JP6565450B2 - Pipe fitting - Google Patents

Description

  The present invention relates to a pipe joint, and more particularly, to a pipe joint having a high tolerance for torsional deformation of piping.

Conventionally, piping is used for fluid transfer. Such pipes are widely used for large-scale plant facilities and buildings as well as being installed as a part of mechanical devices.
In the piping, the piping itself may be deformed due to a temperature change, and may be deformed due to the facility or building in which the piping is installed.

In general, the deformation of a pipe is not only the deformation of its cross-sectional shape, but also the deformation of the pipe axis, that is, expansion (displacement in the axial direction of the pipe), axial deviation (displacement in the shearing direction of the pipe), bending (axial direction of the pipe) ) And twist (rotation around the axis of the pipe).
If such deformation is excessive, the piping may be damaged.
In view of this, a pipe joint having an allowance for deformation is installed in the middle of the pipe to mitigate the deformation, thereby avoiding damage caused by the deformation of the pipe.

Patent Document 1 describes a pipe joint in which a pair of flanges are connected by a pipe main body part having an unevenness in the axial direction around the pipe body, and a plurality of tie rods connecting the pair of flanges are arranged around the pipe main body part. ing.
Moreover, as a prior art, a pipe joint is described in which a pair of flanges are connected by bellows having concaves and convexes continuous in the circumferential direction, and a plurality of tie rods connecting the pair of flanges are arranged around the flanges.

Among these, pipe joints using bellows can permit expansion / contraction, bending and axial displacement of the pipe, but are not sufficiently tolerant of twisting.
On the other hand, by using the tube main body portion in which the unevenness in the axial direction is formed, it is possible to increase the tolerance for twisting while allowing bending and axial deviation of the pipe.

In Patent Document 2, an inner tube is inserted into an outer tube to form a double tube structure, and a gap is secured by sealing each gap, and the outer tube is helically disposed around the outer tube. A pipe joint is described in which a plurality of springs maintain a mechanical connection between the inner pipe and the outer pipe.
This pipe joint prevents vibration transmission by using an inner pipe and an outer pipe as separate members, but this double pipe structure can permit expansion and contraction and twisting of the pipe.

JP 2009-19655 A JP-A-9-189389

In recent years, plant facilities and buildings have been required to take measures against earthquakes and other large-scale disasters. The piping installed in these facilities is also designed to avoid damage even if large deformation occurs in the piping itself. It is demanded.
Specifically, in pipe joints, it is required to increase the tolerance for deformation, that is, expansion / contraction, axial deviation, bending, and twisting of pipes, and in particular, the tolerance for twisting deformation.

However, in the pipe joint of Patent Document 1 described above, although the torsional tolerance is improved by the pipe main body portion having the unevenness in the axial direction, due to the mechanical restrictions of the tie rod, etc., +10 degrees around the axis About −10 degrees is the limit, and it is difficult to further improve the tolerance.
Further, in the pipe joint of Patent Document 2, although the double pipe structure itself has a high tolerance for twisting, the outer cylinder spring is structurally restricted, and it is difficult to further improve the tolerance.

By the way, even if the tolerance of individual torsional deformation of the pipe joint is not sufficient, it is possible to increase the overall tolerance by using a plurality of pipe joints in series.
However, such a combination of pipe joints has many adverse effects such as a complicated piping configuration, an increase in installation space, and an increase in equipment cost, which are difficult to employ.

  An object of the present invention is to provide a pipe joint having a simple configuration and high tolerance for torsional deformation.

