JPH11344176A - Seismic isolation fittings for equipment piping - Google Patents

Abstract

(57) [Summary] [Problem] The space for installation is small, the place where it can be installed is expanded, the cost is low, and the force other than horizontal direction can be absorbed. A seismic isolation joint for equipment piping with good structure, simple structure and seismic isolation followability can be set arbitrarily. SOLUTION: A ball joint 6 is connected to one end of a flexible joint pipe 5 and a universal joint 4 is connected to the other end.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic isolation joint for piping for equipment installed in a seismic isolation building or the like.

[0002]

2. Description of the Related Art In a building, in order to make it a seismic isolation structure, a seismic isolation pit is provided at the foundation of the building, and a seismic isolation device using laminated rubber or the like is provided here. Horizontal displacement is absorbed by this seismic isolation device. Such a seismic isolation device using laminated rubber is effective for buildings in that it has a foundation structure that can cope with displacements of a scale that cannot be accommodated by foundation piles or slab foundations.

However, displacement during an earthquake not only acts on the building frame, but also acts on equipment piping inside and outside the building provided in the building, as a matter of course. In order to ensure the function, it is necessary that the equipment pipes installed between the non-seismic side and the seismic isolated side also have a seismic isolation structure.

[0004] Therefore, there have conventionally been various types of seismic isolation joints for making the equipment piping have a seismic isolation structure. For example, a flexible pipe is mounted on a base with rollers installed on the non-seismic side such as a foundation. A seismic isolation structure in which the horizontal displacement is absorbed by the movement of the gantry by this connection. Two flexible pipes are provided in the middle of the piping section, and a universal joint or the like expands and contracts between these flexible pipes. There is an arrangement in which a flexible joint is arranged to absorb horizontal displacement between the flexible tube and the expansion joint.

Further, as shown in FIGS. 14 and 15, the seismic isolation joint of the equipment piping is constituted by elbow pipes 22 and flexible pipes 21a and 21b made of seismic isolation rubber connected to both sides thereof. There is also one that is suspended by a control damper 23 suspended from the frame on the seismic isolation side 1, and absorbs displacement during an earthquake by the flexibility of the flexible pipes 21a and 21b and the elasticity of the control damper 23. In the figure, reference numeral 24 denotes a fixed base fixed to the building side, which is the frame of the seismic isolation side 1, and reference numeral 25 denotes a fixed base fixed to the foundation of the non-seismic side 2.

[0006] As still another example, a rubber for pressure resistance is used for a joint, and the elastic force of the rubber absorbs displacement during an earthquake.
For example, there is a type that can use both moments.

[0007]

Among the above-mentioned prior arts, those other than those using a universal joint require extra space for installing the joint, are poor in workability, and require maintenance. . Incidentally, the required space is, for example, 2 × 2 m in the case of using the first mount with rollers, the third in which the control damper is used, and the fourth in which the rubber for pressure resistance is used. in 3 to 4 m ^2, than the second one have required space of about 3m in straight section, it can not be arranged when not place to ensure such a space.

[0008] In addition, in the case where equipment such as a movable gantry and a control damper is required, the cost is increased in addition to the above. Furthermore, although the disadvantage is not fewer spaces and 0.1 m ² in need shall use a universal joint, because the displacement amount of the joint is small, when a large earthquake than it was used alone Lack of followability.

Since the seismic isolation device installed in the building is installed as described above to absorb the horizontal displacement by the laminated rubber, the seismic isolation joint 20 of each of these conventional examples is the same as that shown in FIG. As shown in ()), it is installed between the non-seismic side 2 and the seismic isolated side 1 to absorb horizontal displacement. For this reason, as shown in FIG. 16 (b), for a horizontal force, the seismic isolation joint 20 slides, for example, the manual mount slides, the control damper is displaced, the universal joint rotates, and However, as shown in FIG. 16C, stress is applied to the equipment piping as a resultant force against the force acting in the axial force direction, and as a result, the piping may be broken.

An object of the present invention is to solve the above-mentioned disadvantages of the prior art, to reduce the space for installation, to expand the place where it can be installed, to reduce the cost, and to be able to absorb forces other than in the horizontal direction. It is an object of the present invention to provide a seismic isolation joint for equipment piping that has good seismic isolation followability during an earthquake, has a simple structure, and is capable of arbitrarily setting seismic isolation followability.

[0011]

In order to achieve the above object, the present invention firstly connects a ball joint to one end of a flexible joint pipe and a universal joint to the other end thereof. The main point is that the joint is connected to the non-seismic side such as the building foundation, and the universal joint is connected to the seismic isolated side such as the building frame.

Third, ball joints are connected to both ends of the flexible joint pipe. Fourth, the number of peaks of the flexible joint pipe is provided at intervals of 10 cm. Fifth, elbow pipes are connected to both sides thereof. Composed of flexible pipe,
In a seismic isolation joint for suspending and supporting an elbow pipe, a gist is that a ball joint is connected to at least one of the flexible pipes.

According to the first aspect of the present invention, since the seismic isolation joint is constituted by the combination of the flexible joint pipe, the ball joint and the universal joint, the joint can be disposed in a small space with a simple structure. By arranging it between the seismic isolated side and the non-seismic side, it can absorb the rotational force, axial force and horizontal force at the time of the earthquake, and has high seismic isolation followability at the time of a large earthquake,
The seismic isolation followability can be set arbitrarily by selecting the overall length, elongation, etc. of each member.

According to the second aspect of the present invention, in addition to the above operation, when the seismic isolation joint is formed by combining the flexible joint pipe, the ball joint and the universal joint, the ball joint is moved to the non-seismic side. Because it is connected, the large rotational force in the 360-degree rotation direction and minute expansion and contraction are absorbed here. Also, since the universal joint is connected to the seismic isolation side, the small horizontal The force, the rotational force and the axial force are absorbed, and the axial force and the minute horizontal force are absorbed here by the elasticity of the flexible joint piping. By combining the actions of these members, a high seismic isolation followability as a whole can be obtained as a synergistic effect.

