JP7204199B2 - Double pipe joint structure - Google Patents

Description

The present disclosure relates to a joint structure having one pipe, the other pipe, and a sleeve that connects the one pipe and the other pipe, and in particular, the fluid flowing through the one pipe and the other pipe flows out to the outside. It relates to a double pipe joint structure that can prevent external fluid from flowing into the pipe.

2. Description of the Related Art Conventionally, there has been known a joint structure having one pipe, another pipe, and a sleeve connecting the one pipe and the other pipe.

A sealing rubber ring seals between one pipe and the sleeve and between the other pipe and the sleeve.

Such a joint structure is used to convey various fluids, such as for discharging waste water.

By the way, the joint structure having such a configuration may shift due to secular change due to the influence of an earthquake or the like.

If there is a misalignment in the joint structure, it is conceivable that the fluid flowing through one pipe and the other pipe may leak outward.

JP-A-3-285137 JP-A-2005-91215 JP-A-2004-53317 Japanese Patent Application Laid-Open No. 2004-10355

The present disclosure has been made in consideration of such points, and is capable of reliably preventing leakage of the fluid flowing in the pipe and preventing external fluid from flowing into the pipe. An object of the present invention is to provide a heavy pipe joint structure.

The present disclosure includes a first outer tube, a second outer tube, a third outer tube, a first outer sleeve connecting the first outer tube and the second outer tube, and the second outer tube and the An outer pipe having a second outer sleeve connecting a third outer pipe, a first inner pipe, a second inner pipe, a third inner pipe, and connecting the first inner pipe and the second inner pipe. and a second inner sleeve connecting the second inner tube and the third inner tube, wherein the inner tube is disposed within the outer tube and the first The outer tube and the first inner tube are connected, the third outer tube and the third inner tube are connected, and the first inner tube and the second inner tube are connected to each other to form a first hinge structure. and the second inner tube and the third inner tube each have a second hinge portion connected to each other to form a second hinge structure, and the first outer tube and the Each of the second outer tubes has a third hinge portion connected to each other to form a third hinge structure, and the second outer tube and the third outer tube are connected to each other to form a fourth hinge structure. It is a double pipe joint structure, each having a fourth hinge portion that connects.

A pair of first hinge portions of the first hinge structure are rotatable relative to each other and axially movable, and a pair of second hinge portions of the second hinge structure are rotatable relative to each other. and axially movable, the pair of third hinge portions of the third hinge structure being rotatable relative to each other and axially movable, and the pair of fourth hinge portions of the fourth hinge structure being axially movable; is a double pipe joint structure that is rotatable relative to each other and axially movable.

According to the present disclosure, the first outer tube and the second outer tube are fitted to the inner surface of the first outer sleeve, and the second outer tube and the third outer tube are fitted to the inner surface of the second outer sleeve. It is a double pipe joint structure that fits together.

According to the present disclosure, the first inner tube and the second inner tube are fitted to the inner surface of the first inner sleeve, and the second inner tube and the third inner tube are fitted to the inner surface of the second inner sleeve. It is a double pipe joint structure.

In the present disclosure, the first outer tube and the first inner tube are connected via a first connecting body, and the third outer tube and the third inner tube are connected via a second connecting body. Double pipe joint structure.

As described above, according to the present disclosure, it is possible to reliably prevent the fluid flowing through the inner pipe from leaking, and prevent the external fluid from flowing into the inner pipe.

FIG. 1 is a side sectional view schematically showing an embodiment of a double pipe joint structure according to the present disclosure; FIG. FIG. 2 is a detailed view showing a first hinge structure and a second hinge structure of a double pipe joint structure according to the present disclosure; FIG. 3 is a schematic diagram showing a third hinge structure and a fourth hinge structure of the double pipe joint structure according to the present disclosure; FIG. 4 is a diagram showing a connection structure between a first outer tube and a first outer sleeve; FIG. 5 is a diagram showing a connection structure between a first inner tube and a first inner sleeve;

Hereinafter, embodiments of the double pipe joint structure according to the present disclosure will be described with reference to FIGS. 1 to 5. FIG.

Here, FIG. 1 is a side sectional view showing the double pipe joint structure according to the present disclosure, FIG. 2 is a detailed view showing the first hinge structure and the second hinge structure of the double pipe joint structure according to the present disclosure, and FIG. , a schematic diagram showing a third hinge structure and a fourth hinge structure, FIG. 4 is a diagram showing a connection structure between the first outer tube and the first outer sleeve, FIG. 5 is a diagram showing the first inner tube and the first inner sleeve is a diagram showing the connection structure of.