The present invention is installed in the first pipe and the connecting portion of the second pipe plant facilities, a first end member to which the first pipe is connected, and a second end member in which the second pipe is connected, A pipe joint provided between the first end member and the second end member and having a cylindrical portion that communicates the inside of the first pipe and the inside of the second pipe, The portion includes an inner cylinder connected to the first end member, an outer cylinder connected to the second end member and arranged concentrically with the inner cylinder on the outer side of the inner cylinder, and an outer periphery of the inner cylinder A winding plate spring disposed concentrically with the inner cylinder between the inner cylinder and the inner circumference of the outer cylinder, and sealing means for sealing between the inner cylinder and the outer cylinder, Is formed in a cylindrical shape surrounding the inner cylinder, the inner edge of the coil spring is fixed to the outer surface of the inner cylinder, and the outer edge of the coil spring is Is fixed to the inner surface of serial barrel, the winding plate spring, the winding plate spring along the central axis of the tubular portion are arrayed, and adjacent, the feature that it is wound in opposite directions to each other To do.

In such this invention, an inner cylinder and an outer cylinder are connected via a coil spring, and are integrated as a cylindrical part. That is, a 1st end member and an inner cylinder, and a 2nd end member and an outer cylinder are integrated as a pipe joint by connecting via a coil spring.
When such a pipe joint is incorporated into the pipe, first, the end of the first pipe and the end of the second pipe are arranged to face each other, the pipe joint is arranged between each, and the first pipe is attached to the first end member. And the second pipe is connected to the second end member.
Thereby, 1st piping and 2nd piping are connected by the cylindrical part.

In the pipe joint of the present invention, even when deformations such as expansion, contraction, axial deviation, bending, and twisting occur between the first pipe and the second pipe, these deformations can be permitted by the coil spring.
When the deformation is displacement in each central axis direction, that is, expansion and contraction deformation, the inner side of the coil spring can be displaced in the central axis direction with respect to the outer side, and the inner cylinder can be displaced in the central axis direction with respect to the outer cylinder. . Thereby, expansion-contraction deformation can be permitted.
When the deformation is a shift of each central axis, the central axis of the outer cylinder can be translated with respect to the central axis of the inner cylinder while compressing the winding spring to one side. Thereby, an axial deviation deformation | transformation can be accept | permitted.

When the deformation is an inclination of each central axis, that is, a bending deformation, the coil spring is compressed to one side on one side in the axial direction, and compressed in the opposite direction on the other side, with respect to the central axis of the inner cylinder The central axis of the outer cylinder can be inclined. Thereby, bending deformation can be permitted.
When the deformation is a twist about each central axis, the inner cylinder and the outer cylinder can be relatively rotated about the central axis while winding or unwinding the wound spring. Thereby, twist deformation can be permitted.

  Thus, in the pipe joint of the present invention, it is possible to cope with each deformation of expansion / contraction, axial deviation, bending and twisting. In particular, by using a wound plate spring, mechanical restrictions on torsional deformation can be relaxed, and the allowable range of torsional deformation can be increased. For example, in the pipe joint of the present invention, an allowable range of +45 degrees to -45 degrees can be ensured as torsional deformation around the axis.

Furthermore, in the pipe joint of the present invention, even when subjected to torsional deformation, the deformation allowance of the coil spring, that is, the change in outer diameter can be suppressed.
For example, in the pipe joint of the present invention, the outer diameter fluctuation of the wound leaf spring can be suppressed to 13% or less even if the number of turns is one. If the number of turns of the coil spring is two, the outer diameter fluctuation can be about 6%, and if the number of turns is three, the outer diameter fluctuation can be about 4%.
As described above, since the change in the outer diameter of the coil spring when torsional deformation can be reduced, the coil spring can be reliably accommodated in the space between the outer surface of the inner cylinder and the inner surface of the outer cylinder.

As described above, the pipe joint of the present invention can cope with each deformation of expansion, contraction, axial deviation, bending, and twisting, and in the cylindrical portion, the space between the inner cylinder and the outer cylinder is sealed by the sealing means. Therefore, the fluid flowing between the first pipe and the second pipe does not leak out.
As described above, according to the present invention, the first end member and the inner cylinder, the second end member and the outer cylinder, and the winding spring and the sealing means between them have a simple configuration and high tolerance for torsional deformation. A pipe joint can be realized.
Furthermore, in this invention, the characteristic for every twist direction at the time of respond | corresponding to a twist deformation | transformation can be arrange | equalized by combining and using the several leaf | plate spring with which the winding direction was reverse.
Further, since a plurality of coil springs are arranged in the axial direction, the deformability in the axial direction is increased and the tolerance for expansion and contraction can be increased as compared with the case where a single coil spring is used.