According to the third aspect of the present invention, by connecting the ball joints to both ends of the flexible joint pipe, a simple structure can be obtained as in the case where the ball joint and the universal joint are connected to both ends of the flexible joint pipe. Accordingly, it is possible to follow a displacement that cannot be followed by the flexible joint pipe alone.

According to the fourth aspect of the present invention, by providing the number of peaks of the flexible joint pipe at intervals of 10 cm,
Even when a flexible joint pipe is used alone to form a joint, the number of expansion and contraction parts increases, so that the amount of seismic isolation increases, and a predetermined seismic isolation followability can be obtained.

According to the fifth aspect of the present invention, a conventional elbow pipe and flexible pipes connected to both sides thereof are provided.
Even when using a seismic isolation joint that suspends an elbow pipe, a simple structure that simply connects a ball joint to at least one of the flexible pipes further absorbs rotational force and expansion and contraction, and provides high seismic isolation. Followability is obtained.

[0018]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping according to the present invention, in which 1 is a seismic isolation side, 2 is a non-seismic side, and a seismic isolation joint 3 of the present invention is shown in FIG. The universal joint 4 is connected to the base-isolated side 1 and the ball joint 6 is connected to the non-base-isolated side 2 to be disposed between the base-isolated side 1 and the non-base-isolated side 2. The joint 6 was connected with the flexible joint pipe 5.

As shown in FIG. 4, for example, the ball joint 6 has a socket 7 rotatably inserted into a steel body 8, and the distal end of the socket 7 is formed in a substantially spherical body 7a. In addition, the socket 7 is combined with the body 8 so as to be freely rotatable by 360 degrees, and can be extended and contracted by sliding it slightly. In addition, connecting flanges 7b and 8a protrude from ends of the body 8 and the socket 7, respectively.

As shown in FIG. 5, the universal joint 4 has, for example, a slide socket 10 slidably inserted into a steel body 9 and a spherical body 12 around an end of the slide socket 9 via an O-ring 11. Are rotatably mounted, and connection flanges 9a and 10a are protruded from ends of the body 9 and the slide socket 10, respectively. In the illustrated example, the elasticity of 60 mm and the rotation of 15 degrees can be secured.

As shown in FIG. 6, for example, the flexible joint pipe 5 is a bellows-shaped pipe made of rubber or stainless steel, and has a peak so as to secure an elasticity of about ± 50 mm for a length of 600 mm. Is determined, and flanges 5a are formed at both ends.

An installation example will be described by taking as an example a case where the seismic isolation joint 3 constituted by the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 is disposed in the seismic isolation pit 13 formed on the foundation of the building. ,
When the depth inside the seismic isolation pit 13 is 2 m, the flexible joint pipe 5 is 600 mm long, and the distance from the flexible joint pipe 5 to the universal joint 4 and the ball joint 6 is 450 mm. Joint 4 has a length of 300 mm and ball joint 6 has a length
Use a 250 mm one. The maximum operating pressure, the universal joint 4 is 10 kg / cm ^2, the ball joint 6 and 20 kg / cm ^2.

The universal joint 4 is attached to the seismic isolation side 1 and the ball joint 6 is attached to the non-seismic side 2
And the flexible joint pipe 5 is connected to the universal joint 4 by the flanges 10a and 5a.
The flexible joint pipe 5 is connected to the ball joint 6 by the flanges 7b and 5a. Thereby, the universal joint 4 is connected to the flexible joint pipe 5 so as to extend and contract and rotate freely, and the ball joint 6 is rotatably connected to the flexible joint pipe 5.

Since the space required for installation of such a seismic isolation joint 3 is 0.1 m ² in horizontal area, it can be housed in the existing shaft in the seismic isolation pit 13. In addition, the overall length and the degree of expansion and contraction of each member such as the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can be arbitrarily set according to the required seismic isolation followability.

Next, the operation will be described with reference to FIGS.
The part of the universal joint 4 connected to the seismic isolation side 1 when horizontal, axial, and rotational forces are applied to the seismic isolation joint 3 disposed between the seismic isolation side 1 and the non-seismic side 2 by an earthquake Then, when the spherical body 12 rotates with respect to the body 9, the rotational force of the rotation limit of 15 degrees or less is absorbed and the ball joint 6 connected to the non-seismic side 2 and the flexible joint pipe 5 are connected. By absorbing the rotation force of 3.4 degrees or more, the rotation of 18.4 degrees or more can be absorbed as a whole. Thereby, a horizontal displacement of 500 mm or more can be absorbed.

As for the displacement difference in the axial direction, the seismic isolation joint 3 is swung by 18.4 degrees as described above, so that the total length is 15%.
By extending from 00 mm to 1581.1 mm, the displacement difference Δt =
1581.1-1500 = 81.1 mm. And this displacement difference 81.1
mm is 50mm with flexible joint piping 5
The universal joint 4 absorbs 30 mm by sliding the slide socket 10 with respect to the body 9, and the ball joint 6 absorbs 1.1 mm, so that 81.1 mm can be absorbed as a whole.
A horizontal displacement of 0 mm can be secured.

As described above, the seismic isolation joint 3 formed by the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can cope with horizontal force, rotational force, and axial force at the time of an earthquake. In the above-described embodiment, the length and the degree of expansion and contraction of each member are determined in order to secure 500 mm as the displacement in the horizontal direction.However, each member is set in accordance with the value of the displacement in the horizontal direction to be set. May be set as appropriate.

FIG. 7 shows a second embodiment in which ball joints 6 are connected to both ends of a flexible joint pipe 5. For example, in the case of a flexible joint pipe 5 having a length of 900 mm, test data shown in FIG. According to the above, a seismic isolation of 500 mm cannot be secured by the flexible joint pipe 5 alone, but when the ball joint 6 is connected thereto, the ball joint 6 and the universal joint 4 are connected to the flexible joint pipe 5 as shown in FIG. 500 mm as if
Seismic isolation was secured.

