JP6866238B2 - Meter unit - Google Patents

Description

The present invention relates to a meter unit in which a flow meter is detachably connected to a water stopcock unit.

Patent Document 1 describes a meter unit installed at the upstream end of a water pipe that draws tap water from a water pipe into a building such as a house. The meter unit of the same document is a branch pipe that branches the water flowing through the distribution pipe into a plurality of water pipes, a plurality of unit bodies connected to the branch pipe, and a base on which the branch pipe and the plurality of unit bodies are placed. To be equipped. The unit body is equipped with a ball stopcock, a water meter and a check valve. The ball stopcock is connected to the branch pipe, and the water meter is detachably connected between the ball stopcock and the check valve.

As shown in FIG. 7, the branch pipe 101 includes an inflow pipe portion 102 connected to a water distribution pipe, a plurality of tributary pipe portions 103 to which each y-knit main body is connected, an inflow pipe portion 102, and a plurality of tributary pipe portions. It includes a connecting pipe portion 104 that connects to and from 103. The inflow pipe portion 102 projects from the central portion of the connecting pipe portion 104 in the pipe axis direction in a direction orthogonal to the pipe axis of the connecting pipe portion 104. The plurality of tributary pipe portions 103 are provided at equal intervals in the pipe axis direction of the connection pipe portion 104 of the connection pipe portion 104, and each protrudes in a direction orthogonal to the pipe axis of the connection pipe portion 104. The pipe axes of the tributary pipe portions 103 are parallel to each other, and the protruding direction in which each tributary pipe portion 103 protrudes from the connecting pipe portion 104 is opposite to the protruding direction in which the inflow pipe portion 102 protrudes from the connecting pipe portion 104. is there. Each ball stopcock of the plurality of unit bodies is connected to the tip (downstream side) of the tributary pipe portion 103, respectively. The ball stopcock, water meter, and check valve that make up the unit body are arranged along the pipe axis of each tributary pipe portion 103.

Japanese Unexamined Patent Publication No. 2011-214394

Each tributary pipe if the pipe axes of the multiple tributary pipe parts of the branch pipe extend parallel to each other and the ball stopcock, water meter and check valve are arranged along the pipe axis of each tributary pipe part. A ball stopcock, a water meter and a check valve connected to the part are arranged in parallel. Therefore, the meter unit can be relatively compactly configured in the direction orthogonal to the pipe axis of each tributary pipe portion. Here, in order to reduce the installation space of the meter unit, the meter unit is required to be compact in the direction of the pipe axis of each tributary pipe portion and the direction of the pipe shaft of the inflow pipe portion.

An object of the present invention, in view of the above problems, is to provide a meter unit comprising a stop cock unit capable of meter unit compact.

In order to solve the above problems, the meter unit of the present invention has a water stopcock unit, and the water stopcock unit has a first fluid flow port and a second fluid flow coaxial with the first fluid flow port. A valve box provided with a mouth, a ball valve body arranged in the valve box, a first valve seat fixed to the valve box and located between the ball valve body and the first fluid flow port, and A ball stopcock portion having a second valve seat fixed to the valve box and located between the ball valve body and the second fluid flow port, and the first fluid flow port and the second fluid flow port. It has a pipe portion having a pipe shaft extending in a direction intersecting the axis of the valve box passing through the above, and a pipe joint portion having a communication port opening in the inner wall surface of the pipe portion. The first fluid flow port communicates with the valve box portion in which the first fluid flow port and the fixing portion of the first valve seat are formed in the valve box, and the pipe portion is an integral molded product. There, fluid flows in from the second fluid flow port of the water stopcock unit, and a first flow meter is detachably connected to the downstream side of one end opening of the pipe shaft in the direction of the pipe shaft. A second fluid meter is detachably connected to the downstream side of the other end opening .

The faucet unit of the meter unit of the present invention includes a valve box portion in which the first fluid flow port and the fixing portion of the first valve seat are formed in the valve box of the ball faucet portion, and the pipe portion of the pipe joint portion. Is an integrated molded product. Therefore, the valve box and the pipe portion can be brought close to each other in the axial direction of the valve box. Therefore, the faucet unit including the ball faucet portion and the pipe joint portion can be shortened in the axial direction of the valve box. Here, when the water stopcock unit is adopted as a meter unit having a branch pipe having a plurality of tributary pipe portions and a plurality of ball water stopcocks connected to each tributary pipe portion, the connection in the branch pipe is used. A part of the pipe part, one tributary pipe part, and the ball stopcock connected to the tip of the tributary pipe part can be replaced with the water stopcock unit, and the connecting pipe part (pipe part) and the ball water stoppage can be replaced. It can be brought close to the plug (valve box). Further, in this case, since the valve box of the ball stopcock part functions as a tributary pipe part of the branch pipe, the meter unit can be moved in the axial direction of the valve box by the amount that the tributary pipe part can be omitted. Can be shortened.