  In the present invention, it is desirable that the number of turns around the central axis of the cylindrical portion is 2 times or more and 3 times or less.

According to the present invention as described above, it is possible to avoid an increase in weight accompanying an increase in the number of turns while suppressing fluctuations in the outer diameter during torsional deformation.
Here, the number of windings of the coil spring is 2 times or more and 3 or less means that the coil is wound in the range of 720 degrees (2 times) to 1080 degrees (3 times) around the central axis of the coil spring. .

The outer diameter fluctuation when the twist deformation is +45 degrees to −45 degrees (by π / 4 radians in the + direction and the − direction) in the wound spring having the diameter D and the number n of turns can be calculated as follows.
Since the twist angle per winding number is (π / 4) / n = π / 4n, the displacement amount ΔL is:
ΔL = D / 2 × π / 4n = πD / (8n)
It becomes. It can be said that the perimeter L per winding of the wound plate spring when subjected to torsional deformation is relatively short. Therefore, the circumferential length L ′ per winding after the torsional deformation is:
L ′ = D × π−πD / 8n = (1-1 / 8n) · πD
Thus, with the circumference L = πD when there is no twist deformation, the outer diameter varies by (1 / 8n).

  That is, if the number of turns is 1, the shrinkage rate is 1/8 (12.5%), if the number of turns is 1.5, the shrinkage rate is 1/12 (8.3%), if the number of turns is 2, the shrinkage rate is 1/16 (6.25%). If 2.5, the shrinkage ratio is 1/20 (5.0%), if the number of turns is 3, the shrinkage ratio is 1/24 (4.2%), if the number of turns is 3.5, the shrinkage ratio is 1/28 (3.6%), and the number of turns is 4. If so, the shrinkage rate is 1/32 (3.1%).

Accordingly, when the number of turns is less than two, the outer diameter fluctuation becomes remarkable, and it is necessary to take measures such as increasing the diameter of the outer cylinder.
On the other hand, when the number of turns is more than three, the plate material, which is the material of the wound plate spring, becomes longer and the material cost and weight increase, although there is not much change in the outer diameter fluctuation.
Therefore, it can be said that it is practically preferable that the number of turns of the wound leaf spring is 2 times or more and 3 times or less.

  In the present invention, it is desirable that the sealing means is a sealing material filled between the inner cylinder and the outer cylinder, and the wound spring is surrounded by the sealing material.

In the present invention, the fluid that passes through the inside of the inner cylinder through the space between the inner cylinder and the outer cylinder can be prevented from leaking by the sealing material filled between the inner cylinder and the outer cylinder.
At this time, the gap between the inner cylinder and the outer cylinder can be shared by the sealing material and the coil spring, and can be sealed with a sufficient length in the axial direction of the cylindrical portion. The sealing performance can be made sufficient.

Furthermore, if a silicone resin having flexibility even when solidified as a sealing material is used, vibrations of the wound spring surrounded by the sealing material can be suppressed.
Note that the sealing means is not limited to filling with the sealing material, and may have other configurations. For example, an elastomer material seal member may be installed between the inner cylinder and the outer cylinder adjacent to the coil spring, or a mechanical seal such as a labyrinth seal may be installed.

In the present invention, it is preferable that a fastening member that connects the first end member and the second end member and can be elastically deformed and extended is installed outside the outer cylinder.
A plurality of such fastening members may be arranged at predetermined intervals on the outer periphery of the outer cylinder. The fastening member can be a bar or rope or coil spring-like member made of metal or synthetic resin (including fiber reinforcement).

