JP5275171B2 - Vibration suppression support - Google Patents

Description

  The present invention relates to a vibration damping support applied to structures such as piping and tanks of a large plant such as a nuclear power plant.

  Generally, a structure such as a pipe used in a power generation plant or the like is softly supported so as to alleviate the thermal expansion of the structure due to a temperature change. On the other hand, a vibration damping device has been proposed that suppresses the stress generated in a structure by rigidly supporting these structures during an earthquake.

  For example, a mechanical snubber (mechanical vibration isolator) used for supporting a pipe or the like has a complicated mechanism such as converting a displacement in a supporting direction into a rotational motion by a mechanical element. For this reason, there is a concern that the mechanical elements will stick and will not expand and contract, and when applying this mechanical snubber to the earthquake resistant support device of the internal pump, countermeasures when excessive load due to sticking is applied to the mechanical snubber The thing which provided the safety device which open | releases connection as is proposed (patent document 1).

  In addition, a large structure that flexibly supports so as to mitigate thermal expansion of the structure due to temperature change includes, for example, a structure that supports the core of a tank type FBR of a fast breeder reactor. This is because a cylindrical body that surrounds the core disposed in the reactor vessel and forms an annular gap between which the liquid metal as a coolant exists is mechanically separated from the core. The cylindrical body is attached to the reactor vessel with a rigid support member. This support structure suppresses the rocking vibration of the core due to the damping effect based on the inertial resistance of the liquid metal in the annular gap, and allows thermal expansion and contraction due to the annular gap, even if the rocking vibration of the core is about to occur. (Patent Document 2).

  Furthermore, as shown in FIG. 4, a high-temperature pipe for flowing high-temperature and high-pressure thermal fluid and a low-temperature pipe for flowing a low-temperature fluid such as a nuclear power plant or a thermal power plant are used as the inertial resistance of such a liquid. There is a pipe damping device that suppresses vibration of the integrated double pipe. This is because a cylinder 3 for producing a vibration damping action by a fluid is provided in a double pipe in which a small-diameter inner pipe 2 is installed inside a large-diameter outer pipe 1, and the cylinder 3 is fixed in a plurality of ways. The member 4 is fixed to the outer pipe 1 or the inner pipe 2. When the inner pipe 2 vibrates greatly due to the vibration of the earthquake or the fluid flowing in and out of the inner pipe 2, the pressure of the gap fluid 5 between the inner pipe 2 and the cylinder 3 increases, and the direction of vibration in the entire inner pipe 2 A flow regime vibration force (the inertial resistance) that acts as a large force opposite to the (acceleration direction) is obtained. Therefore, the movement of the inner pipe 2 is suppressed with respect to the vibration direction, and the vibration amplitude of the pipe itself can be reduced (Patent Document 3).

JP-A-7-12981 Japanese Examined Patent Publication No. 4-26078 JP 2004-251350 A

  In this way, conventionally, vibration control means that allows thermal expansion of structures due to temperature changes for structures such as equipment and piping, and rigidly supports vibration sources such as fluids and machines and earthquakes has been proposed. Has been.

  However, in a mechanical snubber applied to piping of a nuclear power plant or the like, when high reliability is required, safety measures against sticking are necessary, and sufficient maintenance is also required. Further, for a structure in the fluid, a narrow fluid gap is provided between the structure and the support member, and a support reaction force is obtained by the flow system vibration force (the inertial resistance) generated thereby to suppress the vibration. Proposals have been made, but there are problems that can only be applied to specific structures, such as being unsuitable for structures in the air.

  The present invention has been made to solve the above-described problems, does not require special safety measures or maintenance, allows thermal expansion of the structure due to temperature changes, and is free from vibrations and vibrations of machines and the like. The purpose is to provide a highly versatile and highly reliable vibration damping support that firmly supports the structure.

The present invention has been made to solve the above problems, and the vibration damping support according to the present invention is a cylindrical pipe fixing provided on the outer circumference of the pipe to be dampened so that the inner diameter matches the outer diameter of the pipe And a double cylinder comprising an inner cylinder and an outer cylinder having an inner diameter larger than the outer diameter of the pipe fixing tool, and an inner cylinder , the inner cylinder and the pipe fixing tool are separated and connected. A supporting member for fixing, a connecting member for connecting and fixing the outer cylinder to a supporting structure, an incompressible coupled fluid enclosed in an annular gap between the double cylinders, A sealing member that seals both ends and allows relative displacement of the double cylinder, and at least one of the inner cylinder and the outer cylinder has a multi-cylindrical structure, and an annular gap between the cylinders. Is .

  According to the present invention, it is possible to provide a highly reliable vibration suppression support that can be applied not only to a fluid but also to a structure in a gas without requiring special safety measures or maintenance.

The whole block diagram of the vibration suppression support which concerns on the 1st Embodiment of this invention. Sectional drawing in the AA of FIG. The whole block diagram of the vibration suppression support which concerns on the 2nd Embodiment of this invention. The whole block diagram of the conventional vibration suppression support.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
The vibration suppression support according to the first embodiment will be described with reference to FIGS.