In the present invention, the inner diameter dimension of the first fluid flow port can be different from the inner diameter dimension of the pipe portion. For example, if the inner diameter dimension of the first fluid flow port is shorter than the inner diameter dimension of the pipe portion, it is suitable for branching the fluid flowing through the pipe portion to the valve box side. Further, for example, if the inner diameter dimension of the first fluid flow port is made longer than the inner diameter dimension of the pipe portion, it is suitable for branching the fluid flowing in from the second liquid flow port on the pipe portion side.

In the present invention, it is desirable that the pipe shaft and the axis line intersect vertically, and the first distance between the pipe shaft and the first valve seat is shorter than the inner diameter dimension of the pipe portion. In this way, since the pipe portion and the valve box are close to each other, the water stop valve unit can be easily shortened in the axial direction of the valve box.

In the present invention, the pipe shaft and the axis line intersect vertically, and the second distance between the pipe shaft and the second valve seat is shorter than twice the inner diameter dimension of the pipe portion. desirable. By doing so, it is possible to prevent the valve box from being separated from the pipe portion, so that the water stop valve unit can be easily shortened in the axial direction of the valve box.

In the present invention, the pipe joint portion may be such that one end of the pipe portion in the pipe axial direction is closed. In this way, the water stopcock unit can be provided with a flexible flow path from the pipe portion via the valve box.

Here, a meter unit of the present invention, the fluid flows from the second fluid flow port of the stop cock unit, a first flow rate on the downstream side of the one end opening of the tube axis direction of the tube axis The meter is detachably connected, and the second flow meter is detachably connected to the downstream side of the other end opening.

In the meter unit of the present invention, the water stopcock unit functions as a branch pipe. That is, the branch pipe includes an inflow pipe portion connected to the water distribution pipe, a plurality of tributary pipe portions, and a connecting pipe portion connecting the inflow pipe portion and the plurality of tributary pipe portions. In the present invention, the valve box of the ball stopcock portion of the stopcock unit functions as an inflow pipe portion in the branch pipe, and the pipe portion of the pipe joint portion functions as a connecting pipe portion and a tributary pipe portion. Here, in the water stopcock unit, it is easy to bring the pipe portion and the valve box close to each other. Therefore, the meter knit can be shortened in the axial direction of the valve box (the axial direction of the inflow pipe portion in the branch pipe).

Further, in another form of the meter unit of the present invention, the valve box of the ball faucet portion of the faucet unit functions as the inflow pipe portion in the branch pipe, and the pipe portion of the pipe joint portion is the connecting pipe portion and the tributary pipe. Functions as a part. Here, in the water stopcock unit, it is easy to bring the pipe portion and the valve box close to each other. Therefore, the meter knit can be shortened.

It is a perspective view of the water meter unit of Reference Example 1. FIG. It is a perspective view and a plan view of the internal unit of a water meter unit. It is sectional drawing which cut the internal unit along the axis of the valve box of a water stopcock unit. It is explanatory drawing of the water stopcock unit. It is a perspective view of the internal unit of the water meter unit of Reference Example 2. FIG. It is explanatory drawing of the water meter unit of Example 1. FIG. It is explanatory drawing of a branch pipe.

Hereinafter, the water stopcock unit and the water meter unit according to the embodiment of the present invention will be described with reference to the drawings.

( Reference example 1 )
FIG. 1 is a perspective view of the water meter unit of Reference Example 1 of the present invention. FIG. 2A is a perspective view of the internal unit of the water meter unit, and FIG. 2B is a plan view of the internal unit. The water meter unit 1 (meter unit) of this example is installed at the upstream end of the water pipe 2 that draws tap water from a water pipe (not shown) into a building such as a house. As shown in FIGS. 1 and 2, the water meter unit 1 includes an inflow port 5 (fluid inlet), a first outlet 6 (first fluid outlet), and a second outlet 7 (second fluid outlet). The cheese 8 provided with the above, two water stop valve units 11 (1) and 11 (2) arranged on the side of the first outlet 6 of the cheese 8, and arranged on the side of the second outlet 7 of the cheese 8. It is provided with two water stopcock units 11 (3) and 11 (4). Further, the water meter unit 1 includes a water meter 13 (flow meter) and a check valve 14 connected to each water stop valve unit 11 via a connecting pipe 12. The water meter 13 is detachable between the water stop valve unit 11 and the check valve 14.

Further, the water meter unit 1 includes a base 15 on which cheese 8, four stopcock units 11, four water meters 13, and four check valves 14 are placed. The base 15 includes a tray 16 and a plate-shaped frame 17 installed inside the tray 16. Cheese 8,
The four stopcock units 11 and the four check valves 14 are fixed to the frame 17. Cheese 8, four faucet units 11, four check valves 14, and a frame 17 constitute an internal unit 19 that is placed inside the tray 16.

