 from the viewpoint of securing the measurement distance. Preferably, it is formed.

  In the present embodiment, the front portion 10c of the body main body 10 is an area where a display panel 2 and a return button 4 described later are arranged. A rear portion 10f is located behind the front portion 10c, and left and right side portions 10d and 10e facing each other are located on both sides of the front portion 10c and the rear portion 10f.

  A bulging portion 10d1 bulging outward is set on the right side surface portion 10d of the left and right side surface portions 10d and 10e. For example, the bulging portion 10d1 has an outer curved shape in which a central region of the right side surface portion 10d is bulged in an arc shape, and is set continuously along the longitudinal direction of the body main body 10. On the other hand, a concave portion 10e1 that is depressed inward is set on the left side surface portion 10e. For example, the concave portion 10e1 has an inner curved shape in which the entire area of the central region of the left side surface portion 10e is depressed in an arc shape, and is set continuously along the longitudinal direction of the body main body 10. The bulging portion 10d1 and the concave portion 10e1 are set in shapes corresponding to each other. Therefore, when the right side surface 10d of the gas meter 1 and the left side surface 10e of the gas meter 1 are brought into contact with each other, the side surfaces 10d and 10e have a relationship such that they contact each other over the entire surface.

  The gas meter 1 having such a housing configuration mainly includes a display panel 2, a return button 4, a flow rate sensor 5, a pressure sensor 6, a shutoff valve 7, a communication unit 8, an acceleration sensor 9, and a microcomputer (microcomputer) 100. Have been. Further, the gas meter 1 has a battery (not shown) serving as a power supply mounted therein, and is operated by the power of the battery.

  The display panel 2 is composed of, for example, an LCD or the like. The display panel 2 is controlled by the microcomputer 100 and displays information processed by the microcomputer 100. Representative information displayed on the display panel 2 is the integrated flow rate.

  The display panel 2 is arranged on the front of the gas meter 1, that is, on the front part 10c of the body main body 10, and is arranged so as to be located on the front of the gas flow path 13. In other words, when facing the front of the display panel 2, the gas flow path 13 is positioned behind the display panel 2. Further, the display panel 2 has a rectangular shape that is long in the axial direction of the gas flow path 13.

  The return button 4 is arranged on the front of the gas meter 1 (not shown in FIG. 1). The return button 4 is constituted by, for example, a touch panel arranged so as to overlap the display panel 2. The return button 4 is electrically connected to the microcomputer 100. When the return button 4 is operated, an operation signal is input to the microcomputer 100.

  The return button 4 is operated (for example, a long-press operation) when the shut-off valve 7 is closed to open the shut-off valve 7. For example, when an earthquake or a gas leak is determined, the gas meter 1 closes the shutoff valve 7 to shut off gas. On the other hand, at the time of solving a problem such as an earthquake or a gas leak, by operating the return button 4, the shut-off valve 7 is opened and the use of gas can be resumed.

  The return button 4 functions as an operation unit for operating the gas meter 1 in addition to opening the shutoff valve 7. For example, by operating the return button 4 (for example, a short press operation), various data (integrated flow rate, instantaneous flow rate, etc.) held by the gas meter 1 can be displayed on the display panel 2.

  The return button 4 may be constituted by a mechanical switch or the like in addition to the touch panel.

  The flow rate sensor 5 is provided in the gas flow path 13 inside the gas meter 1. The flow velocity sensor 5 measures the flow (specifically, the flow velocity) of the gas passing through the gas flow path 13 and outputs a signal corresponding to the flow velocity. The signal output from the flow rate sensor 5 is input to the microcomputer 100. As the flow rate sensor 5, for example, an ultrasonic sensor or a flow sensor can be used.

  The pressure sensor 6 is provided in the gas flow path 13 inside the gas meter 1. The pressure sensor 6 measures a gas pressure in the gas flow path 13 and outputs a signal corresponding to the pressure. The signal output from the pressure sensor 6 is input to the microcomputer 100. As the pressure sensor 6, a piezoresistive sensor or a capacitance sensor can be used.

  The shutoff valve 7 is provided in the gas flow path 13 inside the gas meter 1 and shuts off gas in the flow path. As the shutoff valve 7, for example, a ball valve can be used. The ball valve is provided with a ball-shaped valve body having a through flow path rotatably in a valve body, and opens or shuts off gas by rotating the valve body around a valve shaft. By using a ball valve as the shut-off valve 7, the size of the shut-off valve 7 itself can be reduced, and the size of the body 10 can be reduced.