1 and 2 also show a simplified connection structure between the first outer tube, the second outer tube and the third outer tube, and the first outer sleeve and the second outer sleeve. Fig. 4 shows a simplified connection structure between the inner tube, the second inner tube and the third inner tube, and the first inner sleeve and the second inner sleeve;

As shown in FIGS. 1 to 5, the double pipe joint structure 1 includes a first cylindrical outer pipe 11, a second cylindrical outer pipe 12, a third cylindrical outer pipe 13, and a first outer pipe. an outer pipe 10 having a first cylindrical outer sleeve 15 connecting the pipe 11 and the second outer pipe 12 and a second cylindrical outer sleeve 17 connecting the second outer pipe 12 and the third outer pipe; , a cylindrical first inner tube 21, a cylindrical second inner tube 22, a cylindrical third inner tube 23, and a cylindrical first tube connecting the first inner tube 21 and the second inner tube 22 It comprises an inner pipe 20 having an inner sleeve 25 and a cylindrical second inner sleeve 26 connecting the second inner pipe 22 and the third inner pipe 23 .

Among them, the inner pipe 20 is arranged inside the outer pipe 10 . Also, the first outer tube 11 and the second outer tube 12 are fitted to the inner surface of the first outer sleeve 15 . Also, the second outer tube 12 and the third outer tube 13 are fitted to the inner surface of the second outer sleeve 17 . Furthermore, the first inner tube 21 and the second inner tube 22 are fitted to the inner surface of the first inner sleeve 25, and the second inner tube 22 and the third inner tube 23 are fitted to the inner surface of the second inner sleeve 26. ing.

The first outer tube 11 and the first inner tube 21 are arranged inside the first outer tube 11, for example. They are connected to each other via connectors.

Furthermore, the third outer tube 13 and the third inner tube 23 are arranged, for example, inside the third outer tube 13 and are arranged in a second connecting plate 6 such as a disk-shaped second connecting plate 6 perpendicular to the axis of the third outer tube 13 . They are connected to each other via connectors.

Since the first outer tube 11 and the first inner tube 21 are connected via the first connecting plate 5 in this way, the first inner tube 21 is held at a predetermined position inside the first outer tube 11 .

Also, since the third outer tube 13 and the third inner tube 23 are connected via the second connecting plate 6 , the third inner tube 23 is held at a predetermined position inside the third outer tube 13 .

Next, the connection structure between the first outer tube 11 and the first outer sleeve 15, the connection structure between the second outer tube 12 and the first outer sleeve 15, the second outer tube 12 and the second outer sleeve 17 and the connection structure between the third outer tube 13 and the second outer sleeve 17 will be described.

The connection structure between the first outer tube 11 and the first outer sleeve 15, the connection structure between the second outer tube 12 and the first outer sleeve 15, the second outer tube 12 and the second outer sleeve 17 and the connection structure between the third outer tube 13 and the second outer sleeve 17 are substantially the same. Description will be made with reference to FIG.

As shown in FIG. 4, the first outer sleeve 15 has a projecting portion 15a projecting radially outward from its end on the first outer tube 11 side. A seal rubber ring 16 is provided on the outer surface of the first outer tube 11 so as to contact the projecting portion 15 a of the first outer sleeve 15 .

A seal rubber ring housing 18 is attached to cover the seal rubber ring 16 provided on the outer surface of the first outer tube 11 . The seal rubber ring housing 18 holds the seal rubber ring 16 in place on the outer surface of the first outer tube 11 so that the seal rubber ring 16 enhances the sealing between the first outer tube 11 and the first outer sleeve 15. It is. Such a seal rubber ring housing 18 has a plurality of split portions 18 a divided along the circumferential direction, and each split portion 18 a is fixed by a fastening bolt 19 .

Next, the connection structure between the first inner tube 21 and the first inner sleeve 25, the connection structure between the first inner sleeve 25 and the second inner tube 22, the second inner tube 22 and the second inner sleeve 26 A connection structure between and a connection structure between the second inner sleeve 26 and the third inner tube 23 will be described.

The connection structure between the first inner tube 21 and the first inner sleeve 25, the connection structure between the first inner sleeve 25 and the second inner tube 22, the second inner tube 22 and the second inner sleeve 26 Since the connection structure between and the connection structure between the second inner sleeve 26 and the third inner tube 23 have the same structure, here the connection structure between the first inner tube 21 and the first inner sleeve 25 The connection structure will be explained with reference to FIG.