In the following description, the three directions orthogonal to each other are the X-axis direction, the Y-axis direction, and the Z-axis direction. The X-axis direction is the arrangement direction of the four water stopcock units 11 arranged with the cheese 8 in between, and one side thereof is the −X direction and the other side is the + X direction. The Y-axis direction is the arrangement direction of the water stop valve unit 11, the water meter 13, and the check valve 14, and the side where the water stop valve unit 11 is located is in the −Y direction and the side where the check valve 14 is located is in the + Y direction. And. The Z-axis direction is the vertical direction, with the lower direction being the −Z direction and the upper direction being the + Z direction.

The cheese 8 is connected to the water pipe with its inflow port 5 oriented in the −Y direction. Each check valve 14 is connected to four water pipes 2 that are drawn into the building. The water flowing into the cheese 8 from the water distribution pipe branches into four tributaries while flowing through each stopcock unit 11. The four tributaries are parallel to each other, and the water flowing through each tributary flows into the four water pipes 2 via the water meter 13 and the check valve 14. In FIG. 1, the arrow indicates the water flow direction.

(Faucet unit)
FIG. 3 is a cross-sectional view of the internal unit 19 cut along the line AA of FIG. 2 (b). FIG. 4A is a partial cross-sectional view of the water stopcock unit 11, and FIG. 4B is a cross-sectional view of the water stopcock unit 11 and the connecting pipe 12. Since each faucet unit 11 has a corresponding structure, the faucet unit 11 (2) located at the end in the + X direction will be described.

As shown in FIG. 3, the water stopcock unit 11 has a ball water stopcock portion 21 and a pipe joint portion 22. As shown in FIG. 4, the ball stopcock portion 21 has a first distribution port 25 (first fluid distribution port) and a second distribution port 26 (second fluid distribution port) coaxial with the first distribution port 25. A valve box 27 provided, a ball valve body 28 arranged in the valve box 27, and an annular first ball seat 29 (No. 1) fixed to the valve box 27 and located between the ball valve body 28 and the first distribution port 25. 1 valve seat) and a second ball seat 30 (second valve seat) fixed to the valve box 27 and located between the ball valve body 28 and the second distribution port 26. The first distribution port 25 is located on the −Y direction side of the second distribution port 26. The first distribution port 25 and the second distribution port 26 have the same inner diameter. The axis L0 of the valve box 27 passing through the center of the first distribution port 25 and the center of the second distribution port 26 extends in the Y-axis direction. The first ball sheet 29 and the second ball sheet 30 are arranged coaxially with the first distribution port 25 and the second distribution port 26.

As shown in FIG. 4B, the ball valve body 28 includes a through flow path 31 penetrating the center thereof. A shaft member 32 for rotation operation extending in the Z-axis direction is connected to the ball valve body 28. The axis of the rotation operation shaft member 32 passes through the center of the ball valve body 28. Further, the axis L1 of the rotation operation shaft member 32 is orthogonal to the through flow path 31. The rotation operation shaft member 32 is supported by the valve box 27 in a state of being rotatable around the axis L1. An operation knob 33 for operating the rotation operation shaft member 32 is connected to the end portion of the rotation operation shaft member 32 in the + Z direction. When the operation knob 33 is rotated, the rotation operation shaft member 32 is rotated, and the ball valve body 28 is rotated in the valve box 27. As a result, when the through flow path 31 of the ball valve body 28 is in the state along the Y-axis direction, the ball stopcock portion 21 is opened and water flows in the valve box 27. Further, when the through flow path 31 of the ball valve body 28 is in a state along the X-axis direction, the ball stopcock portion 21 is closed and water cannot flow in the valve box 27.

The valve box 27 is composed of two members, a first valve box component 35 (valve box portion) and a second valve box component 36 connected to the first valve box component 35 from the + Y direction. The first valve box component 35 includes a first distribution port 25, a recess 41 recessed from the + Y direction side toward the −Y direction side, and a first valve box component 35.
It includes a first fixing portion 42 to which the ball sheet 29 is fixed, and a supporting portion 43 that rotatably supports the rotation operation shaft member 32.

The first distribution port 25 is open to the inner wall surface of the recess 41 in the −Y direction. The first fixing portion 42 is an annular step portion 44 formed on the outer peripheral side of the first distribution port 25 on the inner wall surface of the recess 41 in the −Y direction. The annular step portion 44 includes an annular surface 44a facing in the + Y direction and an annular wall 44b extending in the + Y direction from the outer peripheral edge of the annular surface 44a. The first ball sheet 29 is inserted into the inner peripheral side of the annular wall 44b and fixed to the first valve box constituent member 35 in a state of being in contact with the annular surface 44a. The support portion 43 includes a through hole 47 that penetrates the first valve box component 35 in the Z-axis direction. An opening is made in the inner wall surface of the recess 41 of the through hole 47 in the + Z direction. The rotation operation shaft member 32 penetrates the through hole 47 from the + Z direction and is connected to the ball valve body 28 arranged in the recess 41.