  The communication unit 8 is for the microcomputer 100 of the gas meter 1 to communicate with external devices (setting device, meter reading device and center device). The communication unit 8 includes terminals through which various signals are input / output (for example, an N-line terminal for a telephone line, a terminal for connecting to a gas leak alarm, a terminal for connecting to a carbon monoxide alarm, and the like). It can be composed of a terminal block, a wireless communication device using radio waves or light, or the like.

  The acceleration sensor 9 detects the direction of gravity. The acceleration sensor 9 is, for example, a three-axis acceleration sensor, detects the direction of gravity in the real space, and outputs a signal according to the detection result. A signal output from the acceleration sensor 9 is input to the microcomputer 100.

  The microcomputer 100 is a control unit that controls the gas meter 1. The microcomputer 100 mainly includes a CPU 100a, a ROM 100b, and a RAM 100c. The CPU 100a controls the overall control of the gas meter 1. The ROM 100b is a read-only memory that can be accessed by the CPU 100a, and stores programs to be executed by the CPU 100a and various data. The RAM 100c is a memory from which data can be read and written freely, and stores various data generated during the operation of the gas meter 1 under the control of the CPU 100a. The microcomputer 100 is mounted on a control board, for example, and the control board is housed inside the body main body 10.

  Hereinafter, the operation of the gas meter 1 will be described. The operation of the gas meter 1 is realized by the microcomputer 100. The microcomputer 100 processes the measurement results measured by the flow rate sensor 5 and the pressure sensor 6.

  For example, the microcomputer 100 calculates the gas flow rate (instantaneous flow rate) by multiplying the flow velocity data output from the flow velocity sensor 5 by the cross-sectional area of the gas flow path 13. Then, the microcomputer 100 calculates the integrated flow rate by integrating the calculated gas flow rates.

  Further, when the microcomputer 100 determines the operation of the return button 4 (for example, a short press operation), the microcomputer 100 displays the integrated flow rate on the display panel 2. Further, when the microcomputer 100 determines that the return button 4 is re-operated (for example, a long-press operation) during the display of the integrated flow, different data (for example, instantaneous flow) is displayed.

  Further, the microcomputer 100 outputs a seismic signal when a change in flow rate, a change in pressure measured by the pressure sensor 6, or a predetermined swing is detected, based on a signal from a seismic sensor (not shown). When the predetermined shutoff condition is satisfied, the control unit controls the return button 4 to shut off the gas.

  FIG. 4 is an explanatory diagram showing the relationship between the attitude of the body main body 10 and the display direction. As one of the features of the present embodiment, the microcomputer 100 determines the posture of the body main body 10 based on the direction of gravity detected by the acceleration sensor 9.

  The posture of the body main body 10 is determined from, for example, four postures: an upward posture, a right lateral posture, a left lateral posture, and a downward posture. The upward posture refers to a posture in which the longitudinal direction of the body main body 10 is within a predetermined angle range θ1 (for example, 45 °) including the direction of gravity with the gas inlet 11 being upward. The right lateral orientation refers to a posture in which the gas inlet 11 is on the right side (the left side surface portion 10e is upward) and the longitudinal direction of the body main body 10 is within a predetermined angle range θ2 (for example, 45 °) including the horizontal direction. The left sideways posture refers to a posture in which the gas inlet 11 is on the left side (the right side portion 10d is upward) and the longitudinal direction of the body main body 10 is within a predetermined angle range θ3 (for example, 45 °) including the horizontal direction. The downward posture refers to a posture in which the longitudinal direction of the body main body 10 is within a predetermined angle range θ4 (for example, 45 °) including the direction of gravity with the gas inlet 11 being below (the gas outlet 12 being above).

  Then, the microcomputer 100 controls the display direction of the information displayed on the display panel 2 according to the determined posture of the body main body 10. In this case, the reference display direction of the display panel 2 is set based on a state in which the longitudinal direction of the body main body 10 coincides with the direction of gravity with the gas inlet 11 being upward.

  First, when the posture of the body main body 10 is the upward posture, the microcomputer 100 displays information in the reference display direction (see FIG. 4A). On the other hand, when the posture of the body main body 10 is the right sideways posture, the microcomputer 100 displays information in a direction (second display direction) rotated by 90 ° counterclockwise from the reference display direction ( FIG. 4B). Further, when the posture of the body main body 10 is the left sideways posture, the microcomputer 100 displays information in a direction (third display direction) rotated clockwise by 90 ° from the reference display direction (FIG. 4 (c)). Furthermore, when the posture of the body main body 10 is the downward posture, the microcomputer 100 displays information in a direction (a fourth display direction) rotated by 180 ° from the reference display direction (see FIG. 4D). ).