By the way, the test data shown in FIG. 8 is the pressure comparison data of two vertical rising type (0 [kgf / cm ² ] and 10 [kgf / cm ² ]) flexible joint pipes 5 and used. The test specimen is a rubber flexible tube (trade name: Tosen Rubber) which is a product of Tosen Industry. Further, the test data shown in FIG. 9 includes data of a type in which ball joints 6 are connected to both ends of the flexible joint pipe 5 and a type in which the ball joint 6 is connected to one end of the flexible joint pipe 5 and the universal joint 4 is connected to the other end. This shows a comparison at the time of pressurization. Each flexible joint pipe 5 is made of a rubber flexible pipe (trade name: Tosen Rubber, 10 [kgf
/ cm ² ]) was used.

FIG. 10 shows a third embodiment in which a flexible joint pipe 5 made of rubber is used alone, and the number of peaks 5b of the flexible joint pipe 5 is set to 15
Fifteen peaks were provided at intervals of 10 cm for a 00 mm one. Fig. 11 is a graph showing the seismic isolation performance when such a flexible joint pipe 5 is used. The same 1500 mm length, 10 [kgf / cm ² ] type flexible joint pipe with nine peaks is added. Compared with the pressure, in the case of 15 peaks, a seismic isolation of 500 mm could be secured even with the flexible joint pipe 5 used alone.

FIG. 12 shows a fourth embodiment, in which the ball joint 6 is connected to the end of one of the flexible pipes 21a made of seismic isolation rubber in the case of the ceiling-suspended seismic isolation joint shown in FIG. . This results in a 500 mm
The seismic isolation of can now be obtained.

The test of the data shown in FIG. 13 was conducted using a rubber flexible tube (trade name: Tosen Rubber, 10 [kgf / c
m ² ]), and it was not possible to confirm the seismic isolation of 500 mm without the ball joint 6 connected. However, the load increased rapidly around 500 mm.
500mm as described above by adding ball joint 6
Seismic isolation performance was secured.

The seismic isolation joint of the present invention can be used for all utilities such as cold and hot water, steam, oil, and medical gas.

[0034]

As described above, the seismic isolation joint for equipment piping of the present invention comprises a seismic isolation joint composed of a flexible joint pipe, a ball joint, and a universal joint in addition thereto. When using a flexible joint pipe alone, the number of peaks has been increased, so it can be installed in a small space with a simple structure, and by installing this joint between the seismic isolated side and the non-seismic side , Can absorb the rotational force, axial force, and horizontal force during an earthquake, and has high seismic isolation followability during a large earthquake, and the seismic isolation followability can be arbitrarily selected by selecting the overall length and elongation of each member. Can be set.

When a seismic isolation joint is formed by combining a flexible joint pipe, a ball joint, and a universal joint, if the ball joint is connected to the non-seismic side, a large rotational force in a 360-degree rotation direction can be obtained. If the universal joint is connected to the seismic isolation side, the small horizontal force, the small rotational force and the small axial force are absorbed here by the rotational force and elasticity, and the flexible joint piping Since the axial force and the minute horizontal force are absorbed here by the elasticity, the action of each of these members is combined to obtain a higher seismic isolation followability as a whole as a synergistic effect.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 2 is an explanatory view of an operation state showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 3 is an explanatory view showing an operation principle showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 4 is a partially cutaway side view of an example of a ball joint which is a main part of an embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 5 is a partially cutaway side view of an example of a universal joint which is a main part of an embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 6 is a front view of an example of a flexible joint pipe which is a main part of the first embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 7 is an explanatory view showing a second embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 8 is a graph showing seismic isolation performance of a seismic isolation joint for equipment piping by using a flexible joint pipe alone.

FIG. 9 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a second embodiment of the present invention.

FIG. 10 is an explanatory view showing a third embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 11 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a third embodiment of the present invention.

FIG. 12 is an explanatory view showing a fourth embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 13 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a fourth embodiment of the present invention.

FIG. 14 is a plan view of a control damper type seismic isolation joint showing a conventional example.

FIG. 15 is a front view of a control damper type seismic isolation joint showing a conventional example.

FIG. 16 is an explanatory view showing the operation of a conventional seismic isolation joint.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Seismic isolation side 2 ... Non-seismic side 3 ... Seismic isolation joint 4 ... Universal joint 5 ... Flexible joint piping 5a ... Flange 5b ... Mountain part 6 ... Ball joint 7 ... Socket 7a ... Substantially spherical body part 7b ... Flange 8 ... Body 8a ... Flange 9 ... Body 9a ... Flange 10 ... Slide socket 10a ... Flange 11 ... O-ring 12 ... Spherical body 13 ... Seismic isolation pit 20 ... Seismic isolation joint 21a, 21b ... Flexible pipe 22 ... Elbow pipe 23 ... Control damper 24 , 25… Fixed stand

[Procedure amendment]

[Submission date] June 29, 1998

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Seismic isolation joint for equipment piping

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic isolation joint for piping for equipment installed in a seismic isolation building or the like.

[0002]

2. Description of the Related Art In a building, in order to make it a seismic isolation structure, a seismic isolation pit is provided at the foundation of the building, and a seismic isolation device using laminated rubber or the like is provided here. Horizontal displacement is absorbed by this seismic isolation device. Such a seismic isolation device using laminated rubber is effective for buildings in that it has a foundation structure that can cope with displacements of a scale that cannot be accommodated by foundation piles or slab foundations.

However, displacement during an earthquake not only acts on the building frame, but also acts on equipment piping inside and outside the building provided in the building, as a matter of course. In order to ensure the function, it is necessary that the equipment pipes installed between the non-seismic side and the seismic isolated side also have a seismic isolation structure.

[0004] Therefore, there have conventionally been various types of seismic isolation joints for making the equipment piping have a seismic isolation structure. For example, a flexible pipe is mounted on a base with rollers installed on the non-seismic side such as a foundation. A seismic isolation structure in which the horizontal displacement is absorbed by the movement of the gantry by this connection. Two flexible pipes are provided in the middle of the piping section, and a universal joint or the like expands and contracts between these flexible pipes. There is an arrangement in which a flexible joint is arranged to absorb horizontal displacement between the flexible tube and the expansion joint.