As shown in FIG. 5, the first inner sleeve 25 has a projecting portion 25a projecting radially outward from its end on the first inner tube 21 side. A seal rubber ring 28 is provided on the outer surface of the first inner tube 21 so as to contact the projecting portion 25 a of the first inner sleeve 25 .

A seal rubber ring housing 31 is attached to cover the seal rubber ring 28 provided on the outer surface of the first inner tube 21 . The seal rubber ring housing 31 holds the seal rubber ring 28 in place on the outer surface of the first inner tube 21 so that the seal rubber ring 28 enhances the sealing between the first inner tube 21 and the first inner sleeve 25. It is. Such a seal rubber ring housing 31 has a plurality of divided portions 31 a divided along the circumferential direction, and each divided portion 31 a is fixed by a fastening bolt 32 .

Also, as shown in FIGS. 1 and 2, the first inner pipe 21 is composed of a plurality of portions connected via flanges 21a, and the second inner pipe 22 is also composed of a plurality of portions connected via flanges 22a. Further, the third inner tube 23 also consists of a plurality of parts connected via a flange 23a.

By the way, as shown in FIG. 2, the first inner pipe 21 and the second inner pipe 22 of the inner pipe 20 are connected to each other via the first hinge structure 41A. Specifically, the first inner tube 21 has a first hinge portion 41 with an axially extending slot 41a, and the second inner tube 22 has a first hinge portion 41 with a pin 42a inserted into the slot 41a. By inserting the pin 42a of the first hinge portion 42 into the slot 41a of the first hinge portion 41, the first hinge portions 41, 42 can be pivotally and axially connected to each other. movably connected. A first hinge structure 41A that connects the first inner tube 21 and the second inner tube 22 is configured by the first hinge portions 41 and 42 that are rotatably and axially movably connected.

Also, the second inner pipe 22 and the third inner pipe 23 of the inner pipe 20 are connected to each other via a second hinge structure 43A. Specifically, the third inner tube 23 has a second hinge portion 43 with a slot 43a, and the second inner tube 22 has a second hinge with a pin 44a inserted in the axially extending slot 43a. A pin 44a of the second hinge portion 44 is inserted into an elongated hole 43a of the second hinge portion 43 so that the second hinge portions 43, 44 are rotatably and axially connected to each other. movably connected. A second hinge structure 42A that connects the second inner tube 22 and the third inner tube 23 is configured by the second hinge portions 43 and 44 that are rotatably and axially movably connected.

Also, the first outer pipe 11 and the second outer pipe 12 of the outer pipe 10 are connected to each other via a third hinge structure 45A. Furthermore, the second outer tube 12 and the third outer tube 13 are connected to each other via a fourth hinge structure 47A. 3 shows the configuration of the third hinge structure 45A and the fourth hinge structure 47A of the outer pipe 10. As shown in FIG.

FIG. 3 is a schematic diagram showing the third hinge structure 45A and the fourth hinge structure 47A.

In FIG. 3, the first outer pipe 11 and the second outer pipe 12 of the outer pipe 10 are connected to each other via a third hinge structure 45A. Specifically, the first outer tube 11 has a third hinge portion 45 with an axially extending slot 45a and the second outer tube 12 has a third hinge portion 45 with a pin 46a inserted into the slot 45a. By inserting the pin 46a of the third hinge portion 46 into the slot 45a of the third hinge portion 45, the third hinge portions 45, 46 are rotatably and axially connected to each other. movably connected. A third hinge structure 45A that connects the first outer tube 11 and the second outer tube 12 is formed by the third hinge portions 45 and 46 that are rotatably and axially movably connected.

Also, the second outer pipe 12 and the third outer pipe 13 of the outer pipe 10 are connected to each other via a fourth hinge structure 47A. Specifically, the third outer tube 13 has a fourth hinge portion 47 having a slot 47a, and the second outer tube 12 has a fourth hinge having a pin 48a inserted in the axially extending slot 47a. A pin 48a of the fourth hinge portion 48 is inserted into the slot 47a of the fourth hinge portion 47 to allow the fourth hinge portions 47, 48 to pivotally and axially relative to each other. movably connected. A fourth hinge structure 47A that connects the second outer tube 12 and the third outer tube 13 is constituted by the fourth hinge portions 47 and 48 that are rotatably and axially movably connected.

By the way, in FIG. 3, the third hinge structure 45A and the fourth hinge structure 47A are both rotatable around horizontally extending pins 46a and 48a. The first hinge structure 41A and the second hinge structure 43A are also pivotable about horizontally extending pins 42a and 44a, so that the first hinge structure 41A, the second hinge structure 43A and the third hinge The pivot axes of structure 45A and fourth hinge structure 47A extend horizontally.