  In the present embodiment, as shown in FIG. 1, the gas meter 1 is installed in an upward posture. However, by performing such display control, the display direction of the information displayed on the display panel 2 is set based on the direction of gravity. Thereby, the installation direction (posture) of the gas meter 1 can be freely selected, and the information displayed on the gas meter 1 can be easily recognized regardless of the installation direction.

  In the present embodiment, the posture of the body main body 10 is divided into four, and information is displayed in any of the four display directions. However, the display direction of the information may be controlled in linear correspondence with the posture of the body main body 10. Further, there may be a case where the installation of the gas meter 1 in a specific posture is prohibited. In this case, when the posture of the body main body 10 is the specific posture, for example, the downward posture, the display of information in the fourth display direction corresponding to the downward posture may be prohibited. By prohibiting the display in the fourth display direction, it can be notified that the gas meter 1 is installed in the prohibited direction through the appropriateness of the display direction.

  Hereinafter, the installation direction of the gas meter 1 according to the present embodiment will be described. The gas meter 1 is installed by connecting the gas inlet 11 of the body main body 10 to the upstream pipe 200 and connecting the gas outlet 12 of the body main body 10 to the downstream pipe 201.

  FIG. 5 is an explanatory diagram of the pipe joint 15. The connection between the gas inlet 11 of the body main body 10 and the upstream pipe 200 and the connection between the gas outlet 12 of the body main body 10 and the downstream pipe 201 can be released by a one-touch operation. Joint structure) is used. Hereinafter, the pipe joint 15 relating to the connection between the gas inlet 11 and the upstream pipe 200 will be described, but the same applies to the joint structure of the pipe joint 15 connecting the gas outlet 12 and the downstream pipe 201.

  The pipe joint 15 includes a plug section 16 on the body main body 10 side and a socket section 210 on the upstream pipe 200 side.

  The plug portion 16 is set at a position corresponding to the gas inlet 11 of the body 10. The plug portion 16 includes a plug body 16a and a ridge 16b. The plug body 16a includes a part on the upstream side of the gas flow path 13 communicating with the gas inlet 11, and is formed in a cylindrical shape. The plug body 16a forms a part to be inserted into the socket part 210. The ridge 16b is a convex portion continuously formed along the circumferential direction on the outer peripheral surface of the plug main body 16a. The ridge 16b has a function of engaging with a lock mechanism 210b described later when the plug 16 is inserted into the socket 210.

  The socket part 210 is provided at a downstream end of the upstream pipe 200. The socket section 210 includes a socket body 210a, a lock mechanism 210b, and a one-touch operation section 210c.

  The socket body 210a has a cylindrical shape having a hollow space (socket space) into which the plug 16 is inserted. The locking mechanism 210b locks the plug 16 inserted into the socket space of the socket main body 210a. For example, the lock mechanism 210b is configured to be able to advance and retreat along the radial direction of the socket main body 210a, and locks the plug portion 16 by engaging the lock mechanism 210b with the ridge 16b of the plug main body 16a.

  The one-touch operation unit 210c is a cylindrical member provided around the socket main body 210a, and is configured to be slidable between a first operation position A1 and a second operation position A2. The one-touch operation section 210c is biased by a biasing means such as a spring and positioned at the second operation position A2. On the other hand, when the operator slides the one-touch operation unit 210c against the urging force, the one-touch operation unit 210c can be switched to the first operation position A1.

  When the one-touch operation unit 210c is located at the first operation position A1, the lock mechanism 210b is in a state where it can freely advance and retreat along the radial direction of the socket body 210a. In this case, when the plug portion 16 is inserted into or removed from the socket space of the socket main body 210a, the lock mechanism 210b is retracted outward, and the lock mechanism 210b is not caught by the ridge 16b of the plug main body 16a. Thus, the plug 16 can be inserted and removed (released state).

  On the other hand, when the one-touch operation section 210c is in the second operation position A2, the lock mechanism 210b is restricted from moving in the radial direction of the socket main body 210a, and the lock mechanism 210b is in a state in which the front end portion partially enters the socket space. Become. Therefore, when the plug portion 16 is inserted into the socket space of the socket main body 210a, the lock mechanism 210b engages with the protrusion 16b of the plug main body 16a. Thereby, the plug part 16 is connected to the socket part 210 (connected state).