Further, as shown in FIGS. 13 and 14, the seismic isolation joint of the equipment piping is constituted by elbow pipes 22 and flexible pipes 21a and 21b made of seismic isolation rubber connected to both sides thereof. There is also one that is suspended by a control damper 23 suspended from the frame on the seismic isolation side 1, and absorbs displacement during an earthquake by the flexibility of the flexible pipes 21a and 21b and the elasticity of the control damper 23. In the figure, reference numeral 24 denotes a fixed base fixed to the building side, which is the frame of the seismic isolation side 1, and reference numeral 25 denotes a fixed base fixed to the foundation of the non-seismic side 2.

[0006] As still another example, a rubber for pressure resistance is used for a joint, and the elastic force of the rubber absorbs displacement during an earthquake.
For example, there is a type that can use both moments.

[0007]

Among the above-mentioned prior arts, those other than those using a universal joint require extra space for installing the joint, are poor in workability, and require maintenance. . Incidentally, the required space is, for example, 2 × 2 m in the case of using the first mount with rollers, the third in which the control damper is used, and the fourth in which the rubber for pressure resistance is used. in 3 to 4 m ^2, than the second one have required space of about 3m in straight section, it can not be arranged when not place to ensure such a space.

[0008] In addition, in the case where equipment such as a movable gantry and a control damper is required, the cost is increased in addition to the above. Furthermore, although the disadvantage is not fewer spaces and 0.1 m ² in need shall use a universal joint, because the displacement amount of the joint is small, when a large earthquake than it was used alone Lack of followability.

[0009] Since the seismic isolation device installed in the building is installed as described above so as to absorb the horizontal displacement by the laminated rubber, the seismic isolation joint 20 of each of these conventional examples is shown in FIG. As shown in ()), it is installed between the non-seismic side 2 and the seismic isolated side 1 to absorb horizontal displacement. For this reason, as shown in FIG. 15 (b), for a horizontal force, the seismic isolation joint 20 slides, for example, the manual mount slides, the control damper is displaced, the universal joint rotates, and However, as shown in FIG. 15C, stress is applied to the equipment piping as a resultant force against the force acting in the axial force direction, and as a result, the piping may be broken.

An object of the present invention is to solve the above-mentioned disadvantages of the prior art, to reduce the space for installation, to expand the place where it can be installed, to reduce the cost, and to be able to absorb forces other than in the horizontal direction. It is an object of the present invention to provide a seismic isolation joint for equipment piping that has good seismic isolation followability during an earthquake, has a simple structure, and is capable of arbitrarily setting seismic isolation followability.

[0011]

In order to achieve the above object, the present invention firstly connects a ball joint to one end of a flexible joint pipe and a universal joint to the other end thereof. The main point is that the joint is connected to the non-seismic side such as the building foundation, and the universal joint is connected to the seismic isolated side such as the building frame.

Third, ball joints are connected to both ends of the flexible joint pipe. Fourth, the number of peaks of the flexible joint pipe is provided at intervals of 10 cm. Fifth, elbow pipes are connected to both sides thereof. Composed of flexible pipe,
In a seismic isolation joint for suspending and supporting an elbow pipe, a gist is that a ball joint is connected to at least one of the flexible pipes.

According to the first aspect of the present invention, since the seismic isolation joint is constituted by the combination of the flexible joint pipe, the ball joint and the universal joint, the joint can be disposed in a small space with a simple structure. By arranging it between the seismic isolated side and the non-seismic side, it can absorb the rotational force, axial force and horizontal force at the time of the earthquake, and has high seismic isolation followability at the time of a large earthquake,
The seismic isolation followability can be set arbitrarily by selecting the overall length, elongation, etc. of each member.

According to the second aspect of the present invention, in addition to the above operation, when the seismic isolation joint is formed by combining the flexible joint pipe, the ball joint and the universal joint, the ball joint is moved to the non-seismic side. Because it is connected, the large rotational force in the 360-degree rotation direction and minute expansion and contraction are absorbed here. Also, since the universal joint is connected to the seismic isolation side, the small horizontal The force, the rotational force and the axial force are absorbed, and the axial force and the minute horizontal force are absorbed here by the elasticity of the flexible joint piping. By combining the actions of these members, a high seismic isolation followability as a whole can be obtained as a synergistic effect.

According to the third aspect of the present invention, by connecting the ball joints to both ends of the flexible joint pipe, a simple structure can be obtained as in the case where the ball joint and the universal joint are connected to both ends of the flexible joint pipe. Accordingly, it is possible to follow a displacement that cannot be followed by the flexible joint pipe alone.

According to the fourth aspect of the present invention, by providing the number of peaks of the flexible joint pipe at intervals of 10 cm,
Even when a flexible joint pipe is used alone to form a joint, the number of expansion and contraction parts increases, so that the amount of seismic isolation increases, and a predetermined seismic isolation followability can be obtained.

According to the fifth aspect of the present invention, a conventional elbow pipe and flexible pipes connected to both sides thereof are provided.
Even when using a seismic isolation joint that suspends an elbow pipe, a simple structure that simply connects a ball joint to at least one of the flexible pipes further absorbs rotational force and expansion and contraction, and provides high seismic isolation. Followability is obtained.

[0018]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping according to the present invention, in which 1 is a seismic isolation side, 2 is a non-seismic side, and a seismic isolation joint 3 of the present invention is shown in FIG. The universal joint 4 is connected to the base-isolated side 1 and the ball joint 6 is connected to the non-base-isolated side 2 to be disposed between the base-isolated side 1 and the non-base-isolated side 2. The joint 6 was connected with the flexible joint pipe 5.

As shown in FIG. 4, for example, the ball joint 6 has a socket 7 rotatably inserted into a steel body 8, and the distal end of the socket 7 is formed in a substantially spherical body 7a. In addition, the socket 7 is combined with the body 8 so as to be freely rotatable 360 degrees, and can be extended and contracted by being slid slightly. In addition, connecting flanges 7b and 8a protrude from ends of the body 8 and the socket 7, respectively.