  In such this invention, a 1st end member and a 2nd end member are connected by a fastening member, and each relative movement is suppressed. For this reason, even when the first pipe and the second pipe are largely displaced relative to each other, it is possible to suppress the large deformation of the cylindrical portion. In particular, since the fastening member is elastically deformable, even when the first pipe and the second pipe are relatively rotated around the central axis of the cylindrical portion, the first end member and the second pipe are extended by the fastening member extending. It is possible to avoid inconveniences such as excessive pulling of the end member and pressing of the cylindrical portion in the central axis direction.

  According to the present invention, it is possible to provide a pipe joint having a simple structure and high tolerance for torsional deformation.

The perspective view which shows the pipe joint of 1st Embodiment of this invention. The top view which shows the pipe joint of the said 1st Embodiment. Sectional drawing which shows the pipe joint of the said 1st Embodiment. The disassembled perspective view which shows the pipe joint of the said 1st Embodiment. Sectional drawing which shows the pipe joint of 2nd Embodiment of this invention. Sectional drawing which shows the pipe joint of 3rd Embodiment of this invention. The side view which shows the pipe joint of 4th Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
1 to 4 show a pipe joint 1 according to a first embodiment of the present invention.
As shown in FIG. 3, the pipe joint 1 connects a first pipe 91 and a second pipe 92 that are disposed to face each other in the direction of the axis A.

The 1st piping 91 and the 2nd piping 92 of this embodiment are piping of plant equipment, for example, have a scale of about 1 m in diameter.
The pipe joint 1 of the present embodiment has a first end member 11 to which a first pipe 91 is connected and a second end member 21 to which a second pipe 92 is connected, and the first pipe is interposed between each of them. A cylindrical portion 9 is provided to allow 91 and the second pipe 92 to communicate with each other.

  The first end member 11 and the second end member 21 are each formed of a disk-shaped steel material, communication holes 111 and 211 are formed at the center, and a plurality of bolt holes 112 and 212 are formed at the periphery. .

  As shown in FIG. 3, the first end member 11 can be fixed to the first pipe 91 by being in close contact with the flange 911 of the first pipe 91 and inserting and tightening the bolt 912 into the bolt hole 112. it can. In the fixed state, the communication hole 111 communicates with the inside of the first pipe 91.

  Similarly, the second end member 21 can be fixed to the second pipe 92 by being in close contact with the flange 921 of the second pipe 92 and inserting and tightening the bolt 922 into the bolt hole 212. In the fixed state, the communication hole 211 is communicated with the inside of the second pipe 92.

  As shown in FIG. 3 and FIG. 4, the cylindrical portion 9 is constituted by an inner cylinder 12, an outer cylinder 22, a wound plate spring 30 and a sealing material 40, and an axis A is a central axis.

The inner cylinder 12 is formed of a steel pipe having a circular cross section, and one end of the inner cylinder 12 is fitted into the communication hole 111 of the first end member 11 and is fixed by welding the entire circumference.
The outer cylinder 22 is formed of a steel pipe having a circular section larger in diameter than the inner cylinder 12, one end of which is in contact with the surface of the second end member 21 and is fixed by welding the entire circumference.

  As shown in FIG. 4, in manufacturing the pipe joint 1, the first end member 11 and the inner cylinder 12 are welded in advance to form the first component 10, and the second end member 21 and the outer cylinder 22 are joined together. It is desirable to form the second part 20 by welding, and assemble the first part 10 and the second part 20 together with the wound leaf spring 30.

As shown in FIGS. 2 and 3, in the state where the first component 10 and the second component 20 are assembled, the front end opening of the inner cylinder 12 is disposed opposite to the communication hole 211 of the second end member 21, and the first end member A continuous flow path is formed from eleven communication holes 111.
Further, a cylindrical space is formed between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22, and the coil spring 30 is installed in this space.

Two coil springs 30 are arranged in the direction of the axis A, and the side close to the first end member 11 is the coil spring 31 and the side close to the second end member 21 is the coil spring 32.
The coil spring 30 is formed by winding a long steel plate around the axis A twice to form a cylinder (the number of turns = 2), and the inner edge 301 and the outer edge 302 are bent at right angles. Yes.