  As shown in FIG. 1, the vibration damping support of the present embodiment includes a pipe fixing tool 9 for attaching the vibration damping support to the pipe 8, a support beam 11 for connecting and fixing the inner cylinder 10 to the pipe fixing tool 9, and an inner cylinder 10. The outer cylinder 12 facing each other, the sealing member 13 attached to both ends of the inner cylinder 10 and the outer cylinder 12, and an incompressible coupling enclosed in an annular gap between the inner cylinder 10 and the outer cylinder 12. A connecting member 16 for connecting the fluid 14 and the outer cylinder 12 to the pin joint 15, one end is connected and fixed to the connecting member 16 via the pin joint 15, and the other end is connected and fixed to the support structure 17 via the pin joint 18. And a support arm 7. Here, as the support structure 17, a wall of a structure, a tank, an inner wall of a pipe, an outer wall, or the like can be applied. The pipe fixture 9 and the support beam 11 constitute a support member, and the support arm 7 constitutes a connecting member.

  Since the pipe fixture 9 is a cylindrical fixture and needs to absorb displacement by being integrated with the pipe, the inner surface thereof is subjected to surface treatment with a high hardness rubber or the like so as to increase the frictional resistance. It is desirable that

  An incompressible fluid such as water is used as the coupled fluid 14 sealed in the annular gap between the inner cylinder 10 and the outer cylinder 12. The sealing member 13 is made of a flexible elastic material such as rubber, and the inner cylinder 10 and the outer cylinder 12 are connected so as to follow the relative displacement between the inner cylinder 10 and the outer cylinder 12. As a specific connection method, a known method such as an adhesion method by high frequency induction heating, an adhesion method between a crosslinked rubber and a metal using an adhesive, or a direct vulcanization adhesion method in which an adhesive is adhered to a metal simultaneously with rubber molding is used. Note that the material and dimensions of the sealing member 13 are set so that the coupled fluid 14 between the cylinders 10 and 12 is not excessively deformed by the pressure during vibration.

  In the first embodiment configured as described above, for example, when the pipe 8 is deformed due to thermal expansion and deformed in the support direction (vertical direction in FIG. 1), the pipe 8 is integrated with the inner cylinder 10. It will move. Since a flexible elastic material such as rubber is used for the sealing member 13, the distance between the inner cylinder 10 and the outer cylinder 12 can be freely changed, and the coupled fluid sealed in the gap between the cylinders 10 and 12. 14 can also move annularly. Thereby, the vibration damping support can absorb the relative displacement accompanying the deformation due to thermal expansion and can act as a support for the flexible structure.

  When an earthquake occurs, the fluid-structure coupling force against the relative acceleration generated in the inner cylinder 10 and the outer cylinder 12 by the coupled fluid 14 enclosed in the gap between the cylinders 10 and 12. Therefore, the relative movement of the inner cylinder 10 and the outer cylinder 12 is suppressed, and it acts as a support for the rigid structure.

  When the heavy fluid SPT (sodium polytungstate), for example, is used as the coupled fluid 14 instead of water, the specific gravity is three times that of water, so that a larger support reaction force can be obtained. Therefore, the device can be further downsized.

  Furthermore, when a liquid metal is adopted as the coupled fluid 14, it can be used in a high-temperature environment by configuring the sealing member 13 with an elastic member made of a metal spring. The use of heavy liquid SPT (sodium polytungstate) or liquid metal as the coupling fluid 14 can also be employed in the second embodiment to be described later.

  As described above, according to the first embodiment, there is no need for special safety measures or maintenance, and it is small and highly reliable that can be applied not only to a fluid but also to a structure in a gas. Vibration suppression support can be provided.

(Second Embodiment)
Next, a vibration suppression support according to the second embodiment will be described with reference to FIG.
In addition, the same code | symbol is attached | subjected to the structure same as 1st Embodiment, and the overlapping description is made into the minimum.

  As shown in FIG. 3, the vibration damping support of the second embodiment has a multi-cylindrical structure for both the inner cylinder and the outer cylinder, and one layer of an annular gap portion in which the coupled fluid 14 between the cylinders is enclosed. 3 layers. In the first embodiment, the pipe fixture 9 for attaching the vibration damping support to the pipe 8 is used. However, in the second embodiment, the pipe 8 slides in the axial direction instead of the pipe fixture. A possible linear guide 19 is installed. In both of the first and second embodiments, a pipe fixture or a linear guide can be applied depending on the installation form of the vibration damping support.