As shown in FIG. 5, the universal joint 4 has, for example, a slide socket 10 slidably inserted into a steel body 9 and a spherical body 12 around an end of the slide socket 9 via an O-ring 11. Are rotatably mounted, and connection flanges 9a and 10a are protruded from ends of the body 9 and the slide socket 10, respectively. In the illustrated example, the elasticity of 60 mm and the rotation of 15 degrees can be secured.

As shown in FIG. 6, for example, the flexible joint pipe 5 is a bellows-like pipe made of rubber or stainless steel. The number is determined, and flanges 5a are formed at both ends.

An installation example will be described by taking as an example a case where the seismic isolation joint 3 constituted by the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 is disposed in the seismic isolation pit 13 formed on the foundation of the building. ,
When the depth inside the seismic isolation pit 13 is 2 m, the flexible joint pipe 5 has a length of 600 mm, and the distance from the flexible joint pipe 5 to the universal joint 4 and the ball joint 6 is 450 mm. Is 300mm long and ball joint 6 is long
Use a 250mm one. The maximum operating pressure, the universal joint 4 is 10 kg / cm ^2, the ball joint 6 and 20 kg / cm ^2.

The universal joint 4 is attached to the seismic isolation side 1 and the ball joint 6 is attached to the non-seismic side 2
And the flexible joint pipe 5 is connected to the universal joint 4 by the flanges 10a and 5a.
The flexible joint pipe 5 is connected to the ball joint 6 by the flanges 7b and 5a. Thereby, the universal joint 4 is connected to the flexible joint pipe 5 so as to extend and contract and rotate freely, and the ball joint 6 is rotatably connected to the flexible joint pipe 5.

Since the space required for installation of such a seismic isolation joint 3 is 0.1 m ² in horizontal area, it can be housed in the existing shaft in the seismic isolation pit 13. In addition, the overall length and the degree of expansion and contraction of each member such as the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can be arbitrarily set according to the required seismic isolation followability.

Next, the operation will be described with reference to FIGS.
The part of the universal joint 4 connected to the seismic isolation side 1 when horizontal, axial, and rotational forces are applied to the seismic isolation joint 3 disposed between the seismic isolation side 1 and the non-seismic side 2 by an earthquake Then, when the spherical body 12 rotates with respect to the body 9, the rotational force of the rotation limit of 15 degrees or less is absorbed and the ball joint 6 connected to the non-seismic side 2 and the flexible joint pipe 5 are connected. By absorbing the rotation force of 3.4 degrees or more, the rotation of 18.4 degrees or more can be absorbed as a whole. Thereby, a horizontal displacement of 500 mm or more can be absorbed.

As for the displacement difference in the axial direction, the seismic isolation joint 3 is swung by 18.4 degrees as described above, so that the total length is 15%.
By extending from 00 mm to 1581.1 mm, the displacement difference Δt =
1581.1-1500 = 81.1 mm. And this displacement difference 81.1
mm is 50mm with flexible joint piping 5
The universal joint 4 absorbs 30 mm by sliding the slide socket 10 with respect to the body 9, and the ball joint 6 absorbs 1.1 mm, so that 81.1 mm can be absorbed as a whole.
A horizontal displacement of 00 mm can be secured.

As described above, the seismic isolation joint 3 formed by the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can cope with horizontal force, rotational force, and axial force at the time of an earthquake. In the above-described embodiment, the length and the degree of expansion and contraction of each member are determined in order to secure 500 mm as the horizontal displacement.However, each member is made to correspond to the set value of the horizontal displacement. What is necessary is just to set length, expansion degree, etc. suitably.

FIG. 7 shows a second embodiment in which ball joints 6 are connected to both ends of a flexible joint pipe 5. For example, in the case of a flexible joint pipe 5 having a length of 900 mm, the test data shown in FIG. According to this, a 500 mm seismic isolation cannot be secured by the flexible joint pipe 5 alone, but when the ball joint 6 is connected to the flexible joint pipe 5, the ball joint 6 and the universal joint 4 are connected to the flexible joint pipe 5 as shown in FIG. 9. Same as 500mm
Seismic isolation was secured.

By the way, the test data shown in FIG. 8 is the pressure comparison data of two vertical rising type (0 [kgf / cm ² ] and 10 [kgf / cm ² ]) flexible joint pipes 5 and used. The test specimen is a rubber flexible tube (trade name: Tosen Rubber) which is a product of Tosen Industry. Further, the test data shown in FIG. 9 includes data of a type in which ball joints 6 are connected to both ends of the flexible joint pipe 5 and a type in which the ball joint 6 is connected to one end of the flexible joint pipe 5 and the universal joint 4 is connected to the other end. This shows a comparison at the time of pressurization. Each flexible joint pipe 5 is made of a rubber flexible pipe (trade name: Tosen Rubber, 10 [kgf
/ cm ² ]) was used.

FIG. 10 shows a third embodiment in which a flexible joint pipe 5 made of rubber is used alone, and the number of peaks 5b of the flexible joint pipe 5 is set to 15
Fifteen peaks were provided at intervals of 10 cm for a 00 mm one. Fig. 11 is a graph showing the seismic isolation performance when such a flexible joint pipe 5 is used. The same 1500 mm length, 10 [kgf / cm ² ] type flexible joint pipe with nine peaks is added. Compared with the pressure, in the case of 15 peaks, a seismic isolation of 500 mm could be secured even when the flexible joint pipe 5 was used alone.

FIG. 12 shows a fourth embodiment, in which the ball joint 6 is connected to the end of one of the flexible pipes 21a made of seismic isolation rubber in the case of the ceiling suspension type seismic isolation joint shown in FIG. .

The seismic isolation joint of the present invention can be used for all utilities such as cold and hot water, steam, oil, and medical gas.

[0033]

As described above, the seismic isolation joint for equipment piping of the present invention comprises a seismic isolation joint composed of a flexible joint pipe, a ball joint, and a universal joint in addition thereto. When using a flexible joint pipe alone, the number of peaks has been increased, so it can be installed in a small space with a simple structure, and by installing this joint between the seismic isolated side and the non-seismic side , Can absorb the rotational force, axial force, and horizontal force during an earthquake, and has high seismic isolation followability during a large earthquake, and the seismic isolation followability can be arbitrarily selected by selecting the overall length and elongation of each member. Can be set.