Next, the operation of this embodiment having such a configuration will be described with reference to FIGS. 1 to 5. FIG.

First, the double pipe joint structure 1 described above is installed in a building structure. Of these, the fluid flows through the inner pipe 20 but does not flow through the outer pipe 10 . The outer pipe 10 has a function of preventing the leaked fluid from flowing outside when the fluid inside the inner pipe 20 leaks. Such a double pipe joint structure 1 shifts in the axial direction or in a direction perpendicular to the axial direction (eccentric direction), that is, in the vertical direction shown in FIGS. 1 and 2 due to an earthquake or secular change.

1 and 2 show the basic shape of the double pipe joint structure 1. FIG. The double pipe joint structure 1 shifts from this reference shape along the axial direction and the direction orthogonal to the axial direction. Specifically, the first outer tube 11 on one side of the pipe and the third outer tube 13 on the other side of the pipe are separated from each other along the axial direction, and the third outer tube is separated from the first outer tube 11 . 13 descends.

Also, the first inner pipe 21 on one pipe side and the third inner pipe 23 on the other pipe side separate from each other along the axial direction, and the third inner pipe 23 descends with respect to the first inner pipe 21 .

At this time, on the outer pipe 10 side, the first outer pipe 11 and the second outer pipe 12 slide on the inner surface of the first outer sleeve 15, and the second outer pipe 12 and the third outer pipe 13 slide on the second outer sleeve. 17, and absorbs deviations in the axial direction of the double pipe joint structure 1 and in directions orthogonal to the axial direction.

Similarly, on the inner pipe 20 side, the first inner pipe 21 and the second inner pipe 22 slide on the inner surface of the first inner sleeve 25, and the second inner pipe 22 and the third inner pipe 23 slide on the second inner sleeve 26. It slides on the inner surface and absorbs the deviation of the double pipe joint structure 1 in the axial direction and in the direction perpendicular to the axial direction.

During this time, as shown in FIGS. 1 and 2, the first inner tube 21 is connected to the first outer tube 11, so that the first inner tube 21 does not drop inside the first outer tube 11, and the first inner tube 21 does not fall. 1 held in place within the outer tube 11 .

In addition, since the third inner tube 23 is connected to the third outer tube 13, the third inner tube 23 does not drop inside the third outer tube 13 and is held at a predetermined position inside the third outer tube 13. be.

During this time, on the side of the inner pipe 20, the first inner pipe 21 and the second inner pipe 22 are rotatably and axially movably connected by a first hinge structure 41A composed of first hinge portions 41 and 42. Because they are connected to each other, axial displacement can be absorbed by this first hinge structure 41A, and the second inner tube 22 is held by the first hinge structure 41A by the first outer tube 11. It can be reliably supported by the inner tube 21 .

Further, the second inner tube 22 and the third inner tube 23 are connected to each other by a second hinge structure 43A consisting of the second hinge portions 43 and 44 which are rotatably and axially movably connected. , axial displacement can be absorbed by this second hinge structure 43A, and the second inner tube 22 is secured by the second hinge structure 43A by the third inner tube 23 held by the second outer tube 12. can support The first inner tube 21 and the second inner tube 22 are rotatably connected by a first hinge structure 41A, and the second inner tube 22 and the third inner tube 23 are also rotatably connected by a second hinge structure 43A. It is Therefore, the first hinge structure 41A and the second hinge structure 43A can also absorb the deviation in the vertical direction (see FIG. 1) perpendicular to the axial direction between the first inner pipe 21 and the third inner pipe 23. can be done.

Further, on the side of the outer pipe 10, the first outer pipe 11 and the second outer pipe 12 are rotatably and axially movably connected by a third hinge structure 45A composed of third hinge portions 45 and 46. Since they are connected to each other, axial deviation can be absorbed by this third hinge structure 45A, and the second outer tube 12 can be reliably supported by the first outer tube 11 by means of the third hinge structure 45A. can be done.

Further, the second outer tube 12 and the third outer tube 13 are connected to each other by a fourth hinge structure 47A consisting of the fourth hinge portions 47 and 48 which are rotatably and axially movably connected. , the axial deviation can be absorbed by this fourth hinge structure 47A, and the second outer tube 12 can be reliably supported by the third outer tube 13 by means of the fourth hinge structure 47A. The first outer tube 11 and the second outer tube 12 are rotatably connected by a third hinge structure 45A, and the second outer tube 12 and the third outer tube 13 are also rotatably connected by a fourth hinge structure 47A. It is Therefore, the deviation in the vertical direction (see FIG. 1) orthogonal to the axial direction between the first outer tube 11 and the third outer tube 13 can be absorbed by the third hinge structure 45A and the fourth hinge structure 47A. can be done.