  In the connection between the gas inlet 11 and the upstream pipe 200, first, the operator grips the one-touch operation unit 210c of the socket unit 210 and operates the one-touch operation unit 210c to the first operation position A1. In this operation state, the plug section 16 of the body main body 10 is inserted into the socket space of the socket main body 210a. Then, after the insertion into the socket space is completed, when the operator releases the gripped one-touch operation unit 210c, the one-touch operation unit 210c switches from the first operation position A1 to the second operation position A2. Thus, the connection by the pipe joint 15 is completed, and the connection between the gas inlet 11 and the upstream pipe 200 is completed.

  Subsequently, the connection between the gas outlet 12 and the downstream pipe 201 is performed. In the connection between the gas outlet 12 and the downstream pipe 201, similarly to the connection between the gas inlet 11 and the upstream pipe 200, the gas outlet 12 and the downstream pipe 201 are operated by one-touch operation of the pipe joint 15 (joint structure). The connection with is completed. In this case, the predetermined range 201a connected to the socket 210 of the downstream pipe 201 is formed of a flexible pipe, and is designed so that the socket 210 and the plug 16 can be easily connected. .

  When a plurality of gas meters 1 are provided, such as in a two-family house or an apartment house, these gas meters 1 are arranged in parallel. As shown in FIG. 6, when arranging the gas meter 1 in an upward posture, a plurality of gas meters 1 are arranged side by side. At this time, the adjacent gas meters 1 are arranged such that the right side portion 10d of one gas meter 1 and the left side portion 10e of the other gas meter 1 are in contact with each other. Since the surface shapes of both side surfaces 10d and 10e correspond to each other, the gas meters 1 adjacent to each other can be arranged side by side in the lateral direction by contacting them.

  As described above, the gas meter 1 according to the present embodiment includes the body main body 10 including the gas inlet 11 and the gas outlet 12 and the gas formed in the body main body 10, and the gas flows from the gas inlet 11 to the gas outlet 12. It has a straight gas passage 13 and a display panel 2 arranged on the outer surface of the body 10. In this case, the gas flow path 13 is positioned behind the display panel 2 in a state facing the front of the display panel 2.

  According to this configuration, the gas passage 13 is formed in a straight shape from the gas inlet 11 to the gas outlet 12. Thus, it is not necessary to include a gas passage having a complicated shape, so that the body main body 10 can be made compact. In addition, since the gas passages 13 are arranged behind the display panel 2 so as to overlap with each other, the body 10 can be made more compact as compared with a state where the display panel 2 and the gas passages 13 are displaced from each other. it can. As a result, conventional inconveniences such as low space efficiency and poor appearance can be solved. Thereby, the degree of freedom relating to the installation of the gas meter 1 can be improved, and the gas meter 1 can be installed in various environments.

  In the present embodiment, the display panel 2 has a shape that is long in the axial direction of the gas flow path 13.

  Since the display panel 2 is provided along the longitudinal direction of the body main body 10, a sense of unity in design can be obtained, and the appearance can be improved. Further, since the display panel 2 exists along the longitudinal direction of the body main body 10, a sufficient display area can be secured.

  Further, in the body main body 10 of the present embodiment, a bulging portion 10d1 bulging outward is set in the right side surface portion 10d, and a concave portion 10e1 concaved inward is set in the left side surface portion 10e. I have. In this case, the bulging portion 10d1 and the concave portion 10e1 are set to have shapes corresponding to each other such that when the right side surface portion 10d and the left side surface portion 10e are brought into contact with each other, the side surface portions 10d and 10e come into contact with each other over the entire surface. ing.

  According to this configuration, when the gas meters 1 are arranged adjacent to each other, the gas meters 1 can be aligned by fitting the left and right side portions 10d and 10e facing each other. Thereby, the adjacent gas meters 1 can be arranged neatly. As a result, the inconvenience of the conventional gas meter, such as low space efficiency and poor appearance, can be solved by arranging the individual gas meters clutteredly.

  In the present embodiment, the gas meter 1 is installed in an upward position, but the gas meter 1 may be installed in a downward position, a right sideways position, or a left sideways position. In the gas meter 1 of the present embodiment, since the body main body 10 is made compact, it is possible to improve the space efficiency and the external appearance even when installed in each posture. Thereby, the degree of freedom related to the installation of the gas meter 1 can be improved, and the gas meter 1 can be used in various environments. Further, even when the gas meters 1 are installed in the right sideways posture or the left sideways posture, by arranging the plurality of gas meters 1 in the vertical direction, they can be arranged neatly. As a result, by arranging a plurality of gas meters, it is possible to solve conventional inconveniences such as low space efficiency and poor appearance.