The second valve box component 36 includes a tubular portion 51 extending in the Z-axis direction. The end portion of the tubular portion 51 in the −Y direction is inserted into the recess 41 of the first valve box constituent member 35 and connected to the first valve box constituent member 35. An inner annular protrusion 52 protruding toward the inner peripheral side is provided at an intermediate position on the inner peripheral surface of the tubular portion 51 in the Y-axis direction. The inner peripheral surface of the inner annular protrusion 52 defines the second distribution port 26 of the valve box 27. The second ball sheet 30 is fixed to the annular surface 52a facing the −Y direction in the inner annular protrusion 52 and the inner peripheral surface portion 51a adjacent to the annular protrusion in the −Y direction on the inner peripheral surface of the tubular portion 51. The second fixed portion 53. The second ball seat 30 is fixed to the second valve box component 36 in a state of being in contact with the annular surface 52a of the inner annular protrusion 52 on the inner peripheral side of the inner peripheral surface portion 51a of the tubular portion 51. Further, the tubular portion 51 includes a connecting mechanism 55 for connecting the connecting pipe 12 to the end portion in the + Y direction. The connection mechanism 55 includes a male screw 56 provided on the outer peripheral surface of the end portion of the tubular portion 51, and a bag nut 57 having a female screw 57a screwed with the male screw 56 on the inner peripheral surface.

Here, the connecting pipe 12 includes an outer annular protrusion 61 at an end portion in the −Y direction. The portion of the connecting pipe 12 on the side of the outer annular protrusion 61 in the −Y direction is the insertion portion 12a inserted into the tubular portion 51. An annular recess 62 is provided on the outer peripheral surface of the insertion portion 12a, and an O-ring 63 is attached to the annular recess 62. The connecting pipe 12 has an insertion portion 12a inserted into the tubular portion 51, and the outer annular protrusion 61 is sandwiched between the end face of the tubular portion 51 and the bag nut 57 in the Y-axis direction, whereby the connection pipe 12 is inserted into the water stopcock unit 11. Be connected. The O-ring 63 elastically deforms between the tubular portion 51 and the insertion portion 12a of the connecting pipe 12, and seals between them in a liquid-tight manner. Further, the connecting pipe 12 includes a water meter connecting mechanism 64 to which the water meter 13 is detachably connected to the end portion in the + Y direction. The water meter connecting mechanism 64 includes an annular stopper portion 65 projecting from the + Y direction end of the outer peripheral surface of the connecting pipe 12 to the outer peripheral side, and a bag nut 66 slidably attached to the outer peripheral side of the connecting pipe 12. .. The stopper portion 65 prevents the bag nut 66 from falling off in the + Y direction. On the inner peripheral surface of the bag nut 66, a female screw 66a that can be screwed into a male screw provided on the outer peripheral surface of the connecting pipe portion on the inflow side of the water meter 13 is formed.

Next, the pipe joint portion 22 is located on the −Y direction side of the ball stopcock portion 21. The pipe joint portion 22 communicates with a pipe portion 71 having a pipe axis T extending in a direction (X-axis direction) orthogonal to the axis L0 of the valve box 27 of the ball stopcock portion 21 and an opening in the inner wall surface of the pipe portion 71. It has a mouth 72. The communication port 72 is coaxial with the first distribution port 25 of the valve box 27 of the ball stopcock portion 21 and communicates with the first distribution port 25. The inner diameter of the communication port 72 is the same as the inner diameter of the first distribution port 25. The inner diameter dimension M1 of the communication port 72 and the first distribution port 25 is shorter than the inner diameter dimension N1 of the pipe portion 71.

As shown in FIG. 2, the faucet unit 11 (1) and the faucet unit 11 (3) connected to the cheese 8 connect the cheese 8 to the end portion of the pipe portion 71 on the side of the cheese 8. The connection portion 73 for connecting the pipe portion 71 of the other water stopcock unit 11 is provided at the other end portion. Further, the water stopcock unit 11 (2) and the water stopcock unit 11 (4) located at both ends in the X-axis direction are respectively at the inner end portion (the side where the cheese 8 is located) in the pipe portion 71. A connecting portion 73 for connecting the pipe portions 71 of the units 11 (1) and 11 (3) is provided, and the outer end of the pipe portion 71 (the side opposite to the side where the cheese 8 is located) is the opening of the pipe portion 71. A sealing portion 74 for sealing is provided. The connecting portion 73 includes a male screw or a female screw.

Here, the first valve box component 35 constituting the valve box 27 is a cast product (molded product) integrated with the pipe portion 71. As a result, the pipe portion 71 and the valve box 27 can be arranged close to each other in the axis L0 direction of the valve box 27. In this example, as shown in FIG. 4B, the first distance D1 between the pipe shaft T of the pipe portion 71 and the first ball sheet 29 is shorter than the inner diameter dimension N1 of the pipe portion 71. More specifically, the first distance D1 from the pipe shaft T of the pipe portion 71 to the first ball sheet 29 is the sum of 1/2 of the inner diameter dimension N1 of the pipe portion 71 and the thickness dimension S of the pipe portion 71. It is less than or equal to the dimensions. As a result, the pipe portion 71 and the valve box 27 are arranged close to each other in the axis L0 direction, and in this example, the pipe portion 71 and the valve box 27 are continuous. Therefore, the water stop valve unit 11 is shortened in the axis L0 direction of the valve box 27.