In order to connect the coil spring 30, an inner receiving portion 121 and an outer receiving portion 221 are formed along the axis A on the outer surface of the inner tube 12 and the inner surface of the outer tube 22, respectively.
As shown in FIG. 2, the coil spring 30 is disposed concentrically between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22, and the inner end edge 301 is locked to the inner receiving portion 121. The outer edge 302 is locked to the outer receiving portion 221.

When installed between the inner cylinder 12 and the outer cylinder 22, a preload in the winding direction (or the unwinding direction may be applied) is applied to the wound leaf spring 30.
For example, in a state where the inner edge 301 is locked to the inner receiving portion 121, the outer edge 302 is moved in the winding direction (or may be the unwinding direction) of the winding spring 30, so that it is against the winding spring 30. Such a preload can be applied by engaging the outer receiving portion 221 with a force generated.

As described above, the two coil springs 30 (coil springs 31 and 32) are used in the pipe joint 1 of the present embodiment.
These coil springs 31 and 32 have their preload directions opposite to each other.
Thereby, the inner cylinder 12 and the outer cylinder 22 can be made stationary at a position where the preloads of the coil springs 31 and 32 that are opposite to each other are balanced.

  The sealing material 40 is filled in a space between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22. For the sealing material 40, a silicone resin having flexibility even in a solidified state is used. As such a sealing resin, a hydraulic resin that reacts with moisture in the air, a reactive curable resin by two-component mixing, and the like can be used.

In installing the sealing material 40, the first component 10 and the second component 20 are first assembled, and at that time, the wound leaf spring 30 is assembled between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22.
Then, the fluid-state sealing material 40 is injected from the gap between the first end member 11 and the tip of the outer cylinder 22, and filled between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22. At this time, it is desirable to temporarily seal the gap between the tip of the inner cylinder 12 and the second end member 21 with a curing tape or the like.

Thereby, the sealing material 40 is filled between the inner cylinder 12 and the outer cylinder 22, and the wound plate spring 30 is immersed in the sealing material 40, that is, the wound plate spring 30 is surrounded by the sealing material 40. .
If the sealing material 40 is filled to the end of the outer cylinder 22, the sealing material 40 can be installed by solidifying the sealing material 40 in that state.

According to the present embodiment as described above, the following effects can be obtained.
In the pipe joint 1 of the present embodiment, the first pipe 91 and the second pipe 92 can be connected by the first end member 11 and the second end member 21. In the connected state, the first pipe 91 and the second pipe 92 can be communicated with each other through the inner cylinder 12 of the cylindrical portion 9. Thereby, the function as a joint is obtained.

  Further, in the connected state, the tubular portion 9 that connects the first end member 11 and the second end member 21 can be allowed to undergo expansion, contraction, bending, and twisting by the winding spring 30. In particular, even the torsional deformation extending from +45 degrees to -45 degrees can be allowed by the wound spring 30.

In the pipe joint 1 of the present embodiment, since the number of turns of the winding plate spring 30 is two, even if there is a twist deformation of 45 degrees on each side, the fluctuation of the outer diameter of the winding plate spring 30 should be about 6%. it can.
For this reason, the space between the outer surface of the inner cylinder 12 and the inner surface of the outer cylinder 22 may be secured with a width of + 6% to −6% with respect to the outer diameter of the coil spring 30, and specifically, the outer cylinder. It is sufficient that the inner diameter of 22 is 12% (6% × 2) of the outer diameter of the inner cylinder 12, and the wound plate spring 30 can be reliably accommodated in the cylindrical portion 9.

In the present embodiment, the fluid (the first pipe 91 and the fluid passing through the inside of the inner cylinder 12 through the space between the inner cylinder 12 and the outer cylinder 22 by the sealing material 40 filled between the inner cylinder 12 and the outer cylinder 22. The fluid flowing between the second pipe 92 and the second pipe 92 can be prevented from leaking.
At this time, the gap between the inner cylinder 12 and the outer cylinder 22 can be shared by the sealing material 40 and the coil spring 30, and the inner cylinder 12 and the outer cylinder 22 are sufficiently long along the axis A. Therefore, the sealing performance as the sealing means can be made sufficient.