When a seismic isolation joint is formed by combining a flexible joint pipe, a ball joint, and a universal joint, if the ball joint is connected to the non-seismic side, a large rotational force in a 360-degree rotation direction can be obtained. If the universal joint is connected to the seismic isolation side, the small horizontal force, the small rotational force and the small axial force are absorbed here by the rotational force and elasticity, and the flexible joint piping Since the axial force and the minute horizontal force are absorbed here by the elasticity, the action of each of these members is combined to obtain a higher seismic isolation followability as a whole as a synergistic effect.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 2 is an explanatory view of an operation state showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 3 is an explanatory view showing an operation principle showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 4 is a partially cutaway side view of an example of a ball joint which is a main part of an embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 5 is a partially cutaway side view of an example of a universal joint which is a main part of an embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 6 is a front view of an example of a flexible joint pipe which is a main part of the first embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 7 is an explanatory view showing a second embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 8 is a graph showing seismic isolation performance of a seismic isolation joint for equipment piping by using a flexible joint pipe alone.

FIG. 9 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a second embodiment of the present invention.

FIG. 10 is an explanatory view showing a third embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 11 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a third embodiment of the present invention.

FIG. 12 is an explanatory view showing a fourth embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 13 is a plan view of a control damper type seismic isolation joint showing a conventional example.

FIG. 14 is a front view of a control damper type seismic isolation joint showing a conventional example.

FIG. 15 is an explanatory view showing the operation of a conventional seismic isolation joint.

[Description of Signs] 1 ... seismic isolation side 2 ... non-seismic side 3 ... seismic isolation joint 4 ... universal joint 5 ... flexible joint piping 5a ... flange 5b ... mountain part 6 ... ball joint 7 ... socket 7a ... approximately spherical body part 7b ... flange 8 ... body 8a ... flange 9 ... body 9a ... flange 10 ... slide socket 10a ... flange 11 ... O-ring 12 ... spherical body 13 ... seismic isolation pit 20 ... seismic isolation joint 21a, 21b ... flexible pipe 22 ... elbow pipe 23… Control damper 24, 25… Fixed stand

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[Submission date] April 23, 1999

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[Title of the Invention] Seismic isolation joint for equipment piping

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic isolation joint for piping for equipment installed in a seismic isolation building or the like.

[0002]

2. Description of the Related Art In a building, in order to make it a seismic isolation structure, a seismic isolation pit is provided at the foundation of the building, and a seismic isolation device using laminated rubber or the like is provided here. Horizontal displacement is absorbed by this seismic isolation device. Such a seismic isolation device using laminated rubber is effective for buildings in that it has a foundation structure that can cope with displacements of a scale that cannot be accommodated by foundation piles or slab foundations.

However, displacement during an earthquake not only acts on the building frame, but also acts on equipment piping inside and outside the building provided in the building, as a matter of course. In order to ensure the function, it is necessary that the equipment pipes installed between the non-seismic side and the seismic isolated side also have a seismic isolation structure.

[0004] Therefore, there have conventionally been various types of seismic isolation joints for making the equipment piping have a seismic isolation structure. For example, a flexible pipe is mounted on a base with rollers installed on the non-seismic side such as a foundation. A seismic isolation structure in which the horizontal displacement is absorbed by the movement of the gantry by this connection. Two flexible pipes are provided in the middle of the piping section, and a universal joint or the like expands and contracts between these flexible pipes. There is an arrangement in which a flexible joint is arranged to absorb horizontal displacement between the flexible tube and the expansion joint.

Further, as shown in FIGS. 12 and 13, the seismic isolation joint of the equipment piping is constituted by elbow pipes 22 and flexible pipes 21a and 21b made of seismic isolation rubber connected to both sides thereof. There is also one that is suspended by a control damper 23 suspended from the frame on the seismic isolation side 1, and absorbs displacement during an earthquake by the flexibility of the flexible pipes 21a and 21b and the elasticity of the control damper 23. In the figure, reference numeral 24 denotes a fixed base fixed to the building side, which is the frame of the seismic isolation side 1, and reference numeral 25 denotes a fixed base fixed to the foundation of the non-seismic side 2.

[0006] As still another example, a rubber for pressure resistance is used for a joint, and the elastic force of the rubber absorbs displacement during an earthquake.
For example, there is a type that can use both moments.

[0007]

Among the above-mentioned prior arts, those other than those using a universal joint require extra space for installing the joint, are poor in workability, and require maintenance. . Incidentally, the required space is, for example, 2 × 2 m in the case of using the first mount with rollers, the third in which the control damper is used, and the fourth in which the rubber for pressure resistance is used. in 3 to 4 m ^2, than the second one have required space of about 3m in straight section, it can not be arranged when not place to ensure such a space.

[0008] In addition, in the case where equipment such as a movable gantry and a control damper is required, the cost is increased in addition to the above. Furthermore, although the disadvantage is not fewer spaces and 0.1 m ² in need shall use a universal joint, because the displacement amount of the joint is small, when a large earthquake than it was used alone Lack of followability.

Since the seismic isolation device installed in the building is installed as described above to absorb the horizontal displacement by the laminated rubber, the seismic isolation joint 20 of each of these conventional examples is the same as that of FIG. As shown in ()), it is installed between the non-seismic side 2 and the seismic isolated side 1 to absorb horizontal displacement. For this reason, as shown in FIG. 14 (b), for horizontal force, the seismic isolation joint 20 is, for example, a slide of a manual mount, a displacement of a control damper, a rotation of a universal joint, and a flexible pipe. However, as shown in FIG. 14C, stress is applied to the equipment piping as a resultant force against the force acting in the axial force direction, and as a result, the piping may be broken.

An object of the present invention is to solve the above-mentioned disadvantages of the prior art, to reduce the space for installation, to expand the place where it can be installed, to reduce the cost, and to be able to absorb forces other than in the horizontal direction. It is an object of the present invention to provide a seismic isolation joint for equipment piping that has good seismic isolation followability during an earthquake, has a simple structure, and is capable of arbitrarily setting seismic isolation followability.