Further, in this example, the second distance D2 between the pipe shaft T of the pipe portion 71 and the second ball sheet 30 is shorter than twice the inner diameter dimension N1 of the pipe portion 71. As a result, the valve box 27 is prevented from being separated from the pipe portion 71, so that the water stop valve unit 11 is shortened in the axis L0 direction of the valve box 27. The first distance D1 can be said to be the distance between the pipe shaft T of the pipe portion 71 and the annular surface 44a of the first fixing portion 42 that fixes the first ball sheet 29.

(Check valve)
As shown in FIG. 3, each check valve 14 faces the water stop valve unit 11 at a predetermined distance in the axis L0 direction of the valve box 27 of the ball stop valve portion 21 of each water stop valve unit 11. It is placed in a position. In this example, the predetermined distance is a distance at which the connection pipe 12 and the water meter 13 can be connected between the water stop valve unit 11 and the check valve 14.

Each check valve 14 includes a valve box 77 having an inflow port 75 and an outflow port 76, an inflow side pipe portion 78 protruding from the valve box 77 in the −Y direction, and an outflow side pipe protruding from the valve box 77 in the + Y direction. A unit 79 is provided. The inflow side pipe portion 78 communicates with the inflow port 75 coaxially with the inflow port 75. The outflow side pipe portion 79 is coaxial with the outflow port 76 and communicates with the outflow port 76. Further, the check valve 14 has an annular valve seat 80 fixed at a position surrounding the inflow port 75 in the valve box 77, a valve body 81 arranged in the valve box 77, and the valve body 81 on the valve seat 80. It is provided with an urging member 82 such as a coil spring that urges toward it. The check valve 14 allows the flow of water from the inflow side pipe portion 78 to the outflow side pipe portion 79, and blocks the flow of water from the outflow side pipe portion 79 to the inflow side pipe portion 78. That is, when water flows from the inflow side pipe portion 78 to the outflow side pipe portion 79, the valve body 81 is separated from the valve seat 80 against the urging force of the urging member 82 by the pressure of the water. As a result, water flows from the inflow side pipe portion 78 to the outflow side pipe portion 79. On the other hand, the water from the outflow side pipe 79 toward the inflow side pipe 78 presses the valve body 81 against the valve seat 80, so that the water does not flow from the outflow side pipe 79 toward the inflow side pipe 78.

A water meter connection mechanism 84 to which the water meter 13 is detachably connected is provided at the tip end portion (end portion in the −Y direction) of the inflow side pipe portion 78. The water meter connection mechanism 84 includes an annular stopper portion 85 projecting from the −Y direction end of the outer peripheral surface of the inflow side pipe portion 78 to the outer peripheral side, and a bag slidably attached to the outer peripheral side of the inflow side pipe portion 78. The nut 86 and an O-ring 87 interposed between the inflow side pipe portion 78 and the bag nut 86 are provided. The stopper portion 85 prevents the bag nut 86 from falling off in the + Y direction. The O-ring 87 is arranged on the + Y direction side of the stopper portion 85. A female screw 86a that can be screwed into a male screw provided on the outer peripheral surface of the connection pipe portion on the outflow side of the water meter 13 is formed on the inner peripheral surface of the bag nut 86. At the tip end portion (end portion in the + Y direction) of the outflow side pipe portion 79, a connection portion 89 for connecting the water pipe 2 drawn into the building is provided. The connecting portion 89 includes a male screw 89a.

(base)
As shown in FIG. 1, the frame 17 of the base 15 has a rectangular shape. The cheese 8, each stopcock unit 11, and each check valve 14 are fixed to the frame 17 using stays and bolts. The tray 16 includes a rectangular bottom plate portion 90 that covers the −Z direction side of the frame 17, and four side plate portions 91 to 94 that rise from the outer peripheral edge of the bottom plate portion 90 to the + Z direction side. Of the four side plate portions 91 to 94, the side plate portion 91 that rises from the end plate portion 90 in the −Y direction and extends in the X-axis direction has an arc shape at the central portion of the end edge in the + Z direction in the X-axis direction. Notched portion 95 is provided. In the notch portion 95, a tubular portion of the cheese 8 provided with the inflow port 5 is placed. Of the four side plate portions 91, the side plate portion 92 that rises from the + Y direction edge of the bottom plate portion 90 and extends in the X-axis direction is provided with four arc-shaped notches 96 at the + Z direction edge. The four notches 96 are provided at equal intervals. Each water pipe 2 connected to the check valve 14 is inserted into each notch 96. As a result, each water pipe 2 is supported by the base 15 (tray 16). The outflow side pipe portion 79 of the check valve 14 is placed in the four notch portions 96, and each water pipe 2 is connected to the outflow side pipe portion 79 of the check valve 14 on the outside of the tray 16. You may.