  Further, since a flexible silicone resin or the like is used even when solidified as the sealing material 40, vibration of the wound leaf spring 30 surrounded by the sealing material 40 can be suppressed.

In the present embodiment, a first component 10 (first end member 11 and inner cylinder 12) and a second component 20 (second end member 21 and outer cylinder 22) are prepared in advance, and these are wound into a leaf spring. The pipe joint 1 can be manufactured by assembling together with 30 and filling the sealing material 40.
Thus, the pipe joint 1 of this embodiment can not only simplify the components but also simplify the manufacturing process.

In the present embodiment, since the two coil springs 31 and 32 whose winding directions are reversed are used in combination as the coil spring 30, the pipe joint 1 is used for each twist direction when dealing with torsional deformation. The characteristics can be aligned.
In addition, since the two wound plate springs 31 and 32 are arranged along the axis A, the deformability in the direction of the axis A is increased and the tolerance for expansion and contraction is increased as compared with the case where a single wound plate spring is used. Can do.

Of the component parts of the pipe joint 1, it is desirable that the natural frequency of the coil spring 30 is set to a value that does not resonate with vibrations that are received during an earthquake or the like.
For example, the load of the wound plate spring 30 can be approximated by the following equation as Young's modulus E, plate width B, plate thickness h, and radius R _n in a free state.
P = (1/24) E · B · h 3 · R n 2
The natural frequency fo of the wound leaf spring 30 is related to the spring constant K _{θ in} the torsional direction and the displacement of the pipe joint 1 in the pipes connected to the pipe joint 1 (first pipe 91 and second pipe 92). As the inertia moment I of the range portion, the following equation is obtained.
fo = (1/2) π · (K _θ / I) ⁻²
Since the spring constant K _θ in this equation is determined by the aforementioned Young's modulus E and the plate thickness h, the spring reaction force (load P) and the natural frequency fo are adjusted by the plate thickness h of the steel plate used as the wound plate spring 30. can do.

[Second Embodiment]
FIG. 5 shows a pipe joint 1A according to the second embodiment of the present invention.
In the pipe joint 1 of the first embodiment described above, the sealing material 40 is filled between the inner cylinder 12 and the outer cylinder 22 of the cylindrical portion 9.
On the other hand, in the pipe joint 1 </ b> A of the present embodiment, an elastomer seal member 41 is installed between the outer surface of the distal end portion of the inner cylinder 12 and the inner surface of the outer cylinder 22.

The seal member 41 can seal the gap between the distal end portion of the inner cylinder 12 and the second end member 21.
The seal member 41 is arranged along the axis A together with the two coil springs 30, and constitutes a cylindrical portion 9 </ b> A together with the inner cylinder 12, the outer cylinder 22, and the coil spring 30.

In such a pipe joint 1A of the present embodiment, the same effects as those of the first embodiment described above can be obtained.
However, the effect by the sealing material 40 in 1st Embodiment is not acquired. On the other hand, since the sealing member 41 made of elastomer is installed as compared with the filling of the sealing material 40, the manufacturing operation can be simplified.

[Third Embodiment]
FIG. 6 shows a pipe joint 1B according to a third embodiment of the present invention.
In the pipe joint 1 of the first embodiment described above, the first part 10 and the inner cylinder 12 form the first part 10, and the second end member 21 and the outer cylinder 22 form the second part 20. It was. Further, the inner cylinder 12, the outer cylinder 22, the two wound leaf springs 30, and the sealing material 40 are formed over substantially the entire length of the cylindrical portion 9 in the axis A direction.

On the other hand, in the pipe joint 1B of the present embodiment, the inner cylinder 12B of the first component 10B has a length equal to or less than half of the cylindrical portion 9B.
The second component 20B is formed by the second end member 21, the auxiliary cylinder 23B, and the outer cylinder 22B. Among these, the second end member 21 and the auxiliary cylinder 23B are the same as the first end member 11 and the inner cylinder 12B of the first component 10B.
Therefore, the second component 20B can be manufactured by diverting the first component 10B and connecting the outer cylinder 22B having a length equal to or less than half of the cylindrical portion 9B to the tip of the auxiliary cylinder 23B.