[0011]

In order to achieve the above object, the present invention firstly connects a ball joint to the non-seismic side of a flexible joint pipe, such as a building foundation, and connects the ball joint to a non-seismic side, such as a building frame. Having joined the universal joint,
Secondly, the gist is that a ball joint is connected to a non-seismic side of a flexible joint pipe such as a building foundation and a ball joint is connected to a seismic isolated side such as a building frame.

According to the first aspect of the present invention, since the seismic isolation joint is constituted by the combination of the flexible joint pipe, the ball joint and the universal joint, it can be disposed in a small space with a simple structure. By arranging it between the seismic isolated side and the non-seismic side, it can absorb the rotational force, axial force and horizontal force at the time of the earthquake, and has high seismic isolation followability at the time of a large earthquake,
The seismic isolation followability can be set arbitrarily by selecting the overall length, elongation, etc. of each member.

Further, when a seismic isolation joint is constructed by combining a flexible joint pipe, a ball joint and a universal joint, the ball joint is connected to the non-seismic side, so that a large rotation in a 360-degree rotation direction is required. Since the force and minute expansion and contraction are absorbed, and the universal joint is connected to the seismic isolation side, the minute horizontal force, the rotation force and the axial force are absorbed here by the rotational force and elasticity, and the flexible joint The axial force and the minute horizontal force are absorbed here by the elasticity of the pipe. By combining the actions of these members, a high seismic isolation followability as a whole can be obtained as a synergistic effect.

According to the second aspect of the present invention, by connecting ball joints to both ends of the flexible joint pipe, a simple structure can be obtained as in the case where the ball joint and the universal joint are connected to both ends of the flexible joint pipe. Accordingly, it is possible to follow a displacement that cannot be followed by the flexible joint pipe alone.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping according to the present invention, in which 1 is a seismic isolation side, 2 is a non-seismic side, and a seismic isolation joint 3 of the present invention is shown in FIG. The universal joint 4 is connected to the base-isolated side 1 and the ball joint 6 is connected to the non-base-isolated side 2 to be disposed between the base-isolated side 1 and the non-base-isolated side 2. The joint 6 was connected with the flexible joint pipe 5.

As shown in FIG. 4, for example, the ball joint 6 has a socket 7 rotatably inserted into a steel body 8, and the tip of the socket 7 is formed in a substantially spherical body 7a. In addition, the socket 7 is combined with the body 8 so as to be freely rotatable 360 degrees, and can be extended and contracted by being slid slightly. In addition, connecting flanges 7b and 8a protrude from ends of the body 8 and the socket 7, respectively.

As shown in FIG. 5, the universal joint 4 has, for example, a slide socket 10 slidably inserted into a steel body 9 and a spherical body 12 around an end of the slide socket 9 via an O-ring 11. Are rotatably mounted, and connection flanges 9a and 10a are protruded from ends of the body 9 and the slide socket 10, respectively. In the illustrated example, the elasticity of 60 mm and the rotation of 15 degrees can be secured.

As shown in FIG. 6, for example, the flexible joint pipe 5 is a bellows-shaped pipe made of rubber or stainless steel. The number is determined, and flanges 5a are formed at both ends.

An installation example will be described by taking as an example a case where the seismic isolation joint 3 composed of the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 is disposed in the seismic isolation pit 13 formed on the foundation of the building. ,
When the depth inside the seismic isolation pit 13 is 2 m, the flexible joint pipe 5 has a length of 600 mm, and the distance from the flexible joint pipe 5 to the universal joint 4 and the ball joint 6 is 450 mm. Is 300mm long and ball joint 6 is long
Use a 250mm one. The maximum operating pressure, the universal joint 4 is 10 kg / cm ^2, the ball joint 6 and 20 kg / cm ^2.

The universal joint 4 is attached to the base-isolated side 1 and the ball joint 6 is connected to the non-seismic side 2
And the flexible joint pipe 5 is connected to the universal joint 4 by the flanges 10a and 5a.
The flexible joint pipe 5 is connected to the ball joint 6 by the flanges 7b and 5a. Thereby, the universal joint 4 is connected to the flexible joint pipe 5 so as to extend and contract and rotate freely, and the ball joint 6 is rotatably connected to the flexible joint pipe 5.

Since the space required for installation of such a seismic isolation joint 3 is 0.1 m ² in horizontal area, it can be housed in an existing shaft in the seismic isolation pit 13. In addition, the overall length and the degree of expansion and contraction of each member such as the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can be arbitrarily set according to the required seismic isolation followability.

Next, the operation will be described with reference to FIGS.
The part of the universal joint 4 connected to the seismic isolation side 1 when horizontal, axial, and rotational forces are applied to the seismic isolation joint 3 disposed between the seismic isolation side 1 and the non-seismic side 2 by an earthquake Then, when the spherical body 12 rotates with respect to the body 9, the rotational force of the rotation limit of 15 degrees or less is absorbed and the ball joint 6 connected to the non-seismic side 2 and the flexible joint pipe 5 are connected. By absorbing the rotation force of 3.4 degrees or more, the rotation of 18.4 degrees or more can be absorbed as a whole. Thereby, the displacement in the horizontal direction of 500 mm or more can be absorbed.

As for the displacement difference in the axial direction, the seismic isolation joint 3 is swung 18.4 degrees as described above, so that the total length is 15
By extending from 00 mm to 1581.1 mm, the displacement difference Δt =
1581.1-1500 = 81.1 mm. And this displacement difference 81.1
mm is 50mm with flexible joint piping 5
The universal joint 4 absorbs 30 mm by sliding the slide socket 10 with respect to the body 9, and the ball joint 6 absorbs 1.1 mm, so that 81.1 mm can be absorbed as a whole.
A horizontal displacement of 00 mm can be secured.

As described above, the seismic isolation joint 3 formed by the combination of the universal joint 4, the ball joint 6, and the flexible joint pipe 5 can cope with horizontal force, rotational force, and axial force during an earthquake. In the above-described embodiment, the length and the degree of expansion and contraction of each member are determined in order to secure 500 mm as the horizontal displacement.However, each member is made to correspond to the set value of the horizontal displacement. What is necessary is just to set length, expansion degree, etc. suitably.