(Action effect)
In the water meter unit 1 of this example, the cheese 8, the pipe portion 71 of the first stopcock unit 11, the pipe portion 71 of the second stopcock unit 11, and the ball stopcock portion of each stopcock unit 11 The valve box 27 of 21 constitutes a branch pipe for branching the water flowing in from the water distribution pipe. That is, as shown in FIG. 7, the branch pipe 101 connects the inflow pipe portion 102 connected to the water distribution pipe, the plurality of tributary pipe portions 103, and the inflow pipe portion 102 and the plurality of tributary pipe portions 103. In the water meter unit 1 of this example, the flow path portion provided with the first inflow port 5 in the cheese 8 functions as the inflow pipe portion 102 in the branch pipe 101. , The flow path portion between the first outlet 6 and the second outlet 7 of the cheese 8 and the pipe portion 71 of the pipe joint portion 22 of each water stop valve unit 11 function as the connection pipe portion 104 in the branch pipe 101. , The valve box 27 of the ball stopcock portion 21 of each stopcock unit 11 functions as each tributary pipe portion 103 in the branch pipe 101.

Here, the water stopcock unit 11 is an integrally molded product in which the first valve box component 35 constituting the valve box 27 of the ball water stopcock portion 21 is integrally cast with the pipe portion 71 of the pipe joint portion 22. .. Therefore, as compared with the case where the branch pipe 101 shown in FIG. 7 is used and the ball stopcock is connected to the tip of the tributary pipe portion 103, the valve box 27 and the pipe portion 71 in which the ball valve body 28 is arranged Can be approached in the direction of the axis L0 of the valve box 27. Therefore, the faucet unit 11 including the ball faucet portion 21 and the pipe joint portion 22 can be shortened in the axis L0 direction of the valve box 27. In particular, in this example, the first distance D1 from the pipe shaft T of the pipe portion 71 to the first ball sheet 29 is the sum of 1/2 of the inner diameter dimension N1 of the pipe portion 71 and the thickness dimension S of the pipe portion 71. It is less than the total size, and the pipe portion 71 and the valve box 27 are continuous. Therefore, the meter knit can be shortened in the axis L0 direction of the valve box 27 (the pipe axis direction of the tributary pipe portion 103 in the branch pipe 101). Further, since the valve box 27 of the ball stopcock portion 21 functions as the tributary pipe portion 103 of the branch pipe 101, the water meter unit 1 can be shortened by the amount that the tributary pipe portion 103 can be omitted.

Further, in this example, the inner diameter dimension M1 of the first flow port 25 of the water stopcock unit 11 is smaller than the inner diameter dimension N1 of the pipe portion 71. Therefore, the branch pipe 101 configured by using the plurality of water stopcock units 11 is suitable for branching the water flowing in from the pipe portion 71 side to the valve box 27 side.

(Modification example)
In the above example, the water meter unit 1 includes four water stopcock units 11, but the number of water stopcock units 11 can be increased or decreased according to the number of water pipes 2 for branching water from the water distribution pipes. it can. Here, since the water stopcock unit 11 can fulfill the functions of the connection pipe portion 104 and the tributary pipe portion 103 in the branch pipe 101, the number of the water stopcock units 11 connecting the pipe portions 71 can be increased or decreased. , The number of branches of water from the water pipe can be changed flexibly.

In the above example, the connection pipe 12 may be omitted. In this case, a connection mechanism (water meter connection mechanism 64) for detachably connecting the water meter 13 to the + Y direction end portion of the tubular portion 51 of the second valve box component 36 constituting the valve box 27. May be provided.

( Reference example 2 )
FIG. 5 is an explanatory diagram of the water meter unit of Reference Example 2 of the present invention. Since the water meter unit 1A of this example has a configuration corresponding to the above water meter unit 1, the corresponding parts are designated by the same reference numerals and the description thereof will be omitted. Although the tray 16 constituting the base 15 is omitted in FIG. 6, in the water meter unit 1A of this example as well, the tray 16 on which the base 15 mounts the internal unit 19 is provided in the same manner as the water meter unit 1A. Can be prepared. The arrow in FIG. 5 indicates the water flow direction.

The water meter unit 1A of this example is attached to an inflow pipe 111 connected to a water distribution pipe, a first stopcock unit 11 (1) connected to the inflow pipe 111, and a first stopcock unit 11 (1). The second water stopcock unit 11 (2) (second water stopcock unit) connected is provided. In the first water stopcock unit 11 (1), the −X direction side of the pipe portion 71 of the pipe joint portion 22 is connected to the inflow pipe 111, and the + X direction side of the pipe portion 71 is the second water stopcock unit 11 It is connected to the pipe portion 71 of (2). In the pipe portion 71 of the pipe joint portion 22 of the second faucet unit 11 (2), the side opposite to the side connected to the first faucet unit 11 is sealed by the sealing portion 74.