  Further, in the present embodiment, the gas meter 1 further includes an acceleration sensor 9 for detecting the direction of gravity, and a microcomputer 100 for controlling information displayed on the display panel 2. In this case, the microcomputer 100 determines the posture of the body main body 10 based on the direction of gravity detected by the acceleration sensor 9, and displays the information displayed on the display panel 2 according to the determined posture of the body main body 10. Is controlling.

  According to this configuration, the display direction is controlled in accordance with the posture at the time of installation of the gas meter 1, so that the displayed information can be easily visually recognized regardless of the posture of the gas meter 1. Thereby, the degree of freedom relating to the installation of the gas meter 1 can be improved, and the gas meter 1 can be installed in various environments.

  Further, in the present embodiment, the body main body 10 has a plug portion 16 which can be connected to a socket portion 210 connected to an end of the gas pipe at a position corresponding to the gas inlet 11 and the gas outlet 12. Each has it. In this case, the socket 210 and the plug 16 have a joint structure that can be disconnected by a one-touch operation.

  According to this configuration, the connection between the gas meter 1 and the upstream pipe 200 / downstream pipe 201 can be performed by one-touch operation. Thereby, it is not necessary to prepare a dedicated tool at the time of the installation work, and the installation work can be easily performed even in a small environment.

  In the present embodiment, a flexible pipe is used in a predetermined range 201a connected to the socket 210 of the downstream pipe 201. In the present embodiment, the gas inlet 11 and the gas outlet 12 are located above and below the body main body 10, however, when the space width between the upstream pipe 200 and the downstream pipe 201 is fixed, the gas meter 1 becomes very difficult. However, since a part of the downstream pipe 201 is formed of a flexible pipe, the connection between the gas meter 1 and the downstream pipe 201 can be easily performed.

  In the present embodiment, a part of the downstream pipe 201 is configured by a flexible pipe, but a similar configuration may be applied to the upstream pipe 200.

  In the embodiment described above, the gas meter 1 having various aspects has been described. However, the gas meter 1 according to the present embodiment includes at least a body main body 10 having a gas inlet 11 and a gas outlet 12, and a gas formed from the gas inlet 11 to the gas outlet 12. It suffices to have the straight gas flow path 13 flowing and the display panel 2 disposed on the outer surface of the body main body 10. In this case, the gas flow path 13 is positioned behind the display panel 2 when facing the front of the display panel 2. Such a gas meter 1 may be configured as shown in FIGS. 7 to 12.

  As described above, the gas meter according to the embodiment of the present invention has been described. However, it goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Gas meter 10 Body main body 10a Upper surface part 10b Lower surface part 10c Front part 10d Right side part 10d1 Swelling part 10e Left side part 10e1 Concave part 10f Back part 11 Gas inlet 12 Gas outlet 13 Gas flow path 15 Pipe joint 16 Plug part 16a Plug Main body 16b Ridge 2 Display panel (display section)
4 return button 5 flow velocity sensor 6 pressure sensor 7 shut-off valve 8 communication unit 9 acceleration sensor 100 microcomputer (control unit)
200 upstream piping 201 downstream piping 210 socket part 210a socket body 210b locking mechanism 210c one-touch operation part

Claims (4)

A body body having a gas inlet and a gas outlet,
A straight gas flow path formed inside the body main body and through which gas flows from the gas inlet to the gas outlet;
A display unit disposed on a front portion of the body main body,
The body main body includes a bulging portion that continuously bulges outward in a central region in an arc shape along the longitudinal direction of one of the right side surface portion and the left side surface portion, and the right side surface portion and the left side surface portion. Having a concave portion in which the central region is continuously depressed in an arc inward along the longitudinal direction of the other side portion,
The bulging portion and the concave portion are characterized in that they are set in a shape corresponding to each other so that each side portion contacts the entire surface when the right side portion and the left side portion are brought into contact with each other. Gas meter.   The gas meter according to claim 1, wherein the display unit has a shape that is long in an axial direction of the gas flow path. An acceleration sensor for detecting the direction of gravity,
A control unit that controls information displayed on the display unit,
The control unit determines a posture of the body main body based on a direction of gravity detected by the acceleration sensor, and controls a display direction of information displayed on the display unit according to the determined posture of the body main body. The gas meter according to claim 1 or 2 , wherein: The body body includes a plug portion connectable to a socket portion connected to an end of a gas pipe at a position corresponding to the gas inlet or the gas outlet,
The gas meter according to any one of claims 1 to 3 , wherein the socket part and the plug part have a joint structure that can be disconnected by a one-touch operation.

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