FIG. 7 shows a second embodiment, in which ball joints 6 are connected to both ends of a flexible joint pipe 5. For example, in the case of a flexible joint pipe 5 having a length of 900 mm, the test data shown in FIG. According to this, a 500 mm seismic isolation cannot be secured by the flexible joint pipe 5 alone, but when the ball joint 6 is connected to the flexible joint pipe 5, the ball joint 6 and the universal joint 4 are connected to the flexible joint pipe 5 as shown in FIG. 9. Same as 500mm
Seismic isolation was secured.

By the way, the test data shown in FIG. 8 are pressure comparison data of two vertical rising type (0 [kgf / cm ² ] and 10 [kgf / cm ² ]) flexible joint pipes 5 and used. The test specimen is a rubber flexible tube (trade name: Tosen Rubber) which is a product of Tosen Industry. Further, the test data shown in FIG. 9 includes data of a type in which ball joints 6 are connected to both ends of the flexible joint pipe 5 and a type in which the ball joint 6 is connected to one end of the flexible joint pipe 5 and the universal joint 4 is connected to the other end. This shows a comparison at the time of pressurization. Each flexible joint pipe 5 is made of a rubber flexible pipe (trade name: Tosen Rubber, 10 [kgf
/ cm ² ]) was used.

FIG. 10 shows a third embodiment, in which a flexible joint pipe 5 made of rubber is used alone.
Fifteen peaks were provided at intervals of 10 cm for a 00 mm one. Fig. 11 is a graph showing the seismic isolation performance when such a flexible joint pipe 5 is used. The same 1500 mm length, 10 [kgf / cm ² ] type flexible joint pipe with nine peaks is added. Compared with the pressure, in the case of 15 peaks, a seismic isolation of 500 mm could be secured even when the flexible joint pipe 5 was used alone.

FIG. 12 shows a fourth embodiment, in which the ball joint 6 is connected to the end of one of the flexible pipes 21a made of seismic isolation rubber in the case of the ceiling-suspended type seismic isolation joint shown in FIG. .

The seismic isolation joint of the present invention can be used for all utilities such as cold and hot water, steam, oil, and medical gas.

[0030]

As described above, the seismic isolation joint for equipment piping of the present invention is constructed by combining a flexible joint pipe, a ball joint, and a universal joint in addition to this, so that it is simple. It can be installed in a small space with a simple structure, and by installing this joint between the seismic isolated side and the non-seismic side, it can absorb the rotational force, axial force, and horizontal force during an earthquake and The seismic isolation followability is high, and the seismic isolation followability can be set arbitrarily by selecting the overall length and elongation of each member.

When a seismic isolation joint is constituted by a combination of a flexible joint pipe, a ball joint and a universal joint, if the ball joint is connected to the non-seismic side, a large rotational force in a 360-degree rotation direction can be obtained. If the universal joint is connected to the seismic isolation side, the small horizontal force, the small rotational force and the small axial force are absorbed here by the rotational force and elasticity, and the flexible joint piping Since the axial force and the minute horizontal force are absorbed here by the elasticity, the action of each of these members is combined to obtain a higher seismic isolation followability as a whole as a synergistic effect.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a first embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 2 is an explanatory view of an operation state showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 3 is an explanatory view showing an operation principle showing a first embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 4 is a partially cutaway side view of an example of a ball joint which is a main part of an embodiment of a seismic isolation joint for equipment piping of the present invention.

FIG. 5 is a partially cutaway side view of an example of a universal joint which is a main part of an embodiment of a seismic isolation joint for facility piping of the present invention.

FIG. 6 is a front view of an example of a flexible joint pipe which is a main part of the first embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 7 is an explanatory view showing a second embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 8 is a graph showing seismic isolation performance of a seismic isolation joint for equipment piping by using a flexible joint pipe alone.

FIG. 9 is a graph showing seismic isolation performance of a seismic isolation joint for facility piping according to a second embodiment of the present invention.

FIG. 10 is an explanatory view showing another embodiment of the seismic isolation joint for facility piping of the present invention.

FIG. 11 is a graph showing seismic isolation performance according to another embodiment of the seismic isolation joint for equipment piping of the present invention.

FIG. 12 is a plan view of a control damper type seismic isolation joint showing a conventional example.

FIG. 13 is a front view of a control damper type seismic isolation joint showing a conventional example.

FIG. 14 is an explanatory view showing the operation of a conventional seismic isolation joint.

[Description of Signs] 1 ... seismic isolation side 2 ... non-seismic side 3 ... seismic isolation joint 4 ... universal joint 5 ... flexible joint piping 5a ... flange 5b ... mountain part 6 ... ball joint 7 ... socket 7a ... approximately spherical body part 7b ... flange 8 ... body 8a ... flange 9 ... body 9a ... flange 10 ... slide socket 10a ... flange 11 ... O-ring 12 ... spherical body 13 ... seismic isolation pit 20 ... seismic isolation joint 21a, 21b ... flexible pipe 22 ... elbow pipe 23… Control damper 24, 25… Fixed stand

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 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Makoto Oshio 2-9-1-1, Tobita-Shi, Chofu-shi, Tokyo Kashima Construction Co., Ltd.

Claims (5)

[Claims] 1. A seismic isolation joint for equipment piping, wherein a ball joint is connected to one end of a flexible joint pipe and a universal joint is connected to the other end. 2. The seismic isolation joint for equipment piping according to claim 1, wherein the ball joint is connected to a non-seismic side such as a building foundation, and the universal joint is connected to the seismic isolation side such as a building frame. 3. A seismic isolation joint for equipment piping, wherein ball joints are connected to both ends of a flexible joint pipe. 4. A seismic isolation joint for equipment piping, wherein the number of peaks of flexible joint piping is provided at intervals of 10 cm. 5. A facility pipe comprising an elbow pipe and flexible pipes connected to both sides thereof, wherein a ball joint is connected to at least one of the flexible pipes in a seismic isolation joint for suspending and supporting the elbow pipe. Seismic isolation fittings.