Further, the water meter unit 1A includes a water meter 13 and a check valve 14 connected to each water stop valve unit 11 via a connecting pipe 12. The water meter 13 is detachable between the water stop valve unit 11 (1) and the check valve 14. Further, the water meter 13 is detachable between the water stop valve unit 11 (2) and the check valve 14. Further, the water meter unit 1A includes an inflow pipe 111, two stopcock units 11, two water meters 13, and a frame 17 on which two check valves 14 are placed. The inflow pipe 111, the two stopcock units 11, and the two check valves 14 are fixed to the frame 17.

Also in this example, the same operation and effect as the above-mentioned water meter unit 1 can be obtained. Further, also in this example, the number of water stopcock units 11 can be increased or decreased according to the number of water pipes 2 for branching water from the water distribution pipe. Further, the connecting pipe 12 can be omitted.

( Example 1 )
FIG. 6 is an explanatory diagram of the water meter unit 1B according to the first embodiment to which the present invention is applied. FIG. 6A is a plan view of the water meter unit 1B as viewed from the + Z direction, and FIG. 6B is a cross-sectional view taken along the line BB of FIG. 6A. The arrow in FIG. 6 indicates the water flow direction. Since the water meter unit 1B of this example has a configuration corresponding to the water meter unit 1 described above, the corresponding parts are designated by the same reference numerals and the description thereof will be omitted. Further, in FIG. 6, the check valve 14 connected to the downstream side of the water meter 13 and the base 15 are omitted, but the water meter unit 1B of this example is the same as the water meter units 1 and 1A described above. A check valve 14 connected to the downstream side of the water meter 13 connected to the downstream side of the water meter 13 and a base 15 on which the water stop valve unit 11, the water meter 13 and the check valve 14 are mounted. Can be provided. In this case, the water stop valve unit 11 and the check valve 14 are fixed to the frame 17 of the base 15, and the water meter 13 is detachable between the water stop valve unit 11 and the check valve 14.

As shown in FIG. 6A, the water meter unit 1B of this example has one water stop valve unit 11 and one end of the pipe joint portion 22 of the water stop valve unit 11 in the pipe axial direction. A first water meter 13 detachably connected to a portion opening via an elbow 115, and a second water meter detachably connected to the other end opening of the pipe portion 71 in the pipe axial direction via an elbow 115. 13 and. The second flow port 26 of the valve box 27 of the ball stopcock portion 21 of the water stopcock unit 11 is a water inlet and is connected to a water distribution pipe. The water flowing in from the second flow port 26 of the valve box 27 of the ball stopcock portion 21 branches at the pipe portion 71, and passes through each elbow 115 to each of the first water meter 13 and the second water meter 13. It flows.

As shown in FIG. 6B, also in this example, the first distance D1 between the pipe shaft T of the pipe portion 71 and the first ball sheet 29 is shorter than the inner diameter dimension N1 of the pipe portion 71. On the other hand, in this example, the inner diameter dimension M1 of the first distribution port 25 of the valve box 27 is longer than the inner diameter dimension N1 of the pipe portion 71.

In the water meter unit 1B of this example, the water stop valve unit 11 and the elbow 115 function as the branch pipe 101 shown in FIG. That is, the valve box 27 of the ball stopcock portion 21 of the stopcock unit 11 functions as the inflow pipe portion 102 in the branch pipe 101, the pipe portion 71 of the pipe joint portion 22 functions as the connection pipe portion 104, and the elbow 115 Functions as a tributary pipe portion 103. Here, in the water stopcock unit 11, the first valve box component 35 constituting the valve box 27 of the ball water stopcock portion 21 is an integrally molded product cast integrally with the pipe portion 71 of the pipe joint portion 22. The valve box 27 in which the ball valve body 28 is arranged and the pipe portion 71 can be brought close to each other in the axis L0 direction of the valve box 27. Therefore, the faucet unit 11 including the ball faucet portion 21 and the pipe joint portion 22 can be shortened in the axis L0 direction of the valve box 27. Therefore, the meter knit can be shortened in the axis L0 direction of the valve box 27 (the pipe axis direction of the inflow pipe portion 102 in the branch pipe 101).

Further, in this example, the inner diameter dimension M1 of the first flow port 25 of the water stopcock unit 11 is larger than the inner diameter dimension N1 of the pipe portion 71. Therefore, the branch pipe configured by using the water stop valve unit 11 is suitable for branching the water flowing in from the valve box 27 side on the pipe portion 71 side.

Further, in this example, the flow of water branched to the two water meters 13 via the faucet unit 11 can be stopped by the ball faucet portion 21 of one faucet unit 11. That is, according to this example, in the water meter unit that branches the water from the water distribution pipe into two water pipes 2, one ball stopcock that stops water on the upstream side of the water meter 13 can be used.

In this example, the elbow 115 may be omitted. In this case, a connection mechanism for detachably connecting the water meter 13 may be provided at the + Y direction end portion of the tubular portion 51 of the second valve box component 36 constituting the valve box 27. it can. Further, in this case, the water flow direction in the water meter 13 is a direction orthogonal to the axis L0 of the valve box 27 in the water stop valve unit 11.