Two wound leaf springs 30B (31B, 32B) are installed between the inner cylinder 12B and the outer cylinder 22B, and further, a sealing material 40 is filled therein.
The length of the coil spring 30B in the direction of the axis A is half or less, but is formed in the same manner as the coil spring 30 of the first embodiment.

The sealing material 40 has an installation range of half or less, but is installed in the same manner as in the first embodiment.
These inner cylinder 12B, outer cylinder 22B, auxiliary cylinder 23B, wound leaf spring 30B, and sealing material 40 constitute a cylindrical portion 9B.

In such a pipe joint 1B of this embodiment, the same effect as that of the first embodiment described above can be obtained.
However, since the length of the inner cylinder 12B, the outer cylinder 22B, the coil spring 30B, and the sealing material 40 in the direction of the axis A is less than half compared to the first embodiment, the allowable limit of each deformation may be limited. There is.
On the other hand, the second component 20B can be manufactured using the same components as the first component 10B, and by sharing these, it is possible to improve the efficiency of conveyance or manufacturing work, reduce the conveyance or manufacturing cost, and the like. it can.

[Fourth Embodiment]
FIG. 7 shows a pipe joint 1C according to a fourth embodiment of the present invention.
The pipe joint 1C of the present embodiment has the same basic configuration as the pipe joint 1 of the first embodiment described above. That is, the cylindrical part 9 is installed between the first end member 11 and the second end member 21, the first component 10 includes the first end member 11 and the inner cylinder 12, and the second component 20 is the second component 20. A two-end member 21 and an outer cylinder 22 are provided.

A first pipe 91 is connected to the first end member 11, a second pipe 92 is connected to the second end member 21, and the first pipe 91 and the second pipe 92 are communicated with each other through the pipe joint 1 </ b> C. ing.
Here, in the pipe joint 1 </ b> C of the present embodiment, a plurality of fastening members 50 that connect the first end member 11 and the second end member 21 are installed outside the outer cylinder 22.

In the present embodiment, four fastening members 50 are installed at intervals of 90 degrees around the axis A, and both ends are fixed to the first end member 11 and the second end member 21 with nuts.
The fastening member 50 is a member that is elastically deformable and can be extended. For example, a rod made of metal, synthetic resin, or fiber reinforced resin, a rope made of a similar material, or a coil spring-like member can be used.

In such a pipe joint 1 </ b> C of this embodiment, the same effects as those of the first embodiment described above can be obtained.
Furthermore, in this embodiment, the 1st end member 11 and the 2nd end member 21 are connected by the fastening member 50, and each relative movement can be suppressed. For this reason, even if it is a case where the 1st piping 91 and the 2nd piping 92 are largely displaced, it can suppress that a big deformation | transformation arises in the cylindrical part 9. FIG.

  In particular, since the fastening member 50 is formed so as to be elastically deformable, when the first pipe 91 and the second pipe 92 rotate relative to each other around the axis A, the fastening member 50 is returned to the original position in the direction of the axis A (see FIG. 7 (indicated by a solid line in FIG. 7). By such inclination and extension, the first end member 11 and the second end member 21 are excessively drawn in the direction of the axis A along with the relative rotation, and the cylindrical portion 9 is moved in the direction of the axis A. Inconveniences such as pressure can be avoided in advance.

[Modification]
The present invention is not limited to the configuration of each of the embodiments described above, and modifications and the like within a scope that can achieve the object of the present invention are included in the present invention.
In the above-described embodiment, two winding plate springs 30 are arranged in the axis A direction, but three or more winding plate springs 30 may be arranged in the axis A direction.