  The inner cylinder 10 is connected and fixed by a linear guide 19 and a support beam 11. Each of the inner cylinder 10 and the outer cylinder 12 has a double cylindrical structure made of metal, for example, and the additional fluid 14 communicates between the additional outer cylinder 20 and the additional inner cylinder 21 provided in the inner cylinder 10. In order to be able to do so, they are alternately arranged via the communication port 23 provided in each cylinder. The coupling fluid 14 is a sealing functioning as an inner cylinder 10, an outer cylinder 12, an outer cylinder side plate 22 attached to a side surface of the outer cylinder 12, and a seal member that absorbs relative displacement between the outer cylinder side plate 22 and the inner cylinder 10. It is sealed by the member 13. In the outer cylinder 12, a connecting member 16 connected to the pin joint 15 and a pin joint 18 fixed to the support structure 17 are connected by the support arm 7. One of the inner cylinder 10 and the outer cylinder 12 has a double cylindrical structure, and the other has a single cylindrical structure, so that the annular gap portion in which the coupled fluid 14 is sealed has a two-layer structure. can do. Of course, the inner cylinder 10 and the outer cylinder 12 may have a triple or more structure.

  As the coupled fluid 14, an incompressible fluid such as water is used as in the first embodiment. The sealing member 13 is made of a laminated rubber or the like so as to have a flexible structure only in the radial direction of the pipe so as to follow the relative displacement between the inner cylinder 10 and the outer cylinder 12. However, the material and dimensions of the sealing member 13 are set so that the sealing member 13 is not excessively deformed by the pressure when the coupled fluid 14 of the inner cylinder 10 and the outer cylinder 12 vibrates.

  In the second embodiment configured as described above, for example, when the pipe 8 is deformed due to thermal expansion and is deformed in the support direction (vertical direction in FIG. 3), the pipe 8 is integrated with the inner circular pipe. Will move to. Since a flexible material such as laminated rubber is used for the sealing member 13, the distance between the inner cylinder 10 and the outer cylinder 12 can be freely changed, and the sealing member 13 is enclosed in a three-layer gap between the inner cylinder 10 and the outer cylinder 12. Since the coupled fluid 14 can also move in an annular shape, relative displacement due to such thermal deformation can be absorbed.

  When an earthquake occurs, the fluid-structure coupling is performed against the relative acceleration generated in the inner cylinder 10 and the outer cylinder 12 by the coupled fluid 14 sealed in the gap between the inner cylinder 10 and the outer cylinder 12. Since a force is generated, the relative movement of the inner cylinder 10 and the outer cylinder 12 is suppressed, and it acts as a support for a rigid structure.

  Therefore, the vibration damping support according to the second embodiment, like the first embodiment, softly supports and absorbs displacement due to long-period displacement such as thermal deformation of piping, For vibration sources such as flow and machines, earthquakes, etc., the structure can be rigidly supported by the fluid-structure coupling force, and the annular gap portion in which the coupling fluid 14 is enclosed is formed as a multilayer. It is possible to obtain a stronger support force. In addition, since the linear guide 19 that slides in the axial direction of the pipe 8 is installed, the deformation perpendicular to the support direction of the vibration damping support can be allowed without applying a reaction force, and the pipe itself or the vibration damping support can be allowed. It is possible to prevent excessive force from being applied to itself.

  As described above, according to the second embodiment, there is no need for special safety measures or maintenance, and it is small and more reliable that can be applied to not only fluid but also gas structures. High vibration control support can be provided.

  DESCRIPTION OF SYMBOLS 1 ... Outer piping, 2 ... Inner piping, 3 ... Cylinder, 4 ... Fixing member, 5 ... Crevice fluid, 6 ... Fixing foundation, 7 ... Support arm (connection member), 8 ... Piping (structure), 9 ... Fixing piping Tool (support member), 10 ... inner cylinder, 11 ... support beam (support member), 12 ... outer cylinder, 13 ... sealing member, 14 ... compound fluid, 15, 18 ... pin joint, 16 ... connecting member, 17 DESCRIPTION OF SYMBOLS ... Support structure, 19 ... Linear guide (slide support) (support member), 20 ... Additional outer cylinder, 21 ... Additional inner cylinder, 22 ... Outer cylinder side plate, 23 ... Communication port.

Claims (5)

A cylindrical pipe fixture provided on the outer circumference of the pipe to be damped so as to match the inner diameter with the outer diameter of the pipe; A cylinder, a support member provided inside the inner cylinder, for connecting and fixing the inner cylinder and the pipe fixing tool apart from each other, a connection member for connecting and fixing the outer cylinder to a support structure, and the double An incompressible coupled fluid sealed in an annular gap between the cylinders, and a sealing member that seals both ends of the double cylinder and allows relative displacement of the double cylinder. ,
A vibration damping support, wherein at least one of the inner cylinder and the outer cylinder has a multi-cylindrical structure, and an annular gap is formed between the cylinders . 2. The vibration damping support according to claim 1 , wherein an inner cylinder and an outer cylinder are alternately arranged in each cylinder, and the gap portion communicates with a communication port provided in each cylinder. 3. The vibration damping support according to claim 1, wherein the coupled fluid is water, sodium polytungstate, or a liquid metal. The sealing member damping support according to any one of claims 1 to 3, characterized in that an elastic member made of laminated rubber or metal spring. Wherein the support member damping support according to any one of 4 to claims 1, characterized in that a linear guide - and.

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