It goes without saying that the water stopcock unit 11 can be used for purposes other than those of the water meter unit.

1.1A / 1B ... Water meter unit (meter unit), 2 ... Water pipe, 5 ... Inflow port (fluid inlet), 6 ... 1st outlet (1st fluid outlet), 7 ... 2nd outlet ( 2nd fluid outlet), 8 ... cheese, 11/11 (1) -11 (4) ... water stopcock unit, 12 ... connection pipe, 12a ... insertion part, 13 ... water meter, 14 ... check valve, 15 ... base, 16 ... tray, 17 ... frame, 19 ... internal unit, 21 ... ball stopcock part, 22 ... pipe joint part, 25 ... first flow port (first fluid flow port), 26 ... second flow port (Second fluid flow port), 27 ... valve box, 27 ... valve box, 28 ... ball valve body, 29 ... first ball seat (first valve seat), 30 ... second ball seat (second valve seat), 31 ... Through flow path, 32 ... Rotational operation shaft member, 33 ... Operation knob, 35 ... First valve box component (valve box part), 36 ... Second valve box component, 41 ... Recess, 42 ... 1 Fixed part, 43 ... Support part, 44 ... Circular step part, 44a ... Circular ring surface, 44b ... Circular wall, 47 ... Through hole, 51 ... Cylindrical part, 51a ... Inner peripheral surface part, 52 ... Inner annular protrusion, 52a ... annular surface, 53 ... second fixing part, 55 ... connection mechanism, 56 ... male screw, 57 ... bag nut, 57a ... female screw, 59 ... connection part, 59a ... male screw, 61 ... outer annular protrusion, 62 ... annular recess, 63 ... O-ring, 64 ... water meter connection mechanism, 65 ... stopper, 66 ... bag nut, 66a ... female screw, 71 ... pipe, 72 ... communication port, 73 ... connection, 74 ... closure Part, 75 ... Inflow port, 76 ... Outlet, 77 ... Valve box, 78 ... Inflow side pipe part, 79 ... Outflow side pipe part, 80 ... Valve seat, 81 ... Valve body, 82 ... Biasing member, 84 ... Water supply Meter connection mechanism, 85 ... Stopper, 86 ... Bag nut, 86a ... Female screw, 87 ... O ring, 89 ... Connection, 90 ... Bottom plate, 91-94 ... Side plate, 95 ... Notch, 96 ... Cut Notch, 101 ... Branch pipe, 102 ... Inflow pipe part, 103 ... Each tributary pipe part, 103 ... Tributary pipe part, 104 ... Connection pipe part, 111 ... Inflow pipe, 115 ... Elbow, D1 ... Pipe shaft The first distance between the first ball sheet, D2 ... the second distance between the tube shaft of the pipe portion and the second ball sheet, L0 ... the axis of the valve box, L1 ... the axis of the shaft member for rotation operation, M1 ... Inner diameter dimension of the first flow port of the valve box, N1 ... Inner diameter dimension of the pipe portion, S ... Thickness dimension of the pipe portion, T ... Pipe shaft of the pipe portion

Claims (5)

Has a faucet unit,
The water stopcock unit is
A valve box having a first fluid flow port and a second fluid flow port coaxial with the first fluid flow port, a ball valve body arranged in the valve box, and the ball valve body fixed to the valve box. A ball having a first valve seat located between the first fluid flow port and a second valve seat fixed to the valve box and located between the ball valve body and the second fluid flow port. The water stopcock part and
A pipe portion having a pipe shaft extending in a direction intersecting the axis of the valve box passing through the first fluid flow port and the second fluid flow port, and a pipe portion having a communication port opening to the inner wall surface of the pipe portion. Has a joint part,
The communication port and the first fluid flow port communicate with each other.
In the valve box, the valve box portion in which the first fluid flow port and the fixing portion of the first valve seat are formed and the pipe portion are integrally molded products.
A fluid flows in from the second fluid flow port of the water stopcock unit, and a first flow meter is detachably connected to the downstream side of one end opening of the pipe shaft in the direction of the pipe axis, and the other. A meter unit characterized in that a second flow meter is detachably connected to the downstream side of the end opening . The meter unit according to claim 1, wherein the inner diameter dimension of the first fluid flow port is different from the inner diameter dimension of the pipe portion. The pipe axis and the axis line intersect vertically, and
The meter unit according to claim 2, wherein the first distance between the pipe shaft and the first valve seat is shorter than the inner diameter dimension of the pipe portion. The pipe axis and the axis line intersect vertically, and
The meter unit according to claim 2, wherein the second distance between the pipe shaft and the second valve seat is shorter than twice the inner diameter dimension of the pipe portion. The meter unit according to any one of claims 1 to 4, wherein the pipe joint portion is closed at one end of the pipe portion in the pipe axis direction.

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