In the above-described embodiment, the number of turns of the winding plate spring 30 is two, but may be three, and the number of turns between two and three times (the center angle is between 720 degrees and 1080 degrees, both ends May not be at the same angular position).
In this way, by setting the winding plate spring 30 to the number of turns of 2 times or more and 3 times or less, a change in the outer diameter can be suppressed while increasing an allowable positive of torsional deformation.
However, in the present invention, the number of turns of the winding leaf spring 30 may be less than 2 times or more than 3 times.

In the above-described embodiment, a long plate material is wound to form the wound plate spring 30. However, as a plate material wound as the wound plate spring 30, an inner edge is formed by winding a taper-shaped plate material in addition to a strip-shaped plate material having a constant width. The length in the axis A direction of 301 and the outer edge 302 may be different.
Further, when winding a plate material as the wound plate spring 30, it is not limited to winding in the continuous direction of the plate material, but a spiral in which the outer side and the inner side of the wound plate spring 30 are shifted in the axis A direction by winding the continuous direction obliquely. You may form so that it may become a shape.
However, in order to accommodate compactly, it is desirable to wind the board | plate material of the same width in the continuous direction like the said embodiment.

  Furthermore, the shapes, dimensions, and materials of the first end member 11, the second end member 21, the inner cylinder 12, the outer cylinder 22, and the like in the above-described embodiment may be appropriately changed in each implementation.

  INDUSTRIAL APPLICABILITY The present invention can be used as a pipe joint for increasing the tolerance for twisting deformation of piping.

  DESCRIPTION OF SYMBOLS 1,1A, 1B, 1C ... Pipe fitting 10, 10B ... 1st part, 11 ... 1st end member, 111 ... Communication hole, 112 ... Bolt hole, 12, 12B ... Inner cylinder, 121 ... Inner receiving part, 20 , 20B ... second part, 21 ... second end member, 211 ... communication hole, 212 ... bolt hole, 22, 22B ... outer cylinder, 221 ... outer receiving portion, 23B ... auxiliary cylinder, 30 ... coil spring, 301 ... Inner edge, 302 ... outer edge, 40 ... sealing material, 41 ... sealing member, 50 ... fastening member, 9, 9A, 9B ... cylindrical part, 91 ... first piping, 911 ... flange, 912 ... bolt, 92 2nd piping, 921 ... Flange, 922 ... Bolt, A ... Axis, D ... Diameter, L ... Circumference, n ... Number of turns, [Delta] L ... Displacement.

Claims (4)

It is installed in the first pipe and the connecting portion of the second pipe plant equipment, the first end member in which the first pipe is connected, and a second end member in which the second piping is connected, the first end A pipe joint that is installed between a member and the second end member and has a cylindrical portion that communicates the inside of the first pipe and the inside of the second pipe,
The cylindrical portion includes an inner cylinder connected to the first end member, an outer cylinder connected to the second end member and arranged concentrically with the inner cylinder on the outer side of the inner cylinder, A winding plate spring disposed concentrically with the inner cylinder between the outer periphery of the cylinder and the inner periphery of the outer cylinder, and sealing means for sealing between the inner cylinder and the outer cylinder;
The coil spring is formed in a cylindrical shape surrounding the inner cylinder, the inner edge of the coil spring is fixed to the outer surface of the inner cylinder, and the outer edge of the coil spring is the outer cylinder Fixed to the inner surface of the
A plurality of the wound leaf springs are arranged along the central axis of the cylindrical portion, and the adjacent wound leaf springs are wound in opposite directions . In the pipe joint according to claim 1,
The coiled leaf spring is characterized in that the number of turns around the central axis of the cylindrical part is 2 times or more and 3 times or less. In the pipe joint according to claim 1 or 2 ,
The pipe joint according to claim 1, wherein the sealing means is a sealing material filled between the inner cylinder and the outer cylinder, and the wound leaf spring is surrounded by the sealing material. In the pipe joint according to any one of claims 1 to 3 ,
A pipe joint characterized in that a fastening member that connects the first end member and the second end member and can be elastically deformed and extended is installed outside the outer cylinder.

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