Also, even if water leakage occurs between the first inner pipe 21 and the first inner sleeve 25 of the inner pipe 20, the leaked fluid will flow into the space 1A between the first connecting plate 5 and the second connecting plate 6. stay. In this case, seal rubber rings 16 are provided between the first outer tube 11 and the second outer tube 12 and the first outer sleeve 15 and between the second outer tube 12 and the third outer tube 13 and the second outer sleeve 17. Therefore, the fluid that has flowed into the space 1A between the first connecting plate 5 and the second connecting plate 6 will not flow out of the outer pipe 10 .

Also, external fluid does not enter the inner pipe 20 through the outer pipe 10 .

As described above, according to the present embodiment, even if water leakage occurs between the inner pipe 20 , for example, between the first inner pipe 21 and the first inner sleeve 25 , the fluid leaking from the inner pipe 20 can flow out of the outer pipe 10 . There is no leakage to the outside.

In the above embodiment, an example is shown in which the first connecting plate 5 is used as the first connecting body and the second connecting plate 6 is used as the second connecting body. As the second connecting bodies, a plurality of rod-shaped first connecting bodies radially extending from the center toward the periphery and a plurality of rod-shaped second connecting bodies extending radially from the center toward the periphery may be used.

1 Double pipe joint structure 5 First connection plate (first connection body)
6 Second connecting plate (second connecting body)
10 outer pipe 11 first outer pipe 12 second outer pipe 13 third outer pipe 15 first outer sleeve 16 seal rubber ring 17 second outer sleeve 18 seal rubber ring housing 20 inner pipe 21 first inner pipe 22 second inner pipe 23 Third inner tube 25 First inner sleeve 26 Second inner sleeve 28 Seal rubber ring 31 Seal rubber ring housing 41A First hinge structures 41, 42 First hinge portion 43A Second hinge structures 43, 44 Second hinge portion 45A Third hinge Structures 45, 46 Third hinge portion 47A Fourth hinge structure 47, 48 Fourth hinge portion

Claims (4)

a first outer tube, a second outer tube, a third outer tube, a first outer sleeve connecting the first outer tube and the second outer tube, the second outer tube and the third outer tube an outer pipe having a second outer sleeve connecting the
a first inner tube, a second inner tube, a third inner tube, a first inner sleeve connecting the first inner tube and the second inner tube, the second inner tube and the third inner tube an inner pipe having a second inner sleeve connecting the
the inner pipe is disposed within the outer pipe;
The first outer tube and the first inner tube are connected, the third outer tube and the third inner tube are connected,
The first inner tube and the second inner tube each have a first hinge portion connected to each other to form a first hinge structure, and the second inner tube and the third inner tube are connected to each other. , each having a second hinge portion forming a second hinge structure;
The first outer tube and the second outer tube each have a third hinge portion that is connected to each other to form a third hinge structure, and the second outer tube and the third outer tube are connected to each other. each having a fourth hinge portion constituting a fourth hinge structure;
The first outer tube and the first inner tube are connected via a first connecting body, the third outer tube and the third inner tube are connected via a second connecting body,
The first outer sleeve, the second outer tube, the second outer sleeve, the first inner sleeve, the second inner tube, and the second inner sleeve are all axially aligned with the first connecting body and the A double pipe joint structure that fits between the second connecting body . the pair of first hinge portions of the first hinge structure are rotatable relative to each other and axially movable;
the pair of second hinge portions of the second hinge structure are rotatable relative to each other and axially movable;
the pair of third hinge portions of the third hinge structure are rotatable relative to each other and axially movable;
2. The double pipe joint structure according to claim 1, wherein a pair of fourth hinge portions of said fourth hinge structure are rotatable relative to each other and axially movable. the first outer tube and the second outer tube are fitted to the inner surface of the first outer sleeve;
3. The double pipe joint structure according to claim 1, wherein said second outer pipe and said third outer pipe are fitted to the inner surface of said second outer sleeve. 4. The first inner tube and the second inner tube are fitted to the inner surface of the first inner sleeve, and the second inner tube and the third inner tube are fitted to the inner surface of the second inner sleeve. 4. The double pipe joint structure according to any one of 1 to 3.

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